The overall specification of how the interpreter evaluates a
combination remains the same as when we first introduced it in
section ![[*]](../image/cross_ref_motif.gif)
:
- To evaluate a combination:
- 1.Evaluate the subexpressions of the
combination.
![[*]](../image/foot_motif.gif)
- 2.Apply the value of the operator subexpression to the values of the operand subexpressions.
The environment model of evaluation replaces the substitution model in specifying what it means to apply a compound procedure to arguments.
In the environment model of evaluation, a procedure is always a pair consisting of some code and a pointer to an environment. Procedures are created in one way only: by evaluating a lambda expression. This produces a procedure whose code is obtained from the text of the lambda expression and whose environment is the environment in which the lambda expression was evaluated to produce the procedure. For example, consider the procedure definition
(define (square x) (* x x))evaluated in the global environment. The procedure definition syntax is just syntactic sugar for an underlying implicit lambda expression. It would have been equivalent to have used
(define square (lambda (x) (* x x)))which evaluates (lambda (x) (* x x)) and binds square to the resulting value, all in the global environment.
Figure shows the result of evaluating this
define expression. The procedure object is a pair whose code
specifies that the procedure has one formal parameter, namely x,
and a procedure body (* x x). The environment part of the
procedure is a pointer to the global environment, since that is the
environment in which the lambda expression was evaluated to
produce the procedure. A new binding, which associates the procedure
object with the symbol square, has been added to the global
frame. In general, define creates definitions by adding
bindings to frames.
Now that we have seen how procedures are created, we can describe how procedures are applied. The environment model specifies: To apply a procedure to arguments, create a new environment containing a frame that binds the parameters to the values of the arguments. The enclosing environment of this frame is the environment specified by the procedure. Now, within this new environment, evaluate the procedure body.
To show how this rule is followed, figure
illustrates the environment structure created by evaluating the
expression (square 5) in the global environment, where
square is the procedure generated in
figure . Applying the procedure results in
the creation of a new environment, labeled E1 in the figure, that
begins with a frame in which x, the formal parameter for the
procedure, is bound to the argument 5. The pointer leading upward
from this frame shows that the frame's enclosing environment is the
global environment. The global environment is chosen here, because
this is the environment that is indicated as part of the square
procedure object. Within E1, we evaluate the body of the procedure,
(* x x). Since the value of x in E1 is 5, the result is
(* 5 5), or 25.
The environment model of procedure application can be summarized by two rules:
- A procedure object is applied to a set of arguments by
constructing a frame, binding the formal parameters of the procedure
to the arguments of the call, and then evaluating the body of
the procedure in the context of the new environment constructed. The
new frame has as its enclosing environment the environment part of the
procedure object being applied.
- A procedure is created by evaluating a lambda expression relative to a given environment. The resulting procedure object is a pair consisting of the text of the lambda expression and a pointer to the environment in which the procedure was created.
We also specify that defining a symbol using define creates a
binding in the current environment frame and assigns to the symbol the
indicated value. Finally, we specify the behavior of
set!, the operation that forced us to introduce the environment
model in the first place. Evaluating the expression (set!
variable value) in some environment locates the binding of
the variable in the environment and changes that binding to indicate
the new value. That is, one finds the first frame in the environment
that contains a binding for the variable and modifies that frame. If
the variable is unbound in the environment, then set! signals
an error.
These evaluation rules, though considerably more complex than the substitution model, are still reasonably straightforward. Moreover, the evaluation model, though abstract, provides a correct description of how the interpreter evaluates expressions. In chapter 4 we shall see how this model can serve as a blueprint for implementing a working interpreter. The following sections elaborate the details of the model by analyzing some illustrative programs.