/* eval2.c Copyright (C) 1989-96 Codemist Ltd */
/*
* Interpreter (part 2). apply & some special forms
*/
/* Signature: 589bce9e 17-Jan-1999 */
#include <stdarg.h>
#include <string.h>
#include <ctype.h>
#include "machine.h"
#include "tags.h"
#include "cslerror.h"
#include "externs.h"
#include "entries.h"
#ifdef TIMEOUT
#include "timeout.h"
#endif
static Lisp_Object apply_lots(int nargs, n_args *f, Lisp_Object def)
/*
* Cases with 8 or more args are lifted out here into a subroutine
* to make APPLY a bit shorter and because these cases should be
* uncommon & not worth optimising much. The code that Microsoft C 6.00A
* produced for this was utterly DREADFUL - maybe other C compilers will
* make a mess of it too. Anyway I hope it will not be called very often.
*/
{
switch(nargs)
{
case 9:
return (*f)(def, 9, stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
case 10:
return (*f)(def, 10, stack[-10], stack[-9], stack[-8],
stack[-7], stack[-6], stack[-5], stack[-4],
stack[-3], stack[-2], stack[-1]);
case 11:
return (*f)(def, 11, stack[-11], stack[-10],
stack[-9], stack[-8], stack[-7], stack[-6],
stack[-5], stack[-4], stack[-3], stack[-2],
stack[-1]);
case 12:
return (*f)(def, 12, stack[-12], stack[-11],
stack[-10], stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
case 13:
return (*f)(def, 13, stack[-13], stack[-12],
stack[-11], stack[-10], stack[-9], stack[-8],
stack[-7], stack[-6], stack[-5], stack[-4],
stack[-3], stack[-2], stack[-1]);
case 14:
return (*f)(def, 14, stack[-14], stack[-13],
stack[-12], stack[-11], stack[-10], stack[-9],
stack[-8], stack[-7], stack[-6], stack[-5],
stack[-4], stack[-3], stack[-2], stack[-1]);
case 15:
return (*f)(def, 15, stack[-15], stack[-14],
stack[-13], stack[-12], stack[-11], stack[-10],
stack[-9], stack[-8], stack[-7], stack[-6],
stack[-5], stack[-4], stack[-3], stack[-2],
stack[-1]);
case 16:
return (*f)(def, 16, stack[-16], stack[-15],
stack[-14], stack[-13], stack[-12], stack[-11],
stack[-10], stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
case 17:
return (*f)(def, 17, stack[-17], stack[-16],
stack[-15], stack[-14], stack[-13], stack[-12],
stack[-11], stack[-10], stack[-9], stack[-8],
stack[-7], stack[-6], stack[-5], stack[-4],
stack[-3], stack[-2], stack[-1]);
case 18:
return (*f)(def, 18, stack[-18], stack[-17],
stack[-16], stack[-15], stack[-14], stack[-13],
stack[-12], stack[-11], stack[-10], stack[-9],
stack[-8], stack[-7], stack[-6], stack[-5],
stack[-4], stack[-3], stack[-2], stack[-1]);
case 19:
return (*f)(def, 19, stack[-19], stack[-18],
stack[-17], stack[-16], stack[-15], stack[-14],
stack[-13], stack[-12], stack[-11], stack[-10],
stack[-9], stack[-8], stack[-7], stack[-6],
stack[-5], stack[-4], stack[-3], stack[-2],
stack[-1]);
case 20:
return (*f)(def, 20, stack[-20], stack[-19],
stack[-18], stack[-17], stack[-16], stack[-15],
stack[-14], stack[-13], stack[-12], stack[-11],
stack[-10], stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
case 21:
return (*f)(def, 21, stack[-21], stack[-20],
stack[-19], stack[-18], stack[-17], stack[-16],
stack[-15], stack[-14], stack[-13], stack[-12],
stack[-11], stack[-10], stack[-9], stack[-8],
stack[-7], stack[-6], stack[-5], stack[-4],
stack[-3], stack[-2], stack[-1]);
case 22:
return (*f)(def, 22, stack[-22], stack[-21],
stack[-20], stack[-19], stack[-18], stack[-17],
stack[-16], stack[-15], stack[-14], stack[-13],
stack[-12], stack[-11], stack[-10], stack[-9],
stack[-8], stack[-7], stack[-6], stack[-5],
stack[-4], stack[-3], stack[-2], stack[-1]);
case 23:
return (*f)(def, 23, stack[-23], stack[-22],
stack[-21], stack[-20], stack[-19], stack[-18],
stack[-17], stack[-16], stack[-15], stack[-14],
stack[-13], stack[-12], stack[-11], stack[-10],
stack[-9], stack[-8], stack[-7], stack[-6],
stack[-5], stack[-4], stack[-3], stack[-2],
stack[-1]);
case 24:
return (*f)(def, 24, stack[-24], stack[-23],
stack[-22], stack[-21], stack[-20], stack[-19],
stack[-18], stack[-17], stack[-16], stack[-15],
stack[-14], stack[-13], stack[-12], stack[-11],
stack[-10], stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
case 25:
return (*f)(def, 25, stack[-25], stack[-24], stack[-23],
stack[-22], stack[-21], stack[-20], stack[-19],
stack[-18], stack[-17], stack[-16], stack[-15],
stack[-14], stack[-13], stack[-12], stack[-11],
stack[-10], stack[-9], stack[-8], stack[-7],
stack[-6], stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
default:
/*
* If more than 25 args are going to be passed I will arrange that the
* final ones are built into a list - as if the 25th arg was specified
* as a "&rest" one. Why? Because passing VERY large numbers of arguments
* in C is not a good idea - ANSI C compilers are only obliged to support
* up to 31 args, and one some machines this limit seems to really matter.
* But Common Lisp can need more args than that. I will ignore the fact that
* what I do here is slow. I will HOPE that calls with 25 or more args
* are very uncommon.
*/
{ int n = nargs;
Lisp_Object w, *tsp = stack, nil = C_nil;
#if (ARG_CUT_OFF != 25)
if (ARG_CUT_OFF != 25)
{ fprintf(stderr, "\n+++ ARG_CUT_OFF incorrectly configured\n");
my_exit(EXIT_FAILURE);
}
#endif
w = ncons(tsp[-1]);
errexit();
tsp[-1] = w;
while (n > ARG_CUT_OFF)
{ w = cons(tsp[-2], tsp[-1]);
errexit();
tsp[-2] = w;
tsp[-1] = tsp[0];
tsp--;
n--;
}
return (*f)(def, nargs, tsp[-25], tsp[-24], tsp[-23],
tsp[-22], tsp[-21], tsp[-20], tsp[-19],
tsp[-18], tsp[-17], tsp[-16], tsp[-15],
tsp[-14], tsp[-13], tsp[-12], tsp[-11],
tsp[-10], tsp[-9], tsp[-8], tsp[-7],
tsp[-6], tsp[-5], tsp[-4], tsp[-3],
tsp[-2], tsp[-1]);
}
}
}
void push_args(va_list a, int nargs)
/*
* The unpacking here must match "apply_lots" as above. For up to
* (and including) ARG_CUT_OFF (=25) args things are passed normally.
* beyond that the first ARG_CUT_OFF-1 args are passed normally, and the
* rest are in a list as a final actual arg. Note that this list will
* have at least two elements.
*/
{
int i;
if (nargs <= ARG_CUT_OFF)
{ for (i = 0; i<nargs; i++)
{ Lisp_Object w = va_arg(a, Lisp_Object);
push(w);
}
}
else
{ Lisp_Object x;
for (i = 0; i<(ARG_CUT_OFF-1); i++)
{ Lisp_Object w = va_arg(a, Lisp_Object);
push(w);
}
x = va_arg(a, Lisp_Object);
/*
* Internal consistency should ensure that the list passed here is long
* enough for the following unpacking operation. But if (as a result of
* internal system muddles it is not maybe the fact that qcar(nil) =
* qcdr(nil) = nil will tend to reduce the damage?
*/
for (; i<nargs; i++)
{ push(qcar(x));
x = qcdr(x);
}
}
va_end(a);
}
void push_args_1(va_list a, int nargs)
/*
* This is very much like push_args(), but is for the (rather small number
* of) cases where the first argument to a function must NOT be pushed on the
* stack. See, for instance, "funcall" as an example.
*/
{
int i;
if (nargs <= ARG_CUT_OFF)
{ for (i = 1; i<nargs; i++)
{ Lisp_Object w = va_arg(a, Lisp_Object);
push(w);
}
}
else
{ Lisp_Object x;
for (i = 1; i<(ARG_CUT_OFF-1); i++)
{ Lisp_Object w = va_arg(a, Lisp_Object);
push(w);
}
x = va_arg(a, Lisp_Object);
for (; i<nargs; i++)
{ push(qcar(x));
x = qcdr(x);
}
}
va_end(a);
}
Lisp_Object apply(Lisp_Object fn, int nargs, Lisp_Object env, Lisp_Object name)
/*
* There are (nargs) arguments on the Lisp stack, and apply() must use them
* then pop them off. They were pushed in the order push(arg1); push(arg2),
* and so on, and the stack grows upwards.
* If I return with an error I will hand back the value name rather than the
* junk value normally used in such cases.
*/
{
Lisp_Object def, nil = C_nil;
for (;;)
{ if (symbolp(fn))
{
def = qenv(fn); /* this is passed as arg1 to the called code */
/*
* apply_lambda() will find arguments on the stack and is responsible for
* popping them before it exits.
*/
{
/*
* Because there are nargs values pushed on the (upwards growing) stack,
* &stack[1-nargs] points at the first value pushed, i.e. arg-1. At one stage
* I had a machine-specific bit of code (called "ncall") to do the following,
* arguing that maybe in assembly code it would be possible to do much better
* than the really ugly switch statement shown now. My belief now (especially
* given that ncall was used in just one place - here) is that the switch will
* cost no more than the procedure call did, and that in-line code will help
* speed up the common and critical cases of 0, 1, 2 and 3 args. Also apply
* is otherwise a reasonably short function, so if this switch is needed
* anywhere here is not too bad.
*/
push(name);
switch (nargs)
{
/*
* The Standard Lisp Report (Marti et al, Utah UUCS-78-101) only
* requires support for 15 args. Common Lisp requires at least 50.
* I deal with up to 8 args in-line here (I expect more than that to be
* amazingly uncommon) so that this function is kept under contol.
* Calls with more than 8 args go over to apply_lots, and within that
* function calls with over 25 args have an even more clumsy treatment.
*/
case 0:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 0);
break;
case 1:
#ifdef DEBUG
if (qfn1(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfn1(fn))(def, stack[-1]);
break;
case 2:
#ifdef DEBUG
if (qfn2(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfn2(fn))(def, stack[-2], stack[-1]);
break;
case 3:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 3, stack[-3], stack[-2], stack[-1]);
break;
case 4:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 4, stack[-4], stack[-3], stack[-2],
stack[-1]);
break;
case 5:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 5, stack[-5], stack[-4], stack[-3],
stack[-2], stack[-1]);
break;
case 6:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 6, stack[-6], stack[-5], stack[-4],
stack[-3], stack[-2], stack[-1]);
break;
case 7:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 7, stack[-7], stack[-6], stack[-5],
stack[-4], stack[-3], stack[-2], stack[-1]);
break;
case 8:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = (*qfnn(fn))(def, 8, stack[-8], stack[-7], stack[-6],
stack[-5], stack[-4], stack[-3], stack[-2],
stack[-1]);
break;
default:
#ifdef DEBUG
if (qfnn(fn) == NULL)
{ term_printf("Illegal APPLY\n");
my_exit(EXIT_FAILURE);
}
#endif
def = apply_lots(nargs, qfnn(fn), def);
break;
}
/*
* here I have to pop the stack by hand - note that popv does not
* corrupt exit_count, which tells me how many results were being handed
* back.
*/
pop(name);
popv(nargs);
nil = C_nil;
if (exception_pending()) return name;
else return def;
}
}
else if (!is_cons(fn))
{ popv(nargs);
push(name);
error(1, err_bad_fn, fn);
pop(name);
return name;
}
/* apply_lambda() will pop the args from the stack when it is done */
if ((def = qcar(fn)) == lambda)
return apply_lambda(qcdr(fn), nargs, env, name);
/*
* A bytecoded funarg is stored as (cfunarg <actual fn> <env>) and any call
* to it behaves as if the actual function was called with the environment
* passed as a forced-in first argument.
*/
else if (def == cfunarg)
{ int i;
push(nil);
def = qcdr(fn);
fn = qcar(def);
for (i=0; i<nargs; i++) stack[-i] = stack[-i-1];
stack[-nargs] = qcdr(def);
nargs++;
continue;
}
else if (def == funarg)
{ def = qcdr(fn);
if (consp(def))
return apply_lambda(qcdr(def), nargs, qcar(def), name);
}
break;
}
/*
* Other cases are all errors.
*/
popv(nargs);
push(name);
error(1, err_bad_apply, fn);
pop(name);
return name;
}
/*
* Now for implementation of all the special forms...
*/
static Lisp_Object and_fn(Lisp_Object args, Lisp_Object env)
/* also needs to be a macro for Common Lisp */
{
Lisp_Object nil = C_nil;
stackcheck2(0, args, env);
if (!consp(args)) return onevalue(lisp_true);
for (;;)
{ Lisp_Object v = qcar(args);
args = qcdr(args);
if (!consp(args)) return eval(v, env);
push2(args, env);
v = eval(v, env);
pop2(env, args);
errexit();
if (v == nil) return onevalue(nil);
}
}
/*
* This is not used at present, but may be wanted sometime so I will
* leave it here for now...
*
Lisp_Object append(Lisp_Object a, Lisp_Object b)
{
Lisp_Object nil = C_nil;
if (!consp(a)) return b;
else
{ stackcheck2(0, a, b);
push(a);
b = append(qcdr(a), b);
pop(a);
errexit();
return cons(qcar(a), b);
}
}
*/
static Lisp_Object block_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object p, nil = C_nil;
if (!consp(args)) return onevalue(nil);
stackcheck2(0, args, env);
push3(qcar(args), /* my_tag */
qcdr(args), /* args */
env);
#define env stack[0]
#define args stack[-1]
#define my_tag stack[-2]
/*
* I need to augment the (lexical) environment with the name of my
* tag in such a way that return-from can throw out to exactly the
* correct matching level. This is done by pushing (0 . tag) onto
* the environment - the 0 marks this as a block name.
*/
my_tag = cons(fixnum_of_int(0), my_tag);
errexitn(3);
env = cons(my_tag, env);
errexitn(3);
p = nil;
while (consp(args))
{ p = qcar(args);
p = eval(p, env);
/*
* one of the sorts of exit that may be activated by marking nil is
* a return_from. Here I need to check to see if that is what
* is going on.
*/
nil = C_nil;
if (exception_pending())
{ flip_exception(); /* Temp restore it */
qcar(my_tag) = fixnum_of_int(2); /* Invalidate */
if (exit_reason == UNWIND_RETURN && exit_tag == my_tag)
{ exit_reason = UNWIND_NULL; /* not strictly needed - but tidy */
popv(3);
return nvalues(exit_value, exit_count);
}
if ((exit_reason & UNWIND_ERROR) != 0)
{ err_printf("\nEvaluating: ");
loop_print_error(qcar(args));
ignore_exception();
}
flip_exception(); /* re-instate exit condition */
popv(3);
return nil;
}
args = qcdr(args);
}
popv(3);
return p;
#undef env
#undef args
#undef my_tag
}
static Lisp_Object catch_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object tag, nil = C_nil;
if (!consp(args)) return onevalue(nil);
stackcheck2(0, args, env);
push2(args, env);
tag = qcar(args);
tag = eval(tag, env);
errexit();
tag = catch_tags = cons(tag, catch_tags);
pop2(env, args);
errexit();
push(tag);
{
Lisp_Object v = progn_fn(qcdr(args), env);
pop(tag);
nil = C_nil;
if (exception_pending())
{ flip_exception();
catch_tags = qcdr(tag);
qcar(tag) = tag;
qcdr(tag) = nil; /* Invalidate the catch frame */
if (exit_reason == UNWIND_THROW && exit_tag == tag)
{ exit_reason = UNWIND_NULL;
return nvalues(exit_value, exit_count);
}
flip_exception();
return nil;
}
catch_tags = qcdr(tag);
qcar(tag) = tag;
qcdr(tag) = nil; /* Invalidate the catch frame */
return v;
}
}
#define BODY_LET 0
#define BODY_COMPILER_LET 1
#define BODY_PROG 2
Lisp_Object let_fn_1(Lisp_Object bvl, Lisp_Object body,
Lisp_Object env, int compilerp)
/*
* This will have to look for (declare (special ...)).
* compiler-let forces all of its bindings to be locally special. In
* CSL mode I do not support local declarations, which simplifies and
* speeds things up here.
*/
{
Lisp_Object nil = C_nil;
stackcheck3(0, bvl, body, env);
push3(bvl, body, env);
nil = C_nil;
push5(nil, nil, env, nil, nil);
#ifdef COMMON
/*
* I lose the name (for security) but leave the junk stack location
* (because doing otherwise seems unduly complicated.
*/
#define local_decs stack[0]
#endif
#define specenv stack[-1]
#define env1 stack[-2]
#define p stack[-3]
#define q stack[-4]
#define env stack[-5]
#define body stack[-6]
#define bvl stack[-7]
#define Return(v) { popv(8); return (v); }
#ifdef COMMON
/*
* Find local declarations - it is necessary to macro-expand
* items in the body to see if they turn into declarations.
*/
for (;;)
{ if (exception_pending() || !consp(body)) break;
p = macroexpand(qcar(body), env);
errexitn(8);
body = qcdr(body);
if (!consp(p))
{ if (stringp(p) && consp(body)) continue;
body = cons(p, body);
nil = C_nil;
break;
}
if (qcar(p) != declare_symbol)
{ body = cons(p, body);
nil = C_nil;
break;
}
for (p = qcdr(p); consp(p); p = qcdr(p))
{ q = qcar(p);
if (!consp(q) || qcar(q) != special_symbol) continue;
/* here q says (special ...) */
for (q=qcdr(q); consp(q); q = qcdr(q))
{ local_decs = cons(qcar(q), local_decs);
nil = C_nil;
if (exception_pending()) break;
}
if (exception_pending()) break;
}
}
if (exception_pending()) Return(nil);
#endif
for (; consp(bvl); bvl=qcdr(bvl))
{ Lisp_Object z;
q = qcar(bvl);
if (consp(q))
{ z = qcdr(q);
q = qcar(q);
if (consp(z)) z = qcar(z); else z = nil;
}
else z = nil;
if (!is_symbol(q))
{ Lisp_Object qq = q;
Return(error(1, err_bad_bvl, qq));
}
else
{
#ifdef COMMON
Header h = qheader(q);
#endif
if (z != nil)
{ z = eval(z, env);
errexitn(8);
}
z = cons(q, z);
errexitn(8);
#ifdef COMMON
if (compilerp == BODY_COMPILER_LET)
{ specenv = cons(z, specenv);
errexitn(8);
q = acons(q, work_symbol, env1);
errexitn(8);
env1 = q; /* Locally special */
}
else
#endif
#ifndef COMMON
specenv = cons(z, specenv);
#else
if (h & SYM_SPECIAL_VAR) specenv = cons(z, specenv);
else
{
Lisp_Object w;
for (w = local_decs; w!=nil; w = qcdr(w))
{ if (q != qcar(w)) continue;
qcar(w) = fixnum_of_int(0);
/* The next few calls to cons() maybe lose w, but that is OK! */
specenv = cons(z, specenv);
errexitn(8);
q = acons(q, work_symbol, env1);
errexitn(8);
env1 = q;
goto bound;
}
env1 = cons(z, env1);
bound: ;
}
#endif
errexitn(8);
}
}
#ifdef COMMON
while (local_decs!=nil) /* Pervasive special declarations */
{ Lisp_Object q1 = qcar(local_decs);
local_decs=qcdr(local_decs);
if (!is_symbol(q1)) continue;
q1 = acons(q1, work_symbol, env1);
errexitn(8);
env1 = q1;
}
#endif
if (specenv == nil)
{ Lisp_Object bodyx = body, env1x = env1;
/*
* See expansion of Return() for an explanation of why body and env1 have
* been moved into new local variables before the call..
*/
if (compilerp == BODY_PROG)
{ Return(tagbody_fn(bodyx, env1x));
}
else
{ Return(progn_fn(bodyx, env1x));
}
}
/*
* I instate the special bindings after all values to bind have been collected
*/
for (p = specenv; p != nil; p = qcdr(p))
{ Lisp_Object w = qcar(p), v = qcar(w), z = qcdr(w);
Lisp_Object old = qvalue(v);
qvalue(v) = z;
qcdr(w) = old;
}
{
if (compilerp == BODY_PROG)
body = tagbody_fn(body, env1);
else body = progn_fn(body, env1);
nil = C_nil;
if (exception_pending())
{ flip_exception();
for (p = specenv; p != nil; p = qcdr(p))
{ Lisp_Object w = qcar(p), v = qcar(w), z = qcdr(w);
qvalue(v) = z;
}
flip_exception();
Return(nil);
}
else
{ for (p = specenv; p != nil; p = qcdr(p))
{ Lisp_Object w = qcar(p), v = qcar(w), z = qcdr(w);
qvalue(v) = z;
}
{ Lisp_Object bodyx = body;
Return(bodyx);
}
}
}
#ifdef COMMON
#undef local_decs
#endif
#undef specenv
#undef env1
#undef p
#undef q
#undef env
#undef body
#undef bvl
#undef Return
}
#ifdef COMMON
static Lisp_Object compiler_let_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object nil = C_nil;
if (!consp(args)) return onevalue(nil);
return let_fn_1(qcar(args), qcdr(args), env, BODY_COMPILER_LET);
}
#endif
static Lisp_Object cond_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object nil = C_nil;
stackcheck2(0, args, env);
while (consp(args))
{
Lisp_Object p = qcar(args);
if (consp(p))
{ Lisp_Object p1;
push2(args, env);
p1 = qcar(p);
p1 = eval(p1, env);
pop2(env, args);
errexit();
if (p1 != nil)
{ args = qcdr(qcar(args));
/* Here I support the case "(cond (predicate) ...)" with no consequents */
if (!consp(args)) return onevalue(p1);
else return progn_fn(args, env);
}
}
args = qcdr(args);
}
return onevalue(nil);
}
#ifdef COMMON
Lisp_Object declare_fn(Lisp_Object args, Lisp_Object env)
/*
* declarations can only properly occur at the heads of various
* special forms, and so may NOT be evaluated in an ordinary manner.
* Thus I am entitled (just about) to make this a no-op. It would
* probably be better to arrange that (declare ...) never got evaluated
* and then I could raise an error if this bit of code got activated.
* Indeed (declare ...) probably does not ever get evaluated - still
* a no-op here seems the safest bet.
*/
{
Lisp_Object nil = C_nil;
CSL_IGNORE(env);
CSL_IGNORE(args);
return onevalue(nil);
}
#endif
#define flagged_lose(v) \
((fv = qfastgets(v)) != nil && elt(fv, 1) != SPID_NOPROP)
static Lisp_Object defun_fn(Lisp_Object args, Lisp_Object env)
{
/*
* defun is eventually expected (required!) to be a macro rather than (maybe
* as well as?) a special form. For bootstrap purposes it seems useful to
* build it in as a special form. Also this special form is quite good enough
* in CSL mode
*/
Lisp_Object fname, nil = C_nil;
CSL_IGNORE(env);
if (consp(args))
{ fname = qcar(args);
args = qcdr(args);
if (is_symbol(fname))
{ Lisp_Object fv;
if (qheader(fname) & SYM_SPECIAL_FORM)
return error(1, err_redef_special, fname);
if ((qheader(fname) & (SYM_C_DEF | SYM_CODEPTR)) ==
(SYM_C_DEF | SYM_CODEPTR)) return onevalue(fname);
if (flagged_lose(fname))
{ debug_printf("\n+++ ");
loop_print_debug(fname);
debug_printf(" not defined because of LOSE flag\n");
return onevalue(nil);
}
qheader(fname) = qheader(fname) & ~SYM_MACRO;
if ((qheader(fname) & SYM_C_DEF) != 0) lose_C_def(fname);
if (qfn1(fname) != undefined1)
{ if (qvalue(redef_msg) != nil)
{ debug_printf("\n+++ ");
loop_print_debug(fname);
debug_printf(" redefined\n");
}
errexit();
set_fns(fname, undefined1, undefined2, undefinedn);
qenv(fname) = fname;
}
/*
* qfn() can contain 'interpreted' for a function defined wrt the null
* environment, or 'funarged' for one with an environment - in the latter
* case the definition (in qenv()) is a pair (<def> . <env>)
*/
qenv(fname) = args; /* Sort of notional lambda present */
set_fns(fname, interpreted1, interpreted2, interpretedn);
if (qvalue(comp_symbol) != nil &&
qfn1(compiler_symbol) != undefined1)
{ push(fname);
args = ncons(fname);
nil = C_nil;
if (!exception_pending())
(qfn1(compiler_symbol))(qenv(compiler_symbol), args);
pop(fname);
}
return onevalue(fname);
}
}
return aerror("defun");
}
static Lisp_Object defmacro_fn(Lisp_Object args, Lisp_Object env)
{
/*
* defmacro is eventually expected (required!) to be a macro rather than (maybe
* as well as?) a special form. For bootstrap purposes it seems useful to
* build it in as a special form.
*/
Lisp_Object fname, nil = C_nil;
CSL_IGNORE(env);
if (consp(args))
{ fname = qcar(args);
args = qcdr(args);
if (is_symbol(fname))
{
if ((qheader(fname) & (SYM_C_DEF | SYM_CODEPTR)) ==
(SYM_C_DEF | SYM_CODEPTR)) return onevalue(fname);
qheader(fname) |= SYM_MACRO;
/*
* Note that a name can have a definition as a macro and as a special form,
* and in that case the qfn() cell gives the special form and the qenv()
* cell the macro definition. Otherwise at present I put 'undefined'
* in the qfn() cell, but in due course I will want something else as better
* protection against compiled code improperly attempting to call a macro.
* Note also that if the symbol was a special form before I do not want
* to clear the C_DEF flag, since the special form must be re-instated when
* I reload the system.
*/
if ((qheader(fname) & SYM_SPECIAL_FORM) == 0)
{ qheader(fname) &= ~SYM_C_DEF;
if (qfn1(fname) != undefined1 &&
qvalue(redef_msg) != nil)
{ debug_printf("\n+++ ");
loop_print_debug(fname);
debug_printf(" redefined as a macro\n");
errexit();
}
set_fns(fname, undefined1, undefined2, undefinedn);
}
qenv(fname) = args; /* Sort of notional lambda present */
if (qvalue(comp_symbol) != nil &&
qfn1(compiler_symbol) != undefined1)
{ Lisp_Object t1, t2;
push(fname);
if (!(consp(args) &&
consp(qcdr(args)) &&
qcdr(qcdr(args)) == nil &&
(t1 = qcar(args),
t2 = qcdr(qcar(qcdr(args))),
equal(t1, t2))))
{ errexitn(1);
fname = stack[0];
args = ncons(fname);
nil = C_nil;
if (!exception_pending())
(qfn1(compiler_symbol))(qenv(compiler_symbol), args);
}
pop(fname);
errexit();
}
return onevalue(fname);
}
}
return aerror("defmacro");
}
static Lisp_Object eval_when_fn(Lisp_Object args, Lisp_Object env)
/*
* When interpreted, eval-when just looks for the situation EVAL.
*/
{
Lisp_Object situations, nil = C_nil;
if (!consp(args)) return onevalue(nil);
situations = qcar(args);
args = qcdr(args);
while (consp(situations))
{ if (qcar(situations) == eval_symbol) return progn_fn(args, env);
situations = qcdr(situations);
}
return onevalue(nil);
}
#ifdef COMMON
static Lisp_Object flet_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object my_env, d, nil = C_nil;
if (!consp(args)) return onevalue(nil);
stackcheck2(0, args, env);
my_env = env;
d = qcar(args); /* The bunch of definitions */
args = qcdr(args);
nil = C_nil;
while (consp(d))
{ Lisp_Object w = qcar(d);
if (consp(w) && consp(qcdr(w)))
{ Lisp_Object w1;
push4(args, d, env, w);
w1 = list2star(funarg, my_env, qcdr(w));
pop(w);
nil = C_nil;
if (!exception_pending()) w1 = cons(w1, qcar(w));
pop(env);
nil = C_nil;
if (!exception_pending()) env = cons(w1, env);
pop2(d, args);
errexit();
}
d = qcdr(d);
}
/*
* Treat body as (let nil ...) to get (declare ...) recognized.
*/
return let_fn_1(nil, args, env, BODY_LET);
}
#endif
Lisp_Object function_fn(Lisp_Object args, Lisp_Object env)
{
/*
* For most things this behaves just like (quote xxx), but
* (function (lambda (x) y)) gets converted to
* (funarg env (x) y).
*/
Lisp_Object nil = C_nil;
if (consp(args) && qcdr(args) == nil)
{ args = qcar(args);
if (consp(args) && qcar(args) == lambda)
args = list2star(funarg, env, qcdr(args));
return onevalue(args);
}
return aerror("function");
}
static Lisp_Object go_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object p, tag, nil = C_nil;
CSL_IGNORE(env);
if (!consp(args)) return aerror("go");
else tag = qcar(args);
for(p=env; consp(p); p=qcdr(p))
{ Lisp_Object w = qcar(p), z;
if (!consp(w)) continue;
if (qcar(w) == fixnum_of_int(1) &&
(z = qcar(qcdr(w)), eql(z, tag)))
{ p = w;
goto tag_found;
}
}
return error(1, err_go_tag, tag);
tag_found:
exit_tag = p;
exit_count = 0;
exit_reason = UNWIND_GO;
flip_exception(); /* Exceptional exit active */
return nil;
}
static Lisp_Object if_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object nil = C_nil;
Lisp_Object p=nil, tr=nil, fs=nil;
if (!consp(args)) return aerror("if");
p = qcar(args);
args = qcdr(args);
if (!consp(args)) return aerror("if");
tr = qcar(args);
args = qcdr(args);
if (!consp(args)) fs = nil;
else
{ fs = qcar(args);
args = qcdr(args);
if (args != nil) return aerror("if");
}
stackcheck4(0, p, env, tr, fs);
push3(fs, tr, env);
p = eval(p, env);
pop3(env, tr, fs);
errexit();
if (p == nil)
return eval(fs, env); /* tail call on result */
else return eval(tr, env); /* ... passing back values */
}
#ifdef COMMON
static Lisp_Object labels_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object my_env, d, nil = C_nil;
if (!consp(args)) return onevalue(nil);
stackcheck2(0, args, env);
my_env = env;
d = qcar(args); /* The bunch of definitions */
while (consp(d))
{ Lisp_Object w = qcar(d);
if (consp(w) && consp(qcdr(w)))
{ Lisp_Object w1;
push4(args, d, env, w);
w1 = list2star(funarg, nil, qcdr(w));
pop(w);
nil = C_nil;
if (!exception_pending()) w1 = cons(w1, qcar(w));
pop(env);
nil = C_nil;
if (!exception_pending()) env = cons(w1, env);
pop2(d, args);
errexit();
}
d = qcdr(d);
}
/*
* Now patch up the environments stored with the local defs so as to
* permit mutual recursion between them all.
*/
for (d=env; d!=my_env; d=qcdr(d))
qcar(qcdr(qcar(qcar(d)))) = env;
return let_fn_1(nil, qcdr(args), env, BODY_LET);
}
#endif
static Lisp_Object let_fn(Lisp_Object args, Lisp_Object env)
{
Lisp_Object nil = C_nil;
if (!consp(args)) return onevalue(nil);
return let_fn_1(qcar(args), qcdr(args), env, BODY_LET);
}
static Lisp_Object letstar_fn(Lisp_Object args, Lisp_Object env)
/*
* This will have to look for (declare (special ...)), unless
* I am in CSL mode.
*/
{
Lisp_Object nil = C_nil;
if (!consp(args)) return onevalue(nil);
stackcheck2(0, args, env);
push3(qcar(args), qcdr(args), env);
nil = C_nil;
push5(nil, nil, /* p, q */
env, nil, nil); /* env1, specenv, local_decs */
#ifdef COMMON
#define local_decs stack[0]
#endif
#define specenv stack[-1]
#define env1 stack[-2]
#define p stack[-3]
#define q stack[-4]
#define env stack[-5]
#define body stack[-6]
#define bvl stack[-7]
#define Return(v) { popv(8); return (v); }
#ifdef COMMON
for (;;)
{ if (exception_pending() || !consp(body)) break;
p = macroexpand(qcar(body), env);
errexitn(8);
body = qcdr(body);
if (!consp(p))
{ if (stringp(p) && consp(body)) continue;
body = cons(p, body);
nil = C_nil;
break;
}
if (qcar(p) != declare_symbol)
{ body = cons(p, body);
nil = C_nil;
break;
}
for (p = qcdr(p); consp(p); p = qcdr(p))
{ q = qcar(p);
if (!consp(q) || qcar(q) != special_symbol) continue;
/* here q says (special ...) */
for (q=qcdr(q); consp(q); q = qcdr(q))
{ local_decs = cons(qcar(q), local_decs);
nil = C_nil;
if (exception_pending()) break;
}
if (exception_pending()) break;
}
}
if (exception_pending()) Return(nil);
#endif
for (; consp(bvl); bvl=qcdr(bvl))
{ Lisp_Object z;
q = qcar(bvl);
if (consp(q))
{ z = qcdr(q);
q = qcar(q);
if (consp(z)) z = qcar(z); else z = nil;
}
else z = nil;
if (!is_symbol(q))
{ error(1, err_bad_bvl, q);
goto unwind_special_bindings;
}
else
{
#ifdef COMMON
Header h = qheader(q);
#endif
if (z != nil)
{ z = eval(z, env);
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
}
#ifndef COMMON
p = z;
z = acons(q, qvalue(q), specenv);
nil = C_nil;
if (!exception_pending()) specenv = z;
qvalue(q) = p;
#else
if (h & SYM_SPECIAL_VAR)
{
p = z;
z = acons(q, qvalue(q), specenv);
nil = C_nil;
if (!exception_pending()) specenv = z;
qvalue(q) = p;
}
else
{
for (p = local_decs; p!=nil; p = qcdr(p))
{ Lisp_Object w;
if (q != qcar(p)) continue;
qcar(p) = fixnum_of_int(0);
w = acons(q, qvalue(q), specenv);
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
specenv = w;
w = acons(q, work_symbol, env);
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
env = w;
qvalue(q) = z;
goto bound;
}
q = acons(q, z, env);
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
env = q;
bound: ;
}
#endif
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
}
}
#ifdef COMMON
while (local_decs!=nil) /* Pervasive special declarations */
{ q = qcar(local_decs);
local_decs=qcdr(local_decs);
if (!is_symbol(q)) continue;
q = acons(q, work_symbol, env);
nil = C_nil;
if (!exception_pending()) env = q;
else goto unwind_special_bindings;
}
#endif
if (specenv == nil)
{ Lisp_Object bodyx = body, envx = env;
Return(progn_fn(bodyx, envx)); /* beware Return macro! */
}
{
body = progn_fn(body, env);
nil = C_nil;
if (exception_pending()) goto unwind_special_bindings;
for (bvl = specenv; bvl != nil; bvl = qcdr(bvl))
{ Lisp_Object w = qcar(bvl), v = qcar(w), z = qcdr(w);
qvalue(v) = z;
}
{ Lisp_Object bodyx = body;
Return(bodyx);
}
}
unwind_special_bindings:
flip_exception();
for (bvl = specenv; bvl != nil; bvl = qcdr(bvl))
{ Lisp_Object w = qcar(bvl), v = qcar(w), z = qcdr(w);
qvalue(v) = z;
}
flip_exception();
popv(8);
return nil;
#ifdef COMMON
#undef local_decs
#endif
#undef specenv
#undef env1
#undef p
#undef q
#undef env
#undef body
#undef bvl
#undef Return
}
setup_type const eval2_setup[] =
/*
* A jolly curiosity - "function" and "declare" are ALSO set up in
* restart.c (because handles are needed on the symbols). I leave
* the redundant initialisation here too since I find it clearer that
* way.
*/
{
{"and", and_fn, bad_special2, bad_specialn},
{"catch", catch_fn, bad_special2, bad_specialn},
{"cond", cond_fn, bad_special2, bad_specialn},
/*
* I am not over-enthusiastic about supporting eval-when in CSL, but
* something of that sort seems needed by some bits of code that I have
* come across...
*/
{"eval-when", eval_when_fn, bad_special2, bad_specialn},
{"function", function_fn, bad_special2, bad_specialn},
{"go", go_fn, bad_special2, bad_specialn},
{"if", if_fn, bad_special2, bad_specialn},
{"let*", letstar_fn, bad_special2, bad_specialn},
/* DE and DM are used as low level primitives in the Common Lisp bootstrap */
{"de", defun_fn, bad_special2, bad_specialn},
{"dm", defmacro_fn, bad_special2, bad_specialn},
#ifdef COMMON
{"block", block_fn, bad_special2, bad_specialn},
{"compiler-let", compiler_let_fn, bad_special2, bad_specialn},
{"declare", declare_fn, bad_special2, bad_specialn},
{"flet", flet_fn, bad_special2, bad_specialn},
{"labels", labels_fn, bad_special2, bad_specialn},
{"let", let_fn, bad_special2, bad_specialn},
#else
{"~block", block_fn, bad_special2, bad_specialn},
{"~let", let_fn, bad_special2, bad_specialn},
#endif
{NULL, 0, 0, 0}};
/* end of eval2.c */