Sec(new Section(Name, Prot, Sections.size())); Sections.push_back(std::move(Sec)); return *Sections.back(); } /// Create a content block. Block &createContentBlock(Section &Parent, StringRef Content, uint64_t Address, uint64_t Alignment, uint64_t AlignmentOffset) { return createBlock(Parent, Content, Address, Alignment, AlignmentOffset); } /// Create a zero-fill block. Block &createZeroFillBlock(Section &Parent, uint64_t Size, uint64_t Address, uint64_t Alignment, uint64_t AlignmentOffset) { return createBlock(Parent, Size, Address, Alignment, AlignmentOffset); } /// Cache type for the splitBlock function. using SplitBlockCache = Optional>; /// Splits block B at the given index which must be greater than zero. /// If SplitIndex == B.getSize() then this function is a no-op and returns B. /// If SplitIndex < B.getSize() then this function returns a new block /// covering the range [ 0, SplitIndex ), and B is modified to cover the range /// [ SplitIndex, B.size() ). /// /// The optional Cache parameter can be used to speed up repeated calls to /// splitBlock for a single block. If the value is None the cache will be /// treated as uninitialized and splitBlock will populate it. Otherwise it /// is assumed to contain the list of Symbols pointing at B, sorted in /// descending order of offset. /// /// Notes: /// /// 1. The newly introduced block will have a new ordinal which will be /// higher than any other ordinals in the section. Clients are responsible /// for re-assigning block ordinals to restore a compatible order if /// needed. /// /// 2. The cache is not automatically updated if new symbols are introduced /// between calls to splitBlock. Any newly introduced symbols may be /// added to the cache manually (descending offset order must be /// preserved), or the cache can be set to None and rebuilt by /// splitBlock on the next call. Block &splitBlock(Block &B, size_t SplitIndex, SplitBlockCache *Cache = nullptr); /// Add an external symbol. /// Some formats (e.g. ELF) allow Symbols to have sizes. For Symbols whose /// size is not known, you should substitute '0'. /// For external symbols Linkage determines whether the symbol must be /// present during lookup: Externals with strong linkage must be found or /// an error will be emitted. Externals with weak linkage are permitted to /// be undefined, in which case they are assigned a value of 0. Symbol &addExternalSymbol(StringRef Name, uint64_t Size, Linkage L) { auto &Sym = Symbol::constructExternal(Allocator.Allocate(), createAddressable(0, false), Name, Size, L); ExternalSymbols.insert(&Sym); return Sym; } /// Add an absolute symbol. Symbol &addAbsoluteSymbol(StringRef Name, JITTargetAddress Address, uint64_t Size, Linkage L, Scope S, bool IsLive) { auto &Sym = Symbol::constructAbsolute(Allocator.Allocate(), createAddressable(Address), Name, Size, L, S, IsLive); AbsoluteSymbols.insert(&Sym); return Sym; } /// Convenience method for adding a weak zero-fill symbol. Symbol &addCommonSymbol(StringRef Name, Scope S, Section &Section, JITTargetAddress Address, uint64_t Size, uint64_t Alignment, bool IsLive) { auto &Sym = Symbol::constructCommon( Allocator.Allocate(), createBlock(Section, Size, Address, Alignment, 0), Name, Size, S, IsLive); Section.addSymbol(Sym); return Sym; } /// Add an anonymous symbol. Symbol &addAnonymousSymbol(Block &Content, JITTargetAddress Offset, JITTargetAddress Size, bool IsCallable, bool IsLive) { auto &Sym = Symbol::constructAnonDef(Allocator.Allocate(), Content, Offset, Size, IsCallable, IsLive); Content.getSection().addSymbol(Sym); return Sym; } /// Add a named symbol. Symbol &addDefinedSymbol(Block &Content, JITTargetAddress Offset, StringRef Name, JITTargetAddress Size, Linkage L, Scope S, bool IsCallable, bool IsLive) { auto &Sym = Symbol::constructNamedDef(Allocator.Allocate(), Content, Offset, Name, Size, L, S, IsLive, IsCallable); Content.getSection().addSymbol(Sym); return Sym; } iterator_range sections() { return make_range(section_iterator(Sections.begin()), section_iterator(Sections.end())); } /// Returns the section with the given name if it exists, otherwise returns /// null. Section *findSectionByName(StringRef Name) { for (auto &S : sections()) if (S.getName() == Name) return &S; return nullptr; } iterator_range blocks() { return make_range(block_iterator(Sections.begin(), Sections.end()), block_iterator(Sections.end(), Sections.end())); } iterator_range blocks() const { return make_range(const_block_iterator(Sections.begin(), Sections.end()), const_block_iterator(Sections.end(), Sections.end())); } iterator_range external_symbols() { return make_range(ExternalSymbols.begin(), ExternalSymbols.end()); } iterator_range absolute_symbols() { return make_range(AbsoluteSymbols.begin(), AbsoluteSymbols.end()); } iterator_range defined_symbols() { return make_range(defined_symbol_iterator(Sections.begin(), Sections.end()), defined_symbol_iterator(Sections.end(), Sections.end())); } iterator_range defined_symbols() const { return make_range( const_defined_symbol_iterator(Sections.begin(), Sections.end()), const_defined_symbol_iterator(Sections.end(), Sections.end())); } /// Turn a defined symbol into an external one. void makeExternal(Symbol &Sym) { if (Sym.getAddressable().isAbsolute()) { assert(AbsoluteSymbols.count(&Sym) && "Sym is not in the absolute symbols set"); AbsoluteSymbols.erase(&Sym); } else { assert(Sym.isDefined() && "Sym is not a defined symbol"); Section &Sec = Sym.getBlock().getSection(); Sec.removeSymbol(Sym); } Sym.makeExternal(createAddressable(false)); ExternalSymbols.insert(&Sym); } /// Removes an external symbol. Also removes the underlying Addressable. void removeExternalSymbol(Symbol &Sym) { assert(!Sym.isDefined() && !Sym.isAbsolute() && "Sym is not an external symbol"); assert(ExternalSymbols.count(&Sym) && "Symbol is not in the externals set"); ExternalSymbols.erase(&Sym); Addressable &Base = *Sym.Base; destroySymbol(Sym); destroyAddressable(Base); } /// Remove an absolute symbol. Also removes the underlying Addressable. void removeAbsoluteSymbol(Symbol &Sym) { assert(!Sym.isDefined() && Sym.isAbsolute() && "Sym is not an absolute symbol"); assert(AbsoluteSymbols.count(&Sym) && "Symbol is not in the absolute symbols set"); AbsoluteSymbols.erase(&Sym); Addressable &Base = *Sym.Base; destroySymbol(Sym); destroyAddressable(Base); } /// Removes defined symbols. Does not remove the underlying block. void removeDefinedSymbol(Symbol &Sym) { assert(Sym.isDefined() && "Sym is not a defined symbol"); Sym.getBlock().getSection().removeSymbol(Sym); destroySymbol(Sym); } /// Remove a block. void removeBlock(Block &B) { B.getSection().removeBlock(B); destroyBlock(B); } /// Dump the graph. /// /// If supplied, the EdgeKindToName function will be used to name edge /// kinds in the debug output. Otherwise raw edge kind numbers will be /// displayed. void dump(raw_ostream &OS, std::function EdegKindToName = std::function()); private: // Put the BumpPtrAllocator first so that we don't free any of the underlying // memory until the Symbol/Addressable destructors have been run. BumpPtrAllocator Allocator; std::string Name; unsigned PointerSize; support::endianness Endianness; SectionList Sections; ExternalSymbolSet ExternalSymbols; ExternalSymbolSet AbsoluteSymbols; }; /// Enables easy lookup of blocks by addresses. class BlockAddressMap { public: using AddrToBlockMap = std::map; using const_iterator = AddrToBlockMap::const_iterator; /// A block predicate that always adds all blocks. static bool includeAllBlocks(const Block &B) { return true; } /// A block predicate that always includes blocks with non-null addresses. static bool includeNonNull(const Block &B) { return B.getAddress(); } BlockAddressMap() = default; /// Add a block to the map. Returns an error if the block overlaps with any /// existing block. template Error addBlock(Block &B, PredFn Pred = includeAllBlocks) { if (!Pred(B)) return Error::success(); auto I = AddrToBlock.upper_bound(B.getAddress()); // If we're not at the end of the map, check for overlap with the next // element. if (I != AddrToBlock.end()) { if (B.getAddress() + B.getSize() > I->second->getAddress()) return overlapError(B, *I->second); } // If we're not at the start of the map, check for overlap with the previous // element. if (I != AddrToBlock.begin()) { auto &PrevBlock = *std::prev(I)->second; if (PrevBlock.getAddress() + PrevBlock.getSize() > B.getAddress()) return overlapError(B, PrevBlock); } AddrToBlock.insert(I, std::make_pair(B.getAddress(), &B)); return Error::success(); } /// Add a block to the map without checking for overlap with existing blocks. /// The client is responsible for ensuring that the block added does not /// overlap with any existing block. void addBlockWithoutChecking(Block &B) { AddrToBlock[B.getAddress()] = &B; } /// Add a range of blocks to the map. Returns an error if any block in the /// range overlaps with any other block in the range, or with any existing /// block in the map. template Error addBlocks(BlockPtrRange &&Blocks, PredFn Pred = includeAllBlocks) { for (auto *B : Blocks) if (auto Err = addBlock(*B, Pred)) return Err; return Error::success(); } /// Add a range of blocks to the map without checking for overlap with /// existing blocks. The client is responsible for ensuring that the block /// added does not overlap with any existing block. template void addBlocksWithoutChecking(BlockPtrRange &&Blocks) { for (auto *B : Blocks) addBlockWithoutChecking(*B); } /// Iterates over (Address, Block*) pairs in ascending order of address. const_iterator begin() const { return AddrToBlock.begin(); } const_iterator end() const { return AddrToBlock.end(); } /// Returns the block starting at the given address, or nullptr if no such /// block exists. Block *getBlockAt(JITTargetAddress Addr) const { auto I = AddrToBlock.find(Addr); if (I == AddrToBlock.end()) return nullptr; return I->second; } /// Returns the block covering the given address, or nullptr if no such block /// exists. Block *getBlockCovering(JITTargetAddress Addr) const { auto I = AddrToBlock.upper_bound(Addr); if (I == AddrToBlock.begin()) return nullptr; auto *B = std::prev(I)->second; if (Addr < B->getAddress() + B->getSize()) return B; return nullptr; } private: Error overlapError(Block &NewBlock, Block &ExistingBlock) { auto NewBlockEnd = NewBlock.getAddress() + NewBlock.getSize(); auto ExistingBlockEnd = ExistingBlock.getAddress() + ExistingBlock.getSize(); return make_error( "Block at " + formatv("{0:x16} -- {1:x16}", NewBlock.getAddress(), NewBlockEnd) + " overlaps " + formatv("{0:x16} -- {1:x16}", ExistingBlock.getAddress(), ExistingBlockEnd)); } AddrToBlockMap AddrToBlock; }; /// A map of addresses to Symbols. class SymbolAddressMap { public: using SymbolVector = SmallVector; /// Add a symbol to the SymbolAddressMap. void addSymbol(Symbol &Sym) { AddrToSymbols[Sym.getAddress()].push_back(&Sym); } /// Add all symbols in a given range to the SymbolAddressMap. template void addSymbols(SymbolPtrCollection &&Symbols) { for (auto *Sym : Symbols) addSymbol(*Sym); } /// Returns the list of symbols that start at the given address, or nullptr if /// no such symbols exist. const SymbolVector *getSymbolsAt(JITTargetAddress Addr) const { auto I = AddrToSymbols.find(Addr); if (I == AddrToSymbols.end()) return nullptr; return &I->second; } private: std::map AddrToSymbols; }; /// A function for mutating LinkGraphs. using LinkGraphPassFunction = std::function; /// A list of LinkGraph passes. using LinkGraphPassList = std::vector; /// An LinkGraph pass configuration, consisting of a list of pre-prune, /// post-prune, and post-fixup passes. struct PassConfiguration { /// Pre-prune passes. /// /// These passes are called on the graph after it is built, and before any /// symbols have been pruned. /// /// Notable use cases: Marking symbols live or should-discard. LinkGraphPassList PrePrunePasses; /// Post-prune passes. /// /// These passes are called on the graph after dead stripping, but before /// fixups are applied. /// /// Notable use cases: Building GOT, stub, and TLV symbols. LinkGraphPassList PostPrunePasses; /// Post-fixup passes. /// /// These passes are called on the graph after block contents has been copied /// to working memory, and fixups applied. /// /// Notable use cases: Testing and validation. LinkGraphPassList PostFixupPasses; }; /// Flags for symbol lookup. /// /// FIXME: These basically duplicate orc::SymbolLookupFlags -- We should merge /// the two types once we have an OrcSupport library. enum class SymbolLookupFlags { RequiredSymbol, WeaklyReferencedSymbol }; raw_ostream &operator<<(raw_ostream &OS, const SymbolLookupFlags &LF); /// A map of symbol names to resolved addresses. using AsyncLookupResult = DenseMap; /// A function object to call with a resolved symbol map (See AsyncLookupResult) /// or an error if resolution failed. class JITLinkAsyncLookupContinuation { public: virtual ~JITLinkAsyncLookupContinuation() {} virtual void run(Expected LR) = 0; private: virtual void anchor(); }; /// Create a lookup continuation from a function object. template std::unique_ptr createLookupContinuation(Continuation Cont) { class Impl final : public JITLinkAsyncLookupContinuation { public: Impl(Continuation C) : C(std::move(C)) {} void run(Expected LR) override { C(std::move(LR)); } private: Continuation C; }; return std::make_unique(std::move(Cont)); } /// Holds context for a single jitLink invocation. class JITLinkContext { public: using LookupMap = DenseMap; /// Destroy a JITLinkContext. virtual ~JITLinkContext(); /// Return the MemoryManager to be used for this link. virtual JITLinkMemoryManager &getMemoryManager() = 0; /// Returns a StringRef for the object buffer. /// This method can not be called once takeObjectBuffer has been called. virtual MemoryBufferRef getObjectBuffer() const = 0; /// Notify this context that linking failed. /// Called by JITLink if linking cannot be completed. virtual void notifyFailed(Error Err) = 0; /// Called by JITLink to resolve external symbols. This method is passed a /// lookup continutation which it must call with a result to continue the /// linking process. virtual void lookup(const LookupMap &Symbols, std::unique_ptr LC) = 0; /// Called by JITLink once all defined symbols in the graph have been assigned /// their final memory locations in the target process. At this point the /// LinkGraph can be inspected to build a symbol table, however the block /// content will not generally have been copied to the target location yet. virtual void notifyResolved(LinkGraph &G) = 0; /// Called by JITLink to notify the context that the object has been /// finalized (i.e. emitted to memory and memory permissions set). If all of /// this objects dependencies have also been finalized then the code is ready /// to run. virtual void notifyFinalized(std::unique_ptr A) = 0; /// Called by JITLink prior to linking to determine whether default passes for /// the target should be added. The default implementation returns true. /// If subclasses override this method to return false for any target then /// they are required to fully configure the pass pipeline for that target. virtual bool shouldAddDefaultTargetPasses(const Triple &TT) const; /// Returns the mark-live pass to be used for this link. If no pass is /// returned (the default) then the target-specific linker implementation will /// choose a conservative default (usually marking all symbols live). /// This function is only called if shouldAddDefaultTargetPasses returns true, /// otherwise the JITContext is responsible for adding a mark-live pass in /// modifyPassConfig. virtual LinkGraphPassFunction getMarkLivePass(const Triple &TT) const; /// Called by JITLink to modify the pass pipeline prior to linking. /// The default version performs no modification. virtual Error modifyPassConfig(const Triple &TT, PassConfiguration &Config); }; /// Marks all symbols in a graph live. This can be used as a default, /// conservative mark-live implementation. Error markAllSymbolsLive(LinkGraph &G); /// Basic JITLink implementation. /// /// This function will use sensible defaults for GOT and Stub handling. void jitLink(std::unique_ptr Ctx); } // end namespace jitlink } // end namespace llvm #endif // LLVM_EXECUTIONENGINE_JITLINK_JITLINK_H