In this section we will implement a normal-order language that is
the same as Scheme except that compound procedures are non-strict
in each argument. Primitive procedures will still be strict.
It is not difficult to modify the evaluator of
section ![[*]](../image/cross_ref_motif.gif)
so that the language it interprets behaves
this way. Almost all the required changes center around procedure
application.
The basic idea is that, when applying a procedure, the interpreter
must determine which arguments are to be
evaluated and which are to be
delayed. The delayed arguments are not
evaluated; instead, they are transformed into objects called
thunks.
![[*]](../image/foot_motif.gif)
The thunk must contain the information required to produce the value
of the argument when it is needed, as if it had been evaluated at
the time of the application. Thus, the thunk must contain the
argument expression and the environment in
which the procedure application is being evaluated.
The process of evaluating the expression in a thunk is called forcing.
In general, a thunk will be forced only when its value is needed:
when it is passed to a primitive procedure that
will use the value of the thunk; when it is the
value of a predicate of a conditional; and when it
is the value of an operator that is about to be applied as a procedure.
One design choice we have available is whether or not to
memoize thunks, as we did with delayed objects in
section . With memoization, the first time a
thunk is forced, it stores the value that is computed. Subsequent
forcings simply return the stored value without repeating the
computation. We'll make our interpreter memoize, because this is
more efficient for many applications. There are tricky
considerations here, however.
Modifying the evaluator
The main difference between the lazy evaluator and the one in
section is in the handling of procedure
applications in eval and apply.
The application? clause of eval becomes
((application? exp)
(apply (actual-value (operator exp) env)
(operands exp)
env))
This is almost the same as the application? clause of eval
in section . For lazy evaluation, however,
we call apply with the operand expressions, rather than the
arguments produced by evaluating them. Since we will need the environment to
construct thunks if the arguments are to be delayed, we must pass this as well.
We still evaluate the
operator, because apply needs the actual procedure to be applied
in order to dispatch on its type (primitive versus compound) and apply it.
Whenever we need the actual value of an expression, we use
(define (actual-value exp env) (force-it (eval exp env)))instead of just eval, so that if the expression's value is a thunk, it will be forced.
Our new version of apply is also almost the same as the
version in section . The difference is
that eval has passed in unevaluated operand expressions:
For primitive procedures (which are strict), we evaluate all the
arguments before applying the primitive;
for compound procedures (which are non-strict) we delay all the
arguments before applying the procedure.
(define (apply procedure arguments env)
(cond ((primitive-procedure? procedure)
(apply-primitive-procedure
procedure
(list-of-arg-values arguments env))) ; changed
((compound-procedure? procedure)
(eval-sequence
(procedure-body procedure)
(extend-environment
(procedure-parameters procedure)
(list-of-delayed-args arguments env) ; changed
(procedure-environment procedure))))
(else
(error
"Unknown procedure type - APPLY" procedure))))
The procedures that process the arguments are just like
list-of-values from section , except that
list-of-delayed-args delays the arguments instead of evaluating
them, and list-of-arg-values uses actual-value instead
of eval:
(define (list-of-arg-values exps env)
(if (no-operands? exps)
'()
(cons (actual-value (first-operand exps) env)
(list-of-arg-values (rest-operands exps)
env))))
(define (list-of-delayed-args exps env)
(if (no-operands? exps)
'()
(cons (delay-it (first-operand exps) env)
(list-of-delayed-args (rest-operands exps)
env))))
The other place we must change the evaluator is in the handling of if, where we must use actual-value instead of eval to get the value of the predicate expression before testing whether it is true or false:
(define (eval-if exp env)
(if (true? (actual-value (if-predicate exp) env))
(eval (if-consequent exp) env)
(eval (if-alternative exp) env)))
Finally, we must change the driver-loop
procedure (section ) to use actual-value instead
of eval, so that if a delayed value
is propagated back to the read-eval-print loop, it will be forced
before being printed. We also change the prompts to indicate that
this is the lazy evaluator:
(define input-prompt ";;; L-Eval input:")
(define output-prompt ";;; L-Eval value:")
(define (driver-loop)
(prompt-for-input input-prompt)
(let ((input (read)))
(let ((output
(actual-value input the-global-environment)))
(announce-output output-prompt)
(user-print output)))
(driver-loop))
With these changes made, we can start the evaluator and test it. The
successful evaluation of the try expression discussed in
section indicates that the interpreter is
performing lazy evaluation:
(define the-global-environment (setup-environment)) (driver-loop) ;;; L-Eval input: (define (try a b) (if (= a 0) 1 b)) ;;; L-Eval value: ok ;;; L-Eval input: (try 0 (/ 1 0)) ;;; L-Eval value: 1
Representing thunks
Our evaluator must arrange to create thunks when procedures are applied to arguments and to force these thunks later. A thunk must package an expression together with the environment, so that the argument can be produced later. To force the thunk, we simply extract the expression and environment from the thunk and evaluate the expression in the environment. We use actual-value rather than eval so that in case the value of the expression is itself a thunk, we will force that, and so on, until we reach something that is not a thunk:
(define (force-it obj)
(if (thunk? obj)
(actual-value (thunk-exp obj) (thunk-env obj))
obj))
One easy way to package an expression with an environment is to make a list containing the expression and the environment. Thus, we create a thunk as follows:
(define (delay-it exp env) (list 'thunk exp env))(define (thunk? obj) (tagged-list? obj 'thunk))
(define (thunk-exp thunk) (cadr thunk))
(define (thunk-env thunk) (caddr thunk))
Actually, what we want for our interpreter is not quite this, but
rather thunks that have been memoized.
When a thunk is forced, we will turn it into an evaluated thunk
by replacing the stored expression with its value and
changing the thunk tag so that it can be recognized as
already evaluated.
(define (evaluated-thunk? obj) (tagged-list? obj 'evaluated-thunk))Notice that the same delay-it procedure works both with and without memoization.(define (thunk-value evaluated-thunk) (cadr evaluated-thunk)) (define (force-it obj) (cond ((thunk? obj) (let ((result (actual-value (thunk-exp obj) (thunk-env obj)))) (set-car! obj 'evaluated-thunk) (set-car! (cdr obj) result) ; replace exp with its value (set-cdr! (cdr obj) '()) ; forget unneeded env result)) ((evaluated-thunk? obj) (thunk-value obj)) (else obj)))
Exercise. Suppose we type in the following definitions to the lazy evaluator:
(define count 0) (define (id x) (set! count (+ count 1)) x)Give the missing values in the following sequence of interactions, and explain your answers.
(define w (id (id 10))) ;;; L-Eval input: count ;;; L-Eval value: response ;;; L-Eval input: w ;;; L-Eval value: response ;;; L-Eval input: count ;;; L-Eval value: response
Exercise. Eval uses actual-value rather than eval to evaluate the operator before passing it to apply, in order to force the value of the operator. Give an example that demonstrates the need for this forcing.
Exercise.
Exhibit a program that you would expect to run much more slowly
without memoization than with memoization. Also, consider the
following interaction, where the id procedure is defined as in
exercise and count starts at 0:
(define (square x) (* x x)) ;;; L-Eval input: (square (id 10)) ;;; L-Eval value: response ;;; L-Eval input: count ;;; L-Eval value: responseGive the responses both when the evaluator memoizes and when it does not.
Exercise.
Cy D. Fect, a reformed C programmer, is worried that some side effects
may never take place, because the lazy evaluator doesn't force the
expressions in a sequence.
Since the value of an expression in a sequence other than the last one
is not used (the expression is there only for its effect, such as
assigning to a variable or printing), there can be no subsequent use
of this value (e.g., as an argument to a primitive procedure) that
will cause it to be forced. Cy thus thinks that when evaluating
sequences, we must force all expressions in the sequence except the
final one. He proposes to modify eval-sequence from
section to use actual-value rather
than eval:
(define (eval-sequence exps env)
(cond ((last-exp? exps) (eval (first-exp exps) env))
(else (actual-value (first-exp exps) env)
(eval-sequence (rest-exps exps) env))))
a. Ben Bitdiddle thinks Cy is wrong.
He shows Cy the for-each procedure described in
exercise , which gives an important example of
a sequence with side effects:
(define (for-each proc items)
(if (null? items)
'done
(begin (proc (car items))
(for-each proc (cdr items)))))
He claims that the evaluator in the text (with the original
eval-sequence) handles this correctly:
;;; L-Eval input:
(for-each (lambda (x) (newline) (display x))
(list 57 321 88))
57
321
88
;;; L-Eval value:
done
Explain why Ben is right about the behavior of for-each.
b. Cy agrees that Ben is right about the for-each example,
but says that that's not the kind of program he was thinking about
when he proposed his change to eval-sequence.
He defines the following two procedures in the lazy evaluator:
(define (p1 x) (set! x (cons x '(2))) x)What are the values of (p1 1) and (p2 1) with the original eval-sequence? What would the values be with Cy's proposed change to eval-sequence?(define (p2 x) (define (p e) e x) (p (set! x (cons x '(2)))))
c. Cy also points out that changing eval-sequence as he proposes
does not affect the behavior of the example in part a.
Explain why this is true.
d. How do you think sequences ought to be treated in the lazy evaluator?
Do you like Cy's approach, the approach in the text, or some other approach?
Exercise. The approach taken in this section is somewhat unpleasant, because it makes an incompatible change to Scheme. It might be nicer to implement lazy evaluation as an upward-compatible extension, that is, so that ordinary Scheme programs will work as before. We can do this by extending the syntax of procedure declarations to let the user control whether or not arguments are to be delayed. While we're at it, we may as well also give the user the choice between delaying with and without memoization. For example, the definition
(define (f a (b lazy) c (d lazy-memo)) ...)would define f to be a procedure of four arguments, where the first and third arguments are evaluated when the procedure is called, the second argument is delayed, and the fourth argument is both delayed and memoized. Thus, ordinary procedure definitions will produce the same behavior as ordinary Scheme, while adding the lazy-memo declaration to each parameter of every compound procedure will produce the behavior of the lazy evaluator defined in this section. Design and implement the changes required to produce such an extension to Scheme. You will have to implement new syntax procedures to handle the new syntax for define. You must also arrange for eval or apply to determine when arguments are to be delayed, and to force or delay arguments accordingly, and you must arrange for forcing to memoize or not, as appropriate.