match-trees.con commit sequencer: introduce todo_list_write_to_file() (616d774)
   1#include "cache.h"
   2#include "tree.h"
   3#include "tree-walk.h"
   4#include "object-store.h"
   5
   6static int score_missing(unsigned mode, const char *path)
   7{
   8        int score;
   9
  10        if (S_ISDIR(mode))
  11                score = -1000;
  12        else if (S_ISLNK(mode))
  13                score = -500;
  14        else
  15                score = -50;
  16        return score;
  17}
  18
  19static int score_differs(unsigned mode1, unsigned mode2, const char *path)
  20{
  21        int score;
  22
  23        if (S_ISDIR(mode1) != S_ISDIR(mode2))
  24                score = -100;
  25        else if (S_ISLNK(mode1) != S_ISLNK(mode2))
  26                score = -50;
  27        else
  28                score = -5;
  29        return score;
  30}
  31
  32static int score_matches(unsigned mode1, unsigned mode2, const char *path)
  33{
  34        int score;
  35
  36        /* Heh, we found SHA-1 collisions between different kind of objects */
  37        if (S_ISDIR(mode1) != S_ISDIR(mode2))
  38                score = -100;
  39        else if (S_ISLNK(mode1) != S_ISLNK(mode2))
  40                score = -50;
  41
  42        else if (S_ISDIR(mode1))
  43                score = 1000;
  44        else if (S_ISLNK(mode1))
  45                score = 500;
  46        else
  47                score = 250;
  48        return score;
  49}
  50
  51static void *fill_tree_desc_strict(struct tree_desc *desc,
  52                                   const struct object_id *hash)
  53{
  54        void *buffer;
  55        enum object_type type;
  56        unsigned long size;
  57
  58        buffer = read_object_file(hash, &type, &size);
  59        if (!buffer)
  60                die("unable to read tree (%s)", oid_to_hex(hash));
  61        if (type != OBJ_TREE)
  62                die("%s is not a tree", oid_to_hex(hash));
  63        init_tree_desc(desc, buffer, size);
  64        return buffer;
  65}
  66
  67static int base_name_entries_compare(const struct name_entry *a,
  68                                     const struct name_entry *b)
  69{
  70        return base_name_compare(a->path, tree_entry_len(a), a->mode,
  71                                 b->path, tree_entry_len(b), b->mode);
  72}
  73
  74/*
  75 * Inspect two trees, and give a score that tells how similar they are.
  76 */
  77static int score_trees(const struct object_id *hash1, const struct object_id *hash2)
  78{
  79        struct tree_desc one;
  80        struct tree_desc two;
  81        void *one_buf = fill_tree_desc_strict(&one, hash1);
  82        void *two_buf = fill_tree_desc_strict(&two, hash2);
  83        int score = 0;
  84
  85        for (;;) {
  86                int cmp;
  87
  88                if (one.size && two.size)
  89                        cmp = base_name_entries_compare(&one.entry, &two.entry);
  90                else if (one.size)
  91                        /* two lacks this entry */
  92                        cmp = -1;
  93                else if (two.size)
  94                        /* two has more entries */
  95                        cmp = 1;
  96                else
  97                        break;
  98
  99                if (cmp < 0) {
 100                        /* path1 does not appear in two */
 101                        score += score_missing(one.entry.mode, one.entry.path);
 102                        update_tree_entry(&one);
 103                } else if (cmp > 0) {
 104                        /* path2 does not appear in one */
 105                        score += score_missing(two.entry.mode, two.entry.path);
 106                        update_tree_entry(&two);
 107                } else {
 108                        /* path appears in both */
 109                        if (!oideq(one.entry.oid, two.entry.oid)) {
 110                                /* they are different */
 111                                score += score_differs(one.entry.mode,
 112                                                       two.entry.mode,
 113                                                       one.entry.path);
 114                        } else {
 115                                /* same subtree or blob */
 116                                score += score_matches(one.entry.mode,
 117                                                       two.entry.mode,
 118                                                       one.entry.path);
 119                        }
 120                        update_tree_entry(&one);
 121                        update_tree_entry(&two);
 122                }
 123        }
 124        free(one_buf);
 125        free(two_buf);
 126        return score;
 127}
 128
 129/*
 130 * Match one itself and its subtrees with two and pick the best match.
 131 */
 132static void match_trees(const struct object_id *hash1,
 133                        const struct object_id *hash2,
 134                        int *best_score,
 135                        char **best_match,
 136                        const char *base,
 137                        int recurse_limit)
 138{
 139        struct tree_desc one;
 140        void *one_buf = fill_tree_desc_strict(&one, hash1);
 141
 142        while (one.size) {
 143                const char *path;
 144                const struct object_id *elem;
 145                unsigned mode;
 146                int score;
 147
 148                elem = tree_entry_extract(&one, &path, &mode);
 149                if (!S_ISDIR(mode))
 150                        goto next;
 151                score = score_trees(elem, hash2);
 152                if (*best_score < score) {
 153                        free(*best_match);
 154                        *best_match = xstrfmt("%s%s", base, path);
 155                        *best_score = score;
 156                }
 157                if (recurse_limit) {
 158                        char *newbase = xstrfmt("%s%s/", base, path);
 159                        match_trees(elem, hash2, best_score, best_match,
 160                                    newbase, recurse_limit - 1);
 161                        free(newbase);
 162                }
 163
 164        next:
 165                update_tree_entry(&one);
 166        }
 167        free(one_buf);
 168}
 169
 170/*
 171 * A tree "oid1" has a subdirectory at "prefix".  Come up with a tree object by
 172 * replacing it with another tree "oid2".
 173 */
 174static int splice_tree(const struct object_id *oid1, const char *prefix,
 175                       const struct object_id *oid2, struct object_id *result)
 176{
 177        char *subpath;
 178        int toplen;
 179        char *buf;
 180        unsigned long sz;
 181        struct tree_desc desc;
 182        struct object_id *rewrite_here;
 183        const struct object_id *rewrite_with;
 184        struct object_id subtree;
 185        enum object_type type;
 186        int status;
 187
 188        subpath = strchrnul(prefix, '/');
 189        toplen = subpath - prefix;
 190        if (*subpath)
 191                subpath++;
 192
 193        buf = read_object_file(oid1, &type, &sz);
 194        if (!buf)
 195                die("cannot read tree %s", oid_to_hex(oid1));
 196        init_tree_desc(&desc, buf, sz);
 197
 198        rewrite_here = NULL;
 199        while (desc.size) {
 200                const char *name;
 201                unsigned mode;
 202                const struct object_id *oid;
 203
 204                oid = tree_entry_extract(&desc, &name, &mode);
 205                if (strlen(name) == toplen &&
 206                    !memcmp(name, prefix, toplen)) {
 207                        if (!S_ISDIR(mode))
 208                                die("entry %s in tree %s is not a tree", name,
 209                                    oid_to_hex(oid1));
 210                        rewrite_here = (struct object_id *)oid;
 211                        break;
 212                }
 213                update_tree_entry(&desc);
 214        }
 215        if (!rewrite_here)
 216                die("entry %.*s not found in tree %s", toplen, prefix,
 217                    oid_to_hex(oid1));
 218        if (*subpath) {
 219                status = splice_tree(rewrite_here, subpath, oid2, &subtree);
 220                if (status)
 221                        return status;
 222                rewrite_with = &subtree;
 223        } else {
 224                rewrite_with = oid2;
 225        }
 226        oidcpy(rewrite_here, rewrite_with);
 227        status = write_object_file(buf, sz, tree_type, result);
 228        free(buf);
 229        return status;
 230}
 231
 232/*
 233 * We are trying to come up with a merge between one and two that
 234 * results in a tree shape similar to one.  The tree two might
 235 * correspond to a subtree of one, in which case it needs to be
 236 * shifted down by prefixing otherwise empty directories.  On the
 237 * other hand, it could cover tree one and we might need to pick a
 238 * subtree of it.
 239 */
 240void shift_tree(const struct object_id *hash1,
 241                const struct object_id *hash2,
 242                struct object_id *shifted,
 243                int depth_limit)
 244{
 245        char *add_prefix;
 246        char *del_prefix;
 247        int add_score, del_score;
 248
 249        /*
 250         * NEEDSWORK: this limits the recursion depth to hardcoded
 251         * value '2' to avoid excessive overhead.
 252         */
 253        if (!depth_limit)
 254                depth_limit = 2;
 255
 256        add_score = del_score = score_trees(hash1, hash2);
 257        add_prefix = xcalloc(1, 1);
 258        del_prefix = xcalloc(1, 1);
 259
 260        /*
 261         * See if one's subtree resembles two; if so we need to prefix
 262         * two with a few fake trees to match the prefix.
 263         */
 264        match_trees(hash1, hash2, &add_score, &add_prefix, "", depth_limit);
 265
 266        /*
 267         * See if two's subtree resembles one; if so we need to
 268         * pick only subtree of two.
 269         */
 270        match_trees(hash2, hash1, &del_score, &del_prefix, "", depth_limit);
 271
 272        /* Assume we do not have to do any shifting */
 273        oidcpy(shifted, hash2);
 274
 275        if (add_score < del_score) {
 276                /* We need to pick a subtree of two */
 277                unsigned mode;
 278
 279                if (!*del_prefix)
 280                        return;
 281
 282                if (get_tree_entry(hash2, del_prefix, shifted, &mode))
 283                        die("cannot find path %s in tree %s",
 284                            del_prefix, oid_to_hex(hash2));
 285                return;
 286        }
 287
 288        if (!*add_prefix)
 289                return;
 290
 291        splice_tree(hash1, add_prefix, hash2, shifted);
 292}
 293
 294/*
 295 * The user says the trees will be shifted by this much.
 296 * Unfortunately we cannot fundamentally tell which one to
 297 * be prefixed, as recursive merge can work in either direction.
 298 */
 299void shift_tree_by(const struct object_id *hash1,
 300                   const struct object_id *hash2,
 301                   struct object_id *shifted,
 302                   const char *shift_prefix)
 303{
 304        struct object_id sub1, sub2;
 305        unsigned mode1, mode2;
 306        unsigned candidate = 0;
 307
 308        /* Can hash2 be a tree at shift_prefix in tree hash1? */
 309        if (!get_tree_entry(hash1, shift_prefix, &sub1, &mode1) &&
 310            S_ISDIR(mode1))
 311                candidate |= 1;
 312
 313        /* Can hash1 be a tree at shift_prefix in tree hash2? */
 314        if (!get_tree_entry(hash2, shift_prefix, &sub2, &mode2) &&
 315            S_ISDIR(mode2))
 316                candidate |= 2;
 317
 318        if (candidate == 3) {
 319                /* Both are plausible -- we need to evaluate the score */
 320                int best_score = score_trees(hash1, hash2);
 321                int score;
 322
 323                candidate = 0;
 324                score = score_trees(&sub1, hash2);
 325                if (score > best_score) {
 326                        candidate = 1;
 327                        best_score = score;
 328                }
 329                score = score_trees(&sub2, hash1);
 330                if (score > best_score)
 331                        candidate = 2;
 332        }
 333
 334        if (!candidate) {
 335                /* Neither is plausible -- do not shift */
 336                oidcpy(shifted, hash2);
 337                return;
 338        }
 339
 340        if (candidate == 1)
 341                /*
 342                 * shift tree2 down by adding shift_prefix above it
 343                 * to match tree1.
 344                 */
 345                splice_tree(hash1, shift_prefix, hash2, shifted);
 346        else
 347                /*
 348                 * shift tree2 up by removing shift_prefix from it
 349                 * to match tree1.
 350                 */
 351                oidcpy(shifted, &sub2);
 352}