Git 2.16
[git/gitweb.git] / ref-filter.c
blob3f9161707e66be86eabaf7347da23a2450ffdd9f
1 #include "builtin.h"
2 #include "cache.h"
3 #include "parse-options.h"
4 #include "refs.h"
5 #include "wildmatch.h"
6 #include "commit.h"
7 #include "remote.h"
8 #include "color.h"
9 #include "tag.h"
10 #include "quote.h"
11 #include "ref-filter.h"
12 #include "revision.h"
13 #include "utf8.h"
14 #include "git-compat-util.h"
15 #include "version.h"
16 #include "trailer.h"
17 #include "wt-status.h"
18 #include "commit-slab.h"
20 static struct ref_msg {
21 const char *gone;
22 const char *ahead;
23 const char *behind;
24 const char *ahead_behind;
25 } msgs = {
26 /* Untranslated plumbing messages: */
27 "gone",
28 "ahead %d",
29 "behind %d",
30 "ahead %d, behind %d"
33 void setup_ref_filter_porcelain_msg(void)
35 msgs.gone = _("gone");
36 msgs.ahead = _("ahead %d");
37 msgs.behind = _("behind %d");
38 msgs.ahead_behind = _("ahead %d, behind %d");
41 typedef enum { FIELD_STR, FIELD_ULONG, FIELD_TIME } cmp_type;
42 typedef enum { COMPARE_EQUAL, COMPARE_UNEQUAL, COMPARE_NONE } cmp_status;
44 struct align {
45 align_type position;
46 unsigned int width;
49 struct if_then_else {
50 cmp_status cmp_status;
51 const char *str;
52 unsigned int then_atom_seen : 1,
53 else_atom_seen : 1,
54 condition_satisfied : 1;
57 struct refname_atom {
58 enum { R_NORMAL, R_SHORT, R_LSTRIP, R_RSTRIP } option;
59 int lstrip, rstrip;
63 * An atom is a valid field atom listed below, possibly prefixed with
64 * a "*" to denote deref_tag().
66 * We parse given format string and sort specifiers, and make a list
67 * of properties that we need to extract out of objects. ref_array_item
68 * structure will hold an array of values extracted that can be
69 * indexed with the "atom number", which is an index into this
70 * array.
72 static struct used_atom {
73 const char *name;
74 cmp_type type;
75 union {
76 char color[COLOR_MAXLEN];
77 struct align align;
78 struct {
79 enum {
80 RR_REF, RR_TRACK, RR_TRACKSHORT, RR_REMOTE_NAME, RR_REMOTE_REF
81 } option;
82 struct refname_atom refname;
83 unsigned int nobracket : 1, push : 1, push_remote : 1;
84 } remote_ref;
85 struct {
86 enum { C_BARE, C_BODY, C_BODY_DEP, C_LINES, C_SIG, C_SUB, C_TRAILERS } option;
87 struct process_trailer_options trailer_opts;
88 unsigned int nlines;
89 } contents;
90 struct {
91 cmp_status cmp_status;
92 const char *str;
93 } if_then_else;
94 struct {
95 enum { O_FULL, O_LENGTH, O_SHORT } option;
96 unsigned int length;
97 } objectname;
98 struct refname_atom refname;
99 char *head;
100 } u;
101 } *used_atom;
102 static int used_atom_cnt, need_tagged, need_symref;
104 static void color_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *color_value)
106 if (!color_value)
107 die(_("expected format: %%(color:<color>)"));
108 if (color_parse(color_value, atom->u.color) < 0)
109 die(_("unrecognized color: %%(color:%s)"), color_value);
111 * We check this after we've parsed the color, which lets us complain
112 * about syntactically bogus color names even if they won't be used.
114 if (!want_color(format->use_color))
115 color_parse("", atom->u.color);
118 static void refname_atom_parser_internal(struct refname_atom *atom,
119 const char *arg, const char *name)
121 if (!arg)
122 atom->option = R_NORMAL;
123 else if (!strcmp(arg, "short"))
124 atom->option = R_SHORT;
125 else if (skip_prefix(arg, "lstrip=", &arg) ||
126 skip_prefix(arg, "strip=", &arg)) {
127 atom->option = R_LSTRIP;
128 if (strtol_i(arg, 10, &atom->lstrip))
129 die(_("Integer value expected refname:lstrip=%s"), arg);
130 } else if (skip_prefix(arg, "rstrip=", &arg)) {
131 atom->option = R_RSTRIP;
132 if (strtol_i(arg, 10, &atom->rstrip))
133 die(_("Integer value expected refname:rstrip=%s"), arg);
134 } else
135 die(_("unrecognized %%(%s) argument: %s"), name, arg);
138 static void remote_ref_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
140 struct string_list params = STRING_LIST_INIT_DUP;
141 int i;
143 if (!strcmp(atom->name, "push") || starts_with(atom->name, "push:"))
144 atom->u.remote_ref.push = 1;
146 if (!arg) {
147 atom->u.remote_ref.option = RR_REF;
148 refname_atom_parser_internal(&atom->u.remote_ref.refname,
149 arg, atom->name);
150 return;
153 atom->u.remote_ref.nobracket = 0;
154 string_list_split(&params, arg, ',', -1);
156 for (i = 0; i < params.nr; i++) {
157 const char *s = params.items[i].string;
159 if (!strcmp(s, "track"))
160 atom->u.remote_ref.option = RR_TRACK;
161 else if (!strcmp(s, "trackshort"))
162 atom->u.remote_ref.option = RR_TRACKSHORT;
163 else if (!strcmp(s, "nobracket"))
164 atom->u.remote_ref.nobracket = 1;
165 else if (!strcmp(s, "remotename")) {
166 atom->u.remote_ref.option = RR_REMOTE_NAME;
167 atom->u.remote_ref.push_remote = 1;
168 } else if (!strcmp(s, "remoteref")) {
169 atom->u.remote_ref.option = RR_REMOTE_REF;
170 atom->u.remote_ref.push_remote = 1;
171 } else {
172 atom->u.remote_ref.option = RR_REF;
173 refname_atom_parser_internal(&atom->u.remote_ref.refname,
174 arg, atom->name);
178 string_list_clear(&params, 0);
181 static void body_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
183 if (arg)
184 die(_("%%(body) does not take arguments"));
185 atom->u.contents.option = C_BODY_DEP;
188 static void subject_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
190 if (arg)
191 die(_("%%(subject) does not take arguments"));
192 atom->u.contents.option = C_SUB;
195 static void trailers_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
197 struct string_list params = STRING_LIST_INIT_DUP;
198 int i;
200 if (arg) {
201 string_list_split(&params, arg, ',', -1);
202 for (i = 0; i < params.nr; i++) {
203 const char *s = params.items[i].string;
204 if (!strcmp(s, "unfold"))
205 atom->u.contents.trailer_opts.unfold = 1;
206 else if (!strcmp(s, "only"))
207 atom->u.contents.trailer_opts.only_trailers = 1;
208 else
209 die(_("unknown %%(trailers) argument: %s"), s);
212 atom->u.contents.option = C_TRAILERS;
213 string_list_clear(&params, 0);
216 static void contents_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
218 if (!arg)
219 atom->u.contents.option = C_BARE;
220 else if (!strcmp(arg, "body"))
221 atom->u.contents.option = C_BODY;
222 else if (!strcmp(arg, "signature"))
223 atom->u.contents.option = C_SIG;
224 else if (!strcmp(arg, "subject"))
225 atom->u.contents.option = C_SUB;
226 else if (skip_prefix(arg, "trailers", &arg)) {
227 skip_prefix(arg, ":", &arg);
228 trailers_atom_parser(format, atom, *arg ? arg : NULL);
229 } else if (skip_prefix(arg, "lines=", &arg)) {
230 atom->u.contents.option = C_LINES;
231 if (strtoul_ui(arg, 10, &atom->u.contents.nlines))
232 die(_("positive value expected contents:lines=%s"), arg);
233 } else
234 die(_("unrecognized %%(contents) argument: %s"), arg);
237 static void objectname_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
239 if (!arg)
240 atom->u.objectname.option = O_FULL;
241 else if (!strcmp(arg, "short"))
242 atom->u.objectname.option = O_SHORT;
243 else if (skip_prefix(arg, "short=", &arg)) {
244 atom->u.objectname.option = O_LENGTH;
245 if (strtoul_ui(arg, 10, &atom->u.objectname.length) ||
246 atom->u.objectname.length == 0)
247 die(_("positive value expected objectname:short=%s"), arg);
248 if (atom->u.objectname.length < MINIMUM_ABBREV)
249 atom->u.objectname.length = MINIMUM_ABBREV;
250 } else
251 die(_("unrecognized %%(objectname) argument: %s"), arg);
254 static void refname_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
256 refname_atom_parser_internal(&atom->u.refname, arg, atom->name);
259 static align_type parse_align_position(const char *s)
261 if (!strcmp(s, "right"))
262 return ALIGN_RIGHT;
263 else if (!strcmp(s, "middle"))
264 return ALIGN_MIDDLE;
265 else if (!strcmp(s, "left"))
266 return ALIGN_LEFT;
267 return -1;
270 static void align_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
272 struct align *align = &atom->u.align;
273 struct string_list params = STRING_LIST_INIT_DUP;
274 int i;
275 unsigned int width = ~0U;
277 if (!arg)
278 die(_("expected format: %%(align:<width>,<position>)"));
280 align->position = ALIGN_LEFT;
282 string_list_split(&params, arg, ',', -1);
283 for (i = 0; i < params.nr; i++) {
284 const char *s = params.items[i].string;
285 int position;
287 if (skip_prefix(s, "position=", &s)) {
288 position = parse_align_position(s);
289 if (position < 0)
290 die(_("unrecognized position:%s"), s);
291 align->position = position;
292 } else if (skip_prefix(s, "width=", &s)) {
293 if (strtoul_ui(s, 10, &width))
294 die(_("unrecognized width:%s"), s);
295 } else if (!strtoul_ui(s, 10, &width))
297 else if ((position = parse_align_position(s)) >= 0)
298 align->position = position;
299 else
300 die(_("unrecognized %%(align) argument: %s"), s);
303 if (width == ~0U)
304 die(_("positive width expected with the %%(align) atom"));
305 align->width = width;
306 string_list_clear(&params, 0);
309 static void if_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
311 if (!arg) {
312 atom->u.if_then_else.cmp_status = COMPARE_NONE;
313 return;
314 } else if (skip_prefix(arg, "equals=", &atom->u.if_then_else.str)) {
315 atom->u.if_then_else.cmp_status = COMPARE_EQUAL;
316 } else if (skip_prefix(arg, "notequals=", &atom->u.if_then_else.str)) {
317 atom->u.if_then_else.cmp_status = COMPARE_UNEQUAL;
318 } else {
319 die(_("unrecognized %%(if) argument: %s"), arg);
323 static void head_atom_parser(const struct ref_format *format, struct used_atom *atom, const char *arg)
325 atom->u.head = resolve_refdup("HEAD", RESOLVE_REF_READING, NULL, NULL);
328 static struct {
329 const char *name;
330 cmp_type cmp_type;
331 void (*parser)(const struct ref_format *format, struct used_atom *atom, const char *arg);
332 } valid_atom[] = {
333 { "refname" , FIELD_STR, refname_atom_parser },
334 { "objecttype" },
335 { "objectsize", FIELD_ULONG },
336 { "objectname", FIELD_STR, objectname_atom_parser },
337 { "tree" },
338 { "parent" },
339 { "numparent", FIELD_ULONG },
340 { "object" },
341 { "type" },
342 { "tag" },
343 { "author" },
344 { "authorname" },
345 { "authoremail" },
346 { "authordate", FIELD_TIME },
347 { "committer" },
348 { "committername" },
349 { "committeremail" },
350 { "committerdate", FIELD_TIME },
351 { "tagger" },
352 { "taggername" },
353 { "taggeremail" },
354 { "taggerdate", FIELD_TIME },
355 { "creator" },
356 { "creatordate", FIELD_TIME },
357 { "subject", FIELD_STR, subject_atom_parser },
358 { "body", FIELD_STR, body_atom_parser },
359 { "trailers", FIELD_STR, trailers_atom_parser },
360 { "contents", FIELD_STR, contents_atom_parser },
361 { "upstream", FIELD_STR, remote_ref_atom_parser },
362 { "push", FIELD_STR, remote_ref_atom_parser },
363 { "symref", FIELD_STR, refname_atom_parser },
364 { "flag" },
365 { "HEAD", FIELD_STR, head_atom_parser },
366 { "color", FIELD_STR, color_atom_parser },
367 { "align", FIELD_STR, align_atom_parser },
368 { "end" },
369 { "if", FIELD_STR, if_atom_parser },
370 { "then" },
371 { "else" },
374 #define REF_FORMATTING_STATE_INIT { 0, NULL }
376 struct ref_formatting_stack {
377 struct ref_formatting_stack *prev;
378 struct strbuf output;
379 void (*at_end)(struct ref_formatting_stack **stack);
380 void *at_end_data;
383 struct ref_formatting_state {
384 int quote_style;
385 struct ref_formatting_stack *stack;
388 struct atom_value {
389 const char *s;
390 void (*handler)(struct atom_value *atomv, struct ref_formatting_state *state);
391 uintmax_t value; /* used for sorting when not FIELD_STR */
392 struct used_atom *atom;
396 * Used to parse format string and sort specifiers
398 static int parse_ref_filter_atom(const struct ref_format *format,
399 const char *atom, const char *ep)
401 const char *sp;
402 const char *arg;
403 int i, at, atom_len;
405 sp = atom;
406 if (*sp == '*' && sp < ep)
407 sp++; /* deref */
408 if (ep <= sp)
409 die(_("malformed field name: %.*s"), (int)(ep-atom), atom);
411 /* Do we have the atom already used elsewhere? */
412 for (i = 0; i < used_atom_cnt; i++) {
413 int len = strlen(used_atom[i].name);
414 if (len == ep - atom && !memcmp(used_atom[i].name, atom, len))
415 return i;
419 * If the atom name has a colon, strip it and everything after
420 * it off - it specifies the format for this entry, and
421 * shouldn't be used for checking against the valid_atom
422 * table.
424 arg = memchr(sp, ':', ep - sp);
425 atom_len = (arg ? arg : ep) - sp;
427 /* Is the atom a valid one? */
428 for (i = 0; i < ARRAY_SIZE(valid_atom); i++) {
429 int len = strlen(valid_atom[i].name);
430 if (len == atom_len && !memcmp(valid_atom[i].name, sp, len))
431 break;
434 if (ARRAY_SIZE(valid_atom) <= i)
435 die(_("unknown field name: %.*s"), (int)(ep-atom), atom);
437 /* Add it in, including the deref prefix */
438 at = used_atom_cnt;
439 used_atom_cnt++;
440 REALLOC_ARRAY(used_atom, used_atom_cnt);
441 used_atom[at].name = xmemdupz(atom, ep - atom);
442 used_atom[at].type = valid_atom[i].cmp_type;
443 if (arg) {
444 arg = used_atom[at].name + (arg - atom) + 1;
445 if (!*arg) {
447 * Treat empty sub-arguments list as NULL (i.e.,
448 * "%(atom:)" is equivalent to "%(atom)").
450 arg = NULL;
453 memset(&used_atom[at].u, 0, sizeof(used_atom[at].u));
454 if (valid_atom[i].parser)
455 valid_atom[i].parser(format, &used_atom[at], arg);
456 if (*atom == '*')
457 need_tagged = 1;
458 if (!strcmp(valid_atom[i].name, "symref"))
459 need_symref = 1;
460 return at;
463 static void quote_formatting(struct strbuf *s, const char *str, int quote_style)
465 switch (quote_style) {
466 case QUOTE_NONE:
467 strbuf_addstr(s, str);
468 break;
469 case QUOTE_SHELL:
470 sq_quote_buf(s, str);
471 break;
472 case QUOTE_PERL:
473 perl_quote_buf(s, str);
474 break;
475 case QUOTE_PYTHON:
476 python_quote_buf(s, str);
477 break;
478 case QUOTE_TCL:
479 tcl_quote_buf(s, str);
480 break;
484 static void append_atom(struct atom_value *v, struct ref_formatting_state *state)
487 * Quote formatting is only done when the stack has a single
488 * element. Otherwise quote formatting is done on the
489 * element's entire output strbuf when the %(end) atom is
490 * encountered.
492 if (!state->stack->prev)
493 quote_formatting(&state->stack->output, v->s, state->quote_style);
494 else
495 strbuf_addstr(&state->stack->output, v->s);
498 static void push_stack_element(struct ref_formatting_stack **stack)
500 struct ref_formatting_stack *s = xcalloc(1, sizeof(struct ref_formatting_stack));
502 strbuf_init(&s->output, 0);
503 s->prev = *stack;
504 *stack = s;
507 static void pop_stack_element(struct ref_formatting_stack **stack)
509 struct ref_formatting_stack *current = *stack;
510 struct ref_formatting_stack *prev = current->prev;
512 if (prev)
513 strbuf_addbuf(&prev->output, &current->output);
514 strbuf_release(&current->output);
515 free(current);
516 *stack = prev;
519 static void end_align_handler(struct ref_formatting_stack **stack)
521 struct ref_formatting_stack *cur = *stack;
522 struct align *align = (struct align *)cur->at_end_data;
523 struct strbuf s = STRBUF_INIT;
525 strbuf_utf8_align(&s, align->position, align->width, cur->output.buf);
526 strbuf_swap(&cur->output, &s);
527 strbuf_release(&s);
530 static void align_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state)
532 struct ref_formatting_stack *new;
534 push_stack_element(&state->stack);
535 new = state->stack;
536 new->at_end = end_align_handler;
537 new->at_end_data = &atomv->atom->u.align;
540 static void if_then_else_handler(struct ref_formatting_stack **stack)
542 struct ref_formatting_stack *cur = *stack;
543 struct ref_formatting_stack *prev = cur->prev;
544 struct if_then_else *if_then_else = (struct if_then_else *)cur->at_end_data;
546 if (!if_then_else->then_atom_seen)
547 die(_("format: %%(if) atom used without a %%(then) atom"));
549 if (if_then_else->else_atom_seen) {
551 * There is an %(else) atom: we need to drop one state from the
552 * stack, either the %(else) branch if the condition is satisfied, or
553 * the %(then) branch if it isn't.
555 if (if_then_else->condition_satisfied) {
556 strbuf_reset(&cur->output);
557 pop_stack_element(&cur);
558 } else {
559 strbuf_swap(&cur->output, &prev->output);
560 strbuf_reset(&cur->output);
561 pop_stack_element(&cur);
563 } else if (!if_then_else->condition_satisfied) {
565 * No %(else) atom: just drop the %(then) branch if the
566 * condition is not satisfied.
568 strbuf_reset(&cur->output);
571 *stack = cur;
572 free(if_then_else);
575 static void if_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state)
577 struct ref_formatting_stack *new;
578 struct if_then_else *if_then_else = xcalloc(sizeof(struct if_then_else), 1);
580 if_then_else->str = atomv->atom->u.if_then_else.str;
581 if_then_else->cmp_status = atomv->atom->u.if_then_else.cmp_status;
583 push_stack_element(&state->stack);
584 new = state->stack;
585 new->at_end = if_then_else_handler;
586 new->at_end_data = if_then_else;
589 static int is_empty(const char *s)
591 while (*s != '\0') {
592 if (!isspace(*s))
593 return 0;
594 s++;
596 return 1;
599 static void then_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state)
601 struct ref_formatting_stack *cur = state->stack;
602 struct if_then_else *if_then_else = NULL;
604 if (cur->at_end == if_then_else_handler)
605 if_then_else = (struct if_then_else *)cur->at_end_data;
606 if (!if_then_else)
607 die(_("format: %%(then) atom used without an %%(if) atom"));
608 if (if_then_else->then_atom_seen)
609 die(_("format: %%(then) atom used more than once"));
610 if (if_then_else->else_atom_seen)
611 die(_("format: %%(then) atom used after %%(else)"));
612 if_then_else->then_atom_seen = 1;
614 * If the 'equals' or 'notequals' attribute is used then
615 * perform the required comparison. If not, only non-empty
616 * strings satisfy the 'if' condition.
618 if (if_then_else->cmp_status == COMPARE_EQUAL) {
619 if (!strcmp(if_then_else->str, cur->output.buf))
620 if_then_else->condition_satisfied = 1;
621 } else if (if_then_else->cmp_status == COMPARE_UNEQUAL) {
622 if (strcmp(if_then_else->str, cur->output.buf))
623 if_then_else->condition_satisfied = 1;
624 } else if (cur->output.len && !is_empty(cur->output.buf))
625 if_then_else->condition_satisfied = 1;
626 strbuf_reset(&cur->output);
629 static void else_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state)
631 struct ref_formatting_stack *prev = state->stack;
632 struct if_then_else *if_then_else = NULL;
634 if (prev->at_end == if_then_else_handler)
635 if_then_else = (struct if_then_else *)prev->at_end_data;
636 if (!if_then_else)
637 die(_("format: %%(else) atom used without an %%(if) atom"));
638 if (!if_then_else->then_atom_seen)
639 die(_("format: %%(else) atom used without a %%(then) atom"));
640 if (if_then_else->else_atom_seen)
641 die(_("format: %%(else) atom used more than once"));
642 if_then_else->else_atom_seen = 1;
643 push_stack_element(&state->stack);
644 state->stack->at_end_data = prev->at_end_data;
645 state->stack->at_end = prev->at_end;
648 static void end_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state)
650 struct ref_formatting_stack *current = state->stack;
651 struct strbuf s = STRBUF_INIT;
653 if (!current->at_end)
654 die(_("format: %%(end) atom used without corresponding atom"));
655 current->at_end(&state->stack);
657 /* Stack may have been popped within at_end(), hence reset the current pointer */
658 current = state->stack;
661 * Perform quote formatting when the stack element is that of
662 * a supporting atom. If nested then perform quote formatting
663 * only on the topmost supporting atom.
665 if (!current->prev->prev) {
666 quote_formatting(&s, current->output.buf, state->quote_style);
667 strbuf_swap(&current->output, &s);
669 strbuf_release(&s);
670 pop_stack_element(&state->stack);
674 * In a format string, find the next occurrence of %(atom).
676 static const char *find_next(const char *cp)
678 while (*cp) {
679 if (*cp == '%') {
681 * %( is the start of an atom;
682 * %% is a quoted per-cent.
684 if (cp[1] == '(')
685 return cp;
686 else if (cp[1] == '%')
687 cp++; /* skip over two % */
688 /* otherwise this is a singleton, literal % */
690 cp++;
692 return NULL;
696 * Make sure the format string is well formed, and parse out
697 * the used atoms.
699 int verify_ref_format(struct ref_format *format)
701 const char *cp, *sp;
703 format->need_color_reset_at_eol = 0;
704 for (cp = format->format; *cp && (sp = find_next(cp)); ) {
705 const char *color, *ep = strchr(sp, ')');
706 int at;
708 if (!ep)
709 return error(_("malformed format string %s"), sp);
710 /* sp points at "%(" and ep points at the closing ")" */
711 at = parse_ref_filter_atom(format, sp + 2, ep);
712 cp = ep + 1;
714 if (skip_prefix(used_atom[at].name, "color:", &color))
715 format->need_color_reset_at_eol = !!strcmp(color, "reset");
717 if (format->need_color_reset_at_eol && !want_color(format->use_color))
718 format->need_color_reset_at_eol = 0;
719 return 0;
723 * Given an object name, read the object data and size, and return a
724 * "struct object". If the object data we are returning is also borrowed
725 * by the "struct object" representation, set *eaten as well---it is a
726 * signal from parse_object_buffer to us not to free the buffer.
728 static void *get_obj(const struct object_id *oid, struct object **obj, unsigned long *sz, int *eaten)
730 enum object_type type;
731 void *buf = read_sha1_file(oid->hash, &type, sz);
733 if (buf)
734 *obj = parse_object_buffer(oid, type, *sz, buf, eaten);
735 else
736 *obj = NULL;
737 return buf;
740 static int grab_objectname(const char *name, const unsigned char *sha1,
741 struct atom_value *v, struct used_atom *atom)
743 if (starts_with(name, "objectname")) {
744 if (atom->u.objectname.option == O_SHORT) {
745 v->s = xstrdup(find_unique_abbrev(sha1, DEFAULT_ABBREV));
746 return 1;
747 } else if (atom->u.objectname.option == O_FULL) {
748 v->s = xstrdup(sha1_to_hex(sha1));
749 return 1;
750 } else if (atom->u.objectname.option == O_LENGTH) {
751 v->s = xstrdup(find_unique_abbrev(sha1, atom->u.objectname.length));
752 return 1;
753 } else
754 die("BUG: unknown %%(objectname) option");
756 return 0;
759 /* See grab_values */
760 static void grab_common_values(struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
762 int i;
764 for (i = 0; i < used_atom_cnt; i++) {
765 const char *name = used_atom[i].name;
766 struct atom_value *v = &val[i];
767 if (!!deref != (*name == '*'))
768 continue;
769 if (deref)
770 name++;
771 if (!strcmp(name, "objecttype"))
772 v->s = typename(obj->type);
773 else if (!strcmp(name, "objectsize")) {
774 v->value = sz;
775 v->s = xstrfmt("%lu", sz);
777 else if (deref)
778 grab_objectname(name, obj->oid.hash, v, &used_atom[i]);
782 /* See grab_values */
783 static void grab_tag_values(struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
785 int i;
786 struct tag *tag = (struct tag *) obj;
788 for (i = 0; i < used_atom_cnt; i++) {
789 const char *name = used_atom[i].name;
790 struct atom_value *v = &val[i];
791 if (!!deref != (*name == '*'))
792 continue;
793 if (deref)
794 name++;
795 if (!strcmp(name, "tag"))
796 v->s = tag->tag;
797 else if (!strcmp(name, "type") && tag->tagged)
798 v->s = typename(tag->tagged->type);
799 else if (!strcmp(name, "object") && tag->tagged)
800 v->s = xstrdup(oid_to_hex(&tag->tagged->oid));
804 /* See grab_values */
805 static void grab_commit_values(struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
807 int i;
808 struct commit *commit = (struct commit *) obj;
810 for (i = 0; i < used_atom_cnt; i++) {
811 const char *name = used_atom[i].name;
812 struct atom_value *v = &val[i];
813 if (!!deref != (*name == '*'))
814 continue;
815 if (deref)
816 name++;
817 if (!strcmp(name, "tree")) {
818 v->s = xstrdup(oid_to_hex(&commit->tree->object.oid));
820 else if (!strcmp(name, "numparent")) {
821 v->value = commit_list_count(commit->parents);
822 v->s = xstrfmt("%lu", (unsigned long)v->value);
824 else if (!strcmp(name, "parent")) {
825 struct commit_list *parents;
826 struct strbuf s = STRBUF_INIT;
827 for (parents = commit->parents; parents; parents = parents->next) {
828 struct commit *parent = parents->item;
829 if (parents != commit->parents)
830 strbuf_addch(&s, ' ');
831 strbuf_addstr(&s, oid_to_hex(&parent->object.oid));
833 v->s = strbuf_detach(&s, NULL);
838 static const char *find_wholine(const char *who, int wholen, const char *buf, unsigned long sz)
840 const char *eol;
841 while (*buf) {
842 if (!strncmp(buf, who, wholen) &&
843 buf[wholen] == ' ')
844 return buf + wholen + 1;
845 eol = strchr(buf, '\n');
846 if (!eol)
847 return "";
848 eol++;
849 if (*eol == '\n')
850 return ""; /* end of header */
851 buf = eol;
853 return "";
856 static const char *copy_line(const char *buf)
858 const char *eol = strchrnul(buf, '\n');
859 return xmemdupz(buf, eol - buf);
862 static const char *copy_name(const char *buf)
864 const char *cp;
865 for (cp = buf; *cp && *cp != '\n'; cp++) {
866 if (!strncmp(cp, " <", 2))
867 return xmemdupz(buf, cp - buf);
869 return "";
872 static const char *copy_email(const char *buf)
874 const char *email = strchr(buf, '<');
875 const char *eoemail;
876 if (!email)
877 return "";
878 eoemail = strchr(email, '>');
879 if (!eoemail)
880 return "";
881 return xmemdupz(email, eoemail + 1 - email);
884 static char *copy_subject(const char *buf, unsigned long len)
886 char *r = xmemdupz(buf, len);
887 int i;
889 for (i = 0; i < len; i++)
890 if (r[i] == '\n')
891 r[i] = ' ';
893 return r;
896 static void grab_date(const char *buf, struct atom_value *v, const char *atomname)
898 const char *eoemail = strstr(buf, "> ");
899 char *zone;
900 timestamp_t timestamp;
901 long tz;
902 struct date_mode date_mode = { DATE_NORMAL };
903 const char *formatp;
906 * We got here because atomname ends in "date" or "date<something>";
907 * it's not possible that <something> is not ":<format>" because
908 * parse_ref_filter_atom() wouldn't have allowed it, so we can assume that no
909 * ":" means no format is specified, and use the default.
911 formatp = strchr(atomname, ':');
912 if (formatp != NULL) {
913 formatp++;
914 parse_date_format(formatp, &date_mode);
917 if (!eoemail)
918 goto bad;
919 timestamp = parse_timestamp(eoemail + 2, &zone, 10);
920 if (timestamp == TIME_MAX)
921 goto bad;
922 tz = strtol(zone, NULL, 10);
923 if ((tz == LONG_MIN || tz == LONG_MAX) && errno == ERANGE)
924 goto bad;
925 v->s = xstrdup(show_date(timestamp, tz, &date_mode));
926 v->value = timestamp;
927 return;
928 bad:
929 v->s = "";
930 v->value = 0;
933 /* See grab_values */
934 static void grab_person(const char *who, struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
936 int i;
937 int wholen = strlen(who);
938 const char *wholine = NULL;
940 for (i = 0; i < used_atom_cnt; i++) {
941 const char *name = used_atom[i].name;
942 struct atom_value *v = &val[i];
943 if (!!deref != (*name == '*'))
944 continue;
945 if (deref)
946 name++;
947 if (strncmp(who, name, wholen))
948 continue;
949 if (name[wholen] != 0 &&
950 strcmp(name + wholen, "name") &&
951 strcmp(name + wholen, "email") &&
952 !starts_with(name + wholen, "date"))
953 continue;
954 if (!wholine)
955 wholine = find_wholine(who, wholen, buf, sz);
956 if (!wholine)
957 return; /* no point looking for it */
958 if (name[wholen] == 0)
959 v->s = copy_line(wholine);
960 else if (!strcmp(name + wholen, "name"))
961 v->s = copy_name(wholine);
962 else if (!strcmp(name + wholen, "email"))
963 v->s = copy_email(wholine);
964 else if (starts_with(name + wholen, "date"))
965 grab_date(wholine, v, name);
969 * For a tag or a commit object, if "creator" or "creatordate" is
970 * requested, do something special.
972 if (strcmp(who, "tagger") && strcmp(who, "committer"))
973 return; /* "author" for commit object is not wanted */
974 if (!wholine)
975 wholine = find_wholine(who, wholen, buf, sz);
976 if (!wholine)
977 return;
978 for (i = 0; i < used_atom_cnt; i++) {
979 const char *name = used_atom[i].name;
980 struct atom_value *v = &val[i];
981 if (!!deref != (*name == '*'))
982 continue;
983 if (deref)
984 name++;
986 if (starts_with(name, "creatordate"))
987 grab_date(wholine, v, name);
988 else if (!strcmp(name, "creator"))
989 v->s = copy_line(wholine);
993 static void find_subpos(const char *buf, unsigned long sz,
994 const char **sub, unsigned long *sublen,
995 const char **body, unsigned long *bodylen,
996 unsigned long *nonsiglen,
997 const char **sig, unsigned long *siglen)
999 const char *eol;
1000 /* skip past header until we hit empty line */
1001 while (*buf && *buf != '\n') {
1002 eol = strchrnul(buf, '\n');
1003 if (*eol)
1004 eol++;
1005 buf = eol;
1007 /* skip any empty lines */
1008 while (*buf == '\n')
1009 buf++;
1011 /* parse signature first; we might not even have a subject line */
1012 *sig = buf + parse_signature(buf, strlen(buf));
1013 *siglen = strlen(*sig);
1015 /* subject is first non-empty line */
1016 *sub = buf;
1017 /* subject goes to first empty line */
1018 while (buf < *sig && *buf && *buf != '\n') {
1019 eol = strchrnul(buf, '\n');
1020 if (*eol)
1021 eol++;
1022 buf = eol;
1024 *sublen = buf - *sub;
1025 /* drop trailing newline, if present */
1026 if (*sublen && (*sub)[*sublen - 1] == '\n')
1027 *sublen -= 1;
1029 /* skip any empty lines */
1030 while (*buf == '\n')
1031 buf++;
1032 *body = buf;
1033 *bodylen = strlen(buf);
1034 *nonsiglen = *sig - buf;
1038 * If 'lines' is greater than 0, append that many lines from the given
1039 * 'buf' of length 'size' to the given strbuf.
1041 static void append_lines(struct strbuf *out, const char *buf, unsigned long size, int lines)
1043 int i;
1044 const char *sp, *eol;
1045 size_t len;
1047 sp = buf;
1049 for (i = 0; i < lines && sp < buf + size; i++) {
1050 if (i)
1051 strbuf_addstr(out, "\n ");
1052 eol = memchr(sp, '\n', size - (sp - buf));
1053 len = eol ? eol - sp : size - (sp - buf);
1054 strbuf_add(out, sp, len);
1055 if (!eol)
1056 break;
1057 sp = eol + 1;
1061 /* See grab_values */
1062 static void grab_sub_body_contents(struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
1064 int i;
1065 const char *subpos = NULL, *bodypos = NULL, *sigpos = NULL;
1066 unsigned long sublen = 0, bodylen = 0, nonsiglen = 0, siglen = 0;
1068 for (i = 0; i < used_atom_cnt; i++) {
1069 struct used_atom *atom = &used_atom[i];
1070 const char *name = atom->name;
1071 struct atom_value *v = &val[i];
1072 if (!!deref != (*name == '*'))
1073 continue;
1074 if (deref)
1075 name++;
1076 if (strcmp(name, "subject") &&
1077 strcmp(name, "body") &&
1078 !starts_with(name, "trailers") &&
1079 !starts_with(name, "contents"))
1080 continue;
1081 if (!subpos)
1082 find_subpos(buf, sz,
1083 &subpos, &sublen,
1084 &bodypos, &bodylen, &nonsiglen,
1085 &sigpos, &siglen);
1087 if (atom->u.contents.option == C_SUB)
1088 v->s = copy_subject(subpos, sublen);
1089 else if (atom->u.contents.option == C_BODY_DEP)
1090 v->s = xmemdupz(bodypos, bodylen);
1091 else if (atom->u.contents.option == C_BODY)
1092 v->s = xmemdupz(bodypos, nonsiglen);
1093 else if (atom->u.contents.option == C_SIG)
1094 v->s = xmemdupz(sigpos, siglen);
1095 else if (atom->u.contents.option == C_LINES) {
1096 struct strbuf s = STRBUF_INIT;
1097 const char *contents_end = bodylen + bodypos - siglen;
1099 /* Size is the length of the message after removing the signature */
1100 append_lines(&s, subpos, contents_end - subpos, atom->u.contents.nlines);
1101 v->s = strbuf_detach(&s, NULL);
1102 } else if (atom->u.contents.option == C_TRAILERS) {
1103 struct strbuf s = STRBUF_INIT;
1105 /* Format the trailer info according to the trailer_opts given */
1106 format_trailers_from_commit(&s, subpos, &atom->u.contents.trailer_opts);
1108 v->s = strbuf_detach(&s, NULL);
1109 } else if (atom->u.contents.option == C_BARE)
1110 v->s = xstrdup(subpos);
1115 * We want to have empty print-string for field requests
1116 * that do not apply (e.g. "authordate" for a tag object)
1118 static void fill_missing_values(struct atom_value *val)
1120 int i;
1121 for (i = 0; i < used_atom_cnt; i++) {
1122 struct atom_value *v = &val[i];
1123 if (v->s == NULL)
1124 v->s = "";
1129 * val is a list of atom_value to hold returned values. Extract
1130 * the values for atoms in used_atom array out of (obj, buf, sz).
1131 * when deref is false, (obj, buf, sz) is the object that is
1132 * pointed at by the ref itself; otherwise it is the object the
1133 * ref (which is a tag) refers to.
1135 static void grab_values(struct atom_value *val, int deref, struct object *obj, void *buf, unsigned long sz)
1137 grab_common_values(val, deref, obj, buf, sz);
1138 switch (obj->type) {
1139 case OBJ_TAG:
1140 grab_tag_values(val, deref, obj, buf, sz);
1141 grab_sub_body_contents(val, deref, obj, buf, sz);
1142 grab_person("tagger", val, deref, obj, buf, sz);
1143 break;
1144 case OBJ_COMMIT:
1145 grab_commit_values(val, deref, obj, buf, sz);
1146 grab_sub_body_contents(val, deref, obj, buf, sz);
1147 grab_person("author", val, deref, obj, buf, sz);
1148 grab_person("committer", val, deref, obj, buf, sz);
1149 break;
1150 case OBJ_TREE:
1151 /* grab_tree_values(val, deref, obj, buf, sz); */
1152 break;
1153 case OBJ_BLOB:
1154 /* grab_blob_values(val, deref, obj, buf, sz); */
1155 break;
1156 default:
1157 die("Eh? Object of type %d?", obj->type);
1161 static inline char *copy_advance(char *dst, const char *src)
1163 while (*src)
1164 *dst++ = *src++;
1165 return dst;
1168 static const char *lstrip_ref_components(const char *refname, int len)
1170 long remaining = len;
1171 const char *start = refname;
1173 if (len < 0) {
1174 int i;
1175 const char *p = refname;
1177 /* Find total no of '/' separated path-components */
1178 for (i = 0; p[i]; p[i] == '/' ? i++ : *p++)
1181 * The number of components we need to strip is now
1182 * the total minus the components to be left (Plus one
1183 * because we count the number of '/', but the number
1184 * of components is one more than the no of '/').
1186 remaining = i + len + 1;
1189 while (remaining > 0) {
1190 switch (*start++) {
1191 case '\0':
1192 return "";
1193 case '/':
1194 remaining--;
1195 break;
1199 return start;
1202 static const char *rstrip_ref_components(const char *refname, int len)
1204 long remaining = len;
1205 char *start = xstrdup(refname);
1207 if (len < 0) {
1208 int i;
1209 const char *p = refname;
1211 /* Find total no of '/' separated path-components */
1212 for (i = 0; p[i]; p[i] == '/' ? i++ : *p++)
1215 * The number of components we need to strip is now
1216 * the total minus the components to be left (Plus one
1217 * because we count the number of '/', but the number
1218 * of components is one more than the no of '/').
1220 remaining = i + len + 1;
1223 while (remaining-- > 0) {
1224 char *p = strrchr(start, '/');
1225 if (p == NULL)
1226 return "";
1227 else
1228 p[0] = '\0';
1230 return start;
1233 static const char *show_ref(struct refname_atom *atom, const char *refname)
1235 if (atom->option == R_SHORT)
1236 return shorten_unambiguous_ref(refname, warn_ambiguous_refs);
1237 else if (atom->option == R_LSTRIP)
1238 return lstrip_ref_components(refname, atom->lstrip);
1239 else if (atom->option == R_RSTRIP)
1240 return rstrip_ref_components(refname, atom->rstrip);
1241 else
1242 return refname;
1245 static void fill_remote_ref_details(struct used_atom *atom, const char *refname,
1246 struct branch *branch, const char **s)
1248 int num_ours, num_theirs;
1249 if (atom->u.remote_ref.option == RR_REF)
1250 *s = show_ref(&atom->u.remote_ref.refname, refname);
1251 else if (atom->u.remote_ref.option == RR_TRACK) {
1252 if (stat_tracking_info(branch, &num_ours,
1253 &num_theirs, NULL)) {
1254 *s = xstrdup(msgs.gone);
1255 } else if (!num_ours && !num_theirs)
1256 *s = "";
1257 else if (!num_ours)
1258 *s = xstrfmt(msgs.behind, num_theirs);
1259 else if (!num_theirs)
1260 *s = xstrfmt(msgs.ahead, num_ours);
1261 else
1262 *s = xstrfmt(msgs.ahead_behind,
1263 num_ours, num_theirs);
1264 if (!atom->u.remote_ref.nobracket && *s[0]) {
1265 const char *to_free = *s;
1266 *s = xstrfmt("[%s]", *s);
1267 free((void *)to_free);
1269 } else if (atom->u.remote_ref.option == RR_TRACKSHORT) {
1270 if (stat_tracking_info(branch, &num_ours,
1271 &num_theirs, NULL))
1272 return;
1274 if (!num_ours && !num_theirs)
1275 *s = "=";
1276 else if (!num_ours)
1277 *s = "<";
1278 else if (!num_theirs)
1279 *s = ">";
1280 else
1281 *s = "<>";
1282 } else if (atom->u.remote_ref.option == RR_REMOTE_NAME) {
1283 int explicit;
1284 const char *remote = atom->u.remote_ref.push ?
1285 pushremote_for_branch(branch, &explicit) :
1286 remote_for_branch(branch, &explicit);
1287 if (explicit)
1288 *s = xstrdup(remote);
1289 else
1290 *s = "";
1291 } else if (atom->u.remote_ref.option == RR_REMOTE_REF) {
1292 int explicit;
1293 const char *merge;
1295 merge = remote_ref_for_branch(branch, atom->u.remote_ref.push,
1296 &explicit);
1297 if (explicit)
1298 *s = xstrdup(merge);
1299 else
1300 *s = "";
1301 } else
1302 die("BUG: unhandled RR_* enum");
1305 char *get_head_description(void)
1307 struct strbuf desc = STRBUF_INIT;
1308 struct wt_status_state state;
1309 memset(&state, 0, sizeof(state));
1310 wt_status_get_state(&state, 1);
1311 if (state.rebase_in_progress ||
1312 state.rebase_interactive_in_progress)
1313 strbuf_addf(&desc, _("(no branch, rebasing %s)"),
1314 state.branch);
1315 else if (state.bisect_in_progress)
1316 strbuf_addf(&desc, _("(no branch, bisect started on %s)"),
1317 state.branch);
1318 else if (state.detached_from) {
1319 if (state.detached_at)
1321 * TRANSLATORS: make sure this matches "HEAD
1322 * detached at " in wt-status.c
1324 strbuf_addf(&desc, _("(HEAD detached at %s)"),
1325 state.detached_from);
1326 else
1328 * TRANSLATORS: make sure this matches "HEAD
1329 * detached from " in wt-status.c
1331 strbuf_addf(&desc, _("(HEAD detached from %s)"),
1332 state.detached_from);
1334 else
1335 strbuf_addstr(&desc, _("(no branch)"));
1336 free(state.branch);
1337 free(state.onto);
1338 free(state.detached_from);
1339 return strbuf_detach(&desc, NULL);
1342 static const char *get_symref(struct used_atom *atom, struct ref_array_item *ref)
1344 if (!ref->symref)
1345 return "";
1346 else
1347 return show_ref(&atom->u.refname, ref->symref);
1350 static const char *get_refname(struct used_atom *atom, struct ref_array_item *ref)
1352 if (ref->kind & FILTER_REFS_DETACHED_HEAD)
1353 return get_head_description();
1354 return show_ref(&atom->u.refname, ref->refname);
1358 * Parse the object referred by ref, and grab needed value.
1360 static void populate_value(struct ref_array_item *ref)
1362 void *buf;
1363 struct object *obj;
1364 int eaten, i;
1365 unsigned long size;
1366 const struct object_id *tagged;
1368 ref->value = xcalloc(used_atom_cnt, sizeof(struct atom_value));
1370 if (need_symref && (ref->flag & REF_ISSYMREF) && !ref->symref) {
1371 ref->symref = resolve_refdup(ref->refname, RESOLVE_REF_READING,
1372 NULL, NULL);
1373 if (!ref->symref)
1374 ref->symref = "";
1377 /* Fill in specials first */
1378 for (i = 0; i < used_atom_cnt; i++) {
1379 struct used_atom *atom = &used_atom[i];
1380 const char *name = used_atom[i].name;
1381 struct atom_value *v = &ref->value[i];
1382 int deref = 0;
1383 const char *refname;
1384 struct branch *branch = NULL;
1386 v->handler = append_atom;
1387 v->atom = atom;
1389 if (*name == '*') {
1390 deref = 1;
1391 name++;
1394 if (starts_with(name, "refname"))
1395 refname = get_refname(atom, ref);
1396 else if (starts_with(name, "symref"))
1397 refname = get_symref(atom, ref);
1398 else if (starts_with(name, "upstream")) {
1399 const char *branch_name;
1400 /* only local branches may have an upstream */
1401 if (!skip_prefix(ref->refname, "refs/heads/",
1402 &branch_name))
1403 continue;
1404 branch = branch_get(branch_name);
1406 refname = branch_get_upstream(branch, NULL);
1407 if (refname)
1408 fill_remote_ref_details(atom, refname, branch, &v->s);
1409 continue;
1410 } else if (atom->u.remote_ref.push) {
1411 const char *branch_name;
1412 if (!skip_prefix(ref->refname, "refs/heads/",
1413 &branch_name))
1414 continue;
1415 branch = branch_get(branch_name);
1417 if (atom->u.remote_ref.push_remote)
1418 refname = NULL;
1419 else {
1420 refname = branch_get_push(branch, NULL);
1421 if (!refname)
1422 continue;
1424 fill_remote_ref_details(atom, refname, branch, &v->s);
1425 continue;
1426 } else if (starts_with(name, "color:")) {
1427 v->s = atom->u.color;
1428 continue;
1429 } else if (!strcmp(name, "flag")) {
1430 char buf[256], *cp = buf;
1431 if (ref->flag & REF_ISSYMREF)
1432 cp = copy_advance(cp, ",symref");
1433 if (ref->flag & REF_ISPACKED)
1434 cp = copy_advance(cp, ",packed");
1435 if (cp == buf)
1436 v->s = "";
1437 else {
1438 *cp = '\0';
1439 v->s = xstrdup(buf + 1);
1441 continue;
1442 } else if (!deref && grab_objectname(name, ref->objectname.hash, v, atom)) {
1443 continue;
1444 } else if (!strcmp(name, "HEAD")) {
1445 if (atom->u.head && !strcmp(ref->refname, atom->u.head))
1446 v->s = "*";
1447 else
1448 v->s = " ";
1449 continue;
1450 } else if (starts_with(name, "align")) {
1451 v->handler = align_atom_handler;
1452 continue;
1453 } else if (!strcmp(name, "end")) {
1454 v->handler = end_atom_handler;
1455 continue;
1456 } else if (starts_with(name, "if")) {
1457 const char *s;
1459 if (skip_prefix(name, "if:", &s))
1460 v->s = xstrdup(s);
1461 v->handler = if_atom_handler;
1462 continue;
1463 } else if (!strcmp(name, "then")) {
1464 v->handler = then_atom_handler;
1465 continue;
1466 } else if (!strcmp(name, "else")) {
1467 v->handler = else_atom_handler;
1468 continue;
1469 } else
1470 continue;
1472 if (!deref)
1473 v->s = refname;
1474 else
1475 v->s = xstrfmt("%s^{}", refname);
1478 for (i = 0; i < used_atom_cnt; i++) {
1479 struct atom_value *v = &ref->value[i];
1480 if (v->s == NULL)
1481 goto need_obj;
1483 return;
1485 need_obj:
1486 buf = get_obj(&ref->objectname, &obj, &size, &eaten);
1487 if (!buf)
1488 die(_("missing object %s for %s"),
1489 oid_to_hex(&ref->objectname), ref->refname);
1490 if (!obj)
1491 die(_("parse_object_buffer failed on %s for %s"),
1492 oid_to_hex(&ref->objectname), ref->refname);
1494 grab_values(ref->value, 0, obj, buf, size);
1495 if (!eaten)
1496 free(buf);
1499 * If there is no atom that wants to know about tagged
1500 * object, we are done.
1502 if (!need_tagged || (obj->type != OBJ_TAG))
1503 return;
1506 * If it is a tag object, see if we use a value that derefs
1507 * the object, and if we do grab the object it refers to.
1509 tagged = &((struct tag *)obj)->tagged->oid;
1512 * NEEDSWORK: This derefs tag only once, which
1513 * is good to deal with chains of trust, but
1514 * is not consistent with what deref_tag() does
1515 * which peels the onion to the core.
1517 buf = get_obj(tagged, &obj, &size, &eaten);
1518 if (!buf)
1519 die(_("missing object %s for %s"),
1520 oid_to_hex(tagged), ref->refname);
1521 if (!obj)
1522 die(_("parse_object_buffer failed on %s for %s"),
1523 oid_to_hex(tagged), ref->refname);
1524 grab_values(ref->value, 1, obj, buf, size);
1525 if (!eaten)
1526 free(buf);
1530 * Given a ref, return the value for the atom. This lazily gets value
1531 * out of the object by calling populate value.
1533 static void get_ref_atom_value(struct ref_array_item *ref, int atom, struct atom_value **v)
1535 if (!ref->value) {
1536 populate_value(ref);
1537 fill_missing_values(ref->value);
1539 *v = &ref->value[atom];
1543 * Unknown has to be "0" here, because that's the default value for
1544 * contains_cache slab entries that have not yet been assigned.
1546 enum contains_result {
1547 CONTAINS_UNKNOWN = 0,
1548 CONTAINS_NO,
1549 CONTAINS_YES
1552 define_commit_slab(contains_cache, enum contains_result);
1554 struct ref_filter_cbdata {
1555 struct ref_array *array;
1556 struct ref_filter *filter;
1557 struct contains_cache contains_cache;
1558 struct contains_cache no_contains_cache;
1562 * Mimicking the real stack, this stack lives on the heap, avoiding stack
1563 * overflows.
1565 * At each recursion step, the stack items points to the commits whose
1566 * ancestors are to be inspected.
1568 struct contains_stack {
1569 int nr, alloc;
1570 struct contains_stack_entry {
1571 struct commit *commit;
1572 struct commit_list *parents;
1573 } *contains_stack;
1576 static int in_commit_list(const struct commit_list *want, struct commit *c)
1578 for (; want; want = want->next)
1579 if (!oidcmp(&want->item->object.oid, &c->object.oid))
1580 return 1;
1581 return 0;
1585 * Test whether the candidate or one of its parents is contained in the list.
1586 * Do not recurse to find out, though, but return -1 if inconclusive.
1588 static enum contains_result contains_test(struct commit *candidate,
1589 const struct commit_list *want,
1590 struct contains_cache *cache)
1592 enum contains_result *cached = contains_cache_at(cache, candidate);
1594 /* If we already have the answer cached, return that. */
1595 if (*cached)
1596 return *cached;
1598 /* or are we it? */
1599 if (in_commit_list(want, candidate)) {
1600 *cached = CONTAINS_YES;
1601 return CONTAINS_YES;
1604 /* Otherwise, we don't know; prepare to recurse */
1605 parse_commit_or_die(candidate);
1606 return CONTAINS_UNKNOWN;
1609 static void push_to_contains_stack(struct commit *candidate, struct contains_stack *contains_stack)
1611 ALLOC_GROW(contains_stack->contains_stack, contains_stack->nr + 1, contains_stack->alloc);
1612 contains_stack->contains_stack[contains_stack->nr].commit = candidate;
1613 contains_stack->contains_stack[contains_stack->nr++].parents = candidate->parents;
1616 static enum contains_result contains_tag_algo(struct commit *candidate,
1617 const struct commit_list *want,
1618 struct contains_cache *cache)
1620 struct contains_stack contains_stack = { 0, 0, NULL };
1621 enum contains_result result = contains_test(candidate, want, cache);
1623 if (result != CONTAINS_UNKNOWN)
1624 return result;
1626 push_to_contains_stack(candidate, &contains_stack);
1627 while (contains_stack.nr) {
1628 struct contains_stack_entry *entry = &contains_stack.contains_stack[contains_stack.nr - 1];
1629 struct commit *commit = entry->commit;
1630 struct commit_list *parents = entry->parents;
1632 if (!parents) {
1633 *contains_cache_at(cache, commit) = CONTAINS_NO;
1634 contains_stack.nr--;
1637 * If we just popped the stack, parents->item has been marked,
1638 * therefore contains_test will return a meaningful yes/no.
1640 else switch (contains_test(parents->item, want, cache)) {
1641 case CONTAINS_YES:
1642 *contains_cache_at(cache, commit) = CONTAINS_YES;
1643 contains_stack.nr--;
1644 break;
1645 case CONTAINS_NO:
1646 entry->parents = parents->next;
1647 break;
1648 case CONTAINS_UNKNOWN:
1649 push_to_contains_stack(parents->item, &contains_stack);
1650 break;
1653 free(contains_stack.contains_stack);
1654 return contains_test(candidate, want, cache);
1657 static int commit_contains(struct ref_filter *filter, struct commit *commit,
1658 struct commit_list *list, struct contains_cache *cache)
1660 if (filter->with_commit_tag_algo)
1661 return contains_tag_algo(commit, list, cache) == CONTAINS_YES;
1662 return is_descendant_of(commit, list);
1666 * Return 1 if the refname matches one of the patterns, otherwise 0.
1667 * A pattern can be a literal prefix (e.g. a refname "refs/heads/master"
1668 * matches a pattern "refs/heads/mas") or a wildcard (e.g. the same ref
1669 * matches "refs/heads/mas*", too).
1671 static int match_pattern(const struct ref_filter *filter, const char *refname)
1673 const char **patterns = filter->name_patterns;
1674 unsigned flags = 0;
1676 if (filter->ignore_case)
1677 flags |= WM_CASEFOLD;
1680 * When no '--format' option is given we need to skip the prefix
1681 * for matching refs of tags and branches.
1683 (void)(skip_prefix(refname, "refs/tags/", &refname) ||
1684 skip_prefix(refname, "refs/heads/", &refname) ||
1685 skip_prefix(refname, "refs/remotes/", &refname) ||
1686 skip_prefix(refname, "refs/", &refname));
1688 for (; *patterns; patterns++) {
1689 if (!wildmatch(*patterns, refname, flags))
1690 return 1;
1692 return 0;
1696 * Return 1 if the refname matches one of the patterns, otherwise 0.
1697 * A pattern can be path prefix (e.g. a refname "refs/heads/master"
1698 * matches a pattern "refs/heads/" but not "refs/heads/m") or a
1699 * wildcard (e.g. the same ref matches "refs/heads/m*", too).
1701 static int match_name_as_path(const struct ref_filter *filter, const char *refname)
1703 const char **pattern = filter->name_patterns;
1704 int namelen = strlen(refname);
1705 unsigned flags = WM_PATHNAME;
1707 if (filter->ignore_case)
1708 flags |= WM_CASEFOLD;
1710 for (; *pattern; pattern++) {
1711 const char *p = *pattern;
1712 int plen = strlen(p);
1714 if ((plen <= namelen) &&
1715 !strncmp(refname, p, plen) &&
1716 (refname[plen] == '\0' ||
1717 refname[plen] == '/' ||
1718 p[plen-1] == '/'))
1719 return 1;
1720 if (!wildmatch(p, refname, WM_PATHNAME))
1721 return 1;
1723 return 0;
1726 /* Return 1 if the refname matches one of the patterns, otherwise 0. */
1727 static int filter_pattern_match(struct ref_filter *filter, const char *refname)
1729 if (!*filter->name_patterns)
1730 return 1; /* No pattern always matches */
1731 if (filter->match_as_path)
1732 return match_name_as_path(filter, refname);
1733 return match_pattern(filter, refname);
1737 * Find the longest prefix of pattern we can pass to
1738 * `for_each_fullref_in()`, namely the part of pattern preceding the
1739 * first glob character. (Note that `for_each_fullref_in()` is
1740 * perfectly happy working with a prefix that doesn't end at a
1741 * pathname component boundary.)
1743 static void find_longest_prefix(struct strbuf *out, const char *pattern)
1745 const char *p;
1747 for (p = pattern; *p && !is_glob_special(*p); p++)
1750 strbuf_add(out, pattern, p - pattern);
1754 * This is the same as for_each_fullref_in(), but it tries to iterate
1755 * only over the patterns we'll care about. Note that it _doesn't_ do a full
1756 * pattern match, so the callback still has to match each ref individually.
1758 static int for_each_fullref_in_pattern(struct ref_filter *filter,
1759 each_ref_fn cb,
1760 void *cb_data,
1761 int broken)
1763 struct strbuf prefix = STRBUF_INIT;
1764 int ret;
1766 if (!filter->match_as_path) {
1768 * in this case, the patterns are applied after
1769 * prefixes like "refs/heads/" etc. are stripped off,
1770 * so we have to look at everything:
1772 return for_each_fullref_in("", cb, cb_data, broken);
1775 if (!filter->name_patterns[0]) {
1776 /* no patterns; we have to look at everything */
1777 return for_each_fullref_in("", cb, cb_data, broken);
1780 if (filter->name_patterns[1]) {
1782 * multiple patterns; in theory this could still work as long
1783 * as the patterns are disjoint. We'd just make multiple calls
1784 * to for_each_ref(). But if they're not disjoint, we'd end up
1785 * reporting the same ref multiple times. So let's punt on that
1786 * for now.
1788 return for_each_fullref_in("", cb, cb_data, broken);
1791 find_longest_prefix(&prefix, filter->name_patterns[0]);
1793 ret = for_each_fullref_in(prefix.buf, cb, cb_data, broken);
1794 strbuf_release(&prefix);
1795 return ret;
1799 * Given a ref (sha1, refname), check if the ref belongs to the array
1800 * of sha1s. If the given ref is a tag, check if the given tag points
1801 * at one of the sha1s in the given sha1 array.
1802 * the given sha1_array.
1803 * NEEDSWORK:
1804 * 1. Only a single level of inderection is obtained, we might want to
1805 * change this to account for multiple levels (e.g. annotated tags
1806 * pointing to annotated tags pointing to a commit.)
1807 * 2. As the refs are cached we might know what refname peels to without
1808 * the need to parse the object via parse_object(). peel_ref() might be a
1809 * more efficient alternative to obtain the pointee.
1811 static const struct object_id *match_points_at(struct oid_array *points_at,
1812 const struct object_id *oid,
1813 const char *refname)
1815 const struct object_id *tagged_oid = NULL;
1816 struct object *obj;
1818 if (oid_array_lookup(points_at, oid) >= 0)
1819 return oid;
1820 obj = parse_object(oid);
1821 if (!obj)
1822 die(_("malformed object at '%s'"), refname);
1823 if (obj->type == OBJ_TAG)
1824 tagged_oid = &((struct tag *)obj)->tagged->oid;
1825 if (tagged_oid && oid_array_lookup(points_at, tagged_oid) >= 0)
1826 return tagged_oid;
1827 return NULL;
1830 /* Allocate space for a new ref_array_item and copy the objectname and flag to it */
1831 static struct ref_array_item *new_ref_array_item(const char *refname,
1832 const unsigned char *objectname,
1833 int flag)
1835 struct ref_array_item *ref;
1836 FLEX_ALLOC_STR(ref, refname, refname);
1837 hashcpy(ref->objectname.hash, objectname);
1838 ref->flag = flag;
1840 return ref;
1843 static int ref_kind_from_refname(const char *refname)
1845 unsigned int i;
1847 static struct {
1848 const char *prefix;
1849 unsigned int kind;
1850 } ref_kind[] = {
1851 { "refs/heads/" , FILTER_REFS_BRANCHES },
1852 { "refs/remotes/" , FILTER_REFS_REMOTES },
1853 { "refs/tags/", FILTER_REFS_TAGS}
1856 if (!strcmp(refname, "HEAD"))
1857 return FILTER_REFS_DETACHED_HEAD;
1859 for (i = 0; i < ARRAY_SIZE(ref_kind); i++) {
1860 if (starts_with(refname, ref_kind[i].prefix))
1861 return ref_kind[i].kind;
1864 return FILTER_REFS_OTHERS;
1867 static int filter_ref_kind(struct ref_filter *filter, const char *refname)
1869 if (filter->kind == FILTER_REFS_BRANCHES ||
1870 filter->kind == FILTER_REFS_REMOTES ||
1871 filter->kind == FILTER_REFS_TAGS)
1872 return filter->kind;
1873 return ref_kind_from_refname(refname);
1877 * A call-back given to for_each_ref(). Filter refs and keep them for
1878 * later object processing.
1880 static int ref_filter_handler(const char *refname, const struct object_id *oid, int flag, void *cb_data)
1882 struct ref_filter_cbdata *ref_cbdata = cb_data;
1883 struct ref_filter *filter = ref_cbdata->filter;
1884 struct ref_array_item *ref;
1885 struct commit *commit = NULL;
1886 unsigned int kind;
1888 if (flag & REF_BAD_NAME) {
1889 warning(_("ignoring ref with broken name %s"), refname);
1890 return 0;
1893 if (flag & REF_ISBROKEN) {
1894 warning(_("ignoring broken ref %s"), refname);
1895 return 0;
1898 /* Obtain the current ref kind from filter_ref_kind() and ignore unwanted refs. */
1899 kind = filter_ref_kind(filter, refname);
1900 if (!(kind & filter->kind))
1901 return 0;
1903 if (!filter_pattern_match(filter, refname))
1904 return 0;
1906 if (filter->points_at.nr && !match_points_at(&filter->points_at, oid, refname))
1907 return 0;
1910 * A merge filter is applied on refs pointing to commits. Hence
1911 * obtain the commit using the 'oid' available and discard all
1912 * non-commits early. The actual filtering is done later.
1914 if (filter->merge_commit || filter->with_commit || filter->no_commit || filter->verbose) {
1915 commit = lookup_commit_reference_gently(oid, 1);
1916 if (!commit)
1917 return 0;
1918 /* We perform the filtering for the '--contains' option... */
1919 if (filter->with_commit &&
1920 !commit_contains(filter, commit, filter->with_commit, &ref_cbdata->contains_cache))
1921 return 0;
1922 /* ...or for the `--no-contains' option */
1923 if (filter->no_commit &&
1924 commit_contains(filter, commit, filter->no_commit, &ref_cbdata->no_contains_cache))
1925 return 0;
1929 * We do not open the object yet; sort may only need refname
1930 * to do its job and the resulting list may yet to be pruned
1931 * by maxcount logic.
1933 ref = new_ref_array_item(refname, oid->hash, flag);
1934 ref->commit = commit;
1936 REALLOC_ARRAY(ref_cbdata->array->items, ref_cbdata->array->nr + 1);
1937 ref_cbdata->array->items[ref_cbdata->array->nr++] = ref;
1938 ref->kind = kind;
1939 return 0;
1942 /* Free memory allocated for a ref_array_item */
1943 static void free_array_item(struct ref_array_item *item)
1945 free((char *)item->symref);
1946 free(item);
1949 /* Free all memory allocated for ref_array */
1950 void ref_array_clear(struct ref_array *array)
1952 int i;
1954 for (i = 0; i < array->nr; i++)
1955 free_array_item(array->items[i]);
1956 FREE_AND_NULL(array->items);
1957 array->nr = array->alloc = 0;
1960 static void do_merge_filter(struct ref_filter_cbdata *ref_cbdata)
1962 struct rev_info revs;
1963 int i, old_nr;
1964 struct ref_filter *filter = ref_cbdata->filter;
1965 struct ref_array *array = ref_cbdata->array;
1966 struct commit **to_clear = xcalloc(sizeof(struct commit *), array->nr);
1968 init_revisions(&revs, NULL);
1970 for (i = 0; i < array->nr; i++) {
1971 struct ref_array_item *item = array->items[i];
1972 add_pending_object(&revs, &item->commit->object, item->refname);
1973 to_clear[i] = item->commit;
1976 filter->merge_commit->object.flags |= UNINTERESTING;
1977 add_pending_object(&revs, &filter->merge_commit->object, "");
1979 revs.limited = 1;
1980 if (prepare_revision_walk(&revs))
1981 die(_("revision walk setup failed"));
1983 old_nr = array->nr;
1984 array->nr = 0;
1986 for (i = 0; i < old_nr; i++) {
1987 struct ref_array_item *item = array->items[i];
1988 struct commit *commit = item->commit;
1990 int is_merged = !!(commit->object.flags & UNINTERESTING);
1992 if (is_merged == (filter->merge == REF_FILTER_MERGED_INCLUDE))
1993 array->items[array->nr++] = array->items[i];
1994 else
1995 free_array_item(item);
1998 for (i = 0; i < old_nr; i++)
1999 clear_commit_marks(to_clear[i], ALL_REV_FLAGS);
2000 clear_commit_marks(filter->merge_commit, ALL_REV_FLAGS);
2001 free(to_clear);
2005 * API for filtering a set of refs. Based on the type of refs the user
2006 * has requested, we iterate through those refs and apply filters
2007 * as per the given ref_filter structure and finally store the
2008 * filtered refs in the ref_array structure.
2010 int filter_refs(struct ref_array *array, struct ref_filter *filter, unsigned int type)
2012 struct ref_filter_cbdata ref_cbdata;
2013 int ret = 0;
2014 unsigned int broken = 0;
2016 ref_cbdata.array = array;
2017 ref_cbdata.filter = filter;
2019 if (type & FILTER_REFS_INCLUDE_BROKEN)
2020 broken = 1;
2021 filter->kind = type & FILTER_REFS_KIND_MASK;
2023 init_contains_cache(&ref_cbdata.contains_cache);
2024 init_contains_cache(&ref_cbdata.no_contains_cache);
2026 /* Simple per-ref filtering */
2027 if (!filter->kind)
2028 die("filter_refs: invalid type");
2029 else {
2031 * For common cases where we need only branches or remotes or tags,
2032 * we only iterate through those refs. If a mix of refs is needed,
2033 * we iterate over all refs and filter out required refs with the help
2034 * of filter_ref_kind().
2036 if (filter->kind == FILTER_REFS_BRANCHES)
2037 ret = for_each_fullref_in("refs/heads/", ref_filter_handler, &ref_cbdata, broken);
2038 else if (filter->kind == FILTER_REFS_REMOTES)
2039 ret = for_each_fullref_in("refs/remotes/", ref_filter_handler, &ref_cbdata, broken);
2040 else if (filter->kind == FILTER_REFS_TAGS)
2041 ret = for_each_fullref_in("refs/tags/", ref_filter_handler, &ref_cbdata, broken);
2042 else if (filter->kind & FILTER_REFS_ALL)
2043 ret = for_each_fullref_in_pattern(filter, ref_filter_handler, &ref_cbdata, broken);
2044 if (!ret && (filter->kind & FILTER_REFS_DETACHED_HEAD))
2045 head_ref(ref_filter_handler, &ref_cbdata);
2048 clear_contains_cache(&ref_cbdata.contains_cache);
2049 clear_contains_cache(&ref_cbdata.no_contains_cache);
2051 /* Filters that need revision walking */
2052 if (filter->merge_commit)
2053 do_merge_filter(&ref_cbdata);
2055 return ret;
2058 static int cmp_ref_sorting(struct ref_sorting *s, struct ref_array_item *a, struct ref_array_item *b)
2060 struct atom_value *va, *vb;
2061 int cmp;
2062 cmp_type cmp_type = used_atom[s->atom].type;
2063 int (*cmp_fn)(const char *, const char *);
2065 get_ref_atom_value(a, s->atom, &va);
2066 get_ref_atom_value(b, s->atom, &vb);
2067 cmp_fn = s->ignore_case ? strcasecmp : strcmp;
2068 if (s->version)
2069 cmp = versioncmp(va->s, vb->s);
2070 else if (cmp_type == FIELD_STR)
2071 cmp = cmp_fn(va->s, vb->s);
2072 else {
2073 if (va->value < vb->value)
2074 cmp = -1;
2075 else if (va->value == vb->value)
2076 cmp = cmp_fn(a->refname, b->refname);
2077 else
2078 cmp = 1;
2081 return (s->reverse) ? -cmp : cmp;
2084 static int compare_refs(const void *a_, const void *b_, void *ref_sorting)
2086 struct ref_array_item *a = *((struct ref_array_item **)a_);
2087 struct ref_array_item *b = *((struct ref_array_item **)b_);
2088 struct ref_sorting *s;
2090 for (s = ref_sorting; s; s = s->next) {
2091 int cmp = cmp_ref_sorting(s, a, b);
2092 if (cmp)
2093 return cmp;
2095 return 0;
2098 void ref_array_sort(struct ref_sorting *sorting, struct ref_array *array)
2100 QSORT_S(array->items, array->nr, compare_refs, sorting);
2103 static void append_literal(const char *cp, const char *ep, struct ref_formatting_state *state)
2105 struct strbuf *s = &state->stack->output;
2107 while (*cp && (!ep || cp < ep)) {
2108 if (*cp == '%') {
2109 if (cp[1] == '%')
2110 cp++;
2111 else {
2112 int ch = hex2chr(cp + 1);
2113 if (0 <= ch) {
2114 strbuf_addch(s, ch);
2115 cp += 3;
2116 continue;
2120 strbuf_addch(s, *cp);
2121 cp++;
2125 void format_ref_array_item(struct ref_array_item *info,
2126 const struct ref_format *format,
2127 struct strbuf *final_buf)
2129 const char *cp, *sp, *ep;
2130 struct ref_formatting_state state = REF_FORMATTING_STATE_INIT;
2132 state.quote_style = format->quote_style;
2133 push_stack_element(&state.stack);
2135 for (cp = format->format; *cp && (sp = find_next(cp)); cp = ep + 1) {
2136 struct atom_value *atomv;
2138 ep = strchr(sp, ')');
2139 if (cp < sp)
2140 append_literal(cp, sp, &state);
2141 get_ref_atom_value(info,
2142 parse_ref_filter_atom(format, sp + 2, ep),
2143 &atomv);
2144 atomv->handler(atomv, &state);
2146 if (*cp) {
2147 sp = cp + strlen(cp);
2148 append_literal(cp, sp, &state);
2150 if (format->need_color_reset_at_eol) {
2151 struct atom_value resetv;
2152 resetv.s = GIT_COLOR_RESET;
2153 append_atom(&resetv, &state);
2155 if (state.stack->prev)
2156 die(_("format: %%(end) atom missing"));
2157 strbuf_addbuf(final_buf, &state.stack->output);
2158 pop_stack_element(&state.stack);
2161 void show_ref_array_item(struct ref_array_item *info,
2162 const struct ref_format *format)
2164 struct strbuf final_buf = STRBUF_INIT;
2166 format_ref_array_item(info, format, &final_buf);
2167 fwrite(final_buf.buf, 1, final_buf.len, stdout);
2168 strbuf_release(&final_buf);
2169 putchar('\n');
2172 void pretty_print_ref(const char *name, const unsigned char *sha1,
2173 const struct ref_format *format)
2175 struct ref_array_item *ref_item;
2176 ref_item = new_ref_array_item(name, sha1, 0);
2177 ref_item->kind = ref_kind_from_refname(name);
2178 show_ref_array_item(ref_item, format);
2179 free_array_item(ref_item);
2182 static int parse_sorting_atom(const char *atom)
2185 * This parses an atom using a dummy ref_format, since we don't
2186 * actually care about the formatting details.
2188 struct ref_format dummy = REF_FORMAT_INIT;
2189 const char *end = atom + strlen(atom);
2190 return parse_ref_filter_atom(&dummy, atom, end);
2193 /* If no sorting option is given, use refname to sort as default */
2194 struct ref_sorting *ref_default_sorting(void)
2196 static const char cstr_name[] = "refname";
2198 struct ref_sorting *sorting = xcalloc(1, sizeof(*sorting));
2200 sorting->next = NULL;
2201 sorting->atom = parse_sorting_atom(cstr_name);
2202 return sorting;
2205 void parse_ref_sorting(struct ref_sorting **sorting_tail, const char *arg)
2207 struct ref_sorting *s;
2209 s = xcalloc(1, sizeof(*s));
2210 s->next = *sorting_tail;
2211 *sorting_tail = s;
2213 if (*arg == '-') {
2214 s->reverse = 1;
2215 arg++;
2217 if (skip_prefix(arg, "version:", &arg) ||
2218 skip_prefix(arg, "v:", &arg))
2219 s->version = 1;
2220 s->atom = parse_sorting_atom(arg);
2223 int parse_opt_ref_sorting(const struct option *opt, const char *arg, int unset)
2225 if (!arg) /* should --no-sort void the list ? */
2226 return -1;
2227 parse_ref_sorting(opt->value, arg);
2228 return 0;
2231 int parse_opt_merge_filter(const struct option *opt, const char *arg, int unset)
2233 struct ref_filter *rf = opt->value;
2234 struct object_id oid;
2235 int no_merged = starts_with(opt->long_name, "no");
2237 if (rf->merge) {
2238 if (no_merged) {
2239 return opterror(opt, "is incompatible with --merged", 0);
2240 } else {
2241 return opterror(opt, "is incompatible with --no-merged", 0);
2245 rf->merge = no_merged
2246 ? REF_FILTER_MERGED_OMIT
2247 : REF_FILTER_MERGED_INCLUDE;
2249 if (get_oid(arg, &oid))
2250 die(_("malformed object name %s"), arg);
2252 rf->merge_commit = lookup_commit_reference_gently(&oid, 0);
2253 if (!rf->merge_commit)
2254 return opterror(opt, "must point to a commit", 0);
2256 return 0;