In section ![[*]](../image/cross_ref_motif.gif)
we saw how to
transform simple Scheme programs into descriptions of register
machines. We will now perform this transformation on a more complex
program, the metacircular evaluator of
sections -,
which shows how
the behavior of a Scheme interpreter can be described in terms of the
procedures eval and apply.
The explicit-control
evaluator that we develop in this section shows how the underlying
procedure-calling and argument-passing mechanisms used in the
evaluation process can be described in terms of operations on
registers and stacks. In addition, the explicit-control evaluator can
serve as an implementation of a Scheme interpreter, written in a
language that is very similar to the native machine language of
conventional computers. The evaluator can be executed by the
register-machine simulator of section .
Alternatively, it can be used as a starting point for building a
machine-language implementation of a Scheme evaluator, or even a
special-purpose machine for evaluating Scheme expressions.
Figure shows such a hardware implementation: a
silicon chip that acts as an evaluator for Scheme. The chip designers
started with the data-path and controller specifications for a
register machine similar to the evaluator described in this section
and used design automation programs to construct the
integrated-circuit layout.![[*]](../image/foot_motif.gif)
Registers and operations
In designing the explicit-control evaluator, we must specify the
operations to be used in our register machine. We described the
metacircular evaluator in terms of abstract syntax, using procedures
such as quoted? and make-procedure. In implementing the
register machine, we could expand these procedures into sequences of
elementary list-structure memory operations, and implement these
operations on our register machine. However, this would make our
evaluator very long, obscuring the basic structure with
details. To clarify the presentation, we will include as primitive
operations of the register machine the syntax procedures given in
section and the procedures for
representing environments and other run-time data given in
sections and .
In order to completely specify an evaluator that could be programmed
in a low-level machine language or implemented in hardware, we would
replace these operations by more elementary operations, using the
list-structure implementation we described in
section .
Our Scheme evaluator register machine includes a stack and seven
registers: exp, env, val, continue, proc,
argl, and unev. Exp is used to hold the expression
to be evaluated, and env contains the environment in which the
evaluation is to be performed. At the end of an evaluation, val
contains the value obtained by evaluating the expression in the
designated environment. The continue register is used to
implement recursion, as explained in
section . (The evaluator needs to call
itself recursively, since evaluating an expression requires evaluating
its subexpressions.) The registers proc, argl, and
unev are used in evaluating combinations.
We will not provide a data-path diagram to show how the registers and operations of the evaluator are connected, nor will we give the complete list of machine operations. These are implicit in the evaluator's controller, which will be presented in detail.