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//===- subzero/src/IceGlobalContext.cpp - Global context defs -------------===//
//
// The Subzero Code Generator
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file
/// \brief Defines aspects of the compilation that persist across multiple
/// functions.
///
//===----------------------------------------------------------------------===//
#include "IceGlobalContext.h"
#include "IceCfg.h"
#include "IceCfgNode.h"
#include "IceClFlags.h"
#include "IceDefs.h"
#include "IceELFObjectWriter.h"
#include "IceGlobalInits.h"
#include "IceLiveness.h"
#include "IceOperand.h"
#include "IceRevision.h"
#include "IceTargetLowering.h"
#include "IceTimerTree.h"
#include "IceTypes.def"
#include "IceTypes.h"
#ifdef __clang__
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wunused-parameter"
#endif // __clang__
#include "llvm/Support/Timer.h"
#ifdef __clang__
#pragma clang diagnostic pop
#endif // __clang__
#include <algorithm> // max()
namespace std {
template <> struct hash<Ice::RelocatableTuple> {
size_t operator()(const Ice::RelocatableTuple &Key) const {
// Use the relocatable's name, plus the hash of a combination of the number
// of OffsetExprs and the known, fixed offset for the reloc. We left shift
// the known relocatable by 5 trying to minimize the interaction between the
// bits in OffsetExpr.size() and Key.Offset.
return hash<Ice::SizeT>()(Key.Name.getID()) +
hash<std::size_t>()(Key.OffsetExpr.size() + (Key.Offset << 5));
}
};
} // end of namespace std
namespace Ice {
namespace {
// Define the key comparison function for the constant pool's unordered_map,
// but only for key types of interest: integer types, floating point types, and
// the special RelocatableTuple.
template <typename KeyType, class Enable = void> struct KeyCompare {};
template <typename KeyType>
struct KeyCompare<KeyType,
typename std::enable_if<
std::is_integral<KeyType>::value ||
std::is_same<KeyType, RelocatableTuple>::value>::type> {
bool operator()(const KeyType &Value1, const KeyType &Value2) const {
return Value1 == Value2;
}
};
template <typename KeyType>
struct KeyCompare<KeyType, typename std::enable_if<
std::is_floating_point<KeyType>::value>::type> {
bool operator()(const KeyType &Value1, const KeyType &Value2) const {
return !memcmp(&Value1, &Value2, sizeof(KeyType));
}
};
// Define a key comparison function for sorting the constant pool's values
// after they are dumped to a vector. This covers integer types, floating point
// types, and ConstantRelocatable values.
template <typename ValueType, class Enable = void> struct KeyCompareLess {};
template <typename ValueType>
struct KeyCompareLess<ValueType,
typename std::enable_if<std::is_floating_point<
typename ValueType::PrimType>::value>::type> {
bool operator()(const Constant *Const1, const Constant *Const2) const {
using CompareType = uint64_t;
static_assert(sizeof(typename ValueType::PrimType) <= sizeof(CompareType),
"Expected floating-point type of width 64-bit or less");
typename ValueType::PrimType V1 = llvm::cast<ValueType>(Const1)->getValue();
typename ValueType::PrimType V2 = llvm::cast<ValueType>(Const2)->getValue();
// We avoid "V1<V2" because of NaN.
// We avoid "memcmp(&V1,&V2,sizeof(V1))<0" which depends on the
// endian-ness of the host system running Subzero.
// Instead, compare the result of bit_cast to uint64_t.
uint64_t I1 = 0, I2 = 0;
memcpy(&I1, &V1, sizeof(V1));
memcpy(&I2, &V2, sizeof(V2));
return I1 < I2;
}
};
template <typename ValueType>
struct KeyCompareLess<ValueType,
typename std::enable_if<std::is_integral<
typename ValueType::PrimType>::value>::type> {
bool operator()(const Constant *Const1, const Constant *Const2) const {
typename ValueType::PrimType V1 = llvm::cast<ValueType>(Const1)->getValue();
typename ValueType::PrimType V2 = llvm::cast<ValueType>(Const2)->getValue();
return V1 < V2;
}
};
template <typename ValueType>
struct KeyCompareLess<
ValueType, typename std::enable_if<
std::is_same<ValueType, ConstantRelocatable>::value>::type> {
bool operator()(const Constant *Const1, const Constant *Const2) const {
auto *V1 = llvm::cast<ValueType>(Const1);
auto *V2 = llvm::cast<ValueType>(Const2);
if (V1->getName() == V2->getName())
return V1->getOffset() < V2->getOffset();
return V1->getName() < V2->getName();
}
};
// TypePool maps constants of type KeyType (e.g. float) to pointers to
// type ValueType (e.g. ConstantFloat).
template <Type Ty, typename KeyType, typename ValueType> class TypePool {
TypePool(const TypePool &) = delete;
TypePool &operator=(const TypePool &) = delete;
public:
TypePool() = default;
ValueType *getOrAdd(GlobalContext *Ctx, KeyType Key) {
auto Iter = Pool.find(Key);
if (Iter != Pool.end()) {
Iter->second->updateLookupCount();
return Iter->second;
}
auto *Result = ValueType::create(Ctx, Ty, Key);
Pool[Key] = Result;
Result->updateLookupCount();
return Result;
}
ConstantList getConstantPool() const {
ConstantList Constants;
Constants.reserve(Pool.size());
for (auto &I : Pool)
Constants.push_back(I.second);
// The sort (and its KeyCompareLess machinery) is not strictly necessary,
// but is desirable for producing output that is deterministic across
// unordered_map::iterator implementations.
std::sort(Constants.begin(), Constants.end(), KeyCompareLess<ValueType>());
return Constants;
}
size_t size() const { return Pool.size(); }
private:
// Use the default hash function, and a custom key comparison function. The
// key comparison function for floating point variables can't use the default
// == based implementation because of special C++ semantics regarding +0.0,
// -0.0, and NaN comparison. However, it's OK to use the default hash for
// floating point values because KeyCompare is the final source of truth - in
// the worst case a "false" collision must be resolved.
using ContainerType =
std::unordered_map<KeyType, ValueType *, std::hash<KeyType>,
KeyCompare<KeyType>>;
ContainerType Pool;
};
// UndefPool maps ICE types to the corresponding ConstantUndef values.
class UndefPool {
UndefPool(const UndefPool &) = delete;
UndefPool &operator=(const UndefPool &) = delete;
public:
UndefPool() : Pool(IceType_NUM) {}
ConstantUndef *getOrAdd(GlobalContext *Ctx, Type Ty) {
if (Pool[Ty] == nullptr)
Pool[Ty] = ConstantUndef::create(Ctx, Ty);
return Pool[Ty];
}
private:
std::vector<ConstantUndef *> Pool;
};
} // end of anonymous namespace
// The global constant pool bundles individual pools of each type of
// interest.
class ConstantPool {
ConstantPool(const ConstantPool &) = delete;
ConstantPool &operator=(const ConstantPool &) = delete;
public:
ConstantPool() = default;
TypePool<IceType_f32, float, ConstantFloat> Floats;
TypePool<IceType_f64, double, ConstantDouble> Doubles;
TypePool<IceType_i1, int8_t, ConstantInteger32> Integers1;
TypePool<IceType_i8, int8_t, ConstantInteger32> Integers8;
TypePool<IceType_i16, int16_t, ConstantInteger32> Integers16;
TypePool<IceType_i32, int32_t, ConstantInteger32> Integers32;
TypePool<IceType_i64, int64_t, ConstantInteger64> Integers64;
TypePool<IceType_i32, RelocatableTuple, ConstantRelocatable> Relocatables;
TypePool<IceType_i32, RelocatableTuple, ConstantRelocatable>
ExternRelocatables;
UndefPool Undefs;
};
void GlobalContext::waitForWorkerThreads() {
if (WaitForWorkerThreadsCalled.exchange(true))
return;
optQueueNotifyEnd();
for (std::thread &Worker : TranslationThreads) {
Worker.join();
}
TranslationThreads.clear();
// Only notify the emit queue to end after all the translation threads have
// ended.
emitQueueNotifyEnd();
for (std::thread &Worker : EmitterThreads) {
Worker.join();
}
EmitterThreads.clear();
if (BuildDefs::timers()) {
auto Timers = getTimers();
for (ThreadContext *TLS : AllThreadContexts)
Timers->mergeFrom(TLS->Timers);
}
if (BuildDefs::dump()) {
// Do a separate loop over AllThreadContexts to avoid holding two locks at
// once.
auto Stats = getStatsCumulative();
for (ThreadContext *TLS : AllThreadContexts)
Stats->add(TLS->StatsCumulative);
}
}
void GlobalContext::CodeStats::dump(const Cfg *Func, GlobalContext *Ctx) {
if (!BuildDefs::dump())
return;
OstreamLocker _(Ctx);
Ostream &Str = Ctx->getStrDump();
const std::string Name =
(Func == nullptr ? "_FINAL_" : Func->getFunctionNameAndSize());
#define X(str, tag) \
Str << "|" << Name << "|" str "|" << Stats[CS_##tag] << "\n";
CODESTATS_TABLE
#undef X
Str << "|" << Name << "|Spills+Fills|"
<< Stats[CS_NumSpills] + Stats[CS_NumFills] << "\n";
Str << "|" << Name << "|Memory Usage |";
if (const auto MemUsed = static_cast<size_t>(
llvm::TimeRecord::getCurrentTime(false).getMemUsed())) {
static constexpr size_t _1MB = 1024 * 1024;
Str << (MemUsed / _1MB) << " MB";
} else {
Str << "(requires '-track-memory')";
}
Str << "\n";
Str << "|" << Name << "|CPool Sizes ";
{
auto Pool = Ctx->getConstPool();
Str << "|f32=" << Pool->Floats.size();
Str << "|f64=" << Pool->Doubles.size();
Str << "|i1=" << Pool->Integers1.size();
Str << "|i8=" << Pool->Integers8.size();
Str << "|i16=" << Pool->Integers16.size();
Str << "|i32=" << Pool->Integers32.size();
Str << "|i64=" << Pool->Integers64.size();
Str << "|Rel=" << Pool->Relocatables.size();
Str << "|ExtRel=" << Pool->ExternRelocatables.size();
}
Str << "\n";
if (Func != nullptr) {
Str << "|" << Name << "|Cfg Memory |" << Func->getTotalMemoryMB()
<< " MB\n";
Str << "|" << Name << "|Liveness Memory |" << Func->getLivenessMemoryMB()
<< " MB\n";
}
}
namespace {
// By default, wake up the main parser thread when the OptQ gets half empty.
static constexpr size_t DefaultOptQWakeupSize = GlobalContext::MaxOptQSize >> 1;
} // end of anonymous namespace
GlobalContext::GlobalContext(Ostream *OsDump, Ostream *OsEmit, Ostream *OsError,
ELFStreamer *ELFStr)
: Strings(new StringPool()), ConstPool(new ConstantPool()), ErrorStatus(),
StrDump(OsDump), StrEmit(OsEmit), StrError(OsError), ObjectWriter(),
OptQWakeupSize(std::max(DefaultOptQWakeupSize,
size_t(getFlags().getNumTranslationThreads()))),
OptQ(/*Sequential=*/getFlags().isSequential(),
/*MaxSize=*/
getFlags().isParseParallel()
? MaxOptQSize
: getFlags().getNumTranslationThreads()),
// EmitQ is allowed unlimited size.
EmitQ(/*Sequential=*/getFlags().isSequential()),
DataLowering(TargetDataLowering::createLowering(this)) {
assert(OsDump && "OsDump is not defined for GlobalContext");
assert(OsEmit && "OsEmit is not defined for GlobalContext");
assert(OsError && "OsError is not defined for GlobalContext");
// Make sure thread_local fields are properly initialized before any
// accesses are made. Do this here instead of at the start of
// main() so that all clients (e.g. unit tests) can benefit for
// free.
GlobalContext::TlsInit();
Cfg::TlsInit();
Liveness::TlsInit();
// Create a new ThreadContext for the current thread. No need to
// lock AllThreadContexts at this point since no other threads have
// access yet to this GlobalContext object.
ThreadContext *MyTLS = new ThreadContext();
AllThreadContexts.push_back(MyTLS);
ICE_TLS_SET_FIELD(TLS, MyTLS);
// Pre-register built-in stack names.
if (BuildDefs::timers()) {
// TODO(stichnot): There needs to be a strong relationship between
// the newTimerStackID() return values and TSK_Default/TSK_Funcs.
newTimerStackID("Total across all functions");
newTimerStackID("Per-function summary");
}
Timers.initInto(MyTLS->Timers);
switch (getFlags().getOutFileType()) {
case FT_Elf:
ObjectWriter.reset(new ELFObjectWriter(*this, *ELFStr));
break;
case FT_Asm:
case FT_Iasm:
break;
}
// Cache up front common constants.
#define X(tag, sizeLog2, align, elts, elty, str, rcstr) \
ConstZeroForType[IceType_##tag] = getConstantZeroInternal(IceType_##tag);
ICETYPE_TABLE;
#undef X
ConstantTrue = getConstantInt1Internal(1);
// Define runtime helper functions.
#define X(Tag, Name) \
RuntimeHelperFunc[static_cast<size_t>(RuntimeHelper::H_##Tag)] = \
getConstantExternSym(getGlobalString(Name));
RUNTIME_HELPER_FUNCTIONS_TABLE
#undef X
TargetLowering::staticInit(this);
if (getFlags().getEmitRevision()) {
// Embed the Subzero revision into the compiled binary by creating a special
// global variable initialized with the revision string.
auto *Revision = VariableDeclaration::create(&Globals, true);
Revision->setName(this, "__Sz_revision");
Revision->setIsConstant(true);
const char *RevisionString = getSubzeroRevision();
Revision->addInitializer(VariableDeclaration::DataInitializer::create(
&Globals, RevisionString, 1 + strlen(RevisionString)));
Globals.push_back(Revision);
}
}
void GlobalContext::translateFunctionsWrapper(ThreadContext *MyTLS) {
ICE_TLS_SET_FIELD(TLS, MyTLS);
translateFunctions();
}
void GlobalContext::translateFunctions() {
TimerMarker Timer(TimerStack::TT_translateFunctions, this);
while (std::unique_ptr<OptWorkItem> OptItem = optQueueBlockingPop()) {
std::unique_ptr<EmitterWorkItem> Item;
auto Func = OptItem->getParsedCfg();
// Install Func in TLS for Cfg-specific container allocators.
CfgLocalAllocatorScope _(Func.get());
// Reset per-function stats being accumulated in TLS.
resetStats();
// Set verbose level to none if the current function does NOT match the
// -verbose-focus command-line option.
if (!getFlags().matchVerboseFocusOn(Func->getFunctionName(),
Func->getSequenceNumber()))
Func->setVerbose(IceV_None);
// Disable translation if -notranslate is specified, or if the current
// function matches the -translate-only option. If translation is disabled,
// just dump the high-level IR and continue.
if (getFlags().getDisableTranslation() ||
!getFlags().matchTranslateOnly(Func->getFunctionName(),
Func->getSequenceNumber())) {
Func->dump();
// Add a dummy work item as a placeholder. This maintains sequence
// numbers so that the emitter thread will emit subsequent functions.
Item = makeUnique<EmitterWorkItem>(Func->getSequenceNumber());
emitQueueBlockingPush(std::move(Item));
continue; // Func goes out of scope and gets deleted
}
Func->translate();
if (Func->hasError()) {
getErrorStatus()->assign(EC_Translation);
OstreamLocker L(this);
getStrError() << "ICE translation error: " << Func->getFunctionName()
<< ": " << Func->getError() << ": "
<< Func->getFunctionNameAndSize() << "\n";
Item = makeUnique<EmitterWorkItem>(Func->getSequenceNumber());
} else {
Func->getAssembler<>()->setInternal(Func->getInternal());
switch (getFlags().getOutFileType()) {
case FT_Elf:
case FT_Iasm: {
Func->emitIAS();
// The Cfg has already emitted into the assembly buffer, so
// stats have been fully collected into this thread's TLS.
// Dump them before TLS is reset for the next Cfg.
if (BuildDefs::dump())
dumpStats(Func.get());
auto Asm = Func->releaseAssembler();
// Copy relevant fields into Asm before Func is deleted.
Asm->setFunctionName(Func->getFunctionName());
Item = makeUnique<EmitterWorkItem>(Func->getSequenceNumber(),
std::move(Asm));
Item->setGlobalInits(Func->getGlobalInits());
} break;
case FT_Asm:
// The Cfg has not been emitted yet, so stats are not ready
// to be dumped.
std::unique_ptr<VariableDeclarationList> GlobalInits =
Func->getGlobalInits();
Item = makeUnique<EmitterWorkItem>(Func->getSequenceNumber(),
std::move(Func));
Item->setGlobalInits(std::move(GlobalInits));
break;
}
}
assert(Item != nullptr);
emitQueueBlockingPush(std::move(Item));
// The Cfg now gets deleted as Func goes out of scope.
}
}
namespace {
// Ensure Pending is large enough that Pending[Index] is valid.
void resizePending(std::vector<std::unique_ptr<EmitterWorkItem>> *Pending,
uint32_t Index) {
if (Index >= Pending->size())
Utils::reserveAndResize(*Pending, Index + 1);
}
} // end of anonymous namespace
// static
void GlobalContext::TlsInit() { ICE_TLS_INIT_FIELD(TLS); }
void GlobalContext::emitFileHeader() {
TimerMarker T1(Ice::TimerStack::TT_emitAsm, this);
if (getFlags().getOutFileType() == FT_Elf) {
getObjectWriter()->writeInitialELFHeader();
} else {
if (!BuildDefs::dump()) {
getStrError() << "emitFileHeader for non-ELF";
getErrorStatus()->assign(EC_Translation);
}
TargetHeaderLowering::createLowering(this)->lower();
}
}
void GlobalContext::lowerConstants() { DataLowering->lowerConstants(); }
void GlobalContext::lowerJumpTables() { DataLowering->lowerJumpTables(); }
void GlobalContext::emitTargetRODataSections() {
DataLowering->emitTargetRODataSections();
}
void GlobalContext::lowerGlobals(const std::string &SectionSuffix) {
TimerMarker T(TimerStack::TT_emitGlobalInitializers, this);
const bool DumpGlobalVariables =
BuildDefs::dump() && (getFlags().getVerbose() & IceV_GlobalInit) &&
getFlags().matchVerboseFocusOn("", 0);
if (DumpGlobalVariables) {
OstreamLocker L(this);
Ostream &Stream = getStrDump();
for (const Ice::VariableDeclaration *Global : Globals) {
Global->dump(Stream);
}
}
if (getFlags().getDisableTranslation())
return;
if (!BuildDefs::minimal() && Instrumentor)
Instrumentor->instrumentGlobals(Globals);
DataLowering->lowerGlobals(Globals, SectionSuffix);
if (DisposeGlobalVariablesAfterLowering) {
Globals.clearAndPurge();
} else {
Globals.clear();
}
}
void GlobalContext::emitterWrapper(ThreadContext *MyTLS) {
ICE_TLS_SET_FIELD(TLS, MyTLS);
emitItems();
}
void GlobalContext::emitItems() {
const bool Threaded = !getFlags().isSequential();
// Pending is a vector containing the reassembled, ordered list of
// work items. When we're ready for the next item, we first check
// whether it's in the Pending list. If not, we take an item from
// the work queue, and if it's not the item we're waiting for, we
// insert it into Pending and repeat. The work item is deleted
// after it is processed.
std::vector<std::unique_ptr<EmitterWorkItem>> Pending;
uint32_t DesiredSequenceNumber = getFirstSequenceNumber();
uint32_t ShuffleStartIndex = DesiredSequenceNumber;
uint32_t ShuffleEndIndex = DesiredSequenceNumber;
bool EmitQueueEmpty = false;
while (!EmitQueueEmpty) {
resizePending(&Pending, DesiredSequenceNumber);
// See if Pending contains DesiredSequenceNumber.
if (Pending[DesiredSequenceNumber] == nullptr) {
// We need to fetch an EmitterWorkItem from the queue.
auto RawItem = emitQueueBlockingPop();
if (RawItem == nullptr) {
// This is the notifier for an empty queue.
EmitQueueEmpty = true;
} else {
// We get an EmitterWorkItem, we need to add it to Pending.
uint32_t ItemSeq = RawItem->getSequenceNumber();
if (Threaded && ItemSeq != DesiredSequenceNumber) {
// Not the desired one, add it to Pending but do not increase
// DesiredSequenceNumber. Continue the loop, do not emit the item.
resizePending(&Pending, ItemSeq);
Pending[ItemSeq] = std::move(RawItem);
continue;
}
// ItemSeq == DesiredSequenceNumber, we need to check if we should
// emit it or not. If !Threaded, we're OK with ItemSeq !=
// DesiredSequenceNumber.
Pending[DesiredSequenceNumber] = std::move(RawItem);
}
}
// We have the desired EmitterWorkItem or nullptr as the end notifier.
// If the emitter queue is not empty, increase DesiredSequenceNumber and
// ShuffleEndIndex.
if (!EmitQueueEmpty) {
DesiredSequenceNumber++;
ShuffleEndIndex++;
}
// Emit the item from ShuffleStartIndex to ShuffleEndIndex.
for (uint32_t I = ShuffleStartIndex; I < ShuffleEndIndex; I++) {
std::unique_ptr<EmitterWorkItem> Item = std::move(Pending[I]);
switch (Item->getKind()) {
case EmitterWorkItem::WI_Nop:
break;
case EmitterWorkItem::WI_GlobalInits: {
accumulateGlobals(Item->getGlobalInits());
} break;
case EmitterWorkItem::WI_Asm: {
lowerGlobalsIfNoCodeHasBeenSeen();
accumulateGlobals(Item->getGlobalInits());
std::unique_ptr<Assembler> Asm = Item->getAsm();
Asm->alignFunction();
GlobalString Name = Asm->getFunctionName();
switch (getFlags().getOutFileType()) {
case FT_Elf:
getObjectWriter()->writeFunctionCode(Name, Asm->getInternal(),
Asm.get());
break;
case FT_Iasm: {
OstreamLocker L(this);
Cfg::emitTextHeader(Name, this, Asm.get());
Asm->emitIASBytes(this);
} break;
case FT_Asm:
llvm::report_fatal_error("Unexpected FT_Asm");
break;
}
} break;
case EmitterWorkItem::WI_Cfg: {
if (!BuildDefs::dump())
llvm::report_fatal_error("WI_Cfg work item created inappropriately");
lowerGlobalsIfNoCodeHasBeenSeen();
accumulateGlobals(Item->getGlobalInits());
assert(getFlags().getOutFileType() == FT_Asm);
std::unique_ptr<Cfg> Func = Item->getCfg();
// Unfortunately, we have to temporarily install the Cfg in TLS
// because Variable::asType() uses the allocator to create the
// differently-typed copy.
CfgLocalAllocatorScope _(Func.get());
Func->emit();
dumpStats(Func.get());
} break;
}
}
// Update the start index for next shuffling queue
ShuffleStartIndex = ShuffleEndIndex;
}
// In case there are no code to be generated, we invoke the conditional
// lowerGlobals again -- this is a no-op if code has been emitted.
lowerGlobalsIfNoCodeHasBeenSeen();
}
GlobalContext::~GlobalContext() {
llvm::DeleteContainerPointers(AllThreadContexts);
LockedPtr<DestructorArray> Dtors = getDestructors();
// Destructors are invoked in the opposite object construction order.
for (const auto &Dtor : reverse_range(*Dtors))
Dtor();
}
void GlobalContext::dumpStrings() {
if (!getFlags().getDumpStrings())
return;
OstreamLocker _(this);
Ostream &Str = getStrDump();
Str << "GlobalContext strings:\n";
getStrings()->dump(Str);
}
void GlobalContext::dumpConstantLookupCounts() {
if (!BuildDefs::dump())
return;
const bool DumpCounts = (getFlags().getVerbose() & IceV_ConstPoolStats) &&
getFlags().matchVerboseFocusOn("", 0);
if (!DumpCounts)
return;
OstreamLocker _(this);
Ostream &Str = getStrDump();
Str << "Constant pool use stats: count+value+type\n";
#define X(WhichPool) \
for (auto *C : getConstPool()->WhichPool.getConstantPool()) { \
Str << C->getLookupCount() << " "; \
C->dump(Str); \
Str << " " << C->getType() << "\n"; \
}
X(Integers1);
X(Integers8);
X(Integers16);
X(Integers32);
X(Integers64);
X(Floats);
X(Doubles);
X(Relocatables);
X(ExternRelocatables);
#undef X
}
// TODO(stichnot): Consider adding thread-local caches of constant pool entries
// to reduce contention.
// All locking is done by the getConstantInt[0-9]+() target function.
Constant *GlobalContext::getConstantInt(Type Ty, int64_t Value) {
switch (Ty) {
case IceType_i1:
return getConstantInt1(Value);
case IceType_i8:
return getConstantInt8(Value);
case IceType_i16:
return getConstantInt16(Value);
case IceType_i32:
return getConstantInt32(Value);
case IceType_i64:
return getConstantInt64(Value);
default:
llvm_unreachable("Bad integer type for getConstant");
}
return nullptr;
}
Constant *GlobalContext::getConstantInt1Internal(int8_t ConstantInt1) {
ConstantInt1 &= INT8_C(1);
return getConstPool()->Integers1.getOrAdd(this, ConstantInt1);
}
Constant *GlobalContext::getConstantInt8Internal(int8_t ConstantInt8) {
return getConstPool()->Integers8.getOrAdd(this, ConstantInt8);
}
Constant *GlobalContext::getConstantInt16Internal(int16_t ConstantInt16) {
return getConstPool()->Integers16.getOrAdd(this, ConstantInt16);
}
Constant *GlobalContext::getConstantInt32Internal(int32_t ConstantInt32) {
return getConstPool()->Integers32.getOrAdd(this, ConstantInt32);
}
Constant *GlobalContext::getConstantInt64Internal(int64_t ConstantInt64) {
return getConstPool()->Integers64.getOrAdd(this, ConstantInt64);
}
Constant *GlobalContext::getConstantFloat(float ConstantFloat) {
return getConstPool()->Floats.getOrAdd(this, ConstantFloat);
}
Constant *GlobalContext::getConstantDouble(double ConstantDouble) {
return getConstPool()->Doubles.getOrAdd(this, ConstantDouble);
}
Constant *GlobalContext::getConstantSymWithEmitString(
const RelocOffsetT Offset, const RelocOffsetArray &OffsetExpr,
GlobalString Name, const std::string &EmitString) {
return getConstPool()->Relocatables.getOrAdd(
this, RelocatableTuple(Offset, OffsetExpr, Name, EmitString));
}
Constant *GlobalContext::getConstantSym(RelocOffsetT Offset,
GlobalString Name) {
constexpr char EmptyEmitString[] = "";
return getConstantSymWithEmitString(Offset, {}, Name, EmptyEmitString);
}
Constant *GlobalContext::getConstantExternSym(GlobalString Name) {
constexpr RelocOffsetT Offset = 0;
return getConstPool()->ExternRelocatables.getOrAdd(
this, RelocatableTuple(Offset, {}, Name));
}
Constant *GlobalContext::getConstantUndef(Type Ty) {
return getConstPool()->Undefs.getOrAdd(this, Ty);
}
Constant *GlobalContext::getConstantZero(Type Ty) {
Constant *Zero = ConstZeroForType[Ty];
if (Zero == nullptr)
llvm::report_fatal_error("Unsupported constant type: " + typeStdString(Ty));
return Zero;
}
// All locking is done by the getConstant*() target function.
Constant *GlobalContext::getConstantZeroInternal(Type Ty) {
switch (Ty) {
case IceType_i1:
return getConstantInt1Internal(0);
case IceType_i8:
return getConstantInt8Internal(0);
case IceType_i16:
return getConstantInt16Internal(0);
case IceType_i32:
return getConstantInt32Internal(0);
case IceType_i64:
return getConstantInt64Internal(0);
case IceType_f32:
return getConstantFloat(0);
case IceType_f64:
return getConstantDouble(0);
default:
return nullptr;
}
}
ConstantList GlobalContext::getConstantPool(Type Ty) {
switch (Ty) {
case IceType_i1:
case IceType_i8:
return getConstPool()->Integers8.getConstantPool();
case IceType_i16:
return getConstPool()->Integers16.getConstantPool();
case IceType_i32:
return getConstPool()->Integers32.getConstantPool();
case IceType_i64:
return getConstPool()->Integers64.getConstantPool();
case IceType_f32:
return getConstPool()->Floats.getConstantPool();
case IceType_f64:
return getConstPool()->Doubles.getConstantPool();
case IceType_v4i1:
case IceType_v8i1:
case IceType_v16i1:
case IceType_v16i8:
case IceType_v8i16:
case IceType_v4i32:
case IceType_v4f32:
llvm::report_fatal_error("Unsupported constant type: " + typeStdString(Ty));
break;
case IceType_void:
case IceType_NUM:
break;
}
llvm_unreachable("Unknown type");
}
ConstantList GlobalContext::getConstantExternSyms() {
return getConstPool()->ExternRelocatables.getConstantPool();
}
GlobalString GlobalContext::getGlobalString(const std::string &Name) {
return GlobalString::createWithString(this, Name);
}
JumpTableDataList GlobalContext::getJumpTables() {
JumpTableDataList JumpTables(*getJumpTableList());
// Make order deterministic by sorting into functions and then ID of the jump
// table within that function.
std::sort(JumpTables.begin(), JumpTables.end(),
[](const JumpTableData &A, const JumpTableData &B) {
if (A.getFunctionName() != B.getFunctionName())
return A.getFunctionName() < B.getFunctionName();
return A.getId() < B.getId();
});
return JumpTables;
}
void GlobalContext::addJumpTableData(JumpTableData JumpTable) {
getJumpTableList()->emplace_back(std::move(JumpTable));
}
TimerStackIdT GlobalContext::newTimerStackID(const std::string &Name) {
if (!BuildDefs::timers())
return 0;
auto Timers = getTimers();
TimerStackIdT NewID = Timers->size();
Timers->push_back(TimerStack(Name));
return NewID;
}
TimerIdT GlobalContext::getTimerID(TimerStackIdT StackID,
const std::string &Name) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
return Timers->at(StackID).getTimerID(Name);
}
void GlobalContext::pushTimer(TimerIdT ID, TimerStackIdT StackID) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
Timers->at(StackID).push(ID);
}
void GlobalContext::popTimer(TimerIdT ID, TimerStackIdT StackID) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
Timers->at(StackID).pop(ID);
}
void GlobalContext::resetTimer(TimerStackIdT StackID) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
Timers->at(StackID).reset();
}
std::string GlobalContext::getTimerName(TimerStackIdT StackID) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
return Timers->at(StackID).getName();
}
void GlobalContext::setTimerName(TimerStackIdT StackID,
const std::string &NewName) {
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(StackID < Timers->size());
Timers->at(StackID).setName(NewName);
}
// Note: optQueueBlockingPush and optQueueBlockingPop use unique_ptr at the
// interface to take and transfer ownership, but they internally store the raw
// Cfg pointer in the work queue. This allows e.g. future queue optimizations
// such as the use of atomics to modify queue elements.
void GlobalContext::optQueueBlockingPush(std::unique_ptr<OptWorkItem> Item) {
assert(Item);
{
TimerMarker _(TimerStack::TT_qTransPush, this);
OptQ.blockingPush(std::move(Item));
}
if (getFlags().isSequential())
translateFunctions();
}
std::unique_ptr<OptWorkItem> GlobalContext::optQueueBlockingPop() {
TimerMarker _(TimerStack::TT_qTransPop, this);
return OptQ.blockingPop(OptQWakeupSize);
}
void GlobalContext::emitQueueBlockingPush(
std::unique_ptr<EmitterWorkItem> Item) {
assert(Item);
{
TimerMarker _(TimerStack::TT_qEmitPush, this);
EmitQ.blockingPush(std::move(Item));
}
if (getFlags().isSequential())
emitItems();
}
std::unique_ptr<EmitterWorkItem> GlobalContext::emitQueueBlockingPop() {
TimerMarker _(TimerStack::TT_qEmitPop, this);
return EmitQ.blockingPop();
}
void GlobalContext::initParserThread() {
ThreadContext *Tls = new ThreadContext();
auto Timers = getTimers();
Timers->initInto(Tls->Timers);
AllThreadContexts.push_back(Tls);
ICE_TLS_SET_FIELD(TLS, Tls);
}
void GlobalContext::startWorkerThreads() {
size_t NumWorkers = getFlags().getNumTranslationThreads();
auto Timers = getTimers();
for (size_t i = 0; i < NumWorkers; ++i) {
ThreadContext *WorkerTLS = new ThreadContext();
Timers->initInto(WorkerTLS->Timers);
AllThreadContexts.push_back(WorkerTLS);
TranslationThreads.push_back(std::thread(
&GlobalContext::translateFunctionsWrapper, this, WorkerTLS));
}
if (NumWorkers) {
ThreadContext *WorkerTLS = new ThreadContext();
Timers->initInto(WorkerTLS->Timers);
AllThreadContexts.push_back(WorkerTLS);
EmitterThreads.push_back(
std::thread(&GlobalContext::emitterWrapper, this, WorkerTLS));
}
}
void GlobalContext::resetStats() {
if (BuildDefs::dump())
ICE_TLS_GET_FIELD(TLS)->StatsFunction.reset();
}
void GlobalContext::dumpStats(const Cfg *Func) {
if (!getFlags().getDumpStats())
return;
if (Func == nullptr) {
getStatsCumulative()->dump(Func, this);
} else {
ICE_TLS_GET_FIELD(TLS)->StatsFunction.dump(Func, this);
}
}
void GlobalContext::statsUpdateEmitted(uint32_t InstCount) {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_InstCount, InstCount);
Tls->StatsCumulative.update(CodeStats::CS_InstCount, InstCount);
}
void GlobalContext::statsUpdateRegistersSaved(uint32_t Num) {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_RegsSaved, Num);
Tls->StatsCumulative.update(CodeStats::CS_RegsSaved, Num);
}
void GlobalContext::statsUpdateFrameBytes(uint32_t Bytes) {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_FrameByte, Bytes);
Tls->StatsCumulative.update(CodeStats::CS_FrameByte, Bytes);
}
void GlobalContext::statsUpdateSpills() {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_NumSpills);
Tls->StatsCumulative.update(CodeStats::CS_NumSpills);
}
void GlobalContext::statsUpdateFills() {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_NumFills);
Tls->StatsCumulative.update(CodeStats::CS_NumFills);
}
void GlobalContext::statsUpdateRPImms() {
if (!getFlags().getDumpStats())
return;
ThreadContext *Tls = ICE_TLS_GET_FIELD(TLS);
Tls->StatsFunction.update(CodeStats::CS_NumRPImms);
Tls->StatsCumulative.update(CodeStats::CS_NumRPImms);
}
void GlobalContext::dumpTimers(TimerStackIdT StackID, bool DumpCumulative) {
if (!BuildDefs::timers())
return;
auto Timers = getTimers();
assert(Timers->size() > StackID);
OstreamLocker L(this);
Timers->at(StackID).dump(getStrDump(), DumpCumulative);
}
void GlobalContext::dumpLocalTimers(const std::string &TimerNameOverride,
TimerStackIdT StackID,
bool DumpCumulative) {
if (!BuildDefs::timers())
return;
auto *Timers = &ICE_TLS_GET_FIELD(TLS)->Timers;
assert(Timers->size() > StackID);
// Temporarily override the thread-local timer name with the given name.
// Don't do it permanently because the final timer merge at the end expects
// the thread-local timer names to be the same as the global timer name.
auto OrigName = getTimerName(StackID);
setTimerName(StackID, TimerNameOverride);
{
OstreamLocker _(this);
Timers->at(StackID).dump(getStrDump(), DumpCumulative);
}
setTimerName(StackID, OrigName);
}
LockedPtr<StringPool>
GlobalStringPoolTraits::getStrings(const GlobalContext *PoolOwner) {
return PoolOwner->getStrings();
}
TimerIdT TimerMarker::getTimerIdFromFuncName(GlobalContext *Ctx,
const std::string &FuncName) {
if (!BuildDefs::timers())
return 0;
if (!getFlags().getTimeEachFunction())
return 0;
return Ctx->getTimerID(GlobalContext::TSK_Funcs, FuncName);
}
void TimerMarker::push() {
switch (StackID) {
case GlobalContext::TSK_Default:
Active = getFlags().getSubzeroTimingEnabled() ||
!getFlags().getTimingFocusOnString().empty();
break;
case GlobalContext::TSK_Funcs:
Active = getFlags().getTimeEachFunction();
break;
default:
break;
}
if (Active)
Ctx->pushTimer(ID, StackID);
}
void TimerMarker::pushCfg(const Cfg *Func) {
Ctx = Func->getContext();
Active = Func->getFocusedTiming() || getFlags().getSubzeroTimingEnabled();
if (Active)
Ctx->pushTimer(ID, StackID);
}
ICE_TLS_DEFINE_FIELD(GlobalContext::ThreadContext *, GlobalContext, TLS);
} // end of namespace Ice