Line data Source code
1 : //===- RegisterPressure.h - Dynamic Register Pressure -----------*- C++ -*-===//
2 : //
3 : // The LLVM Compiler Infrastructure
4 : //
5 : // This file is distributed under the University of Illinois Open Source
6 : // License. See LICENSE.TXT for details.
7 : //
8 : //===----------------------------------------------------------------------===//
9 : //
10 : // This file defines the RegisterPressure class which can be used to track
11 : // MachineInstr level register pressure.
12 : //
13 : //===----------------------------------------------------------------------===//
14 :
15 : #ifndef LLVM_CODEGEN_REGISTERPRESSURE_H
16 : #define LLVM_CODEGEN_REGISTERPRESSURE_H
17 :
18 : #include "llvm/ADT/ArrayRef.h"
19 : #include "llvm/ADT/SmallVector.h"
20 : #include "llvm/ADT/SparseSet.h"
21 : #include "llvm/CodeGen/MachineBasicBlock.h"
22 : #include "llvm/CodeGen/SlotIndexes.h"
23 : #include "llvm/CodeGen/TargetRegisterInfo.h"
24 : #include "llvm/MC/LaneBitmask.h"
25 : #include <cassert>
26 : #include <cstddef>
27 : #include <cstdint>
28 : #include <cstdlib>
29 : #include <limits>
30 : #include <vector>
31 :
32 : namespace llvm {
33 :
34 : class LiveIntervals;
35 : class MachineFunction;
36 : class MachineInstr;
37 : class MachineRegisterInfo;
38 : class RegisterClassInfo;
39 :
40 : struct RegisterMaskPair {
41 : unsigned RegUnit; ///< Virtual register or register unit.
42 : LaneBitmask LaneMask;
43 :
44 : RegisterMaskPair(unsigned RegUnit, LaneBitmask LaneMask)
45 1615487 : : RegUnit(RegUnit), LaneMask(LaneMask) {}
46 : };
47 :
48 : /// Base class for register pressure results.
49 : struct RegisterPressure {
50 : /// Map of max reg pressure indexed by pressure set ID, not class ID.
51 : std::vector<unsigned> MaxSetPressure;
52 :
53 : /// List of live in virtual registers or physical register units.
54 : SmallVector<RegisterMaskPair,8> LiveInRegs;
55 : SmallVector<RegisterMaskPair,8> LiveOutRegs;
56 :
57 : void dump(const TargetRegisterInfo *TRI) const;
58 : };
59 :
60 : /// RegisterPressure computed within a region of instructions delimited by
61 : /// TopIdx and BottomIdx. During pressure computation, the maximum pressure per
62 : /// register pressure set is increased. Once pressure within a region is fully
63 : /// computed, the live-in and live-out sets are recorded.
64 : ///
65 : /// This is preferable to RegionPressure when LiveIntervals are available,
66 : /// because delimiting regions by SlotIndex is more robust and convenient than
67 : /// holding block iterators. The block contents can change without invalidating
68 : /// the pressure result.
69 334315 : struct IntervalPressure : RegisterPressure {
70 : /// Record the boundary of the region being tracked.
71 : SlotIndex TopIdx;
72 : SlotIndex BottomIdx;
73 :
74 : void reset();
75 :
76 : void openTop(SlotIndex NextTop);
77 :
78 : void openBottom(SlotIndex PrevBottom);
79 : };
80 :
81 : /// RegisterPressure computed within a region of instructions delimited by
82 : /// TopPos and BottomPos. This is a less precise version of IntervalPressure for
83 : /// use when LiveIntervals are unavailable.
84 : struct RegionPressure : RegisterPressure {
85 : /// Record the boundary of the region being tracked.
86 : MachineBasicBlock::const_iterator TopPos;
87 : MachineBasicBlock::const_iterator BottomPos;
88 :
89 : void reset();
90 :
91 : void openTop(MachineBasicBlock::const_iterator PrevTop);
92 :
93 : void openBottom(MachineBasicBlock::const_iterator PrevBottom);
94 : };
95 :
96 : /// Capture a change in pressure for a single pressure set. UnitInc may be
97 : /// expressed in terms of upward or downward pressure depending on the client
98 : /// and will be dynamically adjusted for current liveness.
99 : ///
100 : /// Pressure increments are tiny, typically 1-2 units, and this is only for
101 : /// heuristics, so we don't check UnitInc overflow. Instead, we may have a
102 : /// higher level assert that pressure is consistent within a region. We also
103 : /// effectively ignore dead defs which don't affect heuristics much.
104 : class PressureChange {
105 : uint16_t PSetID = 0; // ID+1. 0=Invalid.
106 : int16_t UnitInc = 0;
107 :
108 : public:
109 : PressureChange() = default;
110 7068332 : PressureChange(unsigned id): PSetID(id + 1) {
111 : assert(id < std::numeric_limits<uint16_t>::max() && "PSetID overflow.");
112 : }
113 :
114 0 : bool isValid() const { return PSetID > 0; }
115 :
116 0 : unsigned getPSet() const {
117 : assert(isValid() && "invalid PressureChange");
118 43962826 : return PSetID - 1;
119 : }
120 :
121 : // If PSetID is invalid, return UINT16_MAX to give it lowest priority.
122 0 : unsigned getPSetOrMax() const {
123 66452444 : return (PSetID - 1) & std::numeric_limits<uint16_t>::max();
124 : }
125 :
126 75934395 : int getUnitInc() const { return UnitInc; }
127 :
128 8653113 : void setUnitInc(int Inc) { UnitInc = Inc; }
129 :
130 : bool operator==(const PressureChange &RHS) const {
131 : return PSetID == RHS.PSetID && UnitInc == RHS.UnitInc;
132 : }
133 : };
134 :
135 : template <> struct isPodLike<PressureChange> {
136 : static const bool value = true;
137 : };
138 :
139 : /// List of PressureChanges in order of increasing, unique PSetID.
140 : ///
141 : /// Use a small fixed number, because we can fit more PressureChanges in an
142 : /// empty SmallVector than ever need to be tracked per register class. If more
143 : /// PSets are affected, then we only track the most constrained.
144 : class PressureDiff {
145 : // The initial design was for MaxPSets=4, but that requires PSet partitions,
146 : // which are not yet implemented. (PSet partitions are equivalent PSets given
147 : // the register classes actually in use within the scheduling region.)
148 : enum { MaxPSets = 16 };
149 :
150 : PressureChange PressureChanges[MaxPSets];
151 :
152 : using iterator = PressureChange *;
153 :
154 9858804 : iterator nonconst_begin() { return &PressureChanges[0]; }
155 9858804 : iterator nonconst_end() { return &PressureChanges[MaxPSets]; }
156 :
157 : public:
158 : using const_iterator = const PressureChange *;
159 :
160 10896810 : const_iterator begin() const { return &PressureChanges[0]; }
161 10896810 : const_iterator end() const { return &PressureChanges[MaxPSets]; }
162 :
163 : void addPressureChange(unsigned RegUnit, bool IsDec,
164 : const MachineRegisterInfo *MRI);
165 :
166 : void dump(const TargetRegisterInfo &TRI) const;
167 : };
168 :
169 : /// List of registers defined and used by a machine instruction.
170 : class RegisterOperands {
171 : public:
172 : /// List of virtual registers and register units read by the instruction.
173 : SmallVector<RegisterMaskPair, 8> Uses;
174 : /// List of virtual registers and register units defined by the
175 : /// instruction which are not dead.
176 : SmallVector<RegisterMaskPair, 8> Defs;
177 : /// List of virtual registers and register units defined by the
178 : /// instruction but dead.
179 : SmallVector<RegisterMaskPair, 8> DeadDefs;
180 :
181 : /// Analyze the given instruction \p MI and fill in the Uses, Defs and
182 : /// DeadDefs list based on the MachineOperand flags.
183 : void collect(const MachineInstr &MI, const TargetRegisterInfo &TRI,
184 : const MachineRegisterInfo &MRI, bool TrackLaneMasks,
185 : bool IgnoreDead);
186 :
187 : /// Use liveness information to find dead defs not marked with a dead flag
188 : /// and move them to the DeadDefs vector.
189 : void detectDeadDefs(const MachineInstr &MI, const LiveIntervals &LIS);
190 :
191 : /// Use liveness information to find out which uses/defs are partially
192 : /// undefined/dead and adjust the RegisterMaskPairs accordingly.
193 : /// If \p AddFlagsMI is given then missing read-undef and dead flags will be
194 : /// added to the instruction.
195 : void adjustLaneLiveness(const LiveIntervals &LIS,
196 : const MachineRegisterInfo &MRI, SlotIndex Pos,
197 : MachineInstr *AddFlagsMI = nullptr);
198 : };
199 :
200 : /// Array of PressureDiffs.
201 : class PressureDiffs {
202 : PressureDiff *PDiffArray = nullptr;
203 : unsigned Size = 0;
204 : unsigned Max = 0;
205 :
206 : public:
207 167111 : PressureDiffs() = default;
208 167111 : ~PressureDiffs() { free(PDiffArray); }
209 :
210 979712 : void clear() { Size = 0; }
211 :
212 : void init(unsigned N);
213 :
214 0 : PressureDiff &operator[](unsigned Idx) {
215 : assert(Idx < Size && "PressureDiff index out of bounds");
216 13983708 : return PDiffArray[Idx];
217 : }
218 : const PressureDiff &operator[](unsigned Idx) const {
219 : return const_cast<PressureDiffs*>(this)->operator[](Idx);
220 : }
221 :
222 : /// Record pressure difference induced by the given operand list to
223 : /// node with index \p Idx.
224 : void addInstruction(unsigned Idx, const RegisterOperands &RegOpers,
225 : const MachineRegisterInfo &MRI);
226 : };
227 :
228 : /// Store the effects of a change in pressure on things that MI scheduler cares
229 : /// about.
230 : ///
231 : /// Excess records the value of the largest difference in register units beyond
232 : /// the target's pressure limits across the affected pressure sets, where
233 : /// largest is defined as the absolute value of the difference. Negative
234 : /// ExcessUnits indicates a reduction in pressure that had already exceeded the
235 : /// target's limits.
236 : ///
237 : /// CriticalMax records the largest increase in the tracker's max pressure that
238 : /// exceeds the critical limit for some pressure set determined by the client.
239 : ///
240 : /// CurrentMax records the largest increase in the tracker's max pressure that
241 : /// exceeds the current limit for some pressure set determined by the client.
242 : struct RegPressureDelta {
243 : PressureChange Excess;
244 : PressureChange CriticalMax;
245 : PressureChange CurrentMax;
246 :
247 : RegPressureDelta() = default;
248 :
249 : bool operator==(const RegPressureDelta &RHS) const {
250 : return Excess == RHS.Excess && CriticalMax == RHS.CriticalMax
251 : && CurrentMax == RHS.CurrentMax;
252 : }
253 : bool operator!=(const RegPressureDelta &RHS) const {
254 : return !operator==(RHS);
255 : }
256 : };
257 :
258 : /// A set of live virtual registers and physical register units.
259 : ///
260 : /// This is a wrapper around a SparseSet which deals with mapping register unit
261 : /// and virtual register indexes to an index usable by the sparse set.
262 : class LiveRegSet {
263 : private:
264 : struct IndexMaskPair {
265 : unsigned Index;
266 : LaneBitmask LaneMask;
267 :
268 : IndexMaskPair(unsigned Index, LaneBitmask LaneMask)
269 4350626 : : Index(Index), LaneMask(LaneMask) {}
270 :
271 0 : unsigned getSparseSetIndex() const {
272 0 : return Index;
273 : }
274 : };
275 :
276 : using RegSet = SparseSet<IndexMaskPair>;
277 : RegSet Regs;
278 : unsigned NumRegUnits;
279 :
280 0 : unsigned getSparseIndexFromReg(unsigned Reg) const {
281 14340841 : if (TargetRegisterInfo::isVirtualRegister(Reg))
282 12545926 : return TargetRegisterInfo::virtReg2Index(Reg) + NumRegUnits;
283 : assert(Reg < NumRegUnits);
284 : return Reg;
285 : }
286 :
287 0 : unsigned getRegFromSparseIndex(unsigned SparseIndex) const {
288 0 : if (SparseIndex >= NumRegUnits)
289 1131953 : return TargetRegisterInfo::index2VirtReg(SparseIndex-NumRegUnits);
290 : return SparseIndex;
291 : }
292 :
293 : public:
294 : void clear();
295 : void init(const MachineRegisterInfo &MRI);
296 :
297 15256782 : LaneBitmask contains(unsigned Reg) const {
298 : unsigned SparseIndex = getSparseIndexFromReg(Reg);
299 : RegSet::const_iterator I = Regs.find(SparseIndex);
300 7628391 : if (I == Regs.end())
301 2451986 : return LaneBitmask::getNone();
302 5176405 : return I->LaneMask;
303 : }
304 :
305 : /// Mark the \p Pair.LaneMask lanes of \p Pair.Reg as live.
306 : /// Returns the previously live lanes of \p Pair.Reg.
307 4350626 : LaneBitmask insert(RegisterMaskPair Pair) {
308 4350626 : unsigned SparseIndex = getSparseIndexFromReg(Pair.RegUnit);
309 4350626 : auto InsertRes = Regs.insert(IndexMaskPair(SparseIndex, Pair.LaneMask));
310 4350626 : if (!InsertRes.second) {
311 1761994 : LaneBitmask PrevMask = InsertRes.first->LaneMask;
312 : InsertRes.first->LaneMask |= Pair.LaneMask;
313 1761994 : return PrevMask;
314 : }
315 2588632 : return LaneBitmask::getNone();
316 : }
317 :
318 : /// Clears the \p Pair.LaneMask lanes of \p Pair.Reg (mark them as dead).
319 : /// Returns the previously live lanes of \p Pair.Reg.
320 2361824 : LaneBitmask erase(RegisterMaskPair Pair) {
321 2361824 : unsigned SparseIndex = getSparseIndexFromReg(Pair.RegUnit);
322 : RegSet::iterator I = Regs.find(SparseIndex);
323 2361824 : if (I == Regs.end())
324 90294 : return LaneBitmask::getNone();
325 2271530 : LaneBitmask PrevMask = I->LaneMask;
326 2271530 : I->LaneMask &= ~Pair.LaneMask;
327 2271530 : return PrevMask;
328 : }
329 :
330 : size_t size() const {
331 497794 : return Regs.size();
332 : }
333 :
334 : template<typename ContainerT>
335 497794 : void appendTo(ContainerT &To) const {
336 2110502 : for (const IndexMaskPair &P : Regs) {
337 1612708 : unsigned Reg = getRegFromSparseIndex(P.Index);
338 1612708 : if (P.LaneMask.any())
339 843325 : To.push_back(RegisterMaskPair(Reg, P.LaneMask));
340 : }
341 497794 : }
342 : };
343 :
344 : /// Track the current register pressure at some position in the instruction
345 : /// stream, and remember the high water mark within the region traversed. This
346 : /// does not automatically consider live-through ranges. The client may
347 : /// independently adjust for global liveness.
348 : ///
349 : /// Each RegPressureTracker only works within a MachineBasicBlock. Pressure can
350 : /// be tracked across a larger region by storing a RegisterPressure result at
351 : /// each block boundary and explicitly adjusting pressure to account for block
352 : /// live-in and live-out register sets.
353 : ///
354 : /// RegPressureTracker holds a reference to a RegisterPressure result that it
355 : /// computes incrementally. During downward tracking, P.BottomIdx or P.BottomPos
356 : /// is invalid until it reaches the end of the block or closeRegion() is
357 : /// explicitly called. Similarly, P.TopIdx is invalid during upward
358 : /// tracking. Changing direction has the side effect of closing region, and
359 : /// traversing past TopIdx or BottomIdx reopens it.
360 : class RegPressureTracker {
361 : const MachineFunction *MF = nullptr;
362 : const TargetRegisterInfo *TRI = nullptr;
363 : const RegisterClassInfo *RCI = nullptr;
364 : const MachineRegisterInfo *MRI;
365 : const LiveIntervals *LIS = nullptr;
366 :
367 : /// We currently only allow pressure tracking within a block.
368 : const MachineBasicBlock *MBB = nullptr;
369 :
370 : /// Track the max pressure within the region traversed so far.
371 : RegisterPressure &P;
372 :
373 : /// Run in two modes dependending on whether constructed with IntervalPressure
374 : /// or RegisterPressure. If requireIntervals is false, LIS are ignored.
375 : bool RequireIntervals;
376 :
377 : /// True if UntiedDefs will be populated.
378 : bool TrackUntiedDefs = false;
379 :
380 : /// True if lanemasks should be tracked.
381 : bool TrackLaneMasks = false;
382 :
383 : /// Register pressure corresponds to liveness before this instruction
384 : /// iterator. It may point to the end of the block or a DebugValue rather than
385 : /// an instruction.
386 : MachineBasicBlock::const_iterator CurrPos;
387 :
388 : /// Pressure map indexed by pressure set ID, not class ID.
389 : std::vector<unsigned> CurrSetPressure;
390 :
391 : /// Set of live registers.
392 : LiveRegSet LiveRegs;
393 :
394 : /// Set of vreg defs that start a live range.
395 : SparseSet<unsigned, VirtReg2IndexFunctor> UntiedDefs;
396 : /// Live-through pressure.
397 : std::vector<unsigned> LiveThruPressure;
398 :
399 : public:
400 501423 : RegPressureTracker(IntervalPressure &rp) : P(rp), RequireIntervals(true) {}
401 : RegPressureTracker(RegionPressure &rp) : P(rp), RequireIntervals(false) {}
402 :
403 : void reset();
404 :
405 : void init(const MachineFunction *mf, const RegisterClassInfo *rci,
406 : const LiveIntervals *lis, const MachineBasicBlock *mbb,
407 : MachineBasicBlock::const_iterator pos,
408 : bool TrackLaneMasks, bool TrackUntiedDefs);
409 :
410 : /// Force liveness of virtual registers or physical register
411 : /// units. Particularly useful to initialize the livein/out state of the
412 : /// tracker before the first call to advance/recede.
413 : void addLiveRegs(ArrayRef<RegisterMaskPair> Regs);
414 :
415 : /// Get the MI position corresponding to this register pressure.
416 0 : MachineBasicBlock::const_iterator getPos() const { return CurrPos; }
417 :
418 : // Reset the MI position corresponding to the register pressure. This allows
419 : // schedulers to move instructions above the RegPressureTracker's
420 : // CurrPos. Since the pressure is computed before CurrPos, the iterator
421 : // position changes while pressure does not.
422 348052 : void setPos(MachineBasicBlock::const_iterator Pos) { CurrPos = Pos; }
423 :
424 : /// Recede across the previous instruction.
425 : void recede(SmallVectorImpl<RegisterMaskPair> *LiveUses = nullptr);
426 :
427 : /// Recede across the previous instruction.
428 : /// This "low-level" variant assumes that recedeSkipDebugValues() was
429 : /// called previously and takes precomputed RegisterOperands for the
430 : /// instruction.
431 : void recede(const RegisterOperands &RegOpers,
432 : SmallVectorImpl<RegisterMaskPair> *LiveUses = nullptr);
433 :
434 : /// Recede until we find an instruction which is not a DebugValue.
435 : void recedeSkipDebugValues();
436 :
437 : /// Advance across the current instruction.
438 : void advance();
439 :
440 : /// Advance across the current instruction.
441 : /// This is a "low-level" variant of advance() which takes precomputed
442 : /// RegisterOperands of the instruction.
443 : void advance(const RegisterOperands &RegOpers);
444 :
445 : /// Finalize the region boundaries and recored live ins and live outs.
446 : void closeRegion();
447 :
448 : /// Initialize the LiveThru pressure set based on the untied defs found in
449 : /// RPTracker.
450 : void initLiveThru(const RegPressureTracker &RPTracker);
451 :
452 : /// Copy an existing live thru pressure result.
453 : void initLiveThru(ArrayRef<unsigned> PressureSet) {
454 124424 : LiveThruPressure.assign(PressureSet.begin(), PressureSet.end());
455 : }
456 :
457 : ArrayRef<unsigned> getLiveThru() const { return LiveThruPressure; }
458 :
459 : /// Get the resulting register pressure over the traversed region.
460 : /// This result is complete if closeRegion() was explicitly invoked.
461 0 : RegisterPressure &getPressure() { return P; }
462 : const RegisterPressure &getPressure() const { return P; }
463 :
464 : /// Get the register set pressure at the current position, which may be less
465 : /// than the pressure across the traversed region.
466 : const std::vector<unsigned> &getRegSetPressureAtPos() const {
467 : return CurrSetPressure;
468 : }
469 :
470 : bool isTopClosed() const;
471 : bool isBottomClosed() const;
472 :
473 : void closeTop();
474 : void closeBottom();
475 :
476 : /// Consider the pressure increase caused by traversing this instruction
477 : /// bottom-up. Find the pressure set with the most change beyond its pressure
478 : /// limit based on the tracker's current pressure, and record the number of
479 : /// excess register units of that pressure set introduced by this instruction.
480 : void getMaxUpwardPressureDelta(const MachineInstr *MI,
481 : PressureDiff *PDiff,
482 : RegPressureDelta &Delta,
483 : ArrayRef<PressureChange> CriticalPSets,
484 : ArrayRef<unsigned> MaxPressureLimit);
485 :
486 : void getUpwardPressureDelta(const MachineInstr *MI,
487 : /*const*/ PressureDiff &PDiff,
488 : RegPressureDelta &Delta,
489 : ArrayRef<PressureChange> CriticalPSets,
490 : ArrayRef<unsigned> MaxPressureLimit) const;
491 :
492 : /// Consider the pressure increase caused by traversing this instruction
493 : /// top-down. Find the pressure set with the most change beyond its pressure
494 : /// limit based on the tracker's current pressure, and record the number of
495 : /// excess register units of that pressure set introduced by this instruction.
496 : void getMaxDownwardPressureDelta(const MachineInstr *MI,
497 : RegPressureDelta &Delta,
498 : ArrayRef<PressureChange> CriticalPSets,
499 : ArrayRef<unsigned> MaxPressureLimit);
500 :
501 : /// Find the pressure set with the most change beyond its pressure limit after
502 : /// traversing this instruction either upward or downward depending on the
503 : /// closed end of the current region.
504 103893 : void getMaxPressureDelta(const MachineInstr *MI,
505 : RegPressureDelta &Delta,
506 : ArrayRef<PressureChange> CriticalPSets,
507 : ArrayRef<unsigned> MaxPressureLimit) {
508 103893 : if (isTopClosed())
509 55387 : return getMaxDownwardPressureDelta(MI, Delta, CriticalPSets,
510 55387 : MaxPressureLimit);
511 :
512 : assert(isBottomClosed() && "Uninitialized pressure tracker");
513 48506 : return getMaxUpwardPressureDelta(MI, nullptr, Delta, CriticalPSets,
514 48506 : MaxPressureLimit);
515 : }
516 :
517 : /// Get the pressure of each PSet after traversing this instruction bottom-up.
518 : void getUpwardPressure(const MachineInstr *MI,
519 : std::vector<unsigned> &PressureResult,
520 : std::vector<unsigned> &MaxPressureResult);
521 :
522 : /// Get the pressure of each PSet after traversing this instruction top-down.
523 : void getDownwardPressure(const MachineInstr *MI,
524 : std::vector<unsigned> &PressureResult,
525 : std::vector<unsigned> &MaxPressureResult);
526 :
527 : void getPressureAfterInst(const MachineInstr *MI,
528 : std::vector<unsigned> &PressureResult,
529 : std::vector<unsigned> &MaxPressureResult) {
530 : if (isTopClosed())
531 : return getUpwardPressure(MI, PressureResult, MaxPressureResult);
532 :
533 : assert(isBottomClosed() && "Uninitialized pressure tracker");
534 : return getDownwardPressure(MI, PressureResult, MaxPressureResult);
535 : }
536 :
537 : bool hasUntiedDef(unsigned VirtReg) const {
538 181129 : return UntiedDefs.count(VirtReg);
539 : }
540 :
541 : void dump() const;
542 :
543 : protected:
544 : /// Add Reg to the live out set and increase max pressure.
545 : void discoverLiveOut(RegisterMaskPair Pair);
546 : /// Add Reg to the live in set and increase max pressure.
547 : void discoverLiveIn(RegisterMaskPair Pair);
548 :
549 : /// Get the SlotIndex for the first nondebug instruction including or
550 : /// after the current position.
551 : SlotIndex getCurrSlot() const;
552 :
553 : void increaseRegPressure(unsigned RegUnit, LaneBitmask PreviousMask,
554 : LaneBitmask NewMask);
555 : void decreaseRegPressure(unsigned RegUnit, LaneBitmask PreviousMask,
556 : LaneBitmask NewMask);
557 :
558 : void bumpDeadDefs(ArrayRef<RegisterMaskPair> DeadDefs);
559 :
560 : void bumpUpwardPressure(const MachineInstr *MI);
561 : void bumpDownwardPressure(const MachineInstr *MI);
562 :
563 : void discoverLiveInOrOut(RegisterMaskPair Pair,
564 : SmallVectorImpl<RegisterMaskPair> &LiveInOrOut);
565 :
566 : LaneBitmask getLastUsedLanes(unsigned RegUnit, SlotIndex Pos) const;
567 : LaneBitmask getLiveLanesAt(unsigned RegUnit, SlotIndex Pos) const;
568 : LaneBitmask getLiveThroughAt(unsigned RegUnit, SlotIndex Pos) const;
569 : };
570 :
571 : void dumpRegSetPressure(ArrayRef<unsigned> SetPressure,
572 : const TargetRegisterInfo *TRI);
573 :
574 : } // end namespace llvm
575 :
576 : #endif // LLVM_CODEGEN_REGISTERPRESSURE_H
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