Documentation/prio_tree.txt - linux - Git at Google

 The prio_tree.c code indexes vmas using 3 different indexes:
 	* heap_index  = vm_pgoff + vm_size_in_pages : end_vm_pgoff
 	* radix_index = vm_pgoff : start_vm_pgoff
 	* size_index = vm_size_in_pages

 A regular radix-priority-search-tree indexes vmas using only heap_index and
 radix_index. The conditions for indexing are:
 	* ->heap_index >= ->left->heap_index &&
 		->heap_index >= ->right->heap_index
 	* if (->heap_index == ->left->heap_index)
 		then ->radix_index < ->left->radix_index;
 	* if (->heap_index == ->right->heap_index)
 		then ->radix_index < ->right->radix_index;
 	* nodes are hashed to left or right subtree using radix_index
 	  similar to a pure binary radix tree.

 A regular radix-priority-search-tree helps to store and query
 intervals (vmas). However, a regular radix-priority-search-tree is only
 suitable for storing vmas with different radix indices (vm_pgoff).

 Therefore, the prio_tree.c extends the regular radix-priority-search-tree
 to handle many vmas with the same vm_pgoff. Such vmas are handled in
 2 different ways: 1) All vmas with the same radix _and_ heap indices are
 linked using vm_set.list, 2) if there are many vmas with the same radix
 index, but different heap indices and if the regular radix-priority-search
 tree cannot index them all, we build an overflow-sub-tree that indexes such
 vmas using heap and size indices instead of heap and radix indices. For
 example, in the figure below some vmas with vm_pgoff = 0 (zero) are
 indexed by regular radix-priority-search-tree whereas others are pushed
 into an overflow-subtree. Note that all vmas in an overflow-sub-tree have
 the same vm_pgoff (radix_index) and if necessary we build different
 overflow-sub-trees to handle each possible radix_index. For example,
 in figure we have 3 overflow-sub-trees corresponding to radix indices
 0, 2, and 4.

 In the final tree the first few (prio_tree_root->index_bits) levels
 are indexed using heap and radix indices whereas the overflow-sub-trees below
 those levels (i.e. levels prio_tree_root->index_bits + 1 and higher) are
 indexed using heap and size indices. In overflow-sub-trees the size_index
 is used for hashing the nodes to appropriate places.

 Now, an example prio_tree:

   vmas are represented [radix_index, size_index, heap_index]
                  i.e., [start_vm_pgoff, vm_size_in_pages, end_vm_pgoff]

 level  prio_tree_root->index_bits = 3
 -----
 												_
   0			 				[0,7,7]					 |
   							/     \					 |
 				      ------------------       ------------			 |     Regular
   				     /					   \			 |  radix priority
   1		 		[1,6,7]					  [4,3,7]		 |   search tree
   				/     \					  /     \		 |
 			 -------       -----			    ------       -----		 |  heap-and-radix
 			/		    \			   /		      \		 |      indexed
   2		    [0,6,6]	 	   [2,5,7]		[5,2,7]		    [6,1,7]	 |
 		    /     \		   /     \		/     \		    /     \	 |
   3		[0,5,5]	[1,5,6]		[2,4,6]	[3,4,7]	    [4,2,6] [5,1,6]	[6,0,6]	[7,0,7]	 |
 		   /			   /		       /		   		_
                   /		          /		      /					_
   4	      [0,4,4]		      [2,3,5]		   [4,1,5]				 |
   		 /			 /		      /					 |
   5	     [0,3,3]		     [2,2,4]		  [4,0,4]				 |  Overflow-sub-trees
   		/			/							 |
   6	    [0,2,2]		    [2,1,3]							 |    heap-and-size
   	       /		       /							 |       indexed
   7	   [0,1,1]		   [2,0,2]							 |
   	      /											 |
   8	  [0,0,0]										 |
   												_

 Note that we use prio_tree_root->index_bits to optimize the height
 of the heap-and-radix indexed tree. Since prio_tree_root->index_bits is
 set according to the maximum end_vm_pgoff mapped, we are sure that all
 bits (in vm_pgoff) above prio_tree_root->index_bits are 0 (zero). Therefore,
 we only use the first prio_tree_root->index_bits as radix_index.
 Whenever index_bits is increased in prio_tree_expand, we shuffle the tree
 to make sure that the first prio_tree_root->index_bits levels of the tree
 is indexed properly using heap and radix indices.

 We do not optimize the height of overflow-sub-trees using index_bits.
 The reason is: there can be many such overflow-sub-trees and all of
 them have to be suffled whenever the index_bits increases. This may involve
 walking the whole prio_tree in prio_tree_insert->prio_tree_expand code
 path which is not desirable. Hence, we do not optimize the height of the
 heap-and-size indexed overflow-sub-trees using prio_tree->index_bits.
 Instead the overflow sub-trees are indexed using full BITS_PER_LONG bits
 of size_index. This may lead to skewed sub-trees because most of the
 higher significant bits of the size_index are likely to be 0 (zero). In
 the example above, all 3 overflow-sub-trees are skewed. This may marginally
 affect the performance. However, processes rarely map many vmas with the
 same start_vm_pgoff but different end_vm_pgoffs. Therefore, we normally
 do not require overflow-sub-trees to index all vmas.

 From the above discussion it is clear that the maximum height of
 a prio_tree can be prio_tree_root->index_bits + BITS_PER_LONG.
 However, in most of the common cases we do not need overflow-sub-trees,
 so the tree height in the common cases will be prio_tree_root->index_bits.

 It is fair to mention here that the prio_tree_root->index_bits
 is increased on demand, however, the index_bits is not decreased when
 vmas are removed from the prio_tree. That's tricky to do. Hence, it's
 left as a home work problem.
	The prio_tree.c code indexes vmas using 3 different indexes:
	* heap_index = vm_pgoff + vm_size_in_pages : end_vm_pgoff
	* radix_index = vm_pgoff : start_vm_pgoff
	* size_index = vm_size_in_pages

	A regular radix-priority-search-tree indexes vmas using only heap_index and
	radix_index. The conditions for indexing are:
	* ->heap_index >= ->left->heap_index &&
	->heap_index >= ->right->heap_index
	* if (->heap_index == ->left->heap_index)
	then ->radix_index < ->left->radix_index;
	* if (->heap_index == ->right->heap_index)
	then ->radix_index < ->right->radix_index;
	* nodes are hashed to left or right subtree using radix_index
	similar to a pure binary radix tree.

	A regular radix-priority-search-tree helps to store and query
	intervals (vmas). However, a regular radix-priority-search-tree is only
	suitable for storing vmas with different radix indices (vm_pgoff).

	Therefore, the prio_tree.c extends the regular radix-priority-search-tree
	to handle many vmas with the same vm_pgoff. Such vmas are handled in
	2 different ways: 1) All vmas with the same radix _and_ heap indices are
	linked using vm_set.list, 2) if there are many vmas with the same radix
	index, but different heap indices and if the regular radix-priority-search
	tree cannot index them all, we build an overflow-sub-tree that indexes such
	vmas using heap and size indices instead of heap and radix indices. For
	example, in the figure below some vmas with vm_pgoff = 0 (zero) are
	indexed by regular radix-priority-search-tree whereas others are pushed
	into an overflow-subtree. Note that all vmas in an overflow-sub-tree have
	the same vm_pgoff (radix_index) and if necessary we build different
	overflow-sub-trees to handle each possible radix_index. For example,
	in figure we have 3 overflow-sub-trees corresponding to radix indices
	0, 2, and 4.

	In the final tree the first few (prio_tree_root->index_bits) levels
	are indexed using heap and radix indices whereas the overflow-sub-trees below
	those levels (i.e. levels prio_tree_root->index_bits + 1 and higher) are
	indexed using heap and size indices. In overflow-sub-trees the size_index
	is used for hashing the nodes to appropriate places.

	Now, an example prio_tree:

	vmas are represented [radix_index, size_index, heap_index]
	i.e., [start_vm_pgoff, vm_size_in_pages, end_vm_pgoff]

	level prio_tree_root->index_bits = 3
	-----
	_
	0 [0,7,7] \|
	/ \ \|
	------------------ ------------ \| Regular
	/ \ \| radix priority
	1 [1,6,7] [4,3,7] \| search tree
	/ \ / \ \|
	------- ----- ------ ----- \| heap-and-radix
	/ \ / \ \| indexed
	2 [0,6,6] [2,5,7] [5,2,7] [6,1,7] \|
	/ \ / \ / \ / \ \|
	3 [0,5,5] [1,5,6] [2,4,6] [3,4,7] [4,2,6] [5,1,6] [6,0,6] [7,0,7] \|
	/ / / _
	/ / / _
	4 [0,4,4] [2,3,5] [4,1,5] \|
	/ / / \|
	5 [0,3,3] [2,2,4] [4,0,4] \| Overflow-sub-trees
	/ / \|
	6 [0,2,2] [2,1,3] \| heap-and-size
	/ / \| indexed
	7 [0,1,1] [2,0,2] \|
	/ \|
	8 [0,0,0] \|
	_

	Note that we use prio_tree_root->index_bits to optimize the height
	of the heap-and-radix indexed tree. Since prio_tree_root->index_bits is
	set according to the maximum end_vm_pgoff mapped, we are sure that all
	bits (in vm_pgoff) above prio_tree_root->index_bits are 0 (zero). Therefore,
	we only use the first prio_tree_root->index_bits as radix_index.
	Whenever index_bits is increased in prio_tree_expand, we shuffle the tree
	to make sure that the first prio_tree_root->index_bits levels of the tree
	is indexed properly using heap and radix indices.

	We do not optimize the height of overflow-sub-trees using index_bits.
	The reason is: there can be many such overflow-sub-trees and all of
	them have to be suffled whenever the index_bits increases. This may involve
	walking the whole prio_tree in prio_tree_insert->prio_tree_expand code
	path which is not desirable. Hence, we do not optimize the height of the
	heap-and-size indexed overflow-sub-trees using prio_tree->index_bits.
	Instead the overflow sub-trees are indexed using full BITS_PER_LONG bits
	of size_index. This may lead to skewed sub-trees because most of the
	higher significant bits of the size_index are likely to be 0 (zero). In
	the example above, all 3 overflow-sub-trees are skewed. This may marginally
	affect the performance. However, processes rarely map many vmas with the
	same start_vm_pgoff but different end_vm_pgoffs. Therefore, we normally
	do not require overflow-sub-trees to index all vmas.

	From the above discussion it is clear that the maximum height of
	a prio_tree can be prio_tree_root->index_bits + BITS_PER_LONG.
	However, in most of the common cases we do not need overflow-sub-trees,
	so the tree height in the common cases will be prio_tree_root->index_bits.

	It is fair to mention here that the prio_tree_root->index_bits
	is increased on demand, however, the index_bits is not decreased when
	vmas are removed from the prio_tree. That's tricky to do. Hence, it's
	left as a home work problem.