Provided by: freebsd-manpages_10.1~RC1-1_all bug


     vm_map_entry_resize_free — vm map free space algorithm


     #include <sys/param.h>
     #include <vm/vm.h>
     #include <vm/vm_map.h>

     vm_map_entry_resize_free(vm_map_t map, vm_map_entry_t entry);


     This manual page describes the vm_map_entry fields used in the VM map free space algorithm,
     how to maintain consistency of these variables, and the vm_map_entry_resize_free() function.

     VM map entries are organized as both a doubly-linked list (prev and next pointers) and as a
     binary search tree (left and right pointers).  The search tree is organized as a Sleator and
     Tarjan splay tree, also known as a “self-adjusting tree”.

           struct vm_map_entry {
                   struct vm_map_entry *prev;
                   struct vm_map_entry *next;
                   struct vm_map_entry *left;
                   struct vm_map_entry *right;
                   vm_offset_t start;
                   vm_offset_t end;
                   vm_offset_t avail_ssize;
                   vm_size_t adj_free;
                   vm_size_t max_free;

     The free space algorithm adds two fields to struct vm_map_entry: adj_free and max_free.  The
     adj_free field is the amount of free address space adjacent to and immediately following
     (higher address) the map entry.  This field is unused in the map header.  Note that adj_free
     depends on the linked list, not the splay tree and that adj_free can be computed as:

           entry->adj_free = (entry->next == &map->header ?
               map->max_offset : entry->next->start) - entry->end;

     The max_free field is the maximum amount of contiguous free space in the entry's subtree.
     Note that max_free depends on the splay tree, not the linked list and that max_free is
     computed by taking the maximum of its own adj_free and the max_free of its left and right
     subtrees.  Again, max_free is unused in the map header.

     These fields allow for an O(log n) implementation of vm_map_findspace().  Using max_free, we
     can immediately test for a sufficiently large free region in an entire subtree.  This makes
     it possible to find a first-fit free region of a given size in one pass down the tree, so
     O(log n) amortized using splay trees.

     When a free region changes size, we must update adj_free and max_free in the preceding map
     entry and propagate max_free up the tree.  This is handled in vm_map_entry_link() and
     vm_map_entry_unlink() for the cases of inserting and deleting an entry.  Note that
     vm_map_entry_link() updates both the new entry and the previous entry, and that
     vm_map_entry_unlink() updates the previous entry.  Also note that max_free is not actually
     propagated up the tree.  Instead, that entry is first splayed to the root and then the
     change is made there.  This is a common technique in splay trees and is also how map entries
     are linked and unlinked into the tree.

     The vm_map_entry_resize_free() function updates the free space variables in the given entry
     and propagates those values up the tree.  This function should be called whenever a map
     entry is resized in-place, that is, by modifying its start or end values.  Note that if you
     change end, then you should resize that entry, but if you change start, then you should
     resize the previous entry.  The map must be locked before calling this function, and again,
     propagating max_free is performed by splaying that entry to the root.


     Consider adding a map entry with vm_map_insert().

           ret = vm_map_insert(map, object, offset, start, end, prot,
               max_prot, cow);

     In this case, no further action is required to maintain consistency of the free space
     variables.  The vm_map_insert() function calls vm_map_entry_link() which updates both the
     new entry and the previous entry.  The same would be true for vm_map_delete() and for
     calling vm_map_entry_link() or vm_map_entry_unlink() directly.

     Now consider resizing an entry in-place without a call to vm_map_entry_link() or

           entry->start = new_start;
           if (entry->prev != &map->header)
                   vm_map_entry_resize_free(map, entry->prev);

     In this case, resetting start changes the amount of free space following the previous entry,
     so we use vm_map_entry_resize_free() to update the previous entry.

     Finally, suppose we change an entry's end address.

           entry->end = new_end;
           vm_map_entry_resize_free(map, entry);

     Here, we call vm_map_entry_resize_free() on the entry itself.


     vm_map(9), vm_map_findspace(9)

     Daniel D. Sleator and Robert E. Tarjan, "Self-Adjusting Binary Search Trees", JACM, vol.
     32(3), pp. 652-686, July 1985.


     Splay trees were added to the VM map in FreeBSD 5.0, and the O(log n) tree-based free space
     algorithm was added in FreeBSD 5.3.


     The tree-based free space algorithm and this manual page were written by Mark W. Krentel