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//===- subzero/src/IceGlobalContext.h - Global context defs -----*- C++ -*-===//
//
// The Subzero Code Generator
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file
/// \brief Declares aspects of the compilation that persist across multiple
/// functions.
///
//===----------------------------------------------------------------------===//
#ifndef SUBZERO_SRC_ICEGLOBALCONTEXT_H
#define SUBZERO_SRC_ICEGLOBALCONTEXT_H
#include "IceClFlags.h"
#include "IceDefs.h"
#include "IceInstrumentation.h"
#include "IceIntrinsics.h"
#include "IceRNG.h"
#include "IceStringPool.h"
#include "IceSwitchLowering.h"
#include "IceTargetLowering.def"
#include "IceThreading.h"
#include "IceTimerTree.h"
#include "IceTypes.h"
#include "IceUtils.h"
#include <array>
#include <atomic>
#include <cassert>
#include <functional>
#include <memory>
#include <mutex>
#include <thread>
#include <type_traits>
#include <utility>
#include <vector>
namespace Ice {
class ConstantPool;
class EmitterWorkItem;
class FuncSigType;
class Instrumentation;
// Runtime helper function IDs
enum class RuntimeHelper {
#define X(Tag, Name) H_##Tag,
RUNTIME_HELPER_FUNCTIONS_TABLE
#undef X
H_Num
};
/// OptWorkItem is a simple wrapper used to pass parse information on a function
/// block, to a translator thread.
class OptWorkItem {
OptWorkItem(const OptWorkItem &) = delete;
OptWorkItem &operator=(const OptWorkItem &) = delete;
public:
// Get the Cfg for the funtion to translate.
virtual std::unique_ptr<Cfg> getParsedCfg() = 0;
virtual ~OptWorkItem() = default;
protected:
OptWorkItem() = default;
};
class GlobalContext {
GlobalContext() = delete;
GlobalContext(const GlobalContext &) = delete;
GlobalContext &operator=(const GlobalContext &) = delete;
/// CodeStats collects rudimentary statistics during translation.
class CodeStats {
CodeStats(const CodeStats &) = delete;
CodeStats &operator=(const CodeStats &) = default;
#define CODESTATS_TABLE \
/* dump string, enum value */ \
X("Inst Count ", InstCount) \
X("Regs Saved ", RegsSaved) \
X("Frame Bytes ", FrameByte) \
X("Spills ", NumSpills) \
X("Fills ", NumFills) \
X("R/P Imms ", NumRPImms)
//#define X(str, tag)
public:
enum CSTag {
#define X(str, tag) CS_##tag,
CODESTATS_TABLE
#undef X
CS_NUM
};
CodeStats() { reset(); }
void reset() { Stats.fill(0); }
void update(CSTag Tag, uint32_t Count = 1) {
assert(static_cast<SizeT>(Tag) < Stats.size());
Stats[Tag] += Count;
}
void add(const CodeStats &Other) {
for (uint32_t i = 0; i < Stats.size(); ++i)
Stats[i] += Other.Stats[i];
}
/// Dumps the stats for the given Cfg. If Func==nullptr, it identifies it
/// as the "final" cumulative stats instead as a specific function's name.
void dump(const Cfg *Func, GlobalContext *Ctx);
private:
std::array<uint32_t, CS_NUM> Stats;
};
/// TimerList is a vector of TimerStack objects, with extra methods
/// to initialize and merge these vectors.
class TimerList : public std::vector<TimerStack> {
TimerList(const TimerList &) = delete;
TimerList &operator=(const TimerList &) = delete;
public:
TimerList() = default;
/// initInto() initializes a target list of timers based on the
/// current list. In particular, it creates the same number of
/// timers, in the same order, with the same names, but initially
/// empty of timing data.
void initInto(TimerList &Dest) const {
if (!BuildDefs::timers())
return;
Dest.clear();
for (const TimerStack &Stack : *this) {
Dest.push_back(TimerStack(Stack.getName()));
}
}
void mergeFrom(TimerList &Src) {
if (!BuildDefs::timers())
return;
assert(size() == Src.size());
size_type i = 0;
for (TimerStack &Stack : *this) {
assert(Stack.getName() == Src[i].getName());
Stack.mergeFrom(Src[i]);
++i;
}
}
};
/// ThreadContext contains thread-local data. This data can be
/// combined/reduced as needed after all threads complete.
class ThreadContext {
ThreadContext(const ThreadContext &) = delete;
ThreadContext &operator=(const ThreadContext &) = delete;
public:
ThreadContext() = default;
CodeStats StatsFunction;
CodeStats StatsCumulative;
TimerList Timers;
};
public:
/// The dump stream is a log stream while emit is the stream code
/// is emitted to. The error stream is strictly for logging errors.
GlobalContext(Ostream *OsDump, Ostream *OsEmit, Ostream *OsError,
ELFStreamer *ELFStreamer);
~GlobalContext();
void dumpStrings();
///
/// The dump, error, and emit streams need to be used by only one
/// thread at a time. This is done by exclusively reserving the
/// streams via lockStr() and unlockStr(). The OstreamLocker class
/// can be used to conveniently manage this.
///
/// The model is that a thread grabs the stream lock, then does an
/// arbitrary amount of work during which far-away callees may grab
/// the stream and do something with it, and finally the thread
/// releases the stream lock. This allows large chunks of output to
/// be dumped or emitted without risking interleaving from multiple
/// threads.
void lockStr() { StrLock.lock(); }
void unlockStr() { StrLock.unlock(); }
Ostream &getStrDump() { return *StrDump; }
Ostream &getStrError() { return *StrError; }
Ostream &getStrEmit() { return *StrEmit; }
void setStrEmit(Ostream &NewStrEmit) { StrEmit = &NewStrEmit; }
LockedPtr<ErrorCode> getErrorStatus() {
return LockedPtr<ErrorCode>(&ErrorStatus, &ErrorStatusLock);
}
/// \name Manage Constants.
/// @{
// getConstant*() functions are not const because they might add something to
// the constant pool.
Constant *getConstantInt(Type Ty, int64_t Value);
Constant *getConstantInt1(int8_t ConstantInt1) {
ConstantInt1 &= INT8_C(1);
switch (ConstantInt1) {
case 0:
return getConstantZero(IceType_i1);
case 1:
return ConstantTrue;
default:
assert(false && "getConstantInt1 not on true/false");
return getConstantInt1Internal(ConstantInt1);
}
}
Constant *getConstantInt8(int8_t ConstantInt8) {
switch (ConstantInt8) {
case 0:
return getConstantZero(IceType_i8);
default:
return getConstantInt8Internal(ConstantInt8);
}
}
Constant *getConstantInt16(int16_t ConstantInt16) {
switch (ConstantInt16) {
case 0:
return getConstantZero(IceType_i16);
default:
return getConstantInt16Internal(ConstantInt16);
}
}
Constant *getConstantInt32(int32_t ConstantInt32) {
switch (ConstantInt32) {
case 0:
return getConstantZero(IceType_i32);
default:
return getConstantInt32Internal(ConstantInt32);
}
}
Constant *getConstantInt64(int64_t ConstantInt64) {
switch (ConstantInt64) {
case 0:
return getConstantZero(IceType_i64);
default:
return getConstantInt64Internal(ConstantInt64);
}
}
Constant *getConstantFloat(float Value);
Constant *getConstantDouble(double Value);
/// Returns a symbolic constant.
Constant *getConstantSymWithEmitString(const RelocOffsetT Offset,
const RelocOffsetArray &OffsetExpr,
GlobalString Name,
const std::string &EmitString);
Constant *getConstantSym(RelocOffsetT Offset, GlobalString Name);
Constant *getConstantExternSym(GlobalString Name);
/// Returns an undef.
Constant *getConstantUndef(Type Ty);
/// Returns a zero value.
Constant *getConstantZero(Type Ty);
/// getConstantPool() returns a copy of the constant pool for constants of a
/// given type.
ConstantList getConstantPool(Type Ty);
/// Returns a copy of the list of external symbols.
ConstantList getConstantExternSyms();
/// @}
Constant *getRuntimeHelperFunc(RuntimeHelper FuncID) const {
assert(FuncID < RuntimeHelper::H_Num);
Constant *Result = RuntimeHelperFunc[static_cast<size_t>(FuncID)];
assert(Result != nullptr && "No such runtime helper function");
return Result;
}
GlobalString getGlobalString(const std::string &Name);
/// Return a locked pointer to the registered jump tables.
JumpTableDataList getJumpTables();
/// Adds JumpTable to the list of know jump tables, for a posteriori emission.
void addJumpTableData(JumpTableData JumpTable);
/// Allocate data of type T using the global allocator. We allow entities
/// allocated from this global allocator to be either trivially or
/// non-trivially destructible. We optimize the case when T is trivially
/// destructible by not registering a destructor. Destructors will be invoked
/// during GlobalContext destruction in the reverse object creation order.
template <typename T>
typename std::enable_if<std::is_trivially_destructible<T>::value, T>::type *
allocate() {
return getAllocator()->Allocate<T>();
}
template <typename T>
typename std::enable_if<!std::is_trivially_destructible<T>::value, T>::type *
allocate() {
T *Ret = getAllocator()->Allocate<T>();
getDestructors()->emplace_back([Ret]() { Ret->~T(); });
return Ret;
}
const Intrinsics &getIntrinsicsInfo() const { return IntrinsicsInfo; }
ELFObjectWriter *getObjectWriter() const { return ObjectWriter.get(); }
/// Reset stats at the beginning of a function.
void resetStats();
void dumpStats(const Cfg *Func = nullptr);
void statsUpdateEmitted(uint32_t InstCount);
void statsUpdateRegistersSaved(uint32_t Num);
void statsUpdateFrameBytes(uint32_t Bytes);
void statsUpdateSpills();
void statsUpdateFills();
/// Number of Randomized or Pooled Immediates
void statsUpdateRPImms();
/// These are predefined TimerStackIdT values.
enum TimerStackKind { TSK_Default = 0, TSK_Funcs, TSK_Num };
/// newTimerStackID() creates a new TimerStack in the global space. It does
/// not affect any TimerStack objects in TLS.
TimerStackIdT newTimerStackID(const std::string &Name);
/// dumpTimers() dumps the global timer data. This assumes all the
/// thread-local copies of timer data have been merged into the global timer
/// data.
void dumpTimers(TimerStackIdT StackID = TSK_Default,
bool DumpCumulative = true);
void dumpLocalTimers(const std::string &TimerNameOverride,
TimerStackIdT StackID = TSK_Default,
bool DumpCumulative = true);
/// The following methods affect only the calling thread's TLS timer data.
TimerIdT getTimerID(TimerStackIdT StackID, const std::string &Name);
void pushTimer(TimerIdT ID, TimerStackIdT StackID);
void popTimer(TimerIdT ID, TimerStackIdT StackID);
void resetTimer(TimerStackIdT StackID);
std::string getTimerName(TimerStackIdT StackID);
void setTimerName(TimerStackIdT StackID, const std::string &NewName);
/// This is the first work item sequence number that the parser produces, and
/// correspondingly the first sequence number that the emitter thread will
/// wait for. Start numbering at 1 to leave room for a sentinel, in case e.g.
/// we wish to inject items with a special sequence number that may be
/// executed out of order.
static constexpr uint32_t getFirstSequenceNumber() { return 1; }
/// Adds a newly parsed and constructed function to the Cfg work queue.
/// Notifies any idle workers that a new function is available for
/// translating. May block if the work queue is too large, in order to control
/// memory footprint.
void optQueueBlockingPush(std::unique_ptr<OptWorkItem> Item);
/// Takes a Cfg from the work queue for translating. May block if the work
/// queue is currently empty. Returns nullptr if there is no more work - the
/// queue is empty and either end() has been called or the Sequential flag was
/// set.
std::unique_ptr<OptWorkItem> optQueueBlockingPop();
/// Notifies that no more work will be added to the work queue.
void optQueueNotifyEnd() { OptQ.notifyEnd(); }
/// Emit file header for output file.
void emitFileHeader();
void lowerConstants();
void lowerJumpTables();
/// Emit target specific read-only data sections if any. E.g., for MIPS this
/// generates a .MIPS.abiflags section.
void emitTargetRODataSections();
void emitQueueBlockingPush(std::unique_ptr<EmitterWorkItem> Item);
std::unique_ptr<EmitterWorkItem> emitQueueBlockingPop();
void emitQueueNotifyEnd() { EmitQ.notifyEnd(); }
void initParserThread();
void startWorkerThreads();
void waitForWorkerThreads();
/// sets the instrumentation object to use.
void setInstrumentation(std::unique_ptr<Instrumentation> Instr) {
if (!BuildDefs::minimal())
Instrumentor = std::move(Instr);
}
void instrumentFunc(Cfg *Func) {
if (!BuildDefs::minimal() && Instrumentor)
Instrumentor->instrumentFunc(Func);
}
/// Translation thread startup routine.
void translateFunctionsWrapper(ThreadContext *MyTLS);
/// Translate functions from the Cfg queue until the queue is empty.
void translateFunctions();
/// Emitter thread startup routine.
void emitterWrapper(ThreadContext *MyTLS);
/// Emit functions and global initializers from the emitter queue until the
/// queue is empty.
void emitItems();
/// Uses DataLowering to lower Globals. Side effects:
/// - discards the initializer list for the global variable in Globals.
/// - clears the Globals array.
void lowerGlobals(const std::string &SectionSuffix);
/// Lowers the profile information.
void lowerProfileData();
void dumpConstantLookupCounts();
/// DisposeGlobalVariablesAfterLowering controls whether the memory used by
/// GlobaleVariables can be reclaimed right after they have been lowered.
/// @{
bool getDisposeGlobalVariablesAfterLowering() const {
return DisposeGlobalVariablesAfterLowering;
}
void setDisposeGlobalVariablesAfterLowering(bool Value) {
DisposeGlobalVariablesAfterLowering = Value;
}
/// @}
LockedPtr<StringPool> getStrings() const {
return LockedPtr<StringPool>(Strings.get(), &StringsLock);
}
LockedPtr<VariableDeclarationList> getGlobals() {
return LockedPtr<VariableDeclarationList>(&Globals, &InitAllocLock);
}
/// Number of function blocks that can be queued before waiting for
/// translation
/// threads to consume.
static constexpr size_t MaxOptQSize = 1 << 16;
private:
// Try to ensure mutexes are allocated on separate cache lines.
// Destructors collaborate with Allocator
ICE_CACHELINE_BOUNDARY;
// Managed by getAllocator()
mutable GlobalLockType AllocLock;
ArenaAllocator Allocator;
ICE_CACHELINE_BOUNDARY;
// Managed by getInitializerAllocator()
mutable GlobalLockType InitAllocLock;
VariableDeclarationList Globals;
ICE_CACHELINE_BOUNDARY;
// Managed by getDestructors()
using DestructorArray = std::vector<std::function<void()>>;
mutable GlobalLockType DestructorsLock;
DestructorArray Destructors;
ICE_CACHELINE_BOUNDARY;
// Managed by getStrings()
mutable GlobalLockType StringsLock;
std::unique_ptr<StringPool> Strings;
ICE_CACHELINE_BOUNDARY;
// Managed by getConstPool()
mutable GlobalLockType ConstPoolLock;
std::unique_ptr<ConstantPool> ConstPool;
ICE_CACHELINE_BOUNDARY;
// Managed by getJumpTableList()
mutable GlobalLockType JumpTablesLock;
JumpTableDataList JumpTableList;
ICE_CACHELINE_BOUNDARY;
// Managed by getErrorStatus()
mutable GlobalLockType ErrorStatusLock;
ErrorCode ErrorStatus;
ICE_CACHELINE_BOUNDARY;
// Managed by getStatsCumulative()
mutable GlobalLockType StatsLock;
CodeStats StatsCumulative;
ICE_CACHELINE_BOUNDARY;
// Managed by getTimers()
mutable GlobalLockType TimerLock;
TimerList Timers;
ICE_CACHELINE_BOUNDARY;
/// StrLock is a global lock on the dump and emit output streams.
using StrLockType = std::mutex;
StrLockType StrLock;
Ostream *StrDump; /// Stream for dumping / diagnostics
Ostream *StrEmit; /// Stream for code emission
Ostream *StrError; /// Stream for logging errors.
// True if waitForWorkerThreads() has been called.
std::atomic_bool WaitForWorkerThreadsCalled;
ICE_CACHELINE_BOUNDARY;
Intrinsics IntrinsicsInfo;
// TODO(jpp): move to EmitterContext.
std::unique_ptr<ELFObjectWriter> ObjectWriter;
// Value defining when to wake up the main parse thread.
const size_t OptQWakeupSize;
BoundedProducerConsumerQueue<OptWorkItem, MaxOptQSize> OptQ;
BoundedProducerConsumerQueue<EmitterWorkItem> EmitQ;
// DataLowering is only ever used by a single thread at a time (either in
// emitItems(), or in IceCompiler::run before the compilation is over.)
// TODO(jpp): move to EmitterContext.
std::unique_ptr<TargetDataLowering> DataLowering;
/// If !HasEmittedCode, SubZero will accumulate all Globals (which are "true"
/// program global variables) until the first code WorkItem is seen.
// TODO(jpp): move to EmitterContext.
bool HasSeenCode = false;
// If Instrumentor is not empty then it will be used to instrument globals and
// CFGs.
std::unique_ptr<Instrumentation> Instrumentor = nullptr;
// TODO(jpp): move to EmitterContext.
VariableDeclaration *ProfileBlockInfoVarDecl = nullptr;
std::vector<VariableDeclaration *> ProfileBlockInfos;
/// Indicates if global variable declarations can be disposed of right after
/// lowering.
bool DisposeGlobalVariablesAfterLowering = true;
Constant *ConstZeroForType[IceType_NUM];
Constant *ConstantTrue;
// Holds the constants representing each runtime helper function.
Constant *RuntimeHelperFunc[static_cast<size_t>(RuntimeHelper::H_Num)];
Constant *getConstantZeroInternal(Type Ty);
Constant *getConstantIntInternal(Type Ty, int64_t Value);
Constant *getConstantInt1Internal(int8_t ConstantInt1);
Constant *getConstantInt8Internal(int8_t ConstantInt8);
Constant *getConstantInt16Internal(int16_t ConstantInt16);
Constant *getConstantInt32Internal(int32_t ConstantInt32);
Constant *getConstantInt64Internal(int64_t ConstantInt64);
LockedPtr<ArenaAllocator> getAllocator() {
return LockedPtr<ArenaAllocator>(&Allocator, &AllocLock);
}
LockedPtr<VariableDeclarationList> getInitializerAllocator() {
return LockedPtr<VariableDeclarationList>(&Globals, &InitAllocLock);
}
LockedPtr<ConstantPool> getConstPool() {
return LockedPtr<ConstantPool>(ConstPool.get(), &ConstPoolLock);
}
LockedPtr<JumpTableDataList> getJumpTableList() {
return LockedPtr<JumpTableDataList>(&JumpTableList, &JumpTablesLock);
}
LockedPtr<CodeStats> getStatsCumulative() {
return LockedPtr<CodeStats>(&StatsCumulative, &StatsLock);
}
LockedPtr<TimerList> getTimers() {
return LockedPtr<TimerList>(&Timers, &TimerLock);
}
LockedPtr<DestructorArray> getDestructors() {
return LockedPtr<DestructorArray>(&Destructors, &DestructorsLock);
}
void accumulateGlobals(std::unique_ptr<VariableDeclarationList> Globls) {
LockedPtr<VariableDeclarationList> _(&Globals, &InitAllocLock);
if (Globls != nullptr) {
Globals.merge(Globls.get());
if (!BuildDefs::minimal() && Instrumentor != nullptr)
Instrumentor->setHasSeenGlobals();
}
}
void lowerGlobalsIfNoCodeHasBeenSeen() {
if (HasSeenCode)
return;
constexpr char NoSuffix[] = "";
lowerGlobals(NoSuffix);
HasSeenCode = true;
}
void saveBlockInfoPtrs();
llvm::SmallVector<ThreadContext *, 128> AllThreadContexts;
llvm::SmallVector<std::thread, 128> TranslationThreads;
llvm::SmallVector<std::thread, 128> EmitterThreads;
// Each thread has its own TLS pointer which is also held in
// AllThreadContexts.
ICE_TLS_DECLARE_FIELD(ThreadContext *, TLS);
public:
static void TlsInit();
};
/// Helper class to push and pop a timer marker. The constructor pushes a
/// marker, and the destructor pops it. This is for convenient timing of regions
/// of code.
class TimerMarker {
TimerMarker() = delete;
TimerMarker(const TimerMarker &) = delete;
TimerMarker &operator=(const TimerMarker &) = delete;
public:
TimerMarker(TimerIdT ID, GlobalContext *Ctx,
TimerStackIdT StackID = GlobalContext::TSK_Default)
: ID(ID), Ctx(Ctx), StackID(StackID) {
if (BuildDefs::timers())
push();
}
TimerMarker(TimerIdT ID, const Cfg *Func,
TimerStackIdT StackID = GlobalContext::TSK_Default)
: ID(ID), Ctx(nullptr), StackID(StackID) {
// Ctx gets set at the beginning of pushCfg().
if (BuildDefs::timers())
pushCfg(Func);
}
TimerMarker(GlobalContext *Ctx, const std::string &FuncName)
: ID(getTimerIdFromFuncName(Ctx, FuncName)), Ctx(Ctx),
StackID(GlobalContext::TSK_Funcs) {
if (BuildDefs::timers())
push();
}
~TimerMarker() {
if (BuildDefs::timers() && Active)
Ctx->popTimer(ID, StackID);
}
private:
void push();
void pushCfg(const Cfg *Func);
static TimerIdT getTimerIdFromFuncName(GlobalContext *Ctx,
const std::string &FuncName);
const TimerIdT ID;
GlobalContext *Ctx;
const TimerStackIdT StackID;
bool Active = false;
};
/// Helper class for locking the streams and then automatically unlocking them.
class OstreamLocker {
private:
OstreamLocker() = delete;
OstreamLocker(const OstreamLocker &) = delete;
OstreamLocker &operator=(const OstreamLocker &) = delete;
public:
explicit OstreamLocker(GlobalContext *Ctx) : Ctx(Ctx) { Ctx->lockStr(); }
~OstreamLocker() { Ctx->unlockStr(); }
private:
GlobalContext *const Ctx;
};
} // end of namespace Ice
#endif // SUBZERO_SRC_ICEGLOBALCONTEXT_H