1 //===- bolt/Core/BinaryFunction.h - Low-level function ----------*- 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 // This file contains the declaration of the BinaryFunction class. It represents
10 // a function at the lowest IR level. Typically, a BinaryFunction represents a
11 // function object in a compiled and linked binary file. However, a
12 // BinaryFunction can also be constructed manually, e.g. for injecting into a
13 // binary file.
14 //
15 // A BinaryFunction could be in one of the several states described in
16 // BinaryFunction::State. While in the disassembled state, it will contain a
17 // list of instructions with their offsets. In the CFG state, it will contain a
18 // list of BinaryBasicBlocks that form a control-flow graph. This state is best
19 // suited for binary analysis and optimizations. However, sometimes it's
20 // impossible to build the precise CFG due to the ambiguity of indirect
21 // branches.
22 //
23 //===----------------------------------------------------------------------===//
24 
25 #ifndef BOLT_CORE_BINARY_FUNCTION_H
26 #define BOLT_CORE_BINARY_FUNCTION_H
27 
28 #include "bolt/Core/BinaryBasicBlock.h"
29 #include "bolt/Core/BinaryContext.h"
30 #include "bolt/Core/BinaryLoop.h"
31 #include "bolt/Core/BinarySection.h"
32 #include "bolt/Core/DebugData.h"
33 #include "bolt/Core/JumpTable.h"
34 #include "bolt/Core/MCPlus.h"
35 #include "bolt/Utils/NameResolver.h"
36 #include "llvm/ADT/StringRef.h"
37 #include "llvm/ADT/iterator.h"
38 #include "llvm/BinaryFormat/Dwarf.h"
39 #include "llvm/MC/MCContext.h"
40 #include "llvm/MC/MCDwarf.h"
41 #include "llvm/MC/MCInst.h"
42 #include "llvm/MC/MCSymbol.h"
43 #include "llvm/Object/ObjectFile.h"
44 #include "llvm/Support/raw_ostream.h"
45 #include <algorithm>
46 #include <limits>
47 #include <unordered_map>
48 #include <unordered_set>
49 #include <vector>
50 
51 using namespace llvm::object;
52 
53 namespace llvm {
54 
55 class DWARFUnit;
56 
57 namespace bolt {
58 
59 using InputOffsetToAddressMapTy = std::unordered_multimap<uint64_t, uint64_t>;
60 
61 /// Types of macro-fusion alignment corrections.
62 enum MacroFusionType { MFT_NONE, MFT_HOT, MFT_ALL };
63 
64 enum IndirectCallPromotionType : char {
65   ICP_NONE,        /// Don't perform ICP.
66   ICP_CALLS,       /// Perform ICP on indirect calls.
67   ICP_JUMP_TABLES, /// Perform ICP on jump tables.
68   ICP_ALL          /// Perform ICP on calls and jump tables.
69 };
70 
71 /// Information on a single indirect call to a particular callee.
72 struct IndirectCallProfile {
73   MCSymbol *Symbol;
74   uint32_t Offset;
75   uint64_t Count;
76   uint64_t Mispreds;
77 
78   IndirectCallProfile(MCSymbol *Symbol, uint64_t Count, uint64_t Mispreds,
79                       uint32_t Offset = 0)
80       : Symbol(Symbol), Offset(Offset), Count(Count), Mispreds(Mispreds) {}
81 
82   bool operator==(const IndirectCallProfile &Other) const {
83     return Symbol == Other.Symbol && Offset == Other.Offset;
84   }
85 };
86 
87 /// Aggregated information for an indirect call site.
88 using IndirectCallSiteProfile = SmallVector<IndirectCallProfile, 4>;
89 
90 inline raw_ostream &operator<<(raw_ostream &OS,
91                                const bolt::IndirectCallSiteProfile &ICSP) {
92   std::string TempString;
93   raw_string_ostream SS(TempString);
94 
95   const char *Sep = "\n        ";
96   uint64_t TotalCount = 0;
97   uint64_t TotalMispreds = 0;
98   for (const IndirectCallProfile &CSP : ICSP) {
99     SS << Sep << "{ " << (CSP.Symbol ? CSP.Symbol->getName() : "<unknown>")
100        << ": " << CSP.Count << " (" << CSP.Mispreds << " misses) }";
101     Sep = ",\n        ";
102     TotalCount += CSP.Count;
103     TotalMispreds += CSP.Mispreds;
104   }
105   SS.flush();
106 
107   OS << TotalCount << " (" << TotalMispreds << " misses) :" << TempString;
108   return OS;
109 }
110 
111 /// BinaryFunction is a representation of machine-level function.
112 ///
113 /// In the input binary, an instance of BinaryFunction can represent a fragment
114 /// of a function if the higher-level function was split, e.g. into hot and cold
115 /// parts. The fragment containing the main entry point is called a parent
116 /// or the main fragment.
117 class BinaryFunction {
118 public:
119   enum class State : char {
120     Empty = 0,     /// Function body is empty.
121     Disassembled,  /// Function have been disassembled.
122     CFG,           /// Control flow graph has been built.
123     CFG_Finalized, /// CFG is finalized. No optimizations allowed.
124     EmittedCFG,    /// Instructions have been emitted to output.
125     Emitted,       /// Same as above plus CFG is destroyed.
126   };
127 
128   /// Types of profile the function can use. Could be a combination.
129   enum {
130     PF_NONE = 0,     /// No profile.
131     PF_LBR = 1,      /// Profile is based on last branch records.
132     PF_SAMPLE = 2,   /// Non-LBR sample-based profile.
133     PF_MEMEVENT = 4, /// Profile has mem events.
134   };
135 
136   /// Struct for tracking exception handling ranges.
137   struct CallSite {
138     const MCSymbol *Start;
139     const MCSymbol *End;
140     const MCSymbol *LP;
141     uint64_t Action;
142   };
143 
144   using CallSitesType = SmallVector<CallSite, 0>;
145 
146   using IslandProxiesType =
147       std::map<BinaryFunction *, std::map<const MCSymbol *, MCSymbol *>>;
148 
149   struct IslandInfo {
150     /// Temporary holder of offsets that are data markers (used in AArch)
151     /// It is possible to have data in code sections. To ease the identification
152     /// of data in code sections, the ABI requires the symbol table to have
153     /// symbols named "$d" identifying the start of data inside code and "$x"
154     /// identifying the end of a chunk of data inside code. DataOffsets contain
155     /// all offsets of $d symbols and CodeOffsets all offsets of $x symbols.
156     std::set<uint64_t> DataOffsets;
157     std::set<uint64_t> CodeOffsets;
158 
159     /// List of relocations associated with data in the constant island
160     std::map<uint64_t, Relocation> Relocations;
161 
162     /// Offsets in function that are data values in a constant island identified
163     /// after disassembling
164     std::map<uint64_t, MCSymbol *> Offsets;
165     SmallPtrSet<MCSymbol *, 4> Symbols;
166     DenseMap<const MCSymbol *, BinaryFunction *> ProxySymbols;
167     DenseMap<const MCSymbol *, MCSymbol *> ColdSymbols;
168     /// Keeps track of other functions we depend on because there is a reference
169     /// to the constant islands in them.
170     IslandProxiesType Proxies, ColdProxies;
171     SmallPtrSet<BinaryFunction *, 1> Dependency; // The other way around
172 
173     mutable MCSymbol *FunctionConstantIslandLabel{nullptr};
174     mutable MCSymbol *FunctionColdConstantIslandLabel{nullptr};
175 
176     // Returns constant island alignment
177     uint16_t getAlignment() const { return sizeof(uint64_t); }
178   };
179 
180   static constexpr uint64_t COUNT_NO_PROFILE =
181       BinaryBasicBlock::COUNT_NO_PROFILE;
182 
183   /// We have to use at least 2-byte alignment for functions because of C++ ABI.
184   static constexpr unsigned MinAlign = 2;
185 
186   static const char TimerGroupName[];
187   static const char TimerGroupDesc[];
188 
189   using BasicBlockOrderType = SmallVector<BinaryBasicBlock *, 0>;
190 
191   /// Mark injected functions
192   bool IsInjected = false;
193 
194   using LSDATypeTableTy = SmallVector<uint64_t, 0>;
195 
196   /// List of DWARF CFI instructions. Original CFI from the binary must be
197   /// sorted w.r.t. offset that it appears. We rely on this to replay CFIs
198   /// if needed (to fix state after reordering BBs).
199   using CFIInstrMapType = SmallVector<MCCFIInstruction, 0>;
200   using cfi_iterator = CFIInstrMapType::iterator;
201   using const_cfi_iterator = CFIInstrMapType::const_iterator;
202 
203 private:
204   /// Current state of the function.
205   State CurrentState{State::Empty};
206 
207   /// A list of symbols associated with the function entry point.
208   ///
209   /// Multiple symbols would typically result from identical code-folding
210   /// optimization.
211   typedef SmallVector<MCSymbol *, 1> SymbolListTy;
212   SymbolListTy Symbols;
213 
214   /// The list of names this function is known under. Used for fuzzy-matching
215   /// the function to its name in a profile, command line, etc.
216   SmallVector<std::string, 0> Aliases;
217 
218   /// Containing section in the input file.
219   BinarySection *OriginSection = nullptr;
220 
221   /// Address of the function in memory. Also could be an offset from
222   /// base address for position independent binaries.
223   uint64_t Address;
224 
225   /// Original size of the function.
226   uint64_t Size;
227 
228   /// Address of the function in output.
229   uint64_t OutputAddress{0};
230 
231   /// Size of the function in the output file.
232   uint64_t OutputSize{0};
233 
234   /// Offset in the file.
235   uint64_t FileOffset{0};
236 
237   /// Maximum size this function is allowed to have.
238   uint64_t MaxSize{std::numeric_limits<uint64_t>::max()};
239 
240   /// Alignment requirements for the function.
241   uint16_t Alignment{2};
242 
243   /// Maximum number of bytes used for alignment of hot part of the function.
244   uint16_t MaxAlignmentBytes{0};
245 
246   /// Maximum number of bytes used for alignment of cold part of the function.
247   uint16_t MaxColdAlignmentBytes{0};
248 
249   const MCSymbol *PersonalityFunction{nullptr};
250   uint8_t PersonalityEncoding{dwarf::DW_EH_PE_sdata4 | dwarf::DW_EH_PE_pcrel};
251 
252   BinaryContext &BC;
253 
254   std::unique_ptr<BinaryLoopInfo> BLI;
255 
256   /// Set of external addresses in the code that are not a function start
257   /// and are referenced from this function.
258   std::set<uint64_t> InterproceduralReferences;
259 
260   /// All labels in the function that are referenced via relocations from
261   /// data objects. Typically these are jump table destinations and computed
262   /// goto labels.
263   std::set<uint64_t> ExternallyReferencedOffsets;
264 
265   /// Offsets of indirect branches with unknown destinations.
266   std::set<uint64_t> UnknownIndirectBranchOffsets;
267 
268   /// A set of local and global symbols corresponding to secondary entry points.
269   /// Each additional function entry point has a corresponding entry in the map.
270   /// The key is a local symbol corresponding to a basic block and the value
271   /// is a global symbol corresponding to an external entry point.
272   DenseMap<const MCSymbol *, MCSymbol *> SecondaryEntryPoints;
273 
274   /// False if the function is too complex to reconstruct its control
275   /// flow graph.
276   /// In relocation mode we still disassemble and re-assemble such functions.
277   bool IsSimple{true};
278 
279   /// Indication that the function should be ignored for optimization purposes.
280   /// If we can skip emission of some functions, then ignored functions could
281   /// be not fully disassembled and will not be emitted.
282   bool IsIgnored{false};
283 
284   /// Pseudo functions should not be disassembled or emitted.
285   bool IsPseudo{false};
286 
287   /// True if the original function code has all necessary relocations to track
288   /// addresses of functions emitted to new locations. Typically set for
289   /// functions that we are not going to emit.
290   bool HasExternalRefRelocations{false};
291 
292   /// True if the function has an indirect branch with unknown destination.
293   bool HasUnknownControlFlow{false};
294 
295   /// The code from inside the function references one of the code locations
296   /// from the same function as a data, i.e. it's possible the label is used
297   /// inside an address calculation or could be referenced from outside.
298   bool HasInternalLabelReference{false};
299 
300   /// In AArch64, preserve nops to maintain code equal to input (assuming no
301   /// optimizations are done).
302   bool PreserveNops{false};
303 
304   /// Indicate if this function has associated exception handling metadata.
305   bool HasEHRanges{false};
306 
307   /// True if the function uses DW_CFA_GNU_args_size CFIs.
308   bool UsesGnuArgsSize{false};
309 
310   /// True if the function might have a profile available externally.
311   /// Used to check if processing of the function is required under certain
312   /// conditions.
313   bool HasProfileAvailable{false};
314 
315   bool HasMemoryProfile{false};
316 
317   /// Execution halts whenever this function is entered.
318   bool TrapsOnEntry{false};
319 
320   /// True if the function had an indirect branch with a fixed internal
321   /// destination.
322   bool HasFixedIndirectBranch{false};
323 
324   /// True if the function is a fragment of another function. This means that
325   /// this function could only be entered via its parent or one of its sibling
326   /// fragments. It could be entered at any basic block. It can also return
327   /// the control to any basic block of its parent or its sibling.
328   bool IsFragment{false};
329 
330   /// Indicate that the function body has SDT marker
331   bool HasSDTMarker{false};
332 
333   /// Indicate that the function body has Pseudo Probe
334   bool HasPseudoProbe{BC.getUniqueSectionByName(".pseudo_probe_desc") &&
335                       BC.getUniqueSectionByName(".pseudo_probe")};
336 
337   /// True if the original entry point was patched.
338   bool IsPatched{false};
339 
340   /// True if the function contains jump table with entries pointing to
341   /// locations in fragments.
342   bool HasSplitJumpTable{false};
343 
344   /// True if there are no control-flow edges with successors in other functions
345   /// (i.e. if tail calls have edges to function-local basic blocks).
346   /// Set to false by SCTC. Dynostats can't be reliably computed for
347   /// functions with non-canonical CFG.
348   /// This attribute is only valid when hasCFG() == true.
349   bool HasCanonicalCFG{true};
350 
351   /// The address for the code for this function in codegen memory.
352   /// Used for functions that are emitted in a dedicated section with a fixed
353   /// address. E.g. for functions that are overwritten in-place.
354   uint64_t ImageAddress{0};
355 
356   /// The size of the code in memory.
357   uint64_t ImageSize{0};
358 
359   /// Name for the section this function code should reside in.
360   std::string CodeSectionName;
361 
362   /// Name for the corresponding cold code section.
363   std::string ColdCodeSectionName;
364 
365   /// Parent function fragment for split function fragments.
366   SmallPtrSet<BinaryFunction *, 1> ParentFragments;
367 
368   /// Indicate if the function body was folded into another function.
369   /// Used by ICF optimization.
370   BinaryFunction *FoldedIntoFunction{nullptr};
371 
372   /// All fragments for a parent function.
373   SmallPtrSet<BinaryFunction *, 1> Fragments;
374 
375   /// The profile data for the number of times the function was executed.
376   uint64_t ExecutionCount{COUNT_NO_PROFILE};
377 
378   /// Profile match ratio.
379   float ProfileMatchRatio{0.0f};
380 
381   /// Raw branch count for this function in the profile
382   uint64_t RawBranchCount{0};
383 
384   /// Indicates the type of profile the function is using.
385   uint16_t ProfileFlags{PF_NONE};
386 
387   /// For functions with mismatched profile we store all call profile
388   /// information at a function level (as opposed to tying it to
389   /// specific call sites).
390   IndirectCallSiteProfile AllCallSites;
391 
392   /// Score of the function (estimated number of instructions executed,
393   /// according to profile data). -1 if the score has not been calculated yet.
394   mutable int64_t FunctionScore{-1};
395 
396   /// Original LSDA address for the function.
397   uint64_t LSDAAddress{0};
398 
399   /// Containing compilation unit for the function.
400   DWARFUnit *DwarfUnit{nullptr};
401 
402   /// Last computed hash value. Note that the value could be recomputed using
403   /// different parameters by every pass.
404   mutable uint64_t Hash{0};
405 
406   /// For PLT functions it contains a symbol associated with a function
407   /// reference. It is nullptr for non-PLT functions.
408   const MCSymbol *PLTSymbol{nullptr};
409 
410   /// Function order for streaming into the destination binary.
411   uint32_t Index{-1U};
412 
413   /// Get basic block index assuming it belongs to this function.
414   unsigned getIndex(const BinaryBasicBlock *BB) const {
415     assert(BB->getIndex() < BasicBlocks.size());
416     return BB->getIndex();
417   }
418 
419   /// Return basic block that originally contained offset \p Offset
420   /// from the function start.
421   BinaryBasicBlock *getBasicBlockContainingOffset(uint64_t Offset);
422 
423   const BinaryBasicBlock *getBasicBlockContainingOffset(uint64_t Offset) const {
424     return const_cast<BinaryFunction *>(this)->getBasicBlockContainingOffset(
425         Offset);
426   }
427 
428   /// Return basic block that started at offset \p Offset.
429   BinaryBasicBlock *getBasicBlockAtOffset(uint64_t Offset) {
430     BinaryBasicBlock *BB = getBasicBlockContainingOffset(Offset);
431     return BB && BB->getOffset() == Offset ? BB : nullptr;
432   }
433 
434   /// Release memory taken by the list.
435   template <typename T> BinaryFunction &clearList(T &List) {
436     T TempList;
437     TempList.swap(List);
438     return *this;
439   }
440 
441   /// Update the indices of all the basic blocks starting at StartIndex.
442   void updateBBIndices(const unsigned StartIndex);
443 
444   /// Annotate each basic block entry with its current CFI state. This is
445   /// run right after the construction of CFG while basic blocks are in their
446   /// original order.
447   void annotateCFIState();
448 
449   /// Associate DW_CFA_GNU_args_size info with invoke instructions
450   /// (call instructions with non-empty landing pad).
451   void propagateGnuArgsSizeInfo(MCPlusBuilder::AllocatorIdTy AllocId);
452 
453   /// Synchronize branch instructions with CFG.
454   void postProcessBranches();
455 
456   /// The address offset where we emitted the constant island, that is, the
457   /// chunk of data in the function code area (AArch only)
458   int64_t OutputDataOffset{0};
459   int64_t OutputColdDataOffset{0};
460 
461   /// Map labels to corresponding basic blocks.
462   DenseMap<const MCSymbol *, BinaryBasicBlock *> LabelToBB;
463 
464   using BranchListType = SmallVector<std::pair<uint32_t, uint32_t>, 0>;
465   BranchListType TakenBranches;   /// All local taken branches.
466   BranchListType IgnoredBranches; /// Branches ignored by CFG purposes.
467 
468   /// Map offset in the function to a label.
469   /// Labels are used for building CFG for simple functions. For non-simple
470   /// function in relocation mode we need to emit them for relocations
471   /// referencing function internals to work (e.g. jump tables).
472   using LabelsMapType = std::map<uint32_t, MCSymbol *>;
473   LabelsMapType Labels;
474 
475   /// Temporary holder of instructions before CFG is constructed.
476   /// Map offset in the function to MCInst.
477   using InstrMapType = std::map<uint32_t, MCInst>;
478   InstrMapType Instructions;
479 
480   /// We don't decode Call Frame Info encoded in DWARF program state
481   /// machine. Instead we define a "CFI State" - a frame information that
482   /// is a result of executing FDE CFI program up to a given point. The
483   /// program consists of opaque Call Frame Instructions:
484   ///
485   ///   CFI #0
486   ///   CFI #1
487   ///   ....
488   ///   CFI #N
489   ///
490   /// When we refer to "CFI State K" - it corresponds to a row in an abstract
491   /// Call Frame Info table. This row is reached right before executing CFI #K.
492   ///
493   /// At any point of execution in a function we are in any one of (N + 2)
494   /// states described in the original FDE program. We can't have more states
495   /// without intelligent processing of CFIs.
496   ///
497   /// When the final layout of basic blocks is known, and we finalize CFG,
498   /// we modify the original program to make sure the same state could be
499   /// reached even when basic blocks containing CFI instructions are executed
500   /// in a different order.
501   CFIInstrMapType FrameInstructions;
502 
503   /// A map of restore state CFI instructions to their equivalent CFI
504   /// instructions that produce the same state, in order to eliminate
505   /// remember-restore CFI instructions when rewriting CFI.
506   DenseMap<int32_t, SmallVector<int32_t, 4>> FrameRestoreEquivalents;
507 
508   // For tracking exception handling ranges.
509   CallSitesType CallSites;
510   CallSitesType ColdCallSites;
511 
512   /// Binary blobs representing action, type, and type index tables for this
513   /// function' LSDA (exception handling).
514   ArrayRef<uint8_t> LSDAActionTable;
515   ArrayRef<uint8_t> LSDATypeIndexTable;
516 
517   /// Vector of addresses of types referenced by LSDA.
518   LSDATypeTableTy LSDATypeTable;
519 
520   /// Vector of addresses of entries in LSDATypeTable used for indirect
521   /// addressing.
522   LSDATypeTableTy LSDATypeAddressTable;
523 
524   /// Marking for the beginning of language-specific data area for the function.
525   MCSymbol *LSDASymbol{nullptr};
526   MCSymbol *ColdLSDASymbol{nullptr};
527 
528   /// Map to discover which CFIs are attached to a given instruction offset.
529   /// Maps an instruction offset into a FrameInstructions offset.
530   /// This is only relevant to the buildCFG phase and is discarded afterwards.
531   std::multimap<uint32_t, uint32_t> OffsetToCFI;
532 
533   /// List of CFI instructions associated with the CIE (common to more than one
534   /// function and that apply before the entry basic block).
535   CFIInstrMapType CIEFrameInstructions;
536 
537   /// All compound jump tables for this function. This duplicates what's stored
538   /// in the BinaryContext, but additionally it gives quick access for all
539   /// jump tables used by this function.
540   ///
541   /// <OriginalAddress> -> <JumpTable *>
542   std::map<uint64_t, JumpTable *> JumpTables;
543 
544   /// All jump table sites in the function before CFG is built.
545   SmallVector<std::pair<uint64_t, uint64_t>, 0> JTSites;
546 
547   /// List of relocations in this function.
548   std::map<uint64_t, Relocation> Relocations;
549 
550   /// Information on function constant islands.
551   std::unique_ptr<IslandInfo> Islands;
552 
553   // Blocks are kept sorted in the layout order. If we need to change the
554   // layout (if BasicBlocksLayout stores a different order than BasicBlocks),
555   // the terminating instructions need to be modified.
556   using BasicBlockListType = SmallVector<BinaryBasicBlock *, 0>;
557   BasicBlockListType BasicBlocks;
558   BasicBlockListType DeletedBasicBlocks;
559   BasicBlockOrderType BasicBlocksLayout;
560   /// Previous layout replaced by modifyLayout
561   BasicBlockOrderType BasicBlocksPreviousLayout;
562   bool ModifiedLayout{false};
563 
564   /// BasicBlockOffsets are used during CFG construction to map from code
565   /// offsets to BinaryBasicBlocks.  Any modifications made to the CFG
566   /// after initial construction are not reflected in this data structure.
567   using BasicBlockOffset = std::pair<uint64_t, BinaryBasicBlock *>;
568   struct CompareBasicBlockOffsets {
569     bool operator()(const BasicBlockOffset &A,
570                     const BasicBlockOffset &B) const {
571       return A.first < B.first;
572     }
573   };
574   SmallVector<BasicBlockOffset, 0> BasicBlockOffsets;
575 
576   MCSymbol *ColdSymbol{nullptr};
577 
578   /// Symbol at the end of the function.
579   mutable MCSymbol *FunctionEndLabel{nullptr};
580 
581   /// Symbol at the end of the cold part of split function.
582   mutable MCSymbol *FunctionColdEndLabel{nullptr};
583 
584   /// Unique number associated with the function.
585   uint64_t FunctionNumber;
586 
587   /// Count the number of functions created.
588   static uint64_t Count;
589 
590   /// Map offsets of special instructions to addresses in the output.
591   InputOffsetToAddressMapTy InputOffsetToAddressMap;
592 
593   /// Register alternative function name.
594   void addAlternativeName(std::string NewName) {
595     Aliases.push_back(std::move(NewName));
596   }
597 
598   /// Return a label at a given \p Address in the function. If the label does
599   /// not exist - create it. Assert if the \p Address does not belong to
600   /// the function. If \p CreatePastEnd is true, then return the function
601   /// end label when the \p Address points immediately past the last byte
602   /// of the function.
603   /// NOTE: the function always returns a local (temp) symbol, even if there's
604   ///       a global symbol that corresponds to an entry at this address.
605   MCSymbol *getOrCreateLocalLabel(uint64_t Address, bool CreatePastEnd = false);
606 
607   /// Register an data entry at a given \p Offset into the function.
608   void markDataAtOffset(uint64_t Offset) {
609     if (!Islands)
610       Islands = std::make_unique<IslandInfo>();
611     Islands->DataOffsets.emplace(Offset);
612   }
613 
614   /// Register an entry point at a given \p Offset into the function.
615   void markCodeAtOffset(uint64_t Offset) {
616     if (!Islands)
617       Islands = std::make_unique<IslandInfo>();
618     Islands->CodeOffsets.emplace(Offset);
619   }
620 
621   /// Register secondary entry point at a given \p Offset into the function.
622   /// Return global symbol for use by extern function references.
623   MCSymbol *addEntryPointAtOffset(uint64_t Offset);
624 
625   /// Register an internal offset in a function referenced from outside.
626   void registerReferencedOffset(uint64_t Offset) {
627     ExternallyReferencedOffsets.emplace(Offset);
628   }
629 
630   /// True if there are references to internals of this function from data,
631   /// e.g. from jump tables.
632   bool hasInternalReference() const {
633     return !ExternallyReferencedOffsets.empty();
634   }
635 
636   /// Return an entry ID corresponding to a symbol known to belong to
637   /// the function.
638   ///
639   /// Prefer to use BinaryContext::getFunctionForSymbol(EntrySymbol, &ID)
640   /// instead of calling this function directly.
641   uint64_t getEntryIDForSymbol(const MCSymbol *EntrySymbol) const;
642 
643   /// If the function represents a secondary split function fragment, set its
644   /// parent fragment to \p BF.
645   void addParentFragment(BinaryFunction &BF) {
646     assert(this != &BF);
647     assert(IsFragment && "function must be a fragment to have a parent");
648     ParentFragments.insert(&BF);
649   }
650 
651   /// Register a child fragment for the main fragment of a split function.
652   void addFragment(BinaryFunction &BF) {
653     assert(this != &BF);
654     Fragments.insert(&BF);
655   }
656 
657   void addInstruction(uint64_t Offset, MCInst &&Instruction) {
658     Instructions.emplace(Offset, std::forward<MCInst>(Instruction));
659   }
660 
661   /// Convert CFI instructions to a standard form (remove remember/restore).
662   void normalizeCFIState();
663 
664   /// Analyze and process indirect branch \p Instruction before it is
665   /// added to Instructions list.
666   IndirectBranchType processIndirectBranch(MCInst &Instruction, unsigned Size,
667                                            uint64_t Offset,
668                                            uint64_t &TargetAddress);
669 
670   BinaryFunction &operator=(const BinaryFunction &) = delete;
671   BinaryFunction(const BinaryFunction &) = delete;
672 
673   friend class MachORewriteInstance;
674   friend class RewriteInstance;
675   friend class BinaryContext;
676   friend class DataReader;
677   friend class DataAggregator;
678 
679   static std::string buildCodeSectionName(StringRef Name,
680                                           const BinaryContext &BC);
681   static std::string buildColdCodeSectionName(StringRef Name,
682                                               const BinaryContext &BC);
683 
684   /// Creation should be handled by RewriteInstance or BinaryContext
685   BinaryFunction(const std::string &Name, BinarySection &Section,
686                  uint64_t Address, uint64_t Size, BinaryContext &BC)
687       : OriginSection(&Section), Address(Address), Size(Size), BC(BC),
688         CodeSectionName(buildCodeSectionName(Name, BC)),
689         ColdCodeSectionName(buildColdCodeSectionName(Name, BC)),
690         FunctionNumber(++Count) {
691     Symbols.push_back(BC.Ctx->getOrCreateSymbol(Name));
692   }
693 
694   /// This constructor is used to create an injected function
695   BinaryFunction(const std::string &Name, BinaryContext &BC, bool IsSimple)
696       : Address(0), Size(0), BC(BC), IsSimple(IsSimple),
697         CodeSectionName(buildCodeSectionName(Name, BC)),
698         ColdCodeSectionName(buildColdCodeSectionName(Name, BC)),
699         FunctionNumber(++Count) {
700     Symbols.push_back(BC.Ctx->getOrCreateSymbol(Name));
701     IsInjected = true;
702   }
703 
704   /// Clear state of the function that could not be disassembled or if its
705   /// disassembled state was later invalidated.
706   void clearDisasmState();
707 
708   /// Release memory allocated for CFG and instructions.
709   /// We still keep basic blocks for address translation/mapping purposes.
710   void releaseCFG() {
711     for (BinaryBasicBlock *BB : BasicBlocks)
712       BB->releaseCFG();
713     for (BinaryBasicBlock *BB : DeletedBasicBlocks)
714       BB->releaseCFG();
715 
716     clearList(CallSites);
717     clearList(ColdCallSites);
718     clearList(LSDATypeTable);
719     clearList(LSDATypeAddressTable);
720 
721     clearList(LabelToBB);
722 
723     if (!isMultiEntry())
724       clearList(Labels);
725 
726     clearList(FrameInstructions);
727     clearList(FrameRestoreEquivalents);
728   }
729 
730 public:
731   BinaryFunction(BinaryFunction &&) = default;
732 
733   using iterator = pointee_iterator<BasicBlockListType::iterator>;
734   using const_iterator = pointee_iterator<BasicBlockListType::const_iterator>;
735   using reverse_iterator =
736       pointee_iterator<BasicBlockListType::reverse_iterator>;
737   using const_reverse_iterator =
738       pointee_iterator<BasicBlockListType::const_reverse_iterator>;
739 
740   typedef BasicBlockOrderType::iterator order_iterator;
741   typedef BasicBlockOrderType::const_iterator const_order_iterator;
742   typedef BasicBlockOrderType::reverse_iterator reverse_order_iterator;
743   typedef BasicBlockOrderType::const_reverse_iterator
744       const_reverse_order_iterator;
745 
746   // CFG iterators.
747   iterator                 begin()       { return BasicBlocks.begin(); }
748   const_iterator           begin() const { return BasicBlocks.begin(); }
749   iterator                 end  ()       { return BasicBlocks.end();   }
750   const_iterator           end  () const { return BasicBlocks.end();   }
751 
752   reverse_iterator        rbegin()       { return BasicBlocks.rbegin(); }
753   const_reverse_iterator  rbegin() const { return BasicBlocks.rbegin(); }
754   reverse_iterator        rend  ()       { return BasicBlocks.rend();   }
755   const_reverse_iterator  rend  () const { return BasicBlocks.rend();   }
756 
757   size_t                    size() const { return BasicBlocks.size();}
758   bool                     empty() const { return BasicBlocks.empty(); }
759   const BinaryBasicBlock &front() const  { return *BasicBlocks.front(); }
760         BinaryBasicBlock &front()        { return *BasicBlocks.front(); }
761   const BinaryBasicBlock & back() const  { return *BasicBlocks.back(); }
762         BinaryBasicBlock & back()        { return *BasicBlocks.back(); }
763   inline iterator_range<iterator> blocks() {
764     return iterator_range<iterator>(begin(), end());
765   }
766   inline iterator_range<const_iterator> blocks() const {
767     return iterator_range<const_iterator>(begin(), end());
768   }
769 
770   // Iterators by pointer.
771   BasicBlockListType::iterator pbegin()  { return BasicBlocks.begin(); }
772   BasicBlockListType::iterator pend()    { return BasicBlocks.end(); }
773 
774   order_iterator       layout_begin()    { return BasicBlocksLayout.begin(); }
775   const_order_iterator layout_begin()    const
776                                          { return BasicBlocksLayout.begin(); }
777   order_iterator       layout_end()      { return BasicBlocksLayout.end(); }
778   const_order_iterator layout_end()      const
779                                          { return BasicBlocksLayout.end(); }
780   reverse_order_iterator       layout_rbegin()
781                                          { return BasicBlocksLayout.rbegin(); }
782   const_reverse_order_iterator layout_rbegin() const
783                                          { return BasicBlocksLayout.rbegin(); }
784   reverse_order_iterator       layout_rend()
785                                          { return BasicBlocksLayout.rend(); }
786   const_reverse_order_iterator layout_rend()   const
787                                          { return BasicBlocksLayout.rend(); }
788   size_t   layout_size()  const { return BasicBlocksLayout.size(); }
789   bool     layout_empty() const { return BasicBlocksLayout.empty(); }
790   const BinaryBasicBlock *layout_front() const
791                                          { return BasicBlocksLayout.front(); }
792         BinaryBasicBlock *layout_front() { return BasicBlocksLayout.front(); }
793   const BinaryBasicBlock *layout_back()  const
794                                          { return BasicBlocksLayout.back(); }
795         BinaryBasicBlock *layout_back()  { return BasicBlocksLayout.back(); }
796 
797   inline iterator_range<order_iterator> layout() {
798     return iterator_range<order_iterator>(BasicBlocksLayout.begin(),
799                                           BasicBlocksLayout.end());
800   }
801 
802   inline iterator_range<const_order_iterator> layout() const {
803     return iterator_range<const_order_iterator>(BasicBlocksLayout.begin(),
804                                                 BasicBlocksLayout.end());
805   }
806 
807   inline iterator_range<reverse_order_iterator> rlayout() {
808     return iterator_range<reverse_order_iterator>(BasicBlocksLayout.rbegin(),
809                                                   BasicBlocksLayout.rend());
810   }
811 
812   inline iterator_range<const_reverse_order_iterator> rlayout() const {
813     return iterator_range<const_reverse_order_iterator>(
814         BasicBlocksLayout.rbegin(), BasicBlocksLayout.rend());
815   }
816 
817   cfi_iterator        cie_begin()       { return CIEFrameInstructions.begin(); }
818   const_cfi_iterator  cie_begin() const { return CIEFrameInstructions.begin(); }
819   cfi_iterator        cie_end()         { return CIEFrameInstructions.end(); }
820   const_cfi_iterator  cie_end()   const { return CIEFrameInstructions.end(); }
821   bool                cie_empty() const { return CIEFrameInstructions.empty(); }
822 
823   inline iterator_range<cfi_iterator> cie() {
824     return iterator_range<cfi_iterator>(cie_begin(), cie_end());
825   }
826   inline iterator_range<const_cfi_iterator> cie() const {
827     return iterator_range<const_cfi_iterator>(cie_begin(), cie_end());
828   }
829 
830   /// Iterate over all jump tables associated with this function.
831   iterator_range<std::map<uint64_t, JumpTable *>::const_iterator>
832   jumpTables() const {
833     return make_range(JumpTables.begin(), JumpTables.end());
834   }
835 
836   /// Return relocation associated with a given \p Offset in the function,
837   /// or nullptr if no such relocation exists.
838   const Relocation *getRelocationAt(uint64_t Offset) const {
839     assert(CurrentState == State::Empty &&
840            "Relocations unavailable in the current function state.");
841     auto RI = Relocations.find(Offset);
842     return (RI == Relocations.end()) ? nullptr : &RI->second;
843   }
844 
845   /// Return the first relocation in the function that starts at an address in
846   /// the [StartOffset, EndOffset) range. Return nullptr if no such relocation
847   /// exists.
848   const Relocation *getRelocationInRange(uint64_t StartOffset,
849                                          uint64_t EndOffset) const {
850     assert(CurrentState == State::Empty &&
851            "Relocations unavailable in the current function state.");
852     auto RI = Relocations.lower_bound(StartOffset);
853     if (RI != Relocations.end() && RI->first < EndOffset)
854       return &RI->second;
855 
856     return nullptr;
857   }
858 
859   /// Returns the raw binary encoding of this function.
860   ErrorOr<ArrayRef<uint8_t>> getData() const;
861 
862   BinaryFunction &updateState(BinaryFunction::State State) {
863     CurrentState = State;
864     return *this;
865   }
866 
867   /// Update layout of basic blocks used for output.
868   void updateBasicBlockLayout(BasicBlockOrderType &NewLayout) {
869     BasicBlocksPreviousLayout = BasicBlocksLayout;
870 
871     if (NewLayout != BasicBlocksLayout) {
872       ModifiedLayout = true;
873       BasicBlocksLayout.clear();
874       BasicBlocksLayout.swap(NewLayout);
875     }
876   }
877 
878   /// Recompute landing pad information for the function and all its blocks.
879   void recomputeLandingPads();
880 
881   /// Return current basic block layout.
882   const BasicBlockOrderType &getLayout() const { return BasicBlocksLayout; }
883 
884   /// Return a list of basic blocks sorted using DFS and update layout indices
885   /// using the same order. Does not modify the current layout.
886   BasicBlockOrderType dfs() const;
887 
888   /// Find the loops in the CFG of the function and store information about
889   /// them.
890   void calculateLoopInfo();
891 
892   /// Calculate missed macro-fusion opportunities and update BinaryContext
893   /// stats.
894   void calculateMacroOpFusionStats();
895 
896   /// Returns if loop detection has been run for this function.
897   bool hasLoopInfo() const { return BLI != nullptr; }
898 
899   const BinaryLoopInfo &getLoopInfo() { return *BLI.get(); }
900 
901   bool isLoopFree() {
902     if (!hasLoopInfo())
903       calculateLoopInfo();
904     return BLI->empty();
905   }
906 
907   /// Print loop information about the function.
908   void printLoopInfo(raw_ostream &OS) const;
909 
910   /// View CFG in graphviz program
911   void viewGraph() const;
912 
913   /// Dump CFG in graphviz format
914   void dumpGraph(raw_ostream &OS) const;
915 
916   /// Dump CFG in graphviz format to file.
917   void dumpGraphToFile(std::string Filename) const;
918 
919   /// Dump CFG in graphviz format to a file with a filename that is derived
920   /// from the function name and Annotation strings.  Useful for dumping the
921   /// CFG after an optimization pass.
922   void dumpGraphForPass(std::string Annotation = "") const;
923 
924   /// Return BinaryContext for the function.
925   const BinaryContext &getBinaryContext() const { return BC; }
926 
927   /// Return BinaryContext for the function.
928   BinaryContext &getBinaryContext() { return BC; }
929 
930   /// Attempt to validate CFG invariants.
931   bool validateCFG() const;
932 
933   BinaryBasicBlock *getBasicBlockForLabel(const MCSymbol *Label) {
934     auto I = LabelToBB.find(Label);
935     return I == LabelToBB.end() ? nullptr : I->second;
936   }
937 
938   const BinaryBasicBlock *getBasicBlockForLabel(const MCSymbol *Label) const {
939     auto I = LabelToBB.find(Label);
940     return I == LabelToBB.end() ? nullptr : I->second;
941   }
942 
943   /// Returns the basic block after the given basic block in the layout or
944   /// nullptr the last basic block is given.
945   const BinaryBasicBlock *getBasicBlockAfter(const BinaryBasicBlock *BB,
946                                              bool IgnoreSplits = true) const {
947     return const_cast<BinaryFunction *>(this)->getBasicBlockAfter(BB,
948                                                                   IgnoreSplits);
949   }
950 
951   BinaryBasicBlock *getBasicBlockAfter(const BinaryBasicBlock *BB,
952                                        bool IgnoreSplits = true) {
953     for (auto I = layout_begin(), E = layout_end(); I != E; ++I) {
954       auto Next = std::next(I);
955       if (*I == BB && Next != E) {
956         return (IgnoreSplits || (*I)->isCold() == (*Next)->isCold()) ? *Next
957                                                                      : nullptr;
958       }
959     }
960     return nullptr;
961   }
962 
963   /// Retrieve the landing pad BB associated with invoke instruction \p Invoke
964   /// that is in \p BB. Return nullptr if none exists
965   BinaryBasicBlock *getLandingPadBBFor(const BinaryBasicBlock &BB,
966                                        const MCInst &InvokeInst) const {
967     assert(BC.MIB->isInvoke(InvokeInst) && "must be invoke instruction");
968     const Optional<MCPlus::MCLandingPad> LP = BC.MIB->getEHInfo(InvokeInst);
969     if (LP && LP->first) {
970       BinaryBasicBlock *LBB = BB.getLandingPad(LP->first);
971       assert(LBB && "Landing pad should be defined");
972       return LBB;
973     }
974     return nullptr;
975   }
976 
977   /// Return instruction at a given offset in the function. Valid before
978   /// CFG is constructed or while instruction offsets are available in CFG.
979   MCInst *getInstructionAtOffset(uint64_t Offset);
980 
981   const MCInst *getInstructionAtOffset(uint64_t Offset) const {
982     return const_cast<BinaryFunction *>(this)->getInstructionAtOffset(Offset);
983   }
984 
985   /// Return offset for the first instruction. If there is data at the
986   /// beginning of a function then offset of the first instruction could
987   /// be different from 0
988   uint64_t getFirstInstructionOffset() const {
989     if (Instructions.empty())
990       return 0;
991     return Instructions.begin()->first;
992   }
993 
994   /// Return jump table that covers a given \p Address in memory.
995   JumpTable *getJumpTableContainingAddress(uint64_t Address) {
996     auto JTI = JumpTables.upper_bound(Address);
997     if (JTI == JumpTables.begin())
998       return nullptr;
999     --JTI;
1000     if (JTI->first + JTI->second->getSize() > Address)
1001       return JTI->second;
1002     if (JTI->second->getSize() == 0 && JTI->first == Address)
1003       return JTI->second;
1004     return nullptr;
1005   }
1006 
1007   const JumpTable *getJumpTableContainingAddress(uint64_t Address) const {
1008     return const_cast<BinaryFunction *>(this)->getJumpTableContainingAddress(
1009         Address);
1010   }
1011 
1012   /// Return the name of the function if the function has just one name.
1013   /// If the function has multiple names - return one followed
1014   /// by "(*#<numnames>)".
1015   ///
1016   /// We should use getPrintName() for diagnostics and use
1017   /// hasName() to match function name against a given string.
1018   ///
1019   /// NOTE: for disambiguating names of local symbols we use the following
1020   ///       naming schemes:
1021   ///           primary:     <function>/<id>
1022   ///           alternative: <function>/<file>/<id2>
1023   std::string getPrintName() const {
1024     const size_t NumNames = Symbols.size() + Aliases.size();
1025     return NumNames == 1
1026                ? getOneName().str()
1027                : (getOneName().str() + "(*" + std::to_string(NumNames) + ")");
1028   }
1029 
1030   /// The function may have many names. For that reason, we avoid having
1031   /// getName() method as most of the time the user needs a different
1032   /// interface, such as forEachName(), hasName(), hasNameRegex(), etc.
1033   /// In some cases though, we need just a name uniquely identifying
1034   /// the function, and that's what this method is for.
1035   StringRef getOneName() const { return Symbols[0]->getName(); }
1036 
1037   /// Return the name of the function as getPrintName(), but also trying
1038   /// to demangle it.
1039   std::string getDemangledName() const;
1040 
1041   /// Call \p Callback for every name of this function as long as the Callback
1042   /// returns false. Stop if Callback returns true or all names have been used.
1043   /// Return the name for which the Callback returned true if any.
1044   template <typename FType>
1045   Optional<StringRef> forEachName(FType Callback) const {
1046     for (MCSymbol *Symbol : Symbols)
1047       if (Callback(Symbol->getName()))
1048         return Symbol->getName();
1049 
1050     for (const std::string &Name : Aliases)
1051       if (Callback(StringRef(Name)))
1052         return StringRef(Name);
1053 
1054     return NoneType();
1055   }
1056 
1057   /// Check if (possibly one out of many) function name matches the given
1058   /// string. Use this member function instead of direct name comparison.
1059   bool hasName(const std::string &FunctionName) const {
1060     auto Res =
1061         forEachName([&](StringRef Name) { return Name == FunctionName; });
1062     return Res.hasValue();
1063   }
1064 
1065   /// Check if any of function names matches the given regex.
1066   Optional<StringRef> hasNameRegex(const StringRef NameRegex) const;
1067 
1068   /// Check if any of restored function names matches the given regex.
1069   /// Restored name means stripping BOLT-added suffixes like "/1",
1070   Optional<StringRef> hasRestoredNameRegex(const StringRef NameRegex) const;
1071 
1072   /// Return a vector of all possible names for the function.
1073   const std::vector<StringRef> getNames() const {
1074     std::vector<StringRef> AllNames;
1075     forEachName([&AllNames](StringRef Name) {
1076       AllNames.push_back(Name);
1077       return false;
1078     });
1079 
1080     return AllNames;
1081   }
1082 
1083   /// Return a state the function is in (see BinaryFunction::State definition
1084   /// for description).
1085   State getState() const { return CurrentState; }
1086 
1087   /// Return true if function has a control flow graph available.
1088   bool hasCFG() const {
1089     return getState() == State::CFG || getState() == State::CFG_Finalized ||
1090            getState() == State::EmittedCFG;
1091   }
1092 
1093   /// Return true if the function state implies that it includes instructions.
1094   bool hasInstructions() const {
1095     return getState() == State::Disassembled || hasCFG();
1096   }
1097 
1098   bool isEmitted() const {
1099     return getState() == State::EmittedCFG || getState() == State::Emitted;
1100   }
1101 
1102   /// Return the section in the input binary this function originated from or
1103   /// nullptr if the function did not originate from the file.
1104   BinarySection *getOriginSection() const { return OriginSection; }
1105 
1106   void setOriginSection(BinarySection *Section) { OriginSection = Section; }
1107 
1108   /// Return true if the function did not originate from the primary input file.
1109   bool isInjected() const { return IsInjected; }
1110 
1111   /// Return original address of the function (or offset from base for PIC).
1112   uint64_t getAddress() const { return Address; }
1113 
1114   uint64_t getOutputAddress() const { return OutputAddress; }
1115 
1116   uint64_t getOutputSize() const { return OutputSize; }
1117 
1118   /// Does this function have a valid streaming order index?
1119   bool hasValidIndex() const { return Index != -1U; }
1120 
1121   /// Get the streaming order index for this function.
1122   uint32_t getIndex() const { return Index; }
1123 
1124   /// Set the streaming order index for this function.
1125   void setIndex(uint32_t Idx) {
1126     assert(!hasValidIndex());
1127     Index = Idx;
1128   }
1129 
1130   /// Return offset of the function body in the binary file.
1131   uint64_t getFileOffset() const { return FileOffset; }
1132 
1133   /// Return (original) byte size of the function.
1134   uint64_t getSize() const { return Size; }
1135 
1136   /// Return the maximum size the body of the function could have.
1137   uint64_t getMaxSize() const { return MaxSize; }
1138 
1139   /// Return the number of emitted instructions for this function.
1140   uint32_t getNumNonPseudos() const {
1141     uint32_t N = 0;
1142     for (BinaryBasicBlock *const &BB : layout())
1143       N += BB->getNumNonPseudos();
1144     return N;
1145   }
1146 
1147   /// Return MC symbol associated with the function.
1148   /// All references to the function should use this symbol.
1149   MCSymbol *getSymbol() { return Symbols[0]; }
1150 
1151   /// Return MC symbol associated with the function (const version).
1152   /// All references to the function should use this symbol.
1153   const MCSymbol *getSymbol() const { return Symbols[0]; }
1154 
1155   /// Return a list of symbols associated with the main entry of the function.
1156   SymbolListTy &getSymbols() { return Symbols; }
1157   const SymbolListTy &getSymbols() const { return Symbols; }
1158 
1159   /// If a local symbol \p BBLabel corresponds to a basic block that is a
1160   /// secondary entry point into the function, then return a global symbol
1161   /// that represents the secondary entry point. Otherwise return nullptr.
1162   MCSymbol *getSecondaryEntryPointSymbol(const MCSymbol *BBLabel) const {
1163     auto I = SecondaryEntryPoints.find(BBLabel);
1164     if (I == SecondaryEntryPoints.end())
1165       return nullptr;
1166 
1167     return I->second;
1168   }
1169 
1170   /// If the basic block serves as a secondary entry point to the function,
1171   /// return a global symbol representing the entry. Otherwise return nullptr.
1172   MCSymbol *getSecondaryEntryPointSymbol(const BinaryBasicBlock &BB) const {
1173     return getSecondaryEntryPointSymbol(BB.getLabel());
1174   }
1175 
1176   /// Return true if the basic block is an entry point into the function
1177   /// (either primary or secondary).
1178   bool isEntryPoint(const BinaryBasicBlock &BB) const {
1179     if (&BB == BasicBlocks.front())
1180       return true;
1181     return getSecondaryEntryPointSymbol(BB);
1182   }
1183 
1184   /// Return MC symbol corresponding to an enumerated entry for multiple-entry
1185   /// functions.
1186   MCSymbol *getSymbolForEntryID(uint64_t EntryNum);
1187   const MCSymbol *getSymbolForEntryID(uint64_t EntryNum) const {
1188     return const_cast<BinaryFunction *>(this)->getSymbolForEntryID(EntryNum);
1189   }
1190 
1191   using EntryPointCallbackTy = function_ref<bool(uint64_t, const MCSymbol *)>;
1192 
1193   /// Invoke \p Callback function for every entry point in the function starting
1194   /// with the main entry and using entries in the ascending address order.
1195   /// Stop calling the function after false is returned by the callback.
1196   ///
1197   /// Pass an offset of the entry point in the input binary and a corresponding
1198   /// global symbol to the callback function.
1199   ///
1200   /// Return true of all callbacks returned true, false otherwise.
1201   bool forEachEntryPoint(EntryPointCallbackTy Callback) const;
1202 
1203   MCSymbol *getColdSymbol() {
1204     if (ColdSymbol)
1205       return ColdSymbol;
1206 
1207     ColdSymbol = BC.Ctx->getOrCreateSymbol(
1208         NameResolver::append(getSymbol()->getName(), ".cold.0"));
1209 
1210     return ColdSymbol;
1211   }
1212 
1213   /// Return MC symbol associated with the end of the function.
1214   MCSymbol *getFunctionEndLabel() const {
1215     assert(BC.Ctx && "cannot be called with empty context");
1216     if (!FunctionEndLabel) {
1217       std::unique_lock<std::shared_timed_mutex> Lock(BC.CtxMutex);
1218       FunctionEndLabel = BC.Ctx->createNamedTempSymbol("func_end");
1219     }
1220     return FunctionEndLabel;
1221   }
1222 
1223   /// Return MC symbol associated with the end of the cold part of the function.
1224   MCSymbol *getFunctionColdEndLabel() const {
1225     if (!FunctionColdEndLabel) {
1226       std::unique_lock<std::shared_timed_mutex> Lock(BC.CtxMutex);
1227       FunctionColdEndLabel = BC.Ctx->createNamedTempSymbol("func_cold_end");
1228     }
1229     return FunctionColdEndLabel;
1230   }
1231 
1232   /// Return a label used to identify where the constant island was emitted
1233   /// (AArch only). This is used to update the symbol table accordingly,
1234   /// emitting data marker symbols as required by the ABI.
1235   MCSymbol *getFunctionConstantIslandLabel() const {
1236     assert(Islands && "function expected to have constant islands");
1237 
1238     if (!Islands->FunctionConstantIslandLabel) {
1239       Islands->FunctionConstantIslandLabel =
1240           BC.Ctx->createNamedTempSymbol("func_const_island");
1241     }
1242     return Islands->FunctionConstantIslandLabel;
1243   }
1244 
1245   MCSymbol *getFunctionColdConstantIslandLabel() const {
1246     assert(Islands && "function expected to have constant islands");
1247 
1248     if (!Islands->FunctionColdConstantIslandLabel) {
1249       Islands->FunctionColdConstantIslandLabel =
1250           BC.Ctx->createNamedTempSymbol("func_cold_const_island");
1251     }
1252     return Islands->FunctionColdConstantIslandLabel;
1253   }
1254 
1255   /// Return true if this is a function representing a PLT entry.
1256   bool isPLTFunction() const { return PLTSymbol != nullptr; }
1257 
1258   /// Return PLT function reference symbol for PLT functions and nullptr for
1259   /// non-PLT functions.
1260   const MCSymbol *getPLTSymbol() const { return PLTSymbol; }
1261 
1262   /// Set function PLT reference symbol for PLT functions.
1263   void setPLTSymbol(const MCSymbol *Symbol) {
1264     assert(Size == 0 && "function size should be 0 for PLT functions");
1265     PLTSymbol = Symbol;
1266     IsPseudo = true;
1267   }
1268 
1269   /// Update output values of the function based on the final \p Layout.
1270   void updateOutputValues(const MCAsmLayout &Layout);
1271 
1272   /// Return mapping of input to output addresses. Most users should call
1273   /// translateInputToOutputAddress() for address translation.
1274   InputOffsetToAddressMapTy &getInputOffsetToAddressMap() {
1275     assert(isEmitted() && "cannot use address mapping before code emission");
1276     return InputOffsetToAddressMap;
1277   }
1278 
1279   void addRelocationAArch64(uint64_t Offset, MCSymbol *Symbol, uint64_t RelType,
1280                             uint64_t Addend, uint64_t Value, bool IsCI) {
1281     std::map<uint64_t, Relocation> &Rels =
1282         (IsCI) ? Islands->Relocations : Relocations;
1283     switch (RelType) {
1284     case ELF::R_AARCH64_ABS64:
1285     case ELF::R_AARCH64_ABS32:
1286     case ELF::R_AARCH64_ABS16:
1287     case ELF::R_AARCH64_ADD_ABS_LO12_NC:
1288     case ELF::R_AARCH64_ADR_GOT_PAGE:
1289     case ELF::R_AARCH64_ADR_PREL_LO21:
1290     case ELF::R_AARCH64_ADR_PREL_PG_HI21:
1291     case ELF::R_AARCH64_ADR_PREL_PG_HI21_NC:
1292     case ELF::R_AARCH64_LD64_GOT_LO12_NC:
1293     case ELF::R_AARCH64_LDST8_ABS_LO12_NC:
1294     case ELF::R_AARCH64_LDST16_ABS_LO12_NC:
1295     case ELF::R_AARCH64_LDST32_ABS_LO12_NC:
1296     case ELF::R_AARCH64_LDST64_ABS_LO12_NC:
1297     case ELF::R_AARCH64_LDST128_ABS_LO12_NC:
1298     case ELF::R_AARCH64_TLSDESC_ADD_LO12:
1299     case ELF::R_AARCH64_TLSDESC_ADR_PAGE21:
1300     case ELF::R_AARCH64_TLSDESC_ADR_PREL21:
1301     case ELF::R_AARCH64_TLSDESC_LD64_LO12:
1302     case ELF::R_AARCH64_TLSIE_ADR_GOTTPREL_PAGE21:
1303     case ELF::R_AARCH64_TLSIE_LD64_GOTTPREL_LO12_NC:
1304     case ELF::R_AARCH64_MOVW_UABS_G0:
1305     case ELF::R_AARCH64_MOVW_UABS_G0_NC:
1306     case ELF::R_AARCH64_MOVW_UABS_G1:
1307     case ELF::R_AARCH64_MOVW_UABS_G1_NC:
1308     case ELF::R_AARCH64_MOVW_UABS_G2:
1309     case ELF::R_AARCH64_MOVW_UABS_G2_NC:
1310     case ELF::R_AARCH64_MOVW_UABS_G3:
1311     case ELF::R_AARCH64_PREL16:
1312     case ELF::R_AARCH64_PREL32:
1313     case ELF::R_AARCH64_PREL64:
1314       Rels[Offset] = Relocation{Offset, Symbol, RelType, Addend, Value};
1315       return;
1316     case ELF::R_AARCH64_CALL26:
1317     case ELF::R_AARCH64_JUMP26:
1318     case ELF::R_AARCH64_TSTBR14:
1319     case ELF::R_AARCH64_CONDBR19:
1320     case ELF::R_AARCH64_TLSDESC_CALL:
1321     case ELF::R_AARCH64_TLSLE_ADD_TPREL_HI12:
1322     case ELF::R_AARCH64_TLSLE_ADD_TPREL_LO12_NC:
1323       return;
1324     default:
1325       llvm_unreachable("Unexpected AArch64 relocation type in code");
1326     }
1327   }
1328 
1329   void addRelocationX86(uint64_t Offset, MCSymbol *Symbol, uint64_t RelType,
1330                         uint64_t Addend, uint64_t Value) {
1331     switch (RelType) {
1332     case ELF::R_X86_64_8:
1333     case ELF::R_X86_64_16:
1334     case ELF::R_X86_64_32:
1335     case ELF::R_X86_64_32S:
1336     case ELF::R_X86_64_64:
1337     case ELF::R_X86_64_PC8:
1338     case ELF::R_X86_64_PC32:
1339     case ELF::R_X86_64_PC64:
1340     case ELF::R_X86_64_GOTPCRELX:
1341     case ELF::R_X86_64_REX_GOTPCRELX:
1342       Relocations[Offset] = Relocation{Offset, Symbol, RelType, Addend, Value};
1343       return;
1344     case ELF::R_X86_64_PLT32:
1345     case ELF::R_X86_64_GOTPCREL:
1346     case ELF::R_X86_64_TPOFF32:
1347     case ELF::R_X86_64_GOTTPOFF:
1348       return;
1349     default:
1350       llvm_unreachable("Unexpected x86 relocation type in code");
1351     }
1352   }
1353 
1354   /// Register relocation type \p RelType at a given \p Address in the function
1355   /// against \p Symbol.
1356   /// Assert if the \p Address is not inside this function.
1357   void addRelocation(uint64_t Address, MCSymbol *Symbol, uint64_t RelType,
1358                      uint64_t Addend, uint64_t Value) {
1359     assert(Address >= getAddress() && Address < getAddress() + getMaxSize() &&
1360            "address is outside of the function");
1361     uint64_t Offset = Address - getAddress();
1362     if (BC.isAArch64()) {
1363       return addRelocationAArch64(Offset, Symbol, RelType, Addend, Value,
1364                                   isInConstantIsland(Address));
1365     }
1366 
1367     return addRelocationX86(Offset, Symbol, RelType, Addend, Value);
1368   }
1369 
1370   /// Return the name of the section this function originated from.
1371   Optional<StringRef> getOriginSectionName() const {
1372     if (!OriginSection)
1373       return NoneType();
1374     return OriginSection->getName();
1375   }
1376 
1377   /// Return internal section name for this function.
1378   StringRef getCodeSectionName() const { return StringRef(CodeSectionName); }
1379 
1380   /// Assign a code section name to the function.
1381   void setCodeSectionName(StringRef Name) {
1382     CodeSectionName = std::string(Name);
1383   }
1384 
1385   /// Get output code section.
1386   ErrorOr<BinarySection &> getCodeSection() const {
1387     return BC.getUniqueSectionByName(getCodeSectionName());
1388   }
1389 
1390   /// Return cold code section name for the function.
1391   StringRef getColdCodeSectionName() const {
1392     return StringRef(ColdCodeSectionName);
1393   }
1394 
1395   /// Assign a section name for the cold part of the function.
1396   void setColdCodeSectionName(StringRef Name) {
1397     ColdCodeSectionName = std::string(Name);
1398   }
1399 
1400   /// Get output code section for cold code of this function.
1401   ErrorOr<BinarySection &> getColdCodeSection() const {
1402     return BC.getUniqueSectionByName(getColdCodeSectionName());
1403   }
1404 
1405   /// Return true iif the function will halt execution on entry.
1406   bool trapsOnEntry() const { return TrapsOnEntry; }
1407 
1408   /// Make the function always trap on entry. Other than the trap instruction,
1409   /// the function body will be empty.
1410   void setTrapOnEntry();
1411 
1412   /// Return true if the function could be correctly processed.
1413   bool isSimple() const { return IsSimple; }
1414 
1415   /// Return true if the function should be ignored for optimization purposes.
1416   bool isIgnored() const { return IsIgnored; }
1417 
1418   /// Return true if the function should not be disassembled, emitted, or
1419   /// otherwise processed.
1420   bool isPseudo() const { return IsPseudo; }
1421 
1422   /// Return true if the function contains a jump table with entries pointing
1423   /// to split fragments.
1424   bool hasSplitJumpTable() const { return HasSplitJumpTable; }
1425 
1426   /// Return true if all CFG edges have local successors.
1427   bool hasCanonicalCFG() const { return HasCanonicalCFG; }
1428 
1429   /// Return true if the original function code has all necessary relocations
1430   /// to track addresses of functions emitted to new locations.
1431   bool hasExternalRefRelocations() const { return HasExternalRefRelocations; }
1432 
1433   /// Return true if the function has instruction(s) with unknown control flow.
1434   bool hasUnknownControlFlow() const { return HasUnknownControlFlow; }
1435 
1436   /// Return true if the function body is non-contiguous.
1437   bool isSplit() const {
1438     return isSimple() && layout_size() &&
1439            layout_front()->isCold() != layout_back()->isCold();
1440   }
1441 
1442   bool shouldPreserveNops() const { return PreserveNops; }
1443 
1444   /// Return true if the function has exception handling tables.
1445   bool hasEHRanges() const { return HasEHRanges; }
1446 
1447   /// Return true if the function uses DW_CFA_GNU_args_size CFIs.
1448   bool usesGnuArgsSize() const { return UsesGnuArgsSize; }
1449 
1450   /// Return true if the function has more than one entry point.
1451   bool isMultiEntry() const { return !SecondaryEntryPoints.empty(); }
1452 
1453   /// Return true if the function might have a profile available externally,
1454   /// but not yet populated into the function.
1455   bool hasProfileAvailable() const { return HasProfileAvailable; }
1456 
1457   bool hasMemoryProfile() const { return HasMemoryProfile; }
1458 
1459   /// Return true if the body of the function was merged into another function.
1460   bool isFolded() const { return FoldedIntoFunction != nullptr; }
1461 
1462   /// If this function was folded, return the function it was folded into.
1463   BinaryFunction *getFoldedIntoFunction() const { return FoldedIntoFunction; }
1464 
1465   /// Return true if the function uses jump tables.
1466   bool hasJumpTables() const { return !JumpTables.empty(); }
1467 
1468   /// Return true if the function has SDT marker
1469   bool hasSDTMarker() const { return HasSDTMarker; }
1470 
1471   /// Return true if the function has Pseudo Probe
1472   bool hasPseudoProbe() const { return HasPseudoProbe; }
1473 
1474   /// Return true if the original entry point was patched.
1475   bool isPatched() const { return IsPatched; }
1476 
1477   const JumpTable *getJumpTable(const MCInst &Inst) const {
1478     const uint64_t Address = BC.MIB->getJumpTable(Inst);
1479     return getJumpTableContainingAddress(Address);
1480   }
1481 
1482   JumpTable *getJumpTable(const MCInst &Inst) {
1483     const uint64_t Address = BC.MIB->getJumpTable(Inst);
1484     return getJumpTableContainingAddress(Address);
1485   }
1486 
1487   const MCSymbol *getPersonalityFunction() const { return PersonalityFunction; }
1488 
1489   uint8_t getPersonalityEncoding() const { return PersonalityEncoding; }
1490 
1491   const CallSitesType &getCallSites() const { return CallSites; }
1492 
1493   const CallSitesType &getColdCallSites() const { return ColdCallSites; }
1494 
1495   const ArrayRef<uint8_t> getLSDAActionTable() const { return LSDAActionTable; }
1496 
1497   const LSDATypeTableTy &getLSDATypeTable() const { return LSDATypeTable; }
1498 
1499   const LSDATypeTableTy &getLSDATypeAddressTable() const {
1500     return LSDATypeAddressTable;
1501   }
1502 
1503   const ArrayRef<uint8_t> getLSDATypeIndexTable() const {
1504     return LSDATypeIndexTable;
1505   }
1506 
1507   const LabelsMapType &getLabels() const { return Labels; }
1508 
1509   IslandInfo &getIslandInfo() {
1510     assert(Islands && "function expected to have constant islands");
1511     return *Islands;
1512   }
1513 
1514   const IslandInfo &getIslandInfo() const {
1515     assert(Islands && "function expected to have constant islands");
1516     return *Islands;
1517   }
1518 
1519   /// Return true if the function has CFI instructions
1520   bool hasCFI() const {
1521     return !FrameInstructions.empty() || !CIEFrameInstructions.empty();
1522   }
1523 
1524   /// Return unique number associated with the function.
1525   uint64_t getFunctionNumber() const { return FunctionNumber; }
1526 
1527   /// Return true if the given address \p PC is inside the function body.
1528   bool containsAddress(uint64_t PC, bool UseMaxSize = false) const {
1529     if (UseMaxSize)
1530       return Address <= PC && PC < Address + MaxSize;
1531     return Address <= PC && PC < Address + Size;
1532   }
1533 
1534   /// Create a basic block at a given \p Offset in the
1535   /// function.
1536   /// If \p DeriveAlignment is true, set the alignment of the block based
1537   /// on the alignment of the existing offset.
1538   /// The new block is not inserted into the CFG.  The client must
1539   /// use insertBasicBlocks to add any new blocks to the CFG.
1540   std::unique_ptr<BinaryBasicBlock>
1541   createBasicBlock(uint64_t Offset, MCSymbol *Label = nullptr,
1542                    bool DeriveAlignment = false) {
1543     assert(BC.Ctx && "cannot be called with empty context");
1544     if (!Label) {
1545       std::unique_lock<std::shared_timed_mutex> Lock(BC.CtxMutex);
1546       Label = BC.Ctx->createNamedTempSymbol("BB");
1547     }
1548     auto BB = std::unique_ptr<BinaryBasicBlock>(
1549         new BinaryBasicBlock(this, Label, Offset));
1550 
1551     if (DeriveAlignment) {
1552       uint64_t DerivedAlignment = Offset & (1 + ~Offset);
1553       BB->setAlignment(std::min(DerivedAlignment, uint64_t(32)));
1554     }
1555 
1556     LabelToBB[Label] = BB.get();
1557 
1558     return BB;
1559   }
1560 
1561   /// Create a basic block at a given \p Offset in the
1562   /// function and append it to the end of list of blocks.
1563   /// If \p DeriveAlignment is true, set the alignment of the block based
1564   /// on the alignment of the existing offset.
1565   ///
1566   /// Returns NULL if basic block already exists at the \p Offset.
1567   BinaryBasicBlock *addBasicBlock(uint64_t Offset, MCSymbol *Label = nullptr,
1568                                   bool DeriveAlignment = false) {
1569     assert((CurrentState == State::CFG || !getBasicBlockAtOffset(Offset)) &&
1570            "basic block already exists in pre-CFG state");
1571 
1572     if (!Label) {
1573       std::unique_lock<std::shared_timed_mutex> Lock(BC.CtxMutex);
1574       Label = BC.Ctx->createNamedTempSymbol("BB");
1575     }
1576     std::unique_ptr<BinaryBasicBlock> BBPtr =
1577         createBasicBlock(Offset, Label, DeriveAlignment);
1578     BasicBlocks.emplace_back(BBPtr.release());
1579 
1580     BinaryBasicBlock *BB = BasicBlocks.back();
1581     BB->setIndex(BasicBlocks.size() - 1);
1582 
1583     if (CurrentState == State::Disassembled) {
1584       BasicBlockOffsets.emplace_back(Offset, BB);
1585     } else if (CurrentState == State::CFG) {
1586       BB->setLayoutIndex(layout_size());
1587       BasicBlocksLayout.emplace_back(BB);
1588     }
1589 
1590     assert(CurrentState == State::CFG ||
1591            (std::is_sorted(BasicBlockOffsets.begin(), BasicBlockOffsets.end(),
1592                            CompareBasicBlockOffsets()) &&
1593             std::is_sorted(begin(), end())));
1594 
1595     return BB;
1596   }
1597 
1598   /// Add basic block \BB as an entry point to the function. Return global
1599   /// symbol associated with the entry.
1600   MCSymbol *addEntryPoint(const BinaryBasicBlock &BB);
1601 
1602   /// Mark all blocks that are unreachable from a root (entry point
1603   /// or landing pad) as invalid.
1604   void markUnreachableBlocks();
1605 
1606   /// Rebuilds BBs layout, ignoring dead BBs. Returns the number of removed
1607   /// BBs and the removed number of bytes of code.
1608   std::pair<unsigned, uint64_t> eraseInvalidBBs();
1609 
1610   /// Get the relative order between two basic blocks in the original
1611   /// layout.  The result is > 0 if B occurs before A and < 0 if B
1612   /// occurs after A.  If A and B are the same block, the result is 0.
1613   signed getOriginalLayoutRelativeOrder(const BinaryBasicBlock *A,
1614                                         const BinaryBasicBlock *B) const {
1615     return getIndex(A) - getIndex(B);
1616   }
1617 
1618   /// Insert the BBs contained in NewBBs into the basic blocks for this
1619   /// function. Update the associated state of all blocks as needed, i.e.
1620   /// BB offsets and BB indices. The new BBs are inserted after Start.
1621   /// This operation could affect fallthrough branches for Start.
1622   ///
1623   void
1624   insertBasicBlocks(BinaryBasicBlock *Start,
1625                     std::vector<std::unique_ptr<BinaryBasicBlock>> &&NewBBs,
1626                     const bool UpdateLayout = true,
1627                     const bool UpdateCFIState = true,
1628                     const bool RecomputeLandingPads = true);
1629 
1630   iterator insertBasicBlocks(
1631       iterator StartBB, std::vector<std::unique_ptr<BinaryBasicBlock>> &&NewBBs,
1632       const bool UpdateLayout = true, const bool UpdateCFIState = true,
1633       const bool RecomputeLandingPads = true);
1634 
1635   /// Update the basic block layout for this function.  The BBs from
1636   /// [Start->Index, Start->Index + NumNewBlocks) are inserted into the
1637   /// layout after the BB indicated by Start.
1638   void updateLayout(BinaryBasicBlock *Start, const unsigned NumNewBlocks);
1639 
1640   /// Make sure basic blocks' indices match the current layout.
1641   void updateLayoutIndices() const {
1642     unsigned Index = 0;
1643     for (BinaryBasicBlock *BB : layout())
1644       BB->setLayoutIndex(Index++);
1645   }
1646 
1647   /// Recompute the CFI state for NumNewBlocks following Start after inserting
1648   /// new blocks into the CFG.  This must be called after updateLayout.
1649   void updateCFIState(BinaryBasicBlock *Start, const unsigned NumNewBlocks);
1650 
1651   /// Return true if we detected ambiguous jump tables in this function, which
1652   /// happen when one JT is used in more than one indirect jumps. This precludes
1653   /// us from splitting edges for this JT unless we duplicate the JT (see
1654   /// disambiguateJumpTables).
1655   bool checkForAmbiguousJumpTables();
1656 
1657   /// Detect when two distinct indirect jumps are using the same jump table and
1658   /// duplicate it, allocating a separate JT for each indirect branch. This is
1659   /// necessary for code transformations on the CFG that change an edge induced
1660   /// by an indirect branch, e.g.: instrumentation or shrink wrapping. However,
1661   /// this is only possible if we are not updating jump tables in place, but are
1662   /// writing it to a new location (moving them).
1663   void disambiguateJumpTables(MCPlusBuilder::AllocatorIdTy AllocId);
1664 
1665   /// Change \p OrigDest to \p NewDest in the jump table used at the end of
1666   /// \p BB. Returns false if \p OrigDest couldn't be find as a valid target
1667   /// and no replacement took place.
1668   bool replaceJumpTableEntryIn(BinaryBasicBlock *BB, BinaryBasicBlock *OldDest,
1669                                BinaryBasicBlock *NewDest);
1670 
1671   /// Split the CFG edge <From, To> by inserting an intermediate basic block.
1672   /// Returns a pointer to this new intermediate basic block. BB "From" will be
1673   /// updated to jump to the intermediate block, which in turn will have an
1674   /// unconditional branch to BB "To".
1675   /// User needs to manually call fixBranches(). This function only creates the
1676   /// correct CFG edges.
1677   BinaryBasicBlock *splitEdge(BinaryBasicBlock *From, BinaryBasicBlock *To);
1678 
1679   /// We may have built an overly conservative CFG for functions with calls
1680   /// to functions that the compiler knows will never return. In this case,
1681   /// clear all successors from these blocks.
1682   void deleteConservativeEdges();
1683 
1684   /// Determine direction of the branch based on the current layout.
1685   /// Callee is responsible of updating basic block indices prior to using
1686   /// this function (e.g. by calling BinaryFunction::updateLayoutIndices()).
1687   static bool isForwardBranch(const BinaryBasicBlock *From,
1688                               const BinaryBasicBlock *To) {
1689     assert(From->getFunction() == To->getFunction() &&
1690            "basic blocks should be in the same function");
1691     return To->getLayoutIndex() > From->getLayoutIndex();
1692   }
1693 
1694   /// Determine direction of the call to callee symbol relative to the start
1695   /// of this function.
1696   /// Note: this doesn't take function splitting into account.
1697   bool isForwardCall(const MCSymbol *CalleeSymbol) const;
1698 
1699   /// Dump function information to debug output. If \p PrintInstructions
1700   /// is true - include instruction disassembly.
1701   void dump(bool PrintInstructions = true) const;
1702 
1703   /// Print function information to the \p OS stream.
1704   void print(raw_ostream &OS, std::string Annotation = "",
1705              bool PrintInstructions = true) const;
1706 
1707   /// Print all relocations between \p Offset and \p Offset + \p Size in
1708   /// this function.
1709   void printRelocations(raw_ostream &OS, uint64_t Offset, uint64_t Size) const;
1710 
1711   /// Return true if function has a profile, even if the profile does not
1712   /// match CFG 100%.
1713   bool hasProfile() const { return ExecutionCount != COUNT_NO_PROFILE; }
1714 
1715   /// Return true if function profile is present and accurate.
1716   bool hasValidProfile() const {
1717     return ExecutionCount != COUNT_NO_PROFILE && ProfileMatchRatio == 1.0f;
1718   }
1719 
1720   /// Mark this function as having a valid profile.
1721   void markProfiled(uint16_t Flags) {
1722     if (ExecutionCount == COUNT_NO_PROFILE)
1723       ExecutionCount = 0;
1724     ProfileFlags = Flags;
1725     ProfileMatchRatio = 1.0f;
1726   }
1727 
1728   /// Return flags describing a profile for this function.
1729   uint16_t getProfileFlags() const { return ProfileFlags; }
1730 
1731   void addCFIInstruction(uint64_t Offset, MCCFIInstruction &&Inst) {
1732     assert(!Instructions.empty());
1733 
1734     // Fix CFI instructions skipping NOPs. We need to fix this because changing
1735     // CFI state after a NOP, besides being wrong and inaccurate,  makes it
1736     // harder for us to recover this information, since we can create empty BBs
1737     // with NOPs and then reorder it away.
1738     // We fix this by moving the CFI instruction just before any NOPs.
1739     auto I = Instructions.lower_bound(Offset);
1740     if (Offset == getSize()) {
1741       assert(I == Instructions.end() && "unexpected iterator value");
1742       // Sometimes compiler issues restore_state after all instructions
1743       // in the function (even after nop).
1744       --I;
1745       Offset = I->first;
1746     }
1747     assert(I->first == Offset && "CFI pointing to unknown instruction");
1748     if (I == Instructions.begin()) {
1749       CIEFrameInstructions.emplace_back(std::forward<MCCFIInstruction>(Inst));
1750       return;
1751     }
1752 
1753     --I;
1754     while (I != Instructions.begin() && BC.MIB->isNoop(I->second)) {
1755       Offset = I->first;
1756       --I;
1757     }
1758     OffsetToCFI.emplace(Offset, FrameInstructions.size());
1759     FrameInstructions.emplace_back(std::forward<MCCFIInstruction>(Inst));
1760     return;
1761   }
1762 
1763   BinaryBasicBlock::iterator addCFIInstruction(BinaryBasicBlock *BB,
1764                                                BinaryBasicBlock::iterator Pos,
1765                                                MCCFIInstruction &&Inst) {
1766     size_t Idx = FrameInstructions.size();
1767     FrameInstructions.emplace_back(std::forward<MCCFIInstruction>(Inst));
1768     return addCFIPseudo(BB, Pos, Idx);
1769   }
1770 
1771   /// Insert a CFI pseudo instruction in a basic block. This pseudo instruction
1772   /// is a placeholder that refers to a real MCCFIInstruction object kept by
1773   /// this function that will be emitted at that position.
1774   BinaryBasicBlock::iterator addCFIPseudo(BinaryBasicBlock *BB,
1775                                           BinaryBasicBlock::iterator Pos,
1776                                           uint32_t Offset) {
1777     MCInst CFIPseudo;
1778     BC.MIB->createCFI(CFIPseudo, Offset);
1779     return BB->insertPseudoInstr(Pos, CFIPseudo);
1780   }
1781 
1782   /// Retrieve the MCCFIInstruction object associated with a CFI pseudo.
1783   const MCCFIInstruction *getCFIFor(const MCInst &Instr) const {
1784     if (!BC.MIB->isCFI(Instr))
1785       return nullptr;
1786     uint32_t Offset = Instr.getOperand(0).getImm();
1787     assert(Offset < FrameInstructions.size() && "Invalid CFI offset");
1788     return &FrameInstructions[Offset];
1789   }
1790 
1791   void setCFIFor(const MCInst &Instr, MCCFIInstruction &&CFIInst) {
1792     assert(BC.MIB->isCFI(Instr) &&
1793            "attempting to change CFI in a non-CFI inst");
1794     uint32_t Offset = Instr.getOperand(0).getImm();
1795     assert(Offset < FrameInstructions.size() && "Invalid CFI offset");
1796     FrameInstructions[Offset] = std::move(CFIInst);
1797   }
1798 
1799   void mutateCFIRegisterFor(const MCInst &Instr, MCPhysReg NewReg);
1800 
1801   const MCCFIInstruction *mutateCFIOffsetFor(const MCInst &Instr,
1802                                              int64_t NewOffset);
1803 
1804   BinaryFunction &setFileOffset(uint64_t Offset) {
1805     FileOffset = Offset;
1806     return *this;
1807   }
1808 
1809   BinaryFunction &setSize(uint64_t S) {
1810     Size = S;
1811     return *this;
1812   }
1813 
1814   BinaryFunction &setMaxSize(uint64_t Size) {
1815     MaxSize = Size;
1816     return *this;
1817   }
1818 
1819   BinaryFunction &setOutputAddress(uint64_t Address) {
1820     OutputAddress = Address;
1821     return *this;
1822   }
1823 
1824   BinaryFunction &setOutputSize(uint64_t Size) {
1825     OutputSize = Size;
1826     return *this;
1827   }
1828 
1829   BinaryFunction &setSimple(bool Simple) {
1830     IsSimple = Simple;
1831     return *this;
1832   }
1833 
1834   void setPseudo(bool Pseudo) { IsPseudo = Pseudo; }
1835 
1836   BinaryFunction &setUsesGnuArgsSize(bool Uses = true) {
1837     UsesGnuArgsSize = Uses;
1838     return *this;
1839   }
1840 
1841   BinaryFunction &setHasProfileAvailable(bool V = true) {
1842     HasProfileAvailable = V;
1843     return *this;
1844   }
1845 
1846   /// Mark function that should not be emitted.
1847   void setIgnored();
1848 
1849   void setIsPatched(bool V) { IsPatched = V; }
1850 
1851   void setHasSplitJumpTable(bool V) { HasSplitJumpTable = V; }
1852 
1853   void setHasCanonicalCFG(bool V) { HasCanonicalCFG = V; }
1854 
1855   void setFolded(BinaryFunction *BF) { FoldedIntoFunction = BF; }
1856 
1857   BinaryFunction &setPersonalityFunction(uint64_t Addr) {
1858     assert(!PersonalityFunction && "can't set personality function twice");
1859     PersonalityFunction = BC.getOrCreateGlobalSymbol(Addr, "FUNCat");
1860     return *this;
1861   }
1862 
1863   BinaryFunction &setPersonalityEncoding(uint8_t Encoding) {
1864     PersonalityEncoding = Encoding;
1865     return *this;
1866   }
1867 
1868   BinaryFunction &setAlignment(uint16_t Align) {
1869     Alignment = Align;
1870     return *this;
1871   }
1872 
1873   uint16_t getAlignment() const { return Alignment; }
1874 
1875   BinaryFunction &setMaxAlignmentBytes(uint16_t MaxAlignBytes) {
1876     MaxAlignmentBytes = MaxAlignBytes;
1877     return *this;
1878   }
1879 
1880   uint16_t getMaxAlignmentBytes() const { return MaxAlignmentBytes; }
1881 
1882   BinaryFunction &setMaxColdAlignmentBytes(uint16_t MaxAlignBytes) {
1883     MaxColdAlignmentBytes = MaxAlignBytes;
1884     return *this;
1885   }
1886 
1887   uint16_t getMaxColdAlignmentBytes() const { return MaxColdAlignmentBytes; }
1888 
1889   BinaryFunction &setImageAddress(uint64_t Address) {
1890     ImageAddress = Address;
1891     return *this;
1892   }
1893 
1894   /// Return the address of this function' image in memory.
1895   uint64_t getImageAddress() const { return ImageAddress; }
1896 
1897   BinaryFunction &setImageSize(uint64_t Size) {
1898     ImageSize = Size;
1899     return *this;
1900   }
1901 
1902   /// Return the size of this function' image in memory.
1903   uint64_t getImageSize() const { return ImageSize; }
1904 
1905   /// Return true if the function is a secondary fragment of another function.
1906   bool isFragment() const { return IsFragment; }
1907 
1908   /// Returns if the given function is a parent fragment of this function.
1909   bool isParentFragment(BinaryFunction *Parent) const {
1910     return ParentFragments.count(Parent);
1911   }
1912 
1913   /// Set the profile data for the number of times the function was called.
1914   BinaryFunction &setExecutionCount(uint64_t Count) {
1915     ExecutionCount = Count;
1916     return *this;
1917   }
1918 
1919   /// Adjust execution count for the function by a given \p Count. The value
1920   /// \p Count will be subtracted from the current function count.
1921   ///
1922   /// The function will proportionally adjust execution count for all
1923   /// basic blocks and edges in the control flow graph.
1924   void adjustExecutionCount(uint64_t Count);
1925 
1926   /// Set LSDA address for the function.
1927   BinaryFunction &setLSDAAddress(uint64_t Address) {
1928     LSDAAddress = Address;
1929     return *this;
1930   }
1931 
1932   /// Set LSDA symbol for the function.
1933   BinaryFunction &setLSDASymbol(MCSymbol *Symbol) {
1934     LSDASymbol = Symbol;
1935     return *this;
1936   }
1937 
1938   /// Return the profile information about the number of times
1939   /// the function was executed.
1940   ///
1941   /// Return COUNT_NO_PROFILE if there's no profile info.
1942   uint64_t getExecutionCount() const { return ExecutionCount; }
1943 
1944   /// Return the raw profile information about the number of branch
1945   /// executions corresponding to this function.
1946   uint64_t getRawBranchCount() const { return RawBranchCount; }
1947 
1948   /// Return the execution count for functions with known profile.
1949   /// Return 0 if the function has no profile.
1950   uint64_t getKnownExecutionCount() const {
1951     return ExecutionCount == COUNT_NO_PROFILE ? 0 : ExecutionCount;
1952   }
1953 
1954   /// Return original LSDA address for the function or NULL.
1955   uint64_t getLSDAAddress() const { return LSDAAddress; }
1956 
1957   /// Return symbol pointing to function's LSDA.
1958   MCSymbol *getLSDASymbol() {
1959     if (LSDASymbol)
1960       return LSDASymbol;
1961     if (CallSites.empty())
1962       return nullptr;
1963 
1964     LSDASymbol = BC.Ctx->getOrCreateSymbol(
1965         Twine("GCC_except_table") + Twine::utohexstr(getFunctionNumber()));
1966 
1967     return LSDASymbol;
1968   }
1969 
1970   /// Return symbol pointing to function's LSDA for the cold part.
1971   MCSymbol *getColdLSDASymbol() {
1972     if (ColdLSDASymbol)
1973       return ColdLSDASymbol;
1974     if (ColdCallSites.empty())
1975       return nullptr;
1976 
1977     ColdLSDASymbol = BC.Ctx->getOrCreateSymbol(
1978         Twine("GCC_cold_except_table") + Twine::utohexstr(getFunctionNumber()));
1979 
1980     return ColdLSDASymbol;
1981   }
1982 
1983   void setOutputDataAddress(uint64_t Address) { OutputDataOffset = Address; }
1984 
1985   uint64_t getOutputDataAddress() const { return OutputDataOffset; }
1986 
1987   void setOutputColdDataAddress(uint64_t Address) {
1988     OutputColdDataOffset = Address;
1989   }
1990 
1991   uint64_t getOutputColdDataAddress() const { return OutputColdDataOffset; }
1992 
1993   /// If \p Address represents an access to a constant island managed by this
1994   /// function, return a symbol so code can safely refer to it. Otherwise,
1995   /// return nullptr. First return value is the symbol for reference in the
1996   /// hot code area while the second return value is the symbol for reference
1997   /// in the cold code area, as when the function is split the islands are
1998   /// duplicated.
1999   MCSymbol *getOrCreateIslandAccess(uint64_t Address) {
2000     if (!Islands)
2001       return nullptr;
2002 
2003     MCSymbol *Symbol;
2004     if (!isInConstantIsland(Address))
2005       return nullptr;
2006 
2007     // Register our island at global namespace
2008     Symbol = BC.getOrCreateGlobalSymbol(Address, "ISLANDat");
2009 
2010     // Internal bookkeeping
2011     const uint64_t Offset = Address - getAddress();
2012     assert((!Islands->Offsets.count(Offset) ||
2013             Islands->Offsets[Offset] == Symbol) &&
2014            "Inconsistent island symbol management");
2015     if (!Islands->Offsets.count(Offset)) {
2016       Islands->Offsets[Offset] = Symbol;
2017       Islands->Symbols.insert(Symbol);
2018     }
2019     return Symbol;
2020   }
2021 
2022   /// Called by an external function which wishes to emit references to constant
2023   /// island symbols of this function. We create a proxy for it, so we emit
2024   /// separate symbols when emitting our constant island on behalf of this other
2025   /// function.
2026   MCSymbol *getOrCreateProxyIslandAccess(uint64_t Address,
2027                                          BinaryFunction &Referrer) {
2028     MCSymbol *Symbol = getOrCreateIslandAccess(Address);
2029     if (!Symbol)
2030       return nullptr;
2031 
2032     MCSymbol *Proxy;
2033     if (!Islands->Proxies[&Referrer].count(Symbol)) {
2034       Proxy = BC.Ctx->getOrCreateSymbol(Symbol->getName() + ".proxy.for." +
2035                                         Referrer.getPrintName());
2036       Islands->Proxies[&Referrer][Symbol] = Proxy;
2037       Islands->Proxies[&Referrer][Proxy] = Symbol;
2038     }
2039     Proxy = Islands->Proxies[&Referrer][Symbol];
2040     return Proxy;
2041   }
2042 
2043   /// Make this function depend on \p BF because we have a reference to its
2044   /// constant island. When emitting this function,  we will also emit
2045   //  \p BF's constants. This only happens in custom AArch64 assembly code.
2046   void createIslandDependency(MCSymbol *Island, BinaryFunction *BF) {
2047     if (!Islands)
2048       Islands = std::make_unique<IslandInfo>();
2049 
2050     Islands->Dependency.insert(BF);
2051     Islands->ProxySymbols[Island] = BF;
2052   }
2053 
2054   /// Detects whether \p Address is inside a data region in this function
2055   /// (constant islands).
2056   bool isInConstantIsland(uint64_t Address) const {
2057     if (!Islands)
2058       return false;
2059 
2060     if (Address < getAddress())
2061       return false;
2062 
2063     uint64_t Offset = Address - getAddress();
2064 
2065     if (Offset >= getMaxSize())
2066       return false;
2067 
2068     auto DataIter = Islands->DataOffsets.upper_bound(Offset);
2069     if (DataIter == Islands->DataOffsets.begin())
2070       return false;
2071     DataIter = std::prev(DataIter);
2072 
2073     auto CodeIter = Islands->CodeOffsets.upper_bound(Offset);
2074     if (CodeIter == Islands->CodeOffsets.begin())
2075       return true;
2076 
2077     return *std::prev(CodeIter) <= *DataIter;
2078   }
2079 
2080   uint16_t getConstantIslandAlignment() const {
2081     return Islands ? Islands->getAlignment() : 1;
2082   }
2083 
2084   uint64_t
2085   estimateConstantIslandSize(const BinaryFunction *OnBehalfOf = nullptr) const {
2086     if (!Islands)
2087       return 0;
2088 
2089     uint64_t Size = 0;
2090     for (auto DataIter = Islands->DataOffsets.begin();
2091          DataIter != Islands->DataOffsets.end(); ++DataIter) {
2092       auto NextData = std::next(DataIter);
2093       auto CodeIter = Islands->CodeOffsets.lower_bound(*DataIter);
2094       if (CodeIter == Islands->CodeOffsets.end() &&
2095           NextData == Islands->DataOffsets.end()) {
2096         Size += getMaxSize() - *DataIter;
2097         continue;
2098       }
2099 
2100       uint64_t NextMarker;
2101       if (CodeIter == Islands->CodeOffsets.end())
2102         NextMarker = *NextData;
2103       else if (NextData == Islands->DataOffsets.end())
2104         NextMarker = *CodeIter;
2105       else
2106         NextMarker = (*CodeIter > *NextData) ? *NextData : *CodeIter;
2107 
2108       Size += NextMarker - *DataIter;
2109     }
2110 
2111     if (!OnBehalfOf) {
2112       for (BinaryFunction *ExternalFunc : Islands->Dependency) {
2113         Size = alignTo(Size, ExternalFunc->getConstantIslandAlignment());
2114         Size += ExternalFunc->estimateConstantIslandSize(this);
2115       }
2116     }
2117 
2118     return Size;
2119   }
2120 
2121   bool hasIslandsInfo() const { return !!Islands; }
2122 
2123   bool hasConstantIsland() const {
2124     return Islands && !Islands->DataOffsets.empty();
2125   }
2126 
2127   /// Return true iff the symbol could be seen inside this function otherwise
2128   /// it is probably another function.
2129   bool isSymbolValidInScope(const SymbolRef &Symbol, uint64_t SymbolSize) const;
2130 
2131   /// Disassemble function from raw data.
2132   /// If successful, this function will populate the list of instructions
2133   /// for this function together with offsets from the function start
2134   /// in the input. It will also populate Labels with destinations for
2135   /// local branches, and TakenBranches with [from, to] info.
2136   ///
2137   /// The Function should be properly initialized before this function
2138   /// is called. I.e. function address and size should be set.
2139   ///
2140   /// Returns true on successful disassembly, and updates the current
2141   /// state to State:Disassembled.
2142   ///
2143   /// Returns false if disassembly failed.
2144   bool disassemble();
2145 
2146   /// Scan function for references to other functions. In relocation mode,
2147   /// add relocations for external references.
2148   ///
2149   /// Return true on success.
2150   bool scanExternalRefs();
2151 
2152   /// Return the size of a data object located at \p Offset in the function.
2153   /// Return 0 if there is no data object at the \p Offset.
2154   size_t getSizeOfDataInCodeAt(uint64_t Offset) const;
2155 
2156   /// Verify that starting at \p Offset function contents are filled with
2157   /// zero-value bytes.
2158   bool isZeroPaddingAt(uint64_t Offset) const;
2159 
2160   /// Check that entry points have an associated instruction at their
2161   /// offsets after disassembly.
2162   void postProcessEntryPoints();
2163 
2164   /// Post-processing for jump tables after disassembly. Since their
2165   /// boundaries are not known until all call sites are seen, we need this
2166   /// extra pass to perform any final adjustments.
2167   void postProcessJumpTables();
2168 
2169   /// Builds a list of basic blocks with successor and predecessor info.
2170   ///
2171   /// The function should in Disassembled state prior to call.
2172   ///
2173   /// Returns true on success and update the current function state to
2174   /// State::CFG. Returns false if CFG cannot be built.
2175   bool buildCFG(MCPlusBuilder::AllocatorIdTy);
2176 
2177   /// Perform post-processing of the CFG.
2178   void postProcessCFG();
2179 
2180   /// Verify that any assumptions we've made about indirect branches were
2181   /// correct and also make any necessary changes to unknown indirect branches.
2182   ///
2183   /// Catch-22: we need to know indirect branch targets to build CFG, and
2184   /// in order to determine the value for indirect branches we need to know CFG.
2185   ///
2186   /// As such, the process of decoding indirect branches is broken into 2 steps:
2187   /// first we make our best guess about a branch without knowing the CFG,
2188   /// and later after we have the CFG for the function, we verify our earlier
2189   /// assumptions and also do our best at processing unknown indirect branches.
2190   ///
2191   /// Return true upon successful processing, or false if the control flow
2192   /// cannot be statically evaluated for any given indirect branch.
2193   bool postProcessIndirectBranches(MCPlusBuilder::AllocatorIdTy AllocId);
2194 
2195   /// Return all call site profile info for this function.
2196   IndirectCallSiteProfile &getAllCallSites() { return AllCallSites; }
2197 
2198   const IndirectCallSiteProfile &getAllCallSites() const {
2199     return AllCallSites;
2200   }
2201 
2202   /// Walks the list of basic blocks filling in missing information about
2203   /// edge frequency for fall-throughs.
2204   ///
2205   /// Assumes the CFG has been built and edge frequency for taken branches
2206   /// has been filled with LBR data.
2207   void inferFallThroughCounts();
2208 
2209   /// Clear execution profile of the function.
2210   void clearProfile();
2211 
2212   /// Converts conditional tail calls to unconditional tail calls. We do this to
2213   /// handle conditional tail calls correctly and to give a chance to the
2214   /// simplify conditional tail call pass to decide whether to re-optimize them
2215   /// using profile information.
2216   void removeConditionalTailCalls();
2217 
2218   // Convert COUNT_NO_PROFILE to 0
2219   void removeTagsFromProfile();
2220 
2221   /// Computes a function hotness score: the sum of the products of BB frequency
2222   /// and size.
2223   uint64_t getFunctionScore() const;
2224 
2225   /// Return true if the layout has been changed by basic block reordering,
2226   /// false otherwise.
2227   bool hasLayoutChanged() const;
2228 
2229   /// Get the edit distance of the new layout with respect to the previous
2230   /// layout after basic block reordering.
2231   uint64_t getEditDistance() const;
2232 
2233   /// Get the number of instructions within this function.
2234   uint64_t getInstructionCount() const;
2235 
2236   const CFIInstrMapType &getFDEProgram() const { return FrameInstructions; }
2237 
2238   void moveRememberRestorePair(BinaryBasicBlock *BB);
2239 
2240   bool replayCFIInstrs(int32_t FromState, int32_t ToState,
2241                        BinaryBasicBlock *InBB,
2242                        BinaryBasicBlock::iterator InsertIt);
2243 
2244   /// unwindCFIState is used to unwind from a higher to a lower state number
2245   /// without using remember-restore instructions. We do that by keeping track
2246   /// of what values have been changed from state A to B and emitting
2247   /// instructions that undo this change.
2248   SmallVector<int32_t, 4> unwindCFIState(int32_t FromState, int32_t ToState,
2249                                          BinaryBasicBlock *InBB,
2250                                          BinaryBasicBlock::iterator &InsertIt);
2251 
2252   /// After reordering, this function checks the state of CFI and fixes it if it
2253   /// is corrupted. If it is unable to fix it, it returns false.
2254   bool finalizeCFIState();
2255 
2256   /// Return true if this function needs an address-transaltion table after
2257   /// its code emission.
2258   bool requiresAddressTranslation() const;
2259 
2260   /// Adjust branch instructions to match the CFG.
2261   ///
2262   /// As it comes to internal branches, the CFG represents "the ultimate source
2263   /// of truth". Transformations on functions and blocks have to update the CFG
2264   /// and fixBranches() would make sure the correct branch instructions are
2265   /// inserted at the end of basic blocks.
2266   ///
2267   /// We do require a conditional branch at the end of the basic block if
2268   /// the block has 2 successors as CFG currently lacks the conditional
2269   /// code support (it will probably stay that way). We only use this
2270   /// branch instruction for its conditional code, the destination is
2271   /// determined by CFG - first successor representing true/taken branch,
2272   /// while the second successor - false/fall-through branch.
2273   ///
2274   /// When we reverse the branch condition, the CFG is updated accordingly.
2275   void fixBranches();
2276 
2277   /// Mark function as finalized. No further optimizations are permitted.
2278   void setFinalized() { CurrentState = State::CFG_Finalized; }
2279 
2280   void setEmitted(bool KeepCFG = false) {
2281     CurrentState = State::EmittedCFG;
2282     if (!KeepCFG) {
2283       releaseCFG();
2284       CurrentState = State::Emitted;
2285     }
2286   }
2287 
2288   /// Process LSDA information for the function.
2289   void parseLSDA(ArrayRef<uint8_t> LSDAData, uint64_t LSDAAddress);
2290 
2291   /// Update exception handling ranges for the function.
2292   void updateEHRanges();
2293 
2294   /// Traverse cold basic blocks and replace references to constants in islands
2295   /// with a proxy symbol for the duplicated constant island that is going to be
2296   /// emitted in the cold region.
2297   void duplicateConstantIslands();
2298 
2299   /// Merge profile data of this function into those of the given
2300   /// function. The functions should have been proven identical with
2301   /// isIdenticalWith.
2302   void mergeProfileDataInto(BinaryFunction &BF) const;
2303 
2304   /// Returns the last computed hash value of the function.
2305   size_t getHash() const { return Hash; }
2306 
2307   using OperandHashFuncTy =
2308       function_ref<typename std::string(const MCOperand &)>;
2309 
2310   /// Compute the hash value of the function based on its contents.
2311   ///
2312   /// If \p UseDFS is set, process basic blocks in DFS order. Otherwise, use
2313   /// the existing layout order.
2314   ///
2315   /// By default, instruction operands are ignored while calculating the hash.
2316   /// The caller can change this via passing \p OperandHashFunc function.
2317   /// The return result of this function will be mixed with internal hash.
2318   size_t computeHash(
2319       bool UseDFS = false,
2320       OperandHashFuncTy OperandHashFunc = [](const MCOperand &) {
2321         return std::string();
2322       }) const;
2323 
2324   void setDWARFUnit(DWARFUnit *Unit) { DwarfUnit = Unit; }
2325 
2326   /// Return DWARF compile unit for this function.
2327   DWARFUnit *getDWARFUnit() const { return DwarfUnit; }
2328 
2329   /// Return line info table for this function.
2330   const DWARFDebugLine::LineTable *getDWARFLineTable() const {
2331     return getDWARFUnit() ? BC.DwCtx->getLineTableForUnit(getDWARFUnit())
2332                           : nullptr;
2333   }
2334 
2335   /// Finalize profile for the function.
2336   void postProcessProfile();
2337 
2338   /// Returns an estimate of the function's hot part after splitting.
2339   /// This is a very rough estimate, as with C++ exceptions there are
2340   /// blocks we don't move, and it makes no attempt at estimating the size
2341   /// of the added/removed branch instructions.
2342   /// Note that this size is optimistic and the actual size may increase
2343   /// after relaxation.
2344   size_t estimateHotSize(const bool UseSplitSize = true) const {
2345     size_t Estimate = 0;
2346     if (UseSplitSize && isSplit()) {
2347       for (const BinaryBasicBlock *BB : BasicBlocksLayout)
2348         if (!BB->isCold())
2349           Estimate += BC.computeCodeSize(BB->begin(), BB->end());
2350     } else {
2351       for (const BinaryBasicBlock *BB : BasicBlocksLayout)
2352         if (BB->getKnownExecutionCount() != 0)
2353           Estimate += BC.computeCodeSize(BB->begin(), BB->end());
2354     }
2355     return Estimate;
2356   }
2357 
2358   size_t estimateColdSize() const {
2359     if (!isSplit())
2360       return estimateSize();
2361     size_t Estimate = 0;
2362     for (const BinaryBasicBlock *BB : BasicBlocksLayout)
2363       if (BB->isCold())
2364         Estimate += BC.computeCodeSize(BB->begin(), BB->end());
2365     return Estimate;
2366   }
2367 
2368   size_t estimateSize() const {
2369     size_t Estimate = 0;
2370     for (const BinaryBasicBlock *BB : BasicBlocksLayout)
2371       Estimate += BC.computeCodeSize(BB->begin(), BB->end());
2372     return Estimate;
2373   }
2374 
2375   /// Return output address ranges for a function.
2376   DebugAddressRangesVector getOutputAddressRanges() const;
2377 
2378   /// Given an address corresponding to an instruction in the input binary,
2379   /// return an address of this instruction in output binary.
2380   ///
2381   /// Return 0 if no matching address could be found or the instruction was
2382   /// removed.
2383   uint64_t translateInputToOutputAddress(uint64_t Address) const;
2384 
2385   /// Take address ranges corresponding to the input binary and translate
2386   /// them to address ranges in the output binary.
2387   DebugAddressRangesVector translateInputToOutputRanges(
2388       const DWARFAddressRangesVector &InputRanges) const;
2389 
2390   /// Similar to translateInputToOutputRanges() but operates on location lists
2391   /// and moves associated data to output location lists.
2392   DebugLocationsVector
2393   translateInputToOutputLocationList(const DebugLocationsVector &InputLL) const;
2394 
2395   /// Return true if the function is an AArch64 linker inserted veneer
2396   bool isAArch64Veneer() const;
2397 
2398   virtual ~BinaryFunction();
2399 
2400   /// Info for fragmented functions.
2401   class FragmentInfo {
2402   private:
2403     uint64_t Address{0};
2404     uint64_t ImageAddress{0};
2405     uint64_t ImageSize{0};
2406     uint64_t FileOffset{0};
2407 
2408   public:
2409     uint64_t getAddress() const { return Address; }
2410     uint64_t getImageAddress() const { return ImageAddress; }
2411     uint64_t getImageSize() const { return ImageSize; }
2412     uint64_t getFileOffset() const { return FileOffset; }
2413 
2414     void setAddress(uint64_t VAddress) { Address = VAddress; }
2415     void setImageAddress(uint64_t Address) { ImageAddress = Address; }
2416     void setImageSize(uint64_t Size) { ImageSize = Size; }
2417     void setFileOffset(uint64_t Offset) { FileOffset = Offset; }
2418   };
2419 
2420   /// Cold fragment of the function.
2421   FragmentInfo ColdFragment;
2422 
2423   FragmentInfo &cold() { return ColdFragment; }
2424 
2425   const FragmentInfo &cold() const { return ColdFragment; }
2426 };
2427 
2428 inline raw_ostream &operator<<(raw_ostream &OS,
2429                                const BinaryFunction &Function) {
2430   OS << Function.getPrintName();
2431   return OS;
2432 }
2433 
2434 } // namespace bolt
2435 
2436 // GraphTraits specializations for function basic block graphs (CFGs)
2437 template <>
2438 struct GraphTraits<bolt::BinaryFunction *>
2439     : public GraphTraits<bolt::BinaryBasicBlock *> {
2440   static NodeRef getEntryNode(bolt::BinaryFunction *F) {
2441     return *F->layout_begin();
2442   }
2443 
2444   using nodes_iterator = pointer_iterator<bolt::BinaryFunction::iterator>;
2445 
2446   static nodes_iterator nodes_begin(bolt::BinaryFunction *F) {
2447     llvm_unreachable("Not implemented");
2448     return nodes_iterator(F->begin());
2449   }
2450   static nodes_iterator nodes_end(bolt::BinaryFunction *F) {
2451     llvm_unreachable("Not implemented");
2452     return nodes_iterator(F->end());
2453   }
2454   static size_t size(bolt::BinaryFunction *F) { return F->size(); }
2455 };
2456 
2457 template <>
2458 struct GraphTraits<const bolt::BinaryFunction *>
2459     : public GraphTraits<const bolt::BinaryBasicBlock *> {
2460   static NodeRef getEntryNode(const bolt::BinaryFunction *F) {
2461     return *F->layout_begin();
2462   }
2463 
2464   using nodes_iterator = pointer_iterator<bolt::BinaryFunction::const_iterator>;
2465 
2466   static nodes_iterator nodes_begin(const bolt::BinaryFunction *F) {
2467     llvm_unreachable("Not implemented");
2468     return nodes_iterator(F->begin());
2469   }
2470   static nodes_iterator nodes_end(const bolt::BinaryFunction *F) {
2471     llvm_unreachable("Not implemented");
2472     return nodes_iterator(F->end());
2473   }
2474   static size_t size(const bolt::BinaryFunction *F) { return F->size(); }
2475 };
2476 
2477 template <>
2478 struct GraphTraits<Inverse<bolt::BinaryFunction *>>
2479     : public GraphTraits<Inverse<bolt::BinaryBasicBlock *>> {
2480   static NodeRef getEntryNode(Inverse<bolt::BinaryFunction *> G) {
2481     return *G.Graph->layout_begin();
2482   }
2483 };
2484 
2485 template <>
2486 struct GraphTraits<Inverse<const bolt::BinaryFunction *>>
2487     : public GraphTraits<Inverse<const bolt::BinaryBasicBlock *>> {
2488   static NodeRef getEntryNode(Inverse<const bolt::BinaryFunction *> G) {
2489     return *G.Graph->layout_begin();
2490   }
2491 };
2492 
2493 } // namespace llvm
2494 
2495 #endif
2496