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One easy way to get started at programming is to examine some typical interactions with an interpreter for the Scheme dialect of Lisp. Imagine that you are sitting at a computer terminal. You type an expression, and the interpreter responds by displaying the result of its evaluating that expression.
One kind of primitive expression you might type is a number. (More precisely, the expression that you type consists of the numerals that represent the number in base 10.) If you present Lisp with a number
486the interpreter will respond by printing
![[*]](data:image/svg+xml,<svg xmlns="http://www.w3.org/2000/svg" width="15" height="15"><rect fill-opacity="0"/></svg>)
486
Expressions representing numbers may be combined with an expression representing a primitive procedure (such as + or *) to form a compound expression that represents the application of the procedure to those numbers. For example:
(+ 137 349) 486 (- 1000 334) 666 (* 5 99) 495 (/ 10 5) 2 (+ 2.7 10) 12.7
Expressions such as these, formed by delimiting a list of expressions within parentheses in order to denote procedure application, are called combinations. The leftmost element in the list is called the operator, and the other elements are called operands. The value of a combination is obtained by applying the procedure specified by the operator to the arguments that are the values of the operands.
The convention of placing the operator to the left of the operands is known as prefix notation, and it may be somewhat confusing at first because it departs significantly from the customary mathematical convention. Prefix notation has several advantages, however. One of them is that it can accommodate procedures that may take an arbitrary number of arguments, as in the following examples:
(+ 21 35 12 7) 75No ambiguity can arise, because the operator is always the leftmost element and the entire combination is delimited by the parentheses.(* 25 4 12) 1200
A second advantage of prefix notation is that it extends in a straightforward way to allow combinations to be nested, that is, to have combinations whose elements are themselves combinations:
(+ (* 3 5) (- 10 6)) 19
There is no limit (in principle) to the depth of such nesting and to the overall complexity of the expressions that the Lisp interpreter can evaluate. It is we humans who get confused by still relatively simple expressions such as
(+ (* 3 (+ (* 2 4) (+ 3 5))) (+ (- 10 7) 6))which the interpreter would readily evaluate to be 57. We can help ourselves by writing such an expression in the form
(+ (* 3
(+ (* 2 4)
(+ 3 5)))
(+ (- 10 7)
6))
following a formatting convention known as
pretty-printing, in
which each long combination is written so that the operands are
aligned vertically. The resulting indentations display clearly the
structure of the expression.
Even with complex expressions, the interpreter always operates in the
same basic cycle: It reads an expression from the terminal,
evaluates the expression, and prints the result.
This mode of operation is often expressed by saying that the
interpreter runs in a
read-eval-print loop.
Observe in particular that it is not necessary to explicitly
instruct the interpreter to print the value of the expression.