[llvm-objdump] - Import the test/Object/X86/no-start-symbol.test test case and rewrit...
[llvm-complete.git] / lib / Support / IntervalMap.cpp
blobf15c7c9403c36f2b6415470a6381250784172b3c
1 //===- lib/Support/IntervalMap.cpp - A sorted interval map ----------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // This file implements the few non-templated functions in IntervalMap.
11 //===----------------------------------------------------------------------===//
13 #include "llvm/ADT/IntervalMap.h"
15 namespace llvm {
16 namespace IntervalMapImpl {
18 void Path::replaceRoot(void *Root, unsigned Size, IdxPair Offsets) {
19 assert(!path.empty() && "Can't replace missing root");
20 path.front() = Entry(Root, Size, Offsets.first);
21 path.insert(path.begin() + 1, Entry(subtree(0), Offsets.second));
24 NodeRef Path::getLeftSibling(unsigned Level) const {
25 // The root has no siblings.
26 if (Level == 0)
27 return NodeRef();
29 // Go up the tree until we can go left.
30 unsigned l = Level - 1;
31 while (l && path[l].offset == 0)
32 --l;
34 // We can't go left.
35 if (path[l].offset == 0)
36 return NodeRef();
38 // NR is the subtree containing our left sibling.
39 NodeRef NR = path[l].subtree(path[l].offset - 1);
41 // Keep right all the way down.
42 for (++l; l != Level; ++l)
43 NR = NR.subtree(NR.size() - 1);
44 return NR;
47 void Path::moveLeft(unsigned Level) {
48 assert(Level != 0 && "Cannot move the root node");
50 // Go up the tree until we can go left.
51 unsigned l = 0;
52 if (valid()) {
53 l = Level - 1;
54 while (path[l].offset == 0) {
55 assert(l != 0 && "Cannot move beyond begin()");
56 --l;
58 } else if (height() < Level)
59 // end() may have created a height=0 path.
60 path.resize(Level + 1, Entry(nullptr, 0, 0));
62 // NR is the subtree containing our left sibling.
63 --path[l].offset;
64 NodeRef NR = subtree(l);
66 // Get the rightmost node in the subtree.
67 for (++l; l != Level; ++l) {
68 path[l] = Entry(NR, NR.size() - 1);
69 NR = NR.subtree(NR.size() - 1);
71 path[l] = Entry(NR, NR.size() - 1);
74 NodeRef Path::getRightSibling(unsigned Level) const {
75 // The root has no siblings.
76 if (Level == 0)
77 return NodeRef();
79 // Go up the tree until we can go right.
80 unsigned l = Level - 1;
81 while (l && atLastEntry(l))
82 --l;
84 // We can't go right.
85 if (atLastEntry(l))
86 return NodeRef();
88 // NR is the subtree containing our right sibling.
89 NodeRef NR = path[l].subtree(path[l].offset + 1);
91 // Keep left all the way down.
92 for (++l; l != Level; ++l)
93 NR = NR.subtree(0);
94 return NR;
97 void Path::moveRight(unsigned Level) {
98 assert(Level != 0 && "Cannot move the root node");
100 // Go up the tree until we can go right.
101 unsigned l = Level - 1;
102 while (l && atLastEntry(l))
103 --l;
105 // NR is the subtree containing our right sibling. If we hit end(), we have
106 // offset(0) == node(0).size().
107 if (++path[l].offset == path[l].size)
108 return;
109 NodeRef NR = subtree(l);
111 for (++l; l != Level; ++l) {
112 path[l] = Entry(NR, 0);
113 NR = NR.subtree(0);
115 path[l] = Entry(NR, 0);
119 IdxPair distribute(unsigned Nodes, unsigned Elements, unsigned Capacity,
120 const unsigned *CurSize, unsigned NewSize[],
121 unsigned Position, bool Grow) {
122 assert(Elements + Grow <= Nodes * Capacity && "Not enough room for elements");
123 assert(Position <= Elements && "Invalid position");
124 if (!Nodes)
125 return IdxPair();
127 // Trivial algorithm: left-leaning even distribution.
128 const unsigned PerNode = (Elements + Grow) / Nodes;
129 const unsigned Extra = (Elements + Grow) % Nodes;
130 IdxPair PosPair = IdxPair(Nodes, 0);
131 unsigned Sum = 0;
132 for (unsigned n = 0; n != Nodes; ++n) {
133 Sum += NewSize[n] = PerNode + (n < Extra);
134 if (PosPair.first == Nodes && Sum > Position)
135 PosPair = IdxPair(n, Position - (Sum - NewSize[n]));
137 assert(Sum == Elements + Grow && "Bad distribution sum");
139 // Subtract the Grow element that was added.
140 if (Grow) {
141 assert(PosPair.first < Nodes && "Bad algebra");
142 assert(NewSize[PosPair.first] && "Too few elements to need Grow");
143 --NewSize[PosPair.first];
146 #ifndef NDEBUG
147 Sum = 0;
148 for (unsigned n = 0; n != Nodes; ++n) {
149 assert(NewSize[n] <= Capacity && "Overallocated node");
150 Sum += NewSize[n];
152 assert(Sum == Elements && "Bad distribution sum");
153 #endif
155 return PosPair;
158 } // namespace IntervalMapImpl
159 } // namespace llvm