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Throughout most of this book we're going to be using a technique called functional programming. We can't give a complete definition of this term yet, but in this chapter we introduce the building block of functional programming, the function.
Basically we mean by "function" the same thing that your high school algebra teacher meant, except that our functions don't necessarily relate to numbers. But the essential idea is just like the kind of function described by f(x)=6x−2. In that example, f is the name of a function; that function takes an argument called x, which is a number, and returns some other number.
In this chapter you are going to use the computer to explore functions, but you are not going to use the standard Scheme notation as in the rest of the book. That's because, in this chapter, we want to separate the idea of functions from the complexities of programming language notation. For example, real Scheme notation lets you write expressions that involve more than one function, but in this chapter you can only use one at a time.
To get into this chapter's special computer interface, first start running Scheme as you did in the first chapter, then type
(load "functions.scm")
to tell Scheme to read the program you'll be using. (If you have
trouble loading the program, look in Appendix A for further information
about load
.) Then, to start the program, type
(functions)
You'll then be able to carry out interactions like the
following.[1] In the text below we've
printed what you type in boldface
and what the computer types in lightface
printing:
Function: + Argument: 3 Argument: 5 The result is: 8 Function: sqrt Argument: 144 The result is: 12
As you can see, different functions can have different numbers of arguments. In these examples we added two numbers, and we took the square root of one number. However, every function gives exactly one result each time we use it.
To leave the functions
program, type exit
when it asks for a
function.
Experiment with these arithmetic functions: +
, -
, *
, /
, sqrt
, quotient
, remainder
, random
, round
, max
, and expt
.
Try different kinds of numbers, including integers and numbers with decimal
fractions. What if you try to divide by zero? Throughout this chapter we
are going to let you experiment with functions rather than just give you a
long, boring list of how each one works. (The boring list is available for
reference on page funlist.)
Try these:
Function: / Argument: 1 Argument: 987654321987654321 Function: remainder Argument: 12 Argument: -5 Function: round Argument: 17.5
These are just a few suggestions. Be creative; don't just type in our examples.
Not all Scheme functions deal with numbers. A broader category of
argument is the word, including numbers but also
including English words like spaghetti
or xylophone
.
Even a meaningless sequence of letters and digits such as glo87rp
is considered a word.[2] Try these
functions that accept words as arguments: first
, butfirst
, last
, butlast
, word
, and count
.
What happens if you use a number as the argument to one of these?
Function: butfirst Argument: a Function: count Argument: 765432
So far most of our functions fall into one of two categories: the
arithmetic functions, which require numbers as arguments and return a number
as the result; and the word functions, which accept words as
arguments and return a word as the result. The one exception we've seen is
count
. What kind of argument does count
accept? What kind of
value does it return? The technical term for "a kind of data" is a
type.
In principle you could think of almost anything as a type, such as "numbers
that contain the digit 7
." Such ad hoc types are legitimate
and sometimes useful, but there are also official types that Scheme knows
about. Types can overlap; for example, numbers are also considered words.
Function: word Argument: 3.14 Argument: 1592654 Function: + Argument: 6 Argument: seven
The technical term for "the things that a function accepts as an argument"
is the domain of the function. The name for "the things that
a function returns" is its range. So the domain of count
is words, and the range of count
is numbers (in fact,
nonnegative integers). This example shows that the range may not be exactly
one of our standard data types; there is no "nonnegative integer" type in
Scheme.
How do you talk about the domain and range of a function? You could say, for
example, "The cos
function has numbers as its domain and numbers
between −1 and 1 as its range." Or, informally, you may also say "Cos
takes a number as its argument and returns a number between −1 and
1."[3]
For functions of two or more arguments, the language is a little less
straightforward. The informal version still works: "Remainder
takes
two integers as arguments and returns an integer." But you can't say "The
domain of remainder
is two integers," because the domain of a
function is the set of all possible arguments, not just a statement
about the characteristics of legal arguments.[4]
(By the way, we're making certain simplifications in this chapter. For
example, Scheme's +
function can actually accept any number of
arguments, not just two. But we don't want to go into all the bells and
whistles at once, so we'll start with adding two numbers at a time.)
Here are examples that illustrate the domains of some functions:
Function: expt Argument: -3 Argument: .5 Function: expt Argument: -3 Argument: -3 Function: remainder Argument: 5 Argument: 0
We're going to introduce more data types, and more functions that include those types in their domain or range. The next type is the sentence: a bunch of words enclosed in parentheses, such as
(all you need is love)
(Don't include any punctuation characters within the sentence.)
Many of the functions that accept words in their domain will also accept
sentences. There is also a function sentence
that accepts words and
sentences. Try examples like butfirst
of a sentence.
Function: sentence Argument: (when i get) Argument: home Function: butfirst Argument: (yer blues) Function: butlast Argument: ()
Other important functions are used to ask yes-or-no questions. That is, the
range of these functions contains only two values, one meaning "true" and
the other meaning "false." Try the numeric comparisons =
, <
, >
, <=
, and >=
, and the functions equal?
and member?
that work on words and sentences. (The
question mark is part of the name of the function.) There are also
functions and
, or
,
and not
whose domain and range are both
true-false values. The two values "true" and "false" are called Booleans, named after George Boole (1815-1864), who
developed the formal tools used for true-false values in mathematics.
What good are these true-false values? Often a program must choose between
two options: If the number is positive, do this; if negative, do that.
Scheme has functions to make such choices based on true-false values. For
now, you can experiment with the if
function. Its first argument must
be true or false; the others can be anything.
So far our data types include numbers, words, sentences, and Booleans. Scheme has several more data types, but for now we'll just consider one more. A function can be used as data. Here's an example:
Function: number-of-arguments Argument: equal? The result is: 2
The range of number-of-arguments
is nonnegative integers. But
its domain is functions. For example, try using it as an argument to
itself!
If you've used other computer programming languages, it may seem strange to use a function—that is, a part of a computer program—as data. Most languages make a sharp distinction between program and data. We'll soon see that the ability to treat functions as data helps make Scheme programming very powerful and convenient.
Try these examples:
Function: every Argument: first Argument: (the long and winding road) Function: keep Argument: vowel? Argument: constantinople
Think carefully about these. You aren't applying the function
first
to the sentence (the long and winding road)
; you're applying
the function every
to a function and a sentence.
Other functions that can be used with keep
include even?
and
odd?
, whose domains are the integers, and number?
, whose domain
is everything.
If you've been reading the book but not trying things out on the computer as you go along, get to work! Spend some time getting used to these ideas and thinking about them. When you're done, read ahead.
The idea of function is at the heart of both mathematics and computer science. For example, when mathematicians want to think very formally about the system of numbers, they use functions to create the integers. They say, let's suppose we have one number, called zero; then let's suppose we have the function given by f(x)=x+1. By applying that function repeatedly, we can create 1=f(0), then 2=f(1), and so on.
Functions are important in computer science because they give us a way to think about process—in simple English, a way to think about something happening, something changing. A function embodies a transformation of information, taking in something we know and returning something we didn't know. That's what computers do: They transform information to produce new results.
A lot of the mathematics taught in school is about numbers, but
we've seen that functions don't have to be about numbers. We've
used functions of words and sentences, such as first
, and even
functions of functions, such as keep
. You can imagine functions
that transform information of any kind at all, such as the function
French(window)=fenêtre or the function
capital(California)=Sacramento.
You've done a lot of thinking about the domain and range
of functions. You can add two numbers, but it doesn't make sense to add
two words that aren't numbers. Some two-argument functions have complicated
domains because the acceptable values for one argument depend on the
specific value used for the other one. (The function expt
is an
example; make sure you've tried both positive and negative numbers, and
fractional as well as whole-number powers.)
Part of the definition of a function is that you always get the same answer whenever you call a function with the same argument(s). The value returned by the function, in other words, shouldn't change regardless of anything else you may have computed meanwhile. One of the "functions" you've explored in this chapter isn't a real function according to this rule; which one? The rule may seem too restrictive, and indeed it's often convenient to use the name "function" loosely for processes that can give different results in different circumstances. But we'll see that sometimes it's important to stick with the strict definition and refrain from using processes that aren't truly functions.
We've hinted at two different ways of thinking about functions. The first
is called function as process. Here, a function is a rule that
tells us how to transform some information into some other information. The
function is just a rule, not a thing in its own right. The actual
"things" are the words or numbers or whatever the function manipulates.
The second way of thinking is called function as object. In
this view, a function is a perfectly good "thing" in itself. We can use a
function as an argument to another function, for example. Research with
college math students shows that this second idea is hard for
most people, but it's worth the effort because you'll see that higher-order functions (functions of functions) like keep
and every
can make programs much easier to write.
As a homey analogy, think about a carrot peeler. If we focus our attention
on the carrots—which are, after all, what we want to eat—then the peeler
just represents a process. We are peeling carrots. We are applying the
function peel
to carrots. It's the carrot that counts. But we can
also think about the peeler as a thing in its own right, when we clean it,
or worry about whether its blade is sharp enough.
The big idea that we haven't explored in this chapter (although we used it a lot in Chapter 1) is the composition of functions: using the result from one function as an argument to another function. It's a crucial idea; we write large programs by defining a bunch of small functions and then composing them with each other to produce the desired result. We'll start doing that in the next chapter, where we return to real Scheme notation.
Use the functions
program for all these exercises.
2.1 In each line of the following table we've left out one piece of information. Fill in the missing details.
function | arg 1 | arg 2 | result |
---|---|---|---|
word | now | here
| |
sentence | now | here
| |
first | blackbird | none
| |
first | (blackbird) | none
| |
3 | 4 | 7
| |
every | (thank you girl) | (hank ou irl)
| |
member? | e | aardvark
| |
member? | the | #t
| |
keep | vowel? | (i will)
| |
keep | vowel? | eieio [5]
| |
last | () | none | |
last | (honey pie) | (y e)
| |
taxman | aa
|
2.2
What is the domain of the vowel?
function?
2.3 One of the functions you can use is called appearances
. Experiment
with it, and then describe fully its domain and range, and what it does.
(Make sure to try lots of cases. Hint: Think about its name.)
2.4 One of the functions you can use is called item
. Experiment
with it, and then describe fully its domain and range, and what it does.
The following exercises ask for functions that meet certain criteria. For
your convenience, here are the functions in this chapter: +
, -
, /
, <=
, <
, =
, >=
, >
, and
, appearances
, butfirst
, butlast
, cos
, count
, equal?
, every
, even?
, expt
, first
,
if
, item
, keep
, last
, max
, member?
, not
, number?
, number-of-arguments
, odd?
, or
, quotient
, random
, remainder
, round
, sentence
, sqrt
, vowel?
, and word
.
2.5 List the one-argument functions in this chapter for which the type of the return value is always different from the type of the argument.
2.6 List the one-argument functions in this chapter for which the type of the return value is sometimes different from the type of the argument.
2.7 Mathematicians sometimes use the term "operator" to mean a function of two arguments, both of the same type, that returns a result of the same type. Which of the functions you've seen in this chapter satisfy that definition?
2.8 An operator f is commutative if
f(a,b)=f(b,a) for all possible arguments A and B. For example,
+
is commutative, but word
isn't. Which of the
operators from Exercise 2.7 are commutative?
2.9 An operator f is associative if
f(f(a,b),c)=f(a,f(f(b,c)) for all possible arguments A, B, and C.
For example, *
is associative, but not /
.
Which of the operators from Exercise 2.7 are associative?
(functions)
, just press the Return or Enter key
again. Tell your instructor to read
Appendix A to see how to fix this.[2] Certain punctuation characters can also be used in words, but let's defer the details until you've gotten to know the word functions with simpler examples.
[3] Unless your version of Scheme has complex numbers.
[4] Real mathematicians
say, "The domain of remainder
is the Cartesian cross product of the
integers and the integers." In order to avoid that mouthful, we'll just use
the informal wording.
[5] Yes, there is an English word. It has to do with astronomy.
Brian Harvey,
bh@cs.berkeley.edu