[InstCombine] Signed saturation tests. NFC
[llvm-complete.git] / lib / MCA / Stages / DispatchStage.cpp
blob3a3d82259160a93dc370e72ad31b95253fe6a105
1 //===--------------------- DispatchStage.cpp --------------------*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 /// \file
9 ///
10 /// This file models the dispatch component of an instruction pipeline.
11 ///
12 /// The DispatchStage is responsible for updating instruction dependencies
13 /// and communicating to the simulated instruction scheduler that an instruction
14 /// is ready to be scheduled for execution.
15 ///
16 //===----------------------------------------------------------------------===//
18 #include "llvm/MCA/Stages/DispatchStage.h"
19 #include "llvm/MCA/HWEventListener.h"
20 #include "llvm/MCA/HardwareUnits/Scheduler.h"
21 #include "llvm/Support/Debug.h"
23 #define DEBUG_TYPE "llvm-mca"
25 namespace llvm {
26 namespace mca {
28 DispatchStage::DispatchStage(const MCSubtargetInfo &Subtarget,
29 const MCRegisterInfo &MRI,
30 unsigned MaxDispatchWidth, RetireControlUnit &R,
31 RegisterFile &F)
32 : DispatchWidth(MaxDispatchWidth), AvailableEntries(MaxDispatchWidth),
33 CarryOver(0U), CarriedOver(), STI(Subtarget), RCU(R), PRF(F) {
34 if (!DispatchWidth)
35 DispatchWidth = Subtarget.getSchedModel().IssueWidth;
38 void DispatchStage::notifyInstructionDispatched(const InstRef &IR,
39 ArrayRef<unsigned> UsedRegs,
40 unsigned UOps) const {
41 LLVM_DEBUG(dbgs() << "[E] Instruction Dispatched: #" << IR << '\n');
42 notifyEvent<HWInstructionEvent>(
43 HWInstructionDispatchedEvent(IR, UsedRegs, UOps));
46 bool DispatchStage::checkPRF(const InstRef &IR) const {
47 SmallVector<MCPhysReg, 4> RegDefs;
48 for (const WriteState &RegDef : IR.getInstruction()->getDefs())
49 RegDefs.emplace_back(RegDef.getRegisterID());
51 const unsigned RegisterMask = PRF.isAvailable(RegDefs);
52 // A mask with all zeroes means: register files are available.
53 if (RegisterMask) {
54 notifyEvent<HWStallEvent>(
55 HWStallEvent(HWStallEvent::RegisterFileStall, IR));
56 return false;
59 return true;
62 bool DispatchStage::checkRCU(const InstRef &IR) const {
63 const unsigned NumMicroOps = IR.getInstruction()->getNumMicroOps();
64 if (RCU.isAvailable(NumMicroOps))
65 return true;
66 notifyEvent<HWStallEvent>(
67 HWStallEvent(HWStallEvent::RetireControlUnitStall, IR));
68 return false;
71 bool DispatchStage::canDispatch(const InstRef &IR) const {
72 bool CanDispatch = checkRCU(IR);
73 CanDispatch &= checkPRF(IR);
74 CanDispatch &= checkNextStage(IR);
75 return CanDispatch;
78 Error DispatchStage::dispatch(InstRef IR) {
79 assert(!CarryOver && "Cannot dispatch another instruction!");
80 Instruction &IS = *IR.getInstruction();
81 const InstrDesc &Desc = IS.getDesc();
82 const unsigned NumMicroOps = IS.getNumMicroOps();
83 if (NumMicroOps > DispatchWidth) {
84 assert(AvailableEntries == DispatchWidth);
85 AvailableEntries = 0;
86 CarryOver = NumMicroOps - DispatchWidth;
87 CarriedOver = IR;
88 } else {
89 assert(AvailableEntries >= NumMicroOps);
90 AvailableEntries -= NumMicroOps;
93 // Check if this instructions ends the dispatch group.
94 if (Desc.EndGroup)
95 AvailableEntries = 0;
97 // Check if this is an optimizable reg-reg move.
98 if (IS.isOptimizableMove()) {
99 assert(IS.getDefs().size() == 1 && "Expected a single input!");
100 assert(IS.getUses().size() == 1 && "Expected a single output!");
101 if (PRF.tryEliminateMove(IS.getDefs()[0], IS.getUses()[0]))
102 IS.setEliminated();
105 // A dependency-breaking instruction doesn't have to wait on the register
106 // input operands, and it is often optimized at register renaming stage.
107 // Update RAW dependencies if this instruction is not a dependency-breaking
108 // instruction. A dependency-breaking instruction is a zero-latency
109 // instruction that doesn't consume hardware resources.
110 // An example of dependency-breaking instruction on X86 is a zero-idiom XOR.
112 // We also don't update data dependencies for instructions that have been
113 // eliminated at register renaming stage.
114 if (!IS.isEliminated()) {
115 for (ReadState &RS : IS.getUses())
116 PRF.addRegisterRead(RS, STI);
119 // By default, a dependency-breaking zero-idiom is expected to be optimized
120 // at register renaming stage. That means, no physical register is allocated
121 // to the instruction.
122 SmallVector<unsigned, 4> RegisterFiles(PRF.getNumRegisterFiles());
123 for (WriteState &WS : IS.getDefs())
124 PRF.addRegisterWrite(WriteRef(IR.getSourceIndex(), &WS), RegisterFiles);
126 // Reserve entries in the reorder buffer.
127 unsigned RCUTokenID = RCU.dispatch(IR);
128 // Notify the instruction that it has been dispatched.
129 IS.dispatch(RCUTokenID);
131 // Notify listeners of the "instruction dispatched" event,
132 // and move IR to the next stage.
133 notifyInstructionDispatched(IR, RegisterFiles,
134 std::min(DispatchWidth, NumMicroOps));
135 return moveToTheNextStage(IR);
138 Error DispatchStage::cycleStart() {
139 PRF.cycleStart();
141 if (!CarryOver) {
142 AvailableEntries = DispatchWidth;
143 return ErrorSuccess();
146 AvailableEntries = CarryOver >= DispatchWidth ? 0 : DispatchWidth - CarryOver;
147 unsigned DispatchedOpcodes = DispatchWidth - AvailableEntries;
148 CarryOver -= DispatchedOpcodes;
149 assert(CarriedOver && "Invalid dispatched instruction");
151 SmallVector<unsigned, 8> RegisterFiles(PRF.getNumRegisterFiles(), 0U);
152 notifyInstructionDispatched(CarriedOver, RegisterFiles, DispatchedOpcodes);
153 if (!CarryOver)
154 CarriedOver = InstRef();
155 return ErrorSuccess();
158 bool DispatchStage::isAvailable(const InstRef &IR) const {
159 const Instruction &Inst = *IR.getInstruction();
160 unsigned NumMicroOps = Inst.getNumMicroOps();
161 const InstrDesc &Desc = Inst.getDesc();
162 unsigned Required = std::min(NumMicroOps, DispatchWidth);
163 if (Required > AvailableEntries)
164 return false;
166 if (Desc.BeginGroup && AvailableEntries != DispatchWidth)
167 return false;
169 // The dispatch logic doesn't internally buffer instructions. It only accepts
170 // instructions that can be successfully moved to the next stage during this
171 // same cycle.
172 return canDispatch(IR);
175 Error DispatchStage::execute(InstRef &IR) {
176 assert(canDispatch(IR) && "Cannot dispatch another instruction!");
177 return dispatch(IR);
180 #ifndef NDEBUG
181 void DispatchStage::dump() const {
182 PRF.dump();
183 RCU.dump();
185 #endif
186 } // namespace mca
187 } // namespace llvm