//===---------------------- RetireControlUnit.h -----------------*- 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
///
/// This file simulates the hardware responsible for retiring instructions.
///
//===----------------------------------------------------------------------===//
#ifndef LLVM_MCA_HARDWAREUNITS_RETIRECONTROLUNIT_H
#define LLVM_MCA_HARDWAREUNITS_RETIRECONTROLUNIT_H
#include "llvm/MC/MCSchedule.h"
#include "llvm/MCA/HardwareUnits/HardwareUnit.h"
#include "llvm/MCA/Instruction.h"
#include <vector>
namespace llvm {
namespace mca {
/// This class tracks which instructions are in-flight (i.e., dispatched but not
/// retired) in the OoO backend.
//
/// This class checks on every cycle if/which instructions can be retired.
/// Instructions are retired in program order.
/// In the event of an instruction being retired, the pipeline that owns
/// this RetireControlUnit (RCU) gets notified.
///
/// On instruction retired, register updates are all architecturally
/// committed, and any physicall registers previously allocated for the
/// retired instruction are freed.
struct RetireControlUnit : public HardwareUnit {
// A RUToken is created by the RCU for every instruction dispatched to the
// schedulers. These "tokens" are managed by the RCU in its token Queue.
//
// On every cycle ('cycleEvent'), the RCU iterates through the token queue
// looking for any token with its 'Executed' flag set. If a token has that
// flag set, then the instruction has reached the write-back stage and will
// be retired by the RCU.
//
// 'NumSlots' represents the number of entries consumed by the instruction in
// the reorder buffer. Those entries will become available again once the
// instruction is retired.
//
// Note that the size of the reorder buffer is defined by the scheduling
// model via field 'NumMicroOpBufferSize'.
struct RUToken {
InstRef IR;
unsigned NumSlots; // Slots reserved to this instruction.
bool Executed; // True if the instruction is past the WB stage.
};
private:
unsigned NextAvailableSlotIdx;
unsigned CurrentInstructionSlotIdx;
unsigned NumROBEntries;
unsigned AvailableEntries;
unsigned MaxRetirePerCycle; // 0 means no limit.
std::vector<RUToken> Queue;
unsigned normalizeQuantity(unsigned Quantity) const {
// Some instructions may declare a number of uOps which exceeds the size
// of the reorder buffer. To avoid problems, cap the amount of slots to
// the size of the reorder buffer.
Quantity = std::min(Quantity, NumROBEntries);
// Further normalize the number of micro opcodes for instructions that
// declare zero opcodes. This should match the behavior of method
// reserveSlot().
return std::max(Quantity, 1U);
}
unsigned computeNextSlotIdx() const;
public:
RetireControlUnit(const MCSchedModel &SM);
bool isEmpty() const { return AvailableEntries == NumROBEntries; }
bool isAvailable(unsigned Quantity = 1) const {
return AvailableEntries >= normalizeQuantity(Quantity);
}
unsigned getMaxRetirePerCycle() const { return MaxRetirePerCycle; }
// Reserves a number of slots, and returns a new token reference.
unsigned dispatch(const InstRef &IS);
// Return the current token from the RCU's circular token queue.
const RUToken &getCurrentToken() const;
const RUToken &peekNextToken() const;
// Advance the pointer to the next token in the circular token queue.
void consumeCurrentToken();
// Update the RCU token to represent the executed state.
void onInstructionExecuted(unsigned TokenID);
#ifndef NDEBUG
void dump() const;
#endif
// Assigned to instructions that are not handled by the RCU.
static const unsigned UnhandledTokenID = ~0U;
};
} // namespace mca
} // namespace llvm
#endif // LLVM_MCA_HARDWAREUNITS_RETIRECONTROLUNIT_H