1 //===- InstrRefBasedImpl.cpp - Tracking Debug Value MIs -------------------===//
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 InstrRefBasedImpl.cpp
9 ///
10 /// This is a separate implementation of LiveDebugValues, see
11 /// LiveDebugValues.cpp and VarLocBasedImpl.cpp for more information.
12 ///
13 /// This pass propagates variable locations between basic blocks, resolving
14 /// control flow conflicts between them. The problem is SSA construction, where
15 /// each debug instruction assigns the *value* that a variable has, and every
16 /// instruction where the variable is in scope uses that variable. The resulting
17 /// map of instruction-to-value is then translated into a register (or spill)
18 /// location for each variable over each instruction.
19 ///
20 /// The primary difference from normal SSA construction is that we cannot
21 /// _create_ PHI values that contain variable values. CodeGen has already
22 /// completed, and we can't alter it just to make debug-info complete. Thus:
23 /// we can identify function positions where we would like a PHI value for a
24 /// variable, but must search the MachineFunction to see whether such a PHI is
25 /// available. If no such PHI exists, the variable location must be dropped.
26 ///
27 /// To achieve this, we perform two kinds of analysis. First, we identify
28 /// every value defined by every instruction (ignoring those that only move
29 /// another value), then re-compute an SSA-form representation of the
30 /// MachineFunction, using value propagation to eliminate any un-necessary
31 /// PHI values. This gives us a map of every value computed in the function,
32 /// and its location within the register file / stack.
33 ///
34 /// Secondly, for each variable we perform the same analysis, where each debug
35 /// instruction is considered a def, and every instruction where the variable
36 /// is in lexical scope as a use. Value propagation is used again to eliminate
37 /// any un-necessary PHIs. This gives us a map of each variable to the value
38 /// it should have in a block.
39 ///
40 /// Once both are complete, we have two maps for each block:
41 /// * Variables to the values they should have,
42 /// * Values to the register / spill slot they are located in.
43 /// After which we can marry-up variable values with a location, and emit
44 /// DBG_VALUE instructions specifying those locations. Variable locations may
45 /// be dropped in this process due to the desired variable value not being
46 /// resident in any machine location, or because there is no PHI value in any
47 /// location that accurately represents the desired value. The building of
48 /// location lists for each block is left to DbgEntityHistoryCalculator.
49 ///
50 /// This pass is kept efficient because the size of the first SSA problem
51 /// is proportional to the working-set size of the function, which the compiler
52 /// tries to keep small. (It's also proportional to the number of blocks).
53 /// Additionally, we repeatedly perform the second SSA problem analysis with
54 /// only the variables and blocks in a single lexical scope, exploiting their
55 /// locality.
56 ///
57 /// ### Terminology
58 ///
59 /// A machine location is a register or spill slot, a value is something that's
60 /// defined by an instruction or PHI node, while a variable value is the value
61 /// assigned to a variable. A variable location is a machine location, that must
62 /// contain the appropriate variable value. A value that is a PHI node is
63 /// occasionally called an mphi.
64 ///
65 /// The first SSA problem is the "machine value location" problem,
66 /// because we're determining which machine locations contain which values.
67 /// The "locations" are constant: what's unknown is what value they contain.
68 ///
69 /// The second SSA problem (the one for variables) is the "variable value
70 /// problem", because it's determining what values a variable has, rather than
71 /// what location those values are placed in.
72 ///
73 /// TODO:
74 /// Overlapping fragments
75 /// Entry values
76 /// Add back DEBUG statements for debugging this
77 /// Collect statistics
78 ///
79 //===----------------------------------------------------------------------===//
80
81 #include "llvm/ADT/DenseMap.h"
82 #include "llvm/ADT/PostOrderIterator.h"
83 #include "llvm/ADT/STLExtras.h"
84 #include "llvm/ADT/SmallPtrSet.h"
85 #include "llvm/ADT/SmallSet.h"
86 #include "llvm/ADT/SmallVector.h"
87 #include "llvm/BinaryFormat/Dwarf.h"
88 #include "llvm/CodeGen/LexicalScopes.h"
89 #include "llvm/CodeGen/MachineBasicBlock.h"
90 #include "llvm/CodeGen/MachineDominators.h"
91 #include "llvm/CodeGen/MachineFrameInfo.h"
92 #include "llvm/CodeGen/MachineFunction.h"
93 #include "llvm/CodeGen/MachineInstr.h"
94 #include "llvm/CodeGen/MachineInstrBuilder.h"
95 #include "llvm/CodeGen/MachineInstrBundle.h"
96 #include "llvm/CodeGen/MachineMemOperand.h"
97 #include "llvm/CodeGen/MachineOperand.h"
98 #include "llvm/CodeGen/PseudoSourceValue.h"
99 #include "llvm/CodeGen/TargetFrameLowering.h"
100 #include "llvm/CodeGen/TargetInstrInfo.h"
101 #include "llvm/CodeGen/TargetLowering.h"
102 #include "llvm/CodeGen/TargetPassConfig.h"
103 #include "llvm/CodeGen/TargetRegisterInfo.h"
104 #include "llvm/CodeGen/TargetSubtargetInfo.h"
105 #include "llvm/Config/llvm-config.h"
106 #include "llvm/IR/DebugInfoMetadata.h"
107 #include "llvm/IR/DebugLoc.h"
108 #include "llvm/IR/Function.h"
109 #include "llvm/MC/MCRegisterInfo.h"
110 #include "llvm/Support/Casting.h"
111 #include "llvm/Support/Compiler.h"
112 #include "llvm/Support/Debug.h"
113 #include "llvm/Support/GenericIteratedDominanceFrontier.h"
114 #include "llvm/Support/TypeSize.h"
115 #include "llvm/Support/raw_ostream.h"
116 #include "llvm/Target/TargetMachine.h"
117 #include "llvm/Transforms/Utils/SSAUpdaterImpl.h"
118 #include <algorithm>
119 #include <cassert>
120 #include <climits>
121 #include <cstdint>
122 #include <functional>
123 #include <queue>
124 #include <tuple>
125 #include <utility>
126 #include <vector>
127
128 #include "InstrRefBasedImpl.h"
129 #include "LiveDebugValues.h"
130 #include <optional>
131
132 using namespace llvm;
133 using namespace LiveDebugValues;
134
135 // SSAUpdaterImple sets DEBUG_TYPE, change it.
136 #undef DEBUG_TYPE
137 #define DEBUG_TYPE "livedebugvalues"
138
139 // Act more like the VarLoc implementation, by propagating some locations too
140 // far and ignoring some transfers.
141 static cl::opt<bool> EmulateOldLDV("emulate-old-livedebugvalues", cl::Hidden,
142 cl::desc("Act like old LiveDebugValues did"),
143 cl::init(false));
144
145 // Limit for the maximum number of stack slots we should track, past which we
146 // will ignore any spills. InstrRefBasedLDV gathers detailed information on all
147 // stack slots which leads to high memory consumption, and in some scenarios
148 // (such as asan with very many locals) the working set of the function can be
149 // very large, causing many spills. In these scenarios, it is very unlikely that
150 // the developer has hundreds of variables live at the same time that they're
151 // carefully thinking about -- instead, they probably autogenerated the code.
152 // When this happens, gracefully stop tracking excess spill slots, rather than
153 // consuming all the developer's memory.
154 static cl::opt<unsigned>
155 StackWorkingSetLimit("livedebugvalues-max-stack-slots", cl::Hidden,
156 cl::desc("livedebugvalues-stack-ws-limit"),
157 cl::init(250));
158
159 DbgOpID DbgOpID::UndefID = DbgOpID(0xffffffff);
160
161 /// Tracker for converting machine value locations and variable values into
162 /// variable locations (the output of LiveDebugValues), recorded as DBG_VALUEs
163 /// specifying block live-in locations and transfers within blocks.
164 ///
165 /// Operating on a per-block basis, this class takes a (pre-loaded) MLocTracker
166 /// and must be initialized with the set of variable values that are live-in to
167 /// the block. The caller then repeatedly calls process(). TransferTracker picks
168 /// out variable locations for the live-in variable values (if there _is_ a
169 /// location) and creates the corresponding DBG_VALUEs. Then, as the block is
170 /// stepped through, transfers of values between machine locations are
171 /// identified and if profitable, a DBG_VALUE created.
172 ///
173 /// This is where debug use-before-defs would be resolved: a variable with an
174 /// unavailable value could materialize in the middle of a block, when the
175 /// value becomes available. Or, we could detect clobbers and re-specify the
176 /// variable in a backup location. (XXX these are unimplemented).
177 class TransferTracker {
178 public:
179 const TargetInstrInfo *TII;
180 const TargetLowering *TLI;
181 /// This machine location tracker is assumed to always contain the up-to-date
182 /// value mapping for all machine locations. TransferTracker only reads
183 /// information from it. (XXX make it const?)
184 MLocTracker *MTracker;
185 MachineFunction &MF;
186 const DebugVariableMap &DVMap;
187 bool ShouldEmitDebugEntryValues;
188
189 /// Record of all changes in variable locations at a block position. Awkwardly
190 /// we allow inserting either before or after the point: MBB != nullptr
191 /// indicates it's before, otherwise after.
192 struct Transfer {
193 MachineBasicBlock::instr_iterator Pos; /// Position to insert DBG_VALUes
194 MachineBasicBlock *MBB; /// non-null if we should insert after.
195 /// Vector of DBG_VALUEs to insert. Store with their DebugVariableID so that
196 /// they can be sorted into a stable order for emission at a later time.
197 SmallVector<std::pair<DebugVariableID, MachineInstr *>, 4> Insts;
198 };
199
200 /// Stores the resolved operands (machine locations and constants) and
201 /// qualifying meta-information needed to construct a concrete DBG_VALUE-like
202 /// instruction.
203 struct ResolvedDbgValue {
204 SmallVector<ResolvedDbgOp> Ops;
205 DbgValueProperties Properties;
206
ResolvedDbgValueTransferTracker::ResolvedDbgValue207 ResolvedDbgValue(SmallVectorImpl<ResolvedDbgOp> &Ops,
208 DbgValueProperties Properties)
209 : Ops(Ops.begin(), Ops.end()), Properties(Properties) {}
210
211 /// Returns all the LocIdx values used in this struct, in the order in which
212 /// they appear as operands in the debug value; may contain duplicates.
loc_indicesTransferTracker::ResolvedDbgValue213 auto loc_indices() const {
214 return map_range(
215 make_filter_range(
216 Ops, [](const ResolvedDbgOp &Op) { return !Op.IsConst; }),
217 [](const ResolvedDbgOp &Op) { return Op.Loc; });
218 }
219 };
220
221 /// Collection of transfers (DBG_VALUEs) to be inserted.
222 SmallVector<Transfer, 32> Transfers;
223
224 /// Local cache of what-value-is-in-what-LocIdx. Used to identify differences
225 /// between TransferTrackers view of variable locations and MLocTrackers. For
226 /// example, MLocTracker observes all clobbers, but TransferTracker lazily
227 /// does not.
228 SmallVector<ValueIDNum, 32> VarLocs;
229
230 /// Map from LocIdxes to which DebugVariables are based that location.
231 /// Mantained while stepping through the block. Not accurate if
232 /// VarLocs[Idx] != MTracker->LocIdxToIDNum[Idx].
233 DenseMap<LocIdx, SmallSet<DebugVariableID, 4>> ActiveMLocs;
234
235 /// Map from DebugVariable to it's current location and qualifying meta
236 /// information. To be used in conjunction with ActiveMLocs to construct
237 /// enough information for the DBG_VALUEs for a particular LocIdx.
238 DenseMap<DebugVariableID, ResolvedDbgValue> ActiveVLocs;
239
240 /// Temporary cache of DBG_VALUEs to be entered into the Transfers collection.
241 SmallVector<std::pair<DebugVariableID, MachineInstr *>, 4> PendingDbgValues;
242
243 /// Record of a use-before-def: created when a value that's live-in to the
244 /// current block isn't available in any machine location, but it will be
245 /// defined in this block.
246 struct UseBeforeDef {
247 /// Value of this variable, def'd in block.
248 SmallVector<DbgOp> Values;
249 /// Identity of this variable.
250 DebugVariableID VarID;
251 /// Additional variable properties.
252 DbgValueProperties Properties;
UseBeforeDefTransferTracker::UseBeforeDef253 UseBeforeDef(ArrayRef<DbgOp> Values, DebugVariableID VarID,
254 const DbgValueProperties &Properties)
255 : Values(Values.begin(), Values.end()), VarID(VarID),
256 Properties(Properties) {}
257 };
258
259 /// Map from instruction index (within the block) to the set of UseBeforeDefs
260 /// that become defined at that instruction.
261 DenseMap<unsigned, SmallVector<UseBeforeDef, 1>> UseBeforeDefs;
262
263 /// The set of variables that are in UseBeforeDefs and can become a location
264 /// once the relevant value is defined. An element being erased from this
265 /// collection prevents the use-before-def materializing.
266 DenseSet<DebugVariableID> UseBeforeDefVariables;
267
268 const TargetRegisterInfo &TRI;
269 const BitVector &CalleeSavedRegs;
270
TransferTracker(const TargetInstrInfo * TII,MLocTracker * MTracker,MachineFunction & MF,const DebugVariableMap & DVMap,const TargetRegisterInfo & TRI,const BitVector & CalleeSavedRegs,const TargetPassConfig & TPC)271 TransferTracker(const TargetInstrInfo *TII, MLocTracker *MTracker,
272 MachineFunction &MF, const DebugVariableMap &DVMap,
273 const TargetRegisterInfo &TRI,
274 const BitVector &CalleeSavedRegs, const TargetPassConfig &TPC)
275 : TII(TII), MTracker(MTracker), MF(MF), DVMap(DVMap), TRI(TRI),
276 CalleeSavedRegs(CalleeSavedRegs) {
277 TLI = MF.getSubtarget().getTargetLowering();
278 auto &TM = TPC.getTM<TargetMachine>();
279 ShouldEmitDebugEntryValues = TM.Options.ShouldEmitDebugEntryValues();
280 }
281
isCalleeSaved(LocIdx L) const282 bool isCalleeSaved(LocIdx L) const {
283 unsigned Reg = MTracker->LocIdxToLocID[L];
284 if (Reg >= MTracker->NumRegs)
285 return false;
286 for (MCRegAliasIterator RAI(Reg, &TRI, true); RAI.isValid(); ++RAI)
287 if (CalleeSavedRegs.test(*RAI))
288 return true;
289 return false;
290 };
291
292 // An estimate of the expected lifespan of values at a machine location, with
293 // a greater value corresponding to a longer expected lifespan, i.e. spill
294 // slots generally live longer than callee-saved registers which generally
295 // live longer than non-callee-saved registers. The minimum value of 0
296 // corresponds to an illegal location that cannot have a "lifespan" at all.
297 enum class LocationQuality : unsigned char {
298 Illegal = 0,
299 Register,
300 CalleeSavedRegister,
301 SpillSlot,
302 Best = SpillSlot
303 };
304
305 class LocationAndQuality {
306 unsigned Location : 24;
307 unsigned Quality : 8;
308
309 public:
LocationAndQuality()310 LocationAndQuality() : Location(0), Quality(0) {}
LocationAndQuality(LocIdx L,LocationQuality Q)311 LocationAndQuality(LocIdx L, LocationQuality Q)
312 : Location(L.asU64()), Quality(static_cast<unsigned>(Q)) {}
getLoc() const313 LocIdx getLoc() const {
314 if (!Quality)
315 return LocIdx::MakeIllegalLoc();
316 return LocIdx(Location);
317 }
getQuality() const318 LocationQuality getQuality() const { return LocationQuality(Quality); }
isIllegal() const319 bool isIllegal() const { return !Quality; }
isBest() const320 bool isBest() const { return getQuality() == LocationQuality::Best; }
321 };
322
323 using ValueLocPair = std::pair<ValueIDNum, LocationAndQuality>;
324
ValueToLocSort(const ValueLocPair & A,const ValueLocPair & B)325 static inline bool ValueToLocSort(const ValueLocPair &A,
326 const ValueLocPair &B) {
327 return A.first < B.first;
328 };
329
330 // Returns the LocationQuality for the location L iff the quality of L is
331 // is strictly greater than the provided minimum quality.
332 std::optional<LocationQuality>
getLocQualityIfBetter(LocIdx L,LocationQuality Min) const333 getLocQualityIfBetter(LocIdx L, LocationQuality Min) const {
334 if (L.isIllegal())
335 return std::nullopt;
336 if (Min >= LocationQuality::SpillSlot)
337 return std::nullopt;
338 if (MTracker->isSpill(L))
339 return LocationQuality::SpillSlot;
340 if (Min >= LocationQuality::CalleeSavedRegister)
341 return std::nullopt;
342 if (isCalleeSaved(L))
343 return LocationQuality::CalleeSavedRegister;
344 if (Min >= LocationQuality::Register)
345 return std::nullopt;
346 return LocationQuality::Register;
347 }
348
349 /// For a variable \p Var with the live-in value \p Value, attempts to resolve
350 /// the DbgValue to a concrete DBG_VALUE, emitting that value and loading the
351 /// tracking information to track Var throughout the block.
352 /// \p ValueToLoc is a map containing the best known location for every
353 /// ValueIDNum that Value may use.
354 /// \p MBB is the basic block that we are loading the live-in value for.
355 /// \p DbgOpStore is the map containing the DbgOpID->DbgOp mapping needed to
356 /// determine the values used by Value.
loadVarInloc(MachineBasicBlock & MBB,DbgOpIDMap & DbgOpStore,const SmallVectorImpl<ValueLocPair> & ValueToLoc,DebugVariableID VarID,DbgValue Value)357 void loadVarInloc(MachineBasicBlock &MBB, DbgOpIDMap &DbgOpStore,
358 const SmallVectorImpl<ValueLocPair> &ValueToLoc,
359 DebugVariableID VarID, DbgValue Value) {
360 SmallVector<DbgOp> DbgOps;
361 SmallVector<ResolvedDbgOp> ResolvedDbgOps;
362 bool IsValueValid = true;
363 unsigned LastUseBeforeDef = 0;
364
365 // If every value used by the incoming DbgValue is available at block
366 // entry, ResolvedDbgOps will contain the machine locations/constants for
367 // those values and will be used to emit a debug location.
368 // If one or more values are not yet available, but will all be defined in
369 // this block, then LastUseBeforeDef will track the instruction index in
370 // this BB at which the last of those values is defined, DbgOps will
371 // contain the values that we will emit when we reach that instruction.
372 // If one or more values are undef or not available throughout this block,
373 // and we can't recover as an entry value, we set IsValueValid=false and
374 // skip this variable.
375 for (DbgOpID ID : Value.getDbgOpIDs()) {
376 DbgOp Op = DbgOpStore.find(ID);
377 DbgOps.push_back(Op);
378 if (ID.isUndef()) {
379 IsValueValid = false;
380 break;
381 }
382 if (ID.isConst()) {
383 ResolvedDbgOps.push_back(Op.MO);
384 continue;
385 }
386
387 // Search for the desired ValueIDNum, to examine the best location found
388 // for it. Use an empty ValueLocPair to search for an entry in ValueToLoc.
389 const ValueIDNum &Num = Op.ID;
390 ValueLocPair Probe(Num, LocationAndQuality());
391 auto ValuesPreferredLoc = std::lower_bound(
392 ValueToLoc.begin(), ValueToLoc.end(), Probe, ValueToLocSort);
393
394 // There must be a legitimate entry found for Num.
395 assert(ValuesPreferredLoc != ValueToLoc.end() &&
396 ValuesPreferredLoc->first == Num);
397
398 if (ValuesPreferredLoc->second.isIllegal()) {
399 // If it's a def that occurs in this block, register it as a
400 // use-before-def to be resolved as we step through the block.
401 // Continue processing values so that we add any other UseBeforeDef
402 // entries needed for later.
403 if (Num.getBlock() == (unsigned)MBB.getNumber() && !Num.isPHI()) {
404 LastUseBeforeDef = std::max(LastUseBeforeDef,
405 static_cast<unsigned>(Num.getInst()));
406 continue;
407 }
408 recoverAsEntryValue(VarID, Value.Properties, Num);
409 IsValueValid = false;
410 break;
411 }
412
413 // Defer modifying ActiveVLocs until after we've confirmed we have a
414 // live range.
415 LocIdx M = ValuesPreferredLoc->second.getLoc();
416 ResolvedDbgOps.push_back(M);
417 }
418
419 // If we cannot produce a valid value for the LiveIn value within this
420 // block, skip this variable.
421 if (!IsValueValid)
422 return;
423
424 // Add UseBeforeDef entry for the last value to be defined in this block.
425 if (LastUseBeforeDef) {
426 addUseBeforeDef(VarID, Value.Properties, DbgOps, LastUseBeforeDef);
427 return;
428 }
429
430 // The LiveIn value is available at block entry, begin tracking and record
431 // the transfer.
432 for (const ResolvedDbgOp &Op : ResolvedDbgOps)
433 if (!Op.IsConst)
434 ActiveMLocs[Op.Loc].insert(VarID);
435 auto NewValue = ResolvedDbgValue{ResolvedDbgOps, Value.Properties};
436 auto Result = ActiveVLocs.insert(std::make_pair(VarID, NewValue));
437 if (!Result.second)
438 Result.first->second = NewValue;
439 auto &[Var, DILoc] = DVMap.lookupDVID(VarID);
440 PendingDbgValues.push_back(
441 std::make_pair(VarID, &*MTracker->emitLoc(ResolvedDbgOps, Var, DILoc,
442 Value.Properties)));
443 }
444
445 /// Load object with live-in variable values. \p mlocs contains the live-in
446 /// values in each machine location, while \p vlocs the live-in variable
447 /// values. This method picks variable locations for the live-in variables,
448 /// creates DBG_VALUEs and puts them in #Transfers, then prepares the other
449 /// object fields to track variable locations as we step through the block.
450 /// FIXME: could just examine mloctracker instead of passing in \p mlocs?
451 void
loadInlocs(MachineBasicBlock & MBB,ValueTable & MLocs,DbgOpIDMap & DbgOpStore,const SmallVectorImpl<std::pair<DebugVariableID,DbgValue>> & VLocs,unsigned NumLocs)452 loadInlocs(MachineBasicBlock &MBB, ValueTable &MLocs, DbgOpIDMap &DbgOpStore,
453 const SmallVectorImpl<std::pair<DebugVariableID, DbgValue>> &VLocs,
454 unsigned NumLocs) {
455 ActiveMLocs.clear();
456 ActiveVLocs.clear();
457 VarLocs.clear();
458 VarLocs.reserve(NumLocs);
459 UseBeforeDefs.clear();
460 UseBeforeDefVariables.clear();
461
462 // Mapping of the preferred locations for each value. Collected into this
463 // vector then sorted for easy searching.
464 SmallVector<ValueLocPair, 16> ValueToLoc;
465
466 // Initialized the preferred-location map with illegal locations, to be
467 // filled in later.
468 for (const auto &VLoc : VLocs)
469 if (VLoc.second.Kind == DbgValue::Def)
470 for (DbgOpID OpID : VLoc.second.getDbgOpIDs())
471 if (!OpID.ID.IsConst)
472 ValueToLoc.push_back(
473 {DbgOpStore.find(OpID).ID, LocationAndQuality()});
474
475 llvm::sort(ValueToLoc, ValueToLocSort);
476 ActiveMLocs.reserve(VLocs.size());
477 ActiveVLocs.reserve(VLocs.size());
478
479 // Produce a map of value numbers to the current machine locs they live
480 // in. When emulating VarLocBasedImpl, there should only be one
481 // location; when not, we get to pick.
482 for (auto Location : MTracker->locations()) {
483 LocIdx Idx = Location.Idx;
484 ValueIDNum &VNum = MLocs[Idx.asU64()];
485 if (VNum == ValueIDNum::EmptyValue)
486 continue;
487 VarLocs.push_back(VNum);
488
489 // Is there a variable that wants a location for this value? If not, skip.
490 ValueLocPair Probe(VNum, LocationAndQuality());
491 auto VIt = std::lower_bound(ValueToLoc.begin(), ValueToLoc.end(), Probe,
492 ValueToLocSort);
493 if (VIt == ValueToLoc.end() || VIt->first != VNum)
494 continue;
495
496 auto &Previous = VIt->second;
497 // If this is the first location with that value, pick it. Otherwise,
498 // consider whether it's a "longer term" location.
499 std::optional<LocationQuality> ReplacementQuality =
500 getLocQualityIfBetter(Idx, Previous.getQuality());
501 if (ReplacementQuality)
502 Previous = LocationAndQuality(Idx, *ReplacementQuality);
503 }
504
505 // Now map variables to their picked LocIdxes.
506 for (const auto &Var : VLocs) {
507 loadVarInloc(MBB, DbgOpStore, ValueToLoc, Var.first, Var.second);
508 }
509 flushDbgValues(MBB.begin(), &MBB);
510 }
511
512 /// Record that \p Var has value \p ID, a value that becomes available
513 /// later in the function.
addUseBeforeDef(DebugVariableID VarID,const DbgValueProperties & Properties,const SmallVectorImpl<DbgOp> & DbgOps,unsigned Inst)514 void addUseBeforeDef(DebugVariableID VarID,
515 const DbgValueProperties &Properties,
516 const SmallVectorImpl<DbgOp> &DbgOps, unsigned Inst) {
517 UseBeforeDefs[Inst].emplace_back(DbgOps, VarID, Properties);
518 UseBeforeDefVariables.insert(VarID);
519 }
520
521 /// After the instruction at index \p Inst and position \p pos has been
522 /// processed, check whether it defines a variable value in a use-before-def.
523 /// If so, and the variable value hasn't changed since the start of the
524 /// block, create a DBG_VALUE.
checkInstForNewValues(unsigned Inst,MachineBasicBlock::iterator pos)525 void checkInstForNewValues(unsigned Inst, MachineBasicBlock::iterator pos) {
526 auto MIt = UseBeforeDefs.find(Inst);
527 if (MIt == UseBeforeDefs.end())
528 return;
529
530 // Map of values to the locations that store them for every value used by
531 // the variables that may have become available.
532 SmallDenseMap<ValueIDNum, LocationAndQuality> ValueToLoc;
533
534 // Populate ValueToLoc with illegal default mappings for every value used by
535 // any UseBeforeDef variables for this instruction.
536 for (auto &Use : MIt->second) {
537 if (!UseBeforeDefVariables.count(Use.VarID))
538 continue;
539
540 for (DbgOp &Op : Use.Values) {
541 assert(!Op.isUndef() && "UseBeforeDef erroneously created for a "
542 "DbgValue with undef values.");
543 if (Op.IsConst)
544 continue;
545
546 ValueToLoc.insert({Op.ID, LocationAndQuality()});
547 }
548 }
549
550 // Exit early if we have no DbgValues to produce.
551 if (ValueToLoc.empty())
552 return;
553
554 // Determine the best location for each desired value.
555 for (auto Location : MTracker->locations()) {
556 LocIdx Idx = Location.Idx;
557 ValueIDNum &LocValueID = Location.Value;
558
559 // Is there a variable that wants a location for this value? If not, skip.
560 auto VIt = ValueToLoc.find(LocValueID);
561 if (VIt == ValueToLoc.end())
562 continue;
563
564 auto &Previous = VIt->second;
565 // If this is the first location with that value, pick it. Otherwise,
566 // consider whether it's a "longer term" location.
567 std::optional<LocationQuality> ReplacementQuality =
568 getLocQualityIfBetter(Idx, Previous.getQuality());
569 if (ReplacementQuality)
570 Previous = LocationAndQuality(Idx, *ReplacementQuality);
571 }
572
573 // Using the map of values to locations, produce a final set of values for
574 // this variable.
575 for (auto &Use : MIt->second) {
576 if (!UseBeforeDefVariables.count(Use.VarID))
577 continue;
578
579 SmallVector<ResolvedDbgOp> DbgOps;
580
581 for (DbgOp &Op : Use.Values) {
582 if (Op.IsConst) {
583 DbgOps.push_back(Op.MO);
584 continue;
585 }
586 LocIdx NewLoc = ValueToLoc.find(Op.ID)->second.getLoc();
587 if (NewLoc.isIllegal())
588 break;
589 DbgOps.push_back(NewLoc);
590 }
591
592 // If at least one value used by this debug value is no longer available,
593 // i.e. one of the values was killed before we finished defining all of
594 // the values used by this variable, discard.
595 if (DbgOps.size() != Use.Values.size())
596 continue;
597
598 // Otherwise, we're good to go.
599 auto &[Var, DILoc] = DVMap.lookupDVID(Use.VarID);
600 PendingDbgValues.push_back(std::make_pair(
601 Use.VarID, MTracker->emitLoc(DbgOps, Var, DILoc, Use.Properties)));
602 }
603 flushDbgValues(pos, nullptr);
604 }
605
606 /// Helper to move created DBG_VALUEs into Transfers collection.
flushDbgValues(MachineBasicBlock::iterator Pos,MachineBasicBlock * MBB)607 void flushDbgValues(MachineBasicBlock::iterator Pos, MachineBasicBlock *MBB) {
608 if (PendingDbgValues.size() == 0)
609 return;
610
611 // Pick out the instruction start position.
612 MachineBasicBlock::instr_iterator BundleStart;
613 if (MBB && Pos == MBB->begin())
614 BundleStart = MBB->instr_begin();
615 else
616 BundleStart = getBundleStart(Pos->getIterator());
617
618 Transfers.push_back({BundleStart, MBB, PendingDbgValues});
619 PendingDbgValues.clear();
620 }
621
isEntryValueVariable(const DebugVariable & Var,const DIExpression * Expr) const622 bool isEntryValueVariable(const DebugVariable &Var,
623 const DIExpression *Expr) const {
624 if (!Var.getVariable()->isParameter())
625 return false;
626
627 if (Var.getInlinedAt())
628 return false;
629
630 if (Expr->getNumElements() > 0 && !Expr->isDeref())
631 return false;
632
633 return true;
634 }
635
isEntryValueValue(const ValueIDNum & Val) const636 bool isEntryValueValue(const ValueIDNum &Val) const {
637 // Must be in entry block (block number zero), and be a PHI / live-in value.
638 if (Val.getBlock() || !Val.isPHI())
639 return false;
640
641 // Entry values must enter in a register.
642 if (MTracker->isSpill(Val.getLoc()))
643 return false;
644
645 Register SP = TLI->getStackPointerRegisterToSaveRestore();
646 Register FP = TRI.getFrameRegister(MF);
647 Register Reg = MTracker->LocIdxToLocID[Val.getLoc()];
648 return Reg != SP && Reg != FP;
649 }
650
recoverAsEntryValue(DebugVariableID VarID,const DbgValueProperties & Prop,const ValueIDNum & Num)651 bool recoverAsEntryValue(DebugVariableID VarID,
652 const DbgValueProperties &Prop,
653 const ValueIDNum &Num) {
654 // Is this variable location a candidate to be an entry value. First,
655 // should we be trying this at all?
656 if (!ShouldEmitDebugEntryValues)
657 return false;
658
659 const DIExpression *DIExpr = Prop.DIExpr;
660
661 // We don't currently emit entry values for DBG_VALUE_LISTs.
662 if (Prop.IsVariadic) {
663 // If this debug value can be converted to be non-variadic, then do so;
664 // otherwise give up.
665 auto NonVariadicExpression =
666 DIExpression::convertToNonVariadicExpression(DIExpr);
667 if (!NonVariadicExpression)
668 return false;
669 DIExpr = *NonVariadicExpression;
670 }
671
672 auto &[Var, DILoc] = DVMap.lookupDVID(VarID);
673
674 // Is the variable appropriate for entry values (i.e., is a parameter).
675 if (!isEntryValueVariable(Var, DIExpr))
676 return false;
677
678 // Is the value assigned to this variable still the entry value?
679 if (!isEntryValueValue(Num))
680 return false;
681
682 // Emit a variable location using an entry value expression.
683 DIExpression *NewExpr =
684 DIExpression::prepend(DIExpr, DIExpression::EntryValue);
685 Register Reg = MTracker->LocIdxToLocID[Num.getLoc()];
686 MachineOperand MO = MachineOperand::CreateReg(Reg, false);
687 PendingDbgValues.push_back(std::make_pair(
688 VarID, &*emitMOLoc(MO, Var, {NewExpr, Prop.Indirect, false})));
689 return true;
690 }
691
692 /// Change a variable value after encountering a DBG_VALUE inside a block.
redefVar(const MachineInstr & MI)693 void redefVar(const MachineInstr &MI) {
694 DebugVariable Var(MI.getDebugVariable(), MI.getDebugExpression(),
695 MI.getDebugLoc()->getInlinedAt());
696 DbgValueProperties Properties(MI);
697 DebugVariableID VarID = DVMap.getDVID(Var);
698
699 // Ignore non-register locations, we don't transfer those.
700 if (MI.isUndefDebugValue() ||
701 all_of(MI.debug_operands(),
702 [](const MachineOperand &MO) { return !MO.isReg(); })) {
703 auto It = ActiveVLocs.find(VarID);
704 if (It != ActiveVLocs.end()) {
705 for (LocIdx Loc : It->second.loc_indices())
706 ActiveMLocs[Loc].erase(VarID);
707 ActiveVLocs.erase(It);
708 }
709 // Any use-before-defs no longer apply.
710 UseBeforeDefVariables.erase(VarID);
711 return;
712 }
713
714 SmallVector<ResolvedDbgOp> NewLocs;
715 for (const MachineOperand &MO : MI.debug_operands()) {
716 if (MO.isReg()) {
717 // Any undef regs have already been filtered out above.
718 Register Reg = MO.getReg();
719 LocIdx NewLoc = MTracker->getRegMLoc(Reg);
720 NewLocs.push_back(NewLoc);
721 } else {
722 NewLocs.push_back(MO);
723 }
724 }
725
726 redefVar(MI, Properties, NewLocs);
727 }
728
729 /// Handle a change in variable location within a block. Terminate the
730 /// variables current location, and record the value it now refers to, so
731 /// that we can detect location transfers later on.
redefVar(const MachineInstr & MI,const DbgValueProperties & Properties,SmallVectorImpl<ResolvedDbgOp> & NewLocs)732 void redefVar(const MachineInstr &MI, const DbgValueProperties &Properties,
733 SmallVectorImpl<ResolvedDbgOp> &NewLocs) {
734 DebugVariable Var(MI.getDebugVariable(), MI.getDebugExpression(),
735 MI.getDebugLoc()->getInlinedAt());
736 DebugVariableID VarID = DVMap.getDVID(Var);
737 // Any use-before-defs no longer apply.
738 UseBeforeDefVariables.erase(VarID);
739
740 // Erase any previous location.
741 auto It = ActiveVLocs.find(VarID);
742 if (It != ActiveVLocs.end()) {
743 for (LocIdx Loc : It->second.loc_indices())
744 ActiveMLocs[Loc].erase(VarID);
745 }
746
747 // If there _is_ no new location, all we had to do was erase.
748 if (NewLocs.empty()) {
749 if (It != ActiveVLocs.end())
750 ActiveVLocs.erase(It);
751 return;
752 }
753
754 SmallVector<std::pair<LocIdx, DebugVariableID>> LostMLocs;
755 for (ResolvedDbgOp &Op : NewLocs) {
756 if (Op.IsConst)
757 continue;
758
759 LocIdx NewLoc = Op.Loc;
760
761 // Check whether our local copy of values-by-location in #VarLocs is out
762 // of date. Wipe old tracking data for the location if it's been clobbered
763 // in the meantime.
764 if (MTracker->readMLoc(NewLoc) != VarLocs[NewLoc.asU64()]) {
765 for (const auto &P : ActiveMLocs[NewLoc]) {
766 auto LostVLocIt = ActiveVLocs.find(P);
767 if (LostVLocIt != ActiveVLocs.end()) {
768 for (LocIdx Loc : LostVLocIt->second.loc_indices()) {
769 // Every active variable mapping for NewLoc will be cleared, no
770 // need to track individual variables.
771 if (Loc == NewLoc)
772 continue;
773 LostMLocs.emplace_back(Loc, P);
774 }
775 }
776 ActiveVLocs.erase(P);
777 }
778 for (const auto &LostMLoc : LostMLocs)
779 ActiveMLocs[LostMLoc.first].erase(LostMLoc.second);
780 LostMLocs.clear();
781 It = ActiveVLocs.find(VarID);
782 ActiveMLocs[NewLoc.asU64()].clear();
783 VarLocs[NewLoc.asU64()] = MTracker->readMLoc(NewLoc);
784 }
785
786 ActiveMLocs[NewLoc].insert(VarID);
787 }
788
789 if (It == ActiveVLocs.end()) {
790 ActiveVLocs.insert(
791 std::make_pair(VarID, ResolvedDbgValue(NewLocs, Properties)));
792 } else {
793 It->second.Ops.assign(NewLocs);
794 It->second.Properties = Properties;
795 }
796 }
797
798 /// Account for a location \p mloc being clobbered. Examine the variable
799 /// locations that will be terminated: and try to recover them by using
800 /// another location. Optionally, given \p MakeUndef, emit a DBG_VALUE to
801 /// explicitly terminate a location if it can't be recovered.
clobberMloc(LocIdx MLoc,MachineBasicBlock::iterator Pos,bool MakeUndef=true)802 void clobberMloc(LocIdx MLoc, MachineBasicBlock::iterator Pos,
803 bool MakeUndef = true) {
804 auto ActiveMLocIt = ActiveMLocs.find(MLoc);
805 if (ActiveMLocIt == ActiveMLocs.end())
806 return;
807
808 // What was the old variable value?
809 ValueIDNum OldValue = VarLocs[MLoc.asU64()];
810 clobberMloc(MLoc, OldValue, Pos, MakeUndef);
811 }
812 /// Overload that takes an explicit value \p OldValue for when the value in
813 /// \p MLoc has changed and the TransferTracker's locations have not been
814 /// updated yet.
clobberMloc(LocIdx MLoc,ValueIDNum OldValue,MachineBasicBlock::iterator Pos,bool MakeUndef=true)815 void clobberMloc(LocIdx MLoc, ValueIDNum OldValue,
816 MachineBasicBlock::iterator Pos, bool MakeUndef = true) {
817 auto ActiveMLocIt = ActiveMLocs.find(MLoc);
818 if (ActiveMLocIt == ActiveMLocs.end())
819 return;
820
821 VarLocs[MLoc.asU64()] = ValueIDNum::EmptyValue;
822
823 // Examine the remaining variable locations: if we can find the same value
824 // again, we can recover the location.
825 std::optional<LocIdx> NewLoc;
826 for (auto Loc : MTracker->locations())
827 if (Loc.Value == OldValue)
828 NewLoc = Loc.Idx;
829
830 // If there is no location, and we weren't asked to make the variable
831 // explicitly undef, then stop here.
832 if (!NewLoc && !MakeUndef) {
833 // Try and recover a few more locations with entry values.
834 for (DebugVariableID VarID : ActiveMLocIt->second) {
835 auto &Prop = ActiveVLocs.find(VarID)->second.Properties;
836 recoverAsEntryValue(VarID, Prop, OldValue);
837 }
838 flushDbgValues(Pos, nullptr);
839 return;
840 }
841
842 // Examine all the variables based on this location.
843 DenseSet<DebugVariableID> NewMLocs;
844 // If no new location has been found, every variable that depends on this
845 // MLoc is dead, so end their existing MLoc->Var mappings as well.
846 SmallVector<std::pair<LocIdx, DebugVariableID>> LostMLocs;
847 for (DebugVariableID VarID : ActiveMLocIt->second) {
848 auto ActiveVLocIt = ActiveVLocs.find(VarID);
849 // Re-state the variable location: if there's no replacement then NewLoc
850 // is std::nullopt and a $noreg DBG_VALUE will be created. Otherwise, a
851 // DBG_VALUE identifying the alternative location will be emitted.
852 const DbgValueProperties &Properties = ActiveVLocIt->second.Properties;
853
854 // Produce the new list of debug ops - an empty list if no new location
855 // was found, or the existing list with the substitution MLoc -> NewLoc
856 // otherwise.
857 SmallVector<ResolvedDbgOp> DbgOps;
858 if (NewLoc) {
859 ResolvedDbgOp OldOp(MLoc);
860 ResolvedDbgOp NewOp(*NewLoc);
861 // Insert illegal ops to overwrite afterwards.
862 DbgOps.insert(DbgOps.begin(), ActiveVLocIt->second.Ops.size(),
863 ResolvedDbgOp(LocIdx::MakeIllegalLoc()));
864 replace_copy(ActiveVLocIt->second.Ops, DbgOps.begin(), OldOp, NewOp);
865 }
866
867 auto &[Var, DILoc] = DVMap.lookupDVID(VarID);
868 PendingDbgValues.push_back(std::make_pair(
869 VarID, &*MTracker->emitLoc(DbgOps, Var, DILoc, Properties)));
870
871 // Update machine locations <=> variable locations maps. Defer updating
872 // ActiveMLocs to avoid invalidating the ActiveMLocIt iterator.
873 if (!NewLoc) {
874 for (LocIdx Loc : ActiveVLocIt->second.loc_indices()) {
875 if (Loc != MLoc)
876 LostMLocs.emplace_back(Loc, VarID);
877 }
878 ActiveVLocs.erase(ActiveVLocIt);
879 } else {
880 ActiveVLocIt->second.Ops = DbgOps;
881 NewMLocs.insert(VarID);
882 }
883 }
884
885 // Remove variables from ActiveMLocs if they no longer use any other MLocs
886 // due to being killed by this clobber.
887 for (auto &LocVarIt : LostMLocs) {
888 auto LostMLocIt = ActiveMLocs.find(LocVarIt.first);
889 assert(LostMLocIt != ActiveMLocs.end() &&
890 "Variable was using this MLoc, but ActiveMLocs[MLoc] has no "
891 "entries?");
892 LostMLocIt->second.erase(LocVarIt.second);
893 }
894
895 // We lazily track what locations have which values; if we've found a new
896 // location for the clobbered value, remember it.
897 if (NewLoc)
898 VarLocs[NewLoc->asU64()] = OldValue;
899
900 flushDbgValues(Pos, nullptr);
901
902 // Commit ActiveMLoc changes.
903 ActiveMLocIt->second.clear();
904 if (!NewMLocs.empty())
905 for (DebugVariableID VarID : NewMLocs)
906 ActiveMLocs[*NewLoc].insert(VarID);
907 }
908
909 /// Transfer variables based on \p Src to be based on \p Dst. This handles
910 /// both register copies as well as spills and restores. Creates DBG_VALUEs
911 /// describing the movement.
transferMlocs(LocIdx Src,LocIdx Dst,MachineBasicBlock::iterator Pos)912 void transferMlocs(LocIdx Src, LocIdx Dst, MachineBasicBlock::iterator Pos) {
913 // Does Src still contain the value num we expect? If not, it's been
914 // clobbered in the meantime, and our variable locations are stale.
915 if (VarLocs[Src.asU64()] != MTracker->readMLoc(Src))
916 return;
917
918 // assert(ActiveMLocs[Dst].size() == 0);
919 //^^^ Legitimate scenario on account of un-clobbered slot being assigned to?
920
921 // Move set of active variables from one location to another.
922 auto MovingVars = ActiveMLocs[Src];
923 ActiveMLocs[Dst].insert(MovingVars.begin(), MovingVars.end());
924 VarLocs[Dst.asU64()] = VarLocs[Src.asU64()];
925
926 // For each variable based on Src; create a location at Dst.
927 ResolvedDbgOp SrcOp(Src);
928 ResolvedDbgOp DstOp(Dst);
929 for (DebugVariableID VarID : MovingVars) {
930 auto ActiveVLocIt = ActiveVLocs.find(VarID);
931 assert(ActiveVLocIt != ActiveVLocs.end());
932
933 // Update all instances of Src in the variable's tracked values to Dst.
934 std::replace(ActiveVLocIt->second.Ops.begin(),
935 ActiveVLocIt->second.Ops.end(), SrcOp, DstOp);
936
937 auto &[Var, DILoc] = DVMap.lookupDVID(VarID);
938 MachineInstr *MI = MTracker->emitLoc(ActiveVLocIt->second.Ops, Var, DILoc,
939 ActiveVLocIt->second.Properties);
940 PendingDbgValues.push_back(std::make_pair(VarID, MI));
941 }
942 ActiveMLocs[Src].clear();
943 flushDbgValues(Pos, nullptr);
944
945 // XXX XXX XXX "pretend to be old LDV" means dropping all tracking data
946 // about the old location.
947 if (EmulateOldLDV)
948 VarLocs[Src.asU64()] = ValueIDNum::EmptyValue;
949 }
950
emitMOLoc(const MachineOperand & MO,const DebugVariable & Var,const DbgValueProperties & Properties)951 MachineInstrBuilder emitMOLoc(const MachineOperand &MO,
952 const DebugVariable &Var,
953 const DbgValueProperties &Properties) {
954 DebugLoc DL = DILocation::get(Var.getVariable()->getContext(), 0, 0,
955 Var.getVariable()->getScope(),
956 const_cast<DILocation *>(Var.getInlinedAt()));
957 auto MIB = BuildMI(MF, DL, TII->get(TargetOpcode::DBG_VALUE));
958 MIB.add(MO);
959 if (Properties.Indirect)
960 MIB.addImm(0);
961 else
962 MIB.addReg(0);
963 MIB.addMetadata(Var.getVariable());
964 MIB.addMetadata(Properties.DIExpr);
965 return MIB;
966 }
967 };
968
969 //===----------------------------------------------------------------------===//
970 // Implementation
971 //===----------------------------------------------------------------------===//
972
973 ValueIDNum ValueIDNum::EmptyValue = {UINT_MAX, UINT_MAX, UINT_MAX};
974 ValueIDNum ValueIDNum::TombstoneValue = {UINT_MAX, UINT_MAX, UINT_MAX - 1};
975
976 #ifndef NDEBUG
dump(const MLocTracker * MTrack) const977 void ResolvedDbgOp::dump(const MLocTracker *MTrack) const {
978 if (IsConst) {
979 dbgs() << MO;
980 } else {
981 dbgs() << MTrack->LocIdxToName(Loc);
982 }
983 }
dump(const MLocTracker * MTrack) const984 void DbgOp::dump(const MLocTracker *MTrack) const {
985 if (IsConst) {
986 dbgs() << MO;
987 } else if (!isUndef()) {
988 dbgs() << MTrack->IDAsString(ID);
989 }
990 }
dump(const MLocTracker * MTrack,const DbgOpIDMap * OpStore) const991 void DbgOpID::dump(const MLocTracker *MTrack, const DbgOpIDMap *OpStore) const {
992 if (!OpStore) {
993 dbgs() << "ID(" << asU32() << ")";
994 } else {
995 OpStore->find(*this).dump(MTrack);
996 }
997 }
dump(const MLocTracker * MTrack,const DbgOpIDMap * OpStore) const998 void DbgValue::dump(const MLocTracker *MTrack,
999 const DbgOpIDMap *OpStore) const {
1000 if (Kind == NoVal) {
1001 dbgs() << "NoVal(" << BlockNo << ")";
1002 } else if (Kind == VPHI || Kind == Def) {
1003 if (Kind == VPHI)
1004 dbgs() << "VPHI(" << BlockNo << ",";
1005 else
1006 dbgs() << "Def(";
1007 for (unsigned Idx = 0; Idx < getDbgOpIDs().size(); ++Idx) {
1008 getDbgOpID(Idx).dump(MTrack, OpStore);
1009 if (Idx != 0)
1010 dbgs() << ",";
1011 }
1012 dbgs() << ")";
1013 }
1014 if (Properties.Indirect)
1015 dbgs() << " indir";
1016 if (Properties.DIExpr)
1017 dbgs() << " " << *Properties.DIExpr;
1018 }
1019 #endif
1020
MLocTracker(MachineFunction & MF,const TargetInstrInfo & TII,const TargetRegisterInfo & TRI,const TargetLowering & TLI)1021 MLocTracker::MLocTracker(MachineFunction &MF, const TargetInstrInfo &TII,
1022 const TargetRegisterInfo &TRI,
1023 const TargetLowering &TLI)
1024 : MF(MF), TII(TII), TRI(TRI), TLI(TLI),
1025 LocIdxToIDNum(ValueIDNum::EmptyValue), LocIdxToLocID(0) {
1026 NumRegs = TRI.getNumRegs();
1027 reset();
1028 LocIDToLocIdx.resize(NumRegs, LocIdx::MakeIllegalLoc());
1029 assert(NumRegs < (1u << NUM_LOC_BITS)); // Detect bit packing failure
1030
1031 // Always track SP. This avoids the implicit clobbering caused by regmasks
1032 // from affectings its values. (LiveDebugValues disbelieves calls and
1033 // regmasks that claim to clobber SP).
1034 Register SP = TLI.getStackPointerRegisterToSaveRestore();
1035 if (SP) {
1036 unsigned ID = getLocID(SP);
1037 (void)lookupOrTrackRegister(ID);
1038
1039 for (MCRegAliasIterator RAI(SP, &TRI, true); RAI.isValid(); ++RAI)
1040 SPAliases.insert(*RAI);
1041 }
1042
1043 // Build some common stack positions -- full registers being spilt to the
1044 // stack.
1045 StackSlotIdxes.insert({{8, 0}, 0});
1046 StackSlotIdxes.insert({{16, 0}, 1});
1047 StackSlotIdxes.insert({{32, 0}, 2});
1048 StackSlotIdxes.insert({{64, 0}, 3});
1049 StackSlotIdxes.insert({{128, 0}, 4});
1050 StackSlotIdxes.insert({{256, 0}, 5});
1051 StackSlotIdxes.insert({{512, 0}, 6});
1052
1053 // Traverse all the subregister idxes, and ensure there's an index for them.
1054 // Duplicates are no problem: we're interested in their position in the
1055 // stack slot, we don't want to type the slot.
1056 for (unsigned int I = 1; I < TRI.getNumSubRegIndices(); ++I) {
1057 unsigned Size = TRI.getSubRegIdxSize(I);
1058 unsigned Offs = TRI.getSubRegIdxOffset(I);
1059 unsigned Idx = StackSlotIdxes.size();
1060
1061 // Some subregs have -1, -2 and so forth fed into their fields, to mean
1062 // special backend things. Ignore those.
1063 if (Size > 60000 || Offs > 60000)
1064 continue;
1065
1066 StackSlotIdxes.insert({{Size, Offs}, Idx});
1067 }
1068
1069 // There may also be strange register class sizes (think x86 fp80s).
1070 for (const TargetRegisterClass *RC : TRI.regclasses()) {
1071 unsigned Size = TRI.getRegSizeInBits(*RC);
1072
1073 // We might see special reserved values as sizes, and classes for other
1074 // stuff the machine tries to model. If it's more than 512 bits, then it
1075 // is very unlikely to be a register than can be spilt.
1076 if (Size > 512)
1077 continue;
1078
1079 unsigned Idx = StackSlotIdxes.size();
1080 StackSlotIdxes.insert({{Size, 0}, Idx});
1081 }
1082
1083 for (auto &Idx : StackSlotIdxes)
1084 StackIdxesToPos[Idx.second] = Idx.first;
1085
1086 NumSlotIdxes = StackSlotIdxes.size();
1087 }
1088
trackRegister(unsigned ID)1089 LocIdx MLocTracker::trackRegister(unsigned ID) {
1090 assert(ID != 0);
1091 LocIdx NewIdx = LocIdx(LocIdxToIDNum.size());
1092 LocIdxToIDNum.grow(NewIdx);
1093 LocIdxToLocID.grow(NewIdx);
1094
1095 // Default: it's an mphi.
1096 ValueIDNum ValNum = {CurBB, 0, NewIdx};
1097 // Was this reg ever touched by a regmask?
1098 for (const auto &MaskPair : reverse(Masks)) {
1099 if (MaskPair.first->clobbersPhysReg(ID)) {
1100 // There was an earlier def we skipped.
1101 ValNum = {CurBB, MaskPair.second, NewIdx};
1102 break;
1103 }
1104 }
1105
1106 LocIdxToIDNum[NewIdx] = ValNum;
1107 LocIdxToLocID[NewIdx] = ID;
1108 return NewIdx;
1109 }
1110
writeRegMask(const MachineOperand * MO,unsigned CurBB,unsigned InstID)1111 void MLocTracker::writeRegMask(const MachineOperand *MO, unsigned CurBB,
1112 unsigned InstID) {
1113 // Def any register we track have that isn't preserved. The regmask
1114 // terminates the liveness of a register, meaning its value can't be
1115 // relied upon -- we represent this by giving it a new value.
1116 for (auto Location : locations()) {
1117 unsigned ID = LocIdxToLocID[Location.Idx];
1118 // Don't clobber SP, even if the mask says it's clobbered.
1119 if (ID < NumRegs && !SPAliases.count(ID) && MO->clobbersPhysReg(ID))
1120 defReg(ID, CurBB, InstID);
1121 }
1122 Masks.push_back(std::make_pair(MO, InstID));
1123 }
1124
getOrTrackSpillLoc(SpillLoc L)1125 std::optional<SpillLocationNo> MLocTracker::getOrTrackSpillLoc(SpillLoc L) {
1126 SpillLocationNo SpillID(SpillLocs.idFor(L));
1127
1128 if (SpillID.id() == 0) {
1129 // If there is no location, and we have reached the limit of how many stack
1130 // slots to track, then don't track this one.
1131 if (SpillLocs.size() >= StackWorkingSetLimit)
1132 return std::nullopt;
1133
1134 // Spill location is untracked: create record for this one, and all
1135 // subregister slots too.
1136 SpillID = SpillLocationNo(SpillLocs.insert(L));
1137 for (unsigned StackIdx = 0; StackIdx < NumSlotIdxes; ++StackIdx) {
1138 unsigned L = getSpillIDWithIdx(SpillID, StackIdx);
1139 LocIdx Idx = LocIdx(LocIdxToIDNum.size()); // New idx
1140 LocIdxToIDNum.grow(Idx);
1141 LocIdxToLocID.grow(Idx);
1142 LocIDToLocIdx.push_back(Idx);
1143 LocIdxToLocID[Idx] = L;
1144 // Initialize to PHI value; corresponds to the location's live-in value
1145 // during transfer function construction.
1146 LocIdxToIDNum[Idx] = ValueIDNum(CurBB, 0, Idx);
1147 }
1148 }
1149 return SpillID;
1150 }
1151
LocIdxToName(LocIdx Idx) const1152 std::string MLocTracker::LocIdxToName(LocIdx Idx) const {
1153 unsigned ID = LocIdxToLocID[Idx];
1154 if (ID >= NumRegs) {
1155 StackSlotPos Pos = locIDToSpillIdx(ID);
1156 ID -= NumRegs;
1157 unsigned Slot = ID / NumSlotIdxes;
1158 return Twine("slot ")
1159 .concat(Twine(Slot).concat(Twine(" sz ").concat(Twine(Pos.first)
1160 .concat(Twine(" offs ").concat(Twine(Pos.second))))))
1161 .str();
1162 } else {
1163 return TRI.getRegAsmName(ID).str();
1164 }
1165 }
1166
IDAsString(const ValueIDNum & Num) const1167 std::string MLocTracker::IDAsString(const ValueIDNum &Num) const {
1168 std::string DefName = LocIdxToName(Num.getLoc());
1169 return Num.asString(DefName);
1170 }
1171
1172 #ifndef NDEBUG
dump()1173 LLVM_DUMP_METHOD void MLocTracker::dump() {
1174 for (auto Location : locations()) {
1175 std::string MLocName = LocIdxToName(Location.Value.getLoc());
1176 std::string DefName = Location.Value.asString(MLocName);
1177 dbgs() << LocIdxToName(Location.Idx) << " --> " << DefName << "\n";
1178 }
1179 }
1180
dump_mloc_map()1181 LLVM_DUMP_METHOD void MLocTracker::dump_mloc_map() {
1182 for (auto Location : locations()) {
1183 std::string foo = LocIdxToName(Location.Idx);
1184 dbgs() << "Idx " << Location.Idx.asU64() << " " << foo << "\n";
1185 }
1186 }
1187 #endif
1188
1189 MachineInstrBuilder
emitLoc(const SmallVectorImpl<ResolvedDbgOp> & DbgOps,const DebugVariable & Var,const DILocation * DILoc,const DbgValueProperties & Properties)1190 MLocTracker::emitLoc(const SmallVectorImpl<ResolvedDbgOp> &DbgOps,
1191 const DebugVariable &Var, const DILocation *DILoc,
1192 const DbgValueProperties &Properties) {
1193 DebugLoc DL = DebugLoc(DILoc);
1194
1195 const MCInstrDesc &Desc = Properties.IsVariadic
1196 ? TII.get(TargetOpcode::DBG_VALUE_LIST)
1197 : TII.get(TargetOpcode::DBG_VALUE);
1198
1199 #ifdef EXPENSIVE_CHECKS
1200 assert(all_of(DbgOps,
1201 [](const ResolvedDbgOp &Op) {
1202 return Op.IsConst || !Op.Loc.isIllegal();
1203 }) &&
1204 "Did not expect illegal ops in DbgOps.");
1205 assert((DbgOps.size() == 0 ||
1206 DbgOps.size() == Properties.getLocationOpCount()) &&
1207 "Expected to have either one DbgOp per MI LocationOp, or none.");
1208 #endif
1209
1210 auto GetRegOp = [](unsigned Reg) -> MachineOperand {
1211 return MachineOperand::CreateReg(
1212 /* Reg */ Reg, /* isDef */ false, /* isImp */ false,
1213 /* isKill */ false, /* isDead */ false,
1214 /* isUndef */ false, /* isEarlyClobber */ false,
1215 /* SubReg */ 0, /* isDebug */ true);
1216 };
1217
1218 SmallVector<MachineOperand> MOs;
1219
1220 auto EmitUndef = [&]() {
1221 MOs.clear();
1222 MOs.assign(Properties.getLocationOpCount(), GetRegOp(0));
1223 return BuildMI(MF, DL, Desc, false, MOs, Var.getVariable(),
1224 Properties.DIExpr);
1225 };
1226
1227 // Don't bother passing any real operands to BuildMI if any of them would be
1228 // $noreg.
1229 if (DbgOps.empty())
1230 return EmitUndef();
1231
1232 bool Indirect = Properties.Indirect;
1233
1234 const DIExpression *Expr = Properties.DIExpr;
1235
1236 assert(DbgOps.size() == Properties.getLocationOpCount());
1237
1238 // If all locations are valid, accumulate them into our list of
1239 // MachineOperands. For any spilled locations, either update the indirectness
1240 // register or apply the appropriate transformations in the DIExpression.
1241 for (size_t Idx = 0; Idx < Properties.getLocationOpCount(); ++Idx) {
1242 const ResolvedDbgOp &Op = DbgOps[Idx];
1243
1244 if (Op.IsConst) {
1245 MOs.push_back(Op.MO);
1246 continue;
1247 }
1248
1249 LocIdx MLoc = Op.Loc;
1250 unsigned LocID = LocIdxToLocID[MLoc];
1251 if (LocID >= NumRegs) {
1252 SpillLocationNo SpillID = locIDToSpill(LocID);
1253 StackSlotPos StackIdx = locIDToSpillIdx(LocID);
1254 unsigned short Offset = StackIdx.second;
1255
1256 // TODO: support variables that are located in spill slots, with non-zero
1257 // offsets from the start of the spill slot. It would require some more
1258 // complex DIExpression calculations. This doesn't seem to be produced by
1259 // LLVM right now, so don't try and support it.
1260 // Accept no-subregister slots and subregisters where the offset is zero.
1261 // The consumer should already have type information to work out how large
1262 // the variable is.
1263 if (Offset == 0) {
1264 const SpillLoc &Spill = SpillLocs[SpillID.id()];
1265 unsigned Base = Spill.SpillBase;
1266
1267 // There are several ways we can dereference things, and several inputs
1268 // to consider:
1269 // * NRVO variables will appear with IsIndirect set, but should have
1270 // nothing else in their DIExpressions,
1271 // * Variables with DW_OP_stack_value in their expr already need an
1272 // explicit dereference of the stack location,
1273 // * Values that don't match the variable size need DW_OP_deref_size,
1274 // * Everything else can just become a simple location expression.
1275
1276 // We need to use deref_size whenever there's a mismatch between the
1277 // size of value and the size of variable portion being read.
1278 // Additionally, we should use it whenever dealing with stack_value
1279 // fragments, to avoid the consumer having to determine the deref size
1280 // from DW_OP_piece.
1281 bool UseDerefSize = false;
1282 unsigned ValueSizeInBits = getLocSizeInBits(MLoc);
1283 unsigned DerefSizeInBytes = ValueSizeInBits / 8;
1284 if (auto Fragment = Var.getFragment()) {
1285 unsigned VariableSizeInBits = Fragment->SizeInBits;
1286 if (VariableSizeInBits != ValueSizeInBits || Expr->isComplex())
1287 UseDerefSize = true;
1288 } else if (auto Size = Var.getVariable()->getSizeInBits()) {
1289 if (*Size != ValueSizeInBits) {
1290 UseDerefSize = true;
1291 }
1292 }
1293
1294 SmallVector<uint64_t, 5> OffsetOps;
1295 TRI.getOffsetOpcodes(Spill.SpillOffset, OffsetOps);
1296 bool StackValue = false;
1297
1298 if (Properties.Indirect) {
1299 // This is something like an NRVO variable, where the pointer has been
1300 // spilt to the stack. It should end up being a memory location, with
1301 // the pointer to the variable loaded off the stack with a deref:
1302 assert(!Expr->isImplicit());
1303 OffsetOps.push_back(dwarf::DW_OP_deref);
1304 } else if (UseDerefSize && Expr->isSingleLocationExpression()) {
1305 // TODO: Figure out how to handle deref size issues for variadic
1306 // values.
1307 // We're loading a value off the stack that's not the same size as the
1308 // variable. Add / subtract stack offset, explicitly deref with a
1309 // size, and add DW_OP_stack_value if not already present.
1310 OffsetOps.push_back(dwarf::DW_OP_deref_size);
1311 OffsetOps.push_back(DerefSizeInBytes);
1312 StackValue = true;
1313 } else if (Expr->isComplex() || Properties.IsVariadic) {
1314 // A variable with no size ambiguity, but with extra elements in it's
1315 // expression. Manually dereference the stack location.
1316 OffsetOps.push_back(dwarf::DW_OP_deref);
1317 } else {
1318 // A plain value that has been spilt to the stack, with no further
1319 // context. Request a location expression, marking the DBG_VALUE as
1320 // IsIndirect.
1321 Indirect = true;
1322 }
1323
1324 Expr = DIExpression::appendOpsToArg(Expr, OffsetOps, Idx, StackValue);
1325 MOs.push_back(GetRegOp(Base));
1326 } else {
1327 // This is a stack location with a weird subregister offset: emit an
1328 // undef DBG_VALUE instead.
1329 return EmitUndef();
1330 }
1331 } else {
1332 // Non-empty, non-stack slot, must be a plain register.
1333 MOs.push_back(GetRegOp(LocID));
1334 }
1335 }
1336
1337 return BuildMI(MF, DL, Desc, Indirect, MOs, Var.getVariable(), Expr);
1338 }
1339
1340 /// Default construct and initialize the pass.
1341 InstrRefBasedLDV::InstrRefBasedLDV() = default;
1342
isCalleeSaved(LocIdx L) const1343 bool InstrRefBasedLDV::isCalleeSaved(LocIdx L) const {
1344 unsigned Reg = MTracker->LocIdxToLocID[L];
1345 return isCalleeSavedReg(Reg);
1346 }
isCalleeSavedReg(Register R) const1347 bool InstrRefBasedLDV::isCalleeSavedReg(Register R) const {
1348 for (MCRegAliasIterator RAI(R, TRI, true); RAI.isValid(); ++RAI)
1349 if (CalleeSavedRegs.test(*RAI))
1350 return true;
1351 return false;
1352 }
1353
1354 //===----------------------------------------------------------------------===//
1355 // Debug Range Extension Implementation
1356 //===----------------------------------------------------------------------===//
1357
1358 #ifndef NDEBUG
1359 // Something to restore in the future.
1360 // void InstrRefBasedLDV::printVarLocInMBB(..)
1361 #endif
1362
1363 std::optional<SpillLocationNo>
extractSpillBaseRegAndOffset(const MachineInstr & MI)1364 InstrRefBasedLDV::extractSpillBaseRegAndOffset(const MachineInstr &MI) {
1365 assert(MI.hasOneMemOperand() &&
1366 "Spill instruction does not have exactly one memory operand?");
1367 auto MMOI = MI.memoperands_begin();
1368 const PseudoSourceValue *PVal = (*MMOI)->getPseudoValue();
1369 assert(PVal->kind() == PseudoSourceValue::FixedStack &&
1370 "Inconsistent memory operand in spill instruction");
1371 int FI = cast<FixedStackPseudoSourceValue>(PVal)->getFrameIndex();
1372 const MachineBasicBlock *MBB = MI.getParent();
1373 Register Reg;
1374 StackOffset Offset = TFI->getFrameIndexReference(*MBB->getParent(), FI, Reg);
1375 return MTracker->getOrTrackSpillLoc({Reg, Offset});
1376 }
1377
1378 std::optional<LocIdx>
findLocationForMemOperand(const MachineInstr & MI)1379 InstrRefBasedLDV::findLocationForMemOperand(const MachineInstr &MI) {
1380 std::optional<SpillLocationNo> SpillLoc = extractSpillBaseRegAndOffset(MI);
1381 if (!SpillLoc)
1382 return std::nullopt;
1383
1384 // Where in the stack slot is this value defined -- i.e., what size of value
1385 // is this? An important question, because it could be loaded into a register
1386 // from the stack at some point. Happily the memory operand will tell us
1387 // the size written to the stack.
1388 auto *MemOperand = *MI.memoperands_begin();
1389 LocationSize SizeInBits = MemOperand->getSizeInBits();
1390 assert(SizeInBits.hasValue() && "Expected to find a valid size!");
1391
1392 // Find that position in the stack indexes we're tracking.
1393 auto IdxIt = MTracker->StackSlotIdxes.find({SizeInBits.getValue(), 0});
1394 if (IdxIt == MTracker->StackSlotIdxes.end())
1395 // That index is not tracked. This is suprising, and unlikely to ever
1396 // occur, but the safe action is to indicate the variable is optimised out.
1397 return std::nullopt;
1398
1399 unsigned SpillID = MTracker->getSpillIDWithIdx(*SpillLoc, IdxIt->second);
1400 return MTracker->getSpillMLoc(SpillID);
1401 }
1402
1403 /// End all previous ranges related to @MI and start a new range from @MI
1404 /// if it is a DBG_VALUE instr.
transferDebugValue(const MachineInstr & MI)1405 bool InstrRefBasedLDV::transferDebugValue(const MachineInstr &MI) {
1406 if (!MI.isDebugValue())
1407 return false;
1408
1409 assert(MI.getDebugVariable()->isValidLocationForIntrinsic(MI.getDebugLoc()) &&
1410 "Expected inlined-at fields to agree");
1411
1412 // If there are no instructions in this lexical scope, do no location tracking
1413 // at all, this variable shouldn't get a legitimate location range.
1414 auto *Scope = LS.findLexicalScope(MI.getDebugLoc().get());
1415 if (Scope == nullptr)
1416 return true; // handled it; by doing nothing
1417
1418 // MLocTracker needs to know that this register is read, even if it's only
1419 // read by a debug inst.
1420 for (const MachineOperand &MO : MI.debug_operands())
1421 if (MO.isReg() && MO.getReg() != 0)
1422 (void)MTracker->readReg(MO.getReg());
1423
1424 // If we're preparing for the second analysis (variables), the machine value
1425 // locations are already solved, and we report this DBG_VALUE and the value
1426 // it refers to to VLocTracker.
1427 if (VTracker) {
1428 SmallVector<DbgOpID> DebugOps;
1429 // Feed defVar the new variable location, or if this is a DBG_VALUE $noreg,
1430 // feed defVar None.
1431 if (!MI.isUndefDebugValue()) {
1432 for (const MachineOperand &MO : MI.debug_operands()) {
1433 // There should be no undef registers here, as we've screened for undef
1434 // debug values.
1435 if (MO.isReg()) {
1436 DebugOps.push_back(DbgOpStore.insert(MTracker->readReg(MO.getReg())));
1437 } else if (MO.isImm() || MO.isFPImm() || MO.isCImm()) {
1438 DebugOps.push_back(DbgOpStore.insert(MO));
1439 } else {
1440 llvm_unreachable("Unexpected debug operand type.");
1441 }
1442 }
1443 }
1444 VTracker->defVar(MI, DbgValueProperties(MI), DebugOps);
1445 }
1446
1447 // If performing final tracking of transfers, report this variable definition
1448 // to the TransferTracker too.
1449 if (TTracker)
1450 TTracker->redefVar(MI);
1451 return true;
1452 }
1453
getValueForInstrRef(unsigned InstNo,unsigned OpNo,MachineInstr & MI,const FuncValueTable * MLiveOuts,const FuncValueTable * MLiveIns)1454 std::optional<ValueIDNum> InstrRefBasedLDV::getValueForInstrRef(
1455 unsigned InstNo, unsigned OpNo, MachineInstr &MI,
1456 const FuncValueTable *MLiveOuts, const FuncValueTable *MLiveIns) {
1457 // Various optimizations may have happened to the value during codegen,
1458 // recorded in the value substitution table. Apply any substitutions to
1459 // the instruction / operand number in this DBG_INSTR_REF, and collect
1460 // any subregister extractions performed during optimization.
1461 const MachineFunction &MF = *MI.getParent()->getParent();
1462
1463 // Create dummy substitution with Src set, for lookup.
1464 auto SoughtSub =
1465 MachineFunction::DebugSubstitution({InstNo, OpNo}, {0, 0}, 0);
1466
1467 SmallVector<unsigned, 4> SeenSubregs;
1468 auto LowerBoundIt = llvm::lower_bound(MF.DebugValueSubstitutions, SoughtSub);
1469 while (LowerBoundIt != MF.DebugValueSubstitutions.end() &&
1470 LowerBoundIt->Src == SoughtSub.Src) {
1471 std::tie(InstNo, OpNo) = LowerBoundIt->Dest;
1472 SoughtSub.Src = LowerBoundIt->Dest;
1473 if (unsigned Subreg = LowerBoundIt->Subreg)
1474 SeenSubregs.push_back(Subreg);
1475 LowerBoundIt = llvm::lower_bound(MF.DebugValueSubstitutions, SoughtSub);
1476 }
1477
1478 // Default machine value number is <None> -- if no instruction defines
1479 // the corresponding value, it must have been optimized out.
1480 std::optional<ValueIDNum> NewID;
1481
1482 // Try to lookup the instruction number, and find the machine value number
1483 // that it defines. It could be an instruction, or a PHI.
1484 auto InstrIt = DebugInstrNumToInstr.find(InstNo);
1485 auto PHIIt = llvm::lower_bound(DebugPHINumToValue, InstNo);
1486 if (InstrIt != DebugInstrNumToInstr.end()) {
1487 const MachineInstr &TargetInstr = *InstrIt->second.first;
1488 uint64_t BlockNo = TargetInstr.getParent()->getNumber();
1489
1490 // Pick out the designated operand. It might be a memory reference, if
1491 // a register def was folded into a stack store.
1492 if (OpNo == MachineFunction::DebugOperandMemNumber &&
1493 TargetInstr.hasOneMemOperand()) {
1494 std::optional<LocIdx> L = findLocationForMemOperand(TargetInstr);
1495 if (L)
1496 NewID = ValueIDNum(BlockNo, InstrIt->second.second, *L);
1497 } else if (OpNo != MachineFunction::DebugOperandMemNumber) {
1498 // Permit the debug-info to be completely wrong: identifying a nonexistant
1499 // operand, or one that is not a register definition, means something
1500 // unexpected happened during optimisation. Broken debug-info, however,
1501 // shouldn't crash the compiler -- instead leave the variable value as
1502 // None, which will make it appear "optimised out".
1503 if (OpNo < TargetInstr.getNumOperands()) {
1504 const MachineOperand &MO = TargetInstr.getOperand(OpNo);
1505
1506 if (MO.isReg() && MO.isDef() && MO.getReg()) {
1507 unsigned LocID = MTracker->getLocID(MO.getReg());
1508 LocIdx L = MTracker->LocIDToLocIdx[LocID];
1509 NewID = ValueIDNum(BlockNo, InstrIt->second.second, L);
1510 }
1511 }
1512
1513 if (!NewID) {
1514 LLVM_DEBUG(
1515 { dbgs() << "Seen instruction reference to illegal operand\n"; });
1516 }
1517 }
1518 // else: NewID is left as None.
1519 } else if (PHIIt != DebugPHINumToValue.end() && PHIIt->InstrNum == InstNo) {
1520 // It's actually a PHI value. Which value it is might not be obvious, use
1521 // the resolver helper to find out.
1522 assert(MLiveOuts && MLiveIns);
1523 NewID = resolveDbgPHIs(*MI.getParent()->getParent(), *MLiveOuts, *MLiveIns,
1524 MI, InstNo);
1525 }
1526
1527 // Apply any subregister extractions, in reverse. We might have seen code
1528 // like this:
1529 // CALL64 @foo, implicit-def $rax
1530 // %0:gr64 = COPY $rax
1531 // %1:gr32 = COPY %0.sub_32bit
1532 // %2:gr16 = COPY %1.sub_16bit
1533 // %3:gr8 = COPY %2.sub_8bit
1534 // In which case each copy would have been recorded as a substitution with
1535 // a subregister qualifier. Apply those qualifiers now.
1536 if (NewID && !SeenSubregs.empty()) {
1537 unsigned Offset = 0;
1538 unsigned Size = 0;
1539
1540 // Look at each subregister that we passed through, and progressively
1541 // narrow in, accumulating any offsets that occur. Substitutions should
1542 // only ever be the same or narrower width than what they read from;
1543 // iterate in reverse order so that we go from wide to small.
1544 for (unsigned Subreg : reverse(SeenSubregs)) {
1545 unsigned ThisSize = TRI->getSubRegIdxSize(Subreg);
1546 unsigned ThisOffset = TRI->getSubRegIdxOffset(Subreg);
1547 Offset += ThisOffset;
1548 Size = (Size == 0) ? ThisSize : std::min(Size, ThisSize);
1549 }
1550
1551 // If that worked, look for an appropriate subregister with the register
1552 // where the define happens. Don't look at values that were defined during
1553 // a stack write: we can't currently express register locations within
1554 // spills.
1555 LocIdx L = NewID->getLoc();
1556 if (NewID && !MTracker->isSpill(L)) {
1557 // Find the register class for the register where this def happened.
1558 // FIXME: no index for this?
1559 Register Reg = MTracker->LocIdxToLocID[L];
1560 const TargetRegisterClass *TRC = nullptr;
1561 for (const auto *TRCI : TRI->regclasses())
1562 if (TRCI->contains(Reg))
1563 TRC = TRCI;
1564 assert(TRC && "Couldn't find target register class?");
1565
1566 // If the register we have isn't the right size or in the right place,
1567 // Try to find a subregister inside it.
1568 unsigned MainRegSize = TRI->getRegSizeInBits(*TRC);
1569 if (Size != MainRegSize || Offset) {
1570 // Enumerate all subregisters, searching.
1571 Register NewReg = 0;
1572 for (MCPhysReg SR : TRI->subregs(Reg)) {
1573 unsigned Subreg = TRI->getSubRegIndex(Reg, SR);
1574 unsigned SubregSize = TRI->getSubRegIdxSize(Subreg);
1575 unsigned SubregOffset = TRI->getSubRegIdxOffset(Subreg);
1576 if (SubregSize == Size && SubregOffset == Offset) {
1577 NewReg = SR;
1578 break;
1579 }
1580 }
1581
1582 // If we didn't find anything: there's no way to express our value.
1583 if (!NewReg) {
1584 NewID = std::nullopt;
1585 } else {
1586 // Re-state the value as being defined within the subregister
1587 // that we found.
1588 LocIdx NewLoc = MTracker->lookupOrTrackRegister(NewReg);
1589 NewID = ValueIDNum(NewID->getBlock(), NewID->getInst(), NewLoc);
1590 }
1591 }
1592 } else {
1593 // If we can't handle subregisters, unset the new value.
1594 NewID = std::nullopt;
1595 }
1596 }
1597
1598 return NewID;
1599 }
1600
transferDebugInstrRef(MachineInstr & MI,const FuncValueTable * MLiveOuts,const FuncValueTable * MLiveIns)1601 bool InstrRefBasedLDV::transferDebugInstrRef(MachineInstr &MI,
1602 const FuncValueTable *MLiveOuts,
1603 const FuncValueTable *MLiveIns) {
1604 if (!MI.isDebugRef())
1605 return false;
1606
1607 // Only handle this instruction when we are building the variable value
1608 // transfer function.
1609 if (!VTracker && !TTracker)
1610 return false;
1611
1612 const DILocalVariable *Var = MI.getDebugVariable();
1613 const DIExpression *Expr = MI.getDebugExpression();
1614 const DILocation *DebugLoc = MI.getDebugLoc();
1615 const DILocation *InlinedAt = DebugLoc->getInlinedAt();
1616 assert(Var->isValidLocationForIntrinsic(DebugLoc) &&
1617 "Expected inlined-at fields to agree");
1618
1619 DebugVariable V(Var, Expr, InlinedAt);
1620
1621 auto *Scope = LS.findLexicalScope(MI.getDebugLoc().get());
1622 if (Scope == nullptr)
1623 return true; // Handled by doing nothing. This variable is never in scope.
1624
1625 SmallVector<DbgOpID> DbgOpIDs;
1626 for (const MachineOperand &MO : MI.debug_operands()) {
1627 if (!MO.isDbgInstrRef()) {
1628 assert(!MO.isReg() && "DBG_INSTR_REF should not contain registers");
1629 DbgOpID ConstOpID = DbgOpStore.insert(DbgOp(MO));
1630 DbgOpIDs.push_back(ConstOpID);
1631 continue;
1632 }
1633
1634 unsigned InstNo = MO.getInstrRefInstrIndex();
1635 unsigned OpNo = MO.getInstrRefOpIndex();
1636
1637 // Default machine value number is <None> -- if no instruction defines
1638 // the corresponding value, it must have been optimized out.
1639 std::optional<ValueIDNum> NewID =
1640 getValueForInstrRef(InstNo, OpNo, MI, MLiveOuts, MLiveIns);
1641 // We have a value number or std::nullopt. If the latter, then kill the
1642 // entire debug value.
1643 if (NewID) {
1644 DbgOpIDs.push_back(DbgOpStore.insert(*NewID));
1645 } else {
1646 DbgOpIDs.clear();
1647 break;
1648 }
1649 }
1650
1651 // We have a DbgOpID for every value or for none. Tell the variable value
1652 // tracker about it. The rest of this LiveDebugValues implementation acts
1653 // exactly the same for DBG_INSTR_REFs as DBG_VALUEs (just, the former can
1654 // refer to values that aren't immediately available).
1655 DbgValueProperties Properties(Expr, false, true);
1656 if (VTracker)
1657 VTracker->defVar(MI, Properties, DbgOpIDs);
1658
1659 // If we're on the final pass through the function, decompose this INSTR_REF
1660 // into a plain DBG_VALUE.
1661 if (!TTracker)
1662 return true;
1663
1664 // Fetch the concrete DbgOps now, as we will need them later.
1665 SmallVector<DbgOp> DbgOps;
1666 for (DbgOpID OpID : DbgOpIDs) {
1667 DbgOps.push_back(DbgOpStore.find(OpID));
1668 }
1669
1670 // Pick a location for the machine value number, if such a location exists.
1671 // (This information could be stored in TransferTracker to make it faster).
1672 SmallDenseMap<ValueIDNum, TransferTracker::LocationAndQuality> FoundLocs;
1673 SmallVector<ValueIDNum> ValuesToFind;
1674 // Initialized the preferred-location map with illegal locations, to be
1675 // filled in later.
1676 for (const DbgOp &Op : DbgOps) {
1677 if (!Op.IsConst)
1678 if (FoundLocs.insert({Op.ID, TransferTracker::LocationAndQuality()})
1679 .second)
1680 ValuesToFind.push_back(Op.ID);
1681 }
1682
1683 for (auto Location : MTracker->locations()) {
1684 LocIdx CurL = Location.Idx;
1685 ValueIDNum ID = MTracker->readMLoc(CurL);
1686 auto ValueToFindIt = find(ValuesToFind, ID);
1687 if (ValueToFindIt == ValuesToFind.end())
1688 continue;
1689 auto &Previous = FoundLocs.find(ID)->second;
1690 // If this is the first location with that value, pick it. Otherwise,
1691 // consider whether it's a "longer term" location.
1692 std::optional<TransferTracker::LocationQuality> ReplacementQuality =
1693 TTracker->getLocQualityIfBetter(CurL, Previous.getQuality());
1694 if (ReplacementQuality) {
1695 Previous = TransferTracker::LocationAndQuality(CurL, *ReplacementQuality);
1696 if (Previous.isBest()) {
1697 ValuesToFind.erase(ValueToFindIt);
1698 if (ValuesToFind.empty())
1699 break;
1700 }
1701 }
1702 }
1703
1704 SmallVector<ResolvedDbgOp> NewLocs;
1705 for (const DbgOp &DbgOp : DbgOps) {
1706 if (DbgOp.IsConst) {
1707 NewLocs.push_back(DbgOp.MO);
1708 continue;
1709 }
1710 LocIdx FoundLoc = FoundLocs.find(DbgOp.ID)->second.getLoc();
1711 if (FoundLoc.isIllegal()) {
1712 NewLocs.clear();
1713 break;
1714 }
1715 NewLocs.push_back(FoundLoc);
1716 }
1717 // Tell transfer tracker that the variable value has changed.
1718 TTracker->redefVar(MI, Properties, NewLocs);
1719
1720 // If there were values with no location, but all such values are defined in
1721 // later instructions in this block, this is a block-local use-before-def.
1722 if (!DbgOps.empty() && NewLocs.empty()) {
1723 bool IsValidUseBeforeDef = true;
1724 uint64_t LastUseBeforeDef = 0;
1725 for (auto ValueLoc : FoundLocs) {
1726 ValueIDNum NewID = ValueLoc.first;
1727 LocIdx FoundLoc = ValueLoc.second.getLoc();
1728 if (!FoundLoc.isIllegal())
1729 continue;
1730 // If we have an value with no location that is not defined in this block,
1731 // then it has no location in this block, leaving this value undefined.
1732 if (NewID.getBlock() != CurBB || NewID.getInst() <= CurInst) {
1733 IsValidUseBeforeDef = false;
1734 break;
1735 }
1736 LastUseBeforeDef = std::max(LastUseBeforeDef, NewID.getInst());
1737 }
1738 if (IsValidUseBeforeDef) {
1739 DebugVariableID VID = DVMap.insertDVID(V, MI.getDebugLoc().get());
1740 TTracker->addUseBeforeDef(VID, {MI.getDebugExpression(), false, true},
1741 DbgOps, LastUseBeforeDef);
1742 }
1743 }
1744
1745 // Produce a DBG_VALUE representing what this DBG_INSTR_REF meant.
1746 // This DBG_VALUE is potentially a $noreg / undefined location, if
1747 // FoundLoc is illegal.
1748 // (XXX -- could morph the DBG_INSTR_REF in the future).
1749 MachineInstr *DbgMI =
1750 MTracker->emitLoc(NewLocs, V, MI.getDebugLoc().get(), Properties);
1751 DebugVariableID ID = DVMap.getDVID(V);
1752
1753 TTracker->PendingDbgValues.push_back(std::make_pair(ID, DbgMI));
1754 TTracker->flushDbgValues(MI.getIterator(), nullptr);
1755 return true;
1756 }
1757
transferDebugPHI(MachineInstr & MI)1758 bool InstrRefBasedLDV::transferDebugPHI(MachineInstr &MI) {
1759 if (!MI.isDebugPHI())
1760 return false;
1761
1762 // Analyse these only when solving the machine value location problem.
1763 if (VTracker || TTracker)
1764 return true;
1765
1766 // First operand is the value location, either a stack slot or register.
1767 // Second is the debug instruction number of the original PHI.
1768 const MachineOperand &MO = MI.getOperand(0);
1769 unsigned InstrNum = MI.getOperand(1).getImm();
1770
1771 auto EmitBadPHI = [this, &MI, InstrNum]() -> bool {
1772 // Helper lambda to do any accounting when we fail to find a location for
1773 // a DBG_PHI. This can happen if DBG_PHIs are malformed, or refer to a
1774 // dead stack slot, for example.
1775 // Record a DebugPHIRecord with an empty value + location.
1776 DebugPHINumToValue.push_back(
1777 {InstrNum, MI.getParent(), std::nullopt, std::nullopt});
1778 return true;
1779 };
1780
1781 if (MO.isReg() && MO.getReg()) {
1782 // The value is whatever's currently in the register. Read and record it,
1783 // to be analysed later.
1784 Register Reg = MO.getReg();
1785 ValueIDNum Num = MTracker->readReg(Reg);
1786 auto PHIRec = DebugPHIRecord(
1787 {InstrNum, MI.getParent(), Num, MTracker->lookupOrTrackRegister(Reg)});
1788 DebugPHINumToValue.push_back(PHIRec);
1789
1790 // Ensure this register is tracked.
1791 for (MCRegAliasIterator RAI(MO.getReg(), TRI, true); RAI.isValid(); ++RAI)
1792 MTracker->lookupOrTrackRegister(*RAI);
1793 } else if (MO.isFI()) {
1794 // The value is whatever's in this stack slot.
1795 unsigned FI = MO.getIndex();
1796
1797 // If the stack slot is dead, then this was optimized away.
1798 // FIXME: stack slot colouring should account for slots that get merged.
1799 if (MFI->isDeadObjectIndex(FI))
1800 return EmitBadPHI();
1801
1802 // Identify this spill slot, ensure it's tracked.
1803 Register Base;
1804 StackOffset Offs = TFI->getFrameIndexReference(*MI.getMF(), FI, Base);
1805 SpillLoc SL = {Base, Offs};
1806 std::optional<SpillLocationNo> SpillNo = MTracker->getOrTrackSpillLoc(SL);
1807
1808 // We might be able to find a value, but have chosen not to, to avoid
1809 // tracking too much stack information.
1810 if (!SpillNo)
1811 return EmitBadPHI();
1812
1813 // Any stack location DBG_PHI should have an associate bit-size.
1814 assert(MI.getNumOperands() == 3 && "Stack DBG_PHI with no size?");
1815 unsigned slotBitSize = MI.getOperand(2).getImm();
1816
1817 unsigned SpillID = MTracker->getLocID(*SpillNo, {slotBitSize, 0});
1818 LocIdx SpillLoc = MTracker->getSpillMLoc(SpillID);
1819 ValueIDNum Result = MTracker->readMLoc(SpillLoc);
1820
1821 // Record this DBG_PHI for later analysis.
1822 auto DbgPHI = DebugPHIRecord({InstrNum, MI.getParent(), Result, SpillLoc});
1823 DebugPHINumToValue.push_back(DbgPHI);
1824 } else {
1825 // Else: if the operand is neither a legal register or a stack slot, then
1826 // we're being fed illegal debug-info. Record an empty PHI, so that any
1827 // debug users trying to read this number will be put off trying to
1828 // interpret the value.
1829 LLVM_DEBUG(
1830 { dbgs() << "Seen DBG_PHI with unrecognised operand format\n"; });
1831 return EmitBadPHI();
1832 }
1833
1834 return true;
1835 }
1836
transferRegisterDef(MachineInstr & MI)1837 void InstrRefBasedLDV::transferRegisterDef(MachineInstr &MI) {
1838 // Meta Instructions do not affect the debug liveness of any register they
1839 // define.
1840 if (MI.isImplicitDef()) {
1841 // Except when there's an implicit def, and the location it's defining has
1842 // no value number. The whole point of an implicit def is to announce that
1843 // the register is live, without be specific about it's value. So define
1844 // a value if there isn't one already.
1845 ValueIDNum Num = MTracker->readReg(MI.getOperand(0).getReg());
1846 // Has a legitimate value -> ignore the implicit def.
1847 if (Num.getLoc() != 0)
1848 return;
1849 // Otherwise, def it here.
1850 } else if (MI.isMetaInstruction())
1851 return;
1852
1853 // We always ignore SP defines on call instructions, they don't actually
1854 // change the value of the stack pointer... except for win32's _chkstk. This
1855 // is rare: filter quickly for the common case (no stack adjustments, not a
1856 // call, etc). If it is a call that modifies SP, recognise the SP register
1857 // defs.
1858 bool CallChangesSP = false;
1859 if (AdjustsStackInCalls && MI.isCall() && MI.getOperand(0).isSymbol() &&
1860 !strcmp(MI.getOperand(0).getSymbolName(), StackProbeSymbolName.data()))
1861 CallChangesSP = true;
1862
1863 // Test whether we should ignore a def of this register due to it being part
1864 // of the stack pointer.
1865 auto IgnoreSPAlias = [this, &MI, CallChangesSP](Register R) -> bool {
1866 if (CallChangesSP)
1867 return false;
1868 return MI.isCall() && MTracker->SPAliases.count(R);
1869 };
1870
1871 // Find the regs killed by MI, and find regmasks of preserved regs.
1872 // Max out the number of statically allocated elements in `DeadRegs`, as this
1873 // prevents fallback to std::set::count() operations.
1874 SmallSet<uint32_t, 32> DeadRegs;
1875 SmallVector<const uint32_t *, 4> RegMasks;
1876 SmallVector<const MachineOperand *, 4> RegMaskPtrs;
1877 for (const MachineOperand &MO : MI.operands()) {
1878 // Determine whether the operand is a register def.
1879 if (MO.isReg() && MO.isDef() && MO.getReg() && MO.getReg().isPhysical() &&
1880 !IgnoreSPAlias(MO.getReg())) {
1881 // Remove ranges of all aliased registers.
1882 for (MCRegAliasIterator RAI(MO.getReg(), TRI, true); RAI.isValid(); ++RAI)
1883 // FIXME: Can we break out of this loop early if no insertion occurs?
1884 DeadRegs.insert(*RAI);
1885 } else if (MO.isRegMask()) {
1886 RegMasks.push_back(MO.getRegMask());
1887 RegMaskPtrs.push_back(&MO);
1888 }
1889 }
1890
1891 // Tell MLocTracker about all definitions, of regmasks and otherwise.
1892 for (uint32_t DeadReg : DeadRegs)
1893 MTracker->defReg(DeadReg, CurBB, CurInst);
1894
1895 for (const auto *MO : RegMaskPtrs)
1896 MTracker->writeRegMask(MO, CurBB, CurInst);
1897
1898 // If this instruction writes to a spill slot, def that slot.
1899 if (hasFoldedStackStore(MI)) {
1900 if (std::optional<SpillLocationNo> SpillNo =
1901 extractSpillBaseRegAndOffset(MI)) {
1902 for (unsigned int I = 0; I < MTracker->NumSlotIdxes; ++I) {
1903 unsigned SpillID = MTracker->getSpillIDWithIdx(*SpillNo, I);
1904 LocIdx L = MTracker->getSpillMLoc(SpillID);
1905 MTracker->setMLoc(L, ValueIDNum(CurBB, CurInst, L));
1906 }
1907 }
1908 }
1909
1910 if (!TTracker)
1911 return;
1912
1913 // When committing variable values to locations: tell transfer tracker that
1914 // we've clobbered things. It may be able to recover the variable from a
1915 // different location.
1916
1917 // Inform TTracker about any direct clobbers.
1918 for (uint32_t DeadReg : DeadRegs) {
1919 LocIdx Loc = MTracker->lookupOrTrackRegister(DeadReg);
1920 TTracker->clobberMloc(Loc, MI.getIterator(), false);
1921 }
1922
1923 // Look for any clobbers performed by a register mask. Only test locations
1924 // that are actually being tracked.
1925 if (!RegMaskPtrs.empty()) {
1926 for (auto L : MTracker->locations()) {
1927 // Stack locations can't be clobbered by regmasks.
1928 if (MTracker->isSpill(L.Idx))
1929 continue;
1930
1931 Register Reg = MTracker->LocIdxToLocID[L.Idx];
1932 if (IgnoreSPAlias(Reg))
1933 continue;
1934
1935 for (const auto *MO : RegMaskPtrs)
1936 if (MO->clobbersPhysReg(Reg))
1937 TTracker->clobberMloc(L.Idx, MI.getIterator(), false);
1938 }
1939 }
1940
1941 // Tell TTracker about any folded stack store.
1942 if (hasFoldedStackStore(MI)) {
1943 if (std::optional<SpillLocationNo> SpillNo =
1944 extractSpillBaseRegAndOffset(MI)) {
1945 for (unsigned int I = 0; I < MTracker->NumSlotIdxes; ++I) {
1946 unsigned SpillID = MTracker->getSpillIDWithIdx(*SpillNo, I);
1947 LocIdx L = MTracker->getSpillMLoc(SpillID);
1948 TTracker->clobberMloc(L, MI.getIterator(), true);
1949 }
1950 }
1951 }
1952 }
1953
performCopy(Register SrcRegNum,Register DstRegNum)1954 void InstrRefBasedLDV::performCopy(Register SrcRegNum, Register DstRegNum) {
1955 // In all circumstances, re-def all aliases. It's definitely a new value now.
1956 for (MCRegAliasIterator RAI(DstRegNum, TRI, true); RAI.isValid(); ++RAI)
1957 MTracker->defReg(*RAI, CurBB, CurInst);
1958
1959 ValueIDNum SrcValue = MTracker->readReg(SrcRegNum);
1960 MTracker->setReg(DstRegNum, SrcValue);
1961
1962 // Copy subregisters from one location to another.
1963 for (MCSubRegIndexIterator SRI(SrcRegNum, TRI); SRI.isValid(); ++SRI) {
1964 unsigned SrcSubReg = SRI.getSubReg();
1965 unsigned SubRegIdx = SRI.getSubRegIndex();
1966 unsigned DstSubReg = TRI->getSubReg(DstRegNum, SubRegIdx);
1967 if (!DstSubReg)
1968 continue;
1969
1970 // Do copy. There are two matching subregisters, the source value should
1971 // have been def'd when the super-reg was, the latter might not be tracked
1972 // yet.
1973 // This will force SrcSubReg to be tracked, if it isn't yet. Will read
1974 // mphi values if it wasn't tracked.
1975 LocIdx SrcL = MTracker->lookupOrTrackRegister(SrcSubReg);
1976 LocIdx DstL = MTracker->lookupOrTrackRegister(DstSubReg);
1977 (void)SrcL;
1978 (void)DstL;
1979 ValueIDNum CpyValue = MTracker->readReg(SrcSubReg);
1980
1981 MTracker->setReg(DstSubReg, CpyValue);
1982 }
1983 }
1984
1985 std::optional<SpillLocationNo>
isSpillInstruction(const MachineInstr & MI,MachineFunction * MF)1986 InstrRefBasedLDV::isSpillInstruction(const MachineInstr &MI,
1987 MachineFunction *MF) {
1988 // TODO: Handle multiple stores folded into one.
1989 if (!MI.hasOneMemOperand())
1990 return std::nullopt;
1991
1992 // Reject any memory operand that's aliased -- we can't guarantee its value.
1993 auto MMOI = MI.memoperands_begin();
1994 const PseudoSourceValue *PVal = (*MMOI)->getPseudoValue();
1995 if (PVal->isAliased(MFI))
1996 return std::nullopt;
1997
1998 if (!MI.getSpillSize(TII) && !MI.getFoldedSpillSize(TII))
1999 return std::nullopt; // This is not a spill instruction, since no valid size
2000 // was returned from either function.
2001
2002 return extractSpillBaseRegAndOffset(MI);
2003 }
2004
isLocationSpill(const MachineInstr & MI,MachineFunction * MF,unsigned & Reg)2005 bool InstrRefBasedLDV::isLocationSpill(const MachineInstr &MI,
2006 MachineFunction *MF, unsigned &Reg) {
2007 if (!isSpillInstruction(MI, MF))
2008 return false;
2009
2010 int FI;
2011 Reg = TII->isStoreToStackSlotPostFE(MI, FI);
2012 return Reg != 0;
2013 }
2014
2015 std::optional<SpillLocationNo>
isRestoreInstruction(const MachineInstr & MI,MachineFunction * MF,unsigned & Reg)2016 InstrRefBasedLDV::isRestoreInstruction(const MachineInstr &MI,
2017 MachineFunction *MF, unsigned &Reg) {
2018 if (!MI.hasOneMemOperand())
2019 return std::nullopt;
2020
2021 // FIXME: Handle folded restore instructions with more than one memory
2022 // operand.
2023 if (MI.getRestoreSize(TII)) {
2024 Reg = MI.getOperand(0).getReg();
2025 return extractSpillBaseRegAndOffset(MI);
2026 }
2027 return std::nullopt;
2028 }
2029
transferSpillOrRestoreInst(MachineInstr & MI)2030 bool InstrRefBasedLDV::transferSpillOrRestoreInst(MachineInstr &MI) {
2031 // XXX -- it's too difficult to implement VarLocBasedImpl's stack location
2032 // limitations under the new model. Therefore, when comparing them, compare
2033 // versions that don't attempt spills or restores at all.
2034 if (EmulateOldLDV)
2035 return false;
2036
2037 // Strictly limit ourselves to plain loads and stores, not all instructions
2038 // that can access the stack.
2039 int DummyFI = -1;
2040 if (!TII->isStoreToStackSlotPostFE(MI, DummyFI) &&
2041 !TII->isLoadFromStackSlotPostFE(MI, DummyFI))
2042 return false;
2043
2044 MachineFunction *MF = MI.getMF();
2045 unsigned Reg;
2046
2047 LLVM_DEBUG(dbgs() << "Examining instruction: "; MI.dump(););
2048
2049 // Strictly limit ourselves to plain loads and stores, not all instructions
2050 // that can access the stack.
2051 int FIDummy;
2052 if (!TII->isStoreToStackSlotPostFE(MI, FIDummy) &&
2053 !TII->isLoadFromStackSlotPostFE(MI, FIDummy))
2054 return false;
2055
2056 // First, if there are any DBG_VALUEs pointing at a spill slot that is
2057 // written to, terminate that variable location. The value in memory
2058 // will have changed. DbgEntityHistoryCalculator doesn't try to detect this.
2059 if (std::optional<SpillLocationNo> Loc = isSpillInstruction(MI, MF)) {
2060 // Un-set this location and clobber, so that earlier locations don't
2061 // continue past this store.
2062 for (unsigned SlotIdx = 0; SlotIdx < MTracker->NumSlotIdxes; ++SlotIdx) {
2063 unsigned SpillID = MTracker->getSpillIDWithIdx(*Loc, SlotIdx);
2064 std::optional<LocIdx> MLoc = MTracker->getSpillMLoc(SpillID);
2065 if (!MLoc)
2066 continue;
2067
2068 // We need to over-write the stack slot with something (here, a def at
2069 // this instruction) to ensure no values are preserved in this stack slot
2070 // after the spill. It also prevents TTracker from trying to recover the
2071 // location and re-installing it in the same place.
2072 ValueIDNum Def(CurBB, CurInst, *MLoc);
2073 MTracker->setMLoc(*MLoc, Def);
2074 if (TTracker)
2075 TTracker->clobberMloc(*MLoc, MI.getIterator());
2076 }
2077 }
2078
2079 // Try to recognise spill and restore instructions that may transfer a value.
2080 if (isLocationSpill(MI, MF, Reg)) {
2081 // isLocationSpill returning true should guarantee we can extract a
2082 // location.
2083 SpillLocationNo Loc = *extractSpillBaseRegAndOffset(MI);
2084
2085 auto DoTransfer = [&](Register SrcReg, unsigned SpillID) {
2086 auto ReadValue = MTracker->readReg(SrcReg);
2087 LocIdx DstLoc = MTracker->getSpillMLoc(SpillID);
2088 MTracker->setMLoc(DstLoc, ReadValue);
2089
2090 if (TTracker) {
2091 LocIdx SrcLoc = MTracker->getRegMLoc(SrcReg);
2092 TTracker->transferMlocs(SrcLoc, DstLoc, MI.getIterator());
2093 }
2094 };
2095
2096 // Then, transfer subreg bits.
2097 for (MCPhysReg SR : TRI->subregs(Reg)) {
2098 // Ensure this reg is tracked,
2099 (void)MTracker->lookupOrTrackRegister(SR);
2100 unsigned SubregIdx = TRI->getSubRegIndex(Reg, SR);
2101 unsigned SpillID = MTracker->getLocID(Loc, SubregIdx);
2102 DoTransfer(SR, SpillID);
2103 }
2104
2105 // Directly lookup size of main source reg, and transfer.
2106 unsigned Size = TRI->getRegSizeInBits(Reg, *MRI);
2107 unsigned SpillID = MTracker->getLocID(Loc, {Size, 0});
2108 DoTransfer(Reg, SpillID);
2109 } else {
2110 std::optional<SpillLocationNo> Loc = isRestoreInstruction(MI, MF, Reg);
2111 if (!Loc)
2112 return false;
2113
2114 // Assumption: we're reading from the base of the stack slot, not some
2115 // offset into it. It seems very unlikely LLVM would ever generate
2116 // restores where this wasn't true. This then becomes a question of what
2117 // subregisters in the destination register line up with positions in the
2118 // stack slot.
2119
2120 // Def all registers that alias the destination.
2121 for (MCRegAliasIterator RAI(Reg, TRI, true); RAI.isValid(); ++RAI)
2122 MTracker->defReg(*RAI, CurBB, CurInst);
2123
2124 // Now find subregisters within the destination register, and load values
2125 // from stack slot positions.
2126 auto DoTransfer = [&](Register DestReg, unsigned SpillID) {
2127 LocIdx SrcIdx = MTracker->getSpillMLoc(SpillID);
2128 auto ReadValue = MTracker->readMLoc(SrcIdx);
2129 MTracker->setReg(DestReg, ReadValue);
2130 };
2131
2132 for (MCPhysReg SR : TRI->subregs(Reg)) {
2133 unsigned Subreg = TRI->getSubRegIndex(Reg, SR);
2134 unsigned SpillID = MTracker->getLocID(*Loc, Subreg);
2135 DoTransfer(SR, SpillID);
2136 }
2137
2138 // Directly look up this registers slot idx by size, and transfer.
2139 unsigned Size = TRI->getRegSizeInBits(Reg, *MRI);
2140 unsigned SpillID = MTracker->getLocID(*Loc, {Size, 0});
2141 DoTransfer(Reg, SpillID);
2142 }
2143 return true;
2144 }
2145
transferRegisterCopy(MachineInstr & MI)2146 bool InstrRefBasedLDV::transferRegisterCopy(MachineInstr &MI) {
2147 auto DestSrc = TII->isCopyLikeInstr(MI);
2148 if (!DestSrc)
2149 return false;
2150
2151 const MachineOperand *DestRegOp = DestSrc->Destination;
2152 const MachineOperand *SrcRegOp = DestSrc->Source;
2153
2154 Register SrcReg = SrcRegOp->getReg();
2155 Register DestReg = DestRegOp->getReg();
2156
2157 // Ignore identity copies. Yep, these make it as far as LiveDebugValues.
2158 if (SrcReg == DestReg)
2159 return true;
2160
2161 // For emulating VarLocBasedImpl:
2162 // We want to recognize instructions where destination register is callee
2163 // saved register. If register that could be clobbered by the call is
2164 // included, there would be a great chance that it is going to be clobbered
2165 // soon. It is more likely that previous register, which is callee saved, is
2166 // going to stay unclobbered longer, even if it is killed.
2167 //
2168 // For InstrRefBasedImpl, we can track multiple locations per value, so
2169 // ignore this condition.
2170 if (EmulateOldLDV && !isCalleeSavedReg(DestReg))
2171 return false;
2172
2173 // InstrRefBasedImpl only followed killing copies.
2174 if (EmulateOldLDV && !SrcRegOp->isKill())
2175 return false;
2176
2177 // Before we update MTracker, remember which values were present in each of
2178 // the locations about to be overwritten, so that we can recover any
2179 // potentially clobbered variables.
2180 DenseMap<LocIdx, ValueIDNum> ClobberedLocs;
2181 if (TTracker) {
2182 for (MCRegAliasIterator RAI(DestReg, TRI, true); RAI.isValid(); ++RAI) {
2183 LocIdx ClobberedLoc = MTracker->getRegMLoc(*RAI);
2184 auto MLocIt = TTracker->ActiveMLocs.find(ClobberedLoc);
2185 // If ActiveMLocs isn't tracking this location or there are no variables
2186 // using it, don't bother remembering.
2187 if (MLocIt == TTracker->ActiveMLocs.end() || MLocIt->second.empty())
2188 continue;
2189 ValueIDNum Value = MTracker->readReg(*RAI);
2190 ClobberedLocs[ClobberedLoc] = Value;
2191 }
2192 }
2193
2194 // Copy MTracker info, including subregs if available.
2195 InstrRefBasedLDV::performCopy(SrcReg, DestReg);
2196
2197 // The copy might have clobbered variables based on the destination register.
2198 // Tell TTracker about it, passing the old ValueIDNum to search for
2199 // alternative locations (or else terminating those variables).
2200 if (TTracker) {
2201 for (auto LocVal : ClobberedLocs) {
2202 TTracker->clobberMloc(LocVal.first, LocVal.second, MI.getIterator(), false);
2203 }
2204 }
2205
2206 // Only produce a transfer of DBG_VALUE within a block where old LDV
2207 // would have. We might make use of the additional value tracking in some
2208 // other way, later.
2209 if (TTracker && isCalleeSavedReg(DestReg) && SrcRegOp->isKill())
2210 TTracker->transferMlocs(MTracker->getRegMLoc(SrcReg),
2211 MTracker->getRegMLoc(DestReg), MI.getIterator());
2212
2213 // VarLocBasedImpl would quit tracking the old location after copying.
2214 if (EmulateOldLDV && SrcReg != DestReg)
2215 MTracker->defReg(SrcReg, CurBB, CurInst);
2216
2217 return true;
2218 }
2219
2220 /// Accumulate a mapping between each DILocalVariable fragment and other
2221 /// fragments of that DILocalVariable which overlap. This reduces work during
2222 /// the data-flow stage from "Find any overlapping fragments" to "Check if the
2223 /// known-to-overlap fragments are present".
2224 /// \param MI A previously unprocessed debug instruction to analyze for
2225 /// fragment usage.
accumulateFragmentMap(MachineInstr & MI)2226 void InstrRefBasedLDV::accumulateFragmentMap(MachineInstr &MI) {
2227 assert(MI.isDebugValueLike());
2228 DebugVariable MIVar(MI.getDebugVariable(), MI.getDebugExpression(),
2229 MI.getDebugLoc()->getInlinedAt());
2230 FragmentInfo ThisFragment = MIVar.getFragmentOrDefault();
2231
2232 // If this is the first sighting of this variable, then we are guaranteed
2233 // there are currently no overlapping fragments either. Initialize the set
2234 // of seen fragments, record no overlaps for the current one, and return.
2235 auto SeenIt = SeenFragments.find(MIVar.getVariable());
2236 if (SeenIt == SeenFragments.end()) {
2237 SmallSet<FragmentInfo, 4> OneFragment;
2238 OneFragment.insert(ThisFragment);
2239 SeenFragments.insert({MIVar.getVariable(), OneFragment});
2240
2241 OverlapFragments.insert({{MIVar.getVariable(), ThisFragment}, {}});
2242 return;
2243 }
2244
2245 // If this particular Variable/Fragment pair already exists in the overlap
2246 // map, it has already been accounted for.
2247 auto IsInOLapMap =
2248 OverlapFragments.insert({{MIVar.getVariable(), ThisFragment}, {}});
2249 if (!IsInOLapMap.second)
2250 return;
2251
2252 auto &ThisFragmentsOverlaps = IsInOLapMap.first->second;
2253 auto &AllSeenFragments = SeenIt->second;
2254
2255 // Otherwise, examine all other seen fragments for this variable, with "this"
2256 // fragment being a previously unseen fragment. Record any pair of
2257 // overlapping fragments.
2258 for (const auto &ASeenFragment : AllSeenFragments) {
2259 // Does this previously seen fragment overlap?
2260 if (DIExpression::fragmentsOverlap(ThisFragment, ASeenFragment)) {
2261 // Yes: Mark the current fragment as being overlapped.
2262 ThisFragmentsOverlaps.push_back(ASeenFragment);
2263 // Mark the previously seen fragment as being overlapped by the current
2264 // one.
2265 auto ASeenFragmentsOverlaps =
2266 OverlapFragments.find({MIVar.getVariable(), ASeenFragment});
2267 assert(ASeenFragmentsOverlaps != OverlapFragments.end() &&
2268 "Previously seen var fragment has no vector of overlaps");
2269 ASeenFragmentsOverlaps->second.push_back(ThisFragment);
2270 }
2271 }
2272
2273 AllSeenFragments.insert(ThisFragment);
2274 }
2275
process(MachineInstr & MI,const FuncValueTable * MLiveOuts,const FuncValueTable * MLiveIns)2276 void InstrRefBasedLDV::process(MachineInstr &MI,
2277 const FuncValueTable *MLiveOuts,
2278 const FuncValueTable *MLiveIns) {
2279 // Try to interpret an MI as a debug or transfer instruction. Only if it's
2280 // none of these should we interpret it's register defs as new value
2281 // definitions.
2282 if (transferDebugValue(MI))
2283 return;
2284 if (transferDebugInstrRef(MI, MLiveOuts, MLiveIns))
2285 return;
2286 if (transferDebugPHI(MI))
2287 return;
2288 if (transferRegisterCopy(MI))
2289 return;
2290 if (transferSpillOrRestoreInst(MI))
2291 return;
2292 transferRegisterDef(MI);
2293 }
2294
produceMLocTransferFunction(MachineFunction & MF,SmallVectorImpl<MLocTransferMap> & MLocTransfer,unsigned MaxNumBlocks)2295 void InstrRefBasedLDV::produceMLocTransferFunction(
2296 MachineFunction &MF, SmallVectorImpl<MLocTransferMap> &MLocTransfer,
2297 unsigned MaxNumBlocks) {
2298 // Because we try to optimize around register mask operands by ignoring regs
2299 // that aren't currently tracked, we set up something ugly for later: RegMask
2300 // operands that are seen earlier than the first use of a register, still need
2301 // to clobber that register in the transfer function. But this information
2302 // isn't actively recorded. Instead, we track each RegMask used in each block,
2303 // and accumulated the clobbered but untracked registers in each block into
2304 // the following bitvector. Later, if new values are tracked, we can add
2305 // appropriate clobbers.
2306 SmallVector<BitVector, 32> BlockMasks;
2307 BlockMasks.resize(MaxNumBlocks);
2308
2309 // Reserve one bit per register for the masks described above.
2310 unsigned BVWords = MachineOperand::getRegMaskSize(TRI->getNumRegs());
2311 for (auto &BV : BlockMasks)
2312 BV.resize(TRI->getNumRegs(), true);
2313
2314 // Step through all instructions and inhale the transfer function.
2315 for (auto &MBB : MF) {
2316 // Object fields that are read by trackers to know where we are in the
2317 // function.
2318 CurBB = MBB.getNumber();
2319 CurInst = 1;
2320
2321 // Set all machine locations to a PHI value. For transfer function
2322 // production only, this signifies the live-in value to the block.
2323 MTracker->reset();
2324 MTracker->setMPhis(CurBB);
2325
2326 // Step through each instruction in this block.
2327 for (auto &MI : MBB) {
2328 // Pass in an empty unique_ptr for the value tables when accumulating the
2329 // machine transfer function.
2330 process(MI, nullptr, nullptr);
2331
2332 // Also accumulate fragment map.
2333 if (MI.isDebugValueLike())
2334 accumulateFragmentMap(MI);
2335
2336 // Create a map from the instruction number (if present) to the
2337 // MachineInstr and its position.
2338 if (uint64_t InstrNo = MI.peekDebugInstrNum()) {
2339 auto InstrAndPos = std::make_pair(&MI, CurInst);
2340 auto InsertResult =
2341 DebugInstrNumToInstr.insert(std::make_pair(InstrNo, InstrAndPos));
2342
2343 // There should never be duplicate instruction numbers.
2344 assert(InsertResult.second);
2345 (void)InsertResult;
2346 }
2347
2348 ++CurInst;
2349 }
2350
2351 // Produce the transfer function, a map of machine location to new value. If
2352 // any machine location has the live-in phi value from the start of the
2353 // block, it's live-through and doesn't need recording in the transfer
2354 // function.
2355 for (auto Location : MTracker->locations()) {
2356 LocIdx Idx = Location.Idx;
2357 ValueIDNum &P = Location.Value;
2358 if (P.isPHI() && P.getLoc() == Idx.asU64())
2359 continue;
2360
2361 // Insert-or-update.
2362 auto &TransferMap = MLocTransfer[CurBB];
2363 auto Result = TransferMap.insert(std::make_pair(Idx.asU64(), P));
2364 if (!Result.second)
2365 Result.first->second = P;
2366 }
2367
2368 // Accumulate any bitmask operands into the clobbered reg mask for this
2369 // block.
2370 for (auto &P : MTracker->Masks) {
2371 BlockMasks[CurBB].clearBitsNotInMask(P.first->getRegMask(), BVWords);
2372 }
2373 }
2374
2375 // Compute a bitvector of all the registers that are tracked in this block.
2376 BitVector UsedRegs(TRI->getNumRegs());
2377 for (auto Location : MTracker->locations()) {
2378 unsigned ID = MTracker->LocIdxToLocID[Location.Idx];
2379 // Ignore stack slots, and aliases of the stack pointer.
2380 if (ID >= TRI->getNumRegs() || MTracker->SPAliases.count(ID))
2381 continue;
2382 UsedRegs.set(ID);
2383 }
2384
2385 // Check that any regmask-clobber of a register that gets tracked, is not
2386 // live-through in the transfer function. It needs to be clobbered at the
2387 // very least.
2388 for (unsigned int I = 0; I < MaxNumBlocks; ++I) {
2389 BitVector &BV = BlockMasks[I];
2390 BV.flip();
2391 BV &= UsedRegs;
2392 // This produces all the bits that we clobber, but also use. Check that
2393 // they're all clobbered or at least set in the designated transfer
2394 // elem.
2395 for (unsigned Bit : BV.set_bits()) {
2396 unsigned ID = MTracker->getLocID(Bit);
2397 LocIdx Idx = MTracker->LocIDToLocIdx[ID];
2398 auto &TransferMap = MLocTransfer[I];
2399
2400 // Install a value representing the fact that this location is effectively
2401 // written to in this block. As there's no reserved value, instead use
2402 // a value number that is never generated. Pick the value number for the
2403 // first instruction in the block, def'ing this location, which we know
2404 // this block never used anyway.
2405 ValueIDNum NotGeneratedNum = ValueIDNum(I, 1, Idx);
2406 auto Result =
2407 TransferMap.insert(std::make_pair(Idx.asU64(), NotGeneratedNum));
2408 if (!Result.second) {
2409 ValueIDNum &ValueID = Result.first->second;
2410 if (ValueID.getBlock() == I && ValueID.isPHI())
2411 // It was left as live-through. Set it to clobbered.
2412 ValueID = NotGeneratedNum;
2413 }
2414 }
2415 }
2416 }
2417
mlocJoin(MachineBasicBlock & MBB,SmallPtrSet<const MachineBasicBlock *,16> & Visited,FuncValueTable & OutLocs,ValueTable & InLocs)2418 bool InstrRefBasedLDV::mlocJoin(
2419 MachineBasicBlock &MBB, SmallPtrSet<const MachineBasicBlock *, 16> &Visited,
2420 FuncValueTable &OutLocs, ValueTable &InLocs) {
2421 LLVM_DEBUG(dbgs() << "join MBB: " << MBB.getNumber() << "\n");
2422 bool Changed = false;
2423
2424 // Handle value-propagation when control flow merges on entry to a block. For
2425 // any location without a PHI already placed, the location has the same value
2426 // as its predecessors. If a PHI is placed, test to see whether it's now a
2427 // redundant PHI that we can eliminate.
2428
2429 SmallVector<const MachineBasicBlock *, 8> BlockOrders;
2430 for (auto *Pred : MBB.predecessors())
2431 BlockOrders.push_back(Pred);
2432
2433 // Visit predecessors in RPOT order.
2434 auto Cmp = [&](const MachineBasicBlock *A, const MachineBasicBlock *B) {
2435 return BBToOrder.find(A)->second < BBToOrder.find(B)->second;
2436 };
2437 llvm::sort(BlockOrders, Cmp);
2438
2439 // Skip entry block.
2440 if (BlockOrders.size() == 0) {
2441 // FIXME: We don't use assert here to prevent instr-ref-unreachable.mir
2442 // failing.
2443 LLVM_DEBUG(if (!MBB.isEntryBlock()) dbgs()
2444 << "Found not reachable block " << MBB.getFullName()
2445 << " from entry which may lead out of "
2446 "bound access to VarLocs\n");
2447 return false;
2448 }
2449
2450 // Step through all machine locations, look at each predecessor and test
2451 // whether we can eliminate redundant PHIs.
2452 for (auto Location : MTracker->locations()) {
2453 LocIdx Idx = Location.Idx;
2454
2455 // Pick out the first predecessors live-out value for this location. It's
2456 // guaranteed to not be a backedge, as we order by RPO.
2457 ValueIDNum FirstVal = OutLocs[*BlockOrders[0]][Idx.asU64()];
2458
2459 // If we've already eliminated a PHI here, do no further checking, just
2460 // propagate the first live-in value into this block.
2461 if (InLocs[Idx.asU64()] != ValueIDNum(MBB.getNumber(), 0, Idx)) {
2462 if (InLocs[Idx.asU64()] != FirstVal) {
2463 InLocs[Idx.asU64()] = FirstVal;
2464 Changed |= true;
2465 }
2466 continue;
2467 }
2468
2469 // We're now examining a PHI to see whether it's un-necessary. Loop around
2470 // the other live-in values and test whether they're all the same.
2471 bool Disagree = false;
2472 for (unsigned int I = 1; I < BlockOrders.size(); ++I) {
2473 const MachineBasicBlock *PredMBB = BlockOrders[I];
2474 const ValueIDNum &PredLiveOut = OutLocs[*PredMBB][Idx.asU64()];
2475
2476 // Incoming values agree, continue trying to eliminate this PHI.
2477 if (FirstVal == PredLiveOut)
2478 continue;
2479
2480 // We can also accept a PHI value that feeds back into itself.
2481 if (PredLiveOut == ValueIDNum(MBB.getNumber(), 0, Idx))
2482 continue;
2483
2484 // Live-out of a predecessor disagrees with the first predecessor.
2485 Disagree = true;
2486 }
2487
2488 // No disagreement? No PHI. Otherwise, leave the PHI in live-ins.
2489 if (!Disagree) {
2490 InLocs[Idx.asU64()] = FirstVal;
2491 Changed |= true;
2492 }
2493 }
2494
2495 // TODO: Reimplement NumInserted and NumRemoved.
2496 return Changed;
2497 }
2498
findStackIndexInterference(SmallVectorImpl<unsigned> & Slots)2499 void InstrRefBasedLDV::findStackIndexInterference(
2500 SmallVectorImpl<unsigned> &Slots) {
2501 // We could spend a bit of time finding the exact, minimal, set of stack
2502 // indexes that interfere with each other, much like reg units. Or, we can
2503 // rely on the fact that:
2504 // * The smallest / lowest index will interfere with everything at zero
2505 // offset, which will be the largest set of registers,
2506 // * Most indexes with non-zero offset will end up being interference units
2507 // anyway.
2508 // So just pick those out and return them.
2509
2510 // We can rely on a single-byte stack index existing already, because we
2511 // initialize them in MLocTracker.
2512 auto It = MTracker->StackSlotIdxes.find({8, 0});
2513 assert(It != MTracker->StackSlotIdxes.end());
2514 Slots.push_back(It->second);
2515
2516 // Find anything that has a non-zero offset and add that too.
2517 for (auto &Pair : MTracker->StackSlotIdxes) {
2518 // Is offset zero? If so, ignore.
2519 if (!Pair.first.second)
2520 continue;
2521 Slots.push_back(Pair.second);
2522 }
2523 }
2524
placeMLocPHIs(MachineFunction & MF,SmallPtrSetImpl<MachineBasicBlock * > & AllBlocks,FuncValueTable & MInLocs,SmallVectorImpl<MLocTransferMap> & MLocTransfer)2525 void InstrRefBasedLDV::placeMLocPHIs(
2526 MachineFunction &MF, SmallPtrSetImpl<MachineBasicBlock *> &AllBlocks,
2527 FuncValueTable &MInLocs, SmallVectorImpl<MLocTransferMap> &MLocTransfer) {
2528 SmallVector<unsigned, 4> StackUnits;
2529 findStackIndexInterference(StackUnits);
2530
2531 // To avoid repeatedly running the PHI placement algorithm, leverage the
2532 // fact that a def of register MUST also def its register units. Find the
2533 // units for registers, place PHIs for them, and then replicate them for
2534 // aliasing registers. Some inputs that are never def'd (DBG_PHIs of
2535 // arguments) don't lead to register units being tracked, just place PHIs for
2536 // those registers directly. Stack slots have their own form of "unit",
2537 // store them to one side.
2538 SmallSet<Register, 32> RegUnitsToPHIUp;
2539 SmallSet<LocIdx, 32> NormalLocsToPHI;
2540 SmallSet<SpillLocationNo, 32> StackSlots;
2541 for (auto Location : MTracker->locations()) {
2542 LocIdx L = Location.Idx;
2543 if (MTracker->isSpill(L)) {
2544 StackSlots.insert(MTracker->locIDToSpill(MTracker->LocIdxToLocID[L]));
2545 continue;
2546 }
2547
2548 Register R = MTracker->LocIdxToLocID[L];
2549 SmallSet<Register, 8> FoundRegUnits;
2550 bool AnyIllegal = false;
2551 for (MCRegUnit Unit : TRI->regunits(R.asMCReg())) {
2552 for (MCRegUnitRootIterator URoot(Unit, TRI); URoot.isValid(); ++URoot) {
2553 if (!MTracker->isRegisterTracked(*URoot)) {
2554 // Not all roots were loaded into the tracking map: this register
2555 // isn't actually def'd anywhere, we only read from it. Generate PHIs
2556 // for this reg, but don't iterate units.
2557 AnyIllegal = true;
2558 } else {
2559 FoundRegUnits.insert(*URoot);
2560 }
2561 }
2562 }
2563
2564 if (AnyIllegal) {
2565 NormalLocsToPHI.insert(L);
2566 continue;
2567 }
2568
2569 RegUnitsToPHIUp.insert(FoundRegUnits.begin(), FoundRegUnits.end());
2570 }
2571
2572 // Lambda to fetch PHIs for a given location, and write into the PHIBlocks
2573 // collection.
2574 SmallVector<MachineBasicBlock *, 32> PHIBlocks;
2575 auto CollectPHIsForLoc = [&](LocIdx L) {
2576 // Collect the set of defs.
2577 SmallPtrSet<MachineBasicBlock *, 32> DefBlocks;
2578 for (unsigned int I = 0; I < OrderToBB.size(); ++I) {
2579 MachineBasicBlock *MBB = OrderToBB[I];
2580 const auto &TransferFunc = MLocTransfer[MBB->getNumber()];
2581 if (TransferFunc.contains(L))
2582 DefBlocks.insert(MBB);
2583 }
2584
2585 // The entry block defs the location too: it's the live-in / argument value.
2586 // Only insert if there are other defs though; everything is trivially live
2587 // through otherwise.
2588 if (!DefBlocks.empty())
2589 DefBlocks.insert(&*MF.begin());
2590
2591 // Ask the SSA construction algorithm where we should put PHIs. Clear
2592 // anything that might have been hanging around from earlier.
2593 PHIBlocks.clear();
2594 BlockPHIPlacement(AllBlocks, DefBlocks, PHIBlocks);
2595 };
2596
2597 auto InstallPHIsAtLoc = [&PHIBlocks, &MInLocs](LocIdx L) {
2598 for (const MachineBasicBlock *MBB : PHIBlocks)
2599 MInLocs[*MBB][L.asU64()] = ValueIDNum(MBB->getNumber(), 0, L);
2600 };
2601
2602 // For locations with no reg units, just place PHIs.
2603 for (LocIdx L : NormalLocsToPHI) {
2604 CollectPHIsForLoc(L);
2605 // Install those PHI values into the live-in value array.
2606 InstallPHIsAtLoc(L);
2607 }
2608
2609 // For stack slots, calculate PHIs for the equivalent of the units, then
2610 // install for each index.
2611 for (SpillLocationNo Slot : StackSlots) {
2612 for (unsigned Idx : StackUnits) {
2613 unsigned SpillID = MTracker->getSpillIDWithIdx(Slot, Idx);
2614 LocIdx L = MTracker->getSpillMLoc(SpillID);
2615 CollectPHIsForLoc(L);
2616 InstallPHIsAtLoc(L);
2617
2618 // Find anything that aliases this stack index, install PHIs for it too.
2619 unsigned Size, Offset;
2620 std::tie(Size, Offset) = MTracker->StackIdxesToPos[Idx];
2621 for (auto &Pair : MTracker->StackSlotIdxes) {
2622 unsigned ThisSize, ThisOffset;
2623 std::tie(ThisSize, ThisOffset) = Pair.first;
2624 if (ThisSize + ThisOffset <= Offset || Size + Offset <= ThisOffset)
2625 continue;
2626
2627 unsigned ThisID = MTracker->getSpillIDWithIdx(Slot, Pair.second);
2628 LocIdx ThisL = MTracker->getSpillMLoc(ThisID);
2629 InstallPHIsAtLoc(ThisL);
2630 }
2631 }
2632 }
2633
2634 // For reg units, place PHIs, and then place them for any aliasing registers.
2635 for (Register R : RegUnitsToPHIUp) {
2636 LocIdx L = MTracker->lookupOrTrackRegister(R);
2637 CollectPHIsForLoc(L);
2638
2639 // Install those PHI values into the live-in value array.
2640 InstallPHIsAtLoc(L);
2641
2642 // Now find aliases and install PHIs for those.
2643 for (MCRegAliasIterator RAI(R, TRI, true); RAI.isValid(); ++RAI) {
2644 // Super-registers that are "above" the largest register read/written by
2645 // the function will alias, but will not be tracked.
2646 if (!MTracker->isRegisterTracked(*RAI))
2647 continue;
2648
2649 LocIdx AliasLoc = MTracker->lookupOrTrackRegister(*RAI);
2650 InstallPHIsAtLoc(AliasLoc);
2651 }
2652 }
2653 }
2654
buildMLocValueMap(MachineFunction & MF,FuncValueTable & MInLocs,FuncValueTable & MOutLocs,SmallVectorImpl<MLocTransferMap> & MLocTransfer)2655 void InstrRefBasedLDV::buildMLocValueMap(
2656 MachineFunction &MF, FuncValueTable &MInLocs, FuncValueTable &MOutLocs,
2657 SmallVectorImpl<MLocTransferMap> &MLocTransfer) {
2658 std::priority_queue<unsigned int, std::vector<unsigned int>,
2659 std::greater<unsigned int>>
2660 Worklist, Pending;
2661
2662 // We track what is on the current and pending worklist to avoid inserting
2663 // the same thing twice. We could avoid this with a custom priority queue,
2664 // but this is probably not worth it.
2665 SmallPtrSet<MachineBasicBlock *, 16> OnPending, OnWorklist;
2666
2667 // Initialize worklist with every block to be visited. Also produce list of
2668 // all blocks.
2669 SmallPtrSet<MachineBasicBlock *, 32> AllBlocks;
2670 for (unsigned int I = 0; I < BBToOrder.size(); ++I) {
2671 Worklist.push(I);
2672 OnWorklist.insert(OrderToBB[I]);
2673 AllBlocks.insert(OrderToBB[I]);
2674 }
2675
2676 // Initialize entry block to PHIs. These represent arguments.
2677 for (auto Location : MTracker->locations())
2678 MInLocs.tableForEntryMBB()[Location.Idx.asU64()] =
2679 ValueIDNum(0, 0, Location.Idx);
2680
2681 MTracker->reset();
2682
2683 // Start by placing PHIs, using the usual SSA constructor algorithm. Consider
2684 // any machine-location that isn't live-through a block to be def'd in that
2685 // block.
2686 placeMLocPHIs(MF, AllBlocks, MInLocs, MLocTransfer);
2687
2688 // Propagate values to eliminate redundant PHIs. At the same time, this
2689 // produces the table of Block x Location => Value for the entry to each
2690 // block.
2691 // The kind of PHIs we can eliminate are, for example, where one path in a
2692 // conditional spills and restores a register, and the register still has
2693 // the same value once control flow joins, unbeknowns to the PHI placement
2694 // code. Propagating values allows us to identify such un-necessary PHIs and
2695 // remove them.
2696 SmallPtrSet<const MachineBasicBlock *, 16> Visited;
2697 while (!Worklist.empty() || !Pending.empty()) {
2698 // Vector for storing the evaluated block transfer function.
2699 SmallVector<std::pair<LocIdx, ValueIDNum>, 32> ToRemap;
2700
2701 while (!Worklist.empty()) {
2702 MachineBasicBlock *MBB = OrderToBB[Worklist.top()];
2703 CurBB = MBB->getNumber();
2704 Worklist.pop();
2705
2706 // Join the values in all predecessor blocks.
2707 bool InLocsChanged;
2708 InLocsChanged = mlocJoin(*MBB, Visited, MOutLocs, MInLocs[*MBB]);
2709 InLocsChanged |= Visited.insert(MBB).second;
2710
2711 // Don't examine transfer function if we've visited this loc at least
2712 // once, and inlocs haven't changed.
2713 if (!InLocsChanged)
2714 continue;
2715
2716 // Load the current set of live-ins into MLocTracker.
2717 MTracker->loadFromArray(MInLocs[*MBB], CurBB);
2718
2719 // Each element of the transfer function can be a new def, or a read of
2720 // a live-in value. Evaluate each element, and store to "ToRemap".
2721 ToRemap.clear();
2722 for (auto &P : MLocTransfer[CurBB]) {
2723 if (P.second.getBlock() == CurBB && P.second.isPHI()) {
2724 // This is a movement of whatever was live in. Read it.
2725 ValueIDNum NewID = MTracker->readMLoc(P.second.getLoc());
2726 ToRemap.push_back(std::make_pair(P.first, NewID));
2727 } else {
2728 // It's a def. Just set it.
2729 assert(P.second.getBlock() == CurBB);
2730 ToRemap.push_back(std::make_pair(P.first, P.second));
2731 }
2732 }
2733
2734 // Commit the transfer function changes into mloc tracker, which
2735 // transforms the contents of the MLocTracker into the live-outs.
2736 for (auto &P : ToRemap)
2737 MTracker->setMLoc(P.first, P.second);
2738
2739 // Now copy out-locs from mloc tracker into out-loc vector, checking
2740 // whether changes have occurred. These changes can have come from both
2741 // the transfer function, and mlocJoin.
2742 bool OLChanged = false;
2743 for (auto Location : MTracker->locations()) {
2744 OLChanged |= MOutLocs[*MBB][Location.Idx.asU64()] != Location.Value;
2745 MOutLocs[*MBB][Location.Idx.asU64()] = Location.Value;
2746 }
2747
2748 MTracker->reset();
2749
2750 // No need to examine successors again if out-locs didn't change.
2751 if (!OLChanged)
2752 continue;
2753
2754 // All successors should be visited: put any back-edges on the pending
2755 // list for the next pass-through, and any other successors to be
2756 // visited this pass, if they're not going to be already.
2757 for (auto *s : MBB->successors()) {
2758 // Does branching to this successor represent a back-edge?
2759 if (BBToOrder[s] > BBToOrder[MBB]) {
2760 // No: visit it during this dataflow iteration.
2761 if (OnWorklist.insert(s).second)
2762 Worklist.push(BBToOrder[s]);
2763 } else {
2764 // Yes: visit it on the next iteration.
2765 if (OnPending.insert(s).second)
2766 Pending.push(BBToOrder[s]);
2767 }
2768 }
2769 }
2770
2771 Worklist.swap(Pending);
2772 std::swap(OnPending, OnWorklist);
2773 OnPending.clear();
2774 // At this point, pending must be empty, since it was just the empty
2775 // worklist
2776 assert(Pending.empty() && "Pending should be empty");
2777 }
2778
2779 // Once all the live-ins don't change on mlocJoin(), we've eliminated all
2780 // redundant PHIs.
2781 }
2782
BlockPHIPlacement(const SmallPtrSetImpl<MachineBasicBlock * > & AllBlocks,const SmallPtrSetImpl<MachineBasicBlock * > & DefBlocks,SmallVectorImpl<MachineBasicBlock * > & PHIBlocks)2783 void InstrRefBasedLDV::BlockPHIPlacement(
2784 const SmallPtrSetImpl<MachineBasicBlock *> &AllBlocks,
2785 const SmallPtrSetImpl<MachineBasicBlock *> &DefBlocks,
2786 SmallVectorImpl<MachineBasicBlock *> &PHIBlocks) {
2787 // Apply IDF calculator to the designated set of location defs, storing
2788 // required PHIs into PHIBlocks. Uses the dominator tree stored in the
2789 // InstrRefBasedLDV object.
2790 IDFCalculatorBase<MachineBasicBlock, false> IDF(DomTree->getBase());
2791
2792 IDF.setLiveInBlocks(AllBlocks);
2793 IDF.setDefiningBlocks(DefBlocks);
2794 IDF.calculate(PHIBlocks);
2795 }
2796
pickVPHILoc(SmallVectorImpl<DbgOpID> & OutValues,const MachineBasicBlock & MBB,const LiveIdxT & LiveOuts,FuncValueTable & MOutLocs,const SmallVectorImpl<const MachineBasicBlock * > & BlockOrders)2797 bool InstrRefBasedLDV::pickVPHILoc(
2798 SmallVectorImpl<DbgOpID> &OutValues, const MachineBasicBlock &MBB,
2799 const LiveIdxT &LiveOuts, FuncValueTable &MOutLocs,
2800 const SmallVectorImpl<const MachineBasicBlock *> &BlockOrders) {
2801
2802 // No predecessors means no PHIs.
2803 if (BlockOrders.empty())
2804 return false;
2805
2806 // All the location operands that do not already agree need to be joined,
2807 // track the indices of each such location operand here.
2808 SmallDenseSet<unsigned> LocOpsToJoin;
2809
2810 auto FirstValueIt = LiveOuts.find(BlockOrders[0]);
2811 if (FirstValueIt == LiveOuts.end())
2812 return false;
2813 const DbgValue &FirstValue = *FirstValueIt->second;
2814
2815 for (const auto p : BlockOrders) {
2816 auto OutValIt = LiveOuts.find(p);
2817 if (OutValIt == LiveOuts.end())
2818 // If we have a predecessor not in scope, we'll never find a PHI position.
2819 return false;
2820 const DbgValue &OutVal = *OutValIt->second;
2821
2822 // No-values cannot have locations we can join on.
2823 if (OutVal.Kind == DbgValue::NoVal)
2824 return false;
2825
2826 // For unjoined VPHIs where we don't know the location, we definitely
2827 // can't find a join loc unless the VPHI is a backedge.
2828 if (OutVal.isUnjoinedPHI() && OutVal.BlockNo != MBB.getNumber())
2829 return false;
2830
2831 if (!FirstValue.Properties.isJoinable(OutVal.Properties))
2832 return false;
2833
2834 for (unsigned Idx = 0; Idx < FirstValue.getLocationOpCount(); ++Idx) {
2835 // An unjoined PHI has no defined locations, and so a shared location must
2836 // be found for every operand.
2837 if (OutVal.isUnjoinedPHI()) {
2838 LocOpsToJoin.insert(Idx);
2839 continue;
2840 }
2841 DbgOpID FirstValOp = FirstValue.getDbgOpID(Idx);
2842 DbgOpID OutValOp = OutVal.getDbgOpID(Idx);
2843 if (FirstValOp != OutValOp) {
2844 // We can never join constant ops - the ops must either both be equal
2845 // constant ops or non-const ops.
2846 if (FirstValOp.isConst() || OutValOp.isConst())
2847 return false;
2848 else
2849 LocOpsToJoin.insert(Idx);
2850 }
2851 }
2852 }
2853
2854 SmallVector<DbgOpID> NewDbgOps;
2855
2856 for (unsigned Idx = 0; Idx < FirstValue.getLocationOpCount(); ++Idx) {
2857 // If this op doesn't need to be joined because the values agree, use that
2858 // already-agreed value.
2859 if (!LocOpsToJoin.contains(Idx)) {
2860 NewDbgOps.push_back(FirstValue.getDbgOpID(Idx));
2861 continue;
2862 }
2863
2864 std::optional<ValueIDNum> JoinedOpLoc =
2865 pickOperandPHILoc(Idx, MBB, LiveOuts, MOutLocs, BlockOrders);
2866
2867 if (!JoinedOpLoc)
2868 return false;
2869
2870 NewDbgOps.push_back(DbgOpStore.insert(*JoinedOpLoc));
2871 }
2872
2873 OutValues.append(NewDbgOps);
2874 return true;
2875 }
2876
pickOperandPHILoc(unsigned DbgOpIdx,const MachineBasicBlock & MBB,const LiveIdxT & LiveOuts,FuncValueTable & MOutLocs,const SmallVectorImpl<const MachineBasicBlock * > & BlockOrders)2877 std::optional<ValueIDNum> InstrRefBasedLDV::pickOperandPHILoc(
2878 unsigned DbgOpIdx, const MachineBasicBlock &MBB, const LiveIdxT &LiveOuts,
2879 FuncValueTable &MOutLocs,
2880 const SmallVectorImpl<const MachineBasicBlock *> &BlockOrders) {
2881
2882 // Collect a set of locations from predecessor where its live-out value can
2883 // be found.
2884 SmallVector<SmallVector<LocIdx, 4>, 8> Locs;
2885 unsigned NumLocs = MTracker->getNumLocs();
2886
2887 for (const auto p : BlockOrders) {
2888 auto OutValIt = LiveOuts.find(p);
2889 assert(OutValIt != LiveOuts.end());
2890 const DbgValue &OutVal = *OutValIt->second;
2891 DbgOpID OutValOpID = OutVal.getDbgOpID(DbgOpIdx);
2892 DbgOp OutValOp = DbgOpStore.find(OutValOpID);
2893 assert(!OutValOp.IsConst);
2894
2895 // Create new empty vector of locations.
2896 Locs.resize(Locs.size() + 1);
2897
2898 // If the live-in value is a def, find the locations where that value is
2899 // present. Do the same for VPHIs where we know the VPHI value.
2900 if (OutVal.Kind == DbgValue::Def ||
2901 (OutVal.Kind == DbgValue::VPHI && OutVal.BlockNo != MBB.getNumber() &&
2902 !OutValOp.isUndef())) {
2903 ValueIDNum ValToLookFor = OutValOp.ID;
2904 // Search the live-outs of the predecessor for the specified value.
2905 for (unsigned int I = 0; I < NumLocs; ++I) {
2906 if (MOutLocs[*p][I] == ValToLookFor)
2907 Locs.back().push_back(LocIdx(I));
2908 }
2909 } else {
2910 assert(OutVal.Kind == DbgValue::VPHI);
2911 // Otherwise: this is a VPHI on a backedge feeding back into itself, i.e.
2912 // a value that's live-through the whole loop. (It has to be a backedge,
2913 // because a block can't dominate itself). We can accept as a PHI location
2914 // any location where the other predecessors agree, _and_ the machine
2915 // locations feed back into themselves. Therefore, add all self-looping
2916 // machine-value PHI locations.
2917 for (unsigned int I = 0; I < NumLocs; ++I) {
2918 ValueIDNum MPHI(MBB.getNumber(), 0, LocIdx(I));
2919 if (MOutLocs[*p][I] == MPHI)
2920 Locs.back().push_back(LocIdx(I));
2921 }
2922 }
2923 }
2924 // We should have found locations for all predecessors, or returned.
2925 assert(Locs.size() == BlockOrders.size());
2926
2927 // Starting with the first set of locations, take the intersection with
2928 // subsequent sets.
2929 SmallVector<LocIdx, 4> CandidateLocs = Locs[0];
2930 for (unsigned int I = 1; I < Locs.size(); ++I) {
2931 auto &LocVec = Locs[I];
2932 SmallVector<LocIdx, 4> NewCandidates;
2933 std::set_intersection(CandidateLocs.begin(), CandidateLocs.end(),
2934 LocVec.begin(), LocVec.end(), std::inserter(NewCandidates, NewCandidates.begin()));
2935 CandidateLocs = NewCandidates;
2936 }
2937 if (CandidateLocs.empty())
2938 return std::nullopt;
2939
2940 // We now have a set of LocIdxes that contain the right output value in
2941 // each of the predecessors. Pick the lowest; if there's a register loc,
2942 // that'll be it.
2943 LocIdx L = *CandidateLocs.begin();
2944
2945 // Return a PHI-value-number for the found location.
2946 ValueIDNum PHIVal = {(unsigned)MBB.getNumber(), 0, L};
2947 return PHIVal;
2948 }
2949
vlocJoin(MachineBasicBlock & MBB,LiveIdxT & VLOCOutLocs,SmallPtrSet<const MachineBasicBlock *,8> & BlocksToExplore,DbgValue & LiveIn)2950 bool InstrRefBasedLDV::vlocJoin(
2951 MachineBasicBlock &MBB, LiveIdxT &VLOCOutLocs,
2952 SmallPtrSet<const MachineBasicBlock *, 8> &BlocksToExplore,
2953 DbgValue &LiveIn) {
2954 LLVM_DEBUG(dbgs() << "join MBB: " << MBB.getNumber() << "\n");
2955 bool Changed = false;
2956
2957 // Order predecessors by RPOT order, for exploring them in that order.
2958 SmallVector<MachineBasicBlock *, 8> BlockOrders(MBB.predecessors());
2959
2960 auto Cmp = [&](MachineBasicBlock *A, MachineBasicBlock *B) {
2961 return BBToOrder[A] < BBToOrder[B];
2962 };
2963
2964 llvm::sort(BlockOrders, Cmp);
2965
2966 unsigned CurBlockRPONum = BBToOrder[&MBB];
2967
2968 // Collect all the incoming DbgValues for this variable, from predecessor
2969 // live-out values.
2970 SmallVector<InValueT, 8> Values;
2971 bool Bail = false;
2972 int BackEdgesStart = 0;
2973 for (auto *p : BlockOrders) {
2974 // If the predecessor isn't in scope / to be explored, we'll never be
2975 // able to join any locations.
2976 if (!BlocksToExplore.contains(p)) {
2977 Bail = true;
2978 break;
2979 }
2980
2981 // All Live-outs will have been initialized.
2982 DbgValue &OutLoc = *VLOCOutLocs.find(p)->second;
2983
2984 // Keep track of where back-edges begin in the Values vector. Relies on
2985 // BlockOrders being sorted by RPO.
2986 unsigned ThisBBRPONum = BBToOrder[p];
2987 if (ThisBBRPONum < CurBlockRPONum)
2988 ++BackEdgesStart;
2989
2990 Values.push_back(std::make_pair(p, &OutLoc));
2991 }
2992
2993 // If there were no values, or one of the predecessors couldn't have a
2994 // value, then give up immediately. It's not safe to produce a live-in
2995 // value. Leave as whatever it was before.
2996 if (Bail || Values.size() == 0)
2997 return false;
2998
2999 // All (non-entry) blocks have at least one non-backedge predecessor.
3000 // Pick the variable value from the first of these, to compare against
3001 // all others.
3002 const DbgValue &FirstVal = *Values[0].second;
3003
3004 // If the old live-in value is not a PHI then either a) no PHI is needed
3005 // here, or b) we eliminated the PHI that was here. If so, we can just
3006 // propagate in the first parent's incoming value.
3007 if (LiveIn.Kind != DbgValue::VPHI || LiveIn.BlockNo != MBB.getNumber()) {
3008 Changed = LiveIn != FirstVal;
3009 if (Changed)
3010 LiveIn = FirstVal;
3011 return Changed;
3012 }
3013
3014 // Scan for variable values that can never be resolved: if they have
3015 // different DIExpressions, different indirectness, or are mixed constants /
3016 // non-constants.
3017 for (const auto &V : Values) {
3018 if (!V.second->Properties.isJoinable(FirstVal.Properties))
3019 return false;
3020 if (V.second->Kind == DbgValue::NoVal)
3021 return false;
3022 if (!V.second->hasJoinableLocOps(FirstVal))
3023 return false;
3024 }
3025
3026 // Try to eliminate this PHI. Do the incoming values all agree?
3027 bool Disagree = false;
3028 for (auto &V : Values) {
3029 if (*V.second == FirstVal)
3030 continue; // No disagreement.
3031
3032 // If both values are not equal but have equal non-empty IDs then they refer
3033 // to the same value from different sources (e.g. one is VPHI and the other
3034 // is Def), which does not cause disagreement.
3035 if (V.second->hasIdenticalValidLocOps(FirstVal))
3036 continue;
3037
3038 // Eliminate if a backedge feeds a VPHI back into itself.
3039 if (V.second->Kind == DbgValue::VPHI &&
3040 V.second->BlockNo == MBB.getNumber() &&
3041 // Is this a backedge?
3042 std::distance(Values.begin(), &V) >= BackEdgesStart)
3043 continue;
3044
3045 Disagree = true;
3046 }
3047
3048 // No disagreement -> live-through value.
3049 if (!Disagree) {
3050 Changed = LiveIn != FirstVal;
3051 if (Changed)
3052 LiveIn = FirstVal;
3053 return Changed;
3054 } else {
3055 // Otherwise use a VPHI.
3056 DbgValue VPHI(MBB.getNumber(), FirstVal.Properties, DbgValue::VPHI);
3057 Changed = LiveIn != VPHI;
3058 if (Changed)
3059 LiveIn = VPHI;
3060 return Changed;
3061 }
3062 }
3063
getBlocksForScope(const DILocation * DILoc,SmallPtrSetImpl<const MachineBasicBlock * > & BlocksToExplore,const SmallPtrSetImpl<MachineBasicBlock * > & AssignBlocks)3064 void InstrRefBasedLDV::getBlocksForScope(
3065 const DILocation *DILoc,
3066 SmallPtrSetImpl<const MachineBasicBlock *> &BlocksToExplore,
3067 const SmallPtrSetImpl<MachineBasicBlock *> &AssignBlocks) {
3068 // Get the set of "normal" in-lexical-scope blocks.
3069 LS.getMachineBasicBlocks(DILoc, BlocksToExplore);
3070
3071 // VarLoc LiveDebugValues tracks variable locations that are defined in
3072 // blocks not in scope. This is something we could legitimately ignore, but
3073 // lets allow it for now for the sake of coverage.
3074 BlocksToExplore.insert(AssignBlocks.begin(), AssignBlocks.end());
3075
3076 // Storage for artificial blocks we intend to add to BlocksToExplore.
3077 DenseSet<const MachineBasicBlock *> ToAdd;
3078
3079 // To avoid needlessly dropping large volumes of variable locations, propagate
3080 // variables through aritifical blocks, i.e. those that don't have any
3081 // instructions in scope at all. To accurately replicate VarLoc
3082 // LiveDebugValues, this means exploring all artificial successors too.
3083 // Perform a depth-first-search to enumerate those blocks.
3084 for (const auto *MBB : BlocksToExplore) {
3085 // Depth-first-search state: each node is a block and which successor
3086 // we're currently exploring.
3087 SmallVector<std::pair<const MachineBasicBlock *,
3088 MachineBasicBlock::const_succ_iterator>,
3089 8>
3090 DFS;
3091
3092 // Find any artificial successors not already tracked.
3093 for (auto *succ : MBB->successors()) {
3094 if (BlocksToExplore.count(succ))
3095 continue;
3096 if (!ArtificialBlocks.count(succ))
3097 continue;
3098 ToAdd.insert(succ);
3099 DFS.push_back({succ, succ->succ_begin()});
3100 }
3101
3102 // Search all those blocks, depth first.
3103 while (!DFS.empty()) {
3104 const MachineBasicBlock *CurBB = DFS.back().first;
3105 MachineBasicBlock::const_succ_iterator &CurSucc = DFS.back().second;
3106 // Walk back if we've explored this blocks successors to the end.
3107 if (CurSucc == CurBB->succ_end()) {
3108 DFS.pop_back();
3109 continue;
3110 }
3111
3112 // If the current successor is artificial and unexplored, descend into
3113 // it.
3114 if (!ToAdd.count(*CurSucc) && ArtificialBlocks.count(*CurSucc)) {
3115 ToAdd.insert(*CurSucc);
3116 DFS.push_back({*CurSucc, (*CurSucc)->succ_begin()});
3117 continue;
3118 }
3119
3120 ++CurSucc;
3121 }
3122 };
3123
3124 BlocksToExplore.insert(ToAdd.begin(), ToAdd.end());
3125 }
3126
buildVLocValueMap(const DILocation * DILoc,const SmallSet<DebugVariableID,4> & VarsWeCareAbout,SmallPtrSetImpl<MachineBasicBlock * > & AssignBlocks,LiveInsT & Output,FuncValueTable & MOutLocs,FuncValueTable & MInLocs,SmallVectorImpl<VLocTracker> & AllTheVLocs)3127 void InstrRefBasedLDV::buildVLocValueMap(
3128 const DILocation *DILoc,
3129 const SmallSet<DebugVariableID, 4> &VarsWeCareAbout,
3130 SmallPtrSetImpl<MachineBasicBlock *> &AssignBlocks, LiveInsT &Output,
3131 FuncValueTable &MOutLocs, FuncValueTable &MInLocs,
3132 SmallVectorImpl<VLocTracker> &AllTheVLocs) {
3133 // This method is much like buildMLocValueMap: but focuses on a single
3134 // LexicalScope at a time. Pick out a set of blocks and variables that are
3135 // to have their value assignments solved, then run our dataflow algorithm
3136 // until a fixedpoint is reached.
3137 std::priority_queue<unsigned int, std::vector<unsigned int>,
3138 std::greater<unsigned int>>
3139 Worklist, Pending;
3140 SmallPtrSet<MachineBasicBlock *, 16> OnWorklist, OnPending;
3141
3142 // The set of blocks we'll be examining.
3143 SmallPtrSet<const MachineBasicBlock *, 8> BlocksToExplore;
3144
3145 // The order in which to examine them (RPO).
3146 SmallVector<MachineBasicBlock *, 16> BlockOrders;
3147 SmallVector<unsigned, 32> BlockOrderNums;
3148
3149 getBlocksForScope(DILoc, BlocksToExplore, AssignBlocks);
3150
3151 // Single block scope: not interesting! No propagation at all. Note that
3152 // this could probably go above ArtificialBlocks without damage, but
3153 // that then produces output differences from original-live-debug-values,
3154 // which propagates from a single block into many artificial ones.
3155 if (BlocksToExplore.size() == 1)
3156 return;
3157
3158 // Convert a const set to a non-const set. LexicalScopes
3159 // getMachineBasicBlocks returns const MBB pointers, IDF wants mutable ones.
3160 // (Neither of them mutate anything).
3161 SmallPtrSet<MachineBasicBlock *, 8> MutBlocksToExplore;
3162 for (const auto *MBB : BlocksToExplore)
3163 MutBlocksToExplore.insert(const_cast<MachineBasicBlock *>(MBB));
3164
3165 // Picks out relevants blocks RPO order and sort them. Sort their
3166 // order-numbers and map back to MBB pointers later, to avoid repeated
3167 // DenseMap queries during comparisons.
3168 for (const auto *MBB : BlocksToExplore)
3169 BlockOrderNums.push_back(BBToOrder[MBB]);
3170
3171 llvm::sort(BlockOrderNums);
3172 for (unsigned int I : BlockOrderNums)
3173 BlockOrders.push_back(OrderToBB[I]);
3174 BlockOrderNums.clear();
3175 unsigned NumBlocks = BlockOrders.size();
3176
3177 // Allocate some vectors for storing the live ins and live outs. Large.
3178 SmallVector<DbgValue, 32> LiveIns, LiveOuts;
3179 LiveIns.reserve(NumBlocks);
3180 LiveOuts.reserve(NumBlocks);
3181
3182 // Initialize all values to start as NoVals. This signifies "it's live
3183 // through, but we don't know what it is".
3184 DbgValueProperties EmptyProperties(EmptyExpr, false, false);
3185 for (unsigned int I = 0; I < NumBlocks; ++I) {
3186 DbgValue EmptyDbgValue(I, EmptyProperties, DbgValue::NoVal);
3187 LiveIns.push_back(EmptyDbgValue);
3188 LiveOuts.push_back(EmptyDbgValue);
3189 }
3190
3191 // Produce by-MBB indexes of live-in/live-outs, to ease lookup within
3192 // vlocJoin.
3193 LiveIdxT LiveOutIdx, LiveInIdx;
3194 LiveOutIdx.reserve(NumBlocks);
3195 LiveInIdx.reserve(NumBlocks);
3196 for (unsigned I = 0; I < NumBlocks; ++I) {
3197 LiveOutIdx[BlockOrders[I]] = &LiveOuts[I];
3198 LiveInIdx[BlockOrders[I]] = &LiveIns[I];
3199 }
3200
3201 // Loop over each variable and place PHIs for it, then propagate values
3202 // between blocks. This keeps the locality of working on one lexical scope at
3203 // at time, but avoids re-processing variable values because some other
3204 // variable has been assigned.
3205 for (DebugVariableID VarID : VarsWeCareAbout) {
3206 // Re-initialize live-ins and live-outs, to clear the remains of previous
3207 // variables live-ins / live-outs.
3208 for (unsigned int I = 0; I < NumBlocks; ++I) {
3209 DbgValue EmptyDbgValue(I, EmptyProperties, DbgValue::NoVal);
3210 LiveIns[I] = EmptyDbgValue;
3211 LiveOuts[I] = EmptyDbgValue;
3212 }
3213
3214 // Place PHIs for variable values, using the LLVM IDF calculator.
3215 // Collect the set of blocks where variables are def'd.
3216 SmallPtrSet<MachineBasicBlock *, 32> DefBlocks;
3217 for (const MachineBasicBlock *ExpMBB : BlocksToExplore) {
3218 auto &TransferFunc = AllTheVLocs[ExpMBB->getNumber()].Vars;
3219 if (TransferFunc.contains(VarID))
3220 DefBlocks.insert(const_cast<MachineBasicBlock *>(ExpMBB));
3221 }
3222
3223 SmallVector<MachineBasicBlock *, 32> PHIBlocks;
3224
3225 // Request the set of PHIs we should insert for this variable. If there's
3226 // only one value definition, things are very simple.
3227 if (DefBlocks.size() == 1) {
3228 placePHIsForSingleVarDefinition(MutBlocksToExplore, *DefBlocks.begin(),
3229 AllTheVLocs, VarID, Output);
3230 continue;
3231 }
3232
3233 // Otherwise: we need to place PHIs through SSA and propagate values.
3234 BlockPHIPlacement(MutBlocksToExplore, DefBlocks, PHIBlocks);
3235
3236 // Insert PHIs into the per-block live-in tables for this variable.
3237 for (MachineBasicBlock *PHIMBB : PHIBlocks) {
3238 unsigned BlockNo = PHIMBB->getNumber();
3239 DbgValue *LiveIn = LiveInIdx[PHIMBB];
3240 *LiveIn = DbgValue(BlockNo, EmptyProperties, DbgValue::VPHI);
3241 }
3242
3243 for (auto *MBB : BlockOrders) {
3244 Worklist.push(BBToOrder[MBB]);
3245 OnWorklist.insert(MBB);
3246 }
3247
3248 // Iterate over all the blocks we selected, propagating the variables value.
3249 // This loop does two things:
3250 // * Eliminates un-necessary VPHIs in vlocJoin,
3251 // * Evaluates the blocks transfer function (i.e. variable assignments) and
3252 // stores the result to the blocks live-outs.
3253 // Always evaluate the transfer function on the first iteration, and when
3254 // the live-ins change thereafter.
3255 bool FirstTrip = true;
3256 while (!Worklist.empty() || !Pending.empty()) {
3257 while (!Worklist.empty()) {
3258 auto *MBB = OrderToBB[Worklist.top()];
3259 CurBB = MBB->getNumber();
3260 Worklist.pop();
3261
3262 auto LiveInsIt = LiveInIdx.find(MBB);
3263 assert(LiveInsIt != LiveInIdx.end());
3264 DbgValue *LiveIn = LiveInsIt->second;
3265
3266 // Join values from predecessors. Updates LiveInIdx, and writes output
3267 // into JoinedInLocs.
3268 bool InLocsChanged =
3269 vlocJoin(*MBB, LiveOutIdx, BlocksToExplore, *LiveIn);
3270
3271 SmallVector<const MachineBasicBlock *, 8> Preds;
3272 for (const auto *Pred : MBB->predecessors())
3273 Preds.push_back(Pred);
3274
3275 // If this block's live-in value is a VPHI, try to pick a machine-value
3276 // for it. This makes the machine-value available and propagated
3277 // through all blocks by the time value propagation finishes. We can't
3278 // do this any earlier as it needs to read the block live-outs.
3279 if (LiveIn->Kind == DbgValue::VPHI && LiveIn->BlockNo == (int)CurBB) {
3280 // There's a small possibility that on a preceeding path, a VPHI is
3281 // eliminated and transitions from VPHI-with-location to
3282 // live-through-value. As a result, the selected location of any VPHI
3283 // might change, so we need to re-compute it on each iteration.
3284 SmallVector<DbgOpID> JoinedOps;
3285
3286 if (pickVPHILoc(JoinedOps, *MBB, LiveOutIdx, MOutLocs, Preds)) {
3287 bool NewLocPicked = !equal(LiveIn->getDbgOpIDs(), JoinedOps);
3288 InLocsChanged |= NewLocPicked;
3289 if (NewLocPicked)
3290 LiveIn->setDbgOpIDs(JoinedOps);
3291 }
3292 }
3293
3294 if (!InLocsChanged && !FirstTrip)
3295 continue;
3296
3297 DbgValue *LiveOut = LiveOutIdx[MBB];
3298 bool OLChanged = false;
3299
3300 // Do transfer function.
3301 auto &VTracker = AllTheVLocs[MBB->getNumber()];
3302 auto TransferIt = VTracker.Vars.find(VarID);
3303 if (TransferIt != VTracker.Vars.end()) {
3304 // Erase on empty transfer (DBG_VALUE $noreg).
3305 if (TransferIt->second.Kind == DbgValue::Undef) {
3306 DbgValue NewVal(MBB->getNumber(), EmptyProperties, DbgValue::NoVal);
3307 if (*LiveOut != NewVal) {
3308 *LiveOut = NewVal;
3309 OLChanged = true;
3310 }
3311 } else {
3312 // Insert new variable value; or overwrite.
3313 if (*LiveOut != TransferIt->second) {
3314 *LiveOut = TransferIt->second;
3315 OLChanged = true;
3316 }
3317 }
3318 } else {
3319 // Just copy live-ins to live-outs, for anything not transferred.
3320 if (*LiveOut != *LiveIn) {
3321 *LiveOut = *LiveIn;
3322 OLChanged = true;
3323 }
3324 }
3325
3326 // If no live-out value changed, there's no need to explore further.
3327 if (!OLChanged)
3328 continue;
3329
3330 // We should visit all successors. Ensure we'll visit any non-backedge
3331 // successors during this dataflow iteration; book backedge successors
3332 // to be visited next time around.
3333 for (auto *s : MBB->successors()) {
3334 // Ignore out of scope / not-to-be-explored successors.
3335 if (!LiveInIdx.contains(s))
3336 continue;
3337
3338 if (BBToOrder[s] > BBToOrder[MBB]) {
3339 if (OnWorklist.insert(s).second)
3340 Worklist.push(BBToOrder[s]);
3341 } else if (OnPending.insert(s).second && (FirstTrip || OLChanged)) {
3342 Pending.push(BBToOrder[s]);
3343 }
3344 }
3345 }
3346 Worklist.swap(Pending);
3347 std::swap(OnWorklist, OnPending);
3348 OnPending.clear();
3349 assert(Pending.empty());
3350 FirstTrip = false;
3351 }
3352
3353 // Save live-ins to output vector. Ignore any that are still marked as being
3354 // VPHIs with no location -- those are variables that we know the value of,
3355 // but are not actually available in the register file.
3356 for (auto *MBB : BlockOrders) {
3357 DbgValue *BlockLiveIn = LiveInIdx[MBB];
3358 if (BlockLiveIn->Kind == DbgValue::NoVal)
3359 continue;
3360 if (BlockLiveIn->isUnjoinedPHI())
3361 continue;
3362 if (BlockLiveIn->Kind == DbgValue::VPHI)
3363 BlockLiveIn->Kind = DbgValue::Def;
3364 [[maybe_unused]] auto &[Var, DILoc] = DVMap.lookupDVID(VarID);
3365 assert(BlockLiveIn->Properties.DIExpr->getFragmentInfo() ==
3366 Var.getFragment() &&
3367 "Fragment info missing during value prop");
3368 Output[MBB->getNumber()].push_back(std::make_pair(VarID, *BlockLiveIn));
3369 }
3370 } // Per-variable loop.
3371
3372 BlockOrders.clear();
3373 BlocksToExplore.clear();
3374 }
3375
placePHIsForSingleVarDefinition(const SmallPtrSetImpl<MachineBasicBlock * > & InScopeBlocks,MachineBasicBlock * AssignMBB,SmallVectorImpl<VLocTracker> & AllTheVLocs,DebugVariableID VarID,LiveInsT & Output)3376 void InstrRefBasedLDV::placePHIsForSingleVarDefinition(
3377 const SmallPtrSetImpl<MachineBasicBlock *> &InScopeBlocks,
3378 MachineBasicBlock *AssignMBB, SmallVectorImpl<VLocTracker> &AllTheVLocs,
3379 DebugVariableID VarID, LiveInsT &Output) {
3380 // If there is a single definition of the variable, then working out it's
3381 // value everywhere is very simple: it's every block dominated by the
3382 // definition. At the dominance frontier, the usual algorithm would:
3383 // * Place PHIs,
3384 // * Propagate values into them,
3385 // * Find there's no incoming variable value from the other incoming branches
3386 // of the dominance frontier,
3387 // * Specify there's no variable value in blocks past the frontier.
3388 // This is a common case, hence it's worth special-casing it.
3389
3390 // Pick out the variables value from the block transfer function.
3391 VLocTracker &VLocs = AllTheVLocs[AssignMBB->getNumber()];
3392 auto ValueIt = VLocs.Vars.find(VarID);
3393 const DbgValue &Value = ValueIt->second;
3394
3395 // If it's an explicit assignment of "undef", that means there is no location
3396 // anyway, anywhere.
3397 if (Value.Kind == DbgValue::Undef)
3398 return;
3399
3400 // Assign the variable value to entry to each dominated block that's in scope.
3401 // Skip the definition block -- it's assigned the variable value in the middle
3402 // of the block somewhere.
3403 for (auto *ScopeBlock : InScopeBlocks) {
3404 if (!DomTree->properlyDominates(AssignMBB, ScopeBlock))
3405 continue;
3406
3407 Output[ScopeBlock->getNumber()].push_back({VarID, Value});
3408 }
3409
3410 // All blocks that aren't dominated have no live-in value, thus no variable
3411 // value will be given to them.
3412 }
3413
3414 #if !defined(NDEBUG) || defined(LLVM_ENABLE_DUMP)
dump_mloc_transfer(const MLocTransferMap & mloc_transfer) const3415 void InstrRefBasedLDV::dump_mloc_transfer(
3416 const MLocTransferMap &mloc_transfer) const {
3417 for (const auto &P : mloc_transfer) {
3418 std::string foo = MTracker->LocIdxToName(P.first);
3419 std::string bar = MTracker->IDAsString(P.second);
3420 dbgs() << "Loc " << foo << " --> " << bar << "\n";
3421 }
3422 }
3423 #endif
3424
initialSetup(MachineFunction & MF)3425 void InstrRefBasedLDV::initialSetup(MachineFunction &MF) {
3426 // Build some useful data structures.
3427
3428 LLVMContext &Context = MF.getFunction().getContext();
3429 EmptyExpr = DIExpression::get(Context, {});
3430
3431 auto hasNonArtificialLocation = [](const MachineInstr &MI) -> bool {
3432 if (const DebugLoc &DL = MI.getDebugLoc())
3433 return DL.getLine() != 0;
3434 return false;
3435 };
3436
3437 // Collect a set of all the artificial blocks. Collect the size too, ilist
3438 // size calls are O(n).
3439 unsigned int Size = 0;
3440 for (auto &MBB : MF) {
3441 ++Size;
3442 if (none_of(MBB.instrs(), hasNonArtificialLocation))
3443 ArtificialBlocks.insert(&MBB);
3444 }
3445
3446 // Compute mappings of block <=> RPO order.
3447 ReversePostOrderTraversal<MachineFunction *> RPOT(&MF);
3448 unsigned int RPONumber = 0;
3449 OrderToBB.reserve(Size);
3450 BBToOrder.reserve(Size);
3451 BBNumToRPO.reserve(Size);
3452 auto processMBB = [&](MachineBasicBlock *MBB) {
3453 OrderToBB.push_back(MBB);
3454 BBToOrder[MBB] = RPONumber;
3455 BBNumToRPO[MBB->getNumber()] = RPONumber;
3456 ++RPONumber;
3457 };
3458 for (MachineBasicBlock *MBB : RPOT)
3459 processMBB(MBB);
3460 for (MachineBasicBlock &MBB : MF)
3461 if (!BBToOrder.contains(&MBB))
3462 processMBB(&MBB);
3463
3464 // Order value substitutions by their "source" operand pair, for quick lookup.
3465 llvm::sort(MF.DebugValueSubstitutions);
3466
3467 #ifdef EXPENSIVE_CHECKS
3468 // As an expensive check, test whether there are any duplicate substitution
3469 // sources in the collection.
3470 if (MF.DebugValueSubstitutions.size() > 2) {
3471 for (auto It = MF.DebugValueSubstitutions.begin();
3472 It != std::prev(MF.DebugValueSubstitutions.end()); ++It) {
3473 assert(It->Src != std::next(It)->Src && "Duplicate variable location "
3474 "substitution seen");
3475 }
3476 }
3477 #endif
3478 }
3479
3480 // Produce an "ejection map" for blocks, i.e., what's the highest-numbered
3481 // lexical scope it's used in. When exploring in DFS order and we pass that
3482 // scope, the block can be processed and any tracking information freed.
makeDepthFirstEjectionMap(SmallVectorImpl<unsigned> & EjectionMap,const ScopeToDILocT & ScopeToDILocation,ScopeToAssignBlocksT & ScopeToAssignBlocks)3483 void InstrRefBasedLDV::makeDepthFirstEjectionMap(
3484 SmallVectorImpl<unsigned> &EjectionMap,
3485 const ScopeToDILocT &ScopeToDILocation,
3486 ScopeToAssignBlocksT &ScopeToAssignBlocks) {
3487 SmallPtrSet<const MachineBasicBlock *, 8> BlocksToExplore;
3488 SmallVector<std::pair<LexicalScope *, ssize_t>, 4> WorkStack;
3489 auto *TopScope = LS.getCurrentFunctionScope();
3490
3491 // Unlike lexical scope explorers, we explore in reverse order, to find the
3492 // "last" lexical scope used for each block early.
3493 WorkStack.push_back({TopScope, TopScope->getChildren().size() - 1});
3494
3495 while (!WorkStack.empty()) {
3496 auto &ScopePosition = WorkStack.back();
3497 LexicalScope *WS = ScopePosition.first;
3498 ssize_t ChildNum = ScopePosition.second--;
3499
3500 const SmallVectorImpl<LexicalScope *> &Children = WS->getChildren();
3501 if (ChildNum >= 0) {
3502 // If ChildNum is positive, there are remaining children to explore.
3503 // Push the child and its children-count onto the stack.
3504 auto &ChildScope = Children[ChildNum];
3505 WorkStack.push_back(
3506 std::make_pair(ChildScope, ChildScope->getChildren().size() - 1));
3507 } else {
3508 WorkStack.pop_back();
3509
3510 // We've explored all children and any later blocks: examine all blocks
3511 // in our scope. If they haven't yet had an ejection number set, then
3512 // this scope will be the last to use that block.
3513 auto DILocationIt = ScopeToDILocation.find(WS);
3514 if (DILocationIt != ScopeToDILocation.end()) {
3515 getBlocksForScope(DILocationIt->second, BlocksToExplore,
3516 ScopeToAssignBlocks.find(WS)->second);
3517 for (const auto *MBB : BlocksToExplore) {
3518 unsigned BBNum = MBB->getNumber();
3519 if (EjectionMap[BBNum] == 0)
3520 EjectionMap[BBNum] = WS->getDFSOut();
3521 }
3522
3523 BlocksToExplore.clear();
3524 }
3525 }
3526 }
3527 }
3528
depthFirstVLocAndEmit(unsigned MaxNumBlocks,const ScopeToDILocT & ScopeToDILocation,const ScopeToVarsT & ScopeToVars,ScopeToAssignBlocksT & ScopeToAssignBlocks,LiveInsT & Output,FuncValueTable & MOutLocs,FuncValueTable & MInLocs,SmallVectorImpl<VLocTracker> & AllTheVLocs,MachineFunction & MF,const TargetPassConfig & TPC)3529 bool InstrRefBasedLDV::depthFirstVLocAndEmit(
3530 unsigned MaxNumBlocks, const ScopeToDILocT &ScopeToDILocation,
3531 const ScopeToVarsT &ScopeToVars, ScopeToAssignBlocksT &ScopeToAssignBlocks,
3532 LiveInsT &Output, FuncValueTable &MOutLocs, FuncValueTable &MInLocs,
3533 SmallVectorImpl<VLocTracker> &AllTheVLocs, MachineFunction &MF,
3534 const TargetPassConfig &TPC) {
3535 TTracker =
3536 new TransferTracker(TII, MTracker, MF, DVMap, *TRI, CalleeSavedRegs, TPC);
3537 unsigned NumLocs = MTracker->getNumLocs();
3538 VTracker = nullptr;
3539
3540 // No scopes? No variable locations.
3541 if (!LS.getCurrentFunctionScope())
3542 return false;
3543
3544 // Build map from block number to the last scope that uses the block.
3545 SmallVector<unsigned, 16> EjectionMap;
3546 EjectionMap.resize(MaxNumBlocks, 0);
3547 makeDepthFirstEjectionMap(EjectionMap, ScopeToDILocation,
3548 ScopeToAssignBlocks);
3549
3550 // Helper lambda for ejecting a block -- if nothing is going to use the block,
3551 // we can translate the variable location information into DBG_VALUEs and then
3552 // free all of InstrRefBasedLDV's data structures.
3553 auto EjectBlock = [&](MachineBasicBlock &MBB) -> void {
3554 unsigned BBNum = MBB.getNumber();
3555 AllTheVLocs[BBNum].clear();
3556
3557 // Prime the transfer-tracker, and then step through all the block
3558 // instructions, installing transfers.
3559 MTracker->reset();
3560 MTracker->loadFromArray(MInLocs[MBB], BBNum);
3561 TTracker->loadInlocs(MBB, MInLocs[MBB], DbgOpStore, Output[BBNum], NumLocs);
3562
3563 CurBB = BBNum;
3564 CurInst = 1;
3565 for (auto &MI : MBB) {
3566 process(MI, &MOutLocs, &MInLocs);
3567 TTracker->checkInstForNewValues(CurInst, MI.getIterator());
3568 ++CurInst;
3569 }
3570
3571 // Free machine-location tables for this block.
3572 MInLocs.ejectTableForBlock(MBB);
3573 MOutLocs.ejectTableForBlock(MBB);
3574 // We don't need live-in variable values for this block either.
3575 Output[BBNum].clear();
3576 AllTheVLocs[BBNum].clear();
3577 };
3578
3579 SmallPtrSet<const MachineBasicBlock *, 8> BlocksToExplore;
3580 SmallVector<std::pair<LexicalScope *, ssize_t>, 4> WorkStack;
3581 WorkStack.push_back({LS.getCurrentFunctionScope(), 0});
3582 unsigned HighestDFSIn = 0;
3583
3584 // Proceed to explore in depth first order.
3585 while (!WorkStack.empty()) {
3586 auto &ScopePosition = WorkStack.back();
3587 LexicalScope *WS = ScopePosition.first;
3588 ssize_t ChildNum = ScopePosition.second++;
3589
3590 // We obesrve scopes with children twice here, once descending in, once
3591 // ascending out of the scope nest. Use HighestDFSIn as a ratchet to ensure
3592 // we don't process a scope twice. Additionally, ignore scopes that don't
3593 // have a DILocation -- by proxy, this means we never tracked any variable
3594 // assignments in that scope.
3595 auto DILocIt = ScopeToDILocation.find(WS);
3596 if (HighestDFSIn <= WS->getDFSIn() && DILocIt != ScopeToDILocation.end()) {
3597 const DILocation *DILoc = DILocIt->second;
3598 auto &VarsWeCareAbout = ScopeToVars.find(WS)->second;
3599 auto &BlocksInScope = ScopeToAssignBlocks.find(WS)->second;
3600
3601 buildVLocValueMap(DILoc, VarsWeCareAbout, BlocksInScope, Output, MOutLocs,
3602 MInLocs, AllTheVLocs);
3603 }
3604
3605 HighestDFSIn = std::max(HighestDFSIn, WS->getDFSIn());
3606
3607 // Descend into any scope nests.
3608 const SmallVectorImpl<LexicalScope *> &Children = WS->getChildren();
3609 if (ChildNum < (ssize_t)Children.size()) {
3610 // There are children to explore -- push onto stack and continue.
3611 auto &ChildScope = Children[ChildNum];
3612 WorkStack.push_back(std::make_pair(ChildScope, 0));
3613 } else {
3614 WorkStack.pop_back();
3615
3616 // We've explored a leaf, or have explored all the children of a scope.
3617 // Try to eject any blocks where this is the last scope it's relevant to.
3618 auto DILocationIt = ScopeToDILocation.find(WS);
3619 if (DILocationIt == ScopeToDILocation.end())
3620 continue;
3621
3622 getBlocksForScope(DILocationIt->second, BlocksToExplore,
3623 ScopeToAssignBlocks.find(WS)->second);
3624 for (const auto *MBB : BlocksToExplore)
3625 if (WS->getDFSOut() == EjectionMap[MBB->getNumber()])
3626 EjectBlock(const_cast<MachineBasicBlock &>(*MBB));
3627
3628 BlocksToExplore.clear();
3629 }
3630 }
3631
3632 // Some artificial blocks may not have been ejected, meaning they're not
3633 // connected to an actual legitimate scope. This can technically happen
3634 // with things like the entry block. In theory, we shouldn't need to do
3635 // anything for such out-of-scope blocks, but for the sake of being similar
3636 // to VarLocBasedLDV, eject these too.
3637 for (auto *MBB : ArtificialBlocks)
3638 if (MInLocs.hasTableFor(*MBB))
3639 EjectBlock(*MBB);
3640
3641 return emitTransfers();
3642 }
3643
emitTransfers()3644 bool InstrRefBasedLDV::emitTransfers() {
3645 // Go through all the transfers recorded in the TransferTracker -- this is
3646 // both the live-ins to a block, and any movements of values that happen
3647 // in the middle.
3648 for (auto &P : TTracker->Transfers) {
3649 // We have to insert DBG_VALUEs in a consistent order, otherwise they
3650 // appear in DWARF in different orders. Use the order that they appear
3651 // when walking through each block / each instruction, stored in
3652 // DVMap.
3653 llvm::sort(P.Insts, llvm::less_first());
3654
3655 // Insert either before or after the designated point...
3656 if (P.MBB) {
3657 MachineBasicBlock &MBB = *P.MBB;
3658 for (const auto &Pair : P.Insts)
3659 MBB.insert(P.Pos, Pair.second);
3660 } else {
3661 // Terminators, like tail calls, can clobber things. Don't try and place
3662 // transfers after them.
3663 if (P.Pos->isTerminator())
3664 continue;
3665
3666 MachineBasicBlock &MBB = *P.Pos->getParent();
3667 for (const auto &Pair : P.Insts)
3668 MBB.insertAfterBundle(P.Pos, Pair.second);
3669 }
3670 }
3671
3672 return TTracker->Transfers.size() != 0;
3673 }
3674
3675 /// Calculate the liveness information for the given machine function and
3676 /// extend ranges across basic blocks.
ExtendRanges(MachineFunction & MF,MachineDominatorTree * DomTree,TargetPassConfig * TPC,unsigned InputBBLimit,unsigned InputDbgValLimit)3677 bool InstrRefBasedLDV::ExtendRanges(MachineFunction &MF,
3678 MachineDominatorTree *DomTree,
3679 TargetPassConfig *TPC,
3680 unsigned InputBBLimit,
3681 unsigned InputDbgValLimit) {
3682 // No subprogram means this function contains no debuginfo.
3683 if (!MF.getFunction().getSubprogram())
3684 return false;
3685
3686 LLVM_DEBUG(dbgs() << "\nDebug Range Extension\n");
3687 this->TPC = TPC;
3688
3689 this->DomTree = DomTree;
3690 TRI = MF.getSubtarget().getRegisterInfo();
3691 MRI = &MF.getRegInfo();
3692 TII = MF.getSubtarget().getInstrInfo();
3693 TFI = MF.getSubtarget().getFrameLowering();
3694 TFI->getCalleeSaves(MF, CalleeSavedRegs);
3695 MFI = &MF.getFrameInfo();
3696 LS.initialize(MF);
3697
3698 const auto &STI = MF.getSubtarget();
3699 AdjustsStackInCalls = MFI->adjustsStack() &&
3700 STI.getFrameLowering()->stackProbeFunctionModifiesSP();
3701 if (AdjustsStackInCalls)
3702 StackProbeSymbolName = STI.getTargetLowering()->getStackProbeSymbolName(MF);
3703
3704 MTracker =
3705 new MLocTracker(MF, *TII, *TRI, *MF.getSubtarget().getTargetLowering());
3706 VTracker = nullptr;
3707 TTracker = nullptr;
3708
3709 SmallVector<MLocTransferMap, 32> MLocTransfer;
3710 SmallVector<VLocTracker, 8> vlocs;
3711 LiveInsT SavedLiveIns;
3712
3713 int MaxNumBlocks = -1;
3714 for (auto &MBB : MF)
3715 MaxNumBlocks = std::max(MBB.getNumber(), MaxNumBlocks);
3716 assert(MaxNumBlocks >= 0);
3717 ++MaxNumBlocks;
3718
3719 initialSetup(MF);
3720
3721 MLocTransfer.resize(MaxNumBlocks);
3722 vlocs.resize(MaxNumBlocks, VLocTracker(DVMap, OverlapFragments, EmptyExpr));
3723 SavedLiveIns.resize(MaxNumBlocks);
3724
3725 produceMLocTransferFunction(MF, MLocTransfer, MaxNumBlocks);
3726
3727 // Allocate and initialize two array-of-arrays for the live-in and live-out
3728 // machine values. The outer dimension is the block number; while the inner
3729 // dimension is a LocIdx from MLocTracker.
3730 unsigned NumLocs = MTracker->getNumLocs();
3731 FuncValueTable MOutLocs(MaxNumBlocks, NumLocs);
3732 FuncValueTable MInLocs(MaxNumBlocks, NumLocs);
3733
3734 // Solve the machine value dataflow problem using the MLocTransfer function,
3735 // storing the computed live-ins / live-outs into the array-of-arrays. We use
3736 // both live-ins and live-outs for decision making in the variable value
3737 // dataflow problem.
3738 buildMLocValueMap(MF, MInLocs, MOutLocs, MLocTransfer);
3739
3740 // Patch up debug phi numbers, turning unknown block-live-in values into
3741 // either live-through machine values, or PHIs.
3742 for (auto &DBG_PHI : DebugPHINumToValue) {
3743 // Identify unresolved block-live-ins.
3744 if (!DBG_PHI.ValueRead)
3745 continue;
3746
3747 ValueIDNum &Num = *DBG_PHI.ValueRead;
3748 if (!Num.isPHI())
3749 continue;
3750
3751 unsigned BlockNo = Num.getBlock();
3752 LocIdx LocNo = Num.getLoc();
3753 ValueIDNum ResolvedValue = MInLocs[BlockNo][LocNo.asU64()];
3754 // If there is no resolved value for this live-in then it is not directly
3755 // reachable from the entry block -- model it as a PHI on entry to this
3756 // block, which means we leave the ValueIDNum unchanged.
3757 if (ResolvedValue != ValueIDNum::EmptyValue)
3758 Num = ResolvedValue;
3759 }
3760 // Later, we'll be looking up ranges of instruction numbers.
3761 llvm::sort(DebugPHINumToValue);
3762
3763 // Walk back through each block / instruction, collecting DBG_VALUE
3764 // instructions and recording what machine value their operands refer to.
3765 for (MachineBasicBlock *MBB : OrderToBB) {
3766 CurBB = MBB->getNumber();
3767 VTracker = &vlocs[CurBB];
3768 VTracker->MBB = MBB;
3769 MTracker->loadFromArray(MInLocs[*MBB], CurBB);
3770 CurInst = 1;
3771 for (auto &MI : *MBB) {
3772 process(MI, &MOutLocs, &MInLocs);
3773 ++CurInst;
3774 }
3775 MTracker->reset();
3776 }
3777
3778 // Map from one LexicalScope to all the variables in that scope.
3779 ScopeToVarsT ScopeToVars;
3780
3781 // Map from One lexical scope to all blocks where assignments happen for
3782 // that scope.
3783 ScopeToAssignBlocksT ScopeToAssignBlocks;
3784
3785 // Store map of DILocations that describes scopes.
3786 ScopeToDILocT ScopeToDILocation;
3787
3788 // To mirror old LiveDebugValues, enumerate variables in RPOT order. Otherwise
3789 // the order is unimportant, it just has to be stable.
3790 unsigned VarAssignCount = 0;
3791 for (unsigned int I = 0; I < OrderToBB.size(); ++I) {
3792 auto *MBB = OrderToBB[I];
3793 auto *VTracker = &vlocs[MBB->getNumber()];
3794 // Collect each variable with a DBG_VALUE in this block.
3795 for (auto &idx : VTracker->Vars) {
3796 DebugVariableID VarID = idx.first;
3797 const DILocation *ScopeLoc = VTracker->Scopes[VarID];
3798 assert(ScopeLoc != nullptr);
3799 auto *Scope = LS.findLexicalScope(ScopeLoc);
3800
3801 // No insts in scope -> shouldn't have been recorded.
3802 assert(Scope != nullptr);
3803
3804 ScopeToVars[Scope].insert(VarID);
3805 ScopeToAssignBlocks[Scope].insert(VTracker->MBB);
3806 ScopeToDILocation[Scope] = ScopeLoc;
3807 ++VarAssignCount;
3808 }
3809 }
3810
3811 bool Changed = false;
3812
3813 // If we have an extremely large number of variable assignments and blocks,
3814 // bail out at this point. We've burnt some time doing analysis already,
3815 // however we should cut our losses.
3816 if ((unsigned)MaxNumBlocks > InputBBLimit &&
3817 VarAssignCount > InputDbgValLimit) {
3818 LLVM_DEBUG(dbgs() << "Disabling InstrRefBasedLDV: " << MF.getName()
3819 << " has " << MaxNumBlocks << " basic blocks and "
3820 << VarAssignCount
3821 << " variable assignments, exceeding limits.\n");
3822 } else {
3823 // Optionally, solve the variable value problem and emit to blocks by using
3824 // a lexical-scope-depth search. It should be functionally identical to
3825 // the "else" block of this condition.
3826 Changed = depthFirstVLocAndEmit(
3827 MaxNumBlocks, ScopeToDILocation, ScopeToVars, ScopeToAssignBlocks,
3828 SavedLiveIns, MOutLocs, MInLocs, vlocs, MF, *TPC);
3829 }
3830
3831 delete MTracker;
3832 delete TTracker;
3833 MTracker = nullptr;
3834 VTracker = nullptr;
3835 TTracker = nullptr;
3836
3837 ArtificialBlocks.clear();
3838 OrderToBB.clear();
3839 BBToOrder.clear();
3840 BBNumToRPO.clear();
3841 DebugInstrNumToInstr.clear();
3842 DebugPHINumToValue.clear();
3843 OverlapFragments.clear();
3844 SeenFragments.clear();
3845 SeenDbgPHIs.clear();
3846 DbgOpStore.clear();
3847 DVMap.clear();
3848
3849 return Changed;
3850 }
3851
makeInstrRefBasedLiveDebugValues()3852 LDVImpl *llvm::makeInstrRefBasedLiveDebugValues() {
3853 return new InstrRefBasedLDV();
3854 }
3855
3856 namespace {
3857 class LDVSSABlock;
3858 class LDVSSAUpdater;
3859
3860 // Pick a type to identify incoming block values as we construct SSA. We
3861 // can't use anything more robust than an integer unfortunately, as SSAUpdater
3862 // expects to zero-initialize the type.
3863 typedef uint64_t BlockValueNum;
3864
3865 /// Represents an SSA PHI node for the SSA updater class. Contains the block
3866 /// this PHI is in, the value number it would have, and the expected incoming
3867 /// values from parent blocks.
3868 class LDVSSAPhi {
3869 public:
3870 SmallVector<std::pair<LDVSSABlock *, BlockValueNum>, 4> IncomingValues;
3871 LDVSSABlock *ParentBlock;
3872 BlockValueNum PHIValNum;
LDVSSAPhi(BlockValueNum PHIValNum,LDVSSABlock * ParentBlock)3873 LDVSSAPhi(BlockValueNum PHIValNum, LDVSSABlock *ParentBlock)
3874 : ParentBlock(ParentBlock), PHIValNum(PHIValNum) {}
3875
getParent()3876 LDVSSABlock *getParent() { return ParentBlock; }
3877 };
3878
3879 /// Thin wrapper around a block predecessor iterator. Only difference from a
3880 /// normal block iterator is that it dereferences to an LDVSSABlock.
3881 class LDVSSABlockIterator {
3882 public:
3883 MachineBasicBlock::pred_iterator PredIt;
3884 LDVSSAUpdater &Updater;
3885
LDVSSABlockIterator(MachineBasicBlock::pred_iterator PredIt,LDVSSAUpdater & Updater)3886 LDVSSABlockIterator(MachineBasicBlock::pred_iterator PredIt,
3887 LDVSSAUpdater &Updater)
3888 : PredIt(PredIt), Updater(Updater) {}
3889
operator !=(const LDVSSABlockIterator & OtherIt) const3890 bool operator!=(const LDVSSABlockIterator &OtherIt) const {
3891 return OtherIt.PredIt != PredIt;
3892 }
3893
operator ++()3894 LDVSSABlockIterator &operator++() {
3895 ++PredIt;
3896 return *this;
3897 }
3898
3899 LDVSSABlock *operator*();
3900 };
3901
3902 /// Thin wrapper around a block for SSA Updater interface. Necessary because
3903 /// we need to track the PHI value(s) that we may have observed as necessary
3904 /// in this block.
3905 class LDVSSABlock {
3906 public:
3907 MachineBasicBlock &BB;
3908 LDVSSAUpdater &Updater;
3909 using PHIListT = SmallVector<LDVSSAPhi, 1>;
3910 /// List of PHIs in this block. There should only ever be one.
3911 PHIListT PHIList;
3912
LDVSSABlock(MachineBasicBlock & BB,LDVSSAUpdater & Updater)3913 LDVSSABlock(MachineBasicBlock &BB, LDVSSAUpdater &Updater)
3914 : BB(BB), Updater(Updater) {}
3915
succ_begin()3916 LDVSSABlockIterator succ_begin() {
3917 return LDVSSABlockIterator(BB.succ_begin(), Updater);
3918 }
3919
succ_end()3920 LDVSSABlockIterator succ_end() {
3921 return LDVSSABlockIterator(BB.succ_end(), Updater);
3922 }
3923
3924 /// SSAUpdater has requested a PHI: create that within this block record.
newPHI(BlockValueNum Value)3925 LDVSSAPhi *newPHI(BlockValueNum Value) {
3926 PHIList.emplace_back(Value, this);
3927 return &PHIList.back();
3928 }
3929
3930 /// SSAUpdater wishes to know what PHIs already exist in this block.
phis()3931 PHIListT &phis() { return PHIList; }
3932 };
3933
3934 /// Utility class for the SSAUpdater interface: tracks blocks, PHIs and values
3935 /// while SSAUpdater is exploring the CFG. It's passed as a handle / baton to
3936 // SSAUpdaterTraits<LDVSSAUpdater>.
3937 class LDVSSAUpdater {
3938 public:
3939 /// Map of value numbers to PHI records.
3940 DenseMap<BlockValueNum, LDVSSAPhi *> PHIs;
3941 /// Map of which blocks generate Undef values -- blocks that are not
3942 /// dominated by any Def.
3943 DenseMap<MachineBasicBlock *, BlockValueNum> PoisonMap;
3944 /// Map of machine blocks to our own records of them.
3945 DenseMap<MachineBasicBlock *, LDVSSABlock *> BlockMap;
3946 /// Machine location where any PHI must occur.
3947 LocIdx Loc;
3948 /// Table of live-in machine value numbers for blocks / locations.
3949 const FuncValueTable &MLiveIns;
3950
LDVSSAUpdater(LocIdx L,const FuncValueTable & MLiveIns)3951 LDVSSAUpdater(LocIdx L, const FuncValueTable &MLiveIns)
3952 : Loc(L), MLiveIns(MLiveIns) {}
3953
reset()3954 void reset() {
3955 for (auto &Block : BlockMap)
3956 delete Block.second;
3957
3958 PHIs.clear();
3959 PoisonMap.clear();
3960 BlockMap.clear();
3961 }
3962
~LDVSSAUpdater()3963 ~LDVSSAUpdater() { reset(); }
3964
3965 /// For a given MBB, create a wrapper block for it. Stores it in the
3966 /// LDVSSAUpdater block map.
getSSALDVBlock(MachineBasicBlock * BB)3967 LDVSSABlock *getSSALDVBlock(MachineBasicBlock *BB) {
3968 auto it = BlockMap.find(BB);
3969 if (it == BlockMap.end()) {
3970 BlockMap[BB] = new LDVSSABlock(*BB, *this);
3971 it = BlockMap.find(BB);
3972 }
3973 return it->second;
3974 }
3975
3976 /// Find the live-in value number for the given block. Looks up the value at
3977 /// the PHI location on entry.
getValue(LDVSSABlock * LDVBB)3978 BlockValueNum getValue(LDVSSABlock *LDVBB) {
3979 return MLiveIns[LDVBB->BB][Loc.asU64()].asU64();
3980 }
3981 };
3982
operator *()3983 LDVSSABlock *LDVSSABlockIterator::operator*() {
3984 return Updater.getSSALDVBlock(*PredIt);
3985 }
3986
3987 #ifndef NDEBUG
3988
operator <<(raw_ostream & out,const LDVSSAPhi & PHI)3989 raw_ostream &operator<<(raw_ostream &out, const LDVSSAPhi &PHI) {
3990 out << "SSALDVPHI " << PHI.PHIValNum;
3991 return out;
3992 }
3993
3994 #endif
3995
3996 } // namespace
3997
3998 namespace llvm {
3999
4000 /// Template specialization to give SSAUpdater access to CFG and value
4001 /// information. SSAUpdater calls methods in these traits, passing in the
4002 /// LDVSSAUpdater object, to learn about blocks and the values they define.
4003 /// It also provides methods to create PHI nodes and track them.
4004 template <> class SSAUpdaterTraits<LDVSSAUpdater> {
4005 public:
4006 using BlkT = LDVSSABlock;
4007 using ValT = BlockValueNum;
4008 using PhiT = LDVSSAPhi;
4009 using BlkSucc_iterator = LDVSSABlockIterator;
4010
4011 // Methods to access block successors -- dereferencing to our wrapper class.
BlkSucc_begin(BlkT * BB)4012 static BlkSucc_iterator BlkSucc_begin(BlkT *BB) { return BB->succ_begin(); }
BlkSucc_end(BlkT * BB)4013 static BlkSucc_iterator BlkSucc_end(BlkT *BB) { return BB->succ_end(); }
4014
4015 /// Iterator for PHI operands.
4016 class PHI_iterator {
4017 private:
4018 LDVSSAPhi *PHI;
4019 unsigned Idx;
4020
4021 public:
PHI_iterator(LDVSSAPhi * P)4022 explicit PHI_iterator(LDVSSAPhi *P) // begin iterator
4023 : PHI(P), Idx(0) {}
PHI_iterator(LDVSSAPhi * P,bool)4024 PHI_iterator(LDVSSAPhi *P, bool) // end iterator
4025 : PHI(P), Idx(PHI->IncomingValues.size()) {}
4026
operator ++()4027 PHI_iterator &operator++() {
4028 Idx++;
4029 return *this;
4030 }
operator ==(const PHI_iterator & X) const4031 bool operator==(const PHI_iterator &X) const { return Idx == X.Idx; }
operator !=(const PHI_iterator & X) const4032 bool operator!=(const PHI_iterator &X) const { return !operator==(X); }
4033
getIncomingValue()4034 BlockValueNum getIncomingValue() { return PHI->IncomingValues[Idx].second; }
4035
getIncomingBlock()4036 LDVSSABlock *getIncomingBlock() { return PHI->IncomingValues[Idx].first; }
4037 };
4038
PHI_begin(PhiT * PHI)4039 static inline PHI_iterator PHI_begin(PhiT *PHI) { return PHI_iterator(PHI); }
4040
PHI_end(PhiT * PHI)4041 static inline PHI_iterator PHI_end(PhiT *PHI) {
4042 return PHI_iterator(PHI, true);
4043 }
4044
4045 /// FindPredecessorBlocks - Put the predecessors of BB into the Preds
4046 /// vector.
FindPredecessorBlocks(LDVSSABlock * BB,SmallVectorImpl<LDVSSABlock * > * Preds)4047 static void FindPredecessorBlocks(LDVSSABlock *BB,
4048 SmallVectorImpl<LDVSSABlock *> *Preds) {
4049 for (MachineBasicBlock *Pred : BB->BB.predecessors())
4050 Preds->push_back(BB->Updater.getSSALDVBlock(Pred));
4051 }
4052
4053 /// GetPoisonVal - Normally creates an IMPLICIT_DEF instruction with a new
4054 /// register. For LiveDebugValues, represents a block identified as not having
4055 /// any DBG_PHI predecessors.
GetPoisonVal(LDVSSABlock * BB,LDVSSAUpdater * Updater)4056 static BlockValueNum GetPoisonVal(LDVSSABlock *BB, LDVSSAUpdater *Updater) {
4057 // Create a value number for this block -- it needs to be unique and in the
4058 // "poison" collection, so that we know it's not real. Use a number
4059 // representing a PHI into this block.
4060 BlockValueNum Num = ValueIDNum(BB->BB.getNumber(), 0, Updater->Loc).asU64();
4061 Updater->PoisonMap[&BB->BB] = Num;
4062 return Num;
4063 }
4064
4065 /// CreateEmptyPHI - Create a (representation of a) PHI in the given block.
4066 /// SSAUpdater will populate it with information about incoming values. The
4067 /// value number of this PHI is whatever the machine value number problem
4068 /// solution determined it to be. This includes non-phi values if SSAUpdater
4069 /// tries to create a PHI where the incoming values are identical.
CreateEmptyPHI(LDVSSABlock * BB,unsigned NumPreds,LDVSSAUpdater * Updater)4070 static BlockValueNum CreateEmptyPHI(LDVSSABlock *BB, unsigned NumPreds,
4071 LDVSSAUpdater *Updater) {
4072 BlockValueNum PHIValNum = Updater->getValue(BB);
4073 LDVSSAPhi *PHI = BB->newPHI(PHIValNum);
4074 Updater->PHIs[PHIValNum] = PHI;
4075 return PHIValNum;
4076 }
4077
4078 /// AddPHIOperand - Add the specified value as an operand of the PHI for
4079 /// the specified predecessor block.
AddPHIOperand(LDVSSAPhi * PHI,BlockValueNum Val,LDVSSABlock * Pred)4080 static void AddPHIOperand(LDVSSAPhi *PHI, BlockValueNum Val, LDVSSABlock *Pred) {
4081 PHI->IncomingValues.push_back(std::make_pair(Pred, Val));
4082 }
4083
4084 /// ValueIsPHI - Check if the instruction that defines the specified value
4085 /// is a PHI instruction.
ValueIsPHI(BlockValueNum Val,LDVSSAUpdater * Updater)4086 static LDVSSAPhi *ValueIsPHI(BlockValueNum Val, LDVSSAUpdater *Updater) {
4087 return Updater->PHIs.lookup(Val);
4088 }
4089
4090 /// ValueIsNewPHI - Like ValueIsPHI but also check if the PHI has no source
4091 /// operands, i.e., it was just added.
ValueIsNewPHI(BlockValueNum Val,LDVSSAUpdater * Updater)4092 static LDVSSAPhi *ValueIsNewPHI(BlockValueNum Val, LDVSSAUpdater *Updater) {
4093 LDVSSAPhi *PHI = ValueIsPHI(Val, Updater);
4094 if (PHI && PHI->IncomingValues.size() == 0)
4095 return PHI;
4096 return nullptr;
4097 }
4098
4099 /// GetPHIValue - For the specified PHI instruction, return the value
4100 /// that it defines.
GetPHIValue(LDVSSAPhi * PHI)4101 static BlockValueNum GetPHIValue(LDVSSAPhi *PHI) { return PHI->PHIValNum; }
4102 };
4103
4104 } // end namespace llvm
4105
resolveDbgPHIs(MachineFunction & MF,const FuncValueTable & MLiveOuts,const FuncValueTable & MLiveIns,MachineInstr & Here,uint64_t InstrNum)4106 std::optional<ValueIDNum> InstrRefBasedLDV::resolveDbgPHIs(
4107 MachineFunction &MF, const FuncValueTable &MLiveOuts,
4108 const FuncValueTable &MLiveIns, MachineInstr &Here, uint64_t InstrNum) {
4109 // This function will be called twice per DBG_INSTR_REF, and might end up
4110 // computing lots of SSA information: memoize it.
4111 auto SeenDbgPHIIt = SeenDbgPHIs.find(std::make_pair(&Here, InstrNum));
4112 if (SeenDbgPHIIt != SeenDbgPHIs.end())
4113 return SeenDbgPHIIt->second;
4114
4115 std::optional<ValueIDNum> Result =
4116 resolveDbgPHIsImpl(MF, MLiveOuts, MLiveIns, Here, InstrNum);
4117 SeenDbgPHIs.insert({std::make_pair(&Here, InstrNum), Result});
4118 return Result;
4119 }
4120
resolveDbgPHIsImpl(MachineFunction & MF,const FuncValueTable & MLiveOuts,const FuncValueTable & MLiveIns,MachineInstr & Here,uint64_t InstrNum)4121 std::optional<ValueIDNum> InstrRefBasedLDV::resolveDbgPHIsImpl(
4122 MachineFunction &MF, const FuncValueTable &MLiveOuts,
4123 const FuncValueTable &MLiveIns, MachineInstr &Here, uint64_t InstrNum) {
4124 // Pick out records of DBG_PHI instructions that have been observed. If there
4125 // are none, then we cannot compute a value number.
4126 auto RangePair = std::equal_range(DebugPHINumToValue.begin(),
4127 DebugPHINumToValue.end(), InstrNum);
4128 auto LowerIt = RangePair.first;
4129 auto UpperIt = RangePair.second;
4130
4131 // No DBG_PHI means there can be no location.
4132 if (LowerIt == UpperIt)
4133 return std::nullopt;
4134
4135 // If any DBG_PHIs referred to a location we didn't understand, don't try to
4136 // compute a value. There might be scenarios where we could recover a value
4137 // for some range of DBG_INSTR_REFs, but at this point we can have high
4138 // confidence that we've seen a bug.
4139 auto DBGPHIRange = make_range(LowerIt, UpperIt);
4140 for (const DebugPHIRecord &DBG_PHI : DBGPHIRange)
4141 if (!DBG_PHI.ValueRead)
4142 return std::nullopt;
4143
4144 // If there's only one DBG_PHI, then that is our value number.
4145 if (std::distance(LowerIt, UpperIt) == 1)
4146 return *LowerIt->ValueRead;
4147
4148 // Pick out the location (physreg, slot) where any PHIs must occur. It's
4149 // technically possible for us to merge values in different registers in each
4150 // block, but highly unlikely that LLVM will generate such code after register
4151 // allocation.
4152 LocIdx Loc = *LowerIt->ReadLoc;
4153
4154 // We have several DBG_PHIs, and a use position (the Here inst). All each
4155 // DBG_PHI does is identify a value at a program position. We can treat each
4156 // DBG_PHI like it's a Def of a value, and the use position is a Use of a
4157 // value, just like SSA. We use the bulk-standard LLVM SSA updater class to
4158 // determine which Def is used at the Use, and any PHIs that happen along
4159 // the way.
4160 // Adapted LLVM SSA Updater:
4161 LDVSSAUpdater Updater(Loc, MLiveIns);
4162 // Map of which Def or PHI is the current value in each block.
4163 DenseMap<LDVSSABlock *, BlockValueNum> AvailableValues;
4164 // Set of PHIs that we have created along the way.
4165 SmallVector<LDVSSAPhi *, 8> CreatedPHIs;
4166
4167 // Each existing DBG_PHI is a Def'd value under this model. Record these Defs
4168 // for the SSAUpdater.
4169 for (const auto &DBG_PHI : DBGPHIRange) {
4170 LDVSSABlock *Block = Updater.getSSALDVBlock(DBG_PHI.MBB);
4171 const ValueIDNum &Num = *DBG_PHI.ValueRead;
4172 AvailableValues.insert(std::make_pair(Block, Num.asU64()));
4173 }
4174
4175 LDVSSABlock *HereBlock = Updater.getSSALDVBlock(Here.getParent());
4176 const auto &AvailIt = AvailableValues.find(HereBlock);
4177 if (AvailIt != AvailableValues.end()) {
4178 // Actually, we already know what the value is -- the Use is in the same
4179 // block as the Def.
4180 return ValueIDNum::fromU64(AvailIt->second);
4181 }
4182
4183 // Otherwise, we must use the SSA Updater. It will identify the value number
4184 // that we are to use, and the PHIs that must happen along the way.
4185 SSAUpdaterImpl<LDVSSAUpdater> Impl(&Updater, &AvailableValues, &CreatedPHIs);
4186 BlockValueNum ResultInt = Impl.GetValue(Updater.getSSALDVBlock(Here.getParent()));
4187 ValueIDNum Result = ValueIDNum::fromU64(ResultInt);
4188
4189 // We have the number for a PHI, or possibly live-through value, to be used
4190 // at this Use. There are a number of things we have to check about it though:
4191 // * Does any PHI use an 'Undef' (like an IMPLICIT_DEF) value? If so, this
4192 // Use was not completely dominated by DBG_PHIs and we should abort.
4193 // * Are the Defs or PHIs clobbered in a block? SSAUpdater isn't aware that
4194 // we've left SSA form. Validate that the inputs to each PHI are the
4195 // expected values.
4196 // * Is a PHI we've created actually a merging of values, or are all the
4197 // predecessor values the same, leading to a non-PHI machine value number?
4198 // (SSAUpdater doesn't know that either). Remap validated PHIs into the
4199 // the ValidatedValues collection below to sort this out.
4200 DenseMap<LDVSSABlock *, ValueIDNum> ValidatedValues;
4201
4202 // Define all the input DBG_PHI values in ValidatedValues.
4203 for (const auto &DBG_PHI : DBGPHIRange) {
4204 LDVSSABlock *Block = Updater.getSSALDVBlock(DBG_PHI.MBB);
4205 const ValueIDNum &Num = *DBG_PHI.ValueRead;
4206 ValidatedValues.insert(std::make_pair(Block, Num));
4207 }
4208
4209 // Sort PHIs to validate into RPO-order.
4210 SmallVector<LDVSSAPhi *, 8> SortedPHIs;
4211 for (auto &PHI : CreatedPHIs)
4212 SortedPHIs.push_back(PHI);
4213
4214 llvm::sort(SortedPHIs, [&](LDVSSAPhi *A, LDVSSAPhi *B) {
4215 return BBToOrder[&A->getParent()->BB] < BBToOrder[&B->getParent()->BB];
4216 });
4217
4218 for (auto &PHI : SortedPHIs) {
4219 ValueIDNum ThisBlockValueNum = MLiveIns[PHI->ParentBlock->BB][Loc.asU64()];
4220
4221 // Are all these things actually defined?
4222 for (auto &PHIIt : PHI->IncomingValues) {
4223 // Any undef input means DBG_PHIs didn't dominate the use point.
4224 if (Updater.PoisonMap.contains(&PHIIt.first->BB))
4225 return std::nullopt;
4226
4227 ValueIDNum ValueToCheck;
4228 const ValueTable &BlockLiveOuts = MLiveOuts[PHIIt.first->BB];
4229
4230 auto VVal = ValidatedValues.find(PHIIt.first);
4231 if (VVal == ValidatedValues.end()) {
4232 // We cross a loop, and this is a backedge. LLVMs tail duplication
4233 // happens so late that DBG_PHI instructions should not be able to
4234 // migrate into loops -- meaning we can only be live-through this
4235 // loop.
4236 ValueToCheck = ThisBlockValueNum;
4237 } else {
4238 // Does the block have as a live-out, in the location we're examining,
4239 // the value that we expect? If not, it's been moved or clobbered.
4240 ValueToCheck = VVal->second;
4241 }
4242
4243 if (BlockLiveOuts[Loc.asU64()] != ValueToCheck)
4244 return std::nullopt;
4245 }
4246
4247 // Record this value as validated.
4248 ValidatedValues.insert({PHI->ParentBlock, ThisBlockValueNum});
4249 }
4250
4251 // All the PHIs are valid: we can return what the SSAUpdater said our value
4252 // number was.
4253 return Result;
4254 }
4255