857 lines
30 KiB
C
857 lines
30 KiB
C
/*
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* Elastic Binary Trees - generic macros and structures.
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* Version 6.0.6
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* (C) 2002-2011 - Willy Tarreau <w@1wt.eu>
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*
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Lesser General Public
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* License as published by the Free Software Foundation, version 2.1
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* exclusively.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General Public
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* License along with this library; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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*/
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/*
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General idea:
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-------------
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In a radix binary tree, we may have up to 2N-1 nodes for N keys if all of
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them are leaves. If we find a way to differentiate intermediate nodes (later
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called "nodes") and final nodes (later called "leaves"), and we associate
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them by two, it is possible to build sort of a self-contained radix tree with
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intermediate nodes always present. It will not be as cheap as the ultree for
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optimal cases as shown below, but the optimal case almost never happens :
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Eg, to store 8, 10, 12, 13, 14 :
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ultree this theorical tree
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8 8
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/ \ / \
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10 12 10 12
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/ \ / \
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13 14 12 14
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/ \
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12 13
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Note that on real-world tests (with a scheduler), is was verified that the
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case with data on an intermediate node never happens. This is because the
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data spectrum is too large for such coincidences to happen. It would require
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for instance that a task has its expiration time at an exact second, with
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other tasks sharing that second. This is too rare to try to optimize for it.
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What is interesting is that the node will only be added above the leaf when
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necessary, which implies that it will always remain somewhere above it. So
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both the leaf and the node can share the exact value of the leaf, because
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when going down the node, the bit mask will be applied to comparisons. So we
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are tempted to have one single key shared between the node and the leaf.
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The bit only serves the nodes, and the dups only serve the leaves. So we can
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put a lot of information in common. This results in one single entity with
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two branch pointers and two parent pointers, one for the node part, and one
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for the leaf part :
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node's leaf's
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parent parent
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[node] [leaf]
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/ \
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left right
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branch branch
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The node may very well refer to its leaf counterpart in one of its branches,
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indicating that its own leaf is just below it :
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node's
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parent
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[node]
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/ \
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left [leaf]
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branch
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Adding keys in such a tree simply consists in inserting nodes between
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other nodes and/or leaves :
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[root]
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[node2]
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/ \
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[leaf1] [node3]
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/ \
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[leaf2] [leaf3]
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On this diagram, we notice that [node2] and [leaf2] have been pulled away
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from each other due to the insertion of [node3], just as if there would be
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an elastic between both parts. This elastic-like behaviour gave its name to
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the tree : "Elastic Binary Tree", or "EBtree". The entity which associates a
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node part and a leaf part will be called an "EB node".
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We also notice on the diagram that there is a root entity required to attach
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the tree. It only contains two branches and there is nothing above it. This
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is an "EB root". Some will note that [leaf1] has no [node1]. One property of
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the EBtree is that all nodes have their branches filled, and that if a node
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has only one branch, it does not need to exist. Here, [leaf1] was added
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below [root] and did not need any node.
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An EB node contains :
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- a pointer to the node's parent (node_p)
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- a pointer to the leaf's parent (leaf_p)
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- two branches pointing to lower nodes or leaves (branches)
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- a bit position (bit)
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- an optional key.
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The key here is optional because it's used only during insertion, in order
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to classify the nodes. Nothing else in the tree structure requires knowledge
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of the key. This makes it possible to write type-agnostic primitives for
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everything, and type-specific insertion primitives. This has led to consider
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two types of EB nodes. The type-agnostic ones will serve as a header for the
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other ones, and will simply be called "struct eb_node". The other ones will
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have their type indicated in the structure name. Eg: "struct eb32_node" for
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nodes carrying 32 bit keys.
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We will also node that the two branches in a node serve exactly the same
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purpose as an EB root. For this reason, a "struct eb_root" will be used as
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well inside the struct eb_node. In order to ease pointer manipulation and
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ROOT detection when walking upwards, all the pointers inside an eb_node will
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point to the eb_root part of the referenced EB nodes, relying on the same
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principle as the linked lists in Linux.
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Another important point to note, is that when walking inside a tree, it is
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very convenient to know where a node is attached in its parent, and what
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type of branch it has below it (leaf or node). In order to simplify the
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operations and to speed up the processing, it was decided in this specific
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implementation to use the lowest bit from the pointer to designate the side
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of the upper pointers (left/right) and the type of a branch (leaf/node).
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This practise is not mandatory by design, but an implementation-specific
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optimisation permitted on all platforms on which data must be aligned. All
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known 32 bit platforms align their integers and pointers to 32 bits, leaving
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the two lower bits unused. So, we say that the pointers are "tagged". And
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since they designate pointers to root parts, we simply call them
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"tagged root pointers", or "eb_troot" in the code.
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Duplicate keys are stored in a special manner. When inserting a key, if
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the same one is found, then an incremental binary tree is built at this
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place from these keys. This ensures that no special case has to be written
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to handle duplicates when walking through the tree or when deleting entries.
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It also guarantees that duplicates will be walked in the exact same order
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they were inserted. This is very important when trying to achieve fair
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processing distribution for instance.
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Algorithmic complexity can be derived from 3 variables :
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- the number of possible different keys in the tree : P
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- the number of entries in the tree : N
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- the number of duplicates for one key : D
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Note that this tree is deliberately NOT balanced. For this reason, the worst
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case may happen with a small tree (eg: 32 distinct keys of one bit). BUT,
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the operations required to manage such data are so much cheap that they make
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it worth using it even under such conditions. For instance, a balanced tree
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may require only 6 levels to store those 32 keys when this tree will
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require 32. But if per-level operations are 5 times cheaper, it wins.
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Minimal, Maximal and Average times are specified in number of operations.
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Minimal is given for best condition, Maximal for worst condition, and the
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average is reported for a tree containing random keys. An operation
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generally consists in jumping from one node to the other.
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Complexity :
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- lookup : min=1, max=log(P), avg=log(N)
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- insertion from root : min=1, max=log(P), avg=log(N)
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- insertion of dups : min=1, max=log(D), avg=log(D)/2 after lookup
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- deletion : min=1, max=1, avg=1
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- prev/next : min=1, max=log(P), avg=2 :
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N/2 nodes need 1 hop => 1*N/2
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N/4 nodes need 2 hops => 2*N/4
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N/8 nodes need 3 hops => 3*N/8
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...
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N/x nodes need log(x) hops => log2(x)*N/x
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Total cost for all N nodes : sum[i=1..N](log2(i)*N/i) = N*sum[i=1..N](log2(i)/i)
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Average cost across N nodes = total / N = sum[i=1..N](log2(i)/i) = 2
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This design is currently limited to only two branches per node. Most of the
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tree descent algorithm would be compatible with more branches (eg: 4, to cut
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the height in half), but this would probably require more complex operations
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and the deletion algorithm would be problematic.
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Useful properties :
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- a node is always added above the leaf it is tied to, and never can get
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below nor in another branch. This implies that leaves directly attached
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to the root do not use their node part, which is indicated by a NULL
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value in node_p. This also enhances the cache efficiency when walking
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down the tree, because when the leaf is reached, its node part will
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already have been visited (unless it's the first leaf in the tree).
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- pointers to lower nodes or leaves are stored in "branch" pointers. Only
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the root node may have a NULL in either branch, it is not possible for
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other branches. Since the nodes are attached to the left branch of the
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root, it is not possible to see a NULL left branch when walking up a
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tree. Thus, an empty tree is immediately identified by a NULL left
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branch at the root. Conversely, the one and only way to identify the
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root node is to check that it right branch is NULL. Note that the
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NULL pointer may have a few low-order bits set.
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- a node connected to its own leaf will have branch[0|1] pointing to
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itself, and leaf_p pointing to itself.
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- a node can never have node_p pointing to itself.
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- a node is linked in a tree if and only if it has a non-null leaf_p.
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- a node can never have both branches equal, except for the root which can
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have them both NULL.
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- deletion only applies to leaves. When a leaf is deleted, its parent must
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be released too (unless it's the root), and its sibling must attach to
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the grand-parent, replacing the parent. Also, when a leaf is deleted,
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the node tied to this leaf will be removed and must be released too. If
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this node is different from the leaf's parent, the freshly released
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leaf's parent will be used to replace the node which must go. A released
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node will never be used anymore, so there's no point in tracking it.
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- the bit index in a node indicates the bit position in the key which is
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represented by the branches. That means that a node with (bit == 0) is
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just above two leaves. Negative bit values are used to build a duplicate
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tree. The first node above two identical leaves gets (bit == -1). This
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value logarithmically decreases as the duplicate tree grows. During
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duplicate insertion, a node is inserted above the highest bit value (the
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lowest absolute value) in the tree during the right-sided walk. If bit
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-1 is not encountered (highest < -1), we insert above last leaf.
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Otherwise, we insert above the node with the highest value which was not
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equal to the one of its parent + 1.
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- the "eb_next" primitive walks from left to right, which means from lower
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to higher keys. It returns duplicates in the order they were inserted.
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The "eb_first" primitive returns the left-most entry.
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- the "eb_prev" primitive walks from right to left, which means from
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higher to lower keys. It returns duplicates in the opposite order they
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were inserted. The "eb_last" primitive returns the right-most entry.
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- a tree which has 1 in the lower bit of its root's right branch is a
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tree with unique nodes. This means that when a node is inserted with
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a key which already exists will not be inserted, and the previous
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entry will be returned.
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*/
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#ifndef _EBTREE_H
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#define _EBTREE_H
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#include <stdlib.h>
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#include "compiler.h"
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static inline int flsnz8_generic(unsigned int x)
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{
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int ret = 0;
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if (x >> 4) { x >>= 4; ret += 4; }
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return ret + ((0xFFFFAA50U >> (x << 1)) & 3) + 1;
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}
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/* Note: we never need to run fls on null keys, so we can optimize the fls
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* function by removing a conditional jump.
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*/
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#if defined(__i386__) || defined(__x86_64__)
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/* this code is similar on 32 and 64 bit */
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static inline int flsnz(int x)
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{
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int r;
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__asm__("bsrl %1,%0\n"
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: "=r" (r) : "rm" (x));
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return r+1;
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}
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static inline int flsnz8(unsigned char x)
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{
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int r;
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__asm__("movzbl %%al, %%eax\n"
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"bsrl %%eax,%0\n"
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: "=r" (r) : "a" (x));
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return r+1;
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}
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#else
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// returns 1 to 32 for 1<<0 to 1<<31. Undefined for 0.
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#define flsnz(___a) ({ \
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register int ___x, ___bits = 0; \
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___x = (___a); \
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if (___x & 0xffff0000) { ___x &= 0xffff0000; ___bits += 16;} \
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if (___x & 0xff00ff00) { ___x &= 0xff00ff00; ___bits += 8;} \
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if (___x & 0xf0f0f0f0) { ___x &= 0xf0f0f0f0; ___bits += 4;} \
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if (___x & 0xcccccccc) { ___x &= 0xcccccccc; ___bits += 2;} \
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if (___x & 0xaaaaaaaa) { ___x &= 0xaaaaaaaa; ___bits += 1;} \
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___bits + 1; \
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})
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static inline int flsnz8(unsigned int x)
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{
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return flsnz8_generic(x);
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}
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#endif
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static inline int fls64(unsigned long long x)
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{
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unsigned int h;
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unsigned int bits = 32;
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h = x >> 32;
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if (!h) {
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h = x;
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bits = 0;
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}
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return flsnz(h) + bits;
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}
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#define fls_auto(x) ((sizeof(x) > 4) ? fls64(x) : flsnz(x))
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/* Linux-like "container_of". It returns a pointer to the structure of type
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* <type> which has its member <name> stored at address <ptr>.
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*/
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#ifndef container_of
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#define container_of(ptr, type, name) ((type *)(((void *)(ptr)) - ((long)&((type *)0)->name)))
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#endif
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/* Number of bits per node, and number of leaves per node */
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#define EB_NODE_BITS 1
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#define EB_NODE_BRANCHES (1 << EB_NODE_BITS)
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#define EB_NODE_BRANCH_MASK (EB_NODE_BRANCHES - 1)
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/* Be careful not to tweak those values. The walking code is optimized for NULL
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* detection on the assumption that the following values are intact.
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*/
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#define EB_LEFT 0
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#define EB_RGHT 1
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#define EB_LEAF 0
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#define EB_NODE 1
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/* Tags to set in root->b[EB_RGHT] :
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* - EB_NORMAL is a normal tree which stores duplicate keys.
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* - EB_UNIQUE is a tree which stores unique keys.
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*/
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#define EB_NORMAL 0
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#define EB_UNIQUE 1
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/* This is the same as an eb_node pointer, except that the lower bit embeds
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* a tag. See eb_dotag()/eb_untag()/eb_gettag(). This tag has two meanings :
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* - 0=left, 1=right to designate the parent's branch for leaf_p/node_p
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* - 0=link, 1=leaf to designate the branch's type for branch[]
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*/
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typedef void eb_troot_t;
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/* The eb_root connects the node which contains it, to two nodes below it, one
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* of which may be the same node. At the top of the tree, we use an eb_root
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* too, which always has its right branch NULL (+/1 low-order bits).
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*/
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struct eb_root {
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eb_troot_t *b[EB_NODE_BRANCHES]; /* left and right branches */
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};
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/* The eb_node contains the two parts, one for the leaf, which always exists,
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* and one for the node, which remains unused in the very first node inserted
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* into the tree. This structure is 20 bytes per node on 32-bit machines. Do
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* not change the order, benchmarks have shown that it's optimal this way.
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*/
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struct eb_node {
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struct eb_root branches; /* branches, must be at the beginning */
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eb_troot_t *node_p; /* link node's parent */
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eb_troot_t *leaf_p; /* leaf node's parent */
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short int bit; /* link's bit position. */
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short unsigned int pfx; /* data prefix length, always related to leaf */
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};
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/* Return the structure of type <type> whose member <member> points to <ptr> */
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#define eb_entry(ptr, type, member) container_of(ptr, type, member)
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/* The root of a tree is an eb_root initialized with both pointers NULL.
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* During its life, only the left pointer will change. The right one will
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* always remain NULL, which is the way we detect it.
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*/
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#define EB_ROOT \
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(struct eb_root) { \
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.b = {[0] = NULL, [1] = NULL }, \
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}
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#define EB_ROOT_UNIQUE \
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(struct eb_root) { \
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.b = {[0] = NULL, [1] = (void *)1 }, \
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}
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#define EB_TREE_HEAD(name) \
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struct eb_root name = EB_ROOT
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/***************************************\
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* Private functions. Not for end-user *
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\***************************************/
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/* Converts a root pointer to its equivalent eb_troot_t pointer,
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* ready to be stored in ->branch[], leaf_p or node_p. NULL is not
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* conserved. To be used with EB_LEAF, EB_NODE, EB_LEFT or EB_RGHT in <tag>.
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*/
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static inline eb_troot_t *eb_dotag(const struct eb_root *root, const int tag)
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{
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return (eb_troot_t *)((void *)root + tag);
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}
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/* Converts an eb_troot_t pointer pointer to its equivalent eb_root pointer,
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* for use with pointers from ->branch[], leaf_p or node_p. NULL is conserved
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* as long as the tree is not corrupted. To be used with EB_LEAF, EB_NODE,
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* EB_LEFT or EB_RGHT in <tag>.
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*/
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static inline struct eb_root *eb_untag(const eb_troot_t *troot, const int tag)
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{
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return (struct eb_root *)((void *)troot - tag);
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}
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/* returns the tag associated with an eb_troot_t pointer */
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static inline int eb_gettag(eb_troot_t *troot)
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{
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return (unsigned long)troot & 1;
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}
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/* Converts a root pointer to its equivalent eb_troot_t pointer and clears the
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* tag, no matter what its value was.
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*/
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static inline struct eb_root *eb_clrtag(const eb_troot_t *troot)
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{
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return (struct eb_root *)((unsigned long)troot & ~1UL);
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}
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/* Returns a pointer to the eb_node holding <root> */
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static inline struct eb_node *eb_root_to_node(struct eb_root *root)
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{
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return container_of(root, struct eb_node, branches);
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}
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/* Walks down starting at root pointer <start>, and always walking on side
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* <side>. It either returns the node hosting the first leaf on that side,
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* or NULL if no leaf is found. <start> may either be NULL or a branch pointer.
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* The pointer to the leaf (or NULL) is returned.
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*/
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static inline struct eb_node *eb_walk_down(eb_troot_t *start, unsigned int side)
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{
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/* A NULL pointer on an empty tree root will be returned as-is */
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while (eb_gettag(start) == EB_NODE)
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start = (eb_untag(start, EB_NODE))->b[side];
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/* NULL is left untouched (root==eb_node, EB_LEAF==0) */
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return eb_root_to_node(eb_untag(start, EB_LEAF));
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}
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/* This function is used to build a tree of duplicates by adding a new node to
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* a subtree of at least 2 entries. It will probably never be needed inlined,
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* and it is not for end-user.
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*/
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static forceinline struct eb_node *
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__eb_insert_dup(struct eb_node *sub, struct eb_node *new)
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{
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struct eb_node *head = sub;
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eb_troot_t *new_left = eb_dotag(&new->branches, EB_LEFT);
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eb_troot_t *new_rght = eb_dotag(&new->branches, EB_RGHT);
|
|
eb_troot_t *new_leaf = eb_dotag(&new->branches, EB_LEAF);
|
|
|
|
/* first, identify the deepest hole on the right branch */
|
|
while (eb_gettag(head->branches.b[EB_RGHT]) != EB_LEAF) {
|
|
struct eb_node *last = head;
|
|
head = container_of(eb_untag(head->branches.b[EB_RGHT], EB_NODE),
|
|
struct eb_node, branches);
|
|
if (head->bit > last->bit + 1)
|
|
sub = head; /* there's a hole here */
|
|
}
|
|
|
|
/* Here we have a leaf attached to (head)->b[EB_RGHT] */
|
|
if (head->bit < -1) {
|
|
/* A hole exists just before the leaf, we insert there */
|
|
new->bit = -1;
|
|
sub = container_of(eb_untag(head->branches.b[EB_RGHT], EB_LEAF),
|
|
struct eb_node, branches);
|
|
head->branches.b[EB_RGHT] = eb_dotag(&new->branches, EB_NODE);
|
|
|
|
new->node_p = sub->leaf_p;
|
|
new->leaf_p = new_rght;
|
|
sub->leaf_p = new_left;
|
|
new->branches.b[EB_LEFT] = eb_dotag(&sub->branches, EB_LEAF);
|
|
new->branches.b[EB_RGHT] = new_leaf;
|
|
return new;
|
|
} else {
|
|
int side;
|
|
/* No hole was found before a leaf. We have to insert above
|
|
* <sub>. Note that we cannot be certain that <sub> is attached
|
|
* to the right of its parent, as this is only true if <sub>
|
|
* is inside the dup tree, not at the head.
|
|
*/
|
|
new->bit = sub->bit - 1; /* install at the lowest level */
|
|
side = eb_gettag(sub->node_p);
|
|
head = container_of(eb_untag(sub->node_p, side), struct eb_node, branches);
|
|
head->branches.b[side] = eb_dotag(&new->branches, EB_NODE);
|
|
|
|
new->node_p = sub->node_p;
|
|
new->leaf_p = new_rght;
|
|
sub->node_p = new_left;
|
|
new->branches.b[EB_LEFT] = eb_dotag(&sub->branches, EB_NODE);
|
|
new->branches.b[EB_RGHT] = new_leaf;
|
|
return new;
|
|
}
|
|
}
|
|
|
|
|
|
/**************************************\
|
|
* Public functions, for the end-user *
|
|
\**************************************/
|
|
|
|
/* Return non-zero if the tree is empty, otherwise zero */
|
|
static inline int eb_is_empty(struct eb_root *root)
|
|
{
|
|
return !root->b[EB_LEFT];
|
|
}
|
|
|
|
/* Return the first leaf in the tree starting at <root>, or NULL if none */
|
|
static inline struct eb_node *eb_first(struct eb_root *root)
|
|
{
|
|
return eb_walk_down(root->b[0], EB_LEFT);
|
|
}
|
|
|
|
/* Return the last leaf in the tree starting at <root>, or NULL if none */
|
|
static inline struct eb_node *eb_last(struct eb_root *root)
|
|
{
|
|
return eb_walk_down(root->b[0], EB_RGHT);
|
|
}
|
|
|
|
/* Return previous leaf node before an existing leaf node, or NULL if none. */
|
|
static inline struct eb_node *eb_prev(struct eb_node *node)
|
|
{
|
|
eb_troot_t *t = node->leaf_p;
|
|
|
|
while (eb_gettag(t) == EB_LEFT) {
|
|
/* Walking up from left branch. We must ensure that we never
|
|
* walk beyond root.
|
|
*/
|
|
if (unlikely(eb_clrtag((eb_untag(t, EB_LEFT))->b[EB_RGHT]) == NULL))
|
|
return NULL;
|
|
t = (eb_root_to_node(eb_untag(t, EB_LEFT)))->node_p;
|
|
}
|
|
/* Note that <t> cannot be NULL at this stage */
|
|
t = (eb_untag(t, EB_RGHT))->b[EB_LEFT];
|
|
return eb_walk_down(t, EB_RGHT);
|
|
}
|
|
|
|
/* Return next leaf node after an existing leaf node, or NULL if none. */
|
|
static inline struct eb_node *eb_next(struct eb_node *node)
|
|
{
|
|
eb_troot_t *t = node->leaf_p;
|
|
|
|
while (eb_gettag(t) != EB_LEFT)
|
|
/* Walking up from right branch, so we cannot be below root */
|
|
t = (eb_root_to_node(eb_untag(t, EB_RGHT)))->node_p;
|
|
|
|
/* Note that <t> cannot be NULL at this stage */
|
|
t = (eb_untag(t, EB_LEFT))->b[EB_RGHT];
|
|
if (eb_clrtag(t) == NULL)
|
|
return NULL;
|
|
return eb_walk_down(t, EB_LEFT);
|
|
}
|
|
|
|
/* Return previous leaf node before an existing leaf node, skipping duplicates,
|
|
* or NULL if none. */
|
|
static inline struct eb_node *eb_prev_unique(struct eb_node *node)
|
|
{
|
|
eb_troot_t *t = node->leaf_p;
|
|
|
|
while (1) {
|
|
if (eb_gettag(t) != EB_LEFT) {
|
|
node = eb_root_to_node(eb_untag(t, EB_RGHT));
|
|
/* if we're right and not in duplicates, stop here */
|
|
if (node->bit >= 0)
|
|
break;
|
|
t = node->node_p;
|
|
}
|
|
else {
|
|
/* Walking up from left branch. We must ensure that we never
|
|
* walk beyond root.
|
|
*/
|
|
if (unlikely(eb_clrtag((eb_untag(t, EB_LEFT))->b[EB_RGHT]) == NULL))
|
|
return NULL;
|
|
t = (eb_root_to_node(eb_untag(t, EB_LEFT)))->node_p;
|
|
}
|
|
}
|
|
/* Note that <t> cannot be NULL at this stage */
|
|
t = (eb_untag(t, EB_RGHT))->b[EB_LEFT];
|
|
return eb_walk_down(t, EB_RGHT);
|
|
}
|
|
|
|
/* Return next leaf node after an existing leaf node, skipping duplicates, or
|
|
* NULL if none.
|
|
*/
|
|
static inline struct eb_node *eb_next_unique(struct eb_node *node)
|
|
{
|
|
eb_troot_t *t = node->leaf_p;
|
|
|
|
while (1) {
|
|
if (eb_gettag(t) == EB_LEFT) {
|
|
if (unlikely(eb_clrtag((eb_untag(t, EB_LEFT))->b[EB_RGHT]) == NULL))
|
|
return NULL; /* we reached root */
|
|
node = eb_root_to_node(eb_untag(t, EB_LEFT));
|
|
/* if we're left and not in duplicates, stop here */
|
|
if (node->bit >= 0)
|
|
break;
|
|
t = node->node_p;
|
|
}
|
|
else {
|
|
/* Walking up from right branch, so we cannot be below root */
|
|
t = (eb_root_to_node(eb_untag(t, EB_RGHT)))->node_p;
|
|
}
|
|
}
|
|
|
|
/* Note that <t> cannot be NULL at this stage */
|
|
t = (eb_untag(t, EB_LEFT))->b[EB_RGHT];
|
|
if (eb_clrtag(t) == NULL)
|
|
return NULL;
|
|
return eb_walk_down(t, EB_LEFT);
|
|
}
|
|
|
|
|
|
/* Removes a leaf node from the tree if it was still in it. Marks the node
|
|
* as unlinked.
|
|
*/
|
|
static forceinline void __eb_delete(struct eb_node *node)
|
|
{
|
|
__label__ delete_unlink;
|
|
unsigned int pside, gpside, sibtype;
|
|
struct eb_node *parent;
|
|
struct eb_root *gparent;
|
|
|
|
if (!node->leaf_p)
|
|
return;
|
|
|
|
/* we need the parent, our side, and the grand parent */
|
|
pside = eb_gettag(node->leaf_p);
|
|
parent = eb_root_to_node(eb_untag(node->leaf_p, pside));
|
|
|
|
/* We likely have to release the parent link, unless it's the root,
|
|
* in which case we only set our branch to NULL. Note that we can
|
|
* only be attached to the root by its left branch.
|
|
*/
|
|
|
|
if (eb_clrtag(parent->branches.b[EB_RGHT]) == NULL) {
|
|
/* we're just below the root, it's trivial. */
|
|
parent->branches.b[EB_LEFT] = NULL;
|
|
goto delete_unlink;
|
|
}
|
|
|
|
/* To release our parent, we have to identify our sibling, and reparent
|
|
* it directly to/from the grand parent. Note that the sibling can
|
|
* either be a link or a leaf.
|
|
*/
|
|
|
|
gpside = eb_gettag(parent->node_p);
|
|
gparent = eb_untag(parent->node_p, gpside);
|
|
|
|
gparent->b[gpside] = parent->branches.b[!pside];
|
|
sibtype = eb_gettag(gparent->b[gpside]);
|
|
|
|
if (sibtype == EB_LEAF) {
|
|
eb_root_to_node(eb_untag(gparent->b[gpside], EB_LEAF))->leaf_p =
|
|
eb_dotag(gparent, gpside);
|
|
} else {
|
|
eb_root_to_node(eb_untag(gparent->b[gpside], EB_NODE))->node_p =
|
|
eb_dotag(gparent, gpside);
|
|
}
|
|
/* Mark the parent unused. Note that we do not check if the parent is
|
|
* our own node, but that's not a problem because if it is, it will be
|
|
* marked unused at the same time, which we'll use below to know we can
|
|
* safely remove it.
|
|
*/
|
|
parent->node_p = NULL;
|
|
|
|
/* The parent node has been detached, and is currently unused. It may
|
|
* belong to another node, so we cannot remove it that way. Also, our
|
|
* own node part might still be used. so we can use this spare node
|
|
* to replace ours if needed.
|
|
*/
|
|
|
|
/* If our link part is unused, we can safely exit now */
|
|
if (!node->node_p)
|
|
goto delete_unlink;
|
|
|
|
/* From now on, <node> and <parent> are necessarily different, and the
|
|
* <node>'s node part is in use. By definition, <parent> is at least
|
|
* below <node>, so keeping its key for the bit string is OK.
|
|
*/
|
|
|
|
parent->node_p = node->node_p;
|
|
parent->branches = node->branches;
|
|
parent->bit = node->bit;
|
|
|
|
/* We must now update the new node's parent... */
|
|
gpside = eb_gettag(parent->node_p);
|
|
gparent = eb_untag(parent->node_p, gpside);
|
|
gparent->b[gpside] = eb_dotag(&parent->branches, EB_NODE);
|
|
|
|
/* ... and its branches */
|
|
for (pside = 0; pside <= 1; pside++) {
|
|
if (eb_gettag(parent->branches.b[pside]) == EB_NODE) {
|
|
eb_root_to_node(eb_untag(parent->branches.b[pside], EB_NODE))->node_p =
|
|
eb_dotag(&parent->branches, pside);
|
|
} else {
|
|
eb_root_to_node(eb_untag(parent->branches.b[pside], EB_LEAF))->leaf_p =
|
|
eb_dotag(&parent->branches, pside);
|
|
}
|
|
}
|
|
delete_unlink:
|
|
/* Now the node has been completely unlinked */
|
|
node->leaf_p = NULL;
|
|
return; /* tree is not empty yet */
|
|
}
|
|
|
|
/* Compare blocks <a> and <b> byte-to-byte, from bit <ignore> to bit <len-1>.
|
|
* Return the number of equal bits between strings, assuming that the first
|
|
* <ignore> bits are already identical. It is possible to return slightly more
|
|
* than <len> bits if <len> does not stop on a byte boundary and we find exact
|
|
* bytes. Note that parts or all of <ignore> bits may be rechecked. It is only
|
|
* passed here as a hint to speed up the check.
|
|
*/
|
|
static forceinline int equal_bits(const unsigned char *a,
|
|
const unsigned char *b,
|
|
int ignore, int len)
|
|
{
|
|
for (ignore >>= 3, a += ignore, b += ignore, ignore <<= 3;
|
|
ignore < len; ) {
|
|
unsigned char c;
|
|
|
|
a++; b++;
|
|
ignore += 8;
|
|
c = b[-1] ^ a[-1];
|
|
|
|
if (c) {
|
|
/* OK now we know that old and new differ at byte <ptr> and that <c> holds
|
|
* the bit differences. We have to find what bit is differing and report
|
|
* it as the number of identical bits. Note that low bit numbers are
|
|
* assigned to high positions in the byte, as we compare them as strings.
|
|
*/
|
|
ignore -= flsnz8(c);
|
|
break;
|
|
}
|
|
}
|
|
return ignore;
|
|
}
|
|
|
|
/* check that the two blocks <a> and <b> are equal on <len> bits. If it is known
|
|
* they already are on some bytes, this number of equal bytes to be skipped may
|
|
* be passed in <skip>. It returns 0 if they match, otherwise non-zero.
|
|
*/
|
|
static forceinline int check_bits(const unsigned char *a,
|
|
const unsigned char *b,
|
|
int skip,
|
|
int len)
|
|
{
|
|
int bit, ret;
|
|
|
|
/* This uncommon construction gives the best performance on x86 because
|
|
* it makes heavy use multiple-index addressing and parallel instructions,
|
|
* and it prevents gcc from reordering the loop since it is already
|
|
* properly oriented. Tested to be fine with 2.95 to 4.2.
|
|
*/
|
|
bit = ~len + (skip << 3) + 9; // = (skip << 3) + (8 - len)
|
|
ret = a[skip] ^ b[skip];
|
|
if (unlikely(bit >= 0))
|
|
return ret >> bit;
|
|
while (1) {
|
|
skip++;
|
|
if (ret)
|
|
return ret;
|
|
ret = a[skip] ^ b[skip];
|
|
bit += 8;
|
|
if (bit >= 0)
|
|
return ret >> bit;
|
|
}
|
|
}
|
|
|
|
|
|
/* Compare strings <a> and <b> byte-to-byte, from bit <ignore> to the last 0.
|
|
* Return the number of equal bits between strings, assuming that the first
|
|
* <ignore> bits are already identical. Note that parts or all of <ignore> bits
|
|
* may be rechecked. It is only passed here as a hint to speed up the check.
|
|
* The caller is responsible for not passing an <ignore> value larger than any
|
|
* of the two strings. However, referencing any bit from the trailing zero is
|
|
* permitted. Equal strings are reported as a negative number of bits, which
|
|
* indicates the end was reached.
|
|
*/
|
|
static forceinline int string_equal_bits(const unsigned char *a,
|
|
const unsigned char *b,
|
|
int ignore)
|
|
{
|
|
int beg;
|
|
unsigned char c;
|
|
|
|
beg = ignore >> 3;
|
|
|
|
/* skip known and identical bits. We stop at the first different byte
|
|
* or at the first zero we encounter on either side.
|
|
*/
|
|
while (1) {
|
|
unsigned char d;
|
|
|
|
c = a[beg];
|
|
d = b[beg];
|
|
beg++;
|
|
|
|
c ^= d;
|
|
if (c)
|
|
break;
|
|
if (!d)
|
|
return -1;
|
|
}
|
|
/* OK now we know that a and b differ at byte <beg>, or that both are zero.
|
|
* We have to find what bit is differing and report it as the number of
|
|
* identical bits. Note that low bit numbers are assigned to high positions
|
|
* in the byte, as we compare them as strings.
|
|
*/
|
|
return (beg << 3) - flsnz8(c);
|
|
}
|
|
|
|
static forceinline int cmp_bits(const unsigned char *a, const unsigned char *b, unsigned int pos)
|
|
{
|
|
unsigned int ofs;
|
|
unsigned char bit_a, bit_b;
|
|
|
|
ofs = pos >> 3;
|
|
pos = ~pos & 7;
|
|
|
|
bit_a = (a[ofs] >> pos) & 1;
|
|
bit_b = (b[ofs] >> pos) & 1;
|
|
|
|
return bit_a - bit_b; /* -1: a<b; 0: a=b; 1: a>b */
|
|
}
|
|
|
|
static forceinline int get_bit(const unsigned char *a, unsigned int pos)
|
|
{
|
|
unsigned int ofs;
|
|
|
|
ofs = pos >> 3;
|
|
pos = ~pos & 7;
|
|
return (a[ofs] >> pos) & 1;
|
|
}
|
|
|
|
/* These functions are declared in ebtree.c */
|
|
void eb_delete(struct eb_node *node);
|
|
REGPRM1 struct eb_node *eb_insert_dup(struct eb_node *sub, struct eb_node *new);
|
|
|
|
#endif /* _EB_TREE_H */
|
|
|
|
/*
|
|
* Local variables:
|
|
* c-indent-level: 8
|
|
* c-basic-offset: 8
|
|
* End:
|
|
*/
|