[Alignment][NFC] Convert StoreInst to MaybeAlign
[llvm-complete.git] / include / llvm / IR / ModuleSummaryIndex.h
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1 //===- llvm/ModuleSummaryIndex.h - Module Summary Index ---------*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 /// @file
10 /// ModuleSummaryIndex.h This file contains the declarations the classes that
11 /// hold the module index and summary for function importing.
13 //===----------------------------------------------------------------------===//
15 #ifndef LLVM_IR_MODULESUMMARYINDEX_H
16 #define LLVM_IR_MODULESUMMARYINDEX_H
18 #include "llvm/ADT/ArrayRef.h"
19 #include "llvm/ADT/DenseMap.h"
20 #include "llvm/ADT/STLExtras.h"
21 #include "llvm/ADT/SmallString.h"
22 #include "llvm/ADT/StringExtras.h"
23 #include "llvm/ADT/StringMap.h"
24 #include "llvm/ADT/StringRef.h"
25 #include "llvm/ADT/TinyPtrVector.h"
26 #include "llvm/IR/GlobalValue.h"
27 #include "llvm/IR/Module.h"
28 #include "llvm/Support/Allocator.h"
29 #include "llvm/Support/MathExtras.h"
30 #include "llvm/Support/ScaledNumber.h"
31 #include "llvm/Support/StringSaver.h"
32 #include <algorithm>
33 #include <array>
34 #include <cassert>
35 #include <cstddef>
36 #include <cstdint>
37 #include <map>
38 #include <memory>
39 #include <set>
40 #include <string>
41 #include <utility>
42 #include <vector>
44 namespace llvm {
46 namespace yaml {
48 template <typename T> struct MappingTraits;
50 } // end namespace yaml
52 /// Class to accumulate and hold information about a callee.
53 struct CalleeInfo {
54 enum class HotnessType : uint8_t {
55 Unknown = 0,
56 Cold = 1,
57 None = 2,
58 Hot = 3,
59 Critical = 4
62 // The size of the bit-field might need to be adjusted if more values are
63 // added to HotnessType enum.
64 uint32_t Hotness : 3;
66 /// The value stored in RelBlockFreq has to be interpreted as the digits of
67 /// a scaled number with a scale of \p -ScaleShift.
68 uint32_t RelBlockFreq : 29;
69 static constexpr int32_t ScaleShift = 8;
70 static constexpr uint64_t MaxRelBlockFreq = (1 << 29) - 1;
72 CalleeInfo()
73 : Hotness(static_cast<uint32_t>(HotnessType::Unknown)), RelBlockFreq(0) {}
74 explicit CalleeInfo(HotnessType Hotness, uint64_t RelBF)
75 : Hotness(static_cast<uint32_t>(Hotness)), RelBlockFreq(RelBF) {}
77 void updateHotness(const HotnessType OtherHotness) {
78 Hotness = std::max(Hotness, static_cast<uint32_t>(OtherHotness));
81 HotnessType getHotness() const { return HotnessType(Hotness); }
83 /// Update \p RelBlockFreq from \p BlockFreq and \p EntryFreq
84 ///
85 /// BlockFreq is divided by EntryFreq and added to RelBlockFreq. To represent
86 /// fractional values, the result is represented as a fixed point number with
87 /// scale of -ScaleShift.
88 void updateRelBlockFreq(uint64_t BlockFreq, uint64_t EntryFreq) {
89 if (EntryFreq == 0)
90 return;
91 using Scaled64 = ScaledNumber<uint64_t>;
92 Scaled64 Temp(BlockFreq, ScaleShift);
93 Temp /= Scaled64::get(EntryFreq);
95 uint64_t Sum =
96 SaturatingAdd<uint64_t>(Temp.toInt<uint64_t>(), RelBlockFreq);
97 Sum = std::min(Sum, uint64_t(MaxRelBlockFreq));
98 RelBlockFreq = static_cast<uint32_t>(Sum);
102 inline const char *getHotnessName(CalleeInfo::HotnessType HT) {
103 switch (HT) {
104 case CalleeInfo::HotnessType::Unknown:
105 return "unknown";
106 case CalleeInfo::HotnessType::Cold:
107 return "cold";
108 case CalleeInfo::HotnessType::None:
109 return "none";
110 case CalleeInfo::HotnessType::Hot:
111 return "hot";
112 case CalleeInfo::HotnessType::Critical:
113 return "critical";
115 llvm_unreachable("invalid hotness");
118 class GlobalValueSummary;
120 using GlobalValueSummaryList = std::vector<std::unique_ptr<GlobalValueSummary>>;
122 struct alignas(8) GlobalValueSummaryInfo {
123 union NameOrGV {
124 NameOrGV(bool HaveGVs) {
125 if (HaveGVs)
126 GV = nullptr;
127 else
128 Name = "";
131 /// The GlobalValue corresponding to this summary. This is only used in
132 /// per-module summaries and when the IR is available. E.g. when module
133 /// analysis is being run, or when parsing both the IR and the summary
134 /// from assembly.
135 const GlobalValue *GV;
137 /// Summary string representation. This StringRef points to BC module
138 /// string table and is valid until module data is stored in memory.
139 /// This is guaranteed to happen until runThinLTOBackend function is
140 /// called, so it is safe to use this field during thin link. This field
141 /// is only valid if summary index was loaded from BC file.
142 StringRef Name;
143 } U;
145 GlobalValueSummaryInfo(bool HaveGVs) : U(HaveGVs) {}
147 /// List of global value summary structures for a particular value held
148 /// in the GlobalValueMap. Requires a vector in the case of multiple
149 /// COMDAT values of the same name.
150 GlobalValueSummaryList SummaryList;
153 /// Map from global value GUID to corresponding summary structures. Use a
154 /// std::map rather than a DenseMap so that pointers to the map's value_type
155 /// (which are used by ValueInfo) are not invalidated by insertion. Also it will
156 /// likely incur less overhead, as the value type is not very small and the size
157 /// of the map is unknown, resulting in inefficiencies due to repeated
158 /// insertions and resizing.
159 using GlobalValueSummaryMapTy =
160 std::map<GlobalValue::GUID, GlobalValueSummaryInfo>;
162 /// Struct that holds a reference to a particular GUID in a global value
163 /// summary.
164 struct ValueInfo {
165 enum Flags { HaveGV = 1, ReadOnly = 2, WriteOnly = 4 };
166 PointerIntPair<const GlobalValueSummaryMapTy::value_type *, 3, int>
167 RefAndFlags;
169 ValueInfo() = default;
170 ValueInfo(bool HaveGVs, const GlobalValueSummaryMapTy::value_type *R) {
171 RefAndFlags.setPointer(R);
172 RefAndFlags.setInt(HaveGVs);
175 operator bool() const { return getRef(); }
177 GlobalValue::GUID getGUID() const { return getRef()->first; }
178 const GlobalValue *getValue() const {
179 assert(haveGVs());
180 return getRef()->second.U.GV;
183 ArrayRef<std::unique_ptr<GlobalValueSummary>> getSummaryList() const {
184 return getRef()->second.SummaryList;
187 StringRef name() const {
188 return haveGVs() ? getRef()->second.U.GV->getName()
189 : getRef()->second.U.Name;
192 bool haveGVs() const { return RefAndFlags.getInt() & HaveGV; }
193 bool isReadOnly() const {
194 assert(isValidAccessSpecifier());
195 return RefAndFlags.getInt() & ReadOnly;
197 bool isWriteOnly() const {
198 assert(isValidAccessSpecifier());
199 return RefAndFlags.getInt() & WriteOnly;
201 unsigned getAccessSpecifier() const {
202 assert(isValidAccessSpecifier());
203 return RefAndFlags.getInt() & (ReadOnly | WriteOnly);
205 bool isValidAccessSpecifier() const {
206 unsigned BadAccessMask = ReadOnly | WriteOnly;
207 return (RefAndFlags.getInt() & BadAccessMask) != BadAccessMask;
209 void setReadOnly() {
210 // We expect ro/wo attribute to set only once during
211 // ValueInfo lifetime.
212 assert(getAccessSpecifier() == 0);
213 RefAndFlags.setInt(RefAndFlags.getInt() | ReadOnly);
215 void setWriteOnly() {
216 assert(getAccessSpecifier() == 0);
217 RefAndFlags.setInt(RefAndFlags.getInt() | WriteOnly);
220 const GlobalValueSummaryMapTy::value_type *getRef() const {
221 return RefAndFlags.getPointer();
224 bool isDSOLocal() const;
226 /// Checks if all copies are eligible for auto-hiding (have flag set).
227 bool canAutoHide() const;
230 inline raw_ostream &operator<<(raw_ostream &OS, const ValueInfo &VI) {
231 OS << VI.getGUID();
232 if (!VI.name().empty())
233 OS << " (" << VI.name() << ")";
234 return OS;
237 inline bool operator==(const ValueInfo &A, const ValueInfo &B) {
238 assert(A.getRef() && B.getRef() &&
239 "Need ValueInfo with non-null Ref for comparison");
240 return A.getRef() == B.getRef();
243 inline bool operator!=(const ValueInfo &A, const ValueInfo &B) {
244 assert(A.getRef() && B.getRef() &&
245 "Need ValueInfo with non-null Ref for comparison");
246 return A.getRef() != B.getRef();
249 inline bool operator<(const ValueInfo &A, const ValueInfo &B) {
250 assert(A.getRef() && B.getRef() &&
251 "Need ValueInfo with non-null Ref to compare GUIDs");
252 return A.getGUID() < B.getGUID();
255 template <> struct DenseMapInfo<ValueInfo> {
256 static inline ValueInfo getEmptyKey() {
257 return ValueInfo(false, (GlobalValueSummaryMapTy::value_type *)-8);
260 static inline ValueInfo getTombstoneKey() {
261 return ValueInfo(false, (GlobalValueSummaryMapTy::value_type *)-16);
264 static inline bool isSpecialKey(ValueInfo V) {
265 return V == getTombstoneKey() || V == getEmptyKey();
268 static bool isEqual(ValueInfo L, ValueInfo R) {
269 // We are not supposed to mix ValueInfo(s) with different HaveGVs flag
270 // in a same container.
271 assert(isSpecialKey(L) || isSpecialKey(R) || (L.haveGVs() == R.haveGVs()));
272 return L.getRef() == R.getRef();
274 static unsigned getHashValue(ValueInfo I) { return (uintptr_t)I.getRef(); }
277 /// Function and variable summary information to aid decisions and
278 /// implementation of importing.
279 class GlobalValueSummary {
280 public:
281 /// Sububclass discriminator (for dyn_cast<> et al.)
282 enum SummaryKind : unsigned { AliasKind, FunctionKind, GlobalVarKind };
284 /// Group flags (Linkage, NotEligibleToImport, etc.) as a bitfield.
285 struct GVFlags {
286 /// The linkage type of the associated global value.
288 /// One use is to flag values that have local linkage types and need to
289 /// have module identifier appended before placing into the combined
290 /// index, to disambiguate from other values with the same name.
291 /// In the future this will be used to update and optimize linkage
292 /// types based on global summary-based analysis.
293 unsigned Linkage : 4;
295 /// Indicate if the global value cannot be imported (e.g. it cannot
296 /// be renamed or references something that can't be renamed).
297 unsigned NotEligibleToImport : 1;
299 /// In per-module summary, indicate that the global value must be considered
300 /// a live root for index-based liveness analysis. Used for special LLVM
301 /// values such as llvm.global_ctors that the linker does not know about.
303 /// In combined summary, indicate that the global value is live.
304 unsigned Live : 1;
306 /// Indicates that the linker resolved the symbol to a definition from
307 /// within the same linkage unit.
308 unsigned DSOLocal : 1;
310 /// In the per-module summary, indicates that the global value is
311 /// linkonce_odr and global unnamed addr (so eligible for auto-hiding
312 /// via hidden visibility). In the combined summary, indicates that the
313 /// prevailing linkonce_odr copy can be auto-hidden via hidden visibility
314 /// when it is upgraded to weak_odr in the backend. This is legal when
315 /// all copies are eligible for auto-hiding (i.e. all copies were
316 /// linkonce_odr global unnamed addr. If any copy is not (e.g. it was
317 /// originally weak_odr, we cannot auto-hide the prevailing copy as it
318 /// means the symbol was externally visible.
319 unsigned CanAutoHide : 1;
321 /// Convenience Constructors
322 explicit GVFlags(GlobalValue::LinkageTypes Linkage,
323 bool NotEligibleToImport, bool Live, bool IsLocal,
324 bool CanAutoHide)
325 : Linkage(Linkage), NotEligibleToImport(NotEligibleToImport),
326 Live(Live), DSOLocal(IsLocal), CanAutoHide(CanAutoHide) {}
329 private:
330 /// Kind of summary for use in dyn_cast<> et al.
331 SummaryKind Kind;
333 GVFlags Flags;
335 /// This is the hash of the name of the symbol in the original file. It is
336 /// identical to the GUID for global symbols, but differs for local since the
337 /// GUID includes the module level id in the hash.
338 GlobalValue::GUID OriginalName = 0;
340 /// Path of module IR containing value's definition, used to locate
341 /// module during importing.
343 /// This is only used during parsing of the combined index, or when
344 /// parsing the per-module index for creation of the combined summary index,
345 /// not during writing of the per-module index which doesn't contain a
346 /// module path string table.
347 StringRef ModulePath;
349 /// List of values referenced by this global value's definition
350 /// (either by the initializer of a global variable, or referenced
351 /// from within a function). This does not include functions called, which
352 /// are listed in the derived FunctionSummary object.
353 std::vector<ValueInfo> RefEdgeList;
355 protected:
356 GlobalValueSummary(SummaryKind K, GVFlags Flags, std::vector<ValueInfo> Refs)
357 : Kind(K), Flags(Flags), RefEdgeList(std::move(Refs)) {
358 assert((K != AliasKind || Refs.empty()) &&
359 "Expect no references for AliasSummary");
362 public:
363 virtual ~GlobalValueSummary() = default;
365 /// Returns the hash of the original name, it is identical to the GUID for
366 /// externally visible symbols, but not for local ones.
367 GlobalValue::GUID getOriginalName() const { return OriginalName; }
369 /// Initialize the original name hash in this summary.
370 void setOriginalName(GlobalValue::GUID Name) { OriginalName = Name; }
372 /// Which kind of summary subclass this is.
373 SummaryKind getSummaryKind() const { return Kind; }
375 /// Set the path to the module containing this function, for use in
376 /// the combined index.
377 void setModulePath(StringRef ModPath) { ModulePath = ModPath; }
379 /// Get the path to the module containing this function.
380 StringRef modulePath() const { return ModulePath; }
382 /// Get the flags for this GlobalValue (see \p struct GVFlags).
383 GVFlags flags() const { return Flags; }
385 /// Return linkage type recorded for this global value.
386 GlobalValue::LinkageTypes linkage() const {
387 return static_cast<GlobalValue::LinkageTypes>(Flags.Linkage);
390 /// Sets the linkage to the value determined by global summary-based
391 /// optimization. Will be applied in the ThinLTO backends.
392 void setLinkage(GlobalValue::LinkageTypes Linkage) {
393 Flags.Linkage = Linkage;
396 /// Return true if this global value can't be imported.
397 bool notEligibleToImport() const { return Flags.NotEligibleToImport; }
399 bool isLive() const { return Flags.Live; }
401 void setLive(bool Live) { Flags.Live = Live; }
403 void setDSOLocal(bool Local) { Flags.DSOLocal = Local; }
405 bool isDSOLocal() const { return Flags.DSOLocal; }
407 void setCanAutoHide(bool CanAutoHide) { Flags.CanAutoHide = CanAutoHide; }
409 bool canAutoHide() const { return Flags.CanAutoHide; }
411 /// Flag that this global value cannot be imported.
412 void setNotEligibleToImport() { Flags.NotEligibleToImport = true; }
414 /// Return the list of values referenced by this global value definition.
415 ArrayRef<ValueInfo> refs() const { return RefEdgeList; }
417 /// If this is an alias summary, returns the summary of the aliased object (a
418 /// global variable or function), otherwise returns itself.
419 GlobalValueSummary *getBaseObject();
420 const GlobalValueSummary *getBaseObject() const;
422 friend class ModuleSummaryIndex;
425 /// Alias summary information.
426 class AliasSummary : public GlobalValueSummary {
427 ValueInfo AliaseeValueInfo;
429 /// This is the Aliasee in the same module as alias (could get from VI, trades
430 /// memory for time). Note that this pointer may be null (and the value info
431 /// empty) when we have a distributed index where the alias is being imported
432 /// (as a copy of the aliasee), but the aliasee is not.
433 GlobalValueSummary *AliaseeSummary;
435 public:
436 AliasSummary(GVFlags Flags)
437 : GlobalValueSummary(AliasKind, Flags, ArrayRef<ValueInfo>{}),
438 AliaseeSummary(nullptr) {}
440 /// Check if this is an alias summary.
441 static bool classof(const GlobalValueSummary *GVS) {
442 return GVS->getSummaryKind() == AliasKind;
445 void setAliasee(ValueInfo &AliaseeVI, GlobalValueSummary *Aliasee) {
446 AliaseeValueInfo = AliaseeVI;
447 AliaseeSummary = Aliasee;
450 bool hasAliasee() const {
451 assert(!!AliaseeSummary == (AliaseeValueInfo &&
452 !AliaseeValueInfo.getSummaryList().empty()) &&
453 "Expect to have both aliasee summary and summary list or neither");
454 return !!AliaseeSummary;
457 const GlobalValueSummary &getAliasee() const {
458 assert(AliaseeSummary && "Unexpected missing aliasee summary");
459 return *AliaseeSummary;
462 GlobalValueSummary &getAliasee() {
463 return const_cast<GlobalValueSummary &>(
464 static_cast<const AliasSummary *>(this)->getAliasee());
466 ValueInfo getAliaseeVI() const {
467 assert(AliaseeValueInfo && "Unexpected missing aliasee");
468 return AliaseeValueInfo;
470 GlobalValue::GUID getAliaseeGUID() const {
471 assert(AliaseeValueInfo && "Unexpected missing aliasee");
472 return AliaseeValueInfo.getGUID();
476 const inline GlobalValueSummary *GlobalValueSummary::getBaseObject() const {
477 if (auto *AS = dyn_cast<AliasSummary>(this))
478 return &AS->getAliasee();
479 return this;
482 inline GlobalValueSummary *GlobalValueSummary::getBaseObject() {
483 if (auto *AS = dyn_cast<AliasSummary>(this))
484 return &AS->getAliasee();
485 return this;
488 /// Function summary information to aid decisions and implementation of
489 /// importing.
490 class FunctionSummary : public GlobalValueSummary {
491 public:
492 /// <CalleeValueInfo, CalleeInfo> call edge pair.
493 using EdgeTy = std::pair<ValueInfo, CalleeInfo>;
495 /// Types for -force-summary-edges-cold debugging option.
496 enum ForceSummaryHotnessType : unsigned {
497 FSHT_None,
498 FSHT_AllNonCritical,
499 FSHT_All
502 /// An "identifier" for a virtual function. This contains the type identifier
503 /// represented as a GUID and the offset from the address point to the virtual
504 /// function pointer, where "address point" is as defined in the Itanium ABI:
505 /// https://itanium-cxx-abi.github.io/cxx-abi/abi.html#vtable-general
506 struct VFuncId {
507 GlobalValue::GUID GUID;
508 uint64_t Offset;
511 /// A specification for a virtual function call with all constant integer
512 /// arguments. This is used to perform virtual constant propagation on the
513 /// summary.
514 struct ConstVCall {
515 VFuncId VFunc;
516 std::vector<uint64_t> Args;
519 /// All type identifier related information. Because these fields are
520 /// relatively uncommon we only allocate space for them if necessary.
521 struct TypeIdInfo {
522 /// List of type identifiers used by this function in llvm.type.test
523 /// intrinsics referenced by something other than an llvm.assume intrinsic,
524 /// represented as GUIDs.
525 std::vector<GlobalValue::GUID> TypeTests;
527 /// List of virtual calls made by this function using (respectively)
528 /// llvm.assume(llvm.type.test) or llvm.type.checked.load intrinsics that do
529 /// not have all constant integer arguments.
530 std::vector<VFuncId> TypeTestAssumeVCalls, TypeCheckedLoadVCalls;
532 /// List of virtual calls made by this function using (respectively)
533 /// llvm.assume(llvm.type.test) or llvm.type.checked.load intrinsics with
534 /// all constant integer arguments.
535 std::vector<ConstVCall> TypeTestAssumeConstVCalls,
536 TypeCheckedLoadConstVCalls;
539 /// Flags specific to function summaries.
540 struct FFlags {
541 // Function attribute flags. Used to track if a function accesses memory,
542 // recurses or aliases.
543 unsigned ReadNone : 1;
544 unsigned ReadOnly : 1;
545 unsigned NoRecurse : 1;
546 unsigned ReturnDoesNotAlias : 1;
548 // Indicate if the global value cannot be inlined.
549 unsigned NoInline : 1;
552 /// Create an empty FunctionSummary (with specified call edges).
553 /// Used to represent external nodes and the dummy root node.
554 static FunctionSummary
555 makeDummyFunctionSummary(std::vector<FunctionSummary::EdgeTy> Edges) {
556 return FunctionSummary(
557 FunctionSummary::GVFlags(
558 GlobalValue::LinkageTypes::AvailableExternallyLinkage,
559 /*NotEligibleToImport=*/true, /*Live=*/true, /*IsLocal=*/false,
560 /*CanAutoHide=*/false),
561 /*InsCount=*/0, FunctionSummary::FFlags{}, /*EntryCount=*/0,
562 std::vector<ValueInfo>(), std::move(Edges),
563 std::vector<GlobalValue::GUID>(),
564 std::vector<FunctionSummary::VFuncId>(),
565 std::vector<FunctionSummary::VFuncId>(),
566 std::vector<FunctionSummary::ConstVCall>(),
567 std::vector<FunctionSummary::ConstVCall>());
570 /// A dummy node to reference external functions that aren't in the index
571 static FunctionSummary ExternalNode;
573 private:
574 /// Number of instructions (ignoring debug instructions, e.g.) computed
575 /// during the initial compile step when the summary index is first built.
576 unsigned InstCount;
578 /// Function summary specific flags.
579 FFlags FunFlags;
581 /// The synthesized entry count of the function.
582 /// This is only populated during ThinLink phase and remains unused while
583 /// generating per-module summaries.
584 uint64_t EntryCount = 0;
586 /// List of <CalleeValueInfo, CalleeInfo> call edge pairs from this function.
587 std::vector<EdgeTy> CallGraphEdgeList;
589 std::unique_ptr<TypeIdInfo> TIdInfo;
591 public:
592 FunctionSummary(GVFlags Flags, unsigned NumInsts, FFlags FunFlags,
593 uint64_t EntryCount, std::vector<ValueInfo> Refs,
594 std::vector<EdgeTy> CGEdges,
595 std::vector<GlobalValue::GUID> TypeTests,
596 std::vector<VFuncId> TypeTestAssumeVCalls,
597 std::vector<VFuncId> TypeCheckedLoadVCalls,
598 std::vector<ConstVCall> TypeTestAssumeConstVCalls,
599 std::vector<ConstVCall> TypeCheckedLoadConstVCalls)
600 : GlobalValueSummary(FunctionKind, Flags, std::move(Refs)),
601 InstCount(NumInsts), FunFlags(FunFlags), EntryCount(EntryCount),
602 CallGraphEdgeList(std::move(CGEdges)) {
603 if (!TypeTests.empty() || !TypeTestAssumeVCalls.empty() ||
604 !TypeCheckedLoadVCalls.empty() || !TypeTestAssumeConstVCalls.empty() ||
605 !TypeCheckedLoadConstVCalls.empty())
606 TIdInfo = std::make_unique<TypeIdInfo>(TypeIdInfo{
607 std::move(TypeTests), std::move(TypeTestAssumeVCalls),
608 std::move(TypeCheckedLoadVCalls),
609 std::move(TypeTestAssumeConstVCalls),
610 std::move(TypeCheckedLoadConstVCalls)});
612 // Gets the number of readonly and writeonly refs in RefEdgeList
613 std::pair<unsigned, unsigned> specialRefCounts() const;
615 /// Check if this is a function summary.
616 static bool classof(const GlobalValueSummary *GVS) {
617 return GVS->getSummaryKind() == FunctionKind;
620 /// Get function summary flags.
621 FFlags fflags() const { return FunFlags; }
623 /// Get the instruction count recorded for this function.
624 unsigned instCount() const { return InstCount; }
626 /// Get the synthetic entry count for this function.
627 uint64_t entryCount() const { return EntryCount; }
629 /// Set the synthetic entry count for this function.
630 void setEntryCount(uint64_t EC) { EntryCount = EC; }
632 /// Return the list of <CalleeValueInfo, CalleeInfo> pairs.
633 ArrayRef<EdgeTy> calls() const { return CallGraphEdgeList; }
635 void addCall(EdgeTy E) { CallGraphEdgeList.push_back(E); }
637 /// Returns the list of type identifiers used by this function in
638 /// llvm.type.test intrinsics other than by an llvm.assume intrinsic,
639 /// represented as GUIDs.
640 ArrayRef<GlobalValue::GUID> type_tests() const {
641 if (TIdInfo)
642 return TIdInfo->TypeTests;
643 return {};
646 /// Returns the list of virtual calls made by this function using
647 /// llvm.assume(llvm.type.test) intrinsics that do not have all constant
648 /// integer arguments.
649 ArrayRef<VFuncId> type_test_assume_vcalls() const {
650 if (TIdInfo)
651 return TIdInfo->TypeTestAssumeVCalls;
652 return {};
655 /// Returns the list of virtual calls made by this function using
656 /// llvm.type.checked.load intrinsics that do not have all constant integer
657 /// arguments.
658 ArrayRef<VFuncId> type_checked_load_vcalls() const {
659 if (TIdInfo)
660 return TIdInfo->TypeCheckedLoadVCalls;
661 return {};
664 /// Returns the list of virtual calls made by this function using
665 /// llvm.assume(llvm.type.test) intrinsics with all constant integer
666 /// arguments.
667 ArrayRef<ConstVCall> type_test_assume_const_vcalls() const {
668 if (TIdInfo)
669 return TIdInfo->TypeTestAssumeConstVCalls;
670 return {};
673 /// Returns the list of virtual calls made by this function using
674 /// llvm.type.checked.load intrinsics with all constant integer arguments.
675 ArrayRef<ConstVCall> type_checked_load_const_vcalls() const {
676 if (TIdInfo)
677 return TIdInfo->TypeCheckedLoadConstVCalls;
678 return {};
681 /// Add a type test to the summary. This is used by WholeProgramDevirt if we
682 /// were unable to devirtualize a checked call.
683 void addTypeTest(GlobalValue::GUID Guid) {
684 if (!TIdInfo)
685 TIdInfo = std::make_unique<TypeIdInfo>();
686 TIdInfo->TypeTests.push_back(Guid);
689 const TypeIdInfo *getTypeIdInfo() const { return TIdInfo.get(); };
691 friend struct GraphTraits<ValueInfo>;
694 template <> struct DenseMapInfo<FunctionSummary::VFuncId> {
695 static FunctionSummary::VFuncId getEmptyKey() { return {0, uint64_t(-1)}; }
697 static FunctionSummary::VFuncId getTombstoneKey() {
698 return {0, uint64_t(-2)};
701 static bool isEqual(FunctionSummary::VFuncId L, FunctionSummary::VFuncId R) {
702 return L.GUID == R.GUID && L.Offset == R.Offset;
705 static unsigned getHashValue(FunctionSummary::VFuncId I) { return I.GUID; }
708 template <> struct DenseMapInfo<FunctionSummary::ConstVCall> {
709 static FunctionSummary::ConstVCall getEmptyKey() {
710 return {{0, uint64_t(-1)}, {}};
713 static FunctionSummary::ConstVCall getTombstoneKey() {
714 return {{0, uint64_t(-2)}, {}};
717 static bool isEqual(FunctionSummary::ConstVCall L,
718 FunctionSummary::ConstVCall R) {
719 return DenseMapInfo<FunctionSummary::VFuncId>::isEqual(L.VFunc, R.VFunc) &&
720 L.Args == R.Args;
723 static unsigned getHashValue(FunctionSummary::ConstVCall I) {
724 return I.VFunc.GUID;
728 /// The ValueInfo and offset for a function within a vtable definition
729 /// initializer array.
730 struct VirtFuncOffset {
731 VirtFuncOffset(ValueInfo VI, uint64_t Offset)
732 : FuncVI(VI), VTableOffset(Offset) {}
734 ValueInfo FuncVI;
735 uint64_t VTableOffset;
737 /// List of functions referenced by a particular vtable definition.
738 using VTableFuncList = std::vector<VirtFuncOffset>;
740 /// Global variable summary information to aid decisions and
741 /// implementation of importing.
743 /// Global variable summary has two extra flag, telling if it is
744 /// readonly or writeonly. Both readonly and writeonly variables
745 /// can be optimized in the backed: readonly variables can be
746 /// const-folded, while writeonly vars can be completely eliminated
747 /// together with corresponding stores. We let both things happen
748 /// by means of internalizing such variables after ThinLTO import.
749 class GlobalVarSummary : public GlobalValueSummary {
750 private:
751 /// For vtable definitions this holds the list of functions and
752 /// their corresponding offsets within the initializer array.
753 std::unique_ptr<VTableFuncList> VTableFuncs;
755 public:
756 struct GVarFlags {
757 GVarFlags(bool ReadOnly, bool WriteOnly)
758 : MaybeReadOnly(ReadOnly), MaybeWriteOnly(WriteOnly) {}
760 // In permodule summaries both MaybeReadOnly and MaybeWriteOnly
761 // bits are set, because attribute propagation occurs later on
762 // thin link phase.
763 unsigned MaybeReadOnly : 1;
764 unsigned MaybeWriteOnly : 1;
765 } VarFlags;
767 GlobalVarSummary(GVFlags Flags, GVarFlags VarFlags,
768 std::vector<ValueInfo> Refs)
769 : GlobalValueSummary(GlobalVarKind, Flags, std::move(Refs)),
770 VarFlags(VarFlags) {}
772 /// Check if this is a global variable summary.
773 static bool classof(const GlobalValueSummary *GVS) {
774 return GVS->getSummaryKind() == GlobalVarKind;
777 GVarFlags varflags() const { return VarFlags; }
778 void setReadOnly(bool RO) { VarFlags.MaybeReadOnly = RO; }
779 void setWriteOnly(bool WO) { VarFlags.MaybeWriteOnly = WO; }
780 bool maybeReadOnly() const { return VarFlags.MaybeReadOnly; }
781 bool maybeWriteOnly() const { return VarFlags.MaybeWriteOnly; }
783 void setVTableFuncs(VTableFuncList Funcs) {
784 assert(!VTableFuncs);
785 VTableFuncs = std::make_unique<VTableFuncList>(std::move(Funcs));
788 ArrayRef<VirtFuncOffset> vTableFuncs() const {
789 if (VTableFuncs)
790 return *VTableFuncs;
791 return {};
795 struct TypeTestResolution {
796 /// Specifies which kind of type check we should emit for this byte array.
797 /// See http://clang.llvm.org/docs/ControlFlowIntegrityDesign.html for full
798 /// details on each kind of check; the enumerators are described with
799 /// reference to that document.
800 enum Kind {
801 Unsat, ///< Unsatisfiable type (i.e. no global has this type metadata)
802 ByteArray, ///< Test a byte array (first example)
803 Inline, ///< Inlined bit vector ("Short Inline Bit Vectors")
804 Single, ///< Single element (last example in "Short Inline Bit Vectors")
805 AllOnes, ///< All-ones bit vector ("Eliminating Bit Vector Checks for
806 /// All-Ones Bit Vectors")
807 } TheKind = Unsat;
809 /// Range of size-1 expressed as a bit width. For example, if the size is in
810 /// range [1,256], this number will be 8. This helps generate the most compact
811 /// instruction sequences.
812 unsigned SizeM1BitWidth = 0;
814 // The following fields are only used if the target does not support the use
815 // of absolute symbols to store constants. Their meanings are the same as the
816 // corresponding fields in LowerTypeTestsModule::TypeIdLowering in
817 // LowerTypeTests.cpp.
819 uint64_t AlignLog2 = 0;
820 uint64_t SizeM1 = 0;
821 uint8_t BitMask = 0;
822 uint64_t InlineBits = 0;
825 struct WholeProgramDevirtResolution {
826 enum Kind {
827 Indir, ///< Just do a regular virtual call
828 SingleImpl, ///< Single implementation devirtualization
829 BranchFunnel, ///< When retpoline mitigation is enabled, use a branch funnel
830 ///< that is defined in the merged module. Otherwise same as
831 ///< Indir.
832 } TheKind = Indir;
834 std::string SingleImplName;
836 struct ByArg {
837 enum Kind {
838 Indir, ///< Just do a regular virtual call
839 UniformRetVal, ///< Uniform return value optimization
840 UniqueRetVal, ///< Unique return value optimization
841 VirtualConstProp, ///< Virtual constant propagation
842 } TheKind = Indir;
844 /// Additional information for the resolution:
845 /// - UniformRetVal: the uniform return value.
846 /// - UniqueRetVal: the return value associated with the unique vtable (0 or
847 /// 1).
848 uint64_t Info = 0;
850 // The following fields are only used if the target does not support the use
851 // of absolute symbols to store constants.
853 uint32_t Byte = 0;
854 uint32_t Bit = 0;
857 /// Resolutions for calls with all constant integer arguments (excluding the
858 /// first argument, "this"), where the key is the argument vector.
859 std::map<std::vector<uint64_t>, ByArg> ResByArg;
862 struct TypeIdSummary {
863 TypeTestResolution TTRes;
865 /// Mapping from byte offset to whole-program devirt resolution for that
866 /// (typeid, byte offset) pair.
867 std::map<uint64_t, WholeProgramDevirtResolution> WPDRes;
870 /// 160 bits SHA1
871 using ModuleHash = std::array<uint32_t, 5>;
873 /// Type used for iterating through the global value summary map.
874 using const_gvsummary_iterator = GlobalValueSummaryMapTy::const_iterator;
875 using gvsummary_iterator = GlobalValueSummaryMapTy::iterator;
877 /// String table to hold/own module path strings, which additionally holds the
878 /// module ID assigned to each module during the plugin step, as well as a hash
879 /// of the module. The StringMap makes a copy of and owns inserted strings.
880 using ModulePathStringTableTy = StringMap<std::pair<uint64_t, ModuleHash>>;
882 /// Map of global value GUID to its summary, used to identify values defined in
883 /// a particular module, and provide efficient access to their summary.
884 using GVSummaryMapTy = DenseMap<GlobalValue::GUID, GlobalValueSummary *>;
886 /// Map of a type GUID to type id string and summary (multimap used
887 /// in case of GUID conflicts).
888 using TypeIdSummaryMapTy =
889 std::multimap<GlobalValue::GUID, std::pair<std::string, TypeIdSummary>>;
891 /// The following data structures summarize type metadata information.
892 /// For type metadata overview see https://llvm.org/docs/TypeMetadata.html.
893 /// Each type metadata includes both the type identifier and the offset of
894 /// the address point of the type (the address held by objects of that type
895 /// which may not be the beginning of the virtual table). Vtable definitions
896 /// are decorated with type metadata for the types they are compatible with.
898 /// Holds information about vtable definitions decorated with type metadata:
899 /// the vtable definition value and its address point offset in a type
900 /// identifier metadata it is decorated (compatible) with.
901 struct TypeIdOffsetVtableInfo {
902 TypeIdOffsetVtableInfo(uint64_t Offset, ValueInfo VI)
903 : AddressPointOffset(Offset), VTableVI(VI) {}
905 uint64_t AddressPointOffset;
906 ValueInfo VTableVI;
908 /// List of vtable definitions decorated by a particular type identifier,
909 /// and their corresponding offsets in that type identifier's metadata.
910 /// Note that each type identifier may be compatible with multiple vtables, due
911 /// to inheritance, which is why this is a vector.
912 using TypeIdCompatibleVtableInfo = std::vector<TypeIdOffsetVtableInfo>;
914 /// Class to hold module path string table and global value map,
915 /// and encapsulate methods for operating on them.
916 class ModuleSummaryIndex {
917 private:
918 /// Map from value name to list of summary instances for values of that
919 /// name (may be duplicates in the COMDAT case, e.g.).
920 GlobalValueSummaryMapTy GlobalValueMap;
922 /// Holds strings for combined index, mapping to the corresponding module ID.
923 ModulePathStringTableTy ModulePathStringTable;
925 /// Mapping from type identifier GUIDs to type identifier and its summary
926 /// information. Produced by thin link.
927 TypeIdSummaryMapTy TypeIdMap;
929 /// Mapping from type identifier to information about vtables decorated
930 /// with that type identifier's metadata. Produced by per module summary
931 /// analysis and consumed by thin link. For more information, see description
932 /// above where TypeIdCompatibleVtableInfo is defined.
933 std::map<std::string, TypeIdCompatibleVtableInfo> TypeIdCompatibleVtableMap;
935 /// Mapping from original ID to GUID. If original ID can map to multiple
936 /// GUIDs, it will be mapped to 0.
937 std::map<GlobalValue::GUID, GlobalValue::GUID> OidGuidMap;
939 /// Indicates that summary-based GlobalValue GC has run, and values with
940 /// GVFlags::Live==false are really dead. Otherwise, all values must be
941 /// considered live.
942 bool WithGlobalValueDeadStripping = false;
944 /// Indicates that summary-based synthetic entry count propagation has run
945 bool HasSyntheticEntryCounts = false;
947 /// Indicates that distributed backend should skip compilation of the
948 /// module. Flag is suppose to be set by distributed ThinLTO indexing
949 /// when it detected that the module is not needed during the final
950 /// linking. As result distributed backend should just output a minimal
951 /// valid object file.
952 bool SkipModuleByDistributedBackend = false;
954 /// If true then we're performing analysis of IR module, or parsing along with
955 /// the IR from assembly. The value of 'false' means we're reading summary
956 /// from BC or YAML source. Affects the type of value stored in NameOrGV
957 /// union.
958 bool HaveGVs;
960 // True if the index was created for a module compiled with -fsplit-lto-unit.
961 bool EnableSplitLTOUnit;
963 // True if some of the modules were compiled with -fsplit-lto-unit and
964 // some were not. Set when the combined index is created during the thin link.
965 bool PartiallySplitLTOUnits = false;
967 std::set<std::string> CfiFunctionDefs;
968 std::set<std::string> CfiFunctionDecls;
970 // Used in cases where we want to record the name of a global, but
971 // don't have the string owned elsewhere (e.g. the Strtab on a module).
972 StringSaver Saver;
973 BumpPtrAllocator Alloc;
975 // YAML I/O support.
976 friend yaml::MappingTraits<ModuleSummaryIndex>;
978 GlobalValueSummaryMapTy::value_type *
979 getOrInsertValuePtr(GlobalValue::GUID GUID) {
980 return &*GlobalValueMap.emplace(GUID, GlobalValueSummaryInfo(HaveGVs))
981 .first;
984 public:
985 // See HaveGVs variable comment.
986 ModuleSummaryIndex(bool HaveGVs, bool EnableSplitLTOUnit = false)
987 : HaveGVs(HaveGVs), EnableSplitLTOUnit(EnableSplitLTOUnit), Saver(Alloc) {
990 bool haveGVs() const { return HaveGVs; }
992 gvsummary_iterator begin() { return GlobalValueMap.begin(); }
993 const_gvsummary_iterator begin() const { return GlobalValueMap.begin(); }
994 gvsummary_iterator end() { return GlobalValueMap.end(); }
995 const_gvsummary_iterator end() const { return GlobalValueMap.end(); }
996 size_t size() const { return GlobalValueMap.size(); }
998 /// Convenience function for doing a DFS on a ValueInfo. Marks the function in
999 /// the FunctionHasParent map.
1000 static void discoverNodes(ValueInfo V,
1001 std::map<ValueInfo, bool> &FunctionHasParent) {
1002 if (!V.getSummaryList().size())
1003 return; // skip external functions that don't have summaries
1005 // Mark discovered if we haven't yet
1006 auto S = FunctionHasParent.emplace(V, false);
1008 // Stop if we've already discovered this node
1009 if (!S.second)
1010 return;
1012 FunctionSummary *F =
1013 dyn_cast<FunctionSummary>(V.getSummaryList().front().get());
1014 assert(F != nullptr && "Expected FunctionSummary node");
1016 for (auto &C : F->calls()) {
1017 // Insert node if necessary
1018 auto S = FunctionHasParent.emplace(C.first, true);
1020 // Skip nodes that we're sure have parents
1021 if (!S.second && S.first->second)
1022 continue;
1024 if (S.second)
1025 discoverNodes(C.first, FunctionHasParent);
1026 else
1027 S.first->second = true;
1031 // Calculate the callgraph root
1032 FunctionSummary calculateCallGraphRoot() {
1033 // Functions that have a parent will be marked in FunctionHasParent pair.
1034 // Once we've marked all functions, the functions in the map that are false
1035 // have no parent (so they're the roots)
1036 std::map<ValueInfo, bool> FunctionHasParent;
1038 for (auto &S : *this) {
1039 // Skip external functions
1040 if (!S.second.SummaryList.size() ||
1041 !isa<FunctionSummary>(S.second.SummaryList.front().get()))
1042 continue;
1043 discoverNodes(ValueInfo(HaveGVs, &S), FunctionHasParent);
1046 std::vector<FunctionSummary::EdgeTy> Edges;
1047 // create edges to all roots in the Index
1048 for (auto &P : FunctionHasParent) {
1049 if (P.second)
1050 continue; // skip over non-root nodes
1051 Edges.push_back(std::make_pair(P.first, CalleeInfo{}));
1053 if (Edges.empty()) {
1054 // Failed to find root - return an empty node
1055 return FunctionSummary::makeDummyFunctionSummary({});
1057 auto CallGraphRoot = FunctionSummary::makeDummyFunctionSummary(Edges);
1058 return CallGraphRoot;
1061 bool withGlobalValueDeadStripping() const {
1062 return WithGlobalValueDeadStripping;
1064 void setWithGlobalValueDeadStripping() {
1065 WithGlobalValueDeadStripping = true;
1068 bool hasSyntheticEntryCounts() const { return HasSyntheticEntryCounts; }
1069 void setHasSyntheticEntryCounts() { HasSyntheticEntryCounts = true; }
1071 bool skipModuleByDistributedBackend() const {
1072 return SkipModuleByDistributedBackend;
1074 void setSkipModuleByDistributedBackend() {
1075 SkipModuleByDistributedBackend = true;
1078 bool enableSplitLTOUnit() const { return EnableSplitLTOUnit; }
1079 void setEnableSplitLTOUnit() { EnableSplitLTOUnit = true; }
1081 bool partiallySplitLTOUnits() const { return PartiallySplitLTOUnits; }
1082 void setPartiallySplitLTOUnits() { PartiallySplitLTOUnits = true; }
1084 bool isGlobalValueLive(const GlobalValueSummary *GVS) const {
1085 return !WithGlobalValueDeadStripping || GVS->isLive();
1087 bool isGUIDLive(GlobalValue::GUID GUID) const;
1089 /// Return a ValueInfo for the index value_type (convenient when iterating
1090 /// index).
1091 ValueInfo getValueInfo(const GlobalValueSummaryMapTy::value_type &R) const {
1092 return ValueInfo(HaveGVs, &R);
1095 /// Return a ValueInfo for GUID if it exists, otherwise return ValueInfo().
1096 ValueInfo getValueInfo(GlobalValue::GUID GUID) const {
1097 auto I = GlobalValueMap.find(GUID);
1098 return ValueInfo(HaveGVs, I == GlobalValueMap.end() ? nullptr : &*I);
1101 /// Return a ValueInfo for \p GUID.
1102 ValueInfo getOrInsertValueInfo(GlobalValue::GUID GUID) {
1103 return ValueInfo(HaveGVs, getOrInsertValuePtr(GUID));
1106 // Save a string in the Index. Use before passing Name to
1107 // getOrInsertValueInfo when the string isn't owned elsewhere (e.g. on the
1108 // module's Strtab).
1109 StringRef saveString(StringRef String) { return Saver.save(String); }
1111 /// Return a ValueInfo for \p GUID setting value \p Name.
1112 ValueInfo getOrInsertValueInfo(GlobalValue::GUID GUID, StringRef Name) {
1113 assert(!HaveGVs);
1114 auto VP = getOrInsertValuePtr(GUID);
1115 VP->second.U.Name = Name;
1116 return ValueInfo(HaveGVs, VP);
1119 /// Return a ValueInfo for \p GV and mark it as belonging to GV.
1120 ValueInfo getOrInsertValueInfo(const GlobalValue *GV) {
1121 assert(HaveGVs);
1122 auto VP = getOrInsertValuePtr(GV->getGUID());
1123 VP->second.U.GV = GV;
1124 return ValueInfo(HaveGVs, VP);
1127 /// Return the GUID for \p OriginalId in the OidGuidMap.
1128 GlobalValue::GUID getGUIDFromOriginalID(GlobalValue::GUID OriginalID) const {
1129 const auto I = OidGuidMap.find(OriginalID);
1130 return I == OidGuidMap.end() ? 0 : I->second;
1133 std::set<std::string> &cfiFunctionDefs() { return CfiFunctionDefs; }
1134 const std::set<std::string> &cfiFunctionDefs() const { return CfiFunctionDefs; }
1136 std::set<std::string> &cfiFunctionDecls() { return CfiFunctionDecls; }
1137 const std::set<std::string> &cfiFunctionDecls() const { return CfiFunctionDecls; }
1139 /// Add a global value summary for a value.
1140 void addGlobalValueSummary(const GlobalValue &GV,
1141 std::unique_ptr<GlobalValueSummary> Summary) {
1142 addGlobalValueSummary(getOrInsertValueInfo(&GV), std::move(Summary));
1145 /// Add a global value summary for a value of the given name.
1146 void addGlobalValueSummary(StringRef ValueName,
1147 std::unique_ptr<GlobalValueSummary> Summary) {
1148 addGlobalValueSummary(getOrInsertValueInfo(GlobalValue::getGUID(ValueName)),
1149 std::move(Summary));
1152 /// Add a global value summary for the given ValueInfo.
1153 void addGlobalValueSummary(ValueInfo VI,
1154 std::unique_ptr<GlobalValueSummary> Summary) {
1155 addOriginalName(VI.getGUID(), Summary->getOriginalName());
1156 // Here we have a notionally const VI, but the value it points to is owned
1157 // by the non-const *this.
1158 const_cast<GlobalValueSummaryMapTy::value_type *>(VI.getRef())
1159 ->second.SummaryList.push_back(std::move(Summary));
1162 /// Add an original name for the value of the given GUID.
1163 void addOriginalName(GlobalValue::GUID ValueGUID,
1164 GlobalValue::GUID OrigGUID) {
1165 if (OrigGUID == 0 || ValueGUID == OrigGUID)
1166 return;
1167 if (OidGuidMap.count(OrigGUID) && OidGuidMap[OrigGUID] != ValueGUID)
1168 OidGuidMap[OrigGUID] = 0;
1169 else
1170 OidGuidMap[OrigGUID] = ValueGUID;
1173 /// Find the summary for ValueInfo \p VI in module \p ModuleId, or nullptr if
1174 /// not found.
1175 GlobalValueSummary *findSummaryInModule(ValueInfo VI, StringRef ModuleId) const {
1176 auto SummaryList = VI.getSummaryList();
1177 auto Summary =
1178 llvm::find_if(SummaryList,
1179 [&](const std::unique_ptr<GlobalValueSummary> &Summary) {
1180 return Summary->modulePath() == ModuleId;
1182 if (Summary == SummaryList.end())
1183 return nullptr;
1184 return Summary->get();
1187 /// Find the summary for global \p GUID in module \p ModuleId, or nullptr if
1188 /// not found.
1189 GlobalValueSummary *findSummaryInModule(GlobalValue::GUID ValueGUID,
1190 StringRef ModuleId) const {
1191 auto CalleeInfo = getValueInfo(ValueGUID);
1192 if (!CalleeInfo)
1193 return nullptr; // This function does not have a summary
1194 return findSummaryInModule(CalleeInfo, ModuleId);
1197 /// Returns the first GlobalValueSummary for \p GV, asserting that there
1198 /// is only one if \p PerModuleIndex.
1199 GlobalValueSummary *getGlobalValueSummary(const GlobalValue &GV,
1200 bool PerModuleIndex = true) const {
1201 assert(GV.hasName() && "Can't get GlobalValueSummary for GV with no name");
1202 return getGlobalValueSummary(GV.getGUID(), PerModuleIndex);
1205 /// Returns the first GlobalValueSummary for \p ValueGUID, asserting that
1206 /// there
1207 /// is only one if \p PerModuleIndex.
1208 GlobalValueSummary *getGlobalValueSummary(GlobalValue::GUID ValueGUID,
1209 bool PerModuleIndex = true) const;
1211 /// Table of modules, containing module hash and id.
1212 const StringMap<std::pair<uint64_t, ModuleHash>> &modulePaths() const {
1213 return ModulePathStringTable;
1216 /// Table of modules, containing hash and id.
1217 StringMap<std::pair<uint64_t, ModuleHash>> &modulePaths() {
1218 return ModulePathStringTable;
1221 /// Get the module ID recorded for the given module path.
1222 uint64_t getModuleId(const StringRef ModPath) const {
1223 return ModulePathStringTable.lookup(ModPath).first;
1226 /// Get the module SHA1 hash recorded for the given module path.
1227 const ModuleHash &getModuleHash(const StringRef ModPath) const {
1228 auto It = ModulePathStringTable.find(ModPath);
1229 assert(It != ModulePathStringTable.end() && "Module not registered");
1230 return It->second.second;
1233 /// Convenience method for creating a promoted global name
1234 /// for the given value name of a local, and its original module's ID.
1235 static std::string getGlobalNameForLocal(StringRef Name, ModuleHash ModHash) {
1236 SmallString<256> NewName(Name);
1237 NewName += ".llvm.";
1238 NewName += utostr((uint64_t(ModHash[0]) << 32) |
1239 ModHash[1]); // Take the first 64 bits
1240 return NewName.str();
1243 /// Helper to obtain the unpromoted name for a global value (or the original
1244 /// name if not promoted).
1245 static StringRef getOriginalNameBeforePromote(StringRef Name) {
1246 std::pair<StringRef, StringRef> Pair = Name.split(".llvm.");
1247 return Pair.first;
1250 typedef ModulePathStringTableTy::value_type ModuleInfo;
1252 /// Add a new module with the given \p Hash, mapped to the given \p
1253 /// ModID, and return a reference to the module.
1254 ModuleInfo *addModule(StringRef ModPath, uint64_t ModId,
1255 ModuleHash Hash = ModuleHash{{0}}) {
1256 return &*ModulePathStringTable.insert({ModPath, {ModId, Hash}}).first;
1259 /// Return module entry for module with the given \p ModPath.
1260 ModuleInfo *getModule(StringRef ModPath) {
1261 auto It = ModulePathStringTable.find(ModPath);
1262 assert(It != ModulePathStringTable.end() && "Module not registered");
1263 return &*It;
1266 /// Check if the given Module has any functions available for exporting
1267 /// in the index. We consider any module present in the ModulePathStringTable
1268 /// to have exported functions.
1269 bool hasExportedFunctions(const Module &M) const {
1270 return ModulePathStringTable.count(M.getModuleIdentifier());
1273 const TypeIdSummaryMapTy &typeIds() const { return TypeIdMap; }
1275 /// Return an existing or new TypeIdSummary entry for \p TypeId.
1276 /// This accessor can mutate the map and therefore should not be used in
1277 /// the ThinLTO backends.
1278 TypeIdSummary &getOrInsertTypeIdSummary(StringRef TypeId) {
1279 auto TidIter = TypeIdMap.equal_range(GlobalValue::getGUID(TypeId));
1280 for (auto It = TidIter.first; It != TidIter.second; ++It)
1281 if (It->second.first == TypeId)
1282 return It->second.second;
1283 auto It = TypeIdMap.insert(
1284 {GlobalValue::getGUID(TypeId), {TypeId, TypeIdSummary()}});
1285 return It->second.second;
1288 /// This returns either a pointer to the type id summary (if present in the
1289 /// summary map) or null (if not present). This may be used when importing.
1290 const TypeIdSummary *getTypeIdSummary(StringRef TypeId) const {
1291 auto TidIter = TypeIdMap.equal_range(GlobalValue::getGUID(TypeId));
1292 for (auto It = TidIter.first; It != TidIter.second; ++It)
1293 if (It->second.first == TypeId)
1294 return &It->second.second;
1295 return nullptr;
1298 TypeIdSummary *getTypeIdSummary(StringRef TypeId) {
1299 return const_cast<TypeIdSummary *>(
1300 static_cast<const ModuleSummaryIndex *>(this)->getTypeIdSummary(
1301 TypeId));
1304 const std::map<std::string, TypeIdCompatibleVtableInfo> &
1305 typeIdCompatibleVtableMap() const {
1306 return TypeIdCompatibleVtableMap;
1309 /// Return an existing or new TypeIdCompatibleVtableMap entry for \p TypeId.
1310 /// This accessor can mutate the map and therefore should not be used in
1311 /// the ThinLTO backends.
1312 TypeIdCompatibleVtableInfo &
1313 getOrInsertTypeIdCompatibleVtableSummary(StringRef TypeId) {
1314 return TypeIdCompatibleVtableMap[TypeId];
1317 /// For the given \p TypeId, this returns the TypeIdCompatibleVtableMap
1318 /// entry if present in the summary map. This may be used when importing.
1319 Optional<TypeIdCompatibleVtableInfo>
1320 getTypeIdCompatibleVtableSummary(StringRef TypeId) const {
1321 auto I = TypeIdCompatibleVtableMap.find(TypeId);
1322 if (I == TypeIdCompatibleVtableMap.end())
1323 return None;
1324 return I->second;
1327 /// Collect for the given module the list of functions it defines
1328 /// (GUID -> Summary).
1329 void collectDefinedFunctionsForModule(StringRef ModulePath,
1330 GVSummaryMapTy &GVSummaryMap) const;
1332 /// Collect for each module the list of Summaries it defines (GUID ->
1333 /// Summary).
1334 template <class Map>
1335 void
1336 collectDefinedGVSummariesPerModule(Map &ModuleToDefinedGVSummaries) const {
1337 for (auto &GlobalList : *this) {
1338 auto GUID = GlobalList.first;
1339 for (auto &Summary : GlobalList.second.SummaryList) {
1340 ModuleToDefinedGVSummaries[Summary->modulePath()][GUID] = Summary.get();
1345 /// Print to an output stream.
1346 void print(raw_ostream &OS, bool IsForDebug = false) const;
1348 /// Dump to stderr (for debugging).
1349 void dump() const;
1351 /// Export summary to dot file for GraphViz.
1352 void exportToDot(raw_ostream& OS) const;
1354 /// Print out strongly connected components for debugging.
1355 void dumpSCCs(raw_ostream &OS);
1357 /// Analyze index and detect unmodified globals
1358 void propagateAttributes(const DenseSet<GlobalValue::GUID> &PreservedSymbols);
1361 /// GraphTraits definition to build SCC for the index
1362 template <> struct GraphTraits<ValueInfo> {
1363 typedef ValueInfo NodeRef;
1364 using EdgeRef = FunctionSummary::EdgeTy &;
1366 static NodeRef valueInfoFromEdge(FunctionSummary::EdgeTy &P) {
1367 return P.first;
1369 using ChildIteratorType =
1370 mapped_iterator<std::vector<FunctionSummary::EdgeTy>::iterator,
1371 decltype(&valueInfoFromEdge)>;
1373 using ChildEdgeIteratorType = std::vector<FunctionSummary::EdgeTy>::iterator;
1375 static NodeRef getEntryNode(ValueInfo V) { return V; }
1377 static ChildIteratorType child_begin(NodeRef N) {
1378 if (!N.getSummaryList().size()) // handle external function
1379 return ChildIteratorType(
1380 FunctionSummary::ExternalNode.CallGraphEdgeList.begin(),
1381 &valueInfoFromEdge);
1382 FunctionSummary *F =
1383 cast<FunctionSummary>(N.getSummaryList().front()->getBaseObject());
1384 return ChildIteratorType(F->CallGraphEdgeList.begin(), &valueInfoFromEdge);
1387 static ChildIteratorType child_end(NodeRef N) {
1388 if (!N.getSummaryList().size()) // handle external function
1389 return ChildIteratorType(
1390 FunctionSummary::ExternalNode.CallGraphEdgeList.end(),
1391 &valueInfoFromEdge);
1392 FunctionSummary *F =
1393 cast<FunctionSummary>(N.getSummaryList().front()->getBaseObject());
1394 return ChildIteratorType(F->CallGraphEdgeList.end(), &valueInfoFromEdge);
1397 static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
1398 if (!N.getSummaryList().size()) // handle external function
1399 return FunctionSummary::ExternalNode.CallGraphEdgeList.begin();
1401 FunctionSummary *F =
1402 cast<FunctionSummary>(N.getSummaryList().front()->getBaseObject());
1403 return F->CallGraphEdgeList.begin();
1406 static ChildEdgeIteratorType child_edge_end(NodeRef N) {
1407 if (!N.getSummaryList().size()) // handle external function
1408 return FunctionSummary::ExternalNode.CallGraphEdgeList.end();
1410 FunctionSummary *F =
1411 cast<FunctionSummary>(N.getSummaryList().front()->getBaseObject());
1412 return F->CallGraphEdgeList.end();
1415 static NodeRef edge_dest(EdgeRef E) { return E.first; }
1418 template <>
1419 struct GraphTraits<ModuleSummaryIndex *> : public GraphTraits<ValueInfo> {
1420 static NodeRef getEntryNode(ModuleSummaryIndex *I) {
1421 std::unique_ptr<GlobalValueSummary> Root =
1422 std::make_unique<FunctionSummary>(I->calculateCallGraphRoot());
1423 GlobalValueSummaryInfo G(I->haveGVs());
1424 G.SummaryList.push_back(std::move(Root));
1425 static auto P =
1426 GlobalValueSummaryMapTy::value_type(GlobalValue::GUID(0), std::move(G));
1427 return ValueInfo(I->haveGVs(), &P);
1431 static inline bool canImportGlobalVar(GlobalValueSummary *S) {
1432 assert(isa<GlobalVarSummary>(S->getBaseObject()));
1434 // We don't import GV with references, because it can result
1435 // in promotion of local variables in the source module.
1436 return !GlobalValue::isInterposableLinkage(S->linkage()) &&
1437 !S->notEligibleToImport() && S->refs().empty();
1439 } // end namespace llvm
1441 #endif // LLVM_IR_MODULESUMMARYINDEX_H