src/third_party/llvm-project/lld/ELF/CallGraphSort.cpp - cobalt - Git at Google

 //===- CallGraphSort.cpp --------------------------------------------------===//
 //
 //                             The LLVM Linker
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// Implementation of Call-Chain Clustering from: Optimizing Function Placement
 /// for Large-Scale Data-Center Applications
 /// https://research.fb.com/wp-content/uploads/2017/01/cgo2017-hfsort-final1.pdf
 ///
 /// The goal of this algorithm is to improve runtime performance of the final
 /// executable by arranging code sections such that page table and i-cache
 /// misses are minimized.
 ///
 /// Definitions:
 /// * Cluster
 ///   * An ordered list of input sections which are layed out as a unit. At the
 ///     beginning of the algorithm each input section has its own cluster and
 ///     the weight of the cluster is the sum of the weight of all incomming
 ///     edges.
 /// * Call-Chain Clustering (C³) Heuristic
 ///   * Defines when and how clusters are combined. Pick the highest weighted
 ///     input section then add it to its most likely predecessor if it wouldn't
 ///     penalize it too much.
 /// * Density
 ///   * The weight of the cluster divided by the size of the cluster. This is a
 ///     proxy for the ammount of execution time spent per byte of the cluster.
 ///
 /// It does so given a call graph profile by the following:
 /// * Build a weighted call graph from the call graph profile
 /// * Sort input sections by weight
 /// * For each input section starting with the highest weight
 ///   * Find its most likely predecessor cluster
 ///   * Check if the combined cluster would be too large, or would have too low
 ///     a density.
 ///   * If not, then combine the clusters.
 /// * Sort non-empty clusters by density
 ///
 //===----------------------------------------------------------------------===//

 #include "CallGraphSort.h"
 #include "OutputSections.h"
 #include "SymbolTable.h"
 #include "Symbols.h"

 using namespace llvm;
 using namespace lld;
 using namespace lld::elf;

 namespace {
 struct Edge {
   int From;
   uint64_t Weight;
 };

 struct Cluster {
   Cluster(int Sec, size_t S) {
     Sections.push_back(Sec);
     Size = S;
   }

   double getDensity() const {
     if (Size == 0)
       return 0;
     return double(Weight) / double(Size);
   }

   std::vector<int> Sections;
   size_t Size = 0;
   uint64_t Weight = 0;
   uint64_t InitialWeight = 0;
   std::vector<Edge> Preds;
 };

 class CallGraphSort {
 public:
   CallGraphSort();

   DenseMap<const InputSectionBase *, int> run();

 private:
   std::vector<Cluster> Clusters;
   std::vector<const InputSectionBase *> Sections;

   void groupClusters();
 };

 // Maximum ammount the combined cluster density can be worse than the original
 // cluster to consider merging.
 constexpr int MAX_DENSITY_DEGRADATION = 8;

 // Maximum cluster size in bytes.
 constexpr uint64_t MAX_CLUSTER_SIZE = 1024 * 1024;
 } // end anonymous namespace

 // Take the edge list in Config->CallGraphProfile, resolve symbol names to
 // Symbols, and generate a graph between InputSections with the provided
 // weights.
 CallGraphSort::CallGraphSort() {
   llvm::MapVector<std::pair<const InputSectionBase *, const InputSectionBase *>,
                   uint64_t> &Profile = Config->CallGraphProfile;
   DenseMap<const InputSectionBase *, int> SecToCluster;

   auto GetOrCreateNode = [&](const InputSectionBase *IS) -> int {
     auto Res = SecToCluster.insert(std::make_pair(IS, Clusters.size()));
     if (Res.second) {
       Sections.push_back(IS);
       Clusters.emplace_back(Clusters.size(), IS->getSize());
     }
     return Res.first->second;
   };

   // Create the graph.
   for (const auto &C : Profile) {
     const auto *FromSB = cast<InputSectionBase>(C.first.first->Repl);
     const auto *ToSB = cast<InputSectionBase>(C.first.second->Repl);
     uint64_t Weight = C.second;

     // Ignore edges between input sections belonging to different output
     // sections.  This is done because otherwise we would end up with clusters
     // containing input sections that can't actually be placed adjacently in the
     // output.  This messes with the cluster size and density calculations.  We
     // would also end up moving input sections in other output sections without
     // moving them closer to what calls them.
     if (FromSB->getOutputSection() != ToSB->getOutputSection())
       continue;

     int From = GetOrCreateNode(FromSB);
     int To = GetOrCreateNode(ToSB);

     Clusters[To].Weight += Weight;

     if (From == To)
       continue;

     // Add an edge
     Clusters[To].Preds.push_back({From, Weight});
   }
   for (Cluster &C : Clusters)
     C.InitialWeight = C.Weight;
 }

 // It's bad to merge clusters which would degrade the density too much.
 static bool isNewDensityBad(Cluster &A, Cluster &B) {
   double NewDensity = double(A.Weight + B.Weight) / double(A.Size + B.Size);
   if (NewDensity < A.getDensity() / MAX_DENSITY_DEGRADATION)
     return true;
   return false;
 }

 static void mergeClusters(Cluster &Into, Cluster &From) {
   Into.Sections.insert(Into.Sections.end(), From.Sections.begin(),
                        From.Sections.end());
   Into.Size += From.Size;
   Into.Weight += From.Weight;
   From.Sections.clear();
   From.Size = 0;
   From.Weight = 0;
 }

 // Group InputSections into clusters using the Call-Chain Clustering heuristic
 // then sort the clusters by density.
 void CallGraphSort::groupClusters() {
   std::vector<int> SortedSecs(Clusters.size());
   std::vector<Cluster *> SecToCluster(Clusters.size());

   for (int SI = 0, SE = Clusters.size(); SI != SE; ++SI) {
     SortedSecs[SI] = SI;
     SecToCluster[SI] = &Clusters[SI];
   }

   std::stable_sort(SortedSecs.begin(), SortedSecs.end(), [&](int A, int B) {
     return Clusters[B].getDensity() < Clusters[A].getDensity();
   });

   for (int SI : SortedSecs) {
     // Clusters[SI] is the same as SecToClusters[SI] here because it has not
     // been merged into another cluster yet.
     Cluster &C = Clusters[SI];

     int BestPred = -1;
     uint64_t BestWeight = 0;

     for (Edge &E : C.Preds) {
       if (BestPred == -1 || E.Weight > BestWeight) {
         BestPred = E.From;
         BestWeight = E.Weight;
       }
     }

     // don't consider merging if the edge is unlikely.
     if (BestWeight * 10 <= C.InitialWeight)
       continue;

     Cluster *PredC = SecToCluster[BestPred];
     if (PredC == &C)
       continue;

     if (C.Size + PredC->Size > MAX_CLUSTER_SIZE)
       continue;

     if (isNewDensityBad(*PredC, C))
       continue;

     // NOTE: Consider using a disjoint-set to track section -> cluster mapping
     // if this is ever slow.
     for (int SI : C.Sections)
       SecToCluster[SI] = PredC;

     mergeClusters(*PredC, C);
   }

   // Remove empty or dead nodes. Invalidates all cluster indices.
   llvm::erase_if(Clusters, [](const Cluster &C) {
     return C.Size == 0 || C.Sections.empty();
   });

   // Sort by density.
   std::stable_sort(Clusters.begin(), Clusters.end(),
                    [](const Cluster &A, const Cluster &B) {
                      return A.getDensity() > B.getDensity();
                    });
 }

 DenseMap<const InputSectionBase *, int> CallGraphSort::run() {
   groupClusters();

   // Generate order.
   llvm::DenseMap<const InputSectionBase *, int> OrderMap;
   ssize_t CurOrder = 1;

   for (const Cluster &C : Clusters)
     for (int SecIndex : C.Sections)
       OrderMap[Sections[SecIndex]] = CurOrder++;

   return OrderMap;
 }

 // Sort sections by the profile data provided by -callgraph-profile-file
 //
 // This first builds a call graph based on the profile data then merges sections
 // according to the C³ huristic. All clusters are then sorted by a density
 // metric to further improve locality.
 DenseMap<const InputSectionBase *, int> elf::computeCallGraphProfileOrder() {
   return CallGraphSort().run();
 }
	//===- CallGraphSort.cpp --------------------------------------------------===//
	//
	// The LLVM Linker
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// Implementation of Call-Chain Clustering from: Optimizing Function Placement
	/// for Large-Scale Data-Center Applications
	/// https://research.fb.com/wp-content/uploads/2017/01/cgo2017-hfsort-final1.pdf
	///
	/// The goal of this algorithm is to improve runtime performance of the final
	/// executable by arranging code sections such that page table and i-cache
	/// misses are minimized.
	///
	/// Definitions:
	/// * Cluster
	/// * An ordered list of input sections which are layed out as a unit. At the
	/// beginning of the algorithm each input section has its own cluster and
	/// the weight of the cluster is the sum of the weight of all incomming
	/// edges.
	/// * Call-Chain Clustering (C³) Heuristic
	/// * Defines when and how clusters are combined. Pick the highest weighted
	/// input section then add it to its most likely predecessor if it wouldn't
	/// penalize it too much.
	/// * Density
	/// * The weight of the cluster divided by the size of the cluster. This is a
	/// proxy for the ammount of execution time spent per byte of the cluster.
	///
	/// It does so given a call graph profile by the following:
	/// * Build a weighted call graph from the call graph profile
	/// * Sort input sections by weight
	/// * For each input section starting with the highest weight
	/// * Find its most likely predecessor cluster
	/// * Check if the combined cluster would be too large, or would have too low
	/// a density.
	/// * If not, then combine the clusters.
	/// * Sort non-empty clusters by density
	///
	//===----------------------------------------------------------------------===//

	#include "CallGraphSort.h"
	#include "OutputSections.h"
	#include "SymbolTable.h"
	#include "Symbols.h"

	using namespace llvm;
	using namespace lld;
	using namespace lld::elf;

	namespace {
	struct Edge {
	int From;
	uint64_t Weight;
	};

	struct Cluster {
	Cluster(int Sec, size_t S) {
	Sections.push_back(Sec);
	Size = S;
	}

	double getDensity() const {
	if (Size == 0)
	return 0;
	return double(Weight) / double(Size);
	}

	std::vector<int> Sections;
	size_t Size = 0;
	uint64_t Weight = 0;
	uint64_t InitialWeight = 0;
	std::vector<Edge> Preds;
	};

	class CallGraphSort {
	public:
	CallGraphSort();

	DenseMap<const InputSectionBase *, int> run();

	private:
	std::vector<Cluster> Clusters;
	std::vector<const InputSectionBase *> Sections;

	void groupClusters();
	};

	// Maximum ammount the combined cluster density can be worse than the original
	// cluster to consider merging.
	constexpr int MAX_DENSITY_DEGRADATION = 8;

	// Maximum cluster size in bytes.
	constexpr uint64_t MAX_CLUSTER_SIZE = 1024 * 1024;
	} // end anonymous namespace

	// Take the edge list in Config->CallGraphProfile, resolve symbol names to
	// Symbols, and generate a graph between InputSections with the provided
	// weights.
	CallGraphSort::CallGraphSort() {
	llvm::MapVector<std::pair<const InputSectionBase , const InputSectionBase >,
	uint64_t> &Profile = Config->CallGraphProfile;
	DenseMap<const InputSectionBase *, int> SecToCluster;

	auto GetOrCreateNode = [&](const InputSectionBase *IS) -> int {
	auto Res = SecToCluster.insert(std::make_pair(IS, Clusters.size()));
	if (Res.second) {
	Sections.push_back(IS);
	Clusters.emplace_back(Clusters.size(), IS->getSize());
	}
	return Res.first->second;
	};

	// Create the graph.
	for (const auto &C : Profile) {
	const auto *FromSB = cast<InputSectionBase>(C.first.first->Repl);
	const auto *ToSB = cast<InputSectionBase>(C.first.second->Repl);
	uint64_t Weight = C.second;

	// Ignore edges between input sections belonging to different output
	// sections. This is done because otherwise we would end up with clusters
	// containing input sections that can't actually be placed adjacently in the
	// output. This messes with the cluster size and density calculations. We
	// would also end up moving input sections in other output sections without
	// moving them closer to what calls them.
	if (FromSB->getOutputSection() != ToSB->getOutputSection())
	continue;

	int From = GetOrCreateNode(FromSB);
	int To = GetOrCreateNode(ToSB);

	Clusters[To].Weight += Weight;

	if (From == To)
	continue;

	// Add an edge
	Clusters[To].Preds.push_back({From, Weight});
	}
	for (Cluster &C : Clusters)
	C.InitialWeight = C.Weight;
	}

	// It's bad to merge clusters which would degrade the density too much.
	static bool isNewDensityBad(Cluster &A, Cluster &B) {
	double NewDensity = double(A.Weight + B.Weight) / double(A.Size + B.Size);
	if (NewDensity < A.getDensity() / MAX_DENSITY_DEGRADATION)
	return true;
	return false;
	}

	static void mergeClusters(Cluster &Into, Cluster &From) {
	Into.Sections.insert(Into.Sections.end(), From.Sections.begin(),
	From.Sections.end());
	Into.Size += From.Size;
	Into.Weight += From.Weight;
	From.Sections.clear();
	From.Size = 0;
	From.Weight = 0;
	}

	// Group InputSections into clusters using the Call-Chain Clustering heuristic
	// then sort the clusters by density.
	void CallGraphSort::groupClusters() {
	std::vector<int> SortedSecs(Clusters.size());
	std::vector<Cluster *> SecToCluster(Clusters.size());

	for (int SI = 0, SE = Clusters.size(); SI != SE; ++SI) {
	SortedSecs[SI] = SI;
	SecToCluster[SI] = &Clusters[SI];
	}

	std::stable_sort(SortedSecs.begin(), SortedSecs.end(), [&](int A, int B) {
	return Clusters[B].getDensity() < Clusters[A].getDensity();
	});

	for (int SI : SortedSecs) {
	// Clusters[SI] is the same as SecToClusters[SI] here because it has not
	// been merged into another cluster yet.
	Cluster &C = Clusters[SI];

	int BestPred = -1;
	uint64_t BestWeight = 0;

	for (Edge &E : C.Preds) {
	if (BestPred == -1 \|\| E.Weight > BestWeight) {
	BestPred = E.From;
	BestWeight = E.Weight;
	}
	}

	// don't consider merging if the edge is unlikely.
	if (BestWeight * 10 <= C.InitialWeight)
	continue;

	Cluster *PredC = SecToCluster[BestPred];
	if (PredC == &C)
	continue;

	if (C.Size + PredC->Size > MAX_CLUSTER_SIZE)
	continue;

	if (isNewDensityBad(*PredC, C))
	continue;

	// NOTE: Consider using a disjoint-set to track section -> cluster mapping
	// if this is ever slow.
	for (int SI : C.Sections)
	SecToCluster[SI] = PredC;

	mergeClusters(*PredC, C);
	}

	// Remove empty or dead nodes. Invalidates all cluster indices.
	llvm::erase_if(Clusters, [](const Cluster &C) {
	return C.Size == 0 \|\| C.Sections.empty();
	});

	// Sort by density.
	std::stable_sort(Clusters.begin(), Clusters.end(),
	[](const Cluster &A, const Cluster &B) {
	return A.getDensity() > B.getDensity();
	});
	}

	DenseMap<const InputSectionBase *, int> CallGraphSort::run() {
	groupClusters();

	// Generate order.
	llvm::DenseMap<const InputSectionBase *, int> OrderMap;
	ssize_t CurOrder = 1;

	for (const Cluster &C : Clusters)
	for (int SecIndex : C.Sections)
	OrderMap[Sections[SecIndex]] = CurOrder++;

	return OrderMap;
	}

	// Sort sections by the profile data provided by -callgraph-profile-file
	//
	// This first builds a call graph based on the profile data then merges sections
	// according to the C³ huristic. All clusters are then sorted by a density
	// metric to further improve locality.
	DenseMap<const InputSectionBase *, int> elf::computeCallGraphProfileOrder() {
	return CallGraphSort().run();
	}