LET'S BUILD A COMPILER!
By
Jack W. Crenshaw, Ph.D.
7 November 1988
Part VII: LEXICAL SCANNING
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* COPYRIGHT NOTICE *
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* Copyright (C) 1988 Jack W. Crenshaw. All rights reserved. *
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INTRODUCTION
In the last installment, I left you with a compiler that would
ALMOST work, except that we were still limited to single-
character tokens. The purpose of this session is to get rid of
that restriction, once and for all. This means that we must deal
with the concept of the lexical scanner.
Maybe I should mention why we need a lexical scanner at all ...
after all, we've been able to manage all right without one, up
till now, even when we provided for multi-character tokens.
The ONLY reason, really, has to do with keywords. It's a fact of
computer life that the syntax for a keyword has the same form as
that for any other identifier. We can't tell until we get the
complete word whether or not it IS a keyword. For example, the
variable IFILE and the keyword IF look just alike, until you get
to the third character. In the examples to date, we were always
able to make a decision based upon the first character of the
token, but that's no longer possible when keywords are present.
We need to know that a given string is a keyword BEFORE we begin
to process it. And that's why we need a scanner.
In the last session, I also promised that we would be able to
provide for normal tokens without making wholesale changes to
what we have already done. I didn't lie ... we can, as you will
see later. But every time I set out to install these elements of
the software into the parser we have already built, I had bad
feelings about it. The whole thing felt entirely too much like a
band-aid. I finally figured out what was causing the problem: I
was installing lexical scanning software without first explaining
to you what scanning is all about, and what the alternatives are.
Up till now, I have studiously avoided giving you a lot of
theory, and certainly not alternatives. I generally don't
respond well to the textbooks that give you twenty-five different
ways to do something, but no clue as to which way best fits your
needs. I've tried to avoid that pitfall by just showing you ONE
method, that WORKS.
But this is an important area. While the lexical scanner is
hardly the most exciting part of a compiler, it often has the
most profound effect on the general "look & feel" of the
language, since after all it's the part closest to the user. I
have a particular structure in mind for the scanner to be used
with KISS. It fits the look & feel that I want for that
language. But it may not work at all for the language YOU'RE
cooking up, so in this one case I feel that it's important for
you to know your options.
So I'm going to depart, again, from my usual format. In this
session we'll be getting much deeper than usual into the basic
theory of languages and grammars. I'll also be talking about
areas OTHER than compilers in which lexical scanning plays an
important role. Finally, I will show you some alternatives for
the structure of the lexical scanner. Then, and only then, will
we get back to our parser from the last installment. Bear with
me ... I think you'll find it's worth the wait. In fact, since
scanners have many applications outside of compilers, you may
well find this to be the most useful session for you.
LEXICAL SCANNING
Lexical scanning is the process of scanning the stream of input
characters and separating it into strings called tokens. Most
compiler texts start here, and devote several chapters to
discussing various ways to build scanners. This approach has its
place, but as you have already seen, there is a lot you can do
without ever even addressing the issue, and in fact the scanner
we'll end up with here won't look much like what the texts
describe. The reason? Compiler theory and, consequently, the
programs resulting from it, must deal with the most general kind
of parsing rules. We don't. In the real world, it is possible
to specify the language syntax in such a way that a pretty simple
scanner will suffice. And as always, KISS is our motto.
Typically, lexical scanning is done in a separate part of the
compiler, so that the parser per se sees only a stream of input
tokens. Now, theoretically it is not necessary to separate this
function from the rest of the parser. There is only one set of
syntax equations that define the whole language, so in theory we
could write the whole parser in one module.
Why the separation? The answer has both practical and
theoretical bases.
In 1956, Noam Chomsky defined the "Chomsky Hierarchy" of
grammars. They are:
o Type 0: Unrestricted (e.g., English)
o Type 1: Context-Sensitive
o Type 2: Context-Free
o Type 3: Regular
A few features of the typical programming language (particularly
the older ones, such as FORTRAN) are Type 1, but for the most
part all modern languages can be described using only the last
two types, and those are all we'll be dealing with here.
The neat part about these two types is that there are very
specific ways to parse them. It has been shown that any regular
grammar can be parsed using a particular form of abstract machine
called the state machine (finite automaton). We have already
implemented state machines in some of our recognizers.
Similarly, Type 2 (context-free) grammars can always be parsed
using a push-down automaton (a state machine augmented by a
stack). We have also implemented these machines. Instead of
implementing a literal stack, we have relied on the built-in
stack associated with recursive coding to do the job, and that in
fact is the preferred approach for top-down parsing.
Now, it happens that in real, practical grammars, the parts that
qualify as regular expressions tend to be the lower-level parts,
such as the definition of an identifier:
<ident> ::= <letter> [ <letter> | <digit> ]*
Since it takes a different kind of abstract machine to parse the
two types of grammars, it makes sense to separate these lower-
level functions into a separate module, the lexical scanner,
which is built around the idea of a state machine. The idea is to
use the simplest parsing technique needed for the job.
There is another, more practical reason for separating scanner
from parser. We like to think of the input source file as a
stream of characters, which we process right to left without
backtracking. In practice that isn't possible. Almost every
language has certain keywords such as IF, WHILE, and END. As I
mentioned earlier, we can't really know whether a given
character string is a keyword, until we've reached the end of it,
as defined by a space or other delimiter. So in that sense, we
MUST save the string long enough to find out whether we have a
keyword or not. That's a limited form of backtracking.
So the structure of a conventional compiler involves splitting up
the functions of the lower-level and higher-level parsing. The
lexical scanner deals with things at the character level,
collecting characters into strings, etc., and passing them along
to the parser proper as indivisible tokens. It's also considered
normal to let the scanner have the job of identifying keywords.
STATE MACHINES AND ALTERNATIVES
I mentioned that the regular expressions can be parsed using a
state machine. In most compiler texts, and indeed in most
compilers as well, you will find this taken literally. There is
typically a real implementation of the state machine, with
integers used to define the current state, and a table of actions
to take for each combination of current state and input
character. If you write a compiler front end using the popular
Unix tools LEX and YACC, that's what you'll get. The output of
LEX is a state machine implemented in C, plus a table of actions
corresponding to the input grammar given to LEX. The YACC output
is similar ... a canned table-driven parser, plus the table
corresponding to the language syntax.
That is not the only choice, though. In our previous
installments, you have seen over and over that it is possible to
implement parsers without dealing specifically with tables,
stacks, or state variables. In fact, in Installment V I warned
you that if you find yourself needing these things you might be
doing something wrong, and not taking advantage of the power of
Pascal. There are basically two ways to define a state machine's
state: explicitly, with a state number or code, and implicitly,
simply by virtue of the fact that I'm at a certain place in the
code (if it's Tuesday, this must be Belgium). We've relied
heavily on the implicit approaches before, and I think you'll
find that they work well here, too.
In practice, it may not even be necessary to HAVE a well-defined
lexical scanner. This isn't our first experience at dealing with
multi-character tokens. In Installment III, we extended our
parser to provide for them, and we didn't even NEED a lexical
scanner. That was because in that narrow context, we could
always tell, just by looking at the single lookahead character,
whether we were dealing with a number, a variable, or an
operator. In effect, we built a distributed lexical scanner,
using procedures GetName and GetNum.
With keywords present, we can't know anymore what we're dealing
with, until the entire token is read. This leads us to a more
localized scanner; although, as you will see, the idea of a
distributed scanner still has its merits.
SOME EXPERIMENTS IN SCANNING
Before getting back to our compiler, it will be useful to
experiment a bit with the general concepts.
Let's begin with the two definitions most often seen in real
programming languages:
<ident> ::= <letter> [ <letter> | <digit> ]*
<number ::= [<digit>]+
(Remember, the '*' indicates zero or more occurences of the terms
in brackets, and the '+', one or more.)
We have already dealt with similar items in Installment III.
Let's begin (as usual) with a bare cradle. Not surprisingly, we
are going to need a new recognizer:
{--------------------------------------------------------------}
{ Recognize an Alphanumeric Character }
function IsAlNum(c: char): boolean;
begin
IsAlNum := IsAlpha(c) or IsDigit(c);
end;
{--------------------------------------------------------------}
Using this let's write the following two routines, which are very
similar to those we've used before:
{--------------------------------------------------------------}
{ Get an Identifier }
function GetName: string;
var x: string[8];
begin
x := '';
if not IsAlpha(Look) then Expected('Name');
while IsAlNum(Look) do begin
x := x + UpCase(Look);
GetChar;
end;
GetName := x;
end;
{--------------------------------------------------------------}
{ Get a Number }
function GetNum: string;
var x: string[16];
begin
x := '';
if not IsDigit(Look) then Expected('Integer');
while IsDigit(Look) do begin
x := x + Look;
GetChar;
end;
GetNum := x;
end;
{--------------------------------------------------------------}
(Notice that this version of GetNum returns a string, not an
integer as before.)
You can easily verify that these routines work by calling them
from the main program, as in
WriteLn(GetName);
This program will print any legal name typed in (maximum eight
characters, since that's what we told GetName). It will reject
anything else.
Test the other routine similarly.
WHITE SPACE
We also have dealt with embedded white space before, using the
two routines IsWhite and SkipWhite. Make sure that these
routines are in your current version of the cradle, and add the
the line
SkipWhite;
at the end of both GetName and GetNum.
Now, let's define the new procedure:
{--------------------------------------------------------------}
{ Lexical Scanner }
Function Scan: string;
begin
if IsAlpha(Look) then
Scan := GetName
else if IsDigit(Look) then
Scan := GetNum
else begin
Scan := Look;
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
We can call this from the new main program:
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
repeat
Token := Scan;
writeln(Token);
until Token = CR;
end.
{--------------------------------------------------------------}
(You will have to add the declaration of the string Token at the
beginning of the program. Make it any convenient length, say 16
characters.)
Now, run the program. Note how the input string is, indeed,
separated into distinct tokens.
STATE MACHINES
For the record, a parse routine like GetName does indeed
implement a state machine. The state is implicit in the current
position in the code. A very useful trick for visualizing what's
going on is the syntax diagram, or "railroad-track" diagram.
It's a little difficult to draw one in this medium, so I'll use
them very sparingly, but the figure below should give you the
idea:
|-----> Other---------------------------> Error
|
Start -------> Letter ---------------> Other -----> Finish
^ V
| |
|<----- Letter <---------|
| |
|<----- Digit <----------
As you can see, this diagram shows how the logic flows as
characters are read. Things begin, of course, in the start
state, and end when a character other than an alphanumeric is
found. If the first character is not alpha, an error occurs.
Otherwise the machine will continue looping until the terminating
delimiter is found.
Note that at any point in the flow, our position is entirely
dependent on the past history of the input characters. At that
point, the action to be taken depends only on the current state,
plus the current input character. That's what make this a state
machine.
Because of the difficulty of drawing railroad-track diagrams in
this medium, I'll continue to stick to syntax equations from now
on. But I highly recommend the diagrams to you for anything you
do that involves parsing. After a little practice you can begin
to see how to write a parser directly from the diagrams.
Parallel paths get coded into guarded actions (guarded by IF's or
CASE statements), serial paths into sequential calls. It's
almost like working from a schematic.
We didn't even discuss SkipWhite, which was introduced earlier,
but it also is a simple state machine, as is GetNum. So is their
parent procedure, Scan. Little machines make big machines.
The neat thing that I'd like you to note is how painlessly this
implicit approach creates these state machines. I personally
prefer it a lot over the table-driven approach. It also results
is a small, tight, and fast scanner.
NEWLINES
Moving right along, let's modify our scanner to handle more than
one line. As I mentioned last time, the most straightforward way
to do this is to simply treat the newline characters, carriage
return and line feed, as white space. This is, in fact, the way
the C standard library routine, iswhite, works. We didn't
actually try this before. I'd like to do it now, so you can get
a feel for the results.
To do this, simply modify the single executable line of IsWhite
to read:
IsWhite := c in [' ', TAB, CR, LF];
We need to give the main program a new stop condition, since it
will never see a CR. Let's just use:
until Token = '.';
OK, compile this program and run it. Try a couple of lines,
terminated by the period. I used:
now is the time
for all good men.
Hey, what happened? When I tried it, I didn't get the last
token, the period. The program didn't halt. What's more, when I
pressed the 'enter' key a few times, I still didn't get the
period.
If you're still stuck in your program, you'll find that typing a
period on a new line will terminate it.
What's going on here? The answer is that we're hanging up in
SkipWhite. A quick look at that routine will show that as long
as we're typing null lines, we're going to just continue to loop.
After SkipWhite encounters an LF, it tries to execute a GetChar.
But since the input buffer is now empty, GetChar's read statement
insists on having another line. Procedure Scan gets the
terminating period, all right, but it calls SkipWhite to clean
up, and SkipWhite won't return until it gets a non-null line.
This kind of behavior is not quite as bad as it seems. In a real
compiler, we'd be reading from an input file instead of the
console, and as long as we have some procedure for dealing with
end-of-files, everything will come out OK. But for reading data
from the console, the behavior is just too bizarre. The fact of
the matter is that the C/Unix convention is just not compatible
with the structure of our parser, which calls for a lookahead
character. The code that the Bell wizards have implemented
doesn't use that convention, which is why they need 'ungetc'.
OK, let's fix the problem. To do that, we need to go back to the
old definition of IsWhite (delete the CR and LF characters) and
make use of the procedure Fin that I introduced last time. If
it's not in your current version of the cradle, put it there now.
Also, modify the main program to read:
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
repeat
Token := Scan;
writeln(Token);
if Token = CR then Fin;
until Token = '.';
end.
{--------------------------------------------------------------}
Note the "guard" test preceding the call to Fin. That's what
makes the whole thing work, and ensures that we don't try to read
a line ahead.
Try the code now. I think you'll like it better.
If you refer to the code we did in the last installment, you'll
find that I quietly sprinkled calls to Fin throughout the code,
wherever a line break was appropriate. This is one of those
areas that really affects the look & feel that I mentioned. At
this point I would urge you to experiment with different
arrangements and see how you like them. If you want your
language to be truly free-field, then newlines should be
transparent. In this case, the best approach is to put the
following lines at the BEGINNING of Scan:
while Look = CR do
Fin;
If, on the other hand, you want a line-oriented language like
Assembler, BASIC, or FORTRAN (or even Ada... note that it has
comments terminated by newlines), then you'll need for Scan to
return CR's as tokens. It must also eat the trailing LF. The
best way to do that is to use this line, again at the beginning
of Scan:
if Look = LF then Fin;
For other conventions, you'll have to use other arrangements.
In my example of the last session, I allowed newlines only at
specific places, so I was somewhere in the middle ground. In the
rest of these sessions, I'll be picking ways to handle newlines
that I happen to like, but I want you to know how to choose other
ways for yourselves.
OPERATORS
We could stop now and have a pretty useful scanner for our
purposes. In the fragments of KISS that we've built so far, the
only tokens that have multiple characters are the identifiers and
numbers. All operators were single characters. The only
exception I can think of is the relops <=, >=, and <>, but they
could be dealt with as special cases.
Still, other languages have multi-character operators, such as
the ':=' of Pascal or the '++' and '>>' of C. So while we may
not need multi-character operators, it's nice to know how to get
them if necessary.
Needless to say, we can handle operators very much the same way
as the other tokens. Let's start with a recognizer:
{--------------------------------------------------------------}
{ Recognize Any Operator }
function IsOp(c: char): boolean;
begin
IsOp := c in ['+', '-', '*', '/', '<', '>', ':', '='];
end;
{--------------------------------------------------------------}
It's important to note that we DON'T have to include every
possible operator in this list. For example, the paretheses
aren't included, nor is the terminating period. The current
version of Scan handles single-character operators just fine as
it is. The list above includes only those characters that can
appear in multi-character operators. (For specific languages, of
course, the list can always be edited.)
Now, let's modify Scan to read:
{--------------------------------------------------------------}
{ Lexical Scanner }
Function Scan: string;
begin
while Look = CR do
Fin;
if IsAlpha(Look) then
Scan := GetName
else if IsDigit(Look) then
Scan := GetNum
else if IsOp(Look) then
Scan := GetOp
else begin
Scan := Look;
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
Try the program now. You will find that any code fragments you
care to throw at it will be neatly broken up into individual
tokens.
LISTS, COMMAS AND COMMAND LINES
Before getting back to the main thrust of our study, I'd like to
get on my soapbox for a moment.
How many times have you worked with a program or operating system
that had rigid rules about how you must separate items in a list?
(Try, the last time you used MSDOS!) Some programs require
spaces as delimiters, and some require commas. Worst of all,
some require both, in different places. Most are pretty
unforgiving about violations of their rules.
I think this is inexcusable. It's too easy to write a parser
that will handle both spaces and commas in a flexible way.
Consider the following procedure:
{--------------------------------------------------------------}
{ Skip Over a Comma }
procedure SkipComma;
begin
SkipWhite;
if Look = ',' then begin
GetChar;
SkipWhite;
end;
end;
{--------------------------------------------------------------}
This eight-line procedure will skip over a delimiter consisting
of any number (including zero) of spaces, with zero or one comma
embedded in the string.
TEMPORARILY, change the call to SkipWhite in Scan to a call to
SkipComma, and try inputting some lists. Works nicely, eh?
Don't you wish more software authors knew about SkipComma?
For the record, I found that adding the equivalent of SkipComma
to my Z80 assembler-language programs took all of 6 (six) extra
bytes of code. Even in a 64K machine, that's not a very high
price to pay for user-friendliness!
I think you can see where I'm going here. Even if you never
write a line of a compiler code in your life, there are places in
every program where you can use the concepts of parsing. Any
program that processes a command line needs them. In fact, if
you think about it for a bit, you'll have to conclude that any
time you write a program that processes user inputs, you're
defining a language. People communicate with languages, and the
syntax implicit in your program defines that language. The real
question is: are you going to define it deliberately and
explicitly, or just let it turn out to be whatever the program
ends up parsing?
I claim that you'll have a better, more user-friendly program if
you'll take the time to define the syntax explicitly. Write down
the syntax equations or draw the railroad-track diagrams, and
code the parser using the techniques I've shown you here. You'll
end up with a better program, and it will be easier to write, to
boot.
GETTING FANCY
OK, at this point we have a pretty nice lexical scanner that will
break an input stream up into tokens. We could use it as it
stands and have a servicable compiler. But there are some other
aspects of lexical scanning that we need to cover.
The main consideration is <shudder> efficiency. Remember when we
were dealing with single-character tokens, every test was a
comparison of a single character, Look, with a byte constant. We
also used the Case statement heavily.
With the multi-character tokens being returned by Scan, all those
tests now become string comparisons. Much slower. And not only
slower, but more awkward, since there is no string equivalent of
the Case statement in Pascal. It seems especially wasteful to
test for what used to be single characters ... the '=', '+', and
other operators ... using string comparisons.
Using string comparison is not impossible ... Ron Cain used just
that approach in writing Small C. Since we're sticking to the
KISS principle here, we would be truly justified in settling for
this approach. But then I would have failed to tell you about
one of the key approaches used in "real" compilers.
You have to remember: the lexical scanner is going to be called a
_LOT_! Once for every token in the whole source program, in
fact. Experiments have indicated that the average compiler
spends anywhere from 20% to 40% of its time in the scanner
routines. If there were ever a place where efficiency deserves
real consideration, this is it.
For this reason, most compiler writers ask the lexical scanner to
do a little more work, by "tokenizing" the input stream. The
idea is to match every token against a list of acceptable
keywords and operators, and return unique codes for each one
recognized. In the case of ordinary variable names or numbers,
we just return a code that says what kind of token they are, and
save the actual string somewhere else.
One of the first things we're going to need is a way to identify
keywords. We can always do it with successive IF tests, but it
surely would be nice if we had a general-purpose routine that
could compare a given string with a table of keywords. (By the
way, we're also going to need such a routine later, for dealing
with symbol tables.) This usually presents a problem in Pascal,
because standard Pascal doesn't allow for arrays of variable
lengths. It's a real bother to have to declare a different
search routine for every table. Standard Pascal also doesn't
allow for initializing arrays, so you tend to see code like
Table[1] := 'IF';
Table[2] := 'ELSE';
.
.
Table[n] := 'END';
which can get pretty old if there are many keywords.
Fortunately, Turbo Pascal 4.0 has extensions that eliminate both
of these problems. Constant arrays can be declared using TP's
"typed constant" facility, and the variable dimensions can be
handled with its C-like extensions for pointers.
First, modify your declarations like this:
{--------------------------------------------------------------}
{ Type Declarations }
type Symbol = string[8];
SymTab = array[1..1000] of Symbol;
TabPtr = ^SymTab;
{--------------------------------------------------------------}
(The dimension used in SymTab is not real ... no storage is
allocated by the declaration itself, and the number need only be
"big enough.")
Now, just beneath those declarations, add the following:
{--------------------------------------------------------------}
{ Definition of Keywords and Token Types }
const KWlist: array [1..4] of Symbol ('IF', 'ELSE', 'ENDIF', 'END');
{--------------------------------------------------------------}
Next, insert the following new function:
{--------------------------------------------------------------}
{ Table Lookup }
{ If the input string matches a table entry, return the entry
index. If not, return a zero. }
function Lookup(T: TabPtr; s: string; n: integer): integer;
var i: integer;
found: boolean;
begin
found := false;
i := n;
while (i > 0) and not found do
if s = T^[i] then
found := true
else
dec(i);
Lookup := i;
end;
{--------------------------------------------------------------}
To test it, you can temporarily change the main program as
follows:
{--------------------------------------------------------------}
{ Main Program }
begin
ReadLn(Token);
WriteLn(Lookup(Addr(KWList), Token, 4));
end.
{--------------------------------------------------------------}
Notice how Lookup is called: The Addr function sets up a pointer
to KWList, which gets passed to Lookup.
OK, give this a try. Since we're bypassing Scan here, you'll
have to type the keywords in upper case to get any matches.
Now that we can recognize keywords, the next thing is to arrange
to return codes for them.
So what kind of code should we return? There are really only two
reasonable choices. This seems like an ideal application for the
Pascal enumerated type. For example, you can define something
like
SymType = (IfSym, ElseSym, EndifSym, EndSym, Ident, Number,
Operator);
and arrange to return a variable of this type. Let's give it a
try. Insert the line above into your type definitions.
Now, add the two variable declarations:
Token: Symtype; { Current Token }
Value: String[16]; { String Token of Look }
Modify the scanner to read:
{--------------------------------------------------------------}
{ Lexical Scanner }
procedure Scan;
var k: integer;
begin
while Look = CR do
Fin;
if IsAlpha(Look) then begin
Value := GetName;
k := Lookup(Addr(KWlist), Value, 4);
if k = 0 then
Token := Ident
else
Token := SymType(k - 1);
end
else if IsDigit(Look) then begin
Value := GetNum;
Token := Number;
end
else if IsOp(Look) then begin
Value := GetOp;
Token := Operator;
end
else begin
Value := Look;
Token := Operator;
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
(Notice that Scan is now a procedure, not a function.)
Finally, modify the main program to read:
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
repeat
Scan;
case Token of
Ident: write('Ident ');
Number: Write('Number ');
Operator: Write('Operator ');
IfSym, ElseSym, EndifSym, EndSym: Write('Keyword ');
end;
Writeln(Value);
until Token = EndSym;
end.
{--------------------------------------------------------------}
What we've done here is to replace the string Token used earlier
with an enumerated type. Scan returns the type in variable Token,
and returns the string itself in the new variable Value.
OK, compile this and give it a whirl. If everything goes right,
you should see that we are now recognizing keywords.
What we have now is working right, and it was easy to generate
from what we had earlier. However, it still seems a little
"busy" to me. We can simplify things a bit by letting GetName,
GetNum, GetOp, and Scan be procedures working with the global
variables Token and Value, thereby eliminating the local copies.
It also seems a little cleaner to move the table lookup into
GetName. The new form for the four procedures is, then:
{--------------------------------------------------------------}
{ Get an Identifier }
procedure GetName;
var k: integer;
begin
Value := '';
if not IsAlpha(Look) then Expected('Name');
while IsAlNum(Look) do begin
Value := Value + UpCase(Look);
GetChar;
end;
k := Lookup(Addr(KWlist), Value, 4);
if k = 0 then
Token := Ident
else
Token := SymType(k-1);
end;
{--------------------------------------------------------------}
{ Get a Number }
procedure GetNum;
begin
Value := '';
if not IsDigit(Look) then Expected('Integer');
while IsDigit(Look) do begin
Value := Value + Look;
GetChar;
end;
Token := Number;
end;
{--------------------------------------------------------------}
{ Get an Operator }
procedure GetOp;
begin
Value := '';
if not IsOp(Look) then Expected('Operator');
while IsOp(Look) do begin
Value := Value + Look;
GetChar;
end;
Token := Operator;
end;
{--------------------------------------------------------------}
{ Lexical Scanner }
procedure Scan;
var k: integer;
begin
while Look = CR do
Fin;
if IsAlpha(Look) then
GetName
else if IsDigit(Look) then
GetNum
else if IsOp(Look) then
GetOp
else begin
Value := Look;
Token := Operator;
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
RETURNING A CHARACTER
Essentially every scanner I've ever seen that was written in
Pascal used the mechanism of an enumerated type that I've just
described. It is certainly a workable mechanism, but it doesn't
seem the simplest approach to me.
For one thing, the list of possible symbol types can get pretty
long. Here, I've used just one symbol, "Operator," to stand for
all of the operators, but I've seen other designs that actually
return different codes for each one.
There is, of course, another simple type that can be returned as
a code: the character. Instead of returning the enumeration
value 'Operator' for a '+' sign, what's wrong with just returning
the character itself? A character is just as good a variable for
encoding the different token types, it can be used in case
statements easily, and it's sure a lot easier to type. What
could be simpler?
Besides, we've already had experience with the idea of encoding
keywords as single characters. Our previous programs are already
written that way, so using this approach will minimize the
changes to what we've already done.
Some of you may feel that this idea of returning character codes
is too mickey-mouse. I must admit it gets a little awkward for
multi-character operators like '<='. If you choose to stay with
the enumerated type, fine. For the rest, I'd like to show you
how to change what we've done above to support that approach.
First, you can delete the SymType declaration now ... we won't be
needing that. And you can change the type of Token to char.
Next, to replace SymType, add the following constant string:
const KWcode: string[5] = 'xilee';
(I'll be encoding all idents with the single character 'x'.)
Lastly, modify Scan and its relatives as follows:
{--------------------------------------------------------------}
{ Get an Identifier }
procedure GetName;
begin
Value := '';
if not IsAlpha(Look) then Expected('Name');
while IsAlNum(Look) do begin
Value := Value + UpCase(Look);
GetChar;
end;
Token := KWcode[Lookup(Addr(KWlist), Value, 4) + 1];
end;
{--------------------------------------------------------------}
{ Get a Number }
procedure GetNum;
begin
Value := '';
if not IsDigit(Look) then Expected('Integer');
while IsDigit(Look) do begin
Value := Value + Look;
GetChar;
end;
Token := '#';
end;
{--------------------------------------------------------------}
{ Get an Operator }
procedure GetOp;
begin
Value := '';
if not IsOp(Look) then Expected('Operator');
while IsOp(Look) do begin
Value := Value + Look;
GetChar;
end;
if Length(Value) = 1 then
Token := Value[1]
else
Token := '?';
end;
{--------------------------------------------------------------}
{ Lexical Scanner }
procedure Scan;
var k: integer;
begin
while Look = CR do
Fin;
if IsAlpha(Look) then
GetName
else if IsDigit(Look) then
GetNum
else if IsOp(Look) then begin
GetOp
else begin
Value := Look;
Token := '?';
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
repeat
Scan;
case Token of
'x': write('Ident ');
'#': Write('Number ');
'i', 'l', 'e': Write('Keyword ');
else Write('Operator ');
end;
Writeln(Value);
until Value = 'END';
end.
{--------------------------------------------------------------}
This program should work the same as the previous version. A
minor difference in structure, maybe, but it seems more
straightforward to me.
DISTRIBUTED vs CENTRALIZED SCANNERS
The structure for the lexical scanner that I've just shown you is
very conventional, and about 99% of all compilers use something
very close to it. This is not, however, the only possible
structure, or even always the best one.
The problem with the conventional approach is that the scanner
has no knowledge of context. For example, it can't distinguish
between the assignment operator '=' and the relational operator
'=' (perhaps that's why both C and Pascal use different strings
for the two). All the scanner can do is to pass the operator
along to the parser, which can hopefully tell from the context
which operator is meant. Similarly, a keyword like 'IF' has no
place in the middle of a math expression, but if one happens to
appear there, the scanner will see no problem with it, and will
return it to the parser, properly encoded as an 'IF'.
With this kind of approach, we are not really using all the
information at our disposal. In the middle of an expression, for
example, the parser "knows" that there is no need to look for
keywords, but it has no way of telling the scanner that. So the
scanner continues to do so. This, of course, slows down the
compilation.
In real-world compilers, the designers often arrange for more
information to be passed between parser and scanner, just to
avoid this kind of problem. But that can get awkward, and
certainly destroys a lot of the modularity of the structure.
The alternative is to seek some way to use the contextual
information that comes from knowing where we are in the parser.
This leads us back to the notion of a distributed scanner, in
which various portions of the scanner are called depending upon
the context.
In KISS, as in most languages, keywords ONLY appear at the
beginning of a statement. In places like expressions, they are
not allowed. Also, with one minor exception (the multi-character
relops) that is easily handled, all operators are single
characters, which means that we don't need GetOp at all.
So it turns out that even with multi-character tokens, we can
still always tell from the current lookahead character exactly
what kind of token is coming, except at the very beginning of a
statement.
Even at that point, the ONLY kind of token we can accept is an
identifier. We need only to determine if that identifier is a
keyword or the target of an assignment statement.
We end up, then, still needing only GetName and GetNum, which are
used very much as we've used them in earlier installments.
It may seem at first to you that this is a step backwards, and a
rather primitive approach. In fact, it is an improvement over
the classical scanner, since we're using the scanning routines
only where they're really needed. In places where keywords are
not allowed, we don't slow things down by looking for them.
MERGING SCANNER AND PARSER
Now that we've covered all of the theory and general aspects of
lexical scanning that we'll be needing, I'm FINALLY ready to back
up my claim that we can accomodate multi-character tokens with
minimal change to our previous work. To keep things short and
simple I will restrict myself here to a subset of what we've done
before; I'm allowing only one control construct (the IF) and no
Boolean expressions. That's enough to demonstrate the parsing of
both keywords and expressions. The extension to the full set of
constructs should be pretty apparent from what we've already
done.
All the elements of the program to parse this subset, using
single-character tokens, exist already in our previous programs.
I built it by judicious copying of these files, but I wouldn't
dare try to lead you through that process. Instead, to avoid any
confusion, the whole program is shown below:
{--------------------------------------------------------------}
program KISS;
{--------------------------------------------------------------}
{ Constant Declarations }
const TAB = ^I;
CR = ^M;
LF = ^J;
{--------------------------------------------------------------}
{ Type Declarations }
type Symbol = string[8];
SymTab = array[1..1000] of Symbol;
TabPtr = ^SymTab;
{--------------------------------------------------------------}
{ Variable Declarations }
var Look : char; { Lookahead Character }
Lcount: integer; { Label Counter }
{--------------------------------------------------------------}
{ Read New Character From Input Stream }
procedure GetChar;
begin
Read(Look);
end;
{--------------------------------------------------------------}
{ Report an Error }
procedure Error(s: string);
begin
WriteLn;
WriteLn(^G, 'Error: ', s, '.');
end;
{--------------------------------------------------------------}
{ Report Error and Halt }
procedure Abort(s: string);
begin
Error(s);
Halt;
end;
{--------------------------------------------------------------}
{ Report What Was Expected }
procedure Expected(s: string);
begin
Abort(s + ' Expected');
end;
{--------------------------------------------------------------}
{ Recognize an Alpha Character }
function IsAlpha(c: char): boolean;
begin
IsAlpha := UpCase(c) in ['A'..'Z'];
end;
{--------------------------------------------------------------}
{ Recognize a Decimal Digit }
function IsDigit(c: char): boolean;
begin
IsDigit := c in ['0'..'9'];
end;
{--------------------------------------------------------------}
{ Recognize an AlphaNumeric Character }
function IsAlNum(c: char): boolean;
begin
IsAlNum := IsAlpha(c) or IsDigit(c);
end;
{--------------------------------------------------------------}
{ Recognize an Addop }
function IsAddop(c: char): boolean;
begin
IsAddop := c in ['+', '-'];
end;
{--------------------------------------------------------------}
{ Recognize a Mulop }
function IsMulop(c: char): boolean;
begin
IsMulop := c in ['*', '/'];
end;
{--------------------------------------------------------------}
{ Recognize White Space }
function IsWhite(c: char): boolean;
begin
IsWhite := c in [' ', TAB];
end;
{--------------------------------------------------------------}
{ Skip Over Leading White Space }
procedure SkipWhite;
begin
while IsWhite(Look) do
GetChar;
end;
{--------------------------------------------------------------}
{ Match a Specific Input Character }
procedure Match(x: char);
begin
if Look <> x then Expected('''' + x + '''');
GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Skip a CRLF }
procedure Fin;
begin
if Look = CR then GetChar;
if Look = LF then GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Get an Identifier }
function GetName: char;
begin
while Look = CR do
Fin;
if not IsAlpha(Look) then Expected('Name');
Getname := UpCase(Look);
GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Get a Number }
function GetNum: char;
begin
if not IsDigit(Look) then Expected('Integer');
GetNum := Look;
GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Generate a Unique Label }
function NewLabel: string;
var S: string;
begin
Str(LCount, S);
NewLabel := 'L' + S;
Inc(LCount);
end;
{--------------------------------------------------------------}
{ Post a Label To Output }
procedure PostLabel(L: string);
begin
WriteLn(L, ':');
end;
{--------------------------------------------------------------}
{ Output a String with Tab }
procedure Emit(s: string);
begin
Write(TAB, s);
end;
{--------------------------------------------------------------}
{ Output a String with Tab and CRLF }
procedure EmitLn(s: string);
begin
Emit(s);
WriteLn;
end;
{---------------------------------------------------------------}
{ Parse and Translate an Identifier }
procedure Ident;
var Name: char;
begin
Name := GetName;
if Look = '(' then begin
Match('(');
Match(')');
EmitLn('BSR ' + Name);
end
else
EmitLn('MOVE ' + Name + '(PC),D0');
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Factor }
procedure Expression; Forward;
procedure Factor;
begin
if Look = '(' then begin
Match('(');
Expression;
Match(')');
end
else if IsAlpha(Look) then
Ident
else
EmitLn('MOVE #' + GetNum + ',D0');
end;
{---------------------------------------------------------------}
{ Parse and Translate the First Math Factor }
procedure SignedFactor;
var s: boolean;
begin
s := Look = '-';
if IsAddop(Look) then begin
GetChar;
SkipWhite;
end;
Factor;
if s then
EmitLn('NEG D0');
end;
{--------------------------------------------------------------}
{ Recognize and Translate a Multiply }
procedure Multiply;
begin
Match('*');
Factor;
EmitLn('MULS (SP)+,D0');
end;
{-------------------------------------------------------------}
{ Recognize and Translate a Divide }
procedure Divide;
begin
Match('/');
Factor;
EmitLn('MOVE (SP)+,D1');
EmitLn('EXS.L D0');
EmitLn('DIVS D1,D0');
end;
{---------------------------------------------------------------}
{ Completion of Term Processing (called by Term and FirstTerm }
procedure Term1;
begin
while IsMulop(Look) do begin
EmitLn('MOVE D0,-(SP)');
case Look of
'*': Multiply;
'/': Divide;
end;
end;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Term }
procedure Term;
begin
Factor;
Term1;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Term with Possible Leading Sign }
procedure FirstTerm;
begin
SignedFactor;
Term1;
end;
{---------------------------------------------------------------}
{ Recognize and Translate an Add }
procedure Add;
begin
Match('+');
Term;
EmitLn('ADD (SP)+,D0');
end;
{---------------------------------------------------------------}
{ Recognize and Translate a Subtract }
procedure Subtract;
begin
Match('-');
Term;
EmitLn('SUB (SP)+,D0');
EmitLn('NEG D0');
end;
{---------------------------------------------------------------}
{ Parse and Translate an Expression }
procedure Expression;
begin
FirstTerm;
while IsAddop(Look) do begin
EmitLn('MOVE D0,-(SP)');
case Look of
'+': Add;
'-': Subtract;
end;
end;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Boolean Condition }
{ This version is a dummy }
Procedure Condition;
begin
EmitLn('Condition');
end;
{---------------------------------------------------------------}
{ Recognize and Translate an IF Construct }
procedure Block;
Forward;
procedure DoIf;
var L1, L2: string;
begin
Match('i');
Condition;
L1 := NewLabel;
L2 := L1;
EmitLn('BEQ ' + L1);
Block;
if Look = 'l' then begin
Match('l');
L2 := NewLabel;
EmitLn('BRA ' + L2);
PostLabel(L1);
Block;
end;
PostLabel(L2);
Match('e');
end;
{--------------------------------------------------------------}
{ Parse and Translate an Assignment Statement }
procedure Assignment;
var Name: char;
begin
Name := GetName;
Match('=');
Expression;
EmitLn('LEA ' + Name + '(PC),A0');
EmitLn('MOVE D0,(A0)');
end;
{--------------------------------------------------------------}
{ Recognize and Translate a Statement Block }
procedure Block;
begin
while not(Look in ['e', 'l']) do begin
case Look of
'i': DoIf;
CR: while Look = CR do
Fin;
else Assignment;
end;
end;
end;
{--------------------------------------------------------------}
{ Parse and Translate a Program }
procedure DoProgram;
begin
Block;
if Look <> 'e' then Expected('END');
EmitLn('END')
end;
{--------------------------------------------------------------}
{ Initialize }
procedure Init;
begin
LCount := 0;
GetChar;
end;
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
DoProgram;
end.
{--------------------------------------------------------------}
A couple of comments:
(1) The form for the expression parser, using FirstTerm, etc.,
is a little different from what you've seen before. It's
yet another variation on the same theme. Don't let it throw
you ... the change is not required for what follows.
(2) Note that, as usual, I had to add calls to Fin at strategic
spots to allow for multiple lines.
Before we proceed to adding the scanner, first copy this file and
verify that it does indeed parse things correctly. Don't forget
the "codes": 'i' for IF, 'l' for ELSE, and 'e' for END or ENDIF.
If the program works, then let's press on. In adding the scanner
modules to the program, it helps to have a systematic plan. In
all the parsers we've written to date, we've stuck to a
convention that the current lookahead character should always be
a non-blank character. We preload the lookahead character in
Init, and keep the "pump primed" after that. To keep the thing
working right at newlines, we had to modify this a bit and treat
the newline as a legal token.
In the multi-character version, the rule is similar: The current
lookahead character should always be left at the BEGINNING of the
next token, or at a newline.
The multi-character version is shown next. To get it, I've made
the following changes:
o Added the variables Token and Value, and the type definitions
needed by Lookup.
o Added the definitions of KWList and KWcode.
o Added Lookup.
o Replaced GetName and GetNum by their multi-character versions.
(Note that the call to Lookup has been moved out of GetName,
so that it will not be executed for calls within an
expression.)
o Created a new, vestigial Scan that calls GetName, then scans
for keywords.
o Created a new procedure, MatchString, that looks for a
specific keyword. Note that, unlike Match, MatchString does
NOT read the next keyword.
o Modified Block to call Scan.
o Changed the calls to Fin a bit. Fin is now called within
GetName.
Here is the program in its entirety:
{--------------------------------------------------------------}
program KISS;
{--------------------------------------------------------------}
{ Constant Declarations }
const TAB = ^I;
CR = ^M;
LF = ^J;
{--------------------------------------------------------------}
{ Type Declarations }
type Symbol = string[8];
SymTab = array[1..1000] of Symbol;
TabPtr = ^SymTab;
{--------------------------------------------------------------}
{ Variable Declarations }
var Look : char; { Lookahead Character }
Token : char; { Encoded Token }
Value : string[16]; { Unencoded Token }
Lcount: integer; { Label Counter }
{--------------------------------------------------------------}
{ Definition of Keywords and Token Types }
const KWlist: array [1..4] of Symbol ('IF', 'ELSE', 'ENDIF', 'END');
const KWcode: string[5] = 'xilee';
{--------------------------------------------------------------}
{ Read New Character From Input Stream }
procedure GetChar;
begin
Read(Look);
end;
{--------------------------------------------------------------}
{ Report an Error }
procedure Error(s: string);
begin
WriteLn;
WriteLn(^G, 'Error: ', s, '.');
end;
{--------------------------------------------------------------}
{ Report Error and Halt }
procedure Abort(s: string);
begin
Error(s);
Halt;
end;
{--------------------------------------------------------------}
{ Report What Was Expected }
procedure Expected(s: string);
begin
Abort(s + ' Expected');
end;
{--------------------------------------------------------------}
{ Recognize an Alpha Character }
function IsAlpha(c: char): boolean;
begin
IsAlpha := UpCase(c) in ['A'..'Z'];
end;
{--------------------------------------------------------------}
{ Recognize a Decimal Digit }
function IsDigit(c: char): boolean;
begin
IsDigit := c in ['0'..'9'];
end;
{--------------------------------------------------------------}
{ Recognize an AlphaNumeric Character }
function IsAlNum(c: char): boolean;
begin
IsAlNum := IsAlpha(c) or IsDigit(c);
end;
{--------------------------------------------------------------}
{ Recognize an Addop }
function IsAddop(c: char): boolean;
begin
IsAddop := c in ['+', '-'];
end;
{--------------------------------------------------------------}
{ Recognize a Mulop }
function IsMulop(c: char): boolean;
begin
IsMulop := c in ['*', '/'];
end;
{--------------------------------------------------------------}
{ Recognize White Space }
function IsWhite(c: char): boolean;
begin
IsWhite := c in [' ', TAB];
end;
{--------------------------------------------------------------}
{ Skip Over Leading White Space }
procedure SkipWhite;
begin
while IsWhite(Look) do
GetChar;
end;
{--------------------------------------------------------------}
{ Match a Specific Input Character }
procedure Match(x: char);
begin
if Look <> x then Expected('''' + x + '''');
GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Skip a CRLF }
procedure Fin;
begin
if Look = CR then GetChar;
if Look = LF then GetChar;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Table Lookup }
function Lookup(T: TabPtr; s: string; n: integer): integer;
var i: integer;
found: boolean;
begin
found := false;
i := n;
while (i > 0) and not found do
if s = T^[i] then
found := true
else
dec(i);
Lookup := i;
end;
{--------------------------------------------------------------}
{ Get an Identifier }
procedure GetName;
begin
while Look = CR do
Fin;
if not IsAlpha(Look) then Expected('Name');
Value := '';
while IsAlNum(Look) do begin
Value := Value + UpCase(Look);
GetChar;
end;
SkipWhite;
end;
{--------------------------------------------------------------}
{ Get a Number }
procedure GetNum;
begin
if not IsDigit(Look) then Expected('Integer');
Value := '';
while IsDigit(Look) do begin
Value := Value + Look;
GetChar;
end;
Token := '#';
SkipWhite;
end;
{--------------------------------------------------------------}
{ Get an Identifier and Scan it for Keywords }
procedure Scan;
begin
GetName;
Token := KWcode[Lookup(Addr(KWlist), Value, 4) + 1];
end;
{--------------------------------------------------------------}
{ Match a Specific Input String }
procedure MatchString(x: string);
begin
if Value <> x then Expected('''' + x + '''');
end;
{--------------------------------------------------------------}
{ Generate a Unique Label }
function NewLabel: string;
var S: string;
begin
Str(LCount, S);
NewLabel := 'L' + S;
Inc(LCount);
end;
{--------------------------------------------------------------}
{ Post a Label To Output }
procedure PostLabel(L: string);
begin
WriteLn(L, ':');
end;
{--------------------------------------------------------------}
{ Output a String with Tab }
procedure Emit(s: string);
begin
Write(TAB, s);
end;
{--------------------------------------------------------------}
{ Output a String with Tab and CRLF }
procedure EmitLn(s: string);
begin
Emit(s);
WriteLn;
end;
{---------------------------------------------------------------}
{ Parse and Translate an Identifier }
procedure Ident;
begin
GetName;
if Look = '(' then begin
Match('(');
Match(')');
EmitLn('BSR ' + Value);
end
else
EmitLn('MOVE ' + Value + '(PC),D0');
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Factor }
procedure Expression; Forward;
procedure Factor;
begin
if Look = '(' then begin
Match('(');
Expression;
Match(')');
end
else if IsAlpha(Look) then
Ident
else begin
GetNum;
EmitLn('MOVE #' + Value + ',D0');
end;
end;
{---------------------------------------------------------------}
{ Parse and Translate the First Math Factor }
procedure SignedFactor;
var s: boolean;
begin
s := Look = '-';
if IsAddop(Look) then begin
GetChar;
SkipWhite;
end;
Factor;
if s then
EmitLn('NEG D0');
end;
{--------------------------------------------------------------}
{ Recognize and Translate a Multiply }
procedure Multiply;
begin
Match('*');
Factor;
EmitLn('MULS (SP)+,D0');
end;
{-------------------------------------------------------------}
{ Recognize and Translate a Divide }
procedure Divide;
begin
Match('/');
Factor;
EmitLn('MOVE (SP)+,D1');
EmitLn('EXS.L D0');
EmitLn('DIVS D1,D0');
end;
{---------------------------------------------------------------}
{ Completion of Term Processing (called by Term and FirstTerm }
procedure Term1;
begin
while IsMulop(Look) do begin
EmitLn('MOVE D0,-(SP)');
case Look of
'*': Multiply;
'/': Divide;
end;
end;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Term }
procedure Term;
begin
Factor;
Term1;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Math Term with Possible Leading Sign }
procedure FirstTerm;
begin
SignedFactor;
Term1;
end;
{---------------------------------------------------------------}
{ Recognize and Translate an Add }
procedure Add;
begin
Match('+');
Term;
EmitLn('ADD (SP)+,D0');
end;
{---------------------------------------------------------------}
{ Recognize and Translate a Subtract }
procedure Subtract;
begin
Match('-');
Term;
EmitLn('SUB (SP)+,D0');
EmitLn('NEG D0');
end;
{---------------------------------------------------------------}
{ Parse and Translate an Expression }
procedure Expression;
begin
FirstTerm;
while IsAddop(Look) do begin
EmitLn('MOVE D0,-(SP)');
case Look of
'+': Add;
'-': Subtract;
end;
end;
end;
{---------------------------------------------------------------}
{ Parse and Translate a Boolean Condition }
{ This version is a dummy }
Procedure Condition;
begin
EmitLn('Condition');
end;
{---------------------------------------------------------------}
{ Recognize and Translate an IF Construct }
procedure Block; Forward;
procedure DoIf;
var L1, L2: string;
begin
Condition;
L1 := NewLabel;
L2 := L1;
EmitLn('BEQ ' + L1);
Block;
if Token = 'l' then begin
L2 := NewLabel;
EmitLn('BRA ' + L2);
PostLabel(L1);
Block;
end;
PostLabel(L2);
MatchString('ENDIF');
end;
{--------------------------------------------------------------}
{ Parse and Translate an Assignment Statement }
procedure Assignment;
var Name: string;
begin
Name := Value;
Match('=');
Expression;
EmitLn('LEA ' + Name + '(PC),A0');
EmitLn('MOVE D0,(A0)');
end;
{--------------------------------------------------------------}
{ Recognize and Translate a Statement Block }
procedure Block;
begin
Scan;
while not (Token in ['e', 'l']) do begin
case Token of
'i': DoIf;
else Assignment;
end;
Scan;
end;
end;
{--------------------------------------------------------------}
{ Parse and Translate a Program }
procedure DoProgram;
begin
Block;
MatchString('END');
EmitLn('END')
end;
{--------------------------------------------------------------}
{ Initialize }
procedure Init;
begin
LCount := 0;
GetChar;
end;
{--------------------------------------------------------------}
{ Main Program }
begin
Init;
DoProgram;
end.
{--------------------------------------------------------------}
Compare this program with its single-character counterpart. I
think you will agree that the differences are minor.
CONCLUSION
At this point, you have learned how to parse and generate code
for expressions, Boolean expressions, and control structures.
You have now learned how to develop lexical scanners, and how to
incorporate their elements into a translator. You have still not
seen ALL the elements combined into one program, but on the basis
of what we've done before you should find it a straightforward
matter to extend our earlier programs to include scanners.
We are very close to having all the elements that we need to
build a real, functional compiler. There are still a few things
missing, notably procedure calls and type definitions. We will
deal with those in the next few sessions. Before doing so,
however, I thought it would be fun to turn the translator above
into a true compiler. That's what we'll be doing in the next
installment.
Up till now, we've taken a rather bottom-up approach to parsing,
beginning with low-level constructs and working our way up. In
the next installment, I'll also be taking a look from the top
down, and we'll discuss how the structure of the translator is
altered by changes in the language definition.
See you then.
*****************************************************************
* *
* COPYRIGHT NOTICE *
* *
* Copyright (C) 1988 Jack W. Crenshaw. All rights reserved. *
* *
*****************************************************************
--
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