| blob | a7624d8be8e58e0807cf0b2dc5e3bae52ac53af9 |
14 off_t offset;
16 };
18 /*
19 * Pack index for existing packs give us easy access to the offsets into
20 * corresponding pack file where each object's data starts, but the entries
21 * do not store the size of the compressed representation (uncompressed
22 * size is easily available by examining the pack entry header). It is
23 * also rather expensive to find the sha1 for an object given its offset.
24 *
25 * The pack index file is sorted by object name mapping to offset;
26 * this revindex array is a list of offset/index_nr pairs
27 * ordered by offset, so if you know the offset of an object, next offset
28 * is where its packed representation ends and the index_nr can be used to
29 * get the object sha1 from the main index.
30 */
32 /*
33 * This is a least-significant-digit radix sort.
34 *
35 * It sorts each of the "n" items in "entries" by its offset field. The "max"
36 * parameter must be at least as large as the largest offset in the array,
37 * and lets us quit the sort early.
38 */
40 {
41 /*
42 * We use a "digit" size of 16 bits. That keeps our memory
43 * usage reasonable, and we can generally (for a 4G or smaller
44 * packfile) quit after two rounds of radix-sorting.
45 */
46 #define DIGIT_SIZE (16)
47 #define BUCKETS (1 << DIGIT_SIZE)
48 /*
49 * We want to know the bucket that a[i] will go into when we are using
50 * the digit that is N bits from the (least significant) end.
51 */
52 #define BUCKET_FOR(a, i, bits) (((a)[(i)].offset >> (bits)) & (BUCKETS-1))
54 /*
55 * We need O(n) temporary storage. Rather than do an extra copy of the
56 * partial results into "entries", we sort back and forth between the
57 * real array and temporary storage. In each iteration of the loop, we
58 * keep track of them with alias pointers, always sorting from "from"
59 * to "to".
60 */
70 /*
71 * If (max >> bits) is zero, then we know that the radix digit we are
72 * on (and any higher) will be zero for all entries, and our loop will
73 * be a no-op, as everybody lands in the same zero-th bucket.
74 */
80 /*
81 * We want pos[i] to store the index of the last element that
82 * will go in bucket "i" (actually one past the last element).
83 * To do this, we first count the items that will go in each
84 * bucket, which gives us a relative offset from the last
85 * bucket. We can then cumulatively add the index from the
86 * previous bucket to get the true index.
87 */
93 /*
94 * Now we can drop the elements into their correct buckets (in
95 * our temporary array). We iterate the pos counter backwards
96 * to avoid using an extra index to count up. And since we are
97 * going backwards there, we must also go backwards through the
98 * array itself, to keep the sort stable.
99 *
100 * Note that we use an unsigned iterator to make sure we can
101 * handle 2^32-1 objects, even on a 32-bit system. But this
102 * means we cannot use the more obvious "i >= 0" loop condition
103 * for counting backwards, and must instead check for
104 * wrap-around with UINT_MAX.
105 */
109 /*
110 * Now "to" contains the most sorted list, so we swap "from" and
111 * "to" for the next iteration.
112 */
114 }
116 /*
117 * If we ended with our data in the original array, great. If not,
118 * we have to move it back from the temporary storage.
119 */
125 #undef BUCKET_FOR
126 #undef BUCKETS
127 #undef DIGIT_SIZE
128 }
130 /*
131 * Ordered list of offsets of objects in the pack.
132 */
134 {
154 }
156 }
162 }
163 }
165 /*
166 * This knows the pack format -- the hash trailer
167 * follows immediately after the last object data.
168 */
172 }
175 {
178 GIT_TEST_REV_INDEX_DIE_IN_MEMORY);
183 }
186 {
191 }
193 #define RIDX_HEADER_SIZE (12)
194 #define RIDX_MIN_SIZE (RIDX_HEADER_SIZE + (2 * the_hash_algo->rawsz))
200 };
205 {
218 /* "No file" means return 1. */
221 }
225 }
232 }
237 }
245 }
250 }
255 }
257 cleanup:
264 }
269 }
272 {
289 cleanup:
292 }
295 {
307 }
309 /*
310 * verify_pack_revindex verifies that the on-disk rev-index for the given
311 * pack-file is the same that would be created if written from scratch.
312 *
313 * A negative number is returned on error.
314 */
316 {
319 /* Do not bother checking if not initialized. */
326 }
328 /* This may fail due to a broken .idx. */
340 }
341 }
344 }
347 {
353 }
355 }
358 {
366 /*
367 * If the MIDX `m` has a `RIDX` chunk, then use its contents for
368 * the reverse index instead of trying to load a separate `.rev`
369 * file.
370 *
371 * Note that we do *not* set `m->revindex_map` here, since we do
372 * not want to accidentally call munmap() in the middle of the
373 * MIDX.
374 */
379 }
395 cleanup:
398 }
401 {
412 }
415 {
433 else
439 }
442 {
450 else
452 }
455 {
465 else
467 }
470 {
476 }
480 off_t offset;
484 };
487 {
491 uint32_t versus = pack_pos_to_midx(midx, (uint32_t*)vb - (const uint32_t *)midx->revindex_data);
493 off_t versus_offset;
498 /*
499 * First, compare the preferred-ness, noting that the preferred pack
500 * comes first.
501 */
507 /* Then, break ties first by comparing the pack IDs. */
513 /* Finally, break ties by comparing offsets within a pack. */
521 }
526 {
529 /*
530 * The preferred pack sorts first, so determine its identifier by
531 * looking at the first object in pseudo-pack order.
532 *
533 * Note that if no --preferred-pack is explicitly given when writing a
534 * multi-pack index, then whichever pack has the lowest identifier
535 * implicitly is preferred (and includes all its objects, since ties are
536 * broken first by pack identifier).
537 */
543 midx_pack_order_cmp);
550 }
553 {
566 }
570 {
575 };
577 }