\input bkmacs
\pagetag{\typing}
\photo{}{\pspicture{4in}{io}{io}{}\vfill}
\chapter{Input and Output}
\chaptag{\io}
In the tic-tac-toe project in Chapter \ttt, we didn't write a complete game
program. We wrote a {\it function\/} that took a board position and {\tt x}
or {\tt o} as arguments, returning the next move. We noted at the time that
a complete game program would also need to carry on a {\it conversation\/}
with the user. Instead of computing and returning one single value, a
\bkidx{conversational}{program} must carry out a sequence of events in time,
reading information from the \idx{keyboard} and displaying other information
on the \idx{screen}.
Before we complete the tic-tac-toe project, we'll start by
exploring Scheme's mechanisms for \bkidx{interactive}{programming}.
\backskipsubhd{Printing}{5}
\justidx{printing}
Up until now, we've never told Scheme to print anything. The programs we've
written have computed values and returned them; we've relied on the
\idx{read-eval-print loop} to print these values.\footnt{The only
exception is that we've used {\tt trace}, which prints messages about
the progress of a computation.}
But let's say we want to write a program to print out all of the words to
``99 Bottles of Beer on the Wall.'' We could implement a function to produce a
humongous {\it list\/} of the lines of the song, like this:
{\prgex%
(define (bottles n)
(if (= n 0)
'()
(append (verse n)
(bottles (- n 1)))))
}
{\medskipamount=4pt\prgexskipamount=9pt\prgexbaselineamount=10pt
{\prgex%
(define (verse n)
(list (cons n '(bottles of beer on the wall))
(cons n '(bottles of beer))
'(if one of those bottles should happen to fall)
(cons (- n 1) '(bottles of beer on the wall))
'()))
> (bottles 3)
((3 BOTTLES OF BEER ON THE WALL)
(3 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(2 BOTTLES OF BEER ON THE WALL)
()
(2 BOTTLES OF BEER ON THE WALL)
(2 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(1 BOTTLES OF BEER ON THE WALL)
()
(1 BOTTLES OF BEER ON THE WALL)
(1 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(0 BOTTLES OF BEER ON THE WALL)
())
}
\noindent The problem is that we don't want a list. All we
want is to print out the lines of the song; storing them in a data structure
is unnecessary and inefficient. Also, some versions of Scheme would print
the above list like this:
{\prgex%
((3 BOTTLES OF BEER ON THE WALL) (3 BOTTLES OF BEER) (IF ONE OF
THOSE BOTTLES SHOULD HAPPEN TO FALL) (2 BOTTLES OF BEER ON THE
WALL) () (2 BOTTLES OF BEER ON THE WALL) (2 BOTTLES OF BEER) (IF
ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL) (1 BOTTLES OF BEER ON
THE WALL) () (1 BOTTLES OF BEER ON THE WALL) (1 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL) (0 BOTTLES OF BEER
ON THE WALL) ())
}
\noindent or even all on one line. We can't rely on Scheme's mechanism for
printing lists if we want to be sure of a particular arrangement on the
screen.
Instead we'll write a program to {\it print\/} a verse, rather
than return it in a list:
\justtt{show}
{\prgex%
(define (\ufun{bottles} n)
(if (= n 0)
'burp
(begin (verse n)
(bottles (- n 1)))))
(define (\ufun{verse} n)
(show (cons n '(bottles of beer on the wall)))
(show (cons n '(bottles of beer)))
(show '(if one of those bottles should happen to fall))
(show (cons (- n 1) '(bottles of beer on the wall)))
(show '()))
> (bottles 3)
(3 BOTTLES OF BEER ON THE WALL)
(3 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(2 BOTTLES OF BEER ON THE WALL)
()
(2 BOTTLES OF BEER ON THE WALL)
(2 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(1 BOTTLES OF BEER ON THE WALL)
()
(1 BOTTLES OF BEER ON THE WALL)
(1 BOTTLES OF BEER)
(IF ONE OF THOSE BOTTLES SHOULD HAPPEN TO FALL)
(0 BOTTLES OF BEER ON THE WALL)
()
BURP
}
} % skip kludges
\noindent Notice that Scheme doesn't print an outer set of parentheses.
Each line was printed separately; there isn't one big list containing all of
them.\footnt{We know that it's still not as beautiful as can be, because of
the capital letters and parentheses, but we'll get to that later.}
Why was ``burp''\ printed at the end? Just because we're printing things
explicitly doesn't mean that the read-eval-print loop stops functioning. We
typed the expression {\tt (bottles~3)}. In the course of evaluating that
expression, Scheme printed several lines for us. But the {\it value\/} of
the expression was the word {\tt burp}, because that's what {\tt bottles}
returned.
\subhd{Side Effects and Sequencing}
How does our program work? There are two new ideas here:\ {\it
\bkidx{side}{effect}s\/} and {\it sequencing.}
Until now, whenever we've invoked a procedure, our only goal has been to get
a return value. The procedures we've used compute and return a value, and do
nothing else. {\tt Show} is different. Although every Scheme procedure
returns a value, the Scheme language standard doesn't specify what
value the printing procedures should return.\footnt{Suppose {\tt show}
returns {\tt \#f} in your version of Scheme. Then you might see
{\prgex%
> (show 7)
7
#F
}
\noindent But since the return value is unspecified, we try to write
programs in such a way that we never use {\tt show}'s return value as the
return value from our procedures. That's why we return values like {\tt
burp}.} Instead, we are interested in their side effects. In other words,
we invoke {\tt show} because we want it to {\it do\/} something, namely,
print its argument on the screen.
What exactly do we mean by ``side effect''? The kinds of procedures that
we've used before this chapter can compute values, invoke helper procedures,
provide arguments to the helper procedures, and return a value. There may be
a lot of activity going on within the procedure, but the procedure
affects the world outside of itself only by returning a value that some
other procedure might use. {\tt Show} affects the world outside of itself
by putting something on the screen. After {\tt show} has finished its
work, someone who looks at the screen can tell that {\tt show} was
used.\footnt{The term {\it side\/} effect is based on the idea that a
procedure may have a useful return value as its main purpose and may also
have an effect ``on the side.'' It's a misnomer to talk about the
side effect of {\tt show}, since the effect is its main purpose. But nobody
ever says ``side return value''!}
{\medskipamount=4pt\prgexskipamount=9pt\prgexbaselineamount=10pt
\def\psate{\prgexskipamount=8pt}
Here's an example to illustrate the difference between values and effects:
{\prgex%
(define (\ufun{effect} x)
(show x)
'done)
(define (\ufun{value} x)
x)
> (effect '(oh! darling))
(OH! DARLING)
DONE
> (value '(oh! darling))
(OH! DARLING)
> (bf (effect '(oh! darling)))
(OH! DARLING)
ONE\psate
> (bf (value '(oh! darling)))
(DARLING)
> (define (\ufun{lots-of-effect} x)
(effect x)
(effect x)
(effect x))
> (define (\ufun{lots-of-value} x)
(value x)
(value x)
(value x))
> (lots-of-effect '(oh! darling))
(OH! DARLING)
(OH! DARLING)
(OH! DARLING)
DONE
> (lots-of-value '(oh! darling))
(OH! DARLING)
}
} % skip kludge
This example also demonstrates the second new idea,
\idx{sequencing}: Each of {\tt effect}, {\tt lots-of-effect},
and {\tt lots-of-value} contains more than one expression in
its body. When you invoke such a procedure, Scheme evaluates all
the expressions in the body, in order, and returns the value of the
last one.\footnt{In Chapter \defining, we said that the body of a
procedure was always one single expression. We lied. But as long
as you don't use any procedures with side effects, it doesn't do you
any good to evaluate more than one expression in a body.} This also
works in the body of a {\tt let}, which is really the body of a
procedure, and in each clause of a {\ttidx cond}.\footnt{For example:
{\zfprgex%
> (cond ((< 4 0)
(show '(how interesting))
(show '(4 is less than zero?))
#f)
((> 4 0)
(show '(more reasonable))
(show '(4 really is more than zero))
'value)
(else
(show '(you mean 4=0?))
#f))
(MORE REASONABLE)
(4 REALLY IS MORE THAN ZERO)
VALUE}}
When we invoked {\tt lots-of-value}, Scheme invoked {\tt value} three times;
it discarded the values returned by the first two invocations, and returned
the value from the third invocation. Similarly, when we invoked {\tt
lots-of-effect}, Scheme invoked {\tt effect} three times and returned the
value from the third invocation. But each invocation of {\tt effect} caused
its argument to be printed by invoking {\tt show}.
\subhd{The \ttpmb{Begin} Special Form}
\pagetag{\beg}
The {\tt lots-of-effect} procedure accomplished sequencing by having more
than one expression in its body. This works fine if the sequence of events
that you want to perform is the entire body of a procedure. But in {\tt
bottles} we wanted to include a sequence as one of the alternatives in an
{\tt if} construction. We couldn't just say
{\prgex%
(define (bottles n) ;; wrong
(if (= n 0)
'()
(verse n)
(bottles (- n 1))))
}
\noindent because {\tt if} must have exactly three arguments. Otherwise,
how would {\tt if} know whether we meant {\tt (verse~n)} to be the second
expression in the true case, or the first expression in the false case?
Instead, to turn the sequence of expressions into a single expression, we
use the \bkidx{special}{form} \ttidx{begin}. It takes any number of
arguments, evaluates them from left to right, and returns the value of the
last one.
{\prgex%
(define bottles n)
(if (= n 0)
'burp
(begin (verse n)
(bottles (- n 1)))))
}
\noindent (One way to think about sequences in procedure bodies is that
every procedure body has an invisible {\tt begin} surrounding it.)
\subhd{This Isn't Functional Programming}
Sequencing and side effects are radical departures from the idea of
\bkidx{functional}{programming}. In fact, we'd like to reserve the name {\it
function\/} for something that computes and returns one value, with no side
effects. ``Procedure'' is the general term for the thing that {\tt lambda}
returns---an embodiment of an algorithm. If the algorithm is the kind that
computes and returns a single value without side effects, then we say that
the procedure implements a function.\footnt{Sometimes people sloppily
say that the procedure {\it is\/} a function. In fact, you may hear people
be {\it really\/} sloppy and call a non-functional procedure a function!}
There is a certain kind of sequencing even in functional programming. If
you say
{\prgex%
(* (+ 3 4) (- 92 15))
}
\noindent it's clear that the addition has to happen before the
multiplication, because the result of the addition provides one of the
arguments to the multiplication. What's new in the sequential programming
style is the {\it emphasis\/} on sequence, and the fact that the expressions
in the sequence are {\it independent\/} instead of contributing values to
each other. In this multiplication problem, for example, we don't care
whether the addition happens before or after the subtraction. If the
addition and subtraction were in a sequence, we'd be using them for
independent purposes:
{\prgex%
(begin
(show (+ 3 4))
(show (- 92 15)))
}
\noindent This is what we mean by being independent. Neither expression
helps in computing the other. And the order matters because we can see
the order in which the results are printed.
\subhd{Not Moving to the Next Line}
Each invocation of {\tt show} prints a separate line. What if we
want a program that prints several things on the same line, like this:
{\prgex%
> (begin (show-addition 3 4)
(show-addition 6 8)
'done)
3+4=7
6+8=14
DONE
}
\noindent We use \ttidx{display}, which doesn't move to the next line after
printing its argument:
{\prgex%
(define (\ufun{show-addition} x y)
(display x)
(display '+)
(display y)
(display '=)
(show (+ x y)))
}
\noindent (The last one is a {\tt show} because we {\it do\/} want to start
a new line after it.)
What if you just want to print a blank line? You use \ttidx{newline}:
{\prgex%
(define (verse n)
(show (cons n '(bottles of beer on the wall)))
(show (cons n '(bottles of beer)))
(show '(if one of those bottles should happen to fall))
(show (cons (- n 1) '(bottles of beer on the wall)))
(newline)) ; replaces (show '())
}
In fact, {\tt show} isn't an official Scheme primitive; we wrote it
in terms of {\tt display} and {\tt newline}.
\subhd{Strings}
Throughout the book we've occasionally used strings, that is, words enclosed in
double-quote marks so that Scheme will permit the use of punctuation or other
unusual characters. Strings also preserve the case of letters, so they can
be used to beautify our song even more. Since {\it any\/} character can be
in a \idx{string}, including spaces, the easiest thing to do in this case is
to treat all the letters, spaces, and punctuation characters of each line of
the song as one long word. (If we wanted to be able to compute functions of
the individual words in each line, that wouldn't be such a good idea.)
{\prgex%
(define (\ufun{verse} n)
(display n)
(show " bottles of beer on the wall,")
(display n)
(show " bottles of beer.")
(show "If one of those bottles should happen to fall,")
(display (- n 1))
(show " bottles of beer on the wall.")
(newline))
}
{\medskipamount=4pt\prgexskipamount=8pt\prgexbaselineamount=10pt
{\prgex%
> (verse 6)
6 bottles of beer on the wall,
6 bottles of beer.
If one of those bottles should happen to fall,
5 bottles of beer on the wall.
#F ; or whatever is returned by (newline)
}
% \def\vb{\vispc\penalty 0{}}
% \def\vb{\_}
\def\vb{\ }
\noindent It's strange to think of ``{\tt\vb bottles\vb of\vb
beer\vb on\vb the\vb wall,}'' as a single word. But the rule is that
anything inside double quotes counts as a single word. It doesn't have to
be an English word.
\backskipsubhd{A Higher-Order Procedure for Sequencing}{8}
Sometimes we want to print each element of a list separately:
{\prgex%
(define (\ufun{show-list} lst)
(if (null? lst)
'done
(begin (show (car lst))
(show-list (cdr lst)))))
> (show-list '((dig a pony) (doctor robert) (for you blue)))
(DIG A PONY)
(DOCTOR ROBERT)
(FOR YOU BLUE)
DONE
}
Like other patterns of computation involving lists, this one can be
abstracted into a higher-order procedure. (We can't call it a
``higher-order function'' because this one is for computations with side
effects.) The procedure {\tt \ttidx{for-each}} is part of standard Scheme:
{\prgex%
> (for-each show '((mean mr mustard) (no reply) (tell me why)))
(MEAN MR MUSTARD)
(NO REPLY)
(TELL ME WHY)
}
\noindent The value returned by {\tt for-each} is unspecified.
Why couldn't we just use {\tt map} for this purpose? There are two reasons.
One is just an efficiency issue: {\tt Map} constructs a list containing the
values returned by each of its sub-computations; in this example, it would
be a list of three instances of the unspecified value returned by {\tt
show}. But we aren't going to use that list for anything, so there's no
point in constructing it. The second reason is more serious. In functional
programming, the order of evaluation of subexpressions is unspecified. For
example, when we evaluate the expression
{\prgex%
(- (+ 4 5) (* 6 7))
}
\noindent we don't know whether the addition or the multiplication happens
first. Similarly, the order in which {\tt map} computes the results for
each element is unspecified. That's okay as long as the ultimately returned
list of results is in the right order. But when we are using side effects,
we {\it do\/} care about the order of evaluation. In this case, we want
to make sure that the elements of the argument list are printed from left to
right. {\tt For-each} guarantees this ordering.
\backskipsubhd{Tic-Tac-Toe Revisited}{8}
We're working up toward playing a game of tic-tac-toe against the computer.
But as a first step, let's have the computer play against itself. What we
already have is {\tt ttt}, a {\it strategy\/} function:\ one that takes a
board position as argument (and also a letter {\tt x} or {\tt o}) and
returns the chosen next move. In order to play a game of tic-tac-toe, we
need two players; to make it more interesting, each should have its own
strategy. So we'll write another one, quickly, that just moves in the first
empty square it sees:
{\prgex%
(define (\ufun{stupid-ttt} position letter)
(location '_ position))
(define (\ufun{location} letter word)
(if (equal? letter (first word))
1
(+ 1 (location letter (bf word)))))
}
Now we can write a program that takes two strategies as arguments and
actually plays a game between them.
{\prgex%
(define (\ufun{play-ttt} x-strat o-strat)
(play-ttt-helper x-strat o-strat '_________ 'x))
(define (\ufun{play-ttt-helper} x-strat o-strat position whose-turn)
(cond ((already-won? position (opponent whose-turn))
(list (opponent whose-turn) 'wins!))
((tie-game? position) '(tie game))
(else (let ((square (if (equal? whose-turn 'x)
(x-strat position 'x)
(o-strat position 'o))))
(play-ttt-helper x-strat
o-strat
(add-move square whose-turn position)
(opponent whose-turn))))))
}
} % skip kludge
\noindent We use a helper procedure because we need to keep track of two
pieces of information besides the strategy procedures:\ the current board
position and whose turn it is ({\tt x} or {\tt o}). The helper procedure
is invoked recursively for each move. First it checks whether the game
is already over (won or tied).\footnt{You wrote the procedures {\tt
already-won?}\ and {\tt tie-game?}\ in Exercises \tttwon\ and \ttttied:
{\prgex%
(define (\ufun{already-won?} position who)
(member? (word who who who) (find-triples position)))
(define (\ufun{tie-game?} position)
(not (member? '_ position)))
}}
If not, the helper procedure invokes the current player's strategy procedure,
which returns the square number for the next move. For the recursive call,
the arguments are the same two strategies, the new position after the move,
and the letter for the other player.
We still need {\tt add-move}, the procedure that takes a square and an old
position as arguments and returns the new position.
{\prgex%
(define (\ufun{add-move} square letter position)
(if (= square 1)
(word letter (bf position))
(word (first position)
(add-move (- square 1) letter (bf position)))))
> (play-ttt ttt stupid-ttt)
(X WINS!)
> (play-ttt stupid-ttt ttt)
(O WINS!)
}
\subhd{Accepting User Input}
The work we did in the last section was purely functional. We didn't print
anything (except the ultimate return value, as always) and we didn't
have to read information from a human player, because there wasn't one.
You might expect that the structure of an {\it interactive\/} game program
would be very different, with a top-level procedure full of sequential
operations. But the fact is that we hardly have to change anything to turn
this into an interactive game. All we need is a new ``strategy'' procedure
that asks the user where to move, instead of computing a move based on
built-in rules.
{\prgex%
(define (\ufun{ask-user} position letter)
(print-position position)
(display letter)
(display "'s move: ")
(read))
(define (print-position position) ;; first version
(show position))
}
\noindent (Ultimately we're going to want a beautiful two-dimensional
display of the current position, but we don't want to get distracted by that
just now. That's why we've written a trivial temporary version.)
{\prgex%
> (play-ttt ttt ask-user)
____X____
O'S MOVE: \pmb{1}
O___XX___
O'S MOVE: \pmb{4}
O__OXXX__
O'S MOVE: \pmb{3}
OXOOXXX__
O'S MOVE: \pmb{8}
(TIE GAME)
}
\noindent What the user typed is just the single digits shown in boldface at
the ends of the lines.
What's new here is that we invoke the procedure \ttidx{read}. It waits for
you to type a Scheme expression, and returns that expression. Don't
be confused: {\tt Read} does {\it not\/} evaluate what you type. It
returns exactly the same expression that you type:
{\prgex%
(define (\ufun{echo})
(display "What? ")
(let ((expr (read)))
(if (equal? expr 'stop)
'okay
(begin
(show expr)
(echo)))))
}
{\medskipamount=2pt\prgexskipamount=7.5pt\prgexbaselineamount=10pt
{\prgex%
> (echo)
What? \pmb{hello}
HELLO
What? \pmb{(+ 2 3)}
(+ 2 3)
What? \pmb{(first (glass onion))}
(FIRST (GLASS ONION))
What? \pmb{stop}
OKAY
}
\backskipsubhd{Aesthetic Board Display}{9}
Here's our beautiful position printer:
{%\setbox2=\hbox{{\ninett +}}\catcode`+=\active\def+{\lower1pt\copy2}
{\prgex%
(define (\ufun{print-position} position)
(print-row (subword position 1 3))
(show "-+-+-")
(print-row (subword position 4 6))
(show "-+-+-")
(print-row (subword position 7 9))
(newline))
(define (\ufun{print-row} row)
(maybe-display (first row))
(display "|")
(maybe-display (first (bf row)))
(display "|")
(maybe-display (last row))
(newline))
(define (\ufun{maybe-display} letter)
(if (not (equal? letter '_))
(display letter)
(display " ")))
(define (\ufun{subword} wd start end)
((repeated bf (- start 1))
((repeated bl (- (count wd) end))
wd)))\pgfoot
\nobreak}
\nobreak\vfootnt{Alternate version:
\def\fpskip{\vskip 5pt\relax}
{\prgex\fprgexbaselineamount=9.5pt%
(define (subword wd start end)
(cond ((> start 1) (subword (bf wd) (- start 1) (- end 1)))
((< end (count wd)) (subword (bl wd) start end))
(else wd)))
}
\noindent You can take your choice, depending on which you think is easier,
recursion or higher-order functions.
}
} % skip kludge
Here's how it works:
{\prgex%
> (print-position '_x_oo__xx)
|X|
-+-+-
O|O|
-+-+-
|X|X
}
} %%%%%%%%% active + kludge %%%%%%%%%%%%%
\subhd{Reading and Writing Normal Text}
The {\tt read} procedure works fine as long as what you type looks like a
Lisp program. That is, it reads one expression at a time. In the
tic-tac-toe program the user types a single number, which is a Scheme
expression, so {\tt read} works fine. But what if we want to read more than
one word?
{\prgex%
(define (music-critic) ;; first version
(show "What's your favorite Beatles song?")
(let ((song (read)))
(show (se "I like" song "too."))))
> (music-critic)
What's your favorite Beatles song?
\pmb{She Loves You}
(I like SHE too.)
}
\noindent If the user had typed the song title in parentheses, then it would
have been a single Scheme expression and {\tt read} would have accepted it.
But we don't want the users of our program to have to be typing parentheses
all the time.
Scheme also lets you read one character at a time. This allows you to read
any text, with no constraints on its format. The disadvantage is that you
find yourself putting a lot of effort into minor details. We've provided a
procedure {\tt \ttidx{read-line}} that reads one line of input and returns a
sentence. The words in that sentence will contain any punctuation
characters that appear on the line, including parentheses, which are not
interpreted as sublist delimiters by {\tt read-line}. {\tt Read-line} also
preserves the case of letters.
{\prgex%
(define (music-critic) ;; second version
(read-line) ; See explanation on next page.
(show "What's your favorite Beatles song?")
(let ((song (read-line)))
(show (se "I like" song "too."))))
> (music-critic)
What's your favorite Beatles song?
\pmb{She Loves You}
(I like She Loves You too.)
}
\noindent Why do we call {\tt read-line} and ignore its result at the
beginning of {\tt music-critic}? It has to do with the interaction between
{\tt read-line} and {\tt read}. {\tt Read} treats what you type as a
sequence of Scheme expressions; each invocation of {\tt read} reads one of
them. {\tt Read} pays no attention to formatting details, such as several
consecutive spaces or line breaks. If, for example, you type several
expressions on the same line, it will take several invocations of {\tt read}
to read them all.
By contrast, {\tt read-line} treats what you type as a sequence of lines,
reading one line per invocation, so it does pay attention to line breaks.
Either of these ways to read input is sensible in itself, but if you mix
the two, by invoking {\tt read} sometimes and {\tt read-line} sometimes in
the same program, the results can be confusing. Suppose you type a line
containing an expression and your program invokes {\tt read} to read it.
Since there might have been another expression on the line, {\tt read}
doesn't advance to the next line until you ask for the next
expression. So if you now invoke {\tt read-line}, thinking that it will
read another line from the keyboard, it will instead return an empty list,
because what it sees is an empty line---what's left after {\tt read} uses up
the expression you typed.
You may be thinking, ``But {\tt music-critic} doesn't call {\tt read}!''
That's true, but Scheme itself used {\tt read} to read the expression that
you used to invoke {\tt music-critic}. So the first invocation of {\tt
read-line} is needed to skip over the spurious empty line.
Our solution works only if {\tt music-critic} is invoked directly at a
Scheme prompt. If {\tt music-critic} were a subprocedure of some larger
program that has already called {\tt read-line} before calling {\tt
music-critic}, the extra {\tt read-line} in {\tt music-critic} would really
read and ignore a useful line of text.
If you write a procedure using {\tt read-line} that will sometimes be called
directly and sometimes be used as a subprocedure, you can't include an extra
{\tt read-line} call in it. Instead, when you call your procedure directly
from the Scheme prompt, you must say
{\prgex%
> (begin (read-line) (my-procedure))
}
Another technical detail about {\tt read-line} is that since
it preserves the capitalization of words, its result may
include strings, which will be shown in quotation marks if you return the
value rather than {\tt show}ing it:
{\prgex%
(define (music-critic-return)
(read-line)
(show "What's your favorite Beatles song?")
(let ((song (read-line)))
(se "I like" song "too.")))
> (music-critic-return)
What's your favorite Beatles song?
\pmb{She Loves You}
("I like" "She" "Loves" "You" "too.")
}
We have also provided {\tt \ttidx{show-line},} which takes a sentence
as argument. It prints the sentence without surrounding parentheses,
followed by a newline. (Actually, it takes any list as argument; it prints
all the parentheses except for the outer ones.)
{\prgex%
(define (\ufun{music-critic})
(read-line)
(show "What's your favorite Beatles song?")
(let ((song (read-line)))
(show-line (se "I like" song "too."))))
> (music-critic)
What's your favorite Beatles song?
\pmb{She Loves You}
I like She Loves You too.
}
The difference between {\tt show} and {\tt show-line} isn't
crucial. It's just a matter of a pair of parentheses. The point is that
{\tt read-line} and {\tt show-line} go together. {\tt Read-line} reads a
bunch of disconnected words and combines them into a sentence. {\tt
Show-line} takes a sentence and prints it as if it were a bunch of
disconnected words. Later, when we read and write files in Chapter
\files, this ability to print in the same form in which we read will be
important.
\subhd{Formatted Text}
We've been concentrating on the use of sequential programming with explicit
\pagetag{\spformat}
printing instructions for the sake of conversational programs. Another
common application of sequential printing is to display tabular information,
such as columns of numbers. The difficulty is to get the numbers to line up
so that corresponding digits are in the same position, even when the numbers
have very widely separated values. The
\ttidx{align} function can be used to convert a number to a printable word
with a fixed number of positions before and after the decimal point:
{\prgex%
(define (square-root-table nums)
(if (null? nums)
'done
(begin (display (align (car nums) 7 1))
(show (align (sqrt (car nums)) 10 5))
(square-root-table (cdr nums)))))
> (square-root-table '(7 8 9 10 20 98 99 100 101 1234 56789))
7.0 2.64575
8.0 2.82843
9.0 3.00000
10.0 3.16228
20.0 4.47214
98.0 9.89949
99.0 9.94987
100.0 10.00000
101.0 10.04988
1234.0 35.12834
56789.0 238.30443
DONE
}
\noindent {\tt Align} takes three arguments. The first is the value to be
displayed. The second is the width of the column in which it will be
displayed; the returned value will be a word with that many characters in it.
The third argument is the number of digits that should be displayed to the
right of the decimal point. (If this number is zero, then no decimal point
will be displayed.) The width must be great enough to include all the
digits, as well as the decimal point and minus sign, if any.
As the program example above indicates, {\tt align} does not print
anything. It's a function that returns a value suitable for printing with
{\tt display} or {\tt show}.
What if the number is too big to fit in the available space?
{\prgex%
> (align 12345679 4 0)
"123+"
}
\noindent {\tt Align} returns a word containing the first few digits,
as many as fit, ending with a plus sign to indicate that part of the value
is missing.
{\tt Align} can also be used to include non-numeric text in columns. If
the first argument is not a number, then only two arguments are needed; the
second is the column width. In this case {\tt align} returns a word with
extra spaces at the right, if necessary, so that the argument word will
appear at the left in its column:
{\prgex%
(define (\ufun{name-table} names)
(if (null? names)
'done
(begin (display (align (cadar names) 11))
(show (caar names))
(name-table (cdr names)))))
> (name-table '((john lennon) (paul mccartney)
(george harrison) (ringo starr)))
LENNON JOHN
MCCARTNEY PAUL
HARRISON GEORGE
STARR RINGO
DONE
}
\noindent As with numbers, if a non-numeric word won't fit in the allowed
space, {\tt align} returns a partial word ending with a plus sign.
This {\tt align} function is not part of standard Scheme. Most programming
languages, including some versions of Scheme, offer much more elaborate
formatting capabilities with many alternate ways to represent both numbers
and general text. Our version is a minimal capability to show the flavor
and to meet the needs of projects in this book.
\subhd{Sequential Programming and Order of Evaluation}
Our expanded tic-tac-toe program includes both functional and sequential
parts. The program computes its strategy functionally but uses sequences
of commands to control the {\it \bkidx{user}{interface}\/} by alternately
printing information to the screen and reading information from the keyboard.
By adding sequential programming to our toolkit, we've increased our ability
to write interactive programs. But there is a cost that goes along with
this benefit: We now have to pay more attention to the order of events than
we did in purely functional programs.
The obvious concern about order of events is that sequences of {\tt show}
expressions must come in the order in which we want them to appear, and {\tt
read} expressions must fit into the sequence properly so that the user is
asked for the right information at the right time.
But there is another, less obvious issue about order of events. When the
evaluation of expressions can have side effects in addition to returning
values, the order of evaluation of argument subexpressions becomes important.
Here's an example to show what we mean. Suppose we type the expression
{\prgex%
(list (+ 3 4) (- 10 2))
}
\noindent The answer, of course, is {\tt (7~8)}. It doesn't matter whether
Scheme computes the seven first (left to right) or the eight first (right to
left). But here's a similar example in which it {\it does\/} matter:
{\prgex%
(define (\ufun{show-and-return} x)
(show x)
x)
> (list (show-and-return (+ 3 4)) (show-and-return (- 10 2)))
8
7
(7 8)
}
\noindent The value that's ultimately returned, in this example, is the same
as before. But the two numeric values that go into the list are also
printed separately, so we can see which is computed first. (We've shown
the case of right-to-left computation; your Scheme might be different.)
Suppose you want to make sure that the seven prints first, regardless of
which order your Scheme uses. You could do this:
{\prgex%
> (let ((left (show-and-return (+ 3 4))))
(list left (show-and-return (- 10 2))))
7
8
(7 8)
}
\noindent The expression in the body of a {\tt let} can't be evaluated until
the {\tt let} variables (such as {\tt left}) have had their values computed.
It's hard to imagine a practical use for the artificial {\tt
show-and-return} procedure, but a similar situation arises whenever we use
{\tt read}. Suppose we want to write a procedure to ask a person for his or
her full name, returning a two-element list containing the first and last
name. A natural mistake to make would be to write this procedure:
{\prgex%
(define (ask-for-name) ;; wrong
(show "Please type your first name, then your last name:")
(list (read) (read)))
> (ask-for-name)
Please type your first name, then your last name:
\pmb{John
Lennon}
(LENNON JOHN)
}
\noindent What went wrong? We happen to be using a version of Scheme that
evaluates argument subexpressions from right to left. Therefore, the word
{\tt John} was read by the rightmost call to {\tt read}, which provided the
second argument to {\tt list}. The best solution is to use {\tt let} as we
did above:
{\prgex%
(define (\ufun{ask-for-name})
(show "Please type your first name, then your last name:")
(let ((first-name (read)))
(list first-name (read))))
}
Even this example looks artificially simple, because of the two invocations
of {\tt read} that are visibly right next to each other in the erroneous
version. But look at {\tt play-ttt-helper}. The word {\tt read} doesn't
appear in its body at all. But when we invoke it using {\tt ask-user} as
the strategy procedure for {\tt x}, the expression
{\prgex%
(x-strat position 'x)
}
\noindent hides an invocation of {\tt read}. The structure of {\tt
play-ttt-helper} includes a {\tt let} that controls the timing of that {\tt
read}. (As it turns out, in this particular case we could have gotten away
with writing the program without {\tt let}. The hidden invocation of {\tt
read} is the only subexpression with a side effect, so there aren't two
effects that might get out of order. But we had to think carefully about
the program to be sure of that.)
\subhd{Pitfalls}
\pit It's easy to get confused about what is printed explicitly by your
\justidx{printing}
program and what is printed by Scheme's read-eval-print loop. Until now,
{\it all\/} printing was of the second kind. Here's an example that doesn't
do anything very interesting but will help make the point clear:
{\prgex%
(define (name)
(display "MATT ")
'wright)
> (name)
MATT WRIGHT
}
\noindent At first glance it looks as if putting the word ``Matt'' inside a
call to {\tt display} is unnecessary. After all, the word {\tt wright} is
printed even without using {\tt display}. But watch this:
{\prgex%
> (bf (name))
MATT RIGHT
}
\noindent Every time you invoke {\tt name}, whether or not as the entire
expression used at a Scheme prompt, the word {\tt MATT} is printed. But
the word {\tt wright} is {\it returned,\/} and may or may not be printed
depending on the context in which {\tt name} is invoked.
\pit A sequence of expressions returns the value of the {\it last\/}
expression. If that isn't what you want, you must remember the value you
want to return using {\tt let}:
{\prgex%
(let ((result (compute-this-first)))
(begin
(compute-this-second)
(compute-this-third)
result))
}
\pit Don't forget that the first call to {\tt read-line}, or any call to
{\tt read-line} after a call to {\tt read}, will probably read the empty
line that {\tt read} left behind.
\pit Sometimes you want to use what the user typed more than once in your
program. But don't forget that {\tt read} has an effect as well as a return
value. Don't try to read the same expression twice:
{\prgex%
(define (ask-question question) ;; wrong
(show question)
(cond ((equal? (read) 'yes) #t)
((equal? (read) 'no) #f)
(else (show "Please answer yes or no.")
(ask-question question))))
}
\noindent If the answer is {\tt yes}, this procedure will work fine. But if
not, the second invocation of {\tt read} will read a second expression, not
test the same expression again as intended. To avoid this problem, invoke
{\tt read} only once for each expression you want to read, and use {\tt let}
to remember the result:
{\prgex%
(define (\ufun{ask-question} question)
(show question)
(let ((answer (read)))
(cond ((equal? answer 'yes) #t)
((equal? answer 'no) #f)
(else (show "Please answer yes or no.")
(ask-question question)))))
}
\esubhd{Boring Exercises}
{\exercise
What happens when we evaluate the following expression? What is printed,
and what is the return value? Try to figure it out in your head before you
try it on the computer.
{\prgex%
(cond ((= 2 3) (show '(lady madonna)) '(i call your name))
((< 2 3) (show '(the night before)) '(hello little girl))
(else '(p.s. i love you)))
}}
\solution
{\tt (THE NIGHT BEFORE)} is printed.
{\tt (HELLO LITTLE GIRL)} is returned.
@
{\exercise
What does {\tt newline} return in your version of Scheme?
}
{\exercise
Define {\tt show} in terms of {\tt newline} and {\tt display}.
}
\solution
{\prgex%
(define (show stuff)
(display stuff)
(newline))
}
@
\esubhd{Real Exercises}
{\exercise
Write a program that carries on a conversation like the following example.
What the user types is in boldface.
{\prgex%
> \pmb{(\ufun{converse})}
Hello, I'm the computer. What's your name? \pmb{Brian Harvey}
Hi, Brian. How are you? \pmb{I'm fine.}
Glad to hear it.
}}
\solution
Here's a boring version that's glad to hear anything about how you're
doing. Naturally you could make it do a lot more if you were so inclined.
{\prgex%
(define (converse)
(read-line)
(display "Hello, I'm the computer. What's your name? ")
(let ((name (read-line)))
(display (word "Hi, " (first name) ". How are you? "))
(read-line)
(show "Glad to hear it.")))
}
@
{\exercise
Our {\tt name-table} procedure uses a fixed width for the column containing
the last names of the people in the argument list. Suppose that instead of
liking British-invasion music you are into late romantic Russian composers:
{\prgex%
> (name-table '((piotr tchaikovsky) (nicolay rimsky-korsakov)
(sergei rachmaninov) (modest musorgsky)))
}
\noindent Alternatively, perhaps you like jazz:
{\prgex%
> (name-table '((bill evans) (paul motian) (scott lefaro)))
}
\noindent Modify {\tt name-table} so that it figures out the longest last
name in its argument list, adds two for spaces, and uses that number as the
width of the first column.
}
\solution
{\prgex%
(define (name-table names)
(if (null? names)
'done
(nt-help names
(+ 2 (reduce max (map (lambda (nm) (count (last nm)))
names))))))
(define (nt-help names width)
(if (null? names)
'done
(begin (display (align (cadar names) width))
(show (caar names))
(nt-help (cdr names) width))))
}
The {\tt null?} test in {\tt name-table} is needed only for the case
in which the user gives an empty argument; the {\tt null?} test that
serves as the base case for the recursion is the one in {\tt nt-help}.
@
{\exercise
The procedure {\tt ask-user} isn't robust. What happens if you type
something that isn't a number, or isn't between 1 and 9? Modify it to check
that what the user types is a number between 1 and 9. If not, it should
print a message and ask the user to try again.
}
\solution
The changed parts of the procedure are shown here in boldface.
{\prgex%
(define (ask-user position letter)
(print-position position)
(display letter)
(display "'s move: ")
\pmb{(let ((answer (read)))}
\pmb{(if (and (integer? answer) (>= answer 1) (<= answer 9))}
\pmb{answer}
\pmb{(begin (show "That's not a move, silly!")}
\pmb{(ask-user position letter)))))}
}
@
{\exercise
Another problem with {\tt ask-user} is that it allows a user to request a
square that isn't free. If the user does this, what happens? Fix {\tt
ask-user} to ensure that this can't happen.
}
\solution
If the user asks for a square that's already taken, the square will
be reassigned to the user. The following solution assumes that the
previous exercise is also included.
The changed parts of the procedure are shown here in boldface.
{\prgex%
(define (ask-user position letter)
(print-position position)
(display letter)
(display "'s move: ")
(let ((answer (read)))
\pmb{(cond ((not} (and (integer? answer) (>= answer 1) (<= answer 9)))
(show "That's not a move, silly!")
(ask-user position letter))
\pmb{((not (equal? '_ (item answer position)))}
\pmb{(show "That square is occupied.")}
\pmb{(ask-user position letter))}
\pmb{(else} answer))))
}
@
{\exercise
At the end of the game, if the computer wins or ties, you never find out
which square it chose for its final move. Modify the program to correct
this. (Notice that this exercise requires you to make {\tt play-ttt-helper}
non-functional.)
}
\solution
The changed parts of the procedure are shown here in boldface.
{\prgex%
(define (play-ttt-helper x-strat o-strat position whose-turn)
(cond ((already-won? position (opponent whose-turn))
\pmb{(print-position position)}
(list (opponent whose-turn) 'wins!))
((tie-game? position)
\pmb{(print-position position)}
'(tie game))
(else (let ((square (if (equal? whose-turn 'x)
(x-strat position 'x)
(o-strat position 'o))))
(play-ttt-helper x-strat
o-strat
(add-move square whose-turn position)
(opponent whose-turn))))))
}
@
{\exercise
The way we invoke the game program isn't very user-friendly. Write a
procedure {\tt game} that asks you whether you wish to play {\tt x} or {\tt
o}, then starts a game. (By definition, {\tt x} plays first.) Then write a
procedure {\tt games} that allows you to keep playing repeatedly. It
can ask ``do you want to play again?''\ after each game. (Make sure that
the outcome of each game is still reported, and that the user can choose
whether to play {\tt x} or {\tt o} before each game.)
}
\solution
{\prgex%
(define (game)
(display "Do you want to play X or O? ")
(let ((letter (read)))
(cond ((equal? letter 'x)
(play-ttt ask-user ttt))
((equal? letter 'o)
(play-ttt ttt ask-user))
(else (show "Please type X or O!")
(game)))))
(define (games)
(show (game))
(display "Do you want to play again (Y or N)? ")
(if (another?)
(games)
"Thank you for playing, have a day."))
(define (another?)
(let ((letter (read)))
(cond ((equal? letter 'y) #t)
((equal? letter 'n) #f)
(else (show "C'mon, Y or N!")
(another?)))))
}
{\tt Game} and {\tt games} both ask a question, and both include a
check for invalid answers. But {\tt game} is able to repeat the
question itself, if the answer was invalid, whereas {\tt games}
uses a helper procedure {\tt another?} to ask the question. The
reason for this difference is that {\tt games} plays a game before
asking its question, whereas the question is the first thing in
{\tt game}. If {\tt games} were written as a single procedure,
an invalid answer would result in playing another game before
asking again.
@
\bye