git/tree-diff.c
Kirill Smelkov 72441af7c4 tree-diff: rework diff_tree() to generate diffs for multiparent cases as well
Previously diff_tree(), which is now named ll_diff_tree_sha1(), was
generating diff_filepair(s) for two trees t1 and t2, and that was
usually used for a commit as t1=HEAD~, and t2=HEAD - i.e. to see changes
a commit introduces.

In Git, however, we have fundamentally built flexibility in that a
commit can have many parents - 1 for a plain commit, 2 for a simple merge,
but also more than 2 for merging several heads at once.

For merges there is a so called combine-diff, which shows diff, a merge
introduces by itself, omitting changes done by any parent. That works
through first finding paths, that are different to all parents, and then
showing generalized diff, with separate columns for +/- for each parent.
The code lives in combine-diff.c .

There is an impedance mismatch, however, in that a commit could
generally have any number of parents, and that while diffing trees, we
divide cases for 2-tree diffs and more-than-2-tree diffs. I mean there
is no special casing for multiple parents commits in e.g.
revision-walker .

That impedance mismatch *hurts* *performance* *badly* for generating
combined diffs - in "combine-diff: optimize combine_diff_path
sets intersection" I've already removed some slowness from it, but from
the timings provided there, it could be seen, that combined diffs still
cost more than an order of magnitude more cpu time, compared to diff for
usual commits, and that would only be an optimistic estimate, if we take
into account that for e.g. linux.git there is only one merge for several
dozens of plain commits.

That slowness comes from the fact that currently, while generating
combined diff, a lot of time is spent computing diff(commit,commit^2)
just to only then intersect that huge diff to almost small set of files
from diff(commit,commit^1).

That's because at present, to compute combine-diff, for first finding
paths, that "every parent touches", we use the following combine-diff
property/definition:

D(A,P1...Pn) = D(A,P1) ^ ... ^ D(A,Pn)      (w.r.t. paths)

where

D(A,P1...Pn) is combined diff between commit A, and parents Pi

and

D(A,Pi) is usual two-tree diff Pi..A

So if any of that D(A,Pi) is huge, tracting 1 n-parent combine-diff as n
1-parent diffs and intersecting results will be slow.

And usually, for linux.git and other topic-based workflows, that
D(A,P2) is huge, because, if merge-base of A and P2, is several dozens
of merges (from A, via first parent) below, that D(A,P2) will be diffing
sum of merges from several subsystems to 1 subsystem.

The solution is to avoid computing n 1-parent diffs, and to find
changed-to-all-parents paths via scanning A's and all Pi's trees
simultaneously, at each step comparing their entries, and based on that
comparison, populate paths result, and deduce we could *skip*
*recursing* into subdirectories, if at least for 1 parent, sha1 of that
dir tree is the same as in A. That would save us from doing significant
amount of needless work.

Such approach is very similar to what diff_tree() does, only there we
deal with scanning only 2 trees simultaneously, and for n+1 tree, the
logic is a bit more complex:

D(T,P1...Pn) calculation scheme
-------------------------------

D(T,P1...Pn) = D(T,P1) ^ ... ^ D(T,Pn)	(regarding resulting paths set)

    D(T,Pj)		- diff between T..Pj
    D(T,P1...Pn)	- combined diff from T to parents P1,...,Pn

We start from all trees, which are sorted, and compare their entries in
lock-step:

     T     P1       Pn
     -     -        -
    |t|   |p1|     |pn|
    |-|   |--| ... |--|      imin = argmin(p1...pn)
    | |   |  |     |  |
    |-|   |--|     |--|
    |.|   |. |     |. |
     .     .        .
     .     .        .

at any time there could be 3 cases:

    1)  t < p[imin];
    2)  t > p[imin];
    3)  t = p[imin].

Schematic deduction of what every case means, and what to do, follows:

1)  t < p[imin]  ->  ∀j t ∉ Pj  ->  "+t" ∈ D(T,Pj)  ->  D += "+t";  t↓

2)  t > p[imin]

    2.1) ∃j: pj > p[imin]  ->  "-p[imin]" ∉ D(T,Pj)  ->  D += ø;  ∀ pi=p[imin]  pi↓
    2.2) ∀i  pi = p[imin]  ->  pi ∉ T  ->  "-pi" ∈ D(T,Pi)  ->  D += "-p[imin]";  ∀i pi↓

3)  t = p[imin]

    3.1) ∃j: pj > p[imin]  ->  "+t" ∈ D(T,Pj)  ->  only pi=p[imin] remains to investigate
    3.2) pi = p[imin]  ->  investigate δ(t,pi)
     |
     |
     v

    3.1+3.2) looking at δ(t,pi) ∀i: pi=p[imin] - if all != ø  ->

                      ⎧δ(t,pi)  - if pi=p[imin]
             ->  D += ⎨
                      ⎩"+t"     - if pi>p[imin]

    in any case t↓  ∀ pi=p[imin]  pi↓

~

For comparison, here is how diff_tree() works:

D(A,B) calculation scheme
-------------------------

    A     B
    -     -
   |a|   |b|    a < b   ->  a ∉ B   ->   D(A,B) +=  +a    a↓
   |-|   |-|    a > b   ->  b ∉ A   ->   D(A,B) +=  -b    b↓
   | |   | |    a = b   ->  investigate δ(a,b)            a↓ b↓
   |-|   |-|
   |.|   |.|
    .     .
    .     .

~~~~~~~~

This patch generalizes diff tree-walker to work with arbitrary number of
parents as described above - i.e. now there is a resulting tree t, and
some parents trees tp[i] i=[0..nparent). The generalization builds on
the fact that usual diff

D(A,B)

is by definition the same as combined diff

D(A,[B]),

so if we could rework the code for common case and make it be not slower
for nparent=1 case, usual diff(t1,t2) generation will not be slower, and
multiparent diff tree-walker would greatly benefit generating
combine-diff.

What we do is as follows:

1) diff tree-walker ll_diff_tree_sha1() is internally reworked to be
   a paths generator (new name diff_tree_paths()), with each generated path
   being `struct combine_diff_path` with info for path, new sha1,mode and for
   every parent which sha1,mode it was in it.

2) From that info, we can still generate usual diff queue with
   struct diff_filepairs, via "exporting" generated
   combine_diff_path, if we know we run for nparent=1 case.
   (see emit_diff() which is now named emit_diff_first_parent_only())

3) In order for diff_can_quit_early(), which checks

       DIFF_OPT_TST(opt, HAS_CHANGES))

   to work, that exporting have to be happening not in bulk, but
   incrementally, one diff path at a time.

   For such consumers, there is a new callback in diff_options
   introduced:

       ->pathchange(opt, struct combine_diff_path *)

   which, if set to !NULL, is called for every generated path.

   (see new compat ll_diff_tree_sha1() wrapper around new paths
    generator for setup)

4) The paths generation itself, is reworked from previous
   ll_diff_tree_sha1() code according to "D(A,P1...Pn) calculation
   scheme" provided above:

   On the start we allocate [nparent] arrays in place what was
   earlier just for one parent tree.

   then we just generalize loops, and comparison according to the
   algorithm.

Some notes(*):

1) alloca(), for small arrays, is used for "runs not slower for
   nparent=1 case than before" goal - if we change it to xmalloc()/free()
   the timings get ~1% worse. For alloca() we use just-introduced
   xalloca/xalloca_free compatibility wrappers, so it should not be a
   portability problem.

2) For every parent tree, we need to keep a tag, whether entry from that
   parent equals to entry from minimal parent. For performance reasons I'm
   keeping that tag in entry's mode field in unused bit - see S_IFXMIN_NEQ.
   Not doing so, we'd need to alloca another [nparent] array, which hurts
   performance.

3) For emitted paths, memory could be reused, if we know the path was
   processed via callback and will not be needed later. We use efficient
   hand-made realloc-style path_appendnew(), that saves us from ~1-1.5%
   of potential additional slowdown.

4) goto(s) are used in several places, as the code executes a little bit
   faster with lowered register pressure.

Also

- we should now check for FIND_COPIES_HARDER not only when two entries
  names are the same, and their hashes are equal, but also for a case,
  when a path was removed from some of all parents having it.

  The reason is, if we don't, that path won't be emitted at all (see
  "a > xi" case), and we'll just skip it, and FIND_COPIES_HARDER wants
  all paths - with diff or without - to be emitted, to be later analyzed
  for being copies sources.

  The new check is only necessary for nparent >1, as for nparent=1 case
  xmin_eqtotal always =1 =nparent, and a path is always added to diff as
  removal.

~~~~~~~~

Timings for

    # without -c, i.e. testing only nparent=1 case
    `git log --raw --no-abbrev --no-renames`

before and after the patch are as follows:

                navy.git        linux.git v3.10..v3.11

    before      0.611s          1.889s
    after       0.619s          1.907s
    slowdown    1.3%            0.9%

This timings show we did no harm to usual diff(tree1,tree2) generation.
From the table we can see that we actually did ~1% slowdown, but I think
I've "earned" that 1% in the previous patch ("tree-diff: reuse base
str(buf) memory on sub-tree recursion", HEAD~~) so for nparent=1 case,
net timings stays approximately the same.

The output also stayed the same.

(*) If we revert 1)-4) to more usual techniques, for nparent=1 case,
    we'll get ~2-2.5% of additional slowdown, which I've tried to avoid, as
   "do no harm for nparent=1 case" rule.

For linux.git, combined diff will run an order of magnitude faster and
appropriate timings will be provided in the next commit, as we'll be
taking advantage of the new diff tree-walker for combined-diff
generation there.

P.S. and combined diff is not some exotic/for-play-only stuff - for
example for a program I write to represent Git archives as readonly
filesystem, there is initial scan with

    `git log --reverse --raw --no-abbrev --no-renames -c`

to extract log of what was created/changed when, as a result building a
map

    {}  sha1    ->  in which commit (and date) a content was added

that `-c` means also show combined diff for merges, and without them, if
a merge is non-trivial (merges changes from two parents with both having
separate changes to a file), or an evil one, the map will not be full,
i.e. some valid sha1 would be absent from it.

That case was my initial motivation for combined diffs speedup.

Signed-off-by: Kirill Smelkov <kirr@mns.spb.ru>
Signed-off-by: Junio C Hamano <gitster@pobox.com>
2014-04-07 14:40:46 -07:00

708 lines
18 KiB
C

/*
* Helper functions for tree diff generation
*/
#include "cache.h"
#include "diff.h"
#include "diffcore.h"
#include "tree.h"
/*
* internal mode marker, saying a tree entry != entry of tp[imin]
* (see ll_diff_tree_paths for what it means there)
*
* we will update/use/emit entry for diff only with it unset.
*/
#define S_IFXMIN_NEQ S_DIFFTREE_IFXMIN_NEQ
static struct combine_diff_path *ll_diff_tree_paths(
struct combine_diff_path *p, const unsigned char *sha1,
const unsigned char **parents_sha1, int nparent,
struct strbuf *base, struct diff_options *opt);
static int ll_diff_tree_sha1(const unsigned char *old, const unsigned char *new,
struct strbuf *base, struct diff_options *opt);
/*
* Compare two tree entries, taking into account only path/S_ISDIR(mode),
* but not their sha1's.
*
* NOTE files and directories *always* compare differently, even when having
* the same name - thanks to base_name_compare().
*
* NOTE empty (=invalid) descriptor(s) take part in comparison as +infty,
* so that they sort *after* valid tree entries.
*
* Due to this convention, if trees are scanned in sorted order, all
* non-empty descriptors will be processed first.
*/
static int tree_entry_pathcmp(struct tree_desc *t1, struct tree_desc *t2)
{
struct name_entry *e1, *e2;
int cmp;
/* empty descriptors sort after valid tree entries */
if (!t1->size)
return t2->size ? 1 : 0;
else if (!t2->size)
return -1;
e1 = &t1->entry;
e2 = &t2->entry;
cmp = base_name_compare(e1->path, tree_entry_len(e1), e1->mode,
e2->path, tree_entry_len(e2), e2->mode);
return cmp;
}
/*
* convert path -> opt->diff_*() callbacks
*
* emits diff to first parent only, and tells diff tree-walker that we are done
* with p and it can be freed.
*/
static int emit_diff_first_parent_only(struct diff_options *opt, struct combine_diff_path *p)
{
struct combine_diff_parent *p0 = &p->parent[0];
if (p->mode && p0->mode) {
opt->change(opt, p0->mode, p->mode, p0->sha1, p->sha1,
1, 1, p->path, 0, 0);
}
else {
const unsigned char *sha1;
unsigned int mode;
int addremove;
if (p->mode) {
addremove = '+';
sha1 = p->sha1;
mode = p->mode;
} else {
addremove = '-';
sha1 = p0->sha1;
mode = p0->mode;
}
opt->add_remove(opt, addremove, mode, sha1, 1, p->path, 0);
}
return 0; /* we are done with p */
}
/*
* Make a new combine_diff_path from path/mode/sha1
* and append it to paths list tail.
*
* Memory for created elements could be reused:
*
* - if last->next == NULL, the memory is allocated;
*
* - if last->next != NULL, it is assumed that p=last->next was returned
* earlier by this function, and p->next was *not* modified.
* The memory is then reused from p.
*
* so for clients,
*
* - if you do need to keep the element
*
* p = path_appendnew(p, ...);
* process(p);
* p->next = NULL;
*
* - if you don't need to keep the element after processing
*
* pprev = p;
* p = path_appendnew(p, ...);
* process(p);
* p = pprev;
* ; don't forget to free tail->next in the end
*
* p->parent[] remains uninitialized.
*/
static struct combine_diff_path *path_appendnew(struct combine_diff_path *last,
int nparent, const struct strbuf *base, const char *path, int pathlen,
unsigned mode, const unsigned char *sha1)
{
struct combine_diff_path *p;
int len = base->len + pathlen;
int alloclen = combine_diff_path_size(nparent, len);
/* if last->next is !NULL - it is a pre-allocated memory, we can reuse */
p = last->next;
if (p && (alloclen > (intptr_t)p->next)) {
free(p);
p = NULL;
}
if (!p) {
p = xmalloc(alloclen);
/*
* until we go to it next round, .next holds how many bytes we
* allocated (for faster realloc - we don't need copying old data).
*/
p->next = (struct combine_diff_path *)(intptr_t)alloclen;
}
last->next = p;
p->path = (char *)&(p->parent[nparent]);
memcpy(p->path, base->buf, base->len);
memcpy(p->path + base->len, path, pathlen);
p->path[len] = 0;
p->mode = mode;
hashcpy(p->sha1, sha1 ? sha1 : null_sha1);
return p;
}
/*
* new path should be added to combine diff
*
* 3 cases on how/when it should be called and behaves:
*
* t, !tp -> path added, all parents lack it
* !t, tp -> path removed from all parents
* t, tp -> path modified/added
* (M for tp[i]=tp[imin], A otherwise)
*/
static struct combine_diff_path *emit_path(struct combine_diff_path *p,
struct strbuf *base, struct diff_options *opt, int nparent,
struct tree_desc *t, struct tree_desc *tp,
int imin)
{
unsigned mode;
const char *path;
const unsigned char *sha1;
int pathlen;
int old_baselen = base->len;
int i, isdir, recurse = 0, emitthis = 1;
/* at least something has to be valid */
assert(t || tp);
if (t) {
/* path present in resulting tree */
sha1 = tree_entry_extract(t, &path, &mode);
pathlen = tree_entry_len(&t->entry);
isdir = S_ISDIR(mode);
} else {
/*
* a path was removed - take path from imin parent. Also take
* mode from that parent, to decide on recursion(1).
*
* 1) all modes for tp[i]=tp[imin] should be the same wrt
* S_ISDIR, thanks to base_name_compare().
*/
tree_entry_extract(&tp[imin], &path, &mode);
pathlen = tree_entry_len(&tp[imin].entry);
isdir = S_ISDIR(mode);
sha1 = NULL;
mode = 0;
}
if (DIFF_OPT_TST(opt, RECURSIVE) && isdir) {
recurse = 1;
emitthis = DIFF_OPT_TST(opt, TREE_IN_RECURSIVE);
}
if (emitthis) {
int keep;
struct combine_diff_path *pprev = p;
p = path_appendnew(p, nparent, base, path, pathlen, mode, sha1);
for (i = 0; i < nparent; ++i) {
/*
* tp[i] is valid, if present and if tp[i]==tp[imin] -
* otherwise, we should ignore it.
*/
int tpi_valid = tp && !(tp[i].entry.mode & S_IFXMIN_NEQ);
const unsigned char *sha1_i;
unsigned mode_i;
p->parent[i].status =
!t ? DIFF_STATUS_DELETED :
tpi_valid ?
DIFF_STATUS_MODIFIED :
DIFF_STATUS_ADDED;
if (tpi_valid) {
sha1_i = tp[i].entry.sha1;
mode_i = tp[i].entry.mode;
}
else {
sha1_i = NULL;
mode_i = 0;
}
p->parent[i].mode = mode_i;
hashcpy(p->parent[i].sha1, sha1_i ? sha1_i : null_sha1);
}
keep = 1;
if (opt->pathchange)
keep = opt->pathchange(opt, p);
/*
* If a path was filtered or consumed - we don't need to add it
* to the list and can reuse its memory, leaving it as
* pre-allocated element on the tail.
*
* On the other hand, if path needs to be kept, we need to
* correct its .next to NULL, as it was pre-initialized to how
* much memory was allocated.
*
* see path_appendnew() for details.
*/
if (!keep)
p = pprev;
else
p->next = NULL;
}
if (recurse) {
const unsigned char **parents_sha1;
parents_sha1 = xalloca(nparent * sizeof(parents_sha1[0]));
for (i = 0; i < nparent; ++i) {
/* same rule as in emitthis */
int tpi_valid = tp && !(tp[i].entry.mode & S_IFXMIN_NEQ);
parents_sha1[i] = tpi_valid ? tp[i].entry.sha1
: NULL;
}
strbuf_add(base, path, pathlen);
strbuf_addch(base, '/');
p = ll_diff_tree_paths(p, sha1, parents_sha1, nparent, base, opt);
xalloca_free(parents_sha1);
}
strbuf_setlen(base, old_baselen);
return p;
}
static void skip_uninteresting(struct tree_desc *t, struct strbuf *base,
struct diff_options *opt)
{
enum interesting match;
while (t->size) {
match = tree_entry_interesting(&t->entry, base, 0, &opt->pathspec);
if (match) {
if (match == all_entries_not_interesting)
t->size = 0;
break;
}
update_tree_entry(t);
}
}
/*
* generate paths for combined diff D(sha1,parents_sha1[])
*
* Resulting paths are appended to combine_diff_path linked list, and also, are
* emitted on the go via opt->pathchange() callback, so it is possible to
* process the result as batch or incrementally.
*
* The paths are generated scanning new tree and all parents trees
* simultaneously, similarly to what diff_tree() was doing for 2 trees.
* The theory behind such scan is as follows:
*
*
* D(T,P1...Pn) calculation scheme
* -------------------------------
*
* D(T,P1...Pn) = D(T,P1) ^ ... ^ D(T,Pn) (regarding resulting paths set)
*
* D(T,Pj) - diff between T..Pj
* D(T,P1...Pn) - combined diff from T to parents P1,...,Pn
*
*
* We start from all trees, which are sorted, and compare their entries in
* lock-step:
*
* T P1 Pn
* - - -
* |t| |p1| |pn|
* |-| |--| ... |--| imin = argmin(p1...pn)
* | | | | | |
* |-| |--| |--|
* |.| |. | |. |
* . . .
* . . .
*
* at any time there could be 3 cases:
*
* 1) t < p[imin];
* 2) t > p[imin];
* 3) t = p[imin].
*
* Schematic deduction of what every case means, and what to do, follows:
*
* 1) t < p[imin] -> ∀j t ∉ Pj -> "+t" ∈ D(T,Pj) -> D += "+t"; t↓
*
* 2) t > p[imin]
*
* 2.1) ∃j: pj > p[imin] -> "-p[imin]" ∉ D(T,Pj) -> D += ø; ∀ pi=p[imin] pi↓
* 2.2) ∀i pi = p[imin] -> pi ∉ T -> "-pi" ∈ D(T,Pi) -> D += "-p[imin]"; ∀i pi↓
*
* 3) t = p[imin]
*
* 3.1) ∃j: pj > p[imin] -> "+t" ∈ D(T,Pj) -> only pi=p[imin] remains to investigate
* 3.2) pi = p[imin] -> investigate δ(t,pi)
* |
* |
* v
*
* 3.1+3.2) looking at δ(t,pi) ∀i: pi=p[imin] - if all != ø ->
*
* ⎧δ(t,pi) - if pi=p[imin]
* -> D += ⎨
* ⎩"+t" - if pi>p[imin]
*
*
* in any case t↓ ∀ pi=p[imin] pi↓
*
*
* ~~~~~~~~
*
* NOTE
*
* Usual diff D(A,B) is by definition the same as combined diff D(A,[B]),
* so this diff paths generator can, and is used, for plain diffs
* generation too.
*
* Please keep attention to the common D(A,[B]) case when working on the
* code, in order not to slow it down.
*
* NOTE
* nparent must be > 0.
*/
/* ∀ pi=p[imin] pi↓ */
static inline void update_tp_entries(struct tree_desc *tp, int nparent)
{
int i;
for (i = 0; i < nparent; ++i)
if (!(tp[i].entry.mode & S_IFXMIN_NEQ))
update_tree_entry(&tp[i]);
}
static struct combine_diff_path *ll_diff_tree_paths(
struct combine_diff_path *p, const unsigned char *sha1,
const unsigned char **parents_sha1, int nparent,
struct strbuf *base, struct diff_options *opt)
{
struct tree_desc t, *tp;
void *ttree, **tptree;
int i;
tp = xalloca(nparent * sizeof(tp[0]));
tptree = xalloca(nparent * sizeof(tptree[0]));
/*
* load parents first, as they are probably already cached.
*
* ( log_tree_diff() parses commit->parent before calling here via
* diff_tree_sha1(parent, commit) )
*/
for (i = 0; i < nparent; ++i)
tptree[i] = fill_tree_descriptor(&tp[i], parents_sha1[i]);
ttree = fill_tree_descriptor(&t, sha1);
/* Enable recursion indefinitely */
opt->pathspec.recursive = DIFF_OPT_TST(opt, RECURSIVE);
for (;;) {
int imin, cmp;
if (diff_can_quit_early(opt))
break;
if (opt->pathspec.nr) {
skip_uninteresting(&t, base, opt);
for (i = 0; i < nparent; i++)
skip_uninteresting(&tp[i], base, opt);
}
/* comparing is finished when all trees are done */
if (!t.size) {
int done = 1;
for (i = 0; i < nparent; ++i)
if (tp[i].size) {
done = 0;
break;
}
if (done)
break;
}
/*
* lookup imin = argmin(p1...pn),
* mark entries whether they =p[imin] along the way
*/
imin = 0;
tp[0].entry.mode &= ~S_IFXMIN_NEQ;
for (i = 1; i < nparent; ++i) {
cmp = tree_entry_pathcmp(&tp[i], &tp[imin]);
if (cmp < 0) {
imin = i;
tp[i].entry.mode &= ~S_IFXMIN_NEQ;
}
else if (cmp == 0) {
tp[i].entry.mode &= ~S_IFXMIN_NEQ;
}
else {
tp[i].entry.mode |= S_IFXMIN_NEQ;
}
}
/* fixup markings for entries before imin */
for (i = 0; i < imin; ++i)
tp[i].entry.mode |= S_IFXMIN_NEQ; /* pi > p[imin] */
/* compare t vs p[imin] */
cmp = tree_entry_pathcmp(&t, &tp[imin]);
/* t = p[imin] */
if (cmp == 0) {
/* are either pi > p[imin] or diff(t,pi) != ø ? */
if (!DIFF_OPT_TST(opt, FIND_COPIES_HARDER)) {
for (i = 0; i < nparent; ++i) {
/* p[i] > p[imin] */
if (tp[i].entry.mode & S_IFXMIN_NEQ)
continue;
/* diff(t,pi) != ø */
if (hashcmp(t.entry.sha1, tp[i].entry.sha1) ||
(t.entry.mode != tp[i].entry.mode))
continue;
goto skip_emit_t_tp;
}
}
/* D += {δ(t,pi) if pi=p[imin]; "+a" if pi > p[imin]} */
p = emit_path(p, base, opt, nparent,
&t, tp, imin);
skip_emit_t_tp:
/* t↓, ∀ pi=p[imin] pi↓ */
update_tree_entry(&t);
update_tp_entries(tp, nparent);
}
/* t < p[imin] */
else if (cmp < 0) {
/* D += "+t" */
p = emit_path(p, base, opt, nparent,
&t, /*tp=*/NULL, -1);
/* t↓ */
update_tree_entry(&t);
}
/* t > p[imin] */
else {
/* ∀i pi=p[imin] -> D += "-p[imin]" */
if (!DIFF_OPT_TST(opt, FIND_COPIES_HARDER)) {
for (i = 0; i < nparent; ++i)
if (tp[i].entry.mode & S_IFXMIN_NEQ)
goto skip_emit_tp;
}
p = emit_path(p, base, opt, nparent,
/*t=*/NULL, tp, imin);
skip_emit_tp:
/* ∀ pi=p[imin] pi↓ */
update_tp_entries(tp, nparent);
}
}
free(ttree);
for (i = nparent-1; i >= 0; i--)
free(tptree[i]);
xalloca_free(tptree);
xalloca_free(tp);
return p;
}
struct combine_diff_path *diff_tree_paths(
struct combine_diff_path *p, const unsigned char *sha1,
const unsigned char **parents_sha1, int nparent,
struct strbuf *base, struct diff_options *opt)
{
p = ll_diff_tree_paths(p, sha1, parents_sha1, nparent, base, opt);
/*
* free pre-allocated last element, if any
* (see path_appendnew() for details about why)
*/
if (p->next) {
free(p->next);
p->next = NULL;
}
return p;
}
/*
* Does it look like the resulting diff might be due to a rename?
* - single entry
* - not a valid previous file
*/
static inline int diff_might_be_rename(void)
{
return diff_queued_diff.nr == 1 &&
!DIFF_FILE_VALID(diff_queued_diff.queue[0]->one);
}
static void try_to_follow_renames(const unsigned char *old, const unsigned char *new, struct strbuf *base, struct diff_options *opt)
{
struct diff_options diff_opts;
struct diff_queue_struct *q = &diff_queued_diff;
struct diff_filepair *choice;
int i;
/*
* follow-rename code is very specific, we need exactly one
* path. Magic that matches more than one path is not
* supported.
*/
GUARD_PATHSPEC(&opt->pathspec, PATHSPEC_FROMTOP | PATHSPEC_LITERAL);
#if 0
/*
* We should reject wildcards as well. Unfortunately we
* haven't got a reliable way to detect that 'foo\*bar' in
* fact has no wildcards. nowildcard_len is merely a hint for
* optimization. Let it slip for now until wildmatch is taught
* about dry-run mode and returns wildcard info.
*/
if (opt->pathspec.has_wildcard)
die("BUG:%s:%d: wildcards are not supported",
__FILE__, __LINE__);
#endif
/* Remove the file creation entry from the diff queue, and remember it */
choice = q->queue[0];
q->nr = 0;
diff_setup(&diff_opts);
DIFF_OPT_SET(&diff_opts, RECURSIVE);
DIFF_OPT_SET(&diff_opts, FIND_COPIES_HARDER);
diff_opts.output_format = DIFF_FORMAT_NO_OUTPUT;
diff_opts.single_follow = opt->pathspec.items[0].match;
diff_opts.break_opt = opt->break_opt;
diff_opts.rename_score = opt->rename_score;
diff_setup_done(&diff_opts);
ll_diff_tree_sha1(old, new, base, &diff_opts);
diffcore_std(&diff_opts);
free_pathspec(&diff_opts.pathspec);
/* Go through the new set of filepairing, and see if we find a more interesting one */
opt->found_follow = 0;
for (i = 0; i < q->nr; i++) {
struct diff_filepair *p = q->queue[i];
/*
* Found a source? Not only do we use that for the new
* diff_queued_diff, we will also use that as the path in
* the future!
*/
if ((p->status == 'R' || p->status == 'C') &&
!strcmp(p->two->path, opt->pathspec.items[0].match)) {
const char *path[2];
/* Switch the file-pairs around */
q->queue[i] = choice;
choice = p;
/* Update the path we use from now on.. */
path[0] = p->one->path;
path[1] = NULL;
free_pathspec(&opt->pathspec);
parse_pathspec(&opt->pathspec,
PATHSPEC_ALL_MAGIC & ~PATHSPEC_LITERAL,
PATHSPEC_LITERAL_PATH, "", path);
/*
* The caller expects us to return a set of vanilla
* filepairs to let a later call to diffcore_std()
* it makes to sort the renames out (among other
* things), but we already have found renames
* ourselves; signal diffcore_std() not to muck with
* rename information.
*/
opt->found_follow = 1;
break;
}
}
/*
* Then, discard all the non-relevant file pairs...
*/
for (i = 0; i < q->nr; i++) {
struct diff_filepair *p = q->queue[i];
diff_free_filepair(p);
}
/*
* .. and re-instate the one we want (which might be either the
* original one, or the rename/copy we found)
*/
q->queue[0] = choice;
q->nr = 1;
}
static int ll_diff_tree_sha1(const unsigned char *old, const unsigned char *new,
struct strbuf *base, struct diff_options *opt)
{
struct combine_diff_path phead, *p;
pathchange_fn_t pathchange_old = opt->pathchange;
phead.next = NULL;
opt->pathchange = emit_diff_first_parent_only;
diff_tree_paths(&phead, new, &old, 1, base, opt);
for (p = phead.next; p;) {
struct combine_diff_path *pprev = p;
p = p->next;
free(pprev);
}
opt->pathchange = pathchange_old;
return 0;
}
int diff_tree_sha1(const unsigned char *old, const unsigned char *new, const char *base_str, struct diff_options *opt)
{
struct strbuf base;
int retval;
strbuf_init(&base, PATH_MAX);
strbuf_addstr(&base, base_str);
retval = ll_diff_tree_sha1(old, new, &base, opt);
if (!*base_str && DIFF_OPT_TST(opt, FOLLOW_RENAMES) && diff_might_be_rename())
try_to_follow_renames(old, new, &base, opt);
strbuf_release(&base);
return retval;
}
int diff_root_tree_sha1(const unsigned char *new, const char *base, struct diff_options *opt)
{
return diff_tree_sha1(NULL, new, base, opt);
}