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https://github.com/capstone-engine/llvm-capstone.git
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07837b8f49
Similar to D74882. This reverts much code from commit
bd8cfe65f5
(D68323) and fixes some
problems before D68323.
Sorry for the churn but D68323 was a mistake. Namespace qualifiers avoid
bugs where the definition does not match the declaration from the
header. See
https://llvm.org/docs/CodingStandards.html#use-namespace-qualifiers-to-implement-previously-declared-functions (D74515)
Differential Revision: https://reviews.llvm.org/D79982
270 lines
8.8 KiB
C++
270 lines
8.8 KiB
C++
//===- CallGraphSort.cpp --------------------------------------------------===//
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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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/// Implementation of Call-Chain Clustering from: Optimizing Function Placement
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/// for Large-Scale Data-Center Applications
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/// https://research.fb.com/wp-content/uploads/2017/01/cgo2017-hfsort-final1.pdf
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///
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/// The goal of this algorithm is to improve runtime performance of the final
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/// executable by arranging code sections such that page table and i-cache
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/// misses are minimized.
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///
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/// Definitions:
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/// * Cluster
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/// * An ordered list of input sections which are laid out as a unit. At the
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/// beginning of the algorithm each input section has its own cluster and
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/// the weight of the cluster is the sum of the weight of all incoming
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/// edges.
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/// * Call-Chain Clustering (C³) Heuristic
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/// * Defines when and how clusters are combined. Pick the highest weighted
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/// input section then add it to its most likely predecessor if it wouldn't
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/// penalize it too much.
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/// * Density
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/// * The weight of the cluster divided by the size of the cluster. This is a
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/// proxy for the amount of execution time spent per byte of the cluster.
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///
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/// It does so given a call graph profile by the following:
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/// * Build a weighted call graph from the call graph profile
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/// * Sort input sections by weight
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/// * For each input section starting with the highest weight
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/// * Find its most likely predecessor cluster
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/// * Check if the combined cluster would be too large, or would have too low
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/// a density.
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/// * If not, then combine the clusters.
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/// * Sort non-empty clusters by density
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///
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//===----------------------------------------------------------------------===//
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#include "CallGraphSort.h"
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#include "OutputSections.h"
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#include "SymbolTable.h"
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#include "Symbols.h"
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#include <numeric>
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using namespace llvm;
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using namespace lld;
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using namespace lld::elf;
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namespace {
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struct Edge {
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int from;
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uint64_t weight;
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};
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struct Cluster {
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Cluster(int sec, size_t s) : next(sec), prev(sec), size(s) {}
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double getDensity() const {
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if (size == 0)
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return 0;
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return double(weight) / double(size);
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}
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int next;
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int prev;
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size_t size = 0;
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uint64_t weight = 0;
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uint64_t initialWeight = 0;
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Edge bestPred = {-1, 0};
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};
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class CallGraphSort {
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public:
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CallGraphSort();
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DenseMap<const InputSectionBase *, int> run();
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private:
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std::vector<Cluster> clusters;
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std::vector<const InputSectionBase *> sections;
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};
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// Maximum amount the combined cluster density can be worse than the original
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// cluster to consider merging.
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constexpr int MAX_DENSITY_DEGRADATION = 8;
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// Maximum cluster size in bytes.
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constexpr uint64_t MAX_CLUSTER_SIZE = 1024 * 1024;
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} // end anonymous namespace
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using SectionPair =
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std::pair<const InputSectionBase *, const InputSectionBase *>;
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// Take the edge list in Config->CallGraphProfile, resolve symbol names to
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// Symbols, and generate a graph between InputSections with the provided
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// weights.
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CallGraphSort::CallGraphSort() {
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MapVector<SectionPair, uint64_t> &profile = config->callGraphProfile;
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DenseMap<const InputSectionBase *, int> secToCluster;
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auto getOrCreateNode = [&](const InputSectionBase *isec) -> int {
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auto res = secToCluster.try_emplace(isec, clusters.size());
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if (res.second) {
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sections.push_back(isec);
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clusters.emplace_back(clusters.size(), isec->getSize());
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}
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return res.first->second;
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};
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// Create the graph.
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for (std::pair<SectionPair, uint64_t> &c : profile) {
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const auto *fromSB = cast<InputSectionBase>(c.first.first->repl);
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const auto *toSB = cast<InputSectionBase>(c.first.second->repl);
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uint64_t weight = c.second;
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// Ignore edges between input sections belonging to different output
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// sections. This is done because otherwise we would end up with clusters
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// containing input sections that can't actually be placed adjacently in the
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// output. This messes with the cluster size and density calculations. We
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// would also end up moving input sections in other output sections without
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// moving them closer to what calls them.
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if (fromSB->getOutputSection() != toSB->getOutputSection())
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continue;
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int from = getOrCreateNode(fromSB);
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int to = getOrCreateNode(toSB);
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clusters[to].weight += weight;
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if (from == to)
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continue;
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// Remember the best edge.
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Cluster &toC = clusters[to];
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if (toC.bestPred.from == -1 || toC.bestPred.weight < weight) {
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toC.bestPred.from = from;
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toC.bestPred.weight = weight;
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}
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}
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for (Cluster &c : clusters)
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c.initialWeight = c.weight;
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}
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// It's bad to merge clusters which would degrade the density too much.
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static bool isNewDensityBad(Cluster &a, Cluster &b) {
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double newDensity = double(a.weight + b.weight) / double(a.size + b.size);
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return newDensity < a.getDensity() / MAX_DENSITY_DEGRADATION;
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}
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// Find the leader of V's belonged cluster (represented as an equivalence
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// class). We apply union-find path-halving technique (simple to implement) in
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// the meantime as it decreases depths and the time complexity.
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static int getLeader(std::vector<int> &leaders, int v) {
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while (leaders[v] != v) {
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leaders[v] = leaders[leaders[v]];
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v = leaders[v];
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}
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return v;
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}
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static void mergeClusters(std::vector<Cluster> &cs, Cluster &into, int intoIdx,
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Cluster &from, int fromIdx) {
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int tail1 = into.prev, tail2 = from.prev;
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into.prev = tail2;
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cs[tail2].next = intoIdx;
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from.prev = tail1;
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cs[tail1].next = fromIdx;
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into.size += from.size;
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into.weight += from.weight;
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from.size = 0;
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from.weight = 0;
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}
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// Group InputSections into clusters using the Call-Chain Clustering heuristic
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// then sort the clusters by density.
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DenseMap<const InputSectionBase *, int> CallGraphSort::run() {
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std::vector<int> sorted(clusters.size());
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std::vector<int> leaders(clusters.size());
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std::iota(leaders.begin(), leaders.end(), 0);
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std::iota(sorted.begin(), sorted.end(), 0);
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llvm::stable_sort(sorted, [&](int a, int b) {
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return clusters[a].getDensity() > clusters[b].getDensity();
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});
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for (int l : sorted) {
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// The cluster index is the same as the index of its leader here because
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// clusters[L] has not been merged into another cluster yet.
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Cluster &c = clusters[l];
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// Don't consider merging if the edge is unlikely.
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if (c.bestPred.from == -1 || c.bestPred.weight * 10 <= c.initialWeight)
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continue;
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int predL = getLeader(leaders, c.bestPred.from);
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if (l == predL)
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continue;
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Cluster *predC = &clusters[predL];
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if (c.size + predC->size > MAX_CLUSTER_SIZE)
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continue;
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if (isNewDensityBad(*predC, c))
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continue;
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leaders[l] = predL;
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mergeClusters(clusters, *predC, predL, c, l);
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}
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// Sort remaining non-empty clusters by density.
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sorted.clear();
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for (int i = 0, e = (int)clusters.size(); i != e; ++i)
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if (clusters[i].size > 0)
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sorted.push_back(i);
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llvm::stable_sort(sorted, [&](int a, int b) {
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return clusters[a].getDensity() > clusters[b].getDensity();
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});
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DenseMap<const InputSectionBase *, int> orderMap;
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int curOrder = 1;
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for (int leader : sorted)
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for (int i = leader;;) {
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orderMap[sections[i]] = curOrder++;
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i = clusters[i].next;
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if (i == leader)
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break;
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}
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if (!config->printSymbolOrder.empty()) {
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std::error_code ec;
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raw_fd_ostream os(config->printSymbolOrder, ec, sys::fs::OF_None);
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if (ec) {
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error("cannot open " + config->printSymbolOrder + ": " + ec.message());
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return orderMap;
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}
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// Print the symbols ordered by C3, in the order of increasing curOrder
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// Instead of sorting all the orderMap, just repeat the loops above.
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for (int leader : sorted)
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for (int i = leader;;) {
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// Search all the symbols in the file of the section
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// and find out a Defined symbol with name that is within the section.
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for (Symbol *sym : sections[i]->file->getSymbols())
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if (!sym->isSection()) // Filter out section-type symbols here.
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if (auto *d = dyn_cast<Defined>(sym))
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if (sections[i] == d->section)
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os << sym->getName() << "\n";
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i = clusters[i].next;
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if (i == leader)
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break;
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}
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}
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return orderMap;
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}
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// Sort sections by the profile data provided by -callgraph-profile-file
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//
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// This first builds a call graph based on the profile data then merges sections
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// according to the C³ heuristic. All clusters are then sorted by a density
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// metric to further improve locality.
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DenseMap<const InputSectionBase *, int> elf::computeCallGraphProfileOrder() {
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return CallGraphSort().run();
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}
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