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391 lines
13 KiB
Markdown
391 lines
13 KiB
Markdown
---
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category: tool
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name: AWK
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filename: learnawk.awk
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contributors:
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- ["Marshall Mason", "http://github.com/marshallmason"]
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---
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AWK is a standard tool on every POSIX-compliant UNIX system. It's like
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flex/lex, from the command-line, perfect for text-processing tasks and
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other scripting needs. It has a C-like syntax, but without mandatory
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semicolons (although, you should use them anyway, because they are required
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when you're writing one-liners, something AWK excels at), manual memory
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management, or static typing. It excels at text processing. You can call to
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it from a shell script, or you can use it as a stand-alone scripting language.
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Why use AWK instead of Perl? Readability. AWK is easier to read
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than Perl. For simple text-processing scripts, particularly ones that read
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files line by line and split on delimiters, AWK is probably the right tool for
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the job.
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```awk
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#!/usr/bin/awk -f
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# Comments are like this
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# AWK programs consist of a collection of patterns and actions.
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pattern1 { action; } # just like lex
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pattern2 { action; }
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# There is an implied loop and AWK automatically reads and parses each
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# record of each file supplied. Each record is split by the FS delimiter,
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# which defaults to white-space (multiple spaces,tabs count as one)
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# You can assign FS either on the command line (-F C) or in your BEGIN
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# pattern
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# One of the special patterns is BEGIN. The BEGIN pattern is true
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# BEFORE any of the files are read. The END pattern is true after
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# an End-of-file from the last file (or standard-in if no files specified)
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# There is also an output field separator (OFS) that you can assign, which
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# defaults to a single space
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BEGIN {
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# BEGIN will run at the beginning of the program. It's where you put all
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# the preliminary set-up code, before you process any text files. If you
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# have no text files, then think of BEGIN as the main entry point.
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# Variables are global. Just set them or use them, no need to declare.
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count = 0;
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# Operators just like in C and friends
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a = count + 1;
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b = count - 1;
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c = count * 1;
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d = count / 1; # integer division
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e = count % 1; # modulus
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f = count ^ 1; # exponentiation
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a += 1;
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b -= 1;
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c *= 1;
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d /= 1;
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e %= 1;
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f ^= 1;
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# Incrementing and decrementing by one
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a++;
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b--;
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# As a prefix operator, it returns the incremented value
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++a;
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--b;
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# Notice, also, no punctuation such as semicolons to terminate statements
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# Control statements
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if (count == 0)
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print "Starting with count of 0";
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else
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print "Huh?";
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# Or you could use the ternary operator
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print (count == 0) ? "Starting with count of 0" : "Huh?";
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# Blocks consisting of multiple lines use braces
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while (a < 10) {
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print "String concatenation is done" " with a series" " of"
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" space-separated strings";
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print a;
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a++;
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}
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for (i = 0; i < 10; i++)
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print "Good ol' for loop";
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# As for comparisons, they're the standards:
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# a < b # Less than
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# a <= b # Less than or equal
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# a != b # Not equal
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# a == b # Equal
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# a > b # Greater than
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# a >= b # Greater than or equal
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# Logical operators as well
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# a && b # AND
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# a || b # OR
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# In addition, there's the super useful regular expression match
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if ("foo" ~ "^fo+$")
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print "Fooey!";
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if ("boo" !~ "^fo+$")
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print "Boo!";
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# Arrays
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arr[0] = "foo";
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arr[1] = "bar";
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# You can also initialize an array with the built-in function split()
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n = split("foo:bar:baz", arr, ":");
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# You also have associative arrays (indeed, they're all associative arrays)
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assoc["foo"] = "bar";
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assoc["bar"] = "baz";
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# And multi-dimensional arrays, with some limitations I won't mention here
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multidim[0,0] = "foo";
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multidim[0,1] = "bar";
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multidim[1,0] = "baz";
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multidim[1,1] = "boo";
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# You can test for array membership
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if ("foo" in assoc)
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print "Fooey!";
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# You can also use the 'in' operator to traverse the keys of an array
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for (key in assoc)
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print assoc[key];
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# The command line is in a special array called ARGV
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for (argnum in ARGV)
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print ARGV[argnum];
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# You can remove elements of an array
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# This is particularly useful to prevent AWK from assuming the arguments
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# are files for it to process
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delete ARGV[1];
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# The number of command line arguments is in a variable called ARGC
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print ARGC;
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# AWK has several built-in functions. They fall into three categories. I'll
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# demonstrate each of them in their own functions, defined later.
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return_value = arithmetic_functions(a, b, c);
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string_functions();
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io_functions();
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}
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# Here's how you define a function
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function arithmetic_functions(a, b, c, d) {
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# Probably the most annoying part of AWK is that there are no local
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# variables. Everything is global. For short scripts, this is fine, even
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# useful, but for longer scripts, this can be a problem.
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# There is a work-around (ahem, hack). Function arguments are local to the
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# function, and AWK allows you to define more function arguments than it
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# needs. So just stick local variable in the function declaration, like I
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# did above. As a convention, stick in some extra whitespace to distinguish
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# between actual function parameters and local variables. In this example,
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# a, b, and c are actual parameters, while d is merely a local variable.
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# Now, to demonstrate the arithmetic functions
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# Most AWK implementations have some standard trig functions
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d = sin(a);
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d = cos(a);
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d = atan2(b, a); # arc tangent of b / a
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# And logarithmic stuff
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d = exp(a);
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d = log(a);
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# Square root
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d = sqrt(a);
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# Truncate floating point to integer
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d = int(5.34); # d => 5
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# Random numbers
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srand(); # Supply a seed as an argument. By default, it uses the time of day
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d = rand(); # Random number between 0 and 1.
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# Here's how to return a value
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return d;
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}
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function string_functions( localvar, arr) {
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# AWK, being a string-processing language, has several string-related
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# functions, many of which rely heavily on regular expressions.
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# Search and replace, first instance (sub) or all instances (gsub)
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# Both return number of matches replaced
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localvar = "fooooobar";
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sub("fo+", "Meet me at the ", localvar); # localvar => "Meet me at the bar"
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gsub("e", ".", localvar); # localvar => "M..t m. at th. bar"
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# Search for a string that matches a regular expression
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# index() does the same thing, but doesn't allow a regular expression
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match(localvar, "t"); # => 4, since the 't' is the fourth character
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# Split on a delimiter
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n = split("foo-bar-baz", arr, "-");
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# result: a[1] = "foo"; a[2] = "bar"; a[3] = "baz"; n = 3
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# Other useful stuff
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sprintf("%s %d %d %d", "Testing", 1, 2, 3); # => "Testing 1 2 3"
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substr("foobar", 2, 3); # => "oob"
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substr("foobar", 4); # => "bar"
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length("foo"); # => 3
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tolower("FOO"); # => "foo"
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toupper("foo"); # => "FOO"
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}
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function io_functions( localvar) {
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# You've already seen print
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print "Hello world";
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# There's also printf
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printf("%s %d %d %d\n", "Testing", 1, 2, 3);
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# AWK doesn't have file handles, per se. It will automatically open a file
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# handle for you when you use something that needs one. The string you used
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# for this can be treated as a file handle, for purposes of I/O. This makes
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# it feel sort of like shell scripting, but to get the same output, the
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# string must match exactly, so use a variable:
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outfile = "/tmp/foobar.txt";
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print "foobar" > outfile;
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# Now the string outfile is a file handle. You can close it:
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close(outfile);
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# Here's how you run something in the shell
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system("echo foobar"); # => prints foobar
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# Reads a line from standard input and stores in localvar
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getline localvar;
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# Reads a line from a pipe (again, use a string so you close it properly)
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cmd = "echo foobar";
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cmd | getline localvar; # localvar => "foobar"
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close(cmd);
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# Reads a line from a file and stores in localvar
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infile = "/tmp/foobar.txt";
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getline localvar < infile;
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close(infile);
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}
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# As I said at the beginning, AWK programs consist of a collection of patterns
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# and actions. You've already seen the BEGIN pattern. Other
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# patterns are used only if you're processing lines from files or standard
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# input.
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#
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# When you pass arguments to AWK, they are treated as file names to process.
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# It will process them all, in order. Think of it like an implicit for loop,
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# iterating over the lines in these files. these patterns and actions are like
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# switch statements inside the loop.
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/^fo+bar$/ {
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# This action will execute for every line that matches the regular
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# expression, /^fo+bar$/, and will be skipped for any line that fails to
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# match it. Let's just print the line:
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print;
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# Whoa, no argument! That's because print has a default argument: $0.
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# $0 is the name of the current line being processed. It is created
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# automatically for you.
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# You can probably guess there are other $ variables. Every line is
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# implicitly split before every action is called, much like the shell
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# does. And, like the shell, each field can be access with a dollar sign
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# This will print the second and fourth fields in the line
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print $2, $4;
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# AWK automatically defines many other variables to help you inspect and
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# process each line. The most important one is NF
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# Prints the number of fields on this line
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print NF;
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# Print the last field on this line
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print $NF;
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}
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# Every pattern is actually a true/false test. The regular expression in the
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# last pattern is also a true/false test, but part of it was hidden. If you
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# don't give it a string to test, it will assume $0, the line that it's
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# currently processing. Thus, the complete version of it is this:
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$0 ~ /^fo+bar$/ {
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print "Equivalent to the last pattern";
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}
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a > 0 {
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# This will execute once for each line, as long as a is positive
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}
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# You get the idea. Processing text files, reading in a line at a time, and
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# doing something with it, particularly splitting on a delimiter, is so common
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# in UNIX that AWK is a scripting language that does all of it for you, without
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# you needing to ask. All you have to do is write the patterns and actions
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# based on what you expect of the input, and what you want to do with it.
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# Here's a quick example of a simple script, the sort of thing AWK is perfect
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# for. It will read a name from standard input and then will print the average
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# age of everyone with that first name. Let's say you supply as an argument the
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# name of a this data file:
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#
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# Bob Jones 32
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# Jane Doe 22
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# Steve Stevens 83
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# Bob Smith 29
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# Bob Barker 72
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#
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# Here's the script:
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BEGIN {
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# First, ask the user for the name
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print "What name would you like the average age for?";
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# Get a line from standard input, not from files on the command line
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getline name < "/dev/stdin";
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}
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# Now, match every line whose first field is the given name
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$1 == name {
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# Inside here, we have access to a number of useful variables, already
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# pre-loaded for us:
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# $0 is the entire line
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# $3 is the third field, the age, which is what we're interested in here
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# NF is the number of fields, which should be 3
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# NR is the number of records (lines) seen so far
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# FILENAME is the name of the file being processed
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# FS is the field separator being used, which is " " here
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# ...etc. There are plenty more, documented in the man page.
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# Keep track of a running total and how many lines matched
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sum += $3;
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nlines++;
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}
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# Another special pattern is called END. It will run after processing all the
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# text files. Unlike BEGIN, it will only run if you've given it input to
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# process. It will run after all the files have been read and processed
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# according to the rules and actions you've provided. The purpose of it is
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# usually to output some kind of final report, or do something with the
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# aggregate of the data you've accumulated over the course of the script.
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END {
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if (nlines)
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print "The average age for " name " is " sum / nlines;
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}
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```
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Further Reading:
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* [Awk tutorial](http://www.grymoire.com/Unix/Awk.html)
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* [Awk man page](https://linux.die.net/man/1/awk)
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* [The GNU Awk User's Guide](https://www.gnu.org/software/gawk/manual/gawk.html)
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GNU Awk is found on most Linux systems.
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* [AWK one-liner collection](http://tuxgraphics.org/~guido/scripts/awk-one-liner.html)
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* [Awk alpinelinux wiki](https://wiki.alpinelinux.org/wiki/Awk) a technical
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summary and list of "gotchas" (places where different implementations may
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behave in different or unexpected ways).
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* [basic libraries for awk](https://github.com/dubiousjim/awkenough)
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