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766c0d3596
Before this patch, register writes were always invalidated by the RegisterFile at instruction commit stage. So, the RegisterFile was often losing the knowledge about the `execute cycle` of writes already committed. While this was not problematic for non-delayed reads, this was sometimes leading to inaccurate read latency computations in the presence of negative read-advance cycles. This patch fixes the issue by changing how the RegisterFile component internally keeps track of the `execute cycle` information of each write. On every instruction executed, the RegisterFile gets notified by the RetireStage, so that it can internally record the execute cycle of each executed write. The `execute cycle` information is stored within WriteRef itself, and it is not invalidated when the write is committed.
246 lines
6.7 KiB
C++
246 lines
6.7 KiB
C++
//===--------------------- Instruction.cpp ----------------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines abstractions used by the Pipeline to model register reads,
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// register writes and instructions.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/MCA/Instruction.h"
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#include "llvm/Support/Debug.h"
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#include "llvm/Support/raw_ostream.h"
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namespace llvm {
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namespace mca {
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void WriteState::writeStartEvent(unsigned IID, MCPhysReg RegID,
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unsigned Cycles) {
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CRD.IID = IID;
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CRD.RegID = RegID;
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CRD.Cycles = Cycles;
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DependentWriteCyclesLeft = Cycles;
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DependentWrite = nullptr;
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}
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void ReadState::writeStartEvent(unsigned IID, MCPhysReg RegID,
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unsigned Cycles) {
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assert(DependentWrites);
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assert(CyclesLeft == UNKNOWN_CYCLES);
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// This read may be dependent on more than one write. This typically occurs
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// when a definition is the result of multiple writes where at least one
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// write does a partial register update.
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// The HW is forced to do some extra bookkeeping to track of all the
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// dependent writes, and implement a merging scheme for the partial writes.
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--DependentWrites;
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if (TotalCycles < Cycles) {
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CRD.IID = IID;
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CRD.RegID = RegID;
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CRD.Cycles = Cycles;
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TotalCycles = Cycles;
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}
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if (!DependentWrites) {
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CyclesLeft = TotalCycles;
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IsReady = !CyclesLeft;
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}
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}
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void WriteState::onInstructionIssued(unsigned IID) {
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assert(CyclesLeft == UNKNOWN_CYCLES);
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// Update the number of cycles left based on the WriteDescriptor info.
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CyclesLeft = getLatency();
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// Now that the time left before write-back is known, notify
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// all the users.
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for (const std::pair<ReadState *, int> &User : Users) {
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ReadState *RS = User.first;
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unsigned ReadCycles = std::max(0, CyclesLeft - User.second);
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RS->writeStartEvent(IID, RegisterID, ReadCycles);
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}
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// Notify any writes that are in a false dependency with this write.
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if (PartialWrite)
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PartialWrite->writeStartEvent(IID, RegisterID, CyclesLeft);
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}
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void WriteState::addUser(unsigned IID, ReadState *User, int ReadAdvance) {
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// If CyclesLeft is different than -1, then we don't need to
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// update the list of users. We can just notify the user with
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// the actual number of cycles left (which may be zero).
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if (CyclesLeft != UNKNOWN_CYCLES) {
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unsigned ReadCycles = std::max(0, CyclesLeft - ReadAdvance);
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User->writeStartEvent(IID, RegisterID, ReadCycles);
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return;
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}
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Users.emplace_back(User, ReadAdvance);
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}
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void WriteState::addUser(unsigned IID, WriteState *User) {
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if (CyclesLeft != UNKNOWN_CYCLES) {
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User->writeStartEvent(IID, RegisterID, std::max(0, CyclesLeft));
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return;
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}
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assert(!PartialWrite && "PartialWrite already set!");
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PartialWrite = User;
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User->setDependentWrite(this);
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}
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void WriteState::cycleEvent() {
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// Note: CyclesLeft can be a negative number. It is an error to
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// make it an unsigned quantity because users of this write may
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// specify a negative ReadAdvance.
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if (CyclesLeft != UNKNOWN_CYCLES)
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CyclesLeft--;
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if (DependentWriteCyclesLeft)
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DependentWriteCyclesLeft--;
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}
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void ReadState::cycleEvent() {
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// Update the total number of cycles.
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if (DependentWrites && TotalCycles) {
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--TotalCycles;
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return;
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}
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// Bail out immediately if we don't know how many cycles are left.
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if (CyclesLeft == UNKNOWN_CYCLES)
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return;
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if (CyclesLeft) {
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--CyclesLeft;
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IsReady = !CyclesLeft;
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}
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}
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#ifndef NDEBUG
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void WriteState::dump() const {
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dbgs() << "{ OpIdx=" << WD->OpIndex << ", Lat=" << getLatency() << ", RegID "
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<< getRegisterID() << ", Cycles Left=" << getCyclesLeft() << " }";
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}
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#endif
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const CriticalDependency &Instruction::computeCriticalRegDep() {
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if (CriticalRegDep.Cycles)
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return CriticalRegDep;
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unsigned MaxLatency = 0;
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for (const WriteState &WS : getDefs()) {
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const CriticalDependency &WriteCRD = WS.getCriticalRegDep();
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if (WriteCRD.Cycles > MaxLatency)
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CriticalRegDep = WriteCRD;
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}
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for (const ReadState &RS : getUses()) {
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const CriticalDependency &ReadCRD = RS.getCriticalRegDep();
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if (ReadCRD.Cycles > MaxLatency)
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CriticalRegDep = ReadCRD;
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}
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return CriticalRegDep;
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}
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void Instruction::dispatch(unsigned RCUToken) {
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assert(Stage == IS_INVALID);
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Stage = IS_DISPATCHED;
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RCUTokenID = RCUToken;
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// Check if input operands are already available.
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if (updateDispatched())
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updatePending();
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}
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void Instruction::execute(unsigned IID) {
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assert(Stage == IS_READY);
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Stage = IS_EXECUTING;
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// Set the cycles left before the write-back stage.
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CyclesLeft = getLatency();
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for (WriteState &WS : getDefs())
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WS.onInstructionIssued(IID);
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// Transition to the "executed" stage if this is a zero-latency instruction.
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if (!CyclesLeft)
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Stage = IS_EXECUTED;
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}
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void Instruction::forceExecuted() {
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assert(Stage == IS_READY && "Invalid internal state!");
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CyclesLeft = 0;
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Stage = IS_EXECUTED;
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}
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bool Instruction::updatePending() {
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assert(isPending() && "Unexpected instruction stage found!");
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if (!all_of(getUses(), [](const ReadState &Use) { return Use.isReady(); }))
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return false;
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// A partial register write cannot complete before a dependent write.
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if (!all_of(getDefs(), [](const WriteState &Def) { return Def.isReady(); }))
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return false;
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Stage = IS_READY;
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return true;
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}
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bool Instruction::updateDispatched() {
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assert(isDispatched() && "Unexpected instruction stage found!");
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if (!all_of(getUses(), [](const ReadState &Use) {
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return Use.isPending() || Use.isReady();
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}))
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return false;
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// A partial register write cannot complete before a dependent write.
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if (!all_of(getDefs(),
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[](const WriteState &Def) { return !Def.getDependentWrite(); }))
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return false;
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Stage = IS_PENDING;
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return true;
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}
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void Instruction::update() {
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if (isDispatched())
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updateDispatched();
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if (isPending())
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updatePending();
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}
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void Instruction::cycleEvent() {
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if (isReady())
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return;
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if (isDispatched() || isPending()) {
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for (ReadState &Use : getUses())
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Use.cycleEvent();
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for (WriteState &Def : getDefs())
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Def.cycleEvent();
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update();
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return;
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}
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assert(isExecuting() && "Instruction not in-flight?");
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assert(CyclesLeft && "Instruction already executed?");
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for (WriteState &Def : getDefs())
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Def.cycleEvent();
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CyclesLeft--;
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if (!CyclesLeft)
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Stage = IS_EXECUTED;
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}
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} // namespace mca
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} // namespace llvm
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