ImplicitNullChecks.cpp source code [llvm/lib/CodeGen/ImplicitNullChecks.cpp]

1	//===- ImplicitNullChecks.cpp - Fold null checks into memory accesses -----===//
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	//
9	// This pass turns explicit null checks of the form
10	//
11	// test %r10, %r10
12	// je throw_npe
13	// movl (%r10), %esi
14	// ...
15	//
16	// to
17	//
18	// faulting_load_op("movl (%r10), %esi", throw_npe)
19	// ...
20	//
21	// With the help of a runtime that understands the .fault_maps section,
22	// faulting_load_op branches to throw_npe if executing movl (%r10), %esi incurs
23	// a page fault.
24	// Store and LoadStore are also supported.
25	//
26	//===----------------------------------------------------------------------===//
27
28	#include "llvm/ADT/ArrayRef.h"
29	#include "llvm/ADT/STLExtras.h"
30	#include "llvm/ADT/SmallVector.h"
31	#include "llvm/ADT/Statistic.h"
32	#include "llvm/Analysis/AliasAnalysis.h"
33	#include "llvm/Analysis/MemoryLocation.h"
34	#include "llvm/CodeGen/FaultMaps.h"
35	#include "llvm/CodeGen/MachineBasicBlock.h"
36	#include "llvm/CodeGen/MachineFunction.h"
37	#include "llvm/CodeGen/MachineFunctionPass.h"
38	#include "llvm/CodeGen/MachineInstr.h"
39	#include "llvm/CodeGen/MachineInstrBuilder.h"
40	#include "llvm/CodeGen/MachineMemOperand.h"
41	#include "llvm/CodeGen/MachineOperand.h"
42	#include "llvm/CodeGen/MachineRegisterInfo.h"
43	#include "llvm/CodeGen/PseudoSourceValue.h"
44	#include "llvm/CodeGen/TargetInstrInfo.h"
45	#include "llvm/CodeGen/TargetOpcodes.h"
46	#include "llvm/CodeGen/TargetRegisterInfo.h"
47	#include "llvm/CodeGen/TargetSubtargetInfo.h"
48	#include "llvm/IR/BasicBlock.h"
49	#include "llvm/IR/DebugLoc.h"
50	#include "llvm/IR/LLVMContext.h"
51	#include "llvm/InitializePasses.h"
52	#include "llvm/MC/MCInstrDesc.h"
53	#include "llvm/MC/MCRegisterInfo.h"
54	#include "llvm/Pass.h"
55	#include "llvm/Support/CommandLine.h"
56	#include <cassert>
57	#include <cstdint>
58	#include <iterator>
59
60	using namespace llvm;
61
62	static cl::opt<int> PageSize("imp-null-check-page-size",
63	cl::desc ("The page size of the target in bytes"),
64	cl::init(Val: `4096`), cl::Hidden);
65
66	static cl::opt<unsigned> MaxInstsToConsider(
67	"imp-null-max-insts-to-consider",
68	cl::desc ("The max number of instructions to consider hoisting loads over "
69	"(the algorithm is quadratic over this number)"),
70	cl::Hidden, cl::init(Val: `8`));
71
72	#define DEBUG_TYPE "implicit-null-checks"
73
74	STATISTIC(NumImplicitNullChecks,
75	"Number of explicit null checks made implicit");
76
77	namespace {
78
79	class ImplicitNullChecks : public MachineFunctionPass {
80	/// Return true if \c computeDependence can process \p MI.
81	static bool canHandle(const MachineInstr *MI);
82
83	/// Helper function for \c computeDependence. Return true if \p A
84	/// and \p B do not have any dependences between them, and can be
85	/// re-ordered without changing program semantics.
86	bool canReorder(const MachineInstr A, const* MachineInstr *B);
87
88	/// A data type for representing the result computed by \c
89	/// computeDependence. States whether it is okay to reorder the
90	/// instruction passed to \c computeDependence with at most one
91	/// dependency.
92	struct DependenceResult {
93	/// Can we actually re-order \p MI with \p Insts (see \c
94	/// computeDependence).
95	bool CanReorder;
96
97	/// If non-std::nullopt, then an instruction in \p Insts that also must be
98	/// hoisted.
99	std::optional<ArrayRef<MachineInstr *>::iterator> PotentialDependence;
100
101	/implicit/ DependenceResult(
102	bool CanReorder,
103	std::optional<ArrayRef<MachineInstr *>::iterator> PotentialDependence)
104	: CanReorder(CanReorder), PotentialDependence (PotentialDependence) {
105	assert((!PotentialDependence \|\| CanReorder) &&
106	"!CanReorder && PotentialDependence.hasValue() not allowed!");
107	}
108	};
109
110	/// Compute a result for the following question: can \p MI be
111	/// re-ordered from after \p Insts to before it.
112	///
113	/// \c canHandle should return true for all instructions in \p
114	/// Insts.
115	DependenceResult computeDependence(const MachineInstr *MI,
116	ArrayRef<MachineInstr *> Block);
117
118	/// Represents one null check that can be made implicit.
119	class NullCheck {
120	// The memory operation the null check can be folded into.
121	MachineInstr *MemOperation;
122
123	// The instruction actually doing the null check (Ptr != 0).
124	MachineInstr *CheckOperation;
125
126	// The block the check resides in.
127	MachineBasicBlock *CheckBlock;
128
129	// The block branched to if the pointer is non-null.
130	MachineBasicBlock *NotNullSucc;
131
132	// The block branched to if the pointer is null.
133	MachineBasicBlock *NullSucc;
134
135	// If this is non-null, then MemOperation has a dependency on this
136	// instruction; and it needs to be hoisted to execute before MemOperation.
137	MachineInstr *OnlyDependency;
138
139	public:
140	explicit NullCheck(MachineInstr memOperation, MachineInstr checkOperation,
141	MachineBasicBlock *checkBlock,
142	MachineBasicBlock *notNullSucc,
143	MachineBasicBlock *nullSucc,
144	MachineInstr *onlyDependency)
145	: MemOperation(memOperation), CheckOperation(checkOperation),
146	CheckBlock(checkBlock), NotNullSucc(notNullSucc), NullSucc(nullSucc),
147	OnlyDependency(onlyDependency) {}
148
149	MachineInstr getMemOperation() const* { return MemOperation; }
150
151	MachineInstr getCheckOperation() const* { return CheckOperation; }
152
153	MachineBasicBlock getCheckBlock() const* { return CheckBlock; }
154
155	MachineBasicBlock getNotNullSucc() const* { return NotNullSucc; }
156
157	MachineBasicBlock getNullSucc() const* { return NullSucc; }
158
159	MachineInstr getOnlyDependency() const* { return OnlyDependency; }
160	};
161
162	const TargetInstrInfo TII = nullptr*;
163	const TargetRegisterInfo TRI = nullptr*;
164	AliasAnalysis AA = nullptr*;
165	MachineFrameInfo MFI = nullptr*;
166
167	bool analyzeBlockForNullChecks(MachineBasicBlock &MBB,
168	SmallVectorImpl<NullCheck> &NullCheckList);
169	MachineInstr insertFaultingInstr(MachineInstr MI, MachineBasicBlock *MBB,
170	MachineBasicBlock *HandlerMBB);
171	void rewriteNullChecks(ArrayRef<NullCheck> NullCheckList);
172
173	enum AliasResult {
174	AR_NoAlias,
175	AR_MayAlias,
176	AR_WillAliasEverything
177	};
178
179	/// Returns AR_NoAlias if \p MI memory operation does not alias with
180	/// \p PrevMI, AR_MayAlias if they may alias and AR_WillAliasEverything if
181	/// they may alias and any further memory operation may alias with \p PrevMI.
182	AliasResult areMemoryOpsAliased(const MachineInstr &MI,
183	const MachineInstr PrevMI) const*;
184
185	enum SuitabilityResult {
186	SR_Suitable,
187	SR_Unsuitable,
188	SR_Impossible
189	};
190
191	/// Return SR_Suitable if \p MI a memory operation that can be used to
192	/// implicitly null check the value in \p PointerReg, SR_Unsuitable if
193	/// \p MI cannot be used to null check and SR_Impossible if there is
194	/// no sense to continue lookup due to any other instruction will not be able
195	/// to be used. \p PrevInsts is the set of instruction seen since
196	/// the explicit null check on \p PointerReg.
197	SuitabilityResult isSuitableMemoryOp(const MachineInstr &MI,
198	unsigned PointerReg,
199	ArrayRef<MachineInstr *> PrevInsts);
200
201	/// Returns true if \p DependenceMI can clobber the liveIns in NullSucc block
202	/// if it was hoisted to the NullCheck block. This is used by caller
203	/// canHoistInst to decide if DependenceMI can be hoisted safely.
204	bool canDependenceHoistingClobberLiveIns(MachineInstr *DependenceMI,
205	MachineBasicBlock *NullSucc);
206
207	/// Return true if \p FaultingMI can be hoisted from after the
208	/// instructions in \p InstsSeenSoFar to before them. Set \p Dependence to a
209	/// non-null value if we also need to (and legally can) hoist a dependency.
210	bool canHoistInst(MachineInstr *FaultingMI,
211	ArrayRef<MachineInstr *> InstsSeenSoFar,
212	MachineBasicBlock NullSucc, MachineInstr &Dependence);
213
214	public:
215	static char ID;
216
217	ImplicitNullChecks() : MachineFunctionPass (ID) {
218	initializeImplicitNullChecksPass(*PassRegistry::getPassRegistry());
219	}
220
221	bool runOnMachineFunction(MachineFunction &MF) override;
222
223	void getAnalysisUsage(AnalysisUsage &AU) const override {
224	AU.addRequired<AAResultsWrapperPass>();
225	MachineFunctionPass::getAnalysisUsage(AU);
226	}
227
228	MachineFunctionProperties getRequiredProperties() const override {
229	return MachineFunctionProperties ().set(
230	MachineFunctionProperties::Property::NoVRegs);
231	}
232	};
233
234	} // end anonymous namespace
235
236	bool ImplicitNullChecks::canHandle(const MachineInstr *MI) {
237	if (MI->isCall() \|\| MI->mayRaiseFPException() \|\|
238	MI->hasUnmodeledSideEffects())
239	return false;
240	auto IsRegMask = [](const MachineOperand &MO) { return MO.isRegMask(); };
241	(void)IsRegMask;
242
243	assert(llvm::none_of(MI->operands(), IsRegMask) &&
244	"Calls were filtered out above!");
245
246	auto IsUnordered = [](MachineMemOperand MMO) { return* MMO->isUnordered(); };
247	return llvm::all_of(Range: MI->memoperands(), P: IsUnordered);
248	}
249
250	ImplicitNullChecks::DependenceResult
251	ImplicitNullChecks::computeDependence(const MachineInstr *MI,
252	ArrayRef<MachineInstr *> Block) {
253	assert(llvm::all_of(Block, canHandle) && "Check this first!");
254	assert(!is_contained(Block, MI) && "Block must be exclusive of MI!");
255
256	std::optional<ArrayRef<MachineInstr *>::iterator> Dep;
257
258	for (auto I = Block.begin(), E = Block.end(); I != E; ++I) {
259	if (canReorder(A: *I, B: MI))
260	continue;
261
262	if (Dep == std::nullopt) {
263	// Found one possible dependency, keep track of it.
264	Dep = I;
265	} else {
266	// We found two dependencies, so bail out.
267	return {false, std::nullopt};
268	}
269	}
270
271	return {true, Dep};
272	}
273
274	bool ImplicitNullChecks::canReorder(const MachineInstr *A,
275	const MachineInstr *B) {
276	assert(canHandle(A) && canHandle(B) && "Precondition!");
277
278	// canHandle makes sure that we _can_ correctly analyze the dependencies
279	// between A and B here -- for instance, we should not be dealing with heap
280	// load-store dependencies here.
281
282	for (const auto &MOA : A->operands()) {
283	if (!(MOA.isReg() && MOA.getReg()))
284	continue;
285
286	Register RegA = MOA.getReg();
287	for (const auto &MOB : B->operands()) {
288	if (!(MOB.isReg() && MOB.getReg()))
289	continue;
290
291	Register RegB = MOB.getReg();
292
293	if (TRI->regsOverlap(RegA, RegB) && (MOA.isDef() \|\| MOB.isDef()))
294	return false;
295	}
296	}
297
298	return true;
299	}
300
301	bool ImplicitNullChecks::runOnMachineFunction(MachineFunction &MF) {
302	TII = MF.getSubtarget().getInstrInfo();
303	TRI = MF.getRegInfo().getTargetRegisterInfo();
304	MFI = &MF.getFrameInfo();
305	AA = &getAnalysis<AAResultsWrapperPass>().getAAResults();
306
307	SmallVector<NullCheck, `16`> NullCheckList;
308
309	for (auto &MBB : MF)
310	analyzeBlockForNullChecks(MBB, NullCheckList);
311
312	if (!NullCheckList.empty())
313	rewriteNullChecks(NullCheckList);
314
315	return !NullCheckList.empty();
316	}
317
318	// Return true if any register aliasing \p Reg is live-in into \p MBB.
319	static bool AnyAliasLiveIn(const TargetRegisterInfo *TRI,
320	MachineBasicBlock MBB, unsigned* Reg) {
321	for (MCRegAliasIterator AR(Reg, TRI, /IncludeSelf/ true); AR.isValid();
322	++AR)
323	if (MBB->isLiveIn(Reg: *AR))
324	return true;
325	return false;
326	}
327
328	ImplicitNullChecks::AliasResult
329	ImplicitNullChecks::areMemoryOpsAliased(const MachineInstr &MI,
330	const MachineInstr PrevMI) const* {
331	// If it is not memory access, skip the check.
332	if (!(PrevMI->mayStore() \|\| PrevMI->mayLoad()))
333	return AR_NoAlias;
334	// Load-Load may alias
335	if (!(MI.mayStore() \|\| PrevMI->mayStore()))
336	return AR_NoAlias;
337	// We lost info, conservatively alias. If it was store then no sense to
338	// continue because we won't be able to check against it further.
339	if (MI.memoperands_empty())
340	return MI.mayStore() ? AR_WillAliasEverything : AR_MayAlias;
341	if (PrevMI->memoperands_empty())
342	return PrevMI->mayStore() ? AR_WillAliasEverything : AR_MayAlias;
343
344	for (MachineMemOperand *MMO1 : MI.memoperands()) {
345	// MMO1 should have a value due it comes from operation we'd like to use
346	// as implicit null check.
347	assert(MMO1->getValue() && "MMO1 should have a Value!");
348	for (MachineMemOperand *MMO2 : PrevMI->memoperands()) {
349	if (const PseudoSourceValue *PSV = MMO2->getPseudoValue()) {
350	if (PSV->mayAlias(MFI))
351	return AR_MayAlias;
352	continue;
353	}
354	if (!AA->isNoAlias(
355	LocA: MemoryLocation::getAfter(Ptr: MMO1->getValue(), AATags: MMO1->getAAInfo()),
356	LocB: MemoryLocation::getAfter(Ptr: MMO2->getValue(), AATags: MMO2->getAAInfo())))
357	return AR_MayAlias;
358	}
359	}
360	return AR_NoAlias;
361	}
362
363	ImplicitNullChecks::SuitabilityResult
364	ImplicitNullChecks::isSuitableMemoryOp(const MachineInstr &MI,
365	unsigned PointerReg,
366	ArrayRef<MachineInstr *> PrevInsts) {
367	// Implementation restriction for faulting_op insertion
368	// TODO: This could be relaxed if we find a test case which warrants it.
369	if (MI.getDesc().getNumDefs() > `1`)
370	return SR_Unsuitable;
371
372	if (!MI.mayLoadOrStore() \|\| MI.isPredicable())
373	return SR_Unsuitable;
374	auto AM = TII->getAddrModeFromMemoryOp(MemI: MI, TRI);
375	if (!AM \|\| AM ->Form != ExtAddrMode::Formula::Basic)
376	return SR_Unsuitable;
377	auto AddrMode = *AM;
378	const Register BaseReg = AddrMode.BaseReg, ScaledReg = AddrMode.ScaledReg;
379	int64_t Displacement = AddrMode.Displacement;
380
381	// We need the base of the memory instruction to be same as the register
382	// where the null check is performed (i.e. PointerReg).
383	if (BaseReg != PointerReg && ScaledReg != PointerReg)
384	return SR_Unsuitable;
385	const MachineRegisterInfo &MRI = MI.getMF()->getRegInfo();
386	unsigned PointerRegSizeInBits = TRI->getRegSizeInBits(Reg: PointerReg, MRI);
387	// Bail out of the sizes of BaseReg, ScaledReg and PointerReg are not the
388	// same.
389	if ((BaseReg &&
390	TRI->getRegSizeInBits(Reg: BaseReg, MRI) != PointerRegSizeInBits) \|\|
391	(ScaledReg &&
392	TRI->getRegSizeInBits(Reg: ScaledReg, MRI) != PointerRegSizeInBits))
393	return SR_Unsuitable;
394
395	// Returns true if RegUsedInAddr is used for calculating the displacement
396	// depending on addressing mode. Also calculates the Displacement.
397	auto CalculateDisplacementFromAddrMode = [&](Register RegUsedInAddr,
398	int64_t Multiplier) {
399	// The register can be NoRegister, which is defined as zero for all targets.
400	// Consider instruction of interest as `movq 8(,%rdi,8), %rax`. Here the
401	// ScaledReg is %rdi, while there is no BaseReg.
402	if (!RegUsedInAddr)
403	return false;
404	assert(Multiplier && "expected to be non-zero!");
405	MachineInstr ModifyingMI = nullptr*;
406	for (auto It = std::next(x: MachineBasicBlock::const_reverse_iterator (&MI));
407	It != MI.getParent()->rend(); It ++) {
408	const MachineInstr CurrMI = &It;
409	if (CurrMI->modifiesRegister(Reg: RegUsedInAddr, TRI)) {
410	ModifyingMI = const_cast<MachineInstr *>(CurrMI);
411	break;
412	}
413	}
414	if (!ModifyingMI)
415	return false;
416	// Check for the const value defined in register by ModifyingMI. This means
417	// all other previous values for that register has been invalidated.
418	int64_t ImmVal;
419	if (!TII->getConstValDefinedInReg(MI: *ModifyingMI, Reg: RegUsedInAddr, ImmVal))
420	return false;
421	// Calculate the reg size in bits, since this is needed for bailing out in
422	// case of overflow.
423	int32_t RegSizeInBits = TRI->getRegSizeInBits(Reg: RegUsedInAddr, MRI);
424	APInt ImmValC(RegSizeInBits, ImmVal, true /IsSigned/);
425	APInt MultiplierC(RegSizeInBits, Multiplier);
426	assert(MultiplierC.isStrictlyPositive() &&
427	"expected to be a positive value!");
428	bool IsOverflow;
429	// Sign of the product depends on the sign of the ImmVal, since Multiplier
430	// is always positive.
431	APInt Product = ImmValC.smul_ov(RHS: MultiplierC, Overflow&: IsOverflow);
432	if (IsOverflow)
433	return false;
434	APInt DisplacementC(`64`, Displacement, true /isSigned/);
435	DisplacementC = Product.sadd_ov(RHS: DisplacementC, Overflow&: IsOverflow);
436	if (IsOverflow)
437	return false;
438
439	// We only handle diplacements upto 64 bits wide.
440	if (DisplacementC.getActiveBits() > `64`)
441	return false;
442	Displacement = DisplacementC.getSExtValue();
443	return true;
444	};
445
446	// If a register used in the address is constant, fold it's effect into the
447	// displacement for ease of analysis.
448	bool BaseRegIsConstVal = false, ScaledRegIsConstVal = false;
449	if (CalculateDisplacementFromAddrMode (BaseReg, `1`))
450	BaseRegIsConstVal = true;
451	if (CalculateDisplacementFromAddrMode (ScaledReg, AddrMode.Scale))
452	ScaledRegIsConstVal = true;
453
454	// The register which is not null checked should be part of the Displacement
455	// calculation, otherwise we do not know whether the Displacement is made up
456	// by some symbolic values.
457	// This matters because we do not want to incorrectly assume that load from
458	// falls in the zeroth faulting page in the "sane offset check" below.
459	if ((BaseReg && BaseReg != PointerReg && !BaseRegIsConstVal) \|\|
460	(ScaledReg && ScaledReg != PointerReg && !ScaledRegIsConstVal))
461	return SR_Unsuitable;
462
463	// We want the mem access to be issued at a sane offset from PointerReg,
464	// so that if PointerReg is null then the access reliably page faults.
465	if (!(-PageSize < Displacement && Displacement < PageSize))
466	return SR_Unsuitable;
467
468	// Finally, check whether the current memory access aliases with previous one.
469	for (auto *PrevMI : PrevInsts) {
470	AliasResult AR = areMemoryOpsAliased(MI, PrevMI);
471	if (AR == AR_WillAliasEverything)
472	return SR_Impossible;
473	if (AR == AR_MayAlias)
474	return SR_Unsuitable;
475	}
476	return SR_Suitable;
477	}
478
479	bool ImplicitNullChecks::canDependenceHoistingClobberLiveIns(
480	MachineInstr DependenceMI, MachineBasicBlock NullSucc) {
481	for (const auto &DependenceMO : DependenceMI->operands()) {
482	if (!(DependenceMO.isReg() && DependenceMO.getReg()))
483	continue;
484
485	// Make sure that we won't clobber any live ins to the sibling block by
486	// hoisting Dependency. For instance, we can't hoist INST to before the
487	// null check (even if it safe, and does not violate any dependencies in
488	// the non_null_block) if %rdx is live in to _null_block.
489	//
490	// test %rcx, %rcx
491	// je _null_block
492	// _non_null_block:
493	// %rdx = INST
494	// ...
495	//
496	// This restriction does not apply to the faulting load inst because in
497	// case the pointer loaded from is in the null page, the load will not
498	// semantically execute, and affect machine state. That is, if the load
499	// was loading into %rax and it faults, the value of %rax should stay the
500	// same as it would have been had the load not have executed and we'd have
501	// branched to NullSucc directly.
502	if (AnyAliasLiveIn(TRI, MBB: NullSucc, Reg: DependenceMO.getReg()))
503	return true;
504
505	}
506
507	// The dependence does not clobber live-ins in NullSucc block.
508	return false;
509	}
510
511	bool ImplicitNullChecks::canHoistInst(MachineInstr *FaultingMI,
512	ArrayRef<MachineInstr *> InstsSeenSoFar,
513	MachineBasicBlock *NullSucc,
514	MachineInstr *&Dependence) {
515	auto DepResult = computeDependence(MI: FaultingMI, Block: InstsSeenSoFar);
516	if (!DepResult.CanReorder)
517	return false;
518
519	if (!DepResult.PotentialDependence) {
520	Dependence = nullptr;
521	return true;
522	}
523
524	auto DependenceItr = *DepResult.PotentialDependence;
525	auto DependenceMI = DependenceItr;
526
527	// We don't want to reason about speculating loads. Note -- at this point
528	// we should have already filtered out all of the other non-speculatable
529	// things, like calls and stores.
530	// We also do not want to hoist stores because it might change the memory
531	// while the FaultingMI may result in faulting.
532	assert(canHandle(DependenceMI) && "Should never have reached here!");
533	if (DependenceMI->mayLoadOrStore())
534	return false;
535
536	if (canDependenceHoistingClobberLiveIns(DependenceMI, NullSucc))
537	return false;
538
539	auto DepDepResult =
540	computeDependence(MI: DependenceMI, Block: {InstsSeenSoFar.begin(), DependenceItr});
541
542	if (!DepDepResult.CanReorder \|\| DepDepResult.PotentialDependence)
543	return false;
544
545	Dependence = DependenceMI;
546	return true;
547	}
548
549	/// Analyze MBB to check if its terminating branch can be turned into an
550	/// implicit null check. If yes, append a description of the said null check to
551	/// NullCheckList and return true, else return false.
552	bool ImplicitNullChecks::analyzeBlockForNullChecks(
553	MachineBasicBlock &MBB, SmallVectorImpl<NullCheck> &NullCheckList) {
554	using MachineBranchPredicate = TargetInstrInfo::MachineBranchPredicate;
555
556	MDNode BranchMD = nullptr*;
557	if (auto *BB = MBB.getBasicBlock())
558	BranchMD = BB->getTerminator()->getMetadata(KindID: LLVMContext::MD_make_implicit);
559
560	if (!BranchMD)
561	return false;
562
563	MachineBranchPredicate MBP;
564
565	if (TII->analyzeBranchPredicate(MBB, MBP, AllowModify: true))
566	return false;
567
568	// Is the predicate comparing an integer to zero?
569	if (!(MBP.LHS.isReg() && MBP.RHS.isImm() && MBP.RHS.getImm() == `0` &&
570	(MBP.Predicate == MachineBranchPredicate::PRED_NE \|\|
571	MBP.Predicate == MachineBranchPredicate::PRED_EQ)))
572	return false;
573
574	// If there is a separate condition generation instruction, we chose not to
575	// transform unless we can remove both condition and consuming branch.
576	if (MBP.ConditionDef && !MBP.SingleUseCondition)
577	return false;
578
579	MachineBasicBlock NotNullSucc, NullSucc;
580
581	if (MBP.Predicate == MachineBranchPredicate::PRED_NE) {
582	NotNullSucc = MBP.TrueDest;
583	NullSucc = MBP.FalseDest;
584	} else {
585	NotNullSucc = MBP.FalseDest;
586	NullSucc = MBP.TrueDest;
587	}
588
589	// We handle the simplest case for now. We can potentially do better by using
590	// the machine dominator tree.
591	if (NotNullSucc->pred_size() != `1`)
592	return false;
593
594	const Register PointerReg = MBP.LHS.getReg();
595
596	if (MBP.ConditionDef) {
597	// To prevent the invalid transformation of the following code:
598	//
599	// mov %rax, %rcx
600	// test %rax, %rax
601	// %rax = ...
602	// je throw_npe
603	// mov(%rcx), %r9
604	// mov(%rax), %r10
605	//
606	// into:
607	//
608	// mov %rax, %rcx
609	// %rax = ....
610	// faulting_load_op("movl (%rax), %r10", throw_npe)
611	// mov(%rcx), %r9
612	//
613	// we must ensure that there are no instructions between the 'test' and
614	// conditional jump that modify %rax.
615	assert(MBP.ConditionDef->getParent() == &MBB &&
616	"Should be in basic block");
617
618	for (auto I = MBB.rbegin(); MBP.ConditionDef != &*I; ++I)
619	if (I ->modifiesRegister(Reg: PointerReg, TRI))
620	return false;
621	}
622	// Starting with a code fragment like:
623	//
624	// test %rax, %rax
625	// jne LblNotNull
626	//
627	// LblNull:
628	// callq throw_NullPointerException
629	//
630	// LblNotNull:
631	// Inst0
632	// Inst1
633	// ...
634	// Def = Load (%rax + <offset>)
635	// ...
636	//
637	//
638	// we want to end up with
639	//
640	// Def = FaultingLoad (%rax + <offset>), LblNull
641	// jmp LblNotNull ;; explicit or fallthrough
642	//
643	// LblNotNull:
644	// Inst0
645	// Inst1
646	// ...
647	//
648	// LblNull:
649	// callq throw_NullPointerException
650	//
651	//
652	// To see why this is legal, consider the two possibilities:
653	//
654	// 1. %rax is null: since we constrain <offset> to be less than PageSize, the
655	// load instruction dereferences the null page, causing a segmentation
656	// fault.
657	//
658	// 2. %rax is not null: in this case we know that the load cannot fault, as
659	// otherwise the load would've faulted in the original program too and the
660	// original program would've been undefined.
661	//
662	// This reasoning cannot be extended to justify hoisting through arbitrary
663	// control flow. For instance, in the example below (in pseudo-C)
664	//
665	// if (ptr == null) { throw_npe(); unreachable; }
666	// if (some_cond) { return 42; }
667	// v = ptr->field; // LD
668	// ...
669	//
670	// we cannot (without code duplication) use the load marked "LD" to null check
671	// ptr -- clause (2) above does not apply in this case. In the above program
672	// the safety of ptr->field can be dependent on some_cond; and, for instance,
673	// ptr could be some non-null invalid reference that never gets loaded from
674	// because some_cond is always true.
675
676	SmallVector<MachineInstr *, `8`> InstsSeenSoFar;
677
678	for (auto &MI : *NotNullSucc) {
679	if (!canHandle(MI: &MI) \|\| InstsSeenSoFar.size() >= MaxInstsToConsider)
680	return false;
681
682	MachineInstr *Dependence;
683	SuitabilityResult SR = isSuitableMemoryOp(MI, PointerReg, PrevInsts: InstsSeenSoFar);
684	if (SR == SR_Impossible)
685	return false;
686	if (SR == SR_Suitable &&
687	canHoistInst(FaultingMI: &MI, InstsSeenSoFar, NullSucc, Dependence)) {
688	NullCheckList.emplace_back(Args: &MI, Args&: MBP.ConditionDef, Args: &MBB, Args&: NotNullSucc,
689	Args&: NullSucc, Args&: Dependence);
690	return true;
691	}
692
693	// If MI re-defines the PointerReg in a way that changes the value of
694	// PointerReg if it was null, then we cannot move further.
695	if (!TII->preservesZeroValueInReg(MI: &MI, NullValueReg: PointerReg, TRI))
696	return false;
697	InstsSeenSoFar.push_back(Elt: &MI);
698	}
699
700	return false;
701	}
702
703	/// Wrap a machine instruction, MI, into a FAULTING machine instruction.
704	/// The FAULTING instruction does the same load/store as MI
705	/// (defining the same register), and branches to HandlerMBB if the mem access
706	/// faults. The FAULTING instruction is inserted at the end of MBB.
707	MachineInstr *ImplicitNullChecks::insertFaultingInstr(
708	MachineInstr MI, MachineBasicBlock MBB, MachineBasicBlock *HandlerMBB) {
709	const unsigned NoRegister = `0`; // Guaranteed to be the NoRegister value for
710	// all targets.
711
712	DebugLoc DL;
713	unsigned NumDefs = MI->getDesc().getNumDefs();
714	assert(NumDefs <= `1` && "other cases unhandled!");
715
716	unsigned DefReg = NoRegister;
717	if (NumDefs != `0`) {
718	DefReg = MI->getOperand(i: `0`).getReg();
719	assert(NumDefs == `1` && "expected exactly one def!");
720	}
721
722	FaultMaps::FaultKind FK;
723	if (MI->mayLoad())
724	FK =
725	MI->mayStore() ? FaultMaps::FaultingLoadStore : FaultMaps::FaultingLoad;
726	else
727	FK = FaultMaps::FaultingStore;
728
729	auto MIB = BuildMI(BB: MBB, MIMD: DL, MCID: TII->get(Opcode: TargetOpcode::FAULTING_OP), DestReg: DefReg)
730	.addImm(Val: FK)
731	.addMBB(MBB: HandlerMBB)
732	.addImm(Val: MI->getOpcode());
733
734	for (auto &MO : MI->uses()) {
735	if (MO.isReg()) {
736	MachineOperand NewMO = MO;
737	if (MO.isUse()) {
738	NewMO.setIsKill(false);
739	} else {
740	assert(MO.isDef() && "Expected def or use");
741	NewMO.setIsDead(false);
742	}
743	MIB.add(MO: NewMO);
744	} else {
745	MIB.add(MO);
746	}
747	}
748
749	MIB.setMemRefs(MI->memoperands());
750
751	return MIB;
752	}
753
754	/// Rewrite the null checks in NullCheckList into implicit null checks.
755	void ImplicitNullChecks::rewriteNullChecks(
756	ArrayRef<ImplicitNullChecks::NullCheck> NullCheckList) {
757	DebugLoc DL;
758
759	for (const auto &NC : NullCheckList) {
760	// Remove the conditional branch dependent on the null check.
761	unsigned BranchesRemoved = TII->removeBranch(MBB&: *NC.getCheckBlock());
762	(void)BranchesRemoved;
763	assert(BranchesRemoved > `0` && "expected at least one branch!");
764
765	if (auto *DepMI = NC.getOnlyDependency()) {
766	DepMI->removeFromParent();
767	NC.getCheckBlock()->insert(I: NC.getCheckBlock()->end(), MI: DepMI);
768	}
769
770	// Insert a faulting instruction where the conditional branch was
771	// originally. We check earlier ensures that this bit of code motion
772	// is legal. We do not touch the successors list for any basic block
773	// since we haven't changed control flow, we've just made it implicit.
774	MachineInstr *FaultingInstr = insertFaultingInstr(
775	MI: NC.getMemOperation(), MBB: NC.getCheckBlock(), HandlerMBB: NC.getNullSucc());
776	// Now the values defined by MemOperation, if any, are live-in of
777	// the block of MemOperation.
778	// The original operation may define implicit-defs alongside
779	// the value.
780	MachineBasicBlock *MBB = NC.getMemOperation()->getParent();
781	for (const MachineOperand &MO : FaultingInstr->all_defs()) {
782	Register Reg = MO.getReg();
783	if (!Reg \|\| MBB->isLiveIn(Reg))
784	continue;
785	MBB->addLiveIn(PhysReg: Reg);
786	}
787
788	if (auto *DepMI = NC.getOnlyDependency()) {
789	for (auto &MO : DepMI->all_defs()) {
790	if (!MO.getReg() \|\| MO.isDead())
791	continue;
792	if (!NC.getNotNullSucc()->isLiveIn(Reg: MO.getReg()))
793	NC.getNotNullSucc()->addLiveIn(PhysReg: MO.getReg());
794	}
795	}
796
797	NC.getMemOperation()->eraseFromParent();
798	if (auto *CheckOp = NC.getCheckOperation())
799	CheckOp->eraseFromParent();
800
801	// Insert an unconditional* branch to not-null successor - we expect*
802	// block placement to remove fallthroughs later.
803	TII->insertBranch(MBB&: NC.getCheckBlock(), TBB: NC.getNotNullSucc(), FBB: nullptr*,
804	/Cond=/std::nullopt, DL);
805
806	NumImplicitNullChecks ++;
807	}
808	}
809
810	char ImplicitNullChecks::ID = `0`;
811
812	char &llvm::ImplicitNullChecksID = ImplicitNullChecks::ID;
813
814	INITIALIZE_PASS_BEGIN(ImplicitNullChecks, DEBUG_TYPE,
815	"Implicit null checks", false, false)
816	INITIALIZE_PASS_DEPENDENCY(AAResultsWrapperPass)
817	INITIALIZE_PASS_END(ImplicitNullChecks, DEBUG_TYPE,
818	"Implicit null checks", false, false)
819

source code of llvm/lib/CodeGen/ImplicitNullChecks.cpp