interval-tree: Add a utility to iterate over spans in an interval tree
The span iterator travels over the indexes of the interval_tree, not the nodes, and classifies spans of indexes as either 'used' or 'hole'. 'used' spans are fully covered by nodes in the tree and 'hole' spans have no node intersecting the span. This is done greedily such that spans are maximally sized and every iteration step switches between used/hole. As an example a trivial allocator can be written as: for (interval_tree_span_iter_first(&span, itree, 0, ULONG_MAX); !interval_tree_span_iter_done(&span); interval_tree_span_iter_next(&span)) if (span.is_hole && span.last_hole - span.start_hole >= allocation_size - 1) return span.start_hole; With all the tricky boundary conditions handled by the library code. The following iommufd patches have several algorithms for its overlapping node interval trees that are significantly simplified with this kind of iteration primitive. As it seems generally useful, put it into lib/. Link: https://lore.kernel.org/r/3-v6-a196d26f289e+11787-iommufd_jgg@nvidia.com Reviewed-by: Kevin Tian <kevin.tian@intel.com> Reviewed-by: Eric Auger <eric.auger@redhat.com> Tested-by: Nicolin Chen <nicolinc@nvidia.com> Tested-by: Yi Liu <yi.l.liu@intel.com> Tested-by: Lixiao Yang <lixiao.yang@intel.com> Tested-by: Matthew Rosato <mjrosato@linux.ibm.com> Signed-off-by: Jason Gunthorpe <jgg@nvidia.com>
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Jason Gunthorpe
parent
89395ccedb
commit
5fe937862c
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@ -440,6 +440,7 @@ ForEachMacros:
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- 'inet_lhash2_for_each_icsk'
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- 'inet_lhash2_for_each_icsk_continue'
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- 'inet_lhash2_for_each_icsk_rcu'
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- 'interval_tree_for_each_span'
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- 'intlist__for_each_entry'
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- 'intlist__for_each_entry_safe'
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- 'kcore_copy__for_each_phdr'
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@ -27,4 +27,62 @@ extern struct interval_tree_node *
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interval_tree_iter_next(struct interval_tree_node *node,
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unsigned long start, unsigned long last);
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/**
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* struct interval_tree_span_iter - Find used and unused spans.
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* @start_hole: Start of an interval for a hole when is_hole == 1
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* @last_hole: Inclusive end of an interval for a hole when is_hole == 1
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* @start_used: Start of a used interval when is_hole == 0
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* @last_used: Inclusive end of a used interval when is_hole == 0
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* @is_hole: 0 == used, 1 == is_hole, -1 == done iteration
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*
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* This iterator travels over spans in an interval tree. It does not return
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* nodes but classifies each span as either a hole, where no nodes intersect, or
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* a used, which is fully covered by nodes. Each iteration step toggles between
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* hole and used until the entire range is covered. The returned spans always
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* fully cover the requested range.
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*
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* The iterator is greedy, it always returns the largest hole or used possible,
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* consolidating all consecutive nodes.
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*
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* Use interval_tree_span_iter_done() to detect end of iteration.
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*/
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struct interval_tree_span_iter {
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/* private: not for use by the caller */
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struct interval_tree_node *nodes[2];
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unsigned long first_index;
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unsigned long last_index;
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/* public: */
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union {
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unsigned long start_hole;
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unsigned long start_used;
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};
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union {
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unsigned long last_hole;
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unsigned long last_used;
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};
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int is_hole;
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};
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void interval_tree_span_iter_first(struct interval_tree_span_iter *state,
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struct rb_root_cached *itree,
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unsigned long first_index,
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unsigned long last_index);
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void interval_tree_span_iter_advance(struct interval_tree_span_iter *iter,
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struct rb_root_cached *itree,
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unsigned long new_index);
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void interval_tree_span_iter_next(struct interval_tree_span_iter *state);
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static inline bool
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interval_tree_span_iter_done(struct interval_tree_span_iter *state)
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{
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return state->is_hole == -1;
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}
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#define interval_tree_for_each_span(span, itree, first_index, last_index) \
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for (interval_tree_span_iter_first(span, itree, \
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first_index, last_index); \
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!interval_tree_span_iter_done(span); \
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interval_tree_span_iter_next(span))
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#endif /* _LINUX_INTERVAL_TREE_H */
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@ -479,6 +479,10 @@ config INTERVAL_TREE
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for more information.
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config INTERVAL_TREE_SPAN_ITER
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bool
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depends on INTERVAL_TREE
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config XARRAY_MULTI
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bool
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help
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@ -15,3 +15,135 @@ EXPORT_SYMBOL_GPL(interval_tree_insert);
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EXPORT_SYMBOL_GPL(interval_tree_remove);
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EXPORT_SYMBOL_GPL(interval_tree_iter_first);
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EXPORT_SYMBOL_GPL(interval_tree_iter_next);
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#ifdef CONFIG_INTERVAL_TREE_SPAN_ITER
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/*
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* Roll nodes[1] into nodes[0] by advancing nodes[1] to the end of a contiguous
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* span of nodes. This makes nodes[0]->last the end of that contiguous used span
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* indexes that started at the original nodes[1]->start. nodes[1] is now the
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* first node starting the next used span. A hole span is between nodes[0]->last
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* and nodes[1]->start. nodes[1] must be !NULL.
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*/
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static void
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interval_tree_span_iter_next_gap(struct interval_tree_span_iter *state)
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{
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struct interval_tree_node *cur = state->nodes[1];
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state->nodes[0] = cur;
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do {
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if (cur->last > state->nodes[0]->last)
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state->nodes[0] = cur;
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cur = interval_tree_iter_next(cur, state->first_index,
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state->last_index);
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} while (cur && (state->nodes[0]->last >= cur->start ||
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state->nodes[0]->last + 1 == cur->start));
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state->nodes[1] = cur;
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}
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void interval_tree_span_iter_first(struct interval_tree_span_iter *iter,
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struct rb_root_cached *itree,
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unsigned long first_index,
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unsigned long last_index)
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{
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iter->first_index = first_index;
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iter->last_index = last_index;
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iter->nodes[0] = NULL;
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iter->nodes[1] =
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interval_tree_iter_first(itree, first_index, last_index);
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if (!iter->nodes[1]) {
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/* No nodes intersect the span, whole span is hole */
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iter->start_hole = first_index;
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iter->last_hole = last_index;
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iter->is_hole = 1;
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return;
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}
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if (iter->nodes[1]->start > first_index) {
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/* Leading hole on first iteration */
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iter->start_hole = first_index;
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iter->last_hole = iter->nodes[1]->start - 1;
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iter->is_hole = 1;
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interval_tree_span_iter_next_gap(iter);
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return;
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}
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/* Starting inside a used */
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iter->start_used = first_index;
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iter->is_hole = 0;
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interval_tree_span_iter_next_gap(iter);
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iter->last_used = iter->nodes[0]->last;
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if (iter->last_used >= last_index) {
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iter->last_used = last_index;
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iter->nodes[0] = NULL;
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iter->nodes[1] = NULL;
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}
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}
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EXPORT_SYMBOL_GPL(interval_tree_span_iter_first);
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void interval_tree_span_iter_next(struct interval_tree_span_iter *iter)
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{
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if (!iter->nodes[0] && !iter->nodes[1]) {
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iter->is_hole = -1;
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return;
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}
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if (iter->is_hole) {
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iter->start_used = iter->last_hole + 1;
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iter->last_used = iter->nodes[0]->last;
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if (iter->last_used >= iter->last_index) {
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iter->last_used = iter->last_index;
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iter->nodes[0] = NULL;
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iter->nodes[1] = NULL;
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}
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iter->is_hole = 0;
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return;
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}
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if (!iter->nodes[1]) {
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/* Trailing hole */
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iter->start_hole = iter->nodes[0]->last + 1;
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iter->last_hole = iter->last_index;
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iter->nodes[0] = NULL;
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iter->is_hole = 1;
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return;
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}
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/* must have both nodes[0] and [1], interior hole */
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iter->start_hole = iter->nodes[0]->last + 1;
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iter->last_hole = iter->nodes[1]->start - 1;
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iter->is_hole = 1;
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interval_tree_span_iter_next_gap(iter);
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}
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EXPORT_SYMBOL_GPL(interval_tree_span_iter_next);
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/*
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* Advance the iterator index to a specific position. The returned used/hole is
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* updated to start at new_index. This is faster than calling
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* interval_tree_span_iter_first() as it can avoid full searches in several
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* cases where the iterator is already set.
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*/
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void interval_tree_span_iter_advance(struct interval_tree_span_iter *iter,
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struct rb_root_cached *itree,
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unsigned long new_index)
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{
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if (iter->is_hole == -1)
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return;
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iter->first_index = new_index;
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if (new_index > iter->last_index) {
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iter->is_hole = -1;
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return;
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}
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/* Rely on the union aliasing hole/used */
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if (iter->start_hole <= new_index && new_index <= iter->last_hole) {
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iter->start_hole = new_index;
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return;
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}
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if (new_index == iter->last_hole + 1)
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interval_tree_span_iter_next(iter);
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else
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interval_tree_span_iter_first(iter, itree, new_index,
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iter->last_index);
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}
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EXPORT_SYMBOL_GPL(interval_tree_span_iter_advance);
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#endif
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