NAME
top - display Linux processes
SYNOPSIS
top [options]
DESCRIPTION
The top program provides a dynamic real-time view of a running system. It can display system summary information as well as a list of processes or threads currently being managed by the Linux kernel. The types of system summary information shown and the types, order and size of information displayed for processes are all user configurable and that configuration can be made persistent across restarts.
The program provides a limited interactive interface for process manipulation as well as a much more extensive interface for personal configuration -- encompassing every aspect of its operation. And while top is referred to throughout this document, you are free to name the program anything you wish. That new name, possibly an alias, will then be reflected on top’s display and used when reading and writing a configuration file.
OVERVIEW
Documentation
The remaining Table of Contents
OVERVIEW
Operation
Linux Memory Types
1. COMMAND-LINE Options
2. SUMMARY Display
a. UPTIME and LOAD Averages
b. TASK and CPU States
c. MEMORY Usage
3. FIELDS / Columns Display
a. DESCRIPTIONS of Fields
b. MANAGING Fields
4. INTERACTIVE Commands
a. GLOBAL Commands
b. SUMMARY AREA Commands
c. TASK AREA Commands
1. Appearance
2. Content
3. Size
4. Sorting
d. COLOR Mapping
5. ALTERNATE-DISPLAY Provisions
a. WINDOWS Overview
b. COMMANDS for Windows
c. SCROLLING a Window
d. SEARCHING in a Window
e. FILTERING in a Window
6. FILES
a. PERSONAL Configuration File
b. ADDING INSPECT Entries
c. SYSTEM Configuration File
d. SYSTEM Restrictions File
7. ENVIRONMENT VARIABLE(S)
8. STUPID TRICKS Sampler
a. Kernel Magic
b. Bouncing Windows
c. The Big Bird Window
d. The Ol’ Switcheroo
9. BUGS, 10. SEE Also
Operation
When operating top, the two most important keys are the help
(h or ?) key and quit (’q’) key. Alternatively,
you could simply use the traditional interrupt key (^C) when
you’re done.
When started for the first time, you’ll be presented with these traditional elements on the main top screen: 1) Summary Area; 2) Fields/Columns Header; 3) Task Area. Each of these will be explored in the sections that follow. There is also an Input/Message line between the Summary Area and Columns Header which needs no further explanation.
The main top screen is generally quite adaptive to changes in terminal dimensions under X-Windows. Other top screens may be less so, especially those with static text. It ultimately depends, however, on your particular window manager and terminal emulator. There may be occasions when their view of terminal size and current contents differs from top’s view, which is always based on operating system calls.
Following any
re-size operation, if a top screen is corrupted, appears
incomplete or disordered, simply typing something innocuous
like a punctuation character or cursor motion key will
usually restore it. In extreme cases, the following sequence
almost certainly will:
key/cmd objective
^Z suspend top
fg resume top
<Left> force a screen redraw (if necessary)
But if the
display is still corrupted, there is one more step you could
try. Insert this command after top has been suspended but
before resuming it.
key/cmd objective
reset restore your terminal settings
Note: the width of top’s display will be limited to 512 positions. Displaying all fields requires approximately 250 characters. Remaining screen width is usually allocated to any variable width columns currently visible. The variable width columns, such as COMMAND, are noted in topic 3a. DESCRIPTIONS of Fields. Actual output width may also be influenced by the -w switch, which is discussed in topic 1. COMMAND-LINE Options.
Lastly, some of
top’s screens or functions require the use of cursor
motion keys like the standard arrow keys plus the Home, End,
PgUp and PgDn keys. If your terminal or emulator does not
provide those keys, the following combinations are accepted
as alternatives:
key equivalent-keys
Left alt + h
Down alt + j
Up alt + k
Right alt + l
Home alt + ctrl + h
PgDn alt + ctrl + j
PgUp alt + ctrl + k
End alt + ctrl + l
The Up
and Down arrow keys have special significance when
prompted for line input terminated with the <Enter>
key. Those keys, or their aliases, can be used to retrieve
previous input lines which can then be edited and re-input.
And there are four additional keys available with line
oriented input.
key special-significance
Up recall older strings for re-editing
Down recall newer strings or erase entire line
Insert toggle between insert and overtype
modes
Delete character removed at cursor, moving others
left
Home jump to beginning of input line
End jump to end of input line
Linux Memory
Types
For our purposes there are three types of memory, and one is
optional. First is physical memory, a limited resource where
code and data must reside when executed or referenced. Next
is the optional swap file, where modified (dirty) memory can
be saved and later retrieved if too many demands are made on
physical memory. Lastly we have virtual memory, a nearly
unlimited resource serving the following goals:
1. abstraction,
free from physical memory addresses/limits
2. isolation, every process in a separate address space
3. sharing, a single mapping can serve multiple needs
4. flexibility, assign a virtual address to a file
Regardless of which of these forms memory may take, all are managed as pages (typically 4096 bytes) but expressed by default in top as KiB (kibibyte). The memory discussed under topic ’2c. MEMORY Usage’ deals with physical memory and the swap file for the system as a whole. The memory reviewed in topic ’3. FIELDS / Columns Display’ embraces all three memory types, but for individual processes.
For each such process, every memory page is restricted to a single quadrant from the table below. Both physical memory and virtual memory can include any of the four, while the swap file only includes #1 through #3. The memory in quadrant #4, when modified, acts as its own dedicated swap file.
Private
| Shared
1 | 2
Anonymous . stack |
. malloc() |
. brk()/sbrk() | . POSIX shm*
. mmap(PRIVATE, ANON) | . mmap(SHARED, ANON)
-----------------------+----------------------
. mmap(PRIVATE, fd) | . mmap(SHARED, fd)
File-backed . pgms/shared libs |
3 | 4
The following may help in interpreting process level memory values displayed as scalable columns and discussed under topic ’3a. DESCRIPTIONS of Fields’.
%MEM - simply
RES divided by total physical memory
CODE - the ’pgms’ portion of quadrant 3
DATA - the entire quadrant 1 portion of VIRT plus all
explicit mmap file-backed pages of quadrant 3
RES - anything occupying physical memory which, beginning
with
Linux-4.5, is the sum of the following three fields:
RSan - quadrant 1 pages, which include any
former quadrant 3 pages if modified
RSfd - quadrant 3 and quadrant 4 pages
RSsh - quadrant 2 pages
RSlk - subset of RES which cannot be swapped out (any
quadrant)
SHR - subset of RES (excludes 1, includes all
2 & 4, some 3)
SWAP - potentially any quadrant except 4
USED - simply the sum of RES and SWAP
VIRT - everything in-use and/or reserved (all quadrants)
Note: Even though program images and shared libraries are considered private to a process, they will be accounted for as shared (SHR) by the kernel.
1. COMMAND-LINE Options
Mandatory arguments to long options are mandatory for short options too.
Although not
required, the equals sign can be used with either option
form and whitespace before and/or after the ’=’
is permitted.
-b, --batch
Starts top in Batch mode, which could be useful for sending output from top to other programs or to a file. In this mode, top will not accept input and runs until the iterations limit you’ve set with the ’-n’ command-line option or until killed.
-c, --cmdline-toggle
Starts top with the last remembered ’c’ state reversed. Thus, if top was displaying command lines, now that field will show program names, and vice versa. See the ’c’ interactive command for additional information.
-d, --delay = SECS [.TENTHS]
Specifies the delay between screen updates, and overrides the corresponding value in one’s personal configuration file or the startup default. Later this can be changed with the ’d’ or ’s’ interactive commands.
Fractional seconds are honored, but a negative number is not allowed. In all cases, however, such changes are prohibited if top is running in Secure mode, except for root (unless the ’s’ command-line option was used). For additional information on Secure mode see topic 6d. SYSTEM Restrictions File.
-E, --scale-summary-mem = k | m | g | t | p | e
Instructs top to force summary
area memory to be scaled as:
k - kibibytes
m - mebibytes
g - gibibytes
t - tebibytes
p - pebibytes
e - exbibytes
Later this can be changed with the ’E’ command toggle.
-e, --scale-task-mem = k | m | g | t | p
Instructs top to force task
area memory to be scaled as:
k - kibibytes
m - mebibytes
g - gibibytes
t - tebibytes
p - pebibytes
Later this can be changed with the ’e’ command toggle.
-H, --threads-show
Instructs top to display individual threads. Without this command-line option a summation of all threads in each process is shown. Later this can be changed with the ’H’ interactive command.
-h, --help
Display usage help text, then quit.
-i, --idle-toggle
Starts top with the last remembered ’i’ state reversed. When this toggle is Off, tasks that have not used any CPU since the last update will not be displayed. For additional information regarding this toggle see topic 4c. TASK AREA Commands, SIZE.
-n, --iterations = NUMBER
Specifies the maximum number of iterations, or frames, top should produce before ending.
-O, --list-fields
This option acts as a form of help for the -o option shown below. It will cause top to print each of the available field names on a separate line, then quit. Such names are subject to NLS (National Language Support) translation.
-o, --sort-override = FIELDNAME
Specifies the name of the field on which tasks will be sorted, independent of what is reflected in the configuration file. You can prepend a ’+’ or ’-’ to the field name to also override the sort direction. A leading ’+’ will force sorting high to low, whereas a ’-’ will ensure a low to high ordering.
This option exists primarily to support automated/scripted batch mode operation.
-p, --pid = PIDLIST (as: 1,2,3, ... or -p1 -p2 -p3 ...)
Monitor only processes with specified process IDs. However, when combined with Threads mode (’H’), all processes in the thread group (see TGID) of each monitored PID will also be shown.
This option can be given up to 20 times, or you can provide a comma delimited list with up to 20 pids. Co-mingling both approaches is permitted.
A pid value of zero will be treated as the process id of the top program itself once it is running.
This is a command-line option only and should you wish to return to normal operation, it is not necessary to quit and restart top -- just issue any of these interactive commands: ’=’, ’u’ or ’U’.
The ’p’, ’u’ and ’U’ command-line options are mutually exclusive.
-S, --accum-time-toggle
Starts top with the last remembered ’S’ state reversed. When Cumulative time mode is On, each process is listed with the cpu time that it and its dead children have used. See the ’S’ interactive command for additional information regarding this mode.
-s, --secure-mode
Starts top with secure mode forced, even for root. This mode is far better controlled through a system configuration file (see topic 6. FILES).
-U, --filter-any-user = USER (as: number or name)
Display only processes with a user id or user name matching that given. This option matches on any user (real, effective, saved, or filesystem).
Prepending an exclamation point (’!’) to the user id or name instructs top to display only processes with users not matching the one provided.
The ’p’, ’U’ and ’u’ command-line options are mutually exclusive.
-u, --filter-only-euser = USER (as: number or name)
Display only processes with a user id or user name matching that given. This option matches on the effective user id only.
Prepending an exclamation point (’!’) to the user id or name instructs top to display only processes with users not matching the one provided.
The ’p’, ’U’ and ’u’ command-line options are mutually exclusive.
-V, --version
Display version information, then quit.
-w, --width [=COLUMNS]
In Batch mode, when used without an argument top will format output using the COLUMNS= and LINES= environment variables, if set. Otherwise, width will be fixed at the maximum 512 columns. With an argument, output width can be decreased or increased (up to 512) but the number of rows is considered unlimited.
In normal display mode, when used without an argument top will attempt to format output using the COLUMNS= and LINES= environment variables, if set. With an argument, output width can only be decreased, not increased. Whether using environment variables or an argument with -w, when not in Batch mode actual terminal dimensions can never be exceeded.
Note: Without the use of this command-line option, output width is always based on the terminal at which top was invoked whether or not in Batch mode.
-1, --single-cpu-toggle
Starts top with the last remembered Cpu States portion of the summary area reversed. Either all cpu information will be displayed in a single line or each cpu will be displayed separately, depending on the state of the NUMA Node command toggle (’2’).
See the ’1’ and ’2’ interactive commands for additional information.
2. SUMMARY Display
Each of the following three areas are individually controlled through one or more interactive commands. See topic 4b. SUMMARY AREA Commands for additional information regarding these provisions.
2a. UPTIME
and LOAD Averages
This portion consists of a single line containing:
program or window name, depending on display mode
current time and length of time since last boot
total number of users
system load avg over the last 1, 5 and 15 minutes
2b. TASK and
CPU States
This portion consists of a minimum of two lines. In an SMP
environment, additional lines can reflect individual CPU
state percentages.
Line 1 shows
total tasks or threads, depending on the state
of the Threads-mode toggle. That total is further classified
as:
running; sleeping; stopped; zombie
Line 2 shows CPU state percentages based on the interval since the last refresh.
As a default,
percentages for these individual categories are displayed.
Depending on your kernel version, the st field may
not be shown.
us : time running un-niced user processes
sy : time running kernel processes
ni : time running niced user processes
id : time spent in the kernel idle handler
wa : time waiting for I/O completion
hi : time spent servicing hardware interrupts
si : time spent servicing software interrupts
st : time stolen from this vm by the hypervisor
The ’sy’ value above also reflects the time running a virtual cpu for guest operating systems, including those that have been niced.
Beyond the
first tasks/threads line, there are alternate CPU display
modes available via the 4-way ’t’ command
toggle. They show an abbreviated summary consisting of these
elements:
a b c d
%Cpu(s): 75.0/25.0 100[ ... ]
Where: a) is the ’user’ (us + ni) percentage; b) is the ’system’ (sy + hi + si + guests) percentage; c) is the total percentage; and d) is one of two visual graphs of those representations. Such graphs also reflect separate ’user’ and ’system’ portions.
If the ’4’ command toggle is used to yield more than two cpus per line, results will be further abridged eliminating the a) and b) elements. However, that information is still reflected in the graph itself assuming color is active or, if not, bars vs. blocks are being shown.
See topic 4b. SUMMARY AREA Commands for additional information on the ’t’ and ’4’ command toggles.
2c. MEMORY
Usage
This portion consists of two lines which may express values
in kibibytes (KiB) through exbibytes (EiB) depending on the
scaling factor enforced with the ’E’ interactive
command. The /proc/meminfo source fields are shown in
parenthesis.
Line 1 reflects
physical memory, classified as:
total ( MemTotal )
free ( MemFree )
used ( MemTotal - MemAvailable )
buff/cache ( Buffers + Cached + SReclaimable )
Line 2 reflects
mostly virtual memory, classified as:
total ( SwapTotal )
free ( SwapFree )
used ( SwapTotal - SwapFree )
avail ( MemAvailable, which is physical memory )
The avail number on line 2 is an estimation of physical memory available for starting new applications, without swapping. Unlike the free field, it attempts to account for readily reclaimable page cache and memory slabs. It is available on kernels 3.14, emulated on kernels 2.6.27+, otherwise the same as free.
In the
alternate memory display modes, two abbreviated summary
lines are shown consisting of these elements:
a b c
GiB Mem : 18.7/15.738 [ ... ]
GiB Swap: 0.0/7.999 [ ... ]
Where: a) is the percentage used; b) is the total available; and c) is one of two visual graphs of those representations.
In the case of physical memory, the percentage represents the total minus the estimated avail noted above. The ’Mem’ graph itself is divided between the non-cached portion of used and any remaining memory not otherwise accounted for by avail. See topic 4b. SUMMARY AREA Commands and the ’m’ command for additional information on that special 4-way toggle.
This table may
help in interpreting the scaled values displayed:
KiB = kibibyte = 1024 bytes
MiB = mebibyte = 1024 KiB = 1,048,576 bytes
GiB = gibibyte = 1024 MiB = 1,073,741,824 bytes
TiB = tebibyte = 1024 GiB = 1,099,511,627,776 bytes
PiB = pebibyte = 1024 TiB = 1,125,899,906,842,624 bytes
EiB = exbibyte = 1024 PiB = 1,152,921,504,606,846,976
bytes
3. FIELDS / Columns
3a.
DESCRIPTIONS of Fields
Listed below are top’s available process fields
(columns). They are shown in strict ascii alphabetical
order. You may customize their position and whether or not
they are displayable with the ’f’ (Fields
Management) interactive command.
Any field is selectable as the sort field, and you control whether they are sorted high-to-low or low-to-high. For additional information on sort provisions see topic 4c. TASK AREA Commands, SORTING.
The fields
related to physical memory or virtual memory reference
’(KiB)’ which is the unsuffixed display mode.
Such fields may, however, be scaled from KiB through PiB.
That scaling is influenced via the ’e’
interactive command or established for startup through a
build option.
%CPU -- CPU Usage
The task’s share of the elapsed CPU time since the last screen update, expressed as a percentage of total CPU time.
In a true SMP environment, if a process is multi-threaded and top is not operating in Threads mode, amounts greater than 100% may be reported. You toggle Threads mode with the ’H’ interactive command.
Also for multi-processor environments, if Irix mode is Off, top will operate in Solaris mode where a task’s cpu usage will be divided by the total number of CPUs. You toggle Irix/Solaris modes with the ’I’ interactive command.
Note: When running in forest view mode (’V’) with children collapsed (’v’), this field will also include the CPU time of those unseen children. See topic 4c. TASK AREA Commands, CONTENT for more information regarding the ’V’ and ’v’ toggles.
%CUC -- CPU Utilization
This field is identical to %CUU below, except the percentage also reflects reaped child processes.
%CUU -- CPU Utilization
A task’s total CPU usage divided by its elapsed running time, expressed as a percentage.
If a process currently displays high CPU usage, this field can help determine if such behavior is normal. Conversely, if a process has low CPU usage currently, %CUU may reflect historically higher demands over its lifetime.
%MEM -- Memory Usage (RES)
A task’s currently resident share of available physical memory.
See ’OVERVIEW, Linux Memory Types’ for additional details.
AGID -- Autogroup Identifier
The autogroup identifier associated with a process. This feature operates in conjunction with the CFS scheduler to improve interactive desktop performance.
When /proc/sys/kernel/sched_autogroup_enabled is set, a new autogroup is created with each new session (see SID). All subsequently forked processes in that session inherit membership in this autogroup. The kernel then attempts to equalize distribution of CPU cycles across such groups. Thus, an autogroup with many CPU intensive processes (e.g make -j) will not dominate an autogroup with only one or two processes.
When -1 is displayed it means this information is not available.
AGNI -- Autogroup Nice Value
The autogroup nice value which affects scheduling of all processes in that group. A negative nice value means higher priority, whereas a positive nice value means lower priority.
CGNAME -- Control Group Name
The name of the control group to which a process belongs, or ’-’ if not applicable for that process.
This will typically be the last entry in the full list of control groups as shown under the next heading (CGROUPS). And as is true there, this field is also variable width.
CGROUPS -- Control Groups
The names of the control group(s) to which a process belongs, or ’-’ if not applicable for that process.
Control Groups provide for allocating resources (cpu, memory, network bandwidth, etc.) among installation-defined groups of processes. They enable fine-grained control over allocating, denying, prioritizing, managing and monitoring those resources.
Many different hierarchies of cgroups can exist simultaneously on a system and each hierarchy is attached to one or more subsystems. A subsystem represents a single resource.
Note: The CGROUPS field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters). Even so, such variable width fields could still suffer truncation. See topic 5c. SCROLLING a Window for additional information on accessing any truncated data.
CODE -- Code Size (KiB)
The amount of physical memory currently devoted to executable code, also known as the Text Resident Set size or TRS.
See ’OVERVIEW, Linux Memory Types’ for additional details.
COMMAND -- Command Name or Command Line
Display the command line used to start a task or the name of the associated program. You toggle between command line and name with ’c’, which is both a command-line option and an interactive command.
When
you’ve chosen to display command lines, processes
without a command line (like kernel threads) will be shown
with only the program name in brackets, as in this example:
[kthreadd]
This field may also be impacted by the forest view display mode. See the ’V’ interactive command for additional information regarding that mode.
Note: The COMMAND field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters). Even so, such variable width fields could still suffer truncation. This is especially true for this field when command lines are being displayed (the ’c’ interactive command.) See topic 5c. SCROLLING a Window for additional information on accessing any truncated data.
DATA -- Data + Stack Size (KiB)
The amount of private memory reserved by a process. It is also known as the Data Resident Set or DRS. Such memory may not yet be mapped to physical memory (RES) but will always be included in the virtual memory (VIRT) amount.
See ’OVERVIEW, Linux Memory Types’ for additional details.
ELAPSED -- Elapsed Running Time
The length of time since a process was started. Thus, the most recently started task will display the smallest time interval.
The value will be expressed as ’HH,MM’ (hours,minutes) but is subject to additional scaling if the interval becomes too great to fit column width. At that point it will be scaled to ’DD+HH’ (days+hours) and possibly beyond.
ENVIRON -- Environment variables
Display all of the environment variables, if any, as seen by the respective processes. These variables will be displayed in their raw native order, not the sorted order you are accustomed to seeing with an unqualified ’set’.
Note: The ENVIRON field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters). Even so, such variable width fields could still suffer truncation. This is especially true for this field. See topic 5c. SCROLLING a Window for additional information on accessing any truncated data.
EXE -- Executable Path
Where available, this is the full path to the executable, including the program name.
Note: The EXE field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters).
Flags -- Task Flags
This column represents the task’s current scheduling flags which are expressed in hexadecimal notation and with zeros suppressed. These flags are officially documented in <linux/sched.h>.
GID -- Group Id
The effective group ID.
GROUP -- Group Name
The effective group name.
LOGID -- Login User Id
The user ID used at login. When -1 is displayed it means this information is not available.
LXC -- Lxc Container Name
The name of the lxc container within which a task is running. If a process is not running inside a container, a dash (’-’) will be shown.
NI -- Nice Value
The nice value of the task. A negative nice value means higher priority, whereas a positive nice value means lower priority. Zero in this field simply means priority will not be adjusted in determining a task’s dispatch-ability.
Note: This value only affects scheduling priority relative to other processes in the same autogroup. See the ’AGID’ and ’AGNI’ fields for additional information on autogroups.
NU -- Last known NUMA node
A number representing the NUMA node associated with the last used processor (’P’). When -1 is displayed it means that NUMA information is not available.
See the ’2’ and ’3’ interactive commands for additional NUMA provisions affecting the summary area.
OOMa -- Out of Memory Adjustment Factor
The value, ranging from -1000 to +1000, added to the current out of memory score (OOMs) which is then used to determine which task to kill when memory is exhausted.
OOMs -- Out of Memory Score
The value, ranging from 0 to +1000, used to select task(s) to kill when memory is exhausted. Zero translates to ’never kill’ whereas 1000 means ’always kill’.
P -- Last used CPU (SMP)
A number representing the last used processor. In a true SMP environment this will likely change frequently since the kernel intentionally uses weak affinity. Also, the very act of running top may break this weak affinity and cause more processes to change CPUs more often (because of the extra demand for cpu time).
PGRP -- Process Group Id
Every process is member of a unique process group which is used for distribution of signals and by terminals to arbitrate requests for their input and output. When a process is created (forked), it becomes a member of the process group of its parent. By convention, this value equals the process ID (see PID) of the first member of a process group, called the process group leader.
PID -- Process Id
The task’s unique process ID, which periodically wraps, though never restarting at zero. In kernel terms, it is a dispatchable entity defined by a task_struct.
This value may also be used as: a process group ID (see PGRP); a session ID for the session leader (see SID); a thread group ID for the thread group leader (see TGID); and a TTY process group ID for the process group leader (see TPGID).
PPID -- Parent Process Id
The process ID (pid) of a task’s parent.
PR -- Priority
The scheduling priority of the task. If you see ’rt’ in this field, it means the task is running under real time scheduling priority.
Under linux, real time priority is somewhat misleading since traditionally the operating itself was not preemptible. And while the 2.6 kernel can be made mostly preemptible, it is not always so.
PSS -- Proportional Resident Memory, smaps (KiB)
The proportion of this task’s share of ’RSS’ where each page is divided by the number of processes sharing it. It is also the sum of the ’PSan’, ’PSfd’ and ’PSsh’ fields.
For example, if a process has 1000 resident pages alone and 1000 resident pages shared with another process, its ’PSS’ would be 1500 (times page size).
Accessing smaps values is 10x more costly than other memory statistics and data for other users requires root privileges.
PSan
-- Proportional Anonymous Memory, smaps
(KiB)
PSfd -- Proportional File Memory, smaps
(KiB)
PSsh -- Proportional Shmem Memory, smaps
(KiB)
As was true for ’PSS’ above (total proportional resident memory), these fields represent the proportion of this task’s share of each type of memory divided by the number of processes sharing it.
Accessing smaps values is 10x more costly than other memory statistics and data for other users requires root privileges.
RES -- Resident Memory Size (KiB)
A subset of the virtual address space (VIRT) representing the non-swapped physical memory a task is currently using. It is also the sum of the ’RSan’, ’RSfd’ and ’RSsh’ fields.
It can include private anonymous pages, private pages mapped to files (including program images and shared libraries) plus shared anonymous pages. All such memory is backed by the swap file represented separately under SWAP.
Lastly, this field may also include shared file-backed pages which, when modified, act as a dedicated swap file and thus will never impact SWAP.
See ’OVERVIEW, Linux Memory Types’ for additional details.
RSS -- Resident Memory, smaps (KiB)
Another, more precise view of process non-swapped physical memory. It is obtained from the ’smaps_rollup’ file and is generally slightly larger than that shown for ’RES’.
Accessing smaps values is 10x more costly than other memory statistics and data for other users requires root privileges.
RSan -- Resident Anonymous Memory Size (KiB)
A subset of resident memory (RES) representing private pages not mapped to a file.
RSfd -- Resident File-Backed Memory Size (KiB)
A subset of resident memory (RES) representing the implicitly shared pages supporting program images and shared libraries. It also includes explicit file mappings, both private and shared.
RSlk -- Resident Locked Memory Size (KiB)
A subset of resident memory (RES) which cannot be swapped out.
RSsh -- Resident Shared Memory Size (KiB)
A subset of resident memory (RES) representing the explicitly shared anonymous shm*/mmap pages.
RUID -- Real User Id
The real user ID.
RUSER -- Real User Name
The real user name.
S -- Process Status
The status of the task which
can be one of:
D = uninterruptible sleep
I = idle
R = running
S = sleeping
T = stopped by job control signal
t = stopped by debugger during trace
Z = zombie
Tasks shown as running should be more properly thought of as ready to run -- their task_struct is simply represented on the Linux run-queue. Even without a true SMP machine, you may see numerous tasks in this state depending on top’s delay interval and nice value.
SHR -- Shared Memory Size (KiB)
A subset of resident memory (RES) that may be used by other processes. It will include shared anonymous pages and shared file-backed pages. It also includes private pages mapped to files representing program images and shared libraries.
See ’OVERVIEW, Linux Memory Types’ for additional details.
SID -- Session Id
A session is a collection of process groups (see PGRP), usually established by the login shell. A newly forked process joins the session of its creator. By convention, this value equals the process ID (see PID) of the first member of the session, called the session leader, which is usually the login shell.
STARTED -- Start Time Interval
The length of time since system boot when a process started. Thus, the most recently started task will display the largest time interval.
The value will be expressed as ’MM:SS’ (minutes:seconds). But if the interval is too great to fit column width it will be scaled as ’HH,MM’ (hours,minutes) and possibly beyond.
SUID -- Saved User Id
The saved user ID.
SUPGIDS -- Supplementary Group IDs
The IDs of any supplementary group(s) established at login or inherited from a task’s parent. They are displayed in a comma delimited list.
Note: The SUPGIDS field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters).
SUPGRPS -- Supplementary Group Names
The names of any supplementary group(s) established at login or inherited from a task’s parent. They are displayed in a comma delimited list.
Note: The SUPGRPS field, unlike most columns, is not fixed-width. When displayed, it plus any other variable width columns will be allocated all remaining screen width (up to the maximum 512 characters).
SUSER -- Saved User Name
The saved user name.
SWAP -- Swapped Size (KiB)
The formerly resident portion of a task’s address space written to the swap file when physical memory becomes over committed.
See ’OVERVIEW, Linux Memory Types’ for additional details.
TGID -- Thread Group Id
The ID of the thread group to which a task belongs. It is the PID of the thread group leader. In kernel terms, it represents those tasks that share an mm_struct.
TIME -- CPU Time
Total CPU time the task has used since it started. When Cumulative mode is On, each process is listed with the cpu time that it and its dead children have used. You toggle Cumulative mode with ’S’, which is both a command-line option and an interactive command. See the ’S’ interactive command for additional information regarding this mode.
TIME+ -- CPU Time, hundredths
The same as TIME, but reflecting more granularity through hundredths of a second.
TPGID -- Tty Process Group Id
The process group ID of the foreground process for the connected tty, or -1 if a process is not connected to a terminal. By convention, this value equals the process ID (see PID) of the process group leader (see PGRP).
TTY -- Controlling Tty
The name of the controlling terminal. This is usually the device (serial port, pty, etc.) from which the process was started, and which it uses for input or output. However, a task need not be associated with a terminal, in which case you’ll see ’?’ displayed.
UID -- User Id
The effective user ID of the task’s owner.
USED -- Memory in Use (KiB)
This field represents the non-swapped physical memory a task is using (RES) plus the swapped out portion of its address space (SWAP).
See ’OVERVIEW, Linux Memory Types’ for additional details.
USER -- User Name
The effective user name of the task’s owner.
USS -- Unique Set Size
The non-swapped portion of physical memory (’RSS’) not shared with any other process. It is derived from the ’smaps_rollup’ file.
Accessing smaps values is 10x more costly than other memory statistics and data for other users requires root privileges.
VIRT -- Virtual Memory Size (KiB)
The total amount of virtual memory used by the task. It includes all code, data and shared libraries plus pages that have been swapped out and pages that have been mapped but not used.
See ’OVERVIEW, Linux Memory Types’ for additional details.
WCHAN -- Sleeping in Function
This field will show the name of the kernel function in which the task is currently sleeping. Running tasks will display a dash (’-’) in this column.
ioR -- I/O Bytes Read
The number of bytes a process caused to be fetched from the storage layer.
Root privileges are required to display ’io’ data for other users.
ioRop -- I/O Read Operations
The number of read I/O operations (syscalls) for a process. Such calls might not result in actual physical disk I/O.
ioW -- I/O Bytes Written
The number of bytes a process caused to be sent to the storage layer.
ioWop -- I/O Write Operations
The number of write I/O operations (syscalls) for a process. Such calls might not result in actual physical disk I/O.
nDRT -- Dirty Pages Count
The number of pages that have been modified since they were last written to auxiliary storage. Dirty pages must be written to auxiliary storage before the corresponding physical memory location can be used for some other virtual page.
This field was deprecated with linux 2.6 and is always zero.
nMaj -- Major Page Fault Count
The number of major page faults that have occurred for a task. A page fault occurs when a process attempts to read from or write to a virtual page that is not currently present in its address space. A major page fault is when auxiliary storage access is involved in making that page available.
nMin -- Minor Page Fault count
The number of minor page faults that have occurred for a task. A page fault occurs when a process attempts to read from or write to a virtual page that is not currently present in its address space. A minor page fault does not involve auxiliary storage access in making that page available.
nTH -- Number of Threads
The number of threads associated with a process.
nsCGROUP -- CGROUP namespace
The Inode of the namespace used to hide the identity of the control group of which process is a member.
nsIPC -- IPC namespace
The Inode of the namespace used to isolate interprocess communication (IPC) resources such as System V IPC objects and POSIX message queues.
nsMNT -- MNT namespace
The Inode of the namespace used to isolate filesystem mount points thus offering different views of the filesystem hierarchy.
nsNET -- NET namespace
The Inode of the namespace used to isolate resources such as network devices, IP addresses, IP routing, port numbers, etc.
nsPID -- PID namespace
The Inode of the namespace used to isolate process ID numbers meaning they need not remain unique. Thus, each such namespace could have its own ’init/systemd’ (PID #1) to manage various initialization tasks and reap orphaned child processes.
nsTIME -- TIME namespace
The Inode of the namespace which allows processes to see different system times in a way similar to the UTS namespace.
nsUSER -- USER namespace
The Inode of the namespace used to isolate the user and group ID numbers. Thus, a process could have a normal unprivileged user ID outside a user namespace while having a user ID of 0, with full root privileges, inside that namespace.
nsUTS -- UTS namespace
The Inode of the namespace used to isolate hostname and NIS domain name. UTS simply means "UNIX Time-sharing System".
vMj -- Major Page Fault Count Delta
The number of major page faults that have occurred since the last update (see nMaj).
vMn -- Minor Page Fault Count Delta
The number of minor page faults that have occurred since the last update (see nMin).
3b. MANAGING
Fields
After pressing the interactive command ’f’
(Fields Management) you will be presented with a screen
showing: 1) the ’current’ window name; 2) the
designated sort field; 3) all fields in their current order
along with descriptions. Entries marked with an asterisk are
the currently displayed fields, screen width permitting.
• |
As the on screen instructions indicate, you navigate among the fields with the Up and Down arrow keys. The PgUp, PgDn, Home and End keys can also be used to quickly reach the first or last available field. | ||
• |
The Right arrow key selects a field for repositioning and the Left arrow key or the <Enter> key commits that field’s placement. | ||
• |
The ’d’ key or the <Space> bar toggles a field’s display status, and thus the presence or absence of the asterisk. | ||
• |
The ’s’ key designates a field as the sort field. See topic 4c. TASK AREA Commands, SORTING for additional information regarding your selection of a sort field. | ||
• |
The ’a’ and ’w’ keys can be used to cycle through all available windows and the ’q’ or <Esc> keys exit Fields Management. |
The Fields Management screen can also be used to change the ’current’ window/field group in either full-screen mode or alternate-display mode. Whatever was targeted when ’q’ or <Esc> was pressed will be made current as you return to the top display. See topic 5. ALTERNATE-DISPLAY Provisions and the ’g’ interactive command for insight into ’current’ windows and field groups.
Note: Any window that has been scrolled horizontally will be reset if any field changes are made via the Fields Management screen. Any vertical scrolled position, however, will not be affected. See topic 5c. SCROLLING a Window for additional information regarding vertical and horizontal scrolling.
4. INTERACTIVE Commands
Listed below is a brief index of commands within categories. Some commands appear more than once -- their meaning or scope may vary depending on the context in which they are issued.
4a.
Global-Commands
<Ent/Sp> ?, =, 0,
A, B, d, E, e, g, H, h, I, k, q, r, s, W, X, Y, Z,
^G, ^K, ^N, ^P, ^U, ^L, ^R
4b. Summary-Area-Commands
C, l, t, m, 1, 2, 3, 4, 5, !
4c. Task-Area-Commands
Appearance: b, J, j, x, y, z
Content: c, F, f, O, o, S, U, u, V, v, ^E
Size: #, i, n
Sorting: <, >, f, R
4d. Color-Mapping
<Ret>, a, B, b, H, M, q, S, T, w, z, 0 - 7
5b. Commands-for-Windows
-, _, =, +, A, a, G, g, w
5c. Scrolling-a-Window
C, Up, Dn, Left, Right, PgUp, PgDn, Home, End
5d. Searching-in-a-Window
L, &
5e. Filtering-in-a-Window
O, o, ^O, =, +
4a. GLOBAL
Commands
The global interactive commands are always available
in both full-screen mode and alternate-display mode.
However, some of these interactive commands are not
available when running in Secure mode.
If you wish to
know in advance whether or not your top has been secured,
simply ask for help and view the system summary on the
second line.
<Enter> or
<Space> :Refresh-Display
These commands awaken top and following receipt of any input the entire display will be repainted. They also force an update of any hotplugged cpu or physical memory changes.
Use either of these keys if you have a large delay interval and wish to see current status,
? | h :Help
There are two help levels available. The first will provide a reminder of all the basic interactive commands. If top is secured, that screen will be abbreviated.
Typing ’h’ or ’?’ on that help screen will take you to help for those interactive commands applicable to alternate-display mode.
= :Exit-Display-Limits
Removes restrictions on what is shown. This command will reverse any ’i’ (idle tasks), ’n’ (max tasks), ’v’ (hide children) and ’F’ focus commands that might be active. It also provides for an exit from PID monitoring, User filtering, Other filtering, Locate processing and Combine Cpus mode.
Additionally, if the window has been scrolled it will be reset with this command.
0 :Zero-Suppress toggle
This command determines whether zeros are shown or suppressed for many of the fields in a task window. Fields like UID, GID, NI, PR or P are not affected by this toggle.
A :Alternate-Display-Mode toggle
This command will switch between full-screen mode and alternate-display mode. See topic 5. ALTERNATE-DISPLAY Provisions and the ’g’ interactive command for insight into ’current’ windows and field groups.
B :Bold-Disable/Enable toggle
This command will influence use of the bold terminfo capability and alters both the summary area and task area for the ’current’ window. While it is intended primarily for use with dumb terminals, it can be applied anytime.
Note: When this toggle is On and top is operating in monochrome mode, the entire display will appear as normal text. Thus, unless the ’x’ and/or ’y’ toggles are using reverse for emphasis, there will be no visual confirmation that they are even on.
* d | s :Change-Delay-Time-interval
You will be prompted to enter the delay time, in seconds, between display updates.
Fractional seconds are honored, but a negative number is not allowed. Entering 0 causes (nearly) continuous updates, with an unsatisfactory display as the system and tty driver try to keep up with top’s demands. The delay value is inversely proportional to system loading, so set it with care.
If at any time you wish to know the current delay time, simply ask for help and view the system summary on the second line.
E :Enforce-Summary-Memory-Scale in Summary Area
With this command you can cycle through the available summary area memory scaling which ranges from KiB (kibibytes or 1,024 bytes) through EiB (exbibytes or 1,152,921,504,606,846,976 bytes).
If you see a ’+’ between a displayed number and the following label, it means that top was forced to truncate some portion of that number. By raising the scaling factor, such truncation can be avoided.
e :Enforce-Task-Memory-Scale in Task Area
With this command you can cycle through the available task area memory scaling which ranges from KiB (kibibytes or 1,024 bytes) through PiB (pebibytes or 1,125,899,906,842,624 bytes).
While top will try to honor the selected target range, additional scaling might still be necessary in order to accommodate current values. If you wish to see a more homogeneous result in the memory columns, raising the scaling range will usually accomplish that goal. Raising it too high, however, is likely to produce an all zero result which cannot be suppressed with the ’0’ interactive command.
g :Choose-Another-Window/Field-Group
You will be prompted to enter a number between 1 and 4 designating the field group which should be made the ’current’ window. You will soon grow comfortable with these 4 windows, especially after experimenting with alternate-display mode.
H :Threads-mode toggle
When this toggle is On, individual threads will be displayed for all processes in all visible task windows. Otherwise, top displays a summation of all threads in each process.
I :Irix/Solaris-Mode toggle
When operating in Solaris mode (’I’ toggled Off), a task’s cpu usage will be divided by the total number of CPUs. After issuing this command, you’ll be told the new state of this toggle.
* k :Kill-a-task
You will be prompted for a PID and then the signal to send.
Entering no PID or a negative number will be interpreted as the default shown in the prompt (the first task displayed). A PID value of zero means the top program itself.
The default signal, as reflected in the prompt, is SIGTERM. However, you can send any signal, via number or name.
If you wish to
abort the kill process, do one of the following depending on
your progress:
1) at the pid prompt, type an invalid number
2) at the signal prompt, type 0 (or any invalid signal)
3) at any prompt, type <Esc>
q :Quit
* r :Renice-a-Task
You will be prompted for a PID and then the value to nice it to.
Entering no PID or a negative number will be interpreted as the default shown in the prompt (the first task displayed). A PID value of zero means the top program itself.
A positive nice value will cause a process to lose priority. Conversely, a negative nice value will cause a process to be viewed more favorably by the kernel. As a general rule, ordinary users can only increase the nice value and are prevented from lowering it.
If you wish to
abort the renice process, do one of the following depending
on your progress:
1) at the pid prompt, type an invalid number
2) at the nice prompt, type <Enter> with no input
3) at any prompt, type <Esc>
W :Write-the-Configuration-File
This will save all of your options and toggles plus the current display mode and delay time. By issuing this command just before quitting top, you will be able restart later in exactly that same state.
X :Extra-Fixed-Width
Some fields are fixed width and not scalable. As such, they are subject to truncation which would be indicated by a ’+’ in the last position.
This interactive command can be used to alter the widths of the following fields:
field
default field default field default
GID 5 GROUP 8 WCHAN 10
LOGID 5 LXC 8 nsCGROUP 10
RUID 5 RUSER 8 nsIPC 10
SUID 5 SUSER 8 nsMNT 10
UID 5 TTY 8 nsNET 10
USER 8 nsPID 10
nsTIME 10
nsUSER 10
nsUTS 10
You will be prompted for the amount to be added to the default widths shown above. Entering zero forces a return to those defaults.
If you enter a negative number, top will automatically increase the column size as needed until there is no more truncated data.
Note: Whether explicitly or automatically increased, the widths for these fields are never decreased by top. To narrow them you must specify a smaller number or restore the defaults.
Y :Inspect-Other-Output
After issuing the ’Y’ interactive command, you will be prompted for a target PID. Typing a value or accepting the default results in a separate screen. That screen can be used to view a variety of files or piped command output while the normal top iterative display is paused.
Note: This interactive command is only fully realized when supporting entries have been manually added to the end of the top configuration file. For details on creating those entries, see topic 6b. ADDING INSPECT Entries.
Most of the keys used to navigate the Inspect feature are reflected in its header prologue. There are, however, additional keys available once you have selected a particular file or command. They are familiar to anyone who has used the pager ’less’ and are summarized here for future reference.
key
function
= alternate status-line, file or pipeline
/ find, equivalent to ’L’ locate
n find next, equivalent to ’&’ locate next
<Space> scroll down, equivalent to <PgDn>
b scroll up, equivalent to <PgUp>
g first line, equivalent to <Home>
G last line, equivalent to <End>
Z :Change-Color-Mapping
This key will take you to a separate screen where you can change the colors for the ’current’ window, or for all windows. For details regarding this interactive command see topic 4d. COLOR Mapping.
^G :Display-Control-Groups
(Ctrl key + ’g’)
^K :Display-Cmdline (Ctrl key +
’k’)
^N :Display-Environment (Ctrl key +
’n’)
^P :Display-Namesspaces (Ctrl key +
’p’)
^U :Display-Supplementary-Groups (Ctrl
key + ’u’)
Applied to the first process displayed, these commands will show that task’s full (potentially wrapped) information. Such data will be displayed in a separate window at the bottom of the screen while normal top monitoring continues.
Keying the same ’Ctrl’ command a second time removes that separate window as does the ’=’ command. Keying a different ’Ctrl’ combination, while one is already active, immediately transitions to the new information.
Notable among these provisions is the Ctrl+N (environment) command. Its output can be extensive and not easily read when line wrapped. A more readable version can be achieved with an ’Inspect’ entry in the rcfile like the following.
pipe ^I Environment ^I cat /proc/%d/environ | tr ’\0’ ’\n’
See the ’Y’ interactive command above and topic 6b. ADDING INSPECT Entries for additional information.
As an alternative to ’Inspect’, and available to all of these ’Ctrl’ commands, the tab key can be used to highlight individual elements in the bottom window.
^L :Logged-Messages (Ctrl key + ’l’)
The 10 most recent messages are displayed in a separate window at the bottom of the screen while normal top monitoring continues. Keying ’^L’ a second time removes that window as does the ’=’ command. Use the tab key to highlight individual messages.
* ^R :Renice-an-Autogroup (Ctrl key + ’r’)
You will be prompted for a PID and then the value for its autogroup AGNI.
Entering no PID will be interpreted as the default shown in the prompt (the first task displayed).
A positive AGNI value will cause processes in that autogroup to lose priority. Conversely, a negative value causes them to be viewed more favorably by the kernel. Ordinary users are not allowed to set negative AGNI values.
If you wish to abort the renice process type <Esc>.
* |
The commands shown with an asterisk (’*’) are not available in Secure mode, nor will they be shown on the level-1 help screen. |
4b. SUMMARY
AREA Commands
The summary area interactive commands are always
available in both full-screen mode and alternate-display
mode. They affect the beginning lines of your display and
will determine the position of messages and prompts.
These commands
always impact just the ’current’ window/field
group. See topic 5. ALTERNATE-DISPLAY Provisions and the
’g’ interactive command for insight into
’current’ windows and field groups.
C :Show-scroll-coordinates toggle
Toggle an informational message which is displayed whenever the message line is not otherwise being used. For additional information see topic 5c. SCROLLING a Window.
l :Load-Average/Uptime toggle
This is also the line containing the program name (possibly an alias) when operating in full-screen mode or the ’current’ window name when operating in alternate-display mode.
t :Task/Cpu-States toggle
This command affects from 2 to many summary area lines, depending on the state of the ’1’, ’2’ or ’3’ command toggles and whether or not top is running under true SMP.
This portion of the summary area is also influenced by the ’H’ interactive command toggle, as reflected in the total label which shows either Tasks or Threads.
This command
serves as a 4-way toggle, cycling through these modes:
1. detailed percentages by category
2. abbreviated user/system and total % + bar graph
3. abbreviated user/system and total % + block graph
4. turn off task and cpu states display
When operating in either of the graphic modes, the display becomes much more meaningful when individual CPUs or NUMA nodes are also displayed. See the the ’1’, ’2’ and ’3’ commands below for additional information.
m :Memory/Swap-Usage toggle
This command affects the two summary area lines dealing with physical and virtual memory.
This command
serves as a 4-way toggle, cycling through these modes:
1. detailed percentages by memory type
2. abbreviated % used/total available + bar graph
3. abbreviated % used/total available + block graph
4. turn off memory display
1 :Single/Separate-Cpu-States toggle
This command affects how the ’t’ command’s Cpu States portion is shown. Although this toggle exists primarily to serve massively-parallel SMP machines, it is not restricted to solely SMP environments.
When you see ’%Cpu(s):’ in the summary area, the ’1’ toggle is On and all cpu information is gathered in a single line. Otherwise, each cpu is displayed separately as: ’%Cpu0, %Cpu1, ...’ up to available screen height.
2 :NUMA-Nodes/Cpu-Summary toggle
This command toggles between the ’1’ command cpu summary display (only) or a summary display plus the cpu usage statistics for each NUMA Node. It is only available if a system has the requisite NUMA support.
3 :Expand-NUMA-Node
You will be invited to enter a number representing a NUMA Node. Thereafter, a node summary plus the statistics for each cpu in that node will be shown until the ’1’, ’2’ or ’4’ command toggle is pressed. This interactive command is only available if a system has the requisite NUMA support.
4 :Display-Multiple-Elements-Adjacent toggle
This command toggle turns the ’1’ toggle Off and shows multiple CPU and Memory results on each line. Each successive ’4’ key adds another CPU until again reverting to separate lines for CPU and Memory results.
A maximum of 8 CPUs per line can be displayed in this manner. However, data truncation may occur before reaching the maximum. That is definitely true when displaying detailed statistics via the ’t’ command toggle since such data cannot be scaled like the graphic representations.
If one wished to quickly exit adjacent mode without cycling all the way to 8, simply use the ’1’ command toggle.
5 :Display-P-Cores-and-E-Cores toggle
This command toggle is only active when the ’t’ toggle is On and the ’1’, ’2’, ’3’ and ’!’ toggles are Off, thus showing individual CPU results. It assumes a platform has multiple cores of two distinct types, either multi-threaded (P-Core) or single-threaded (E-Core).
While normally each cpu is displayed as ’%Cpu0, %Cpu1, ...’, this toggle can be used to identify and/or filter those cpus by their core type, either P-Core (performance) or E-Core (efficient).
The 1st time ’5’ is struck, each CPU is displayed as ’%CpP’ or ’%CpE’ representing the two core types. The 2nd time, only P-Cores (%CpP) will be shown. The 3rd time, only E-Cores (%CpE) are displayed. When this command toggle is struck for the 4th time, the CPU display returns to the normal ’%Cpu’ convention.
If separate performance and efficient categories are not present, this command toggle will have no effect.
! :Combine-Cpus-Mode toggle
This command toggle is intended for massively parallel SMP environments where, even with the ’4’ command toggle, not all processors can be displayed. With each press of ’!’ the number of cpus combined is doubled thus reducing the total number of cpu lines displayed.
For example, with the first press of ’!’ two cpus will be combined and displayed as ’0-1, 2-3, ...’ instead of the normal ’%Cpu0, %Cpu1, %Cpu2, %Cpu3, ...’. With a second ’!’ command toggle four cpus are combined and shown as ’0-3, 4-7, ...’. Then the third ’!’ press, combining eight cpus, shows as ’0-7, 8-15, ...’, etc.
Such progression continues until individual cpus are again displayed and impacts both the ’1’ and ’4’ toggles (one or multiple columns). Use the ’=’ command to exit Combine Cpus mode.
Note: If the entire summary area has been toggled Off for any window, you would be left with just the message line. In that way, you will have maximized available task rows but (temporarily) sacrificed the program name in full-screen mode or the ’current’ window name when in alternate-display mode.
4c. TASK
AREA Commands
The task area interactive commands are always
available in full-screen mode.
The task area interactive commands are never available in alternate-display mode if the ’current’ window’s task display has been toggled Off (see topic 5. ALTERNATE-DISPLAY Provisions).
APPEARANCE
of task window
J :Justify-Numeric-Columns toggle
Alternates between right-justified (the default) and left-justified numeric data. If the numeric data completely fills the available column, this command toggle may impact the column header only.
j :Justify-Character-Columns toggle
Alternates between left-justified (the default) and right-justified character data. If the character data completely fills the available column, this command toggle may impact the column header only.
The following commands will also be influenced by the state of the global ’B’ (bold enable) toggle.
b :Bold/Reverse toggle
This command will impact how the ’x’ and ’y’ toggles are displayed. It may also impact the summary area when a bar graph has been selected for cpu states or memory usage via the ’t’ or ’m’ toggles.
x :Column-Highlight toggle
Changes highlighting for the
current sort field. If you forget which field is being
sorted this command can serve as a quick visual reminder,
providing the sort field is being displayed. The sort field
might not be visible because:
1) there is insufficient Screen Width
2) the ’f’ interactive command turned it Off
y :Row-Highlight toggle
Changes highlighting for "running" tasks. For additional insight into this task state, see topic 3a. DESCRIPTIONS of Fields, the ’S’ field (Process Status).
Use of this provision provides important insight into your system’s health. The only costs will be a few additional tty escape sequences.
z :Color/Monochrome toggle
Switches the ’current’ window between your last used color scheme and the older form of black-on-white or white-on-black. This command will alter both the summary area and task area but does not affect the state of the ’x’, ’y’ or ’b’ toggles.
CONTENT
of task window
c :Command-Line/Program-Name
toggle
This command will be honored whether or not the COMMAND column is currently visible. Later, should that field come into view, the change you applied will be seen.
F :Maintain-Parent-Focus toggle
When in forest view mode, this key serves as a toggle to retain focus on a target task, presumably one with forked children. If forest view mode is Off this key has no effect.
The toggle is applied to the first (topmost) process in the ’current’ window. Once established, that task is always displayed as the first (topmost) process along with its forked children. All other processes will be suppressed.
Note: keys like ’i’ (idle tasks), ’n’ (max tasks), ’v’ (hide children) and User/Other filtering remain accessible and can impact what is displayed.
f :Fields-Management
This key displays a separate screen where you can change which fields are displayed, their order and also designate the sort field. For additional information on this interactive command see topic 3b. MANAGING Fields.
O | o :Other-Filtering
You will be prompted for the selection criteria which then determines which tasks will be shown in the ’current’ window. Your criteria can be made case sensitive or case can be ignored. And you determine if top should include or exclude matching tasks.
See topic 5e. FILTERING in a window for details on these and additional related interactive commands.
S :Cumulative-Time-Mode toggle
When Cumulative mode is On, each process is listed with the cpu time that it and its dead children have used.
When Off, programs that fork into many separate tasks will appear less demanding. For programs like ’init’ or a shell this is appropriate but for others, like compilers, perhaps not. Experiment with two task windows sharing the same sort field but with different ’S’ states and see which representation you prefer.
After issuing this command, you’ll be informed of the new state of this toggle. If you wish to know in advance whether or not Cumulative mode is in effect, simply ask for help and view the window summary on the second line.
U | u :Show-Specific-User-Only
You will be prompted for the uid or name of the user to display. The -u option matches on effective user whereas the -U option matches on any user (real, effective, saved, or filesystem).
Thereafter, in that task window only matching users will be shown, or possibly no processes will be shown. Prepending an exclamation point (’!’) to the user id or name instructs top to display only processes with users not matching the one provided.
Different task windows can be used to filter different users. Later, if you wish to monitor all users again in the ’current’ window, re-issue this command but just press <Enter> at the prompt.
V :Forest-View-Mode toggle
In this mode, processes are reordered according to their parents and the layout of the COMMAND column resembles that of a tree. In forest view mode it is still possible to toggle between program name and command line (see the ’c’ interactive command) or between processes and threads (see the ’H’ interactive command).
Note: Typing any key affecting the sort order will exit forest view mode in the ’current’ window. See topic 4c. TASK AREA Commands, SORTING for information on those keys.
v :Hide/Show-Children toggle
When in forest view mode, this key serves as a toggle to collapse or expand the children of a parent.
The toggle is applied against the first (topmost) process in the ’current’ window. See topic 5c. SCROLLING a Window for additional information regarding vertical scrolling.
If the target process has not forked any children, this key has no effect. It also has no effect when not in forest view mode.
^E :Scale-CPU-Time-fields (Ctrl key + ’e’)
The ’time’ fields are normally displayed with the greatest precision their widths permit. This toggle reduces that precision until it wraps. It also illustrates the scaling those fields might experience automatically, which usually depends on how long the system runs.
For example, if ’MMM:SS.hh’ is shown, each ^E keystroke would change it to: ’MM:SS’, ’Hours,MM’, ’Days+Hours’ and finally ’Weeks+Days’.
Not all time fields are subject to the full range of such scaling.
SIZE of
task window
i :Idle-Process toggle
Displays all tasks or just active tasks. When this toggle is Off, tasks that have not used any CPU since the last update will not be displayed. However, due to the granularity of the %CPU and TIME+ fields, some processes may still be displayed that appear to have used no CPU.
If this command is applied to the last task display when in alternate-display mode, then it will not affect the window’s size, as all prior task displays will have already been painted.
n | # :Set-Maximum-Tasks
You will be prompted to enter the number of tasks to display. The lessor of your number and available screen rows will be used.
When used in alternate-display mode, this is the command that gives you precise control over the size of each currently visible task display, except for the very last. It will not affect the last window’s size, as all prior task displays will have already been painted.
Note: If you wish to increase the size of the last visible task display when in alternate-display mode, simply decrease the size of the task display(s) above it.
SORTING of task window
For
compatibility, this top supports most of the former top sort
keys. Since this is primarily a service to former top users,
these commands do not appear on any help screen.
command sorted-field supported
A start time (non-display) No
M %MEM Yes
N PID Yes
P %CPU Yes
T TIME+ Yes
Before using any of the following sort provisions, top suggests that you temporarily turn on column highlighting using the ’x’ interactive command. That will help ensure that the actual sort environment matches your intent.
The following
interactive commands will only be honored when the
current sort field is visible. The sort field might
not be visible because:
1) there is insufficient Screen Width
2) the ’f’ interactive command turned it Off
< :Move-Sort-Field-Left
Moves the sort column to the left unless the current sort field is the first field being displayed.
> :Move-Sort-Field-Right
Moves the sort column to the right unless the current sort field is the last field being displayed.
The following
interactive commands will always be honored whether
or not the current sort field is visible.
f :Fields-Management
This key displays a separate screen where you can change which field is used as the sort column, among other functions. This can be a convenient way to simply verify the current sort field, when running top with column highlighting turned Off.
R :Reverse/Normal-Sort-Field toggle
Using this interactive command you can alternate between high-to-low and low-to-high sorts.
4d. COLOR
Mapping
When you issue the ’Z’ interactive command, you
will be presented with a separate screen. That screen can be
used to change the colors in just the ’current’
window or in all four windows before returning to the top
display.
The following
interactive commands are available.
4 upper case letters to select a target
8 numbers to select a color
normal toggles available
B :bold disable/enable
b :running tasks "bold"/reverse
z :color/mono
other commands available
a/w :apply, then go to next/prior
<Enter> :apply and exit
q :abandon current changes and exit
If you use ’a’ or ’w’ to cycle the targeted window, you will have applied the color scheme that was displayed when you left that window. You can, of course, easily return to any window and reapply different colors or turn colors Off completely with the ’z’ toggle.
The Color Mapping screen can also be used to change the ’current’ window/field group in either full-screen mode or alternate-display mode. Whatever was targeted when ’q’ or <Enter> was pressed will be made current as you return to the top display.
5. ALTERNATE-DISPLAY Provisions
5a. WINDOWS
Overview
Field Groups/Windows:
In full-screen mode there is a single window represented by the entire screen. That single window can still be changed to display 1 of 4 different field groups (see the ’g’ interactive command, repeated below). Each of the 4 field groups has a unique separately configurable summary area and its own configurable task area.
In alternate-display mode, those 4 underlying field groups can now be made visible simultaneously, or can be turned Off individually at your command.
The summary area will always exist, even if it’s only the message line. At any given time only one summary area can be displayed. However, depending on your commands, there could be from zero to four separate task displays currently showing on the screen.
Current Window:
The ’current’ window is the window associated with the summary area and the window to which task related commands are always directed. Since in alternate-display mode you can toggle the task display Off, some commands might be restricted for the ’current’ window.
A further complication arises when you have toggled the first summary area line Off. With the loss of the window name (the ’l’ toggled line), you’ll not easily know what window is the ’current’ window.
5b. COMMANDS
for Windows
- | _ :Show/Hide-Window(s)
toggles
The ’-’ key turns the ’current’ window’s task display On and Off. When On, that task area will show a minimum of the columns header you’ve established with the ’f’ interactive command. It will also reflect any other task area options/toggles you’ve applied yielding zero or more tasks.
The ’_’ key does the same for all task displays. In other words, it switches between the currently visible task display(s) and any task display(s) you had toggled Off. If all 4 task displays are currently visible, this interactive command will leave the summary area as the only display element.
* = | + :Equalize/Reset-Window(s)
The ’=’ key forces the ’current’ window’s task display to be visible. It also reverses any active ’i’ (idle tasks), ’n’ (max tasks), ’u/U’ (user filter), ’o/O’ (other filter), ’v’ (hide children), ’F’ focused, ’L’ (locate) and ’!’ (combine cpus) commands. Also, if the window had been scrolled, it will be reset with this command. See topic 5c. SCROLLING a Window for additional information regarding vertical and horizontal scrolling.
The ’+’ key does the same for all windows. The four task displays will reappear, evenly balanced, while retaining any customizations previously applied beyond those noted for the ’=’ command toggle.
* A :Alternate-Display-Mode toggle
This command will switch between full-screen mode and alternate-display mode.
The first time you issue this command, all four task displays will be shown. Thereafter when you switch modes, you will see only the task display(s) you’ve chosen to make visible.
* a | w :Next-Window-Forward/Backward
This will change the ’current’ window, which in turn changes the window to which commands are directed. These keys act in a circular fashion so you can reach any desired window using either key.
Assuming the window name is visible (you have not toggled ’l’ Off), whenever the ’current’ window name loses its emphasis/color, that’s a reminder the task display is Off and many commands will be restricted.
G :Change-Window/Field-Group-Name
You will be prompted for a new name to be applied to the ’current’ window. It does not require that the window name be visible (the ’l’ toggle to be On).
* |
The interactive commands shown with an asterisk (’*’) have use beyond alternate-display mode. |
=, A, g are always available
a, w act the same with color mapping
and fields management
* g :Choose-Another-Window/Field-Group
You will be prompted to enter a number between 1 and 4 designating the field group which should be made the ’current’ window.
In full-screen mode, this command is necessary to alter the ’current’ window. In alternate-display mode, it is simply a less convenient alternative to the ’a’ and ’w’ commands.
5c.
SCROLLING a Window
Typically a task window is a partial view into a
system’s total tasks/threads which shows only some of
the available fields/columns. With these scrolling keys, you
can move that view vertically or horizontally to reveal any
desired task or column.
Up,PgUp :Scroll-Tasks
Move the view up toward the first task row, until the first task is displayed at the top of the ’current’ window. The Up arrow key moves a single line while PgUp scrolls the entire window.
Down,PgDn :Scroll-Tasks
Move the view down toward the last task row, until the last task is the only task displayed at the top of the ’current’ window. The Down arrow key moves a single line while PgDn scrolls the entire window.
Left,Right :Scroll-Columns
Move the view of displayable fields horizontally one column at a time.
Note: As a reminder, some fields/columns are not fixed-width but allocated all remaining screen width when visible. When scrolling right or left, that feature may produce some unexpected results initially.
Additionally, there are special provisions for any variable width field when positioned as the last displayed field. Once that field is reached via the right arrow key, and is thus the only column shown, you can continue scrolling horizontally within such a field. See the ’C’ interactive command below for additional information.
Home :Jump-to-Home-Position
Reposition the display to the un-scrolled coordinates.
End :Jump-to-End-Position
Reposition the display so that the rightmost column reflects the last displayable field and the bottom task row represents the last task.
Note: From this position it is still possible to scroll down and right using the arrow keys. This is true until a single column and a single task is left as the only display element.
C :Show-scroll-coordinates toggle
Toggle an informational message which is displayed whenever the message line is not otherwise being used. That message will take one of two forms depending on whether or not a variable width column has also been scrolled.
scroll
coordinates: y = n/n (tasks), x = n/n (fields)
scroll coordinates: y = n/n (tasks), x = n/n (fields) +
nn
The coordinates
shown as n/n are relative to the upper left
corner of the ’current’ window. The additional
’+ nn’ represents the displacement
into a variable width column when it has been scrolled
horizontally. Such displacement occurs in normal 8 character
tab stop amounts via the right and left arrow keys.
y = n/n (tasks)
The first n represents the topmost visible task and is controlled by scrolling keys. The second n is updated automatically to reflect total tasks.
x = n/n (fields)
The first n represents the leftmost displayed column and is controlled by scrolling keys. The second n is the total number of displayable fields and is established with the ’f’ interactive command.
The above interactive commands are always available in full-screen mode but never available in alternate-display mode if the ’current’ window’s task display has been toggled Off.
Note: When any form of filtering is active, you can expect some slight aberrations when scrolling since not all tasks will be visible. This is particularly apparent when using the Up/Down arrow keys.
5d.
SEARCHING in a Window
You can use these interactive commands to locate a task row
containing a particular value.
L :Locate-a-string
You will be prompted for the case-sensitive string to locate starting from the current window coordinates. There are no restrictions on search string content.
Searches are not limited to values from a single field or column. All of the values displayed in a task row are allowed in a search string. You may include spaces, numbers, symbols and even forest view artwork.
Keying <Enter> with no input will effectively disable the ’&’ key until a new search string is entered.
& :Locate-next
Assuming a search string has been established, top will attempt to locate the next occurrence.
When a match is found, the current window is repositioned vertically so the task row containing that string is first. The scroll coordinates message can provide confirmation of such vertical repositioning (see the ’C’ interactive command). Horizontal scrolling, however, is never altered via searching.
The availability of a matching string will be influenced by the following factors.
a. Which fields are displayable from the total available,
see topic 3b. MANAGING Fields.
b. Scrolling a window vertically and/or horizontally,
see topic 5c. SCROLLING a Window.
c. The state of the command/command-line toggle,
see the ’c’ interactive command.
d. The stability of the chosen sort column,
for example PID is good but %CPU bad.
If a search fails, restoring the ’current’ window home (unscrolled) position, scrolling horizontally, displaying command-lines or choosing a more stable sort field could yet produce a successful ’&’ search.
The above interactive commands are always available in full-screen mode but never available in alternate-display mode if the ’current’ window’s task display has been toggled Off.
5e.
FILTERING in a Window
You can use this ’Other Filter’ feature to
establish selection criteria which will then determine which
tasks are shown in the ’current’ window. Such
filters can be made persistent if preserved in the rcfile
via the ’W’ interactive command.
Establishing a filter requires: 1) a field name; 2) an operator; and 3) a selection value, as a minimum. This is the most complex of top’s user input requirements so, when you make a mistake, command recall will be your friend. Remember the Up/Down arrow keys or their aliases when prompted for input.
Filter Basics
1. field names are case
sensitive and spelled as in the header
2. selection values need not comprise the full displayed
field
3. a selection is either case insensitive or sensitive to
case
4. the default is inclusion, prepending ’!’
denotes exclusions
5. multiple selection criteria can be applied to a task
window
6. inclusion and exclusion criteria can be used
simultaneously
7. the 1 equality and 2 relational filters can be freely
mixed
8. separate unique filters are maintained for each task
window
If a field is not turned on or is not currently in view, then your selection criteria will not affect the display. Later, should a filtered field become visible, the selection criteria will then be applied.
Keyboard
Summary
O :Other-Filter (upper case)
You will be prompted to establish a case sensitive filter.
o :Other-Filter (lower case)
You will be prompted to establish a filter that ignores case when matching.
^O :Show-Active-Filters (Ctrl key + ’o’)
This can serve as a reminder of which filters are active in the ’current’ window. A summary will be shown on the message line until you press the <Enter> key.
= :Reset-Filtering in current window
This clears all of your selection criteria in the ’current’ window. It also has additional impact so please see topic 4a. GLOBAL Commands.
+ :Reset-Filtering in all windows
This clears the selection criteria in all windows, assuming you are in alternate-display mode. As with the ’=’ interactive command, it too has additional consequences so you might wish to see topic 5b. COMMANDS for Windows.
Input Requirements
When prompted
for selection criteria, the data you provide must take one
of two forms. There are 3 required pieces of information,
with a 4th as optional. These examples use spaces for
clarity but your input generally would not.
#1 #2 #3 ( required )
Field-Name ? include-if-value
! Field-Name ? exclude-if-value
#4 ( optional )
Items #1, #3 and #4 should be self-explanatory. Item #2 represents both a required delimiter and the operator which must be one of either equality (’=’) or relation (’<’ or ’>’).
The ’=’ equality operator requires only a partial match and that can reduce your ’if-value’ input requirements. The ’>’ or ’<’ relational operators always employ string comparisons, even with numeric fields. They are designed to work with a field’s default justification and with homogeneous data. When some field’s numeric amounts have been subjected to scaling while others have not, that data is no longer homogeneous.
If you establish a relational filter and you have changed the default Numeric or Character justification, that filter is likely to fail. When a relational filter is applied to a memory field and you have not changed the scaling, it may produce misleading results. This happens, for example, because ’100.0m’ (MiB) would appear greater than ’1.000g’ (GiB) when compared as strings.
If your filtered results appear suspect, simply altering justification or scaling may yet achieve the desired objective. See the ’j’, ’J’ and ’e’ interactive commands for additional information.
Potential Problems
These
GROUP filters could produce the exact same results or
the second one might not display anything at all, just a
blank task window.
GROUP=root ( only the same results when )
GROUP=ROOT ( invoked via lower case ’o’ )
Either of these
RES filters might yield inconsistent and/or
misleading results, depending on the current memory scaling
factor. Or both filters could produce the exact same
results.
RES>9999 ( only the same results when )
!RES<10000 ( memory scaling is at ’KiB’ )
This
nMin filter illustrates a problem unique to scalable
fields. This particular field can display a maximum of 4
digits, beyond which values are automatically scaled to KiB
or above. So while amounts greater than 9999 exist, they
will appear as 2.6m, 197k, etc.
nMin>9999 ( always a blank task window )
Potential Solutions
These examples illustrate how Other Filtering can be creatively applied to achieve almost any desired result. Single quotes are sometimes shown to delimit the spaces which are part of a filter or to represent a request for status (^O) accurately. But if you used them with if-values in real life, no matches would be found.
Assuming field
nTH is displayed, the first filter will result in
only multi-threaded processes being shown. It also reminds
us that a trailing space is part of every displayed field.
The second filter achieves the exact same results with less
typing.
!nTH=’ 1 ’ ( ’ for clarity only )
nTH>1 ( same with less i/p )
With Forest
View mode active and the COMMAND column in view, this
filter effectively collapses child processes so that just 3
levels are shown.
!COMMAND=’ ’- ’ ( ’ for clarity only
)
The final two
filters appear as in response to the status request key
(^O). In reality, each filter would have required separate
input. The PR example shows the two concurrent
filters necessary to display tasks with priorities of 20 or
more, since some might be negative. Then by exploiting
trailing spaces, the nMin series of filters could
achieve the failed ’9999’ objective discussed
above.
’PR>20’ + ’!PR=-’ ( 2 for right
result )
’!nMin=0 ’ + ’!nMin=1 ’ +
’!nMin=2 ’ + ’!nMin=3 ’ ...
6. FILES
6a. PERSONAL
Configuration File
This file is created or updated via the ’W’
interactive command.
The legacy version is written as ’$HOME/.your-name-4-top’ + ’rc’ with a leading period.
A newly created configuration file is written as procps/your-name-4-top’ + ’rc’ without a leading period. The procps directory will be subordinate to either $XDG_CONFIG_HOME when set as an absolute path or the $HOME/.config directory.
While not
intended to be edited manually, here is the general layout:
global # line 1: the program name/alias notation
" # line 2: id,altscr,irixps,delay,curwin
per ea # line a: winname,fieldscur
window # line b: winflags,sortindx,maxtasks,etc
" # line c: summclr,msgsclr,headclr,taskclr
global # line 15: additional miscellaneous settings
" # any remaining lines are devoted to optional
" # active ’other filters’ discussed in
section 5e above
" # plus ’inspect’ entries discussed in
section 6b below
If a valid absolute path to the rcfile cannot be established, customizations made to a running top will be impossible to preserve.
6b. ADDING
INSPECT Entries
To exploit the ’Y’ interactive command, you must
add entries at the end of the top personal
configuration file. Such entries simply reflect a file to be
read or command/pipeline to be executed whose results will
then be displayed in a separate scrollable, searchable
window.
If you don’t know the location or name of your top rcfile, use the ’W’ interactive command to rewrite it and note those details.
Inspect entries can be added with a redirected echo or by editing the configuration file. Redirecting an echo risks overwriting the rcfile should it replace (>) rather than append (>>) to that file. Conversely, when using an editor care must be taken not to corrupt existing lines, some of which could contain unprintable data or unusual characters depending on the top version under which that configuration file was saved.
Those Inspect entries beginning with a ’#’ character are ignored, regardless of content. Otherwise they consist of the following 3 elements, each of which must be separated by a tab character (thus 2 ’\t’ total):
.type: literal
’file’ or ’pipe’
.name: selection shown on the Inspect screen
.fmts: string representing a path or command
The two types of Inspect entries are not interchangeable. Those designated ’file’ will be accessed using fopen and must reference a single file in the ’.fmts’ element. Entries specifying ’pipe’ will employ popen, their ’.fmts’ element could contain many pipelined commands and, none can be interactive.
If the file or pipeline represented in your ’.fmts’ deals with the specific PID input or accepted when prompted, then the format string must also contain the ’%d’ specifier, as these examples illustrate.
.fmts=
/proc/%d/numa_maps
.fmts= lsof -P -p %d
For ’pipe’ type entries only, you may also wish to redirect stderr to stdout for a more comprehensive result. Thus the format string becomes:
.fmts= pmap -x %d 2>&1
Here are examples of both types of Inspect entries as they might appear in the rcfile. The first entry will be ignored due to the initial ’#’ character. For clarity, the pseudo tab depictions (^I) are surrounded by an extra space but the actual tabs would not be.
# pipe ^I
Sockets ^I lsof -n -P -i 2>&1
pipe ^I Open Files ^I lsof -P -p %d 2>&1
file ^I NUMA Info ^I /proc/%d/numa_maps
pipe ^I Log ^I tail -n100 /var/log/syslog | sort -Mr
Except for the commented entry above, these next examples show what could be echoed to achieve similar results, assuming the rcfile name was ’.toprc’. However, due to the embedded tab characters, each of these lines should be preceded by ’/bin/echo -e’, not just a simple an ’echo’, to enable backslash interpretation regardless of which shell you use.
"pipe\tOpen
Files\tlsof -P -p %d 2>&1" >> ~/.toprc
"file\tNUMA Info\t/proc/%d/numa_maps" >>
~/.toprc
"pipe\tLog\ttail -n200 /var/log/syslog | sort -Mr"
>> ~/.toprc
If any inspect entry you create produces output with unprintable characters they will be displayed in either the ^C notation or hexadecimal <FF> form, depending on their value. This applies to tab characters as well, which will show as ’^I’. If you want a truer representation, any embedded tabs should be expanded. The following example takes what could have been a ’file’ entry but employs a ’pipe’ instead so as to expand the embedded tabs.
# next would
have contained ’\t’ ...
# file ^I <your_name> ^I /proc/%d/status
# but this will eliminate embedded ’\t’ ...
pipe ^I <your_name> ^I cat /proc/%d/status | expand
-
Note: Some programs might rely on SIGINT to end. Therefore, if a ’pipe’ such as the following is established, one must use Ctrl-C to terminate it in order to review the results. This is the single occasion where a ’^C’ will not also terminate top.
pipe ^I Trace ^I /usr/bin/strace -p %d 2>&1
Lastly, while ’pipe’ type entries have been discussed in terms of pipelines and commands, there is nothing to prevent you from including shell scripts as well. Perhaps even newly created scripts designed specifically for the ’Y’ interactive command.
For example, as the number of your Inspect entries grows over time, the ’Options:’ row will be truncated when screen width is exceeded. That does not affect operation other than to make some selections invisible. However, if some choices are lost to truncation but you want to see more options, there is an easy solution hinted at below.
Inspection
Pause at pid ...
Use: left/right then <Enter> ...
Options: help 1 2 3 4 5 6 7 8 9 10 11 ...
The entries in the top rcfile would have a number for the ’.name’ element and the ’help’ entry would identify a shell script you’ve written explaining what those numbered selections actually mean. In that way, many more choices can be made visible.
6c. SYSTEM
Configuration File
This configuration file represents defaults for users who
have not saved their own configuration file. The format
mirrors exactly the personal configuration file and can also
include ’inspect’ entries as explained
above.
Creating it is a simple process.
1. Configure top appropriately for your installation and preserve that configuration with the ’W’ interactive command.
2. Add and test any desired ’inspect’ entries.
3. Copy that configuration file to the /etc/ directory as ’topdefaultrc’.
6d. SYSTEM
Restrictions File
The presence of this file will influence which version of
the help screen is shown to an ordinary user.
More
importantly, it will limit what ordinary users are allowed
to do when top is running. They will not be able to issue
the following commands.
k Kill a task
r Renice a task
d or s Change delay/sleep interval
This configuration file is not created by top. Rather, it is created manually and placed it in the /etc/ directory as ’toprc’.
It should have
exactly two lines, as shown in this example:
s # line 1: secure mode switch
5.0 # line 2: delay interval in seconds
7. ENVIRONMENT VARIABLE(S)
The value set
for the following is unimportant, just its presence.
LIBPROC_HIDE_KERNEL
This will prevent display of any kernel threads and exclude such processes from the summary area Tasks/Threads counts.
8. STUPID TRICKS Sampler
Many of these tricks work best when you give top a scheduling boost. So plan on starting him with a nice value of -10, assuming you’ve got the authority.
7a. Kernel
Magic
For these stupid tricks, top needs full-screen mode.
• |
The user interface, through prompts and help, intentionally implies that the delay interval is limited to tenths of a second. However, you’re free to set any desired delay. If you want to see Linux at his scheduling best, try a delay of .09 seconds or less. |
For this
experiment, under x-windows open an xterm and maximize it.
Then do the following:
. provide a scheduling boost and tiny delay via:
nice -n -10 top -d.09
. keep sorted column highlighting Off so as to
minimize path length
. turn On reverse row highlighting for emphasis
. try various sort columns (TIME/MEM work well),
and normal or reverse sorts to bring the most
active processes into view
What you’ll see is a very busy Linux doing what he’s always done for you, but there was no program available to illustrate this.
• |
Under an xterm using ’white-on-black’ colors, on top’s Color Mapping screen set the task color to black and be sure that task highlighting is set to bold, not reverse. Then set the delay interval to around .3 seconds. |
After bringing the most active processes into view, what you’ll see are the ghostly images of just the currently running tasks.
• |
Delete the existing rcfile, or create a new symlink. Start this new version then type ’T’ (a secret key, see topic 4c. Task Area Commands, SORTING) followed by ’W’ and ’q’. Finally, restart the program with -d0 (zero delay). |
Your display will be refreshed at three times the rate of the former top, a 300% speed advantage. As top climbs the TIME ladder, be as patient as you can while speculating on whether or not top will ever reach the top.
7b. Bouncing
Windows
For these stupid tricks, top needs alternate-display
mode.
• |
With 3 or 4 task displays visible, pick any window other than the last and turn idle processes Off using the ’i’ command toggle. Depending on where you applied ’i’, sometimes several task displays are bouncing and sometimes it’s like an accordion, as top tries his best to allocate space. | ||
• |
Set each window’s summary lines differently: one with no memory (’m’); another with no states (’t’); maybe one with nothing at all, just the message line. Then hold down ’a’ or ’w’ and watch a variation on bouncing windows -- hopping windows. | ||
• |
Display all 4 windows and for each, in turn, set idle processes to Off using the ’i’ command toggle. You’ve just entered the "extreme bounce" zone. |
7c. The Big
Bird Window
This stupid trick also requires alternate-display mode.
• |
Display all 4 windows and make sure that 1:Def is the ’current’ window. Then, keep increasing window size with the ’n’ interactive command until all the other task displays are "pushed out of the nest". |
When
they’ve all been displaced, toggle between all
visible/invisible windows using the ’_’ command
toggle. Then ponder this:
is top fibbing or telling honestly your imposed truth?
7d. The
Ol’ Switcheroo
This stupid trick works best without alternate-display mode,
since justification is active on a per window basis.
• |
Start top and make COMMAND the last (rightmost) column displayed. If necessary, use the ’c’ command toggle to display command lines and ensure that forest view mode is active with the ’V’ command toggle. |
Then use the up/down arrow keys to position the display so that some truncated command lines are shown (’+’ in last position). You may have to resize your xterm to produce truncation.
Lastly, use the ’j’ command toggle to make the COMMAND column right justified.
Now use the right arrow key to reach the COMMAND column. Continuing with the right arrow key, watch closely the direction of travel for the command lines being shown.
some lines travel left, while others travel right
eventually all lines will Switcheroo, and move right
9. BUGS
Please send bug reports to procps [AT] freelists.org">procps [AT] freelists.org.
10. SEE Also
free(1), ps(1), uptime(1), atop(1), slabtop(1), vmstat(8), w(1)