git/refs/packed-backend.c
Patrick Steinhardt e7da938570 global: introduce USE_THE_REPOSITORY_VARIABLE macro
Use of the `the_repository` variable is deprecated nowadays, and we
slowly but steadily convert the codebase to not use it anymore. Instead,
callers should be passing down the repository to work on via parameters.

It is hard though to prove that a given code unit does not use this
variable anymore. The most trivial case, merely demonstrating that there
is no direct use of `the_repository`, is already a bit of a pain during
code reviews as the reviewer needs to manually verify claims made by the
patch author. The bigger problem though is that we have many interfaces
that implicitly rely on `the_repository`.

Introduce a new `USE_THE_REPOSITORY_VARIABLE` macro that allows code
units to opt into usage of `the_repository`. The intent of this macro is
to demonstrate that a certain code unit does not use this variable
anymore, and to keep it from new dependencies on it in future changes,
be it explicit or implicit

For now, the macro only guards `the_repository` itself as well as
`the_hash_algo`. There are many more known interfaces where we have an
implicit dependency on `the_repository`, but those are not guarded at
the current point in time. Over time though, we should start to add
guards as required (or even better, just remove them).

Define the macro as required in our code units. As expected, most of our
code still relies on the global variable. Nearly all of our builtins
rely on the variable as there is no way yet to pass `the_repository` to
their entry point. For now, declare the macro in "biultin.h" to keep the
required changes at least a little bit more contained.

Signed-off-by: Patrick Steinhardt <ps@pks.im>
Signed-off-by: Junio C Hamano <gitster@pobox.com>
2024-06-14 10:26:33 -07:00

1766 lines
47 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(rec, oid))
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(p, &iter->oid, &p) ||
!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, the_repository->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(p, &iter->peeled, &p) ||
*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, the_repository->hash_algo);
iter->base.flags &= ~REF_KNOWS_PEELED;
} else {
iter->base.flags |= REF_KNOWS_PEELED;
}
} else {
oidclr(&iter->peeled, the_repository->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();
}
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,
};