/* Evaluator for GNU Emacs Lisp interpreter. Copyright (C) 1985-1987, 1993-1995, 1999-2020 Free Software Foundation, Inc. This file is part of GNU Emacs. GNU Emacs is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. GNU Emacs is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNU Emacs. If not, see . */ #include #include #include #include "lisp.h" #include "blockinput.h" #include "commands.h" #include "keyboard.h" #include "dispextern.h" #include "buffer.h" #include "pdumper.h" /* CACHEABLE is ordinarily nothing, except it is 'volatile' if necessary to cajole GCC into not warning incorrectly that a variable should be volatile. */ #if defined GCC_LINT || defined lint # define CACHEABLE volatile #else # define CACHEABLE /* empty */ #endif /* Non-nil means record all fset's and provide's, to be undone if the file being autoloaded is not fully loaded. They are recorded by being consed onto the front of Vautoload_queue: (FUN . ODEF) for a defun, (0 . OFEATURES) for a provide. */ Lisp_Object Vautoload_queue; /* This holds either the symbol `run-hooks' or nil. It is nil at an early stage of startup, and when Emacs is shutting down. */ Lisp_Object Vrun_hooks; /* The function from which the last `signal' was called. Set in Fsignal. */ /* FIXME: We should probably get rid of this! */ Lisp_Object Vsignaling_function; /* These would ordinarily be static, but they need to be visible to GDB. */ bool backtrace_p (union specbinding *) EXTERNALLY_VISIBLE; Lisp_Object *backtrace_args (union specbinding *) EXTERNALLY_VISIBLE; Lisp_Object backtrace_function (union specbinding *) EXTERNALLY_VISIBLE; union specbinding *backtrace_next (union specbinding *) EXTERNALLY_VISIBLE; union specbinding *backtrace_top (void) EXTERNALLY_VISIBLE; static Lisp_Object funcall_lambda (Lisp_Object, ptrdiff_t, Lisp_Object *); static Lisp_Object apply_lambda (Lisp_Object, Lisp_Object, ptrdiff_t); static Lisp_Object lambda_arity (Lisp_Object); static Lisp_Object specpdl_symbol (union specbinding *pdl) { eassert (pdl->kind >= SPECPDL_LET); return pdl->let.symbol; } static enum specbind_tag specpdl_kind (union specbinding *pdl) { eassert (pdl->kind >= SPECPDL_LET); return pdl->let.kind; } static Lisp_Object specpdl_old_value (union specbinding *pdl) { eassert (pdl->kind >= SPECPDL_LET); return pdl->let.old_value; } static void set_specpdl_old_value (union specbinding *pdl, Lisp_Object val) { eassert (pdl->kind >= SPECPDL_LET); pdl->let.old_value = val; } static Lisp_Object specpdl_where (union specbinding *pdl) { eassert (pdl->kind > SPECPDL_LET); return pdl->let.where; } static Lisp_Object specpdl_saved_value (union specbinding *pdl) { eassert (pdl->kind >= SPECPDL_LET); return pdl->let.saved_value; } static Lisp_Object specpdl_arg (union specbinding *pdl) { eassert (pdl->kind == SPECPDL_UNWIND); return pdl->unwind.arg; } Lisp_Object backtrace_function (union specbinding *pdl) { eassert (pdl->kind == SPECPDL_BACKTRACE); return pdl->bt.function; } static ptrdiff_t backtrace_nargs (union specbinding *pdl) { eassert (pdl->kind == SPECPDL_BACKTRACE); return pdl->bt.nargs; } Lisp_Object * backtrace_args (union specbinding *pdl) { eassert (pdl->kind == SPECPDL_BACKTRACE); return pdl->bt.args; } static bool backtrace_debug_on_exit (union specbinding *pdl) { eassert (pdl->kind == SPECPDL_BACKTRACE); return pdl->bt.debug_on_exit; } /* Functions to modify slots of backtrace records. */ static void set_backtrace_args (union specbinding *pdl, Lisp_Object *args, ptrdiff_t nargs) { eassert (pdl->kind == SPECPDL_BACKTRACE); pdl->bt.args = args; pdl->bt.nargs = nargs; } static void set_backtrace_debug_on_exit (union specbinding *pdl, bool doe) { eassert (pdl->kind == SPECPDL_BACKTRACE); pdl->bt.debug_on_exit = doe; } /* Helper functions to scan the backtrace. */ bool backtrace_p (union specbinding *pdl) { return specpdl ? pdl >= specpdl : false; } static bool backtrace_thread_p (struct thread_state *tstate, union specbinding *pdl) { return pdl >= tstate->m_specpdl; } union specbinding * backtrace_top (void) { /* This is so "xbacktrace" doesn't crash in pdumped Emacs if they invoke the command before init_eval_once_for_pdumper initializes specpdl machinery. See also backtrace_p above. */ if (!specpdl) return NULL; union specbinding *pdl = specpdl_ptr - 1; while (backtrace_p (pdl) && pdl->kind != SPECPDL_BACKTRACE) pdl--; return pdl; } static union specbinding * backtrace_thread_top (struct thread_state *tstate) { union specbinding *pdl = tstate->m_specpdl_ptr - 1; while (backtrace_thread_p (tstate, pdl) && pdl->kind != SPECPDL_BACKTRACE) pdl--; return pdl; } union specbinding * backtrace_next (union specbinding *pdl) { pdl--; while (backtrace_p (pdl) && pdl->kind != SPECPDL_BACKTRACE) pdl--; return pdl; } static void init_eval_once_for_pdumper (void); static union specbinding * backtrace_thread_next (struct thread_state *tstate, union specbinding *pdl) { pdl--; while (backtrace_thread_p (tstate, pdl) && pdl->kind != SPECPDL_BACKTRACE) pdl--; return pdl; } void init_eval_once (void) { /* Don't forget to update docs (lispref node "Local Variables"). */ max_specpdl_size = 1600; /* 1500 is not enough for cl-generic.el. */ max_lisp_eval_depth = 800; Vrun_hooks = Qnil; pdumper_do_now_and_after_load (init_eval_once_for_pdumper); } static void init_eval_once_for_pdumper (void) { enum { size = 50 }; union specbinding *pdlvec = malloc ((size + 1) * sizeof *specpdl); specpdl_size = size; specpdl = specpdl_ptr = pdlvec + 1; } void init_eval (void) { specpdl_ptr = specpdl; { /* Put a dummy catcher at top-level so that handlerlist is never NULL. This is important since handlerlist->nextfree holds the freelist which would otherwise leak every time we unwind back to top-level. */ handlerlist_sentinel = xzalloc (sizeof (struct handler)); handlerlist = handlerlist_sentinel->nextfree = handlerlist_sentinel; struct handler *c = push_handler (Qunbound, CATCHER); eassert (c == handlerlist_sentinel); handlerlist_sentinel->nextfree = NULL; handlerlist_sentinel->next = NULL; } Vquit_flag = Qnil; debug_on_next_call = 0; lisp_eval_depth = 0; /* This is less than the initial value of num_nonmacro_input_events. */ when_entered_debugger = -1; } /* Ensure that *M is at least A + B if possible, or is its maximum value otherwise. */ static void max_ensure_room (intmax_t *m, intmax_t a, intmax_t b) { intmax_t sum = INT_ADD_WRAPV (a, b, &sum) ? INTMAX_MAX : sum; *m = max (*m, sum); } /* Unwind-protect function used by call_debugger. */ static void restore_stack_limits (Lisp_Object data) { integer_to_intmax (XCAR (data), &max_specpdl_size); integer_to_intmax (XCDR (data), &max_lisp_eval_depth); } static void grow_specpdl (void); /* Call the Lisp debugger, giving it argument ARG. */ Lisp_Object call_debugger (Lisp_Object arg) { bool debug_while_redisplaying; ptrdiff_t count = SPECPDL_INDEX (); Lisp_Object val; intmax_t old_depth = max_lisp_eval_depth; /* Do not allow max_specpdl_size less than actual depth (Bug#16603). */ intmax_t old_max = max (max_specpdl_size, count); /* The previous value of 40 is too small now that the debugger prints using cl-prin1 instead of prin1. Printing lists nested 8 deep (which is the value of print-level used in the debugger) currently requires 77 additional frames. See bug#31919. */ max_ensure_room (&max_lisp_eval_depth, lisp_eval_depth, 100); /* While debugging Bug#16603, previous value of 100 was found too small to avoid specpdl overflow in the debugger itself. */ max_ensure_room (&max_specpdl_size, count, 200); if (old_max == count) { /* We can enter the debugger due to specpdl overflow (Bug#16603). */ specpdl_ptr--; grow_specpdl (); } /* Restore limits after leaving the debugger. */ record_unwind_protect (restore_stack_limits, Fcons (make_int (old_max), make_int (old_depth))); #ifdef HAVE_WINDOW_SYSTEM if (display_hourglass_p) cancel_hourglass (); #endif debug_on_next_call = 0; when_entered_debugger = num_nonmacro_input_events; /* Resetting redisplaying_p to 0 makes sure that debug output is displayed if the debugger is invoked during redisplay. */ debug_while_redisplaying = redisplaying_p; redisplaying_p = 0; specbind (intern ("debugger-may-continue"), debug_while_redisplaying ? Qnil : Qt); specbind (Qinhibit_redisplay, Qnil); specbind (Qinhibit_debugger, Qt); /* If we are debugging an error while `inhibit-changing-match-data' is bound to non-nil (e.g., within a call to `string-match-p'), then make sure debugger code can still use match data. */ specbind (Qinhibit_changing_match_data, Qnil); #if 0 /* Binding this prevents execution of Lisp code during redisplay, which necessarily leads to display problems. */ specbind (Qinhibit_eval_during_redisplay, Qt); #endif val = apply1 (Vdebugger, arg); /* Interrupting redisplay and resuming it later is not safe under all circumstances. So, when the debugger returns, abort the interrupted redisplay by going back to the top-level. */ if (debug_while_redisplaying) Ftop_level (); return unbind_to (count, val); } static void do_debug_on_call (Lisp_Object code, ptrdiff_t count) { debug_on_next_call = 0; set_backtrace_debug_on_exit (specpdl + count, true); call_debugger (list1 (code)); } /* NOTE!!! Every function that can call EVAL must protect its args and temporaries from garbage collection while it needs them. The definition of `For' shows what you have to do. */ DEFUN ("or", For, Sor, 0, UNEVALLED, 0, doc: /* Eval args until one of them yields non-nil, then return that value. The remaining args are not evalled at all. If all args return nil, return nil. usage: (or CONDITIONS...) */) (Lisp_Object args) { Lisp_Object val = Qnil; while (CONSP (args)) { Lisp_Object arg = XCAR (args); args = XCDR (args); val = eval_sub (arg); if (!NILP (val)) break; } return val; } DEFUN ("and", Fand, Sand, 0, UNEVALLED, 0, doc: /* Eval args until one of them yields nil, then return nil. The remaining args are not evalled at all. If no arg yields nil, return the last arg's value. usage: (and CONDITIONS...) */) (Lisp_Object args) { Lisp_Object val = Qt; while (CONSP (args)) { Lisp_Object arg = XCAR (args); args = XCDR (args); val = eval_sub (arg); if (NILP (val)) break; } return val; } DEFUN ("if", Fif, Sif, 2, UNEVALLED, 0, doc: /* If COND yields non-nil, do THEN, else do ELSE... Returns the value of THEN or the value of the last of the ELSE's. THEN must be one expression, but ELSE... can be zero or more expressions. If COND yields nil, and there are no ELSE's, the value is nil. usage: (if COND THEN ELSE...) */) (Lisp_Object args) { Lisp_Object cond; cond = eval_sub (XCAR (args)); if (!NILP (cond)) return eval_sub (Fcar (XCDR (args))); return Fprogn (Fcdr (XCDR (args))); } DEFUN ("cond", Fcond, Scond, 0, UNEVALLED, 0, doc: /* Try each clause until one succeeds. Each clause looks like (CONDITION BODY...). CONDITION is evaluated and, if the value is non-nil, this clause succeeds: then the expressions in BODY are evaluated and the last one's value is the value of the cond-form. If a clause has one element, as in (CONDITION), then the cond-form returns CONDITION's value, if that is non-nil. If no clause succeeds, cond returns nil. usage: (cond CLAUSES...) */) (Lisp_Object args) { Lisp_Object val = args; while (CONSP (args)) { Lisp_Object clause = XCAR (args); val = eval_sub (Fcar (clause)); if (!NILP (val)) { if (!NILP (XCDR (clause))) val = Fprogn (XCDR (clause)); break; } args = XCDR (args); } return val; } DEFUN ("progn", Fprogn, Sprogn, 0, UNEVALLED, 0, doc: /* Eval BODY forms sequentially and return value of last one. usage: (progn BODY...) */) (Lisp_Object body) { Lisp_Object val = Qnil; while (CONSP (body)) { Lisp_Object form = XCAR (body); body = XCDR (body); val = eval_sub (form); } return val; } /* Evaluate BODY sequentially, discarding its value. */ void prog_ignore (Lisp_Object body) { Fprogn (body); } DEFUN ("prog1", Fprog1, Sprog1, 1, UNEVALLED, 0, doc: /* Eval FIRST and BODY sequentially; return value from FIRST. The value of FIRST is saved during the evaluation of the remaining args, whose values are discarded. usage: (prog1 FIRST BODY...) */) (Lisp_Object args) { Lisp_Object val = eval_sub (XCAR (args)); prog_ignore (XCDR (args)); return val; } DEFUN ("setq", Fsetq, Ssetq, 0, UNEVALLED, 0, doc: /* Set each SYM to the value of its VAL. The symbols SYM are variables; they are literal (not evaluated). The values VAL are expressions; they are evaluated. Thus, (setq x (1+ y)) sets `x' to the value of `(1+ y)'. The second VAL is not computed until after the first SYM is set, and so on; each VAL can use the new value of variables set earlier in the `setq'. The return value of the `setq' form is the value of the last VAL. usage: (setq [SYM VAL]...) */) (Lisp_Object args) { Lisp_Object val = args, tail = args; for (EMACS_INT nargs = 0; CONSP (tail); nargs += 2) { Lisp_Object sym = XCAR (tail); tail = XCDR (tail); if (!CONSP (tail)) xsignal2 (Qwrong_number_of_arguments, Qsetq, make_fixnum (nargs + 1)); Lisp_Object arg = XCAR (tail); tail = XCDR (tail); val = eval_sub (arg); /* Like for eval_sub, we do not check declared_special here since it's been done when let-binding. */ Lisp_Object lex_binding = ((!NILP (Vinternal_interpreter_environment) /* Mere optimization! */ && SYMBOLP (sym)) ? Fassq (sym, Vinternal_interpreter_environment) : Qnil); if (!NILP (lex_binding)) XSETCDR (lex_binding, val); /* SYM is lexically bound. */ else Fset (sym, val); /* SYM is dynamically bound. */ } return val; } DEFUN ("quote", Fquote, Squote, 1, UNEVALLED, 0, doc: /* Return the argument, without evaluating it. `(quote x)' yields `x'. Warning: `quote' does not construct its return value, but just returns the value that was pre-constructed by the Lisp reader (see info node `(elisp)Printed Representation'). This means that \\='(a . b) is not identical to (cons \\='a \\='b): the former does not cons. Quoting should be reserved for constants that will never be modified by side-effects, unless you like self-modifying code. See the common pitfall in info node `(elisp)Rearrangement' for an example of unexpected results when a quoted object is modified. usage: (quote ARG) */) (Lisp_Object args) { if (!NILP (XCDR (args))) xsignal2 (Qwrong_number_of_arguments, Qquote, Flength (args)); return XCAR (args); } DEFUN ("function", Ffunction, Sfunction, 1, UNEVALLED, 0, doc: /* Like `quote', but preferred for objects which are functions. In byte compilation, `function' causes its argument to be handled by the byte compiler. Similarly, when expanding macros and expressions, ARG can be examined and possibly expanded. If `quote' is used instead, this doesn't happen. usage: (function ARG) */) (Lisp_Object args) { Lisp_Object quoted = XCAR (args); if (!NILP (XCDR (args))) xsignal2 (Qwrong_number_of_arguments, Qfunction, Flength (args)); if (!NILP (Vinternal_interpreter_environment) && CONSP (quoted) && EQ (XCAR (quoted), Qlambda)) { /* This is a lambda expression within a lexical environment; return an interpreted closure instead of a simple lambda. */ Lisp_Object cdr = XCDR (quoted); Lisp_Object tmp = cdr; if (CONSP (tmp) && (tmp = XCDR (tmp), CONSP (tmp)) && (tmp = XCAR (tmp), CONSP (tmp)) && (EQ (QCdocumentation, XCAR (tmp)))) { /* Handle the special (:documentation
) to build the docstring dynamically. */ Lisp_Object docstring = eval_sub (Fcar (XCDR (tmp))); CHECK_STRING (docstring); cdr = Fcons (XCAR (cdr), Fcons (docstring, XCDR (XCDR (cdr)))); } return Fcons (Qclosure, Fcons (Vinternal_interpreter_environment, cdr)); } else /* Simply quote the argument. */ return quoted; } DEFUN ("defvaralias", Fdefvaralias, Sdefvaralias, 2, 3, 0, doc: /* Make NEW-ALIAS a variable alias for symbol BASE-VARIABLE. Aliased variables always have the same value; setting one sets the other. Third arg DOCSTRING, if non-nil, is documentation for NEW-ALIAS. If it is omitted or nil, NEW-ALIAS gets the documentation string of BASE-VARIABLE, or of the variable at the end of the chain of aliases, if BASE-VARIABLE is itself an alias. If NEW-ALIAS is bound, and BASE-VARIABLE is not, then the value of BASE-VARIABLE is set to that of NEW-ALIAS. The return value is BASE-VARIABLE. */) (Lisp_Object new_alias, Lisp_Object base_variable, Lisp_Object docstring) { struct Lisp_Symbol *sym; CHECK_SYMBOL (new_alias); CHECK_SYMBOL (base_variable); if (SYMBOL_CONSTANT_P (new_alias)) /* Making it an alias effectively changes its value. */ error ("Cannot make a constant an alias"); sym = XSYMBOL (new_alias); switch (sym->u.s.redirect) { case SYMBOL_FORWARDED: error ("Cannot make an internal variable an alias"); case SYMBOL_LOCALIZED: error ("Don't know how to make a localized variable an alias"); case SYMBOL_PLAINVAL: case SYMBOL_VARALIAS: break; default: emacs_abort (); } /* https://lists.gnu.org/r/emacs-devel/2008-04/msg00834.html If n_a is bound, but b_v is not, set the value of b_v to n_a, so that old-code that affects n_a before the aliasing is setup still works. */ if (NILP (Fboundp (base_variable))) set_internal (base_variable, find_symbol_value (new_alias), Qnil, SET_INTERNAL_BIND); else if (!NILP (Fboundp (new_alias)) && !EQ (find_symbol_value (new_alias), find_symbol_value (base_variable))) call2 (intern ("display-warning"), list3 (Qdefvaralias, intern ("losing-value"), new_alias), CALLN (Fformat_message, build_string ("Overwriting value of `%s' by aliasing to `%s'"), new_alias, base_variable)); { union specbinding *p; for (p = specpdl_ptr; p > specpdl; ) if ((--p)->kind >= SPECPDL_LET && (EQ (new_alias, specpdl_symbol (p)))) error ("Don't know how to make a let-bound variable an alias"); } if (sym->u.s.trapped_write == SYMBOL_TRAPPED_WRITE) notify_variable_watchers (new_alias, base_variable, Qdefvaralias, Qnil); sym->u.s.declared_special = true; XSYMBOL (base_variable)->u.s.declared_special = true; sym->u.s.redirect = SYMBOL_VARALIAS; SET_SYMBOL_ALIAS (sym, XSYMBOL (base_variable)); sym->u.s.trapped_write = XSYMBOL (base_variable)->u.s.trapped_write; LOADHIST_ATTACH (new_alias); /* Even if docstring is nil: remove old docstring. */ Fput (new_alias, Qvariable_documentation, docstring); return base_variable; } static union specbinding * default_toplevel_binding (Lisp_Object symbol) { union specbinding *binding = NULL; union specbinding *pdl = specpdl_ptr; while (pdl > specpdl) { switch ((--pdl)->kind) { case SPECPDL_LET_DEFAULT: case SPECPDL_LET: if (EQ (specpdl_symbol (pdl), symbol)) binding = pdl; break; case SPECPDL_UNWIND: case SPECPDL_UNWIND_ARRAY: case SPECPDL_UNWIND_PTR: case SPECPDL_UNWIND_INT: case SPECPDL_UNWIND_INTMAX: case SPECPDL_UNWIND_EXCURSION: case SPECPDL_UNWIND_VOID: case SPECPDL_BACKTRACE: #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: case SPECPDL_MODULE_ENVIRONMENT: #endif case SPECPDL_LET_LOCAL: break; default: emacs_abort (); } } return binding; } /* Look for a lexical-binding of SYMBOL somewhere up the stack. This will only find bindings created with interpreted code, since once compiled names of lexical variables are basically gone anyway. */ static bool lexbound_p (Lisp_Object symbol) { union specbinding *pdl = specpdl_ptr; while (pdl > specpdl) { switch ((--pdl)->kind) { case SPECPDL_LET_DEFAULT: case SPECPDL_LET: if (EQ (specpdl_symbol (pdl), Qinternal_interpreter_environment)) { Lisp_Object env = specpdl_old_value (pdl); if (CONSP (env) && !NILP (Fassq (symbol, env))) return true; } break; case SPECPDL_UNWIND: case SPECPDL_UNWIND_ARRAY: case SPECPDL_UNWIND_PTR: case SPECPDL_UNWIND_INT: case SPECPDL_UNWIND_INTMAX: case SPECPDL_UNWIND_EXCURSION: case SPECPDL_UNWIND_VOID: case SPECPDL_BACKTRACE: #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: case SPECPDL_MODULE_ENVIRONMENT: #endif case SPECPDL_LET_LOCAL: break; default: emacs_abort (); } } return false; } DEFUN ("default-toplevel-value", Fdefault_toplevel_value, Sdefault_toplevel_value, 1, 1, 0, doc: /* Return SYMBOL's toplevel default value. "Toplevel" means outside of any let binding. */) (Lisp_Object symbol) { union specbinding *binding = default_toplevel_binding (symbol); Lisp_Object value = binding ? specpdl_old_value (binding) : Fdefault_value (symbol); if (!EQ (value, Qunbound)) return value; xsignal1 (Qvoid_variable, symbol); } DEFUN ("set-default-toplevel-value", Fset_default_toplevel_value, Sset_default_toplevel_value, 2, 2, 0, doc: /* Set SYMBOL's toplevel default value to VALUE. "Toplevel" means outside of any let binding. */) (Lisp_Object symbol, Lisp_Object value) { union specbinding *binding = default_toplevel_binding (symbol); if (binding) set_specpdl_old_value (binding, value); else Fset_default (symbol, value); return Qnil; } DEFUN ("internal--define-uninitialized-variable", Finternal__define_uninitialized_variable, Sinternal__define_uninitialized_variable, 1, 2, 0, doc: /* Define SYMBOL as a variable, with DOC as its docstring. This is like `defvar' and `defconst' but without affecting the variable's value. */) (Lisp_Object symbol, Lisp_Object doc) { if (!XSYMBOL (symbol)->u.s.declared_special && lexbound_p (symbol)) /* This test tries to catch the situation where we do (let (( ...)) ...( ...)....) and where the `foo` package only gets loaded when is called, so the outer `let` incorrectly made the binding lexical because the wasn't yet declared as dynamic at that point. */ error ("Defining as dynamic an already lexical var"); XSYMBOL (symbol)->u.s.declared_special = true; if (!NILP (doc)) { if (!NILP (Vpurify_flag)) doc = Fpurecopy (doc); Fput (symbol, Qvariable_documentation, doc); } LOADHIST_ATTACH (symbol); return Qnil; } DEFUN ("defvar", Fdefvar, Sdefvar, 1, UNEVALLED, 0, doc: /* Define SYMBOL as a variable, and return SYMBOL. You are not required to define a variable in order to use it, but defining it lets you supply an initial value and documentation, which can be referred to by the Emacs help facilities and other programming tools. The `defvar' form also declares the variable as \"special\", so that it is always dynamically bound even if `lexical-binding' is t. If SYMBOL's value is void and the optional argument INITVALUE is provided, INITVALUE is evaluated and the result used to set SYMBOL's value. If SYMBOL is buffer-local, its default value is what is set; buffer-local values are not affected. If INITVALUE is missing, SYMBOL's value is not set. If SYMBOL has a local binding, then this form affects the local binding. This is usually not what you want. Thus, if you need to load a file defining variables, with this form or with `defconst' or `defcustom', you should always load that file _outside_ any bindings for these variables. (`defconst' and `defcustom' behave similarly in this respect.) The optional argument DOCSTRING is a documentation string for the variable. To define a user option, use `defcustom' instead of `defvar'. usage: (defvar SYMBOL &optional INITVALUE DOCSTRING) */) (Lisp_Object args) { Lisp_Object sym, tem, tail; sym = XCAR (args); tail = XCDR (args); CHECK_SYMBOL (sym); if (!NILP (tail)) { if (!NILP (XCDR (tail)) && !NILP (XCDR (XCDR (tail)))) error ("Too many arguments"); Lisp_Object exp = XCAR (tail); tem = Fdefault_boundp (sym); tail = XCDR (tail); /* Do it before evaluating the initial value, for self-references. */ Finternal__define_uninitialized_variable (sym, CAR (tail)); if (NILP (tem)) Fset_default (sym, eval_sub (exp)); else { /* Check if there is really a global binding rather than just a let binding that shadows the global unboundness of the var. */ union specbinding *binding = default_toplevel_binding (sym); if (binding && EQ (specpdl_old_value (binding), Qunbound)) { set_specpdl_old_value (binding, eval_sub (exp)); } } } else if (!NILP (Vinternal_interpreter_environment) && (SYMBOLP (sym) && !XSYMBOL (sym)->u.s.declared_special)) /* A simple (defvar foo) with lexical scoping does "nothing" except declare that var to be dynamically scoped *locally* (i.e. within the current file or let-block). */ Vinternal_interpreter_environment = Fcons (sym, Vinternal_interpreter_environment); else { /* Simple (defvar ) should not count as a definition at all. It could get in the way of other definitions, and unloading this package could try to make the variable unbound. */ } return sym; } DEFUN ("defconst", Fdefconst, Sdefconst, 2, UNEVALLED, 0, doc: /* Define SYMBOL as a constant variable. This declares that neither programs nor users should ever change the value. This constancy is not actually enforced by Emacs Lisp, but SYMBOL is marked as a special variable so that it is never lexically bound. The `defconst' form always sets the value of SYMBOL to the result of evalling INITVALUE. If SYMBOL is buffer-local, its default value is what is set; buffer-local values are not affected. If SYMBOL has a local binding, then this form sets the local binding's value. However, you should normally not make local bindings for variables defined with this form. The optional DOCSTRING specifies the variable's documentation string. usage: (defconst SYMBOL INITVALUE [DOCSTRING]) */) (Lisp_Object args) { Lisp_Object sym, tem; sym = XCAR (args); CHECK_SYMBOL (sym); Lisp_Object docstring = Qnil; if (!NILP (XCDR (XCDR (args)))) { if (!NILP (XCDR (XCDR (XCDR (args))))) error ("Too many arguments"); docstring = XCAR (XCDR (XCDR (args))); } Finternal__define_uninitialized_variable (sym, docstring); tem = eval_sub (XCAR (XCDR (args))); if (!NILP (Vpurify_flag)) tem = Fpurecopy (tem); Fset_default (sym, tem); /* FIXME: set-default-toplevel-value? */ Fput (sym, Qrisky_local_variable, Qt); /* FIXME: Why? */ return sym; } /* Make SYMBOL lexically scoped. */ DEFUN ("internal-make-var-non-special", Fmake_var_non_special, Smake_var_non_special, 1, 1, 0, doc: /* Internal function. */) (Lisp_Object symbol) { CHECK_SYMBOL (symbol); XSYMBOL (symbol)->u.s.declared_special = false; return Qnil; } DEFUN ("let*", FletX, SletX, 1, UNEVALLED, 0, doc: /* Bind variables according to VARLIST then eval BODY. The value of the last form in BODY is returned. Each element of VARLIST is a symbol (which is bound to nil) or a list (SYMBOL VALUEFORM) (which binds SYMBOL to the value of VALUEFORM). Each VALUEFORM can refer to the symbols already bound by this VARLIST. usage: (let* VARLIST BODY...) */) (Lisp_Object args) { Lisp_Object var, val, elt, lexenv; ptrdiff_t count = SPECPDL_INDEX (); lexenv = Vinternal_interpreter_environment; Lisp_Object varlist = XCAR (args); while (CONSP (varlist)) { maybe_quit (); elt = XCAR (varlist); varlist = XCDR (varlist); if (SYMBOLP (elt)) { var = elt; val = Qnil; } else { var = Fcar (elt); if (! NILP (Fcdr (XCDR (elt)))) signal_error ("`let' bindings can have only one value-form", elt); val = eval_sub (Fcar (XCDR (elt))); } if (!NILP (lexenv) && SYMBOLP (var) && !XSYMBOL (var)->u.s.declared_special && NILP (Fmemq (var, Vinternal_interpreter_environment))) /* Lexically bind VAR by adding it to the interpreter's binding alist. */ { Lisp_Object newenv = Fcons (Fcons (var, val), Vinternal_interpreter_environment); if (EQ (Vinternal_interpreter_environment, lexenv)) /* Save the old lexical environment on the specpdl stack, but only for the first lexical binding, since we'll never need to revert to one of the intermediate ones. */ specbind (Qinternal_interpreter_environment, newenv); else Vinternal_interpreter_environment = newenv; } else specbind (var, val); } CHECK_LIST_END (varlist, XCAR (args)); val = Fprogn (XCDR (args)); return unbind_to (count, val); } DEFUN ("let", Flet, Slet, 1, UNEVALLED, 0, doc: /* Bind variables according to VARLIST then eval BODY. The value of the last form in BODY is returned. Each element of VARLIST is a symbol (which is bound to nil) or a list (SYMBOL VALUEFORM) (which binds SYMBOL to the value of VALUEFORM). All the VALUEFORMs are evalled before any symbols are bound. usage: (let VARLIST BODY...) */) (Lisp_Object args) { Lisp_Object *temps, tem, lexenv; Lisp_Object elt; ptrdiff_t count = SPECPDL_INDEX (); ptrdiff_t argnum; USE_SAFE_ALLOCA; Lisp_Object varlist = XCAR (args); /* Make space to hold the values to give the bound variables. */ EMACS_INT varlist_len = list_length (varlist); SAFE_ALLOCA_LISP (temps, varlist_len); ptrdiff_t nvars = varlist_len; /* Compute the values and store them in `temps'. */ for (argnum = 0; argnum < nvars && CONSP (varlist); argnum++) { maybe_quit (); elt = XCAR (varlist); varlist = XCDR (varlist); if (SYMBOLP (elt)) temps[argnum] = Qnil; else if (! NILP (Fcdr (Fcdr (elt)))) signal_error ("`let' bindings can have only one value-form", elt); else temps[argnum] = eval_sub (Fcar (Fcdr (elt))); } nvars = argnum; lexenv = Vinternal_interpreter_environment; varlist = XCAR (args); for (argnum = 0; argnum < nvars && CONSP (varlist); argnum++) { Lisp_Object var; elt = XCAR (varlist); varlist = XCDR (varlist); var = SYMBOLP (elt) ? elt : Fcar (elt); tem = temps[argnum]; if (!NILP (lexenv) && SYMBOLP (var) && !XSYMBOL (var)->u.s.declared_special && NILP (Fmemq (var, Vinternal_interpreter_environment))) /* Lexically bind VAR by adding it to the lexenv alist. */ lexenv = Fcons (Fcons (var, tem), lexenv); else /* Dynamically bind VAR. */ specbind (var, tem); } if (!EQ (lexenv, Vinternal_interpreter_environment)) /* Instantiate a new lexical environment. */ specbind (Qinternal_interpreter_environment, lexenv); elt = Fprogn (XCDR (args)); return SAFE_FREE_UNBIND_TO (count, elt); } DEFUN ("while", Fwhile, Swhile, 1, UNEVALLED, 0, doc: /* If TEST yields non-nil, eval BODY... and repeat. The order of execution is thus TEST, BODY, TEST, BODY and so on until TEST returns nil. The value of a `while' form is always nil. usage: (while TEST BODY...) */) (Lisp_Object args) { Lisp_Object test, body; test = XCAR (args); body = XCDR (args); while (!NILP (eval_sub (test))) { maybe_quit (); prog_ignore (body); } return Qnil; } DEFUN ("macroexpand", Fmacroexpand, Smacroexpand, 1, 2, 0, doc: /* Return result of expanding macros at top level of FORM. If FORM is not a macro call, it is returned unchanged. Otherwise, the macro is expanded and the expansion is considered in place of FORM. When a non-macro-call results, it is returned. The second optional arg ENVIRONMENT specifies an environment of macro definitions to shadow the loaded ones for use in file byte-compilation. */) (Lisp_Object form, Lisp_Object environment) { /* With cleanups from Hallvard Furuseth. */ register Lisp_Object expander, sym, def, tem; while (1) { /* Come back here each time we expand a macro call, in case it expands into another macro call. */ if (!CONSP (form)) break; /* Set SYM, give DEF and TEM right values in case SYM is not a symbol. */ def = sym = XCAR (form); tem = Qnil; /* Trace symbols aliases to other symbols until we get a symbol that is not an alias. */ while (SYMBOLP (def)) { maybe_quit (); sym = def; tem = Fassq (sym, environment); if (NILP (tem)) { def = XSYMBOL (sym)->u.s.function; if (!NILP (def)) continue; } break; } /* Right now TEM is the result from SYM in ENVIRONMENT, and if TEM is nil then DEF is SYM's function definition. */ if (NILP (tem)) { /* SYM is not mentioned in ENVIRONMENT. Look at its function definition. */ def = Fautoload_do_load (def, sym, Qmacro); if (!CONSP (def)) /* Not defined or definition not suitable. */ break; if (!EQ (XCAR (def), Qmacro)) break; else expander = XCDR (def); } else { expander = XCDR (tem); if (NILP (expander)) break; } { Lisp_Object newform = apply1 (expander, XCDR (form)); if (EQ (form, newform)) break; else form = newform; } } return form; } DEFUN ("catch", Fcatch, Scatch, 1, UNEVALLED, 0, doc: /* Eval BODY allowing nonlocal exits using `throw'. TAG is evalled to get the tag to use; it must not be nil. Then the BODY is executed. Within BODY, a call to `throw' with the same TAG exits BODY and this `catch'. If no throw happens, `catch' returns the value of the last BODY form. If a throw happens, it specifies the value to return from `catch'. usage: (catch TAG BODY...) */) (Lisp_Object args) { Lisp_Object tag = eval_sub (XCAR (args)); return internal_catch (tag, Fprogn, XCDR (args)); } /* Assert that E is true, but do not evaluate E. Use this instead of eassert (E) when E contains variables that might be clobbered by a longjmp. */ #define clobbered_eassert(E) verify (sizeof (E) != 0) /* Set up a catch, then call C function FUNC on argument ARG. FUNC should return a Lisp_Object. This is how catches are done from within C code. */ Lisp_Object internal_catch (Lisp_Object tag, Lisp_Object (*func) (Lisp_Object), Lisp_Object arg) { /* This structure is made part of the chain `catchlist'. */ struct handler *c = push_handler (tag, CATCHER); /* Call FUNC. */ if (! sys_setjmp (c->jmp)) { Lisp_Object val = func (arg); eassert (handlerlist == c); handlerlist = c->next; return val; } else { /* Throw works by a longjmp that comes right here. */ Lisp_Object val = handlerlist->val; clobbered_eassert (handlerlist == c); handlerlist = handlerlist->next; return val; } } /* Unwind the specbind, catch, and handler stacks back to CATCH, and jump to that CATCH, returning VALUE as the value of that catch. This is the guts of Fthrow and Fsignal; they differ only in the way they choose the catch tag to throw to. A catch tag for a condition-case form has a TAG of Qnil. Before each catch is discarded, unbind all special bindings and execute all unwind-protect clauses made above that catch. Unwind the handler stack as we go, so that the proper handlers are in effect for each unwind-protect clause we run. At the end, restore some static info saved in CATCH, and longjmp to the location specified there. This is used for correct unwinding in Fthrow and Fsignal. */ static AVOID unwind_to_catch (struct handler *catch, enum nonlocal_exit type, Lisp_Object value) { bool last_time; eassert (catch->next); /* Save the value in the tag. */ catch->nonlocal_exit = type; catch->val = value; /* Restore certain special C variables. */ set_poll_suppress_count (catch->poll_suppress_count); unblock_input_to (catch->interrupt_input_blocked); do { /* Unwind the specpdl stack, and then restore the proper set of handlers. */ unbind_to (handlerlist->pdlcount, Qnil); last_time = handlerlist == catch; if (! last_time) handlerlist = handlerlist->next; } while (! last_time); eassert (handlerlist == catch); lisp_eval_depth = catch->f_lisp_eval_depth; sys_longjmp (catch->jmp, 1); } DEFUN ("throw", Fthrow, Sthrow, 2, 2, 0, doc: /* Throw to the catch for TAG and return VALUE from it. Both TAG and VALUE are evalled. */ attributes: noreturn) (register Lisp_Object tag, Lisp_Object value) { struct handler *c; if (!NILP (tag)) for (c = handlerlist; c; c = c->next) { if (c->type == CATCHER_ALL) unwind_to_catch (c, NONLOCAL_EXIT_THROW, Fcons (tag, value)); if (c->type == CATCHER && EQ (c->tag_or_ch, tag)) unwind_to_catch (c, NONLOCAL_EXIT_THROW, value); } xsignal2 (Qno_catch, tag, value); } DEFUN ("unwind-protect", Funwind_protect, Sunwind_protect, 1, UNEVALLED, 0, doc: /* Do BODYFORM, protecting with UNWINDFORMS. If BODYFORM completes normally, its value is returned after executing the UNWINDFORMS. If BODYFORM exits nonlocally, the UNWINDFORMS are executed anyway. usage: (unwind-protect BODYFORM UNWINDFORMS...) */) (Lisp_Object args) { Lisp_Object val; ptrdiff_t count = SPECPDL_INDEX (); record_unwind_protect (prog_ignore, XCDR (args)); val = eval_sub (XCAR (args)); return unbind_to (count, val); } DEFUN ("condition-case", Fcondition_case, Scondition_case, 2, UNEVALLED, 0, doc: /* Regain control when an error is signaled. Executes BODYFORM and returns its value if no error happens. Each element of HANDLERS looks like (CONDITION-NAME BODY...) where the BODY is made of Lisp expressions. A handler is applicable to an error if CONDITION-NAME is one of the error's condition names. Handlers may also apply when non-error symbols are signaled (e.g., `quit'). A CONDITION-NAME of t applies to any symbol, including non-error symbols. If multiple handlers are applicable, only the first one runs. The car of a handler may be a list of condition names instead of a single condition name; then it handles all of them. If the special condition name `debug' is present in this list, it allows another condition in the list to run the debugger if `debug-on-error' and the other usual mechanisms say it should (otherwise, `condition-case' suppresses the debugger). When a handler handles an error, control returns to the `condition-case' and it executes the handler's BODY... with VAR bound to (ERROR-SYMBOL . SIGNAL-DATA) from the error. \(If VAR is nil, the handler can't access that information.) Then the value of the last BODY form is returned from the `condition-case' expression. See also the function `signal' for more info. usage: (condition-case VAR BODYFORM &rest HANDLERS) */) (Lisp_Object args) { Lisp_Object var = XCAR (args); Lisp_Object bodyform = XCAR (XCDR (args)); Lisp_Object handlers = XCDR (XCDR (args)); return internal_lisp_condition_case (var, bodyform, handlers); } /* Like Fcondition_case, but the args are separate rather than passed in a list. Used by Fbyte_code. */ Lisp_Object internal_lisp_condition_case (Lisp_Object var, Lisp_Object bodyform, Lisp_Object handlers) { struct handler *oldhandlerlist = handlerlist; ptrdiff_t CACHEABLE clausenb = 0; CHECK_SYMBOL (var); for (Lisp_Object tail = handlers; CONSP (tail); tail = XCDR (tail)) { Lisp_Object tem = XCAR (tail); clausenb++; if (! (NILP (tem) || (CONSP (tem) && (SYMBOLP (XCAR (tem)) || CONSP (XCAR (tem)))))) error ("Invalid condition handler: %s", SDATA (Fprin1_to_string (tem, Qt))); } /* The first clause is the one that should be checked first, so it should be added to handlerlist last. So build in CLAUSES a table that contains HANDLERS but in reverse order. CLAUSES is pointer to volatile to avoid issues with setjmp and local storage. SAFE_ALLOCA won't work here due to the setjmp, so impose a MAX_ALLOCA limit. */ if (MAX_ALLOCA / word_size < clausenb) memory_full (SIZE_MAX); Lisp_Object volatile *clauses = alloca (clausenb * sizeof *clauses); clauses += clausenb; for (Lisp_Object tail = handlers; CONSP (tail); tail = XCDR (tail)) *--clauses = XCAR (tail); for (ptrdiff_t i = 0; i < clausenb; i++) { Lisp_Object clause = clauses[i]; Lisp_Object condition = CONSP (clause) ? XCAR (clause) : Qnil; if (!CONSP (condition)) condition = list1 (condition); struct handler *c = push_handler (condition, CONDITION_CASE); if (sys_setjmp (c->jmp)) { Lisp_Object val = handlerlist->val; Lisp_Object volatile *chosen_clause = clauses; for (struct handler *h = handlerlist->next; h != oldhandlerlist; h = h->next) chosen_clause++; Lisp_Object handler_body = XCDR (*chosen_clause); handlerlist = oldhandlerlist; if (NILP (var)) return Fprogn (handler_body); Lisp_Object handler_var = var; if (!NILP (Vinternal_interpreter_environment)) { val = Fcons (Fcons (var, val), Vinternal_interpreter_environment); handler_var = Qinternal_interpreter_environment; } /* Bind HANDLER_VAR to VAL while evaluating HANDLER_BODY. The unbind_to undoes just this binding; whoever longjumped to us unwound the stack to C->pdlcount before throwing. */ ptrdiff_t count = SPECPDL_INDEX (); specbind (handler_var, val); return unbind_to (count, Fprogn (handler_body)); } } Lisp_Object result = eval_sub (bodyform); handlerlist = oldhandlerlist; return result; } /* Call the function BFUN with no arguments, catching errors within it according to HANDLERS. If there is an error, call HFUN with one argument which is the data that describes the error: (SIGNALNAME . DATA) HANDLERS can be a list of conditions to catch. If HANDLERS is Qt, catch all errors. If HANDLERS is Qerror, catch all errors but allow the debugger to run if that is enabled. */ Lisp_Object internal_condition_case (Lisp_Object (*bfun) (void), Lisp_Object handlers, Lisp_Object (*hfun) (Lisp_Object)) { struct handler *c = push_handler (handlers, CONDITION_CASE); if (sys_setjmp (c->jmp)) { Lisp_Object val = handlerlist->val; clobbered_eassert (handlerlist == c); handlerlist = handlerlist->next; return hfun (val); } else { Lisp_Object val = bfun (); eassert (handlerlist == c); handlerlist = c->next; return val; } } /* Like internal_condition_case but call BFUN with ARG as its argument. */ Lisp_Object internal_condition_case_1 (Lisp_Object (*bfun) (Lisp_Object), Lisp_Object arg, Lisp_Object handlers, Lisp_Object (*hfun) (Lisp_Object)) { struct handler *c = push_handler (handlers, CONDITION_CASE); if (sys_setjmp (c->jmp)) { Lisp_Object val = handlerlist->val; clobbered_eassert (handlerlist == c); handlerlist = handlerlist->next; return hfun (val); } else { Lisp_Object val = bfun (arg); eassert (handlerlist == c); handlerlist = c->next; return val; } } /* Like internal_condition_case_1 but call BFUN with ARG1 and ARG2 as its arguments. */ Lisp_Object internal_condition_case_2 (Lisp_Object (*bfun) (Lisp_Object, Lisp_Object), Lisp_Object arg1, Lisp_Object arg2, Lisp_Object handlers, Lisp_Object (*hfun) (Lisp_Object)) { struct handler *c = push_handler (handlers, CONDITION_CASE); if (sys_setjmp (c->jmp)) { Lisp_Object val = handlerlist->val; clobbered_eassert (handlerlist == c); handlerlist = handlerlist->next; return hfun (val); } else { Lisp_Object val = bfun (arg1, arg2); eassert (handlerlist == c); handlerlist = c->next; return val; } } /* Like internal_condition_case but call BFUN with NARGS as first, and ARGS as second argument. */ Lisp_Object internal_condition_case_n (Lisp_Object (*bfun) (ptrdiff_t, Lisp_Object *), ptrdiff_t nargs, Lisp_Object *args, Lisp_Object handlers, Lisp_Object (*hfun) (Lisp_Object err, ptrdiff_t nargs, Lisp_Object *args)) { struct handler *c = push_handler (handlers, CONDITION_CASE); if (sys_setjmp (c->jmp)) { Lisp_Object val = handlerlist->val; clobbered_eassert (handlerlist == c); handlerlist = handlerlist->next; return hfun (val, nargs, args); } else { Lisp_Object val = bfun (nargs, args); eassert (handlerlist == c); handlerlist = c->next; return val; } } static Lisp_Object Qcatch_all_memory_full; /* Like a combination of internal_condition_case_1 and internal_catch. Catches all signals and throws. Never exits nonlocally; returns Qcatch_all_memory_full if no handler could be allocated. */ Lisp_Object internal_catch_all (Lisp_Object (*function) (void *), void *argument, Lisp_Object (*handler) (enum nonlocal_exit, Lisp_Object)) { struct handler *c = push_handler_nosignal (Qt, CATCHER_ALL); if (c == NULL) return Qcatch_all_memory_full; if (sys_setjmp (c->jmp) == 0) { Lisp_Object val = function (argument); eassert (handlerlist == c); handlerlist = c->next; return val; } else { eassert (handlerlist == c); enum nonlocal_exit type = c->nonlocal_exit; Lisp_Object val = c->val; handlerlist = c->next; return handler (type, val); } } struct handler * push_handler (Lisp_Object tag_ch_val, enum handlertype handlertype) { struct handler *c = push_handler_nosignal (tag_ch_val, handlertype); if (!c) memory_full (sizeof *c); return c; } struct handler * push_handler_nosignal (Lisp_Object tag_ch_val, enum handlertype handlertype) { struct handler *CACHEABLE c = handlerlist->nextfree; if (!c) { c = malloc (sizeof *c); if (!c) return c; if (profiler_memory_running) malloc_probe (sizeof *c); c->nextfree = NULL; handlerlist->nextfree = c; } c->type = handlertype; c->tag_or_ch = tag_ch_val; c->val = Qnil; c->next = handlerlist; c->f_lisp_eval_depth = lisp_eval_depth; c->pdlcount = SPECPDL_INDEX (); c->poll_suppress_count = poll_suppress_count; c->interrupt_input_blocked = interrupt_input_blocked; handlerlist = c; return c; } static Lisp_Object signal_or_quit (Lisp_Object, Lisp_Object, bool); static Lisp_Object find_handler_clause (Lisp_Object, Lisp_Object); static bool maybe_call_debugger (Lisp_Object conditions, Lisp_Object sig, Lisp_Object data); static void process_quit_flag (void) { Lisp_Object flag = Vquit_flag; Vquit_flag = Qnil; if (EQ (flag, Qkill_emacs)) Fkill_emacs (Qnil); if (EQ (Vthrow_on_input, flag)) Fthrow (Vthrow_on_input, Qt); quit (); } /* Check quit-flag and quit if it is non-nil. Typing C-g does not directly cause a quit; it only sets Vquit_flag. So the program needs to call maybe_quit at times when it is safe to quit. Every loop that might run for a long time or might not exit ought to call maybe_quit at least once, at a safe place. Unless that is impossible, of course. But it is very desirable to avoid creating loops where maybe_quit is impossible. If quit-flag is set to `kill-emacs' the SIGINT handler has received a request to exit Emacs when it is safe to do. When not quitting, process any pending signals. */ void maybe_quit (void) { if (!NILP (Vquit_flag) && NILP (Vinhibit_quit)) process_quit_flag (); else if (pending_signals) process_pending_signals (); } DEFUN ("signal", Fsignal, Ssignal, 2, 2, 0, doc: /* Signal an error. Args are ERROR-SYMBOL and associated DATA. This function does not return. An error symbol is a symbol with an `error-conditions' property that is a list of condition names. The symbol should be non-nil. A handler for any of those names will get to handle this signal. The symbol `error' should normally be one of them. DATA should be a list. Its elements are printed as part of the error message. See Info anchor `(elisp)Definition of signal' for some details on how this error message is constructed. If the signal is handled, DATA is made available to the handler. See also the function `condition-case'. */ attributes: noreturn) (Lisp_Object error_symbol, Lisp_Object data) { /* If they call us with nonsensical arguments, produce "peculiar error". */ if (NILP (error_symbol) && NILP (data)) error_symbol = Qerror; signal_or_quit (error_symbol, data, false); eassume (false); } /* Quit, in response to a keyboard quit request. */ Lisp_Object quit (void) { return signal_or_quit (Qquit, Qnil, true); } /* Signal an error, or quit. ERROR_SYMBOL and DATA are as with Fsignal. If KEYBOARD_QUIT, this is a quit; ERROR_SYMBOL should be Qquit and DATA should be Qnil, and this function may return. Otherwise this function is like Fsignal and does not return. */ static Lisp_Object signal_or_quit (Lisp_Object error_symbol, Lisp_Object data, bool keyboard_quit) { /* When memory is full, ERROR-SYMBOL is nil, and DATA is (REAL-ERROR-SYMBOL . REAL-DATA). That is a special case--don't do this in other situations. */ Lisp_Object conditions; Lisp_Object string; Lisp_Object real_error_symbol = (NILP (error_symbol) ? Fcar (data) : error_symbol); Lisp_Object clause = Qnil; struct handler *h; if (gc_in_progress || waiting_for_input) emacs_abort (); #if 0 /* rms: I don't know why this was here, but it is surely wrong for an error that is handled. */ #ifdef HAVE_WINDOW_SYSTEM if (display_hourglass_p) cancel_hourglass (); #endif #endif /* This hook is used by edebug. */ if (! NILP (Vsignal_hook_function) && ! NILP (error_symbol) /* Don't try to call a lisp function if we've already overflowed the specpdl stack. */ && specpdl_ptr < specpdl + specpdl_size) { /* Edebug takes care of restoring these variables when it exits. */ max_ensure_room (&max_lisp_eval_depth, lisp_eval_depth, 20); max_ensure_room (&max_specpdl_size, SPECPDL_INDEX (), 40); call2 (Vsignal_hook_function, error_symbol, data); } conditions = Fget (real_error_symbol, Qerror_conditions); /* Remember from where signal was called. Skip over the frame for `signal' itself. If a frame for `error' follows, skip that, too. Don't do this when ERROR_SYMBOL is nil, because that is a memory-full error. */ Vsignaling_function = Qnil; if (!NILP (error_symbol)) { union specbinding *pdl = backtrace_next (backtrace_top ()); if (backtrace_p (pdl) && EQ (backtrace_function (pdl), Qerror)) pdl = backtrace_next (pdl); if (backtrace_p (pdl)) Vsignaling_function = backtrace_function (pdl); } for (h = handlerlist; h; h = h->next) { if (h->type == CATCHER_ALL) { clause = Qt; break; } if (h->type != CONDITION_CASE) continue; clause = find_handler_clause (h->tag_or_ch, conditions); if (!NILP (clause)) break; } bool debugger_called = false; if (/* Don't run the debugger for a memory-full error. (There is no room in memory to do that!) */ !NILP (error_symbol) && (!NILP (Vdebug_on_signal) /* If no handler is present now, try to run the debugger. */ || NILP (clause) /* A `debug' symbol in the handler list disables the normal suppression of the debugger. */ || (CONSP (clause) && !NILP (Fmemq (Qdebug, clause))) /* Special handler that means "print a message and run debugger if requested". */ || EQ (h->tag_or_ch, Qerror))) { debugger_called = maybe_call_debugger (conditions, error_symbol, data); /* We can't return values to code which signaled an error, but we can continue code which has signaled a quit. */ if (keyboard_quit && debugger_called && EQ (real_error_symbol, Qquit)) return Qnil; } /* If we're in batch mode, print a backtrace unconditionally to help with debugging. Make sure to use `debug' unconditionally to not interfere with ERT or other packages that install custom debuggers. */ if (!debugger_called && !NILP (error_symbol) && (NILP (clause) || EQ (h->tag_or_ch, Qerror)) && noninteractive) { ptrdiff_t count = SPECPDL_INDEX (); specbind (Vdebugger, Qdebug); call_debugger (list2 (Qerror, Fcons (error_symbol, data))); unbind_to (count, Qnil); } if (!NILP (clause)) { Lisp_Object unwind_data = (NILP (error_symbol) ? data : Fcons (error_symbol, data)); unwind_to_catch (h, NONLOCAL_EXIT_SIGNAL, unwind_data); } else { if (handlerlist != handlerlist_sentinel) /* FIXME: This will come right back here if there's no `top-level' catcher. A better solution would be to abort here, and instead add a catch-all condition handler so we never come here. */ Fthrow (Qtop_level, Qt); } if (! NILP (error_symbol)) data = Fcons (error_symbol, data); string = Ferror_message_string (data); fatal ("%s", SDATA (string)); } /* Like xsignal, but takes 0, 1, 2, or 3 args instead of a list. */ void xsignal0 (Lisp_Object error_symbol) { xsignal (error_symbol, Qnil); } void xsignal1 (Lisp_Object error_symbol, Lisp_Object arg) { xsignal (error_symbol, list1 (arg)); } void xsignal2 (Lisp_Object error_symbol, Lisp_Object arg1, Lisp_Object arg2) { xsignal (error_symbol, list2 (arg1, arg2)); } void xsignal3 (Lisp_Object error_symbol, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3) { xsignal (error_symbol, list3 (arg1, arg2, arg3)); } /* Signal `error' with message S, and additional arg ARG. If ARG is not a proper list, make it a one-element list. */ void signal_error (const char *s, Lisp_Object arg) { if (NILP (Fproper_list_p (arg))) arg = list1 (arg); xsignal (Qerror, Fcons (build_string (s), arg)); } /* Use this for arithmetic overflow, e.g., when an integer result is too large even for a bignum. */ void overflow_error (void) { xsignal0 (Qoverflow_error); } /* Return true if LIST is a non-nil atom or a list containing one of CONDITIONS. */ static bool wants_debugger (Lisp_Object list, Lisp_Object 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; } /* Return true if an error with condition-symbols CONDITIONS, and described by SIGNAL-DATA, should skip the debugger according to debugger-ignored-errors. */ static bool skip_debugger (Lisp_Object conditions, Lisp_Object data) { Lisp_Object tail; bool 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; } /* Call the debugger if calling it is currently enabled for CONDITIONS. SIG and DATA describe the signal. There are two ways to pass them: = SIG is the error symbol, and DATA is the rest of the data. = SIG is nil, and DATA is (SYMBOL . REST-OF-DATA). This is for memory-full errors only. */ static bool maybe_call_debugger (Lisp_Object conditions, Lisp_Object sig, Lisp_Object data) { Lisp_Object combined_data; combined_data = Fcons (sig, data); if ( /* Don't try to run the debugger with interrupts blocked. The editing loop would return anyway. */ ! input_blocked_p () && NILP (Vinhibit_debugger) /* Does user want to enter debugger for this kind of error? */ && (EQ (sig, Qquit) ? debug_on_quit : wants_debugger (Vdebug_on_error, conditions)) && ! skip_debugger (conditions, combined_data) /* See commentary on definition of `internal-when-entered-debugger'. */ && when_entered_debugger < num_nonmacro_input_events) { call_debugger (list2 (Qerror, combined_data)); return 1; } return 0; } static Lisp_Object find_handler_clause (Lisp_Object handlers, Lisp_Object conditions) { register Lisp_Object h; /* t is used by handlers for all conditions, set up by C code. */ if (EQ (handlers, Qt)) return Qt; /* error is used similarly, but means print an error message and run the debugger if that is enabled. */ if (EQ (handlers, Qerror)) return Qt; for (h = handlers; CONSP (h); h = XCDR (h)) { Lisp_Object handler = XCAR (h); if (!NILP (Fmemq (handler, conditions)) /* t is also used as a catch-all by Lisp code. */ || EQ (handler, Qt)) return handlers; } return Qnil; } /* Format and return a string; called like vprintf. */ Lisp_Object vformat_string (const char *m, va_list ap) { char buf[4000]; ptrdiff_t size = sizeof buf; ptrdiff_t size_max = STRING_BYTES_BOUND + 1; char *buffer = buf; ptrdiff_t used; Lisp_Object string; used = evxprintf (&buffer, &size, buf, size_max, m, ap); string = make_string (buffer, used); if (buffer != buf) xfree (buffer); return string; } /* Dump an error message; called like vprintf. */ void verror (const char *m, va_list ap) { xsignal1 (Qerror, vformat_string (m, ap)); } /* Dump an error message; called like printf. */ void error (const char *m, ...) { va_list ap; va_start (ap, m); verror (m, ap); } DEFUN ("commandp", Fcommandp, Scommandp, 1, 2, 0, doc: /* Non-nil if FUNCTION makes provisions for interactive calling. This means it contains a description for how to read arguments to give it. The value is nil for an invalid function or a symbol with no function definition. Interactively callable functions include strings and vectors (treated as keyboard macros), lambda-expressions that contain a top-level call to `interactive', autoload definitions made by `autoload' with non-nil fourth argument, and some of the built-in functions of Lisp. Also, a symbol satisfies `commandp' if its function definition does so. If the optional argument FOR-CALL-INTERACTIVELY is non-nil, then strings and vectors are not accepted. */) (Lisp_Object function, Lisp_Object for_call_interactively) { register Lisp_Object fun; register Lisp_Object funcar; Lisp_Object if_prop = Qnil; fun = function; fun = indirect_function (fun); /* Check cycles. */ if (NILP (fun)) return Qnil; /* Check an `interactive-form' property if present, analogous to the function-documentation property. */ fun = function; while (SYMBOLP (fun)) { Lisp_Object tmp = Fget (fun, Qinteractive_form); if (!NILP (tmp)) if_prop = Qt; fun = Fsymbol_function (fun); } /* Emacs primitives are interactive if their DEFUN specifies an interactive spec. */ if (SUBRP (fun)) return XSUBR (fun)->intspec ? Qt : if_prop; /* Bytecode objects are interactive if they are long enough to have an element whose index is COMPILED_INTERACTIVE, which is where the interactive spec is stored. */ else if (COMPILEDP (fun)) return (PVSIZE (fun) > COMPILED_INTERACTIVE ? Qt : if_prop); #ifdef HAVE_MODULES /* Module functions are interactive if their `interactive_form' field is non-nil. */ else if (MODULE_FUNCTIONP (fun)) return NILP (module_function_interactive_form (XMODULE_FUNCTION (fun))) ? if_prop : Qt; #endif /* Strings and vectors are keyboard macros. */ if (STRINGP (fun) || VECTORP (fun)) return (NILP (for_call_interactively) ? Qt : Qnil); /* Lists may represent commands. */ if (!CONSP (fun)) return Qnil; funcar = XCAR (fun); if (EQ (funcar, Qclosure)) return (!NILP (Fassq (Qinteractive, Fcdr (Fcdr (XCDR (fun))))) ? Qt : if_prop); else if (EQ (funcar, Qlambda)) return !NILP (Fassq (Qinteractive, Fcdr (XCDR (fun)))) ? Qt : if_prop; else if (EQ (funcar, Qautoload)) return !NILP (Fcar (Fcdr (Fcdr (XCDR (fun))))) ? Qt : if_prop; else return Qnil; } DEFUN ("autoload", Fautoload, Sautoload, 2, 5, 0, doc: /* Define FUNCTION to autoload from FILE. FUNCTION is a symbol; FILE is a file name string to pass to `load'. Third arg DOCSTRING is documentation for the function. Fourth arg INTERACTIVE if non-nil says function can be called interactively. Fifth arg TYPE indicates the type of the object: nil or omitted says FUNCTION is a function, `keymap' says FUNCTION is really a keymap, and `macro' or t says FUNCTION is really a macro. Third through fifth args give info about the real definition. They default to nil. If FUNCTION is already defined other than as an autoload, this does nothing and returns nil. */) (Lisp_Object function, Lisp_Object file, Lisp_Object docstring, Lisp_Object interactive, Lisp_Object type) { CHECK_SYMBOL (function); CHECK_STRING (file); /* If function is defined and not as an autoload, don't override. */ if (!NILP (XSYMBOL (function)->u.s.function) && !AUTOLOADP (XSYMBOL (function)->u.s.function)) return Qnil; if (!NILP (Vpurify_flag) && EQ (docstring, make_fixnum (0))) /* `read1' in lread.c has found the docstring starting with "\ and assumed the docstring will be provided by Snarf-documentation, so it passed us 0 instead. But that leads to accidental sharing in purecopy's hash-consing, so we use a (hopefully) unique integer instead. */ docstring = make_ufixnum (XHASH (function)); return Fdefalias (function, list5 (Qautoload, file, docstring, interactive, type), Qnil); } void un_autoload (Lisp_Object oldqueue) { Lisp_Object queue, first, second; /* Queue to unwind is current value of Vautoload_queue. oldqueue is the shadowed value to leave in Vautoload_queue. */ queue = Vautoload_queue; Vautoload_queue = oldqueue; while (CONSP (queue)) { first = XCAR (queue); second = Fcdr (first); first = Fcar (first); if (EQ (first, make_fixnum (0))) Vfeatures = second; else Ffset (first, second); queue = XCDR (queue); } } /* Load an autoloaded function. FUNNAME is the symbol which is the function's name. FUNDEF is the autoload definition (a list). */ DEFUN ("autoload-do-load", Fautoload_do_load, Sautoload_do_load, 1, 3, 0, doc: /* Load FUNDEF which should be an autoload. If non-nil, FUNNAME should be the symbol whose function value is FUNDEF, in which case the function returns the new autoloaded function value. If equal to `macro', MACRO-ONLY specifies that FUNDEF should only be loaded if it defines a macro. */) (Lisp_Object fundef, Lisp_Object funname, Lisp_Object macro_only) { ptrdiff_t count = SPECPDL_INDEX (); if (!CONSP (fundef) || !EQ (Qautoload, XCAR (fundef))) return fundef; Lisp_Object kind = Fnth (make_fixnum (4), fundef); if (EQ (macro_only, Qmacro) && !(EQ (kind, Qt) || EQ (kind, Qmacro))) return fundef; /* This is to make sure that loadup.el gives a clear picture of what files are preloaded and when. */ if (will_dump_p () && !will_bootstrap_p ()) error ("Attempt to autoload %s while preparing to dump", SDATA (SYMBOL_NAME (funname))); CHECK_SYMBOL (funname); /* If autoloading gets an error (which includes the error of failing to define the function being called), we use Vautoload_queue to undo function definitions and `provide' calls made by the function. We do this in the specific case of autoloading because autoloading is not an explicit request "load this file", but rather a request to "call this function". The value saved here is to be restored into Vautoload_queue. */ record_unwind_protect (un_autoload, Vautoload_queue); Vautoload_queue = Qt; /* If `macro_only' is set and fundef isn't a macro, assume this autoload to be a "best-effort" (e.g. to try and find a compiler macro), so don't signal an error if autoloading fails. */ Lisp_Object ignore_errors = (EQ (kind, Qt) || EQ (kind, Qmacro)) ? Qnil : macro_only; save_match_data_load (Fcar (Fcdr (fundef)), ignore_errors, Qt, Qnil, Qt); /* Once loading finishes, don't undo it. */ Vautoload_queue = Qt; unbind_to (count, Qnil); if (NILP (funname) || !NILP (ignore_errors)) return Qnil; else { Lisp_Object fun = Findirect_function (funname, Qnil); if (!NILP (Fequal (fun, fundef))) error ("Autoloading file %s failed to define function %s", SDATA (Fcar (Fcar (Vload_history))), SDATA (SYMBOL_NAME (funname))); else return fun; } } DEFUN ("eval", Feval, Seval, 1, 2, 0, doc: /* Evaluate FORM and return its value. If LEXICAL is t, evaluate using lexical scoping. LEXICAL can also be an actual lexical environment, in the form of an alist mapping symbols to their value. */) (Lisp_Object form, Lisp_Object lexical) { ptrdiff_t count = SPECPDL_INDEX (); specbind (Qinternal_interpreter_environment, CONSP (lexical) || NILP (lexical) ? lexical : list1 (Qt)); return unbind_to (count, eval_sub (form)); } /* Grow the specpdl stack by one entry. The caller should have already initialized the entry. Signal an error on stack overflow. Make sure that there is always one unused entry past the top of the stack, so that the just-initialized entry is safely unwound if memory exhausted and an error is signaled here. Also, allocate a never-used entry just before the bottom of the stack; sometimes its address is taken. */ static void grow_specpdl (void) { specpdl_ptr++; if (specpdl_ptr == specpdl + specpdl_size) { ptrdiff_t count = SPECPDL_INDEX (); ptrdiff_t max_size = min (max_specpdl_size, PTRDIFF_MAX - 1000); union specbinding *pdlvec = specpdl - 1; ptrdiff_t pdlvecsize = specpdl_size + 1; if (max_size <= specpdl_size) { if (max_specpdl_size < 400) max_size = max_specpdl_size = 400; if (max_size <= specpdl_size) signal_error ("Variable binding depth exceeds max-specpdl-size", Qnil); } pdlvec = xpalloc (pdlvec, &pdlvecsize, 1, max_size + 1, sizeof *specpdl); specpdl = pdlvec + 1; specpdl_size = pdlvecsize - 1; specpdl_ptr = specpdl + count; } } ptrdiff_t record_in_backtrace (Lisp_Object function, Lisp_Object *args, ptrdiff_t nargs) { ptrdiff_t count = SPECPDL_INDEX (); eassert (nargs >= UNEVALLED); specpdl_ptr->bt.kind = SPECPDL_BACKTRACE; specpdl_ptr->bt.debug_on_exit = false; specpdl_ptr->bt.function = function; current_thread->stack_top = specpdl_ptr->bt.args = args; specpdl_ptr->bt.nargs = nargs; grow_specpdl (); return count; } /* Eval a sub-expression of the current expression (i.e. in the same lexical scope). */ Lisp_Object eval_sub (Lisp_Object form) { if (SYMBOLP (form)) { /* Look up its binding in the lexical environment. We do not pay attention to the declared_special flag here, since we already did that when let-binding the variable. */ Lisp_Object lex_binding = (!NILP (Vinternal_interpreter_environment) /* Mere optimization! */ ? Fassq (form, Vinternal_interpreter_environment) : Qnil); return !NILP (lex_binding) ? XCDR (lex_binding) : Fsymbol_value (form); } if (!CONSP (form)) return form; maybe_quit (); maybe_gc (); 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'"); } Lisp_Object original_fun = XCAR (form); Lisp_Object original_args = XCDR (form); CHECK_LIST (original_args); /* This also protects them from gc. */ ptrdiff_t count = record_in_backtrace (original_fun, &original_args, UNEVALLED); if (debug_on_next_call) do_debug_on_call (Qt, count); Lisp_Object fun, val, funcar; /* Declare here, as this array may be accessed by call_debugger near the end of this function. See Bug#21245. */ Lisp_Object argvals[8]; retry: /* Optimize for no indirection. */ fun = original_fun; if (!SYMBOLP (fun)) fun = Ffunction (list1 (fun)); else if (!NILP (fun) && (fun = XSYMBOL (fun)->u.s.function, SYMBOLP (fun))) fun = indirect_function (fun); if (SUBRP (fun)) { Lisp_Object args_left = original_args; ptrdiff_t numargs = list_length (args_left); if (numargs < XSUBR (fun)->min_args || (XSUBR (fun)->max_args >= 0 && XSUBR (fun)->max_args < numargs)) xsignal2 (Qwrong_number_of_arguments, original_fun, make_fixnum (numargs)); else if (XSUBR (fun)->max_args == UNEVALLED) val = (XSUBR (fun)->function.aUNEVALLED) (args_left); else if (XSUBR (fun)->max_args == MANY) { /* Pass a vector of evaluated arguments. */ Lisp_Object *vals; ptrdiff_t argnum = 0; USE_SAFE_ALLOCA; SAFE_ALLOCA_LISP (vals, numargs); while (CONSP (args_left) && argnum < numargs) { Lisp_Object arg = XCAR (args_left); args_left = XCDR (args_left); vals[argnum++] = eval_sub (arg); } set_backtrace_args (specpdl + count, vals, argnum); val = XSUBR (fun)->function.aMANY (argnum, vals); lisp_eval_depth--; /* Do the debug-on-exit now, while VALS still exists. */ if (backtrace_debug_on_exit (specpdl + count)) val = call_debugger (list2 (Qexit, val)); SAFE_FREE (); specpdl_ptr--; return val; } else { int i, maxargs = XSUBR (fun)->max_args; for (i = 0; i < maxargs; i++) { argvals[i] = eval_sub (Fcar (args_left)); args_left = Fcdr (args_left); } set_backtrace_args (specpdl + count, argvals, numargs); switch (i) { case 0: val = (XSUBR (fun)->function.a0 ()); break; case 1: val = (XSUBR (fun)->function.a1 (argvals[0])); break; case 2: val = (XSUBR (fun)->function.a2 (argvals[0], argvals[1])); break; case 3: val = (XSUBR (fun)->function.a3 (argvals[0], argvals[1], argvals[2])); break; case 4: val = (XSUBR (fun)->function.a4 (argvals[0], argvals[1], argvals[2], argvals[3])); break; case 5: val = (XSUBR (fun)->function.a5 (argvals[0], argvals[1], argvals[2], argvals[3], argvals[4])); break; case 6: val = (XSUBR (fun)->function.a6 (argvals[0], argvals[1], argvals[2], argvals[3], argvals[4], argvals[5])); break; case 7: val = (XSUBR (fun)->function.a7 (argvals[0], argvals[1], argvals[2], argvals[3], argvals[4], argvals[5], argvals[6])); break; case 8: val = (XSUBR (fun)->function.a8 (argvals[0], argvals[1], argvals[2], argvals[3], argvals[4], argvals[5], argvals[6], argvals[7])); break; default: /* Someone has created a subr that takes more arguments than is supported by this code. We need to either rewrite the subr to use a different argument protocol, or add more cases to this switch. */ emacs_abort (); } } } else if (COMPILEDP (fun) || MODULE_FUNCTIONP (fun)) return apply_lambda (fun, original_args, count); else { if (NILP (fun)) xsignal1 (Qvoid_function, original_fun); if (!CONSP (fun)) xsignal1 (Qinvalid_function, original_fun); funcar = XCAR (fun); if (!SYMBOLP (funcar)) xsignal1 (Qinvalid_function, original_fun); if (EQ (funcar, Qautoload)) { Fautoload_do_load (fun, original_fun, Qnil); goto retry; } if (EQ (funcar, Qmacro)) { ptrdiff_t count1 = SPECPDL_INDEX (); Lisp_Object exp; /* Bind lexical-binding during expansion of the macro, so the macro can know reliably if the code it outputs will be interpreted using lexical-binding or not. */ specbind (Qlexical_binding, NILP (Vinternal_interpreter_environment) ? Qnil : Qt); exp = apply1 (Fcdr (fun), original_args); exp = unbind_to (count1, exp); val = eval_sub (exp); } else if (EQ (funcar, Qlambda) || EQ (funcar, Qclosure)) return apply_lambda (fun, original_args, count); else xsignal1 (Qinvalid_function, original_fun); } lisp_eval_depth--; if (backtrace_debug_on_exit (specpdl + count)) val = call_debugger (list2 (Qexit, val)); specpdl_ptr--; return val; } DEFUN ("apply", Fapply, Sapply, 1, MANY, 0, doc: /* Call FUNCTION with our remaining args, using our last arg as list of args. Then return the value FUNCTION returns. With a single argument, call the argument's first element using the other elements as args. Thus, (apply \\='+ 1 2 \\='(3 4)) returns 10. usage: (apply FUNCTION &rest ARGUMENTS) */) (ptrdiff_t nargs, Lisp_Object *args) { ptrdiff_t i, funcall_nargs; Lisp_Object *funcall_args = NULL; Lisp_Object spread_arg = args[nargs - 1]; Lisp_Object fun = args[0]; USE_SAFE_ALLOCA; ptrdiff_t numargs = list_length (spread_arg); if (numargs == 0) return Ffuncall (max (1, nargs - 1), args); else if (numargs == 1) { args [nargs - 1] = XCAR (spread_arg); return Ffuncall (nargs, args); } numargs += nargs - 2; /* Optimize for no indirection. */ if (SYMBOLP (fun) && !NILP (fun) && (fun = XSYMBOL (fun)->u.s.function, SYMBOLP (fun))) { fun = indirect_function (fun); if (NILP (fun)) /* Let funcall get the error. */ fun = args[0]; } if (SUBRP (fun) && XSUBR (fun)->max_args > numargs /* Don't hide an error by adding missing arguments. */ && numargs >= XSUBR (fun)->min_args) { /* Avoid making funcall cons up a yet another new vector of arguments by explicitly supplying nil's for optional values. */ SAFE_ALLOCA_LISP (funcall_args, 1 + XSUBR (fun)->max_args); memclear (funcall_args + numargs + 1, (XSUBR (fun)->max_args - numargs) * word_size); funcall_nargs = 1 + XSUBR (fun)->max_args; } else { /* We add 1 to numargs because funcall_args includes the function itself as well as its arguments. */ SAFE_ALLOCA_LISP (funcall_args, 1 + numargs); funcall_nargs = 1 + numargs; } memcpy (funcall_args, args, nargs * word_size); /* Spread the last arg we got. Its first element goes in the slot that it used to occupy, hence this value of I. */ i = nargs - 1; while (!NILP (spread_arg)) { funcall_args [i++] = XCAR (spread_arg); spread_arg = XCDR (spread_arg); } Lisp_Object retval = Ffuncall (funcall_nargs, funcall_args); SAFE_FREE (); return retval; } /* Run hook variables in various ways. */ static Lisp_Object funcall_nil (ptrdiff_t nargs, Lisp_Object *args) { Ffuncall (nargs, args); return Qnil; } DEFUN ("run-hooks", Frun_hooks, Srun_hooks, 0, MANY, 0, doc: /* Run each hook in HOOKS. Each argument should be a symbol, a hook variable. These symbols are processed in the order specified. If a hook symbol has a non-nil value, that value may be a function or a list of functions to be called to run the hook. If the value is a function, it is called with no arguments. If it is a list, the elements are called, in order, with no arguments. Major modes should not use this function directly to run their mode hook; they should use `run-mode-hooks' instead. Do not use `make-local-variable' to make a hook variable buffer-local. Instead, use `add-hook' and specify t for the LOCAL argument. usage: (run-hooks &rest HOOKS) */) (ptrdiff_t nargs, Lisp_Object *args) { ptrdiff_t i; for (i = 0; i < nargs; i++) run_hook (args[i]); return Qnil; } DEFUN ("run-hook-with-args", Frun_hook_with_args, Srun_hook_with_args, 1, MANY, 0, doc: /* Run HOOK with the specified arguments ARGS. HOOK should be a symbol, a hook variable. The value of HOOK may be nil, a function, or a list of functions. Call each function in order with arguments ARGS. The final return value is unspecified. Do not use `make-local-variable' to make a hook variable buffer-local. Instead, use `add-hook' and specify t for the LOCAL argument. usage: (run-hook-with-args HOOK &rest ARGS) */) (ptrdiff_t nargs, Lisp_Object *args) { return run_hook_with_args (nargs, args, funcall_nil); } /* NB this one still documents a specific non-nil return value. (As did run-hook-with-args and run-hook-with-args-until-failure until they were changed in 24.1.) */ DEFUN ("run-hook-with-args-until-success", Frun_hook_with_args_until_success, Srun_hook_with_args_until_success, 1, MANY, 0, doc: /* Run HOOK with the specified arguments ARGS. HOOK should be a symbol, a hook variable. The value of HOOK may be nil, a function, or a list of functions. Call each function in order with arguments ARGS, stopping at the first one that returns non-nil, and return that value. Otherwise (if all functions return nil, or if there are no functions to call), return nil. Do not use `make-local-variable' to make a hook variable buffer-local. Instead, use `add-hook' and specify t for the LOCAL argument. usage: (run-hook-with-args-until-success HOOK &rest ARGS) */) (ptrdiff_t nargs, Lisp_Object *args) { return run_hook_with_args (nargs, args, Ffuncall); } static Lisp_Object funcall_not (ptrdiff_t nargs, Lisp_Object *args) { return NILP (Ffuncall (nargs, args)) ? Qt : Qnil; } DEFUN ("run-hook-with-args-until-failure", Frun_hook_with_args_until_failure, Srun_hook_with_args_until_failure, 1, MANY, 0, doc: /* Run HOOK with the specified arguments ARGS. HOOK should be a symbol, a hook variable. The value of HOOK may be nil, a function, or a list of functions. Call each function in order with arguments ARGS, stopping at the first one that returns nil, and return nil. Otherwise (if all functions return non-nil, or if there are no functions to call), return non-nil \(do not rely on the precise return value in this case). Do not use `make-local-variable' to make a hook variable buffer-local. Instead, use `add-hook' and specify t for the LOCAL argument. usage: (run-hook-with-args-until-failure HOOK &rest ARGS) */) (ptrdiff_t nargs, Lisp_Object *args) { return NILP (run_hook_with_args (nargs, args, funcall_not)) ? Qt : Qnil; } static Lisp_Object run_hook_wrapped_funcall (ptrdiff_t nargs, Lisp_Object *args) { Lisp_Object tmp = args[0], ret; args[0] = args[1]; args[1] = tmp; ret = Ffuncall (nargs, args); args[1] = args[0]; args[0] = tmp; return ret; } DEFUN ("run-hook-wrapped", Frun_hook_wrapped, Srun_hook_wrapped, 2, MANY, 0, doc: /* Run HOOK, passing each function through WRAP-FUNCTION. I.e. instead of calling each function FUN directly with arguments ARGS, it calls WRAP-FUNCTION with arguments FUN and ARGS. As soon as a call to WRAP-FUNCTION returns non-nil, `run-hook-wrapped' aborts and returns that value. usage: (run-hook-wrapped HOOK WRAP-FUNCTION &rest ARGS) */) (ptrdiff_t nargs, Lisp_Object *args) { return run_hook_with_args (nargs, args, run_hook_wrapped_funcall); } /* ARGS[0] should be a hook symbol. Call each of the functions in the hook value, passing each of them as arguments all the rest of ARGS (all NARGS - 1 elements). FUNCALL specifies how to call each function on the hook. */ Lisp_Object run_hook_with_args (ptrdiff_t nargs, Lisp_Object *args, Lisp_Object (*funcall) (ptrdiff_t nargs, Lisp_Object *args)) { Lisp_Object sym, val, ret = Qnil; /* If we are dying or still initializing, don't do anything--it would probably crash if we tried. */ if (NILP (Vrun_hooks)) return Qnil; sym = args[0]; val = find_symbol_value (sym); if (EQ (val, Qunbound) || NILP (val)) return ret; else if (!CONSP (val) || FUNCTIONP (val)) { args[0] = val; return funcall (nargs, args); } else { Lisp_Object global_vals = Qnil; for (; CONSP (val) && NILP (ret); val = XCDR (val)) { if (EQ (XCAR (val), Qt)) { /* t indicates this hook has a local binding; it means to run the global binding too. */ global_vals = Fdefault_value (sym); if (NILP (global_vals)) continue; if (!CONSP (global_vals) || EQ (XCAR (global_vals), Qlambda)) { args[0] = global_vals; ret = funcall (nargs, args); } else { for (; CONSP (global_vals) && NILP (ret); global_vals = XCDR (global_vals)) { args[0] = XCAR (global_vals); /* In a global value, t should not occur. If it does, we must ignore it to avoid an endless loop. */ if (!EQ (args[0], Qt)) ret = funcall (nargs, args); } } } else { args[0] = XCAR (val); ret = funcall (nargs, args); } } return ret; } } /* Run the hook HOOK, giving each function no args. */ void run_hook (Lisp_Object hook) { Frun_hook_with_args (1, &hook); } /* Run the hook HOOK, giving each function the two args ARG1 and ARG2. */ void run_hook_with_args_2 (Lisp_Object hook, Lisp_Object arg1, Lisp_Object arg2) { CALLN (Frun_hook_with_args, hook, arg1, arg2); } /* Apply fn to arg. */ Lisp_Object apply1 (Lisp_Object fn, Lisp_Object arg) { return NILP (arg) ? Ffuncall (1, &fn) : CALLN (Fapply, fn, arg); } /* Call function fn on no arguments. */ Lisp_Object call0 (Lisp_Object fn) { return Ffuncall (1, &fn); } /* Call function fn with 1 argument arg1. */ Lisp_Object call1 (Lisp_Object fn, Lisp_Object arg1) { return CALLN (Ffuncall, fn, arg1); } /* Call function fn with 2 arguments arg1, arg2. */ Lisp_Object call2 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2) { return CALLN (Ffuncall, fn, arg1, arg2); } /* Call function fn with 3 arguments arg1, arg2, arg3. */ Lisp_Object call3 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3) { return CALLN (Ffuncall, fn, arg1, arg2, arg3); } /* Call function fn with 4 arguments arg1, arg2, arg3, arg4. */ Lisp_Object call4 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3, Lisp_Object arg4) { return CALLN (Ffuncall, fn, arg1, arg2, arg3, arg4); } /* Call function fn with 5 arguments arg1, arg2, arg3, arg4, arg5. */ Lisp_Object call5 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3, Lisp_Object arg4, Lisp_Object arg5) { return CALLN (Ffuncall, fn, arg1, arg2, arg3, arg4, arg5); } /* Call function fn with 6 arguments arg1, arg2, arg3, arg4, arg5, arg6. */ Lisp_Object call6 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3, Lisp_Object arg4, Lisp_Object arg5, Lisp_Object arg6) { return CALLN (Ffuncall, fn, arg1, arg2, arg3, arg4, arg5, arg6); } /* Call function fn with 7 arguments arg1, arg2, arg3, arg4, arg5, arg6, arg7. */ Lisp_Object call7 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3, Lisp_Object arg4, Lisp_Object arg5, Lisp_Object arg6, Lisp_Object arg7) { return CALLN (Ffuncall, fn, arg1, arg2, arg3, arg4, arg5, arg6, arg7); } /* Call function fn with 8 arguments arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8. */ Lisp_Object call8 (Lisp_Object fn, Lisp_Object arg1, Lisp_Object arg2, Lisp_Object arg3, Lisp_Object arg4, Lisp_Object arg5, Lisp_Object arg6, Lisp_Object arg7, Lisp_Object arg8) { return CALLN (Ffuncall, fn, arg1, arg2, arg3, arg4, arg5, arg6, arg7, arg8); } DEFUN ("functionp", Ffunctionp, Sfunctionp, 1, 1, 0, doc: /* Return t if OBJECT is a function. */) (Lisp_Object object) { if (FUNCTIONP (object)) return Qt; return Qnil; } bool FUNCTIONP (Lisp_Object object) { if (SYMBOLP (object) && !NILP (Ffboundp (object))) { object = Findirect_function (object, Qt); if (CONSP (object) && EQ (XCAR (object), Qautoload)) { /* Autoloaded symbols are functions, except if they load macros or keymaps. */ for (int i = 0; i < 4 && CONSP (object); i++) object = XCDR (object); return ! (CONSP (object) && !NILP (XCAR (object))); } } if (SUBRP (object)) return XSUBR (object)->max_args != UNEVALLED; else if (COMPILEDP (object) || MODULE_FUNCTIONP (object)) return true; else if (CONSP (object)) { Lisp_Object car = XCAR (object); return EQ (car, Qlambda) || EQ (car, Qclosure); } else return false; } DEFUN ("funcall", Ffuncall, Sfuncall, 1, MANY, 0, doc: /* Call first argument as a function, passing remaining arguments to it. Return the value that function returns. Thus, (funcall \\='cons \\='x \\='y) returns (x . y). usage: (funcall FUNCTION &rest ARGUMENTS) */) (ptrdiff_t nargs, Lisp_Object *args) { Lisp_Object fun, original_fun; Lisp_Object funcar; ptrdiff_t numargs = nargs - 1; Lisp_Object val; ptrdiff_t count; maybe_quit (); 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'"); } count = record_in_backtrace (args[0], &args[1], nargs - 1); maybe_gc (); if (debug_on_next_call) do_debug_on_call (Qlambda, count); original_fun = args[0]; retry: /* Optimize for no indirection. */ fun = original_fun; if (SYMBOLP (fun) && !NILP (fun) && (fun = XSYMBOL (fun)->u.s.function, SYMBOLP (fun))) fun = indirect_function (fun); if (SUBRP (fun)) val = funcall_subr (XSUBR (fun), numargs, args + 1); else if (COMPILEDP (fun) || MODULE_FUNCTIONP (fun)) val = funcall_lambda (fun, numargs, args + 1); else { if (NILP (fun)) xsignal1 (Qvoid_function, original_fun); if (!CONSP (fun)) xsignal1 (Qinvalid_function, original_fun); funcar = XCAR (fun); if (!SYMBOLP (funcar)) xsignal1 (Qinvalid_function, original_fun); if (EQ (funcar, Qlambda) || EQ (funcar, Qclosure)) val = funcall_lambda (fun, numargs, args + 1); else if (EQ (funcar, Qautoload)) { Fautoload_do_load (fun, original_fun, Qnil); goto retry; } else xsignal1 (Qinvalid_function, original_fun); } lisp_eval_depth--; if (backtrace_debug_on_exit (specpdl + count)) val = call_debugger (list2 (Qexit, val)); specpdl_ptr--; return val; } /* Apply a C subroutine SUBR to the NUMARGS evaluated arguments in ARG_VECTOR and return the result of evaluation. */ Lisp_Object funcall_subr (struct Lisp_Subr *subr, ptrdiff_t numargs, Lisp_Object *args) { if (numargs < subr->min_args || (subr->max_args >= 0 && subr->max_args < numargs)) { Lisp_Object fun; XSETSUBR (fun, subr); xsignal2 (Qwrong_number_of_arguments, fun, make_fixnum (numargs)); } else if (subr->max_args == UNEVALLED) { Lisp_Object fun; XSETSUBR (fun, subr); xsignal1 (Qinvalid_function, fun); } else if (subr->max_args == MANY) return (subr->function.aMANY) (numargs, args); else { Lisp_Object internal_argbuf[8]; Lisp_Object *internal_args; if (subr->max_args > numargs) { eassert (subr->max_args <= ARRAYELTS (internal_argbuf)); internal_args = internal_argbuf; memcpy (internal_args, args, numargs * word_size); memclear (internal_args + numargs, (subr->max_args - numargs) * word_size); } else internal_args = args; switch (subr->max_args) { case 0: return (subr->function.a0 ()); case 1: return (subr->function.a1 (internal_args[0])); case 2: return (subr->function.a2 (internal_args[0], internal_args[1])); case 3: return (subr->function.a3 (internal_args[0], internal_args[1], internal_args[2])); case 4: return (subr->function.a4 (internal_args[0], internal_args[1], internal_args[2], internal_args[3])); case 5: return (subr->function.a5 (internal_args[0], internal_args[1], internal_args[2], internal_args[3], internal_args[4])); case 6: return (subr->function.a6 (internal_args[0], internal_args[1], internal_args[2], internal_args[3], internal_args[4], internal_args[5])); case 7: return (subr->function.a7 (internal_args[0], internal_args[1], internal_args[2], internal_args[3], internal_args[4], internal_args[5], internal_args[6])); case 8: return (subr->function.a8 (internal_args[0], internal_args[1], internal_args[2], internal_args[3], internal_args[4], internal_args[5], internal_args[6], internal_args[7])); default: /* If a subr takes more than 8 arguments without using MANY or UNEVALLED, we need to extend this function to support it. Until this is done, there is no way to call the function. */ emacs_abort (); } } } /* Call the compiled Lisp function FUN. If we have not yet read FUN's bytecode string and constants vector, fetch them from the file first. */ static Lisp_Object fetch_and_exec_byte_code (Lisp_Object fun, Lisp_Object syms_left, ptrdiff_t nargs, Lisp_Object *args) { if (CONSP (AREF (fun, COMPILED_BYTECODE))) Ffetch_bytecode (fun); return exec_byte_code (AREF (fun, COMPILED_BYTECODE), AREF (fun, COMPILED_CONSTANTS), AREF (fun, COMPILED_STACK_DEPTH), syms_left, nargs, args); } static Lisp_Object apply_lambda (Lisp_Object fun, Lisp_Object args, ptrdiff_t count) { Lisp_Object *arg_vector; Lisp_Object tem; USE_SAFE_ALLOCA; ptrdiff_t numargs = list_length (args); SAFE_ALLOCA_LISP (arg_vector, numargs); Lisp_Object args_left = args; for (ptrdiff_t i = 0; i < numargs; i++) { tem = Fcar (args_left), args_left = Fcdr (args_left); tem = eval_sub (tem); arg_vector[i] = tem; } set_backtrace_args (specpdl + count, arg_vector, numargs); tem = funcall_lambda (fun, numargs, arg_vector); lisp_eval_depth--; /* Do the debug-on-exit now, while arg_vector still exists. */ if (backtrace_debug_on_exit (specpdl + count)) tem = call_debugger (list2 (Qexit, tem)); SAFE_FREE (); specpdl_ptr--; return tem; } /* Apply a Lisp function FUN to the NARGS evaluated arguments in ARG_VECTOR and return the result of evaluation. FUN must be either a lambda-expression, a compiled-code object, or a module function. */ static Lisp_Object funcall_lambda (Lisp_Object fun, ptrdiff_t nargs, register Lisp_Object *arg_vector) { Lisp_Object val, syms_left, next, lexenv; ptrdiff_t count = SPECPDL_INDEX (); ptrdiff_t i; bool optional, rest; if (CONSP (fun)) { if (EQ (XCAR (fun), Qclosure)) { Lisp_Object cdr = XCDR (fun); /* Drop `closure'. */ if (! CONSP (cdr)) xsignal1 (Qinvalid_function, fun); fun = cdr; lexenv = XCAR (fun); } else lexenv = Qnil; syms_left = XCDR (fun); if (CONSP (syms_left)) syms_left = XCAR (syms_left); else xsignal1 (Qinvalid_function, fun); } else if (COMPILEDP (fun)) { syms_left = AREF (fun, COMPILED_ARGLIST); if (FIXNUMP (syms_left)) /* A byte-code object with an integer args template means we shouldn't bind any arguments, instead just call the byte-code interpreter directly; it will push arguments as necessary. Byte-code objects with a nil args template (the default) have dynamically-bound arguments, and use the argument-binding code below instead (as do all interpreted functions, even lexically bound ones). */ { return fetch_and_exec_byte_code (fun, syms_left, nargs, arg_vector); } lexenv = Qnil; } #ifdef HAVE_MODULES else if (MODULE_FUNCTIONP (fun)) return funcall_module (fun, nargs, arg_vector); #endif else emacs_abort (); i = optional = rest = 0; for (; CONSP (syms_left); syms_left = XCDR (syms_left)) { maybe_quit (); next = XCAR (syms_left); if (!SYMBOLP (next)) xsignal1 (Qinvalid_function, fun); if (EQ (next, Qand_rest)) { if (rest) xsignal1 (Qinvalid_function, fun); rest = 1; } else if (EQ (next, Qand_optional)) { if (optional || rest) xsignal1 (Qinvalid_function, fun); optional = 1; } else { Lisp_Object arg; if (rest) { arg = Flist (nargs - i, &arg_vector[i]); i = nargs; } else if (i < nargs) arg = arg_vector[i++]; else if (!optional) xsignal2 (Qwrong_number_of_arguments, fun, make_fixnum (nargs)); else arg = Qnil; /* Bind the argument. */ if (!NILP (lexenv) && SYMBOLP (next)) /* Lexically bind NEXT by adding it to the lexenv alist. */ lexenv = Fcons (Fcons (next, arg), lexenv); else /* Dynamically bind NEXT. */ specbind (next, arg); } } if (!NILP (syms_left)) xsignal1 (Qinvalid_function, fun); else if (i < nargs) xsignal2 (Qwrong_number_of_arguments, fun, make_fixnum (nargs)); if (!EQ (lexenv, Vinternal_interpreter_environment)) /* Instantiate a new lexical environment. */ specbind (Qinternal_interpreter_environment, lexenv); if (CONSP (fun)) val = Fprogn (XCDR (XCDR (fun))); else val = fetch_and_exec_byte_code (fun, Qnil, 0, NULL); return unbind_to (count, val); } DEFUN ("func-arity", Ffunc_arity, Sfunc_arity, 1, 1, 0, doc: /* Return minimum and maximum number of args allowed for FUNCTION. FUNCTION must be a function of some kind. The returned value is a cons cell (MIN . MAX). MIN is the minimum number of args. MAX is the maximum number, or the symbol `many', for a function with `&rest' args, or `unevalled' for a special form. */) (Lisp_Object function) { Lisp_Object original; Lisp_Object funcar; Lisp_Object result; original = function; retry: /* Optimize for no indirection. */ function = original; if (SYMBOLP (function) && !NILP (function)) { function = XSYMBOL (function)->u.s.function; if (SYMBOLP (function)) function = indirect_function (function); } if (CONSP (function) && EQ (XCAR (function), Qmacro)) function = XCDR (function); if (SUBRP (function)) result = Fsubr_arity (function); else if (COMPILEDP (function)) result = lambda_arity (function); #ifdef HAVE_MODULES else if (MODULE_FUNCTIONP (function)) result = module_function_arity (XMODULE_FUNCTION (function)); #endif else { if (NILP (function)) xsignal1 (Qvoid_function, original); if (!CONSP (function)) xsignal1 (Qinvalid_function, original); funcar = XCAR (function); if (!SYMBOLP (funcar)) xsignal1 (Qinvalid_function, original); if (EQ (funcar, Qlambda) || EQ (funcar, Qclosure)) result = lambda_arity (function); else if (EQ (funcar, Qautoload)) { Fautoload_do_load (function, original, Qnil); goto retry; } else xsignal1 (Qinvalid_function, original); } return result; } /* FUN must be either a lambda-expression or a compiled-code object. */ static Lisp_Object lambda_arity (Lisp_Object fun) { Lisp_Object syms_left; if (CONSP (fun)) { if (EQ (XCAR (fun), Qclosure)) { fun = XCDR (fun); /* Drop `closure'. */ CHECK_CONS (fun); } syms_left = XCDR (fun); if (CONSP (syms_left)) syms_left = XCAR (syms_left); else xsignal1 (Qinvalid_function, fun); } else if (COMPILEDP (fun)) { syms_left = AREF (fun, COMPILED_ARGLIST); if (FIXNUMP (syms_left)) return get_byte_code_arity (syms_left); } else emacs_abort (); EMACS_INT minargs = 0, maxargs = 0; bool optional = false; for (; CONSP (syms_left); syms_left = XCDR (syms_left)) { Lisp_Object next = XCAR (syms_left); if (!SYMBOLP (next)) xsignal1 (Qinvalid_function, fun); if (EQ (next, Qand_rest)) return Fcons (make_fixnum (minargs), Qmany); else if (EQ (next, Qand_optional)) optional = true; else { if (!optional) minargs++; maxargs++; } } if (!NILP (syms_left)) xsignal1 (Qinvalid_function, fun); return Fcons (make_fixnum (minargs), make_fixnum (maxargs)); } DEFUN ("fetch-bytecode", Ffetch_bytecode, Sfetch_bytecode, 1, 1, 0, doc: /* If byte-compiled OBJECT is lazy-loaded, fetch it now. */) (Lisp_Object object) { Lisp_Object tem; if (COMPILEDP (object)) { if (CONSP (AREF (object, COMPILED_BYTECODE))) { tem = read_doc_string (AREF (object, COMPILED_BYTECODE)); if (! (CONSP (tem) && STRINGP (XCAR (tem)) && VECTORP (XCDR (tem)))) { tem = AREF (object, COMPILED_BYTECODE); if (CONSP (tem) && STRINGP (XCAR (tem))) error ("Invalid byte code in %s", SDATA (XCAR (tem))); else error ("Invalid byte code"); } Lisp_Object bytecode = XCAR (tem); if (STRING_MULTIBYTE (bytecode)) { /* BYTECODE must have been produced by Emacs 20.2 or earlier because it produced a raw 8-bit string for byte-code and now such a byte-code string is loaded as multibyte with raw 8-bit characters converted to multibyte form. Convert them back to the original unibyte form. */ bytecode = Fstring_as_unibyte (bytecode); } ASET (object, COMPILED_BYTECODE, bytecode); ASET (object, COMPILED_CONSTANTS, XCDR (tem)); } } return object; } /* Return true if SYMBOL currently has a let-binding which was made in the buffer that is now current. */ bool let_shadows_buffer_binding_p (struct Lisp_Symbol *symbol) { union specbinding *p; Lisp_Object buf = Fcurrent_buffer (); for (p = specpdl_ptr; p > specpdl; ) if ((--p)->kind > SPECPDL_LET) { struct Lisp_Symbol *let_bound_symbol = XSYMBOL (specpdl_symbol (p)); eassert (let_bound_symbol->u.s.redirect != SYMBOL_VARALIAS); if (symbol == let_bound_symbol && EQ (specpdl_where (p), buf)) return 1; } return 0; } static void do_specbind (struct Lisp_Symbol *sym, union specbinding *bind, Lisp_Object value, enum Set_Internal_Bind bindflag) { switch (sym->u.s.redirect) { case SYMBOL_PLAINVAL: if (!sym->u.s.trapped_write) SET_SYMBOL_VAL (sym, value); else set_internal (specpdl_symbol (bind), value, Qnil, bindflag); break; case SYMBOL_FORWARDED: if (BUFFER_OBJFWDP (SYMBOL_FWD (sym)) && specpdl_kind (bind) == SPECPDL_LET_DEFAULT) { set_default_internal (specpdl_symbol (bind), value, bindflag); return; } FALLTHROUGH; case SYMBOL_LOCALIZED: set_internal (specpdl_symbol (bind), value, Qnil, bindflag); break; default: emacs_abort (); } } /* `specpdl_ptr' describes which variable is let-bound, so it can be properly undone when we unbind_to. It can be either a plain SPECPDL_LET or a SPECPDL_LET_LOCAL/DEFAULT. - SYMBOL is the variable being bound. Note that it should not be aliased (i.e. when let-binding V1 that's aliased to V2, we want to record V2 here). - WHERE tells us in which buffer the binding took place. This is used for SPECPDL_LET_LOCAL bindings (i.e. bindings to a buffer-local variable) as well as for SPECPDL_LET_DEFAULT bindings, i.e. bindings to the default value of a variable which can be buffer-local. */ void specbind (Lisp_Object symbol, Lisp_Object value) { struct Lisp_Symbol *sym; CHECK_SYMBOL (symbol); sym = XSYMBOL (symbol); start: switch (sym->u.s.redirect) { case SYMBOL_VARALIAS: sym = indirect_variable (sym); XSETSYMBOL (symbol, sym); goto start; case SYMBOL_PLAINVAL: /* The most common case is that of a non-constant symbol with a trivial value. Make that as fast as we can. */ specpdl_ptr->let.kind = SPECPDL_LET; specpdl_ptr->let.symbol = symbol; specpdl_ptr->let.old_value = SYMBOL_VAL (sym); specpdl_ptr->let.saved_value = Qnil; grow_specpdl (); do_specbind (sym, specpdl_ptr - 1, value, SET_INTERNAL_BIND); break; case SYMBOL_LOCALIZED: case SYMBOL_FORWARDED: { Lisp_Object ovalue = find_symbol_value (symbol); specpdl_ptr->let.kind = SPECPDL_LET_LOCAL; specpdl_ptr->let.symbol = symbol; specpdl_ptr->let.old_value = ovalue; specpdl_ptr->let.where = Fcurrent_buffer (); specpdl_ptr->let.saved_value = Qnil; eassert (sym->u.s.redirect != SYMBOL_LOCALIZED || (EQ (SYMBOL_BLV (sym)->where, Fcurrent_buffer ()))); if (sym->u.s.redirect == SYMBOL_LOCALIZED) { if (!blv_found (SYMBOL_BLV (sym))) specpdl_ptr->let.kind = SPECPDL_LET_DEFAULT; } else if (BUFFER_OBJFWDP (SYMBOL_FWD (sym))) { /* If SYMBOL is a per-buffer variable which doesn't have a buffer-local value here, make the `let' change the global value by changing the value of SYMBOL in all buffers not having their own value. This is consistent with what happens with other buffer-local variables. */ if (NILP (Flocal_variable_p (symbol, Qnil))) { specpdl_ptr->let.kind = SPECPDL_LET_DEFAULT; grow_specpdl (); do_specbind (sym, specpdl_ptr - 1, value, SET_INTERNAL_BIND); return; } } else specpdl_ptr->let.kind = SPECPDL_LET; grow_specpdl (); do_specbind (sym, specpdl_ptr - 1, value, SET_INTERNAL_BIND); break; } default: emacs_abort (); } } /* Push unwind-protect entries of various types. */ void record_unwind_protect (void (*function) (Lisp_Object), Lisp_Object arg) { specpdl_ptr->unwind.kind = SPECPDL_UNWIND; specpdl_ptr->unwind.func = function; specpdl_ptr->unwind.arg = arg; specpdl_ptr->unwind.eval_depth = lisp_eval_depth; grow_specpdl (); } void record_unwind_protect_array (Lisp_Object *array, ptrdiff_t nelts) { specpdl_ptr->unwind_array.kind = SPECPDL_UNWIND_ARRAY; specpdl_ptr->unwind_array.array = array; specpdl_ptr->unwind_array.nelts = nelts; grow_specpdl (); } void record_unwind_protect_ptr (void (*function) (void *), void *arg) { specpdl_ptr->unwind_ptr.kind = SPECPDL_UNWIND_PTR; specpdl_ptr->unwind_ptr.func = function; specpdl_ptr->unwind_ptr.arg = arg; grow_specpdl (); } void record_unwind_protect_int (void (*function) (int), int arg) { specpdl_ptr->unwind_int.kind = SPECPDL_UNWIND_INT; specpdl_ptr->unwind_int.func = function; specpdl_ptr->unwind_int.arg = arg; grow_specpdl (); } void record_unwind_protect_intmax (void (*function) (intmax_t), intmax_t arg) { specpdl_ptr->unwind_intmax.kind = SPECPDL_UNWIND_INTMAX; specpdl_ptr->unwind_intmax.func = function; specpdl_ptr->unwind_intmax.arg = arg; grow_specpdl (); } void record_unwind_protect_excursion (void) { specpdl_ptr->unwind_excursion.kind = SPECPDL_UNWIND_EXCURSION; save_excursion_save (specpdl_ptr); grow_specpdl (); } void record_unwind_protect_void (void (*function) (void)) { specpdl_ptr->unwind_void.kind = SPECPDL_UNWIND_VOID; specpdl_ptr->unwind_void.func = function; grow_specpdl (); } void record_unwind_protect_module (enum specbind_tag kind, void *ptr) { specpdl_ptr->kind = kind; specpdl_ptr->unwind_ptr.func = NULL; specpdl_ptr->unwind_ptr.arg = ptr; grow_specpdl (); } void rebind_for_thread_switch (void) { union specbinding *bind; for (bind = specpdl; bind != specpdl_ptr; ++bind) { if (bind->kind >= SPECPDL_LET) { Lisp_Object value = specpdl_saved_value (bind); Lisp_Object sym = specpdl_symbol (bind); bind->let.saved_value = Qnil; do_specbind (XSYMBOL (sym), bind, value, SET_INTERNAL_THREAD_SWITCH); } } } static void do_one_unbind (union specbinding *this_binding, bool unwinding, enum Set_Internal_Bind bindflag) { eassert (unwinding || this_binding->kind >= SPECPDL_LET); switch (this_binding->kind) { case SPECPDL_UNWIND: lisp_eval_depth = this_binding->unwind.eval_depth; this_binding->unwind.func (this_binding->unwind.arg); break; case SPECPDL_UNWIND_ARRAY: xfree (this_binding->unwind_array.array); break; case SPECPDL_UNWIND_PTR: this_binding->unwind_ptr.func (this_binding->unwind_ptr.arg); break; case SPECPDL_UNWIND_INT: this_binding->unwind_int.func (this_binding->unwind_int.arg); break; case SPECPDL_UNWIND_INTMAX: this_binding->unwind_intmax.func (this_binding->unwind_intmax.arg); break; case SPECPDL_UNWIND_VOID: this_binding->unwind_void.func (); break; case SPECPDL_UNWIND_EXCURSION: save_excursion_restore (this_binding->unwind_excursion.marker, this_binding->unwind_excursion.window); break; case SPECPDL_BACKTRACE: break; #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: finalize_runtime_unwind (this_binding->unwind_ptr.arg); break; case SPECPDL_MODULE_ENVIRONMENT: finalize_environment_unwind (this_binding->unwind_ptr.arg); break; #endif case SPECPDL_LET: { /* If variable has a trivial value (no forwarding), and isn't trapped, we can just set it. */ Lisp_Object sym = specpdl_symbol (this_binding); if (SYMBOLP (sym) && XSYMBOL (sym)->u.s.redirect == SYMBOL_PLAINVAL) { if (XSYMBOL (sym)->u.s.trapped_write == SYMBOL_UNTRAPPED_WRITE) SET_SYMBOL_VAL (XSYMBOL (sym), specpdl_old_value (this_binding)); else set_internal (sym, specpdl_old_value (this_binding), Qnil, bindflag); break; } } /* Come here only if make_local_foo was used for the first time on this var within this let. */ FALLTHROUGH; case SPECPDL_LET_DEFAULT: set_default_internal (specpdl_symbol (this_binding), specpdl_old_value (this_binding), bindflag); break; case SPECPDL_LET_LOCAL: { Lisp_Object symbol = specpdl_symbol (this_binding); Lisp_Object where = specpdl_where (this_binding); Lisp_Object old_value = specpdl_old_value (this_binding); eassert (BUFFERP (where)); /* If this was a local binding, reset the value in the appropriate buffer, but only if that buffer's binding still exists. */ if (!NILP (Flocal_variable_p (symbol, where))) set_internal (symbol, old_value, where, bindflag); } break; } } static void do_nothing (void) {} /* Push an unwind-protect entry that does nothing, so that set_unwind_protect_ptr can overwrite it later. */ void record_unwind_protect_nothing (void) { record_unwind_protect_void (do_nothing); } /* Clear the unwind-protect entry COUNT, so that it does nothing. It need not be at the top of the stack. */ void clear_unwind_protect (ptrdiff_t count) { union specbinding *p = specpdl + count; p->unwind_void.kind = SPECPDL_UNWIND_VOID; p->unwind_void.func = do_nothing; } /* Set the unwind-protect entry COUNT so that it invokes FUNC (ARG). It need not be at the top of the stack. Discard the entry's previous value without invoking it. */ void set_unwind_protect (ptrdiff_t count, void (*func) (Lisp_Object), Lisp_Object arg) { union specbinding *p = specpdl + count; p->unwind.kind = SPECPDL_UNWIND; p->unwind.func = func; p->unwind.arg = arg; p->unwind.eval_depth = lisp_eval_depth; } void set_unwind_protect_ptr (ptrdiff_t count, void (*func) (void *), void *arg) { union specbinding *p = specpdl + count; p->unwind_ptr.kind = SPECPDL_UNWIND_PTR; p->unwind_ptr.func = func; p->unwind_ptr.arg = arg; } /* Pop and execute entries from the unwind-protect stack until the depth COUNT is reached. Return VALUE. */ Lisp_Object unbind_to (ptrdiff_t count, Lisp_Object value) { Lisp_Object quitf = Vquit_flag; Vquit_flag = Qnil; while (specpdl_ptr != specpdl + count) { /* Copy the binding, and decrement specpdl_ptr, before we do the work to unbind it. We decrement first so that an error in unbinding won't try to unbind the same entry again, and we copy the binding first in case more bindings are made during some of the code we run. */ union specbinding this_binding; this_binding = *--specpdl_ptr; do_one_unbind (&this_binding, true, SET_INTERNAL_UNBIND); } if (NILP (Vquit_flag) && !NILP (quitf)) Vquit_flag = quitf; return value; } void unbind_for_thread_switch (struct thread_state *thr) { union specbinding *bind; for (bind = thr->m_specpdl_ptr; bind > thr->m_specpdl;) { if ((--bind)->kind >= SPECPDL_LET) { Lisp_Object sym = specpdl_symbol (bind); bind->let.saved_value = find_symbol_value (sym); do_one_unbind (bind, false, SET_INTERNAL_THREAD_SWITCH); } } } DEFUN ("special-variable-p", Fspecial_variable_p, Sspecial_variable_p, 1, 1, 0, doc: /* Return non-nil if SYMBOL's global binding has been declared special. A special variable is one that will be bound dynamically, even in a context where binding is lexical by default. */) (Lisp_Object symbol) { CHECK_SYMBOL (symbol); return XSYMBOL (symbol)->u.s.declared_special ? Qt : Qnil; } static union specbinding * get_backtrace_starting_at (Lisp_Object base) { union specbinding *pdl = backtrace_top (); if (!NILP (base)) { /* Skip up to `base'. */ base = Findirect_function (base, Qt); while (backtrace_p (pdl) && !EQ (base, Findirect_function (backtrace_function (pdl), Qt))) pdl = backtrace_next (pdl); } return pdl; } static union specbinding * get_backtrace_frame (Lisp_Object nframes, Lisp_Object base) { register EMACS_INT i; CHECK_FIXNAT (nframes); union specbinding *pdl = get_backtrace_starting_at (base); /* Find the frame requested. */ for (i = XFIXNAT (nframes); i > 0 && backtrace_p (pdl); i--) pdl = backtrace_next (pdl); return pdl; } static Lisp_Object backtrace_frame_apply (Lisp_Object function, union specbinding *pdl) { if (!backtrace_p (pdl)) return Qnil; Lisp_Object flags = Qnil; if (backtrace_debug_on_exit (pdl)) flags = list2 (QCdebug_on_exit, Qt); if (backtrace_nargs (pdl) == UNEVALLED) return call4 (function, Qnil, backtrace_function (pdl), *backtrace_args (pdl), flags); else { Lisp_Object tem = Flist (backtrace_nargs (pdl), backtrace_args (pdl)); return call4 (function, Qt, backtrace_function (pdl), tem, flags); } } DEFUN ("backtrace-debug", Fbacktrace_debug, Sbacktrace_debug, 2, 2, 0, doc: /* Set the debug-on-exit flag of eval frame LEVEL levels down to FLAG. The debugger is entered when that frame exits, if the flag is non-nil. */) (Lisp_Object level, Lisp_Object flag) { CHECK_FIXNUM (level); union specbinding *pdl = get_backtrace_frame(level, Qnil); if (backtrace_p (pdl)) set_backtrace_debug_on_exit (pdl, !NILP (flag)); return flag; } DEFUN ("mapbacktrace", Fmapbacktrace, Smapbacktrace, 1, 2, 0, doc: /* Call FUNCTION for each frame in backtrace. If BASE is non-nil, it should be a function and iteration will start from its nearest activation frame. FUNCTION is called with 4 arguments: EVALD, FUNC, ARGS, and FLAGS. If a frame has not evaluated its arguments yet or is a special form, EVALD is nil and ARGS is a list of forms. If a frame has evaluated its arguments and called its function already, EVALD is t and ARGS is a list of values. FLAGS is a plist of properties of the current frame: currently, the only supported property is :debug-on-exit. `mapbacktrace' always returns nil. */) (Lisp_Object function, Lisp_Object base) { union specbinding *pdl = get_backtrace_starting_at (base); while (backtrace_p (pdl)) { ptrdiff_t i = pdl - specpdl; backtrace_frame_apply (function, pdl); /* Beware! PDL is no longer valid here because FUNCTION might have caused grow_specpdl to reallocate pdlvec. We must use the saved index, cf. Bug#27258. */ pdl = backtrace_next (&specpdl[i]); } return Qnil; } DEFUN ("backtrace-frame--internal", Fbacktrace_frame_internal, Sbacktrace_frame_internal, 3, 3, NULL, doc: /* Call FUNCTION on stack frame NFRAMES away from BASE. Return the result of FUNCTION, or nil if no matching frame could be found. */) (Lisp_Object function, Lisp_Object nframes, Lisp_Object base) { return backtrace_frame_apply (function, get_backtrace_frame (nframes, base)); } DEFUN ("backtrace--frames-from-thread", Fbacktrace_frames_from_thread, Sbacktrace_frames_from_thread, 1, 1, NULL, doc: /* Return the list of backtrace frames from current execution point in THREAD. If a frame has not evaluated the arguments yet (or is a special form), the value of the list element is (nil FUNCTION ARG-FORMS...). If a frame has evaluated its arguments and called its function already, the value of the list element is (t FUNCTION ARG-VALUES...). A &rest arg is represented as the tail of the list ARG-VALUES. FUNCTION is whatever was supplied as car of evaluated list, or a lambda expression for macro calls. */) (Lisp_Object thread) { struct thread_state *tstate; CHECK_THREAD (thread); tstate = XTHREAD (thread); union specbinding *pdl = backtrace_thread_top (tstate); Lisp_Object list = Qnil; while (backtrace_thread_p (tstate, pdl)) { Lisp_Object frame; if (backtrace_nargs (pdl) == UNEVALLED) frame = Fcons (Qnil, Fcons (backtrace_function (pdl), *backtrace_args (pdl))); else { Lisp_Object tem = Flist (backtrace_nargs (pdl), backtrace_args (pdl)); frame = Fcons (Qt, Fcons (backtrace_function (pdl), tem)); } list = Fcons (frame, list); pdl = backtrace_thread_next (tstate, pdl); } return Fnreverse (list); } /* For backtrace-eval, we want to temporarily unwind the last few elements of the specpdl stack, and then rewind them. We store the pre-unwind values directly in the pre-existing specpdl elements (i.e. we swap the current value and the old value stored in the specpdl), kind of like the inplace pointer-reversal trick. As it turns out, the rewind does the same as the unwind, except it starts from the other end of the specpdl stack, so we use the same function for both unwind and rewind. */ static void backtrace_eval_unrewind (int distance) { union specbinding *tmp = specpdl_ptr; int step = -1; if (distance < 0) { /* It's a rewind rather than unwind. */ tmp += distance - 1; step = 1; distance = -distance; } for (; distance > 0; distance--) { tmp += step; switch (tmp->kind) { /* FIXME: Ideally we'd like to "temporarily unwind" (some of) those unwind_protect, but the problem is that we don't know how to rewind them afterwards. */ case SPECPDL_UNWIND: if (tmp->unwind.func == set_buffer_if_live) { Lisp_Object oldarg = tmp->unwind.arg; tmp->unwind.arg = Fcurrent_buffer (); set_buffer_if_live (oldarg); } break; case SPECPDL_UNWIND_EXCURSION: { Lisp_Object marker = tmp->unwind_excursion.marker; Lisp_Object window = tmp->unwind_excursion.window; save_excursion_save (tmp); save_excursion_restore (marker, window); } break; case SPECPDL_UNWIND_ARRAY: case SPECPDL_UNWIND_PTR: case SPECPDL_UNWIND_INT: case SPECPDL_UNWIND_INTMAX: case SPECPDL_UNWIND_VOID: case SPECPDL_BACKTRACE: #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: case SPECPDL_MODULE_ENVIRONMENT: #endif break; case SPECPDL_LET: { /* If variable has a trivial value (no forwarding), we can just set it. No need to check for constant symbols here, since that was already done by specbind. */ Lisp_Object sym = specpdl_symbol (tmp); if (SYMBOLP (sym) && XSYMBOL (sym)->u.s.redirect == SYMBOL_PLAINVAL) { Lisp_Object old_value = specpdl_old_value (tmp); set_specpdl_old_value (tmp, SYMBOL_VAL (XSYMBOL (sym))); SET_SYMBOL_VAL (XSYMBOL (sym), old_value); break; } } /* Come here only if make_local_foo was used for the first time on this var within this let. */ FALLTHROUGH; case SPECPDL_LET_DEFAULT: { Lisp_Object sym = specpdl_symbol (tmp); Lisp_Object old_value = specpdl_old_value (tmp); set_specpdl_old_value (tmp, default_value (sym)); Fset_default (sym, old_value); } break; case SPECPDL_LET_LOCAL: { Lisp_Object symbol = specpdl_symbol (tmp); Lisp_Object where = specpdl_where (tmp); Lisp_Object old_value = specpdl_old_value (tmp); eassert (BUFFERP (where)); /* If this was a local binding, reset the value in the appropriate buffer, but only if that buffer's binding still exists. */ if (!NILP (Flocal_variable_p (symbol, where))) { set_specpdl_old_value (tmp, buffer_local_value (symbol, where)); set_internal (symbol, old_value, where, SET_INTERNAL_UNBIND); } } break; } } } DEFUN ("backtrace-eval", Fbacktrace_eval, Sbacktrace_eval, 2, 3, NULL, doc: /* Evaluate EXP in the context of some activation frame. NFRAMES and BASE specify the activation frame to use, as in `backtrace-frame'. */) (Lisp_Object exp, Lisp_Object nframes, Lisp_Object base) { union specbinding *pdl = get_backtrace_frame (nframes, base); ptrdiff_t count = SPECPDL_INDEX (); ptrdiff_t distance = specpdl_ptr - pdl; eassert (distance >= 0); if (!backtrace_p (pdl)) error ("Activation frame not found!"); backtrace_eval_unrewind (distance); record_unwind_protect_int (backtrace_eval_unrewind, -distance); /* Use eval_sub rather than Feval since the main motivation behind backtrace-eval is to be able to get/set the value of lexical variables from the debugger. */ return unbind_to (count, eval_sub (exp)); } DEFUN ("backtrace--locals", Fbacktrace__locals, Sbacktrace__locals, 1, 2, NULL, doc: /* Return names and values of local variables of a stack frame. NFRAMES and BASE specify the activation frame to use, as in `backtrace-frame'. */) (Lisp_Object nframes, Lisp_Object base) { union specbinding *frame = get_backtrace_frame (nframes, base); union specbinding *prevframe = get_backtrace_frame (make_fixnum (XFIXNAT (nframes) - 1), base); ptrdiff_t distance = specpdl_ptr - frame; Lisp_Object result = Qnil; eassert (distance >= 0); if (!backtrace_p (prevframe)) error ("Activation frame not found!"); if (!backtrace_p (frame)) error ("Activation frame not found!"); /* The specpdl entries normally contain the symbol being bound along with its `old_value', so it can be restored. The new value to which it is bound is available in one of two places: either in the current value of the variable (if it hasn't been rebound yet) or in the `old_value' slot of the next specpdl entry for it. `backtrace_eval_unrewind' happens to swap the role of `old_value' and "new value", so we abuse it here, to fetch the new value. It's ugly (we'd rather not modify global data) and a bit inefficient, but it does the job for now. */ backtrace_eval_unrewind (distance); /* Grab values. */ { union specbinding *tmp = prevframe; for (; tmp > frame; tmp--) { switch (tmp->kind) { case SPECPDL_LET: case SPECPDL_LET_DEFAULT: case SPECPDL_LET_LOCAL: { Lisp_Object sym = specpdl_symbol (tmp); Lisp_Object val = specpdl_old_value (tmp); if (EQ (sym, Qinternal_interpreter_environment)) { Lisp_Object env = val; for (; CONSP (env); env = XCDR (env)) { Lisp_Object binding = XCAR (env); if (CONSP (binding)) result = Fcons (Fcons (XCAR (binding), XCDR (binding)), result); } } else result = Fcons (Fcons (sym, val), result); } break; case SPECPDL_UNWIND: case SPECPDL_UNWIND_ARRAY: case SPECPDL_UNWIND_PTR: case SPECPDL_UNWIND_INT: case SPECPDL_UNWIND_INTMAX: case SPECPDL_UNWIND_EXCURSION: case SPECPDL_UNWIND_VOID: case SPECPDL_BACKTRACE: #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: case SPECPDL_MODULE_ENVIRONMENT: #endif break; default: emacs_abort (); } } } /* Restore values from specpdl to original place. */ backtrace_eval_unrewind (-distance); return result; } void mark_specpdl (union specbinding *first, union specbinding *ptr) { union specbinding *pdl; for (pdl = first; pdl != ptr; pdl++) { switch (pdl->kind) { case SPECPDL_UNWIND: mark_object (specpdl_arg (pdl)); break; case SPECPDL_UNWIND_ARRAY: mark_objects (pdl->unwind_array.array, pdl->unwind_array.nelts); break; case SPECPDL_UNWIND_EXCURSION: mark_object (pdl->unwind_excursion.marker); mark_object (pdl->unwind_excursion.window); break; case SPECPDL_BACKTRACE: { ptrdiff_t nargs = backtrace_nargs (pdl); mark_object (backtrace_function (pdl)); if (nargs == UNEVALLED) nargs = 1; mark_objects (backtrace_args (pdl), nargs); } break; #ifdef HAVE_MODULES case SPECPDL_MODULE_RUNTIME: break; case SPECPDL_MODULE_ENVIRONMENT: mark_module_environment (pdl->unwind_ptr.arg); break; #endif case SPECPDL_LET_DEFAULT: case SPECPDL_LET_LOCAL: mark_object (specpdl_where (pdl)); FALLTHROUGH; case SPECPDL_LET: mark_object (specpdl_symbol (pdl)); mark_object (specpdl_old_value (pdl)); mark_object (specpdl_saved_value (pdl)); break; case SPECPDL_UNWIND_PTR: case SPECPDL_UNWIND_INT: case SPECPDL_UNWIND_INTMAX: case SPECPDL_UNWIND_VOID: break; default: emacs_abort (); } } } void get_backtrace (Lisp_Object array) { union specbinding *pdl = backtrace_next (backtrace_top ()); ptrdiff_t i = 0, asize = ASIZE (array); /* Copy the backtrace contents into working memory. */ for (; i < asize; i++) { if (backtrace_p (pdl)) { ASET (array, i, backtrace_function (pdl)); pdl = backtrace_next (pdl); } else ASET (array, i, Qnil); } } Lisp_Object backtrace_top_function (void) { union specbinding *pdl = backtrace_top (); return (backtrace_p (pdl) ? backtrace_function (pdl) : Qnil); } void syms_of_eval (void) { DEFVAR_INT ("max-specpdl-size", max_specpdl_size, doc: /* Limit on number of Lisp variable bindings and `unwind-protect's. If Lisp code tries to increase the total number past this amount, an error is signaled. You can safely use a value considerably larger than the default value, if that proves inconveniently small. However, if you increase it too far, Emacs could run out of memory trying to make the stack bigger. Note that this limit may be silently increased by the debugger if `debug-on-error' or `debug-on-quit' is set. */); DEFVAR_INT ("max-lisp-eval-depth", max_lisp_eval_depth, doc: /* Limit on depth in `eval', `apply' and `funcall' before error. This limit serves to catch infinite recursions for you before they cause actual stack overflow in C, which would be fatal for Emacs. You can safely make it considerably larger than its default value, if that proves inconveniently small. However, if you increase it too far, Emacs could overflow the real C stack, and crash. */); DEFVAR_LISP ("quit-flag", Vquit_flag, doc: /* Non-nil causes `eval' to abort, unless `inhibit-quit' is non-nil. If the value is t, that means do an ordinary quit. If the value equals `throw-on-input', that means quit by throwing to the tag specified in `throw-on-input'; it's for handling `while-no-input'. Typing C-g sets `quit-flag' to t, regardless of `inhibit-quit', but `inhibit-quit' non-nil prevents anything from taking notice of that. */); Vquit_flag = Qnil; DEFVAR_LISP ("inhibit-quit", Vinhibit_quit, doc: /* Non-nil inhibits C-g quitting from happening immediately. Note that `quit-flag' will still be set by typing C-g, so a quit will be signaled as soon as `inhibit-quit' is nil. To prevent this happening, set `quit-flag' to nil before making `inhibit-quit' nil. */); Vinhibit_quit = Qnil; DEFSYM (Qsetq, "setq"); DEFSYM (Qinhibit_quit, "inhibit-quit"); DEFSYM (Qautoload, "autoload"); DEFSYM (Qinhibit_debugger, "inhibit-debugger"); DEFSYM (Qmacro, "macro"); /* Note that the process handling also uses Qexit, but we don't want to staticpro it twice, so we just do it here. */ DEFSYM (Qexit, "exit"); DEFSYM (Qinteractive, "interactive"); DEFSYM (Qcommandp, "commandp"); DEFSYM (Qand_rest, "&rest"); DEFSYM (Qand_optional, "&optional"); DEFSYM (Qclosure, "closure"); DEFSYM (QCdocumentation, ":documentation"); DEFSYM (Qdebug, "debug"); DEFVAR_LISP ("inhibit-debugger", Vinhibit_debugger, doc: /* Non-nil means never enter the debugger. Normally set while the debugger is already active, to avoid recursive invocations. */); Vinhibit_debugger = Qnil; DEFVAR_LISP ("debug-on-error", Vdebug_on_error, doc: /* Non-nil means enter debugger if an error is signaled. Does not apply to errors handled by `condition-case' or those matched by `debug-ignored-errors'. If the value is a list, an error only means to enter the debugger if one of its condition symbols appears in the list. When you evaluate an expression interactively, this variable is temporarily non-nil if `eval-expression-debug-on-error' is non-nil. The command `toggle-debug-on-error' toggles this. See also the variable `debug-on-quit' and `inhibit-debugger'. */); Vdebug_on_error = Qnil; DEFVAR_LISP ("debug-ignored-errors", Vdebug_ignored_errors, doc: /* List of errors for which the debugger should not be called. Each element may be a condition-name or a regexp that matches error messages. If any element applies to a given error, that error skips the debugger and just returns to top level. This overrides the variable `debug-on-error'. It does not apply to errors handled by `condition-case'. */); Vdebug_ignored_errors = Qnil; DEFVAR_BOOL ("debug-on-quit", debug_on_quit, doc: /* Non-nil means enter debugger if quit is signaled (C-g, for example). Does not apply if quit is handled by a `condition-case'. */); debug_on_quit = 0; DEFVAR_BOOL ("debug-on-next-call", debug_on_next_call, doc: /* Non-nil means enter debugger before next `eval', `apply' or `funcall'. */); DEFVAR_BOOL ("debugger-may-continue", debugger_may_continue, doc: /* Non-nil means debugger may continue execution. This is nil when the debugger is called under circumstances where it might not be safe to continue. */); debugger_may_continue = 1; DEFVAR_BOOL ("debugger-stack-frame-as-list", debugger_stack_frame_as_list, doc: /* Non-nil means display call stack frames as lists. */); debugger_stack_frame_as_list = 0; DEFVAR_LISP ("debugger", Vdebugger, doc: /* Function to call to invoke debugger. If due to frame exit, args are `exit' and the value being returned; this function's value will be returned instead of that. If due to error, args are `error' and a list of the args to `signal'. If due to `apply' or `funcall' entry, one arg, `lambda'. If due to `eval' entry, one arg, t. */); Vdebugger = Qnil; DEFVAR_LISP ("signal-hook-function", Vsignal_hook_function, doc: /* If non-nil, this is a function for `signal' to call. It receives the same arguments that `signal' was given. The Edebug package uses this to regain control. */); Vsignal_hook_function = Qnil; DEFVAR_LISP ("debug-on-signal", Vdebug_on_signal, doc: /* Non-nil means call the debugger regardless of condition handlers. Note that `debug-on-error', `debug-on-quit' and friends still determine whether to handle the particular condition. */); Vdebug_on_signal = Qnil; /* The value of num_nonmacro_input_events as of the last time we started to enter the debugger. If we decide to enter the debugger again when this is still equal to num_nonmacro_input_events, then we know that the debugger itself has an error, and we should just signal the error instead of entering an infinite loop of debugger invocations. */ DEFSYM (Qinternal_when_entered_debugger, "internal-when-entered-debugger"); DEFVAR_INT ("internal-when-entered-debugger", when_entered_debugger, doc: /* The number of keyboard events as of last time `debugger' was called. Used to avoid infinite loops if the debugger itself has an error. Don't set this unless you're sure that can't happen. */); /* When lexical binding is being used, Vinternal_interpreter_environment is non-nil, and contains an alist of lexically-bound variable, or (t), indicating an empty environment. The lisp name of this variable would be `internal-interpreter-environment' if it weren't hidden. Every element of this list can be either a cons (VAR . VAL) specifying a lexical binding, or a single symbol VAR indicating that this variable should use dynamic scoping. */ DEFSYM (Qinternal_interpreter_environment, "internal-interpreter-environment"); DEFVAR_LISP ("internal-interpreter-environment", Vinternal_interpreter_environment, doc: /* If non-nil, the current lexical environment of the lisp interpreter. When lexical binding is not being used, this variable is nil. A value of `(t)' indicates an empty environment, otherwise it is an alist of active lexical bindings. */); Vinternal_interpreter_environment = Qnil; /* Don't export this variable to Elisp, so no one can mess with it (Just imagine if someone makes it buffer-local). */ Funintern (Qinternal_interpreter_environment, Qnil); Vrun_hooks = intern_c_string ("run-hooks"); staticpro (&Vrun_hooks); staticpro (&Vautoload_queue); Vautoload_queue = Qnil; staticpro (&Vsignaling_function); Vsignaling_function = Qnil; staticpro (&Qcatch_all_memory_full); /* Make sure Qcatch_all_memory_full is a unique object. We could also use something like Fcons (Qnil, Qnil), but json.c treats any cons cell as error data, so use an uninterned symbol instead. */ Qcatch_all_memory_full = Fmake_symbol (build_pure_c_string ("catch-all-memory-full")); defsubr (&Sor); defsubr (&Sand); defsubr (&Sif); defsubr (&Scond); defsubr (&Sprogn); defsubr (&Sprog1); defsubr (&Ssetq); defsubr (&Squote); defsubr (&Sfunction); defsubr (&Sdefault_toplevel_value); defsubr (&Sset_default_toplevel_value); defsubr (&Sdefvar); defsubr (&Sdefvaralias); DEFSYM (Qdefvaralias, "defvaralias"); defsubr (&Sdefconst); defsubr (&Sinternal__define_uninitialized_variable); defsubr (&Smake_var_non_special); defsubr (&Slet); defsubr (&SletX); defsubr (&Swhile); defsubr (&Smacroexpand); defsubr (&Scatch); defsubr (&Sthrow); defsubr (&Sunwind_protect); defsubr (&Scondition_case); defsubr (&Ssignal); defsubr (&Scommandp); defsubr (&Sautoload); defsubr (&Sautoload_do_load); defsubr (&Seval); defsubr (&Sapply); defsubr (&Sfuncall); defsubr (&Sfunc_arity); defsubr (&Srun_hooks); defsubr (&Srun_hook_with_args); defsubr (&Srun_hook_with_args_until_success); defsubr (&Srun_hook_with_args_until_failure); defsubr (&Srun_hook_wrapped); defsubr (&Sfetch_bytecode); defsubr (&Sbacktrace_debug); DEFSYM (QCdebug_on_exit, ":debug-on-exit"); defsubr (&Smapbacktrace); defsubr (&Sbacktrace_frame_internal); defsubr (&Sbacktrace_frames_from_thread); defsubr (&Sbacktrace_eval); defsubr (&Sbacktrace__locals); defsubr (&Sspecial_variable_p); defsubr (&Sfunctionp); }