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

 //===- ICF.cpp ------------------------------------------------------------===//
 //
 //                             The LLVM Linker
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // ICF is short for Identical Code Folding. This is a size optimization to
 // identify and merge two or more read-only sections (typically functions)
 // that happened to have the same contents. It usually reduces output size
 // by a few percent.
 //
 // In ICF, two sections are considered identical if they have the same
 // section flags, section data, and relocations. Relocations are tricky,
 // because two relocations are considered the same if they have the same
 // relocation types, values, and if they point to the same sections *in
 // terms of ICF*.
 //
 // Here is an example. If foo and bar defined below are compiled to the
 // same machine instructions, ICF can and should merge the two, although
 // their relocations point to each other.
 //
 //   void foo() { bar(); }
 //   void bar() { foo(); }
 //
 // If you merge the two, their relocations point to the same section and
 // thus you know they are mergeable, but how do you know they are
 // mergeable in the first place? This is not an easy problem to solve.
 //
 // What we are doing in LLD is to partition sections into equivalence
 // classes. Sections in the same equivalence class when the algorithm
 // terminates are considered identical. Here are details:
 //
 // 1. First, we partition sections using their hash values as keys. Hash
 //    values contain section types, section contents and numbers of
 //    relocations. During this step, relocation targets are not taken into
 //    account. We just put sections that apparently differ into different
 //    equivalence classes.
 //
 // 2. Next, for each equivalence class, we visit sections to compare
 //    relocation targets. Relocation targets are considered equivalent if
 //    their targets are in the same equivalence class. Sections with
 //    different relocation targets are put into different equivalence
 //    clases.
 //
 // 3. If we split an equivalence class in step 2, two relocations
 //    previously target the same equivalence class may now target
 //    different equivalence classes. Therefore, we repeat step 2 until a
 //    convergence is obtained.
 //
 // 4. For each equivalence class C, pick an arbitrary section in C, and
 //    merge all the other sections in C with it.
 //
 // For small programs, this algorithm needs 3-5 iterations. For large
 // programs such as Chromium, it takes more than 20 iterations.
 //
 // This algorithm was mentioned as an "optimistic algorithm" in [1],
 // though gold implements a different algorithm than this.
 //
 // We parallelize each step so that multiple threads can work on different
 // equivalence classes concurrently. That gave us a large performance
 // boost when applying ICF on large programs. For example, MSVC link.exe
 // or GNU gold takes 10-20 seconds to apply ICF on Chromium, whose output
 // size is about 1.5 GB, but LLD can finish it in less than 2 seconds on a
 // 2.8 GHz 40 core machine. Even without threading, LLD's ICF is still
 // faster than MSVC or gold though.
 //
 // [1] Safe ICF: Pointer Safe and Unwinding aware Identical Code Folding
 // in the Gold Linker
 // http://static.googleusercontent.com/media/research.google.com/en//pubs/archive/36912.pdf
 //
 //===----------------------------------------------------------------------===//

 #include "ICF.h"
 #include "Config.h"
 #include "SymbolTable.h"
 #include "Symbols.h"
 #include "SyntheticSections.h"
 #include "Writer.h"
 #include "lld/Common/Threads.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/BinaryFormat/ELF.h"
 #include "llvm/Object/ELF.h"
 #include "llvm/Support/xxhash.h"
 #include <algorithm>
 #include <atomic>

 using namespace lld;
 using namespace lld::elf;
 using namespace llvm;
 using namespace llvm::ELF;
 using namespace llvm::object;

 namespace {
 template <class ELFT> class ICF {
 public:
   void run();

 private:
   void segregate(size_t Begin, size_t End, bool Constant);

   template <class RelTy>
   bool constantEq(const InputSection *A, ArrayRef<RelTy> RelsA,
                   const InputSection *B, ArrayRef<RelTy> RelsB);

   template <class RelTy>
   bool variableEq(const InputSection *A, ArrayRef<RelTy> RelsA,
                   const InputSection *B, ArrayRef<RelTy> RelsB);

   bool equalsConstant(const InputSection *A, const InputSection *B);
   bool equalsVariable(const InputSection *A, const InputSection *B);

   size_t findBoundary(size_t Begin, size_t End);

   void forEachClassRange(size_t Begin, size_t End,
                          llvm::function_ref<void(size_t, size_t)> Fn);

   void forEachClass(llvm::function_ref<void(size_t, size_t)> Fn);

   std::vector<InputSection *> Sections;

   // We repeat the main loop while `Repeat` is true.
   std::atomic<bool> Repeat;

   // The main loop counter.
   int Cnt = 0;

   // We have two locations for equivalence classes. On the first iteration
   // of the main loop, Class[0] has a valid value, and Class[1] contains
   // garbage. We read equivalence classes from slot 0 and write to slot 1.
   // So, Class[0] represents the current class, and Class[1] represents
   // the next class. On each iteration, we switch their roles and use them
   // alternately.
   //
   // Why are we doing this? Recall that other threads may be working on
   // other equivalence classes in parallel. They may read sections that we
   // are updating. We cannot update equivalence classes in place because
   // it breaks the invariance that all possibly-identical sections must be
   // in the same equivalence class at any moment. In other words, the for
   // loop to update equivalence classes is not atomic, and that is
   // observable from other threads. By writing new classes to other
   // places, we can keep the invariance.
   //
   // Below, `Current` has the index of the current class, and `Next` has
   // the index of the next class. If threading is enabled, they are either
   // (0, 1) or (1, 0).
   //
   // Note on single-thread: if that's the case, they are always (0, 0)
   // because we can safely read the next class without worrying about race
   // conditions. Using the same location makes this algorithm converge
   // faster because it uses results of the same iteration earlier.
   int Current = 0;
   int Next = 0;
 };
 }

 // Returns true if section S is subject of ICF.
 static bool isEligible(InputSection *S) {
   if (!S->Live || S->KeepUnique || !(S->Flags & SHF_ALLOC))
     return false;

   // Don't merge writable sections. .data.rel.ro sections are marked as writable
   // but are semantically read-only.
   if ((S->Flags & SHF_WRITE) && S->Name != ".data.rel.ro" &&
       !S->Name.startswith(".data.rel.ro."))
     return false;

   // SHF_LINK_ORDER sections are ICF'd as a unit with their dependent sections,
   // so we don't consider them for ICF individually.
   if (S->Flags & SHF_LINK_ORDER)
     return false;

   // Don't merge synthetic sections as their Data member is not valid and empty.
   // The Data member needs to be valid for ICF as it is used by ICF to determine
   // the equality of section contents.
   if (isa<SyntheticSection>(S))
     return false;

   // .init and .fini contains instructions that must be executed to initialize
   // and finalize the process. They cannot and should not be merged.
   if (S->Name == ".init" || S->Name == ".fini")
     return false;

   // A user program may enumerate sections named with a C identifier using
   // __start_* and __stop_* symbols. We cannot ICF any such sections because
   // that could change program semantics.
   if (isValidCIdentifier(S->Name))
     return false;

   return true;
 }

 // Split an equivalence class into smaller classes.
 template <class ELFT>
 void ICF<ELFT>::segregate(size_t Begin, size_t End, bool Constant) {
   // This loop rearranges sections in [Begin, End) so that all sections
   // that are equal in terms of equals{Constant,Variable} are contiguous
   // in [Begin, End).
   //
   // The algorithm is quadratic in the worst case, but that is not an
   // issue in practice because the number of the distinct sections in
   // each range is usually very small.

   while (Begin < End) {
     // Divide [Begin, End) into two. Let Mid be the start index of the
     // second group.
     auto Bound =
         std::stable_partition(Sections.begin() + Begin + 1,
                               Sections.begin() + End, [&](InputSection *S) {
                                 if (Constant)
                                   return equalsConstant(Sections[Begin], S);
                                 return equalsVariable(Sections[Begin], S);
                               });
     size_t Mid = Bound - Sections.begin();

     // Now we split [Begin, End) into [Begin, Mid) and [Mid, End) by
     // updating the sections in [Begin, Mid). We use Mid as an equivalence
     // class ID because every group ends with a unique index.
     for (size_t I = Begin; I < Mid; ++I)
       Sections[I]->Class[Next] = Mid;

     // If we created a group, we need to iterate the main loop again.
     if (Mid != End)
       Repeat = true;

     Begin = Mid;
   }
 }

 // Compare two lists of relocations.
 template <class ELFT>
 template <class RelTy>
 bool ICF<ELFT>::constantEq(const InputSection *SecA, ArrayRef<RelTy> RA,
                            const InputSection *SecB, ArrayRef<RelTy> RB) {
   for (size_t I = 0; I < RA.size(); ++I) {
     if (RA[I].r_offset != RB[I].r_offset ||
         RA[I].getType(Config->IsMips64EL) != RB[I].getType(Config->IsMips64EL))
       return false;

     uint64_t AddA = getAddend<ELFT>(RA[I]);
     uint64_t AddB = getAddend<ELFT>(RB[I]);

     Symbol &SA = SecA->template getFile<ELFT>()->getRelocTargetSym(RA[I]);
     Symbol &SB = SecB->template getFile<ELFT>()->getRelocTargetSym(RB[I]);
     if (&SA == &SB) {
       if (AddA == AddB)
         continue;
       return false;
     }

     auto *DA = dyn_cast<Defined>(&SA);
     auto *DB = dyn_cast<Defined>(&SB);
     if (!DA || !DB)
       return false;

     // Relocations referring to absolute symbols are constant-equal if their
     // values are equal.
     if (!DA->Section && !DB->Section && DA->Value + AddA == DB->Value + AddB)
       continue;
     if (!DA->Section || !DB->Section)
       return false;

     if (DA->Section->kind() != DB->Section->kind())
       return false;

     // Relocations referring to InputSections are constant-equal if their
     // section offsets are equal.
     if (isa<InputSection>(DA->Section)) {
       if (DA->Value + AddA == DB->Value + AddB)
         continue;
       return false;
     }

     // Relocations referring to MergeInputSections are constant-equal if their
     // offsets in the output section are equal.
     auto *X = dyn_cast<MergeInputSection>(DA->Section);
     if (!X)
       return false;
     auto *Y = cast<MergeInputSection>(DB->Section);
     if (X->getParent() != Y->getParent())
       return false;

     uint64_t OffsetA =
         SA.isSection() ? X->getOffset(AddA) : X->getOffset(DA->Value) + AddA;
     uint64_t OffsetB =
         SB.isSection() ? Y->getOffset(AddB) : Y->getOffset(DB->Value) + AddB;
     if (OffsetA != OffsetB)
       return false;
   }

   return true;
 }

 // Compare "non-moving" part of two InputSections, namely everything
 // except relocation targets.
 template <class ELFT>
 bool ICF<ELFT>::equalsConstant(const InputSection *A, const InputSection *B) {
   if (A->NumRelocations != B->NumRelocations || A->Flags != B->Flags ||
       A->getSize() != B->getSize() || A->Data != B->Data)
     return false;

   // If two sections have different output sections, we cannot merge them.
   // FIXME: This doesn't do the right thing in the case where there is a linker
   // script. We probably need to move output section assignment before ICF to
   // get the correct behaviour here.
   if (getOutputSectionName(A) != getOutputSectionName(B))
     return false;

   if (A->AreRelocsRela)
     return constantEq(A, A->template relas<ELFT>(), B,
                       B->template relas<ELFT>());
   return constantEq(A, A->template rels<ELFT>(), B, B->template rels<ELFT>());
 }

 // Compare two lists of relocations. Returns true if all pairs of
 // relocations point to the same section in terms of ICF.
 template <class ELFT>
 template <class RelTy>
 bool ICF<ELFT>::variableEq(const InputSection *SecA, ArrayRef<RelTy> RA,
                            const InputSection *SecB, ArrayRef<RelTy> RB) {
   assert(RA.size() == RB.size());

   for (size_t I = 0; I < RA.size(); ++I) {
     // The two sections must be identical.
     Symbol &SA = SecA->template getFile<ELFT>()->getRelocTargetSym(RA[I]);
     Symbol &SB = SecB->template getFile<ELFT>()->getRelocTargetSym(RB[I]);
     if (&SA == &SB)
       continue;

     auto *DA = cast<Defined>(&SA);
     auto *DB = cast<Defined>(&SB);

     // We already dealt with absolute and non-InputSection symbols in
     // constantEq, and for InputSections we have already checked everything
     // except the equivalence class.
     if (!DA->Section)
       continue;
     auto *X = dyn_cast<InputSection>(DA->Section);
     if (!X)
       continue;
     auto *Y = cast<InputSection>(DB->Section);

     // Ineligible sections are in the special equivalence class 0.
     // They can never be the same in terms of the equivalence class.
     if (X->Class[Current] == 0)
       return false;
     if (X->Class[Current] != Y->Class[Current])
       return false;
   };

   return true;
 }

 // Compare "moving" part of two InputSections, namely relocation targets.
 template <class ELFT>
 bool ICF<ELFT>::equalsVariable(const InputSection *A, const InputSection *B) {
   if (A->AreRelocsRela)
     return variableEq(A, A->template relas<ELFT>(), B,
                       B->template relas<ELFT>());
   return variableEq(A, A->template rels<ELFT>(), B, B->template rels<ELFT>());
 }

 template <class ELFT> size_t ICF<ELFT>::findBoundary(size_t Begin, size_t End) {
   uint32_t Class = Sections[Begin]->Class[Current];
   for (size_t I = Begin + 1; I < End; ++I)
     if (Class != Sections[I]->Class[Current])
       return I;
   return End;
 }

 // Sections in the same equivalence class are contiguous in Sections
 // vector. Therefore, Sections vector can be considered as contiguous
 // groups of sections, grouped by the class.
 //
 // This function calls Fn on every group within [Begin, End).
 template <class ELFT>
 void ICF<ELFT>::forEachClassRange(size_t Begin, size_t End,
                                   llvm::function_ref<void(size_t, size_t)> Fn) {
   while (Begin < End) {
     size_t Mid = findBoundary(Begin, End);
     Fn(Begin, Mid);
     Begin = Mid;
   }
 }

 // Call Fn on each equivalence class.
 template <class ELFT>
 void ICF<ELFT>::forEachClass(llvm::function_ref<void(size_t, size_t)> Fn) {
   // If threading is disabled or the number of sections are
   // too small to use threading, call Fn sequentially.
   if (!ThreadsEnabled || Sections.size() < 1024) {
     forEachClassRange(0, Sections.size(), Fn);
     ++Cnt;
     return;
   }

   Current = Cnt % 2;
   Next = (Cnt + 1) % 2;

   // Shard into non-overlapping intervals, and call Fn in parallel.
   // The sharding must be completed before any calls to Fn are made
   // so that Fn can modify the Chunks in its shard without causing data
   // races.
   const size_t NumShards = 256;
   size_t Step = Sections.size() / NumShards;
   size_t Boundaries[NumShards + 1];
   Boundaries[0] = 0;
   Boundaries[NumShards] = Sections.size();

   parallelForEachN(1, NumShards, [&](size_t I) {
     Boundaries[I] = findBoundary((I - 1) * Step, Sections.size());
   });

   parallelForEachN(1, NumShards + 1, [&](size_t I) {
     if (Boundaries[I - 1] < Boundaries[I])
       forEachClassRange(Boundaries[I - 1], Boundaries[I], Fn);
   });
   ++Cnt;
 }

 static void print(const Twine &S) {
   if (Config->PrintIcfSections)
     message(S);
 }

 // The main function of ICF.
 template <class ELFT> void ICF<ELFT>::run() {
   // Collect sections to merge.
   for (InputSectionBase *Sec : InputSections)
     if (auto *S = dyn_cast<InputSection>(Sec))
       if (isEligible(S))
         Sections.push_back(S);

   // Initially, we use hash values to partition sections.
   parallelForEach(Sections, [&](InputSection *S) {
     // Set MSB to 1 to avoid collisions with non-hash IDs.
     S->Class[0] = xxHash64(S->Data) | (1U << 31);
   });

   // From now on, sections in Sections vector are ordered so that sections
   // in the same equivalence class are consecutive in the vector.
   std::stable_sort(Sections.begin(), Sections.end(),
                    [](InputSection *A, InputSection *B) {
                      return A->Class[0] < B->Class[0];
                    });

   // Compare static contents and assign unique IDs for each static content.
   forEachClass([&](size_t Begin, size_t End) { segregate(Begin, End, true); });

   // Split groups by comparing relocations until convergence is obtained.
   do {
     Repeat = false;
     forEachClass(
         [&](size_t Begin, size_t End) { segregate(Begin, End, false); });
   } while (Repeat);

   log("ICF needed " + Twine(Cnt) + " iterations");

   // Merge sections by the equivalence class.
   forEachClassRange(0, Sections.size(), [&](size_t Begin, size_t End) {
     if (End - Begin == 1)
       return;
     print("selected section " + toString(Sections[Begin]));
     for (size_t I = Begin + 1; I < End; ++I) {
       print("  removing identical section " + toString(Sections[I]));
       Sections[Begin]->replace(Sections[I]);

       // At this point we know sections merged are fully identical and hence
       // we want to remove duplicate implicit dependencies such as link order
       // and relocation sections.
       for (InputSection *IS : Sections[I]->DependentSections)
         IS->Live = false;
     }
   });
 }

 // ICF entry point function.
 template <class ELFT> void elf::doIcf() { ICF<ELFT>().run(); }

 template void elf::doIcf<ELF32LE>();
 template void elf::doIcf<ELF32BE>();
 template void elf::doIcf<ELF64LE>();
 template void elf::doIcf<ELF64BE>();
	//===- ICF.cpp ------------------------------------------------------------===//
	//
	// The LLVM Linker
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// ICF is short for Identical Code Folding. This is a size optimization to
	// identify and merge two or more read-only sections (typically functions)
	// that happened to have the same contents. It usually reduces output size
	// by a few percent.
	//
	// In ICF, two sections are considered identical if they have the same
	// section flags, section data, and relocations. Relocations are tricky,
	// because two relocations are considered the same if they have the same
	// relocation types, values, and if they point to the same sections *in
	// terms of ICF*.
	//
	// Here is an example. If foo and bar defined below are compiled to the
	// same machine instructions, ICF can and should merge the two, although
	// their relocations point to each other.
	//
	// void foo() { bar(); }
	// void bar() { foo(); }
	//
	// If you merge the two, their relocations point to the same section and
	// thus you know they are mergeable, but how do you know they are
	// mergeable in the first place? This is not an easy problem to solve.
	//
	// What we are doing in LLD is to partition sections into equivalence
	// classes. Sections in the same equivalence class when the algorithm
	// terminates are considered identical. Here are details:
	//
	// 1. First, we partition sections using their hash values as keys. Hash
	// values contain section types, section contents and numbers of
	// relocations. During this step, relocation targets are not taken into
	// account. We just put sections that apparently differ into different
	// equivalence classes.
	//
	// 2. Next, for each equivalence class, we visit sections to compare
	// relocation targets. Relocation targets are considered equivalent if
	// their targets are in the same equivalence class. Sections with
	// different relocation targets are put into different equivalence
	// clases.
	//
	// 3. If we split an equivalence class in step 2, two relocations
	// previously target the same equivalence class may now target
	// different equivalence classes. Therefore, we repeat step 2 until a
	// convergence is obtained.
	//
	// 4. For each equivalence class C, pick an arbitrary section in C, and
	// merge all the other sections in C with it.
	//
	// For small programs, this algorithm needs 3-5 iterations. For large
	// programs such as Chromium, it takes more than 20 iterations.
	//
	// This algorithm was mentioned as an "optimistic algorithm" in [1],
	// though gold implements a different algorithm than this.
	//
	// We parallelize each step so that multiple threads can work on different
	// equivalence classes concurrently. That gave us a large performance
	// boost when applying ICF on large programs. For example, MSVC link.exe
	// or GNU gold takes 10-20 seconds to apply ICF on Chromium, whose output
	// size is about 1.5 GB, but LLD can finish it in less than 2 seconds on a
	// 2.8 GHz 40 core machine. Even without threading, LLD's ICF is still
	// faster than MSVC or gold though.
	//
	// [1] Safe ICF: Pointer Safe and Unwinding aware Identical Code Folding
	// in the Gold Linker
	// http://static.googleusercontent.com/media/research.google.com/en//pubs/archive/36912.pdf
	//
	//===----------------------------------------------------------------------===//

	#include "ICF.h"
	#include "Config.h"
	#include "SymbolTable.h"
	#include "Symbols.h"
	#include "SyntheticSections.h"
	#include "Writer.h"
	#include "lld/Common/Threads.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/BinaryFormat/ELF.h"
	#include "llvm/Object/ELF.h"
	#include "llvm/Support/xxhash.h"
	#include <algorithm>
	#include <atomic>

	using namespace lld;
	using namespace lld::elf;
	using namespace llvm;
	using namespace llvm::ELF;
	using namespace llvm::object;

	namespace {
	template <class ELFT> class ICF {
	public:
	void run();

	private:
	void segregate(size_t Begin, size_t End, bool Constant);

	template <class RelTy>
	bool constantEq(const InputSection *A, ArrayRef<RelTy> RelsA,
	const InputSection *B, ArrayRef<RelTy> RelsB);

	template <class RelTy>
	bool variableEq(const InputSection *A, ArrayRef<RelTy> RelsA,
	const InputSection *B, ArrayRef<RelTy> RelsB);

	bool equalsConstant(const InputSection A, const InputSection B);
	bool equalsVariable(const InputSection A, const InputSection B);

	size_t findBoundary(size_t Begin, size_t End);

	void forEachClassRange(size_t Begin, size_t End,
	llvm::function_ref<void(size_t, size_t)> Fn);

	void forEachClass(llvm::function_ref<void(size_t, size_t)> Fn);

	std::vector<InputSection *> Sections;

	// We repeat the main loop while `Repeat` is true.
	std::atomic<bool> Repeat;

	// The main loop counter.
	int Cnt = 0;

	// We have two locations for equivalence classes. On the first iteration
	// of the main loop, Class[0] has a valid value, and Class[1] contains
	// garbage. We read equivalence classes from slot 0 and write to slot 1.
	// So, Class[0] represents the current class, and Class[1] represents
	// the next class. On each iteration, we switch their roles and use them
	// alternately.
	//
	// Why are we doing this? Recall that other threads may be working on
	// other equivalence classes in parallel. They may read sections that we
	// are updating. We cannot update equivalence classes in place because
	// it breaks the invariance that all possibly-identical sections must be
	// in the same equivalence class at any moment. In other words, the for
	// loop to update equivalence classes is not atomic, and that is
	// observable from other threads. By writing new classes to other
	// places, we can keep the invariance.
	//
	// Below, `Current` has the index of the current class, and `Next` has
	// the index of the next class. If threading is enabled, they are either
	// (0, 1) or (1, 0).
	//
	// Note on single-thread: if that's the case, they are always (0, 0)
	// because we can safely read the next class without worrying about race
	// conditions. Using the same location makes this algorithm converge
	// faster because it uses results of the same iteration earlier.
	int Current = 0;
	int Next = 0;
	};
	}

	// Returns true if section S is subject of ICF.
	static bool isEligible(InputSection *S) {
	if (!S->Live \|\| S->KeepUnique \|\| !(S->Flags & SHF_ALLOC))
	return false;

	// Don't merge writable sections. .data.rel.ro sections are marked as writable
	// but are semantically read-only.
	if ((S->Flags & SHF_WRITE) && S->Name != ".data.rel.ro" &&
	!S->Name.startswith(".data.rel.ro."))
	return false;

	// SHF_LINK_ORDER sections are ICF'd as a unit with their dependent sections,
	// so we don't consider them for ICF individually.
	if (S->Flags & SHF_LINK_ORDER)
	return false;

	// Don't merge synthetic sections as their Data member is not valid and empty.
	// The Data member needs to be valid for ICF as it is used by ICF to determine
	// the equality of section contents.
	if (isa<SyntheticSection>(S))
	return false;

	// .init and .fini contains instructions that must be executed to initialize
	// and finalize the process. They cannot and should not be merged.
	if (S->Name == ".init" \|\| S->Name == ".fini")
	return false;

	// A user program may enumerate sections named with a C identifier using
	// __start_* and __stop_* symbols. We cannot ICF any such sections because
	// that could change program semantics.
	if (isValidCIdentifier(S->Name))
	return false;

	return true;
	}

	// Split an equivalence class into smaller classes.
	template <class ELFT>
	void ICF<ELFT>::segregate(size_t Begin, size_t End, bool Constant) {
	// This loop rearranges sections in [Begin, End) so that all sections
	// that are equal in terms of equals{Constant,Variable} are contiguous
	// in [Begin, End).
	//
	// The algorithm is quadratic in the worst case, but that is not an
	// issue in practice because the number of the distinct sections in
	// each range is usually very small.

	while (Begin < End) {
	// Divide [Begin, End) into two. Let Mid be the start index of the
	// second group.
	auto Bound =
	std::stable_partition(Sections.begin() + Begin + 1,
	Sections.begin() + End, [&](InputSection *S) {
	if (Constant)
	return equalsConstant(Sections[Begin], S);
	return equalsVariable(Sections[Begin], S);
	});
	size_t Mid = Bound - Sections.begin();

	// Now we split [Begin, End) into [Begin, Mid) and [Mid, End) by
	// updating the sections in [Begin, Mid). We use Mid as an equivalence
	// class ID because every group ends with a unique index.
	for (size_t I = Begin; I < Mid; ++I)
	Sections[I]->Class[Next] = Mid;

	// If we created a group, we need to iterate the main loop again.
	if (Mid != End)
	Repeat = true;

	Begin = Mid;
	}
	}

	// Compare two lists of relocations.
	template <class ELFT>
	template <class RelTy>
	bool ICF<ELFT>::constantEq(const InputSection *SecA, ArrayRef<RelTy> RA,
	const InputSection *SecB, ArrayRef<RelTy> RB) {
	for (size_t I = 0; I < RA.size(); ++I) {
	if (RA[I].r_offset != RB[I].r_offset \|\|
	RA[I].getType(Config->IsMips64EL) != RB[I].getType(Config->IsMips64EL))
	return false;

	uint64_t AddA = getAddend<ELFT>(RA[I]);
	uint64_t AddB = getAddend<ELFT>(RB[I]);

	Symbol &SA = SecA->template getFile<ELFT>()->getRelocTargetSym(RA[I]);
	Symbol &SB = SecB->template getFile<ELFT>()->getRelocTargetSym(RB[I]);
	if (&SA == &SB) {
	if (AddA == AddB)
	continue;
	return false;
	}

	auto *DA = dyn_cast<Defined>(&SA);
	auto *DB = dyn_cast<Defined>(&SB);
	if (!DA \|\| !DB)
	return false;

	// Relocations referring to absolute symbols are constant-equal if their
	// values are equal.
	if (!DA->Section && !DB->Section && DA->Value + AddA == DB->Value + AddB)
	continue;
	if (!DA->Section \|\| !DB->Section)
	return false;

	if (DA->Section->kind() != DB->Section->kind())
	return false;

	// Relocations referring to InputSections are constant-equal if their
	// section offsets are equal.
	if (isa<InputSection>(DA->Section)) {
	if (DA->Value + AddA == DB->Value + AddB)
	continue;
	return false;
	}

	// Relocations referring to MergeInputSections are constant-equal if their
	// offsets in the output section are equal.
	auto *X = dyn_cast<MergeInputSection>(DA->Section);
	if (!X)
	return false;
	auto *Y = cast<MergeInputSection>(DB->Section);
	if (X->getParent() != Y->getParent())
	return false;

	uint64_t OffsetA =
	SA.isSection() ? X->getOffset(AddA) : X->getOffset(DA->Value) + AddA;
	uint64_t OffsetB =
	SB.isSection() ? Y->getOffset(AddB) : Y->getOffset(DB->Value) + AddB;
	if (OffsetA != OffsetB)
	return false;
	}

	return true;
	}

	// Compare "non-moving" part of two InputSections, namely everything
	// except relocation targets.
	template <class ELFT>
	bool ICF<ELFT>::equalsConstant(const InputSection A, const InputSection B) {
	if (A->NumRelocations != B->NumRelocations \|\| A->Flags != B->Flags \|\|
	A->getSize() != B->getSize() \|\| A->Data != B->Data)
	return false;

	// If two sections have different output sections, we cannot merge them.
	// FIXME: This doesn't do the right thing in the case where there is a linker
	// script. We probably need to move output section assignment before ICF to
	// get the correct behaviour here.
	if (getOutputSectionName(A) != getOutputSectionName(B))
	return false;

	if (A->AreRelocsRela)
	return constantEq(A, A->template relas<ELFT>(), B,
	B->template relas<ELFT>());
	return constantEq(A, A->template rels<ELFT>(), B, B->template rels<ELFT>());
	}

	// Compare two lists of relocations. Returns true if all pairs of
	// relocations point to the same section in terms of ICF.
	template <class ELFT>
	template <class RelTy>
	bool ICF<ELFT>::variableEq(const InputSection *SecA, ArrayRef<RelTy> RA,
	const InputSection *SecB, ArrayRef<RelTy> RB) {
	assert(RA.size() == RB.size());

	for (size_t I = 0; I < RA.size(); ++I) {
	// The two sections must be identical.
	Symbol &SA = SecA->template getFile<ELFT>()->getRelocTargetSym(RA[I]);
	Symbol &SB = SecB->template getFile<ELFT>()->getRelocTargetSym(RB[I]);
	if (&SA == &SB)
	continue;

	auto *DA = cast<Defined>(&SA);
	auto *DB = cast<Defined>(&SB);

	// We already dealt with absolute and non-InputSection symbols in
	// constantEq, and for InputSections we have already checked everything
	// except the equivalence class.
	if (!DA->Section)
	continue;
	auto *X = dyn_cast<InputSection>(DA->Section);
	if (!X)
	continue;
	auto *Y = cast<InputSection>(DB->Section);

	// Ineligible sections are in the special equivalence class 0.
	// They can never be the same in terms of the equivalence class.
	if (X->Class[Current] == 0)
	return false;
	if (X->Class[Current] != Y->Class[Current])
	return false;
	};

	return true;
	}

	// Compare "moving" part of two InputSections, namely relocation targets.
	template <class ELFT>
	bool ICF<ELFT>::equalsVariable(const InputSection A, const InputSection B) {
	if (A->AreRelocsRela)
	return variableEq(A, A->template relas<ELFT>(), B,
	B->template relas<ELFT>());
	return variableEq(A, A->template rels<ELFT>(), B, B->template rels<ELFT>());
	}

	template <class ELFT> size_t ICF<ELFT>::findBoundary(size_t Begin, size_t End) {
	uint32_t Class = Sections[Begin]->Class[Current];
	for (size_t I = Begin + 1; I < End; ++I)
	if (Class != Sections[I]->Class[Current])
	return I;
	return End;
	}

	// Sections in the same equivalence class are contiguous in Sections
	// vector. Therefore, Sections vector can be considered as contiguous
	// groups of sections, grouped by the class.
	//
	// This function calls Fn on every group within [Begin, End).
	template <class ELFT>
	void ICF<ELFT>::forEachClassRange(size_t Begin, size_t End,
	llvm::function_ref<void(size_t, size_t)> Fn) {
	while (Begin < End) {
	size_t Mid = findBoundary(Begin, End);
	Fn(Begin, Mid);
	Begin = Mid;
	}
	}

	// Call Fn on each equivalence class.
	template <class ELFT>
	void ICF<ELFT>::forEachClass(llvm::function_ref<void(size_t, size_t)> Fn) {
	// If threading is disabled or the number of sections are
	// too small to use threading, call Fn sequentially.
	if (!ThreadsEnabled \|\| Sections.size() < 1024) {
	forEachClassRange(0, Sections.size(), Fn);
	++Cnt;
	return;
	}

	Current = Cnt % 2;
	Next = (Cnt + 1) % 2;

	// Shard into non-overlapping intervals, and call Fn in parallel.
	// The sharding must be completed before any calls to Fn are made
	// so that Fn can modify the Chunks in its shard without causing data
	// races.
	const size_t NumShards = 256;
	size_t Step = Sections.size() / NumShards;
	size_t Boundaries[NumShards + 1];
	Boundaries[0] = 0;
	Boundaries[NumShards] = Sections.size();

	parallelForEachN(1, NumShards, [&](size_t I) {
	Boundaries[I] = findBoundary((I - 1) * Step, Sections.size());
	});

	parallelForEachN(1, NumShards + 1, [&](size_t I) {
	if (Boundaries[I - 1] < Boundaries[I])
	forEachClassRange(Boundaries[I - 1], Boundaries[I], Fn);
	});
	++Cnt;
	}

	static void print(const Twine &S) {
	if (Config->PrintIcfSections)
	message(S);
	}

	// The main function of ICF.
	template <class ELFT> void ICF<ELFT>::run() {
	// Collect sections to merge.
	for (InputSectionBase *Sec : InputSections)
	if (auto *S = dyn_cast<InputSection>(Sec))
	if (isEligible(S))
	Sections.push_back(S);

	// Initially, we use hash values to partition sections.
	parallelForEach(Sections, [&](InputSection *S) {
	// Set MSB to 1 to avoid collisions with non-hash IDs.
	S->Class[0] = xxHash64(S->Data) \| (1U << 31);
	});

	// From now on, sections in Sections vector are ordered so that sections
	// in the same equivalence class are consecutive in the vector.
	std::stable_sort(Sections.begin(), Sections.end(),
	[](InputSection A, InputSection B) {
	return A->Class[0] < B->Class[0];
	});

	// Compare static contents and assign unique IDs for each static content.
	forEachClass([&](size_t Begin, size_t End) { segregate(Begin, End, true); });

	// Split groups by comparing relocations until convergence is obtained.
	do {
	Repeat = false;
	forEachClass(
	[&](size_t Begin, size_t End) { segregate(Begin, End, false); });
	} while (Repeat);

	log("ICF needed " + Twine(Cnt) + " iterations");

	// Merge sections by the equivalence class.
	forEachClassRange(0, Sections.size(), [&](size_t Begin, size_t End) {
	if (End - Begin == 1)
	return;
	print("selected section " + toString(Sections[Begin]));
	for (size_t I = Begin + 1; I < End; ++I) {
	print(" removing identical section " + toString(Sections[I]));
	Sections[Begin]->replace(Sections[I]);

	// At this point we know sections merged are fully identical and hence
	// we want to remove duplicate implicit dependencies such as link order
	// and relocation sections.
	for (InputSection *IS : Sections[I]->DependentSections)
	IS->Live = false;
	}
	});
	}

	// ICF entry point function.
	template <class ELFT> void elf::doIcf() { ICF<ELFT>().run(); }

	template void elf::doIcf<ELF32LE>();
	template void elf::doIcf<ELF32BE>();
	template void elf::doIcf<ELF64LE>();
	template void elf::doIcf<ELF64BE>();