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Thu Jun 15 18:12:51 BST 1995
This file is compiled automatically from the URLs listed below. Between
each page is the line containing only '----- boundary ' followed by the URL
of the next page or 'begin' or 'end' followed by ' -----'. The URLs are:
http://agora.leeds.ac.uk/nik/Perl/start.html
http://agora.leeds.ac.uk/nik/Perl/basic.html
http://agora.leeds.ac.uk/nik/Perl/running.html
http://agora.leeds.ac.uk/nik/Perl/scalars.html
http://agora.leeds.ac.uk/nik/Perl/arrays.html
http://agora.leeds.ac.uk/nik/Perl/filehandling.html
http://agora.leeds.ac.uk/nik/Perl/control.html
http://agora.leeds.ac.uk/nik/Perl/conditionals.html
http://agora.leeds.ac.uk/nik/Perl/matching.html
http://agora.leeds.ac.uk/nik/Perl/sandtr.html
http://agora.leeds.ac.uk/nik/Perl/split.html
http://agora.leeds.ac.uk/nik/Perl/associative.html
http://agora.leeds.ac.uk/nik/Perl/subroutines.html
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_________________________________________________________________
This is the start of a tutorial on Perl, originally run by me, Nik
Silver, as the first part of a one-day hands-on workshop at the School
of Computer Studies, University of Leeds, in the UK. The second part
of the workshop looked at designing pages for the World Wide Web using
Perl to deal with buttons and text boxes to generate custom Web pages
on the fly. Creating a Web page without all these things is a much
easier task. There is information about how to do this at Leeds but
otherwise you should look at NCSA's definitive Beginner's Guide to
HTML.
There are plenty of other Perl tutorials around, and most (if not all)
of them can be found at the UF/NA Perl Archive. However I wanted
something that included exercises developing a consistent theme; none
of the others seemed to do this.
This tutorial assumes a very basic knowledge of UNIX and concentrates
on how to write basic working perl programs. It does not explain why
many things are as they are, nor does it draw generalisations about
the language; it is assumed that the reader can make most of these
inferences correctly for themselves. You can find more information on
those topics elsewhere (see above).
Thanks to Neil Bowers whose Perl page is where I ripped off the camel
icon (though he ripped it off someone before me, of course) and to our
Support team for their technical wizardry.
The structure of this tutorial is as follows:
* A basic perl program
+ The first line
+ Comments and statements
+ Simple printing
* Running the program
* Scalar variables
+ Operations and assignment
+ Interpolation
+ Exercise
* Array variables
+ Array assignments
+ Displaying arrays
+ Exercise
* Filehandling
+ Exercise
* Control structures
+ foreach
+ Testing
+ for
+ while and until
+ Exercise
* Conditionals
+ Exercise
* String matching
+ Regular expressions
+ The $_ special variable
+ More on REs
+ Some example REs
+ Exercise
* Substitution and translation
+ Options
+ Remembering patterns
+ Translation
+ Exercise
* Split
+ Exercise
* Associative arrays
+ Operators
+ Environment variables
* Subroutines
+ Parameters
+ Returning values
+ Local variables
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* PERL TUTORIAL: A BASIC PROGRAM *
Here is the basic perl program that we'll use to get started.
#!/usr/local/bin/perl
#
# Program to do the obvious
#
print 'Hello world.'; # Print a message
Each of the parts will be discussed in turn.
Every perl program starts off with this as its very first line:
#!/usr/local/bin/perl
although this may vary from system to system. This line tells the
machine what to do with the file when it is executed (ie it tells it
to run the file through Perl).
Comments can be inserted into a program with the # symbol, and
anything from the # to the end of the line is ignored (with the
exception of the first line). The only way to stretch comments over
several lines is to use a # on each line.
Everything else is a Perl statement which must end with a semicolon,
like the last line above.
The print function outputs some information. In the above case it
prints out the the literal string Hello world. and of course the
statement ends with a semicolon.
You may find the above program produces an slightly unexpected result.
So the next thing to do is to run it.
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Type in the example program using a text editor, and save it. Emacs is
a good editor to use for this because it has its own Perl mode which
formats lines nicely when you hit tab (use `M-x perl-mode'). But as
ever, use whichever you're most comfortable with.
After you've entered and saved the program make sure the file is
executable by using the command
chmod u+x progname
at the UNIX prompt, where progname is the filename of the program. Now
to run the program just type any of the following at the prompt.
perl progname
./progname
progname
If something goes wrong then you may get error messages, or you may
get nothing. You can always run the program with warnings using the
command
perl -w progname
at the prompt. This will display warnings and other (hopefully)
helpful messages before it tries to execute the program. To run the
program with a debugger use the command
perl -d progname
When the file is executed Perl first compiles it and then executes
that compiled version. So after a short pause for compilation the
program should run quite quickly. This also explains why you can get
compilation errors when you execute a Perl file which consists only of
text.
Make sure your program works before proceeding. The program's output
may be slightly unexpected - at least it isn't very pretty. We'll look
next at variables and then tie this in with prettier printing.
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The most basic kind of variable in Perl is the scalar variable. Scalar
variables hold both strings and numbers, and are remarkable in that
strings and numbers are completely interchangable. For example, the
statement
$priority = 9;
sets the scalar variable $priority to 9, but you can also assign a
string to exactly the same variable:
$priority = 'high';
Perl also accepts numbers as strings, like this:
$priority = '9';
$default = '0009';
and can still cope with arithmetic and other operations quite happily.
In general variable names consists of numbers, letters and
underscores, but they should not start with a number and the variable
$_ is special, as we'll see later. Also, Perl is case sensitive, so
$a and $A are different.
Operations and Assignment
Perl uses all the usual C arithmetic operators:
$a = 1 + 2; # Add 1 and 2 and store in $a
$a = 3 - 4; # Subtract 4 from 3 and store in $a
$a = 5 * 6; # Multiply 5 and 6
$a = 7 / 8; # Divide 7 by 8 to give 0.875
$a = 9 ** 10; # Nine to the power of 10
$a = 5 % 2; # Remainder of 5 divided by 2
++$a; # Increment $a and then return it
$a++; # Return $a and then increment it
--$a; # Decrement $a and then return it
$a--; # Return $a and then decrement it
and for strings Perl has the following among others:
$a = $b . $c; # Concatenate $b and $c
$a = $b x $c; # $b repeated $c times
To assign values Perl includes
$a = $b; # Assign $b to $a
$a += $b; # Add $b to $a
$a -= $b; # Subtract $b from $a
$a .= $b; # Append $b onto $a
Note that when Perl assigns a value with $a = $b it makes a copy of $b
and then assigns that to $a. Therefore the next time you change $b it
will not alter $a.
Other operators can be found on the perlop manual page. Type man
perlop at the prompt.
The following code prints apples and pears using concatenation:
$a = 'apples';
$b = 'pears';
print $a.' and '.$b;
It would be nicer to include only one string in the final print
statement, but the line
print '$a and $b';
prints literally $a and $b which isn't very helpful. Instead we can
use the double quotes in place of the single quotes:
print "$a and $b";
The double quotes force interpolation of any codes, including
interpreting variables. This is a much nicer than our original
statement. Other codes that are interpolated include special
characters such as newline and tab. The code \n is a newline and \t is
a tab.
This exercise is to rewrite the Hello world program so that (a) the
string is assigned to a variable and (b) this variable is then printed
with a newline character. Use the double quotes and don't use the
concatenation operator. Make sure you can get this to work before
proceeding.
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A slightly more interesting kind of variable is the array variable
which is a list of scalars (ie numbers and strings). Array variables
have the same format as scalar variables except that they are prefixed
by an @ symbol. The statement
@food = ("apples", "pears", "eels");
@music = ("whistle", "flute");
assigns a three element list to the array variable @food and a two
element list to the array variable @music.
The array is accessed by using indices starting from 0, and square
brackets are used to specify the index. The expression
$food[2]
returns eels. Notice that the @ has changed to a $ because eels is a
scalar.
As in all of Perl, the same expression in a different context can
produce a different result. The first assignment below explodes the
@music variable so that it is equivalent to the second assignment.
@moremusic = ("organ", @music, "harp");
@moremusic = ("organ", "whistle", "flute", "harp");
This should suggest a way of adding elements to an array. A neater way
of adding elements is to use the statement
push(@food, "eggs");
which pushes eggs onto the end of the array @food. To push two or more
items onto the array use one of the following forms:
push(@food, "eggs", "lard");
push(@food, ("eggs", "lard"));
push(@food, @morefood);
The push function returns the length of the new list.
To remove the last item from a list and return it use the pop
function. From our original list the pop function returns eels and
@food now has two elements:
$grub = pop(@food); # Now $grub = "eels"
It is also possible to assign an array to a scalar variable. As usual
context is important. The line
$f = @food;
assigns the length of @food, but
$f = "@food";
turns the list into a string with a space between each element. This
space can be replaced by any other string by changing the value of the
special $" variable. This variable is just one of Perl's many special
variables, most of which have odd names.
Arrays can also be used to make multiple assignments to scalar
variables:
($a, $b) = ($c, $d); # Same as $a=$c; $b=$d;
($a, $b) = @food; # $a and $b are the first two
# items of @food.
($a, @somefood) = @food; # $a is the first item of @food
# @somefood is a list of the
# others.
(@somefood, $a) = @food; # @somefood is @food and
# $a is undefined.
The last assignment occurs because arrays are greedy, and @somefood
will swallow up as much of @food as it can. Therefore that form is
best avoided.
Finally, you may want to find the index of the last element of a list.
To do this for the @food array use the expression
$#food
Since context is important, it shouldn't be too surprising that the
following all produce different results:
print @food; # By itself
print "@food"; # Embedded in double quotes
print @food.""; # In a scalar context
Try out each of the above three print statements to see what they do.
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Here is the basic perl program which does the same as the UNIX cat
command on a certain file.
#!/usr/local/bin/perl
#
# Program to open the password file, read it in,
# print it, and close it again.
$file = '/etc/passwd'; # Name the file
open(INFO, $file); # Open the file
@lines = <INFO>; # Read it into an array
close(INFO); # Close the file
print @lines; # Print the array
The open function opens a file for input (i.e. for reading). The first
parameter is the filehandle which allows Perl to refer to the file in
future. The second parameter is an expression denoting the filename.
If the filename was given in quotes then it is taken literally without
shell expansion. So the expression '~/notes/todolist' will not be
interpreted successfully. If you want to force shell expansion then
use angled brackets: that is, use <~/notes/todolist> instead.
The close function tells Perl to finish with that file.
There are a few useful points to add to this discussion on
filehandling. First, the open statement can also specify a file for
output and for appending as well as for input. To do this, prefix the
filename with a > for output and a >> for appending:
open(INFO, $file); # Open for input
open(INFO, ">$file"); # Open for output
open(INFO, ">>$file"); # Open for appending
open(INFO, "<$file"); # Also open for input
Second, if you want to print something to a file you've already opened
for output then you can use the print statement with an extra
parameter. To print a string to the file with the INFO filehandle use
print INFO "This line goes to the file.\n";
Third, you can use the following to open the standard input (usually
the keyboard) and standard output (usually the screen) respectively:
open(INFO, '-'); # Open standard input
open(INFO, '>-'); # Open standard output
In the above program the information is read from a file. The file is
the INFO file and to read from it Perl uses angled brackets. So the
statement
@lines = <INFO>;
reads the file denoted by the filehandle into the array @lines. Note
that the <INFO> expression reads in the file entirely in one go. This
because the reading takes place in the context of an array variable.
If @lines is replaced by the scalar $lines then only the next one line
would be read in. In either case each line is stored complete with its
newline character at the end.
Modify the above program so that the entire file is printed with a #
symbol at the beginning of each line. You should only have to add one
line and modify another. Use the $" variable. Unexpected things can
happen with files, so you may find it helpful to use the -w option as
mentioned in the section on running Perl programs.
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More interesting possiblities arise when we introduce control
structures and looping. Perl supports lots of different kinds of
control structures which tend to be like those in C, but are very
similar to Pascal, too. Here we discuss a few of them.
To go through each line of an array or other list-like structure (such
as lines in a file) Perl uses the foreach structure. This has the form
foreach $morsel (@food) # Visit each item in turn
# and call it $morsel
{
print "$morsel\n"; # Print the item
print "Yum yum\n"; # That was nice
}
The actions to be performed each time are enclosed in a block of curly
braces. The first time through the block $morsel is assigned the value
of the first item in the array @food. Next time it is assigned the
value of the second item, and so until the end. If @food is empty to
start with then the block of statements is never executed.
The next few structures rely on a test being true or false. In Perl
any non-zero number and non-empty string is counted as true. The
number zero, zero by itself in a string, and the empty string are
counted as false. Here are some tests on numbers and strings.
$a == $b # Is $a numerically equal to $b?
# Beware: Don't use the = operator.
$a != $b # Is $a numerically unequal to $b?
$a eq $b # Is $a string-equal to $b?
$a ne $b # Is $a string-unequal to $b?
You can also use logical and, or and not:
($a && $b) # Is $a and $b true?
($a || $b) # Is either $a or $b true?
!($a) # is $a false?
Perl has a for structure that mimics that of C. It has the form
for (initialise; test; inc)
{
first_action;
second_action;
etc
}
First of all the statement initialise is executed. Then while test is
true the block of actions is executed. After each time the block is
executed inc takes place. Here is an example for loop to print out the
numbers 0 to 9.
for ($i = 0; $i < 10; ++$i) # Start with $i = 1
# Do it while $i < 10
# Increment $i before repeating
{
print "$i\n";
}
Here is a program that reads some input from the keyboard and won't
continue until it is the correct password
#!/usr/local/bin/perl
print "Password? "; # Ask for input
$a = <STDIN>; # Get input
chop $a; # Remove the newline at end
while ($a ne "fred") # While input is wrong...
{
print "sorry. Again? "; # Ask again
$a = <STDIN>; # Get input again
chop $a; # Chop off newline again
}
The curly-braced block of code is executed while the input does not
equal the password. The while structure should be fairly clear, but
this is the opportunity to notice several things. First, we can we
read from the standard input (the keyboard) without opening the file
first. Second, when the password is entered $a is given that value
including the newline character at the end. The chop function removes
the last character of a string which in this case is the newline.
To test the opposite thing we can use the until statement in just the
same way. This executes the block repeatedly until the expression is
true, not while it is true.
Another useful technique is putting the while or until check at the
end of the statement block rather than at the beginning. This will
require the presence of the do operator to mark the beginning of the
block and the test at the end. If we forgo the sorry. Again message in
the above password program then it could be written like this.
#!/usr/local/bin/perl
do
{
"Password? "; # Ask for input
$a = <STDIN>; # Get input
chop $a; # Chop off newline
}
while ($a ne "fred") # Redo while wrong input
Modify the program from the previous exercise so that each line of the
file is read in one by one and is output with a line number at the
beginning. You should get something like:
1 root:oYpYXm/qRO6N2:0:0:Super-User:/:/bin/csh
2 sysadm:*:0:0:System V Administration:/usr/admin:/bin/sh
3 diag:*:0:996:Hardware Diagnostics:/usr/diags:/bin/csh
etc
You may find it useful to use the structure
while ($line = <INFO>)
{
...
}
When you have done this see if you can alter it so that line numbers
are printed as 001, 002, ..., 009, 010, 011, 012, etc. To do this you
should only need to change one line by inserting an extra four
characters. Perl's clever like that.
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Of course Perl also allows if/then/else statements. These are of the
following form:
if ($a)
{
print "The string is not empty\n";
}
else
{
print "The string is empty\n";
}
For this, remember that an empty string is considered to be false. It
will also give an "empty" result if $a is the string 0.
It is also possible to include more alternatives in a conditional
statement:
if (!$a) # The ! is the not operator
{
print "The string is empty\n";
}
elsif (length($a) == 1) # If above fails, try this
{
print "The string has one character\n";
}
elsif (length($a) == 2) # If that fails, try this
{
print "The string has two characters\n";
}
else # Now, everything has failed
{
print "The string has lots of characters\n";
}
In this, it is important to notice that the elsif statement really
does have an "e" missing.
Find a fairly large file that contains some text and some blank lines.
The file ~nik/WWW/Misc/electricity.txt is pretty good because it's
funny apart from anything else. It was originally posted to our local
news system by David O'Brien.
From the previous exercise you should have a program which prints out
the password file with line numbers. Change it so that works with the
text file. Now alter the program so that line numbers aren't printed
or counted with blank lines, but every line is still printed,
including the blank ones. Remember that when a line of the file is
read in it will still include its newline character at the end.
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One of the most useful features of Perl (if not the most useful
feature) is its powerful string manipulation facilities. At the heart
of this is the regular expression (RE) which is shared by many other
UNIX utilities.
A regular expression is contained in slashes, and matching occurs with
the =~ operator. The following expression is true if the string the
appears in variable $sentence.
$sentence =~ /the/
The RE is case sensitive, so if
$sentence = "The quick brown fox";
then the above match will be false. The operator !~ is used for
spotting a non-match. In the above example
$sentence !~ /the/
is true because the string the does not appear in $sentence.
We could use a conditional as
if ($sentence =~ /under/)
{
print "We're talking about rugby\n";
}
which would print out a message if we had either of the following
$sentence = "Up and under";
$sentence = "Best winkles in Sunderland";
But it's often much easier if we assign the sentence to the special
variable $_ which is of course a scalar. If we do this then we can
avoid using the match and non-match operators and the above can be
written simply as
if (/under/)
{
print "We're talking about rugby\n";
}
The $_ variable is the default for many Perl operations and tends to
be used very heavily.
In an RE there are plenty of special characters, and it is these that
both give them their power and make them appear very complicated. It's
best to build up your use of REs slowly; their creation can be
something of an art form.
Here are some special RE characters and their meaning
. # Any single character except a newline
^ # The beginning of the line or string
$ # The end of the line or string
* # Zero or more of the last character
+ # One or more of the last character
? # Zero or one of the last character
and here are some example matches. Remember that should be enclosed in
/.../ slashes to be used.
t.e # t followed by anthing followed by e
# This will match the
# tre
# tle
# but not te
# tale
^f # f at the beginning of a line
^ftp # ftp at the beginning of a line
e$ # e at the end of a line
tle$ # tle at the end of a line
und* # un followed by zero or more d characters
# This will match un
# und
# undd
# unddd (etc)
.* # Any string without a newline. This is because
# the . matches anything except a newline and
# the * means zero or more of these.
^$ # A line with nothing in it.
There are even more options. Square brackets are used to match any one
of the characters inside them. Inside square brackets a - indicates
"between" and a ^ at the beginning means "not":
[qjk] # Either q or j or k
[^qjk] # Neither q nor j nor k
[a-z] # Anything from a to z inclusive
[^a-z] # No lower case letters
[a-zA-Z] # Any letter
[a-z]+ # Any non-zero sequence of lower case letters
At this point you can probably skip to the end and do at least most of
the exercise. The rest is mostly just for reference.
A vertical bar | represents an "or" and parentheses (...) can be used
to group things together:
jelly|cream # Either jelly or cream
(eg|le)gs # Either eggs or legs
(da)+ # Either da or dada or dadada or...
Here are some more special characters:
\n # A newline
\t # A tab
\w # Any alphanumeric (word) character.
# The same as [a-zA-Z0-9_]
\W # Any non-word character.
# The same as [^a-zA-Z0-9_]
\d # Any digit. The same as [0-9]
\D # Any non-digit. The same as [^0-9]
\s # Any whitespace character: space,
# tab, newline, etc
\S # Any non-whitespace character
\b # A word boundary, outside [] only
\B # No word boundary
Clearly characters like $, |, [, ), \, / and so on are peculiar cases
in regular expressions. If you want to match for one of those then you
have to preceed it by a backslash. So:
\| # Vertical bar
\[ # An open square bracket
\) # A closing parenthesis
\* # An asterisk
\^ # A carat symbol
\/ # A slash
\\ # A backslash
and so on.
As was mentioned earlier, it's probably best to build up your use of
regular expressions slowly. Here are a few examples. Remember that to
use them for matching they should be put in /.../ slashes
[01] # Either "0" or "1"
\/0 # A division by zero: "/0"
\/ 0 # A division by zero with a space: "/ 0"
\/\s0 # A division by zero with a whitespace:
# "/ 0" where the space may be a tab etc.
\/ *0 # A division by zero with possibly some
# spaces: "/0" or "/ 0" or "/ 0" etc.
\/\s*0 # A division by zero with possibly some
# whitespace.
\/\s*0\.0* # As the previous one, but with decimal
# point and maybe some 0s after it. Accepts
# "/0." and "/0.0" and "/0.00" etc and
# "/ 0." and "/ 0.0" and "/ 0.00" etc.
Previously your program counted non-empty lines. Alter it so that
instead of counting non-empty lines it counts only lines with
* the letter x
* the string the
* the string the which may or may not have a capital t
* the word the with or without a capital. Use \b to detect word
boundaries.
In each case the program should print out every line, but it should
only number those specified. Try to use the $_ variable to avoid using
the =~ match operator explicitly.
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* SUBSTITUTION AND TRANSLATION *
As well as identifying regular expressions Perl can make substitutions
based on those matches. The way to do this is to use the s function
which is designed to mimic the way substitution is done in the vi text
editor. Once again the match operator is used, and once again if it is
omitted then the substitution is assumed to take place with the $_
variable.
To replace an occurrence of london by London in the string $sentence
we use the expression
$sentence =~ s/london/London/
and to do the same thing with the $_ variable just
s/london/London/
Notice that the two regular expressions (london and London) are
surrounded by a total of three slashes. The result of this expression
is the number of substitutions made, so it is either 0 (false) or 1
(true) in this case.
This example only replaces the first occurrence of the string, and it
may be that there will be more than one such string we want to
replace. To make a global substitution the last slash is followed by a
g as follows:
s/london/London/g
which of course works on the $_ variable. Again the expression returns
the number of substitutions made, which is 0 (false) or something
greater than 0 (true).
If we want to also replace occurrences of lOndon, lonDON, LoNDoN and
so on then we could use
s/[Ll][Oo][Nn][Dd][Oo][Nn]/London/g
but an easier way is to use the i option (for "ignore case"). The
expression
s/london/London/gi
will make a global substitution ignoring case. The i option is also
used in the basic /.../ regular expression match.
It's often useful to remember patterns that have been matched so that
they can be used again. It just so happens that anything matched in
parentheses gets remembered in the variables $1,...,$9. These strings
can also be used in the same regular expression (or substitution) by
using the special RE codes \1,...,\9. For example
$_ = "Lord Whopper of Fibbing";
s/([A-Z])/:\1:/g;
print "$_\n";
will replace each upper case letter by that letter surrounded by
colons. It will print :L:ord :W:hopper of :F:ibbing. The variables
$1,...,$9 are read-only variables; you cannot alter them yourself.
As another example, the test
if (/(\b.+\b) \1/)
{
print "Found $1 repeated\n";
}
will identify any words repeated. Each \b represents a word boundary
and the .+ matches any non-empty string, so \b.+\b matches anything
between two word boundaries. This is then remembered by the
parentheses and stored as \1 for regular expressions and as $1 for the
rest of the program.
The following swaps the first and last characters of a line in the $_
variable:
s/^(.)(.*)(.)$/\3\2\1/
The ^ and $ match the beginning and end of the line. The \1 code
stores the first character; the \2 code stores everything else up the
last character which is stored in the \3 code. Then that whole line is
replaced with \1 and \3 swapped round.
After a match, you can use the special read-only variables $` and $&
and $' to find what was matched before, during and after the seach. So
after
$_ = "Lord Whopper of Fibbing";
/pp/;
all of the following are true. (Remember that eq is the
string-equality test.)
$` eq "Lord Wo";
$& eq "pp";
$' eq "er of Fibbing";
Finally on the subject of remembering patterns it's worth knowing that
inside of the slashes of a match or a substitution variables are
interpolated. So
$search = "the";
s/$search/xxx/g;
will replace every occurrence of the with xxx. If you want to replace
every occurence of there then you cannot do s/$searchre/xxx/ because
this will be interpolated as the variable $searchre. Instead you
should put the variable name in curly braces so that the code becomes
$search = "the";
s/${search}re/xxx/;
The tr function allows character-by-character translation. The
following expression replaces each a with e, each b with d, and each c
with f in the variable $sentence. The expression returns the number of
substitutions made.
$sentence =~ tr/abc/edf/
Most of the special RE codes do not apply in the tr function. For
example, the statement here counts the number of asterisks in the
$sentence variable and stores that in the $count variable.
$count = ($sentence =~ tr/*/*/);
However, the dash is still used to mean "between". This statement
converts $_ to upper case.
tr/a-z/A-Z/;
Your current program should count lines of a file which contain a
certain string. Modify it so that it counts lines with double letters
(or any other double character). Modify it again so that these double
letters appear also in parentheses. For example your program would
produce a line like this among others:
023 Amp, James Wa(tt), Bob Transformer, etc. These pion(ee)rs conducted many
Try to get it so that all pairs of letters are in parentheses, not
just the first pair on each line.
For a slightly more interesting program you might like to try the
following. Suppose your program is called countlines. Then you would
call it with
./countlines
However, if you call it with several arguments, as in
./countlines first second etc
then those arguments are stored in the array @ARGV. In the above
example we have $ARGV[0] is first and $ARGV[1] is second and $ARGV[2]
is etc. Modify your program so that it accepts one argument and counts
only those lines with that string. It should also put occurrences of
this string in paretheses. So
./countlines the
will output something like this line among others:
019 But (the) greatest Electrical Pioneer of (the)m all was Thomas Edison, who
_________________________________________________________________
----- boundary http://agora.leeds.ac.uk/nik/Perl/split.html -----
A very useful function in Perl is split, which splits up a string and
places it into an array. The function uses a regular expression and as
usual works on the $_ variable unless otherwise specified.
The split function is used like this:
$info = "Caine:Michael:Actor:14, Leafy Drive";
@personal = split(/:/, $info);
which has the same overall effect as
@personal = ("Caine", "Michael", "Actor", "14, Leafy Drive");
If we have the information stored in the $_ variable then we can just
use this instead
@personal = split(/:/);
If the fields are divided by any number of colons then we can use the
RE codes to get round this. The code
$_ = "Capes:Geoff::Shot putter:::Big Avenue";
@personal = split(/:+/);
is the same as
@personal = ("Capes", "Geoff",
"Shot putter", "Big Avenue");
But this:
$_ = "Capes:Geoff::Shot putter:::Big Avenue";
@personal = split(/:/);
would be like
@personal = ("Capes", "Geoff", "",
"Shot putter", "", "", "Big Avenue");
A word can be split into characters, a sentence split into words and a
paragraph split into sentences:
@chars = split(//, $word);
@words = split(/ /, $sentence);
@sentences = split(/\./, $paragraph);
In the first case the null string is matched between each character,
and that is why the @chars array is an array of characters - ie an
array of strings of length 1.
A useful tool in natural language processing is concordance. This
allows a specific string to be displayed in its immediate context
whereever it appears in a text. For example, a concordance program
identifying the target string the might produce some of the following
output. Notice how the occurrences of the target string line up
vertically.
discovered (this is the truth) that when he
t kinds of metal to the leg of a frog, an e
rrent developed and the frog's leg kicked,
longer attached to the frog, which was dea
normous advances in the field of amphibian
ch it hop back into the pond -- almost. Bu
ond -- almost. But the greatest Electrical
ectrical Pioneer of them all was Thomas Edi
This exercise is to write such a program. Here are some tips:
* Read the entire file into array (this obviously isn't useful in
general because the file may be extremely large, but we won't
worry about that here). Each item in the array will be a line of
the file.
* When the chop function is used on an array it chops off the last
character of every item in the array.
* Recall that you can join the whole array together with a statement
like $text = "@lines";
* Use the target string as delimiter for splitting the text. (Ie,
use the target string in place of the colon in our previous
examples.) You should then have an array of all the strings
between the target strings.
* For each array element in turn, print it out, print the target
string, and then print the next array element.
* Recall that the last element of an array @food has index $#food.
As it stands this would be a pretty good program, but the target
strings won't line up vertically. To tidy up the strings you'll need
the substr function. Here are three examples of its use.
substr("Once upon a time", 3, 4); # returns "e up"
substr("Once upon a time", 7); # returns "on a time"
substr("Once upon a time", -6, 5); # returns "a tim"
The first example returns a substring of length 4 starting at position
3. Remember that the first character of a string has index 0. The
second example shows that missing out the length gives the substring
right to the end of the string The third example shows that you can
also index from the end using a negative index. It returns the
substring that starts at the 6th character from the end and has length
5.
If you use a negative index that extends beyond the beginning of the
string then Perl will return nothing or give a warning. To avoid this
happening you can pad out the string by using the x operator mentioned
earlier. The expression (" "x30) produces 30 spaces, for example.
_________________________________________________________________
----- boundary http://agora.leeds.ac.uk/nik/Perl/associative.html -----
Ordinary list arrays allow us to access their element by number. The
first element of array @food is $food[0]. The second element is
$food[1], and so on. But Perl also allows us to create arrays which
are accessed by string. These are called associative arrays.
To define an associative array we use the usual parenthesis notation,
but the array itself is prefixed by a % sign. Suppose we want to
create an array of people and their ages. It would look like this:
%ages = ("Michael Caine", 39,
"Dirty Den", 34,
"Angie", 27,
"Willy", "21 in dog years",
"The Queen Mother", 108);
Now we can find the age of people with the following expressions
$ages{"Michael Caine"}; # Returns 39
$ages{"Dirty Den"}; # Returns 34
$ages{"Angie"}; # Returns 27
$ages{"Willy"}; # Returns "21 in dog years"
$ages{"The Queen Mother"}; # Returns 108
Notice that like list arrays each % sign has changed to a $ to access
an individual element because that element is a scalar. Unlike list
arrays the index (in this case the person's name) is enclosed in curly
braces, the idea being that associative arrays are fancier than list
arrays.
An associative array can be converted back into a list array just by
assigning it to a list array variable. A list array can be converted
into an associative array by assigning it to an associative array
variable. Ideally the list array will have an even number of elements:
@info = %ages; # @info is a list array. It
# now has 10 elements
$info[5]; # Returns the value 27 from
# the list array @info
%moreages = @info; # %moreages is an associative
# array. It is the same as %ages
Associative arrays do not have any order to their elements (they are
just like hash tables) but is it possible to access all the elements
in turn using the keys function and the values function:
foreach $person (keys %ages)
{
print "I know the age of $person\n";
}
foreach $age (values %ages)
{
print "Somebody is $age\n";
}
When keys is called it returns a list of the keys (indices) of the
associative array. When values is called it returns a list of the
values of the array. These functions return their lists in the same
order, but this order has nothing to do with the order in which the
elements have been entered.
When keys and values are called in a scalar context they return the
number of key/value pairs in the associative array.
There is also a function each which returns a two element list of a
key and its value. Every time each is called it returns another
key/value pair:
while (($person, $age) = each(%ages))
{
print "$person is $age\n";
}
When you run a perl program, or any script in UNIX, there will be
certain environment variables set. These will be things like USER
which contains your username and DISPLAY which specifies which screen
your graphics will go to. When you run a perl CGI script on the World
Wide Web there are environment variables which hold other useful
information. All these variables and their values are stored in the
associative %ENV array in which the keys are the variable names. Try
the following in a perl program:
print "You are called $ENV{'USER'} and you are ";
print "using display $ENV{'DISPLAY'}\n";
_________________________________________________________________
----- boundary http://agora.leeds.ac.uk/nik/Perl/subroutines.html -----
Like any good programming langauge Perl allows the user to define
their own functions, called subroutines. They may be placed anywhere
in your program but it's probably best to put them all at the
beginning or all at the end. A subroutine has the form
sub mysubroutine
{
print "Not a very interesting routine\n";
print "This does the same thing every time\n";
}
regardless of any parameters that we may want to pass to it. All of
the following will work to call this subroutine. Notice that a
subroutine is called with an & character in front of the name:
&mysubroutine; # Call the subroutine
&mysubroutine($_); # Call it with a parameter
&mysubroutine(1+2, $_); # Call it with two parameters
In the above case the parameters are acceptable but ignored. When the
subroutine is called any parameters are passed as a list in the
special @_ list array variable. This variable has absolutely nothing
to do with the $_ scalar variable. The following subroutine merely
prints out the list that it was called with. It is followed by a
couple of examples of its use.
sub printargs
{
print "@_\n";
}
&printargs("perly", "king"); # Example prints "perly king"
&printargs("frog", "and", "toad"); # Prints "frog and toad"
Just like any other list array the individual elements of @_ can be
accessed with the square bracket notation:
sub printfirsttwo
{
print "Your first argument was $_[0]\n";
print "and $_[1] was your second\n";
}
Again it should be stressed that the indexed scalars $_[0] and $_[1]
and so on have nothing to with the scalar $_ which can also be used
without fear of a clash.
Result of a subroutine is always the last thing evaluated. This
subroutine returns the maximum of two input parameters. An example of
its use follows.
sub maximum
{
if ($_[0] > $_[1])
{
$_[0];
}
else
{
$_[1];
}
}
$biggest = &maximise(37, 24); # Now $biggest is 37
The &printfirsttwo subroutine above also returns a value, in this case
1. This is because the last thing that subroutine did was a print
statement and the result of a successful print statement is always 1.
The @_ variable is local to the current subroutine, and so of course
are $_[0], $_[1], $_[2], and so on. Other variables can be made local
too, and this is useful if we want to start altering the input
parameters. The following subroutine tests to see if one string is
inside another, spaces not withstanding. An example follows.
sub inside
{
local($a, $b); # Make local variables
($a, $b) = ($_[0], $_[1]); # Assign values
$a =~ s/ //g; # Strip spaces from
$b =~ s/ //g; # local variables
($a =~ /$b/ || $b =~ /$a/); # Is $b inside $a
# or $a inside $b?
}
&inside("lemon", "dole money"); # true
In fact, it can even be tidied up by replacing the first two lines
with
local($a, $b) = ($_[0], $_[1]);
Популярность: 1, Last-modified: Mon, 18 Jan 1999 20:50:35 GmT