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#include "builtin.h"
#include "cache.h"
#include "parse-options.h"
#include "refs.h"
#include "wildmatch.h"
#include "object-store.h"
#include "repository.h"
#include "commit.h"
#include "remote.h"
#include "color.h"
#include "tag.h"
#include "quote.h"
#include "ref-filter.h"
#include "revision.h"
#include "utf8.h"
#include "git-compat-util.h"
#include "version.h"
#include "trailer.h"
#include "wt-status.h"
#include "commit-slab.h"
#include "commit-graph.h"
#include "commit-reach.h"
#include "worktree.h"
#include "hashmap.h"
#include "strvec.h"
static struct ref_msg {
const char *gone;
const char *ahead;
const char *behind;
const char *ahead_behind;
} msgs = {
/* Untranslated plumbing messages: */
"gone",
"ahead %d",
"behind %d",
"ahead %d, behind %d"
};
void setup_ref_filter_porcelain_msg(void)
{
msgs.gone = _("gone");
msgs.ahead = _("ahead %d");
msgs.behind = _("behind %d");
msgs.ahead_behind = _("ahead %d, behind %d");
}
typedef enum { FIELD_STR, FIELD_ULONG, FIELD_TIME } cmp_type;
typedef enum { COMPARE_EQUAL, COMPARE_UNEQUAL, COMPARE_NONE } cmp_status;
typedef enum { SOURCE_NONE = 0, SOURCE_OBJ, SOURCE_OTHER } info_source;
struct align {
align_type position;
unsigned int width;
};
struct if_then_else {
cmp_status cmp_status;
const char *str;
unsigned int then_atom_seen : 1,
else_atom_seen : 1,
condition_satisfied : 1;
};
struct refname_atom {
enum { R_NORMAL, R_SHORT, R_LSTRIP, R_RSTRIP } option;
int lstrip, rstrip;
};
static struct ref_trailer_buf {
struct string_list filter_list;
struct strbuf sepbuf;
struct strbuf kvsepbuf;
} ref_trailer_buf = {STRING_LIST_INIT_NODUP, STRBUF_INIT, STRBUF_INIT};
static struct expand_data {
struct object_id oid;
enum object_type type;
unsigned long size;
off_t disk_size;
struct object_id delta_base_oid;
void *content;
struct object_info info;
} oi, oi_deref;
struct ref_to_worktree_entry {
struct hashmap_entry ent;
struct worktree *wt; /* key is wt->head_ref */
};
static int ref_to_worktree_map_cmpfnc(const void *unused_lookupdata,
const struct hashmap_entry *eptr,
const struct hashmap_entry *kptr,
const void *keydata_aka_refname)
{
const struct ref_to_worktree_entry *e, *k;
e = container_of(eptr, const struct ref_to_worktree_entry, ent);
k = container_of(kptr, const struct ref_to_worktree_entry, ent);
return strcmp(e->wt->head_ref,
keydata_aka_refname ? keydata_aka_refname : k->wt->head_ref);
}
static struct ref_to_worktree_map {
struct hashmap map;
struct worktree **worktrees;
} ref_to_worktree_map;
/*
* The enum atom_type is used as the index of valid_atom array.
* In the atom parsing stage, it will be passed to used_atom.atom_type
* as the identifier of the atom type. We can check the type of used_atom
* entry by `if (used_atom[i].atom_type == ATOM_*)`.
*/
enum atom_type {
ATOM_REFNAME,
ATOM_OBJECTTYPE,
ATOM_OBJECTSIZE,
ATOM_OBJECTNAME,
ATOM_DELTABASE,
ATOM_TREE,
ATOM_PARENT,
ATOM_NUMPARENT,
ATOM_OBJECT,
ATOM_TYPE,
ATOM_TAG,
ATOM_AUTHOR,
ATOM_AUTHORNAME,
ATOM_AUTHOREMAIL,
ATOM_AUTHORDATE,
ATOM_COMMITTER,
ATOM_COMMITTERNAME,
ATOM_COMMITTEREMAIL,
ATOM_COMMITTERDATE,
ATOM_TAGGER,
ATOM_TAGGERNAME,
ATOM_TAGGEREMAIL,
ATOM_TAGGERDATE,
ATOM_CREATOR,
ATOM_CREATORDATE,
ATOM_SUBJECT,
ATOM_BODY,
ATOM_TRAILERS,
ATOM_CONTENTS,
ATOM_RAW,
ATOM_UPSTREAM,
ATOM_PUSH,
ATOM_SYMREF,
ATOM_FLAG,
ATOM_HEAD,
ATOM_COLOR,
ATOM_WORKTREEPATH,
ATOM_ALIGN,
ATOM_END,
ATOM_IF,
ATOM_THEN,
ATOM_ELSE,
ATOM_REST,
};
/*
* An atom is a valid field atom listed below, possibly prefixed with
* a "*" to denote deref_tag().
*
* We parse given format string and sort specifiers, and make a list
* of properties that we need to extract out of objects. ref_array_item
* structure will hold an array of values extracted that can be
* indexed with the "atom number", which is an index into this
* array.
*/
static struct used_atom {
enum atom_type atom_type;
const char *name;
cmp_type type;
info_source source;
union {
char color[COLOR_MAXLEN];
struct align align;
struct {
enum {
RR_REF, RR_TRACK, RR_TRACKSHORT, RR_REMOTE_NAME, RR_REMOTE_REF
} option;
struct refname_atom refname;
unsigned int nobracket : 1, push : 1, push_remote : 1;
} remote_ref;
struct {
enum { C_BARE, C_BODY, C_BODY_DEP, C_LENGTH, C_LINES,
C_SIG, C_SUB, C_SUB_SANITIZE, C_TRAILERS } option;
struct process_trailer_options trailer_opts;
unsigned int nlines;
} contents;
struct {
enum { RAW_BARE, RAW_LENGTH } option;
} raw_data;
struct {
cmp_status cmp_status;
const char *str;
} if_then_else;
struct {
enum { O_FULL, O_LENGTH, O_SHORT } option;
unsigned int length;
} oid;
struct {
enum { O_SIZE, O_SIZE_DISK } option;
} objectsize;
struct email_option {
enum { EO_RAW, EO_TRIM, EO_LOCALPART } option;
} email_option;
struct refname_atom refname;
char *head;
} u;
} *used_atom;
static int used_atom_cnt, need_tagged, need_symref;
/*
* Expand string, append it to strbuf *sb, then return error code ret.
* Allow to save few lines of code.
*/
__attribute__((format (printf, 3, 4)))
static int strbuf_addf_ret(struct strbuf *sb, int ret, const char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
strbuf_vaddf(sb, fmt, ap);
va_end(ap);
return ret;
}
static int color_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *color_value, struct strbuf *err)
{
if (!color_value)
return strbuf_addf_ret(err, -1, _("expected format: %%(color:<color>)"));
if (color_parse(color_value, atom->u.color) < 0)
return strbuf_addf_ret(err, -1, _("unrecognized color: %%(color:%s)"),
color_value);
/*
* We check this after we've parsed the color, which lets us complain
* about syntactically bogus color names even if they won't be used.
*/
if (!want_color(format->use_color))
color_parse("", atom->u.color);
return 0;
}
static int refname_atom_parser_internal(struct refname_atom *atom, const char *arg,
const char *name, struct strbuf *err)
{
if (!arg)
atom->option = R_NORMAL;
else if (!strcmp(arg, "short"))
atom->option = R_SHORT;
else if (skip_prefix(arg, "lstrip=", &arg) ||
skip_prefix(arg, "strip=", &arg)) {
atom->option = R_LSTRIP;
if (strtol_i(arg, 10, &atom->lstrip))
return strbuf_addf_ret(err, -1, _("Integer value expected refname:lstrip=%s"), arg);
} else if (skip_prefix(arg, "rstrip=", &arg)) {
atom->option = R_RSTRIP;
if (strtol_i(arg, 10, &atom->rstrip))
return strbuf_addf_ret(err, -1, _("Integer value expected refname:rstrip=%s"), arg);
} else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), name, arg);
return 0;
}
static int remote_ref_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
struct string_list params = STRING_LIST_INIT_DUP;
int i;
if (!strcmp(atom->name, "push") || starts_with(atom->name, "push:"))
atom->u.remote_ref.push = 1;
if (!arg) {
atom->u.remote_ref.option = RR_REF;
return refname_atom_parser_internal(&atom->u.remote_ref.refname,
arg, atom->name, err);
}
atom->u.remote_ref.nobracket = 0;
string_list_split(¶ms, arg, ',', -1);
for (i = 0; i < params.nr; i++) {
const char *s = params.items[i].string;
if (!strcmp(s, "track"))
atom->u.remote_ref.option = RR_TRACK;
else if (!strcmp(s, "trackshort"))
atom->u.remote_ref.option = RR_TRACKSHORT;
else if (!strcmp(s, "nobracket"))
atom->u.remote_ref.nobracket = 1;
else if (!strcmp(s, "remotename")) {
atom->u.remote_ref.option = RR_REMOTE_NAME;
atom->u.remote_ref.push_remote = 1;
} else if (!strcmp(s, "remoteref")) {
atom->u.remote_ref.option = RR_REMOTE_REF;
atom->u.remote_ref.push_remote = 1;
} else {
atom->u.remote_ref.option = RR_REF;
if (refname_atom_parser_internal(&atom->u.remote_ref.refname,
arg, atom->name, err)) {
string_list_clear(¶ms, 0);
return -1;
}
}
}
string_list_clear(¶ms, 0);
return 0;
}
static int objecttype_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (arg)
return strbuf_addf_ret(err, -1, _("%%(objecttype) does not take arguments"));
if (*atom->name == '*')
oi_deref.info.typep = &oi_deref.type;
else
oi.info.typep = &oi.type;
return 0;
}
static int objectsize_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg) {
atom->u.objectsize.option = O_SIZE;
if (*atom->name == '*')
oi_deref.info.sizep = &oi_deref.size;
else
oi.info.sizep = &oi.size;
} else if (!strcmp(arg, "disk")) {
atom->u.objectsize.option = O_SIZE_DISK;
if (*atom->name == '*')
oi_deref.info.disk_sizep = &oi_deref.disk_size;
else
oi.info.disk_sizep = &oi.disk_size;
} else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), "objectsize", arg);
return 0;
}
static int deltabase_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (arg)
return strbuf_addf_ret(err, -1, _("%%(deltabase) does not take arguments"));
if (*atom->name == '*')
oi_deref.info.delta_base_oid = &oi_deref.delta_base_oid;
else
oi.info.delta_base_oid = &oi.delta_base_oid;
return 0;
}
static int body_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (arg)
return strbuf_addf_ret(err, -1, _("%%(body) does not take arguments"));
atom->u.contents.option = C_BODY_DEP;
return 0;
}
static int subject_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg)
atom->u.contents.option = C_SUB;
else if (!strcmp(arg, "sanitize"))
atom->u.contents.option = C_SUB_SANITIZE;
else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), "subject", arg);
return 0;
}
static int trailers_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
atom->u.contents.trailer_opts.no_divider = 1;
if (arg) {
const char *argbuf = xstrfmt("%s)", arg);
char *invalid_arg = NULL;
if (format_set_trailers_options(&atom->u.contents.trailer_opts,
&ref_trailer_buf.filter_list,
&ref_trailer_buf.sepbuf,
&ref_trailer_buf.kvsepbuf,
&argbuf, &invalid_arg)) {
if (!invalid_arg)
strbuf_addf(err, _("expected %%(trailers:key=<value>)"));
else
strbuf_addf(err, _("unknown %%(trailers) argument: %s"), invalid_arg);
free((char *)invalid_arg);
return -1;
}
}
atom->u.contents.option = C_TRAILERS;
return 0;
}
static int contents_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg)
atom->u.contents.option = C_BARE;
else if (!strcmp(arg, "body"))
atom->u.contents.option = C_BODY;
else if (!strcmp(arg, "size"))
atom->u.contents.option = C_LENGTH;
else if (!strcmp(arg, "signature"))
atom->u.contents.option = C_SIG;
else if (!strcmp(arg, "subject"))
atom->u.contents.option = C_SUB;
else if (!strcmp(arg, "trailers")) {
if (trailers_atom_parser(format, atom, NULL, err))
return -1;
} else if (skip_prefix(arg, "trailers:", &arg)) {
if (trailers_atom_parser(format, atom, arg, err))
return -1;
} else if (skip_prefix(arg, "lines=", &arg)) {
atom->u.contents.option = C_LINES;
if (strtoul_ui(arg, 10, &atom->u.contents.nlines))
return strbuf_addf_ret(err, -1, _("positive value expected contents:lines=%s"), arg);
} else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), "contents", arg);
return 0;
}
static int raw_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg)
atom->u.raw_data.option = RAW_BARE;
else if (!strcmp(arg, "size"))
atom->u.raw_data.option = RAW_LENGTH;
else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), "raw", arg);
return 0;
}
static int oid_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg)
atom->u.oid.option = O_FULL;
else if (!strcmp(arg, "short"))
atom->u.oid.option = O_SHORT;
else if (skip_prefix(arg, "short=", &arg)) {
atom->u.oid.option = O_LENGTH;
if (strtoul_ui(arg, 10, &atom->u.oid.length) ||
atom->u.oid.length == 0)
return strbuf_addf_ret(err, -1, _("positive value expected '%s' in %%(%s)"), arg, atom->name);
if (atom->u.oid.length < MINIMUM_ABBREV)
atom->u.oid.length = MINIMUM_ABBREV;
} else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), atom->name, arg);
return 0;
}
static int person_email_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg)
atom->u.email_option.option = EO_RAW;
else if (!strcmp(arg, "trim"))
atom->u.email_option.option = EO_TRIM;
else if (!strcmp(arg, "localpart"))
atom->u.email_option.option = EO_LOCALPART;
else
return strbuf_addf_ret(err, -1, _("unrecognized email option: %s"), arg);
return 0;
}
static int refname_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
return refname_atom_parser_internal(&atom->u.refname, arg, atom->name, err);
}
static align_type parse_align_position(const char *s)
{
if (!strcmp(s, "right"))
return ALIGN_RIGHT;
else if (!strcmp(s, "middle"))
return ALIGN_MIDDLE;
else if (!strcmp(s, "left"))
return ALIGN_LEFT;
return -1;
}
static int align_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
struct align *align = &atom->u.align;
struct string_list params = STRING_LIST_INIT_DUP;
int i;
unsigned int width = ~0U;
if (!arg)
return strbuf_addf_ret(err, -1, _("expected format: %%(align:<width>,<position>)"));
align->position = ALIGN_LEFT;
string_list_split(¶ms, arg, ',', -1);
for (i = 0; i < params.nr; i++) {
const char *s = params.items[i].string;
int position;
if (skip_prefix(s, "position=", &s)) {
position = parse_align_position(s);
if (position < 0) {
strbuf_addf(err, _("unrecognized position:%s"), s);
string_list_clear(¶ms, 0);
return -1;
}
align->position = position;
} else if (skip_prefix(s, "width=", &s)) {
if (strtoul_ui(s, 10, &width)) {
strbuf_addf(err, _("unrecognized width:%s"), s);
string_list_clear(¶ms, 0);
return -1;
}
} else if (!strtoul_ui(s, 10, &width))
;
else if ((position = parse_align_position(s)) >= 0)
align->position = position;
else {
strbuf_addf(err, _("unrecognized %%(%s) argument: %s"), "align", s);
string_list_clear(¶ms, 0);
return -1;
}
}
if (width == ~0U) {
string_list_clear(¶ms, 0);
return strbuf_addf_ret(err, -1, _("positive width expected with the %%(align) atom"));
}
align->width = width;
string_list_clear(¶ms, 0);
return 0;
}
static int if_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (!arg) {
atom->u.if_then_else.cmp_status = COMPARE_NONE;
return 0;
} else if (skip_prefix(arg, "equals=", &atom->u.if_then_else.str)) {
atom->u.if_then_else.cmp_status = COMPARE_EQUAL;
} else if (skip_prefix(arg, "notequals=", &atom->u.if_then_else.str)) {
atom->u.if_then_else.cmp_status = COMPARE_UNEQUAL;
} else
return strbuf_addf_ret(err, -1, _("unrecognized %%(%s) argument: %s"), "if", arg);
return 0;
}
static int rest_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err)
{
if (arg)
return strbuf_addf_ret(err, -1, _("%%(rest) does not take arguments"));
format->use_rest = 1;
return 0;
}
static int head_atom_parser(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *unused_err)
{
atom->u.head = resolve_refdup("HEAD", RESOLVE_REF_READING, NULL, NULL);
return 0;
}
static struct {
const char *name;
info_source source;
cmp_type cmp_type;
int (*parser)(struct ref_format *format, struct used_atom *atom,
const char *arg, struct strbuf *err);
} valid_atom[] = {
[ATOM_REFNAME] = { "refname", SOURCE_NONE, FIELD_STR, refname_atom_parser },
[ATOM_OBJECTTYPE] = { "objecttype", SOURCE_OTHER, FIELD_STR, objecttype_atom_parser },
[ATOM_OBJECTSIZE] = { "objectsize", SOURCE_OTHER, FIELD_ULONG, objectsize_atom_parser },
[ATOM_OBJECTNAME] = { "objectname", SOURCE_OTHER, FIELD_STR, oid_atom_parser },
[ATOM_DELTABASE] = { "deltabase", SOURCE_OTHER, FIELD_STR, deltabase_atom_parser },
[ATOM_TREE] = { "tree", SOURCE_OBJ, FIELD_STR, oid_atom_parser },
[ATOM_PARENT] = { "parent", SOURCE_OBJ, FIELD_STR, oid_atom_parser },
[ATOM_NUMPARENT] = { "numparent", SOURCE_OBJ, FIELD_ULONG },
[ATOM_OBJECT] = { "object", SOURCE_OBJ },
[ATOM_TYPE] = { "type", SOURCE_OBJ },
[ATOM_TAG] = { "tag", SOURCE_OBJ },
[ATOM_AUTHOR] = { "author", SOURCE_OBJ },
[ATOM_AUTHORNAME] = { "authorname", SOURCE_OBJ },
[ATOM_AUTHOREMAIL] = { "authoremail", SOURCE_OBJ, FIELD_STR, person_email_atom_parser },
[ATOM_AUTHORDATE] = { "authordate", SOURCE_OBJ, FIELD_TIME },
[ATOM_COMMITTER] = { "committer", SOURCE_OBJ },
[ATOM_COMMITTERNAME] = { "committername", SOURCE_OBJ },
[ATOM_COMMITTEREMAIL] = { "committeremail", SOURCE_OBJ, FIELD_STR, person_email_atom_parser },
[ATOM_COMMITTERDATE] = { "committerdate", SOURCE_OBJ, FIELD_TIME },
[ATOM_TAGGER] = { "tagger", SOURCE_OBJ },
[ATOM_TAGGERNAME] = { "taggername", SOURCE_OBJ },
[ATOM_TAGGEREMAIL] = { "taggeremail", SOURCE_OBJ, FIELD_STR, person_email_atom_parser },
[ATOM_TAGGERDATE] = { "taggerdate", SOURCE_OBJ, FIELD_TIME },
[ATOM_CREATOR] = { "creator", SOURCE_OBJ },
[ATOM_CREATORDATE] = { "creatordate", SOURCE_OBJ, FIELD_TIME },
[ATOM_SUBJECT] = { "subject", SOURCE_OBJ, FIELD_STR, subject_atom_parser },
[ATOM_BODY] = { "body", SOURCE_OBJ, FIELD_STR, body_atom_parser },
[ATOM_TRAILERS] = { "trailers", SOURCE_OBJ, FIELD_STR, trailers_atom_parser },
[ATOM_CONTENTS] = { "contents", SOURCE_OBJ, FIELD_STR, contents_atom_parser },
[ATOM_RAW] = { "raw", SOURCE_OBJ, FIELD_STR, raw_atom_parser },
[ATOM_UPSTREAM] = { "upstream", SOURCE_NONE, FIELD_STR, remote_ref_atom_parser },
[ATOM_PUSH] = { "push", SOURCE_NONE, FIELD_STR, remote_ref_atom_parser },
[ATOM_SYMREF] = { "symref", SOURCE_NONE, FIELD_STR, refname_atom_parser },
[ATOM_FLAG] = { "flag", SOURCE_NONE },
[ATOM_HEAD] = { "HEAD", SOURCE_NONE, FIELD_STR, head_atom_parser },
[ATOM_COLOR] = { "color", SOURCE_NONE, FIELD_STR, color_atom_parser },
[ATOM_WORKTREEPATH] = { "worktreepath", SOURCE_NONE },
[ATOM_ALIGN] = { "align", SOURCE_NONE, FIELD_STR, align_atom_parser },
[ATOM_END] = { "end", SOURCE_NONE },
[ATOM_IF] = { "if", SOURCE_NONE, FIELD_STR, if_atom_parser },
[ATOM_THEN] = { "then", SOURCE_NONE },
[ATOM_ELSE] = { "else", SOURCE_NONE },
[ATOM_REST] = { "rest", SOURCE_NONE, FIELD_STR, rest_atom_parser },
/*
* Please update $__git_ref_fieldlist in git-completion.bash
* when you add new atoms
*/
};
#define REF_FORMATTING_STATE_INIT { 0 }
struct ref_formatting_stack {
struct ref_formatting_stack *prev;
struct strbuf output;
void (*at_end)(struct ref_formatting_stack **stack);
void *at_end_data;
};
struct ref_formatting_state {
int quote_style;
struct ref_formatting_stack *stack;
};
struct atom_value {
const char *s;
ssize_t s_size;
int (*handler)(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *err);
uintmax_t value; /* used for sorting when not FIELD_STR */
struct used_atom *atom;
};
#define ATOM_SIZE_UNSPECIFIED (-1)
#define ATOM_VALUE_INIT { \
.s_size = ATOM_SIZE_UNSPECIFIED \
}
/*
* Used to parse format string and sort specifiers
*/
static int parse_ref_filter_atom(struct ref_format *format,
const char *atom, const char *ep,
struct strbuf *err)
{
const char *sp;
const char *arg;
int i, at, atom_len;
sp = atom;
if (*sp == '*' && sp < ep)
sp++; /* deref */
if (ep <= sp)
return strbuf_addf_ret(err, -1, _("malformed field name: %.*s"),
(int)(ep-atom), atom);
/*
* If the atom name has a colon, strip it and everything after
* it off - it specifies the format for this entry, and
* shouldn't be used for checking against the valid_atom
* table.
*/
arg = memchr(sp, ':', ep - sp);
atom_len = (arg ? arg : ep) - sp;
/* Do we have the atom already used elsewhere? */
for (i = 0; i < used_atom_cnt; i++) {
int len = strlen(used_atom[i].name);
if (len == ep - atom && !memcmp(used_atom[i].name, atom, len))
return i;
}
/* Is the atom a valid one? */
for (i = 0; i < ARRAY_SIZE(valid_atom); i++) {
int len = strlen(valid_atom[i].name);
if (len == atom_len && !memcmp(valid_atom[i].name, sp, len))
break;
}
if (ARRAY_SIZE(valid_atom) <= i)
return strbuf_addf_ret(err, -1, _("unknown field name: %.*s"),
(int)(ep-atom), atom);
if (valid_atom[i].source != SOURCE_NONE && !have_git_dir())
return strbuf_addf_ret(err, -1,
_("not a git repository, but the field '%.*s' requires access to object data"),
(int)(ep-atom), atom);
/* Add it in, including the deref prefix */
at = used_atom_cnt;
used_atom_cnt++;
REALLOC_ARRAY(used_atom, used_atom_cnt);
used_atom[at].atom_type = i;
used_atom[at].name = xmemdupz(atom, ep - atom);
used_atom[at].type = valid_atom[i].cmp_type;
used_atom[at].source = valid_atom[i].source;
if (used_atom[at].source == SOURCE_OBJ) {
if (*atom == '*')
oi_deref.info.contentp = &oi_deref.content;
else
oi.info.contentp = &oi.content;
}
if (arg) {
arg = used_atom[at].name + (arg - atom) + 1;
if (!*arg) {
/*
* Treat empty sub-arguments list as NULL (i.e.,
* "%(atom:)" is equivalent to "%(atom)").
*/
arg = NULL;
}
}
memset(&used_atom[at].u, 0, sizeof(used_atom[at].u));
if (valid_atom[i].parser && valid_atom[i].parser(format, &used_atom[at], arg, err))
return -1;
if (*atom == '*')
need_tagged = 1;
if (i == ATOM_SYMREF)
need_symref = 1;
return at;
}
static void quote_formatting(struct strbuf *s, const char *str, ssize_t len, int quote_style)
{
switch (quote_style) {
case QUOTE_NONE:
if (len < 0)
strbuf_addstr(s, str);
else
strbuf_add(s, str, len);
break;
case QUOTE_SHELL:
sq_quote_buf(s, str);
break;
case QUOTE_PERL:
if (len < 0)
perl_quote_buf(s, str);
else
perl_quote_buf_with_len(s, str, len);
break;
case QUOTE_PYTHON:
python_quote_buf(s, str);
break;
case QUOTE_TCL:
tcl_quote_buf(s, str);
break;
}
}
static int append_atom(struct atom_value *v, struct ref_formatting_state *state,
struct strbuf *unused_err)
{
/*
* Quote formatting is only done when the stack has a single
* element. Otherwise quote formatting is done on the
* element's entire output strbuf when the %(end) atom is
* encountered.
*/
if (!state->stack->prev)
quote_formatting(&state->stack->output, v->s, v->s_size, state->quote_style);
else if (v->s_size < 0)
strbuf_addstr(&state->stack->output, v->s);
else
strbuf_add(&state->stack->output, v->s, v->s_size);
return 0;
}
static void push_stack_element(struct ref_formatting_stack **stack)
{
struct ref_formatting_stack *s = xcalloc(1, sizeof(struct ref_formatting_stack));
strbuf_init(&s->output, 0);
s->prev = *stack;
*stack = s;
}
static void pop_stack_element(struct ref_formatting_stack **stack)
{
struct ref_formatting_stack *current = *stack;
struct ref_formatting_stack *prev = current->prev;
if (prev)
strbuf_addbuf(&prev->output, ¤t->output);
strbuf_release(¤t->output);
free(current);
*stack = prev;
}
static void end_align_handler(struct ref_formatting_stack **stack)
{
struct ref_formatting_stack *cur = *stack;
struct align *align = (struct align *)cur->at_end_data;
struct strbuf s = STRBUF_INIT;
strbuf_utf8_align(&s, align->position, align->width, cur->output.buf);
strbuf_swap(&cur->output, &s);
strbuf_release(&s);
}
static int align_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *unused_err)
{
struct ref_formatting_stack *new_stack;
push_stack_element(&state->stack);
new_stack = state->stack;
new_stack->at_end = end_align_handler;
new_stack->at_end_data = &atomv->atom->u.align;
return 0;
}
static void if_then_else_handler(struct ref_formatting_stack **stack)
{
struct ref_formatting_stack *cur = *stack;
struct ref_formatting_stack *prev = cur->prev;
struct if_then_else *if_then_else = (struct if_then_else *)cur->at_end_data;
if (!if_then_else->then_atom_seen)
die(_("format: %%(%s) atom used without a %%(%s) atom"), "if", "then");
if (if_then_else->else_atom_seen) {
/*
* There is an %(else) atom: we need to drop one state from the
* stack, either the %(else) branch if the condition is satisfied, or
* the %(then) branch if it isn't.
*/
if (if_then_else->condition_satisfied) {
strbuf_reset(&cur->output);
pop_stack_element(&cur);
} else {
strbuf_swap(&cur->output, &prev->output);
strbuf_reset(&cur->output);
pop_stack_element(&cur);
}
} else if (!if_then_else->condition_satisfied) {
/*
* No %(else) atom: just drop the %(then) branch if the
* condition is not satisfied.
*/
strbuf_reset(&cur->output);
}
*stack = cur;
free(if_then_else);
}
static int if_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *unused_err)
{
struct ref_formatting_stack *new_stack;
struct if_then_else *if_then_else = xcalloc(1,
sizeof(struct if_then_else));
if_then_else->str = atomv->atom->u.if_then_else.str;
if_then_else->cmp_status = atomv->atom->u.if_then_else.cmp_status;
push_stack_element(&state->stack);
new_stack = state->stack;
new_stack->at_end = if_then_else_handler;
new_stack->at_end_data = if_then_else;
return 0;
}
static int is_empty(struct strbuf *buf)
{
const char *cur = buf->buf;
const char *end = buf->buf + buf->len;
while (cur != end && (isspace(*cur)))
cur++;
return cur == end;
}
static int then_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *err)
{
struct ref_formatting_stack *cur = state->stack;
struct if_then_else *if_then_else = NULL;
size_t str_len = 0;
if (cur->at_end == if_then_else_handler)
if_then_else = (struct if_then_else *)cur->at_end_data;
if (!if_then_else)
return strbuf_addf_ret(err, -1, _("format: %%(%s) atom used without a %%(%s) atom"), "then", "if");
if (if_then_else->then_atom_seen)
return strbuf_addf_ret(err, -1, _("format: %%(then) atom used more than once"));
if (if_then_else->else_atom_seen)
return strbuf_addf_ret(err, -1, _("format: %%(then) atom used after %%(else)"));
if_then_else->then_atom_seen = 1;
if (if_then_else->str)
str_len = strlen(if_then_else->str);
/*
* If the 'equals' or 'notequals' attribute is used then
* perform the required comparison. If not, only non-empty
* strings satisfy the 'if' condition.
*/
if (if_then_else->cmp_status == COMPARE_EQUAL) {
if (str_len == cur->output.len &&
!memcmp(if_then_else->str, cur->output.buf, cur->output.len))
if_then_else->condition_satisfied = 1;
} else if (if_then_else->cmp_status == COMPARE_UNEQUAL) {
if (str_len != cur->output.len ||
memcmp(if_then_else->str, cur->output.buf, cur->output.len))
if_then_else->condition_satisfied = 1;
} else if (cur->output.len && !is_empty(&cur->output))
if_then_else->condition_satisfied = 1;
strbuf_reset(&cur->output);
return 0;
}
static int else_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *err)
{
struct ref_formatting_stack *prev = state->stack;
struct if_then_else *if_then_else = NULL;
if (prev->at_end == if_then_else_handler)
if_then_else = (struct if_then_else *)prev->at_end_data;
if (!if_then_else)
return strbuf_addf_ret(err, -1, _("format: %%(%s) atom used without a %%(%s) atom"), "else", "if");
if (!if_then_else->then_atom_seen)
return strbuf_addf_ret(err, -1, _("format: %%(%s) atom used without a %%(%s) atom"), "else", "then");
if (if_then_else->else_atom_seen)
return strbuf_addf_ret(err, -1, _("format: %%(else) atom used more than once"));
if_then_else->else_atom_seen = 1;
push_stack_element(&state->stack);
state->stack->at_end_data = prev->at_end_data;
state->stack->at_end = prev->at_end;
return 0;
}
static int end_atom_handler(struct atom_value *atomv, struct ref_formatting_state *state,
struct strbuf *err)
{
struct ref_formatting_stack *current = state->stack;
struct strbuf s = STRBUF_INIT;
if (!current->at_end)
return strbuf_addf_ret(err, -1, _("format: %%(end) atom used without corresponding atom"));
current->at_end(&state->stack);
/* Stack may have been popped within at_end(), hence reset the current pointer */
current = state->stack;
/*
* Perform quote formatting when the stack element is that of
* a supporting atom. If nested then perform quote formatting
* only on the topmost supporting atom.
*/
if (!current->prev->prev) {
quote_formatting(&s, current->output.buf, current->output.len, state->quote_style);
strbuf_swap(¤t->output, &s);
}
strbuf_release(&s);
pop_stack_element(&state->stack);
return 0;
}
/*
* In a format string, find the next occurrence of %(atom).
*/
static const char *find_next(const char *cp)
{
while (*cp) {
if (*cp == '%') {
/*
* %( is the start of an atom;
* %% is a quoted per-cent.
*/
if (cp[1] == '(')
return cp;
else if (cp[1] == '%')
cp++; /* skip over two % */
/* otherwise this is a singleton, literal % */
}
cp++;
}
return NULL;
}
static int reject_atom(enum atom_type atom_type)
{
return atom_type == ATOM_REST;
}
/*
* Make sure the format string is well formed, and parse out
* the used atoms.
*/
int verify_ref_format(struct ref_format *format)
{
const char *cp, *sp;
format->need_color_reset_at_eol = 0;
for (cp = format->format; *cp && (sp = find_next(cp)); ) {
struct strbuf err = STRBUF_INIT;
const char *color, *ep = strchr(sp, ')');
int at;
if (!ep)
return error(_("malformed format string %s"), sp);
/* sp points at "%(" and ep points at the closing ")" */
at = parse_ref_filter_atom(format, sp + 2, ep, &err);
if (at < 0)
die("%s", err.buf);
if (reject_atom(used_atom[at].atom_type))
die(_("this command reject atom %%(%.*s)"), (int)(ep - sp - 2), sp + 2);
if ((format->quote_style == QUOTE_PYTHON ||
format->quote_style == QUOTE_SHELL ||
format->quote_style == QUOTE_TCL) &&
used_atom[at].atom_type == ATOM_RAW &&
used_atom[at].u.raw_data.option == RAW_BARE)
die(_("--format=%.*s cannot be used with "
"--python, --shell, --tcl"), (int)(ep - sp - 2), sp + 2);
cp = ep + 1;
if (skip_prefix(used_atom[at].name, "color:", &color))
format->need_color_reset_at_eol = !!strcmp(color, "reset");
strbuf_release(&err);
}
if (format->need_color_reset_at_eol && !want_color(format->use_color))
format->need_color_reset_at_eol = 0;
return 0;
}
static const char *do_grab_oid(const char *field, const struct object_id *oid,
struct used_atom *atom)
{
switch (atom->u.oid.option) {
case O_FULL:
return oid_to_hex(oid);
case O_LENGTH:
return find_unique_abbrev(oid, atom->u.oid.length);
case O_SHORT:
return find_unique_abbrev(oid, DEFAULT_ABBREV);
default:
BUG("unknown %%(%s) option", field);
}
}
static int grab_oid(const char *name, const char *field, const struct object_id *oid,
struct atom_value *v, struct used_atom *atom)
{
if (starts_with(name, field)) {
v->s = xstrdup(do_grab_oid(field, oid, atom));
return 1;
}
return 0;
}
/* See grab_values */
static void grab_common_values(struct atom_value *val, int deref, struct expand_data *oi)
{
int i;
for (i = 0; i < used_atom_cnt; i++) {
const char *name = used_atom[i].name;
enum atom_type atom_type = used_atom[i].atom_type;
struct atom_value *v = &val[i];
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (atom_type == ATOM_OBJECTTYPE)
v->s = xstrdup(type_name(oi->type));
else if (atom_type == ATOM_OBJECTSIZE) {
if (used_atom[i].u.objectsize.option == O_SIZE_DISK) {
v->value = oi->disk_size;
v->s = xstrfmt("%"PRIuMAX, (uintmax_t)oi->disk_size);
} else if (used_atom[i].u.objectsize.option == O_SIZE) {
v->value = oi->size;
v->s = xstrfmt("%"PRIuMAX , (uintmax_t)oi->size);
}
} else if (atom_type == ATOM_DELTABASE)
v->s = xstrdup(oid_to_hex(&oi->delta_base_oid));
else if (atom_type == ATOM_OBJECTNAME && deref)
grab_oid(name, "objectname", &oi->oid, v, &used_atom[i]);
}
}
/* See grab_values */
static void grab_tag_values(struct atom_value *val, int deref, struct object *obj)
{
int i;
struct tag *tag = (struct tag *) obj;
for (i = 0; i < used_atom_cnt; i++) {
const char *name = used_atom[i].name;
enum atom_type atom_type = used_atom[i].atom_type;
struct atom_value *v = &val[i];
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (atom_type == ATOM_TAG)
v->s = xstrdup(tag->tag);
else if (atom_type == ATOM_TYPE && tag->tagged)
v->s = xstrdup(type_name(tag->tagged->type));
else if (atom_type == ATOM_OBJECT && tag->tagged)
v->s = xstrdup(oid_to_hex(&tag->tagged->oid));
}
}
/* See grab_values */
static void grab_commit_values(struct atom_value *val, int deref, struct object *obj)
{
int i;
struct commit *commit = (struct commit *) obj;
for (i = 0; i < used_atom_cnt; i++) {
const char *name = used_atom[i].name;
enum atom_type atom_type = used_atom[i].atom_type;
struct atom_value *v = &val[i];
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (atom_type == ATOM_TREE &&
grab_oid(name, "tree", get_commit_tree_oid(commit), v, &used_atom[i]))
continue;
if (atom_type == ATOM_NUMPARENT) {
v->value = commit_list_count(commit->parents);
v->s = xstrfmt("%lu", (unsigned long)v->value);
}
else if (atom_type == ATOM_PARENT) {
struct commit_list *parents;
struct strbuf s = STRBUF_INIT;
for (parents = commit->parents; parents; parents = parents->next) {
struct object_id *oid = &parents->item->object.oid;
if (parents != commit->parents)
strbuf_addch(&s, ' ');
strbuf_addstr(&s, do_grab_oid("parent", oid, &used_atom[i]));
}
v->s = strbuf_detach(&s, NULL);
}
}
}
static const char *find_wholine(const char *who, int wholen, const char *buf)
{
const char *eol;
while (*buf) {
if (!strncmp(buf, who, wholen) &&
buf[wholen] == ' ')
return buf + wholen + 1;
eol = strchr(buf, '\n');
if (!eol)
return "";
eol++;
if (*eol == '\n')
return ""; /* end of header */
buf = eol;
}
return "";
}
static const char *copy_line(const char *buf)
{
const char *eol = strchrnul(buf, '\n');
return xmemdupz(buf, eol - buf);
}
static const char *copy_name(const char *buf)
{
const char *cp;
for (cp = buf; *cp && *cp != '\n'; cp++) {
if (!strncmp(cp, " <", 2))
return xmemdupz(buf, cp - buf);
}
return xstrdup("");
}
static const char *copy_email(const char *buf, struct used_atom *atom)
{
const char *email = strchr(buf, '<');
const char *eoemail;
if (!email)
return xstrdup("");
switch (atom->u.email_option.option) {
case EO_RAW:
eoemail = strchr(email, '>');
if (eoemail)
eoemail++;
break;
case EO_TRIM:
email++;
eoemail = strchr(email, '>');
break;
case EO_LOCALPART:
email++;
eoemail = strchr(email, '@');
if (!eoemail)
eoemail = strchr(email, '>');
break;
default:
BUG("unknown email option");
}
if (!eoemail)
return xstrdup("");
return xmemdupz(email, eoemail - email);
}
static char *copy_subject(const char *buf, unsigned long len)
{
struct strbuf sb = STRBUF_INIT;
int i;
for (i = 0; i < len; i++) {
if (buf[i] == '\r' && i + 1 < len && buf[i + 1] == '\n')
continue; /* ignore CR in CRLF */
if (buf[i] == '\n')
strbuf_addch(&sb, ' ');
else
strbuf_addch(&sb, buf[i]);
}
return strbuf_detach(&sb, NULL);
}
static void grab_date(const char *buf, struct atom_value *v, const char *atomname)
{
const char *eoemail = strstr(buf, "> ");
char *zone;
timestamp_t timestamp;
long tz;
struct date_mode date_mode = DATE_MODE_INIT;
const char *formatp;
/*
* We got here because atomname ends in "date" or "date<something>";
* it's not possible that <something> is not ":<format>" because
* parse_ref_filter_atom() wouldn't have allowed it, so we can assume that no
* ":" means no format is specified, and use the default.
*/
formatp = strchr(atomname, ':');
if (formatp != NULL) {
formatp++;
parse_date_format(formatp, &date_mode);
}
if (!eoemail)
goto bad;
timestamp = parse_timestamp(eoemail + 2, &zone, 10);
if (timestamp == TIME_MAX)
goto bad;
tz = strtol(zone, NULL, 10);
if ((tz == LONG_MIN || tz == LONG_MAX) && errno == ERANGE)
goto bad;
v->s = xstrdup(show_date(timestamp, tz, &date_mode));
v->value = timestamp;
date_mode_release(&date_mode);
return;
bad:
v->s = xstrdup("");
v->value = 0;
}
/* See grab_values */
static void grab_person(const char *who, struct atom_value *val, int deref, void *buf)
{
int i;
int wholen = strlen(who);
const char *wholine = NULL;
for (i = 0; i < used_atom_cnt; i++) {
const char *name = used_atom[i].name;
struct atom_value *v = &val[i];
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (strncmp(who, name, wholen))
continue;
if (name[wholen] != 0 &&
strcmp(name + wholen, "name") &&
!starts_with(name + wholen, "email") &&
!starts_with(name + wholen, "date"))
continue;
if (!wholine)
wholine = find_wholine(who, wholen, buf);
if (!wholine)
return; /* no point looking for it */
if (name[wholen] == 0)
v->s = copy_line(wholine);
else if (!strcmp(name + wholen, "name"))
v->s = copy_name(wholine);
else if (starts_with(name + wholen, "email"))
v->s = copy_email(wholine, &used_atom[i]);
else if (starts_with(name + wholen, "date"))
grab_date(wholine, v, name);
}
/*
* For a tag or a commit object, if "creator" or "creatordate" is
* requested, do something special.
*/
if (strcmp(who, "tagger") && strcmp(who, "committer"))
return; /* "author" for commit object is not wanted */
if (!wholine)
wholine = find_wholine(who, wholen, buf);
if (!wholine)
return;
for (i = 0; i < used_atom_cnt; i++) {
const char *name = used_atom[i].name;
enum atom_type atom_type = used_atom[i].atom_type;
struct atom_value *v = &val[i];
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (atom_type == ATOM_CREATORDATE)
grab_date(wholine, v, name);
else if (atom_type == ATOM_CREATOR)
v->s = copy_line(wholine);
}
}
static void find_subpos(const char *buf,
const char **sub, size_t *sublen,
const char **body, size_t *bodylen,
size_t *nonsiglen,
const char **sig, size_t *siglen)
{
struct strbuf payload = STRBUF_INIT;
struct strbuf signature = STRBUF_INIT;
const char *eol;
const char *end = buf + strlen(buf);
const char *sigstart;
/* parse signature first; we might not even have a subject line */
parse_signature(buf, end - buf, &payload, &signature);
/* skip past header until we hit empty line */
while (*buf && *buf != '\n') {
eol = strchrnul(buf, '\n');
if (*eol)
eol++;
buf = eol;
}
/* skip any empty lines */
while (*buf == '\n')
buf++;
*sig = strbuf_detach(&signature, siglen);
sigstart = buf + parse_signed_buffer(buf, strlen(buf));
/* subject is first non-empty line */
*sub = buf;
/* subject goes to first empty line before signature begins */
if ((eol = strstr(*sub, "\n\n"))) {
eol = eol < sigstart ? eol : sigstart;
/* check if message uses CRLF */
} else if (! (eol = strstr(*sub, "\r\n\r\n"))) {
/* treat whole message as subject */
eol = strrchr(*sub, '\0');
}
buf = eol;
*sublen = buf - *sub;
/* drop trailing newline, if present */
while (*sublen && ((*sub)[*sublen - 1] == '\n' ||
(*sub)[*sublen - 1] == '\r'))
*sublen -= 1;
/* skip any empty lines */
while (*buf == '\n' || *buf == '\r')
buf++;
*body = buf;
*bodylen = strlen(buf);
*nonsiglen = sigstart - buf;
}
/*
* If 'lines' is greater than 0, append that many lines from the given
* 'buf' of length 'size' to the given strbuf.
*/
static void append_lines(struct strbuf *out, const char *buf, unsigned long size, int lines)
{
int i;
const char *sp, *eol;
size_t len;
sp = buf;
for (i = 0; i < lines && sp < buf + size; i++) {
if (i)
strbuf_addstr(out, "\n ");
eol = memchr(sp, '\n', size - (sp - buf));
len = eol ? eol - sp : size - (sp - buf);
strbuf_add(out, sp, len);
if (!eol)
break;
sp = eol + 1;
}
}
/* See grab_values */
static void grab_sub_body_contents(struct atom_value *val, int deref, struct expand_data *data)
{
int i;
const char *subpos = NULL, *bodypos = NULL, *sigpos = NULL;
size_t sublen = 0, bodylen = 0, nonsiglen = 0, siglen = 0;
void *buf = data->content;
for (i = 0; i < used_atom_cnt; i++) {
struct used_atom *atom = &used_atom[i];
const char *name = atom->name;
struct atom_value *v = &val[i];
enum atom_type atom_type = atom->atom_type;
if (!!deref != (*name == '*'))
continue;
if (deref)
name++;
if (atom_type == ATOM_RAW) {
unsigned long buf_size = data->size;
if (atom->u.raw_data.option == RAW_BARE) {
v->s = xmemdupz(buf, buf_size);
v->s_size = buf_size;
} else if (atom->u.raw_data.option == RAW_LENGTH) {
v->s = xstrfmt("%"PRIuMAX, (uintmax_t)buf_size);
}
continue;
}
if ((data->type != OBJ_TAG &&
data->type != OBJ_COMMIT) ||
(strcmp(name, "body") &&
!starts_with(name, "subject") &&
!starts_with(name, "trailers") &&
!starts_with(name, "contents")))
continue;
if (!subpos)
find_subpos(buf,
&subpos, &sublen,
&bodypos, &bodylen, &nonsiglen,
&sigpos, &siglen);
if (atom->u.contents.option == C_SUB)
v->s = copy_subject(subpos, sublen);
else if (atom->u.contents.option == C_SUB_SANITIZE) {
struct strbuf sb = STRBUF_INIT;
format_sanitized_subject(&sb, subpos, sublen);
v->s = strbuf_detach(&sb, NULL);
} else if (atom->u.contents.option == C_BODY_DEP)
v->s = xmemdupz(bodypos, bodylen);
else if (atom->u.contents.option == C_LENGTH)
v->s = xstrfmt("%"PRIuMAX, (uintmax_t)strlen(subpos));
else if (atom->u.contents.option == C_BODY)
v->s = xmemdupz(bodypos, nonsiglen);
else if (atom->u.contents.option == C_SIG)
v->s = xmemdupz(sigpos, siglen);
else if (atom->u.contents.option == C_LINES) {
struct strbuf s = STRBUF_INIT;
const char *contents_end = bodypos + nonsiglen;
/* Size is the length of the message after removing the signature */
append_lines(&s, subpos, contents_end - subpos, atom->u.contents.nlines);
v->s = strbuf_detach(&s, NULL);
} else if (atom->u.contents.option == C_TRAILERS) {
struct strbuf s = STRBUF_INIT;
/* Format the trailer info according to the trailer_opts given */
format_trailers_from_commit(&s, subpos, &atom->u.contents.trailer_opts);
v->s = strbuf_detach(&s, NULL);
} else if (atom->u.contents.option == C_BARE)
v->s = xstrdup(subpos);
}
free((void *)sigpos);
}
/*
* We want to have empty print-string for field requests
* that do not apply (e.g. "authordate" for a tag object)
*/
static void fill_missing_values(struct atom_value *val)
{
int i;
for (i = 0; i < used_atom_cnt; i++) {
struct atom_value *v = &val[i];
if (v->s == NULL)
v->s = xstrdup("");
}
}
/*
* val is a list of atom_value to hold returned values. Extract
* the values for atoms in used_atom array out of (obj, buf, sz).
* when deref is false, (obj, buf, sz) is the object that is
* pointed at by the ref itself; otherwise it is the object the
* ref (which is a tag) refers to.
*/
static void grab_values(struct atom_value *val, int deref, struct object *obj, struct expand_data *data)
{
void *buf = data->content;
switch (obj->type) {
case OBJ_TAG:
grab_tag_values(val, deref, obj);
grab_sub_body_contents(val, deref, data);
grab_person("tagger", val, deref, buf);
break;
case OBJ_COMMIT:
grab_commit_values(val, deref, obj);
grab_sub_body_contents(val, deref, data);
grab_person("author", val, deref, buf);
grab_person("committer", val, deref, buf);
break;
case OBJ_TREE:
/* grab_tree_values(val, deref, obj, buf, sz); */
grab_sub_body_contents(val, deref, data);
break;
case OBJ_BLOB:
/* grab_blob_values(val, deref, obj, buf, sz); */
grab_sub_body_contents(val, deref, data);
break;
default:
die("Eh? Object of type %d?", obj->type);
}
}
static inline char *copy_advance(char *dst, const char *src)
{
while (*src)
*dst++ = *src++;
return dst;
}
static const char *lstrip_ref_components(const char *refname, int len)
{
long remaining = len;
const char *start = xstrdup(refname);
const char *to_free = start;
if (len < 0) {
int i;
const char *p = refname;
/* Find total no of '/' separated path-components */
for (i = 0; p[i]; p[i] == '/' ? i++ : *p++)
;
/*
* The number of components we need to strip is now
* the total minus the components to be left (Plus one
* because we count the number of '/', but the number
* of components is one more than the no of '/').
*/
remaining = i + len + 1;
}
while (remaining > 0) {
switch (*start++) {
case '\0':
free((char *)to_free);
return xstrdup("");
case '/':
remaining--;
break;
}
}
start = xstrdup(start);
free((char *)to_free);
return start;
}
static const char *rstrip_ref_components(const char *refname, int len)
{
long remaining = len;
const char *start = xstrdup(refname);
const char *to_free = start;
if (len < 0) {
int i;
const char *p = refname;
/* Find total no of '/' separated path-components */
for (i = 0; p[i]; p[i] == '/' ? i++ : *p++)
;
/*
* The number of components we need to strip is now
* the total minus the components to be left (Plus one
* because we count the number of '/', but the number
* of components is one more than the no of '/').
*/
remaining = i + len + 1;
}
while (remaining-- > 0) {
char *p = strrchr(start, '/');
if (p == NULL) {
free((char *)to_free);
return xstrdup("");
} else
p[0] = '\0';
}
return start;
}
static const char *show_ref(struct refname_atom *atom, const char *refname)
{
if (atom->option == R_SHORT)
return shorten_unambiguous_ref(refname, warn_ambiguous_refs);
else if (atom->option == R_LSTRIP)
return lstrip_ref_components(refname, atom->lstrip);
else if (atom->option == R_RSTRIP)
return rstrip_ref_components(refname, atom->rstrip);
else
return xstrdup(refname);
}
static void fill_remote_ref_details(struct used_atom *atom, const char *refname,
struct branch *branch, const char **s)
{
int num_ours, num_theirs;
if (atom->u.remote_ref.option == RR_REF)
*s = show_ref(&atom->u.remote_ref.refname, refname);
else if (atom->u.remote_ref.option == RR_TRACK) {
if (stat_tracking_info(branch, &num_ours, &num_theirs,
NULL, atom->u.remote_ref.push,
AHEAD_BEHIND_FULL) < 0) {
*s = xstrdup(msgs.gone);
} else if (!num_ours && !num_theirs)
*s = xstrdup("");
else if (!num_ours)
*s = xstrfmt(msgs.behind, num_theirs);
else if (!num_theirs)
*s = xstrfmt(msgs.ahead, num_ours);
else
*s = xstrfmt(msgs.ahead_behind,
num_ours, num_theirs);
if (!atom->u.remote_ref.nobracket && *s[0]) {
const char *to_free = *s;
*s = xstrfmt("[%s]", *s);
free((void *)to_free);
}
} else if (atom->u.remote_ref.option == RR_TRACKSHORT) {
if (stat_tracking_info(branch, &num_ours, &num_theirs,
NULL, atom->u.remote_ref.push,
AHEAD_BEHIND_FULL) < 0) {
*s = xstrdup("");
return;
}
if (!num_ours && !num_theirs)
*s = xstrdup("=");
else if (!num_ours)
*s = xstrdup("<");
else if (!num_theirs)
*s = xstrdup(">");
else
*s = xstrdup("<>");
} else if (atom->u.remote_ref.option == RR_REMOTE_NAME) {
int explicit;
const char *remote = atom->u.remote_ref.push ?
pushremote_for_branch(branch, &explicit) :
remote_for_branch(branch, &explicit);
*s = xstrdup(explicit ? remote : "");
} else if (atom->u.remote_ref.option == RR_REMOTE_REF) {
const char *merge;
merge = remote_ref_for_branch(branch, atom->u.remote_ref.push);
*s = xstrdup(merge ? merge : "");
} else
BUG("unhandled RR_* enum");
}
char *get_head_description(void)
{
struct strbuf desc = STRBUF_INIT;
struct wt_status_state state;
memset(&state, 0, sizeof(state));
wt_status_get_state(the_repository, &state, 1);
if (state.rebase_in_progress ||
state.rebase_interactive_in_progress) {
if (state.branch)
strbuf_addf(&desc, _("(no branch, rebasing %s)"),
state.branch);
else
strbuf_addf(&desc, _("(no branch, rebasing detached HEAD %s)"),
state.detached_from);
} else if (state.bisect_in_progress)
strbuf_addf(&desc, _("(no branch, bisect started on %s)"),
state.branch);
else if (state.detached_from) {
if (state.detached_at)
strbuf_addf(&desc, _("(HEAD detached at %s)"),
state.detached_from);
else
strbuf_addf(&desc, _("(HEAD detached from %s)"),
state.detached_from);
} else
strbuf_addstr(&desc, _("(no branch)"));
return strbuf_detach(&desc, NULL);
}
static const char *get_symref(struct used_atom *atom, struct ref_array_item *ref)
{
if (!ref->symref)
return xstrdup("");
else
return show_ref(&atom->u.refname, ref->symref);
}
static const char *get_refname(struct used_atom *atom, struct ref_array_item *ref)
{
if (ref->kind & FILTER_REFS_DETACHED_HEAD)
return get_head_description();
return show_ref(&atom->u.refname, ref->refname);
}
static int get_object(struct ref_array_item *ref, int deref, struct object **obj,
struct expand_data *oi, struct strbuf *err)
{
/* parse_object_buffer() will set eaten to 0 if free() will be needed */
int eaten = 1;
if (oi->info.contentp) {
/* We need to know that to use parse_object_buffer properly */
oi->info.sizep = &oi->size;
oi->info.typep = &oi->type;
}
if (oid_object_info_extended(the_repository, &oi->oid, &oi->info,
OBJECT_INFO_LOOKUP_REPLACE))
return strbuf_addf_ret(err, -1, _("missing object %s for %s"),
oid_to_hex(&oi->oid), ref->refname);
if (oi->info.disk_sizep && oi->disk_size < 0)
BUG("Object size is less than zero.");
if (oi->info.contentp) {
*obj = parse_object_buffer(the_repository, &oi->oid, oi->type, oi->size, oi->content, &eaten);
if (!*obj) {
if (!eaten)
free(oi->content);
return strbuf_addf_ret(err, -1, _("parse_object_buffer failed on %s for %s"),
oid_to_hex(&oi->oid), ref->refname);
}
grab_values(ref->value, deref, *obj, oi);
}
grab_common_values(ref->value, deref, oi);
if (!eaten)
free(oi->content);
return 0;
}
static void populate_worktree_map(struct hashmap *map, struct worktree **worktrees)
{
int i;
for (i = 0; worktrees[i]; i++) {
if (worktrees[i]->head_ref) {
struct ref_to_worktree_entry *entry;
entry = xmalloc(sizeof(*entry));
entry->wt = worktrees[i];
hashmap_entry_init(&entry->ent,
strhash(worktrees[i]->head_ref));
hashmap_add(map, &entry->ent);
}
}
}
static void lazy_init_worktree_map(void)
{
if (ref_to_worktree_map.worktrees)
return;
ref_to_worktree_map.worktrees = get_worktrees();
hashmap_init(&(ref_to_worktree_map.map), ref_to_worktree_map_cmpfnc, NULL, 0);
populate_worktree_map(&(ref_to_worktree_map.map), ref_to_worktree_map.worktrees);
}
static char *get_worktree_path(const struct used_atom *atom, const struct ref_array_item *ref)
{
struct hashmap_entry entry, *e;
struct ref_to_worktree_entry *lookup_result;
lazy_init_worktree_map();
hashmap_entry_init(&entry, strhash(ref->refname));
e = hashmap_get(&(ref_to_worktree_map.map), &entry, ref->refname);
if (!e)
return xstrdup("");
lookup_result = container_of(e, struct ref_to_worktree_entry, ent);
return xstrdup(lookup_result->wt->path);
}
/*
* Parse the object referred by ref, and grab needed value.
*/
static int populate_value(struct ref_array_item *ref, struct strbuf *err)
{
struct object *obj;
int i;
struct object_info empty = OBJECT_INFO_INIT;
CALLOC_ARRAY(ref->value, used_atom_cnt);
if (need_symref && (ref->flag & REF_ISSYMREF) && !ref->symref) {
ref->symref = resolve_refdup(ref->refname, RESOLVE_REF_READING,
NULL, NULL);
if (!ref->symref)
ref->symref = xstrdup("");
}
/* Fill in specials first */
for (i = 0; i < used_atom_cnt; i++) {
struct used_atom *atom = &used_atom[i];
enum atom_type atom_type = atom->atom_type;
const char *name = used_atom[i].name;
struct atom_value *v = &ref->value[i];
int deref = 0;
const char *refname;
struct branch *branch = NULL;
v->s_size = ATOM_SIZE_UNSPECIFIED;
v->handler = append_atom;
v->atom = atom;
if (*name == '*') {
deref = 1;
name++;
}
if (atom_type == ATOM_REFNAME)
refname = get_refname(atom, ref);
else if (atom_type == ATOM_WORKTREEPATH) {
if (ref->kind == FILTER_REFS_BRANCHES)
v->s = get_worktree_path(atom, ref);
else
v->s = xstrdup("");
continue;
}
else if (atom_type == ATOM_SYMREF)
refname = get_symref(atom, ref);
else if (atom_type == ATOM_UPSTREAM) {
const char *branch_name;
/* only local branches may have an upstream */
if (!skip_prefix(ref->refname, "refs/heads/",
&branch_name)) {
v->s = xstrdup("");
continue;
}
branch = branch_get(branch_name);
refname = branch_get_upstream(branch, NULL);
if (refname)
fill_remote_ref_details(atom, refname, branch, &v->s);
else
v->s = xstrdup("");
continue;
} else if (atom_type == ATOM_PUSH && atom->u.remote_ref.push) {
const char *branch_name;
v->s = xstrdup("");
if (!skip_prefix(ref->refname, "refs/heads/",
&branch_name))
continue;
branch = branch_get(branch_name);
if (atom->u.remote_ref.push_remote)
refname = NULL;
else {
refname = branch_get_push(branch, NULL);
if (!refname)
continue;
}
/* We will definitely re-init v->s on the next line. */
free((char *)v->s);
fill_remote_ref_details(atom, refname, branch, &v->s);
continue;
} else if (atom_type == ATOM_COLOR) {
v->s = xstrdup(atom->u.color);
continue;
} else if (atom_type == ATOM_FLAG) {
char buf[256], *cp = buf;
if (ref->flag & REF_ISSYMREF)
cp = copy_advance(cp, ",symref");
if (ref->flag & REF_ISPACKED)
cp = copy_advance(cp, ",packed");
if (cp == buf)
v->s = xstrdup("");
else {
*cp = '\0';
v->s = xstrdup(buf + 1);
}
continue;
} else if (!deref && atom_type == ATOM_OBJECTNAME &&
grab_oid(name, "objectname", &ref->objectname, v, atom)) {
continue;
} else if (atom_type == ATOM_HEAD) {
if (atom->u.head && !strcmp(ref->refname, atom->u.head))
v->s = xstrdup("*");
else
v->s = xstrdup(" ");
continue;
} else if (atom_type == ATOM_ALIGN) {
v->handler = align_atom_handler;
v->s = xstrdup("");
continue;
} else if (atom_type == ATOM_END) {
v->handler = end_atom_handler;
v->s = xstrdup("");
continue;
} else if (atom_type == ATOM_IF) {
const char *s;
if (skip_prefix(name, "if:", &s))
v->s = xstrdup(s);
else
v->s = xstrdup("");
v->handler = if_atom_handler;
continue;
} else if (atom_type == ATOM_THEN) {
v->handler = then_atom_handler;
v->s = xstrdup("");
continue;
} else if (atom_type == ATOM_ELSE) {
v->handler = else_atom_handler;
v->s = xstrdup("");
continue;
} else if (atom_type == ATOM_REST) {
if (ref->rest)
v->s = xstrdup(ref->rest);
else
v->s = xstrdup("");
continue;
} else
continue;
if (!deref)
v->s = xstrdup(refname);
else
v->s = xstrfmt("%s^{}", refname);
free((char *)refname);
}
for (i = 0; i < used_atom_cnt; i++) {
struct atom_value *v = &ref->value[i];
if (v->s == NULL && used_atom[i].source == SOURCE_NONE)
return strbuf_addf_ret(err, -1, _("missing object %s for %s"),
oid_to_hex(&ref->objectname), ref->refname);
}
if (need_tagged)
oi.info.contentp = &oi.content;
if (!memcmp(&oi.info, &empty, sizeof(empty)) &&
!memcmp(&oi_deref.info, &empty, sizeof(empty)))
return 0;
oi.oid = ref->objectname;
if (get_object(ref, 0, &obj, &oi, err))
return -1;
/*
* If there is no atom that wants to know about tagged
* object, we are done.
*/
if (!need_tagged || (obj->type != OBJ_TAG))
return 0;
/*
* If it is a tag object, see if we use a value that derefs
* the object, and if we do grab the object it refers to.
*/
oi_deref.oid = *get_tagged_oid((struct tag *)obj);
/*
* NEEDSWORK: This derefs tag only once, which
* is good to deal with chains of trust, but
* is not consistent with what deref_tag() does
* which peels the onion to the core.
*/
return get_object(ref, 1, &obj, &oi_deref, err);
}
/*
* Given a ref, return the value for the atom. This lazily gets value
* out of the object by calling populate value.
*/
static int get_ref_atom_value(struct ref_array_item *ref, int atom,
struct atom_value **v, struct strbuf *err)
{
if (!ref->value) {
if (populate_value(ref, err))
return -1;
fill_missing_values(ref->value);
}
*v = &ref->value[atom];
return 0;
}
/*
* Return 1 if the refname matches one of the patterns, otherwise 0.
* A pattern can be a literal prefix (e.g. a refname "refs/heads/master"
* matches a pattern "refs/heads/mas") or a wildcard (e.g. the same ref
* matches "refs/heads/mas*", too).
*/
static int match_pattern(const struct ref_filter *filter, const char *refname)
{
const char **patterns = filter->name_patterns;
unsigned flags = 0;
if (filter->ignore_case)
flags |= WM_CASEFOLD;
/*
* When no '--format' option is given we need to skip the prefix
* for matching refs of tags and branches.
*/
(void)(skip_prefix(refname, "refs/tags/", &refname) ||
skip_prefix(refname, "refs/heads/", &refname) ||
skip_prefix(refname, "refs/remotes/", &refname) ||
skip_prefix(refname, "refs/", &refname));
for (; *patterns; patterns++) {
if (!wildmatch(*patterns, refname, flags))
return 1;
}
return 0;
}
/*
* Return 1 if the refname matches one of the patterns, otherwise 0.
* A pattern can be path prefix (e.g. a refname "refs/heads/master"
* matches a pattern "refs/heads/" but not "refs/heads/m") or a
* wildcard (e.g. the same ref matches "refs/heads/m*", too).
*/
static int match_name_as_path(const struct ref_filter *filter, const char *refname)
{
const char **pattern = filter->name_patterns;
int namelen = strlen(refname);
unsigned flags = WM_PATHNAME;
if (filter->ignore_case)
flags |= WM_CASEFOLD;
for (; *pattern; pattern++) {
const char *p = *pattern;
int plen = strlen(p);
if ((plen <= namelen) &&
!strncmp(refname, p, plen) &&
(refname[plen] == '\0' ||
refname[plen] == '/' ||
p[plen-1] == '/'))
return 1;
if (!wildmatch(p, refname, flags))
return 1;
}
return 0;
}
/* Return 1 if the refname matches one of the patterns, otherwise 0. */
static int filter_pattern_match(struct ref_filter *filter, const char *refname)
{
if (!*filter->name_patterns)
return 1; /* No pattern always matches */
if (filter->match_as_path)
return match_name_as_path(filter, refname);
return match_pattern(filter, refname);
}
/*
* This is the same as for_each_fullref_in(), but it tries to iterate
* only over the patterns we'll care about. Note that it _doesn't_ do a full
* pattern match, so the callback still has to match each ref individually.
*/
static int for_each_fullref_in_pattern(struct ref_filter *filter,
each_ref_fn cb,
void *cb_data)
{
if (!filter->match_as_path) {
/*
* in this case, the patterns are applied after
* prefixes like "refs/heads/" etc. are stripped off,
* so we have to look at everything:
*/
return for_each_fullref_in("", cb, cb_data);
}
if (filter->ignore_case) {
/*
* we can't handle case-insensitive comparisons,
* so just return everything and let the caller
* sort it out.
*/
return for_each_fullref_in("", cb, cb_data);
}
if (!filter->name_patterns[0]) {
/* no patterns; we have to look at everything */
return for_each_fullref_in("", cb, cb_data);
}
return for_each_fullref_in_prefixes(NULL, filter->name_patterns,
cb, cb_data);
}
/*
* Given a ref (oid, refname), check if the ref belongs to the array
* of oids. If the given ref is a tag, check if the given tag points
* at one of the oids in the given oid array.
* NEEDSWORK:
* 1. Only a single level of indirection is obtained, we might want to
* change this to account for multiple levels (e.g. annotated tags
* pointing to annotated tags pointing to a commit.)
* 2. As the refs are cached we might know what refname peels to without
* the need to parse the object via parse_object(). peel_ref() might be a
* more efficient alternative to obtain the pointee.
*/
static const struct object_id *match_points_at(struct oid_array *points_at,
const struct object_id *oid,
const char *refname)
{
const struct object_id *tagged_oid = NULL;
struct object *obj;
if (oid_array_lookup(points_at, oid) >= 0)
return oid;
obj = parse_object(the_repository, oid);
if (!obj)
die(_("malformed object at '%s'"), refname);
if (obj->type == OBJ_TAG)
tagged_oid = get_tagged_oid((struct tag *)obj);
if (tagged_oid && oid_array_lookup(points_at, tagged_oid) >= 0)
return tagged_oid;
return NULL;
}
/*
* Allocate space for a new ref_array_item and copy the name and oid to it.
*
* Callers can then fill in other struct members at their leisure.
*/
static struct ref_array_item *new_ref_array_item(const char *refname,
const struct object_id *oid)
{
struct ref_array_item *ref;
FLEX_ALLOC_STR(ref, refname, refname);
oidcpy(&ref->objectname, oid);
ref->rest = NULL;
return ref;
}
struct ref_array_item *ref_array_push(struct ref_array *array,
const char *refname,
const struct object_id *oid)
{
struct ref_array_item *ref = new_ref_array_item(refname, oid);
ALLOC_GROW(array->items, array->nr + 1, array->alloc);
array->items[array->nr++] = ref;
return ref;
}
static int ref_kind_from_refname(const char *refname)
{
unsigned int i;
static struct {
const char *prefix;
unsigned int kind;
} ref_kind[] = {
{ "refs/heads/" , FILTER_REFS_BRANCHES },
{ "refs/remotes/" , FILTER_REFS_REMOTES },
{ "refs/tags/", FILTER_REFS_TAGS}
};
if (!strcmp(refname, "HEAD"))
return FILTER_REFS_DETACHED_HEAD;
for (i = 0; i < ARRAY_SIZE(ref_kind); i++) {
if (starts_with(refname, ref_kind[i].prefix))
return ref_kind[i].kind;
}
return FILTER_REFS_OTHERS;
}
static int filter_ref_kind(struct ref_filter *filter, const char *refname)
{
if (filter->kind == FILTER_REFS_BRANCHES ||
filter->kind == FILTER_REFS_REMOTES ||
filter->kind == FILTER_REFS_TAGS)
return filter->kind;
return ref_kind_from_refname(refname);
}
struct ref_filter_cbdata {
struct ref_array *array;
struct ref_filter *filter;
struct contains_cache contains_cache;
struct contains_cache no_contains_cache;
};
/*
* A call-back given to for_each_ref(). Filter refs and keep them for
* later object processing.
*/
static int ref_filter_handler(const char *refname, const struct object_id *oid, int flag, void *cb_data)
{
struct ref_filter_cbdata *ref_cbdata = cb_data;
struct ref_filter *filter = ref_cbdata->filter;
struct ref_array_item *ref;
struct commit *commit = NULL;
unsigned int kind;
if (flag & REF_BAD_NAME) {
warning(_("ignoring ref with broken name %s"), refname);
return 0;
}
if (flag & REF_ISBROKEN) {
warning(_("ignoring broken ref %s"), refname);
return 0;
}
/* Obtain the current ref kind from filter_ref_kind() and ignore unwanted refs. */
kind = filter_ref_kind(filter, refname);
if (!(kind & filter->kind))
return 0;
if (!filter_pattern_match(filter, refname))
return 0;
if (filter->points_at.nr && !match_points_at(&filter->points_at, oid, refname))
return 0;
/*
* A merge filter is applied on refs pointing to commits. Hence
* obtain the commit using the 'oid' available and discard all
* non-commits early. The actual filtering is done later.
*/
if (filter->reachable_from || filter->unreachable_from ||
filter->with_commit || filter->no_commit || filter->verbose) {
commit = lookup_commit_reference_gently(the_repository, oid, 1);
if (!commit)
return 0;
/* We perform the filtering for the '--contains' option... */
if (filter->with_commit &&
!commit_contains(filter, commit, filter->with_commit, &ref_cbdata->contains_cache))
return 0;
/* ...or for the `--no-contains' option */
if (filter->no_commit &&
commit_contains(filter, commit, filter->no_commit, &ref_cbdata->no_contains_cache))
return 0;
}
/*
* We do not open the object yet; sort may only need refname
* to do its job and the resulting list may yet to be pruned
* by maxcount logic.
*/
ref = ref_array_push(ref_cbdata->array, refname, oid);
ref->commit = commit;
ref->flag = flag;
ref->kind = kind;
return 0;
}
/* Free memory allocated for a ref_array_item */
static void free_array_item(struct ref_array_item *item)
{
free((char *)item->symref);
if (item->value) {
int i;
for (i = 0; i < used_atom_cnt; i++)
free((char *)item->value[i].s);
free(item->value);
}
free(item);
}
/* Free all memory allocated for ref_array */
void ref_array_clear(struct ref_array *array)
{
int i;
for (i = 0; i < array->nr; i++)
free_array_item(array->items[i]);
FREE_AND_NULL(array->items);
array->nr = array->alloc = 0;
for (i = 0; i < used_atom_cnt; i++) {
struct used_atom *atom = &used_atom[i];
if (atom->atom_type == ATOM_HEAD)
free(atom->u.head);
free((char *)atom->name);
}
FREE_AND_NULL(used_atom);
used_atom_cnt = 0;
if (ref_to_worktree_map.worktrees) {
hashmap_clear_and_free(&(ref_to_worktree_map.map),
struct ref_to_worktree_entry, ent);
free_worktrees(ref_to_worktree_map.worktrees);
ref_to_worktree_map.worktrees = NULL;
}
}
#define EXCLUDE_REACHED 0
#define INCLUDE_REACHED 1
static void reach_filter(struct ref_array *array,
struct commit_list *check_reachable,
int include_reached)
{
struct rev_info revs;
int i, old_nr;
struct commit **to_clear;
struct commit_list *cr;
if (!check_reachable)
return;
CALLOC_ARRAY(to_clear, array->nr);
repo_init_revisions(the_repository, &revs, NULL);
for (i = 0; i < array->nr; i++) {
struct ref_array_item *item = array->items[i];
add_pending_object(&revs, &item->commit->object, item->refname);
to_clear[i] = item->commit;
}
for (cr = check_reachable; cr; cr = cr->next) {
struct commit *merge_commit = cr->item;
merge_commit->object.flags |= UNINTERESTING;
add_pending_object(&revs, &merge_commit->object, "");
}
revs.limited = 1;
if (prepare_revision_walk(&revs))
die(_("revision walk setup failed"));
old_nr = array->nr;
array->nr = 0;
for (i = 0; i < old_nr; i++) {
struct ref_array_item *item = array->items[i];
struct commit *commit = item->commit;
int is_merged = !!(commit->object.flags & UNINTERESTING);
if (is_merged == include_reached)
array->items[array->nr++] = array->items[i];
else
free_array_item(item);
}
clear_commit_marks_many(old_nr, to_clear, ALL_REV_FLAGS);
while (check_reachable) {
struct commit *merge_commit = pop_commit(&check_reachable);
clear_commit_marks(merge_commit, ALL_REV_FLAGS);
}
free(to_clear);
}
/*
* API for filtering a set of refs. Based on the type of refs the user
* has requested, we iterate through those refs and apply filters
* as per the given ref_filter structure and finally store the
* filtered refs in the ref_array structure.
*/
int filter_refs(struct ref_array *array, struct ref_filter *filter, unsigned int type)
{
struct ref_filter_cbdata ref_cbdata;
int ret = 0;
ref_cbdata.array = array;
ref_cbdata.filter = filter;
filter->kind = type & FILTER_REFS_KIND_MASK;
init_contains_cache(&ref_cbdata.contains_cache);
init_contains_cache(&ref_cbdata.no_contains_cache);
/* Simple per-ref filtering */
if (!filter->kind)
die("filter_refs: invalid type");
else {
/*
* For common cases where we need only branches or remotes or tags,
* we only iterate through those refs. If a mix of refs is needed,
* we iterate over all refs and filter out required refs with the help
* of filter_ref_kind().
*/
if (filter->kind == FILTER_REFS_BRANCHES)
ret = for_each_fullref_in("refs/heads/", ref_filter_handler, &ref_cbdata);
else if (filter->kind == FILTER_REFS_REMOTES)
ret = for_each_fullref_in("refs/remotes/", ref_filter_handler, &ref_cbdata);
else if (filter->kind == FILTER_REFS_TAGS)
ret = for_each_fullref_in("refs/tags/", ref_filter_handler, &ref_cbdata);
else if (filter->kind & FILTER_REFS_ALL)
ret = for_each_fullref_in_pattern(filter, ref_filter_handler, &ref_cbdata);
if (!ret && (filter->kind & FILTER_REFS_DETACHED_HEAD))
head_ref(ref_filter_handler, &ref_cbdata);
}
clear_contains_cache(&ref_cbdata.contains_cache);
clear_contains_cache(&ref_cbdata.no_contains_cache);
/* Filters that need revision walking */
reach_filter(array, filter->reachable_from, INCLUDE_REACHED);
reach_filter(array, filter->unreachable_from, EXCLUDE_REACHED);
return ret;
}
static int compare_detached_head(struct ref_array_item *a, struct ref_array_item *b)
{
if (!(a->kind ^ b->kind))
BUG("ref_kind_from_refname() should only mark one ref as HEAD");
if (a->kind & FILTER_REFS_DETACHED_HEAD)
return -1;
else if (b->kind & FILTER_REFS_DETACHED_HEAD)
return 1;
BUG("should have died in the xor check above");
return 0;
}
static int memcasecmp(const void *vs1, const void *vs2, size_t n)
{
const char *s1 = vs1, *s2 = vs2;
const char *end = s1 + n;
for (; s1 < end; s1++, s2++) {
int diff = tolower(*s1) - tolower(*s2);
if (diff)
return diff;
}
return 0;
}
struct ref_sorting {
struct ref_sorting *next;
int atom; /* index into used_atom array (internal) */
enum ref_sorting_order sort_flags;
};
static int cmp_ref_sorting(struct ref_sorting *s, struct ref_array_item *a, struct ref_array_item *b)
{
struct atom_value *va, *vb;
int cmp;
int cmp_detached_head = 0;
cmp_type cmp_type = used_atom[s->atom].type;
struct strbuf err = STRBUF_INIT;
if (get_ref_atom_value(a, s->atom, &va, &err))
die("%s", err.buf);
if (get_ref_atom_value(b, s->atom, &vb, &err))
die("%s", err.buf);
strbuf_release(&err);
if (s->sort_flags & REF_SORTING_DETACHED_HEAD_FIRST &&
((a->kind | b->kind) & FILTER_REFS_DETACHED_HEAD)) {
cmp = compare_detached_head(a, b);
cmp_detached_head = 1;
} else if (s->sort_flags & REF_SORTING_VERSION) {
cmp = versioncmp(va->s, vb->s);
} else if (cmp_type == FIELD_STR) {
if (va->s_size < 0 && vb->s_size < 0) {
int (*cmp_fn)(const char *, const char *);
cmp_fn = s->sort_flags & REF_SORTING_ICASE
? strcasecmp : strcmp;
cmp = cmp_fn(va->s, vb->s);
} else {
size_t a_size = va->s_size < 0 ?
strlen(va->s) : va->s_size;
size_t b_size = vb->s_size < 0 ?
strlen(vb->s) : vb->s_size;
int (*cmp_fn)(const void *, const void *, size_t);
cmp_fn = s->sort_flags & REF_SORTING_ICASE
? memcasecmp : memcmp;
cmp = cmp_fn(va->s, vb->s, b_size > a_size ?
a_size : b_size);
if (!cmp) {
if (a_size > b_size)
cmp = 1;
else if (a_size < b_size)
cmp = -1;
}
}
} else {
if (va->value < vb->value)
cmp = -1;
else if (va->value == vb->value)
cmp = 0;
else
cmp = 1;
}
return (s->sort_flags & REF_SORTING_REVERSE && !cmp_detached_head)
? -cmp : cmp;
}
static int compare_refs(const void *a_, const void *b_, void *ref_sorting)
{
struct ref_array_item *a = *((struct ref_array_item **)a_);
struct ref_array_item *b = *((struct ref_array_item **)b_);
struct ref_sorting *s;
for (s = ref_sorting; s; s = s->next) {
int cmp = cmp_ref_sorting(s, a, b);
if (cmp)
return cmp;
}
s = ref_sorting;
return s && s->sort_flags & REF_SORTING_ICASE ?
strcasecmp(a->refname, b->refname) :
strcmp(a->refname, b->refname);
}
void ref_sorting_set_sort_flags_all(struct ref_sorting *sorting,
unsigned int mask, int on)
{
for (; sorting; sorting = sorting->next) {
if (on)
sorting->sort_flags |= mask;
else
sorting->sort_flags &= ~mask;
}
}
void ref_array_sort(struct ref_sorting *sorting, struct ref_array *array)
{
QSORT_S(array->items, array->nr, compare_refs, sorting);
}
static void append_literal(const char *cp, const char *ep, struct ref_formatting_state *state)
{
struct strbuf *s = &state->stack->output;
while (*cp && (!ep || cp < ep)) {
if (*cp == '%') {
if (cp[1] == '%')
cp++;
else {
int ch = hex2chr(cp + 1);
if (0 <= ch) {
strbuf_addch(s, ch);
cp += 3;
continue;
}
}
}
strbuf_addch(s, *cp);
cp++;
}
}
int format_ref_array_item(struct ref_array_item *info,
struct ref_format *format,
struct strbuf *final_buf,
struct strbuf *error_buf)
{
const char *cp, *sp, *ep;
struct ref_formatting_state state = REF_FORMATTING_STATE_INIT;
state.quote_style = format->quote_style;
push_stack_element(&state.stack);
for (cp = format->format; *cp && (sp = find_next(cp)); cp = ep + 1) {
struct atom_value *atomv;
int pos;
ep = strchr(sp, ')');
if (cp < sp)
append_literal(cp, sp, &state);
pos = parse_ref_filter_atom(format, sp + 2, ep, error_buf);
if (pos < 0 || get_ref_atom_value(info, pos, &atomv, error_buf) ||
atomv->handler(atomv, &state, error_buf)) {
pop_stack_element(&state.stack);
return -1;
}
}
if (*cp) {
sp = cp + strlen(cp);
append_literal(cp, sp, &state);
}
if (format->need_color_reset_at_eol) {
struct atom_value resetv = ATOM_VALUE_INIT;
resetv.s = GIT_COLOR_RESET;
if (append_atom(&resetv, &state, error_buf)) {
pop_stack_element(&state.stack);
return -1;
}
}
if (state.stack->prev) {
pop_stack_element(&state.stack);
return strbuf_addf_ret(error_buf, -1, _("format: %%(end) atom missing"));
}
strbuf_addbuf(final_buf, &state.stack->output);
pop_stack_element(&state.stack);
return 0;
}
void pretty_print_ref(const char *name, const struct object_id *oid,
struct ref_format *format)
{
struct ref_array_item *ref_item;
struct strbuf output = STRBUF_INIT;
struct strbuf err = STRBUF_INIT;
ref_item = new_ref_array_item(name, oid);
ref_item->kind = ref_kind_from_refname(name);
if (format_ref_array_item(ref_item, format, &output, &err))
die("%s", err.buf);
fwrite(output.buf, 1, output.len, stdout);
putchar('\n');
strbuf_release(&err);
strbuf_release(&output);
free_array_item(ref_item);
}
static int parse_sorting_atom(const char *atom)
{
/*
* This parses an atom using a dummy ref_format, since we don't
* actually care about the formatting details.
*/
struct ref_format dummy = REF_FORMAT_INIT;
const char *end = atom + strlen(atom);
struct strbuf err = STRBUF_INIT;
int res = parse_ref_filter_atom(&dummy, atom, end, &err);
if (res < 0)
die("%s", err.buf);
strbuf_release(&err);
return res;
}
/* If no sorting option is given, use refname to sort as default */
static struct ref_sorting *ref_default_sorting(void)
{
static const char cstr_name[] = "refname";
struct ref_sorting *sorting = xcalloc(1, sizeof(*sorting));
sorting->next = NULL;
sorting->atom = parse_sorting_atom(cstr_name);
return sorting;
}
static void parse_ref_sorting(struct ref_sorting **sorting_tail, const char *arg)
{
struct ref_sorting *s;
CALLOC_ARRAY(s, 1);
s->next = *sorting_tail;
*sorting_tail = s;
if (*arg == '-') {
s->sort_flags |= REF_SORTING_REVERSE;
arg++;
}
if (skip_prefix(arg, "version:", &arg) ||
skip_prefix(arg, "v:", &arg))
s->sort_flags |= REF_SORTING_VERSION;
s->atom = parse_sorting_atom(arg);
}
struct ref_sorting *ref_sorting_options(struct string_list *options)
{
struct string_list_item *item;
struct ref_sorting *sorting = NULL, **tail = &sorting;
if (!options->nr) {
sorting = ref_default_sorting();
} else {
for_each_string_list_item(item, options)
parse_ref_sorting(tail, item->string);
}
/*
* From here on, the ref_sorting list should be used to talk
* about the sort order used for the output. The caller
* should not touch the string form anymore.
*/
string_list_clear(options, 0);
return sorting;
}
void ref_sorting_release(struct ref_sorting *sorting)
{
while (sorting) {
struct ref_sorting *next = sorting->next;
free(sorting);
sorting = next;
}
}
int parse_opt_merge_filter(const struct option *opt, const char *arg, int unset)
{
struct ref_filter *rf = opt->value;
struct object_id oid;
struct commit *merge_commit;
BUG_ON_OPT_NEG(unset);
if (get_oid(arg, &oid))
die(_("malformed object name %s"), arg);
merge_commit = lookup_commit_reference_gently(the_repository, &oid, 0);
if (!merge_commit)
return error(_("option `%s' must point to a commit"), opt->long_name);
if (starts_with(opt->long_name, "no"))
commit_list_insert(merge_commit, &rf->unreachable_from);
else
commit_list_insert(merge_commit, &rf->reachable_from);
return 0;
}
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