You could add DCG-rules that describe what a lexem is. For example:
lexem(key(K)) --> % key(K) is a lexem
key(K). % if K is a key
lexem(sep(S)) --> % sep(S) is a lexem
sep(S). % if S is a separator
% rules for your keywords here
key(read) -->
"read".
key(write) -->
"write".
% rules for your seperators
sep(;) -->
";".
sep(:=) -->
":=".
You also might like to add rules to your lexer for whitespace, e.g.:
lexer(Ts) -->
whitespace, % whitespace is ignored
lexer(Ts).
whitespace -->
[W],
{char_type(W,space)}. % space is whitespace
With this minimal example you can already query a little bit:
?- phrase(lexer(L), "read ; write").
L = [key(read),sep(;),key(write)] ? ;
no
The identifiers and the number are little bit trickier, as you probably want the longest input match, e.g. "SUM"
matched as id('SUM')
instead of id('S'), id('U'), id('M')
. So it's opportune to write identifier//1 such that it produces the longest match as first solution and to use the cut to not search for further solutions. You can use the built-in predicates atom_chars/2 and number_chars/2 to convert between atoms/strings and numbers/strings. The rest is pretty self-explanatory:
lexem(id(IA)) -->
identifier(I),
!, % longest input match
{atom_chars(IA,I)}.
lexem(int(NA)) -->
number(A),
!, % longest input match
{number_chars(NA,A)}.
identifier([C|Cs]) --> % identifiers are
capital(C), % capital letters
ident(Cs). % followed by other cl's
ident([C|Cs]) -->
capital(C),
ident(Cs).
ident([]) -->
[].
capital(C) -->
[C], % capitals are
{char_type(C,upper)}. % uppercase letters
number([D|Ds]) --> % numbers are
digit(D), % a digit followed
digits(Ds). % by other digits
digits([D|Ds]) -->
digit(D),
digits(Ds).
digits([]) -->
[].
digit(D) --> % a single digit
[D],
{char_type(D,digit)}.
Now you can query for your above example:
?- phrase(lexer(L), "read N; SUM := 0; ").
L = [key(read), id('N'), sep(;), id('SUM'), sep(:=), int('0'), sep(;)] ;
false.
lex(Tail)
you meanlexer(Tail)
. Andlexem --> ?????
should belexem(Token) --> ?????
.?????
describes what a token looks like. The input stream to your DCG is going to be your string, one character at a time. So start from there, knowing how you have seen a whole token, character by character.