git/builtin/repack.c

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#include "builtin.h"
#include "cache.h"
#include "config.h"
#include "dir.h"
#include "parse-options.h"
#include "run-command.h"
#include "sigchain.h"
#include "strbuf.h"
#include "string-list.h"
#include "strvec.h"
#include "midx.h"
#include "packfile.h"
#include "prune-packed.h"
#include "object-store.h"
#include "promisor-remote.h"
#include "shallow.h"
#include "pack.h"
#include "pack-bitmap.h"
#include "refs.h"
#define ALL_INTO_ONE 1
#define LOOSEN_UNREACHABLE 2
#define PACK_CRUFT 4
#define DELETE_PACK 1
#define CRUFT_PACK 2
static int pack_everything;
static int delta_base_offset = 1;
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
static int pack_kept_objects = -1;
static int write_bitmaps = -1;
static int use_delta_islands;
static int run_update_server_info = 1;
repack: avoid loosening promisor objects in partial clones When `git repack -A -d` is run in a partial clone, `pack-objects` is invoked twice: once to repack all promisor objects, and once to repack all non-promisor objects. The latter `pack-objects` invocation is with --exclude-promisor-objects and --unpack-unreachable, which loosens all objects unused during this invocation. Unfortunately, this includes promisor objects. Because the -d argument to `git repack` subsequently deletes all loose objects also in packs, these just-loosened promisor objects will be immediately deleted. However, this extra disk churn is unnecessary in the first place. For example, in a newly-cloned partial repo that filters all blob objects (e.g. `--filter=blob:none`), `repack` ends up unpacking all trees and commits into the filesystem because every object, in this particular case, is a promisor object. Depending on the repo size, this increases the disk usage considerably: In my copy of the linux.git, the object directory peaked 26GB of more disk usage. In order to avoid this extra disk churn, pass the names of the promisor packfiles as --keep-pack arguments to the second invocation of `pack-objects`. This informs `pack-objects` that the promisor objects are already in a safe packfile and, therefore, do not need to be loosened. For testing, we need to validate whether any object was loosened. However, the "evidence" (loosened objects) is deleted during the process which prevents us from inspecting the object directory. Instead, let's teach `pack-objects` to count loosened objects and emit via trace2 thus allowing inspecting the debug events after the process is finished. This new event is used on the added regression test. Lastly, add a new perf test to evaluate the performance impact made by this changes (tested on git.git): Test HEAD^ HEAD ---------------------------------------------------------- 5600.3: gc 134.38(41.93+90.95) 7.80(6.72+1.35) -94.2% For a bigger repository, such as linux.git, the improvement is even bigger: Test HEAD^ HEAD ------------------------------------------------------------------- 5600.3: gc 6833.00(918.07+3162.74) 268.79(227.02+39.18) -96.1% These improvements are particular big because every object in the newly-cloned partial repository is a promisor object. Reported-by: SZEDER Gábor <szeder.dev@gmail.com> Helped-by: Jeff King <peff@peff.net> Helped-by: Jonathan Tan <jonathantanmy@google.com> Signed-off-by: Rafael Silva <rafaeloliveira.cs@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-04-21 19:32:12 +00:00
static char *packdir, *packtmp_name, *packtmp;
static char *cruft_expiration;
static const char *const git_repack_usage[] = {
N_("git repack [<options>]"),
NULL
};
static const char incremental_bitmap_conflict_error[] = N_(
"Incremental repacks are incompatible with bitmap indexes. Use\n"
"--no-write-bitmap-index or disable the pack.writeBitmaps configuration."
);
struct pack_objects_args {
const char *window;
const char *window_memory;
const char *depth;
const char *threads;
const char *max_pack_size;
int no_reuse_delta;
int no_reuse_object;
int quiet;
int local;
};
static int repack_config(const char *var, const char *value, void *cb)
{
struct pack_objects_args *cruft_po_args = cb;
if (!strcmp(var, "repack.usedeltabaseoffset")) {
delta_base_offset = git_config_bool(var, value);
return 0;
}
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
if (!strcmp(var, "repack.packkeptobjects")) {
pack_kept_objects = git_config_bool(var, value);
return 0;
}
if (!strcmp(var, "repack.writebitmaps") ||
!strcmp(var, "pack.writebitmaps")) {
write_bitmaps = git_config_bool(var, value);
return 0;
}
if (!strcmp(var, "repack.usedeltaislands")) {
use_delta_islands = git_config_bool(var, value);
return 0;
}
if (strcmp(var, "repack.updateserverinfo") == 0) {
run_update_server_info = git_config_bool(var, value);
return 0;
}
if (!strcmp(var, "repack.cruftwindow"))
return git_config_string(&cruft_po_args->window, var, value);
if (!strcmp(var, "repack.cruftwindowmemory"))
return git_config_string(&cruft_po_args->window_memory, var, value);
if (!strcmp(var, "repack.cruftdepth"))
return git_config_string(&cruft_po_args->depth, var, value);
if (!strcmp(var, "repack.cruftthreads"))
return git_config_string(&cruft_po_args->threads, var, value);
return git_default_config(var, value, cb);
}
/*
* Adds all packs hex strings to either fname_nonkept_list or
* fname_kept_list based on whether each pack has a corresponding
* .keep file or not. Packs without a .keep file are not to be kept
* if we are going to pack everything into one file.
*/
static void collect_pack_filenames(struct string_list *fname_nonkept_list,
struct string_list *fname_kept_list,
const struct string_list *extra_keep)
{
DIR *dir;
struct dirent *e;
char *fname;
if (!(dir = opendir(packdir)))
return;
while ((e = readdir(dir)) != NULL) {
size_t len;
int i;
if (!strip_suffix(e->d_name, ".pack", &len))
continue;
for (i = 0; i < extra_keep->nr; i++)
if (!fspathcmp(e->d_name, extra_keep->items[i].string))
break;
fname = xmemdupz(e->d_name, len);
if ((extra_keep->nr > 0 && i < extra_keep->nr) ||
(file_exists(mkpath("%s/%s.keep", packdir, fname)))) {
string_list_append_nodup(fname_kept_list, fname);
} else {
struct string_list_item *item;
item = string_list_append_nodup(fname_nonkept_list,
fname);
if (file_exists(mkpath("%s/%s.mtimes", packdir, fname)))
item->util = (void*)(uintptr_t)CRUFT_PACK;
}
}
closedir(dir);
string_list_sort(fname_kept_list);
}
static void remove_redundant_pack(const char *dir_name, const char *base_name)
{
struct strbuf buf = STRBUF_INIT;
midx: traverse the local MIDX first When a repository has an alternate object directory configured, callers can traverse through each alternate's MIDX by walking the '->next' pointer. But, when 'prepare_multi_pack_index_one()' loads multiple MIDXs, it places the new ones at the front of this pointer chain, not at the end. This can be confusing for callers such as 'git repack -ad', causing test failures like in t7700.6 with 'GIT_TEST_MULTI_PACK_INDEX=1'. The occurs when dropping a pack known to the local MIDX with alternates configured that have their own MIDX. Since the alternate's MIDX is returned via 'get_multi_pack_index()', 'midx_contains_pack()' returns true (which is correct, since it traverses through the '->next' pointer to find the MIDX in the chain that does contain the requested object). But, we call 'clear_midx_file()' on 'the_repository', which drops the MIDX at the path of the first MIDX in the chain, which (in the case of t7700.6 is the one in the alternate). This patch addresses that by: - placing the local MIDX first in the chain when calling 'prepare_multi_pack_index_one()', and - introducing a new 'get_local_multi_pack_index()', which explicitly returns the repository-local MIDX, if any. Don't impose an additional order on the MIDX's '->next' pointer beyond that the first item in the chain must be local if one exists so that we avoid a quadratic insertion. Likewise, use 'get_local_multi_pack_index()' in 'remove_redundant_pack()' to fix the formerly broken t7700.6 when run with 'GIT_TEST_MULTI_PACK_INDEX=1'. Finally, note that the MIDX ordering invariant is only preserved by the insertion order in 'prepare_packed_git()', which traverses through the ODB's '->next' pointer, meaning we visit the local object store first. This fragility makes this an undesirable long-term solution if more callers are added, but it is acceptable for now since this is the only caller. Helped-by: Jeff King <peff@peff.net> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-28 20:22:13 +00:00
struct multi_pack_index *m = get_local_multi_pack_index(the_repository);
strbuf_addf(&buf, "%s.pack", base_name);
if (m && midx_contains_pack(m, buf.buf))
clear_midx_file(the_repository);
strbuf_insertf(&buf, 0, "%s/", dir_name);
unlink_pack_path(buf.buf, 1);
strbuf_release(&buf);
}
static void prepare_pack_objects(struct child_process *cmd,
const struct pack_objects_args *args)
{
strvec_push(&cmd->args, "pack-objects");
if (args->window)
strvec_pushf(&cmd->args, "--window=%s", args->window);
if (args->window_memory)
strvec_pushf(&cmd->args, "--window-memory=%s", args->window_memory);
if (args->depth)
strvec_pushf(&cmd->args, "--depth=%s", args->depth);
if (args->threads)
strvec_pushf(&cmd->args, "--threads=%s", args->threads);
if (args->max_pack_size)
strvec_pushf(&cmd->args, "--max-pack-size=%s", args->max_pack_size);
if (args->no_reuse_delta)
strvec_pushf(&cmd->args, "--no-reuse-delta");
if (args->no_reuse_object)
strvec_pushf(&cmd->args, "--no-reuse-object");
if (args->local)
strvec_push(&cmd->args, "--local");
if (args->quiet)
strvec_push(&cmd->args, "--quiet");
if (delta_base_offset)
strvec_push(&cmd->args, "--delta-base-offset");
strvec_push(&cmd->args, packtmp);
cmd->git_cmd = 1;
cmd->out = -1;
}
/*
* Write oid to the given struct child_process's stdin, starting it first if
* necessary.
*/
static int write_oid(const struct object_id *oid, struct packed_git *pack,
uint32_t pos, void *data)
{
struct child_process *cmd = data;
if (cmd->in == -1) {
if (start_command(cmd))
die(_("could not start pack-objects to repack promisor objects"));
}
xwrite(cmd->in, oid_to_hex(oid), the_hash_algo->hexsz);
xwrite(cmd->in, "\n", 1);
return 0;
}
static struct {
const char *name;
unsigned optional:1;
} exts[] = {
{".pack"},
packfile: prepare for the existence of '*.rev' files Specify the format of the on-disk reverse index 'pack-*.rev' file, as well as prepare the code for the existence of such files. The reverse index maps from pack relative positions (i.e., an index into the array of object which is sorted by their offsets within the packfile) to their position within the 'pack-*.idx' file. Today, this is done by building up a list of (off_t, uint32_t) tuples for each object (the off_t corresponding to that object's offset, and the uint32_t corresponding to its position in the index). To convert between pack and index position quickly, this array of tuples is radix sorted based on its offset. This has two major drawbacks: First, the in-memory cost scales linearly with the number of objects in a pack. Each 'struct revindex_entry' is sizeof(off_t) + sizeof(uint32_t) + padding bytes for a total of 16. To observe this, force Git to load the reverse index by, for e.g., running 'git cat-file --batch-check="%(objectsize:disk)"'. When asking for a single object in a fresh clone of the kernel, Git needs to allocate 120+ MB of memory in order to hold the reverse index in memory. Second, the cost to sort also scales with the size of the pack. Luckily, this is a linear function since 'load_pack_revindex()' uses a radix sort, but this cost still must be paid once per pack per process. As an example, it takes ~60x longer to print the _size_ of an object as it does to print that entire object's _contents_: Benchmark #1: git.compile cat-file --batch <obj Time (mean ± σ): 3.4 ms ± 0.1 ms [User: 3.3 ms, System: 2.1 ms] Range (min … max): 3.2 ms … 3.7 ms 726 runs Benchmark #2: git.compile cat-file --batch-check="%(objectsize:disk)" <obj Time (mean ± σ): 210.3 ms ± 8.9 ms [User: 188.2 ms, System: 23.2 ms] Range (min … max): 193.7 ms … 224.4 ms 13 runs Instead, avoid computing and sorting the revindex once per process by writing it to a file when the pack itself is generated. The format is relatively straightforward. It contains an array of uint32_t's, the length of which is equal to the number of objects in the pack. The ith entry in this table contains the index position of the ith object in the pack, where "ith object in the pack" is determined by pack offset. One thing that the on-disk format does _not_ contain is the full (up to) eight-byte offset corresponding to each object. This is something that the in-memory revindex contains (it stores an off_t in 'struct revindex_entry' along with the same uint32_t that the on-disk format has). Omit it in the on-disk format, since knowing the index position for some object is sufficient to get a constant-time lookup in the pack-*.idx file to ask for an object's offset within the pack. This trades off between the on-disk size of the 'pack-*.rev' file for runtime to chase down the offset for some object. Even though the lookup is constant time, the constant is heavier, since it can potentially involve two pointer walks in v2 indexes (one to access the 4-byte offset table, and potentially a second to access the double wide offset table). Consider trying to map an object's pack offset to a relative position within that pack. In a cold-cache scenario, more page faults occur while switching between binary searching through the reverse index and searching through the *.idx file for an object's offset. Sure enough, with a cold cache (writing '3' into '/proc/sys/vm/drop_caches' after 'sync'ing), printing out the entire object's contents is still marginally faster than printing its size: Benchmark #1: git.compile cat-file --batch-check="%(objectsize:disk)" <obj >/dev/null Time (mean ± σ): 22.6 ms ± 0.5 ms [User: 2.4 ms, System: 7.9 ms] Range (min … max): 21.4 ms … 23.5 ms 41 runs Benchmark #2: git.compile cat-file --batch <obj >/dev/null Time (mean ± σ): 17.2 ms ± 0.7 ms [User: 2.8 ms, System: 5.5 ms] Range (min … max): 15.6 ms … 18.2 ms 45 runs (Numbers taken in the kernel after cheating and using the next patch to generate a reverse index). There are a couple of approaches to improve cold cache performance not pursued here: - We could include the object offsets in the reverse index format. Predictably, this does result in fewer page faults, but it triples the size of the file, while simultaneously duplicating a ton of data already available in the .idx file. (This was the original way I implemented the format, and it did show `--batch-check='%(objectsize:disk)'` winning out against `--batch`.) On the other hand, this increase in size also results in a large block-cache footprint, which could potentially hurt other workloads. - We could store the mapping from pack to index position in more cache-friendly way, like constructing a binary search tree from the table and writing the values in breadth-first order. This would result in much better locality, but the price you pay is trading O(1) lookup in 'pack_pos_to_index()' for an O(log n) one (since you can no longer directly index the table). So, neither of these approaches are taken here. (Thankfully, the format is versioned, so we are free to pursue these in the future.) But, cold cache performance likely isn't interesting outside of one-off cases like asking for the size of an object directly. In real-world usage, Git is often performing many operations in the revindex (i.e., asking about many objects rather than a single one). The trade-off is worth it, since we will avoid the vast majority of the cost of generating the revindex that the extra pointer chase will look like noise in the following patch's benchmarks. This patch describes the format and prepares callers (like in pack-revindex.c) to be able to read *.rev files once they exist. An implementation of the writer will appear in the next patch, and callers will gradually begin to start using the writer in the patches that follow after that. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-01-25 23:37:14 +00:00
{".rev", 1},
{".mtimes", 1},
{".bitmap", 1},
{".promisor", 1},
{".idx"},
};
struct generated_pack_data {
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
struct tempfile *tempfiles[ARRAY_SIZE(exts)];
};
static struct generated_pack_data *populate_pack_exts(const char *name)
{
struct stat statbuf;
struct strbuf path = STRBUF_INIT;
struct generated_pack_data *data = xcalloc(1, sizeof(*data));
int i;
for (i = 0; i < ARRAY_SIZE(exts); i++) {
strbuf_reset(&path);
strbuf_addf(&path, "%s-%s%s", packtmp, name, exts[i].name);
if (stat(path.buf, &statbuf))
continue;
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
data->tempfiles[i] = register_tempfile(path.buf);
}
strbuf_release(&path);
return data;
}
static void repack_promisor_objects(const struct pack_objects_args *args,
struct string_list *names)
{
struct child_process cmd = CHILD_PROCESS_INIT;
FILE *out;
struct strbuf line = STRBUF_INIT;
prepare_pack_objects(&cmd, args);
cmd.in = -1;
/*
* NEEDSWORK: Giving pack-objects only the OIDs without any ordering
* hints may result in suboptimal deltas in the resulting pack. See if
* the OIDs can be sent with fake paths such that pack-objects can use a
* {type -> existing pack order} ordering when computing deltas instead
* of a {type -> size} ordering, which may produce better deltas.
*/
for_each_packed_object(write_oid, &cmd,
FOR_EACH_OBJECT_PROMISOR_ONLY);
if (cmd.in == -1) {
/* No packed objects; cmd was never started */
child_process_clear(&cmd);
return;
}
close(cmd.in);
out = xfdopen(cmd.out, "r");
while (strbuf_getline_lf(&line, out) != EOF) {
struct string_list_item *item;
char *promisor_name;
if (line.len != the_hash_algo->hexsz)
die(_("repack: Expecting full hex object ID lines only from pack-objects."));
item = string_list_append(names, line.buf);
/*
* pack-objects creates the .pack and .idx files, but not the
* .promisor file. Create the .promisor file, which is empty.
*
* NEEDSWORK: fetch-pack sometimes generates non-empty
* .promisor files containing the ref names and associated
* hashes at the point of generation of the corresponding
* packfile, but this would not preserve their contents. Maybe
* concatenate the contents of all .promisor files instead of
* just creating a new empty file.
*/
promisor_name = mkpathdup("%s-%s.promisor", packtmp,
line.buf);
write_promisor_file(promisor_name, NULL, 0);
item->util = populate_pack_exts(item->string);
free(promisor_name);
}
fclose(out);
if (finish_command(&cmd))
die(_("could not finish pack-objects to repack promisor objects"));
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
struct pack_geometry {
struct packed_git **pack;
uint32_t pack_nr, pack_alloc;
uint32_t split;
};
static uint32_t geometry_pack_weight(struct packed_git *p)
{
if (open_pack_index(p))
die(_("cannot open index for %s"), p->pack_name);
return p->num_objects;
}
static int geometry_cmp(const void *va, const void *vb)
{
uint32_t aw = geometry_pack_weight(*(struct packed_git **)va),
bw = geometry_pack_weight(*(struct packed_git **)vb);
if (aw < bw)
return -1;
if (aw > bw)
return 1;
return 0;
}
static void init_pack_geometry(struct pack_geometry **geometry_p,
struct string_list *existing_kept_packs)
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
{
struct packed_git *p;
struct pack_geometry *geometry;
struct strbuf buf = STRBUF_INIT;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
*geometry_p = xcalloc(1, sizeof(struct pack_geometry));
geometry = *geometry_p;
for (p = get_all_packs(the_repository); p; p = p->next) {
if (!pack_kept_objects) {
/*
* Any pack that has its pack_keep bit set will appear
* in existing_kept_packs below, but this saves us from
* doing a more expensive check.
*/
if (p->pack_keep)
continue;
/*
* The pack may be kept via the --keep-pack option;
* check 'existing_kept_packs' to determine whether to
* ignore it.
*/
strbuf_reset(&buf);
strbuf_addstr(&buf, pack_basename(p));
strbuf_strip_suffix(&buf, ".pack");
if (string_list_has_string(existing_kept_packs, buf.buf))
continue;
}
if (p->is_cruft)
continue;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
ALLOC_GROW(geometry->pack,
geometry->pack_nr + 1,
geometry->pack_alloc);
geometry->pack[geometry->pack_nr] = p;
geometry->pack_nr++;
}
QSORT(geometry->pack, geometry->pack_nr, geometry_cmp);
strbuf_release(&buf);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
}
static void split_pack_geometry(struct pack_geometry *geometry, int factor)
{
uint32_t i;
uint32_t split;
off_t total_size = 0;
if (!geometry->pack_nr) {
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
geometry->split = geometry->pack_nr;
return;
}
/*
* First, count the number of packs (in descending order of size) which
* already form a geometric progression.
*/
for (i = geometry->pack_nr - 1; i > 0; i--) {
struct packed_git *ours = geometry->pack[i];
struct packed_git *prev = geometry->pack[i - 1];
if (unsigned_mult_overflows(factor, geometry_pack_weight(prev)))
die(_("pack %s too large to consider in geometric "
"progression"),
prev->pack_name);
if (geometry_pack_weight(ours) < factor * geometry_pack_weight(prev))
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
break;
}
split = i;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (split) {
/*
* Move the split one to the right, since the top element in the
* last-compared pair can't be in the progression. Only do this
* when we split in the middle of the array (otherwise if we got
* to the end, then the split is in the right place).
*/
split++;
}
/*
* Then, anything to the left of 'split' must be in a new pack. But,
* creating that new pack may cause packs in the heavy half to no longer
* form a geometric progression.
*
* Compute an expected size of the new pack, and then determine how many
* packs in the heavy half need to be joined into it (if any) to restore
* the geometric progression.
*/
for (i = 0; i < split; i++) {
struct packed_git *p = geometry->pack[i];
if (unsigned_add_overflows(total_size, geometry_pack_weight(p)))
die(_("pack %s too large to roll up"), p->pack_name);
total_size += geometry_pack_weight(p);
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
for (i = split; i < geometry->pack_nr; i++) {
struct packed_git *ours = geometry->pack[i];
if (unsigned_mult_overflows(factor, total_size))
die(_("pack %s too large to roll up"), ours->pack_name);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (geometry_pack_weight(ours) < factor * total_size) {
if (unsigned_add_overflows(total_size,
geometry_pack_weight(ours)))
die(_("pack %s too large to roll up"),
ours->pack_name);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
split++;
total_size += geometry_pack_weight(ours);
} else
break;
}
geometry->split = split;
}
static struct packed_git *get_largest_active_pack(struct pack_geometry *geometry)
{
if (!geometry) {
/*
* No geometry means either an all-into-one repack (in which
* case there is only one pack left and it is the largest) or an
* incremental one.
*
* If repacking incrementally, then we could check the size of
* all packs to determine which should be preferred, but leave
* this for later.
*/
return NULL;
}
if (geometry->split == geometry->pack_nr)
return NULL;
return geometry->pack[geometry->pack_nr - 1];
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
static void clear_pack_geometry(struct pack_geometry *geometry)
{
if (!geometry)
return;
free(geometry->pack);
geometry->pack_nr = 0;
geometry->pack_alloc = 0;
geometry->split = 0;
}
struct midx_snapshot_ref_data {
struct tempfile *f;
struct oidset seen;
int preferred;
};
static int midx_snapshot_ref_one(const char *refname UNUSED,
const struct object_id *oid,
int flag UNUSED, void *_data)
{
struct midx_snapshot_ref_data *data = _data;
struct object_id peeled;
if (!peel_iterated_oid(oid, &peeled))
oid = &peeled;
if (oidset_insert(&data->seen, oid))
return 0; /* already seen */
if (oid_object_info(the_repository, oid, NULL) != OBJ_COMMIT)
return 0;
fprintf(data->f->fp, "%s%s\n", data->preferred ? "+" : "",
oid_to_hex(oid));
return 0;
}
static void midx_snapshot_refs(struct tempfile *f)
{
struct midx_snapshot_ref_data data;
const struct string_list *preferred = bitmap_preferred_tips(the_repository);
data.f = f;
data.preferred = 0;
oidset_init(&data.seen, 0);
if (!fdopen_tempfile(f, "w"))
die(_("could not open tempfile %s for writing"),
get_tempfile_path(f));
if (preferred) {
struct string_list_item *item;
data.preferred = 1;
for_each_string_list_item(item, preferred)
for_each_ref_in(item->string, midx_snapshot_ref_one, &data);
data.preferred = 0;
}
for_each_ref(midx_snapshot_ref_one, &data);
if (close_tempfile_gently(f)) {
int save_errno = errno;
delete_tempfile(&f);
errno = save_errno;
die_errno(_("could not close refs snapshot tempfile"));
}
oidset_clear(&data.seen);
}
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
static void midx_included_packs(struct string_list *include,
struct string_list *existing_nonkept_packs,
struct string_list *existing_kept_packs,
struct string_list *names,
struct pack_geometry *geometry)
{
struct string_list_item *item;
for_each_string_list_item(item, existing_kept_packs)
string_list_insert(include, xstrfmt("%s.idx", item->string));
for_each_string_list_item(item, names)
string_list_insert(include, xstrfmt("pack-%s.idx", item->string));
if (geometry) {
struct strbuf buf = STRBUF_INIT;
uint32_t i;
for (i = geometry->split; i < geometry->pack_nr; i++) {
struct packed_git *p = geometry->pack[i];
strbuf_addstr(&buf, pack_basename(p));
strbuf_strip_suffix(&buf, ".pack");
strbuf_addstr(&buf, ".idx");
string_list_insert(include, strbuf_detach(&buf, NULL));
}
for_each_string_list_item(item, existing_nonkept_packs) {
if (!((uintptr_t)item->util & CRUFT_PACK)) {
/*
* no need to check DELETE_PACK, since we're not
* doing an ALL_INTO_ONE repack
*/
continue;
}
string_list_insert(include, xstrfmt("%s.idx", item->string));
}
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
} else {
for_each_string_list_item(item, existing_nonkept_packs) {
if ((uintptr_t)item->util & DELETE_PACK)
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
continue;
string_list_insert(include, xstrfmt("%s.idx", item->string));
}
}
}
static int write_midx_included_packs(struct string_list *include,
struct pack_geometry *geometry,
const char *refs_snapshot,
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
int show_progress, int write_bitmaps)
{
struct child_process cmd = CHILD_PROCESS_INIT;
struct string_list_item *item;
struct packed_git *largest = get_largest_active_pack(geometry);
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
FILE *in;
int ret;
if (!include->nr)
return 0;
cmd.in = -1;
cmd.git_cmd = 1;
strvec_push(&cmd.args, "multi-pack-index");
strvec_pushl(&cmd.args, "write", "--stdin-packs", NULL);
if (show_progress)
strvec_push(&cmd.args, "--progress");
else
strvec_push(&cmd.args, "--no-progress");
if (write_bitmaps)
strvec_push(&cmd.args, "--bitmap");
if (largest)
strvec_pushf(&cmd.args, "--preferred-pack=%s",
pack_basename(largest));
if (refs_snapshot)
strvec_pushf(&cmd.args, "--refs-snapshot=%s", refs_snapshot);
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
ret = start_command(&cmd);
if (ret)
return ret;
in = xfdopen(cmd.in, "w");
for_each_string_list_item(item, include)
fprintf(in, "%s\n", item->string);
fclose(in);
return finish_command(&cmd);
}
static void remove_redundant_bitmaps(struct string_list *include,
const char *packdir)
{
struct strbuf path = STRBUF_INIT;
struct string_list_item *item;
size_t packdir_len;
strbuf_addstr(&path, packdir);
strbuf_addch(&path, '/');
packdir_len = path.len;
/*
* Remove any pack bitmaps corresponding to packs which are now
* included in the MIDX.
*/
for_each_string_list_item(item, include) {
strbuf_addstr(&path, item->string);
strbuf_strip_suffix(&path, ".idx");
strbuf_addstr(&path, ".bitmap");
if (unlink(path.buf) && errno != ENOENT)
warning_errno(_("could not remove stale bitmap: %s"),
path.buf);
strbuf_setlen(&path, packdir_len);
}
strbuf_release(&path);
}
static int write_cruft_pack(const struct pack_objects_args *args,
const char *pack_prefix,
struct string_list *names,
struct string_list *existing_packs,
struct string_list *existing_kept_packs)
{
struct child_process cmd = CHILD_PROCESS_INIT;
struct strbuf line = STRBUF_INIT;
struct string_list_item *item;
FILE *in, *out;
int ret;
prepare_pack_objects(&cmd, args);
strvec_push(&cmd.args, "--cruft");
if (cruft_expiration)
strvec_pushf(&cmd.args, "--cruft-expiration=%s",
cruft_expiration);
strvec_push(&cmd.args, "--honor-pack-keep");
strvec_push(&cmd.args, "--non-empty");
strvec_push(&cmd.args, "--max-pack-size=0");
cmd.in = -1;
ret = start_command(&cmd);
if (ret)
return ret;
/*
* names has a confusing double use: it both provides the list
* of just-written new packs, and accepts the name of the cruft
* pack we are writing.
*
* By the time it is read here, it contains only the pack(s)
* that were just written, which is exactly the set of packs we
* want to consider kept.
*/
in = xfdopen(cmd.in, "w");
for_each_string_list_item(item, names)
fprintf(in, "%s-%s.pack\n", pack_prefix, item->string);
for_each_string_list_item(item, existing_packs)
fprintf(in, "-%s.pack\n", item->string);
for_each_string_list_item(item, existing_kept_packs)
fprintf(in, "%s.pack\n", item->string);
fclose(in);
out = xfdopen(cmd.out, "r");
while (strbuf_getline_lf(&line, out) != EOF) {
struct string_list_item *item;
if (line.len != the_hash_algo->hexsz)
die(_("repack: Expecting full hex object ID lines only "
"from pack-objects."));
item = string_list_append(names, line.buf);
item->util = populate_pack_exts(line.buf);
}
fclose(out);
strbuf_release(&line);
return finish_command(&cmd);
}
int cmd_repack(int argc, const char **argv, const char *prefix)
{
struct child_process cmd = CHILD_PROCESS_INIT;
struct string_list_item *item;
struct string_list names = STRING_LIST_INIT_DUP;
struct string_list existing_nonkept_packs = STRING_LIST_INIT_DUP;
struct string_list existing_kept_packs = STRING_LIST_INIT_DUP;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
struct pack_geometry *geometry = NULL;
struct strbuf line = STRBUF_INIT;
struct tempfile *refs_snapshot = NULL;
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
int i, ext, ret;
FILE *out;
int show_progress;
/* variables to be filled by option parsing */
int delete_redundant = 0;
const char *unpack_unreachable = NULL;
int keep_unreachable = 0;
struct string_list keep_pack_list = STRING_LIST_INIT_NODUP;
struct pack_objects_args po_args = {NULL};
struct pack_objects_args cruft_po_args = {NULL};
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
int geometric_factor = 0;
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
int write_midx = 0;
struct option builtin_repack_options[] = {
OPT_BIT('a', NULL, &pack_everything,
N_("pack everything in a single pack"), ALL_INTO_ONE),
OPT_BIT('A', NULL, &pack_everything,
N_("same as -a, and turn unreachable objects loose"),
LOOSEN_UNREACHABLE | ALL_INTO_ONE),
OPT_BIT(0, "cruft", &pack_everything,
N_("same as -a, pack unreachable cruft objects separately"),
PACK_CRUFT),
OPT_STRING(0, "cruft-expiration", &cruft_expiration, N_("approxidate"),
N_("with -C, expire objects older than this")),
OPT_BOOL('d', NULL, &delete_redundant,
N_("remove redundant packs, and run git-prune-packed")),
OPT_BOOL('f', NULL, &po_args.no_reuse_delta,
N_("pass --no-reuse-delta to git-pack-objects")),
OPT_BOOL('F', NULL, &po_args.no_reuse_object,
N_("pass --no-reuse-object to git-pack-objects")),
OPT_NEGBIT('n', NULL, &run_update_server_info,
N_("do not run git-update-server-info"), 1),
OPT__QUIET(&po_args.quiet, N_("be quiet")),
OPT_BOOL('l', "local", &po_args.local,
N_("pass --local to git-pack-objects")),
OPT_BOOL('b', "write-bitmap-index", &write_bitmaps,
N_("write bitmap index")),
OPT_BOOL('i', "delta-islands", &use_delta_islands,
N_("pass --delta-islands to git-pack-objects")),
OPT_STRING(0, "unpack-unreachable", &unpack_unreachable, N_("approxidate"),
N_("with -A, do not loosen objects older than this")),
OPT_BOOL('k', "keep-unreachable", &keep_unreachable,
N_("with -a, repack unreachable objects")),
OPT_STRING(0, "window", &po_args.window, N_("n"),
N_("size of the window used for delta compression")),
OPT_STRING(0, "window-memory", &po_args.window_memory, N_("bytes"),
N_("same as the above, but limit memory size instead of entries count")),
OPT_STRING(0, "depth", &po_args.depth, N_("n"),
N_("limits the maximum delta depth")),
OPT_STRING(0, "threads", &po_args.threads, N_("n"),
N_("limits the maximum number of threads")),
OPT_STRING(0, "max-pack-size", &po_args.max_pack_size, N_("bytes"),
N_("maximum size of each packfile")),
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
OPT_BOOL(0, "pack-kept-objects", &pack_kept_objects,
N_("repack objects in packs marked with .keep")),
OPT_STRING_LIST(0, "keep-pack", &keep_pack_list, N_("name"),
N_("do not repack this pack")),
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
OPT_INTEGER('g', "geometric", &geometric_factor,
N_("find a geometric progression with factor <N>")),
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
OPT_BOOL('m', "write-midx", &write_midx,
N_("write a multi-pack index of the resulting packs")),
OPT_END()
};
git_config(repack_config, &cruft_po_args);
argc = parse_options(argc, argv, prefix, builtin_repack_options,
git_repack_usage, 0);
if (delete_redundant && repository_format_precious_objects)
die(_("cannot delete packs in a precious-objects repo"));
if (keep_unreachable &&
(unpack_unreachable || (pack_everything & LOOSEN_UNREACHABLE)))
die(_("options '%s' and '%s' cannot be used together"), "--keep-unreachable", "-A");
if (pack_everything & PACK_CRUFT) {
pack_everything |= ALL_INTO_ONE;
if (unpack_unreachable || (pack_everything & LOOSEN_UNREACHABLE))
die(_("options '%s' and '%s' cannot be used together"), "--cruft", "-A");
if (keep_unreachable)
die(_("options '%s' and '%s' cannot be used together"), "--cruft", "-k");
}
if (write_bitmaps < 0) {
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
if (!write_midx &&
(!(pack_everything & ALL_INTO_ONE) || !is_bare_repository()))
write_bitmaps = 0;
} else if (write_bitmaps &&
git_env_bool(GIT_TEST_MULTI_PACK_INDEX, 0) &&
git_env_bool(GIT_TEST_MULTI_PACK_INDEX_WRITE_BITMAP, 0)) {
write_bitmaps = 0;
}
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
if (pack_kept_objects < 0)
pack_kept_objects = write_bitmaps > 0 && !write_midx;
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
if (write_bitmaps && !(pack_everything & ALL_INTO_ONE) && !write_midx)
die(_(incremental_bitmap_conflict_error));
if (write_midx && write_bitmaps) {
struct strbuf path = STRBUF_INIT;
strbuf_addf(&path, "%s/%s_XXXXXX", get_object_directory(),
"bitmap-ref-tips");
refs_snapshot = xmks_tempfile(path.buf);
midx_snapshot_refs(refs_snapshot);
strbuf_release(&path);
}
packdir = mkpathdup("%s/pack", get_object_directory());
packtmp_name = xstrfmt(".tmp-%d-pack", (int)getpid());
packtmp = mkpathdup("%s/%s", packdir, packtmp_name);
collect_pack_filenames(&existing_nonkept_packs, &existing_kept_packs,
&keep_pack_list);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (geometric_factor) {
if (pack_everything)
die(_("options '%s' and '%s' cannot be used together"), "--geometric", "-A/-a");
init_pack_geometry(&geometry, &existing_kept_packs);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
split_pack_geometry(geometry, geometric_factor);
}
prepare_pack_objects(&cmd, &po_args);
show_progress = !po_args.quiet && isatty(2);
strvec_push(&cmd.args, "--keep-true-parents");
repack: add `repack.packKeptObjects` config var The git-repack command always passes `--honor-pack-keep` to pack-objects. This has traditionally been a good thing, as we do not want to duplicate those objects in a new pack, and we are not going to delete the old pack. However, when bitmaps are in use, it is important for a full repack to include all reachable objects, even if they may be duplicated in a .keep pack. Otherwise, we cannot generate the bitmaps, as the on-disk format requires the set of objects in the pack to be fully closed. Even if the repository does not generally have .keep files, a simultaneous push could cause a race condition in which a .keep file exists at the moment of a repack. The repack may try to include those objects in one of two situations: 1. The pushed .keep pack contains objects that were already in the repository (e.g., blobs due to a revert of an old commit). 2. Receive-pack updates the refs, making the objects reachable, but before it removes the .keep file, the repack runs. In either case, we may prefer to duplicate some objects in the new, full pack, and let the next repack (after the .keep file is cleaned up) take care of removing them. This patch introduces both a command-line and config option to disable the `--honor-pack-keep` option. By default, it is triggered when pack.writeBitmaps (or `--write-bitmap-index` is turned on), but specifying it explicitly can override the behavior (e.g., in cases where you prefer .keep files to bitmaps, but only when they are present). Note that this option just disables the pack-objects behavior. We still leave packs with a .keep in place, as we do not necessarily know that we have duplicated all of their objects. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-03-03 20:04:20 +00:00
if (!pack_kept_objects)
strvec_push(&cmd.args, "--honor-pack-keep");
for (i = 0; i < keep_pack_list.nr; i++)
strvec_pushf(&cmd.args, "--keep-pack=%s",
keep_pack_list.items[i].string);
strvec_push(&cmd.args, "--non-empty");
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (!geometry) {
/*
* We need to grab all reachable objects, including those that
* are reachable from reflogs and the index.
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
*
* When repacking into a geometric progression of packs,
* however, we ask 'git pack-objects --stdin-packs', and it is
* not about packing objects based on reachability but about
* repacking all the objects in specified packs and loose ones
* (indeed, --stdin-packs is incompatible with these options).
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
*/
strvec_push(&cmd.args, "--all");
strvec_push(&cmd.args, "--reflog");
strvec_push(&cmd.args, "--indexed-objects");
}
if (has_promisor_remote())
strvec_push(&cmd.args, "--exclude-promisor-objects");
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
if (!write_midx) {
if (write_bitmaps > 0)
strvec_push(&cmd.args, "--write-bitmap-index");
else if (write_bitmaps < 0)
strvec_push(&cmd.args, "--write-bitmap-index-quiet");
}
if (use_delta_islands)
strvec_push(&cmd.args, "--delta-islands");
if (pack_everything & ALL_INTO_ONE) {
repack_promisor_objects(&po_args, &names);
if (existing_nonkept_packs.nr && delete_redundant &&
!(pack_everything & PACK_CRUFT)) {
repack: avoid loosening promisor objects in partial clones When `git repack -A -d` is run in a partial clone, `pack-objects` is invoked twice: once to repack all promisor objects, and once to repack all non-promisor objects. The latter `pack-objects` invocation is with --exclude-promisor-objects and --unpack-unreachable, which loosens all objects unused during this invocation. Unfortunately, this includes promisor objects. Because the -d argument to `git repack` subsequently deletes all loose objects also in packs, these just-loosened promisor objects will be immediately deleted. However, this extra disk churn is unnecessary in the first place. For example, in a newly-cloned partial repo that filters all blob objects (e.g. `--filter=blob:none`), `repack` ends up unpacking all trees and commits into the filesystem because every object, in this particular case, is a promisor object. Depending on the repo size, this increases the disk usage considerably: In my copy of the linux.git, the object directory peaked 26GB of more disk usage. In order to avoid this extra disk churn, pass the names of the promisor packfiles as --keep-pack arguments to the second invocation of `pack-objects`. This informs `pack-objects` that the promisor objects are already in a safe packfile and, therefore, do not need to be loosened. For testing, we need to validate whether any object was loosened. However, the "evidence" (loosened objects) is deleted during the process which prevents us from inspecting the object directory. Instead, let's teach `pack-objects` to count loosened objects and emit via trace2 thus allowing inspecting the debug events after the process is finished. This new event is used on the added regression test. Lastly, add a new perf test to evaluate the performance impact made by this changes (tested on git.git): Test HEAD^ HEAD ---------------------------------------------------------- 5600.3: gc 134.38(41.93+90.95) 7.80(6.72+1.35) -94.2% For a bigger repository, such as linux.git, the improvement is even bigger: Test HEAD^ HEAD ------------------------------------------------------------------- 5600.3: gc 6833.00(918.07+3162.74) 268.79(227.02+39.18) -96.1% These improvements are particular big because every object in the newly-cloned partial repository is a promisor object. Reported-by: SZEDER Gábor <szeder.dev@gmail.com> Helped-by: Jeff King <peff@peff.net> Helped-by: Jonathan Tan <jonathantanmy@google.com> Signed-off-by: Rafael Silva <rafaeloliveira.cs@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-04-21 19:32:12 +00:00
for_each_string_list_item(item, &names) {
strvec_pushf(&cmd.args, "--keep-pack=%s-%s.pack",
packtmp_name, item->string);
}
if (unpack_unreachable) {
strvec_pushf(&cmd.args,
"--unpack-unreachable=%s",
unpack_unreachable);
} else if (pack_everything & LOOSEN_UNREACHABLE) {
strvec_push(&cmd.args,
"--unpack-unreachable");
} else if (keep_unreachable) {
strvec_push(&cmd.args, "--keep-unreachable");
strvec_push(&cmd.args, "--pack-loose-unreachable");
}
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
} else if (geometry) {
strvec_push(&cmd.args, "--stdin-packs");
strvec_push(&cmd.args, "--unpacked");
} else {
strvec_push(&cmd.args, "--unpacked");
strvec_push(&cmd.args, "--incremental");
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (geometry)
cmd.in = -1;
else
cmd.no_stdin = 1;
ret = start_command(&cmd);
if (ret)
return ret;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (geometry) {
FILE *in = xfdopen(cmd.in, "w");
/*
* The resulting pack should contain all objects in packs that
* are going to be rolled up, but exclude objects in packs which
* are being left alone.
*/
for (i = 0; i < geometry->split; i++)
fprintf(in, "%s\n", pack_basename(geometry->pack[i]));
for (i = geometry->split; i < geometry->pack_nr; i++)
fprintf(in, "^%s\n", pack_basename(geometry->pack[i]));
fclose(in);
}
out = xfdopen(cmd.out, "r");
while (strbuf_getline_lf(&line, out) != EOF) {
struct string_list_item *item;
if (line.len != the_hash_algo->hexsz)
die(_("repack: Expecting full hex object ID lines only from pack-objects."));
item = string_list_append(&names, line.buf);
item->util = populate_pack_exts(item->string);
}
fclose(out);
ret = finish_command(&cmd);
if (ret)
return ret;
if (!names.nr && !po_args.quiet)
printf_ln(_("Nothing new to pack."));
if (pack_everything & PACK_CRUFT) {
const char *pack_prefix;
if (!skip_prefix(packtmp, packdir, &pack_prefix))
die(_("pack prefix %s does not begin with objdir %s"),
packtmp, packdir);
if (*pack_prefix == '/')
pack_prefix++;
if (!cruft_po_args.window)
cruft_po_args.window = po_args.window;
if (!cruft_po_args.window_memory)
cruft_po_args.window_memory = po_args.window_memory;
if (!cruft_po_args.depth)
cruft_po_args.depth = po_args.depth;
if (!cruft_po_args.threads)
cruft_po_args.threads = po_args.threads;
cruft_po_args.local = po_args.local;
cruft_po_args.quiet = po_args.quiet;
ret = write_cruft_pack(&cruft_po_args, pack_prefix, &names,
&existing_nonkept_packs,
&existing_kept_packs);
if (ret)
return ret;
}
string_list_sort(&names);
close_object_store(the_repository->objects);
/*
* Ok we have prepared all new packfiles.
*/
for_each_string_list_item(item, &names) {
struct generated_pack_data *data = item->util;
for (ext = 0; ext < ARRAY_SIZE(exts); ext++) {
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
char *fname;
fname = mkpathdup("%s/pack-%s%s",
packdir, item->string, exts[ext].name);
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
if (data->tempfiles[ext]) {
const char *fname_old = get_tempfile_path(data->tempfiles[ext]);
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
struct stat statbuffer;
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
if (!stat(fname_old, &statbuffer)) {
statbuffer.st_mode &= ~(S_IWUSR | S_IWGRP | S_IWOTH);
chmod(fname_old, statbuffer.st_mode);
}
repack: use tempfiles for signal cleanup When git-repack exits due to a signal, it tries to clean up by calling its remove_temporary_files() function, which walks through the packs dir looking for ".tmp-$$-pack-*" files to delete (where "$$" is the pid of the current process). The biggest problem here is that remove_temporary_files() is not safe to call in a signal handler. It uses opendir(), which isn't on the POSIX async-signal-safe list. The details will be platform-specific, but a likely issue is that it needs to allocate memory; if we receive a signal while inside malloc(), etc, we'll conflict on the allocator lock and deadlock with ourselves. We can fix this by just cleaning up the files directly, without walking the directory. We already know the complete list of .tmp-* files that were generated, because we recorded them via populate_pack_exts(). When we find files there, we can use register_tempfile() to record the filenames. If we receive a signal, then the tempfile API will clean them up for us, and it's async-safe and pretty battle-tested. Note that this is slightly racier than the existing scheme. We don't record the filenames until pack-objects tells us the hash over stdout. So during the period between it generating the file and reporting the hash, we'd fail to clean up. However, that period is very small. During most of the pack generation process pack-objects is using its own internal tempfiles. It's only at the very end that it moves them into the names git-repack expects, and then it immediately reports the name to us. Given that cleanup like this is best effort (after all, we may get SIGKILL), this level of race is acceptable. When we register the tempfiles, we'll record them locally and use the result to call rename_tempfile(), rather than renaming by hand. This isn't strictly necessary, as once we've renamed the files they're gone, and the tempfile API's cleanup unlink() would simply become a pointless noop. But managing the lifetimes of the tempfile objects is the cleanest thing to do, and the tempfile pointers naturally fill the same role as the old booleans. This patch also fixes another small problem. We only hook signals, and don't set up an atexit handler. So if we see an error that causes us to die(), we'll leave the .tmp-* files in place. But since the tempfile API handles this for us, this is now fixed for free. The new test covers this by stimulating a failure of pack-objects when generating a cruft pack. Before this patch, the .tmp-* file for the main pack would have been left, but now we correctly clean it up. Two small subtleties on the implementation: - in the renaming loop, we can stop re-constructing fname_old; we only use it when we have a tempfile to rename, so we can just ask the tempfile for its path (which, barring bugs, should be identical) - when renaming fails, our error message mentions fname_old. But since a failed rename_tempfile() invalidates the tempfile struct, we'll lose access to that string. Instead, let's mention the destination filename, which is what most other callers do. Reported-by: Jan Pokorný <poki@fnusa.cz> Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-22 00:21:54 +00:00
if (rename_tempfile(&data->tempfiles[ext], fname))
die_errno(_("renaming pack to '%s' failed"), fname);
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
} else if (!exts[ext].optional)
die(_("pack-objects did not write a '%s' file for pack %s-%s"),
exts[ext].name, packtmp, item->string);
builtin/repack.c: don't move existing packs out of the way When 'git repack' creates a pack with the same name as any existing pack, it moves the existing one to 'old-pack-xxx.{pack,idx,...}' and then renames the new one into place. Eventually, it would be nice to have 'git repack' allow for writing a multi-pack index at the critical time (after the new packs have been written / moved into place, but before the old ones have been deleted). Guessing that this option might be called '--write-midx', this makes the following situation (where repacks are issued back-to-back without any new objects) impossible: $ git repack -adb $ git repack -adb --write-midx In the second repack, the existing packs are overwritten verbatim with the same rename-to-old sequence. At that point, the current MIDX is invalidated, since it refers to now-missing packs. So that code wants to be run after the MIDX is re-written. But (prior to this patch) the new MIDX can't be written until the new packs are moved into place. So, we have a circular dependency. This is all hypothetical, since no code currently exists to write a MIDX safely during a 'git repack' (the 'GIT_TEST_MULTI_PACK_INDEX' does so unsafely). Putting hypothetical aside, though: why do we need to rename existing packs to be prefixed with 'old-' anyway? This behavior dates all the way back to 2ad47d6 (git-repack: Be careful when updating the same pack as an existing one., 2006-06-25). 2ad47d6 is mainly concerned about a case where a newly written pack would have a different structure than its index. This used to be possible when the pack name was a hash of the set of objects. Under this naming scheme, two packs that store the same set of objects could differ in delta selection, object positioning, or both. If this happened, then any such packs would be unreadable in the instant between copying the new pack and new index (i.e., either the index or pack will be stale depending on the order that they were copied). But since 1190a1a (pack-objects: name pack files after trailer hash, 2013-12-05), this is no longer possible, since pack files are named not after their logical contents (i.e., the set of objects), but by the actual checksum of their contents. So, this old- behavior can safely go, which allows us to avoid our circular dependency above. In addition to avoiding the circular dependency, this patch also makes 'git repack' a lot simpler, since we don't have to deal with failures encountered when renaming existing packs to be prefixed with 'old-'. This patch is mostly limited to removing code paths that deal with the 'old' prefixing, with the exception of files that include the pack's name in their own filename, like .idx, .bitmap, and related files. The exception is that we want to continue to trust what pack-objects wrote. That is, it is not the case that we pretend as if pack-objects didn't write files identical to ones that already exist, but rather that we respect what pack-objects wrote as the source of truth. That cuts two ways: - If pack-objects produced an identical pack to one that already exists with a bitmap, but did not produce a bitmap, we remove the bitmap that already exists. (This behavior is codified in t7700.14). - If pack-objects produced an identical pack to one that already exists, we trust the just-written version of the coresponding .idx, .promisor, and other files over the ones that already exist. This ensures that we use the most up-to-date versions of this files, which is safe even in the face of format changes in, say, the .idx file (which would not be reflected in the .idx file's name). Helped-by: Jeff King <peff@peff.net> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-11-17 20:15:16 +00:00
else if (unlink(fname) < 0 && errno != ENOENT)
die_errno(_("could not unlink: %s"), fname);
free(fname);
}
}
/* End of pack replacement. */
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
if (delete_redundant && pack_everything & ALL_INTO_ONE) {
const int hexsz = the_hash_algo->hexsz;
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
for_each_string_list_item(item, &existing_nonkept_packs) {
char *sha1;
size_t len = strlen(item->string);
if (len < hexsz)
continue;
sha1 = item->string + len - hexsz;
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
/*
* Mark this pack for deletion, which ensures that this
* pack won't be included in a MIDX (if `--write-midx`
* was given) and that we will actually delete this pack
* (if `-d` was given).
*/
if (!string_list_has_string(&names, sha1))
item->util = (void*)(uintptr_t)((size_t)item->util | DELETE_PACK);
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
}
}
if (write_midx) {
struct string_list include = STRING_LIST_INIT_NODUP;
midx_included_packs(&include, &existing_nonkept_packs,
&existing_kept_packs, &names, geometry);
ret = write_midx_included_packs(&include, geometry,
refs_snapshot ? get_tempfile_path(refs_snapshot) : NULL,
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
show_progress, write_bitmaps > 0);
if (!ret && write_bitmaps)
remove_redundant_bitmaps(&include, packdir);
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
string_list_clear(&include, 0);
if (ret)
return ret;
}
reprepare_packed_git(the_repository);
if (delete_redundant) {
int opts = 0;
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
for_each_string_list_item(item, &existing_nonkept_packs) {
if (!((uintptr_t)item->util & DELETE_PACK))
builtin/repack.c: support writing a MIDX while repacking Teach `git repack` a new `--write-midx` option for callers that wish to persist a multi-pack index in their repository while repacking. There are two existing alternatives to this new flag, but they don't cover our particular use-case. These alternatives are: - Call 'git multi-pack-index write' after running 'git repack', or - Set 'GIT_TEST_MULTI_PACK_INDEX=1' in your environment when running 'git repack'. The former works, but introduces a gap in bitmap coverage between repacking and writing a new MIDX (since the repack may have deleted a pack included in the existing MIDX, invalidating it altogether). Setting the 'GIT_TEST_' environment variable is obviously unsupported. In fact, even if it were supported officially, it still wouldn't work, because it generates the MIDX *after* redundant packs have been dropped, leading to the same issue as above. Introduce a new option which eliminates this race by teaching `git repack` to generate the MIDX at the critical point: after the new packs have been written and moved into place, but before the redundant packs have been removed. This option is compatible with `git repack`'s '--bitmap' option (it changes the interpretation to be: "write a bitmap corresponding to the MIDX after one has been generated"). There is a little bit of additional noise in the patch below to avoid repeating ourselves when selecting which packs to delete. Instead of a single loop as before (where we iterate over 'existing_packs', decide if a pack is worth deleting, and if so, delete it), we have two loops (the first where we decide which ones are worth deleting, and the second where we actually do the deleting). This makes it so we have a single check we can make consistently when (1) telling the MIDX which packs we want to exclude, and (2) actually unlinking the redundant packs. There is also a tiny change to short-circuit the body of write_midx_included_packs() when no packs remain in the case of an empty repository. The MIDX code does not handle this, so avoid trying to generate a MIDX covering zero packs in the first place. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:18 +00:00
continue;
remove_redundant_pack(packdir, item->string);
}
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
if (geometry) {
struct strbuf buf = STRBUF_INIT;
uint32_t i;
for (i = 0; i < geometry->split; i++) {
struct packed_git *p = geometry->pack[i];
if (string_list_has_string(&names,
hash_to_hex(p->hash)))
continue;
strbuf_reset(&buf);
strbuf_addstr(&buf, pack_basename(p));
strbuf_strip_suffix(&buf, ".pack");
repack: don't remove .keep packs with `--pack-kept-objects` `git repack` supports a `--pack-kept-objects` flag which more or less translates to whether or not we pass `--honor-pack-keep` down to `git pack-objects` when assembling a new pack. This behavior has existed since ee34a2bead (repack: add `repack.packKeptObjects` config var, 2014-03-03). In that commit, the documentation was extended to say: [...] Note that we still do not delete `.keep` packs after `pack-objects` finishes. Unfortunately, this is not the case when `--pack-kept-objects` is combined with a `--geometric` repack. When doing a geometric repack, we include `.keep` packs when enumerating available packs only when `pack_kept_objects` is set. So this all works fine when `--no-pack-kept-objects` (or similar) is given. Kept packs are excluded from the geometric roll-up, so when we go to delete redundant packs (with `-d`), no `.keep` packs appear "below the split" in our geometric progression. But when `--pack-kept-objects` is given, things can go awry. Namely, when a kept pack is included in the list of packs tracked by the `pack_geometry` struct *and* part of the pack roll-up, we will delete the `.keep` pack when we shouldn't. Note that this *doesn't* result in object corruption, since the `.keep` pack's objects are still present in the new pack. But the `.keep` pack itself is removed, which violates our promise from back in ee34a2bead. But there's more. Because `repack` computes the geometric roll-up independently from selecting which packs belong in a MIDX (with `--write-midx`), this can lead to odd behavior. Consider when a `.keep` pack appears below the geometric split (ie., its objects will be part of the new pack we generate). We'll write a MIDX containing the new pack along with the existing `.keep` pack. But because the `.keep` pack appears below the geometric split line, we'll (incorrectly) try to remove it. While this doesn't corrupt the repository, it does cause us to remove the MIDX we just wrote, since removing that pack would invalidate the new MIDX. Funny enough, this behavior became far less noticeable after e4d0c11c04 (repack: respect kept objects with '--write-midx -b', 2021-12-20), which made `pack_kept_objects` be enabled by default only when we were writing a non-MIDX bitmap. But e4d0c11c04 didn't resolve this bug, it just made it harder to notice unless callers explicitly passed `--pack-kept-objects`. The solution is to avoid trying to remove `.keep` packs during `--geometric` repacks, even when they appear below the geometric split line, which is the approach this patch implements. Co-authored-by: Victoria Dye <vdye@github.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2022-10-18 02:26:06 +00:00
if ((p->pack_keep) ||
(string_list_has_string(&existing_kept_packs,
buf.buf)))
continue;
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
remove_redundant_pack(packdir, buf.buf);
}
strbuf_release(&buf);
}
if (show_progress)
opts |= PRUNE_PACKED_VERBOSE;
prune_packed_objects(opts);
repack -ad: prune the list of shallow commits `git repack` can drop unreachable commits without further warning, making the corresponding entries in `.git/shallow` invalid, which causes serious problems when deepening the branches. One scenario where unreachable commits are dropped by `git repack` is when a `git fetch --prune` (or even a `git fetch` when a ref was force-pushed in the meantime) can make a commit unreachable that was reachable before. Therefore it is not safe to assume that a `git repack -adlf` will keep unreachable commits alone (under the assumption that they had not been packed in the first place, which is an assumption at least some of Git's code seems to make). This is particularly important to keep in mind when looking at the `.git/shallow` file: if any commits listed in that file become unreachable, it is not a problem, but if they go missing, it *is* a problem. One symptom of this problem is that a deepening fetch may now fail with fatal: error in object: unshallow <commit-hash> To avoid this problem, let's prune the shallow list in `git repack` when the `-d` option is passed, unless `-A` is passed, too (which would force the now-unreachable objects to be turned into loose objects instead of being deleted). Additionally, we also need to take `--keep-reachable` and `--unpack-unreachable=<date>` into account. Note: an alternative solution discussed during the review of this patch was to teach `git fetch` to simply ignore entries in .git/shallow if the corresponding commits do not exist locally. A quick test, however, revealed that the .git/shallow file is written during a shallow *clone*, in which case the commits do not exist, either, but the "shallow" line *does* need to be sent. Therefore, this approach would be a lot more finicky than the approach presented by the this patch. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-10-24 15:56:13 +00:00
if (!keep_unreachable &&
(!(pack_everything & LOOSEN_UNREACHABLE) ||
unpack_unreachable) &&
is_repository_shallow(the_repository))
prune_shallow(PRUNE_QUICK);
}
if (run_update_server_info)
update_server_info(0);
if (git_env_bool(GIT_TEST_MULTI_PACK_INDEX, 0)) {
unsigned flags = 0;
if (git_env_bool(GIT_TEST_MULTI_PACK_INDEX_WRITE_BITMAP, 0))
flags |= MIDX_WRITE_BITMAP | MIDX_WRITE_REV_INDEX;
midx: preliminary support for `--refs-snapshot` To figure out which commits we can write a bitmap for, the multi-pack index/bitmap code does a reachability traversal, marking any commit which can be found in the MIDX as eligible to receive a bitmap. This approach will cause a problem when multi-pack bitmaps are able to be generated from `git repack`, since the reference tips can change during the repack. Even though we ignore commits that don't exist in the MIDX (when doing a scan of the ref tips), it's possible that a commit in the MIDX reaches something that isn't. This can happen when a multi-pack index contains some pack which refers to loose objects (e.g., if a pack was pushed after starting the repack but before generating the MIDX which depends on an object which is stored as loose in the repository, and by definition isn't included in the multi-pack index). By taking a snapshot of the references before we start repacking, we can close that race window. In the above scenario (where we have a packed object pointing at a loose one), we'll either (a) take a snapshot of the references before seeing the packed one, or (b) take it after, at which point we can guarantee that the loose object will be packed and included in the MIDX. This patch does just that. It writes a temporary "reference snapshot", which is a list of OIDs that are at the ref tips before writing a multi-pack bitmap. References that are "preferred" (i.e,. are a suffix of at least one value of the 'pack.preferBitmapTips' configuration) are marked with a special '+'. The format is simple: one line per commit at each tip, with an optional '+' at the beginning (for preferred references, as described above). When provided, the reference snapshot is used to drive bitmap selection instead of the MIDX code doing its own traversal. When it isn't provided, the usual traversal takes place instead. Signed-off-by: Taylor Blau <me@ttaylorr.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-29 01:55:07 +00:00
write_midx_file(get_object_directory(), NULL, NULL, flags);
}
string_list_clear(&names, 1);
string_list_clear(&existing_nonkept_packs, 0);
string_list_clear(&existing_kept_packs, 0);
builtin/repack.c: add '--geometric' option Often it is useful to both: - have relatively few packfiles in a repository, and - avoid having so few packfiles in a repository that we repack its entire contents regularly This patch implements a '--geometric=<n>' option in 'git repack'. This allows the caller to specify that they would like each pack to be at least a factor times as large as the previous largest pack (by object count). Concretely, say that a repository has 'n' packfiles, labeled P1, P2, ..., up to Pn. Each packfile has an object count equal to 'objects(Pn)'. With a geometric factor of 'r', it should be that: objects(Pi) > r*objects(P(i-1)) for all i in [1, n], where the packs are sorted by objects(P1) <= objects(P2) <= ... <= objects(Pn). Since finding a true optimal repacking is NP-hard, we approximate it along two directions: 1. We assume that there is a cutoff of packs _before starting the repack_ where everything to the right of that cut-off already forms a geometric progression (or no cutoff exists and everything must be repacked). 2. We assume that everything smaller than the cutoff count must be repacked. This forms our base assumption, but it can also cause even the "heavy" packs to get repacked, for e.g., if we have 6 packs containing the following number of objects: 1, 1, 1, 2, 4, 32 then we would place the cutoff between '1, 1' and '1, 2, 4, 32', rolling up the first two packs into a pack with 2 objects. That breaks our progression and leaves us: 2, 1, 2, 4, 32 ^ (where the '^' indicates the position of our split). To restore a progression, we move the split forward (towards larger packs) joining each pack into our new pack until a geometric progression is restored. Here, that looks like: 2, 1, 2, 4, 32 ~> 3, 2, 4, 32 ~> 5, 4, 32 ~> ... ~> 9, 32 ^ ^ ^ ^ This has the advantage of not repacking the heavy-side of packs too often while also only creating one new pack at a time. Another wrinkle is that we assume that loose, indexed, and reflog'd objects are insignificant, and lump them into any new pack that we create. This can lead to non-idempotent results. Suggested-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Taylor Blau <me@ttaylorr.com> Reviewed-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-02-23 02:25:27 +00:00
clear_pack_geometry(geometry);
strbuf_release(&line);
return 0;
}