6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
6.001 Notes,Section 16.1
Slide 16.1.1
Last time,we completed building our evaluator,And as you
saw,we slightly misled you,We started off saying we were
going to user Scheme's lexical analyzer and parser,but then
build our own evaluator,which we did initially for arithmetic
expressions,then for defines,then for applications,and
eventually we ended up with something that basically looked
like Scheme's evaluator,written in Scheme!
Today,we are going to build on that idea,by examining the
actual Scheme evaluator,We will run through a quick,but
grand tour of the full evaluator,looking at several key ideas,
First,remember that we are basically describing the process of
evaluation,which in our case means making the environment
model a concrete set of procedures,Second,the essential message is that by defining the process of evaluation,we
are also defining our language,This means that the evaluator design then provides the basis on which we can create
abstractions,especially procedural abstractions,as it provides the mechanism for unwinding the abstraction back
down to primitive pieces when we want to get an actual value,And finally,given that designing an evaluator is
essentially equivalent to defining a language,we are going to look at how variations in a Scheme evaluator can
lead to very different language behavior,
Slide 16.1.2
To do this,we are going to have to look at several different
parts of the language design,We will start with the core of
eval and apply,then look at how we support the syntax
of the language,how we create and manipulate the
environments that let us look up values that are associated with
that syntax,and then how primitives are installed into the initial
or global environment,Finally,we will put together the overall
infrastructure for letting a user interact with the evaluator,and
we will see all of these pieces as we quickly walk through our
full evaluator,
As with previous lectures,there is a code handout that goes
with this lecture,and we suggest you print out a copy and have it available as we walk through our discussion,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.1.3
Let's start with the heart of the interpreter,We have already
seen this with our simple interpreter from the last lecture,The
essence of the evaluator is a tight loop,in which the evaluation
of an expression with respect to an environment reduces in the
general case to an application of a procedure to a set of
arguments,This in turn generally reduces to an evaluation of a
simpler expression (the body of the procedure) with respect to a
new environment (one in which the formal parameters of the
procedure have been bound to the arguments passed in),
This loop continues,unwinding expressions,until it reaches the
application of a primitive procedure to primitive values or the
evaluation of a primitive data object,
Slide 16.1.4
Our convention is that we will use an eval that does dispatch
on type,Thus,it checks the expression type,and based on that,
sends the expression to a procedure designed to handle that type
of expression,Our convention on apply is that it will first
evaluate the arguments,and then apply the procedure that is the
value of the first argument to the values of the others,
Slide 16.1.5
So here is our implementation of eval,Notice its form,First,
it is a dispatch on type,so it checks the expression to figure out
which type matches,Once it does,it sends the expression to a
procedure specific to that type,Notice that we are assuming a
data abstraction for checking types,We are not making any
assumptions about how types are represented,but are rather
using a set of procedures to check each type,This will allow us
to cleanly add to or alter our types,without having to change
the evaluator directly,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.1.6
Notice the order in which we check things in eval,We first
start out by checking for primitives,things like self-evaluating
expressions,or variables,These are easy things to deal with,
Slide 16.1.7
Next,we check out the special forms,Remember that this is an
expression that does not follow the normal rules of evaluation
for compound expressions,These are things like assignment or
definition,in which we only want to evaluate one of the
subexpressions,or things like if,where we know we want to
evaluate in a different order,Each of these expressions we will
treat separately,with a specific procedure to deal with that kind
of expression,We've added a couple of new ones,and we will
come back to those shortly,The issue to note is that this section
deals with all the special forms,
Slide 16.1.8
Finally,we get to an application,This is the case where we are
treating an expression that has a set of subexpressions that we
will evaluate,then apply the operator (or value of the first
subexpression) to all the rest of them,We have left
application? as an abstraction to check if something
is an application,but as you saw with our earlier evaluators,
most likely we will just make sure this is a combination,
meaning we will assume that if the expression is a compound
expression but not a known special form,then it must be an
application,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.1.9
In general,however,we see that our evaluator has exactly the
kind of form that we slowly evolved in our previous examples,
Given an expression and an environment,eval will check
the type of the expression,using some abstractions that we will
get to,to see if it is a primitive,or if it is a special form,or
ultimately if it is an application,In each case,eval
dispatches that expression to a specific procedure,We have
already seen many of these pieces,We know that for variables,
we should just look up the value of the variable in the
environment,We know that for quoted expressions,we should
simply grab the expression as tree structure and return it,
Similarly for the special forms,a definition should create a new
binding for a name and a value in the environment; an if should change the order of evaluation of the
subexpressions,
For an application,we should evaluate the first subexpression (the operator),then evaluate all the other
subexpressions,and apply that operator to that list of values,Notice that I have slightly misled you because we
don't have to assume that the operator is the first subexpression,Operator is simply some data abstraction
that will get the appropriate subexpression but it could in fact be some piece other than the first or leftmost one,
Slide 16.1.10
Here is a quick synopsis of what we see on that evaluator,It
dispatches on type,first for primitives,either self-evaluating
things or things that should not be evaluated; then for
expressions that deal with variables and their manipulation
within the environment (creating,looking up,or changing
values of variables); then for conditionals,ways of branching
depending on the value of an expression; then procedure
application,
Note there are several new forms here that we will have to
define,quoted objects,cond,and begin,Let's take a look at
some of these,
Slide 16.1.11
In our evaluators from the previous lectures,when we applied a
procedure to a set of arguments,we saw that reduced to simply
evaluating the body of the procedure with respect to a new
environment,Evaluation of the body was simply a case of using
eval on that expression,and that was because we assumed
the body was just a single expression,Before we introduced
mutation into our language,this made perfect sense,because
the value of the body would be the value of the last expression
in it,and it only made sense to have one expression,since any
other expression's value in a body would be lost,
Once we have mutation,however,expressions can do things
other than return values,they can create side effects,So a generalization for an evaluator is to let the body of a
procedure be a sequence of one or more expressions,That is shown here,in which we define foo to be a
procedure whose body has two expressions,The first does something,probably a side effect,and the second of
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
which computes and returns a value,
We still have to figure out how to do evaluation of a sequence (we'll get to that in a second) but given the idea that
evaluating a sequence could take a series of expressions,evaluate them in order and return the value of the last one,
we can now let bodies have multiple expressions,and inside of apply we can generally evaluate the body as a
sequence,not a single expression,
Slide 16.1.12
Thus,our apply,our way of dealing with applications of
procedures to arguments,will be slightly different,As before,it
will have a way of dealing with primitive procedures,in this
case just sending the expression to the underlying machine
primitive,For compound procedures (application of something
we built using a lambda),we make a slight change,We still
create a new environment,binding the parameters of the
procedure (obtained using the appropriate data abstraction) to
the values of the arguments in a frame that extends the
environment specified by the procedure object,Within this new
environment,we will evaluate the body of the procedure,but
notice here we will evaluate it as a sequence,not as a single expression,Thus,we will treat the body as a set of
expressions,evaluate each one in order,and then return the value of the last one as the value of the entire
application,
With that,we now see the intertwining of eval and apply,Let's take a look at some of the specific pieces,
Slide 16.1.13
First,self-evaluating expressions,Remember that exp is just a
tree structure,and in this case,we simply return that tree
structure directly,Thus numbers get returned without any
additional work,
Slide 16.1.14
If an expression is just a variable (a symbol) we will just look
up that variable's value in the environment,and we'll deal with
details of that shortly,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.1.15
Next,let's skip down to procedure applications,With our
change,we can see that the evaluator gets the value of the
operator by recursively evaluating that subexpression,then gets
a list of values of the other expressions (note that we explicitly
require a list here) by evaluating each piece in turn and
constructing a list,Note,however,that our data abstraction
isolates the issue of the order of the arguments from our
evaluator,We don't know if the operator is the first expression
or not in this case,Operator will simply select out
whatever we decide on in terms of syntax for our language,
And as we saw,apply will now evaluate the sequence of
expressions that it assumes the body contains,
Slide 16.1.16
What about ifs? We know that an if expression should take
a set of expressions,evaluate the first subexpression (or rather
we are assuming it is the first subexpression) and then
depending on that value,either evaluates the consequent or the
alternative,
Slide 16.1.17
And what about begins? Remember that a sequence is either
something identified by an explicit begin statement or is
used as the body of a procedure,as we just saw,In this case,we
want to extract the set of expressions,and evaluate them,We
use the following trick,shown on the next slide,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.1.18
Our plan is to evaluate each of the expressions in order,When
we get to the last one,we should return its value as the value of
the entire sequence,We will bury some of the details behind
data abstractions,but we can see the general form for
evaluating a sequence,If we have the last expression,we will
simply evaluate it and return the value,If it is not,we evaluate
it,then recursively walk down the sequence and do the same
thing,
Slide 16.1.19
Expressions like definitions and assignments either create or
change existing bindings of variables and values in the
environment,Notice the form,however,In both cases,we get
out the part of the expression that corresponds to the new value,
and actually evaluate it,by recursively applying meval to it,
We simply get out the part of the expression that corresponds to
the variable as a tree structure manipulation,however,without
evaluation,Then we do the appropriate manipulation of the
environment,
Notice how by using data abstractions we have not specified
what order the expressions will take,While we will eventually
decide that,from the perspective of this code,any change in that order will not affect the evaluation process,
Slide 16.1.20
So there is the whirlwind tour of eval and apply,We
have buried some details behind some data abstractions,which
we will address shortly,The part that you see here really is the
heart of evaluation,
The essence of the evaluator is a tight loop,in which the
evaluation of an expression with respect to an environment
reduces in the general case to an application of a procedure to
a set of arguments,This in turn generally reduces to an
evaluation of a simpler expression (the body of the procedure)
with respect to a new environment (one in which the formal
parameters of the procedure have been bound to the arguments
passed in),while inheriting values from other environments,
6.001 Notes,Section 16.2
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.1
So what have we done so far? Basically we have defined the
semantics of our language,By defining eval and apply
we have specified what the language means and the model of
computation we are going to use,Notice that we have done this
in terms of data abstractions,Everything we have used to pull
out list structure from expressions has used an abstraction,
There are no cars and cdrs anywhere in the code so far,
This is important,because we have separated the syntax of the
language from the semantics of the language,But eventually we
do need to focus on the syntax,the details of how we write
legal expressions in our language,This will force us to specify
things like how to identify kinds of expressions,and the order
of arguments,At the same time,this separation of syntax from semantics is extremely useful,as it allows us to very
easily change the syntax without having to change the actual evaluator,We simply change the interface to the
abstractions,We are now going to examine this issue,by looking at details of implementing the abstractions and by
looking at changes to that abstraction,
Slide 16.2.2
The second page of the code handout contains all of this in
much more detail,Here we will simply highlight some of the
key issues in syntax,
First,we need a set of routines to detect different kinds of
expressions,An easy way to do this is to have each one of them
check to see if it is a "tagged" list,So,for example,if? will
check to see if the expression is a list,that is something
constructed out of cons pairs,It will then check to see if the
first element of that list is the symbol if,Ditto for lambda,
For application,we will use a slightly different form,We will
assume that anything that has not been caught by one of the tag
checkers for a special form but is in fact a list of expressions,we can treat as an application,This means that we
may get into some trouble but it is the easiest way of allowing us to generalize to having any kind of procedure
applied to any set of expressions as long as that procedure was created using our lambda,
Slide 16.2.3
Given that we can detect different kinds of expressions and ship
them off to the procedures that handle them,those procedures
will also need to have ways of getting information out of
expressions,They will have to have ways of pulling out pieces
by walking down the list structure,So,for example,if we have
an application,we need a way of getting out the operator,and
the other expressions,Here we will assume that the first
subexpression is the operator,so we use car to get it out of
the expression,And we will assume that operands is a list of all
the remaining expressions,so we use cdr to get that part,Of
course we could have made a different design choice,as we
will see,The key point is that we now have an abstraction that pulls out pieces to pass on to the evaluator,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.4
And we will need routines that manipulate expressions,that is,
walk along the expressions finding pieces,For example,if we
are applying a procedure to a set of arguments,we need to get
out different parts of the argument list,So we will have
something to check if there are arguments,something to get the
next operand,and something to get the other operands,This is
just list structure that we are manipulating,Notice that we have
made an explicit choice about order,assuming the operands are
arranged in a left-to-right ordering,
Overall,our syntax (see page 2 of the code) is defined by a set
of expressions to deal with the list structure that is passed in to
the evaluator,These procedures walk down the list structure to
test for kind of expression,to get out pieces or otherwise manipulate that list structure,
Slide 16.2.5
The rest of the code on page 2 of the handout just fills out the
rest of the details of the syntax,the representation of
expressions,Look it over to be sure you understand it,but it is
basically the same sort of material,tagged lists for identifying
types,list operations (car and cdr) to get out pieces,
As we said earlier,one of the reasons for using data
abstractions everywhere within eval is to let us separate the
syntax from the semantics,Eval and apply define the
semantics,how expressions get their values in this language,
The syntax tells us how to write legal expressions in this
language,By doing that separation,we can make changes to the
syntax without affecting the semantics,Here is one such example,
Slide 16.2.6
Suppose I decide that rather than having the convention that the
operator is the first subexpression of a combination,and the
operands are all the other subexpressions,instead I want to be
much more verbose,I might want expressions like the one
shown here,explicitly identifying the procedure and the
arguments,How would I make this change to my language?
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.7
We have already hinted at the answer,All we need to do is
change the syntax,For example,now checking to see if
something is an application involves looking to see if the first
element of the list is the special symbol CALL,This is clearly
different from our earlier version,where we assumed any
combination that was not a special form was an application,
Here,we are explicitly identifying applications,
Slide 16.2.8
So how do I get out the pieces? Before,we would have gotten
the operator as the first subexpression,here it is the second
subexpression,since the first subexpression is the symbol
CALL,And for the operands,we have to skip past the ARGS
to get the right parts,Again,the key point,all I have changed is
the syntax,the routines that walk down the tree structure and
pull out the pieces,Nothing has changed in eval or
apply,
Slide 16.2.9
The second reason for separating syntax from semantics is that
it allows us to easily accommodate alternative forms for
expressions,We often call this "syntactic sugar",meaning that
it looks nicer,but it actually just coats the same underlying
idea,with a sweeter way of expressing the same thing,Let me
show you an example,Remember let?
We could treat let as a special form and write a handler for
it,We could have something that handles dispatches,having
detected expressions of this type (let),But we could also realize
that let is just a cleaner way of creating a procedure,then
applying it to capture some local state variables,
Said another way,a let expression is really just the same as the expression shown here,That is,we create a
lambda,whose argument list is the same as the arguments for the bindings in the let,whose body is just the
body of the let,and that lambda would then be applied to expressions whose values we want to bind to those
names,These are equivalent forms,As we saw in the environment model,they create exactly the same kind of
structure,
So rather than building a special form for let,let's see how we could use syntax and syntactical manipulation to
convert this form of let into an application of a procedure to a set of arguments,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.10
First,here is the change we will make inside of our evaluator,
We will have something that detects lets,What we will do in
this case is write something that manipulates the syntax,turns a
let into a combination,and then simply evaluates that
combination,i.e,recursively calls meval treating this as a
normal combination,
Thus in this case the dispatch is different,Rather than going off
to a procedure,it manipulates syntax,then evaluates the new
expression,
Slide 16.2.11
Thus now we just need to figure out how to rewrite the tree
structure that represents a let expression into something that
looks like a procedure application,
First,we will need a way to check if we have a let
expression,which is just a tagged list check,as before,Next,
we need to pull out the variables of the let,we need to pull
out the values to which they will be bound,and we need to pull
out the body,Notice how let-bound-variables
takes in one of these tree structures,will get the cadr which
gives us the set of let clauses,and then will map car down
that list,As we will see,this pulls off all the variable names from the clauses,
Getting the values is almost the same,but maps cadr down the list of clauses,For the body,we simply take the
cddr of the expression to get everything but the let tag,and the variable clauses,We convert that into a single
expression by wrapping a sequence label (a begin) around it,
Ignoring for the moment the specific details,these three procedures are basically walking through the tree structure
corresponding to a let expression,and pulling out the right pieces,the list of variables,the list of values and the
body (which gets converted into a sequence),
Slide 16.2.12
Now we can put all of this together,So let-
combination is going to take in a tree structure
representing a let expression,It will then convert this into a
form that we can just evaluate,
To do this,it takes the tree structure corresponding to the
variables,the tree structure corresponding to the values,and the
tree structure corresponding to the body,and then it creates a
new tree structure,Notice this structure! The first part of this
list (because we are doing a cons) is a list that represents a
procedure in our syntax,It is a list of the symbol lambda,
followed by a list of names,followed by a body! That looks exactly like a lambda expression,
And then we put that at the beginning of a list of the values,So this will convert a let combination into a new
tree structure,a tree structure that looks exactly like an application of a lambda to a set of values,That will then
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
be passed to meval,which will cause the evaluation of the whole expression,creating the thing we want,
Slide 16.2.13
So let's trace this through,Remember that a let expression
such as that shown on the slide gets converted by the parser into
a tree structure that looks exactly like this,The first part of the
tree is the symbol let,the second part is a tree that captures
the set of clauses,and the last part is another tree that represents
the body of the let,This tree structure is what is passed into
meval and let's see what happens when we do that,
Slide 16.2.14
What does the syntactic manipulation that converts a let
expression into a combination do? First it wants to get the
bound variables,and the code says to get the cadr of this
tree,So it is going to grab this piece,.,
Slide 16.2.15
..,and then it says to walk down this piece of list structure,
using a map,and apply car to each element,That creates a
new list,with the car of each element of the old list copied into
that list,shown as,.,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.16
..,here,The next thing it does is take the same cadr
structure,but now map cadr down it,This creates a new list
structure,copying the cadr of each element onto it,creating
this,.,
Slide 16.2.17
..,structure,And then this syntactic manipulation procedure
walks down the let tree structure and grabs the body,given
us this,.,
Slide 16.2.18
..,structure,Note what we have done,We have created three
new pieces of list structure here,We have done NO evaluation,
we have simply manipulated pieces of the tree structure,Given
those pieces,we now glue them together,The code says to
create a list with the symbol lambda,followed by the set of
names,followed by the body,Take that whole piece and put it
on the front of the structure representing the values,
Slide 16.2.19
That gives us this list structure,which represents an expression,
and check out its form,We have a list whose first element is a
lambda expression,followed by a list of expressions,and
we return a pointer to this whole list structure,Evaluating this
tree structure,or if you like the expression that is represented
by this tree structure turns into an evaluation of an application,
as we wanted,
So the key point is that we can do syntactic manipulation of
expressions to convert one form into another form,in this case
converting a let into its underlying lambda application,
Then we let our evaluator do the work to complete the
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
evaluation,
Slide 16.2.20
What other syntactic variations are possible? Remember how
we had named procedures,that is,forms such as that shown in
the slide,Earlier,we would have had to write (define
foo (lambda,..)) to separate the lambda that
created the procedure from the define that gave it a name,
We saw it was convenient,especially when thinking about the
substitution model,to have this alternative form,in which we
clearly identify the application of a procedure to a set of
arguments,How can we add this form to our system,which so
far meval cannot support,
In terms of semantics this is just another define,We are
defining a variable to be a particular value,What else do we need?
Slide 16.2.21
So we don't want to change the semantics,Evaluating a
definition should behave exactly the same as before,All we
need to do is change the syntax,that is,the thing that
manipulates the tree structure,to support both kinds of
definitions of procedures,
Before,getting the value out of a definition would have simply
grabbed the third subexpression,But now we can be careful,
We will first check to see if the second subexpression is a
symbol,If it is,then we know we have the form of a define we
handled before,and we will simply grab the right piece and
return it,On the other hand,if it is not a symbol,then we can
assume we have one of these new forms,What should we do in
this case? We need to desugar or unwrap the hidden lambda,So we will construct a new lambda using a
constructor for lambdas,passing in the formal parameters,which we get by walking down the tree structure of
the expression,and the body,which we also get by walking down the tree structure of the expression,In this
getting the value of the expression will convert the actual expression into a lambda,This is great,because that
then gets passed back to eval-definition,which evaluates this expression to create the procedure,
which is then returned to be bound to the name,
Notice how again we are simply manipulating the tree structure of an expression to convert it into a new
expression,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.2.22
In summary,we have both created eval and apply to
define the semantics for our language,and we have separately
defined the syntax,the legal expressions in our language,By
using data abstractions between eval and apply,and the
procedures that manipulate expressions,we give ourselves a
clean way for changing syntax,for adding to the syntax,for
manipulating syntactic variations on expressions,without ever
changing eval or apply,
Thus we have seen both the semantics and the syntax of our
language,
6.001 Notes,Section 16.3
Slide 16.3.1
So you can see that we are making progress in building a
complete evaluator for Scheme,We started by building eval
and apply,on top of some data abstractions so that we could
see the flow of evaluation,between evaluating an expression
with respect to an environment; to applying a procedure to a set
of arguments,We have also filled in the details of the evaluator,
separating the semantics from the syntax,i.e,how we write and
manipulate expressions in the language,
What else do we need to fill in? What about environments? So
far,we have simply relied on there being some kind of abstract
table for dealing with storing of bindings,and retrieving them,
Let's make that explicit as well,
Slide 16.3.2
What do we need in an environment? Abstractly we just want to
build the environment diagrams we had in our model,That is,
we need a way of taking bindings (pairings of names and
values) and gluing them together into tables,Those tables will
need pointers to other tables,to allow for sequences of frames,
Thus we need to glue things together as sequences of tables,
and the tables need to glue together bindings of variables and
values,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.3.3
We can just do this using list structure! Page 3 of the code
handout shows this,An environment will be created as a list of
frames,Thus in this example E2 would be a list whose first
element points to a frame and whose cdr points off to the
enclosing environment,This list can continue until it terminates
in the global environment,as the last element in the list,
Slide 16.3.4
To represent a frame,we have lots of choices,Abstractly,we
need a paired collection of variables and values,We could just
glue them together in that order,variable,value,variable,value,
A second way however is to create two lists,The first
component will be a list of the variables,and the second
component will be a list of the corresponding values,The
correspondence or binding is determined by the order,the first
variable matches the first value,the second variable matches
the second value,and so on,
Slide 16.3.5
As we have seen,the integral loop of eval and apply is
to reduce the evaluation of one expression with respect to some
environment to evaluation of another expression with respect to
a new environment that extends the original environment,So
we need to specify how to extend an environment to allow for
this new evaluation,
Slide 16.3.6
Abstractly,we should take a list of variable names,a list of
corresponding values,and a current environment,and we
should create a new frame that is enclosed or scoped by the
original environment,and within which the list of parameters is
bound to the corresponding list of variables,This is just our
environment model,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.3.7
Concretely,our environment was just a list of frames,so to
extend an environment we simply want to add to the front of
that list a new frame,Check the code,which simply "conses" a
new frame onto the existing environment,And what is a frame?
It just constructs one of these pairings of a list of variables and
a list of values,The code is careful to ensure that number of
variables and values matches,
Thus in our concrete implementation,extending an
environment just creates a new frame by pairing up two lists,
then puts that frame at the front of the list of frames that
represents our environment,We now start evaluation with
respect to the new frame at the front of the list,
Slide 16.3.8
Once we have an implementation for building environments,
we can turn to using them,In particular,environments are
intended to help us look up values of variables,We now need
some procedures to support value lookup,So what do we need?
First,we should look for a binding in a frame,Thus we will
take the current frame and loop through the list of variables and
the list of values in parallel (remember that we stored those as
two separate lists in our implementation),Thus we just walk
down these lists in synchrony,If we find the variable for which
we are looking,we return the associated value,If we reach the
end of that pairing of lists without finding the variable,then we
know there is no binding for that variable in this frame,Thus
we move on to the next enclosing environment,And we know all of this should just be manipulation of list
structure,The next slide shows the detailed code to do this for us,
Slide 16.3.9
To implement this idea in our particular structure,we just need
two different looping mechanisms,The first one,when we are
going to look up a variable value,loops over environments,So
notice what env-loop does,it takes in an environment,
and if it is empty,complains about an unbound variable;
otherwise it will look in the first frame of that environment for
a binding,where first-frame is just a data abstraction
for getting the first frame of the sequence,If it doesn't find a
binding there,it should move on to the next frame in the
sequence,Thus,env-loop is the top-level loop for looking
up bindings in a frame,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.3.10
Once it gets the first frame of the environment,the method runs
a second loop,scan on that frame's list of variables and list
of corresponding values,Scan works its way down both lists
in synchrony,If it runs out of variables,it must not have found
a binding in this frame,and we go on to the next frame,Notice
that it calls env-loop to go back up to the top level to get
the next frame and rescan,
If there are variables left to check,then we compare our search
variable against the next one in the list,If it is,I return the next
element from the values list,If it is not,I scan again,moving
in synchrony down both lists,
There are the two loops that let us look up the value of a variable in an environment,
Slide 16.3.11
Other aspects of manipulating variables in environments,e.g,
setting a variable,will have a very similar form,In the case of
setting a value,we similarly look for the right pairing,then
change it (see the code for details),
Thus we can build environments just out of list structure,
6.001 Notes,Section 16.4
Slide 16.4.1
To get things going,we need an initial environment,also called
the global environment,This will be our default environment,
where we will normally evaluate expressions from the user,
Therefore,in this environment we need bindings for the built-in
names of procedures,This will also be our backstop,meaning if
we look through all the environments for a binding,and get to
and through the global environment,without out finding a
binding,we will stop and signal an unbound variable error,
Remember that we are representing our environment just as
lists of frames,so to get the initial environment,we will take an
empty environment (just the empty list) and extend it,building
a single frame in which we do the following,We take a set of
possible names for built-in primitives and a set of procedures to go with those names,and we will install them into
the environment,Look at the code handout on page 4 to see how we give our own names to the built-in Scheme
primitives,Remember that the names are our choice,here we have used the same ones as those in Scheme but we
could have made other selections,Also notice that the set of things we choose to have as primitives is also our
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
choice,In addition to creating bindings for our primitive procedures,we also create bindings for true and
false to the Boolean values used by the machine to represent these values,Finally we return this environment
as our initial environment,
For details,check out the code handout,
Slide 16.4.2
To interact with our evaluator,we need some mechanisms for
getting expressions into it,For this,we build a simple little
driver loop,which is often known as an REP or read-eval-print
loop,This loop runs through a constant cycle of reading in an
expression,evaluating it using the interpreter,then printing out
the result and cycling to read the next expression,Note how the
code on the slide runs through exactly that cycle,
It prints a prompt to the user on the screen,then reads in an
expression using Scheme's read operator,It then passes that
parsed tree structure to our evaluator for interpretation,with
respect to our global environment,When done,it prompts the
It then cycles through this process again,
user with a note that the value follows,and prints out the value,
With this piece we have completed our construction of an evaluator,We have eval and apply to unwrap our
abstractions to primitive operations,we have a definition of the syntax of the language which is abstracted away
from the interpreter to allow ease of modification,we have details of how to create and use environments to hold
our values for variables,and we have a simple interface to the interpreter,
6.001 Notes,Section 16.5
Slide 16.5.1
So there you have it! We have built an evaluator for Scheme,
implementing eval and apply,Although there is a lot of
code here,you should try to step back from the details to see
the general outline of this evaluator,
Having built our evaluator,we can ask some questions about
choices that were made in designing this evaluator,In
particular,we said much earlier in the term that Scheme uses
lexical scoping,So what does that mean?
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.2
Think about what happens when we apply a procedure to a set
of arguments,In detail,we get the values of the arguments and
the value of the procedure,then we create a new environment in
which the variables of the procedure are bound to the
arguments passed in,and relative to that environment we
evaluate the body of the procedure,So what happens inside that
body? In particular,that body will be an expression that
contains lots of names,and the issue is,how do we find the
values associated with those names?
First,any name that was a formal parameter of the procedure
gets its value from the frame we just created,Those are called
bound parameters,But any variable in that body that is not
one of the formal parameters is known as a free variable,How do we find the bindings for those? We have said
that if we have a procedure that has free variables,the values for them come from bindings made by enclosing
procedure definitions,In other words,they are looked up in the environment in which the procedure was defined,
Slide 16.5.3
Or said another way,it says we walk up that chain of
environments looking for a binding of the variable,And we
know that chain of environments comes from sets of
procedures,So if our procedure is defined inside another
procedure we know that if we can't find a scoping (a formal
parameter) binding the thing we are looking for in the initial
lambda we go outside the scope of that lambda to the
enclosing lambda,looking for a corresponding formal
parameter here,Thus,the boundaries of the lambda
expressions define the chain of frames we are going to see in
our environment model,and that is how we are going to capture
our lexical scoping to determine the values of variables,How does this happen in practice?
Slide 16.5.4
Look at the code for make-procedure,which you will
find on page 3 of the handout,It glues together a tag,the
parameters,the body,and the environment in which it is
evaluated,As a consequence,the evaluation environment is
stored away and is always going to be the enclosing lexical
scope,It is going to tell use where to look to find a binding for
a free variable,Why?
Well that was just a design choice! This came from our design
of procedure application,which said,hang a frame,bind the
parameters to the actual values passed in,then evaluate the
body in this new environment,The choice here was to scope
together frames based on where the procedures were actually evaluated,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.5
So let's remind ourselves of how that works,This is just
reviewing the environment model,but with our detailed
implementation now in mind,Suppose we consider the
definition shown here,In the environment model,we know
what happens,.,
Slide 16.5.6
Evaluation of this expression will create a binding for foo in
the global environment to a procedure of arguments x and y
coming from that hidden lambda (due to the desugaring of
the syntactic sugar),Note that the body of this procedure is
another lambda expression that has not yet been evaluated,
but just exists as tree structure,
Slide 16.5.7
Let's apply foo to a couple of arguments,and give the result
the name bar,Foo then hangs a new frame scoped by the
same environment as the procedure,binds x and y to the
values 1 and 2,and relative to this frame we evaluate the body,
This is another lambda so we create the double bubble
scoped by this frame since that is where the evaluation takes
places,Bar is bound to this value,i.e,this procedure object,
Slide 16.5.8
Now let's apply bar,We can trace through our evaluator,or
alternatively our environment model,to drop a frame whose
enclosing environment is identical to the procedure's,within
which we bind the formal parameter to its argument,and
relative to which we evaluate the body of this procedure,Notice
that we are getting the values of x,y and z with respect to
E2,Thus the binding for z will come from this frame as it is
scoped by the lambda but to get the bindings for x and y
we move up the chain to the next frame which comes from the
enclosing lambda,To get the value of + we move further
up the chain to the global environment,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.9
As a consequence of this,we can see that we will always
evaluate the expression (+ x y z) (the body of bar) in
a new environment within the lexical scope established by the
enclosing procedure,Every time we apply this procedure,we
will hang a new frame that will always scope back to E1,which
is the surrounding lexical environment,meaning we will always
get the same bindings for x and y,
This was a particular choice we made in constructing our
evaluator,but it is not the only such choice,
Slide 16.5.10
An alternative way to get bindings for free variables would be
to look them up in the caller's environment,meaning in the
environment that corresponds to the procedure asking for the
values,rather than in the surrounding lexical environment,This
will lead to a different behavior,and this style of handling free
variables is known as dynamic scoping,because it is based on
the values in place when the caller asks for them,
Slide 16.5.11
This model leads to a different behavior,Consider this
definition for pooh,Notice that there is no explicit reference
to the parameter x within this body,We can define bear as
shown,Notice that x is used in the body of bear but there is
no explicit parameter for x in the definition,Thus,bear
needs to get the value from somewhere else,
If we call (pooh 9) it will call (bear 20) and given
that the value of x was specified to be 9 in the call to pooh
we could get out the value shown,
This looks strange,as this certainly would not work under
lexical scoping,or our normal Scheme,We are now changing the behavior of our evaluator,we are asking pooh
to set a binding for its parameter x so that when bear is used,it can use that value of x created in the caller's
environment,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.12
Suppose we want to change our evaluator to use dynamic
scoping rather than lexical scoping,Conceptually,how would
this change our environment model? First,note that our double
bubble becomes a single bubble,Under dynamic binding we
don't need to keep track of the enclosing environment in which
a procedure was created,as it is no longer used to define the
scoping for free variables,
Slide 16.5.13
Now,let's apply pooh to some argument,Applying pooh
under this new model says to drop a frame in which we bind the
formal parameter x to the value 9,That frame now gets scoped
by the caller's environment,which in this case happens to be
the global environment,since that is where we are asking for
the evaluation,So far this looks like before,Now,relative to
that frame we are going to evaluate the body of pooh,
Slide 16.5.14
And the body of pooh says to apply bear,Thus,we apply
a procedure so we build a frame in which y is bound to 20,
But now,the scoping environment for this frame is the
environment in place when the caller asked,i.e,E1,It does not
inherit the environment that was there when bear was
created but rather it inherits the environment that was used
when the value of applying bear was asked for,Now we can
evaluate the body (+ x y) in this frame,and thus it will
inherit the value of x that was passed in back when we
evaluated pooh,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.15
The key thing to note is that we will evaluate the expression
(+ x y) in an environment that extends the caller's
environment,This means that as we call this at different times,
we will have different environments,as opposed to the lexical
case in which we would always point back to the environment
created when the procedure was created,
So we can see we can get a very different behavior when we
shift to dynamic scoping,
Slide 16.5.16
We will return to the issues of why one might want to have
dynamic binding rather than lexical binding,Here,we want to
focus on how simple it is to make this change in our evaluator,
In fact,only a very small number of changes can cause this
drastic change in behavior,
First,when we evaluate a lambda we will make a procedure
as before,but now we don't need to include the enclosing
environment,We don't make a double bubble,we make a single
bubble,Thus we can use the same form,but just pass in a
symbol indicating that no environment is stored,
Slide 16.5.17
The second change occurs when we go about actually applying
a procedure (something we built with a lambda) to a set of
arguments,Remember that in the previous case,we got the
value of the operator,we got the values of the operands,and
then we apply the operator,which meant evaluating the body of
the operator in a new environment that extended the
environment part of the procedure with a frame binding the
parameters to the values,Here,we change that,Now our
application says,get the value of the operator,get the list of
values of the operands,and then apply that operator in the
current environment,Thus we have added one more argument
to our apply,
6.001 Structure and Interpretation of Computer Programs,Copyright? 2004 by Massachusetts Institute of Technology,
Slide 16.5.18
The only other change we need is a dynamic apply,This
apply takes in a procedure,a list of values,and an
environment,the environment that the caller is in,
For primitives,this apply does the same thing,However,
application of a compound procedure (something we built with
a lambda) will evaluate the body (which we expect to be a
sequence) in an environment,but here the environment comes
from extending the calling environment,
The key thing to note is how an incredibly small set of changes
to eval and apply can dramatically change the way in
which variables are interpreted,
Slide 16.5.19
This was really the whole point of this example of dynamic
scoping,It leads to a different kind of behavior and it is worth
thinking about what kinds of advantages one might get from
such a change,But what we have really done is show how by
making a few small changes to eval and apply we have
changed the semantics of the language,That is exactly the point
of having eval and apply,They define what it means to
evaluate expressions in a language,
The second point is that by cleanly separating the syntax of a
language from the semantics,we have enabled making that kind
of change in an easy manner,The data abstractions that define
the syntax separate them from the rules for interpretation,Thus we can change the evaluation rules,but not have to
make any changes to the syntax,
In the next lecture,we will return to the idea of changing the rules of evaluation,and examining the impact of those
changes on the behavior of the language,