git/read-tree.c

604 строки
16 KiB
C

/*
* GIT - The information manager from hell
*
* Copyright (C) Linus Torvalds, 2005
*/
#include "cache.h"
static int stage = 0;
static int update = 0;
static int unpack_tree(unsigned char *sha1)
{
void *buffer;
unsigned long size;
int ret;
buffer = read_object_with_reference(sha1, "tree", &size, NULL);
if (!buffer)
return -1;
ret = read_tree(buffer, size, stage, NULL);
free(buffer);
return ret;
}
static int path_matches(struct cache_entry *a, struct cache_entry *b)
{
int len = ce_namelen(a);
return ce_namelen(b) == len &&
!memcmp(a->name, b->name, len);
}
static int same(struct cache_entry *a, struct cache_entry *b)
{
return a->ce_mode == b->ce_mode &&
!memcmp(a->sha1, b->sha1, 20);
}
/*
* This removes all trivial merges that don't change the tree
* and collapses them to state 0.
*/
static struct cache_entry *merge_entries(struct cache_entry *a,
struct cache_entry *b,
struct cache_entry *c)
{
/*
* Ok, all three entries describe the same
* filename, but maybe the contents or file
* mode have changed?
*
* The trivial cases end up being the ones where two
* out of three files are the same:
* - both destinations the same, trivially take either
* - one of the destination versions hasn't changed,
* take the other.
*
* The "all entries exactly the same" case falls out as
* a special case of any of the "two same" cases.
*
* Here "a" is "original", and "b" and "c" are the two
* trees we are merging.
*/
if (a && b && c) {
if (same(b,c))
return c;
if (same(a,b))
return c;
if (same(a,c))
return b;
}
return NULL;
}
/*
* When a CE gets turned into an unmerged entry, we
* want it to be up-to-date
*/
static void verify_uptodate(struct cache_entry *ce)
{
struct stat st;
if (!lstat(ce->name, &st)) {
unsigned changed = ce_match_stat(ce, &st);
if (!changed)
return;
errno = 0;
}
if (errno == ENOENT)
return;
die("Entry '%s' not uptodate. Cannot merge.", ce->name);
}
/*
* If the old tree contained a CE that isn't even in the
* result, that's always a problem, regardless of whether
* it's up-to-date or not (ie it can be a file that we
* have updated but not committed yet).
*/
static void reject_merge(struct cache_entry *ce)
{
die("Entry '%s' would be overwritten by merge. Cannot merge.", ce->name);
}
static int merged_entry_internal(struct cache_entry *merge, struct cache_entry *old, struct cache_entry **dst, int allow_dirty)
{
merge->ce_flags |= htons(CE_UPDATE);
if (old) {
/*
* See if we can re-use the old CE directly?
* That way we get the uptodate stat info.
*
* This also removes the UPDATE flag on
* a match.
*/
if (same(old, merge)) {
*merge = *old;
} else if (!allow_dirty) {
verify_uptodate(old);
}
}
merge->ce_flags &= ~htons(CE_STAGEMASK);
*dst++ = merge;
return 1;
}
static int merged_entry_allow_dirty(struct cache_entry *merge, struct cache_entry *old, struct cache_entry **dst)
{
return merged_entry_internal(merge, old, dst, 1);
}
static int merged_entry(struct cache_entry *merge, struct cache_entry *old, struct cache_entry **dst)
{
return merged_entry_internal(merge, old, dst, 0);
}
static int deleted_entry(struct cache_entry *ce, struct cache_entry *old, struct cache_entry **dst)
{
if (old)
verify_uptodate(old);
ce->ce_mode = 0;
*dst++ = ce;
return 1;
}
static int causes_df_conflict(struct cache_entry *ce, int stage,
struct cache_entry **dst_,
struct cache_entry **next_,
int tail)
{
/* This is called during the merge operation and walking
* the active_cache[] array is messy, because it is in the
* middle of overlapping copy operation. The invariants
* are:
* (1) active_cache points at the first (zeroth) entry.
* (2) up to dst pointer are resolved entries.
* (3) from the next pointer (head-inclusive) to the tail
* of the active_cache array have the remaining paths
* to be processed. There can be a gap between dst
* and next. Note that next is called "src" in the
* merge_cache() function, and tail is the original
* end of active_cache array when merge_cache() started.
* (4) the path corresponding to *ce is not found in (2)
* or (3). It is in the gap.
*
* active_cache -----......+++++++++++++.
* ^dst ^next ^tail
*/
int i, next, dst;
const char *path = ce->name;
int namelen = ce_namelen(ce);
next = next_ - active_cache;
dst = dst_ - active_cache;
for (i = 0; i < tail; i++) {
int entlen, len;
const char *one, *two;
if (dst <= i && i < next)
continue;
ce = active_cache[i];
if (ce_stage(ce) != stage)
continue;
/* If ce->name is a prefix of path, then path is a file
* that hangs underneath ce->name, which is bad.
* If path is a prefix of ce->name, then it is the
* other way around which also is bad.
*/
entlen = ce_namelen(ce);
if (namelen == entlen)
continue;
if (namelen < entlen) {
len = namelen;
one = path;
two = ce->name;
} else {
len = entlen;
one = ce->name;
two = path;
}
if (memcmp(one, two, len))
continue;
if (two[len] == '/')
return 1;
}
return 0;
}
static int threeway_merge(struct cache_entry *stages[4],
struct cache_entry **dst,
struct cache_entry **next, int tail)
{
struct cache_entry *old = stages[0];
struct cache_entry *a = stages[1], *b = stages[2], *c = stages[3];
struct cache_entry *merge;
int count;
/* #5ALT */
if (!a && b && c && same(b, c)) {
if (old && !same(b, old))
return -1;
return merged_entry_allow_dirty(b, old, dst);
}
/* #2ALT and #3ALT */
if (!a && (!!b != !!c)) {
/*
* The reason we need to worry about directory/file
* conflicts only in #2ALT and #3ALT case is this:
*
* (1) For all other cases that read-tree internally
* resolves a path, we always have such a path in
* *both* stage2 and stage3 when we begin.
* Traditionally, the behaviour has been even
* stricter and we did not resolve a path without
* initially being in all of stage1, 2, and 3.
*
* (2) When read-tree finishes, all resolved paths (i.e.
* the paths that are in stage0) must have come from
* either stage2 or stage3. It is not possible to
* have a stage0 path as a result of a merge if
* neither stage2 nor stage3 had that path.
*
* (3) It is guaranteed that just after reading the
* stages, each stage cannot have directory/file
* conflicts on its own, because they are populated
* by reading hierarchy of a tree. Combined with
* (1) and (2) above, this means that no matter what
* combination of paths we take from stage2 and
* stage3 as a result of a merge, they cannot cause
* a directory/file conflict situation (otherwise
* the "guilty" path would have already had such a
* conflict in the original stage, either stage2
* or stage3). Although its stage2 is synthesized
* by overlaying the current index on top of "our
* head" tree, --emu23 case also has this guarantee,
* by calling add_cache_entry() to create such stage2
* entries.
*
* (4) Only #2ALT and #3ALT lack the guarantee (1).
* They resolve paths that exist only in stage2
* or stage3. The stage2 tree may have a file DF
* while stage3 tree may have a file DF/DF. If
* #2ALT and #3ALT rules happen to apply to both
* of them, we would end up having DF (coming from
* stage2) and DF/DF (from stage3) in the result.
* When we attempt to resolve a path that exists
* only in stage2, we need to make sure there is
* no path that would conflict with it in stage3
* and vice versa.
*/
if (c) { /* #2ALT */
if (!causes_df_conflict(c, 2, dst, next, tail) &&
(!old || same(c, old)))
return merged_entry_allow_dirty(c, old, dst);
}
else { /* #3ALT */
if (!causes_df_conflict(b, 3, dst, next, tail) &&
(!old || same(b, old)))
return merged_entry_allow_dirty(b, old, dst);
}
/* otherwise we will apply the original rule */
}
/* #14ALT */
if (a && b && c && same(a, b) && !same(a, c)) {
if (old && same(old, c))
return merged_entry_allow_dirty(c, old, dst);
/* otherwise the regular rule applies */
}
/*
* If we have an entry in the index cache ("old"), then we want
* to make sure that it matches any entries in stage 2 ("first
* branch", aka "b").
*/
if (old) {
if (!b || !same(old, b))
return -1;
}
merge = merge_entries(a, b, c);
if (merge)
return merged_entry(merge, old, dst);
if (old)
verify_uptodate(old);
count = 0;
if (a) { *dst++ = a; count++; }
if (b) { *dst++ = b; count++; }
if (c) { *dst++ = c; count++; }
return count;
}
/*
* Two-way merge.
*
* The rule is to "carry forward" what is in the index without losing
* information across a "fast forward", favoring a successful merge
* over a merge failure when it makes sense. For details of the
* "carry forward" rule, please see <Documentation/git-read-tree.txt>.
*
*/
static int twoway_merge(struct cache_entry **src, struct cache_entry **dst,
struct cache_entry **next, int tail)
{
struct cache_entry *current = src[0];
struct cache_entry *oldtree = src[1], *newtree = src[2];
if (src[3])
return -1;
if (current) {
if ((!oldtree && !newtree) || /* 4 and 5 */
(!oldtree && newtree &&
same(current, newtree)) || /* 6 and 7 */
(oldtree && newtree &&
same(oldtree, newtree)) || /* 14 and 15 */
(oldtree && newtree &&
!same(oldtree, newtree) && /* 18 and 19*/
same(current, newtree))) {
*dst++ = current;
return 1;
}
else if (oldtree && !newtree && same(current, oldtree)) {
/* 10 or 11 */
return deleted_entry(oldtree, current, dst);
}
else if (oldtree && newtree &&
same(current, oldtree) && !same(current, newtree)) {
/* 20 or 21 */
return merged_entry(newtree, current, dst);
}
else
/* all other failures */
return -1;
}
else if (newtree)
return merged_entry(newtree, current, dst);
else
return deleted_entry(oldtree, current, dst);
}
/*
* Two-way merge emulated with three-way merge.
*
* This treats "read-tree -m H M" by transforming it internally
* into "read-tree -m H I+H M", where I+H is a tree that would
* contain the contents of the current index file, overlayed on
* top of H. Unlike the traditional two-way merge, this leaves
* the stages in the resulting index file and lets the user resolve
* the merge conflicts using standard tools for three-way merge.
*
* This function is just to set-up such an arrangement, and the
* actual merge uses threeway_merge() function.
*/
static void setup_emu23(void)
{
/* stage0 contains I, stage1 H, stage2 M.
* move stage2 to stage3, and create stage2 entries
* by scanning stage0 and stage1 entries.
*/
int i, namelen, size;
struct cache_entry *ce, *stage2;
for (i = 0; i < active_nr; i++) {
ce = active_cache[i];
if (ce_stage(ce) != 2)
continue;
/* hoist them up to stage 3 */
namelen = ce_namelen(ce);
ce->ce_flags = create_ce_flags(namelen, 3);
}
for (i = 0; i < active_nr; i++) {
ce = active_cache[i];
if (ce_stage(ce) > 1)
continue;
namelen = ce_namelen(ce);
size = cache_entry_size(namelen);
stage2 = xmalloc(size);
memcpy(stage2, ce, size);
stage2->ce_flags = create_ce_flags(namelen, 2);
if (add_cache_entry(stage2, ADD_CACHE_OK_TO_ADD) < 0)
die("cannot merge index and our head tree");
/* We are done with this name, so skip to next name */
while (i < active_nr &&
ce_namelen(active_cache[i]) == namelen &&
!memcmp(active_cache[i]->name, ce->name, namelen))
i++;
i--; /* compensate for the loop control */
}
}
/*
* One-way merge.
*
* The rule is:
* - take the stat information from stage0, take the data from stage1
*/
static int oneway_merge(struct cache_entry **src, struct cache_entry **dst,
struct cache_entry **next, int tail)
{
struct cache_entry *old = src[0];
struct cache_entry *a = src[1];
if (src[2] || src[3])
return -1;
if (!a)
return 0;
if (old && same(old, a)) {
*dst++ = old;
return 1;
}
return merged_entry(a, NULL, dst);
}
static void check_updates(struct cache_entry **src, int nr)
{
static struct checkout state = {
.base_dir = "",
.force = 1,
.quiet = 1,
.refresh_cache = 1,
};
unsigned short mask = htons(CE_UPDATE);
while (nr--) {
struct cache_entry *ce = *src++;
if (!ce->ce_mode) {
if (update)
unlink(ce->name);
continue;
}
if (ce->ce_flags & mask) {
ce->ce_flags &= ~mask;
if (update)
checkout_entry(ce, &state);
}
}
}
typedef int (*merge_fn_t)(struct cache_entry **, struct cache_entry **, struct cache_entry **, int);
static void merge_cache(struct cache_entry **src, int nr, merge_fn_t fn)
{
struct cache_entry **dst = src;
int tail = nr;
while (nr) {
int entries;
struct cache_entry *name, *ce, *stages[4] = { NULL, };
name = ce = *src;
for (;;) {
int stage = ce_stage(ce);
stages[stage] = ce;
ce = *++src;
active_nr--;
if (!--nr)
break;
if (!path_matches(ce, name))
break;
}
entries = fn(stages, dst, src, tail);
if (entries < 0)
reject_merge(name);
dst += entries;
active_nr += entries;
}
check_updates(active_cache, active_nr);
}
static int read_cache_unmerged(void)
{
int i, deleted;
struct cache_entry **dst;
read_cache();
dst = active_cache;
deleted = 0;
for (i = 0; i < active_nr; i++) {
struct cache_entry *ce = active_cache[i];
if (ce_stage(ce)) {
deleted++;
continue;
}
if (deleted)
*dst = ce;
dst++;
}
active_nr -= deleted;
return deleted;
}
static char *read_tree_usage = "git-read-tree (<sha> | -m [-u] <sha1> [<sha2> [<sha3>]])";
static struct cache_file cache_file;
int main(int argc, char **argv)
{
int i, newfd, merge, reset, emu23;
unsigned char sha1[20];
newfd = hold_index_file_for_update(&cache_file, get_index_file());
if (newfd < 0)
die("unable to create new cachefile");
merge = 0;
reset = 0;
emu23 = 0;
for (i = 1; i < argc; i++) {
const char *arg = argv[i];
/* "-u" means "update", meaning that a merge will update the working directory */
if (!strcmp(arg, "-u")) {
update = 1;
continue;
}
/* This differs from "-m" in that we'll silently ignore unmerged entries */
if (!strcmp(arg, "--reset")) {
if (stage || merge || emu23)
usage(read_tree_usage);
reset = 1;
merge = 1;
stage = 1;
read_cache_unmerged();
continue;
}
/* "-m" stands for "merge", meaning we start in stage 1 */
if (!strcmp(arg, "-m")) {
if (stage || merge || emu23)
usage(read_tree_usage);
if (read_cache_unmerged())
die("you need to resolve your current index first");
stage = 1;
merge = 1;
continue;
}
/* "-emu23" uses 3-way merge logic to perform fast-forward */
if (!strcmp(arg, "--emu23")) {
if (stage || merge || emu23)
usage(read_tree_usage);
if (read_cache_unmerged())
die("you need to resolve your current index first");
merge = emu23 = stage = 1;
continue;
}
if (get_sha1(arg, sha1) < 0)
usage(read_tree_usage);
if (stage > 3)
usage(read_tree_usage);
if (unpack_tree(sha1) < 0)
die("failed to unpack tree object %s", arg);
stage++;
}
if (update && !merge)
usage(read_tree_usage);
if (merge) {
static const merge_fn_t merge_function[] = {
[1] = oneway_merge,
[2] = twoway_merge,
[3] = threeway_merge,
};
merge_fn_t fn;
if (stage < 2 || stage > 4)
die("just how do you expect me to merge %d trees?", stage-1);
if (emu23 && stage != 3)
die("--emu23 takes only two trees");
fn = merge_function[stage-1];
if (stage == 3 && emu23) {
setup_emu23();
fn = merge_function[3];
}
merge_cache(active_cache, active_nr, fn);
}
if (write_cache(newfd, active_cache, active_nr) ||
commit_index_file(&cache_file))
die("unable to write new index file");
return 0;
}