#include <config.h>
#include "lisp.h"
#include "blockinput.h"
#include "commands.h"
#include "keyboard.h"
#include "dispextern.h"
#include <setjmp.h>
struct backtrace
{
struct backtrace *next;
Lisp_Object *function;
Lisp_Object *args;
int nargs;
char evalargs;
char debug_on_exit;
};
struct backtrace *backtrace_list;
struct catchtag
{
Lisp_Object tag;
Lisp_Object val;
struct catchtag *next;
struct gcpro *gcpro;
jmp_buf jmp;
struct backtrace *backlist;
struct handler *handlerlist;
int lisp_eval_depth;
int pdlcount;
int poll_suppress_count;
struct byte_stack *byte_stack;
};
struct catchtag *catchlist;
#ifdef DEBUG_GCPRO
int gcpro_level;
#endif
Lisp_Object Qautoload, Qmacro, Qexit, Qinteractive, Qcommandp, Qdefun;
Lisp_Object Qinhibit_quit, Vinhibit_quit, Vquit_flag;
Lisp_Object Qmocklisp_arguments, Vmocklisp_arguments, Qmocklisp;
Lisp_Object Qand_rest, Qand_optional;
Lisp_Object Qdebug_on_error;
Lisp_Object Vrun_hooks;
Lisp_Object Vautoload_queue;
int specpdl_size;
struct specbinding *specpdl;
struct specbinding *specpdl_ptr;
int max_specpdl_size;
int lisp_eval_depth;
int max_lisp_eval_depth;
int debug_on_next_call;
int debugger_may_continue;
Lisp_Object Vstack_trace_on_error;
Lisp_Object Vdebug_on_error;
Lisp_Object Vdebug_ignored_errors;
Lisp_Object Vdebug_on_signal;
Lisp_Object Vsignal_hook_function;
int debug_on_quit;
int when_entered_debugger;
Lisp_Object Vdebugger;
Lisp_Object Vsignaling_function;
int handling_signal;
void specbind (), record_unwind_protect ();
Lisp_Object run_hook_with_args ();
Lisp_Object funcall_lambda ();
extern Lisp_Object ml_apply ();
void
init_eval_once ()
{
specpdl_size = 50;
specpdl = (struct specbinding *) xmalloc (specpdl_size * sizeof (struct specbinding));
specpdl_ptr = specpdl;
max_specpdl_size = 600;
max_lisp_eval_depth = 300;
Vrun_hooks = Qnil;
}
void
init_eval ()
{
specpdl_ptr = specpdl;
catchlist = 0;
handlerlist = 0;
backtrace_list = 0;
Vquit_flag = Qnil;
debug_on_next_call = 0;
lisp_eval_depth = 0;
#ifdef DEBUG_GCPRO
gcpro_level = 0;
#endif
when_entered_debugger = -1;
}
Lisp_Object
call_debugger (arg)
Lisp_Object arg;
{
int debug_while_redisplaying;
int count = specpdl_ptr - specpdl;
Lisp_Object val;
if (lisp_eval_depth + 20 > max_lisp_eval_depth)
max_lisp_eval_depth = lisp_eval_depth + 20;
if (specpdl_size + 40 > max_specpdl_size)
max_specpdl_size = specpdl_size + 40;
#ifdef HAVE_X_WINDOWS
if (display_hourglass_p)
cancel_hourglass ();
#endif
debug_on_next_call = 0;
when_entered_debugger = num_nonmacro_input_events;
debug_while_redisplaying = redisplaying_p;
redisplaying_p = 0;
specbind (intern ("debugger-may-continue"),
debug_while_redisplaying ? Qnil : Qt);
specbind (Qinhibit_redisplay, Qnil);
#if 0
specbind (Qinhibit_eval_during_redisplay, Qt);
#endif
val = apply1 (Vdebugger, arg);
if (debug_while_redisplaying)
Ftop_level ();
return unbind_to (count, val);
}
void
do_debug_on_call (code)
Lisp_Object code;
{
debug_on_next_call = 0;
backtrace_list->debug_on_exit = 1;
call_debugger (Fcons (code, Qnil));
}
DEFUN ("or", For, Sor, 0, UNEVALLED, 0,
"Eval args until one of them yields non-nil, then return that value.\n\
The remaining args are not evalled at all.\n\
If all args return nil, return nil.")
(args)
Lisp_Object args;
{
register Lisp_Object val;
Lisp_Object args_left;
struct gcpro gcpro1;
if (NILP(args))
return Qnil;
args_left = args;
GCPRO1 (args_left);
do
{
val = Feval (Fcar (args_left));
if (!NILP (val))
break;
args_left = Fcdr (args_left);
}
while (!NILP(args_left));
UNGCPRO;
return val;
}
DEFUN ("and", Fand, Sand, 0, UNEVALLED, 0,
"Eval args until one of them yields nil, then return nil.\n\
The remaining args are not evalled at all.\n\
If no arg yields nil, return the last arg's value.")
(args)
Lisp_Object args;
{
register Lisp_Object val;
Lisp_Object args_left;
struct gcpro gcpro1;
if (NILP(args))
return Qt;
args_left = args;
GCPRO1 (args_left);
do
{
val = Feval (Fcar (args_left));
if (NILP (val))
break;
args_left = Fcdr (args_left);
}
while (!NILP(args_left));
UNGCPRO;
return val;
}
DEFUN ("if", Fif, Sif, 2, UNEVALLED, 0,
"If COND yields non-nil, do THEN, else do ELSE...\n\
Returns the value of THEN or the value of the last of the ELSE's.\n\
THEN must be one expression, but ELSE... can be zero or more expressions.\n\
If COND yields nil, and there are no ELSE's, the value is nil.")
(args)
Lisp_Object args;
{
register Lisp_Object cond;
struct gcpro gcpro1;
GCPRO1 (args);
cond = Feval (Fcar (args));
UNGCPRO;
if (!NILP (cond))
return Feval (Fcar (Fcdr (args)));
return Fprogn (Fcdr (Fcdr (args)));
}
DEFUN ("cond", Fcond, Scond, 0, UNEVALLED, 0,
"Try each clause until one succeeds.\n\
Each clause looks like (CONDITION BODY...). CONDITION is evaluated\n\
and, if the value is non-nil, this clause succeeds:\n\
then the expressions in BODY are evaluated and the last one's\n\
value is the value of the cond-form.\n\
If no clause succeeds, cond returns nil.\n\
If a clause has one element, as in (CONDITION),\n\
CONDITION's value if non-nil is returned from the cond-form.")
(args)
Lisp_Object args;
{
register Lisp_Object clause, val;
struct gcpro gcpro1;
val = Qnil;
GCPRO1 (args);
while (!NILP (args))
{
clause = Fcar (args);
val = Feval (Fcar (clause));
if (!NILP (val))
{
if (!EQ (XCDR (clause), Qnil))
val = Fprogn (XCDR (clause));
break;
}
args = XCDR (args);
}
UNGCPRO;
return val;
}
DEFUN ("progn", Fprogn, Sprogn, 0, UNEVALLED, 0,
"Eval BODY forms sequentially and return value of last one.")
(args)
Lisp_Object args;
{
register Lisp_Object val, tem;
Lisp_Object args_left;
struct gcpro gcpro1;
if (!EQ (Vmocklisp_arguments, Qt))
{
val = make_number (0);
while (!NILP (args) && (tem = Fcar (args), SYMBOLP (tem)))
{
QUIT;
specbind (tem, val), args = Fcdr (args);
}
}
if (NILP(args))
return Qnil;
args_left = args;
GCPRO1 (args_left);
do
{
val = Feval (Fcar (args_left));
args_left = Fcdr (args_left);
}
while (!NILP(args_left));
UNGCPRO;
return val;
}
DEFUN ("prog1", Fprog1, Sprog1, 1, UNEVALLED, 0,
"Eval FIRST and BODY sequentially; value from FIRST.\n\
The value of FIRST is saved during the evaluation of the remaining args,\n\
whose values are discarded.")
(args)
Lisp_Object args;
{
Lisp_Object val;
register Lisp_Object args_left;
struct gcpro gcpro1, gcpro2;
register int argnum = 0;
if (NILP(args))
return Qnil;
args_left = args;
val = Qnil;
GCPRO2 (args, val);
do
{
if (!(argnum++))
val = Feval (Fcar (args_left));
else
Feval (Fcar (args_left));
args_left = Fcdr (args_left);
}
while (!NILP(args_left));
UNGCPRO;
return val;
}
DEFUN ("prog2", Fprog2, Sprog2, 2, UNEVALLED, 0,
"Eval X, Y and BODY sequentially; value from Y.\n\
The value of Y is saved during the evaluation of the remaining args,\n\
whose values are discarded.")
(args)
Lisp_Object args;
{
Lisp_Object val;
register Lisp_Object args_left;
struct gcpro gcpro1, gcpro2;
register int argnum = -1;
val = Qnil;
if (NILP (args))
return Qnil;
args_left = args;
val = Qnil;
GCPRO2 (args, val);
do
{
if (!(argnum++))
val = Feval (Fcar (args_left));
else
Feval (Fcar (args_left));
args_left = Fcdr (args_left);
}
while (!NILP (args_left));
UNGCPRO;
return val;
}
DEFUN ("setq", Fsetq, Ssetq, 0, UNEVALLED, 0,
"Set each SYM to the value of its VAL.\n\
The symbols SYM are variables; they are literal (not evaluated).\n\
The values VAL are expressions; they are evaluated.\n\
Thus, (setq x (1+ y)) sets `x' to the value of `(1+ y)'.\n\
The second VAL is not computed until after the first SYM is set, and so on;\n\
each VAL can use the new value of variables set earlier in the `setq'.\n\
The return value of the `setq' form is the value of the last VAL.")
(args)
Lisp_Object args;
{
register Lisp_Object args_left;
register Lisp_Object val, sym;
struct gcpro gcpro1;
if (NILP(args))
return Qnil;
args_left = args;
GCPRO1 (args);
do
{
val = Feval (Fcar (Fcdr (args_left)));
sym = Fcar (args_left);
Fset (sym, val);
args_left = Fcdr (Fcdr (args_left));
}
while (!NILP(args_left));
UNGCPRO;
return val;
}
DEFUN ("quote", Fquote, Squote, 1, UNEVALLED, 0,
"Return the argument, without evaluating it. `(quote x)' yields `x'.")
(args)
Lisp_Object args;
{
return Fcar (args);
}
DEFUN ("function", Ffunction, Sfunction, 1, UNEVALLED, 0,
"Like `quote', but preferred for objects which are functions.\n\
In byte compilation, `function' causes its argument to be compiled.\n\
`quote' cannot do that.")
(args)
Lisp_Object args;
{
return Fcar (args);
}
DEFUN ("interactive-p", Finteractive_p, Sinteractive_p, 0, 0, 0,
"Return t if function in which this appears was called interactively.\n\
This means that the function was called with call-interactively (which\n\
includes being called as the binding of a key)\n\
and input is currently coming from the keyboard (not in keyboard macro).")
()
{
return interactive_p (1) ? Qt : Qnil;
}
int
interactive_p (exclude_subrs_p)
int exclude_subrs_p;
{
struct backtrace *btp;
Lisp_Object fun;
if (!INTERACTIVE)
return 0;
btp = backtrace_list;
fun = Findirect_function (*btp->function);
if (SUBRP (fun) && XSUBR (fun) == &Sinteractive_p)
btp = btp->next;
if (EQ (*btp->function, Qbytecode))
btp = btp->next;
while (btp &&
btp->nargs == UNEVALLED)
btp = btp->next;
fun = Findirect_function (*btp->function);
if (exclude_subrs_p && SUBRP (fun))
return 0;
if (btp && btp->next && EQ (*btp->next->function, Qcall_interactively))
return 1;
return 0;
}
DEFUN ("defun", Fdefun, Sdefun, 2, UNEVALLED, 0,
"Define NAME as a function.\n\
The definition is (lambda ARGLIST [DOCSTRING] BODY...).\n\
See also the function `interactive'.")
(args)
Lisp_Object args;
{
register Lisp_Object fn_name;
register Lisp_Object defn;
fn_name = Fcar (args);
defn = Fcons (Qlambda, Fcdr (args));
if (!NILP (Vpurify_flag))
defn = Fpurecopy (defn);
Ffset (fn_name, defn);
LOADHIST_ATTACH (fn_name);
return fn_name;
}
DEFUN ("defmacro", Fdefmacro, Sdefmacro, 2, UNEVALLED, 0,
"Define NAME as a macro.\n\
The definition is (macro lambda ARGLIST [DOCSTRING] BODY...).\n\
When the macro is called, as in (NAME ARGS...),\n\
the function (lambda ARGLIST BODY...) is applied to\n\
the list ARGS... as it appears in the expression,\n\
and the result should be a form to be evaluated instead of the original.")
(args)
Lisp_Object args;
{
register Lisp_Object fn_name;
register Lisp_Object defn;
fn_name = Fcar (args);
defn = Fcons (Qmacro, Fcons (Qlambda, Fcdr (args)));
if (!NILP (Vpurify_flag))
defn = Fpurecopy (defn);
Ffset (fn_name, defn);
LOADHIST_ATTACH (fn_name);
return fn_name;
}
DEFUN ("defvar", Fdefvar, Sdefvar, 1, UNEVALLED, 0,
"Define SYMBOL as a variable.\n\
You are not required to define a variable in order to use it,\n\
but the definition can supply documentation and an initial value\n\
in a way that tags can recognize.\n\n\
INITVALUE is evaluated, and used to set SYMBOL, only if SYMBOL's value is void.\n\
If SYMBOL is buffer-local, its default value is what is set;\n\
buffer-local values are not affected.\n\
INITVALUE and DOCSTRING are optional.\n\
If DOCSTRING starts with *, this variable is identified as a user option.\n\
This means that M-x set-variable recognizes it.\n\
See also `user-variable-p'.\n\
If INITVALUE is missing, SYMBOL's value is not set.")
(args)
Lisp_Object args;
{
register Lisp_Object sym, tem, tail;
sym = Fcar (args);
tail = Fcdr (args);
if (!NILP (Fcdr (Fcdr (tail))))
error ("too many arguments");
tem = Fdefault_boundp (sym);
if (!NILP (tail))
{
if (NILP (tem))
Fset_default (sym, Feval (Fcar (tail)));
tail = Fcdr (tail);
if (!NILP (Fcar (tail)))
{
tem = Fcar (tail);
if (!NILP (Vpurify_flag))
tem = Fpurecopy (tem);
Fput (sym, Qvariable_documentation, tem);
}
LOADHIST_ATTACH (sym);
}
else
if (NILP (tem))
LOADHIST_ATTACH (sym);
return sym;
}
DEFUN ("defconst", Fdefconst, Sdefconst, 2, UNEVALLED, 0,
"Define SYMBOL as a constant variable.\n\
The intent is that neither programs nor users should ever change this value.\n\
Always sets the value of SYMBOL to the result of evalling INITVALUE.\n\
If SYMBOL is buffer-local, its default value is what is set;\n\
buffer-local values are not affected.\n\
DOCSTRING is optional.")
(args)
Lisp_Object args;
{
register Lisp_Object sym, tem;
sym = Fcar (args);
if (!NILP (Fcdr (Fcdr (Fcdr (args)))))
error ("too many arguments");
tem = Feval (Fcar (Fcdr (args)));
if (!NILP (Vpurify_flag))
tem = Fpurecopy (tem);
Fset_default (sym, tem);
tem = Fcar (Fcdr (Fcdr (args)));
if (!NILP (tem))
{
if (!NILP (Vpurify_flag))
tem = Fpurecopy (tem);
Fput (sym, Qvariable_documentation, tem);
}
LOADHIST_ATTACH (sym);
return sym;
}
DEFUN ("user-variable-p", Fuser_variable_p, Suser_variable_p, 1, 1, 0,
"Returns t if VARIABLE is intended to be set and modified by users.\n\
\(The alternative is a variable used internally in a Lisp program.)\n\
Determined by whether the first character of the documentation\n\
for the variable is `*' or if the variable is customizable (has a non-nil\n\
value of any of `custom-type', `custom-loads' or `standard-value'\n\
on its property list).")
(variable)
Lisp_Object variable;
{
Lisp_Object documentation;
if (!SYMBOLP (variable))
return Qnil;
documentation = Fget (variable, Qvariable_documentation);
if (INTEGERP (documentation) && XINT (documentation) < 0)
return Qt;
if (STRINGP (documentation)
&& ((unsigned char) XSTRING (documentation)->data[0] == '*'))
return Qt;
if (CONSP (documentation)
&& STRINGP (XCAR (documentation))
&& INTEGERP (XCDR (documentation))
&& XINT (XCDR (documentation)) < 0)
return Qt;
if ((!NILP (Fget (variable, intern ("custom-type"))))
|| (!NILP (Fget (variable, intern ("custom-loads"))))
|| (!NILP (Fget (variable, intern ("standard-value")))))
return Qt;
return Qnil;
}
DEFUN ("let*", FletX, SletX, 1, UNEVALLED, 0,
"Bind variables according to VARLIST then eval BODY.\n\
The value of the last form in BODY is returned.\n\
Each element of VARLIST is a symbol (which is bound to nil)\n\
or a list (SYMBOL VALUEFORM) (which binds SYMBOL to the value of VALUEFORM).\n\
Each VALUEFORM can refer to the symbols already bound by this VARLIST.")
(args)
Lisp_Object args;
{
Lisp_Object varlist, val, elt;
int count = specpdl_ptr - specpdl;
struct gcpro gcpro1, gcpro2, gcpro3;
GCPRO3 (args, elt, varlist);
varlist = Fcar (args);
while (!NILP (varlist))
{
QUIT;
elt = Fcar (varlist);
if (SYMBOLP (elt))
specbind (elt, Qnil);
else if (! NILP (Fcdr (Fcdr (elt))))
Fsignal (Qerror,
Fcons (build_string ("`let' bindings can have only one value-form"),
elt));
else
{
val = Feval (Fcar (Fcdr (elt)));
specbind (Fcar (elt), val);
}
varlist = Fcdr (varlist);
}
UNGCPRO;
val = Fprogn (Fcdr (args));
return unbind_to (count, val);
}
DEFUN ("let", Flet, Slet, 1, UNEVALLED, 0,
"Bind variables according to VARLIST then eval BODY.\n\
The value of the last form in BODY is returned.\n\
Each element of VARLIST is a symbol (which is bound to nil)\n\
or a list (SYMBOL VALUEFORM) (which binds SYMBOL to the value of VALUEFORM).\n\
All the VALUEFORMs are evalled before any symbols are bound.")
(args)
Lisp_Object args;
{
Lisp_Object *temps, tem;
register Lisp_Object elt, varlist;
int count = specpdl_ptr - specpdl;
register int argnum;
struct gcpro gcpro1, gcpro2;
varlist = Fcar (args);
elt = Flength (varlist);
temps = (Lisp_Object *) alloca (XFASTINT (elt) * sizeof (Lisp_Object));
GCPRO2 (args, *temps);
gcpro2.nvars = 0;
for (argnum = 0; !NILP (varlist); varlist = Fcdr (varlist))
{
QUIT;
elt = Fcar (varlist);
if (SYMBOLP (elt))
temps [argnum++] = Qnil;
else if (! NILP (Fcdr (Fcdr (elt))))
Fsignal (Qerror,
Fcons (build_string ("`let' bindings can have only one value-form"),
elt));
else
temps [argnum++] = Feval (Fcar (Fcdr (elt)));
gcpro2.nvars = argnum;
}
UNGCPRO;
varlist = Fcar (args);
for (argnum = 0; !NILP (varlist); varlist = Fcdr (varlist))
{
elt = Fcar (varlist);
tem = temps[argnum++];
if (SYMBOLP (elt))
specbind (elt, tem);
else
specbind (Fcar (elt), tem);
}
elt = Fprogn (Fcdr (args));
return unbind_to (count, elt);
}
DEFUN ("while", Fwhile, Swhile, 1, UNEVALLED, 0,
"If TEST yields non-nil, eval BODY... and repeat.\n\
The order of execution is thus TEST, BODY, TEST, BODY and so on\n\
until TEST returns nil.")
(args)
Lisp_Object args;
{
Lisp_Object test, body, tem;
struct gcpro gcpro1, gcpro2;
GCPRO2 (test, body);
test = Fcar (args);
body = Fcdr (args);
while (tem = Feval (test),
(!EQ (Vmocklisp_arguments, Qt) ? XINT (tem) : !NILP (tem)))
{
QUIT;
Fprogn (body);
}
UNGCPRO;
return Qnil;
}
DEFUN ("macroexpand", Fmacroexpand, Smacroexpand, 1, 2, 0,
"Return result of expanding macros at top level of FORM.\n\
If FORM is not a macro call, it is returned unchanged.\n\
Otherwise, the macro is expanded and the expansion is considered\n\
in place of FORM. When a non-macro-call results, it is returned.\n\n\
The second optional arg ENVIRONMENT specifies an environment of macro\n\
definitions to shadow the loaded ones for use in file byte-compilation.")
(form, environment)
Lisp_Object form;
Lisp_Object environment;
{
register Lisp_Object expander, sym, def, tem;
while (1)
{
if (!CONSP (form))
break;
def = sym = XCAR (form);
tem = Qnil;
while (SYMBOLP (def))
{
QUIT;
sym = def;
tem = Fassq (sym, environment);
if (NILP (tem))
{
def = XSYMBOL (sym)->function;
if (!EQ (def, Qunbound))
continue;
}
break;
}
if (NILP (tem))
{
if (EQ (def, Qunbound) || !CONSP (def))
break;
if (EQ (XCAR (def), Qautoload))
{
tem = Fnth (make_number (4), def);
if (EQ (tem, Qt) || EQ (tem, Qmacro))
{
struct gcpro gcpro1;
GCPRO1 (form);
do_autoload (def, sym);
UNGCPRO;
continue;
}
else
break;
}
else if (!EQ (XCAR (def), Qmacro))
break;
else expander = XCDR (def);
}
else
{
expander = XCDR (tem);
if (NILP (expander))
break;
}
form = apply1 (expander, XCDR (form));
}
return form;
}
DEFUN ("catch", Fcatch, Scatch, 1, UNEVALLED, 0,
"Eval BODY allowing nonlocal exits using `throw'.\n\
TAG is evalled to get the tag to use; it must not be nil.\n\
\n\
Then the BODY is executed.\n\
Within BODY, (throw TAG) with same tag exits BODY and exits this `catch'.\n\
If no throw happens, `catch' returns the value of the last BODY form.\n\
If a throw happens, it specifies the value to return from `catch'.")
(args)
Lisp_Object args;
{
register Lisp_Object tag;
struct gcpro gcpro1;
GCPRO1 (args);
tag = Feval (Fcar (args));
UNGCPRO;
return internal_catch (tag, Fprogn, Fcdr (args));
}
Lisp_Object
internal_catch (tag, func, arg)
Lisp_Object tag;
Lisp_Object (*func) ();
Lisp_Object arg;
{
struct catchtag c;
c.next = catchlist;
c.tag = tag;
c.val = Qnil;
c.backlist = backtrace_list;
c.handlerlist = handlerlist;
c.lisp_eval_depth = lisp_eval_depth;
c.pdlcount = specpdl_ptr - specpdl;
c.poll_suppress_count = poll_suppress_count;
c.gcpro = gcprolist;
c.byte_stack = byte_stack_list;
catchlist = &c;
if (! _setjmp (c.jmp))
c.val = (*func) (arg);
catchlist = c.next;
return c.val;
}
static void
unwind_to_catch (catch, value)
struct catchtag *catch;
Lisp_Object value;
{
register int last_time;
catch->val = value;
set_poll_suppress_count (catch->poll_suppress_count);
do
{
last_time = catchlist == catch;
unbind_to (catchlist->pdlcount, Qnil);
handlerlist = catchlist->handlerlist;
catchlist = catchlist->next;
}
while (! last_time);
byte_stack_list = catch->byte_stack;
gcprolist = catch->gcpro;
#ifdef DEBUG_GCPRO
if (gcprolist != 0)
gcpro_level = gcprolist->level + 1;
else
gcpro_level = 0;
#endif
backtrace_list = catch->backlist;
lisp_eval_depth = catch->lisp_eval_depth;
_longjmp (catch->jmp, 1);
}
DEFUN ("throw", Fthrow, Sthrow, 2, 2, 0,
"Throw to the catch for TAG and return VALUE from it.\n\
Both TAG and VALUE are evalled.")
(tag, value)
register Lisp_Object tag, value;
{
register struct catchtag *c;
while (1)
{
if (!NILP (tag))
for (c = catchlist; c; c = c->next)
{
if (EQ (c->tag, tag))
unwind_to_catch (c, value);
}
tag = Fsignal (Qno_catch, Fcons (tag, Fcons (value, Qnil)));
}
}
DEFUN ("unwind-protect", Funwind_protect, Sunwind_protect, 1, UNEVALLED, 0,
"Do BODYFORM, protecting with UNWINDFORMS.\n\
If BODYFORM completes normally, its value is returned\n\
after executing the UNWINDFORMS.\n\
If BODYFORM exits nonlocally, the UNWINDFORMS are executed anyway.")
(args)
Lisp_Object args;
{
Lisp_Object val;
int count = specpdl_ptr - specpdl;
record_unwind_protect (0, Fcdr (args));
val = Feval (Fcar (args));
return unbind_to (count, val);
}
struct handler *handlerlist;
DEFUN ("condition-case", Fcondition_case, Scondition_case, 2, UNEVALLED, 0,
"Regain control when an error is signaled.\n\
executes BODYFORM and returns its value if no error happens.\n\
Each element of HANDLERS looks like (CONDITION-NAME BODY...)\n\
where the BODY is made of Lisp expressions.\n\n\
A handler is applicable to an error\n\
if CONDITION-NAME is one of the error's condition names.\n\
If an error happens, the first applicable handler is run.\n\
\n\
The car of a handler may be a list of condition names\n\
instead of a single condition name.\n\
\n\
When a handler handles an error,\n\
control returns to the condition-case and the handler BODY... is executed\n\
with VAR bound to (SIGNALED-CONDITIONS . SIGNAL-DATA).\n\
VAR may be nil; then you do not get access to the signal information.\n\
\n\
The value of the last BODY form is returned from the condition-case.\n\
See also the function `signal' for more info.")
(args)
Lisp_Object args;
{
Lisp_Object val;
struct catchtag c;
struct handler h;
register Lisp_Object bodyform, handlers;
volatile Lisp_Object var;
var = Fcar (args);
bodyform = Fcar (Fcdr (args));
handlers = Fcdr (Fcdr (args));
CHECK_SYMBOL (var, 0);
for (val = handlers; ! NILP (val); val = Fcdr (val))
{
Lisp_Object tem;
tem = Fcar (val);
if (! (NILP (tem)
|| (CONSP (tem)
&& (SYMBOLP (XCAR (tem))
|| CONSP (XCAR (tem))))))
error ("Invalid condition handler", tem);
}
c.tag = Qnil;
c.val = Qnil;
c.backlist = backtrace_list;
c.handlerlist = handlerlist;
c.lisp_eval_depth = lisp_eval_depth;
c.pdlcount = specpdl_ptr - specpdl;
c.poll_suppress_count = poll_suppress_count;
c.gcpro = gcprolist;
c.byte_stack = byte_stack_list;
if (_setjmp (c.jmp))
{
if (!NILP (h.var))
specbind (h.var, c.val);
val = Fprogn (Fcdr (h.chosen_clause));
unbind_to (c.pdlcount, Qnil);
return val;
}
c.next = catchlist;
catchlist = &c;
h.var = var;
h.handler = handlers;
h.next = handlerlist;
h.tag = &c;
handlerlist = &h;
val = Feval (bodyform);
catchlist = c.next;
handlerlist = h.next;
return val;
}
Lisp_Object
internal_condition_case (bfun, handlers, hfun)
Lisp_Object (*bfun) ();
Lisp_Object handlers;
Lisp_Object (*hfun) ();
{
Lisp_Object val;
struct catchtag c;
struct handler h;
#if 0
if (interrupt_input_blocked != 0)
abort ();
#endif
c.tag = Qnil;
c.val = Qnil;
c.backlist = backtrace_list;
c.handlerlist = handlerlist;
c.lisp_eval_depth = lisp_eval_depth;
c.pdlcount = specpdl_ptr - specpdl;
c.poll_suppress_count = poll_suppress_count;
c.gcpro = gcprolist;
c.byte_stack = byte_stack_list;
if (_setjmp (c.jmp))
{
return (*hfun) (c.val);
}
c.next = catchlist;
catchlist = &c;
h.handler = handlers;
h.var = Qnil;
h.next = handlerlist;
h.tag = &c;
handlerlist = &h;
val = (*bfun) ();
catchlist = c.next;
handlerlist = h.next;
return val;
}
Lisp_Object
internal_condition_case_1 (bfun, arg, handlers, hfun)
Lisp_Object (*bfun) ();
Lisp_Object arg;
Lisp_Object handlers;
Lisp_Object (*hfun) ();
{
Lisp_Object val;
struct catchtag c;
struct handler h;
c.tag = Qnil;
c.val = Qnil;
c.backlist = backtrace_list;
c.handlerlist = handlerlist;
c.lisp_eval_depth = lisp_eval_depth;
c.pdlcount = specpdl_ptr - specpdl;
c.poll_suppress_count = poll_suppress_count;
c.gcpro = gcprolist;
c.byte_stack = byte_stack_list;
if (_setjmp (c.jmp))
{
return (*hfun) (c.val);
}
c.next = catchlist;
catchlist = &c;
h.handler = handlers;
h.var = Qnil;
h.next = handlerlist;
h.tag = &c;
handlerlist = &h;
val = (*bfun) (arg);
catchlist = c.next;
handlerlist = h.next;
return val;
}
Lisp_Object
internal_condition_case_2 (bfun, nargs, args, handlers, hfun)
Lisp_Object (*bfun) ();
int nargs;
Lisp_Object *args;
Lisp_Object handlers;
Lisp_Object (*hfun) ();
{
Lisp_Object val;
struct catchtag c;
struct handler h;
c.tag = Qnil;
c.val = Qnil;
c.backlist = backtrace_list;
c.handlerlist = handlerlist;
c.lisp_eval_depth = lisp_eval_depth;
c.pdlcount = specpdl_ptr - specpdl;
c.poll_suppress_count = poll_suppress_count;
c.gcpro = gcprolist;
c.byte_stack = byte_stack_list;
if (_setjmp (c.jmp))
{
return (*hfun) (c.val);
}
c.next = catchlist;
catchlist = &c;
h.handler = handlers;
h.var = Qnil;
h.next = handlerlist;
h.tag = &c;
handlerlist = &h;
val = (*bfun) (nargs, args);
catchlist = c.next;
handlerlist = h.next;
return val;
}
static Lisp_Object find_handler_clause ();
DEFUN ("signal", Fsignal, Ssignal, 2, 2, 0,
"Signal an error. Args are ERROR-SYMBOL and associated DATA.\n\
This function does not return.\n\n\
An error symbol is a symbol with an `error-conditions' property\n\
that is a list of condition names.\n\
A handler for any of those names will get to handle this signal.\n\
The symbol `error' should normally be one of them.\n\
\n\
DATA should be a list. Its elements are printed as part of the error message.\n\
If the signal is handled, DATA is made available to the handler.\n\
See also the function `condition-case'.")
(error_symbol, data)
Lisp_Object error_symbol, data;
{
register struct handler *allhandlers = handlerlist;
Lisp_Object conditions;
extern int gc_in_progress;
extern int waiting_for_input;
Lisp_Object debugger_value;
Lisp_Object string;
Lisp_Object real_error_symbol;
extern int display_hourglass_p;
struct backtrace *bp;
immediate_quit = handling_signal = 0;
if (gc_in_progress || waiting_for_input)
abort ();
TOTALLY_UNBLOCK_INPUT;
if (NILP (error_symbol))
real_error_symbol = Fcar (data);
else
real_error_symbol = error_symbol;
#ifdef HAVE_X_WINDOWS
if (display_hourglass_p)
cancel_hourglass ();
#endif
if (! NILP (Vsignal_hook_function))
call2 (Vsignal_hook_function, error_symbol, data);
conditions = Fget (real_error_symbol, Qerror_conditions);
Vsignaling_function = Qnil;
if (backtrace_list)
{
bp = backtrace_list->next;
if (bp && bp->function && EQ (*bp->function, Qerror))
bp = bp->next;
if (bp && bp->function)
Vsignaling_function = *bp->function;
}
for (; handlerlist; handlerlist = handlerlist->next)
{
register Lisp_Object clause;
if (lisp_eval_depth + 20 > max_lisp_eval_depth)
max_lisp_eval_depth = lisp_eval_depth + 20;
if (specpdl_size + 40 > max_specpdl_size)
max_specpdl_size = specpdl_size + 40;
clause = find_handler_clause (handlerlist->handler, conditions,
error_symbol, data, &debugger_value);
#if 0
if (EQ (clause, Qlambda))
return debugger_value;
#else
if (EQ (clause, Qlambda))
{
if (EQ (real_error_symbol, Qquit))
return Qnil;
else
error ("Cannot return from the debugger in an error");
}
#endif
if (!NILP (clause))
{
Lisp_Object unwind_data;
struct handler *h = handlerlist;
handlerlist = allhandlers;
if (NILP (error_symbol))
unwind_data = data;
else
unwind_data = Fcons (error_symbol, data);
h->chosen_clause = clause;
unwind_to_catch (h->tag, unwind_data);
}
}
handlerlist = allhandlers;
find_handler_clause (Qerror, conditions, error_symbol, data, &debugger_value);
if (catchlist != 0)
Fthrow (Qtop_level, Qt);
if (! NILP (error_symbol))
data = Fcons (error_symbol, data);
string = Ferror_message_string (data);
fatal ("%s", XSTRING (string)->data, 0);
}
static int
wants_debugger (list, conditions)
Lisp_Object list, conditions;
{
if (NILP (list))
return 0;
if (! CONSP (list))
return 1;
while (CONSP (conditions))
{
Lisp_Object this, tail;
this = XCAR (conditions);
for (tail = list; CONSP (tail); tail = XCDR (tail))
if (EQ (XCAR (tail), this))
return 1;
conditions = XCDR (conditions);
}
return 0;
}
static int
skip_debugger (conditions, data)
Lisp_Object conditions, data;
{
Lisp_Object tail;
int first_string = 1;
Lisp_Object error_message;
error_message = Qnil;
for (tail = Vdebug_ignored_errors; CONSP (tail); tail = XCDR (tail))
{
if (STRINGP (XCAR (tail)))
{
if (first_string)
{
error_message = Ferror_message_string (data);
first_string = 0;
}
if (fast_string_match (XCAR (tail), error_message) >= 0)
return 1;
}
else
{
Lisp_Object contail;
for (contail = conditions; CONSP (contail); contail = XCDR (contail))
if (EQ (XCAR (tail), XCAR (contail)))
return 1;
}
}
return 0;
}
static Lisp_Object
find_handler_clause (handlers, conditions, sig, data, debugger_value_ptr)
Lisp_Object handlers, conditions, sig, data;
Lisp_Object *debugger_value_ptr;
{
register Lisp_Object h;
register Lisp_Object tem;
if (EQ (handlers, Qt))
return Qt;
if (EQ (handlers, Qerror)
|| !NILP (Vdebug_on_signal))
{
int count = specpdl_ptr - specpdl;
int debugger_called = 0;
Lisp_Object sig_symbol, combined_data;
int no_debugger = 0;
if (NILP (sig))
{
combined_data = data;
sig_symbol = Fcar (data);
no_debugger = 1;
}
else
{
combined_data = Fcons (sig, data);
sig_symbol = sig;
}
if (wants_debugger (Vstack_trace_on_error, conditions))
{
#ifdef PROTOTYPES
internal_with_output_to_temp_buffer ("*Backtrace*",
(Lisp_Object (*) (Lisp_Object)) Fbacktrace,
Qnil);
#else
internal_with_output_to_temp_buffer ("*Backtrace*",
Fbacktrace, Qnil);
#endif
}
if (! no_debugger
&& (EQ (sig_symbol, Qquit)
? debug_on_quit
: wants_debugger (Vdebug_on_error, conditions))
&& ! skip_debugger (conditions, combined_data)
&& when_entered_debugger < num_nonmacro_input_events)
{
specbind (Qdebug_on_error, Qnil);
*debugger_value_ptr
= call_debugger (Fcons (Qerror,
Fcons (combined_data, Qnil)));
debugger_called = 1;
}
if (EQ (handlers, Qerror))
{
if (debugger_called)
return unbind_to (count, Qlambda);
return Qt;
}
}
for (h = handlers; CONSP (h); h = Fcdr (h))
{
Lisp_Object handler, condit;
handler = Fcar (h);
if (!CONSP (handler))
continue;
condit = Fcar (handler);
if (SYMBOLP (condit))
{
tem = Fmemq (Fcar (handler), conditions);
if (!NILP (tem))
return handler;
}
else if (CONSP (condit))
{
while (CONSP (condit))
{
tem = Fmemq (Fcar (condit), conditions);
if (!NILP (tem))
return handler;
condit = XCDR (condit);
}
}
}
return Qnil;
}
void
error (m, a1, a2, a3)
char *m;
char *a1, *a2, *a3;
{
char buf[200];
int size = 200;
int mlen;
char *buffer = buf;
char *args[3];
int allocated = 0;
Lisp_Object string;
args[0] = a1;
args[1] = a2;
args[2] = a3;
mlen = strlen (m);
while (1)
{
int used = doprnt (buffer, size, m, m + mlen, 3, args);
if (used < size)
break;
size *= 2;
if (allocated)
buffer = (char *) xrealloc (buffer, size);
else
{
buffer = (char *) xmalloc (size);
allocated = 1;
}
}
string = build_string (buffer);
if (allocated)
xfree (buffer);
Fsignal (Qerror, Fcons (string, Qnil));
abort ();
}
DEFUN ("commandp", Fcommandp, Scommandp, 1, 1, 0,
"T if FUNCTION makes provisions for interactive calling.\n\
This means it contains a description for how to read arguments to give it.\n\
The value is nil for an invalid function or a symbol with no function\n\
definition.\n\
\n\
Interactively callable functions include strings and vectors (treated\n\
as keyboard macros), lambda-expressions that contain a top-level call\n\
to `interactive', autoload definitions made by `autoload' with non-nil\n\
fourth argument, and some of the built-in functions of Lisp.\n\
\n\
Also, a symbol satisfies `commandp' if its function definition does so.")
(function)
Lisp_Object function;
{
register Lisp_Object fun;
register Lisp_Object funcar;
fun = function;
fun = indirect_function (fun);
if (EQ (fun, Qunbound))
return Qnil;
if (SUBRP (fun))
{
if (XSUBR (fun)->prompt)
return Qt;
else
return Qnil;
}
else if (COMPILEDP (fun))
return ((XVECTOR (fun)->size & PSEUDOVECTOR_SIZE_MASK) > COMPILED_INTERACTIVE
? Qt : Qnil);
if (STRINGP (fun) || VECTORP (fun))
return Qt;
if (!CONSP (fun))
return Qnil;
funcar = Fcar (fun);
if (!SYMBOLP (funcar))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
if (EQ (funcar, Qlambda))
return Fassq (Qinteractive, Fcdr (Fcdr (fun)));
if (EQ (funcar, Qmocklisp))
return Qt;
if (EQ (funcar, Qautoload))
return Fcar (Fcdr (Fcdr (Fcdr (fun))));
else
return Qnil;
}
DEFUN ("autoload", Fautoload, Sautoload, 2, 5, 0,
"Define FUNCTION to autoload from FILE.\n\
FUNCTION is a symbol; FILE is a file name string to pass to `load'.\n\
Third arg DOCSTRING is documentation for the function.\n\
Fourth arg INTERACTIVE if non-nil says function can be called interactively.\n\
Fifth arg TYPE indicates the type of the object:\n\
nil or omitted says FUNCTION is a function,\n\
`keymap' says FUNCTION is really a keymap, and\n\
`macro' or t says FUNCTION is really a macro.\n\
Third through fifth args give info about the real definition.\n\
They default to nil.\n\
If FUNCTION is already defined other than as an autoload,\n\
this does nothing and returns nil.")
(function, file, docstring, interactive, type)
Lisp_Object function, file, docstring, interactive, type;
{
#ifdef NO_ARG_ARRAY
Lisp_Object args[4];
#endif
CHECK_SYMBOL (function, 0);
CHECK_STRING (file, 1);
if (!EQ (XSYMBOL (function)->function, Qunbound)
&& !(CONSP (XSYMBOL (function)->function)
&& EQ (XCAR (XSYMBOL (function)->function), Qautoload)))
return Qnil;
if (NILP (Vpurify_flag))
LOADHIST_ATTACH (Fcons (Qautoload, function));
#ifdef NO_ARG_ARRAY
args[0] = file;
args[1] = docstring;
args[2] = interactive;
args[3] = type;
return Ffset (function, Fcons (Qautoload, Flist (4, &args[0])));
#else
return Ffset (function, Fcons (Qautoload, Flist (4, &file)));
#endif
}
Lisp_Object
un_autoload (oldqueue)
Lisp_Object oldqueue;
{
register Lisp_Object queue, first, second;
queue = Vautoload_queue;
Vautoload_queue = oldqueue;
while (CONSP (queue))
{
first = Fcar (queue);
second = Fcdr (first);
first = Fcar (first);
if (EQ (second, Qnil))
Vfeatures = first;
else
Ffset (first, second);
queue = Fcdr (queue);
}
return Qnil;
}
void
do_autoload (fundef, funname)
Lisp_Object fundef, funname;
{
int count = specpdl_ptr - specpdl;
Lisp_Object fun, queue, first, second;
struct gcpro gcpro1, gcpro2, gcpro3;
fun = funname;
CHECK_SYMBOL (funname, 0);
GCPRO3 (fun, funname, fundef);
record_unwind_protect (Fset_match_data, Fmatch_data (Qnil, Qnil));
record_unwind_protect (un_autoload, Vautoload_queue);
Vautoload_queue = Qt;
Fload (Fcar (Fcdr (fundef)), Qnil, noninteractive ? Qt : Qnil, Qnil, Qt);
queue = Vautoload_queue;
while (CONSP (queue))
{
first = Fcar (queue);
second = Fcdr (first);
first = Fcar (first);
if (CONSP (second))
Fput (first, Qautoload, (Fcdr (second)));
queue = Fcdr (queue);
}
Vautoload_queue = Qt;
unbind_to (count, Qnil);
fun = Findirect_function (fun);
if (!NILP (Fequal (fun, fundef)))
error ("Autoloading failed to define function %s",
XSYMBOL (funname)->name->data);
UNGCPRO;
}
DEFUN ("eval", Feval, Seval, 1, 1, 0,
"Evaluate FORM and return its value.")
(form)
Lisp_Object form;
{
Lisp_Object fun, val, original_fun, original_args;
Lisp_Object funcar;
struct backtrace backtrace;
struct gcpro gcpro1, gcpro2, gcpro3;
if (handling_signal)
abort ();
if (SYMBOLP (form))
{
if (EQ (Vmocklisp_arguments, Qt))
return Fsymbol_value (form);
val = Fsymbol_value (form);
if (NILP (val))
XSETFASTINT (val, 0);
else if (EQ (val, Qt))
XSETFASTINT (val, 1);
return val;
}
if (!CONSP (form))
return form;
QUIT;
if (consing_since_gc > gc_cons_threshold)
{
GCPRO1 (form);
Fgarbage_collect ();
UNGCPRO;
}
if (++lisp_eval_depth > max_lisp_eval_depth)
{
if (max_lisp_eval_depth < 100)
max_lisp_eval_depth = 100;
if (lisp_eval_depth > max_lisp_eval_depth)
error ("Lisp nesting exceeds max-lisp-eval-depth");
}
original_fun = Fcar (form);
original_args = Fcdr (form);
backtrace.next = backtrace_list;
backtrace_list = &backtrace;
backtrace.function = &original_fun;
backtrace.args = &original_args;
backtrace.nargs = UNEVALLED;
backtrace.evalargs = 1;
backtrace.debug_on_exit = 0;
if (debug_on_next_call)
do_debug_on_call (Qt);
retry:
fun = Findirect_function (original_fun);
if (SUBRP (fun))
{
Lisp_Object numargs;
Lisp_Object argvals[8];
Lisp_Object args_left;
register int i, maxargs;
args_left = original_args;
numargs = Flength (args_left);
if (XINT (numargs) < XSUBR (fun)->min_args ||
(XSUBR (fun)->max_args >= 0 && XSUBR (fun)->max_args < XINT (numargs)))
return Fsignal (Qwrong_number_of_arguments, Fcons (fun, Fcons (numargs, Qnil)));
if (XSUBR (fun)->max_args == UNEVALLED)
{
backtrace.evalargs = 0;
val = (*XSUBR (fun)->function) (args_left);
goto done;
}
if (XSUBR (fun)->max_args == MANY)
{
Lisp_Object *vals;
register int argnum = 0;
vals = (Lisp_Object *) alloca (XINT (numargs) * sizeof (Lisp_Object));
GCPRO3 (args_left, fun, fun);
gcpro3.var = vals;
gcpro3.nvars = 0;
while (!NILP (args_left))
{
vals[argnum++] = Feval (Fcar (args_left));
args_left = Fcdr (args_left);
gcpro3.nvars = argnum;
}
backtrace.args = vals;
backtrace.nargs = XINT (numargs);
val = (*XSUBR (fun)->function) (XINT (numargs), vals);
UNGCPRO;
goto done;
}
GCPRO3 (args_left, fun, fun);
gcpro3.var = argvals;
gcpro3.nvars = 0;
maxargs = XSUBR (fun)->max_args;
for (i = 0; i < maxargs; args_left = Fcdr (args_left))
{
argvals[i] = Feval (Fcar (args_left));
gcpro3.nvars = ++i;
}
UNGCPRO;
backtrace.args = argvals;
backtrace.nargs = XINT (numargs);
switch (i)
{
case 0:
val = (*XSUBR (fun)->function) ();
goto done;
case 1:
val = (*XSUBR (fun)->function) (argvals[0]);
goto done;
case 2:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1]);
goto done;
case 3:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1],
argvals[2]);
goto done;
case 4:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1],
argvals[2], argvals[3]);
goto done;
case 5:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1], argvals[2],
argvals[3], argvals[4]);
goto done;
case 6:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1], argvals[2],
argvals[3], argvals[4], argvals[5]);
goto done;
case 7:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1], argvals[2],
argvals[3], argvals[4], argvals[5],
argvals[6]);
goto done;
case 8:
val = (*XSUBR (fun)->function) (argvals[0], argvals[1], argvals[2],
argvals[3], argvals[4], argvals[5],
argvals[6], argvals[7]);
goto done;
default:
abort ();
}
}
if (COMPILEDP (fun))
val = apply_lambda (fun, original_args, 1);
else
{
if (!CONSP (fun))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
funcar = Fcar (fun);
if (!SYMBOLP (funcar))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
if (EQ (funcar, Qautoload))
{
do_autoload (fun, original_fun);
goto retry;
}
if (EQ (funcar, Qmacro))
val = Feval (apply1 (Fcdr (fun), original_args));
else if (EQ (funcar, Qlambda))
val = apply_lambda (fun, original_args, 1);
else if (EQ (funcar, Qmocklisp))
val = ml_apply (fun, original_args);
else
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
}
done:
if (!EQ (Vmocklisp_arguments, Qt))
{
if (NILP (val))
XSETFASTINT (val, 0);
else if (EQ (val, Qt))
XSETFASTINT (val, 1);
}
lisp_eval_depth--;
if (backtrace.debug_on_exit)
val = call_debugger (Fcons (Qexit, Fcons (val, Qnil)));
backtrace_list = backtrace.next;
return val;
}
DEFUN ("apply", Fapply, Sapply, 2, MANY, 0,
"Call FUNCTION with our remaining args, using our last arg as list of args.\n\
Then return the value FUNCTION returns.\n\
Thus, (apply '+ 1 2 '(3 4)) returns 10.")
(nargs, args)
int nargs;
Lisp_Object *args;
{
register int i, numargs;
register Lisp_Object spread_arg;
register Lisp_Object *funcall_args;
Lisp_Object fun;
struct gcpro gcpro1;
fun = args [0];
funcall_args = 0;
spread_arg = args [nargs - 1];
CHECK_LIST (spread_arg, nargs);
numargs = XINT (Flength (spread_arg));
if (numargs == 0)
return Ffuncall (nargs - 1, args);
else if (numargs == 1)
{
args [nargs - 1] = XCAR (spread_arg);
return Ffuncall (nargs, args);
}
numargs += nargs - 2;
fun = indirect_function (fun);
if (EQ (fun, Qunbound))
{
fun = args[0];
goto funcall;
}
if (SUBRP (fun))
{
if (numargs < XSUBR (fun)->min_args
|| (XSUBR (fun)->max_args >= 0 && XSUBR (fun)->max_args < numargs))
goto funcall;
else if (XSUBR (fun)->max_args > numargs)
{
funcall_args = (Lisp_Object *) alloca ((1 + XSUBR (fun)->max_args)
* sizeof (Lisp_Object));
for (i = numargs; i < XSUBR (fun)->max_args;)
funcall_args[++i] = Qnil;
GCPRO1 (*funcall_args);
gcpro1.nvars = 1 + XSUBR (fun)->max_args;
}
}
funcall:
if (!funcall_args)
{
funcall_args = (Lisp_Object *) alloca ((1 + numargs)
* sizeof (Lisp_Object));
GCPRO1 (*funcall_args);
gcpro1.nvars = 1 + numargs;
}
bcopy (args, funcall_args, nargs * sizeof (Lisp_Object));
i = nargs - 1;
while (!NILP (spread_arg))
{
funcall_args [i++] = XCAR (spread_arg);
spread_arg = XCDR (spread_arg);
}
RETURN_UNGCPRO (Ffuncall (gcpro1.nvars, funcall_args));
}
enum run_hooks_condition {to_completion, until_success, until_failure};
DEFUN ("run-hooks", Frun_hooks, Srun_hooks, 0, MANY, 0,
"Run each hook in HOOKS. Major mode functions use this.\n\
Each argument should be a symbol, a hook variable.\n\
These symbols are processed in the order specified.\n\
If a hook symbol has a non-nil value, that value may be a function\n\
or a list of functions to be called to run the hook.\n\
If the value is a function, it is called with no arguments.\n\
If it is a list, the elements are called, in order, with no arguments.\n\
\n\
To make a hook variable buffer-local, use `make-local-hook',\n\
not `make-local-variable'.")
(nargs, args)
int nargs;
Lisp_Object *args;
{
Lisp_Object hook[1];
register int i;
for (i = 0; i < nargs; i++)
{
hook[0] = args[i];
run_hook_with_args (1, hook, to_completion);
}
return Qnil;
}
DEFUN ("run-hook-with-args", Frun_hook_with_args,
Srun_hook_with_args, 1, MANY, 0,
"Run HOOK with the specified arguments ARGS.\n\
HOOK should be a symbol, a hook variable. If HOOK has a non-nil\n\
value, that value may be a function or a list of functions to be\n\
called to run the hook. If the value is a function, it is called with\n\
the given arguments and its return value is returned. If it is a list\n\
of functions, those functions are called, in order,\n\
with the given arguments ARGS.\n\
It is best not to depend on the value return by `run-hook-with-args',\n\
as that may change.\n\
\n\
To make a hook variable buffer-local, use `make-local-hook',\n\
not `make-local-variable'.")
(nargs, args)
int nargs;
Lisp_Object *args;
{
return run_hook_with_args (nargs, args, to_completion);
}
DEFUN ("run-hook-with-args-until-success", Frun_hook_with_args_until_success,
Srun_hook_with_args_until_success, 1, MANY, 0,
"Run HOOK with the specified arguments ARGS.\n\
HOOK should be a symbol, a hook variable. Its value should\n\
be a list of functions. We call those functions, one by one,\n\
passing arguments ARGS to each of them, until one of them\n\
returns a non-nil value. Then we return that value.\n\
If all the functions return nil, we return nil.\n\
\n\
To make a hook variable buffer-local, use `make-local-hook',\n\
not `make-local-variable'.")
(nargs, args)
int nargs;
Lisp_Object *args;
{
return run_hook_with_args (nargs, args, until_success);
}
DEFUN ("run-hook-with-args-until-failure", Frun_hook_with_args_until_failure,
Srun_hook_with_args_until_failure, 1, MANY, 0,
"Run HOOK with the specified arguments ARGS.\n\
HOOK should be a symbol, a hook variable. Its value should\n\
be a list of functions. We call those functions, one by one,\n\
passing arguments ARGS to each of them, until one of them\n\
returns nil. Then we return nil.\n\
If all the functions return non-nil, we return non-nil.\n\
\n\
To make a hook variable buffer-local, use `make-local-hook',\n\
not `make-local-variable'.")
(nargs, args)
int nargs;
Lisp_Object *args;
{
return run_hook_with_args (nargs, args, until_failure);
}
Lisp_Object
run_hook_with_args (nargs, args, cond)
int nargs;
Lisp_Object *args;
enum run_hooks_condition cond;
{
Lisp_Object sym, val, ret;
Lisp_Object globals;
struct gcpro gcpro1, gcpro2, gcpro3;
if (NILP (Vrun_hooks))
return Qnil;
sym = args[0];
val = find_symbol_value (sym);
ret = (cond == until_failure ? Qt : Qnil);
if (EQ (val, Qunbound) || NILP (val))
return ret;
else if (!CONSP (val) || EQ (XCAR (val), Qlambda))
{
args[0] = val;
return Ffuncall (nargs, args);
}
else
{
globals = Qnil;
GCPRO3 (sym, val, globals);
for (;
CONSP (val) && ((cond == to_completion)
|| (cond == until_success ? NILP (ret)
: !NILP (ret)));
val = XCDR (val))
{
if (EQ (XCAR (val), Qt))
{
for (globals = Fdefault_value (sym);
CONSP (globals) && ((cond == to_completion)
|| (cond == until_success ? NILP (ret)
: !NILP (ret)));
globals = XCDR (globals))
{
args[0] = XCAR (globals);
if (!EQ (args[0], Qt))
ret = Ffuncall (nargs, args);
}
}
else
{
args[0] = XCAR (val);
ret = Ffuncall (nargs, args);
}
}
UNGCPRO;
return ret;
}
}
Lisp_Object
run_hook_list_with_args (funlist, nargs, args)
Lisp_Object funlist;
int nargs;
Lisp_Object *args;
{
Lisp_Object sym;
Lisp_Object val;
Lisp_Object globals;
struct gcpro gcpro1, gcpro2, gcpro3;
sym = args[0];
globals = Qnil;
GCPRO3 (sym, val, globals);
for (val = funlist; CONSP (val); val = XCDR (val))
{
if (EQ (XCAR (val), Qt))
{
for (globals = Fdefault_value (sym);
CONSP (globals);
globals = XCDR (globals))
{
args[0] = XCAR (globals);
if (!EQ (args[0], Qt))
Ffuncall (nargs, args);
}
}
else
{
args[0] = XCAR (val);
Ffuncall (nargs, args);
}
}
UNGCPRO;
return Qnil;
}
void
run_hook_with_args_2 (hook, arg1, arg2)
Lisp_Object hook, arg1, arg2;
{
Lisp_Object temp[3];
temp[0] = hook;
temp[1] = arg1;
temp[2] = arg2;
Frun_hook_with_args (3, temp);
}
Lisp_Object
apply1 (fn, arg)
Lisp_Object fn, arg;
{
struct gcpro gcpro1;
GCPRO1 (fn);
if (NILP (arg))
RETURN_UNGCPRO (Ffuncall (1, &fn));
gcpro1.nvars = 2;
#ifdef NO_ARG_ARRAY
{
Lisp_Object args[2];
args[0] = fn;
args[1] = arg;
gcpro1.var = args;
RETURN_UNGCPRO (Fapply (2, args));
}
#else
RETURN_UNGCPRO (Fapply (2, &fn));
#endif
}
Lisp_Object
call0 (fn)
Lisp_Object fn;
{
struct gcpro gcpro1;
GCPRO1 (fn);
RETURN_UNGCPRO (Ffuncall (1, &fn));
}
Lisp_Object
call1 (fn, arg1)
Lisp_Object fn, arg1;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[2];
args[0] = fn;
args[1] = arg1;
GCPRO1 (args[0]);
gcpro1.nvars = 2;
RETURN_UNGCPRO (Ffuncall (2, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 2;
RETURN_UNGCPRO (Ffuncall (2, &fn));
#endif
}
Lisp_Object
call2 (fn, arg1, arg2)
Lisp_Object fn, arg1, arg2;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[3];
args[0] = fn;
args[1] = arg1;
args[2] = arg2;
GCPRO1 (args[0]);
gcpro1.nvars = 3;
RETURN_UNGCPRO (Ffuncall (3, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 3;
RETURN_UNGCPRO (Ffuncall (3, &fn));
#endif
}
Lisp_Object
call3 (fn, arg1, arg2, arg3)
Lisp_Object fn, arg1, arg2, arg3;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[4];
args[0] = fn;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
GCPRO1 (args[0]);
gcpro1.nvars = 4;
RETURN_UNGCPRO (Ffuncall (4, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 4;
RETURN_UNGCPRO (Ffuncall (4, &fn));
#endif
}
Lisp_Object
call4 (fn, arg1, arg2, arg3, arg4)
Lisp_Object fn, arg1, arg2, arg3, arg4;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[5];
args[0] = fn;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
args[4] = arg4;
GCPRO1 (args[0]);
gcpro1.nvars = 5;
RETURN_UNGCPRO (Ffuncall (5, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 5;
RETURN_UNGCPRO (Ffuncall (5, &fn));
#endif
}
Lisp_Object
call5 (fn, arg1, arg2, arg3, arg4, arg5)
Lisp_Object fn, arg1, arg2, arg3, arg4, arg5;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[6];
args[0] = fn;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
args[4] = arg4;
args[5] = arg5;
GCPRO1 (args[0]);
gcpro1.nvars = 6;
RETURN_UNGCPRO (Ffuncall (6, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 6;
RETURN_UNGCPRO (Ffuncall (6, &fn));
#endif
}
Lisp_Object
call6 (fn, arg1, arg2, arg3, arg4, arg5, arg6)
Lisp_Object fn, arg1, arg2, arg3, arg4, arg5, arg6;
{
struct gcpro gcpro1;
#ifdef NO_ARG_ARRAY
Lisp_Object args[7];
args[0] = fn;
args[1] = arg1;
args[2] = arg2;
args[3] = arg3;
args[4] = arg4;
args[5] = arg5;
args[6] = arg6;
GCPRO1 (args[0]);
gcpro1.nvars = 7;
RETURN_UNGCPRO (Ffuncall (7, args));
#else
GCPRO1 (fn);
gcpro1.nvars = 7;
RETURN_UNGCPRO (Ffuncall (7, &fn));
#endif
}
DEFUN ("funcall", Ffuncall, Sfuncall, 1, MANY, 0,
"Call first argument as a function, passing remaining arguments to it.\n\
Return the value that function returns.\n\
Thus, (funcall 'cons 'x 'y) returns (x . y).")
(nargs, args)
int nargs;
Lisp_Object *args;
{
Lisp_Object fun;
Lisp_Object funcar;
int numargs = nargs - 1;
Lisp_Object lisp_numargs;
Lisp_Object val;
struct backtrace backtrace;
register Lisp_Object *internal_args;
register int i;
QUIT;
if (consing_since_gc > gc_cons_threshold)
Fgarbage_collect ();
if (++lisp_eval_depth > max_lisp_eval_depth)
{
if (max_lisp_eval_depth < 100)
max_lisp_eval_depth = 100;
if (lisp_eval_depth > max_lisp_eval_depth)
error ("Lisp nesting exceeds max-lisp-eval-depth");
}
backtrace.next = backtrace_list;
backtrace_list = &backtrace;
backtrace.function = &args[0];
backtrace.args = &args[1];
backtrace.nargs = nargs - 1;
backtrace.evalargs = 0;
backtrace.debug_on_exit = 0;
if (debug_on_next_call)
do_debug_on_call (Qlambda);
retry:
fun = args[0];
fun = Findirect_function (fun);
if (SUBRP (fun))
{
if (numargs < XSUBR (fun)->min_args
|| (XSUBR (fun)->max_args >= 0 && XSUBR (fun)->max_args < numargs))
{
XSETFASTINT (lisp_numargs, numargs);
return Fsignal (Qwrong_number_of_arguments, Fcons (fun, Fcons (lisp_numargs, Qnil)));
}
if (XSUBR (fun)->max_args == UNEVALLED)
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
if (XSUBR (fun)->max_args == MANY)
{
val = (*XSUBR (fun)->function) (numargs, args + 1);
goto done;
}
if (XSUBR (fun)->max_args > numargs)
{
internal_args = (Lisp_Object *) alloca (XSUBR (fun)->max_args * sizeof (Lisp_Object));
bcopy (args + 1, internal_args, numargs * sizeof (Lisp_Object));
for (i = numargs; i < XSUBR (fun)->max_args; i++)
internal_args[i] = Qnil;
}
else
internal_args = args + 1;
switch (XSUBR (fun)->max_args)
{
case 0:
val = (*XSUBR (fun)->function) ();
goto done;
case 1:
val = (*XSUBR (fun)->function) (internal_args[0]);
goto done;
case 2:
val = (*XSUBR (fun)->function) (internal_args[0],
internal_args[1]);
goto done;
case 3:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2]);
goto done;
case 4:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2],
internal_args[3]);
goto done;
case 5:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2], internal_args[3],
internal_args[4]);
goto done;
case 6:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2], internal_args[3],
internal_args[4], internal_args[5]);
goto done;
case 7:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2], internal_args[3],
internal_args[4], internal_args[5],
internal_args[6]);
goto done;
case 8:
val = (*XSUBR (fun)->function) (internal_args[0], internal_args[1],
internal_args[2], internal_args[3],
internal_args[4], internal_args[5],
internal_args[6], internal_args[7]);
goto done;
default:
abort ();
}
}
if (COMPILEDP (fun))
val = funcall_lambda (fun, numargs, args + 1);
else
{
if (!CONSP (fun))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
funcar = Fcar (fun);
if (!SYMBOLP (funcar))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
if (EQ (funcar, Qlambda))
val = funcall_lambda (fun, numargs, args + 1);
else if (EQ (funcar, Qmocklisp))
val = ml_apply (fun, Flist (numargs, args + 1));
else if (EQ (funcar, Qautoload))
{
do_autoload (fun, args[0]);
goto retry;
}
else
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
}
done:
lisp_eval_depth--;
if (backtrace.debug_on_exit)
val = call_debugger (Fcons (Qexit, Fcons (val, Qnil)));
backtrace_list = backtrace.next;
return val;
}
Lisp_Object
apply_lambda (fun, args, eval_flag)
Lisp_Object fun, args;
int eval_flag;
{
Lisp_Object args_left;
Lisp_Object numargs;
register Lisp_Object *arg_vector;
struct gcpro gcpro1, gcpro2, gcpro3;
register int i;
register Lisp_Object tem;
numargs = Flength (args);
arg_vector = (Lisp_Object *) alloca (XINT (numargs) * sizeof (Lisp_Object));
args_left = args;
GCPRO3 (*arg_vector, args_left, fun);
gcpro1.nvars = 0;
for (i = 0; i < XINT (numargs);)
{
tem = Fcar (args_left), args_left = Fcdr (args_left);
if (eval_flag) tem = Feval (tem);
arg_vector[i++] = tem;
gcpro1.nvars = i;
}
UNGCPRO;
if (eval_flag)
{
backtrace_list->args = arg_vector;
backtrace_list->nargs = i;
}
backtrace_list->evalargs = 0;
tem = funcall_lambda (fun, XINT (numargs), arg_vector);
if (backtrace_list->debug_on_exit)
tem = call_debugger (Fcons (Qexit, Fcons (tem, Qnil)));
backtrace_list->debug_on_exit = 0;
return tem;
}
Lisp_Object
funcall_lambda (fun, nargs, arg_vector)
Lisp_Object fun;
int nargs;
register Lisp_Object *arg_vector;
{
Lisp_Object val, syms_left, next;
int count = specpdl_ptr - specpdl;
int i, optional, rest;
if (NILP (Vmocklisp_arguments))
specbind (Qmocklisp_arguments, Qt);
if (CONSP (fun))
{
syms_left = XCDR (fun);
if (CONSP (syms_left))
syms_left = XCAR (syms_left);
else
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
}
else if (COMPILEDP (fun))
syms_left = XVECTOR (fun)->contents[COMPILED_ARGLIST];
else
abort ();
i = optional = rest = 0;
for (; CONSP (syms_left); syms_left = XCDR (syms_left))
{
QUIT;
next = XCAR (syms_left);
while (!SYMBOLP (next))
next = Fsignal (Qinvalid_function, Fcons (fun, Qnil));
if (EQ (next, Qand_rest))
rest = 1;
else if (EQ (next, Qand_optional))
optional = 1;
else if (rest)
{
specbind (next, Flist (nargs - i, &arg_vector[i]));
i = nargs;
}
else if (i < nargs)
specbind (next, arg_vector[i++]);
else if (!optional)
return Fsignal (Qwrong_number_of_arguments,
Fcons (fun, Fcons (make_number (nargs), Qnil)));
else
specbind (next, Qnil);
}
if (!NILP (syms_left))
return Fsignal (Qinvalid_function, Fcons (fun, Qnil));
else if (i < nargs)
return Fsignal (Qwrong_number_of_arguments,
Fcons (fun, Fcons (make_number (nargs), Qnil)));
if (CONSP (fun))
val = Fprogn (XCDR (XCDR (fun)));
else
{
if (CONSP (XVECTOR (fun)->contents[COMPILED_BYTECODE]))
Ffetch_bytecode (fun);
val = Fbyte_code (XVECTOR (fun)->contents[COMPILED_BYTECODE],
XVECTOR (fun)->contents[COMPILED_CONSTANTS],
XVECTOR (fun)->contents[COMPILED_STACK_DEPTH]);
}
return unbind_to (count, val);
}
DEFUN ("fetch-bytecode", Ffetch_bytecode, Sfetch_bytecode,
1, 1, 0,
"If byte-compiled OBJECT is lazy-loaded, fetch it now.")
(object)
Lisp_Object object;
{
Lisp_Object tem;
if (COMPILEDP (object)
&& CONSP (XVECTOR (object)->contents[COMPILED_BYTECODE]))
{
tem = read_doc_string (XVECTOR (object)->contents[COMPILED_BYTECODE]);
if (!CONSP (tem))
error ("invalid byte code");
XVECTOR (object)->contents[COMPILED_BYTECODE] = XCAR (tem);
XVECTOR (object)->contents[COMPILED_CONSTANTS] = XCDR (tem);
}
return object;
}
void
grow_specpdl ()
{
register int count = specpdl_ptr - specpdl;
if (specpdl_size >= max_specpdl_size)
{
if (max_specpdl_size < 400)
max_specpdl_size = 400;
if (specpdl_size >= max_specpdl_size)
{
if (!NILP (Vdebug_on_error))
max_specpdl_size = specpdl_size + 100;
Fsignal (Qerror,
Fcons (build_string ("Variable binding depth exceeds max-specpdl-size"), Qnil));
}
}
specpdl_size *= 2;
if (specpdl_size > max_specpdl_size)
specpdl_size = max_specpdl_size;
specpdl = (struct specbinding *) xrealloc (specpdl, specpdl_size * sizeof (struct specbinding));
specpdl_ptr = specpdl + count;
}
void
specbind (symbol, value)
Lisp_Object symbol, value;
{
Lisp_Object ovalue;
CHECK_SYMBOL (symbol, 0);
if (specpdl_ptr == specpdl + specpdl_size)
grow_specpdl ();
if (!MISCP (XSYMBOL (symbol)->value)
&& !EQ (symbol, Qnil)
&& !EQ (symbol, Qt)
&& !(XSYMBOL (symbol)->name->data[0] == ':'
&& EQ (XSYMBOL (symbol)->obarray, initial_obarray)
&& !EQ (value, symbol)))
{
specpdl_ptr->symbol = symbol;
specpdl_ptr->old_value = XSYMBOL (symbol)->value;
specpdl_ptr->func = NULL;
++specpdl_ptr;
XSYMBOL (symbol)->value = value;
}
else
{
Lisp_Object valcontents;
ovalue = find_symbol_value (symbol);
specpdl_ptr->func = 0;
specpdl_ptr->old_value = ovalue;
valcontents = XSYMBOL (symbol)->value;
if (BUFFER_LOCAL_VALUEP (valcontents)
|| SOME_BUFFER_LOCAL_VALUEP (valcontents)
|| BUFFER_OBJFWDP (valcontents))
{
Lisp_Object where, current_buffer;
current_buffer = Fcurrent_buffer ();
if (!NILP (Flocal_variable_p (symbol, Qnil)))
where = current_buffer;
else if (!BUFFER_OBJFWDP (valcontents)
&& XBUFFER_LOCAL_VALUE (valcontents)->found_for_frame)
where = XBUFFER_LOCAL_VALUE (valcontents)->frame;
else
where = Qnil;
specpdl_ptr->symbol = Fcons (symbol, Fcons (where, current_buffer));
if (NILP (where)
&& BUFFER_OBJFWDP (valcontents))
{
++specpdl_ptr;
Fset_default (symbol, value);
return;
}
}
else
specpdl_ptr->symbol = symbol;
specpdl_ptr++;
if (BUFFER_OBJFWDP (ovalue) || KBOARD_OBJFWDP (ovalue))
store_symval_forwarding (symbol, ovalue, value, NULL);
else
set_internal (symbol, value, 0, 1);
}
}
void
record_unwind_protect (function, arg)
Lisp_Object (*function) P_ ((Lisp_Object));
Lisp_Object arg;
{
if (specpdl_ptr == specpdl + specpdl_size)
grow_specpdl ();
specpdl_ptr->func = function;
specpdl_ptr->symbol = Qnil;
specpdl_ptr->old_value = arg;
specpdl_ptr++;
}
Lisp_Object
unbind_to (count, value)
int count;
Lisp_Object value;
{
int quitf = !NILP (Vquit_flag);
struct gcpro gcpro1;
GCPRO1 (value);
Vquit_flag = Qnil;
while (specpdl_ptr != specpdl + count)
{
--specpdl_ptr;
if (specpdl_ptr->func != 0)
(*specpdl_ptr->func) (specpdl_ptr->old_value);
else if (NILP (specpdl_ptr->symbol))
Fprogn (specpdl_ptr->old_value);
else if (CONSP (specpdl_ptr->symbol))
{
Lisp_Object symbol, where;
symbol = XCAR (specpdl_ptr->symbol);
where = XCAR (XCDR (specpdl_ptr->symbol));
if (NILP (where))
Fset_default (symbol, specpdl_ptr->old_value);
else if (BUFFERP (where))
set_internal (symbol, specpdl_ptr->old_value, XBUFFER (where), 1);
else
set_internal (symbol, specpdl_ptr->old_value, NULL, 1);
}
else
{
if (!MISCP (XSYMBOL (specpdl_ptr->symbol)->value))
XSYMBOL (specpdl_ptr->symbol)->value = specpdl_ptr->old_value;
else
set_internal (specpdl_ptr->symbol, specpdl_ptr->old_value, 0, 1);
}
}
if (NILP (Vquit_flag) && quitf)
Vquit_flag = Qt;
UNGCPRO;
return value;
}
#if 0
Lisp_Object
top_level_value (symbol)
Lisp_Object symbol;
{
register struct specbinding *ptr = specpdl;
CHECK_SYMBOL (symbol, 0);
for (; ptr != specpdl_ptr; ptr++)
{
if (EQ (ptr->symbol, symbol))
return ptr->old_value;
}
return Fsymbol_value (symbol);
}
Lisp_Object
top_level_set (symbol, newval)
Lisp_Object symbol, newval;
{
register struct specbinding *ptr = specpdl;
CHECK_SYMBOL (symbol, 0);
for (; ptr != specpdl_ptr; ptr++)
{
if (EQ (ptr->symbol, symbol))
{
ptr->old_value = newval;
return newval;
}
}
return Fset (symbol, newval);
}
#endif
DEFUN ("backtrace-debug", Fbacktrace_debug, Sbacktrace_debug, 2, 2, 0,
"Set the debug-on-exit flag of eval frame LEVEL levels down to FLAG.\n\
The debugger is entered when that frame exits, if the flag is non-nil.")
(level, flag)
Lisp_Object level, flag;
{
register struct backtrace *backlist = backtrace_list;
register int i;
CHECK_NUMBER (level, 0);
for (i = 0; backlist && i < XINT (level); i++)
{
backlist = backlist->next;
}
if (backlist)
backlist->debug_on_exit = !NILP (flag);
return flag;
}
DEFUN ("backtrace", Fbacktrace, Sbacktrace, 0, 0, "",
"Print a trace of Lisp function calls currently active.\n\
Output stream used is value of `standard-output'.")
()
{
register struct backtrace *backlist = backtrace_list;
register int i;
Lisp_Object tail;
Lisp_Object tem;
extern Lisp_Object Vprint_level;
struct gcpro gcpro1;
XSETFASTINT (Vprint_level, 3);
tail = Qnil;
GCPRO1 (tail);
while (backlist)
{
write_string (backlist->debug_on_exit ? "* " : " ", 2);
if (backlist->nargs == UNEVALLED)
{
Fprin1 (Fcons (*backlist->function, *backlist->args), Qnil);
write_string ("\n", -1);
}
else
{
tem = *backlist->function;
Fprin1 (tem, Qnil);
write_string ("(", -1);
if (backlist->nargs == MANY)
{
for (tail = *backlist->args, i = 0;
!NILP (tail);
tail = Fcdr (tail), i++)
{
if (i) write_string (" ", -1);
Fprin1 (Fcar (tail), Qnil);
}
}
else
{
for (i = 0; i < backlist->nargs; i++)
{
if (i) write_string (" ", -1);
Fprin1 (backlist->args[i], Qnil);
}
}
write_string (")\n", -1);
}
backlist = backlist->next;
}
Vprint_level = Qnil;
UNGCPRO;
return Qnil;
}
DEFUN ("backtrace-frame", Fbacktrace_frame, Sbacktrace_frame, 1, 1, NULL,
"Return the function and arguments NFRAMES up from current execution point.\n\
If that frame has not evaluated the arguments yet (or is a special form),\n\
the value is (nil FUNCTION ARG-FORMS...).\n\
If that frame has evaluated its arguments and called its function already,\n\
the value is (t FUNCTION ARG-VALUES...).\n\
A &rest arg is represented as the tail of the list ARG-VALUES.\n\
FUNCTION is whatever was supplied as car of evaluated list,\n\
or a lambda expression for macro calls.\n\
If NFRAMES is more than the number of frames, the value is nil.")
(nframes)
Lisp_Object nframes;
{
register struct backtrace *backlist = backtrace_list;
register int i;
Lisp_Object tem;
CHECK_NATNUM (nframes, 0);
for (i = 0; backlist && i < XFASTINT (nframes); i++)
backlist = backlist->next;
if (!backlist)
return Qnil;
if (backlist->nargs == UNEVALLED)
return Fcons (Qnil, Fcons (*backlist->function, *backlist->args));
else
{
if (backlist->nargs == MANY)
tem = *backlist->args;
else
tem = Flist (backlist->nargs, backlist->args);
return Fcons (Qt, Fcons (*backlist->function, tem));
}
}
void
syms_of_eval ()
{
DEFVAR_INT ("max-specpdl-size", &max_specpdl_size,
"*Limit on number of Lisp variable bindings & unwind-protects.\n\
If Lisp code tries to make more than this many at once,\n\
an error is signaled.");
DEFVAR_INT ("max-lisp-eval-depth", &max_lisp_eval_depth,
"*Limit on depth in `eval', `apply' and `funcall' before error.\n\
This limit is to catch infinite recursions for you before they cause\n\
actual stack overflow in C, which would be fatal for Emacs.\n\
You can safely make it considerably larger than its default value,\n\
if that proves inconveniently small.");
DEFVAR_LISP ("quit-flag", &Vquit_flag,
"Non-nil causes `eval' to abort, unless `inhibit-quit' is non-nil.\n\
Typing C-g sets `quit-flag' non-nil, regardless of `inhibit-quit'.");
Vquit_flag = Qnil;
DEFVAR_LISP ("inhibit-quit", &Vinhibit_quit,
"Non-nil inhibits C-g quitting from happening immediately.\n\
Note that `quit-flag' will still be set by typing C-g,\n\
so a quit will be signaled as soon as `inhibit-quit' is nil.\n\
To prevent this happening, set `quit-flag' to nil\n\
before making `inhibit-quit' nil.");
Vinhibit_quit = Qnil;
Qinhibit_quit = intern ("inhibit-quit");
staticpro (&Qinhibit_quit);
Qautoload = intern ("autoload");
staticpro (&Qautoload);
Qdebug_on_error = intern ("debug-on-error");
staticpro (&Qdebug_on_error);
Qmacro = intern ("macro");
staticpro (&Qmacro);
Qexit = intern ("exit");
staticpro (&Qexit);
Qinteractive = intern ("interactive");
staticpro (&Qinteractive);
Qcommandp = intern ("commandp");
staticpro (&Qcommandp);
Qdefun = intern ("defun");
staticpro (&Qdefun);
Qand_rest = intern ("&rest");
staticpro (&Qand_rest);
Qand_optional = intern ("&optional");
staticpro (&Qand_optional);
DEFVAR_LISP ("stack-trace-on-error", &Vstack_trace_on_error,
"*Non-nil means automatically display a backtrace buffer\n\
after any error that is handled by the editor command loop.\n\
If the value is a list, an error only means to display a backtrace\n\
if one of its condition symbols appears in the list.");
Vstack_trace_on_error = Qnil;
DEFVAR_LISP ("debug-on-error", &Vdebug_on_error,
"*Non-nil means enter debugger if an error is signaled.\n\
Does not apply to errors handled by `condition-case' or those\n\
matched by `debug-ignored-errors'.\n\
If the value is a list, an error only means to enter the debugger\n\
if one of its condition symbols appears in the list.\n\
When you evaluate an expression interactively, this variable\n\
is temporarily non-nil if `eval-expression-debug-on-error' is non-nil.\n\
See also variable `debug-on-quit'.");
Vdebug_on_error = Qnil;
DEFVAR_LISP ("debug-ignored-errors", &Vdebug_ignored_errors,
"*List of errors for which the debugger should not be called.\n\
Each element may be a condition-name or a regexp that matches error messages.\n\
If any element applies to a given error, that error skips the debugger\n\
and just returns to top level.\n\
This overrides the variable `debug-on-error'.\n\
It does not apply to errors handled by `condition-case'.");
Vdebug_ignored_errors = Qnil;
DEFVAR_BOOL ("debug-on-quit", &debug_on_quit,
"*Non-nil means enter debugger if quit is signaled (C-g, for example).\n\
Does not apply if quit is handled by a `condition-case'.\n\
When you evaluate an expression interactively, this variable\n\
is temporarily non-nil if `eval-expression-debug-on-quit' is non-nil.");
debug_on_quit = 0;
DEFVAR_BOOL ("debug-on-next-call", &debug_on_next_call,
"Non-nil means enter debugger before next `eval', `apply' or `funcall'.");
DEFVAR_BOOL ("debugger-may-continue", &debugger_may_continue,
"Non-nil means debugger may continue execution.\n\
This is nil when the debugger is called under circumstances where it\n\
might not be safe to continue.");
debugger_may_continue = 1;
DEFVAR_LISP ("debugger", &Vdebugger,
"Function to call to invoke debugger.\n\
If due to frame exit, args are `exit' and the value being returned;\n\
this function's value will be returned instead of that.\n\
If due to error, args are `error' and a list of the args to `signal'.\n\
If due to `apply' or `funcall' entry, one arg, `lambda'.\n\
If due to `eval' entry, one arg, t.");
Vdebugger = Qnil;
DEFVAR_LISP ("signal-hook-function", &Vsignal_hook_function,
"If non-nil, this is a function for `signal' to call.\n\
It receives the same arguments that `signal' was given.\n\
The Edebug package uses this to regain control.");
Vsignal_hook_function = Qnil;
Qmocklisp_arguments = intern ("mocklisp-arguments");
staticpro (&Qmocklisp_arguments);
DEFVAR_LISP ("mocklisp-arguments", &Vmocklisp_arguments,
"While in a mocklisp function, the list of its unevaluated args.");
Vmocklisp_arguments = Qt;
DEFVAR_LISP ("debug-on-signal", &Vdebug_on_signal,
"*Non-nil means call the debugger regardless of condition handlers.\n\
Note that `debug-on-error', `debug-on-quit' and friends\n\
still determine whether to handle the particular condition.");
Vdebug_on_signal = Qnil;
Vrun_hooks = intern ("run-hooks");
staticpro (&Vrun_hooks);
staticpro (&Vautoload_queue);
Vautoload_queue = Qnil;
staticpro (&Vsignaling_function);
Vsignaling_function = Qnil;
defsubr (&Sor);
defsubr (&Sand);
defsubr (&Sif);
defsubr (&Scond);
defsubr (&Sprogn);
defsubr (&Sprog1);
defsubr (&Sprog2);
defsubr (&Ssetq);
defsubr (&Squote);
defsubr (&Sfunction);
defsubr (&Sdefun);
defsubr (&Sdefmacro);
defsubr (&Sdefvar);
defsubr (&Sdefconst);
defsubr (&Suser_variable_p);
defsubr (&Slet);
defsubr (&SletX);
defsubr (&Swhile);
defsubr (&Smacroexpand);
defsubr (&Scatch);
defsubr (&Sthrow);
defsubr (&Sunwind_protect);
defsubr (&Scondition_case);
defsubr (&Ssignal);
defsubr (&Sinteractive_p);
defsubr (&Scommandp);
defsubr (&Sautoload);
defsubr (&Seval);
defsubr (&Sapply);
defsubr (&Sfuncall);
defsubr (&Srun_hooks);
defsubr (&Srun_hook_with_args);
defsubr (&Srun_hook_with_args_until_success);
defsubr (&Srun_hook_with_args_until_failure);
defsubr (&Sfetch_bytecode);
defsubr (&Sbacktrace_debug);
defsubr (&Sbacktrace);
defsubr (&Sbacktrace_frame);
}