lld/MachO/ConcatOutputSection.cpp - llvm-project - Git at Google

 //===- ConcatOutputSection.cpp --------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "ConcatOutputSection.h"
 #include "Config.h"
 #include "OutputSegment.h"
 #include "SymbolTable.h"
 #include "Symbols.h"
 #include "SyntheticSections.h"
 #include "Target.h"
 #include "lld/Common/ErrorHandler.h"
 #include "lld/Common/Memory.h"
 #include "llvm/BinaryFormat/MachO.h"
 #include "llvm/Support/ScopedPrinter.h"
 #include "llvm/Support/TimeProfiler.h"

 using namespace llvm;
 using namespace llvm::MachO;
 using namespace lld;
 using namespace lld::macho;

 MapVector<NamePair, ConcatOutputSection *> macho::concatOutputSections;

 void ConcatOutputSection::addInput(ConcatInputSection *input) {
   assert(input->parent == this);
   if (inputs.empty()) {
     align = input->align;
     flags = input->getFlags();
   } else {
     align = std::max(align, input->align);
     finalizeFlags(input);
   }
   inputs.push_back(input);
 }

 // Branch-range extension can be implemented in two ways, either through ...
 //
 // (1) Branch islands: Single branch instructions (also of limited range),
 //     that might be chained in multiple hops to reach the desired
 //     destination. On ARM64, as 16 branch islands are needed to hop between
 //     opposite ends of a 2 GiB program. LD64 uses branch islands exclusively,
 //     even when it needs excessive hops.
 //
 // (2) Thunks: Instruction(s) to load the destination address into a scratch
 //     register, followed by a register-indirect branch. Thunks are
 //     constructed to reach any arbitrary address, so need not be
 //     chained. Although thunks need not be chained, a program might need
 //     multiple thunks to the same destination distributed throughout a large
 //     program so that all call sites can have one within range.
 //
 // The optimal approach is to mix islands for destinations within two hops,
 // and use thunks for destinations at greater distance. For now, we only
 // implement thunks. TODO: Adding support for branch islands!
 //
 // Internally -- as expressed in LLD's data structures -- a
 // branch-range-extension thunk comprises ...
 //
 // (1) new Defined privateExtern symbol for the thunk named
 //     <FUNCTION>.thunk.<SEQUENCE>, which references ...
 // (2) new InputSection, which contains ...
 // (3.1) new data for the instructions to load & branch to the far address +
 // (3.2) new Relocs on instructions to load the far address, which reference ...
 // (4.1) existing Defined extern symbol for the real function in __text, or
 // (4.2) existing DylibSymbol for the real function in a dylib
 //
 // Nearly-optimal thunk-placement algorithm features:
 //
 // * Single pass: O(n) on the number of call sites.
 //
 // * Accounts for the exact space overhead of thunks - no heuristics
 //
 // * Exploits the full range of call instructions - forward & backward
 //
 // Data:
 //
 // * DenseMap<Symbol *, ThunkInfo> thunkMap: Maps the function symbol
 //   to its thunk bookkeeper.
 //
 // * struct ThunkInfo (bookkeeper): Call instructions have limited range, and
 //   distant call sites might be unable to reach the same thunk, so multiple
 //   thunks are necessary to serve all call sites in a very large program. A
 //   thunkInfo stores state for all thunks associated with a particular
 //   function: (a) thunk symbol, (b) input section containing stub code, and
 //   (c) sequence number for the active thunk incarnation. When an old thunk
 //   goes out of range, we increment the sequence number and create a new
 //   thunk named <FUNCTION>.thunk.<SEQUENCE>.
 //
 // * A thunk incarnation comprises (a) private-extern Defined symbol pointing
 //   to (b) an InputSection holding machine instructions (similar to a MachO
 //   stub), and (c) Reloc(s) that reference the real function for fixing-up
 //   the stub code.
 //
 // * std::vector<InputSection *> MergedInputSection::thunks: A vector parallel
 //   to the inputs vector. We store new thunks via cheap vector append, rather
 //   than costly insertion into the inputs vector.
 //
 // Control Flow:
 //
 // * During address assignment, MergedInputSection::finalize() examines call
 //   sites by ascending address and creates thunks.  When a function is beyond
 //   the range of a call site, we need a thunk. Place it at the largest
 //   available forward address from the call site. Call sites increase
 //   monotonically and thunks are always placed as far forward as possible;
 //   thus, we place thunks at monotonically increasing addresses. Once a thunk
 //   is placed, it and all previous input-section addresses are final.
 //
 // * ConcatInputSection::finalize() and ConcatInputSection::writeTo() merge
 //   the inputs and thunks vectors (both ordered by ascending address), which
 //   is simple and cheap.

 DenseMap<Symbol *, ThunkInfo> lld::macho::thunkMap;

 // Determine whether we need thunks, which depends on the target arch -- RISC
 // (i.e., ARM) generally does because it has limited-range branch/call
 // instructions, whereas CISC (i.e., x86) generally doesn't. RISC only needs
 // thunks for programs so large that branch source & destination addresses
 // might differ more than the range of branch instruction(s).
 bool ConcatOutputSection::needsThunks() const {
   if (!target->usesThunks())
     return false;
   uint64_t isecAddr = addr;
   for (InputSection *isec : inputs)
     isecAddr = alignTo(isecAddr, isec->align) + isec->getSize();
   if (isecAddr - addr + in.stubs->getSize() <=
       std::min(target->backwardBranchRange, target->forwardBranchRange))
     return false;
   // Yes, this program is large enough to need thunks.
   for (InputSection *isec : inputs) {
     for (Reloc &r : isec->relocs) {
       if (!target->hasAttr(r.type, RelocAttrBits::BRANCH))
         continue;
       auto *sym = r.referent.get<Symbol *>();
       // Pre-populate the thunkMap and memoize call site counts for every
       // InputSection and ThunkInfo. We do this for the benefit of
       // ConcatOutputSection::estimateStubsInRangeVA()
       ThunkInfo &thunkInfo = thunkMap[sym];
       // Knowing ThunkInfo call site count will help us know whether or not we
       // might need to create more for this referent at the time we are
       // estimating distance to __stubs in estimateStubsInRangeVA().
       ++thunkInfo.callSiteCount;
       // Knowing InputSection call site count will help us avoid work on those
       // that have no BRANCH relocs.
       ++isec->callSiteCount;
     }
   }
   return true;
 }

 // Since __stubs is placed after __text, we must estimate the address
 // beyond which stubs are within range of a simple forward branch.
 // This is called exactly once, when the last input section has been finalized.
 uint64_t ConcatOutputSection::estimateStubsInRangeVA(size_t callIdx) const {
   // Tally the functions which still have call sites remaining to process,
   // which yields the maximum number of thunks we might yet place.
   size_t maxPotentialThunks = 0;
   for (auto &tp : thunkMap) {
     ThunkInfo &ti = tp.second;
     // This overcounts: Only sections that are in forward jump range from the
     // currently-active section get finalized, and all input sections are
     // finalized when estimateStubsInRangeVA() is called. So only backward
     // jumps will need thunks, but we count all jumps.
     if (ti.callSitesUsed < ti.callSiteCount)
       maxPotentialThunks += 1;
   }
   // Tally the total size of input sections remaining to process.
   uint64_t isecVA = inputs[callIdx]->getVA();
   uint64_t isecEnd = isecVA;
   for (size_t i = callIdx; i < inputs.size(); i++) {
     InputSection *isec = inputs[i];
     isecEnd = alignTo(isecEnd, isec->align) + isec->getSize();
   }
   // Estimate the address after which call sites can safely call stubs
   // directly rather than through intermediary thunks.
   uint64_t forwardBranchRange = target->forwardBranchRange;
   assert(isecEnd > forwardBranchRange &&
          "should not run thunk insertion if all code fits in jump range");
   assert(isecEnd - isecVA <= forwardBranchRange &&
          "should only finalize sections in jump range");
   uint64_t stubsInRangeVA = isecEnd + maxPotentialThunks * target->thunkSize +
                             in.stubs->getSize() - forwardBranchRange;
   log("thunks = " + std::to_string(thunkMap.size()) +
       ", potential = " + std::to_string(maxPotentialThunks) +
       ", stubs = " + std::to_string(in.stubs->getSize()) + ", isecVA = " +
       to_hexString(isecVA) + ", threshold = " + to_hexString(stubsInRangeVA) +
       ", isecEnd = " + to_hexString(isecEnd) +
       ", tail = " + to_hexString(isecEnd - isecVA) +
       ", slop = " + to_hexString(forwardBranchRange - (isecEnd - isecVA)));
   return stubsInRangeVA;
 }

 void ConcatOutputSection::finalize() {
   uint64_t isecAddr = addr;
   uint64_t isecFileOff = fileOff;
   auto finalizeOne = [&](ConcatInputSection *isec) {
     isecAddr = alignTo(isecAddr, isec->align);
     isecFileOff = alignTo(isecFileOff, isec->align);
     isec->outSecOff = isecAddr - addr;
     isec->isFinal = true;
     isecAddr += isec->getSize();
     isecFileOff += isec->getFileSize();
   };

   if (!needsThunks()) {
     for (ConcatInputSection *isec : inputs)
       finalizeOne(isec);
     size = isecAddr - addr;
     fileSize = isecFileOff - fileOff;
     return;
   }

   uint64_t forwardBranchRange = target->forwardBranchRange;
   uint64_t backwardBranchRange = target->backwardBranchRange;
   uint64_t stubsInRangeVA = TargetInfo::outOfRangeVA;
   size_t thunkSize = target->thunkSize;
   size_t relocCount = 0;
   size_t callSiteCount = 0;
   size_t thunkCallCount = 0;
   size_t thunkCount = 0;

   // Walk all sections in order. Finalize all sections that are less than
   // forwardBranchRange in front of it.
   // isecVA is the address of the current section.
   // isecAddr is the start address of the first non-finalized section.

   // inputs[finalIdx] is for finalization (address-assignment)
   size_t finalIdx = 0;
   // Kick-off by ensuring that the first input section has an address
   for (size_t callIdx = 0, endIdx = inputs.size(); callIdx < endIdx;
        ++callIdx) {
     if (finalIdx == callIdx)
       finalizeOne(inputs[finalIdx++]);
     ConcatInputSection *isec = inputs[callIdx];
     assert(isec->isFinal);
     uint64_t isecVA = isec->getVA();

     // Assign addresses up-to the forward branch-range limit.
     // Every call instruction needs a small number of bytes (on Arm64: 4),
     // and each inserted thunk needs a slightly larger number of bytes
     // (on Arm64: 12). If a section starts with a branch instruction and
     // contains several branch instructions in succession, then the distance
     // from the current position to the position where the thunks are inserted
     // grows. So leave room for a bunch of thunks.
     unsigned slop = 100 * thunkSize;
     while (finalIdx < endIdx && isecAddr + inputs[finalIdx]->getSize() <
                                     isecVA + forwardBranchRange - slop)
       finalizeOne(inputs[finalIdx++]);

     if (isec->callSiteCount == 0)
       continue;

     if (finalIdx == endIdx && stubsInRangeVA == TargetInfo::outOfRangeVA) {
       // When we have finalized all input sections, __stubs (destined
       // to follow __text) comes within range of forward branches and
       // we can estimate the threshold address after which we can
       // reach any stub with a forward branch. Note that although it
       // sits in the middle of a loop, this code executes only once.
       // It is in the loop because we need to call it at the proper
       // time: the earliest call site from which the end of __text
       // (and start of __stubs) comes within range of a forward branch.
       stubsInRangeVA = estimateStubsInRangeVA(callIdx);
     }
     // Process relocs by ascending address, i.e., ascending offset within isec
     std::vector<Reloc> &relocs = isec->relocs;
     // FIXME: This property does not hold for object files produced by ld64's
     // `-r` mode.
     assert(is_sorted(relocs,
                      [](Reloc &a, Reloc &b) { return a.offset > b.offset; }));
     for (Reloc &r : reverse(relocs)) {
       ++relocCount;
       if (!target->hasAttr(r.type, RelocAttrBits::BRANCH))
         continue;
       ++callSiteCount;
       // Calculate branch reachability boundaries
       uint64_t callVA = isecVA + r.offset;
       uint64_t lowVA =
           backwardBranchRange < callVA ? callVA - backwardBranchRange : 0;
       uint64_t highVA = callVA + forwardBranchRange;
       // Calculate our call referent address
       auto *funcSym = r.referent.get<Symbol *>();
       ThunkInfo &thunkInfo = thunkMap[funcSym];
       // The referent is not reachable, so we need to use a thunk ...
       if (funcSym->isInStubs() && callVA >= stubsInRangeVA) {
         assert(callVA != TargetInfo::outOfRangeVA);
         // ... Oh, wait! We are close enough to the end that __stubs
         // are now within range of a simple forward branch.
         continue;
       }
       uint64_t funcVA = funcSym->resolveBranchVA();
       ++thunkInfo.callSitesUsed;
       if (lowVA <= funcVA && funcVA <= highVA) {
         // The referent is reachable with a simple call instruction.
         continue;
       }
       ++thunkInfo.thunkCallCount;
       ++thunkCallCount;
       // If an existing thunk is reachable, use it ...
       if (thunkInfo.sym) {
         uint64_t thunkVA = thunkInfo.isec->getVA();
         if (lowVA <= thunkVA && thunkVA <= highVA) {
           r.referent = thunkInfo.sym;
           continue;
         }
       }
       // ... otherwise, create a new thunk.
       if (isecAddr > highVA) {
         // There were too many consecutive branch instructions for `slop`
         // above. If you hit this: For the current algorithm, just bumping up
         // slop above and trying again is probably simplest. (See also PR51578
         // comment 5).
         fatal(Twine(__FUNCTION__) + ": FIXME: thunk range overrun");
       }
       thunkInfo.isec =
           make<ConcatInputSection>(isec->getSegName(), isec->getName());
       thunkInfo.isec->parent = this;

       // This code runs after dead code removal. Need to set the `live` bit
       // on the thunk isec so that asserts that check that only live sections
       // get written are happy.
       thunkInfo.isec->live = true;

       StringRef thunkName = saver.save(funcSym->getName() + ".thunk." +
                                        std::to_string(thunkInfo.sequence++));
       r.referent = thunkInfo.sym = symtab->addDefined(
           thunkName, /*file=*/nullptr, thunkInfo.isec, /*value=*/0,
           /*size=*/thunkSize, /*isWeakDef=*/false, /*isPrivateExtern=*/true,
           /*isThumb=*/false, /*isReferencedDynamically=*/false,
           /*noDeadStrip=*/false, /*isWeakDefCanBeHidden=*/false);
       thunkInfo.sym->used = true;
       target->populateThunk(thunkInfo.isec, funcSym);
       finalizeOne(thunkInfo.isec);
       thunks.push_back(thunkInfo.isec);
       ++thunkCount;
     }
   }
   size = isecAddr - addr;
   fileSize = isecFileOff - fileOff;

   log("thunks for " + parent->name + "," + name +
       ": funcs = " + std::to_string(thunkMap.size()) +
       ", relocs = " + std::to_string(relocCount) +
       ", all calls = " + std::to_string(callSiteCount) +
       ", thunk calls = " + std::to_string(thunkCallCount) +
       ", thunks = " + std::to_string(thunkCount));
 }

 void ConcatOutputSection::writeTo(uint8_t *buf) const {
   // Merge input sections from thunk & ordinary vectors
   size_t i = 0, ie = inputs.size();
   size_t t = 0, te = thunks.size();
   while (i < ie || t < te) {
     while (i < ie && (t == te || inputs[i]->empty() ||
                       inputs[i]->outSecOff < thunks[t]->outSecOff)) {
       inputs[i]->writeTo(buf + inputs[i]->outSecOff);
       ++i;
     }
     while (t < te && (i == ie || thunks[t]->outSecOff < inputs[i]->outSecOff)) {
       thunks[t]->writeTo(buf + thunks[t]->outSecOff);
       ++t;
     }
   }
 }

 void ConcatOutputSection::finalizeFlags(InputSection *input) {
   switch (sectionType(input->getFlags())) {
   default /*type-unspec'ed*/:
     // FIXME: Add additional logic here when supporting emitting obj files.
     break;
   case S_4BYTE_LITERALS:
   case S_8BYTE_LITERALS:
   case S_16BYTE_LITERALS:
   case S_CSTRING_LITERALS:
   case S_ZEROFILL:
   case S_LAZY_SYMBOL_POINTERS:
   case S_MOD_TERM_FUNC_POINTERS:
   case S_THREAD_LOCAL_REGULAR:
   case S_THREAD_LOCAL_ZEROFILL:
   case S_THREAD_LOCAL_VARIABLES:
   case S_THREAD_LOCAL_INIT_FUNCTION_POINTERS:
   case S_THREAD_LOCAL_VARIABLE_POINTERS:
   case S_NON_LAZY_SYMBOL_POINTERS:
   case S_SYMBOL_STUBS:
     flags |= input->getFlags();
     break;
   }
 }

 ConcatOutputSection *
 ConcatOutputSection::getOrCreateForInput(const InputSection *isec) {
   NamePair names = maybeRenameSection({isec->getSegName(), isec->getName()});
   ConcatOutputSection *&osec = concatOutputSections[names];
   if (!osec)
     osec = make<ConcatOutputSection>(names.second);
   return osec;
 }

 NamePair macho::maybeRenameSection(NamePair key) {
   auto newNames = config->sectionRenameMap.find(key);
   if (newNames != config->sectionRenameMap.end())
     return newNames->second;
   return key;
 }
	//===- ConcatOutputSection.cpp --------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "ConcatOutputSection.h"
	#include "Config.h"
	#include "OutputSegment.h"
	#include "SymbolTable.h"
	#include "Symbols.h"
	#include "SyntheticSections.h"
	#include "Target.h"
	#include "lld/Common/ErrorHandler.h"
	#include "lld/Common/Memory.h"
	#include "llvm/BinaryFormat/MachO.h"
	#include "llvm/Support/ScopedPrinter.h"
	#include "llvm/Support/TimeProfiler.h"

	using namespace llvm;
	using namespace llvm::MachO;
	using namespace lld;
	using namespace lld::macho;

	MapVector<NamePair, ConcatOutputSection *> macho::concatOutputSections;

	void ConcatOutputSection::addInput(ConcatInputSection *input) {
	assert(input->parent == this);
	if (inputs.empty()) {
	align = input->align;
	flags = input->getFlags();
	} else {
	align = std::max(align, input->align);
	finalizeFlags(input);
	}
	inputs.push_back(input);
	}

	// Branch-range extension can be implemented in two ways, either through ...
	//
	// (1) Branch islands: Single branch instructions (also of limited range),
	// that might be chained in multiple hops to reach the desired
	// destination. On ARM64, as 16 branch islands are needed to hop between
	// opposite ends of a 2 GiB program. LD64 uses branch islands exclusively,
	// even when it needs excessive hops.
	//
	// (2) Thunks: Instruction(s) to load the destination address into a scratch
	// register, followed by a register-indirect branch. Thunks are
	// constructed to reach any arbitrary address, so need not be
	// chained. Although thunks need not be chained, a program might need
	// multiple thunks to the same destination distributed throughout a large
	// program so that all call sites can have one within range.
	//
	// The optimal approach is to mix islands for destinations within two hops,
	// and use thunks for destinations at greater distance. For now, we only
	// implement thunks. TODO: Adding support for branch islands!
	//
	// Internally -- as expressed in LLD's data structures -- a
	// branch-range-extension thunk comprises ...
	//
	// (1) new Defined privateExtern symbol for the thunk named
	// <FUNCTION>.thunk.<SEQUENCE>, which references ...
	// (2) new InputSection, which contains ...
	// (3.1) new data for the instructions to load & branch to the far address +
	// (3.2) new Relocs on instructions to load the far address, which reference ...
	// (4.1) existing Defined extern symbol for the real function in __text, or
	// (4.2) existing DylibSymbol for the real function in a dylib
	//
	// Nearly-optimal thunk-placement algorithm features:
	//
	// * Single pass: O(n) on the number of call sites.
	//
	// * Accounts for the exact space overhead of thunks - no heuristics
	//
	// * Exploits the full range of call instructions - forward & backward
	//
	// Data:
	//
	// * DenseMap<Symbol *, ThunkInfo> thunkMap: Maps the function symbol
	// to its thunk bookkeeper.
	//
	// * struct ThunkInfo (bookkeeper): Call instructions have limited range, and
	// distant call sites might be unable to reach the same thunk, so multiple
	// thunks are necessary to serve all call sites in a very large program. A
	// thunkInfo stores state for all thunks associated with a particular
	// function: (a) thunk symbol, (b) input section containing stub code, and
	// (c) sequence number for the active thunk incarnation. When an old thunk
	// goes out of range, we increment the sequence number and create a new
	// thunk named <FUNCTION>.thunk.<SEQUENCE>.
	//
	// * A thunk incarnation comprises (a) private-extern Defined symbol pointing
	// to (b) an InputSection holding machine instructions (similar to a MachO
	// stub), and (c) Reloc(s) that reference the real function for fixing-up
	// the stub code.
	//
	// * std::vector<InputSection *> MergedInputSection::thunks: A vector parallel
	// to the inputs vector. We store new thunks via cheap vector append, rather
	// than costly insertion into the inputs vector.
	//
	// Control Flow:
	//
	// * During address assignment, MergedInputSection::finalize() examines call
	// sites by ascending address and creates thunks. When a function is beyond
	// the range of a call site, we need a thunk. Place it at the largest
	// available forward address from the call site. Call sites increase
	// monotonically and thunks are always placed as far forward as possible;
	// thus, we place thunks at monotonically increasing addresses. Once a thunk
	// is placed, it and all previous input-section addresses are final.
	//
	// * ConcatInputSection::finalize() and ConcatInputSection::writeTo() merge
	// the inputs and thunks vectors (both ordered by ascending address), which
	// is simple and cheap.

	DenseMap<Symbol *, ThunkInfo> lld::macho::thunkMap;

	// Determine whether we need thunks, which depends on the target arch -- RISC
	// (i.e., ARM) generally does because it has limited-range branch/call
	// instructions, whereas CISC (i.e., x86) generally doesn't. RISC only needs
	// thunks for programs so large that branch source & destination addresses
	// might differ more than the range of branch instruction(s).
	bool ConcatOutputSection::needsThunks() const {
	if (!target->usesThunks())
	return false;
	uint64_t isecAddr = addr;
	for (InputSection *isec : inputs)
	isecAddr = alignTo(isecAddr, isec->align) + isec->getSize();
	if (isecAddr - addr + in.stubs->getSize() <=
	std::min(target->backwardBranchRange, target->forwardBranchRange))
	return false;
	// Yes, this program is large enough to need thunks.
	for (InputSection *isec : inputs) {
	for (Reloc &r : isec->relocs) {
	if (!target->hasAttr(r.type, RelocAttrBits::BRANCH))
	continue;
	auto sym = r.referent.get<Symbol >();
	// Pre-populate the thunkMap and memoize call site counts for every
	// InputSection and ThunkInfo. We do this for the benefit of
	// ConcatOutputSection::estimateStubsInRangeVA()
	ThunkInfo &thunkInfo = thunkMap[sym];
	// Knowing ThunkInfo call site count will help us know whether or not we
	// might need to create more for this referent at the time we are
	// estimating distance to __stubs in estimateStubsInRangeVA().
	++thunkInfo.callSiteCount;
	// Knowing InputSection call site count will help us avoid work on those
	// that have no BRANCH relocs.
	++isec->callSiteCount;
	}
	}
	return true;
	}

	// Since __stubs is placed after __text, we must estimate the address
	// beyond which stubs are within range of a simple forward branch.
	// This is called exactly once, when the last input section has been finalized.
	uint64_t ConcatOutputSection::estimateStubsInRangeVA(size_t callIdx) const {
	// Tally the functions which still have call sites remaining to process,
	// which yields the maximum number of thunks we might yet place.
	size_t maxPotentialThunks = 0;
	for (auto &tp : thunkMap) {
	ThunkInfo &ti = tp.second;
	// This overcounts: Only sections that are in forward jump range from the
	// currently-active section get finalized, and all input sections are
	// finalized when estimateStubsInRangeVA() is called. So only backward
	// jumps will need thunks, but we count all jumps.
	if (ti.callSitesUsed < ti.callSiteCount)
	maxPotentialThunks += 1;
	}
	// Tally the total size of input sections remaining to process.
	uint64_t isecVA = inputs[callIdx]->getVA();
	uint64_t isecEnd = isecVA;
	for (size_t i = callIdx; i < inputs.size(); i++) {
	InputSection *isec = inputs[i];
	isecEnd = alignTo(isecEnd, isec->align) + isec->getSize();
	}
	// Estimate the address after which call sites can safely call stubs
	// directly rather than through intermediary thunks.
	uint64_t forwardBranchRange = target->forwardBranchRange;
	assert(isecEnd > forwardBranchRange &&
	"should not run thunk insertion if all code fits in jump range");
	assert(isecEnd - isecVA <= forwardBranchRange &&
	"should only finalize sections in jump range");
	uint64_t stubsInRangeVA = isecEnd + maxPotentialThunks * target->thunkSize +
	in.stubs->getSize() - forwardBranchRange;
	log("thunks = " + std::to_string(thunkMap.size()) +
	", potential = " + std::to_string(maxPotentialThunks) +
	", stubs = " + std::to_string(in.stubs->getSize()) + ", isecVA = " +
	to_hexString(isecVA) + ", threshold = " + to_hexString(stubsInRangeVA) +
	", isecEnd = " + to_hexString(isecEnd) +
	", tail = " + to_hexString(isecEnd - isecVA) +
	", slop = " + to_hexString(forwardBranchRange - (isecEnd - isecVA)));
	return stubsInRangeVA;
	}

	void ConcatOutputSection::finalize() {
	uint64_t isecAddr = addr;
	uint64_t isecFileOff = fileOff;
	auto finalizeOne = [&](ConcatInputSection *isec) {
	isecAddr = alignTo(isecAddr, isec->align);
	isecFileOff = alignTo(isecFileOff, isec->align);
	isec->outSecOff = isecAddr - addr;
	isec->isFinal = true;
	isecAddr += isec->getSize();
	isecFileOff += isec->getFileSize();
	};

	if (!needsThunks()) {
	for (ConcatInputSection *isec : inputs)
	finalizeOne(isec);
	size = isecAddr - addr;
	fileSize = isecFileOff - fileOff;
	return;
	}

	uint64_t forwardBranchRange = target->forwardBranchRange;
	uint64_t backwardBranchRange = target->backwardBranchRange;
	uint64_t stubsInRangeVA = TargetInfo::outOfRangeVA;
	size_t thunkSize = target->thunkSize;
	size_t relocCount = 0;
	size_t callSiteCount = 0;
	size_t thunkCallCount = 0;
	size_t thunkCount = 0;

	// Walk all sections in order. Finalize all sections that are less than
	// forwardBranchRange in front of it.
	// isecVA is the address of the current section.
	// isecAddr is the start address of the first non-finalized section.

	// inputs[finalIdx] is for finalization (address-assignment)
	size_t finalIdx = 0;
	// Kick-off by ensuring that the first input section has an address
	for (size_t callIdx = 0, endIdx = inputs.size(); callIdx < endIdx;
	++callIdx) {
	if (finalIdx == callIdx)
	finalizeOne(inputs[finalIdx++]);
	ConcatInputSection *isec = inputs[callIdx];
	assert(isec->isFinal);
	uint64_t isecVA = isec->getVA();

	// Assign addresses up-to the forward branch-range limit.
	// Every call instruction needs a small number of bytes (on Arm64: 4),
	// and each inserted thunk needs a slightly larger number of bytes
	// (on Arm64: 12). If a section starts with a branch instruction and
	// contains several branch instructions in succession, then the distance
	// from the current position to the position where the thunks are inserted
	// grows. So leave room for a bunch of thunks.
	unsigned slop = 100 * thunkSize;
	while (finalIdx < endIdx && isecAddr + inputs[finalIdx]->getSize() <
	isecVA + forwardBranchRange - slop)
	finalizeOne(inputs[finalIdx++]);

	if (isec->callSiteCount == 0)
	continue;

	if (finalIdx == endIdx && stubsInRangeVA == TargetInfo::outOfRangeVA) {
	// When we have finalized all input sections, __stubs (destined
	// to follow __text) comes within range of forward branches and
	// we can estimate the threshold address after which we can
	// reach any stub with a forward branch. Note that although it
	// sits in the middle of a loop, this code executes only once.
	// It is in the loop because we need to call it at the proper
	// time: the earliest call site from which the end of __text
	// (and start of __stubs) comes within range of a forward branch.
	stubsInRangeVA = estimateStubsInRangeVA(callIdx);
	}
	// Process relocs by ascending address, i.e., ascending offset within isec
	std::vector<Reloc> &relocs = isec->relocs;
	// FIXME: This property does not hold for object files produced by ld64's
	// `-r` mode.
	assert(is_sorted(relocs,
	[](Reloc &a, Reloc &b) { return a.offset > b.offset; }));
	for (Reloc &r : reverse(relocs)) {
	++relocCount;
	if (!target->hasAttr(r.type, RelocAttrBits::BRANCH))
	continue;
	++callSiteCount;
	// Calculate branch reachability boundaries
	uint64_t callVA = isecVA + r.offset;
	uint64_t lowVA =
	backwardBranchRange < callVA ? callVA - backwardBranchRange : 0;
	uint64_t highVA = callVA + forwardBranchRange;
	// Calculate our call referent address
	auto funcSym = r.referent.get<Symbol >();
	ThunkInfo &thunkInfo = thunkMap[funcSym];
	// The referent is not reachable, so we need to use a thunk ...
	if (funcSym->isInStubs() && callVA >= stubsInRangeVA) {
	assert(callVA != TargetInfo::outOfRangeVA);
	// ... Oh, wait! We are close enough to the end that __stubs
	// are now within range of a simple forward branch.
	continue;
	}
	uint64_t funcVA = funcSym->resolveBranchVA();
	++thunkInfo.callSitesUsed;
	if (lowVA <= funcVA && funcVA <= highVA) {
	// The referent is reachable with a simple call instruction.
	continue;
	}
	++thunkInfo.thunkCallCount;
	++thunkCallCount;
	// If an existing thunk is reachable, use it ...
	if (thunkInfo.sym) {
	uint64_t thunkVA = thunkInfo.isec->getVA();
	if (lowVA <= thunkVA && thunkVA <= highVA) {
	r.referent = thunkInfo.sym;
	continue;
	}
	}
	// ... otherwise, create a new thunk.
	if (isecAddr > highVA) {
	// There were too many consecutive branch instructions for `slop`
	// above. If you hit this: For the current algorithm, just bumping up
	// slop above and trying again is probably simplest. (See also PR51578
	// comment 5).
	fatal(Twine(__FUNCTION__) + ": FIXME: thunk range overrun");
	}
	thunkInfo.isec =
	make<ConcatInputSection>(isec->getSegName(), isec->getName());
	thunkInfo.isec->parent = this;

	// This code runs after dead code removal. Need to set the `live` bit
	// on the thunk isec so that asserts that check that only live sections
	// get written are happy.
	thunkInfo.isec->live = true;

	StringRef thunkName = saver.save(funcSym->getName() + ".thunk." +
	std::to_string(thunkInfo.sequence++));
	r.referent = thunkInfo.sym = symtab->addDefined(
	thunkName, /file=/nullptr, thunkInfo.isec, /value=/0,
	/size=/thunkSize, /isWeakDef=/false, /isPrivateExtern=/true,
	/isThumb=/false, /isReferencedDynamically=/false,
	/noDeadStrip=/false, /isWeakDefCanBeHidden=/false);
	thunkInfo.sym->used = true;
	target->populateThunk(thunkInfo.isec, funcSym);
	finalizeOne(thunkInfo.isec);
	thunks.push_back(thunkInfo.isec);
	++thunkCount;
	}
	}
	size = isecAddr - addr;
	fileSize = isecFileOff - fileOff;

	log("thunks for " + parent->name + "," + name +
	": funcs = " + std::to_string(thunkMap.size()) +
	", relocs = " + std::to_string(relocCount) +
	", all calls = " + std::to_string(callSiteCount) +
	", thunk calls = " + std::to_string(thunkCallCount) +
	", thunks = " + std::to_string(thunkCount));
	}

	void ConcatOutputSection::writeTo(uint8_t *buf) const {
	// Merge input sections from thunk & ordinary vectors
	size_t i = 0, ie = inputs.size();
	size_t t = 0, te = thunks.size();
	while (i < ie \|\| t < te) {
	while (i < ie && (t == te \|\| inputs[i]->empty() \|\|
	inputs[i]->outSecOff < thunks[t]->outSecOff)) {
	inputs[i]->writeTo(buf + inputs[i]->outSecOff);
	++i;
	}
	while (t < te && (i == ie \|\| thunks[t]->outSecOff < inputs[i]->outSecOff)) {
	thunks[t]->writeTo(buf + thunks[t]->outSecOff);
	++t;
	}
	}
	}

	void ConcatOutputSection::finalizeFlags(InputSection *input) {
	switch (sectionType(input->getFlags())) {
	default /type-unspec'ed/:
	// FIXME: Add additional logic here when supporting emitting obj files.
	break;
	case S_4BYTE_LITERALS:
	case S_8BYTE_LITERALS:
	case S_16BYTE_LITERALS:
	case S_CSTRING_LITERALS:
	case S_ZEROFILL:
	case S_LAZY_SYMBOL_POINTERS:
	case S_MOD_TERM_FUNC_POINTERS:
	case S_THREAD_LOCAL_REGULAR:
	case S_THREAD_LOCAL_ZEROFILL:
	case S_THREAD_LOCAL_VARIABLES:
	case S_THREAD_LOCAL_INIT_FUNCTION_POINTERS:
	case S_THREAD_LOCAL_VARIABLE_POINTERS:
	case S_NON_LAZY_SYMBOL_POINTERS:
	case S_SYMBOL_STUBS:
	flags \|= input->getFlags();
	break;
	}
	}

	ConcatOutputSection *
	ConcatOutputSection::getOrCreateForInput(const InputSection *isec) {
	NamePair names = maybeRenameSection({isec->getSegName(), isec->getName()});
	ConcatOutputSection *&osec = concatOutputSections[names];
	if (!osec)
	osec = make<ConcatOutputSection>(names.second);
	return osec;
	}

	NamePair macho::maybeRenameSection(NamePair key) {
	auto newNames = config->sectionRenameMap.find(key);
	if (newNames != config->sectionRenameMap.end())
	return newNames->second;
	return key;
	}