NAME
awk - pattern scanning and processing language
SYNOPSIS
awk [-F ERE][-v assignment] ... program [argument ...]
awk [-F ERE] -f progfile ... [-v assignment] ...[argument ...]
DESCRIPTION
The awk utility shall execute programs written in the awk programming
language, which is specialized for textual data manipulation. An awk
program is a sequence of patterns and corresponding actions. When input
is read that matches a pattern, the action associated with that pattern
is carried out.
Input shall be interpreted as a sequence of records. By default, a
record is a line, less its terminating <newline>, but this can be
changed by using the RS built-in variable. Each record of input shall
be matched in turn against each pattern in the program. For each
pattern matched, the associated action shall be executed.
The awk utility shall interpret each input record as a sequence of
fields where, by default, a field is a string of non- <blank>s. This
default white-space field delimiter can be changed by using the FS
built-in variable or -F ERE. The awk utility shall denote the first
field in a record $1, the second $2, and so on. The symbol $0 shall
refer to the entire record; setting any other field causes the re-
evaluation of $0. Assigning to $0 shall reset the values of all other
fields and the NF built-in variable.
OPTIONS
The awk utility shall conform to the Base Definitions volume of
IEEE Std 1003.1-2001, Section 12.2, Utility Syntax Guidelines.
The following options shall be supported:
-F ERE
Define the input field separator to be the extended regular
expression ERE, before any input is read; see Regular
Expressions .
-f progfile
Specify the pathname of the file progfile containing an awk
program. If multiple instances of this option are specified, the
concatenation of the files specified as progfile in the order
specified shall be the awk program. The awk program can
alternatively be specified in the command line as a single
argument.
-v assignment
The application shall ensure that the assignment argument is in
the same form as an assignment operand. The specified variable
assignment shall occur prior to executing the awk program,
including the actions associated with BEGIN patterns (if any).
Multiple occurrences of this option can be specified.
OPERANDS
The following operands shall be supported:
program
If no -f option is specified, the first operand to awk shall be
the text of the awk program. The application shall supply the
program operand as a single argument to awk. If the text does
not end in a <newline>, awk shall interpret the text as if it
did.
argument
Either of the following two types of argument can be intermixed:
file
A pathname of a file that contains the input to be read, which
is matched against the set of patterns in the program. If no
file operands are specified, or if a file operand is ’-’ , the
standard input shall be used.
assignment
An operand that begins with an underscore or alphabetic
character from the portable character set (see the table in the
Base Definitions volume of IEEE Std 1003.1-2001, Section 6.1,
Portable Character Set), followed by a sequence of underscores,
digits, and alphabetics from the portable character set,
followed by the ’=’ character, shall specify a variable
assignment rather than a pathname. The characters before the ’=’
represent the name of an awk variable; if that name is an awk
reserved word (see Grammar ) the behavior is undefined. The
characters following the equal sign shall be interpreted as if
they appeared in the awk program preceded and followed by a
double-quote ( ’ )’ character, as a STRING token (see Grammar ),
except that if the last character is an unescaped backslash, it
shall be interpreted as a literal backslash rather than as the
first character of the sequence "\"" . The variable shall be
assigned the value of that STRING token and, if appropriate,
shall be considered a numeric string (see Expressions in awk ),
the variable shall also be assigned its numeric value. Each such
variable assignment shall occur just prior to the processing of
the following file, if any. Thus, an assignment before the first
file argument shall be executed after the BEGIN actions (if
any), while an assignment after the last file argument shall
occur before the END actions (if any). If there are no file
arguments, assignments shall be executed before processing the
standard input.
STDIN
The standard input shall be used only if no file operands are
specified, or if a file operand is ’-’ ; see the INPUT FILES section.
If the awk program contains no actions and no patterns, but is
otherwise a valid awk program, standard input and any file operands
shall not be read and awk shall exit with a return status of zero.
INPUT FILES
Input files to the awk program from any of the following sources shall
be text files:
* Any file operands or their equivalents, achieved by modifying the
awk variables ARGV and ARGC
* Standard input in the absence of any file operands
* Arguments to the getline function
Whether the variable RS is set to a value other than a <newline> or
not, for these files, implementations shall support records terminated
with the specified separator up to {LINE_MAX} bytes and may support
longer records.
If -f progfile is specified, the application shall ensure that the
files named by each of the progfile option-arguments are text files and
their concatenation, in the same order as they appear in the arguments,
is an awk program.
ENVIRONMENT VARIABLES
The following environment variables shall affect the execution of awk:
LANG Provide a default value for the internationalization variables
that are unset or null. (See the Base Definitions volume of
IEEE Std 1003.1-2001, Section 8.2, Internationalization
Variables for the precedence of internationalization variables
used to determine the values of locale categories.)
LC_ALL If set to a non-empty string value, override the values of all
the other internationalization variables.
LC_COLLATE
Determine the locale for the behavior of ranges, equivalence
classes, and multi-character collating elements within regular
expressions and in comparisons of string values.
LC_CTYPE
Determine the locale for the interpretation of sequences of
bytes of text data as characters (for example, single-byte as
opposed to multi-byte characters in arguments and input files),
the behavior of character classes within regular expressions,
the identification of characters as letters, and the mapping of
uppercase and lowercase characters for the toupper and tolower
functions.
LC_MESSAGES
Determine the locale that should be used to affect the format
and contents of diagnostic messages written to standard error.
LC_NUMERIC
Determine the radix character used when interpreting numeric
input, performing conversions between numeric and string values,
and formatting numeric output. Regardless of locale, the period
character (the decimal-point character of the POSIX locale) is
the decimal-point character recognized in processing awk
programs (including assignments in command line arguments).
NLSPATH
Determine the location of message catalogs for the processing of
LC_MESSAGES .
PATH Determine the search path when looking for commands executed by
system(expr), or input and output pipes; see the Base
Definitions volume of IEEE Std 1003.1-2001, Chapter 8,
Environment Variables.
In addition, all environment variables shall be visible via the awk
variable ENVIRON.
ASYNCHRONOUS EVENTS
Default.
STDOUT
The nature of the output files depends on the awk program.
STDERR
The standard error shall be used only for diagnostic messages.
OUTPUT FILES
The nature of the output files depends on the awk program.
EXTENDED DESCRIPTION
Overall Program Structure
An awk program is composed of pairs of the form:
pattern { action }
Either the pattern or the action (including the enclosing brace
characters) can be omitted.
A missing pattern shall match any record of input, and a missing action
shall be equivalent to:
{ print }
Execution of the awk program shall start by first executing the actions
associated with all BEGIN patterns in the order they occur in the
program. Then each file operand (or standard input if no files were
specified) shall be processed in turn by reading data from the file
until a record separator is seen ( <newline> by default). Before the
first reference to a field in the record is evaluated, the record shall
be split into fields, according to the rules in Regular Expressions ,
using the value of FS that was current at the time the record was read.
Each pattern in the program then shall be evaluated in the order of
occurrence, and the action associated with each pattern that matches
the current record executed. The action for a matching pattern shall be
executed before evaluating subsequent patterns. Finally, the actions
associated with all END patterns shall be executed in the order they
occur in the program.
Expressions in awk
Expressions describe computations used in patterns and actions. In the
following table, valid expression operations are given in groups from
highest precedence first to lowest precedence last, with equal-
precedence operators grouped between horizontal lines. In expression
evaluation, where the grammar is formally ambiguous, higher precedence
operators shall be evaluated before lower precedence operators. In this
table expr, expr1, expr2, and expr3 represent any expression, while
lvalue represents any entity that can be assigned to (that is, on the
left side of an assignment operator). The precise syntax of expressions
is given in Grammar .
Table: Expressions in Decreasing Precedence in awk
Syntax Name Type of Result Associativity
( expr ) Grouping Type of expr N/A
$expr Field reference String N/A
++ lvalue Pre-increment Numeric N/A
-- lvalue Pre-decrement Numeric N/A
lvalue ++ Post-increment Numeric N/A
lvalue -- Post-decrement Numeric N/A
expr ^ expr Exponentiation Numeric Right
! expr Logical not Numeric N/A
+ expr Unary plus Numeric N/A
- expr Unary minus Numeric N/A
expr * expr Multiplication Numeric Left
expr / expr Division Numeric Left
expr % expr Modulus Numeric Left
expr + expr Addition Numeric Left
expr - expr Subtraction Numeric Left
expr expr String concatenation String Left
expr < expr Less than Numeric None
expr <= expr Less than or equal to Numeric None
expr != expr Not equal to Numeric None
expr == expr Equal to Numeric None
expr > expr Greater than Numeric None
expr >= expr Greater than or equal to Numeric None
expr ~ expr ERE match Numeric None
expr !~ expr ERE non-match Numeric None
expr in array Array membership Numeric Left
( index ) in array Multi-dimension array Numeric Left
membership
expr && expr Logical AND Numeric Left
expr || expr Logical OR Numeric Left
expr1 ? expr2 : expr3 Conditional expression Type of selected Right
expr2 or expr3
lvalue ^= expr Exponentiation assignment Numeric Right
lvalue %= expr Modulus assignment Numeric Right
lvalue *= expr Multiplication assignment Numeric Right
lvalue /= expr Division assignment Numeric Right
lvalue += expr Addition assignment Numeric Right
lvalue -= expr Subtraction assignment Numeric Right
lvalue = expr Assignment Type of expr Right
Each expression shall have either a string value, a numeric value, or
both. Except as stated for specific contexts, the value of an
expression shall be implicitly converted to the type needed for the
context in which it is used. A string value shall be converted to a
numeric value by the equivalent of the following calls to functions
defined by the ISO C standard:
setlocale(LC_NUMERIC, "");
numeric_value = atof(string_value);
A numeric value that is exactly equal to the value of an integer (see
Concepts Derived from the ISO C Standard ) shall be converted to a
string by the equivalent of a call to the sprintf function (see String
Functions ) with the string "%d" as the fmt argument and the numeric
value being converted as the first and only expr argument. Any other
numeric value shall be converted to a string by the equivalent of a
call to the sprintf function with the value of the variable CONVFMT as
the fmt argument and the numeric value being converted as the first and
only expr argument. The result of the conversion is unspecified if the
value of CONVFMT is not a floating-point format specification. This
volume of IEEE Std 1003.1-2001 specifies no explicit conversions
between numbers and strings. An application can force an expression to
be treated as a number by adding zero to it, or can force it to be
treated as a string by concatenating the null string ( "" ) to it.
A string value shall be considered a numeric string if it comes from
one of the following:
1. Field variables
2. Input from the getline() function
3. FILENAME
4. ARGV array elements
5. ENVIRON array elements
6. Array elements created by the split() function
7. A command line variable assignment
8. Variable assignment from another numeric string variable
and after all the following conversions have been applied, the
resulting string would lexically be recognized as a NUMBER token as
described by the lexical conventions in Grammar :
* All leading and trailing <blank>s are discarded.
* If the first non- <blank> is ’+’ or ’-’ , it is discarded.
* Changing each occurrence of the decimal point character from the
current locale to a period.
If a ’-’ character is ignored in the preceding description, the numeric
value of the numeric string shall be the negation of the numeric value
of the recognized NUMBER token. Otherwise, the numeric value of the
numeric string shall be the numeric value of the recognized NUMBER
token. Whether or not a string is a numeric string shall be relevant
only in contexts where that term is used in this section.
When an expression is used in a Boolean context, if it has a numeric
value, a value of zero shall be treated as false and any other value
shall be treated as true. Otherwise, a string value of the null string
shall be treated as false and any other value shall be treated as true.
A Boolean context shall be one of the following:
* The first subexpression of a conditional expression
* An expression operated on by logical NOT, logical AND, or logical OR
* The second expression of a for statement
* The expression of an if statement
* The expression of the while clause in either a while or do... while
statement
* An expression used as a pattern (as in Overall Program Structure)
All arithmetic shall follow the semantics of floating-point arithmetic
as specified by the ISO C standard (see Concepts Derived from the ISO C
Standard ).
The value of the expression:
expr1 ^ expr2
shall be equivalent to the value returned by the ISO C standard
function call:
pow(expr1, expr2)
The expression:
lvalue ^= expr
shall be equivalent to the ISO C standard expression:
lvalue = pow(lvalue, expr)
except that lvalue shall be evaluated only once. The value of the
expression:
expr1 % expr2
shall be equivalent to the value returned by the ISO C standard
function call:
fmod(expr1, expr2)
The expression:
lvalue %= expr
shall be equivalent to the ISO C standard expression:
lvalue = fmod(lvalue, expr)
except that lvalue shall be evaluated only once.
Variables and fields shall be set by the assignment statement:
lvalue = expression
and the type of expression shall determine the resulting variable type.
The assignment includes the arithmetic assignments ( "+=" , "-=" , "*="
, "/=" , "%=" , "^=" , "++" , "--" ) all of which shall produce a
numeric result. The left-hand side of an assignment and the target of
increment and decrement operators can be one of a variable, an array
with index, or a field selector.
The awk language supplies arrays that are used for storing numbers or
strings. Arrays need not be declared. They shall initially be empty,
and their sizes shall change dynamically. The subscripts, or element
identifiers, are strings, providing a type of associative array
capability. An array name followed by a subscript within square
brackets can be used as an lvalue and thus as an expression, as
described in the grammar; see Grammar . Unsubscripted array names can
be used in only the following contexts:
* A parameter in a function definition or function call
* The NAME token following any use of the keyword in as specified in
the grammar (see Grammar ); if the name used in this context is not
an array name, the behavior is undefined
A valid array index shall consist of one or more comma-separated
expressions, similar to the way in which multi-dimensional arrays are
indexed in some programming languages. Because awk arrays are really
one-dimensional, such a comma-separated list shall be converted to a
single string by concatenating the string values of the separate
expressions, each separated from the other by the value of the SUBSEP
variable. Thus, the following two index operations shall be
equivalent:
var[expr1, expr2, ... exprn]
var[expr1 SUBSEP expr2 SUBSEP ... SUBSEP exprn]
The application shall ensure that a multi-dimensioned index used with
the in operator is parenthesized. The in operator, which tests for the
existence of a particular array element, shall not cause that element
to exist. Any other reference to a nonexistent array element shall
automatically create it.
Comparisons (with the ’<’ , "<=" , "!=" , "==" , ’>’ , and ">="
operators) shall be made numerically if both operands are numeric, if
one is numeric and the other has a string value that is a numeric
string, or if one is numeric and the other has the uninitialized value.
Otherwise, operands shall be converted to strings as required and a
string comparison shall be made using the locale-specific collation
sequence. The value of the comparison expression shall be 1 if the
relation is true, or 0 if the relation is false.
Variables and Special Variables
Variables can be used in an awk program by referencing them. With the
exception of function parameters (see User-Defined Functions ), they
are not explicitly declared. Function parameter names shall be local to
the function; all other variable names shall be global. The same name
shall not be used as both a function parameter name and as the name of
a function or a special awk variable. The same name shall not be used
both as a variable name with global scope and as the name of a
function. The same name shall not be used within the same scope both as
a scalar variable and as an array. Uninitialized variables, including
scalar variables, array elements, and field variables, shall have an
uninitialized value. An uninitialized value shall have both a numeric
value of zero and a string value of the empty string. Evaluation of
variables with an uninitialized value, to either string or numeric,
shall be determined by the context in which they are used.
Field variables shall be designated by a ’$’ followed by a number or
numerical expression. The effect of the field number expression
evaluating to anything other than a non-negative integer is
unspecified; uninitialized variables or string values need not be
converted to numeric values in this context. New field variables can be
created by assigning a value to them. References to nonexistent fields
(that is, fields after $NF), shall evaluate to the uninitialized value.
Such references shall not create new fields. However, assigning to a
nonexistent field (for example, $(NF+2)=5) shall increase the value of
NF; create any intervening fields with the uninitialized value; and
cause the value of $0 to be recomputed, with the fields being separated
by the value of OFS. Each field variable shall have a string value or
an uninitialized value when created. Field variables shall have the
uninitialized value when created from $0 using FS and the variable does
not contain any characters. If appropriate, the field variable shall be
considered a numeric string (see Expressions in awk ).
Implementations shall support the following other special variables
that are set by awk:
ARGC The number of elements in the ARGV array.
ARGV An array of command line arguments, excluding options and the
program argument, numbered from zero to ARGC-1.
The arguments in ARGV can be modified or added to; ARGC can be altered.
As each input file ends, awk shall treat the next non-null element of
ARGV, up to the current value of ARGC-1, inclusive, as the name of the
next input file. Thus, setting an element of ARGV to null means that it
shall not be treated as an input file. The name ’-’ indicates the
standard input. If an argument matches the format of an assignment
operand, this argument shall be treated as an assignment rather than a
file argument.
CONVFMT
The printf format for converting numbers to strings (except for
output statements, where OFMT is used); "%.6g" by default.
ENVIRON
An array representing the value of the environment, as described
in the exec functions defined in the System Interfaces volume of
IEEE Std 1003.1-2001. The indices of the array shall be strings
consisting of the names of the environment variables, and the
value of each array element shall be a string consisting of the
value of that variable. If appropriate, the environment variable
shall be considered a numeric string (see Expressions in awk );
the array element shall also have its numeric value.
In all cases where the behavior of awk is affected by environment
variables (including the environment of any commands that awk executes
via the system function or via pipeline redirections with the print
statement, the printf statement, or the getline function), the
environment used shall be the environment at the time awk began
executing; it is implementation-defined whether any modification of
ENVIRON affects this environment.
FILENAME
A pathname of the current input file. Inside a BEGIN action the
value is undefined. Inside an END action the value shall be the
name of the last input file processed.
FNR The ordinal number of the current record in the current file.
Inside a BEGIN action the value shall be zero. Inside an END
action the value shall be the number of the last record
processed in the last file processed.
FS Input field separator regular expression; a <space> by default.
NF The number of fields in the current record. Inside a BEGIN
action, the use of NF is undefined unless a getline function
without a var argument is executed previously. Inside an END
action, NF shall retain the value it had for the last record
read, unless a subsequent, redirected, getline function without
a var argument is performed prior to entering the END action.
NR The ordinal number of the current record from the start of
input. Inside a BEGIN action the value shall be zero. Inside an
END action the value shall be the number of the last record
processed.
OFMT The printf format for converting numbers to strings in output
statements (see Output Statements ); "%.6g" by default. The
result of the conversion is unspecified if the value of OFMT is
not a floating-point format specification.
OFS The print statement output field separation; <space> by default.
ORS The print statement output record separator; a <newline> by
default.
RLENGTH
The length of the string matched by the match function.
RS The first character of the string value of RS shall be the input
record separator; a <newline> by default. If RS contains more
than one character, the results are unspecified. If RS is null,
then records are separated by sequences consisting of a
<newline> plus one or more blank lines, leading or trailing
blank lines shall not result in empty records at the beginning
or end of the input, and a <newline> shall always be a field
separator, no matter what the value of FS is.
RSTART The starting position of the string matched by the match
function, numbering from 1. This shall always be equivalent to
the return value of the match function.
SUBSEP The subscript separator string for multi-dimensional arrays; the
default value is implementation-defined.
Regular Expressions
The awk utility shall make use of the extended regular expression
notation (see the Base Definitions volume of IEEE Std 1003.1-2001,
Section 9.4, Extended Regular Expressions) except that it shall allow
the use of C-language conventions for escaping special characters
within the EREs, as specified in the table in the Base Definitions
volume of IEEE Std 1003.1-2001, Chapter 5, File Format Notation ( ’\\’
, ’\a’ , ’\b’ , ’\f’ , ’\n’ , ’\r’ , ’\t’ , ’\v’ ) and the following
table; these escape sequences shall be recognized both inside and
outside bracket expressions. Note that records need not be separated
by <newline>s and string constants can contain <newline>s, so even the
"\n" sequence is valid in awk EREs. Using a slash character within an
ERE requires the escaping shown in the following table.
Table: Escape Sequences in awk
Escape
Sequence Description Meaning
\" Backslash quotation-mark Quotation-mark character
\/ Backslash slash Slash character
\ddd A backslash character followed The character whose encoding
by the longest sequence of is represented by the one,
one, two, or three octal-digit two, or three-digit octal
characters (01234567). If all integer. Multi-byte characters
of the digits are 0 (that is, require multiple, concatenated
representation of the NUL escape sequences of this type,
character), the behavior is including the leading ’\’ for
undefined. each byte.
\c A backslash character followed Undefined
by any character not described
in this table or in the table
in the Base Definitions volume
of IEEE Std 1003.1-2001,
Chapter 5, File Format
Notation ( ’\\’ , ’\a’ , ’\b’
, ’\f’ , ’\n’ , ’\r’ , ’\t’ ,
’\v’ ).
A regular expression can be matched against a specific field or string
by using one of the two regular expression matching operators, ’~’ and
"!~" . These operators shall interpret their right-hand operand as a
regular expression and their left-hand operand as a string. If the
regular expression matches the string, the ’~’ expression shall
evaluate to a value of 1, and the "!~" expression shall evaluate to a
value of 0. (The regular expression matching operation is as defined by
the term matched in the Base Definitions volume of
IEEE Std 1003.1-2001, Section 9.1, Regular Expression Definitions,
where a match occurs on any part of the string unless the regular
expression is limited with the circumflex or dollar sign special
characters.) If the regular expression does not match the string, the
’~’ expression shall evaluate to a value of 0, and the "!~" expression
shall evaluate to a value of 1. If the right-hand operand is any
expression other than the lexical token ERE, the string value of the
expression shall be interpreted as an extended regular expression,
including the escape conventions described above. Note that these same
escape conventions shall also be applied in determining the value of a
string literal (the lexical token STRING), and thus shall be applied a
second time when a string literal is used in this context.
When an ERE token appears as an expression in any context other than as
the right-hand of the ’~’ or "!~" operator or as one of the built-in
function arguments described below, the value of the resulting
expression shall be the equivalent of:
$0 ~ /ere/
The ere argument to the gsub, match, sub functions, and the fs argument
to the split function (see String Functions ) shall be interpreted as
extended regular expressions. These can be either ERE tokens or
arbitrary expressions, and shall be interpreted in the same manner as
the right-hand side of the ’~’ or "!~" operator.
An extended regular expression can be used to separate fields by using
the -F ERE option or by assigning a string containing the expression to
the built-in variable FS. The default value of the FS variable shall be
a single <space>. The following describes FS behavior:
1. If FS is a null string, the behavior is unspecified.
2. If FS is a single character:
a. If FS is <space>, skip leading and trailing <blank>s; fields
shall be delimited by sets of one or more <blank>s.
b. Otherwise, if FS is any other character c, fields shall be
delimited by each single occurrence of c.
3. Otherwise, the string value of FS shall be considered to be an
extended regular expression. Each occurrence of a sequence matching
the extended regular expression shall delimit fields.
Except for the ’~’ and "!~" operators, and in the gsub, match, split,
and sub built-in functions, ERE matching shall be based on input
records; that is, record separator characters (the first character of
the value of the variable RS, <newline> by default) cannot be embedded
in the expression, and no expression shall match the record separator
character. If the record separator is not <newline>, <newline>s
embedded in the expression can be matched. For the ’~’ and "!~"
operators, and in those four built-in functions, ERE matching shall be
based on text strings; that is, any character (including <newline> and
the record separator) can be embedded in the pattern, and an
appropriate pattern shall match any character. However, in all awk ERE
matching, the use of one or more NUL characters in the pattern, input
record, or text string produces undefined results.
Patterns
A pattern is any valid expression, a range specified by two expressions
separated by a comma, or one of the two special patterns BEGIN or END.
Special Patterns
The awk utility shall recognize two special patterns, BEGIN and END.
Each BEGIN pattern shall be matched once and its associated action
executed before the first record of input is read (except possibly by
use of the getline function-see Input/Output and General Functions - in
a prior BEGIN action) and before command line assignment is done. Each
END pattern shall be matched once and its associated action executed
after the last record of input has been read. These two patterns shall
have associated actions.
BEGIN and END shall not combine with other patterns. Multiple BEGIN and
END patterns shall be allowed. The actions associated with the BEGIN
patterns shall be executed in the order specified in the program, as
are the END actions. An END pattern can precede a BEGIN pattern in a
program.
If an awk program consists of only actions with the pattern BEGIN, and
the BEGIN action contains no getline function, awk shall exit without
reading its input when the last statement in the last BEGIN action is
executed. If an awk program consists of only actions with the pattern
END or only actions with the patterns BEGIN and END, the input shall be
read before the statements in the END actions are executed.
Expression Patterns
An expression pattern shall be evaluated as if it were an expression in
a Boolean context. If the result is true, the pattern shall be
considered to match, and the associated action (if any) shall be
executed. If the result is false, the action shall not be executed.
Pattern Ranges
A pattern range consists of two expressions separated by a comma; in
this case, the action shall be performed for all records between a
match of the first expression and the following match of the second
expression, inclusive. At this point, the pattern range can be repeated
starting at input records subsequent to the end of the matched range.
Actions
An action is a sequence of statements as shown in the grammar in
Grammar . Any single statement can be replaced by a statement list
enclosed in braces. The application shall ensure that statements in a
statement list are separated by <newline>s or semicolons. Statements in
a statement list shall be executed sequentially in the order that they
appear.
The expression acting as the conditional in an if statement shall be
evaluated and if it is non-zero or non-null, the following statement
shall be executed; otherwise, if else is present, the statement
following the else shall be executed.
The if, while, do... while, for, break, and continue statements are
based on the ISO C standard (see Concepts Derived from the ISO C
Standard ), except that the Boolean expressions shall be treated as
described in Expressions in awk , and except in the case of:
for (variable in array)
which shall iterate, assigning each index of array to variable in an
unspecified order. The results of adding new elements to array within
such a for loop are undefined. If a break or continue statement occurs
outside of a loop, the behavior is undefined.
The delete statement shall remove an individual array element. Thus,
the following code deletes an entire array:
for (index in array)
delete array[index]
The next statement shall cause all further processing of the current
input record to be abandoned. The behavior is undefined if a next
statement appears or is invoked in a BEGIN or END action.
The exit statement shall invoke all END actions in the order in which
they occur in the program source and then terminate the program without
reading further input. An exit statement inside an END action shall
terminate the program without further execution of END actions. If an
expression is specified in an exit statement, its numeric value shall
be the exit status of awk, unless subsequent errors are encountered or
a subsequent exit statement with an expression is executed.
Output Statements
Both print and printf statements shall write to standard output by
default. The output shall be written to the location specified by
output_redirection if one is supplied, as follows:
> expression>> expression| expression
In all cases, the expression shall be evaluated to produce a string
that is used as a pathname into which to write (for ’>’ or ">>" ) or as
a command to be executed (for ’|’ ). Using the first two forms, if the
file of that name is not currently open, it shall be opened, creating
it if necessary and using the first form, truncating the file. The
output then shall be appended to the file. As long as the file remains
open, subsequent calls in which expression evaluates to the same string
value shall simply append output to the file. The file remains open
until the close function (see Input/Output and General Functions ) is
called with an expression that evaluates to the same string value.
The third form shall write output onto a stream piped to the input of a
command. The stream shall be created if no stream is currently open
with the value of expression as its command name. The stream created
shall be equivalent to one created by a call to the popen() function
defined in the System Interfaces volume of IEEE Std 1003.1-2001 with
the value of expression as the command argument and a value of w as the
mode argument. As long as the stream remains open, subsequent calls in
which expression evaluates to the same string value shall write output
to the existing stream. The stream shall remain open until the close
function (see Input/Output and General Functions ) is called with an
expression that evaluates to the same string value. At that time, the
stream shall be closed as if by a call to the pclose() function defined
in the System Interfaces volume of IEEE Std 1003.1-2001.
As described in detail by the grammar in Grammar , these output
statements shall take a comma-separated list of expressions referred to
in the grammar by the non-terminal symbols expr_list, print_expr_list,
or print_expr_list_opt. This list is referred to here as the expression
list, and each member is referred to as an expression argument.
The print statement shall write the value of each expression argument
onto the indicated output stream separated by the current output field
separator (see variable OFS above), and terminated by the output record
separator (see variable ORS above). All expression arguments shall be
taken as strings, being converted if necessary; this conversion shall
be as described in Expressions in awk , with the exception that the
printf format in OFMT shall be used instead of the value in CONVFMT. An
empty expression list shall stand for the whole input record ($0).
The printf statement shall produce output based on a notation similar
to the File Format Notation used to describe file formats in this
volume of IEEE Std 1003.1-2001 (see the Base Definitions volume of
IEEE Std 1003.1-2001, Chapter 5, File Format Notation). Output shall
be produced as specified with the first expression argument as the
string format and subsequent expression arguments as the strings arg1
to argn, inclusive, with the following exceptions:
1. The format shall be an actual character string rather than a
graphical representation. Therefore, it cannot contain empty
character positions. The <space> in the format string, in any
context other than a flag of a conversion specification, shall be
treated as an ordinary character that is copied to the output.
2. If the character set contains a ’ ’ character and that character
appears in the format string, it shall be treated as an ordinary
character that is copied to the output.
3. The escape sequences beginning with a backslash character shall be
treated as sequences of ordinary characters that are copied to the
output. Note that these same sequences shall be interpreted
lexically by awk when they appear in literal strings, but they
shall not be treated specially by the printf statement.
4. A field width or precision can be specified as the ’*’ character
instead of a digit string. In this case the next argument from the
expression list shall be fetched and its numeric value taken as the
field width or precision.
5. The implementation shall not precede or follow output from the d or
u conversion specifier characters with <blank>s not specified by
the format string.
6. The implementation shall not precede output from the o conversion
specifier character with leading zeros not specified by the format
string.
7. For the c conversion specifier character: if the argument has a
numeric value, the character whose encoding is that value shall be
output. If the value is zero or is not the encoding of any
character in the character set, the behavior is undefined. If the
argument does not have a numeric value, the first character of the
string value shall be output; if the string does not contain any
characters, the behavior is undefined.
8. For each conversion specification that consumes an argument, the
next expression argument shall be evaluated. With the exception of
the c conversion specifier character, the value shall be converted
(according to the rules specified in Expressions in awk ) to the
appropriate type for the conversion specification.
9. If there are insufficient expression arguments to satisfy all the
conversion specifications in the format string, the behavior is
undefined.
10. If any character sequence in the format string begins with a ’%’
character, but does not form a valid conversion specification, the
behavior is unspecified.
Both print and printf can output at least {LINE_MAX} bytes.
Functions
The awk language has a variety of built-in functions: arithmetic,
string, input/output, and general.
Arithmetic Functions
The arithmetic functions, except for int, shall be based on the ISO C
standard (see Concepts Derived from the ISO C Standard ). The behavior
is undefined in cases where the ISO C standard specifies that an error
be returned or that the behavior is undefined. Although the grammar
(see Grammar ) permits built-in functions to appear with no arguments
or parentheses, unless the argument or parentheses are indicated as
optional in the following list (by displaying them within the "[]"
brackets), such use is undefined.
atan2(y,x)
Return arctangent of y/x in radians in the range [-pi,pi].
cos(x) Return cosine of x, where x is in radians.
sin(x) Return sine of x, where x is in radians.
exp(x) Return the exponential function of x.
log(x) Return the natural logarithm of x.
sqrt(x)
Return the square root of x.
int(x) Return the argument truncated to an integer. Truncation shall be
toward 0 when x>0.
rand() Return a random number n, such that 0<=n<1.
srand([expr])
Set the seed value for rand to expr or use the time of day if
expr is omitted. The previous seed value shall be returned.
String Functions
The string functions in the following list shall be supported. Although
the grammar (see Grammar ) permits built-in functions to appear with no
arguments or parentheses, unless the argument or parentheses are
indicated as optional in the following list (by displaying them within
the "[]" brackets), such use is undefined.
gsub(ere, repl[, in])
Behave like sub (see below), except that it shall replace all
occurrences of the regular expression (like the ed utility
global substitute) in $0 or in the in argument, when specified.
index(s, t)
Return the position, in characters, numbering from 1, in string
s where string t first occurs, or zero if it does not occur at
all.
length[([s])]
Return the length, in characters, of its argument taken as a
string, or of the whole record, $0, if there is no argument.
match(s, ere)
Return the position, in characters, numbering from 1, in string
s where the extended regular expression ere occurs, or zero if
it does not occur at all. RSTART shall be set to the starting
position (which is the same as the returned value), zero if no
match is found; RLENGTH shall be set to the length of the
matched string, -1 if no match is found.
split(s, a[, fs ])
Split the string s into array elements a[1], a[2], ..., a[n],
and return n. All elements of the array shall be deleted before
the split is performed. The separation shall be done with the
ERE fs or with the field separator FS if fs is not given. Each
array element shall have a string value when created and, if
appropriate, the array element shall be considered a numeric
string (see Expressions in awk ). The effect of a null string as
the value of fs is unspecified.
sprintf(fmt, expr, expr, ...)
Format the expressions according to the printf format given by
fmt and return the resulting string.
sub(ere, repl[, in ])
Substitute the string repl in place of the first instance of the
extended regular expression ERE in string in and return the
number of substitutions. An ampersand ( ’&’ ) appearing in the
string repl shall be replaced by the string from in that matches
the ERE. An ampersand preceded with a backslash ( ’\’ ) shall be
interpreted as the literal ampersand character. An occurrence of
two consecutive backslashes shall be interpreted as just a
single literal backslash character. Any other occurrence of a
backslash (for example, preceding any other character) shall be
treated as a literal backslash character. Note that if repl is a
string literal (the lexical token STRING; see Grammar ), the
handling of the ampersand character occurs after any lexical
processing, including any lexical backslash escape sequence
processing. If in is specified and it is not an lvalue (see
Expressions in awk ), the behavior is undefined. If in is
omitted, awk shall use the current record ($0) in its place.
substr(s, m[, n ])
Return the at most n-character substring of s that begins at
position m, numbering from 1. If n is omitted, or if n specifies
more characters than are left in the string, the length of the
substring shall be limited by the length of the string s.
tolower(s)
Return a string based on the string s. Each character in s that
is an uppercase letter specified to have a tolower mapping by
the LC_CTYPE category of the current locale shall be replaced in
the returned string by the lowercase letter specified by the
mapping. Other characters in s shall be unchanged in the
returned string.
toupper(s)
Return a string based on the string s. Each character in s that
is a lowercase letter specified to have a toupper mapping by the
LC_CTYPE category of the current locale is replaced in the
returned string by the uppercase letter specified by the
mapping. Other characters in s are unchanged in the returned
string.
All of the preceding functions that take ERE as a parameter expect a
pattern or a string valued expression that is a regular expression as
defined in Regular Expressions .
Input/Output and General Functions
The input/output and general functions are:
close(expression)
Close the file or pipe opened by a print or printf statement or
a call to getline with the same string-valued expression. The
limit on the number of open expression arguments is
implementation-defined. If the close was successful, the
function shall return zero; otherwise, it shall return non-zero.
expression | getline [var]
Read a record of input from a stream piped from the output of a
command. The stream shall be created if no stream is currently
open with the value of expression as its command name. The
stream created shall be equivalent to one created by a call to
the popen() function with the value of expression as the command
argument and a value of r as the mode argument. As long as the
stream remains open, subsequent calls in which expression
evaluates to the same string value shall read subsequent records
from the stream. The stream shall remain open until the close
function is called with an expression that evaluates to the same
string value. At that time, the stream shall be closed as if by
a call to the pclose() function. If var is omitted, $0 and NF
shall be set; otherwise, var shall be set and, if appropriate,
it shall be considered a numeric string (see Expressions in awk
).
The getline operator can form ambiguous constructs when there are
unparenthesized operators (including concatenate) to the left of the
’|’ (to the beginning of the expression containing getline). In the
context of the ’$’ operator, ’|’ shall behave as if it had a lower
precedence than ’$’ . The result of evaluating other operators is
unspecified, and conforming applications shall parenthesize properly
all such usages.
getline
Set $0 to the next input record from the current input file.
This form of getline shall set the NF, NR, and FNR variables.
getline var
Set variable var to the next input record from the current input
file and, if appropriate, var shall be considered a numeric
string (see Expressions in awk ). This form of getline shall set
the FNR and NR variables.
getline [var] < expression
Read the next record of input from a named file. The expression
shall be evaluated to produce a string that is used as a
pathname. If the file of that name is not currently open, it
shall be opened. As long as the stream remains open, subsequent
calls in which expression evaluates to the same string value
shall read subsequent records from the file. The file shall
remain open until the close function is called with an
expression that evaluates to the same string value. If var is
omitted, $0 and NF shall be set; otherwise, var shall be set
and, if appropriate, it shall be considered a numeric string
(see Expressions in awk ).
The getline operator can form ambiguous constructs when there are
unparenthesized binary operators (including concatenate) to the right
of the ’<’ (up to the end of the expression containing the getline).
The result of evaluating such a construct is unspecified, and
conforming applications shall parenthesize properly all such usages.
system(expression)
Execute the command given by expression in a manner equivalent
to the system() function defined in the System Interfaces volume
of IEEE Std 1003.1-2001 and return the exit status of the
command.
All forms of getline shall return 1 for successful input, zero for end-
of-file, and -1 for an error.
Where strings are used as the name of a file or pipeline, the
application shall ensure that the strings are textually identical. The
terminology "same string value" implies that "equivalent strings", even
those that differ only by <space>s, represent different files.
User-Defined Functions
The awk language also provides user-defined functions. Such functions
can be defined as:
function name([parameter, ...]) { statements }
A function can be referred to anywhere in an awk program; in
particular, its use can precede its definition. The scope of a function
is global.
Function parameters, if present, can be either scalars or arrays; the
behavior is undefined if an array name is passed as a parameter that
the function uses as a scalar, or if a scalar expression is passed as a
parameter that the function uses as an array. Function parameters shall
be passed by value if scalar and by reference if array name.
The number of parameters in the function definition need not match the
number of parameters in the function call. Excess formal parameters can
be used as local variables. If fewer arguments are supplied in a
function call than are in the function definition, the extra parameters
that are used in the function body as scalars shall evaluate to the
uninitialized value until they are otherwise initialized, and the extra
parameters that are used in the function body as arrays shall be
treated as uninitialized arrays where each element evaluates to the
uninitialized value until otherwise initialized.
When invoking a function, no white space can be placed between the
function name and the opening parenthesis. Function calls can be nested
and recursive calls can be made upon functions. Upon return from any
nested or recursive function call, the values of all of the calling
function’s parameters shall be unchanged, except for array parameters
passed by reference. The return statement can be used to return a
value. If a return statement appears outside of a function definition,
the behavior is undefined.
In the function definition, <newline>s shall be optional before the
opening brace and after the closing brace. Function definitions can
appear anywhere in the program where a pattern-action pair is allowed.
Grammar
The grammar in this section and the lexical conventions in the
following section shall together describe the syntax for awk programs.
The general conventions for this style of grammar are described in
Grammar Conventions . A valid program can be represented as the non-
terminal symbol program in the grammar. This formal syntax shall take
precedence over the preceding text syntax description.
%token NAME NUMBER STRING ERE
%token FUNC_NAME /* Name followed by ’(’ without white space. */
/* Keywords */
%token Begin End
/* ’BEGIN’ ’END’ */
%token Break Continue Delete Do Else
/* ’break’ ’continue’ ’delete’ ’do’ ’else’ */
%token Exit For Function If In
/* ’exit’ ’for’ ’function’ ’if’ ’in’ */
%token Next Print Printf Return While
/* ’next’ ’print’ ’printf’ ’return’ ’while’ */
/* Reserved function names */
%token BUILTIN_FUNC_NAME
/* One token for the following:
* atan2 cos sin exp log sqrt int rand srand
* gsub index length match split sprintf sub
* substr tolower toupper close system
*/
%token GETLINE
/* Syntactically different from other built-ins. */
/* Two-character tokens. */
%token ADD_ASSIGN SUB_ASSIGN MUL_ASSIGN DIV_ASSIGN MOD_ASSIGN POW_ASSIGN
/* ’+=’ ’-=’ ’*=’ ’/=’ ’%=’ ’^=’ */
%token OR AND NO_MATCH EQ LE GE NE INCR DECR APPEND
/* ’||’ ’&&’ ’!~’ ’==’ ’<=’ ’>=’ ’!=’ ’++’ ’--’ ’>>’ */
/* One-character tokens. */
%token ’{’ ’}’ ’(’ ’)’ ’[’ ’]’ ’,’ ’;’ NEWLINE
%token ’+’ ’-’ ’*’ ’%’ ’^’ ’!’ ’>’ ’<’ ’|’ ’?’ ’:’ ’~’ ’$’ ’=’
%start program
%%
program : item_list
| actionless_item_list
;
item_list : newline_opt
| actionless_item_list item terminator
| item_list item terminator
| item_list action terminator
;
actionless_item_list : item_list pattern terminator
| actionless_item_list pattern terminator
;
item : pattern action
| Function NAME ’(’ param_list_opt ’)’
newline_opt action
| Function FUNC_NAME ’(’ param_list_opt ’)’
newline_opt action
;
param_list_opt : /* empty */
| param_list
;
param_list : NAME
| param_list ’,’ NAME
;
pattern : Begin
| End
| expr
| expr ’,’ newline_opt expr
;
action : ’{’ newline_opt ’}’
| ’{’ newline_opt terminated_statement_list ’}’
| ’{’ newline_opt unterminated_statement_list ’}’
;
terminator : terminator ’;’
| terminator NEWLINE
| ’;’
| NEWLINE
;
terminated_statement_list : terminated_statement
| terminated_statement_list terminated_statement
;
unterminated_statement_list : unterminated_statement
| terminated_statement_list unterminated_statement
;
terminated_statement : action newline_opt
| If ’(’ expr ’)’ newline_opt terminated_statement
| If ’(’ expr ’)’ newline_opt terminated_statement
Else newline_opt terminated_statement
| While ’(’ expr ’)’ newline_opt terminated_statement
| For ’(’ simple_statement_opt ’;’
expr_opt ’;’ simple_statement_opt ’)’ newline_opt
terminated_statement
| For ’(’ NAME In NAME ’)’ newline_opt
terminated_statement
| ’;’ newline_opt
| terminatable_statement NEWLINE newline_opt
| terminatable_statement ’;’ newline_opt
;
unterminated_statement : terminatable_statement
| If ’(’ expr ’)’ newline_opt unterminated_statement
| If ’(’ expr ’)’ newline_opt terminated_statement
Else newline_opt unterminated_statement
| While ’(’ expr ’)’ newline_opt unterminated_statement
| For ’(’ simple_statement_opt ’;’
expr_opt ’;’ simple_statement_opt ’)’ newline_opt
unterminated_statement
| For ’(’ NAME In NAME ’)’ newline_opt
unterminated_statement
;
terminatable_statement : simple_statement
| Break
| Continue
| Next
| Exit expr_opt
| Return expr_opt
| Do newline_opt terminated_statement While ’(’ expr ’)’
;
simple_statement_opt : /* empty */
| simple_statement
;
simple_statement : Delete NAME ’[’ expr_list ’]’
| expr
| print_statement
;
print_statement : simple_print_statement
| simple_print_statement output_redirection
;
simple_print_statement : Print print_expr_list_opt
| Print ’(’ multiple_expr_list ’)’
| Printf print_expr_list
| Printf ’(’ multiple_expr_list ’)’
;
output_redirection : ’>’ expr
| APPEND expr
| ’|’ expr
;
expr_list_opt : /* empty */
| expr_list
;
expr_list : expr
| multiple_expr_list
;
multiple_expr_list : expr ’,’ newline_opt expr
| multiple_expr_list ’,’ newline_opt expr
;
expr_opt : /* empty */
| expr
;
expr : unary_expr
| non_unary_expr
;
unary_expr : ’+’ expr
| ’-’ expr
| unary_expr ’^’ expr
| unary_expr ’*’ expr
| unary_expr ’/’ expr
| unary_expr ’%’ expr
| unary_expr ’+’ expr
| unary_expr ’-’ expr
| unary_expr non_unary_expr
| unary_expr ’<’ expr
| unary_expr LE expr
| unary_expr NE expr
| unary_expr EQ expr
| unary_expr ’>’ expr
| unary_expr GE expr
| unary_expr ’~’ expr
| unary_expr NO_MATCH expr
| unary_expr In NAME
| unary_expr AND newline_opt expr
| unary_expr OR newline_opt expr
| unary_expr ’?’ expr ’:’ expr
| unary_input_function
;
non_unary_expr : ’(’ expr ’)’
| ’!’ expr
| non_unary_expr ’^’ expr
| non_unary_expr ’*’ expr
| non_unary_expr ’/’ expr
| non_unary_expr ’%’ expr
| non_unary_expr ’+’ expr
| non_unary_expr ’-’ expr
| non_unary_expr non_unary_expr
| non_unary_expr ’<’ expr
| non_unary_expr LE expr
| non_unary_expr NE expr
| non_unary_expr EQ expr
| non_unary_expr ’>’ expr
| non_unary_expr GE expr
| non_unary_expr ’~’ expr
| non_unary_expr NO_MATCH expr
| non_unary_expr In NAME
| ’(’ multiple_expr_list ’)’ In NAME
| non_unary_expr AND newline_opt expr
| non_unary_expr OR newline_opt expr
| non_unary_expr ’?’ expr ’:’ expr
| NUMBER
| STRING
| lvalue
| ERE
| lvalue INCR
| lvalue DECR
| INCR lvalue
| DECR lvalue
| lvalue POW_ASSIGN expr
| lvalue MOD_ASSIGN expr
| lvalue MUL_ASSIGN expr
| lvalue DIV_ASSIGN expr
| lvalue ADD_ASSIGN expr
| lvalue SUB_ASSIGN expr
| lvalue ’=’ expr
| FUNC_NAME ’(’ expr_list_opt ’)’
/* no white space allowed before ’(’ */
| BUILTIN_FUNC_NAME ’(’ expr_list_opt ’)’
| BUILTIN_FUNC_NAME
| non_unary_input_function
;
print_expr_list_opt : /* empty */
| print_expr_list
;
print_expr_list : print_expr
| print_expr_list ’,’ newline_opt print_expr
;
print_expr : unary_print_expr
| non_unary_print_expr
;
unary_print_expr : ’+’ print_expr
| ’-’ print_expr
| unary_print_expr ’^’ print_expr
| unary_print_expr ’*’ print_expr
| unary_print_expr ’/’ print_expr
| unary_print_expr ’%’ print_expr
| unary_print_expr ’+’ print_expr
| unary_print_expr ’-’ print_expr
| unary_print_expr non_unary_print_expr
| unary_print_expr ’~’ print_expr
| unary_print_expr NO_MATCH print_expr
| unary_print_expr In NAME
| unary_print_expr AND newline_opt print_expr
| unary_print_expr OR newline_opt print_expr
| unary_print_expr ’?’ print_expr ’:’ print_expr
;
non_unary_print_expr : ’(’ expr ’)’
| ’!’ print_expr
| non_unary_print_expr ’^’ print_expr
| non_unary_print_expr ’*’ print_expr
| non_unary_print_expr ’/’ print_expr
| non_unary_print_expr ’%’ print_expr
| non_unary_print_expr ’+’ print_expr
| non_unary_print_expr ’-’ print_expr
| non_unary_print_expr non_unary_print_expr
| non_unary_print_expr ’~’ print_expr
| non_unary_print_expr NO_MATCH print_expr
| non_unary_print_expr In NAME
| ’(’ multiple_expr_list ’)’ In NAME
| non_unary_print_expr AND newline_opt print_expr
| non_unary_print_expr OR newline_opt print_expr
| non_unary_print_expr ’?’ print_expr ’:’ print_expr
| NUMBER
| STRING
| lvalue
| ERE
| lvalue INCR
| lvalue DECR
| INCR lvalue
| DECR lvalue
| lvalue POW_ASSIGN print_expr
| lvalue MOD_ASSIGN print_expr
| lvalue MUL_ASSIGN print_expr
| lvalue DIV_ASSIGN print_expr
| lvalue ADD_ASSIGN print_expr
| lvalue SUB_ASSIGN print_expr
| lvalue ’=’ print_expr
| FUNC_NAME ’(’ expr_list_opt ’)’
/* no white space allowed before ’(’ */
| BUILTIN_FUNC_NAME ’(’ expr_list_opt ’)’
| BUILTIN_FUNC_NAME
;
lvalue : NAME
| NAME ’[’ expr_list ’]’
| ’$’ expr
;
non_unary_input_function : simple_get
| simple_get ’<’ expr
| non_unary_expr ’|’ simple_get
;
unary_input_function : unary_expr ’|’ simple_get
;
simple_get : GETLINE
| GETLINE lvalue
;
newline_opt : /* empty */
| newline_opt NEWLINE
;
This grammar has several ambiguities that shall be resolved as follows:
* Operator precedence and associativity shall be as described in
Expressions in Decreasing Precedence in awk .
* In case of ambiguity, an else shall be associated with the most
immediately preceding if that would satisfy the grammar.
* In some contexts, a slash ( ’/’ ) that is used to surround an ERE
could also be the division operator. This shall be resolved in such
a way that wherever the division operator could appear, a slash is
assumed to be the division operator. (There is no unary division
operator.)
One convention that might not be obvious from the formal grammar is
where <newline>s are acceptable. There are several obvious placements
such as terminating a statement, and a backslash can be used to escape
<newline>s between any lexical tokens. In addition, <newline>s without
backslashes can follow a comma, an open brace, logical AND operator (
"&&" ), logical OR operator ( "||" ), the do keyword, the else keyword,
and the closing parenthesis of an if, for, or while statement. For
example:
{ print $1,
$2 }
Lexical Conventions
The lexical conventions for awk programs, with respect to the preceding
grammar, shall be as follows:
1. Except as noted, awk shall recognize the longest possible token or
delimiter beginning at a given point.
2. A comment shall consist of any characters beginning with the number
sign character and terminated by, but excluding the next occurrence
of, a <newline>. Comments shall have no effect, except to delimit
lexical tokens.
3. The <newline> shall be recognized as the token NEWLINE.
4. A backslash character immediately followed by a <newline> shall
have no effect.
5. The token STRING shall represent a string constant. A string
constant shall begin with the character ’ .’ Within a string
constant, a backslash character shall be considered to begin an
escape sequence as specified in the table in the Base Definitions
volume of IEEE Std 1003.1-2001, Chapter 5, File Format Notation (
’\\’ , ’\a’ , ’\b’ , ’\f’ , ’\n’ , ’\r’ , ’\t’ , ’\v’ ). In
addition, the escape sequences in Expressions in Decreasing
Precedence in awk shall be recognized. A <newline> shall not occur
within a string constant. A string constant shall be terminated by
the first unescaped occurrence of the character ’’ after the one
that begins the string constant. The value of the string shall be
the sequence of all unescaped characters and values of escape
sequences between, but not including, the two delimiting ’’
characters.
6. The token ERE represents an extended regular expression constant.
An ERE constant shall begin with the slash character. Within an
ERE constant, a backslash character shall be considered to begin an
escape sequence as specified in the table in the Base Definitions
volume of IEEE Std 1003.1-2001, Chapter 5, File Format Notation. In
addition, the escape sequences in Expressions in Decreasing
Precedence in awk shall be recognized. The application shall ensure
that a <newline> does not occur within an ERE constant. An ERE
constant shall be terminated by the first unescaped occurrence of
the slash character after the one that begins the ERE constant. The
extended regular expression represented by the ERE constant shall
be the sequence of all unescaped characters and values of escape
sequences between, but not including, the two delimiting slash
characters.
7. A <blank> shall have no effect, except to delimit lexical tokens or
within STRING or ERE tokens.
8. The token NUMBER shall represent a numeric constant. Its form and
numeric value shall be equivalent to either of the tokens floating-
constant or integer-constant as specified by the ISO C standard,
with the following exceptions:
a. An integer constant cannot begin with 0x or include the
hexadecimal digits ’a’ , ’b’ , ’c’ , ’d’ , ’e’ , ’f’ , ’A’ ,
’B’ , ’C’ , ’D’ , ’E’ , or ’F’ .
b. The value of an integer constant beginning with 0 shall be
taken in decimal rather than octal.
c. An integer constant cannot include a suffix ( ’u’ , ’U’ , ’l’ ,
or ’L’ ).
d. A floating constant cannot include a suffix ( ’f’ , ’F’ , ’l’ ,
or ’L’ ).
If the value is too large or too small to be representable (see
Concepts Derived from the ISO C Standard ), the behavior is undefined.
9. A sequence of underscores, digits, and alphabetics from the
portable character set (see the Base Definitions volume of
IEEE Std 1003.1-2001, Section 6.1, Portable Character Set),
beginning with an underscore or alphabetic, shall be considered a
word.
10. The following words are keywords that shall be recognized as
individual tokens; the name of the token is the same as the
keyword:
BEGIN delete END function in printf
break do exit getline next return
continue else for if print while
11. The following words are names of built-in functions and shall be
recognized as the token BUILTIN_FUNC_NAME:
atan2 gsub log split sub toupper
close index match sprintf substr
cos int rand sqrt system
exp length sin srand tolower
The above-listed keywords and names of built-in functions are
considered reserved words.
12. The token NAME shall consist of a word that is not a keyword or a
name of a built-in function and is not followed immediately
(without any delimiters) by the ’(’ character.
13. The token FUNC_NAME shall consist of a word that is not a keyword
or a name of a built-in function, followed immediately (without any
delimiters) by the ’(’ character. The ’(’ character shall not be
included as part of the token.
14. The following two-character sequences shall be recognized as the
named tokens:
Token Name Sequence Token Name Sequence
ADD_ASSIGN += NO_MATCH !~
SUB_ASSIGN -= EQ ==
MUL_ASSIGN *= LE <=
DIV_ASSIGN /= GE >=
MOD_ASSIGN %= NE !=
POW_ASSIGN ^= INCR ++
OR || DECR --
AND && APPEND >>
15. The following single characters shall be recognized as tokens whose
names are the character:
<newline> { } ( ) [ ] , ; + - * % ^ ! > < | ? : ~ $ =
There is a lexical ambiguity between the token ERE and the tokens ’/’
and DIV_ASSIGN. When an input sequence begins with a slash character in
any syntactic context where the token ’/’ or DIV_ASSIGN could appear as
the next token in a valid program, the longer of those two tokens that
can be recognized shall be recognized. In any other syntactic context
where the token ERE could appear as the next token in a valid program,
the token ERE shall be recognized.
EXIT STATUS
The following exit values shall be returned:
0 All input files were processed successfully.
>0 An error occurred.
The exit status can be altered within the program by using an exit
expression.
CONSEQUENCES OF ERRORS
If any file operand is specified and the named file cannot be accessed,
awk shall write a diagnostic message to standard error and terminate
without any further action.
If the program specified by either the program operand or a progfile
operand is not a valid awk program (as specified in the EXTENDED
DESCRIPTION section), the behavior is undefined.
The following sections are informative.
APPLICATION USAGE
The index, length, match, and substr functions should not be confused
with similar functions in the ISO C standard; the awk versions deal
with characters, while the ISO C standard deals with bytes.
Because the concatenation operation is represented by adjacent
expressions rather than an explicit operator, it is often necessary to
use parentheses to enforce the proper evaluation precedence.
EXAMPLES
The awk program specified in the command line is most easily specified
within single-quotes (for example, programs commonly contain characters
that are special to the shell, including double-quotes. In the cases
where an awk program contains single-quote characters, it is usually
easiest to specify most of the program as strings within single-quotes
concatenated by the shell with quoted single-quote characters. For
example:
awk ’/’\’’/ { print "quote:", $0 }’
prints all lines from the standard input containing a single-quote
character, prefixed with quote:.
The following are examples of simple awk programs:
1. Write to the standard output all input lines for which field 3 is
greater than 5:
$3 > 5
2. Write every tenth line:
(NR % 10) == 0
3. Write any line with a substring matching the regular expression:
/(G|D)(2[0-9][[:alpha:]]*)/
4. Print any line with a substring containing a ’G’ or ’D’ , followed
by a sequence of digits and characters. This example uses
character classes digit and alpha to match language-independent
digit and alphabetic characters respectively:
/(G|D)([[:digit:][:alpha:]]*)/
5. Write any line in which the second field matches the regular
expression and the fourth field does not:
$2 ~ /xyz/ && $4 !~ /xyz/
6. Write any line in which the second field contains a backslash:
$2 ~ /\\/
7. Write any line in which the second field contains a backslash. Note
that backslash escapes are interpreted twice; once in lexical
processing of the string and once in processing the regular
expression:
$2 ~ "\\\\"
8. Write the second to the last and the last field in each line.
Separate the fields by a colon:
{OFS=":";print $(NF-1), $NF}
9. Write the line number and number of fields in each line. The three
strings representing the line number, the colon, and the number of
fields are concatenated and that string is written to standard
output:
{print NR ":" NF}
10. Write lines longer than 72 characters:
length($0) > 72
11. Write the first two fields in opposite order separated by OFS:
{ print $2, $1 }
12. Same, with input fields separated by a comma or <space>s and
<tab>s, or both:
BEGIN { FS = ",[ \t]*|[ \t]+" }
{ print $2, $1 }
13. Add up the first column, print sum, and average:
{s += $1 }
END {print "sum is ", s, " average is", s/NR}
14. Write fields in reverse order, one per line (many lines out for
each line in):
{ for (i = NF; i > 0; --i) print $i }
15. Write all lines between occurrences of the strings start and stop:
/start/, /stop/
16. Write all lines whose first field is different from the previous
one:
$1 != prev { print; prev = $1 }
17. Simulate echo:
BEGIN {
for (i = 1; i < ARGC; ++i)
printf("%s%s", ARGV[i], i==ARGC-1?"\n":" ")
}
18. Write the path prefixes contained in the PATH environment variable,
one per line:
BEGIN {
n = split (ENVIRON["PATH"], path, ":")
for (i = 1; i <= n; ++i)
print path[i]
}
19. If there is a file named input containing page headers of the form:
Page #
and a file named program that contains:
/Page/ { $2 = n++; }
{ print }
then the command line:
awk -f program n=5 input
prints the file input, filling in page numbers starting at 5.
RATIONALE
This description is based on the new awk, "nawk", (see the referenced
The AWK Programming Language), which introduced a number of new
features to the historical awk:
1. New keywords: delete, do, function, return
2. New built-in functions: atan2, close, cos, gsub, match, rand, sin,
srand, sub, system
3. New predefined variables: FNR, ARGC, ARGV, RSTART, RLENGTH, SUBSEP
4. New expression operators: ?, :, ,, ^
5. The FS variable and the third argument to split, now treated as
extended regular expressions.
6. The operator precedence, changed to more closely match the C
language. Two examples of code that operate differently are:
while ( n /= 10 > 1) ...
if (!"wk" ~ /bwk/) ...
Several features have been added based on newer implementations of awk:
* Multiple instances of -f progfile are permitted.
* The new option -v assignment.
* The new predefined variable ENVIRON.
* New built-in functions toupper and tolower.
* More formatting capabilities are added to printf to match the ISO C
standard.
The overall awk syntax has always been based on the C language, with a
few features from the shell command language and other sources. Because
of this, it is not completely compatible with any other language, which
has caused confusion for some users. It is not the intent of the
standard developers to address such issues. A few relatively minor
changes toward making the language more compatible with the ISO C
standard were made; most of these changes are based on similar changes
in recent implementations, as described above. There remain several C-
language conventions that are not in awk. One of the notable ones is
the comma operator, which is commonly used to specify multiple
expressions in the C language for statement. Also, there are various
places where awk is more restrictive than the C language regarding the
type of expression that can be used in a given context. These
limitations are due to the different features that the awk language
does provide.
Regular expressions in awk have been extended somewhat from historical
implementations to make them a pure superset of extended regular
expressions, as defined by IEEE Std 1003.1-2001 (see the Base
Definitions volume of IEEE Std 1003.1-2001, Section 9.4, Extended
Regular Expressions). The main extensions are internationalization
features and interval expressions. Historical implementations of awk
have long supported backslash escape sequences as an extension to
extended regular expressions, and this extension has been retained
despite inconsistency with other utilities. The number of escape
sequences recognized in both extended regular expressions and strings
has varied (generally increasing with time) among implementations. The
set specified by IEEE Std 1003.1-2001 includes most sequences known to
be supported by popular implementations and by the ISO C standard. One
sequence that is not supported is hexadecimal value escapes beginning
with ’\x’ . This would allow values expressed in more than 9 bits to be
used within awk as in the ISO C standard. However, because this syntax
has a non-deterministic length, it does not permit the subsequent
character to be a hexadecimal digit. This limitation can be dealt with
in the C language by the use of lexical string concatenation. In the
awk language, concatenation could also be a solution for strings, but
not for extended regular expressions (either lexical ERE tokens or
strings used dynamically as regular expressions). Because of this
limitation, the feature has not been added to IEEE Std 1003.1-2001.
When a string variable is used in a context where an extended regular
expression normally appears (where the lexical token ERE is used in the
grammar) the string does not contain the literal slashes.
Some versions of awk allow the form:
func name(args, ... ) { statements }
This has been deprecated by the authors of the language, who asked that
it not be specified.
Historical implementations of awk produce an error if a next statement
is executed in a BEGIN action, and cause awk to terminate if a next
statement is executed in an END action. This behavior has not been
documented, and it was not believed that it was necessary to
standardize it.
The specification of conversions between string and numeric values is
much more detailed than in the documentation of historical
implementations or in the referenced The AWK Programming Language.
Although most of the behavior is designed to be intuitive, the details
are necessary to ensure compatible behavior from different
implementations. This is especially important in relational expressions
since the types of the operands determine whether a string or numeric
comparison is performed. From the perspective of an application writer,
it is usually sufficient to expect intuitive behavior and to force
conversions (by adding zero or concatenating a null string) when the
type of an expression does not obviously match what is needed. The
intent has been to specify historical practice in almost all cases. The
one exception is that, in historical implementations, variables and
constants maintain both string and numeric values after their original
value is converted by any use. This means that referencing a variable
or constant can have unexpected side effects. For example, with
historical implementations the following program:
{
a = "+2"
b = 2
if (NR % 2)
c = a + b
if (a == b)
print "numeric comparison"
else
print "string comparison"
}
would perform a numeric comparison (and output numeric comparison) for
each odd-numbered line, but perform a string comparison (and output
string comparison) for each even-numbered line. IEEE Std 1003.1-2001
ensures that comparisons will be numeric if necessary. With historical
implementations, the following program:
BEGIN {
OFMT = "%e"
print 3.14
OFMT = "%f"
print 3.14
}
would output "3.140000e+00" twice, because in the second print
statement the constant "3.14" would have a string value from the
previous conversion. IEEE Std 1003.1-2001 requires that the output of
the second print statement be "3.140000" . The behavior of historical
implementations was seen as too unintuitive and unpredictable.
It was pointed out that with the rules contained in early drafts, the
following script would print nothing:
BEGIN {
y[1.5] = 1
OFMT = "%e"
print y[1.5]
}
Therefore, a new variable, CONVFMT, was introduced. The OFMT variable
is now restricted to affecting output conversions of numbers to strings
and CONVFMT is used for internal conversions, such as comparisons or
array indexing. The default value is the same as that for OFMT, so
unless a program changes CONVFMT (which no historical program would
do), it will receive the historical behavior associated with internal
string conversions.
The POSIX awk lexical and syntactic conventions are specified more
formally than in other sources. Again the intent has been to specify
historical practice. One convention that may not be obvious from the
formal grammar as in other verbal descriptions is where <newline>s are
acceptable. There are several obvious placements such as terminating a
statement, and a backslash can be used to escape <newline>s between any
lexical tokens. In addition, <newline>s without backslashes can follow
a comma, an open brace, a logical AND operator ( "&&" ), a logical OR
operator ( "||" ), the do keyword, the else keyword, and the closing
parenthesis of an if, for, or while statement. For example:
{ print $1,
$2 }
The requirement that awk add a trailing <newline> to the program
argument text is to simplify the grammar, making it match a text file
in form. There is no way for an application or test suite to determine
whether a literal <newline> is added or whether awk simply acts as if
it did.
IEEE Std 1003.1-2001 requires several changes from historical
implementations in order to support internationalization. Probably the
most subtle of these is the use of the decimal-point character, defined
by the LC_NUMERIC category of the locale, in representations of
floating-point numbers. This locale-specific character is used in
recognizing numeric input, in converting between strings and numeric
values, and in formatting output. However, regardless of locale, the
period character (the decimal-point character of the POSIX locale) is
the decimal-point character recognized in processing awk programs
(including assignments in command line arguments). This is essentially
the same convention as the one used in the ISO C standard. The
difference is that the C language includes the setlocale() function,
which permits an application to modify its locale. Because of this
capability, a C application begins executing with its locale set to the
C locale, and only executes in the environment-specified locale after
an explicit call to setlocale(). However, adding such an elaborate new
feature to the awk language was seen as inappropriate for
IEEE Std 1003.1-2001. It is possible to execute an awk program
explicitly in any desired locale by setting the environment in the
shell.
The undefined behavior resulting from NULs in extended regular
expressions allows future extensions for the GNU gawk program to
process binary data.
The behavior in the case of invalid awk programs (including lexical,
syntactic, and semantic errors) is undefined because it was considered
overly limiting on implementations to specify. In most cases such
errors can be expected to produce a diagnostic and a non-zero exit
status. However, some implementations may choose to extend the language
in ways that make use of certain invalid constructs. Other invalid
constructs might be deemed worthy of a warning, but otherwise cause
some reasonable behavior. Still other constructs may be very difficult
to detect in some implementations. Also, different implementations
might detect a given error during an initial parsing of the program
(before reading any input files) while others might detect it when
executing the program after reading some input. Implementors should be
aware that diagnosing errors as early as possible and producing useful
diagnostics can ease debugging of applications, and thus make an
implementation more usable.
The unspecified behavior from using multi-character RS values is to
allow possible future extensions based on extended regular expressions
used for record separators. Historical implementations take the first
character of the string and ignore the others.
Unspecified behavior when split( string, array, <null>) is used is to
allow a proposed future extension that would split up a string into an
array of individual characters.
In the context of the getline function, equally good arguments for
different precedences of the | and < operators can be made. Historical
practice has been that:
getline < "a" "b"
is parsed as:
( getline < "a" ) "b"
although many would argue that the intent was that the file ab should
be read. However:
getline < "x" + 1
parses as:
getline < ( "x" + 1 )
Similar problems occur with the | version of getline, particularly in
combination with $. For example:
$"echo hi" | getline
(This situation is particularly problematic when used in a print
statement, where the |getline part might be a redirection of the
print.)
Since in most cases such constructs are not (or at least should not) be
used (because they have a natural ambiguity for which there is no
conventional parsing), the meaning of these constructs has been made
explicitly unspecified. (The effect is that a conforming application
that runs into the problem must parenthesize to resolve the ambiguity.)
There appeared to be few if any actual uses of such constructs.
Grammars can be written that would cause an error under these
circumstances. Where backwards-compatibility is not a large
consideration, implementors may wish to use such grammars.
Some historical implementations have allowed some built-in functions to
be called without an argument list, the result being a default argument
list chosen in some "reasonable" way. Use of length as a synonym for
length($0) is the only one of these forms that is thought to be widely
known or widely used; this particular form is documented in various
places (for example, most historical awk reference pages, although not
in the referenced The AWK Programming Language) as legitimate practice.
With this exception, default argument lists have always been
undocumented and vaguely defined, and it is not at all clear how (or
if) they should be generalized to user-defined functions. They add no
useful functionality and preclude possible future extensions that might
need to name functions without calling them. Not standardizing them
seems the simplest course. The standard developers considered that
length merited special treatment, however, since it has been documented
in the past and sees possibly substantial use in historical programs.
Accordingly, this usage has been made legitimate, but Issue 5 removed
the obsolescent marking for XSI-conforming implementations and many
otherwise conforming applications depend on this feature.
In sub and gsub, if repl is a string literal (the lexical token
STRING), then two consecutive backslash characters should be used in
the string to ensure a single backslash will precede the ampersand when
the resultant string is passed to the function. (For example, to
specify one literal ampersand in the replacement string, use gsub( ERE,
"\\&" ).)
Historically the only special character in the repl argument of sub and
gsub string functions was the ampersand ( ’&’ ) character and preceding
it with the backslash character was used to turn off its special
meaning.
The description in the ISO POSIX-2:1993 standard introduced behavior
such that the backslash character was another special character and it
was unspecified whether there were any other special characters. This
description introduced several portability problems, some of which are
described below, and so it has been replaced with the more historical
description. Some of the problems include:
* Historically, to create the replacement string, a script could use
gsub( ERE, "\\&" ), but with the ISO POSIX-2:1993 standard wording,
it was necessary to use gsub( ERE, "\\\\&" ). Backslash characters
are doubled here because all string literals are subject to lexical
analysis, which would reduce each pair of backslash characters to a
single backslash before being passed to gsub.
* Since it was unspecified what the special characters were, for
portable scripts to guarantee that characters are printed literally,
each character had to be preceded with a backslash. (For example, a
portable script had to use gsub( ERE, "\\h\\i" ) to produce a
replacement string of "hi" .)
The description for comparisons in the ISO POSIX-2:1993 standard did
not properly describe historical practice because of the way numeric
strings are compared as numbers. The current rules cause the following
code:
if (0 == "000")
print "strange, but true"
else
print "not true"
to do a numeric comparison, causing the if to succeed. It should be
intuitively obvious that this is incorrect behavior, and indeed, no
historical implementation of awk actually behaves this way.
To fix this problem, the definition of numeric string was enhanced to
include only those values obtained from specific circumstances (mostly
external sources) where it is not possible to determine unambiguously
whether the value is intended to be a string or a numeric.
Variables that are assigned to a numeric string shall also be treated
as a numeric string. (For example, the notion of a numeric string can
be propagated across assignments.) In comparisons, all variables having
the uninitialized value are to be treated as a numeric operand
evaluating to the numeric value zero.
Uninitialized variables include all types of variables including
scalars, array elements, and fields. The definition of an uninitialized
value in Variables and Special Variables is necessary to describe the
value placed on uninitialized variables and on fields that are valid
(for example, < $NF) but have no characters in them and to describe how
these variables are to be used in comparisons. A valid field, such as
$1, that has no characters in it can be obtained from an input line of
"\t\t" when FS= ’\t’ . Historically, the comparison ( $1<10) was done
numerically after evaluating $1 to the value zero.
The phrase "... also shall have the numeric value of the numeric
string" was removed from several sections of the ISO POSIX-2:1993
standard because is specifies an unnecessary implementation detail. It
is not necessary for IEEE Std 1003.1-2001 to specify that these objects
be assigned two different values. It is only necessary to specify that
these objects may evaluate to two different values depending on
context.
The description of numeric string processing is based on the behavior
of the atof() function in the ISO C standard. While it is not a
requirement for an implementation to use this function, many historical
implementations of awk do. In the ISO C standard, floating-point
constants use a period as a decimal point character for the language
itself, independent of the current locale, but the atof() function and
the associated strtod() function use the decimal point character of the
current locale when converting strings to numeric values. Similarly in
awk, floating-point constants in an awk script use a period independent
of the locale, but input strings use the decimal point character of the
locale.
FUTURE DIRECTIONS
None.
SEE ALSO
Grammar Conventions , grep , lex , sed , the System Interfaces volume
of IEEE Std 1003.1-2001, atof(), exec, popen(), setlocale(), strtod()
COPYRIGHT
Portions of this text are reprinted and reproduced in electronic form
from IEEE Std 1003.1, 2003 Edition, Standard for Information Technology
-- Portable Operating System Interface (POSIX), The Open Group Base
Specifications Issue 6, Copyright (C) 2001-2003 by the Institute of
Electrical and Electronics Engineers, Inc and The Open Group. In the
event of any discrepancy between this version and the original IEEE and
The Open Group Standard, the original IEEE and The Open Group Standard
is the referee document. The original Standard can be obtained online
at http://www.opengroup.org/unix/online.html .