A Scheme program consists of a sequence of expressions, definitions, and syntax definitions. Expressions are described in chapter section Expressions; definitions and syntax definitions are the subject of the rest of the present chapter.
Programs are typically stored in files or entered interactively to a running Scheme system, although other paradigms are possible; questions of user interface lie outside the scope of this report. (Indeed, Scheme would still be useful as a notation for expressing computational methods even in the absence of a mechanical implementation.)
Definitions and syntax definitions occurring at the top level of a program can be interpreted declaratively. They cause bindings to be created in the top level environment or modify the value of existing top-level bindings. Expressions occurring at the top level of a program are interpreted imperatively; they are executed in order when the program is invoked or loaded, and typically perform some kind of initialization.
At the top level of a program (begin <form1> ...) is
equivalent to the sequence of expressions, definitions, and syntax definitions
that form the body of the
Definitions are valid in some, but not all, contexts where expressions are allowed. They are valid only at the top level of a <program> and at the beginning of a <body>.
A definition should have one of the following forms:
(define <variable> (lambda (<formals>) <body>)).
(define <variable> (lambda <formal> <body>)).
At the top level of a program, a definition
(define <variable> <expression>)
has essentially the same effect as the assignment expression
(set! <variable> <expression>)
if <variable> is bound. If <variable> is not bound, however, then the definition will bind <variable> to a new location before performing the assignment, whereas it would be an error to perform a `set!' on an unbound variable.
(define add3 (lambda (x) (+ x 3))) (add3 3) ==> 6 (define first car) (first '(1 2)) ==> 1
Some implementations of Scheme use an initial environment in which all possible variables are bound to locations, most of which contain undefined values. Top level definitions in such an implementation are truly equivalent to assignments.
Definitions may occur at the
beginning of a <body> (that is, the body of a
expression or that of a definition of an appropriate form).
Such definitions are known as internal definitions as opposed to the top level definitions described above.
The variable defined by an internal definition is local to the
<body>. That is, <variable> is bound rather than assigned,
and the region of the binding is the entire <body>. For example,
(let ((x 5)) (define foo (lambda (y) (bar x y))) (define bar (lambda (a b) (+ (* a b) a))) (foo (+ x 3))) ==> 45
A <body> containing internal definitions can always be converted into a completely equivalent `letrec' expression. For example, the `let' expression in the above example is equivalent to
(let ((x 5)) (letrec ((foo (lambda (y) (bar x y))) (bar (lambda (a b) (+ (* a b) a)))) (foo (+ x 3))))
Just as for the equivalent `letrec' expression, it must be possible to evaluate each <expression> of every internal definition in a <body> without assigning or referring to the value of any <variable> being defined.
Wherever an internal definition may occur
(begin <definition1> ...)
is equivalent to the sequence of definitions
that form the body of the
Syntax definitions are valid only at the top level of a <program>.
They have the following form:
(define-syntax <keyword> <transformer spec>)
<Keyword> is an identifier, and
the <transformer spec> should be an instance of
The top-level syntactic environment is extended by binding the
<keyword> to the specified transformer.
There is no `define-syntax' analogue of internal definitions.
Although macros may expand into definitions and syntax definitions in any context that permits them, it is an error for a definition or syntax definition to shadow a syntactic keyword whose meaning is needed to determine whether some form in the group of forms that contains the shadowing definition is in fact a definition, or, for internal definitions, is needed to determine the boundary between the group and the expressions that follow the group. For example, the following are errors:
(define define 3) (begin (define begin list)) (let-syntax ((foo (syntax-rules () ((foo (proc args ...) body ...) (define proc (lambda (args ...) body ...)))))) (let ((x 3)) (foo (plus x y) (+ x y)) (define foo x) (plus foo x)))
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