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AWK
Paradigm	scripting language, procedural, event-driven
Appeared in	1977, last revised 1985, current POSIX edition is IEEE Std 1003.1-2004
Designed by	Alfred Aho, Peter Weinberger, and Brian Kernighan
Typing discipline	none; can handle strings, integers and floating point numbers; regular expressions
Major implementations	awk, GNU Awk, mawk, nawk, MKS AWK, Thompson AWK (compiler), Awka (compiler)
Dialects	old awk oawk 1977, new awk nawk 1985, GNU Awk
Influenced by	C, SNOBOL4, Bourne shell
Influenced	Perl, Korn Shell (ksh93, dtksh, tksh), JavaScript
OS	Cross-platform
Website	[1]

AWK is a general purpose programming language that is designed for processing text-based data, either in files or data streams. The name AWK is derived from the family names of its authors — Alfred Aho, Peter Weinberger, and Brian Kernighan; however, it is not commonly pronounced as a string of separate letters but rather to sound the same as the name of the bird, auk (which acts as an emblem of the language such as on The AWK Programming Language book cover). awk, when written in all lowercase letters, refers to the Unix or Plan 9 program that runs other programs written in the AWK programming language.

AWK is an example of a programming language that extensively uses the string datatype, associative arrays (that is, arrays indexed by key strings), and regular expressions. The power, terseness, and limitations of AWK programs and sed scripts inspired Larry Wall to write Perl. Because of their dense notation, all these languages are often used for writing one-liner programs.

AWK is one of the early tools to appear in Version 7 Unix and gained popularity as a way to add computational features to a Unix pipeline. A version of the AWK language is a standard feature of nearly every modern Unix-like operating system available today. AWK is mentioned in the Single UNIX Specification as one of the mandatory utilities of a Unix operating system. Besides the Bourne shell, AWK is the only other scripting language available in a standard Unix environment. Implementations of AWK exist as installed software for almost all other operating systems.

Contents 1 Structure of AWK programs 2 AWK commands 2.1 The print command 2.2 Variables and Syntax 2.3 User-defined functions 3 Sample applications 3.1 Hello World 3.2 Print lines longer than 80 characters 3.3 Print a count of words 3.4 Sum last word 3.5 Match a range of input lines 3.6 Calculate word frequencies 4 Self-contained AWK scripts 5 AWK versions and implementations 6 Books 7 References 8 See also 9 External links

An AWK program is a series of

pattern { action }

pairs, where pattern is typically an expression and action is a series of commands. Each line of input is tested against all the patterns in turn and the action executed if the expression is true. Either the pattern or the action may be omitted. The pattern defaults to matching every line of input. The default action is to print the line of input.

In addition to a simple AWK expression, the pattern can be BEGIN or END causing the action to be executed before or after all lines of input have been read, or pattern1, pattern2 which matches the range of lines of input starting with a line that matches pattern1 up to and including the line that matches pattern2 before again trying to match against pattern1 on future lines.

In addition to normal arithmetic and logical operators, AWK expressions include the tilde operator, ~, which matches a regular expressions against a string. As a handy default, /regexp/ without using the tilde operator matches against the current line of input.

AWK commands are the statement that is substituted for action in the examples above. AWK commands can include function calls, variable assignments, calculations, or any combination thereof. AWK contains built-in support for many functions; many more are provided by the various flavors of AWK. Also, some flavors support the inclusion of dynamically linked libraries, which can also provide more functions.

For brevity, the enclosing curly braces ( { } ) will be omitted from these examples.

The print command is used to output text. The output text is always terminated with a predefined string called the output record separator (ORS) whose default value is a newline. The simplest form of this command is:

print

This displays the contents of the current line. In AWK, lines are broken down into fields, and these can be displayed separately:

print $1

Displays the first field of the current line

print $1, $3

Displays the first and third fields of the current line, separated by a predefined string called the output field separator (OFS) whose default value is a single space character

Although these fields ($X) may bear resemblance to variables (the $ symbol indicates variables in perl), they actually refer to the fields of the current line. A special case, $0, refers to the entire line. In fact, the commands "print" and "print $0" are identical in functionality.

The print command can also display the results of calculations and/or function calls:

print 3+2
print foobar(3)
print foobar(variable)
print sin(3-2)

Output may be sent to a file:

print "expression" > "file name"

Variable names can use any of the characters [A-Za-z0-9_], with the exception of language keywords. The operators + - * / are addition, subtraction, multiplication, and division, respectively. For string concatenation, simply place two variables (or string constants) next to each other. It is optional to use a space in between if string constants are involved. But you can't place two variable names adjacent to each other without having a space in between. String constants are delimited by double quotes. Statements need not end with semicolons. Finally, comments can be added to programs by using # as the first character on a line.

In a format similar to C, function definitions consist of the keyword function, the function name, argument names and the function body. Here is an example of a function.

function add_three (number, temp) {
  temp = number + 3
  return temp
}

This statement can be invoked as follows:

print add_three(36)     # Outputs 39

Functions can have variables that are in the local scope. The names of these are added to the end of the argument list, though values for these should be omitted when calling the function. It is convention to add some whitespace in the argument list before the local variables, in order to indicate where the parameters end and the local variables begin.

Here is the ubiquitous "Hello world program" program written in AWK:

BEGIN { print "Hello, world!" }

Print all lines longer than 80 characters. Note that the default action is to print the current line.

length > 80 

Count words in the input, and print lines, words, and characters (like wc)

{
    w += NF
    c += length + 1
}
END { print NR, w, c }

{ s += $NF }
END { print s + 0 }

As there is no pattern for the first line of the program, every line of input matches by default so the s += $NF action is executed. s is incremented by the numeric value of $NF which is the last word on the line as defined by AWK's field separator, by default white-space. NF is the number of fields in the current line, e.g. 4. Since $4 is the value of the fourth field, $NF is the value of the last field in the line regardless of how many fields this line has, or whether it has more or fewer fields than surrounding lines.

(If the line has no fields then NF is 0, $0 is the whole line, which in this case is empty apart from possible white-space, and so has the numeric value 0.)

At the end of the input the END pattern matches so s is printed. However, since there may have been no lines of input at all, and so s has never been assigned to, it will by default be an empty string. Adding zero to a variable is an AWK idiom for coercing it from a string to a numeric value. (Concatenating an empty string is to coerce from a number to a string, e.g. s "". Note, there's no operator to concatenate strings, they're just placed adjacently.) With the coercion the program prints 0 on an empty input, without it an empty line is printed.

$ yes Wikipedia | cat -n | awk 'NR % 4 == 1, NR % 4 == 3' | head -7
     1  Wikipedia
     2  Wikipedia
     3  Wikipedia
     5  Wikipedia
     6  Wikipedia
     7  Wikipedia
     9  Wikipedia
$

The yes and cat commands generate a series of numbered lines as example input. NR is the number of records, typically lines of input, AWK has so far read, i.e. the current line number, starting at 1 for the first line of input. % is the modulo operator. NR % 4 == 1 is true for the first, fifth, ninth, etc., lines of input. Likewise, NR % 4 == 3 is true for the third, seventh, eleventh, etc., lines of input. The range pattern is false until the first part matches, on line 1, and then remains true up to and including when the second part matches, on line 3. It then stays false until the first part matches again on line 5.

The first part of a range pattern being constantly true, e.g. 1, can be used to start the range at the beginning of input. Similarly, if the second part is constantly false, e.g. 0, the range continues until the end of input.

/^--cut here--$/, 0

Prints lines of input from the first line matching the regular expression ^--cut here--$ to the end.

Word frequency, (uses associative arrays)

BEGIN { FS="[^a-zA-Z]+"}

{ for (i=1; i<=NF; i++)
     words[tolower($i)]++
}

END { for (i in words)
    print i, words[i]
}

As with many other programming languages, self-contained AWK script can be constructed using the so-called "shebang" syntax.

For example, a UNIX command called hello.awk that prints the string "Hello, world!" may be built by creating a file named hello.awk containing the following lines:

#!/usr/bin/awk -f
BEGIN { print "Hello, world!"; exit }

AWK was originally written in 1977, and distributed with Version 7 Unix.

In 1985 its authors started expanding the language, most significantly by adding user-defined functions. The language is described in the book The AWK Programming Language, published 1988, and its implementation was made available in releases of UNIX System V. To avoid confusion with the incompatible older version, this version was sometimes known as "new awk" or nawk. This implementation was released under a free software license in 1996, and is still maintained by Brian Kernighan. (see external links below)

BWK awk refers to the version by Brian W. Kernighan. It has been dubbed the "One True AWK" because of the use of the term in association with the book^[1] that originally described the language, and the fact that Kernighan was one of the original authors of awk. FreeBSD refers to this version as one-true-awk^[2].

gawk (GNU awk) is another free software implementation. It was written before the original implementation became freely available, and is still widely used. Many Linux distributions come with a recent version of gawk and gawk is widely recognized as the de-facto standard implementation in the Linux world; gawk version 3.0 was included as awk in FreeBSD prior to version 5.0. Subsequent versions of FreeBSD use BWK awk in order to avoid^[3] the GPL, a more restrictive (in the sense that GPL licensed code cannot be modified to become proprietary software) license than the BSD license. ^[4]

xgawk is a SourceForge project^[5] based on gawk. It extends gawk with dynamically loadable libraries.

mawk is a very fast AWK implementation by Mike Brennan based on a byte code interpreter.

awka (whose front end is written on top of the mawk program) is a translator of awk scripts into C code. When compiled, statically including the author's libawka.a, the resulting executables are considerably sped up and according to the author's tests compare very well with other versions of awk, perl or tcl. Small scripts will turn into programs of 160-170 kB. http://awka.sourceforge.net

Downloads and further information about these versions are available from the sites listed below.

Thompson AWK or TAWK is an AWK compiler for DOS and Windows, previously sold by Thompson Automation Software (which has ceased its activities).

Jawk is a SourceForge project^[6] to implement AWK in Java. Extensions to the language are added to provide access to Java features within AWK scripts (i.e., Java threads, sockets, Collections, etc).

BusyBox includes a sparsely documented Awk implementation that appears to be complete, written by Dmitry Zakharov. This implementation is the smallest Awk implementation out there, suitable for embedded systems.

• Alfred V. Aho, Brian W. Kernighan, and Peter J. Weinberger (1988). The AWK Programming Language. Addison-Wesley. ISBN 0-201-07981-X.  The book's webpage includes downloads of the current implementation of Awk and links to others.
• Arnold Robbins. Effective awk Programming, Edition 3.  Arnold Robbins maintained the GNU Awk implementation of AWK for more than 10 years. The free GNU Awk manual was also published by O'Reilly in May 2001. Free download of this manual is possible through the following book references.
• Arnold Robbins. GAWK: Effective AWK Programming: A User's Guide for GNU Awk, Edition 3. 
• Dale Dougherty, Arnold Robbins (March 1997). sed & awk, Second Edition, Second Edition, O'Reilly Media. ISBN 1-56592-225-5. 

• sed
• List of Unix programs

• awk: pattern scanning and processing language – Commands & Utilities Reference, The Single UNIX® Specification, Issue 6 from The Open Group
• awk maintained by Brian Kernighan.
• comp.lang.awk is a USENET newsgroup dedicated to AWK.
• GAWK (GNU awk) webpage
• mawk download site
• DJGPP port of Gawk 3.11b as a downloadable 768KB zipfile
• xgawk download site
• Awka Open Source, AWK to C Conversion Tool
• TAWK Compiler
• Jawk Open Source, an implementation of AWK in Java with extensions
• gnulamp awk tutorial
• AWK annoyances; This page includes a Linux port of the MKS version of AWK.

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