// SPDX-License-Identifier: GPL-2.0-only #include #include #include #include #define START(node) ((node)->start) #define LAST(node) ((node)->last) INTERVAL_TREE_DEFINE(struct interval_tree_node, rb, unsigned long, __subtree_last, START, LAST,, interval_tree) EXPORT_SYMBOL_GPL(interval_tree_insert); EXPORT_SYMBOL_GPL(interval_tree_remove); EXPORT_SYMBOL_GPL(interval_tree_iter_first); EXPORT_SYMBOL_GPL(interval_tree_iter_next); #ifdef CONFIG_INTERVAL_TREE_SPAN_ITER /* * Roll nodes[1] into nodes[0] by advancing nodes[1] to the end of a contiguous * span of nodes. This makes nodes[0]->last the end of that contiguous used span * indexes that started at the original nodes[1]->start. nodes[1] is now the * first node starting the next used span. A hole span is between nodes[0]->last * and nodes[1]->start. nodes[1] must be !NULL. */ static void interval_tree_span_iter_next_gap(struct interval_tree_span_iter *state) { struct interval_tree_node *cur = state->nodes[1]; state->nodes[0] = cur; do { if (cur->last > state->nodes[0]->last) state->nodes[0] = cur; cur = interval_tree_iter_next(cur, state->first_index, state->last_index); } while (cur && (state->nodes[0]->last >= cur->start || state->nodes[0]->last + 1 == cur->start)); state->nodes[1] = cur; } void interval_tree_span_iter_first(struct interval_tree_span_iter *iter, struct rb_root_cached *itree, unsigned long first_index, unsigned long last_index) { iter->first_index = first_index; iter->last_index = last_index; iter->nodes[0] = NULL; iter->nodes[1] = interval_tree_iter_first(itree, first_index, last_index); if (!iter->nodes[1]) { /* No nodes intersect the span, whole span is hole */ iter->start_hole = first_index; iter->last_hole = last_index; iter->is_hole = 1; return; } if (iter->nodes[1]->start > first_index) { /* Leading hole on first iteration */ iter->start_hole = first_index; iter->last_hole = iter->nodes[1]->start - 1; iter->is_hole = 1; interval_tree_span_iter_next_gap(iter); return; } /* Starting inside a used */ iter->start_used = first_index; iter->is_hole = 0; interval_tree_span_iter_next_gap(iter); iter->last_used = iter->nodes[0]->last; if (iter->last_used >= last_index) { iter->last_used = last_index; iter->nodes[0] = NULL; iter->nodes[1] = NULL; } } EXPORT_SYMBOL_GPL(interval_tree_span_iter_first); void interval_tree_span_iter_next(struct interval_tree_span_iter *iter) { if (!iter->nodes[0] && !iter->nodes[1]) { iter->is_hole = -1; return; } if (iter->is_hole) { iter->start_used = iter->last_hole + 1; iter->last_used = iter->nodes[0]->last; if (iter->last_used >= iter->last_index) { iter->last_used = iter->last_index; iter->nodes[0] = NULL; iter->nodes[1] = NULL; } iter->is_hole = 0; return; } if (!iter->nodes[1]) { /* Trailing hole */ iter->start_hole = iter->nodes[0]->last + 1; iter->last_hole = iter->last_index; iter->nodes[0] = NULL; iter->is_hole = 1; return; } /* must have both nodes[0] and [1], interior hole */ iter->start_hole = iter->nodes[0]->last + 1; iter->last_hole = iter->nodes[1]->start - 1; iter->is_hole = 1; interval_tree_span_iter_next_gap(iter); } EXPORT_SYMBOL_GPL(interval_tree_span_iter_next); /* * Advance the iterator index to a specific position. The returned used/hole is * updated to start at new_index. This is faster than calling * interval_tree_span_iter_first() as it can avoid full searches in several * cases where the iterator is already set. */ void interval_tree_span_iter_advance(struct interval_tree_span_iter *iter, struct rb_root_cached *itree, unsigned long new_index) { if (iter->is_hole == -1) return; iter->first_index = new_index; if (new_index > iter->last_index) { iter->is_hole = -1; return; } /* Rely on the union aliasing hole/used */ if (iter->start_hole <= new_index && new_index <= iter->last_hole) { iter->start_hole = new_index; return; } if (new_index == iter->last_hole + 1) interval_tree_span_iter_next(iter); else interval_tree_span_iter_first(iter, itree, new_index, iter->last_index); } EXPORT_SYMBOL_GPL(interval_tree_span_iter_advance); #endif