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84c169c23a
This moves the SuffixTree test used in the Machine Outliner and moves it into Support for use in other outliners elsewhere in the compilation pipeline. Differential Revision: https://reviews.llvm.org/D80586
211 lines
7.2 KiB
C++
211 lines
7.2 KiB
C++
//===- llvm/Support/SuffixTree.cpp - Implement Suffix Tree ------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file implements the Suffix Tree class.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Support/SuffixTree.h"
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#include "llvm/Support/Allocator.h"
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#include <vector>
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using namespace llvm;
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SuffixTree::SuffixTree(const std::vector<unsigned> &Str) : Str(Str) {
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Root = insertInternalNode(nullptr, EmptyIdx, EmptyIdx, 0);
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Active.Node = Root;
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// Keep track of the number of suffixes we have to add of the current
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// prefix.
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unsigned SuffixesToAdd = 0;
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// Construct the suffix tree iteratively on each prefix of the string.
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// PfxEndIdx is the end index of the current prefix.
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// End is one past the last element in the string.
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for (unsigned PfxEndIdx = 0, End = Str.size(); PfxEndIdx < End; PfxEndIdx++) {
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SuffixesToAdd++;
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LeafEndIdx = PfxEndIdx; // Extend each of the leaves.
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SuffixesToAdd = extend(PfxEndIdx, SuffixesToAdd);
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}
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// Set the suffix indices of each leaf.
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assert(Root && "Root node can't be nullptr!");
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setSuffixIndices();
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}
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SuffixTreeNode *SuffixTree::insertLeaf(SuffixTreeNode &Parent,
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unsigned StartIdx, unsigned Edge) {
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assert(StartIdx <= LeafEndIdx && "String can't start after it ends!");
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SuffixTreeNode *N = new (NodeAllocator.Allocate())
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SuffixTreeNode(StartIdx, &LeafEndIdx, nullptr);
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Parent.Children[Edge] = N;
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return N;
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}
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SuffixTreeNode *SuffixTree::insertInternalNode(SuffixTreeNode *Parent,
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unsigned StartIdx,
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unsigned EndIdx, unsigned Edge) {
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assert(StartIdx <= EndIdx && "String can't start after it ends!");
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assert(!(!Parent && StartIdx != EmptyIdx) &&
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"Non-root internal nodes must have parents!");
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unsigned *E = new (InternalEndIdxAllocator) unsigned(EndIdx);
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SuffixTreeNode *N =
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new (NodeAllocator.Allocate()) SuffixTreeNode(StartIdx, E, Root);
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if (Parent)
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Parent->Children[Edge] = N;
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return N;
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}
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void SuffixTree::setSuffixIndices() {
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// List of nodes we need to visit along with the current length of the
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// string.
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std::vector<std::pair<SuffixTreeNode *, unsigned>> ToVisit;
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// Current node being visited.
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SuffixTreeNode *CurrNode = Root;
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// Sum of the lengths of the nodes down the path to the current one.
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unsigned CurrNodeLen = 0;
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ToVisit.push_back({CurrNode, CurrNodeLen});
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while (!ToVisit.empty()) {
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std::tie(CurrNode, CurrNodeLen) = ToVisit.back();
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ToVisit.pop_back();
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CurrNode->ConcatLen = CurrNodeLen;
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for (auto &ChildPair : CurrNode->Children) {
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assert(ChildPair.second && "Node had a null child!");
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ToVisit.push_back(
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{ChildPair.second, CurrNodeLen + ChildPair.second->size()});
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}
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// No children, so we are at the end of the string.
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if (CurrNode->Children.size() == 0 && !CurrNode->isRoot())
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CurrNode->SuffixIdx = Str.size() - CurrNodeLen;
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}
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}
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unsigned SuffixTree::extend(unsigned EndIdx, unsigned SuffixesToAdd) {
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SuffixTreeNode *NeedsLink = nullptr;
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while (SuffixesToAdd > 0) {
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// Are we waiting to add anything other than just the last character?
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if (Active.Len == 0) {
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// If not, then say the active index is the end index.
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Active.Idx = EndIdx;
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}
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assert(Active.Idx <= EndIdx && "Start index can't be after end index!");
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// The first character in the current substring we're looking at.
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unsigned FirstChar = Str[Active.Idx];
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// Have we inserted anything starting with FirstChar at the current node?
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if (Active.Node->Children.count(FirstChar) == 0) {
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// If not, then we can just insert a leaf and move to the next step.
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insertLeaf(*Active.Node, EndIdx, FirstChar);
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// The active node is an internal node, and we visited it, so it must
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// need a link if it doesn't have one.
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if (NeedsLink) {
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NeedsLink->Link = Active.Node;
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NeedsLink = nullptr;
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}
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} else {
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// There's a match with FirstChar, so look for the point in the tree to
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// insert a new node.
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SuffixTreeNode *NextNode = Active.Node->Children[FirstChar];
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unsigned SubstringLen = NextNode->size();
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// Is the current suffix we're trying to insert longer than the size of
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// the child we want to move to?
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if (Active.Len >= SubstringLen) {
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// If yes, then consume the characters we've seen and move to the next
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// node.
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Active.Idx += SubstringLen;
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Active.Len -= SubstringLen;
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Active.Node = NextNode;
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continue;
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}
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// Otherwise, the suffix we're trying to insert must be contained in the
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// next node we want to move to.
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unsigned LastChar = Str[EndIdx];
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// Is the string we're trying to insert a substring of the next node?
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if (Str[NextNode->StartIdx + Active.Len] == LastChar) {
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// If yes, then we're done for this step. Remember our insertion point
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// and move to the next end index. At this point, we have an implicit
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// suffix tree.
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if (NeedsLink && !Active.Node->isRoot()) {
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NeedsLink->Link = Active.Node;
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NeedsLink = nullptr;
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}
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Active.Len++;
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break;
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}
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// The string we're trying to insert isn't a substring of the next node,
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// but matches up to a point. Split the node.
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//
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// For example, say we ended our search at a node n and we're trying to
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// insert ABD. Then we'll create a new node s for AB, reduce n to just
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// representing C, and insert a new leaf node l to represent d. This
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// allows us to ensure that if n was a leaf, it remains a leaf.
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//
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// | ABC ---split---> | AB
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// n s
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// C / \ D
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// n l
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// The node s from the diagram
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SuffixTreeNode *SplitNode =
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insertInternalNode(Active.Node, NextNode->StartIdx,
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NextNode->StartIdx + Active.Len - 1, FirstChar);
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// Insert the new node representing the new substring into the tree as
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// a child of the split node. This is the node l from the diagram.
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insertLeaf(*SplitNode, EndIdx, LastChar);
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// Make the old node a child of the split node and update its start
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// index. This is the node n from the diagram.
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NextNode->StartIdx += Active.Len;
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SplitNode->Children[Str[NextNode->StartIdx]] = NextNode;
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// SplitNode is an internal node, update the suffix link.
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if (NeedsLink)
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NeedsLink->Link = SplitNode;
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NeedsLink = SplitNode;
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}
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// We've added something new to the tree, so there's one less suffix to
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// add.
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SuffixesToAdd--;
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if (Active.Node->isRoot()) {
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if (Active.Len > 0) {
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Active.Len--;
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Active.Idx = EndIdx - SuffixesToAdd + 1;
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}
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} else {
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// Start the next phase at the next smallest suffix.
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Active.Node = Active.Node->Link;
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}
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}
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return SuffixesToAdd;
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}
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