| blob | 3a767486da3e92b782bb67601a60921b7c747bff |
1 /*
2 * Copyright (c) 2005, Jon Seymour
3 *
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.
8 *
9 */
10 #include <stdlib.h>
12 /* Provides arbitrary precision integers required to accurately represent
13 * fractional mass: */
14 #include <openssl/bn.h>
21 BIGNUM numerator;
22 BIGNUM denominator;
23 };
25 #define HAS_EXACTLY_ONE_PARENT(n) ((n)->parents && !(n)->parents->next)
32 {
35 }
37 }
40 {
47 }
50 {
53 }
56 {
57 BIGNUM bn_divisor;
67 }
70 {
76 }
79 {
83 }
85 }
88 {
91 }
93 }
96 {
100 }
102 static struct fraction *add(struct fraction *result, struct fraction *left, struct fraction *right)
103 {
124 }
127 {
143 }
148 };
151 {
164 }
169 }
172 {
176 }
178 /*
179 * Finds the base commit of a list of commits.
180 *
181 * One property of the commit being searched for is that every commit reachable
182 * from the base commit is reachable from the commits in the starting list only
183 * via paths that include the base commit.
184 *
185 * This algorithm uses a conservation of mass approach to find the base commit.
186 *
187 * We start by injecting one unit of mass into the graph at each
188 * of the commits in the starting list. Injecting mass into a commit
189 * is achieved by adding to its pending mass counter and, if it is not already
190 * enqueued, enqueuing the commit in a list of pending commits, in latest
191 * commit date first order.
192 *
193 * The algorithm then proceeds to visit each commit in the pending queue.
194 * Upon each visit, the pending mass is added to the mass already seen for that
195 * commit and then divided into N equal portions, where N is the number of
196 * parents of the commit being visited. The divided portions are then injected
197 * into each of the parents.
198 *
199 * The algorithm continues until we discover a commit which has seen all the
200 * mass originally injected or until we run out of things to do.
201 *
202 * If we find a commit that has seen all the original mass, we have found
203 * the common base of all the commits in the starting list.
204 *
205 * The algorithm does _not_ depend on accurate timestamps for correct operation.
206 * However, reasonably sane (e.g. non-random) timestamps are required in order
207 * to prevent an exponential performance characteristic. The occasional
208 * timestamp inaccuracy will not dramatically affect performance but may
209 * result in more nodes being processed than strictly necessary.
210 *
211 * This procedure sets *boundary to the address of the base commit. It returns
212 * non-zero if, and only if, there was a problem parsing one of the
213 * commits discovered during the traversal.
214 */
216 {
233 }
234 }
264 }
265 }
268 }
273 }
279 }
286 }
289 /*
290 * Finds the base of an minimal, non-linear epoch, headed at head, by
291 * applying the find_base_for_list to a list consisting of the parents
292 */
294 {
301 }
306 }
308 /*
309 * This procedure traverses to the boundary of the first epoch in the epoch
310 * sequence of the epoch headed at head_of_epoch. This is either the end of
311 * the maximal linear epoch or the base of a minimal non-linear epoch.
312 *
313 * The queue of pending nodes is sorted in reverse date order and each node
314 * is currently in the queue at most once.
315 */
317 {
326 /*
327 * We are at the start of a maximimal linear epoch.
328 * Traverse to the end.
329 */
333 }
337 /*
338 * Otherwise, we are at the start of a minimal, non-linear
339 * epoch - find the common base of all parents.
340 */
342 }
345 }
347 /*
348 * Returns non-zero if parent is known to be a parent of child.
349 */
351 {
357 }
359 }
361 /*
362 * Pushes an item onto the merge order stack. If the top of the stack is
363 * marked as being a possible "break", we check to see whether it actually
364 * is a break.
365 */
367 {
372 }
373 }
375 }
377 /*
378 * Marks all interesting, visited commits reachable from this commit
379 * as uninteresting. We stop recursing when we reach the epoch boundary,
380 * an unvisited node or a node that has already been marking uninteresting.
381 *
382 * This doesn't actually mark all ancestors between the start node and the
383 * epoch boundary uninteresting, but does ensure that they will eventually
384 * be marked uninteresting when the main sort_first_epoch() traversal
385 * eventually reaches them.
386 */
388 {
397 /*
398 * We only need to recurse if
399 * we are not on the boundary and
400 * we have not already been marked uninteresting and
401 * we have already been visited.
402 *
403 * The main sort_first_epoch traverse will mark unreachable
404 * all uninteresting, unvisited parents as they are visited
405 * so there is no need to duplicate that traversal here.
406 *
407 * Similarly, if we are already marked uninteresting
408 * then either all ancestors have already been marked
409 * uninteresting or will be once the sort_first_epoch
410 * traverse reaches them.
411 */
418 }
420 /*
421 * Sorts the nodes of the first epoch of the epoch sequence of the epoch headed at head
422 * into merge order.
423 */
425 {
430 /*
431 * TODO: By sorting the parents in a different order, we can alter the
432 * merge order to show contemporaneous changes in parallel branches
433 * occurring after "local" changes. This is useful for a developer
434 * when a developer wants to see all changes that were incorporated
435 * into the same merge as her own changes occur after her own
436 * changes.
437 */
443 /*
444 * Propagates the uninteresting bit to all parents.
445 * if we have already visited this parent, then
446 * the uninteresting bit will be propagated to each
447 * reachable commit that is still not marked
448 * uninteresting and won't otherwise be reached.
449 */
451 }
458 }
465 /*
466 * This indicates a possible
467 * discontinuity it may not be be
468 * actual discontinuity if the head
469 * of parent N happens to be the tail
470 * of parent N+1.
471 *
472 * The next push onto the stack will
473 * resolve the question.
474 */
476 }
477 }
478 }
479 }
482 }
484 /*
485 * Emit the contents of the stack.
486 *
487 * The stack is freed and replaced by NULL.
488 *
489 * Sets the return value to STOP if no further output should be generated.
490 */
492 {
503 }
504 }
509 }
512 }
514 /*
515 * Sorts an arbitrary epoch into merge order by sorting each epoch
516 * of its epoch sequence into order.
517 *
518 * Note: this algorithm currently leaves traces of its execution in the
519 * object flags of nodes it discovers. This should probably be fixed.
520 */
522 {
549 }
553 }
554 }
561 }
562 }
566 }
569 }
571 /*
572 * Sorts the nodes reachable from a starting list in merge order, we
573 * first find the base for the starting list and then sort all nodes
574 * in this subgraph using the sort_first_epoch algorithm. Once we have
575 * reached the base we can continue sorting using sort_in_merge_order.
576 */
578 {
591 /*
592 * If there is only one element in the list, we can sort it
593 * using sort_in_merge_order.
594 */
597 /*
598 * Otherwise, we search for the base of the list.
599 */
612 /*
613 * If we have more commits
614 * to push, then the first
615 * push for the next parent may
616 * (or may * not) represent a
617 * discontinuity with respect
618 * to the parent currently on
619 * the top of the stack.
620 *
621 * Mark it for checking here,
622 * and check it with the next
623 * push. See sort_first_epoch()
624 * for more details.
625 */
627 }
628 }
629 }
632 }
636 }
639 }