/* * Copyright (C) 2020 Benjamin Otte * Copyright (C) 2011 Patrick O. Perry * Copyright (C) 2008 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef NAME #define NAME WIDTH #endif #define DEFINE_TEMP(temp) gpointer temp = g_alloca (WIDTH) #define ASSIGN(x, y) memcpy (x, y, WIDTH) #define INCPTR(x) ((gpointer) ((char *) (x) + WIDTH)) #define DECPTR(x) ((gpointer) ((char *) (x) - WIDTH)) #define ELEM(a, i) ((char *) (a) + (i) * WIDTH) #define LEN(n) ((n) * WIDTH) #define CONCAT(x, y) gtk_tim_sort_ ## x ## _ ## y #define MAKE_STR(x, y) CONCAT (x, y) #define gtk_tim_sort(x) MAKE_STR (x, NAME) /* * Reverse the specified range of the specified array. * * @param a the array in which a range is to be reversed * @param hi the index after the last element in the range to be reversed */ static void gtk_tim_sort(reverse_range) (GtkTimSort *self, gpointer a, gsize hi) { DEFINE_TEMP (t); char *front = a; char *back = ELEM (a, hi - 1); g_assert (hi > 0); while (front < back) { ASSIGN (t, front); ASSIGN (front, back); ASSIGN (back, t); front = INCPTR (front); back = DECPTR (back); } } /* * Returns the length of the run beginning at the specified position in * the specified array and reverses the run if it is descending (ensuring * that the run will always be ascending when the method returns). * * A run is the longest ascending sequence with: * * a[0] <= a[1] <= a[2] <= ... * * or the longest descending sequence with: * * a[0] > a[1] > a[2] > ... * * For its intended use in a stable mergesort, the strictness of the * definition of "descending" is needed so that the call can safely * reverse a descending sequence without violating stability. * * @param a the array in which a run is to be counted and possibly reversed * @param hi index after the last element that may be contained in the run. * It is required that {@code 0 < hi}. * @param compare the comparator to used for the sort * @return the length of the run beginning at the specified position in * the specified array */ static gsize gtk_tim_sort(prepare_run) (GtkTimSort *self, GtkTimSortRun *out_change) { gsize run_hi = 1; char *cur; char *next; if (self->size <= run_hi) { gtk_tim_sort_set_change (out_change, NULL, 0); return self->size; } cur = INCPTR (self->base); next = INCPTR (cur); run_hi++; /* Find end of run, and reverse range if descending */ if (gtk_tim_sort_compare (self, cur, self->base) < 0) /* Descending */ { while (run_hi < self->size && gtk_tim_sort_compare (self, next, cur) < 0) { run_hi++; cur = next; next = INCPTR (next); } gtk_tim_sort(reverse_range) (self, self->base, run_hi); gtk_tim_sort_set_change (out_change, self->base, run_hi); } else /* Ascending */ { while (run_hi < self->size && gtk_tim_sort_compare (self, next, cur) >= 0) { run_hi++; cur = next; next = INCPTR (next); } gtk_tim_sort_set_change (out_change, NULL, 0); } return run_hi; } /* * Sorts the specified portion of the specified array using a binary * insertion sort. This is the best method for sorting small numbers * of elements. It requires O(n log n) compares, but O(n^2) data * movement (worst case). * * If the initial part of the specified range is already sorted, * this method can take advantage of it: the method assumes that the * elements from index {@code lo}, inclusive, to {@code start}, * exclusive are already sorted. * * @param a the array in which a range is to be sorted * @param hi the index after the last element in the range to be sorted * @param start the index of the first element in the range that is * not already known to be sorted ({@code lo <= start <= hi}) */ static void gtk_tim_sort(binary_sort) (GtkTimSort *self, gpointer a, gsize hi, gsize start, GtkTimSortRun *inout_change) { DEFINE_TEMP (pivot); char *startp; char *change_min = ELEM (a, hi); char *change_max = a; g_assert (start <= hi); if (start == 0) start++; startp = ELEM (a, start); for (; start < hi; start++, startp = INCPTR (startp)) { /* Set left (and right) to the index where a[start] (pivot) belongs */ char *leftp = a; gsize right = start; gsize n; /* * Invariants: * pivot >= all in [0, left). * pivot < all in [right, start). */ while (0 < right) { gsize mid = right >> 1; gpointer midp = ELEM (leftp, mid); if (gtk_tim_sort_compare (self, startp, midp) < 0) { right = mid; } else { leftp = INCPTR (midp); right -= (mid + 1); } } g_assert (0 == right); /* * The invariants still hold: pivot >= all in [lo, left) and * pivot < all in [left, start), so pivot belongs at left. Note * that if there are elements equal to pivot, left points to the * first slot after them -- that's why this sort is stable. * Slide elements over to make room to make room for pivot. */ n = startp - leftp; /* The number of bytes to move */ if (n == 0) continue; ASSIGN (pivot, startp); memmove (INCPTR (leftp), leftp, n); /* POP: overlaps */ /* a[left] = pivot; */ ASSIGN (leftp, pivot); change_min = MIN (change_min, leftp); change_max = MAX (change_max, ELEM (startp, 1)); } if (change_max > (char *) a) { g_assert (change_min < ELEM (a, hi)); if (inout_change && inout_change->len) { change_max = MAX (change_max, ELEM (inout_change->base, inout_change->len)); change_min = MIN (change_min, (char *) inout_change->base); } gtk_tim_sort_set_change (inout_change, change_min, (change_max - change_min) / WIDTH); } } static gboolean gtk_tim_sort(merge_append) (GtkTimSort *self, GtkTimSortRun *out_change) { /* Identify next run */ gsize run_len; run_len = gtk_tim_sort(prepare_run) (self, out_change); if (run_len == 0) return FALSE; /* If run is short, extend to min(self->min_run, self->size) */ if (run_len < self->min_run) { gsize force = MIN (self->size, self->min_run); gtk_tim_sort(binary_sort) (self, self->base, force, run_len, out_change); run_len = force; } /* Push run onto pending-run stack, and maybe merge */ gtk_tim_sort_push_run (self, self->base, run_len); return TRUE; } /* * Locates the position at which to insert the specified key into the * specified sorted range; if the range contains an element equal to key, * returns the index of the leftmost equal element. * * @param key the key whose insertion point to search for * @param base the array in which to search * @param len the length of the range; must be > 0 * @param hint the index at which to begin the search, 0 <= hint < n. * The closer hint is to the result, the faster this method will run. * @param c the comparator used to order the range, and to search * @return the int k, 0 <= k <= n such that a[b + k - 1] < key <= a[b + k], * pretending that a[b - 1] is minus infinity and a[b + n] is infinity. * In other words, key belongs at index b + k; or in other words, * the first k elements of a should precede key, and the last n - k * should follow it. */ static gsize gtk_tim_sort(gallop_left) (GtkTimSort *self, gpointer key, gpointer base, gsize len, gsize hint) { char *hintp = ELEM (base, hint); gsize last_ofs = 0; gsize ofs = 1; g_assert (len > 0 && hint < len); if (gtk_tim_sort_compare (self, key, hintp) > 0) { /* Gallop right until a[hint+last_ofs] < key <= a[hint+ofs] */ gsize max_ofs = len - hint; while (ofs < max_ofs && gtk_tim_sort_compare (self, key, ELEM (hintp, ofs)) > 0) { last_ofs = ofs; ofs = (ofs << 1) + 1; /* eventually this becomes SIZE_MAX */ } if (ofs > max_ofs) ofs = max_ofs; /* Make offsets relative to base */ last_ofs += hint + 1; /* POP: we add 1 here so last_ofs stays non-negative */ ofs += hint; } else /* key <= a[hint] */ /* Gallop left until a[hint-ofs] < key <= a[hint-last_ofs] */ { const gsize max_ofs = hint + 1; gsize tmp; while (ofs < max_ofs && gtk_tim_sort_compare (self, key, ELEM (hintp, -ofs)) <= 0) { last_ofs = ofs; ofs = (ofs << 1) + 1; /* no need to check for overflow */ } if (ofs > max_ofs) ofs = max_ofs; /* Make offsets relative to base */ tmp = last_ofs; last_ofs = hint + 1 - ofs; /* POP: we add 1 here so last_ofs stays non-negative */ ofs = hint - tmp; } g_assert (last_ofs <= ofs && ofs <= len); /* * Now a[last_ofs-1] < key <= a[ofs], so key belongs somewhere * to the right of last_ofs but no farther right than ofs. Do a binary * search, with invariant a[last_ofs - 1] < key <= a[ofs]. */ /* last_ofs++; POP: we added 1 above to keep last_ofs non-negative */ while (last_ofs < ofs) { /*gsize m = last_ofs + ((ofs - last_ofs) >> 1); */ /* http://stackoverflow.com/questions/4844165/safe-integer-middle-value-formula */ gsize m = (last_ofs & ofs) + ((last_ofs ^ ofs) >> 1); if (gtk_tim_sort_compare (self, key, ELEM (base, m)) > 0) last_ofs = m + 1; /* a[m] < key */ else ofs = m; /* key <= a[m] */ } g_assert (last_ofs == ofs); /* so a[ofs - 1] < key <= a[ofs] */ return ofs; } /* * Like gallop_left, except that if the range contains an element equal to * key, gallop_right returns the index after the rightmost equal element. * * @param key the key whose insertion point to search for * @param base the array in which to search * @param len the length of the range; must be > 0 * @param hint the index at which to begin the search, 0 <= hint < n. * The closer hint is to the result, the faster this method will run. * @param c the comparator used to order the range, and to search * @return the int k, 0 <= k <= n such that a[b + k - 1] <= key < a[b + k] */ static gsize gtk_tim_sort(gallop_right) (GtkTimSort *self, gpointer key, gpointer base, gsize len, gsize hint) { char *hintp = ELEM (base, hint); gsize ofs = 1; gsize last_ofs = 0; g_assert (len > 0 && hint < len); if (gtk_tim_sort_compare (self, key, hintp) < 0) { /* Gallop left until a[hint - ofs] <= key < a[hint - last_ofs] */ gsize max_ofs = hint + 1; gsize tmp; while (ofs < max_ofs && gtk_tim_sort_compare (self, key, ELEM (hintp, -ofs)) < 0) { last_ofs = ofs; ofs = (ofs << 1) + 1; /* no need to check for overflow */ } if (ofs > max_ofs) ofs = max_ofs; /* Make offsets relative to base */ tmp = last_ofs; last_ofs = hint + 1 - ofs; ofs = hint - tmp; } else /* a[hint] <= key */ /* Gallop right until a[hint + last_ofs] <= key < a[hint + ofs] */ { gsize max_ofs = len - hint; while (ofs < max_ofs && gtk_tim_sort_compare (self, key, ELEM (hintp, ofs)) >= 0) { last_ofs = ofs; ofs = (ofs << 1) + 1; /* no need to check for overflow */ } if (ofs > max_ofs) ofs = max_ofs; /* Make offsets relative to base */ last_ofs += hint + 1; ofs += hint; } g_assert (last_ofs <= ofs && ofs <= len); /* * Now a[last_ofs - 1] <= key < a[ofs], so key belongs somewhere to * the right of last_ofs but no farther right than ofs. Do a binary * search, with invariant a[last_ofs - 1] <= key < a[ofs]. */ while (last_ofs < ofs) { /* gsize m = last_ofs + ((ofs - last_ofs) >> 1); */ gsize m = (last_ofs & ofs) + ((last_ofs ^ ofs) >> 1); if (gtk_tim_sort_compare (self, key, ELEM (base, m)) < 0) ofs = m; /* key < a[m] */ else last_ofs = m + 1; /* a[m] <= key */ } g_assert (last_ofs == ofs); /* so a[ofs - 1] <= key < a[ofs] */ return ofs; } /* * Merges two adjacent runs in place, in a stable fashion. The first * element of the first run must be greater than the first element of the * second run (a[base1] > a[base2]), and the last element of the first run * (a[base1 + len1-1]) must be greater than all elements of the second run. * * For performance, this method should be called only when len1 <= len2; * its twin, merge_hi should be called if len1 >= len2. (Either method * may be called if len1 == len2.) * * @param base1 first element in first run to be merged * @param len1 length of first run to be merged (must be > 0) * @param base2 first element in second run to be merged * (must be aBase + aLen) * @param len2 length of second run to be merged (must be > 0) */ static void gtk_tim_sort(merge_lo) (GtkTimSort *self, gpointer base1, gsize len1, gpointer base2, gsize len2) { /* Copy first run into temp array */ gpointer tmp = gtk_tim_sort_ensure_capacity (self, len1); char *cursor1; char *cursor2; char *dest; gsize min_gallop; g_assert (len1 > 0 && len2 > 0 && ELEM (base1, len1) == base2); /* System.arraycopy(a, base1, tmp, 0, len1); */ memcpy (tmp, base1, LEN (len1)); /* POP: can't overlap */ cursor1 = tmp; /* Indexes into tmp array */ cursor2 = base2; /* Indexes int a */ dest = base1; /* Indexes int a */ /* Move first element of second run and deal with degenerate cases */ /* a[dest++] = a[cursor2++]; */ ASSIGN (dest, cursor2); dest = INCPTR (dest); cursor2 = INCPTR (cursor2); if (--len2 == 0) { memcpy (dest, cursor1, LEN (len1)); /* POP: can't overlap */ return; } if (len1 == 1) { memmove (dest, cursor2, LEN (len2)); /* POP: overlaps */ /* a[dest + len2] = tmp[cursor1]; // Last elt of run 1 to end of merge */ ASSIGN (ELEM (dest, len2), cursor1); return; } /* Use local variable for performance */ min_gallop = self->min_gallop; while (TRUE) { gsize count1 = 0; /* Number of times in a row that first run won */ gsize count2 = 0; /* Number of times in a row that second run won */ /* * Do the straightforward thing until (if ever) one run starts * winning consistently. */ do { g_assert (len1 > 1 && len2 > 0); if (gtk_tim_sort_compare (self, cursor2, cursor1) < 0) { ASSIGN (dest, cursor2); dest = INCPTR (dest); cursor2 = INCPTR (cursor2); count2++; count1 = 0; if (--len2 == 0) goto outer; if (count2 >= min_gallop) break; } else { ASSIGN (dest, cursor1); dest = INCPTR (dest); cursor1 = INCPTR (cursor1); count1++; count2 = 0; if (--len1 == 1) goto outer; if (count1 >= min_gallop) break; } } while (TRUE); /* (count1 | count2) < min_gallop); */ /* * One run is winning so consistently that galloping may be a * huge win. So try that, and continue galloping until (if ever) * neither run appears to be winning consistently anymore. */ do { g_assert (len1 > 1 && len2 > 0); count1 = gtk_tim_sort(gallop_right) (self, cursor2, cursor1, len1, 0); if (count1 != 0) { memcpy (dest, cursor1, LEN (count1)); /* POP: can't overlap */ dest = ELEM (dest, count1); cursor1 = ELEM (cursor1, count1); len1 -= count1; if (len1 <= 1) /* len1 == 1 || len1 == 0 */ goto outer; } ASSIGN (dest, cursor2); dest = INCPTR (dest); cursor2 = INCPTR (cursor2); if (--len2 == 0) goto outer; count2 = gtk_tim_sort(gallop_left) (self, cursor1, cursor2, len2, 0); if (count2 != 0) { memmove (dest, cursor2, LEN (count2)); /* POP: might overlap */ dest = ELEM (dest, count2); cursor2 = ELEM (cursor2, count2); len2 -= count2; if (len2 == 0) goto outer; } ASSIGN (dest, cursor1); dest = INCPTR (dest); cursor1 = INCPTR (cursor1); if (--len1 == 1) goto outer; if (min_gallop > 0) min_gallop--; } while (count1 >= MIN_GALLOP || count2 >= MIN_GALLOP); min_gallop += 2; /* Penalize for leaving gallop mode */ } /* End of "outer" loop */ outer: self->min_gallop = min_gallop < 1 ? 1 : min_gallop; /* Write back to field */ if (len1 == 1) { g_assert (len2 > 0); memmove (dest, cursor2, LEN (len2)); /* POP: might overlap */ ASSIGN (ELEM (dest, len2), cursor1); /* Last elt of run 1 to end of merge */ } else if (len1 == 0) { g_critical ("Comparison method violates its general contract"); return; } else { g_assert (len2 == 0); g_assert (len1 > 1); memcpy (dest, cursor1, LEN (len1)); /* POP: can't overlap */ } } /* * Like merge_lo, except that this method should be called only if * len1 >= len2; merge_lo should be called if len1 <= len2. (Either method * may be called if len1 == len2.) * * @param base1 first element in first run to be merged * @param len1 length of first run to be merged (must be > 0) * @param base2 first element in second run to be merged * (must be aBase + aLen) * @param len2 length of second run to be merged (must be > 0) */ static void gtk_tim_sort(merge_hi) (GtkTimSort *self, gpointer base1, gsize len1, gpointer base2, gsize len2) { /* Copy second run into temp array */ gpointer tmp = gtk_tim_sort_ensure_capacity (self, len2); char *cursor1; /* Indexes into a */ char *cursor2; /* Indexes into tmp array */ char *dest; /* Indexes into a */ gsize min_gallop; g_assert (len1 > 0 && len2 > 0 && ELEM (base1, len1) == base2); memcpy (tmp, base2, LEN (len2)); /* POP: can't overlap */ cursor1 = ELEM (base1, len1 - 1); /* Indexes into a */ cursor2 = ELEM (tmp, len2 - 1); /* Indexes into tmp array */ dest = ELEM (base2, len2 - 1); /* Indexes into a */ /* Move last element of first run and deal with degenerate cases */ /* a[dest--] = a[cursor1--]; */ ASSIGN (dest, cursor1); dest = DECPTR (dest); cursor1 = DECPTR (cursor1); if (--len1 == 0) { memcpy (ELEM (dest, -(len2 - 1)), tmp, LEN (len2)); /* POP: can't overlap */ return; } if (len2 == 1) { dest = ELEM (dest, -len1); cursor1 = ELEM (cursor1, -len1); memmove (ELEM (dest, 1), ELEM (cursor1, 1), LEN (len1)); /* POP: overlaps */ /* a[dest] = tmp[cursor2]; */ ASSIGN (dest, cursor2); return; } /* Use local variable for performance */ min_gallop = self->min_gallop; while (TRUE) { gsize count1 = 0; /* Number of times in a row that first run won */ gsize count2 = 0; /* Number of times in a row that second run won */ /* * Do the straightforward thing until (if ever) one run * appears to win consistently. */ do { g_assert (len1 > 0 && len2 > 1); if (gtk_tim_sort_compare (self, cursor2, cursor1) < 0) { ASSIGN (dest, cursor1); dest = DECPTR (dest); cursor1 = DECPTR (cursor1); count1++; count2 = 0; if (--len1 == 0) goto outer; } else { ASSIGN (dest, cursor2); dest = DECPTR (dest); cursor2 = DECPTR (cursor2); count2++; count1 = 0; if (--len2 == 1) goto outer; } } while ((count1 | count2) < min_gallop); /* * One run is winning so consistently that galloping may be a * huge win. So try that, and continue galloping until (if ever) * neither run appears to be winning consistently anymore. */ do { g_assert (len1 > 0 && len2 > 1); count1 = len1 - gtk_tim_sort(gallop_right) (self, cursor2, base1, len1, len1 - 1); if (count1 != 0) { dest = ELEM (dest, -count1); cursor1 = ELEM (cursor1, -count1); len1 -= count1; memmove (INCPTR (dest), INCPTR (cursor1), LEN (count1)); /* POP: might overlap */ if (len1 == 0) goto outer; } ASSIGN (dest, cursor2); dest = DECPTR (dest); cursor2 = DECPTR (cursor2); if (--len2 == 1) goto outer; count2 = len2 - gtk_tim_sort(gallop_left) (self, cursor1, tmp, len2, len2 - 1); if (count2 != 0) { dest = ELEM (dest, -count2); cursor2 = ELEM (cursor2, -count2); len2 -= count2; memcpy (INCPTR (dest), INCPTR (cursor2), LEN (count2)); /* POP: can't overlap */ if (len2 <= 1) /* len2 == 1 || len2 == 0 */ goto outer; } ASSIGN (dest, cursor1); dest = DECPTR (dest); cursor1 = DECPTR (cursor1); if (--len1 == 0) goto outer; if (min_gallop > 0) min_gallop--; } while (count1 >= MIN_GALLOP || count2 >= MIN_GALLOP); min_gallop += 2; /* Penalize for leaving gallop mode */ } /* End of "outer" loop */ outer: self->min_gallop = min_gallop < 1 ? 1 : min_gallop; /* Write back to field */ if (len2 == 1) { g_assert (len1 > 0); dest = ELEM (dest, -len1); cursor1 = ELEM (cursor1, -len1); memmove (INCPTR (dest), INCPTR (cursor1), LEN (len1)); /* POP: might overlap */ /* a[dest] = tmp[cursor2]; // Move first elt of run2 to front of merge */ ASSIGN (dest, cursor2); } else if (len2 == 0) { g_critical ("Comparison method violates its general contract"); return; } else { g_assert (len1 == 0); g_assert (len2 > 0); memcpy (ELEM (dest, -(len2 - 1)), tmp, LEN (len2)); /* POP: can't overlap */ } } /* * Merges the two runs at stack indices i and i+1. Run i must be * the penultimate or antepenultimate run on the stack. In other words, * i must be equal to pending_runs-2 or pending_runs-3. * * @param i stack index of the first of the two runs to merge */ static void gtk_tim_sort(merge_at) (GtkTimSort *self, gsize i, GtkTimSortRun *out_change) { gpointer base1 = self->run[i].base; gsize len1 = self->run[i].len; gpointer base2 = self->run[i + 1].base; gsize len2 = self->run[i + 1].len; gsize k; g_assert (self->pending_runs >= 2); g_assert (i == self->pending_runs - 2 || i == self->pending_runs - 3); g_assert (len1 > 0 && len2 > 0); g_assert (ELEM (base1, len1) == base2); /* * Find where the first element of run2 goes in run1. Prior elements * in run1 can be ignored (because they're already in place). */ k = gtk_tim_sort(gallop_right) (self, base2, base1, len1, 0); base1 = ELEM (base1, k); len1 -= k; if (len1 == 0) { gtk_tim_sort_set_change (out_change, NULL, 0); goto done; } /* * Find where the last element of run1 goes in run2. Subsequent elements * in run2 can be ignored (because they're already in place). */ len2 = gtk_tim_sort(gallop_left) (self, ELEM (base1, len1 - 1), base2, len2, len2 - 1); if (len2 == 0) { gtk_tim_sort_set_change (out_change, NULL, 0); goto done; } /* Merge remaining runs, using tmp array with min(len1, len2) elements */ if (len1 <= len2) { if (len1 > self->max_merge_size) { base1 = ELEM (self->run[i].base, self->run[i].len - self->max_merge_size); gtk_tim_sort(merge_lo) (self, base1, self->max_merge_size, base2, len2); gtk_tim_sort_set_change (out_change, base1, self->max_merge_size + len2); self->run[i].len -= self->max_merge_size; self->run[i + 1].base = ELEM (self->run[i + 1].base, - self->max_merge_size); self->run[i + 1].len += self->max_merge_size; g_assert (ELEM (self->run[i].base, self->run[i].len) == self->run[i + 1].base); return; } else { gtk_tim_sort(merge_lo) (self, base1, len1, base2, len2); gtk_tim_sort_set_change (out_change, base1, len1 + len2); } } else { if (len2 > self->max_merge_size) { gtk_tim_sort(merge_hi) (self, base1, len1, base2, self->max_merge_size); gtk_tim_sort_set_change (out_change, base1, len1 + self->max_merge_size); self->run[i].len += self->max_merge_size; self->run[i + 1].base = ELEM (self->run[i + 1].base, self->max_merge_size); self->run[i + 1].len -= self->max_merge_size; g_assert (ELEM (self->run[i].base, self->run[i].len) == self->run[i + 1].base); return; } else { gtk_tim_sort(merge_hi) (self, base1, len1, base2, len2); gtk_tim_sort_set_change (out_change, base1, len1 + len2); } } done: /* * Record the length of the combined runs; if i is the 3rd-last * run now, also slide over the last run (which isn't involved * in this merge). The current run (i+1) goes away in any case. */ self->run[i].len += self->run[i + 1].len; if (i == self->pending_runs - 3) self->run[i + 1] = self->run[i + 2]; self->pending_runs--; } /* * Examines the stack of runs waiting to be merged and merges adjacent runs * until the stack invariants are reestablished: * * 1. run_len[i - 3] > run_len[i - 2] + run_len[i - 1] * 2. run_len[i - 2] > run_len[i - 1] * * This method is called each time a new run is pushed onto the stack, * so the invariants are guaranteed to hold for i < pending_runs upon * entry to the method. * * POP: * Modified according to http://envisage-project.eu/wp-content/uploads/2015/02/sorting.pdf * * and * * https://bugs.openjdk.java.net/browse/JDK-8072909 (suggestion 2) * */ static gboolean gtk_tim_sort(merge_collapse) (GtkTimSort *self, GtkTimSortRun *out_change) { GtkTimSortRun *run = self->run; gsize n; if (self->pending_runs <= 1) return FALSE; n = self->pending_runs - 2; if ((n > 0 && run[n - 1].len <= run[n].len + run[n + 1].len) || (n > 1 && run[n - 2].len <= run[n].len + run[n - 1].len)) { if (run[n - 1].len < run[n + 1].len) n--; } else if (run[n].len > run[n + 1].len) { return FALSE; /* Invariant is established */ } gtk_tim_sort(merge_at) (self, n, out_change); return TRUE; } /* * Merges all runs on the stack until only one remains. This method is * called once, to complete the sort. */ static gboolean gtk_tim_sort(merge_force_collapse) (GtkTimSort *self, GtkTimSortRun *out_change) { gsize n; if (self->pending_runs <= 1) return FALSE; n = self->pending_runs - 2; if (n > 0 && self->run[n - 1].len < self->run[n + 1].len) n--; gtk_tim_sort(merge_at) (self, n, out_change); return TRUE; } static gboolean gtk_tim_sort(step) (GtkTimSort *self, GtkTimSortRun *out_change) { g_assert (self); if (gtk_tim_sort(merge_collapse) (self, out_change)) return TRUE; if (gtk_tim_sort(merge_append) (self, out_change)) return TRUE; if (gtk_tim_sort(merge_force_collapse) (self, out_change)) return TRUE; return FALSE; } #undef DEFINE_TEMP #undef ASSIGN #undef INCPTR #undef DECPTR #undef ELEM #undef LEN #undef CONCAT #undef MAKE_STR #undef gtk_tim_sort #undef WIDTH #undef NAME