2 * Copyright (c) 2005, Jon Seymour
4 * For more information about epoch theory on which this module is based,
5 * refer to http://blackcubes.dyndns.org/epoch/. That web page defines
6 * terms such as "epoch" and "minimal, non-linear epoch" and provides rationales
7 * for some of the algorithms used here.
11 #include <openssl/bn.h> // provides arbitrary precision integers
12 // required to accurately represent fractional
24 #define HAS_EXACTLY_ONE_PARENT(n) ((n)->parents && !(n)->parents->next)
26 static BN_CTX
*context
= NULL
;
27 static struct fraction
*one
= NULL
;
28 static struct fraction
*zero
= NULL
;
30 static BN_CTX
*get_BN_CTX()
33 context
= BN_CTX_new();
38 static struct fraction
*new_zero()
40 struct fraction
*result
= xmalloc(sizeof(*result
));
41 BN_init(&result
->numerator
);
42 BN_init(&result
->denominator
);
43 BN_zero(&result
->numerator
);
44 BN_one(&result
->denominator
);
48 static void clear_fraction(struct fraction
*fraction
)
50 BN_clear(&fraction
->numerator
);
51 BN_clear(&fraction
->denominator
);
54 static struct fraction
*divide(struct fraction
*result
, struct fraction
*fraction
, int divisor
)
59 BN_set_word(&bn_divisor
, divisor
);
61 BN_copy(&result
->numerator
, &fraction
->numerator
);
62 BN_mul(&result
->denominator
, &fraction
->denominator
, &bn_divisor
, get_BN_CTX());
64 BN_clear(&bn_divisor
);
68 static struct fraction
*init_fraction(struct fraction
*fraction
)
70 BN_init(&fraction
->numerator
);
71 BN_init(&fraction
->denominator
);
72 BN_zero(&fraction
->numerator
);
73 BN_one(&fraction
->denominator
);
77 static struct fraction
*get_one()
81 BN_one(&one
->numerator
);
86 static struct fraction
*get_zero()
94 static struct fraction
*copy(struct fraction
*to
, struct fraction
*from
)
96 BN_copy(&to
->numerator
, &from
->numerator
);
97 BN_copy(&to
->denominator
, &from
->denominator
);
101 static struct fraction
*add(struct fraction
*result
, struct fraction
*left
, struct fraction
*right
)
109 BN_mul(&a
, &left
->numerator
, &right
->denominator
, get_BN_CTX());
110 BN_mul(&b
, &left
->denominator
, &right
->numerator
, get_BN_CTX());
111 BN_mul(&result
->denominator
, &left
->denominator
, &right
->denominator
, get_BN_CTX());
112 BN_add(&result
->numerator
, &a
, &b
);
114 BN_gcd(&gcd
, &result
->denominator
, &result
->numerator
, get_BN_CTX());
115 BN_div(&result
->denominator
, NULL
, &result
->denominator
, &gcd
, get_BN_CTX());
116 BN_div(&result
->numerator
, NULL
, &result
->numerator
, &gcd
, get_BN_CTX());
125 static int compare(struct fraction
*left
, struct fraction
*right
)
134 BN_mul(&a
, &left
->numerator
, &right
->denominator
, get_BN_CTX());
135 BN_mul(&b
, &left
->denominator
, &right
->numerator
, get_BN_CTX());
137 result
= BN_cmp(&a
, &b
);
145 struct mass_counter
{
146 struct fraction seen
;
147 struct fraction pending
;
150 static struct mass_counter
*new_mass_counter(struct commit
*commit
, struct fraction
*pending
)
152 struct mass_counter
*mass_counter
= xmalloc(sizeof(*mass_counter
));
153 memset(mass_counter
, 0, sizeof(*mass_counter
));
155 init_fraction(&mass_counter
->seen
);
156 init_fraction(&mass_counter
->pending
);
158 copy(&mass_counter
->pending
, pending
);
159 copy(&mass_counter
->seen
, get_zero());
161 if (commit
->object
.util
) {
162 die("multiple attempts to initialize mass counter for %s\n", sha1_to_hex(commit
->object
.sha1
));
165 commit
->object
.util
= mass_counter
;
170 static void free_mass_counter(struct mass_counter
*counter
)
172 clear_fraction(&counter
->seen
);
173 clear_fraction(&counter
->pending
);
178 // Finds the base commit of a list of commits.
180 // One property of the commit being searched for is that every commit reachable
181 // from the base commit is reachable from the commits in the starting list only
182 // via paths that include the base commit.
184 // This algorithm uses a conservation of mass approach to find the base commit.
186 // We start by injecting one unit of mass into the graph at each
187 // of the commits in the starting list. Injecting mass into a commit
188 // is achieved by adding to its pending mass counter and, if it is not already
189 // enqueued, enqueuing the commit in a list of pending commits, in latest
190 // commit date first order.
192 // The algorithm then preceeds to visit each commit in the pending queue.
193 // Upon each visit, the pending mass is added to the mass already seen for that
194 // commit and then divided into N equal portions, where N is the number of
195 // parents of the commit being visited. The divided portions are then injected
196 // into each of the parents.
198 // The algorithm continues until we discover a commit which has seen all the
199 // mass originally injected or until we run out of things to do.
201 // If we find a commit that has seen all the original mass, we have found
202 // the common base of all the commits in the starting list.
204 // The algorithm does _not_ depend on accurate timestamps for correct operation.
205 // However, reasonably sane (e.g. non-random) timestamps are required in order
206 // to prevent an exponential performance characteristic. The occasional
207 // timestamp inaccuracy will not dramatically affect performance but may
208 // result in more nodes being processed than strictly necessary.
210 // This procedure sets *boundary to the address of the base commit. It returns
211 // non-zero if, and only if, there was a problem parsing one of the
212 // commits discovered during the traversal.
214 static int find_base_for_list(struct commit_list
*list
, struct commit
**boundary
)
219 struct commit_list
*cleaner
= NULL
;
220 struct commit_list
*pending
= NULL
;
224 struct fraction injected
;
226 init_fraction(&injected
);
228 for (; list
; list
= list
->next
) {
230 struct commit
*item
= list
->item
;
232 if (item
->object
.util
) {
233 die("%s:%d:%s: logic error: this should not have happened - commit %s\n",
234 __FILE__
, __LINE__
, __FUNCTION__
, sha1_to_hex(item
->object
.sha1
));
237 new_mass_counter(list
->item
, get_one());
238 add(&injected
, &injected
, get_one());
240 commit_list_insert(list
->item
, &cleaner
);
241 commit_list_insert(list
->item
, &pending
);
244 while (!*boundary
&& pending
&& !ret
) {
246 struct commit
*latest
= pop_commit(&pending
);
248 struct mass_counter
*latest_node
= (struct mass_counter
*) latest
->object
.util
;
250 if ((ret
= parse_commit(latest
)))
253 add(&latest_node
->seen
, &latest_node
->seen
, &latest_node
->pending
);
255 int num_parents
= count_parents(latest
);
259 struct fraction distribution
;
260 struct commit_list
*parents
;
262 divide(init_fraction(&distribution
), &latest_node
->pending
, num_parents
);
264 for (parents
= latest
->parents
; parents
; parents
= parents
->next
) {
266 struct commit
*parent
= parents
->item
;
267 struct mass_counter
*parent_node
= (struct mass_counter
*) parent
->object
.util
;
271 parent_node
= new_mass_counter(parent
, &distribution
);
273 insert_by_date(&pending
, parent
);
274 commit_list_insert(parent
, &cleaner
);
278 if (!compare(&parent_node
->pending
, get_zero())) {
279 insert_by_date(&pending
, parent
);
281 add(&parent_node
->pending
, &parent_node
->pending
, &distribution
);
286 clear_fraction(&distribution
);
290 if (!compare(&latest_node
->seen
, &injected
)) {
294 copy(&latest_node
->pending
, get_zero());
300 struct commit
*next
= pop_commit(&cleaner
);
301 free_mass_counter((struct mass_counter
*) next
->object
.util
);
302 next
->object
.util
= NULL
;
307 free_commit_list(pending
);
309 clear_fraction(&injected
);
317 // Finds the base of an minimal, non-linear epoch, headed at head, by
318 // applying the find_base_for_list to a list consisting of the parents
320 static int find_base(struct commit
*head
, struct commit
**boundary
)
323 struct commit_list
*pending
= NULL
;
324 struct commit_list
*next
;
326 for (next
= head
->parents
; next
; next
= next
->next
) {
327 commit_list_insert(next
->item
, &pending
);
329 ret
= find_base_for_list(pending
, boundary
);
330 free_commit_list(pending
);
336 // This procedure traverses to the boundary of the first epoch in the epoch
337 // sequence of the epoch headed at head_of_epoch. This is either the end of
338 // the maximal linear epoch or the base of a minimal non-linear epoch.
340 // The queue of pending nodes is sorted in reverse date order and each node
341 // is currently in the queue at most once.
343 static int find_next_epoch_boundary(struct commit
*head_of_epoch
, struct commit
**boundary
)
346 struct commit
*item
= head_of_epoch
;
348 ret
= parse_commit(item
);
352 if (HAS_EXACTLY_ONE_PARENT(item
)) {
354 // we are at the start of a maximimal linear epoch .. traverse to the end
356 // traverse to the end of a maximal linear epoch
357 while (HAS_EXACTLY_ONE_PARENT(item
) && !ret
) {
358 item
= item
->parents
->item
;
359 ret
= parse_commit(item
);
365 // otherwise, we are at the start of a minimal, non-linear
366 // epoch - find the common base of all parents.
368 ret
= find_base(item
, boundary
);
376 // Returns non-zero if parent is known to be a parent of child.
378 static int is_parent_of(struct commit
*parent
, struct commit
*child
)
380 struct commit_list
*parents
;
381 for (parents
= child
->parents
; parents
; parents
= parents
->next
) {
382 if (!memcmp(parent
->object
.sha1
, parents
->item
->object
.sha1
, sizeof(parents
->item
->object
.sha1
)))
389 // Pushes an item onto the merge order stack. If the top of the stack is
390 // marked as being a possible "break", we check to see whether it actually
393 static void push_onto_merge_order_stack(struct commit_list
**stack
, struct commit
*item
)
395 struct commit_list
*top
= *stack
;
396 if (top
&& (top
->item
->object
.flags
& DISCONTINUITY
)) {
397 if (is_parent_of(top
->item
, item
)) {
398 top
->item
->object
.flags
&= ~DISCONTINUITY
;
401 commit_list_insert(item
, stack
);
405 // Marks all interesting, visited commits reachable from this commit
406 // as uninteresting. We stop recursing when we reach the epoch boundary,
407 // an unvisited node or a node that has already been marking uninteresting.
408 // This doesn't actually mark all ancestors between the start node and the
409 // epoch boundary uninteresting, but does ensure that they will
410 // eventually be marked uninteresting when the main sort_first_epoch
411 // traversal eventually reaches them.
413 static void mark_ancestors_uninteresting(struct commit
*commit
)
415 unsigned int flags
= commit
->object
.flags
;
416 int visited
= flags
& VISITED
;
417 int boundary
= flags
& BOUNDARY
;
418 int uninteresting
= flags
& UNINTERESTING
;
420 commit
->object
.flags
|= UNINTERESTING
;
421 if (uninteresting
|| boundary
|| !visited
) {
424 // we only need to recurse if
425 // we are not on the boundary, and,
426 // we have not already been marked uninteresting, and,
427 // we have already been visited.
430 // the main sort_first_epoch traverse will
431 // mark unreachable all uninteresting, unvisited parents
432 // as they are visited so there is no need to duplicate
433 // that traversal here.
435 // similarly, if we are already marked uninteresting
436 // then either all ancestors have already been marked
437 // uninteresting or will be once the sort_first_epoch
438 // traverse reaches them.
442 struct commit_list
*next
;
444 for (next
= commit
->parents
; next
; next
= next
->next
)
445 mark_ancestors_uninteresting(next
->item
);
449 // Sorts the nodes of the first epoch of the epoch sequence of the epoch headed at head
452 static void sort_first_epoch(struct commit
*head
, struct commit_list
**stack
)
454 struct commit_list
*parents
;
455 struct commit_list
*reversed_parents
= NULL
;
457 head
->object
.flags
|= VISITED
;
460 // parse_commit builds the parent list in reverse order with respect to the order of
461 // the git-commit-tree arguments.
463 // so we need to reverse this list to output the oldest (or most "local") commits last.
466 for (parents
= head
->parents
; parents
; parents
= parents
->next
)
467 commit_list_insert(parents
->item
, &reversed_parents
);
470 // todo: by sorting the parents in a different order, we can alter the
471 // merge order to show contemporaneous changes in parallel branches
472 // occurring after "local" changes. This is useful for a developer
473 // when a developer wants to see all changes that were incorporated
474 // into the same merge as her own changes occur after her own
478 while (reversed_parents
) {
480 struct commit
*parent
= pop_commit(&reversed_parents
);
482 if (head
->object
.flags
& UNINTERESTING
) {
483 // propagates the uninteresting bit to
484 // all parents. if we have already visited
485 // this parent, then the uninteresting bit
486 // will be propagated to each reachable
487 // commit that is still not marked uninteresting
488 // and won't otherwise be reached.
489 mark_ancestors_uninteresting(parent
);
492 if (!(parent
->object
.flags
& VISITED
)) {
493 if (parent
->object
.flags
& BOUNDARY
) {
496 die("something else is on the stack - %s\n", sha1_to_hex((*stack
)->item
->object
.sha1
));
499 push_onto_merge_order_stack(stack
, parent
);
500 parent
->object
.flags
|= VISITED
;
504 sort_first_epoch(parent
, stack
);
506 if (reversed_parents
) {
508 // this indicates a possible discontinuity
509 // it may not be be actual discontinuity if
510 // the head of parent N happens to be the tail
513 // the next push onto the stack will resolve the
516 (*stack
)->item
->object
.flags
|= DISCONTINUITY
;
522 push_onto_merge_order_stack(stack
, head
);
526 // Emit the contents of the stack.
528 // The stack is freed and replaced by NULL.
530 // Sets the return value to STOP if no further output should be generated.
532 static int emit_stack(struct commit_list
**stack
, emitter_func emitter
)
534 unsigned int seen
= 0;
535 int action
= CONTINUE
;
537 while (*stack
&& (action
!= STOP
)) {
539 struct commit
*next
= pop_commit(stack
);
541 seen
|= next
->object
.flags
;
544 action
= (*emitter
) (next
);
549 free_commit_list(*stack
);
553 return (action
== STOP
|| (seen
& UNINTERESTING
)) ? STOP
: CONTINUE
;
557 // Sorts an arbitrary epoch into merge order by sorting each epoch
558 // of its epoch sequence into order.
560 // Note: this algorithm currently leaves traces of its execution in the
561 // object flags of nodes it discovers. This should probably be fixed.
563 static int sort_in_merge_order(struct commit
*head_of_epoch
, emitter_func emitter
)
565 struct commit
*next
= head_of_epoch
;
567 int action
= CONTINUE
;
569 ret
= parse_commit(head_of_epoch
);
571 while (next
&& next
->parents
&& !ret
&& (action
!= STOP
)) {
573 struct commit
*base
= NULL
;
575 if ((ret
= find_next_epoch_boundary(next
, &base
)))
578 next
->object
.flags
|= BOUNDARY
;
580 base
->object
.flags
|= BOUNDARY
;
583 if (HAS_EXACTLY_ONE_PARENT(next
)) {
585 while (HAS_EXACTLY_ONE_PARENT(next
)
589 if (next
->object
.flags
& UNINTERESTING
) {
592 action
= (*emitter
) (next
);
595 if (action
!= STOP
) {
596 next
= next
->parents
->item
;
597 ret
= parse_commit(next
);
603 struct commit_list
*stack
= NULL
;
604 sort_first_epoch(next
, &stack
);
605 action
= emit_stack(&stack
, emitter
);
612 if (next
&& (action
!= STOP
) && !ret
) {
620 // Sorts the nodes reachable from a starting list in merge order, we
621 // first find the base for the starting list and then sort all nodes in this
622 // subgraph using the sort_first_epoch algorithm. Once we have reached the base
623 // we can continue sorting using sort_in_merge_order.
625 int sort_list_in_merge_order(struct commit_list
*list
, emitter_func emitter
)
627 struct commit_list
*stack
= NULL
;
631 int action
= CONTINUE
;
633 struct commit_list
*reversed
= NULL
;
635 for (; list
; list
= list
->next
) {
637 struct commit
*next
= list
->item
;
639 if (!(next
->object
.flags
& UNINTERESTING
)) {
640 if (next
->object
.flags
& DUPCHECK
) {
641 fprintf(stderr
, "%s: duplicate commit %s ignored\n", __FUNCTION__
, sha1_to_hex(next
->object
.sha1
));
643 next
->object
.flags
|= DUPCHECK
;
644 commit_list_insert(list
->item
, &reversed
);
649 if (!reversed
->next
) {
651 // if there is only one element in the list, we can sort it using
652 // sort_in_merge_order.
654 base
= reversed
->item
;
658 // otherwise, we search for the base of the list
660 if ((ret
= find_base_for_list(reversed
, &base
)))
664 base
->object
.flags
|= BOUNDARY
;
668 sort_first_epoch(pop_commit(&reversed
), &stack
);
671 // if we have more commits to push, then the
672 // first push for the next parent may (or may not)
673 // represent a discontinuity with respect to the
674 // parent currently on the top of the stack.
676 // mark it for checking here, and check it
677 // with the next push...see sort_first_epoch for
680 stack
->item
->object
.flags
|= DISCONTINUITY
;
684 action
= emit_stack(&stack
, emitter
);
687 if (base
&& (action
!= STOP
)) {
688 ret
= sort_in_merge_order(base
, emitter
);