llvm-project/lld/lib/ReaderWriter/MachO/LayoutPass.cpp

489 lines
18 KiB
C++

//===-- ReaderWriter/MachO/LayoutPass.cpp - Layout atoms ------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "LayoutPass.h"
#include "lld/Core/Instrumentation.h"
#include "lld/Core/Parallel.h"
#include "lld/Core/PassManager.h"
#include "lld/ReaderWriter/MachOLinkingContext.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/Twine.h"
#include "llvm/Support/Debug.h"
#include <algorithm>
#include <set>
using namespace lld;
#define DEBUG_TYPE "LayoutPass"
namespace lld {
namespace mach_o {
static bool compareAtoms(const LayoutPass::SortKey &,
const LayoutPass::SortKey &,
LayoutPass::SortOverride customSorter);
#ifndef NDEBUG
// Return "reason (leftval, rightval)"
static std::string formatReason(StringRef reason, int leftVal, int rightVal) {
return (Twine(reason) + " (" + Twine(leftVal) + ", " + Twine(rightVal) + ")")
.str();
}
// Less-than relationship of two atoms must be transitive, which is, if a < b
// and b < c, a < c must be true. This function checks the transitivity by
// checking the sort results.
static void checkTransitivity(std::vector<LayoutPass::SortKey> &vec,
LayoutPass::SortOverride customSorter) {
for (auto i = vec.begin(), e = vec.end(); (i + 1) != e; ++i) {
for (auto j = i + 1; j != e; ++j) {
assert(compareAtoms(*i, *j, customSorter));
assert(!compareAtoms(*j, *i, customSorter));
}
}
}
// Helper functions to check follow-on graph.
typedef llvm::DenseMap<const DefinedAtom *, const DefinedAtom *> AtomToAtomT;
static std::string atomToDebugString(const Atom *atom) {
const DefinedAtom *definedAtom = dyn_cast<DefinedAtom>(atom);
std::string str;
llvm::raw_string_ostream s(str);
if (definedAtom->name().empty())
s << "<anonymous " << definedAtom << ">";
else
s << definedAtom->name();
s << " in ";
if (definedAtom->customSectionName().empty())
s << "<anonymous>";
else
s << definedAtom->customSectionName();
s.flush();
return str;
}
static void showCycleDetectedError(const Registry &registry,
AtomToAtomT &followOnNexts,
const DefinedAtom *atom) {
const DefinedAtom *start = atom;
llvm::dbgs() << "There's a cycle in a follow-on chain!\n";
do {
llvm::dbgs() << " " << atomToDebugString(atom) << "\n";
for (const Reference *ref : *atom) {
StringRef kindValStr;
if (!registry.referenceKindToString(ref->kindNamespace(), ref->kindArch(),
ref->kindValue(), kindValStr)) {
kindValStr = "<unknown>";
}
llvm::dbgs() << " " << kindValStr
<< ": " << atomToDebugString(ref->target()) << "\n";
}
atom = followOnNexts[atom];
} while (atom != start);
llvm::report_fatal_error("Cycle detected");
}
/// Exit if there's a cycle in a followon chain reachable from the
/// given root atom. Uses the tortoise and hare algorithm to detect a
/// cycle.
static void checkNoCycleInFollowonChain(const Registry &registry,
AtomToAtomT &followOnNexts,
const DefinedAtom *root) {
const DefinedAtom *tortoise = root;
const DefinedAtom *hare = followOnNexts[root];
while (true) {
if (!tortoise || !hare)
return;
if (tortoise == hare)
showCycleDetectedError(registry, followOnNexts, tortoise);
tortoise = followOnNexts[tortoise];
hare = followOnNexts[followOnNexts[hare]];
}
}
static void checkReachabilityFromRoot(AtomToAtomT &followOnRoots,
const DefinedAtom *atom) {
if (!atom) return;
auto i = followOnRoots.find(atom);
if (i == followOnRoots.end()) {
llvm_unreachable(((Twine("Atom <") + atomToDebugString(atom) +
"> has no follow-on root!"))
.str()
.c_str());
}
const DefinedAtom *ap = i->second;
while (true) {
const DefinedAtom *next = followOnRoots[ap];
if (!next) {
llvm_unreachable((Twine("Atom <" + atomToDebugString(atom) +
"> is not reachable from its root!"))
.str()
.c_str());
}
if (next == ap)
return;
ap = next;
}
}
static void printDefinedAtoms(const SimpleFile::DefinedAtomRange &atomRange) {
for (const DefinedAtom *atom : atomRange) {
llvm::dbgs() << " file=" << atom->file().path()
<< ", name=" << atom->name()
<< ", size=" << atom->size()
<< ", type=" << atom->contentType()
<< ", ordinal=" << atom->ordinal()
<< "\n";
}
}
/// Verify that the followon chain is sane. Should not be called in
/// release binary.
void LayoutPass::checkFollowonChain(const SimpleFile::DefinedAtomRange &range) {
ScopedTask task(getDefaultDomain(), "LayoutPass::checkFollowonChain");
// Verify that there's no cycle in follow-on chain.
std::set<const DefinedAtom *> roots;
for (const auto &ai : _followOnRoots)
roots.insert(ai.second);
for (const DefinedAtom *root : roots)
checkNoCycleInFollowonChain(_registry, _followOnNexts, root);
// Verify that all the atoms in followOnNexts have references to
// their roots.
for (const auto &ai : _followOnNexts) {
checkReachabilityFromRoot(_followOnRoots, ai.first);
checkReachabilityFromRoot(_followOnRoots, ai.second);
}
}
#endif // #ifndef NDEBUG
/// The function compares atoms by sorting atoms in the following order
/// a) Sorts atoms by their ordinal overrides (layout-after/ingroup)
/// b) Sorts atoms by their permissions
/// c) Sorts atoms by their content
/// d) Sorts atoms by custom sorter
/// e) Sorts atoms on how they appear using File Ordinality
/// f) Sorts atoms on how they appear within the File
static bool compareAtomsSub(const LayoutPass::SortKey &lc,
const LayoutPass::SortKey &rc,
LayoutPass::SortOverride customSorter,
std::string &reason) {
const DefinedAtom *left = lc._atom.get();
const DefinedAtom *right = rc._atom.get();
if (left == right) {
reason = "same";
return false;
}
// Find the root of the chain if it is a part of a follow-on chain.
const DefinedAtom *leftRoot = lc._root;
const DefinedAtom *rightRoot = rc._root;
// Sort atoms by their ordinal overrides only if they fall in the same
// chain.
if (leftRoot == rightRoot) {
DEBUG(reason = formatReason("override", lc._override, rc._override));
return lc._override < rc._override;
}
// Sort same permissions together.
DefinedAtom::ContentPermissions leftPerms = leftRoot->permissions();
DefinedAtom::ContentPermissions rightPerms = rightRoot->permissions();
if (leftPerms != rightPerms) {
DEBUG(reason =
formatReason("contentPerms", (int)leftPerms, (int)rightPerms));
return leftPerms < rightPerms;
}
// Sort same content types together.
DefinedAtom::ContentType leftType = leftRoot->contentType();
DefinedAtom::ContentType rightType = rightRoot->contentType();
if (leftType != rightType) {
DEBUG(reason = formatReason("contentType", (int)leftType, (int)rightType));
return leftType < rightType;
}
// Use custom sorter if supplied.
if (customSorter) {
bool leftBeforeRight;
if (customSorter(leftRoot, rightRoot, leftBeforeRight))
return leftBeforeRight;
}
// Sort by .o order.
const File *leftFile = &leftRoot->file();
const File *rightFile = &rightRoot->file();
if (leftFile != rightFile) {
DEBUG(reason = formatReason(".o order", (int)leftFile->ordinal(),
(int)rightFile->ordinal()));
return leftFile->ordinal() < rightFile->ordinal();
}
// Sort by atom order with .o file.
uint64_t leftOrdinal = leftRoot->ordinal();
uint64_t rightOrdinal = rightRoot->ordinal();
if (leftOrdinal != rightOrdinal) {
DEBUG(reason = formatReason("ordinal", (int)leftRoot->ordinal(),
(int)rightRoot->ordinal()));
return leftOrdinal < rightOrdinal;
}
llvm::errs() << "Unordered: <" << left->name() << "> <"
<< right->name() << ">\n";
llvm_unreachable("Atoms with Same Ordinal!");
}
static bool compareAtoms(const LayoutPass::SortKey &lc,
const LayoutPass::SortKey &rc,
LayoutPass::SortOverride customSorter) {
std::string reason;
bool result = compareAtomsSub(lc, rc, customSorter, reason);
DEBUG({
StringRef comp = result ? "<" : ">=";
llvm::dbgs() << "Layout: '" << lc._atom.get()->name()
<< "' " << comp << " '"
<< rc._atom.get()->name() << "' (" << reason << ")\n";
});
return result;
}
LayoutPass::LayoutPass(const Registry &registry, SortOverride sorter)
: _registry(registry), _customSorter(sorter) {}
// Returns the atom immediately followed by the given atom in the followon
// chain.
const DefinedAtom *LayoutPass::findAtomFollowedBy(
const DefinedAtom *targetAtom) {
// Start from the beginning of the chain and follow the chain until
// we find the targetChain.
const DefinedAtom *atom = _followOnRoots[targetAtom];
while (true) {
const DefinedAtom *prevAtom = atom;
AtomToAtomT::iterator targetFollowOnAtomsIter = _followOnNexts.find(atom);
// The target atom must be in the chain of its root.
assert(targetFollowOnAtomsIter != _followOnNexts.end());
atom = targetFollowOnAtomsIter->second;
if (atom == targetAtom)
return prevAtom;
}
}
// Check if all the atoms followed by the given target atom are of size zero.
// When this method is called, an atom being added is not of size zero and
// will be added to the head of the followon chain. All the atoms between the
// atom and the targetAtom (specified by layout-after) need to be of size zero
// in this case. Otherwise the desired layout is impossible.
bool LayoutPass::checkAllPrevAtomsZeroSize(const DefinedAtom *targetAtom) {
const DefinedAtom *atom = _followOnRoots[targetAtom];
while (true) {
if (atom == targetAtom)
return true;
if (atom->size() != 0)
// TODO: print warning that an impossible layout is being desired by the
// user.
return false;
AtomToAtomT::iterator targetFollowOnAtomsIter = _followOnNexts.find(atom);
// The target atom must be in the chain of its root.
assert(targetFollowOnAtomsIter != _followOnNexts.end());
atom = targetFollowOnAtomsIter->second;
}
}
// Set the root of all atoms in targetAtom's chain to the given root.
void LayoutPass::setChainRoot(const DefinedAtom *targetAtom,
const DefinedAtom *root) {
// Walk through the followon chain and override each node's root.
while (true) {
_followOnRoots[targetAtom] = root;
AtomToAtomT::iterator targetFollowOnAtomsIter =
_followOnNexts.find(targetAtom);
if (targetFollowOnAtomsIter == _followOnNexts.end())
return;
targetAtom = targetFollowOnAtomsIter->second;
}
}
/// This pass builds the followon tables described by two DenseMaps
/// followOnRoots and followonNexts.
/// The followOnRoots map contains a mapping of a DefinedAtom to its root
/// The followOnNexts map contains a mapping of what DefinedAtom follows the
/// current Atom
/// The algorithm follows a very simple approach
/// a) If the atom is first seen, then make that as the root atom
/// b) The targetAtom which this Atom contains, has the root thats set to the
/// root of the current atom
/// c) If the targetAtom is part of a different tree and the root of the
/// targetAtom is itself, Chain all the atoms that are contained in the tree
/// to the current Tree
/// d) If the targetAtom is part of a different chain and the root of the
/// targetAtom until the targetAtom has all atoms of size 0, then chain the
/// targetAtoms and its tree to the current chain
void LayoutPass::buildFollowOnTable(const SimpleFile::DefinedAtomRange &range) {
ScopedTask task(getDefaultDomain(), "LayoutPass::buildFollowOnTable");
// Set the initial size of the followon and the followonNext hash to the
// number of atoms that we have.
_followOnRoots.reserve(range.size());
_followOnNexts.reserve(range.size());
for (const DefinedAtom *ai : range) {
for (const Reference *r : *ai) {
if (r->kindNamespace() != lld::Reference::KindNamespace::all ||
r->kindValue() != lld::Reference::kindLayoutAfter)
continue;
const DefinedAtom *targetAtom = dyn_cast<DefinedAtom>(r->target());
_followOnNexts[ai] = targetAtom;
// If we find a followon for the first time, let's make that atom as the
// root atom.
if (_followOnRoots.count(ai) == 0)
_followOnRoots[ai] = ai;
auto iter = _followOnRoots.find(targetAtom);
if (iter == _followOnRoots.end()) {
// If the targetAtom is not a root of any chain, let's make the root of
// the targetAtom to the root of the current chain.
// The expression m[i] = m[j] where m is a DenseMap and i != j is not
// safe. m[j] returns a reference, which would be invalidated when a
// rehashing occurs. If rehashing occurs to make room for m[i], m[j]
// becomes invalid, and that invalid reference would be used as the RHS
// value of the expression.
// Copy the value to workaround.
const DefinedAtom *tmp = _followOnRoots[ai];
_followOnRoots[targetAtom] = tmp;
continue;
}
if (iter->second == targetAtom) {
// If the targetAtom is the root of a chain, the chain becomes part of
// the current chain. Rewrite the subchain's root to the current
// chain's root.
setChainRoot(targetAtom, _followOnRoots[ai]);
continue;
}
// The targetAtom is already a part of a chain. If the current atom is
// of size zero, we can insert it in the middle of the chain just
// before the target atom, while not breaking other atom's followon
// relationships. If it's not, we can only insert the current atom at
// the beginning of the chain. All the atoms followed by the target
// atom must be of size zero in that case to satisfy the followon
// relationships.
size_t currentAtomSize = ai->size();
if (currentAtomSize == 0) {
const DefinedAtom *targetPrevAtom = findAtomFollowedBy(targetAtom);
_followOnNexts[targetPrevAtom] = ai;
const DefinedAtom *tmp = _followOnRoots[targetPrevAtom];
_followOnRoots[ai] = tmp;
continue;
}
if (!checkAllPrevAtomsZeroSize(targetAtom))
break;
_followOnNexts[ai] = _followOnRoots[targetAtom];
setChainRoot(_followOnRoots[targetAtom], _followOnRoots[ai]);
}
}
}
/// Build an ordinal override map by traversing the followon chain, and
/// assigning ordinals to each atom, if the atoms have their ordinals
/// already assigned skip the atom and move to the next. This is the
/// main map thats used to sort the atoms while comparing two atoms together
void
LayoutPass::buildOrdinalOverrideMap(const SimpleFile::DefinedAtomRange &range) {
ScopedTask task(getDefaultDomain(), "LayoutPass::buildOrdinalOverrideMap");
uint64_t index = 0;
for (const DefinedAtom *ai : range) {
const DefinedAtom *atom = ai;
if (_ordinalOverrideMap.find(atom) != _ordinalOverrideMap.end())
continue;
AtomToAtomT::iterator start = _followOnRoots.find(atom);
if (start == _followOnRoots.end())
continue;
for (const DefinedAtom *nextAtom = start->second; nextAtom;
nextAtom = _followOnNexts[nextAtom]) {
AtomToOrdinalT::iterator pos = _ordinalOverrideMap.find(nextAtom);
if (pos == _ordinalOverrideMap.end())
_ordinalOverrideMap[nextAtom] = index++;
}
}
}
std::vector<LayoutPass::SortKey>
LayoutPass::decorate(SimpleFile::DefinedAtomRange &atomRange) const {
std::vector<SortKey> ret;
for (OwningAtomPtr<DefinedAtom> &atom : atomRange.owning_ptrs()) {
auto ri = _followOnRoots.find(atom.get());
auto oi = _ordinalOverrideMap.find(atom.get());
const auto *root = (ri == _followOnRoots.end()) ? atom.get() : ri->second;
uint64_t override = (oi == _ordinalOverrideMap.end()) ? 0 : oi->second;
ret.push_back(SortKey(std::move(atom), root, override));
}
return ret;
}
void LayoutPass::undecorate(SimpleFile::DefinedAtomRange &atomRange,
std::vector<SortKey> &keys) const {
size_t i = 0;
for (SortKey &k : keys)
atomRange[i++] = std::move(k._atom);
}
/// Perform the actual pass
llvm::Error LayoutPass::perform(SimpleFile &mergedFile) {
DEBUG(llvm::dbgs() << "******** Laying out atoms:\n");
// sort the atoms
ScopedTask task(getDefaultDomain(), "LayoutPass");
SimpleFile::DefinedAtomRange atomRange = mergedFile.definedAtoms();
// Build follow on tables
buildFollowOnTable(atomRange);
// Check the structure of followon graph if running in debug mode.
DEBUG(checkFollowonChain(atomRange));
// Build override maps
buildOrdinalOverrideMap(atomRange);
DEBUG({
llvm::dbgs() << "unsorted atoms:\n";
printDefinedAtoms(atomRange);
});
std::vector<LayoutPass::SortKey> vec = decorate(atomRange);
parallel_sort(vec.begin(), vec.end(),
[&](const LayoutPass::SortKey &l, const LayoutPass::SortKey &r) -> bool {
return compareAtoms(l, r, _customSorter);
});
DEBUG(checkTransitivity(vec, _customSorter));
undecorate(atomRange, vec);
DEBUG({
llvm::dbgs() << "sorted atoms:\n";
printDefinedAtoms(atomRange);
});
DEBUG(llvm::dbgs() << "******** Finished laying out atoms\n");
return llvm::Error();
}
void addLayoutPass(PassManager &pm, const MachOLinkingContext &ctx) {
pm.add(llvm::make_unique<LayoutPass>(
ctx.registry(), [&](const DefinedAtom * left, const DefinedAtom * right,
bool & leftBeforeRight) ->bool {
return ctx.customAtomOrderer(left, right, leftBeforeRight);
}));
}
} // namespace mach_o
} // namespace lld