llvm/lib/MCA/HardwareUnits/LSUnit.cpp - llvm-project - Git at Google

 //===----------------------- LSUnit.cpp --------------------------*- C++-*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 /// \file
 ///
 /// A Load-Store Unit for the llvm-mca tool.
 ///
 //===----------------------------------------------------------------------===//

 #include "llvm/MCA/HardwareUnits/LSUnit.h"
 #include "llvm/MCA/Instruction.h"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/raw_ostream.h"

 #define DEBUG_TYPE "llvm-mca"

 namespace llvm {
 namespace mca {

 LSUnitBase::LSUnitBase(const MCSchedModel &SM, unsigned LQ, unsigned SQ,
                        bool AssumeNoAlias)
     : LQSize(LQ), SQSize(SQ), UsedLQEntries(0), UsedSQEntries(0),
       NoAlias(AssumeNoAlias), NextGroupID(1) {
   if (SM.hasExtraProcessorInfo()) {
     const MCExtraProcessorInfo &EPI = SM.getExtraProcessorInfo();
     if (!LQSize && EPI.LoadQueueID) {
       const MCProcResourceDesc &LdQDesc = *SM.getProcResource(EPI.LoadQueueID);
       LQSize = std::max(0, LdQDesc.BufferSize);
     }

     if (!SQSize && EPI.StoreQueueID) {
       const MCProcResourceDesc &StQDesc = *SM.getProcResource(EPI.StoreQueueID);
       SQSize = std::max(0, StQDesc.BufferSize);
     }
   }
 }

 LSUnitBase::~LSUnitBase() {}

 void LSUnitBase::cycleEvent() {
   for (const std::pair<unsigned, std::unique_ptr<MemoryGroup>> &G : Groups)
     G.second->cycleEvent();
 }

 #ifndef NDEBUG
 void LSUnitBase::dump() const {
   dbgs() << "[LSUnit] LQ_Size = " << getLoadQueueSize() << '\n';
   dbgs() << "[LSUnit] SQ_Size = " << getStoreQueueSize() << '\n';
   dbgs() << "[LSUnit] NextLQSlotIdx = " << getUsedLQEntries() << '\n';
   dbgs() << "[LSUnit] NextSQSlotIdx = " << getUsedSQEntries() << '\n';
   dbgs() << "\n";
   for (const auto &GroupIt : Groups) {
     const MemoryGroup &Group = *GroupIt.second;
     dbgs() << "[LSUnit] Group (" << GroupIt.first << "): "
            << "[ #Preds = " << Group.getNumPredecessors()
            << ", #GIssued = " << Group.getNumExecutingPredecessors()
            << ", #GExecuted = " << Group.getNumExecutedPredecessors()
            << ", #Inst = " << Group.getNumInstructions()
            << ", #IIssued = " << Group.getNumExecuting()
            << ", #IExecuted = " << Group.getNumExecuted() << '\n';
   }
 }
 #endif

 unsigned LSUnit::dispatch(const InstRef &IR) {
   const InstrDesc &Desc = IR.getInstruction()->getDesc();
   unsigned IsMemBarrier = Desc.HasSideEffects;
   assert((Desc.MayLoad || Desc.MayStore) && "Not a memory operation!");

   if (Desc.MayLoad)
     acquireLQSlot();
   if (Desc.MayStore)
     acquireSQSlot();

   if (Desc.MayStore) {
     unsigned NewGID = createMemoryGroup();
     MemoryGroup &NewGroup = getGroup(NewGID);
     NewGroup.addInstruction();

     // A store may not pass a previous load or load barrier.
     unsigned ImmediateLoadDominator =
         std::max(CurrentLoadGroupID, CurrentLoadBarrierGroupID);
     if (ImmediateLoadDominator) {
       MemoryGroup &IDom = getGroup(ImmediateLoadDominator);
       LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << ImmediateLoadDominator
                         << ") --> (" << NewGID << ")\n");
       IDom.addSuccessor(&NewGroup, !assumeNoAlias());
     }

     // A store may not pass a previous store barrier.
     if (CurrentStoreBarrierGroupID) {
       MemoryGroup &StoreGroup = getGroup(CurrentStoreBarrierGroupID);
       LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
                         << CurrentStoreBarrierGroupID
                         << ") --> (" << NewGID << ")\n");
       StoreGroup.addSuccessor(&NewGroup, true);
     }

     // A store may not pass a previous store.
     if (CurrentStoreGroupID &&
         (CurrentStoreGroupID != CurrentStoreBarrierGroupID)) {
       MemoryGroup &StoreGroup = getGroup(CurrentStoreGroupID);
       LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << CurrentStoreGroupID
                         << ") --> (" << NewGID << ")\n");
       StoreGroup.addSuccessor(&NewGroup, !assumeNoAlias());
     }


     CurrentStoreGroupID = NewGID;
     if (IsMemBarrier)
       CurrentStoreBarrierGroupID = NewGID;

     if (Desc.MayLoad) {
       CurrentLoadGroupID = NewGID;
       if (IsMemBarrier)
         CurrentLoadBarrierGroupID = NewGID;
     }

     return NewGID;
   }

   assert(Desc.MayLoad && "Expected a load!");

   unsigned ImmediateLoadDominator =
       std::max(CurrentLoadGroupID, CurrentLoadBarrierGroupID);

   // A new load group is created if we are in one of the following situations:
   // 1) This is a load barrier (by construction, a load barrier is always
   //    assigned to a different memory group).
   // 2) There is no load in flight (by construction we always keep loads and
   //    stores into separate memory groups).
   // 3) There is a load barrier in flight. This load depends on it.
   // 4) There is an intervening store between the last load dispatched to the
   //    LSU and this load. We always create a new group even if this load
   //    does not alias the last dispatched store.
   // 5) There is no intervening store and there is an active load group.
   //    However that group has already started execution, so we cannot add
   //    this load to it.
   bool ShouldCreateANewGroup =
       IsMemBarrier || !ImmediateLoadDominator ||
       CurrentLoadBarrierGroupID == ImmediateLoadDominator ||
       ImmediateLoadDominator <= CurrentStoreGroupID ||
       getGroup(ImmediateLoadDominator).isExecuting();

   if (ShouldCreateANewGroup) {
     unsigned NewGID = createMemoryGroup();
     MemoryGroup &NewGroup = getGroup(NewGID);
     NewGroup.addInstruction();

     // A load may not pass a previous store or store barrier
     // unless flag 'NoAlias' is set.
     if (!assumeNoAlias() && CurrentStoreGroupID) {
       MemoryGroup &StoreGroup = getGroup(CurrentStoreGroupID);
       LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << CurrentStoreGroupID
                         << ") --> (" << NewGID << ")\n");
       StoreGroup.addSuccessor(&NewGroup, true);
     }

     // A load barrier may not pass a previous load or load barrier.
     if (IsMemBarrier) {
       if (ImmediateLoadDominator) {
         MemoryGroup &LoadGroup = getGroup(ImmediateLoadDominator);
         LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
                           << ImmediateLoadDominator
                           << ") --> (" << NewGID << ")\n");
         LoadGroup.addSuccessor(&NewGroup, true);
       }
     } else {
       // A younger load cannot pass a older load barrier.
       if (CurrentLoadBarrierGroupID) {
         MemoryGroup &LoadGroup = getGroup(CurrentLoadBarrierGroupID);
         LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
                           << CurrentLoadBarrierGroupID
                           << ") --> (" << NewGID << ")\n");
         LoadGroup.addSuccessor(&NewGroup, true);
       }
     }

     CurrentLoadGroupID = NewGID;
     if (IsMemBarrier)
       CurrentLoadBarrierGroupID = NewGID;
     return NewGID;
   }

   // A load may pass a previous load.
   MemoryGroup &Group = getGroup(CurrentLoadGroupID);
   Group.addInstruction();
   return CurrentLoadGroupID;
 }

 LSUnit::Status LSUnit::isAvailable(const InstRef &IR) const {
   const InstrDesc &Desc = IR.getInstruction()->getDesc();
   if (Desc.MayLoad && isLQFull())
     return LSUnit::LSU_LQUEUE_FULL;
   if (Desc.MayStore && isSQFull())
     return LSUnit::LSU_SQUEUE_FULL;
   return LSUnit::LSU_AVAILABLE;
 }

 void LSUnitBase::onInstructionExecuted(const InstRef &IR) {
   unsigned GroupID = IR.getInstruction()->getLSUTokenID();
   auto It = Groups.find(GroupID);
   assert(It != Groups.end() && "Instruction not dispatched to the LS unit");
   It->second->onInstructionExecuted(IR);
   if (It->second->isExecuted())
     Groups.erase(It);
 }

 void LSUnitBase::onInstructionRetired(const InstRef &IR) {
   const InstrDesc &Desc = IR.getInstruction()->getDesc();
   bool IsALoad = Desc.MayLoad;
   bool IsAStore = Desc.MayStore;
   assert((IsALoad || IsAStore) && "Expected a memory operation!");

   if (IsALoad) {
     releaseLQSlot();
     LLVM_DEBUG(dbgs() << "[LSUnit]: Instruction idx=" << IR.getSourceIndex()
                       << " has been removed from the load queue.\n");
   }

   if (IsAStore) {
     releaseSQSlot();
     LLVM_DEBUG(dbgs() << "[LSUnit]: Instruction idx=" << IR.getSourceIndex()
                       << " has been removed from the store queue.\n");
   }
 }

 void LSUnit::onInstructionExecuted(const InstRef &IR) {
   const Instruction &IS = *IR.getInstruction();
   if (!IS.isMemOp())
     return;

   LSUnitBase::onInstructionExecuted(IR);
   unsigned GroupID = IS.getLSUTokenID();
   if (!isValidGroupID(GroupID)) {
     if (GroupID == CurrentLoadGroupID)
       CurrentLoadGroupID = 0;
     if (GroupID == CurrentStoreGroupID)
       CurrentStoreGroupID = 0;
     if (GroupID == CurrentLoadBarrierGroupID)
       CurrentLoadBarrierGroupID = 0;
     if (GroupID == CurrentStoreBarrierGroupID)
       CurrentStoreBarrierGroupID = 0;
   }
 }

 } // namespace mca
 } // namespace llvm
	//===----------------------- LSUnit.cpp --------------------------- C++--===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	/// \file
	///
	/// A Load-Store Unit for the llvm-mca tool.
	///
	//===----------------------------------------------------------------------===//

	#include "llvm/MCA/HardwareUnits/LSUnit.h"
	#include "llvm/MCA/Instruction.h"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/raw_ostream.h"

	#define DEBUG_TYPE "llvm-mca"

	namespace llvm {
	namespace mca {

	LSUnitBase::LSUnitBase(const MCSchedModel &SM, unsigned LQ, unsigned SQ,
	bool AssumeNoAlias)
	: LQSize(LQ), SQSize(SQ), UsedLQEntries(0), UsedSQEntries(0),
	NoAlias(AssumeNoAlias), NextGroupID(1) {
	if (SM.hasExtraProcessorInfo()) {
	const MCExtraProcessorInfo &EPI = SM.getExtraProcessorInfo();
	if (!LQSize && EPI.LoadQueueID) {
	const MCProcResourceDesc &LdQDesc = *SM.getProcResource(EPI.LoadQueueID);
	LQSize = std::max(0, LdQDesc.BufferSize);
	}

	if (!SQSize && EPI.StoreQueueID) {
	const MCProcResourceDesc &StQDesc = *SM.getProcResource(EPI.StoreQueueID);
	SQSize = std::max(0, StQDesc.BufferSize);
	}
	}
	}

	LSUnitBase::~LSUnitBase() {}

	void LSUnitBase::cycleEvent() {
	for (const std::pair<unsigned, std::unique_ptr<MemoryGroup>> &G : Groups)
	G.second->cycleEvent();
	}

	#ifndef NDEBUG
	void LSUnitBase::dump() const {
	dbgs() << "[LSUnit] LQ_Size = " << getLoadQueueSize() << '\n';
	dbgs() << "[LSUnit] SQ_Size = " << getStoreQueueSize() << '\n';
	dbgs() << "[LSUnit] NextLQSlotIdx = " << getUsedLQEntries() << '\n';
	dbgs() << "[LSUnit] NextSQSlotIdx = " << getUsedSQEntries() << '\n';
	dbgs() << "\n";
	for (const auto &GroupIt : Groups) {
	const MemoryGroup &Group = *GroupIt.second;
	dbgs() << "[LSUnit] Group (" << GroupIt.first << "): "
	<< "[ #Preds = " << Group.getNumPredecessors()
	<< ", #GIssued = " << Group.getNumExecutingPredecessors()
	<< ", #GExecuted = " << Group.getNumExecutedPredecessors()
	<< ", #Inst = " << Group.getNumInstructions()
	<< ", #IIssued = " << Group.getNumExecuting()
	<< ", #IExecuted = " << Group.getNumExecuted() << '\n';
	}
	}
	#endif

	unsigned LSUnit::dispatch(const InstRef &IR) {
	const InstrDesc &Desc = IR.getInstruction()->getDesc();
	unsigned IsMemBarrier = Desc.HasSideEffects;
	assert((Desc.MayLoad \|\| Desc.MayStore) && "Not a memory operation!");

	if (Desc.MayLoad)
	acquireLQSlot();
	if (Desc.MayStore)
	acquireSQSlot();

	if (Desc.MayStore) {
	unsigned NewGID = createMemoryGroup();
	MemoryGroup &NewGroup = getGroup(NewGID);
	NewGroup.addInstruction();

	// A store may not pass a previous load or load barrier.
	unsigned ImmediateLoadDominator =
	std::max(CurrentLoadGroupID, CurrentLoadBarrierGroupID);
	if (ImmediateLoadDominator) {
	MemoryGroup &IDom = getGroup(ImmediateLoadDominator);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << ImmediateLoadDominator
	<< ") --> (" << NewGID << ")\n");
	IDom.addSuccessor(&NewGroup, !assumeNoAlias());
	}

	// A store may not pass a previous store barrier.
	if (CurrentStoreBarrierGroupID) {
	MemoryGroup &StoreGroup = getGroup(CurrentStoreBarrierGroupID);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
	<< CurrentStoreBarrierGroupID
	<< ") --> (" << NewGID << ")\n");
	StoreGroup.addSuccessor(&NewGroup, true);
	}

	// A store may not pass a previous store.
	if (CurrentStoreGroupID &&
	(CurrentStoreGroupID != CurrentStoreBarrierGroupID)) {
	MemoryGroup &StoreGroup = getGroup(CurrentStoreGroupID);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << CurrentStoreGroupID
	<< ") --> (" << NewGID << ")\n");
	StoreGroup.addSuccessor(&NewGroup, !assumeNoAlias());
	}


	CurrentStoreGroupID = NewGID;
	if (IsMemBarrier)
	CurrentStoreBarrierGroupID = NewGID;

	if (Desc.MayLoad) {
	CurrentLoadGroupID = NewGID;
	if (IsMemBarrier)
	CurrentLoadBarrierGroupID = NewGID;
	}

	return NewGID;
	}

	assert(Desc.MayLoad && "Expected a load!");

	unsigned ImmediateLoadDominator =
	std::max(CurrentLoadGroupID, CurrentLoadBarrierGroupID);

	// A new load group is created if we are in one of the following situations:
	// 1) This is a load barrier (by construction, a load barrier is always
	// assigned to a different memory group).
	// 2) There is no load in flight (by construction we always keep loads and
	// stores into separate memory groups).
	// 3) There is a load barrier in flight. This load depends on it.
	// 4) There is an intervening store between the last load dispatched to the
	// LSU and this load. We always create a new group even if this load
	// does not alias the last dispatched store.
	// 5) There is no intervening store and there is an active load group.
	// However that group has already started execution, so we cannot add
	// this load to it.
	bool ShouldCreateANewGroup =
	IsMemBarrier \|\| !ImmediateLoadDominator \|\|
	CurrentLoadBarrierGroupID == ImmediateLoadDominator \|\|
	ImmediateLoadDominator <= CurrentStoreGroupID \|\|
	getGroup(ImmediateLoadDominator).isExecuting();

	if (ShouldCreateANewGroup) {
	unsigned NewGID = createMemoryGroup();
	MemoryGroup &NewGroup = getGroup(NewGID);
	NewGroup.addInstruction();

	// A load may not pass a previous store or store barrier
	// unless flag 'NoAlias' is set.
	if (!assumeNoAlias() && CurrentStoreGroupID) {
	MemoryGroup &StoreGroup = getGroup(CurrentStoreGroupID);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: (" << CurrentStoreGroupID
	<< ") --> (" << NewGID << ")\n");
	StoreGroup.addSuccessor(&NewGroup, true);
	}

	// A load barrier may not pass a previous load or load barrier.
	if (IsMemBarrier) {
	if (ImmediateLoadDominator) {
	MemoryGroup &LoadGroup = getGroup(ImmediateLoadDominator);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
	<< ImmediateLoadDominator
	<< ") --> (" << NewGID << ")\n");
	LoadGroup.addSuccessor(&NewGroup, true);
	}
	} else {
	// A younger load cannot pass a older load barrier.
	if (CurrentLoadBarrierGroupID) {
	MemoryGroup &LoadGroup = getGroup(CurrentLoadBarrierGroupID);
	LLVM_DEBUG(dbgs() << "[LSUnit]: GROUP DEP: ("
	<< CurrentLoadBarrierGroupID
	<< ") --> (" << NewGID << ")\n");
	LoadGroup.addSuccessor(&NewGroup, true);
	}
	}

	CurrentLoadGroupID = NewGID;
	if (IsMemBarrier)
	CurrentLoadBarrierGroupID = NewGID;
	return NewGID;
	}

	// A load may pass a previous load.
	MemoryGroup &Group = getGroup(CurrentLoadGroupID);
	Group.addInstruction();
	return CurrentLoadGroupID;
	}

	LSUnit::Status LSUnit::isAvailable(const InstRef &IR) const {
	const InstrDesc &Desc = IR.getInstruction()->getDesc();
	if (Desc.MayLoad && isLQFull())
	return LSUnit::LSU_LQUEUE_FULL;
	if (Desc.MayStore && isSQFull())
	return LSUnit::LSU_SQUEUE_FULL;
	return LSUnit::LSU_AVAILABLE;
	}

	void LSUnitBase::onInstructionExecuted(const InstRef &IR) {
	unsigned GroupID = IR.getInstruction()->getLSUTokenID();
	auto It = Groups.find(GroupID);
	assert(It != Groups.end() && "Instruction not dispatched to the LS unit");
	It->second->onInstructionExecuted(IR);
	if (It->second->isExecuted())
	Groups.erase(It);
	}

	void LSUnitBase::onInstructionRetired(const InstRef &IR) {
	const InstrDesc &Desc = IR.getInstruction()->getDesc();
	bool IsALoad = Desc.MayLoad;
	bool IsAStore = Desc.MayStore;
	assert((IsALoad \|\| IsAStore) && "Expected a memory operation!");

	if (IsALoad) {
	releaseLQSlot();
	LLVM_DEBUG(dbgs() << "[LSUnit]: Instruction idx=" << IR.getSourceIndex()
	<< " has been removed from the load queue.\n");
	}

	if (IsAStore) {
	releaseSQSlot();
	LLVM_DEBUG(dbgs() << "[LSUnit]: Instruction idx=" << IR.getSourceIndex()
	<< " has been removed from the store queue.\n");
	}
	}

	void LSUnit::onInstructionExecuted(const InstRef &IR) {
	const Instruction &IS = *IR.getInstruction();
	if (!IS.isMemOp())
	return;

	LSUnitBase::onInstructionExecuted(IR);
	unsigned GroupID = IS.getLSUTokenID();
	if (!isValidGroupID(GroupID)) {
	if (GroupID == CurrentLoadGroupID)
	CurrentLoadGroupID = 0;
	if (GroupID == CurrentStoreGroupID)
	CurrentStoreGroupID = 0;
	if (GroupID == CurrentLoadBarrierGroupID)
	CurrentLoadBarrierGroupID = 0;
	if (GroupID == CurrentStoreBarrierGroupID)
	CurrentStoreBarrierGroupID = 0;
	}
	}

	} // namespace mca
	} // namespace llvm