| blob | 55789b41ad994f051669b7208970de837731b92d |
1 /* Execution of byte code produced by bytecomp.el.
2 Copyright (C) 1985-1988, 1993, 2000-2015 Free Software Foundation,
3 Inc.
5 This file is part of GNU Emacs.
7 GNU Emacs is free software: you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation, either version 3 of the License, or
10 (at your option) any later version.
12 GNU Emacs is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>. */
20 /*
21 hacked on by jwz@lucid.com 17-jun-91
22 o added a compile-time switch to turn on simple sanity checking;
23 o put back the obsolete byte-codes for error-detection;
24 o added a new instruction, unbind_all, which I will use for
25 tail-recursion elimination;
26 o made temp_output_buffer_show be called with the right number
27 of args;
28 o made the new bytecodes be called with args in the right order;
29 o added metering support.
31 by Hallvard:
32 o added relative jump instructions;
33 o all conditionals now only do QUIT if they jump.
34 */
36 #include <config.h>
46 #ifdef CHECK_FRAME_FONT
49 #endif
51 /*
52 * define BYTE_CODE_SAFE to enable some minor sanity checking (useful for
53 * debugging the byte compiler...)
54 *
55 * define BYTE_CODE_METER to enable generation of a byte-op usage histogram.
56 */
57 /* #define BYTE_CODE_SAFE */
58 /* #define BYTE_CODE_METER */
60 /* If BYTE_CODE_THREADED is defined, then the interpreter will be
61 indirect threaded, using GCC's computed goto extension. This code,
62 as currently implemented, is incompatible with BYTE_CODE_SAFE and
63 BYTE_CODE_METER. */
64 #if (defined __GNUC__ && !defined __STRICT_ANSI__ \
65 && !defined BYTE_CODE_SAFE && !defined BYTE_CODE_METER)
66 #define BYTE_CODE_THREADED
67 #endif
69 \f
70 #ifdef BYTE_CODE_METER
72 #define METER_2(code1, code2) AREF (AREF (Vbyte_code_meter, code1), code2)
73 #define METER_1(code) METER_2 (0, code)
75 #define METER_CODE(last_code, this_code) \
76 { \
77 if (byte_metering_on) \
78 { \
79 if (XFASTINT (METER_1 (this_code)) < MOST_POSITIVE_FIXNUM) \
80 XSETFASTINT (METER_1 (this_code), \
81 XFASTINT (METER_1 (this_code)) + 1); \
82 if (last_code \
83 && (XFASTINT (METER_2 (last_code, this_code)) \
84 < MOST_POSITIVE_FIXNUM)) \
85 XSETFASTINT (METER_2 (last_code, this_code), \
86 XFASTINT (METER_2 (last_code, this_code)) + 1); \
87 } \
88 }
91 \f
93 /* Byte codes: */
95 #define BYTE_CODES \
97 DEFINE (Bstack_ref1, 1) \
98 DEFINE (Bstack_ref2, 2) \
99 DEFINE (Bstack_ref3, 3) \
100 DEFINE (Bstack_ref4, 4) \
101 DEFINE (Bstack_ref5, 5) \
102 DEFINE (Bstack_ref6, 6) \
103 DEFINE (Bstack_ref7, 7) \
104 DEFINE (Bvarref, 010) \
105 DEFINE (Bvarref1, 011) \
106 DEFINE (Bvarref2, 012) \
107 DEFINE (Bvarref3, 013) \
108 DEFINE (Bvarref4, 014) \
109 DEFINE (Bvarref5, 015) \
110 DEFINE (Bvarref6, 016) \
111 DEFINE (Bvarref7, 017) \
112 DEFINE (Bvarset, 020) \
113 DEFINE (Bvarset1, 021) \
114 DEFINE (Bvarset2, 022) \
115 DEFINE (Bvarset3, 023) \
116 DEFINE (Bvarset4, 024) \
117 DEFINE (Bvarset5, 025) \
118 DEFINE (Bvarset6, 026) \
119 DEFINE (Bvarset7, 027) \
120 DEFINE (Bvarbind, 030) \
121 DEFINE (Bvarbind1, 031) \
122 DEFINE (Bvarbind2, 032) \
123 DEFINE (Bvarbind3, 033) \
124 DEFINE (Bvarbind4, 034) \
125 DEFINE (Bvarbind5, 035) \
126 DEFINE (Bvarbind6, 036) \
127 DEFINE (Bvarbind7, 037) \
128 DEFINE (Bcall, 040) \
129 DEFINE (Bcall1, 041) \
130 DEFINE (Bcall2, 042) \
131 DEFINE (Bcall3, 043) \
132 DEFINE (Bcall4, 044) \
133 DEFINE (Bcall5, 045) \
134 DEFINE (Bcall6, 046) \
135 DEFINE (Bcall7, 047) \
136 DEFINE (Bunbind, 050) \
137 DEFINE (Bunbind1, 051) \
138 DEFINE (Bunbind2, 052) \
139 DEFINE (Bunbind3, 053) \
140 DEFINE (Bunbind4, 054) \
141 DEFINE (Bunbind5, 055) \
142 DEFINE (Bunbind6, 056) \
143 DEFINE (Bunbind7, 057) \
144 \
145 DEFINE (Bpophandler, 060) \
146 DEFINE (Bpushconditioncase, 061) \
147 DEFINE (Bpushcatch, 062) \
148 \
149 DEFINE (Bnth, 070) \
150 DEFINE (Bsymbolp, 071) \
151 DEFINE (Bconsp, 072) \
152 DEFINE (Bstringp, 073) \
153 DEFINE (Blistp, 074) \
154 DEFINE (Beq, 075) \
155 DEFINE (Bmemq, 076) \
156 DEFINE (Bnot, 077) \
157 DEFINE (Bcar, 0100) \
158 DEFINE (Bcdr, 0101) \
159 DEFINE (Bcons, 0102) \
160 DEFINE (Blist1, 0103) \
161 DEFINE (Blist2, 0104) \
162 DEFINE (Blist3, 0105) \
163 DEFINE (Blist4, 0106) \
164 DEFINE (Blength, 0107) \
165 DEFINE (Baref, 0110) \
166 DEFINE (Baset, 0111) \
167 DEFINE (Bsymbol_value, 0112) \
168 DEFINE (Bsymbol_function, 0113) \
169 DEFINE (Bset, 0114) \
170 DEFINE (Bfset, 0115) \
171 DEFINE (Bget, 0116) \
172 DEFINE (Bsubstring, 0117) \
173 DEFINE (Bconcat2, 0120) \
174 DEFINE (Bconcat3, 0121) \
175 DEFINE (Bconcat4, 0122) \
176 DEFINE (Bsub1, 0123) \
177 DEFINE (Badd1, 0124) \
178 DEFINE (Beqlsign, 0125) \
179 DEFINE (Bgtr, 0126) \
180 DEFINE (Blss, 0127) \
181 DEFINE (Bleq, 0130) \
182 DEFINE (Bgeq, 0131) \
183 DEFINE (Bdiff, 0132) \
184 DEFINE (Bnegate, 0133) \
185 DEFINE (Bplus, 0134) \
186 DEFINE (Bmax, 0135) \
187 DEFINE (Bmin, 0136) \
188 DEFINE (Bmult, 0137) \
189 \
190 DEFINE (Bpoint, 0140) \
193 DEFINE (Bgoto_char, 0142) \
194 DEFINE (Binsert, 0143) \
195 DEFINE (Bpoint_max, 0144) \
196 DEFINE (Bpoint_min, 0145) \
197 DEFINE (Bchar_after, 0146) \
198 DEFINE (Bfollowing_char, 0147) \
199 DEFINE (Bpreceding_char, 0150) \
200 DEFINE (Bcurrent_column, 0151) \
201 DEFINE (Bindent_to, 0152) \
202 DEFINE (Beolp, 0154) \
203 DEFINE (Beobp, 0155) \
204 DEFINE (Bbolp, 0156) \
205 DEFINE (Bbobp, 0157) \
206 DEFINE (Bcurrent_buffer, 0160) \
207 DEFINE (Bset_buffer, 0161) \
210 \
211 DEFINE (Bforward_char, 0165) \
212 DEFINE (Bforward_word, 0166) \
213 DEFINE (Bskip_chars_forward, 0167) \
214 DEFINE (Bskip_chars_backward, 0170) \
215 DEFINE (Bforward_line, 0171) \
216 DEFINE (Bchar_syntax, 0172) \
217 DEFINE (Bbuffer_substring, 0173) \
218 DEFINE (Bdelete_region, 0174) \
219 DEFINE (Bnarrow_to_region, 0175) \
220 DEFINE (Bwiden, 0176) \
221 DEFINE (Bend_of_line, 0177) \
222 \
223 DEFINE (Bconstant2, 0201) \
224 DEFINE (Bgoto, 0202) \
225 DEFINE (Bgotoifnil, 0203) \
226 DEFINE (Bgotoifnonnil, 0204) \
227 DEFINE (Bgotoifnilelsepop, 0205) \
228 DEFINE (Bgotoifnonnilelsepop, 0206) \
229 DEFINE (Breturn, 0207) \
230 DEFINE (Bdiscard, 0210) \
231 DEFINE (Bdup, 0211) \
232 \
233 DEFINE (Bsave_excursion, 0212) \
235 DEFINE (Bsave_restriction, 0214) \
236 DEFINE (Bcatch, 0215) \
237 \
238 DEFINE (Bunwind_protect, 0216) \
239 DEFINE (Bcondition_case, 0217) \
242 \
244 \
245 DEFINE (Bset_marker, 0223) \
246 DEFINE (Bmatch_beginning, 0224) \
247 DEFINE (Bmatch_end, 0225) \
248 DEFINE (Bupcase, 0226) \
249 DEFINE (Bdowncase, 0227) \
250 \
251 DEFINE (Bstringeqlsign, 0230) \
252 DEFINE (Bstringlss, 0231) \
253 DEFINE (Bequal, 0232) \
254 DEFINE (Bnthcdr, 0233) \
255 DEFINE (Belt, 0234) \
256 DEFINE (Bmember, 0235) \
257 DEFINE (Bassq, 0236) \
258 DEFINE (Bnreverse, 0237) \
259 DEFINE (Bsetcar, 0240) \
260 DEFINE (Bsetcdr, 0241) \
261 DEFINE (Bcar_safe, 0242) \
262 DEFINE (Bcdr_safe, 0243) \
263 DEFINE (Bnconc, 0244) \
264 DEFINE (Bquo, 0245) \
265 DEFINE (Brem, 0246) \
266 DEFINE (Bnumberp, 0247) \
267 DEFINE (Bintegerp, 0250) \
268 \
269 DEFINE (BRgoto, 0252) \
270 DEFINE (BRgotoifnil, 0253) \
271 DEFINE (BRgotoifnonnil, 0254) \
272 DEFINE (BRgotoifnilelsepop, 0255) \
273 DEFINE (BRgotoifnonnilelsepop, 0256) \
274 \
275 DEFINE (BlistN, 0257) \
276 DEFINE (BconcatN, 0260) \
277 DEFINE (BinsertN, 0261) \
278 \
280 DEFINE (Bstack_set, 0262) \
281 DEFINE (Bstack_set2, 0263) \
282 DEFINE (BdiscardN, 0266) \
283 \
284 DEFINE (Bconstant, 0300)
286 enum byte_code_op
287 {
288 #define DEFINE(name, value) name = value,
289 BYTE_CODES
290 #undef DEFINE
292 #ifdef BYTE_CODE_SAFE
295 #endif
296 };
298 /* Whether to maintain a `top' and `bottom' field in the stack frame. */
299 #define BYTE_MAINTAIN_TOP (BYTE_CODE_SAFE || BYTE_MARK_STACK)
300 \f
301 /* Structure describing a value stack used during byte-code execution
302 in Fbyte_code. */
304 struct byte_stack
305 {
306 /* Program counter. This points into the byte_string below
307 and is relocated when that string is relocated. */
310 /* Top and bottom of stack. The bottom points to an area of memory
311 allocated with alloca in Fbyte_code. */
312 #if BYTE_MAINTAIN_TOP
314 #endif
316 /* The string containing the byte-code, and its current address.
317 Storing this here protects it from GC because mark_byte_stack
318 marks it. */
319 Lisp_Object byte_string;
322 #if BYTE_MARK_STACK
323 /* The vector of constants used during byte-code execution. Storing
324 this here protects it from GC because mark_byte_stack marks it. */
325 Lisp_Object constants;
326 #endif
328 /* Next entry in byte_stack_list. */
330 };
332 /* A list of currently active byte-code execution value stacks.
333 Fbyte_code adds an entry to the head of this list before it starts
334 processing byte-code, and it removes the entry again when it is
335 done. Signaling an error truncates the list analogous to
336 gcprolist. */
340 \f
341 /* Mark objects on byte_stack_list. Called during GC. */
343 #if BYTE_MARK_STACK
344 void
346 {
351 {
352 /* If STACK->top is null here, this means there's an opcode in
353 Fbyte_code that wasn't expected to GC, but did. To find out
354 which opcode this is, record the value of `stack', and walk
355 up the stack in a debugger, stopping in frames of Fbyte_code.
356 The culprit is found in the frame of Fbyte_code where the
357 address of its local variable `stack' is equal to the
358 recorded value of `stack' here. */
366 }
367 }
368 #endif
370 /* Unmark objects in the stacks on byte_stack_list. Relocate program
371 counters. Called when GC has completed. */
373 void
375 {
379 {
381 {
385 }
386 }
387 }
389 \f
390 /* Fetch the next byte from the bytecode stream. */
392 #ifdef BYTE_CODE_SAFE
393 #define FETCH (eassert (stack.byte_string_start == SDATA (stack.byte_string)), *stack.pc++)
394 #else
395 #define FETCH *stack.pc++
396 #endif
398 /* Fetch two bytes from the bytecode stream and make a 16-bit number
399 out of them. */
401 #define FETCH2 (op = FETCH, op + (FETCH << 8))
403 /* Push x onto the execution stack. This used to be #define PUSH(x)
404 (*++stackp = (x)) This oddity is necessary because Alliant can't be
405 bothered to compile the preincrement operator properly, as of 4/91.
406 -JimB */
408 #define PUSH(x) (top++, *top = (x))
410 /* Pop a value off the execution stack. */
412 #define POP (*top--)
414 /* Discard n values from the execution stack. */
416 #define DISCARD(n) (top -= (n))
418 /* Get the value which is at the top of the execution stack, but don't
419 pop it. */
421 #define TOP (*top)
423 /* Actions that must be performed before and after calling a function
424 that might GC. */
426 #if !BYTE_MAINTAIN_TOP
427 #define BEFORE_POTENTIAL_GC() ((void)0)
428 #define AFTER_POTENTIAL_GC() ((void)0)
429 #else
430 #define BEFORE_POTENTIAL_GC() stack.top = top
431 #define AFTER_POTENTIAL_GC() stack.top = NULL
432 #endif
434 /* Garbage collect if we have consed enough since the last time.
435 We do this at every branch, to avoid loops that never GC. */
437 #define MAYBE_GC() \
438 do { \
439 BEFORE_POTENTIAL_GC (); \
440 maybe_gc (); \
441 AFTER_POTENTIAL_GC (); \
442 } while (0)
444 /* Check for jumping out of range. */
446 #ifdef BYTE_CODE_SAFE
448 #define CHECK_RANGE(ARG) \
449 if (ARG >= bytestr_length) emacs_abort ()
453 #define CHECK_RANGE(ARG)
457 /* A version of the QUIT macro which makes sure that the stack top is
458 set before signaling `quit'. */
460 #define BYTE_CODE_QUIT \
461 do { \
462 if (!NILP (Vquit_flag) && NILP (Vinhibit_quit)) \
463 { \
464 Lisp_Object flag = Vquit_flag; \
465 Vquit_flag = Qnil; \
466 BEFORE_POTENTIAL_GC (); \
467 if (EQ (Vthrow_on_input, flag)) \
468 Fthrow (Vthrow_on_input, Qt); \
469 Fsignal (Qquit, Qnil); \
470 AFTER_POTENTIAL_GC (); \
471 } \
472 else if (pending_signals) \
473 process_pending_signals (); \
474 } while (0)
479 The first argument, BYTESTR, is a string of byte code;
480 the second, VECTOR, a vector of constants;
481 the third, MAXDEPTH, the maximum stack depth used in this function.
484 {
486 }
488 static void
490 {
492 }
494 /* Execute the byte-code in BYTESTR. VECTOR is the constant vector, and
495 MAXDEPTH is the maximum stack depth used (if MAXDEPTH is incorrect,
496 emacs may crash!). If ARGS_TEMPLATE is non-nil, it should be a lisp
497 argument list (including &rest, &optional, etc.), and ARGS, of size
498 NARGS, should be a vector of the actual arguments. The arguments in
499 ARGS are pushed on the stack according to ARGS_TEMPLATE before
500 executing BYTESTR. */
502 Lisp_Object
505 {
507 #ifdef BYTE_CODE_METER
510 #endif
512 /* Lisp_Object v1, v2; */
514 #ifdef BYTE_CODE_SAFE
518 #endif
521 Lisp_Object result;
525 {
531 }
532 #endif
538 #ifdef BYTE_CODE_SAFE
540 #endif
543 /* BYTESTR must have been produced by Emacs 20.2 or the earlier
544 because they produced a raw 8-bit string for byte-code and now
545 such a byte-code string is loaded as multibyte while raw 8-bit
546 characters converted to multibyte form. Thus, now we must
547 convert them back to the originally intended unibyte form. */
550 #ifdef BYTE_CODE_SAFE
552 #endif
557 #if BYTE_MARK_STACK
559 #endif
563 #if BYTE_MAINTAIN_TOP
566 #endif
570 #ifdef BYTE_CODE_SAFE
572 #endif
575 {
582 {
587 /* Too few arguments. */
592 else
593 {
598 }
599 }
601 {
606 }
607 else
608 /* Too many arguments. */
612 }
614 /* We should push some arguments on the stack. */
615 {
617 }
620 {
621 #ifdef BYTE_CODE_SAFE
626 #endif
628 #ifdef BYTE_CODE_METER
632 #else
633 #ifndef BYTE_CODE_THREADED
635 #endif
636 #endif
638 /* The interpreter can be compiled one of two ways: as an
639 ordinary switch-based interpreter, or as a threaded
640 interpreter. The threaded interpreter relies on GCC's
641 computed goto extension, so it is not available everywhere.
642 Threading provides a performance boost. These macros are how
643 we allow the code to be compiled both ways. */
644 #ifdef BYTE_CODE_THREADED
645 /* The CASE macro introduces an instruction's body. It is
646 either a label or a case label. */
647 #define CASE(OP) insn_ ## OP
648 /* NEXT is invoked at the end of an instruction to go to the
649 next instruction. It is either a computed goto, or a
650 plain break. */
651 #define NEXT goto *(targets[op = FETCH])
652 /* FIRST is like NEXT, but is only used at the start of the
653 interpreter body. In the switch-based interpreter it is the
654 switch, so the threaded definition must include a semicolon. */
655 #define FIRST NEXT;
656 /* Most cases are labeled with the CASE macro, above.
657 CASE_DEFAULT is one exception; it is used if the interpreter
658 being built requires a default case. The threaded
659 interpreter does not, because the dispatch table is
660 completely filled. */
661 #define CASE_DEFAULT
662 /* This introduces an instruction that is known to call abort. */
663 #define CASE_ABORT CASE (Bstack_ref): CASE (default)
664 #else
665 /* See above for the meaning of the various defines. */
666 #define CASE(OP) case OP
667 #define NEXT break
668 #define FIRST switch (op)
669 #define CASE_DEFAULT case 255: default:
670 #define CASE_ABORT case 0
671 #endif
673 #ifdef BYTE_CODE_THREADED
675 /* A convenience define that saves us a lot of typing and makes
676 the table clearer. */
677 #define LABEL(OP) [OP] = &&insn_ ## OP
679 #if 4 < __GNUC__ + (6 <= __GNUC_MINOR__)
680 # pragma GCC diagnostic push
682 #elif defined __clang__
683 # pragma GCC diagnostic push
685 #endif
687 /* This is the dispatch table for the threaded interpreter. */
689 {
693 #define DEFINE(name, value) LABEL (name) ,
694 BYTE_CODES
695 #undef DEFINE
696 };
698 #if 4 < __GNUC__ + (6 <= __GNUC_MINOR__) || defined __clang__
699 # pragma GCC diagnostic pop
700 #endif
702 #endif
705 FIRST
706 {
720 /* This seems to be the most frequently executed byte-code
721 among the Bvarref's, so avoid a goto here. */
724 varref:
725 {
730 {
734 {
738 }
739 }
740 else
741 {
745 }
747 NEXT;
748 }
751 {
752 Lisp_Object v1;
757 {
758 BYTE_CODE_QUIT;
761 }
762 NEXT;
763 }
766 {
767 Lisp_Object v1;
773 else
774 {
777 }
778 NEXT;
779 }
782 {
783 Lisp_Object v1;
786 NEXT;
787 }
790 {
791 Lisp_Object v1;
796 NEXT;
797 }
800 {
801 Lisp_Object v1;
807 else
808 {
811 }
812 NEXT;
813 }
830 varset:
831 {
837 /* Inline the most common case. */
843 else
844 {
848 }
849 }
851 NEXT;
854 {
855 Lisp_Object v1;
858 NEXT;
859 }
861 /* ------------------ */
878 varbind:
879 /* Specbind can signal and thus GC. */
883 NEXT;
900 docall:
901 {
904 #ifdef BYTE_CODE_METER
906 {
913 {
916 }
917 }
918 #endif
921 NEXT;
922 }
939 dounbind:
943 NEXT;
946 /* To unbind back to the beginning of this frame. Not used yet,
947 but will be needed for tail-recursion elimination. */
951 NEXT;
955 BYTE_CODE_QUIT;
959 NEXT;
962 {
963 Lisp_Object v1;
968 {
969 BYTE_CODE_QUIT;
972 }
973 NEXT;
974 }
980 {
981 BYTE_CODE_QUIT;
984 }
986 NEXT;
992 {
993 BYTE_CODE_QUIT;
996 }
998 NEXT;
1002 BYTE_CODE_QUIT;
1004 NEXT;
1007 {
1008 Lisp_Object v1;
1012 {
1013 BYTE_CODE_QUIT;
1015 }
1017 NEXT;
1018 }
1021 {
1022 Lisp_Object v1;
1026 {
1027 BYTE_CODE_QUIT;
1029 }
1031 NEXT;
1032 }
1038 {
1039 BYTE_CODE_QUIT;
1041 }
1043 NEXT;
1049 {
1050 BYTE_CODE_QUIT;
1052 }
1054 NEXT;
1062 NEXT;
1066 NEXT;
1071 NEXT;
1076 NEXT;
1079 {
1087 NEXT;
1088 }
1093 NEXT;
1096 {
1097 Lisp_Object v1;
1102 NEXT;
1103 }
1109 {
1111 Lisp_Object tag;
1115 pushhandler:
1124 {
1132 /* Might have been re-set by longjmp! */
1135 }
1137 NEXT;
1138 }
1141 {
1143 NEXT;
1144 }
1147 {
1149 /* Support for a function here is new in 24.4. */
1152 handler);
1153 NEXT;
1154 }
1157 {
1164 NEXT;
1165 }
1173 NEXT;
1176 {
1177 Lisp_Object v1;
1182 /* pop binding of standard-output */
1185 NEXT;
1186 }
1189 {
1191 EMACS_INT n;
1203 NEXT;
1204 }
1208 NEXT;
1212 NEXT;
1216 NEXT;
1220 NEXT;
1224 NEXT;
1227 {
1228 Lisp_Object v1;
1231 NEXT;
1232 }
1236 NEXT;
1239 {
1240 Lisp_Object v1;
1243 NEXT;
1244 }
1249 NEXT;
1254 NEXT;
1260 NEXT;
1266 NEXT;
1269 {
1270 Lisp_Object v1;
1275 NEXT;
1276 }
1279 {
1285 NEXT;
1286 }
1292 NEXT;
1298 NEXT;
1301 {
1302 Lisp_Object v1;
1307 NEXT;
1308 }
1311 {
1312 Lisp_Object v1;
1317 NEXT;
1318 }
1321 {
1322 Lisp_Object v1;
1327 NEXT;
1328 }
1331 {
1337 NEXT;
1338 }
1345 NEXT;
1352 NEXT;
1359 NEXT;
1367 NEXT;
1370 {
1371 Lisp_Object v1;
1374 {
1377 }
1378 else
1379 {
1383 }
1384 NEXT;
1385 }
1388 {
1389 Lisp_Object v1;
1392 {
1395 }
1396 else
1397 {
1401 }
1402 NEXT;
1403 }
1406 {
1414 {
1420 }
1421 else
1423 NEXT;
1424 }
1427 {
1428 Lisp_Object v1;
1433 NEXT;
1434 }
1437 {
1438 Lisp_Object v1;
1443 NEXT;
1444 }
1447 {
1448 Lisp_Object v1;
1453 NEXT;
1454 }
1457 {
1458 Lisp_Object v1;
1463 NEXT;
1464 }
1471 NEXT;
1474 {
1475 Lisp_Object v1;
1478 {
1481 }
1482 else
1483 {
1487 }
1488 NEXT;
1489 }
1496 NEXT;
1503 NEXT;
1510 NEXT;
1517 NEXT;
1524 NEXT;
1527 {
1528 Lisp_Object v1;
1533 NEXT;
1534 }
1537 {
1538 Lisp_Object v1;
1541 NEXT;
1542 }
1548 NEXT;
1554 NEXT;
1562 NEXT;
1565 {
1566 Lisp_Object v1;
1569 NEXT;
1570 }
1573 {
1574 Lisp_Object v1;
1577 NEXT;
1578 }
1584 NEXT;
1587 {
1588 Lisp_Object v1;
1593 NEXT;
1594 }
1597 {
1598 Lisp_Object v1;
1603 NEXT;
1604 }
1607 {
1608 Lisp_Object v1;
1613 NEXT;
1614 }
1620 NEXT;
1624 NEXT;
1628 NEXT;
1632 NEXT;
1636 NEXT;
1640 NEXT;
1646 NEXT;
1652 NEXT;
1658 NEXT;
1664 NEXT;
1667 {
1668 Lisp_Object v1;
1673 NEXT;
1674 }
1677 {
1678 Lisp_Object v1;
1683 NEXT;
1684 }
1690 NEXT;
1693 {
1703 }
1704 NEXT;
1707 {
1708 Lisp_Object v1;
1713 NEXT;
1714 }
1717 {
1718 Lisp_Object v1;
1723 NEXT;
1724 }
1727 {
1728 Lisp_Object v1;
1733 NEXT;
1734 }
1740 NEXT;
1746 NEXT;
1749 {
1756 NEXT;
1757 }
1763 NEXT;
1769 NEXT;
1775 NEXT;
1781 NEXT;
1784 {
1785 Lisp_Object v1;
1790 NEXT;
1791 }
1794 {
1795 Lisp_Object v1;
1800 NEXT;
1801 }
1804 {
1805 Lisp_Object v1;
1808 NEXT;
1809 }
1812 {
1813 Lisp_Object v1;
1818 NEXT;
1819 }
1822 {
1825 {
1826 /* Exchange args and then do nth. */
1827 EMACS_INT n;
1839 }
1840 else
1841 {
1846 }
1847 NEXT;
1848 }
1851 {
1852 Lisp_Object v1;
1857 NEXT;
1858 }
1861 {
1862 Lisp_Object v1;
1867 NEXT;
1868 }
1874 NEXT;
1877 {
1878 Lisp_Object v1;
1883 NEXT;
1884 }
1887 {
1888 Lisp_Object v1;
1893 NEXT;
1894 }
1897 {
1898 Lisp_Object v1;
1901 NEXT;
1902 }
1905 {
1906 Lisp_Object v1;
1909 NEXT;
1910 }
1917 NEXT;
1921 NEXT;
1925 NEXT;
1927 #ifdef BYTE_CODE_SAFE
1928 /* These are intentionally written using 'case' syntax,
1929 because they are incompatible with the threaded
1930 interpreter. */
1942 #endif
1944 CASE_ABORT:
1945 /* Actually this is Bstack_ref with offset 0, but we use Bdup
1946 for that instead. */
1947 /* CASE (Bstack_ref): */
1953 /* Handy byte-codes for lexical binding. */
1959 {
1962 NEXT;
1963 }
1965 {
1968 NEXT;
1969 }
1971 {
1974 NEXT;
1975 }
1977 /* stack-set-0 = discard; stack-set-1 = discard-1-preserve-tos. */
1978 {
1981 NEXT;
1982 }
1984 {
1987 NEXT;
1988 }
1992 {
1995 }
1997 NEXT;
1999 CASE_DEFAULT
2001 #ifdef BYTE_CODE_SAFE
2003 {
2005 }
2007 {
2009 }
2011 #else
2013 #endif
2014 NEXT;
2015 }
2016 }
2018 exit:
2022 /* Binds and unbinds are supposed to be compiled balanced. */
2024 {
2028 }
2031 }
2033 void
2035 {
2038 #ifdef BYTE_CODE_METER
2042 \(aref (aref byte-code-meter 0) CODE) indicates how many times the byte
2043 opcode CODE has been executed.
2044 \(aref (aref byte-code-meter CODE1) CODE2), where CODE1 is not 0,
2045 indicates how many times the byte opcodes CODE1 and CODE2 have been
2050 The variable byte-code-meter indicates how often each byte opcode is used.
2051 If a symbol has a property named `byte-code-meter' whose value is an
2057 {
2062 }
2063 #endif
2064 }