It is often convenient to simply write what one wants done into a file or script, and execute the script as though it were any other operating-system shell command. The interface to more weighty programs is often provided in the form of a script, and users frequently build their own scripts or customize existing ones to suit particular needs. Scripting is arguably the most frequent programming task performed. For many users, it is the only programming they will ever do.
Operating systems such as Unix and DOS (the command-line interface provided in Windows) provide such a scripting mechanism, but the scripting language in both cases is very rudimentary. Often a script is just a sequence or batch of commands that one would type to the shell prompt. It saves the user from having to type every one of the shell commands individually each time they require the same or similar sequence to be performed. Some scripting languages throw in a small amount of programmability in the form of a conditional and a loop, but that is about all. This is enough for smallish tasks, but as one’s scripts become bigger and more demanding, as scripts invariably seem to do, one often feels the need for a fuller fledged programming language. A Scheme with an adequate operating-system interface makes scripting easy and maintainable.
This section will describe how to write scripts in Scheme. Since there is wide variation in the various Scheme dialects on how to accomplish this, we will concentrate on the MzScheme dialect, and document in appendix A the modifications needed for other dialects. We will also concentrate on the Unix operating system for the moment; appendix B will deal with the DOS counterpart.
We will now create a Scheme script that says hello to the world. Saying hello is of course not a demanding scripting problem for traditional scripting languages. However, understanding how to transcribe it into Scheme will launch us on the path to more ambitious scripts. First, a conventional Unix hello script is a file, with contents that look like:
echo Hello, World!
It uses the shell command echo
. The script can be
named hello
, made into an executable by doing
chmod +x hello
and placed in one of
the directories named in the PATH
environment
variable. Thereafter, anytime one types
hello
at the shell prompt, one promptly gets the insufferable greeting.
A Scheme hello script will perform the same output
using Scheme (using the program in chapter 1),
but we need something in the file to inform the
operating system that it needs to construe the commands
in the file as Scheme, and not as its default script
language. The Scheme script file, also called
hello
, looks like:
":"; exec mzscheme -r $0 "$@" (display "Hello, World!") (newline))
Everything following the first line is straight
Scheme. However, the first line is the magic that
makes this into a script. When the user types
hello
at the Unix prompt, Unix will read the file
as a regular script. The first thing it sees is the
":"
, which is a shell no-op. The ;
is the shell
command separator. The next shell command is the
exec
. exec
tells Unix to abandon the
current script and run mzscheme ‑r $0 "$@"
instead,
where the parameter $0
will be replaced by the name
of the script, and the parameter "$@"
will be
replaced by the list of arguments given by the user to
the script. (In this case, there are no such
arguments.)
We have now, in effect, transformed the hello
shell
command into a different shell command, viz.,
mzscheme -r /whereveritis/hello
where /whereveritis/hello
is the pathname of hello
.
mzscheme
calls the MzScheme executable. The ‑r
option tells it to load the immediately following
argument as a Scheme file after collecting any
succeeding arguments into a vector called argv
.
(In this example, argv
will be the null vector.)
Thus, the Scheme script will be run as a Scheme file,
and the Scheme forms in the file will have access to
the script’s original arguments via the vector
argv
.
Now, Scheme has to tackle the first line in the script,
which as we’ve already seen, was really a well-formed,
traditional shell script. The ":""
is a
self-evaluating string in Scheme and thus harmless.
The
‘;
’ marks a Scheme comment, and so the exec ...
is
safely ignored. The rest of the file is of course
straight Scheme, and the expressions therein are
evaluated in sequence. After all of them have been
evaluated, Scheme will exit.
In sum, typing hello
at the shell prompt will produce
Hello, World!
and return you to the shell prompt.
A Scheme script uses the variable argv
to refer to
its arguments. For example, the following script
echoes all its arguments, each on a line:
":""; exec mzscheme -r $0 "$@" ;Put in argv-count the number of arguments supplied (define argv-count (vector-length argv)) (let loop ((i 0)) (unless (>= i argv-count) (display (vector-ref argv i)) (newline) (loop (+ i 1))))
Let’s call this script echoall
. Calling echoall
1 2 3
will display
1 2 3
Note that the script name ("echoall""
) is not included in
the argument vector.
Let’s now tackle a more substantial problem. We need
to transfer files from one computer to another and the
only method we have is to use a 3.5” floppy as a
ferry. We need a script split4floppy
that will
split files larger than 1.44 million bytes into
floppy-sized chunks. The script file split4floppy
is as follows:
":"";exec mzscheme -r $0 "$@" ;floppy-size = number of bytes that will comfortably fit on a ; 3.5" floppy (define floppy-size 1440000) ;split splits the bigfile f into the smaller, floppy-sized ;subfiles, viz., subfile-prefix.1, subfile-prefix.2, etc. (define split (lambda (f subfile-prefix) (call-with-input-file f (lambda (i) (let loop ((n 1)) (if (copy-to-floppy-sized-subfile i subfile-prefix n) (loop (+ n 1)))))))) ;copy-to-floppy-sized-subfile copies the next 1.44 million ;bytes (if there are less than that many bytes left, it ;copies all of them) from the big file to the nth ;subfile. Returns true if there are bytes left over, ;otherwise returns false. (define copy-to-floppy-sized-subfile (lambda (i subfile-prefix n) (let ((nth-subfile (string-append subfile-prefix "."" (number->string n)))) (if (file-exists? nth-subfile) (delete-file nth-subfile)) (call-with-output-file nth-subfile (lambda (o) (let loop ((k 1)) (let ((c (read-char i))) (cond ((eof-object? c) #f) (else (write-char c o) (if (< k floppy-size) (loop (+ k 1)) #t)))))))))) ;bigfile = script’s first arg ; = the file that needs splitting (define bigfile (vector-ref argv 0)) ;subfile-prefix = script’s second arg ; = the basename of the subfiles (define subfile-prefix (vector-ref argv 1)) ;Call split, making subfile-prefix.{1,2,3,...} from ;bigfile (split bigfile subfile-prefix)
Script split4floppy
is called as follows:
split4floppy largefile chunk
This splits largefile
into subfiles chunk.1
,
chunk.2
, ..., such that each subfile fits on a
floppy.
After the chunk.i
have been ferried over to the
target computer, the file largefile
can be
retrieved by stringing the chunk.i
together. This
can be done on Unix with:
cat chunk.1 chunk.2 ... > largefile
and on DOS with:
copy /b chunk.1+chunk.2+... largefile