SYNOPSIS

GENERAL

enum [ OPTIONS ] LEFT .. COUNTx STEP .. RIGHT

SHORTCUTS

enum [ OPTIONS ] LEFT STEP RIGHT

enum [ OPTIONS ] LEFT RIGHT

enum [ OPTIONS ] RIGHT

...

DESCRIPTION

enum enumerates values (numbers) from LEFT to RIGHT adding/subtracting STEP each time. If STEP is not provided a value is implied. No more than COUNT values are printed. Before printing, values are passed through a formatter. Please see OPTIONS for details on controlling the formatter or EXAMPLES for use cases.

Further enum usage details are covered in USAGE IN DETAIL.

EXAMPLES

USE IN FOR-LOOPS

for i in $(enum -e 1 20); do
    touch file_${i}
done

USE FOR RANDOM NUMBERS

number=$(enum --random 3 .. 10)

instead of native Bash like

f() { min=$1; max=$2; echo $((RANDOM * (max - min + 1) / 32767 + min)); }
number=$(f 3 10)

SHOWING AN ASCII TABLE

enum -f '[%3i] "%c"' 0 127

OPTIONS

RANDOM MODE

-r, --random

Produces random numbers (potentially with duplicates) instead of monotonic sequences.

-i, --seed=NUMBER

Pass NUMBER as initializer to the random number generator. By default, the RNG is initialized from the current time and the process ID of the running instance of enum.

FORMATTING

-b, --dumb=TEXT

Overrides the output format to TEXT without interpolating placeholders. For instance, enum -b "foo % 10" 3x produces the string "foo % 10" three times.

-c, --characters

Overrides the output format to %c producing characters. For example, enum -c 65 67 produces the letters "A", "B" and "C".

-e, --equal-width

Equalize width by padding with leading zeroes. NOTE: In the case of mixed negative and non-negative numbers (e.g. with enum -e – -10 1), non-negative values will compensate for the lack of a leading minus with an extra zero to be of equal width.

-f, --format=FORMAT

Overrides the default output format with FORMAT. For details on allowed formats please see printf(3).

FORMAT is subject to processing of C escape sequences (e.g. "\n" makes a newline). If FORMAT does not contain any placeholders, enum will print FORMAT repeatedly. In contrast, jot would have appended the number\(cqs value instead. To make numbers appear at the end with enum, adjust FORMAT appropriately.

-l, --line

Shortcut for "-s ' '" which means having a space instead of a newline as separator.

-n, --omit-newline

Omits the terminating string (defaults to newline) from output, i.e. it\(cqs a shortcut to "-t ''".

-p, --precision=COUNT

Overrides automatic selection of precision to print COUNT decimal places, e.g. "0.100" for COUNT = 3. By default, the number of digits to print is computed from the arguments given and the (given or computed) step size.

-s, --separator=TEXT

Overrides the separator that is printed between values. By default, values are separated by a newline. TEXT is subject to processing of C escape sequences (e.g. "\n" makes a newline).

-t, --terminator=TEXT

Overrides the terminator that is printed in the very end. Default is a newline. TEXT is subject to processing of C escape sequences (e.g. "\n" makes a newline).

-w, --word=FORMAT

Alias for --format, for compatibility with jot. For GNU seq\(cqs -w meaning --equal-width, see -e.

-z, --zero, --null

Print null bytes as separator, not a newline.

OTHER

-h, --help

Outputs usage information and exits with code 0 (success).

-V, --version

Displays version information and exits with code 0 (success).

USAGE IN DETAIL

ARGUMENTS

The logic of enum's command line parameters is:

enum [ OPTIONS ] LEFT .. COUNTx STEP .. RIGHT

Four arguments are involved:

LEFT, the value to start enumeration with

COUNT, the (maximum) number of values to produce

STEP, the gap from one value to another

RIGHT, the value to stop enumeration at (in some cases before)

Not all four arguments are needed, though specifying all four is possible. For a list of all valid combinations see VALID COMBINATIONS below. Details on derivation of defaults are addressed in DERIVATION OF DEFAULTS.

VALID COMBINATIONS

With four arguments:

enum LEFT .. COUNTx STEP .. RIGHT

With three arguments:

enum LEFT COUNTx RIGHT

enum LEFT .. COUNTx STEP ..

enum .. COUNTx STEP .. RIGHT

enum LEFT .. COUNTx .. RIGHT

enum LEFT .. STEP .. RIGHT

enum LEFT STEP RIGHT (for GNU seq compatibility)

With two arguments:

enum .. COUNTx STEP ..

enum .. COUNTx .. RIGHT

enum COUNTx .. RIGHT

enum .. STEP .. RIGHT

enum LEFT .. COUNTx ..

enum LEFT .. STEP ..

enum LEFT .. RIGHT

enum LEFT RIGHT (for GNU seq compatibility)

With one argument:

enum .. STEP ..

enum .. COUNTx ..

enum .. RIGHT

enum RIGHT (for GNU seq compatibility)

enum LEFT ..

enum COUNTx

With less than three arguments, defaults apply. Details are described in DERIVATION OF DEFAULTS below.

Technically, more use cases are possible. For instance, COUNTx STEP .. RIGHT is unambiguous since the order of arguments is fixed. Yet, "enum 3x 4 .. 10" reads a lot like "3 values between 4 and 10" while it actually would mean "3 values up to 10 in steps of 4". In order to keep enum\(cqs user interface as intuitive as possible, cases which could lead to misunderstandings are not implemented.

DERIVATION OF DEFAULTS

AUTO-SELECTION OF PRECISION

enum distinguishes between "2", "2.0", "2.00" and so on:

# enum 1 2
1
2

# enum 1 2.0
1.0
1.1
[..]
1.9
2.0

Also, if the derived step has more decimal places than the specified values for LEFT and RIGHT, the output precision will be raised to that of the step value:

# enum 1 .. 3x .. 2
1.0
1.5
2.0

A specified precision always takes precedence, though:

# enum -p 2 1 .. 3x .. 2
1.00
1.50
2.00

ARGUMENT DEFAULTS

In general, three arguments are needed; any three imply the fourth. This equation brings them together:

LEFT + (COUNT - 1) * STEP = RIGHT

If you specify less than three of them (see VALID COMBINATIONS), the unspecified ones are derived or set to their defaults:

LEFT defaults to 1 (unless STEP and RIGHT are specified, see DERIVATION OF LEFT below)

COUNT is infinity, unless it can be derived from the other three values.

STEP defaults to 1, unless it can be derived.

RIGHT is +/-infinity, unless it can be derived from the other three values.

Obviously, if COUNT is set to zero (0x), enum will output nothing, regardless of the other arguments.

DERIVATION OF LEFT

In general, LEFT defaults to 1:

# enum .. 3
1
2
3

If STEP and RIGHT is given, it is derived as

LEFT = RIGHT - STEP * floor(RIGHT / STEP)

# enum .. 4 .. 10
2
6
10

If, in addition to STEP and RIGHT, COUNT is given, it is derived as:

LEFT = RIGHT - (COUNT - 1) * STEP

# enum .. 2x 4 .. 10
6
10

GENERATION OF VALUES

When a custom step is requested, values are produced as follows:

value[0] = LEFT + 0 * STEP
value[1] = LEFT + 1 * STEP
..
value[i] = LEFT + i * STEP

Otherwise, to avoid imprecision adding up, values are produced as follows:

value[0] = LEFT + (RIGHT - LEFT) / (COUNT - 1) * 0
value[1] = LEFT + (RIGHT - LEFT) / (COUNT - 1) * 1
..
value[i] = LEFT + (RIGHT - LEFT) / (COUNT - 1) * i

Production stops when either COUNT values have been produced or RIGHT has been reached, whichever hits first. When all four values are given in perfect match they hit at the same time.

RANDOM MODE

Basically, random mode differs in these regards:

Produced values are random.

Argument COUNT defaults to 1 (one).

Argument LEFT (always!) defaults to 1 (one).

Argument RIGHT is required: Random does not mix with infinity.

This section covers these differences in detail.

COUNT DEFAULTS TO 1 (ONE)

In random mode only one value is produced, by default:

# enum 1 4
1
2
3
4

# enum -r 1 4
3

By specifying COUNT you can produce more values at a time:

# enum -r 1 .. 3x .. 4
2
1
3

LEFT ALWAYS DEFAULTS TO 1 (ONE)

When you need increasing numbers up to a certain maximum (say 10), each separated by a certain step (say 4) you can let enum calculate the needed starting value for you:

# enum .. 4 .. 10
2
6
10

In random mode LEFT is never calculated and defaults to 1 (one):

# enum -r .. 5x 4 .. 10
1
1
9
1
5

RANDOM DOES NOT MIX WITH INFINITY

In general, enum supports running towards infinity:

# enum 1 .. 2.0 ..
1.0
3.0
5.0
[..]

However, in random mode enum would now produce random numbers from 1 to infinity (or a big number like FLT_MAX from <float.h>), which we have decided against.

HISTORY

enum is a fusion of GNU seq and jot, feature-wise. At the core both tools print sequences of numbers. GNU seq has a clean interface but very limited functionality. jot on the other hand offers more advanced features, like producing random numbers, at the cost of a rather unfriendly interface.

With enum we try to offer a tool with the power of jot and a usable, easily memorable interface. enum is licensed under a BSD license and written in C89 for maximum portability.

The following sections take a look at the differences in detail.

COMPARISON TO JOT

Using enum instead of jot offers two main advantages:

improved usability and

uniform behavior across distributions and operating systems.

As of 2010-10-03, jot implementations still differ subtly between DragonFlyBSD, FreeBSD, MirOS BSD, NetBSD, OpenBSD, and OS X. For instance the command jot - 0 5 produces

6 integers from 0 to 5 on FreeBSD and OS X,

0 1 2 3 4 5

100 integers from 0 to 99 on NetBSD, and

0 1 2 [..] 97 98 99

100 integers from 0 to 5 (with consecutive duplicates) on DragonFlyBSD, MirOS BSD, and OpenBSD.

0 0 0 0 0 0 0 0 0 0 1 1 [..] 4 4 5 5 5 5 5 5 5 5 5 5

Basically, the full feature set of jot plus a few enhancements is contained in enum. Names of parameters have been retained for increased compatibility, e.g. -p 2 works with enum as it does with jot:

# jot -p 2 3
1.00
2.00
3.00

# enum -p 2 3
1.00
2.00
3.00

Please see OPTIONS above for further details.

ADDITIONAL FEATURES

The extra features that enum offers over jot include:

MORE MEMORABLE COMMAND LINE USAGE

In order to produce 3 random numbers between 1 and 10 (inclusively), you would run

jot -r 3 1 10

with jot. We find these alternative calls to enum more intuitive:

enum -r 1 .. 3x .. 10
enum -r 1 3x 10

CUSTOM RESOLUTION OF RANDOM

With enum you can specify that the possible values to be randomly selected from have a particular spacing. These two cases illustrate the difference between a gap of 2 and 3:

# enum -r 4 .. 100x 2 .. 10 | sort -u -n
4
6
8
10

# enum -r 4 .. 100x 3 .. 10 | sort -u -n
4
7
10

SUPPORT FOR SEVERAL PLACEHOLDERS IN FORMAT STRINGS

jot on DragonFlyBSD, FreeBSD, MirOS BSD, OpenBSD, and OS X:

# jot -w %g%g 3
jot: too many conversions

jot on NetBSD:

# jot -w %g%g 3
jot: unknown or invalid format `%g%g'

enum on any platform:

# enum -f %g%g 3
11
22
33

SUPPORT FOR ESCAPE SEQUENCES

None of the jot implementations we tested (DragonFlyBSD, FreeBSD, MirOS BSD, NetBSD, OpenBSD, and OS X) supports escape sequences, say "\n", in FORMAT:

# jot -w '%g\x41' 1
1\x41

enum is able to unescape "\x41" properly:

# enum -w '%g\x41' 1
1A

On a side note, "\x25" produces a literal "%"; it does not make a placeholder:

# enum -w '%g \x25g' 1
1 %g

NULL BYTES AS SEPARATOR

When using format strings containing spaces, you may run into trouble in contexts like for loops or xargs: spaces are treated as separators which breaks up your strings in pieces:

# enum -f 'sheep number %d' 2 | xargs -n 1 echo
sheep
number
1
sheep
number
2

To prevent this, you could pass --null to both enum and xargs:

# enum --null -f 'sheep number %d' 2 | xargs --null -n 1 echo
sheep number 1
sheep number 2

DIFFERENCES

HANDLING OF FORMATS WITHOUT PLACEHOLDERS

In contrast to jot, enum does not append the current value if the formatting string does not contain a placeholder. Behavior of jot:

# jot 3 -w test_
test_1
test_2
test_3

Behavior of enum:

# enum -w test_ 3
test_
test_
test_

In order to achieve jot\(cqs output with enum, you should manually append a placeholder:

# enum -w test_%d 3
test_1
test_2
test_3

NON-NUMBER VALUES FOR LEFT AND RIGHT

enum does not support using ASCII characters instead of their numerical values (e.g. "A" for 65) for LEFT and RIGHT. With jot you can do:

# jot 3 A
65
66
67

Inconsistently,

# jot 3 0
0
1
2

jot does not interpret "0" as the ASCII character with code 48. We have no intention of duplicating this mix, at the moment.

COMPARISON TO GNU SEQ

Basically, enum's usage is backwards-compatible to that of GNU seq.

ADDITIONAL FEATURES

The extra features enum offers over GNU seq include:

RANDOM NUMBER MODE

enum supports output of constrained random numbers, e.g.

enum -r 4 .. 3x 2.0 .. 11

produces three (possibly duplicate) random numbers from the set {4.0, 6.0, 8.0, 10.0}.

SUPPORT FOR INVERSE ORDERING

In contrast to GNU seq, enum supports enumerating decreasing values:

# seq 3 1

# enum 3 1
3
2
1

SUPPORT FOR SEVERAL PLACEHOLDERS IN FORMAT STRINGS

# seq -f %g%g 3
seq: format `%g%g' has too many % directives

# enum -f %g%g 3
11
22
33

SUPPORT FOR ESCAPE SEQUENCES

GNU seq does not support escape sequences, say "\n", in FORMAT:

# seq -f '%g\x41' 1
1\x41

In contrast, some of the other seq implementations around do. These three behaviours can be observed (as of 2010-10-25):

seq of Plan 9, 9base, and GNU seq:

# seq -f '%g\x41' 3
1\x41
2\x41
3\x41

seq on FreeBSD and NetBSD:

# seq -f '%g\x41' 1
1A
2A
3A

seq on DragonFlyBSD:

# seq -f '%g\x41' 1
1A3
2A3
3A3

enum unescape "\x41" to "A" as well:

# enum -f '%g\x41' 3
1A
2A
3A

On a side note, "\x25" produces a literal "%"; it does not make a placeholder:

# enum -f '%g \x25g' 1
1 %g

OMITTING FINAL NEWLINE

By specifying -n as a parameter, you can make enum omit the trailing newline.

DIFFERENCES

GNU seq\(cqs --equal-width shortcut -w conflicts with jot\(cqs -w word. We chose to make -e the shortcut for --equal-width in enum, instead.

Also, while GNU seq is licensed under GPL v3 or later, enum is licensed under the New BSD license.

THANKS

Elias Pipping, Andreas Gunschl, Justin B. Rye, David Prevot, Kamil Dudka, Michael Bienia

AUTHORS

Jan Hauke Rahm <[email protected]>

Sebastian Pipping <[email protected]>

RESOURCES

Main web site: https://fedorahosted.org/enum/

Gitweb: http://git.fedorahosted.org/git/?p=enum.git

RELATED TO enum…

jot(1), seq(1), printf(3)