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Generalize overflowLeaf to also handle overflows in branch nodes.
This doesn't quite work yet because the calls to treeDecrement and treeIncrement operate at the leaf level, not on pathNode(Level) as required. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@120068 91177308-0d34-0410-b5e6-96231b3b80d8
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@ -1020,6 +1020,7 @@ splitRoot(unsigned Position) {
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rootBranch().subtree(n) = Node[n];
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}
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rootSize = Nodes;
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++height;
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return NewOffset;
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}
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@ -1489,8 +1490,8 @@ class IntervalMap<KeyT, ValT, N, Traits>::iterator : public const_iterator {
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void setNodeSize(unsigned Level, unsigned Size);
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void setNodeStop(unsigned Level, KeyT Stop);
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void insertNode(unsigned Level, IntervalMapImpl::NodeRef Node, KeyT Stop);
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void overflowLeaf();
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bool insertNode(unsigned Level, IntervalMapImpl::NodeRef Node, KeyT Stop);
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template <typename NodeT> bool overflow(unsigned Level);
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void treeInsert(KeyT a, KeyT b, ValT y);
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public:
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@ -1528,19 +1529,26 @@ iterator::setNodeStop(unsigned Level, KeyT Stop) {
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/// insertNode - insert a node before the current path at level.
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/// Leave the current path pointing at the new node.
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/// @param Level path index of the node to be inserted.
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/// @param Node The node to be inserted.
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/// @param Stop The last index in the new node.
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/// @return True if the tree height was increased.
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template <typename KeyT, typename ValT, unsigned N, typename Traits>
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void IntervalMap<KeyT, ValT, N, Traits>::
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bool IntervalMap<KeyT, ValT, N, Traits>::
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iterator::insertNode(unsigned Level, IntervalMapImpl::NodeRef Node, KeyT Stop) {
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bool SplitRoot = false;
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if (!Level) {
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// Insert into the root branch node.
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IntervalMap &IM = *this->map;
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if (IM.rootSize < RootBranch::Capacity) {
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IM.rootBranch().insert(this->rootOffset, IM.rootSize, Node, Stop);
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++IM.rootSize;
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return;
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return SplitRoot;
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}
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// We need to split the root while keeping our position.
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SplitRoot = true;
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IdxPair Offset = IM.splitRoot(this->rootOffset);
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this->rootOffset = Offset.first;
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this->path.insert(this->path.begin(),std::make_pair(
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@ -1555,11 +1563,16 @@ iterator::insertNode(unsigned Level, IntervalMapImpl::NodeRef Node, KeyT Stop) {
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}
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// Insert into the branch node at level-1.
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if (this->pathNode(Level-1).size() == Branch::Capacity) {
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assert(!SplitRoot && "Cannot overflow after splitting the root");
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SplitRoot = overflow<Branch>(Level - 1);
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Level += SplitRoot;
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}
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IntervalMapImpl::NodeRef NR = this->pathNode(Level-1);
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unsigned Offset = this->pathOffset(Level-1);
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assert(NR.size() < Branch::Capacity && "Branch overflow");
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NR.get<Branch>().insert(Offset, NR.size(), Node, Stop);
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setNodeSize(Level - 1, NR.size() + 1);
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return SplitRoot;
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}
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// insert
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@ -1603,7 +1616,7 @@ iterator::treeInsert(KeyT a, KeyT b, ValT y) {
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return;
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}
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// Leaf node has no space.
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overflowLeaf();
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overflow<Leaf>(this->map->height - 1);
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IP = this->treeLeaf().insertFrom(this->treeLeafOffset(),
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this->treeLeafSize(), a, b, y);
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this->treeLeafOffset() = IP.first;
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@ -1614,52 +1627,57 @@ iterator::treeInsert(KeyT a, KeyT b, ValT y) {
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// FIXME: Handle cross-node coalescing.
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}
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// overflowLeaf - Distribute entries of the current leaf node evenly among
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// its siblings and ensure that the current node is not full.
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// This may require allocating a new node.
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/// overflow - Distribute entries of the current node evenly among
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/// its siblings and ensure that the current node is not full.
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/// This may require allocating a new node.
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/// @param NodeT The type of node at Level (Leaf or Branch).
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/// @param Level path index of the overflowing node.
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/// @return True when the tree height was changed.
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template <typename KeyT, typename ValT, unsigned N, typename Traits>
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void IntervalMap<KeyT, ValT, N, Traits>::
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iterator::overflowLeaf() {
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template <typename NodeT>
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bool IntervalMap<KeyT, ValT, N, Traits>::
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iterator::overflow(unsigned Level) {
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using namespace IntervalMapImpl;
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unsigned CurSize[4];
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Leaf *Node[4];
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NodeT *Node[4];
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unsigned Nodes = 0;
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unsigned Elements = 0;
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unsigned Offset = this->treeLeafOffset();
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unsigned Offset = this->pathOffset(Level);
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// Do we have a left sibling?
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NodeRef LeftSib = this->leftSibling(this->map->height-1);
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NodeRef LeftSib = this->leftSibling(Level);
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if (LeftSib) {
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Offset += Elements = CurSize[Nodes] = LeftSib.size();
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Node[Nodes++] = &LeftSib.get<Leaf>();
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Node[Nodes++] = &LeftSib.get<NodeT>();
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}
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// Current leaf node.
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Elements += CurSize[Nodes] = this->treeLeafSize();
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Node[Nodes++] = &this->treeLeaf();
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// Current node.
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NodeRef CurNode = this->pathNode(Level);
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Elements += CurSize[Nodes] = CurNode.size();
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Node[Nodes++] = &CurNode.get<NodeT>();
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// Do we have a right sibling?
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NodeRef RightSib = this->rightSibling(this->map->height-1);
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NodeRef RightSib = this->rightSibling(Level);
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if (RightSib) {
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Offset += Elements = CurSize[Nodes] = RightSib.size();
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Node[Nodes++] = &RightSib.get<Leaf>();
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Node[Nodes++] = &RightSib.get<NodeT>();
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}
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// Do we need to allocate a new node?
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unsigned NewNode = 0;
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if (Elements + 1 > Nodes * Leaf::Capacity) {
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if (Elements + 1 > Nodes * NodeT::Capacity) {
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// Insert NewNode at the penultimate position, or after a single node.
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NewNode = Nodes == 1 ? 1 : Nodes - 1;
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CurSize[Nodes] = CurSize[NewNode];
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Node[Nodes] = Node[NewNode];
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CurSize[NewNode] = 0;
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Node[NewNode] = this->map->allocLeaf();
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Node[NewNode] = new(this->map->allocator.template Allocate<NodeT>())NodeT();
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++Nodes;
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}
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// Compute the new element distribution.
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unsigned NewSize[4];
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IdxPair NewOffset = distribute(Nodes, Elements, Leaf::Capacity,
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IdxPair NewOffset = distribute(Nodes, Elements, NodeT::Capacity,
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CurSize, NewSize, Offset, true);
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// Move current location to the leftmost node.
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@ -1702,14 +1720,16 @@ iterator::overflowLeaf() {
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#endif
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// Elements have been rearranged, now update node sizes and stops.
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bool SplitRoot = false;
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unsigned Pos = 0;
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for (;;) {
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KeyT Stop = Node[Pos]->stop(NewSize[Pos]-1);
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if (NewNode && Pos == NewNode)
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insertNode(this->map->height - 1, NodeRef(Node[Pos], NewSize[Pos]), Stop);
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else {
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setNodeSize(this->map->height - 1, NewSize[Pos]);
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setNodeStop(this->map->height - 1, Stop);
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if (NewNode && Pos == NewNode) {
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SplitRoot = insertNode(Level, NodeRef(Node[Pos], NewSize[Pos]), Stop);
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Level += SplitRoot;
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} else {
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setNodeSize(Level, NewSize[Pos]);
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setNodeStop(Level, Stop);
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}
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if (Pos + 1 == Nodes)
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break;
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@ -1722,7 +1742,8 @@ iterator::overflowLeaf() {
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this->treeDecrement();
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--Pos;
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}
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this->treeLeafOffset() = NewOffset.second;
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this->pathOffset(Level) = NewOffset.second;
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return SplitRoot;
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}
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} // namespace llvm
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