Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've been writing up a micro-mini-lisp based on the encoding in minilisp, the McCarthy paper (as emended by the Roots of Lisp), and using a (possibly objectionable) style based on the J Incunabulum. And using the PP_NARG macro from here.

It mostly seems to work, including the reader code. But, although eval(ATOM(QUOTE X)) is correctly yielding T, and eval(ATOM(QUOTE(X Y Z))) is correctly yielding NIL, and eval(QUOTE X) yields X, and eval(QUOTE(X Y Z)) yields (X Y Z); the weird result is eval(QUOTE(ATOM(QUOTE X))) yields ATOM, not the full sub-expression ATOM(QUOTE X).

I suppose it's a long-shot, and I didn't exactly make it easy, but can anyone help me figure out where it's going wrong with the quoting?

By the way, unlike my description above, the interpreter is limited to single-character tokens, so QUOTE is Q and ATOM is A.

/*cf.
http://www.ioccc.org/1989/jar.2.c
http://leon.bottou.org/projects/minilisp
http://www.jsoftware.com/jwiki/Essays/Incunabulum
http://www-formal.stanford.edu/jmc/recursive/recursive.html
http://www.paulgraham.com/rootsoflisp.html
http://codegolf.stackexchange.com/questions/284/write-an-interpreter-for-the-untyped-lambda-calculus/3290#3290
 */
#include<assert.h>
#include<signal.h>
#include<stdarg.h>
#include<stdio.h>
#include<stdlib.h>
#include<unistd.h>
#include"ppnarg.h"
#define R return
int*m,*n,msz;
tag(x){R x&3;}
val(x){R x>>2;}
#define ALPHA 'T'
#define NIL   (0)
#define T atom(ALPHA)
atom(x){R((x-ALPHA)<<2)|1;}
number(x){R(x<<2)|3;}
listp(x){R tag(x)==0;}
atomp(x){R tag(x)==1;}
objectp(x){R tag(x)==2;}
numberp(x){R tag(x)==3;}
consp(x){R x&&listp(x);}
car(x){R consp(x)?val(x)[m]:0;}
cdr(x){R consp(x)?val(x)[m+1]:0;}
caar(x){R car(car(x));}
cadr(x){R car(cdr(x));}
cadar(x){R car(cdr(car(x)));}
caddr(x){R car(cdr(cdr(x)));}
caddar(x){R car(cdr(cdr(car(x))));}
cons(x,y){int z;R z=n-m,*n++=x,*n++=y,z<<2;}
rplaca(x,y){R consp(x)?val(x)[m]=y:0;}
rplacd(x,y){R consp(x)?val(x)[m+1]=y:0;}
eq(x,y){R atomp(x)&&atomp(y)?x==y:0;}
ff(x){R atomp(x)?x:ff(car(x));}
subst(x,y,z){R atomp(z)?(eq(z,y)?x:z):
        cons(subst(x,y,car(z)),subst(x,y,cdr(z)));}
equal(x,y){R(atomp(x)&&atomp(y)&&eq(x,y))
    ||(consp(x)&&consp(y)&&equal(car(x),car(y))&&equal(cdr(x),cdr(y)));}
null(x){R listp(x)&&(val(x)==0);}
lista(int c,int*a){int z=NIL;for(;c;)z=cons(a[--c],z);R z;}
listn(int c,...){va_list a;int*z=n;
    va_start(a,c);for(;c--;)*n++=va_arg(a,int);va_end(a);
    c=n-z;R lista(c,z);}
#define list(...) listn(PP_NARG(__VA_ARGS__),__VA_ARGS__)
append(x,y){R null(x)?y:cons(car(x),append(cdr(x),y));}
among(x,y){R !null(y)&&equal(x,car(y))||among(x,cdr(y));}
pair(x,y){R null(x)&&null(y)?NIL:
    consp(x)&&consp(y)?cons(list(car(x),car(y)),pair(cdr(x),cdr(y))):0;}
assoc(x,y){R eq(caar(y),x)?cadar(y):assoc(x,cdr(y));}
sub2(x,z){R null(x)?z:eq(caar(x),z)?cadar(x):sub2(cdr(x),z);}
sublis(x,y){R atom(y)?sub2(x,y):cons(sublis(x,car(y)),sublis(x,cdr(y)));}
apply(f,args){R eval(cons(f,appq(args)),NIL);}
appq(m){R null(m)?NIL:cons(list(atom('Q'),car(m)),appq(cdr(m)));}
eval(e,a){R numberp(e)?e:
    atomp(e)?assoc(e,a):
    atomp(car(e))?(
    /*QUOTE*/      eq(car(e),atom('Q'))?cadr(e):
    /*ATOM*/       eq(car(e),atom('A'))?atomp(eval(cadr(e),a)):
    /*EQ*/         eq(car(e),atom('E'))?eval(cadr(e),a)==eval(caddr(e),a):
    /*COND*/       eq(car(e),atom('D'))?evcon(cadr(e),a):
    /*CAR*/        eq(car(e),atom('H'))?car(eval(cadr(e),a)):
    /*CDR*/        eq(car(e),atom('R'))?cdr(eval(cadr(e),a)):
    /*CONS*/       eq(car(e),atom('C'))?cons(eval(cadr(e),a),eval(caddr(e),a)):
        //eval(cons(assoc(car(e),a),evlis(cdr(e),a)),a) ):/*cf. Roots of Lisp*/
        eval(cons(assoc(car(e),a),cdr(e)),a) ):
    eq(caar(e),atom('M'))?          /*LABEL*/
        eval(cons(caddar(e),cdr(e)),cons(list(cadar(e),car(e)),a)):
    eq(caar(e),atom('L'))?          /*LAMBDA*/
        eval(caddar(e),append(pair(cadar(e),evlis(cdr(e),a)),a)):0;}
evcon(c,a){R eval(caar(c),a)?eval(cadar(c),a):evcon(cdr(c),a);}
evlis(m,a){R null(m)?NIL:cons(eval(car(m),a),evlis(cdr(m),a));}
maplist(x,f){R null(x)?NIL:cons(apply(f,x),maplist(cdr(x),f));}

prn(x){atomp(x)?printf("'%c' ",val(x)+ALPHA):
    numberp(x)?printf("%d ",val(x)):
    objectp(x)?printf("OBJ %d ",val(x)):
    consp(x)?printf("( "),prn(car(x)),prn(cdr(x)),printf(") "):
    0//printf("NIL ")
    ;}

#define LPAR '('
#define RPAR ')'
rd(char **p){int t,u,v,z;
    if(!(**p))R 0;
    if(**p==' ')R ++(*p),rd(p);
    if(**p==RPAR)R ++(*p),atom(RPAR);
    if(**p==LPAR){++(*p);
        z=NIL;u=rd(p);z=cons(u,z);
        while(u=rd(p),!eq(u,atom(RPAR)))
            //u=cons(u,NIL),
            z=append(z,u);
        R z;}
    if(**p>='0'&&**p<='9')R ++(*p),number(*((*p)-1)-'0');
    R ++(*p),atom(*((*p)-1));}

void fix(x){signal(SIGSEGV,fix);sbrk(msz);msz*=2;}
int main(){
    assert((-1>>1)==-1); /*right-shift must be sign-preserving*/
    n=m=sbrk(sizeof(int)*(msz=getpagesize()));*n++=0;*n++=0;
    //signal(SIGSEGV,fix); /*might let it run longer, obscures problems*/
    char *s="(Q (A (Q X)))";
    char *p=s;
    int a=rd(&p);
    printf("%s\n",s);

    int x,y;
    x = a;
    y = NIL;

    prn(x);
    x = eval(x,y);
    printf("\nEVAL\n");

    printf("x: %d\n", x);
    printf("0: %o\n", x);
    printf("0x: %x\n", x);
    printf("tag(x): %d\n",tag(x));
    printf("val(x): %d\n",val(x));
    printf("car(x): %d\n",car(x));
    printf("cdr(x): %d\n",cdr(x));
    prn(x);

    R 0;
}

Here's the same code processed by indent.

/*cf.
http://www.ioccc.org/1989/jar.2.c
http://leon.bottou.org/projects/minilisp
http://www.jsoftware.com/jwiki/Essays/Incunabulum
http://www-formal.stanford.edu/jmc/recursive/recursive.html
http://www.paulgraham.com/rootsoflisp.html
 */
#include<assert.h>
#include<signal.h>
#include<stdarg.h>
#include<stdio.h>
#include<stdlib.h>
#include<unistd.h>
#include"ppnarg.h"
#define R return
int *m, *n, msz;
tag (x)
{
  R x & 3;
}

val (x)
{
  R x >> 2;
}

#define ALPHA 'T'
#define NIL   (0)
#define T atom(ALPHA)
atom (x)
{
  R ((x - ALPHA) << 2) | 1;
}

number (x)
{
  R (x << 2) | 3;
}

listp (x)
{
  R tag (x) == 0;
}

atomp (x)
{
  R tag (x) == 1;
}

objectp (x)
{
  R tag (x) == 2;
}

numberp (x)
{
  R tag (x) == 3;
}

consp (x)
{
  R x && listp (x);
}

car (x)
{
  R consp (x) ? val (x)[m] : 0;
}

cdr (x)
{
  R consp (x) ? val (x)[m + 1] : 0;
}

caar (x)
{
  R car (car (x));
}

cadr (x)
{
  R car (cdr (x));
}

cadar (x)
{
  R car (cdr (car (x)));
}

caddr (x)
{
  R car (cdr (cdr (x)));
}

caddar (x)
{
  R car (cdr (cdr (car (x))));
}

cons (x, y)
{
  int z;
  R z = n - m, *n++ = x, *n++ = y, z << 2;
}

rplaca (x, y)
{
  R consp (x) ? val (x)[m] = y : 0;
}

rplacd (x, y)
{
  R consp (x) ? val (x)[m + 1] = y : 0;
}

eq (x, y)
{
  R atomp (x) && atomp (y) ? x == y : 0;
}

ff (x)
{
  R atomp (x) ? x : ff (car (x));
}

subst (x, y, z)
{
  R atomp (z) ? (eq (z, y) ? x : z) :
    cons (subst (x, y, car (z)), subst (x, y, cdr (z)));
}

equal (x, y)
{
  R (atomp (x) && atomp (y) && eq (x, y))
    || (consp (x) && consp (y) && equal (car (x), car (y))
    && equal (cdr (x), cdr (y)));
}

null (x)
{
  R listp (x) && (val (x) == 0);
}

lista (int c, int *a)
{
  int z = NIL;
  for (; c;)
    z = cons (a[--c], z);
  R z;
}

listn (int c, ...)
{
  va_list a;
  int *z = n;
  va_start (a, c);
  for (; c--;)
    *n++ = va_arg (a, int);
  va_end (a);
  c = n - z;
  R lista (c, z);
}

#define list(...) listn(PP_NARG(__VA_ARGS__),__VA_ARGS__)
append (x, y)
{
  R null (x) ? y : cons (car (x), append (cdr (x), y));
}

among (x, y)
{
  R ! null (y) && equal (x, car (y)) || among (x, cdr (y));
}

pair (x, y)
{
  R null (x) && null (y) ? NIL :
    consp (x)
    && consp (y) ? cons (list (car (x), car (y)),
             pair (cdr (x), cdr (y))) : 0;
}

assoc (x, y)
{
  R eq (caar (y), x) ? cadar (y) : assoc (x, cdr (y));
}

sub2 (x, z)
{
  R null (x) ? z : eq (caar (x), z) ? cadar (x) : sub2 (cdr (x), z);
}

sublis (x, y)
{
  R atom (y) ? sub2 (x, y) : cons (sublis (x, car (y)), sublis (x, cdr (y)));
}

apply (f, args)
{
  R eval (cons (f, appq (args)), NIL);
}

appq (m)
{
  R null (m) ? NIL : cons (list (atom ('Q'), car (m)), appq (cdr (m)));
}

eval (e, a)
{
  R numberp (e) ? e :
    atomp (e) ? assoc (e, a) :
    atomp (car (e)) ? ( /*QUOTE*/ eq (car (e), atom ('Q')) ? cadr (e) :
               /*ATOM*/ eq (car (e),
                    atom ('A')) ? atomp (eval (cadr (e),
                                   a)) : /*EQ*/
               eq (car (e), atom ('E')) ? eval (cadr (e),
                            a) == eval (caddr (e),
                                    a) :
               /*COND*/ eq (car (e), atom ('D')) ? evcon (cadr (e),
                                  a) : /*CAR*/
               eq (car (e),
               atom ('H')) ? car (eval (cadr (e),
                            a)) : /*CDR*/ eq (car (e),
                                      atom
                                      ('R')) ?
               cdr (eval (cadr (e), a)) : /*CONS*/ eq (car (e),
                                   atom ('C')) ?
               cons (eval (cadr (e), a), eval (caddr (e), a)) :
               //eval(cons(assoc(car(e),a),evlis(cdr(e),a)),a) ):/*cf. Roots of Lisp*/
               eval (cons (assoc (car (e), a), cdr (e)), a)) :
    eq (caar (e), atom ('M')) ? /*LABEL*/
    eval (cons (caddar (e), cdr (e)), cons (list (cadar (e), car (e)), a)) :
    eq (caar (e), atom ('L')) ? /*LAMBDA*/
    eval (caddar (e), append (pair (cadar (e), evlis (cdr (e), a)), a)) : 0;
}

evcon (c, a)
{
  R eval (caar (c), a) ? eval (cadar (c), a) : evcon (cdr (c), a);
}

evlis (m, a)
{
  R null (m) ? NIL : cons (eval (car (m), a), evlis (cdr (m), a));
}

maplist (x, f)
{
  R null (x) ? NIL : cons (apply (f, x), maplist (cdr (x), f));
}

prn (x)
{
  atomp (x) ? printf ("'%c' ", val (x) + ALPHA) : numberp (x) ? printf ("%d ", val (x)) : objectp (x) ? printf ("OBJ %d ", val (x)) : consp (x) ? printf ("( "), prn (car (x)), prn (cdr (x)), printf (") ") : 0    //printf("NIL ")
    ;
}

#define LPAR '('
#define RPAR ')'
rd (char **p)
{
  int t, u, v, z;
  if (!(**p))
    R 0;
  if (**p == ' ')
    R++ (*p), rd (p);
  if (**p == RPAR)
    R++ (*p), atom (RPAR);
  if (**p == LPAR)
    {
      ++(*p);
      z = NIL;
      u = rd (p);
      z = cons (u, z);
      while (u = rd (p), !eq (u, atom (RPAR)))
    //u=cons(u,NIL),
    z = append (z, u);
      R z;
    }
  if (**p >= '0' && **p <= '9')
    R++ (*p), number (*((*p) - 1) - '0');
  R++ (*p), atom (*((*p) - 1));
}

void
fix (x)
{
  signal (SIGSEGV, fix);
  sbrk (msz);
  msz *= 2;
}

int
main ()
{
  assert ((-1 >> 1) == -1); /*right-shift must be sign-preserving */
  n = m = sbrk (sizeof (int) * (msz = getpagesize ()));
  *n++ = 0;
  *n++ = 0;
  //signal(SIGSEGV,fix); /*might let it run longer, obscures problems*/
  char *s = "(Q (A (Q X)))";
  char *p = s;
  int a = rd (&p);
  printf ("%s\n", s);

  int x, y;
  x = a;
  y = NIL;

  prn (x);
  x = eval (x, y);
  printf ("\nEVAL\n");

  printf ("x: %d\n", x);
  printf ("0: %o\n", x);
  printf ("0x: %x\n", x);
  printf ("tag(x): %d\n", tag (x));
  printf ("val(x): %d\n", val (x));
  printf ("car(x): %d\n", car (x));
  printf ("cdr(x): %d\n", cdr (x));
  prn (x);

  R 0;
}

Here's the guts of main again, the testing portion.

    char *s="(Q (A (Q X)))";
    char *p=s;
    int a=rd(&p);
    printf("%s\n",s);

    int x,y;
    x = a;
    y = NIL;

    prn(x);
    x = eval(x,y);
    printf("\nEVAL\n");

    printf("x: %d\n", x);
    printf("0: %o\n", x);
    printf("0x: %x\n", x);
    printf("tag(x): %d\n",tag(x));
    printf("val(x): %d\n",val(x));
    printf("car(x): %d\n",car(x));
    printf("cdr(x): %d\n",cdr(x));
    prn(x);

And the output I'm getting is:

(Q (A (Q X)))
( 'Q' ( 'A' ( 'Q' 'X' ) ) ) 
EVAL
x: -75
0: 37777777665
0x: ffffffb5
tag(x): 1
val(x): -19
car(x): 0
cdr(x): 0
'A' 
share|improve this question
2  
Regarding the formatting, will this be an IOCCC entry? ;-) –  meaning-matters Aug 7 '13 at 6:52
    
The first line of code reads: http://www.ioccc.org/1989/jar.2.c –  devnull Aug 7 '13 at 6:54
    
@devnull Ah, missed that; too early I think :-) –  meaning-matters Aug 7 '13 at 6:57
    
The formatting is a double-edged sword, to be sure. The upside is that the source itself does triple duty as a cheat-sheet, a full-reference-implementation, and a working prototype. The idea is a different sort of embeddable interpreter. Where instead of interfacing, you hack your extensions straight onto it. –  luser droog Aug 7 '13 at 6:57
    
If you going to use someone elses code, at least pick one that is readable and maintainable. You do know what the acronym IOCCC means? –  Joachim Pileborg Aug 7 '13 at 6:58
show 4 more comments

3 Answers

up vote 3 down vote accepted

Your reader is wrong, and your printer is lying to you.

Hint: try reading a list with more than one element, like (1 2 3 4 5).

The problem is that rd calls append with the element it just read as the second argument. (The fix is already there, commented out.) In the test case above, that just happens to be a list itself, so append works. But the datum you're actually passing to eval is actually

(Q . (A . (Q . X)))

when printed correctly, or

(Q A Q . X)

with the standard list abbreviation.

And so yes, eval returns A, which is the right answer, unless you want to check that there are no unexpected terms.

The bug in the printer is that for pairs you print the cdr as if it were an element. You should print a dot between the car and the cdr, or you should write a helper function prnlst that does the abbreviated list printing.

share|improve this answer
    
So for the reader, the element needs to be wrapped in a 1-element list, a single cons-cell. I think I got the printer working, too, mostly (there's an extra closing-paren sometimes). –  luser droog Feb 28 at 5:04
add comment

Much belated, but I finally got the reader and printer functions to (appear to) work with the above code.

prn(x){atomp(x)?printf("'%c' ",val(x)+ALPHA):
    numberp(x)?printf("%d ",val(x)):
    objectp(x)?printf("OBJ %d ",val(x)):
    consp(x)?printf("( "),prn(car(x)),printf(". "),prn(cdr(x)),printf(") "):
    printf("NIL ");}

prnlst(x){
    x==NIL?0:
    !consp(x)?prn(x):
    printf("( "),prnrem(x);
}
prnrem(x){
    if(x==NIL)R;// printf(")0 ");
    if(car(x)!=NIL)
        prn(car(x));
    else
        R;// printf(") ");
    null(cdr(x))?
        printf(") "):
    !listp(cdr(x))?
        prn(cdr(x)),printf(") "):
    printf(" "),prnlst(car(cdr(x))),prnrem(cdr(cdr(x))),printf(") ");
}

#define LPAR '('
#define RPAR ')'
rd(char**p){int t,u,v,z;
    if(!(**p))R 0;
    if(**p==' ')R++(*p),rd(p);
    if(**p==RPAR)R++(*p),atom(RPAR);
    if(**p==LPAR){++(*p);
        z=NIL;
        u=rd(p);
        z=cons(u,NIL);
        while(u=rd(p),!eq(u,atom(RPAR)))
            u=cons(u,NIL),
            z=append(z,u);
        R z;}
    if(**p>='0'&&**p<='9')R++(*p),number(*((*p)-1)-'0');
    R++(*p),atom(*((*p)-1));}

And now that it appears to be working, I've made a project page for it on github.

share|improve this answer
add comment

It does perfectly right:

The sub expression

(QUOTE(ATOM(QUOTE X)))

is

(ATOM 'X)

and

(eval (atom 'x))

is

'X 

(true)

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.