git/refs/packed-backend.c
Junio C Hamano 2b30d66c43 Merge branch 'jk/mark-unused-parameters'
Mark unused parameters as UNUSED to squelch -Wunused warnings.

* jk/mark-unused-parameters:
  t-hashmap: stop calling setup() for t_intern() test
  scalar: mark unused parameters in dummy function
  daemon: mark unused parameters in non-posix fallbacks
  setup: mark unused parameter in config callback
  test-mergesort: mark unused parameters in trivial callback
  t-hashmap: mark unused parameters in callback function
  reftable: mark unused parameters in virtual functions
  reftable: drop obsolete test function declarations
  reftable: ignore unused argc/argv in test functions
  unit-tests: ignore unused argc/argv
  t/helper: mark more unused argv/argc arguments
  oss-fuzz: mark unused argv/argc argument
  refs: mark unused parameters in do_for_each_reflog_helper()
  refs: mark unused parameters in ref_store fsck callbacks
  update-ref: mark more unused parameters in parser callbacks
  imap-send: mark unused parameter in ssl_socket_connect() fallback
2024-08-26 11:32:23 -07:00

1774 lines
48 KiB
C

#define USE_THE_REPOSITORY_VARIABLE
#include "../git-compat-util.h"
#include "../config.h"
#include "../dir.h"
#include "../gettext.h"
#include "../hash.h"
#include "../hex.h"
#include "../refs.h"
#include "refs-internal.h"
#include "packed-backend.h"
#include "../iterator.h"
#include "../lockfile.h"
#include "../chdir-notify.h"
#include "../statinfo.h"
#include "../wrapper.h"
#include "../write-or-die.h"
#include "../trace2.h"
enum mmap_strategy {
/*
* Don't use mmap() at all for reading `packed-refs`.
*/
MMAP_NONE,
/*
* Can use mmap() for reading `packed-refs`, but the file must
* not remain mmapped. This is the usual option on Windows,
* where you cannot rename a new version of a file onto a file
* that is currently mmapped.
*/
MMAP_TEMPORARY,
/*
* It is OK to leave the `packed-refs` file mmapped while
* arbitrary other code is running.
*/
MMAP_OK
};
#if defined(NO_MMAP)
static enum mmap_strategy mmap_strategy = MMAP_NONE;
#elif defined(MMAP_PREVENTS_DELETE)
static enum mmap_strategy mmap_strategy = MMAP_TEMPORARY;
#else
static enum mmap_strategy mmap_strategy = MMAP_OK;
#endif
struct packed_ref_store;
/*
* A `snapshot` represents one snapshot of a `packed-refs` file.
*
* Normally, this will be a mmapped view of the contents of the
* `packed-refs` file at the time the snapshot was created. However,
* if the `packed-refs` file was not sorted, this might point at heap
* memory holding the contents of the `packed-refs` file with its
* records sorted by refname.
*
* `snapshot` instances are reference counted (via
* `acquire_snapshot()` and `release_snapshot()`). This is to prevent
* an instance from disappearing while an iterator is still iterating
* over it. Instances are garbage collected when their `referrers`
* count goes to zero.
*
* The most recent `snapshot`, if available, is referenced by the
* `packed_ref_store`. Its freshness is checked whenever
* `get_snapshot()` is called; if the existing snapshot is obsolete, a
* new snapshot is taken.
*/
struct snapshot {
/*
* A back-pointer to the packed_ref_store with which this
* snapshot is associated:
*/
struct packed_ref_store *refs;
/* Is the `packed-refs` file currently mmapped? */
int mmapped;
/*
* The contents of the `packed-refs` file:
*
* - buf -- a pointer to the start of the memory
* - start -- a pointer to the first byte of actual references
* (i.e., after the header line, if one is present)
* - eof -- a pointer just past the end of the reference
* contents
*
* If the `packed-refs` file was already sorted, `buf` points
* at the mmapped contents of the file. If not, it points at
* heap-allocated memory containing the contents, sorted. If
* there were no contents (e.g., because the file didn't
* exist), `buf`, `start`, and `eof` are all NULL.
*/
char *buf, *start, *eof;
/*
* What is the peeled state of the `packed-refs` file that
* this snapshot represents? (This is usually determined from
* the file's header.)
*/
enum { PEELED_NONE, PEELED_TAGS, PEELED_FULLY } peeled;
/*
* Count of references to this instance, including the pointer
* from `packed_ref_store::snapshot`, if any. The instance
* will not be freed as long as the reference count is
* nonzero.
*/
unsigned int referrers;
/*
* The metadata of the `packed-refs` file from which this
* snapshot was created, used to tell if the file has been
* replaced since we read it.
*/
struct stat_validity validity;
};
/*
* A `ref_store` representing references stored in a `packed-refs`
* file. It implements the `ref_store` interface, though it has some
* limitations:
*
* - It cannot store symbolic references.
*
* - It cannot store reflogs.
*
* - It does not support reference renaming (though it could).
*
* On the other hand, it can be locked outside of a reference
* transaction. In that case, it remains locked even after the
* transaction is done and the new `packed-refs` file is activated.
*/
struct packed_ref_store {
struct ref_store base;
unsigned int store_flags;
/* The path of the "packed-refs" file: */
char *path;
/*
* A snapshot of the values read from the `packed-refs` file,
* if it might still be current; otherwise, NULL.
*/
struct snapshot *snapshot;
/*
* Lock used for the "packed-refs" file. Note that this (and
* thus the enclosing `packed_ref_store`) must not be freed.
*/
struct lock_file lock;
/*
* Temporary file used when rewriting new contents to the
* "packed-refs" file. Note that this (and thus the enclosing
* `packed_ref_store`) must not be freed.
*/
struct tempfile *tempfile;
};
/*
* Increment the reference count of `*snapshot`.
*/
static void acquire_snapshot(struct snapshot *snapshot)
{
snapshot->referrers++;
}
/*
* If the buffer in `snapshot` is active, then either munmap the
* memory and close the file, or free the memory. Then set the buffer
* pointers to NULL.
*/
static void clear_snapshot_buffer(struct snapshot *snapshot)
{
if (snapshot->mmapped) {
if (munmap(snapshot->buf, snapshot->eof - snapshot->buf))
die_errno("error ummapping packed-refs file %s",
snapshot->refs->path);
snapshot->mmapped = 0;
} else {
free(snapshot->buf);
}
snapshot->buf = snapshot->start = snapshot->eof = NULL;
}
/*
* Decrease the reference count of `*snapshot`. If it goes to zero,
* free `*snapshot` and return true; otherwise return false.
*/
static int release_snapshot(struct snapshot *snapshot)
{
if (!--snapshot->referrers) {
stat_validity_clear(&snapshot->validity);
clear_snapshot_buffer(snapshot);
free(snapshot);
return 1;
} else {
return 0;
}
}
static size_t snapshot_hexsz(const struct snapshot *snapshot)
{
return snapshot->refs->base.repo->hash_algo->hexsz;
}
struct ref_store *packed_ref_store_init(struct repository *repo,
const char *gitdir,
unsigned int store_flags)
{
struct packed_ref_store *refs = xcalloc(1, sizeof(*refs));
struct ref_store *ref_store = (struct ref_store *)refs;
struct strbuf sb = STRBUF_INIT;
base_ref_store_init(ref_store, repo, gitdir, &refs_be_packed);
refs->store_flags = store_flags;
strbuf_addf(&sb, "%s/packed-refs", gitdir);
refs->path = strbuf_detach(&sb, NULL);
chdir_notify_reparent("packed-refs", &refs->path);
return ref_store;
}
/*
* Downcast `ref_store` to `packed_ref_store`. Die if `ref_store` is
* not a `packed_ref_store`. Also die if `packed_ref_store` doesn't
* support at least the flags specified in `required_flags`. `caller`
* is used in any necessary error messages.
*/
static struct packed_ref_store *packed_downcast(struct ref_store *ref_store,
unsigned int required_flags,
const char *caller)
{
struct packed_ref_store *refs;
if (ref_store->be != &refs_be_packed)
BUG("ref_store is type \"%s\" not \"packed\" in %s",
ref_store->be->name, caller);
refs = (struct packed_ref_store *)ref_store;
if ((refs->store_flags & required_flags) != required_flags)
BUG("unallowed operation (%s), requires %x, has %x\n",
caller, required_flags, refs->store_flags);
return refs;
}
static void clear_snapshot(struct packed_ref_store *refs)
{
if (refs->snapshot) {
struct snapshot *snapshot = refs->snapshot;
refs->snapshot = NULL;
release_snapshot(snapshot);
}
}
static void packed_ref_store_release(struct ref_store *ref_store)
{
struct packed_ref_store *refs = packed_downcast(ref_store, 0, "release");
clear_snapshot(refs);
rollback_lock_file(&refs->lock);
delete_tempfile(&refs->tempfile);
free(refs->path);
}
static NORETURN void die_unterminated_line(const char *path,
const char *p, size_t len)
{
if (len < 80)
die("unterminated line in %s: %.*s", path, (int)len, p);
else
die("unterminated line in %s: %.75s...", path, p);
}
static NORETURN void die_invalid_line(const char *path,
const char *p, size_t len)
{
const char *eol = memchr(p, '\n', len);
if (!eol)
die_unterminated_line(path, p, len);
else if (eol - p < 80)
die("unexpected line in %s: %.*s", path, (int)(eol - p), p);
else
die("unexpected line in %s: %.75s...", path, p);
}
struct snapshot_record {
const char *start;
size_t len;
};
static int cmp_packed_ref_records(const void *v1, const void *v2,
void *cb_data)
{
const struct snapshot *snapshot = cb_data;
const struct snapshot_record *e1 = v1, *e2 = v2;
const char *r1 = e1->start + snapshot_hexsz(snapshot) + 1;
const char *r2 = e2->start + snapshot_hexsz(snapshot) + 1;
while (1) {
if (*r1 == '\n')
return *r2 == '\n' ? 0 : -1;
if (*r1 != *r2) {
if (*r2 == '\n')
return 1;
else
return (unsigned char)*r1 < (unsigned char)*r2 ? -1 : +1;
}
r1++;
r2++;
}
}
/*
* Compare a snapshot record at `rec` to the specified NUL-terminated
* refname.
*/
static int cmp_record_to_refname(const char *rec, const char *refname,
int start, const struct snapshot *snapshot)
{
const char *r1 = rec + snapshot_hexsz(snapshot) + 1;
const char *r2 = refname;
while (1) {
if (*r1 == '\n')
return *r2 ? -1 : 0;
if (!*r2)
return start ? 1 : -1;
if (*r1 != *r2)
return (unsigned char)*r1 < (unsigned char)*r2 ? -1 : +1;
r1++;
r2++;
}
}
/*
* `snapshot->buf` is not known to be sorted. Check whether it is, and
* if not, sort it into new memory and munmap/free the old storage.
*/
static void sort_snapshot(struct snapshot *snapshot)
{
struct snapshot_record *records = NULL;
size_t alloc = 0, nr = 0;
int sorted = 1;
const char *pos, *eof, *eol;
size_t len, i;
char *new_buffer, *dst;
pos = snapshot->start;
eof = snapshot->eof;
if (pos == eof)
return;
len = eof - pos;
/*
* Initialize records based on a crude estimate of the number
* of references in the file (we'll grow it below if needed):
*/
ALLOC_GROW(records, len / 80 + 20, alloc);
while (pos < eof) {
eol = memchr(pos, '\n', eof - pos);
if (!eol)
/* The safety check should prevent this. */
BUG("unterminated line found in packed-refs");
if (eol - pos < snapshot_hexsz(snapshot) + 2)
die_invalid_line(snapshot->refs->path,
pos, eof - pos);
eol++;
if (eol < eof && *eol == '^') {
/*
* Keep any peeled line together with its
* reference:
*/
const char *peeled_start = eol;
eol = memchr(peeled_start, '\n', eof - peeled_start);
if (!eol)
/* The safety check should prevent this. */
BUG("unterminated peeled line found in packed-refs");
eol++;
}
ALLOC_GROW(records, nr + 1, alloc);
records[nr].start = pos;
records[nr].len = eol - pos;
nr++;
if (sorted &&
nr > 1 &&
cmp_packed_ref_records(&records[nr - 2],
&records[nr - 1], snapshot) >= 0)
sorted = 0;
pos = eol;
}
if (sorted)
goto cleanup;
/* We need to sort the memory. First we sort the records array: */
QSORT_S(records, nr, cmp_packed_ref_records, snapshot);
/*
* Allocate a new chunk of memory, and copy the old memory to
* the new in the order indicated by `records` (not bothering
* with the header line):
*/
new_buffer = xmalloc(len);
for (dst = new_buffer, i = 0; i < nr; i++) {
memcpy(dst, records[i].start, records[i].len);
dst += records[i].len;
}
/*
* Now munmap the old buffer and use the sorted buffer in its
* place:
*/
clear_snapshot_buffer(snapshot);
snapshot->buf = snapshot->start = new_buffer;
snapshot->eof = new_buffer + len;
cleanup:
free(records);
}
/*
* Return a pointer to the start of the record that contains the
* character `*p` (which must be within the buffer). If no other
* record start is found, return `buf`.
*/
static const char *find_start_of_record(const char *buf, const char *p)
{
while (p > buf && (p[-1] != '\n' || p[0] == '^'))
p--;
return p;
}
/*
* Return a pointer to the start of the record following the record
* that contains `*p`. If none is found before `end`, return `end`.
*/
static const char *find_end_of_record(const char *p, const char *end)
{
while (++p < end && (p[-1] != '\n' || p[0] == '^'))
;
return p;
}
/*
* We want to be able to compare mmapped reference records quickly,
* without totally parsing them. We can do so because the records are
* LF-terminated, and the refname should start exactly (GIT_SHA1_HEXSZ
* + 1) bytes past the beginning of the record.
*
* But what if the `packed-refs` file contains garbage? We're willing
* to tolerate not detecting the problem, as long as we don't produce
* totally garbled output (we can't afford to check the integrity of
* the whole file during every Git invocation). But we do want to be
* sure that we never read past the end of the buffer in memory and
* perform an illegal memory access.
*
* Guarantee that minimum level of safety by verifying that the last
* record in the file is LF-terminated, and that it has at least
* (GIT_SHA1_HEXSZ + 1) characters before the LF. Die if either of
* these checks fails.
*/
static void verify_buffer_safe(struct snapshot *snapshot)
{
const char *start = snapshot->start;
const char *eof = snapshot->eof;
const char *last_line;
if (start == eof)
return;
last_line = find_start_of_record(start, eof - 1);
if (*(eof - 1) != '\n' ||
eof - last_line < snapshot_hexsz(snapshot) + 2)
die_invalid_line(snapshot->refs->path,
last_line, eof - last_line);
}
#define SMALL_FILE_SIZE (32*1024)
/*
* Depending on `mmap_strategy`, either mmap or read the contents of
* the `packed-refs` file into the snapshot. Return 1 if the file
* existed and was read, or 0 if the file was absent or empty. Die on
* errors.
*/
static int load_contents(struct snapshot *snapshot)
{
int fd;
struct stat st;
size_t size;
ssize_t bytes_read;
fd = open(snapshot->refs->path, O_RDONLY);
if (fd < 0) {
if (errno == ENOENT) {
/*
* This is OK; it just means that no
* "packed-refs" file has been written yet,
* which is equivalent to it being empty,
* which is its state when initialized with
* zeros.
*/
return 0;
} else {
die_errno("couldn't read %s", snapshot->refs->path);
}
}
stat_validity_update(&snapshot->validity, fd);
if (fstat(fd, &st) < 0)
die_errno("couldn't stat %s", snapshot->refs->path);
size = xsize_t(st.st_size);
if (!size) {
close(fd);
return 0;
} else if (mmap_strategy == MMAP_NONE || size <= SMALL_FILE_SIZE) {
snapshot->buf = xmalloc(size);
bytes_read = read_in_full(fd, snapshot->buf, size);
if (bytes_read < 0 || bytes_read != size)
die_errno("couldn't read %s", snapshot->refs->path);
snapshot->mmapped = 0;
} else {
snapshot->buf = xmmap(NULL, size, PROT_READ, MAP_PRIVATE, fd, 0);
snapshot->mmapped = 1;
}
close(fd);
snapshot->start = snapshot->buf;
snapshot->eof = snapshot->buf + size;
return 1;
}
static const char *find_reference_location_1(struct snapshot *snapshot,
const char *refname, int mustexist,
int start)
{
/*
* This is not *quite* a garden-variety binary search, because
* the data we're searching is made up of records, and we
* always need to find the beginning of a record to do a
* comparison. A "record" here is one line for the reference
* itself and zero or one peel lines that start with '^'. Our
* loop invariant is described in the next two comments.
*/
/*
* A pointer to the character at the start of a record whose
* preceding records all have reference names that come
* *before* `refname`.
*/
const char *lo = snapshot->start;
/*
* A pointer to a the first character of a record whose
* reference name comes *after* `refname`.
*/
const char *hi = snapshot->eof;
while (lo != hi) {
const char *mid, *rec;
int cmp;
mid = lo + (hi - lo) / 2;
rec = find_start_of_record(lo, mid);
cmp = cmp_record_to_refname(rec, refname, start, snapshot);
if (cmp < 0) {
lo = find_end_of_record(mid, hi);
} else if (cmp > 0) {
hi = rec;
} else {
return rec;
}
}
if (mustexist)
return NULL;
else
return lo;
}
/*
* Find the place in `snapshot->buf` where the start of the record for
* `refname` starts. If `mustexist` is true and the reference doesn't
* exist, then return NULL. If `mustexist` is false and the reference
* doesn't exist, then return the point where that reference would be
* inserted, or `snapshot->eof` (which might be NULL) if it would be
* inserted at the end of the file. In the latter mode, `refname`
* doesn't have to be a proper reference name; for example, one could
* search for "refs/replace/" to find the start of any replace
* references.
*
* The record is sought using a binary search, so `snapshot->buf` must
* be sorted.
*/
static const char *find_reference_location(struct snapshot *snapshot,
const char *refname, int mustexist)
{
return find_reference_location_1(snapshot, refname, mustexist, 1);
}
/*
* Find the place in `snapshot->buf` after the end of the record for
* `refname`. In other words, find the location of first thing *after*
* `refname`.
*
* Other semantics are identical to the ones in
* `find_reference_location()`.
*/
static const char *find_reference_location_end(struct snapshot *snapshot,
const char *refname,
int mustexist)
{
return find_reference_location_1(snapshot, refname, mustexist, 0);
}
/*
* Create a newly-allocated `snapshot` of the `packed-refs` file in
* its current state and return it. The return value will already have
* its reference count incremented.
*
* A comment line of the form "# pack-refs with: " may contain zero or
* more traits. We interpret the traits as follows:
*
* Neither `peeled` nor `fully-peeled`:
*
* Probably no references are peeled. But if the file contains a
* peeled value for a reference, we will use it.
*
* `peeled`:
*
* References under "refs/tags/", if they *can* be peeled, *are*
* peeled in this file. References outside of "refs/tags/" are
* probably not peeled even if they could have been, but if we find
* a peeled value for such a reference we will use it.
*
* `fully-peeled`:
*
* All references in the file that can be peeled are peeled.
* Inversely (and this is more important), any references in the
* file for which no peeled value is recorded is not peelable. This
* trait should typically be written alongside "peeled" for
* compatibility with older clients, but we do not require it
* (i.e., "peeled" is a no-op if "fully-peeled" is set).
*
* `sorted`:
*
* The references in this file are known to be sorted by refname.
*/
static struct snapshot *create_snapshot(struct packed_ref_store *refs)
{
struct snapshot *snapshot = xcalloc(1, sizeof(*snapshot));
int sorted = 0;
snapshot->refs = refs;
acquire_snapshot(snapshot);
snapshot->peeled = PEELED_NONE;
if (!load_contents(snapshot))
return snapshot;
/* If the file has a header line, process it: */
if (snapshot->buf < snapshot->eof && *snapshot->buf == '#') {
char *tmp, *p, *eol;
struct string_list traits = STRING_LIST_INIT_NODUP;
eol = memchr(snapshot->buf, '\n',
snapshot->eof - snapshot->buf);
if (!eol)
die_unterminated_line(refs->path,
snapshot->buf,
snapshot->eof - snapshot->buf);
tmp = xmemdupz(snapshot->buf, eol - snapshot->buf);
if (!skip_prefix(tmp, "# pack-refs with:", (const char **)&p))
die_invalid_line(refs->path,
snapshot->buf,
snapshot->eof - snapshot->buf);
string_list_split_in_place(&traits, p, " ", -1);
if (unsorted_string_list_has_string(&traits, "fully-peeled"))
snapshot->peeled = PEELED_FULLY;
else if (unsorted_string_list_has_string(&traits, "peeled"))
snapshot->peeled = PEELED_TAGS;
sorted = unsorted_string_list_has_string(&traits, "sorted");
/* perhaps other traits later as well */
/* The "+ 1" is for the LF character. */
snapshot->start = eol + 1;
string_list_clear(&traits, 0);
free(tmp);
}
verify_buffer_safe(snapshot);
if (!sorted) {
sort_snapshot(snapshot);
/*
* Reordering the records might have moved a short one
* to the end of the buffer, so verify the buffer's
* safety again:
*/
verify_buffer_safe(snapshot);
}
if (mmap_strategy != MMAP_OK && snapshot->mmapped) {
/*
* We don't want to leave the file mmapped, so we are
* forced to make a copy now:
*/
size_t size = snapshot->eof - snapshot->start;
char *buf_copy = xmalloc(size);
memcpy(buf_copy, snapshot->start, size);
clear_snapshot_buffer(snapshot);
snapshot->buf = snapshot->start = buf_copy;
snapshot->eof = buf_copy + size;
}
return snapshot;
}
/*
* Check that `refs->snapshot` (if present) still reflects the
* contents of the `packed-refs` file. If not, clear the snapshot.
*/
static void validate_snapshot(struct packed_ref_store *refs)
{
if (refs->snapshot &&
!stat_validity_check(&refs->snapshot->validity, refs->path))
clear_snapshot(refs);
}
/*
* Get the `snapshot` for the specified packed_ref_store, creating and
* populating it if it hasn't been read before or if the file has been
* changed (according to its `validity` field) since it was last read.
* On the other hand, if we hold the lock, then assume that the file
* hasn't been changed out from under us, so skip the extra `stat()`
* call in `stat_validity_check()`. This function does *not* increase
* the snapshot's reference count on behalf of the caller.
*/
static struct snapshot *get_snapshot(struct packed_ref_store *refs)
{
if (!is_lock_file_locked(&refs->lock))
validate_snapshot(refs);
if (!refs->snapshot)
refs->snapshot = create_snapshot(refs);
return refs->snapshot;
}
static int packed_read_raw_ref(struct ref_store *ref_store, const char *refname,
struct object_id *oid, struct strbuf *referent UNUSED,
unsigned int *type, int *failure_errno)
{
struct packed_ref_store *refs =
packed_downcast(ref_store, REF_STORE_READ, "read_raw_ref");
struct snapshot *snapshot = get_snapshot(refs);
const char *rec;
*type = 0;
rec = find_reference_location(snapshot, refname, 1);
if (!rec) {
/* refname is not a packed reference. */
*failure_errno = ENOENT;
return -1;
}
if (get_oid_hex_algop(rec, oid, ref_store->repo->hash_algo))
die_invalid_line(refs->path, rec, snapshot->eof - rec);
*type = REF_ISPACKED;
return 0;
}
/*
* This value is set in `base.flags` if the peeled value of the
* current reference is known. In that case, `peeled` contains the
* correct peeled value for the reference, which might be `null_oid`
* if the reference is not a tag or if it is broken.
*/
#define REF_KNOWS_PEELED 0x40
/*
* An iterator over a snapshot of a `packed-refs` file.
*/
struct packed_ref_iterator {
struct ref_iterator base;
struct snapshot *snapshot;
/* The current position in the snapshot's buffer: */
const char *pos;
/* The end of the part of the buffer that will be iterated over: */
const char *eof;
struct jump_list_entry {
const char *start;
const char *end;
} *jump;
size_t jump_nr, jump_alloc;
size_t jump_cur;
/* Scratch space for current values: */
struct object_id oid, peeled;
struct strbuf refname_buf;
struct repository *repo;
unsigned int flags;
};
/*
* Move the iterator to the next record in the snapshot, without
* respect for whether the record is actually required by the current
* iteration. Adjust the fields in `iter` and return `ITER_OK` or
* `ITER_DONE`. This function does not free the iterator in the case
* of `ITER_DONE`.
*/
static int next_record(struct packed_ref_iterator *iter)
{
const char *p, *eol;
strbuf_reset(&iter->refname_buf);
/*
* If iter->pos is contained within a skipped region, jump past
* it.
*
* Note that each skipped region is considered at most once,
* since they are ordered based on their starting position.
*/
while (iter->jump_cur < iter->jump_nr) {
struct jump_list_entry *curr = &iter->jump[iter->jump_cur];
if (iter->pos < curr->start)
break; /* not to the next jump yet */
iter->jump_cur++;
if (iter->pos < curr->end) {
iter->pos = curr->end;
trace2_counter_add(TRACE2_COUNTER_ID_PACKED_REFS_JUMPS, 1);
/* jumps are coalesced, so only one jump is necessary */
break;
}
}
if (iter->pos == iter->eof)
return ITER_DONE;
iter->base.flags = REF_ISPACKED;
p = iter->pos;
if (iter->eof - p < snapshot_hexsz(iter->snapshot) + 2 ||
parse_oid_hex_algop(p, &iter->oid, &p, iter->repo->hash_algo) ||
!isspace(*p++))
die_invalid_line(iter->snapshot->refs->path,
iter->pos, iter->eof - iter->pos);
eol = memchr(p, '\n', iter->eof - p);
if (!eol)
die_unterminated_line(iter->snapshot->refs->path,
iter->pos, iter->eof - iter->pos);
strbuf_add(&iter->refname_buf, p, eol - p);
iter->base.refname = iter->refname_buf.buf;
if (check_refname_format(iter->base.refname, REFNAME_ALLOW_ONELEVEL)) {
if (!refname_is_safe(iter->base.refname))
die("packed refname is dangerous: %s",
iter->base.refname);
oidclr(&iter->oid, iter->repo->hash_algo);
iter->base.flags |= REF_BAD_NAME | REF_ISBROKEN;
}
if (iter->snapshot->peeled == PEELED_FULLY ||
(iter->snapshot->peeled == PEELED_TAGS &&
starts_with(iter->base.refname, "refs/tags/")))
iter->base.flags |= REF_KNOWS_PEELED;
iter->pos = eol + 1;
if (iter->pos < iter->eof && *iter->pos == '^') {
p = iter->pos + 1;
if (iter->eof - p < snapshot_hexsz(iter->snapshot) + 1 ||
parse_oid_hex_algop(p, &iter->peeled, &p, iter->repo->hash_algo) ||
*p++ != '\n')
die_invalid_line(iter->snapshot->refs->path,
iter->pos, iter->eof - iter->pos);
iter->pos = p;
/*
* Regardless of what the file header said, we
* definitely know the value of *this* reference. But
* we suppress it if the reference is broken:
*/
if ((iter->base.flags & REF_ISBROKEN)) {
oidclr(&iter->peeled, iter->repo->hash_algo);
iter->base.flags &= ~REF_KNOWS_PEELED;
} else {
iter->base.flags |= REF_KNOWS_PEELED;
}
} else {
oidclr(&iter->peeled, iter->repo->hash_algo);
}
return ITER_OK;
}
static int packed_ref_iterator_advance(struct ref_iterator *ref_iterator)
{
struct packed_ref_iterator *iter =
(struct packed_ref_iterator *)ref_iterator;
int ok;
while ((ok = next_record(iter)) == ITER_OK) {
if (iter->flags & DO_FOR_EACH_PER_WORKTREE_ONLY &&
!is_per_worktree_ref(iter->base.refname))
continue;
if (!(iter->flags & DO_FOR_EACH_INCLUDE_BROKEN) &&
!ref_resolves_to_object(iter->base.refname, iter->repo,
&iter->oid, iter->flags))
continue;
return ITER_OK;
}
if (ref_iterator_abort(ref_iterator) != ITER_DONE)
ok = ITER_ERROR;
return ok;
}
static int packed_ref_iterator_peel(struct ref_iterator *ref_iterator,
struct object_id *peeled)
{
struct packed_ref_iterator *iter =
(struct packed_ref_iterator *)ref_iterator;
if ((iter->base.flags & REF_KNOWS_PEELED)) {
oidcpy(peeled, &iter->peeled);
return is_null_oid(&iter->peeled) ? -1 : 0;
} else if ((iter->base.flags & (REF_ISBROKEN | REF_ISSYMREF))) {
return -1;
} else {
return peel_object(iter->repo, &iter->oid, peeled) ? -1 : 0;
}
}
static int packed_ref_iterator_abort(struct ref_iterator *ref_iterator)
{
struct packed_ref_iterator *iter =
(struct packed_ref_iterator *)ref_iterator;
int ok = ITER_DONE;
strbuf_release(&iter->refname_buf);
free(iter->jump);
release_snapshot(iter->snapshot);
base_ref_iterator_free(ref_iterator);
return ok;
}
static struct ref_iterator_vtable packed_ref_iterator_vtable = {
.advance = packed_ref_iterator_advance,
.peel = packed_ref_iterator_peel,
.abort = packed_ref_iterator_abort
};
static int jump_list_entry_cmp(const void *va, const void *vb)
{
const struct jump_list_entry *a = va;
const struct jump_list_entry *b = vb;
if (a->start < b->start)
return -1;
if (a->start > b->start)
return 1;
return 0;
}
static int has_glob_special(const char *str)
{
const char *p;
for (p = str; *p; p++) {
if (is_glob_special(*p))
return 1;
}
return 0;
}
static void populate_excluded_jump_list(struct packed_ref_iterator *iter,
struct snapshot *snapshot,
const char **excluded_patterns)
{
size_t i, j;
const char **pattern;
struct jump_list_entry *last_disjoint;
if (!excluded_patterns)
return;
for (pattern = excluded_patterns; *pattern; pattern++) {
struct jump_list_entry *e;
const char *start, *end;
/*
* We can't feed any excludes with globs in them to the
* refs machinery. It only understands prefix matching.
* We likewise can't even feed the string leading up to
* the first meta-character, as something like "foo[a]"
* should not exclude "foobar" (but the prefix "foo"
* would match that and mark it for exclusion).
*/
if (has_glob_special(*pattern))
continue;
start = find_reference_location(snapshot, *pattern, 0);
end = find_reference_location_end(snapshot, *pattern, 0);
if (start == end)
continue; /* nothing to jump over */
ALLOC_GROW(iter->jump, iter->jump_nr + 1, iter->jump_alloc);
e = &iter->jump[iter->jump_nr++];
e->start = start;
e->end = end;
}
if (!iter->jump_nr) {
/*
* Every entry in exclude_patterns has a meta-character,
* nothing to do here.
*/
return;
}
QSORT(iter->jump, iter->jump_nr, jump_list_entry_cmp);
/*
* As an optimization, merge adjacent entries in the jump list
* to jump forwards as far as possible when entering a skipped
* region.
*
* For example, if we have two skipped regions:
*
* [[A, B], [B, C]]
*
* we want to combine that into a single entry jumping from A to
* C.
*/
last_disjoint = iter->jump;
for (i = 1, j = 1; i < iter->jump_nr; i++) {
struct jump_list_entry *ours = &iter->jump[i];
if (ours->start <= last_disjoint->end) {
/* overlapping regions extend the previous one */
last_disjoint->end = last_disjoint->end > ours->end
? last_disjoint->end : ours->end;
} else {
/* otherwise, insert a new region */
iter->jump[j++] = *ours;
last_disjoint = ours;
}
}
iter->jump_nr = j;
iter->jump_cur = 0;
}
static struct ref_iterator *packed_ref_iterator_begin(
struct ref_store *ref_store,
const char *prefix, const char **exclude_patterns,
unsigned int flags)
{
struct packed_ref_store *refs;
struct snapshot *snapshot;
const char *start;
struct packed_ref_iterator *iter;
struct ref_iterator *ref_iterator;
unsigned int required_flags = REF_STORE_READ;
if (!(flags & DO_FOR_EACH_INCLUDE_BROKEN))
required_flags |= REF_STORE_ODB;
refs = packed_downcast(ref_store, required_flags, "ref_iterator_begin");
/*
* Note that `get_snapshot()` internally checks whether the
* snapshot is up to date with what is on disk, and re-reads
* it if not.
*/
snapshot = get_snapshot(refs);
if (prefix && *prefix)
start = find_reference_location(snapshot, prefix, 0);
else
start = snapshot->start;
if (start == snapshot->eof)
return empty_ref_iterator_begin();
CALLOC_ARRAY(iter, 1);
ref_iterator = &iter->base;
base_ref_iterator_init(ref_iterator, &packed_ref_iterator_vtable);
if (exclude_patterns)
populate_excluded_jump_list(iter, snapshot, exclude_patterns);
iter->snapshot = snapshot;
acquire_snapshot(snapshot);
iter->pos = start;
iter->eof = snapshot->eof;
strbuf_init(&iter->refname_buf, 0);
iter->base.oid = &iter->oid;
iter->repo = ref_store->repo;
iter->flags = flags;
if (prefix && *prefix)
/* Stop iteration after we've gone *past* prefix: */
ref_iterator = prefix_ref_iterator_begin(ref_iterator, prefix, 0);
return ref_iterator;
}
/*
* Write an entry to the packed-refs file for the specified refname.
* If peeled is non-NULL, write it as the entry's peeled value. On
* error, return a nonzero value and leave errno set at the value left
* by the failing call to `fprintf()`.
*/
static int write_packed_entry(FILE *fh, const char *refname,
const struct object_id *oid,
const struct object_id *peeled)
{
if (fprintf(fh, "%s %s\n", oid_to_hex(oid), refname) < 0 ||
(peeled && fprintf(fh, "^%s\n", oid_to_hex(peeled)) < 0))
return -1;
return 0;
}
int packed_refs_lock(struct ref_store *ref_store, int flags, struct strbuf *err)
{
struct packed_ref_store *refs =
packed_downcast(ref_store, REF_STORE_WRITE | REF_STORE_MAIN,
"packed_refs_lock");
static int timeout_configured = 0;
static int timeout_value = 1000;
if (!timeout_configured) {
git_config_get_int("core.packedrefstimeout", &timeout_value);
timeout_configured = 1;
}
/*
* Note that we close the lockfile immediately because we
* don't write new content to it, but rather to a separate
* tempfile.
*/
if (hold_lock_file_for_update_timeout(
&refs->lock,
refs->path,
flags, timeout_value) < 0) {
unable_to_lock_message(refs->path, errno, err);
return -1;
}
if (close_lock_file_gently(&refs->lock)) {
strbuf_addf(err, "unable to close %s: %s", refs->path, strerror(errno));
rollback_lock_file(&refs->lock);
return -1;
}
/*
* There is a stat-validity problem might cause `update-ref -d`
* lost the newly commit of a ref, because a new `packed-refs`
* file might has the same on-disk file attributes such as
* timestamp, file size and inode value, but has a changed
* ref value.
*
* This could happen with a very small chance when
* `update-ref -d` is called and at the same time another
* `pack-refs --all` process is running.
*
* Now that we hold the `packed-refs` lock, it is important
* to make sure we could read the latest version of
* `packed-refs` file no matter we have just mmap it or not.
* So what need to do is clear the snapshot if we hold it
* already.
*/
clear_snapshot(refs);
/*
* Now make sure that the packed-refs file as it exists in the
* locked state is loaded into the snapshot:
*/
get_snapshot(refs);
return 0;
}
void packed_refs_unlock(struct ref_store *ref_store)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ | REF_STORE_WRITE,
"packed_refs_unlock");
if (!is_lock_file_locked(&refs->lock))
BUG("packed_refs_unlock() called when not locked");
rollback_lock_file(&refs->lock);
}
int packed_refs_is_locked(struct ref_store *ref_store)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ | REF_STORE_WRITE,
"packed_refs_is_locked");
return is_lock_file_locked(&refs->lock);
}
/*
* The packed-refs header line that we write out. Perhaps other traits
* will be added later.
*
* Note that earlier versions of Git used to parse these traits by
* looking for " trait " in the line. For this reason, the space after
* the colon and the trailing space are required.
*/
static const char PACKED_REFS_HEADER[] =
"# pack-refs with: peeled fully-peeled sorted \n";
static int packed_ref_store_create_on_disk(struct ref_store *ref_store UNUSED,
int flags UNUSED,
struct strbuf *err UNUSED)
{
/* Nothing to do. */
return 0;
}
static int packed_ref_store_remove_on_disk(struct ref_store *ref_store,
struct strbuf *err)
{
struct packed_ref_store *refs = packed_downcast(ref_store, 0, "remove");
if (remove_path(refs->path) < 0) {
strbuf_addstr(err, "could not delete packed-refs");
return -1;
}
return 0;
}
/*
* Write the packed refs from the current snapshot to the packed-refs
* tempfile, incorporating any changes from `updates`. `updates` must
* be a sorted string list whose keys are the refnames and whose util
* values are `struct ref_update *`. On error, rollback the tempfile,
* write an error message to `err`, and return a nonzero value.
*
* The packfile must be locked before calling this function and will
* remain locked when it is done.
*/
static int write_with_updates(struct packed_ref_store *refs,
struct string_list *updates,
struct strbuf *err)
{
struct ref_iterator *iter = NULL;
size_t i;
int ok;
FILE *out;
struct strbuf sb = STRBUF_INIT;
char *packed_refs_path;
if (!is_lock_file_locked(&refs->lock))
BUG("write_with_updates() called while unlocked");
/*
* If packed-refs is a symlink, we want to overwrite the
* symlinked-to file, not the symlink itself. Also, put the
* staging file next to it:
*/
packed_refs_path = get_locked_file_path(&refs->lock);
strbuf_addf(&sb, "%s.new", packed_refs_path);
free(packed_refs_path);
refs->tempfile = create_tempfile(sb.buf);
if (!refs->tempfile) {
strbuf_addf(err, "unable to create file %s: %s",
sb.buf, strerror(errno));
strbuf_release(&sb);
return -1;
}
strbuf_release(&sb);
out = fdopen_tempfile(refs->tempfile, "w");
if (!out) {
strbuf_addf(err, "unable to fdopen packed-refs tempfile: %s",
strerror(errno));
goto error;
}
if (fprintf(out, "%s", PACKED_REFS_HEADER) < 0)
goto write_error;
/*
* We iterate in parallel through the current list of refs and
* the list of updates, processing an entry from at least one
* of the lists each time through the loop. When the current
* list of refs is exhausted, set iter to NULL. When the list
* of updates is exhausted, leave i set to updates->nr.
*/
iter = packed_ref_iterator_begin(&refs->base, "", NULL,
DO_FOR_EACH_INCLUDE_BROKEN);
if ((ok = ref_iterator_advance(iter)) != ITER_OK)
iter = NULL;
i = 0;
while (iter || i < updates->nr) {
struct ref_update *update = NULL;
int cmp;
if (i >= updates->nr) {
cmp = -1;
} else {
update = updates->items[i].util;
if (!iter)
cmp = +1;
else
cmp = strcmp(iter->refname, update->refname);
}
if (!cmp) {
/*
* There is both an old value and an update
* for this reference. Check the old value if
* necessary:
*/
if ((update->flags & REF_HAVE_OLD)) {
if (is_null_oid(&update->old_oid)) {
strbuf_addf(err, "cannot update ref '%s': "
"reference already exists",
update->refname);
goto error;
} else if (!oideq(&update->old_oid, iter->oid)) {
strbuf_addf(err, "cannot update ref '%s': "
"is at %s but expected %s",
update->refname,
oid_to_hex(iter->oid),
oid_to_hex(&update->old_oid));
goto error;
}
}
/* Now figure out what to use for the new value: */
if ((update->flags & REF_HAVE_NEW)) {
/*
* The update takes precedence. Skip
* the iterator over the unneeded
* value.
*/
if ((ok = ref_iterator_advance(iter)) != ITER_OK)
iter = NULL;
cmp = +1;
} else {
/*
* The update doesn't actually want to
* change anything. We're done with it.
*/
i++;
cmp = -1;
}
} else if (cmp > 0) {
/*
* There is no old value but there is an
* update for this reference. Make sure that
* the update didn't expect an existing value:
*/
if ((update->flags & REF_HAVE_OLD) &&
!is_null_oid(&update->old_oid)) {
strbuf_addf(err, "cannot update ref '%s': "
"reference is missing but expected %s",
update->refname,
oid_to_hex(&update->old_oid));
goto error;
}
}
if (cmp < 0) {
/* Pass the old reference through. */
struct object_id peeled;
int peel_error = ref_iterator_peel(iter, &peeled);
if (write_packed_entry(out, iter->refname,
iter->oid,
peel_error ? NULL : &peeled))
goto write_error;
if ((ok = ref_iterator_advance(iter)) != ITER_OK)
iter = NULL;
} else if (is_null_oid(&update->new_oid)) {
/*
* The update wants to delete the reference,
* and the reference either didn't exist or we
* have already skipped it. So we're done with
* the update (and don't have to write
* anything).
*/
i++;
} else {
struct object_id peeled;
int peel_error = peel_object(refs->base.repo,
&update->new_oid,
&peeled);
if (write_packed_entry(out, update->refname,
&update->new_oid,
peel_error ? NULL : &peeled))
goto write_error;
i++;
}
}
if (ok != ITER_DONE) {
strbuf_addstr(err, "unable to write packed-refs file: "
"error iterating over old contents");
goto error;
}
if (fflush(out) ||
fsync_component(FSYNC_COMPONENT_REFERENCE, get_tempfile_fd(refs->tempfile)) ||
close_tempfile_gently(refs->tempfile)) {
strbuf_addf(err, "error closing file %s: %s",
get_tempfile_path(refs->tempfile),
strerror(errno));
strbuf_release(&sb);
delete_tempfile(&refs->tempfile);
return -1;
}
return 0;
write_error:
strbuf_addf(err, "error writing to %s: %s",
get_tempfile_path(refs->tempfile), strerror(errno));
error:
if (iter)
ref_iterator_abort(iter);
delete_tempfile(&refs->tempfile);
return -1;
}
int is_packed_transaction_needed(struct ref_store *ref_store,
struct ref_transaction *transaction)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ,
"is_packed_transaction_needed");
struct strbuf referent = STRBUF_INIT;
size_t i;
int ret;
if (!is_lock_file_locked(&refs->lock))
BUG("is_packed_transaction_needed() called while unlocked");
/*
* We're only going to bother returning false for the common,
* trivial case that references are only being deleted, their
* old values are not being checked, and the old `packed-refs`
* file doesn't contain any of those reference(s). This gives
* false positives for some other cases that could
* theoretically be optimized away:
*
* 1. It could be that the old value is being verified without
* setting a new value. In this case, we could verify the
* old value here and skip the update if it agrees. If it
* disagrees, we could either let the update go through
* (the actual commit would re-detect and report the
* problem), or come up with a way of reporting such an
* error to *our* caller.
*
* 2. It could be that a new value is being set, but that it
* is identical to the current packed value of the
* reference.
*
* Neither of these cases will come up in the current code,
* because the only caller of this function passes to it a
* transaction that only includes `delete` updates with no
* `old_id`. Even if that ever changes, false positives only
* cause an optimization to be missed; they do not affect
* correctness.
*/
/*
* Start with the cheap checks that don't require old
* reference values to be read:
*/
for (i = 0; i < transaction->nr; i++) {
struct ref_update *update = transaction->updates[i];
if (update->flags & REF_HAVE_OLD)
/* Have to check the old value -> needed. */
return 1;
if ((update->flags & REF_HAVE_NEW) && !is_null_oid(&update->new_oid))
/* Have to set a new value -> needed. */
return 1;
}
/*
* The transaction isn't checking any old values nor is it
* setting any nonzero new values, so it still might be able
* to be skipped. Now do the more expensive check: the update
* is needed if any of the updates is a delete, and the old
* `packed-refs` file contains a value for that reference.
*/
ret = 0;
for (i = 0; i < transaction->nr; i++) {
struct ref_update *update = transaction->updates[i];
int failure_errno;
unsigned int type;
struct object_id oid;
if (!(update->flags & REF_HAVE_NEW))
/*
* This reference isn't being deleted -> not
* needed.
*/
continue;
if (!refs_read_raw_ref(ref_store, update->refname, &oid,
&referent, &type, &failure_errno) ||
failure_errno != ENOENT) {
/*
* We have to actually delete that reference
* -> this transaction is needed.
*/
ret = 1;
break;
}
}
strbuf_release(&referent);
return ret;
}
struct packed_transaction_backend_data {
/* True iff the transaction owns the packed-refs lock. */
int own_lock;
struct string_list updates;
};
static void packed_transaction_cleanup(struct packed_ref_store *refs,
struct ref_transaction *transaction)
{
struct packed_transaction_backend_data *data = transaction->backend_data;
if (data) {
string_list_clear(&data->updates, 0);
if (is_tempfile_active(refs->tempfile))
delete_tempfile(&refs->tempfile);
if (data->own_lock && is_lock_file_locked(&refs->lock)) {
packed_refs_unlock(&refs->base);
data->own_lock = 0;
}
free(data);
transaction->backend_data = NULL;
}
transaction->state = REF_TRANSACTION_CLOSED;
}
static int packed_transaction_prepare(struct ref_store *ref_store,
struct ref_transaction *transaction,
struct strbuf *err)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ | REF_STORE_WRITE | REF_STORE_ODB,
"ref_transaction_prepare");
struct packed_transaction_backend_data *data;
size_t i;
int ret = TRANSACTION_GENERIC_ERROR;
/*
* Note that we *don't* skip transactions with zero updates,
* because such a transaction might be executed for the side
* effect of ensuring that all of the references are peeled or
* ensuring that the `packed-refs` file is sorted. If the
* caller wants to optimize away empty transactions, it should
* do so itself.
*/
CALLOC_ARRAY(data, 1);
string_list_init_nodup(&data->updates);
transaction->backend_data = data;
/*
* Stick the updates in a string list by refname so that we
* can sort them:
*/
for (i = 0; i < transaction->nr; i++) {
struct ref_update *update = transaction->updates[i];
struct string_list_item *item =
string_list_append(&data->updates, update->refname);
/* Store a pointer to update in item->util: */
item->util = update;
}
string_list_sort(&data->updates);
if (ref_update_reject_duplicates(&data->updates, err))
goto failure;
if (!is_lock_file_locked(&refs->lock)) {
if (packed_refs_lock(ref_store, 0, err))
goto failure;
data->own_lock = 1;
}
if (write_with_updates(refs, &data->updates, err))
goto failure;
transaction->state = REF_TRANSACTION_PREPARED;
return 0;
failure:
packed_transaction_cleanup(refs, transaction);
return ret;
}
static int packed_transaction_abort(struct ref_store *ref_store,
struct ref_transaction *transaction,
struct strbuf *err UNUSED)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ | REF_STORE_WRITE | REF_STORE_ODB,
"ref_transaction_abort");
packed_transaction_cleanup(refs, transaction);
return 0;
}
static int packed_transaction_finish(struct ref_store *ref_store,
struct ref_transaction *transaction,
struct strbuf *err)
{
struct packed_ref_store *refs = packed_downcast(
ref_store,
REF_STORE_READ | REF_STORE_WRITE | REF_STORE_ODB,
"ref_transaction_finish");
int ret = TRANSACTION_GENERIC_ERROR;
char *packed_refs_path;
clear_snapshot(refs);
packed_refs_path = get_locked_file_path(&refs->lock);
if (rename_tempfile(&refs->tempfile, packed_refs_path)) {
strbuf_addf(err, "error replacing %s: %s",
refs->path, strerror(errno));
goto cleanup;
}
ret = 0;
cleanup:
free(packed_refs_path);
packed_transaction_cleanup(refs, transaction);
return ret;
}
static int packed_initial_transaction_commit(struct ref_store *ref_store UNUSED,
struct ref_transaction *transaction,
struct strbuf *err)
{
return ref_transaction_commit(transaction, err);
}
static int packed_pack_refs(struct ref_store *ref_store UNUSED,
struct pack_refs_opts *pack_opts UNUSED)
{
/*
* Packed refs are already packed. It might be that loose refs
* are packed *into* a packed refs store, but that is done by
* updating the packed references via a transaction.
*/
return 0;
}
static struct ref_iterator *packed_reflog_iterator_begin(struct ref_store *ref_store UNUSED)
{
return empty_ref_iterator_begin();
}
static int packed_fsck(struct ref_store *ref_store UNUSED,
struct fsck_options *o UNUSED)
{
return 0;
}
struct ref_storage_be refs_be_packed = {
.name = "packed",
.init = packed_ref_store_init,
.release = packed_ref_store_release,
.create_on_disk = packed_ref_store_create_on_disk,
.remove_on_disk = packed_ref_store_remove_on_disk,
.transaction_prepare = packed_transaction_prepare,
.transaction_finish = packed_transaction_finish,
.transaction_abort = packed_transaction_abort,
.initial_transaction_commit = packed_initial_transaction_commit,
.pack_refs = packed_pack_refs,
.rename_ref = NULL,
.copy_ref = NULL,
.iterator_begin = packed_ref_iterator_begin,
.read_raw_ref = packed_read_raw_ref,
.read_symbolic_ref = NULL,
.reflog_iterator_begin = packed_reflog_iterator_begin,
.for_each_reflog_ent = NULL,
.for_each_reflog_ent_reverse = NULL,
.reflog_exists = NULL,
.create_reflog = NULL,
.delete_reflog = NULL,
.reflog_expire = NULL,
.fsck = packed_fsck,
};