/*===---------------- llvm-c/Orc.h - OrcV2 C bindings -----------*- C++ -*-===*\ |* *| |* Part of the LLVM Project, under the Apache License v2.0 with LLVM *| |* Exceptions. *| |* See https://llvm.org/LICENSE.txt for license information. *| |* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception *| |* *| |*===----------------------------------------------------------------------===*| |* *| |* This header declares the C interface to libLLVMOrcJIT.a, which implements *| |* JIT compilation of LLVM IR. Minimal documentation of C API specific issues *| |* (especially memory ownership rules) is provided. Core Orc concepts are *| |* documented in llvm/docs/ORCv2.rst and APIs are documented in the C++ *| |* headers *| |* *| |* Many exotic languages can interoperate with C code but have a harder time *| |* with C++ due to name mangling. So in addition to C, this interface enables *| |* tools written in such languages. *| |* *| |* Note: This interface is experimental. It is *NOT* stable, and may be *| |* changed without warning. Only C API usage documentation is *| |* provided. See the C++ documentation for all higher level ORC API *| |* details. *| |* *| \*===----------------------------------------------------------------------===*/ #ifndef LLVM_C_ORC_H #define LLVM_C_ORC_H #include "llvm-c/Error.h" #include "llvm-c/TargetMachine.h" #include "llvm-c/Types.h" LLVM_C_EXTERN_C_BEGIN /** * @defgroup LLVMCExecutionEngineORC On-Request-Compilation * @ingroup LLVMCExecutionEngine * * @{ */ /** * Represents an address in the executor process. */ typedef uint64_t LLVMOrcJITTargetAddress; /** * Represents an address in the executor process. */ typedef uint64_t LLVMOrcExecutorAddress; /** * Represents generic linkage flags for a symbol definition. */ typedef enum { LLVMJITSymbolGenericFlagsNone = 0, LLVMJITSymbolGenericFlagsExported = 1U << 0, LLVMJITSymbolGenericFlagsWeak = 1U << 1, LLVMJITSymbolGenericFlagsCallable = 1U << 2, LLVMJITSymbolGenericFlagsMaterializationSideEffectsOnly = 1U << 3 } LLVMJITSymbolGenericFlags; /** * Represents target specific flags for a symbol definition. */ typedef uint8_t LLVMJITSymbolTargetFlags; /** * Represents the linkage flags for a symbol definition. */ typedef struct { uint8_t GenericFlags; uint8_t TargetFlags; } LLVMJITSymbolFlags; /** * Represents an evaluated symbol address and flags. */ typedef struct { LLVMOrcExecutorAddress Address; LLVMJITSymbolFlags Flags; } LLVMJITEvaluatedSymbol; /** * A reference to an orc::ExecutionSession instance. */ typedef struct LLVMOrcOpaqueExecutionSession *LLVMOrcExecutionSessionRef; /** * Error reporter function. */ typedef void (*LLVMOrcErrorReporterFunction)(void *Ctx, LLVMErrorRef Err); /** * A reference to an orc::SymbolStringPool. */ typedef struct LLVMOrcOpaqueSymbolStringPool *LLVMOrcSymbolStringPoolRef; /** * A reference to an orc::SymbolStringPool table entry. */ typedef struct LLVMOrcOpaqueSymbolStringPoolEntry *LLVMOrcSymbolStringPoolEntryRef; /** * Represents a pair of a symbol name and LLVMJITSymbolFlags. */ typedef struct { LLVMOrcSymbolStringPoolEntryRef Name; LLVMJITSymbolFlags Flags; } LLVMOrcCSymbolFlagsMapPair; /** * Represents a list of (SymbolStringPtr, JITSymbolFlags) pairs that can be used * to construct a SymbolFlagsMap. */ typedef LLVMOrcCSymbolFlagsMapPair *LLVMOrcCSymbolFlagsMapPairs; /** * Represents a pair of a symbol name and an evaluated symbol. */ typedef struct { LLVMOrcSymbolStringPoolEntryRef Name; LLVMJITEvaluatedSymbol Sym; } LLVMOrcCSymbolMapPair; /** * Represents a list of (SymbolStringPtr, JITEvaluatedSymbol) pairs that can be * used to construct a SymbolMap. */ typedef LLVMOrcCSymbolMapPair *LLVMOrcCSymbolMapPairs; /** * Represents a SymbolAliasMapEntry */ typedef struct { LLVMOrcSymbolStringPoolEntryRef Name; LLVMJITSymbolFlags Flags; } LLVMOrcCSymbolAliasMapEntry; /** * Represents a pair of a symbol name and SymbolAliasMapEntry. */ typedef struct { LLVMOrcSymbolStringPoolEntryRef Name; LLVMOrcCSymbolAliasMapEntry Entry; } LLVMOrcCSymbolAliasMapPair; /** * Represents a list of (SymbolStringPtr, (SymbolStringPtr, JITSymbolFlags)) * pairs that can be used to construct a SymbolFlagsMap. */ typedef LLVMOrcCSymbolAliasMapPair *LLVMOrcCSymbolAliasMapPairs; /** * A reference to an orc::JITDylib instance. */ typedef struct LLVMOrcOpaqueJITDylib *LLVMOrcJITDylibRef; /** * Represents a list of LLVMOrcSymbolStringPoolEntryRef and the associated * length. */ typedef struct { LLVMOrcSymbolStringPoolEntryRef *Symbols; size_t Length; } LLVMOrcCSymbolsList; /** * Represents a pair of a JITDylib and LLVMOrcCSymbolsList. */ typedef struct { LLVMOrcJITDylibRef JD; LLVMOrcCSymbolsList Names; } LLVMOrcCDependenceMapPair; /** * Represents a list of (JITDylibRef, (LLVMOrcSymbolStringPoolEntryRef*, * size_t)) pairs that can be used to construct a SymbolDependenceMap. */ typedef LLVMOrcCDependenceMapPair *LLVMOrcCDependenceMapPairs; /** * A set of symbols that share dependencies. */ typedef struct { LLVMOrcCSymbolsList Symbols; LLVMOrcCDependenceMapPairs Dependencies; size_t NumDependencies; } LLVMOrcCSymbolDependenceGroup; /** * Lookup kind. This can be used by definition generators when deciding whether * to produce a definition for a requested symbol. * * This enum should be kept in sync with llvm::orc::LookupKind. */ typedef enum { LLVMOrcLookupKindStatic, LLVMOrcLookupKindDLSym } LLVMOrcLookupKind; /** * JITDylib lookup flags. This can be used by definition generators when * deciding whether to produce a definition for a requested symbol. * * This enum should be kept in sync with llvm::orc::JITDylibLookupFlags. */ typedef enum { LLVMOrcJITDylibLookupFlagsMatchExportedSymbolsOnly, LLVMOrcJITDylibLookupFlagsMatchAllSymbols } LLVMOrcJITDylibLookupFlags; /** * An element type for a JITDylib search order. */ typedef struct { LLVMOrcJITDylibRef JD; LLVMOrcJITDylibLookupFlags JDLookupFlags; } LLVMOrcCJITDylibSearchOrderElement; /** * A JITDylib search order. * * The list is terminated with an element containing a null pointer for the JD * field. */ typedef LLVMOrcCJITDylibSearchOrderElement *LLVMOrcCJITDylibSearchOrder; /** * Symbol lookup flags for lookup sets. This should be kept in sync with * llvm::orc::SymbolLookupFlags. */ typedef enum { LLVMOrcSymbolLookupFlagsRequiredSymbol, LLVMOrcSymbolLookupFlagsWeaklyReferencedSymbol } LLVMOrcSymbolLookupFlags; /** * An element type for a symbol lookup set. */ typedef struct { LLVMOrcSymbolStringPoolEntryRef Name; LLVMOrcSymbolLookupFlags LookupFlags; } LLVMOrcCLookupSetElement; /** * A set of symbols to look up / generate. * * The list is terminated with an element containing a null pointer for the * Name field. * * If a client creates an instance of this type then they are responsible for * freeing it, and for ensuring that all strings have been retained over the * course of its life. Clients receiving a copy from a callback are not * responsible for managing lifetime or retain counts. */ typedef LLVMOrcCLookupSetElement *LLVMOrcCLookupSet; /** * A reference to a uniquely owned orc::MaterializationUnit instance. */ typedef struct LLVMOrcOpaqueMaterializationUnit *LLVMOrcMaterializationUnitRef; /** * A reference to a uniquely owned orc::MaterializationResponsibility instance. * * Ownership must be passed to a lower-level layer in a JIT stack. */ typedef struct LLVMOrcOpaqueMaterializationResponsibility *LLVMOrcMaterializationResponsibilityRef; /** * A MaterializationUnit materialize callback. * * Ownership of the Ctx and MR arguments passes to the callback which must * adhere to the LLVMOrcMaterializationResponsibilityRef contract (see comment * for that type). * * If this callback is called then the LLVMOrcMaterializationUnitDestroy * callback will NOT be called. */ typedef void (*LLVMOrcMaterializationUnitMaterializeFunction)( void *Ctx, LLVMOrcMaterializationResponsibilityRef MR); /** * A MaterializationUnit discard callback. * * Ownership of JD and Symbol remain with the caller: These arguments should * not be disposed of or released. */ typedef void (*LLVMOrcMaterializationUnitDiscardFunction)( void *Ctx, LLVMOrcJITDylibRef JD, LLVMOrcSymbolStringPoolEntryRef Symbol); /** * A MaterializationUnit destruction callback. * * If a custom MaterializationUnit is destroyed before its Materialize * function is called then this function will be called to provide an * opportunity for the underlying program representation to be destroyed. */ typedef void (*LLVMOrcMaterializationUnitDestroyFunction)(void *Ctx); /** * A reference to an orc::ResourceTracker instance. */ typedef struct LLVMOrcOpaqueResourceTracker *LLVMOrcResourceTrackerRef; /** * A reference to an orc::DefinitionGenerator. */ typedef struct LLVMOrcOpaqueDefinitionGenerator *LLVMOrcDefinitionGeneratorRef; /** * An opaque lookup state object. Instances of this type can be captured to * suspend a lookup while a custom generator function attempts to produce a * definition. * * If a client captures a lookup state object then they must eventually call * LLVMOrcLookupStateContinueLookup to restart the lookup. This is required * in order to release memory allocated for the lookup state, even if errors * have occurred while the lookup was suspended (if these errors have made the * lookup impossible to complete then it will issue its own error before * destruction). */ typedef struct LLVMOrcOpaqueLookupState *LLVMOrcLookupStateRef; /** * A custom generator function. This can be used to create a custom generator * object using LLVMOrcCreateCustomCAPIDefinitionGenerator. The resulting * object can be attached to a JITDylib, via LLVMOrcJITDylibAddGenerator, to * receive callbacks when lookups fail to match existing definitions. * * GeneratorObj will contain the address of the custom generator object. * * Ctx will contain the context object passed to * LLVMOrcCreateCustomCAPIDefinitionGenerator. * * LookupState will contain a pointer to an LLVMOrcLookupStateRef object. This * can optionally be modified to make the definition generation process * asynchronous: If the LookupStateRef value is copied, and the original * LLVMOrcLookupStateRef set to null, the lookup will be suspended. Once the * asynchronous definition process has been completed clients must call * LLVMOrcLookupStateContinueLookup to continue the lookup (this should be * done unconditionally, even if errors have occurred in the mean time, to * free the lookup state memory and notify the query object of the failures). * If LookupState is captured this function must return LLVMErrorSuccess. * * The Kind argument can be inspected to determine the lookup kind (e.g. * as-if-during-static-link, or as-if-during-dlsym). * * The JD argument specifies which JITDylib the definitions should be generated * into. * * The JDLookupFlags argument can be inspected to determine whether the original * lookup included non-exported symbols. * * Finally, the LookupSet argument contains the set of symbols that could not * be found in JD already (the set of generation candidates). */ typedef LLVMErrorRef (*LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction)( LLVMOrcDefinitionGeneratorRef GeneratorObj, void *Ctx, LLVMOrcLookupStateRef *LookupState, LLVMOrcLookupKind Kind, LLVMOrcJITDylibRef JD, LLVMOrcJITDylibLookupFlags JDLookupFlags, LLVMOrcCLookupSet LookupSet, size_t LookupSetSize); /** * Disposer for a custom generator. * * Will be called by ORC when the JITDylib that the generator is attached to * is destroyed. */ typedef void (*LLVMOrcDisposeCAPIDefinitionGeneratorFunction)(void *Ctx); /** * Predicate function for SymbolStringPoolEntries. */ typedef int (*LLVMOrcSymbolPredicate)(void *Ctx, LLVMOrcSymbolStringPoolEntryRef Sym); /** * A reference to an orc::ThreadSafeContext instance. */ typedef struct LLVMOrcOpaqueThreadSafeContext *LLVMOrcThreadSafeContextRef; /** * A reference to an orc::ThreadSafeModule instance. */ typedef struct LLVMOrcOpaqueThreadSafeModule *LLVMOrcThreadSafeModuleRef; /** * A function for inspecting/mutating IR modules, suitable for use with * LLVMOrcThreadSafeModuleWithModuleDo. */ typedef LLVMErrorRef (*LLVMOrcGenericIRModuleOperationFunction)( void *Ctx, LLVMModuleRef M); /** * A reference to an orc::JITTargetMachineBuilder instance. */ typedef struct LLVMOrcOpaqueJITTargetMachineBuilder *LLVMOrcJITTargetMachineBuilderRef; /** * A reference to an orc::ObjectLayer instance. */ typedef struct LLVMOrcOpaqueObjectLayer *LLVMOrcObjectLayerRef; /** * A reference to an orc::ObjectLinkingLayer instance. */ typedef struct LLVMOrcOpaqueObjectLinkingLayer *LLVMOrcObjectLinkingLayerRef; /** * A reference to an orc::IRTransformLayer instance. */ typedef struct LLVMOrcOpaqueIRTransformLayer *LLVMOrcIRTransformLayerRef; /** * A function for applying transformations as part of an transform layer. * * Implementations of this type are responsible for managing the lifetime * of the Module pointed to by ModInOut: If the LLVMModuleRef value is * overwritten then the function is responsible for disposing of the incoming * module. If the module is simply accessed/mutated in-place then ownership * returns to the caller and the function does not need to do any lifetime * management. * * Clients can call LLVMOrcLLJITGetIRTransformLayer to obtain the transform * layer of a LLJIT instance, and use LLVMOrcIRTransformLayerSetTransform * to set the function. This can be used to override the default transform * layer. */ typedef LLVMErrorRef (*LLVMOrcIRTransformLayerTransformFunction)( void *Ctx, LLVMOrcThreadSafeModuleRef *ModInOut, LLVMOrcMaterializationResponsibilityRef MR); /** * A reference to an orc::ObjectTransformLayer instance. */ typedef struct LLVMOrcOpaqueObjectTransformLayer *LLVMOrcObjectTransformLayerRef; /** * A function for applying transformations to an object file buffer. * * Implementations of this type are responsible for managing the lifetime * of the memory buffer pointed to by ObjInOut: If the LLVMMemoryBufferRef * value is overwritten then the function is responsible for disposing of the * incoming buffer. If the buffer is simply accessed/mutated in-place then * ownership returns to the caller and the function does not need to do any * lifetime management. * * The transform is allowed to return an error, in which case the ObjInOut * buffer should be disposed of and set to null. */ typedef LLVMErrorRef (*LLVMOrcObjectTransformLayerTransformFunction)( void *Ctx, LLVMMemoryBufferRef *ObjInOut); /** * A reference to an orc::IndirectStubsManager instance. */ typedef struct LLVMOrcOpaqueIndirectStubsManager *LLVMOrcIndirectStubsManagerRef; /** * A reference to an orc::LazyCallThroughManager instance. */ typedef struct LLVMOrcOpaqueLazyCallThroughManager *LLVMOrcLazyCallThroughManagerRef; /** * A reference to an orc::DumpObjects object. * * Can be used to dump object files to disk with unique names. Useful as an * ObjectTransformLayer transform. */ typedef struct LLVMOrcOpaqueDumpObjects *LLVMOrcDumpObjectsRef; /** * Attach a custom error reporter function to the ExecutionSession. * * The error reporter will be called to deliver failure notices that can not be * directly reported to a caller. For example, failure to resolve symbols in * the JIT linker is typically reported via the error reporter (callers * requesting definitions from the JIT will typically be delivered a * FailureToMaterialize error instead). */ void LLVMOrcExecutionSessionSetErrorReporter( LLVMOrcExecutionSessionRef ES, LLVMOrcErrorReporterFunction ReportError, void *Ctx); /** * Return a reference to the SymbolStringPool for an ExecutionSession. * * Ownership of the pool remains with the ExecutionSession: The caller is * not required to free the pool. */ LLVMOrcSymbolStringPoolRef LLVMOrcExecutionSessionGetSymbolStringPool(LLVMOrcExecutionSessionRef ES); /** * Clear all unreferenced symbol string pool entries. * * This can be called at any time to release unused entries in the * ExecutionSession's string pool. Since it locks the pool (preventing * interning of any new strings) it is recommended that it only be called * infrequently, ideally when the caller has reason to believe that some * entries will have become unreferenced, e.g. after removing a module or * closing a JITDylib. */ void LLVMOrcSymbolStringPoolClearDeadEntries(LLVMOrcSymbolStringPoolRef SSP); /** * Intern a string in the ExecutionSession's SymbolStringPool and return a * reference to it. This increments the ref-count of the pool entry, and the * returned value should be released once the client is done with it by * calling LLVMOrcReleaseSymbolStringPoolEntry. * * Since strings are uniqued within the SymbolStringPool * LLVMOrcSymbolStringPoolEntryRefs can be compared by value to test string * equality. * * Note that this function does not perform linker-mangling on the string. */ LLVMOrcSymbolStringPoolEntryRef LLVMOrcExecutionSessionIntern(LLVMOrcExecutionSessionRef ES, const char *Name); /** * Callback type for ExecutionSession lookups. * * If Err is LLVMErrorSuccess then Result will contain a pointer to a * list of ( SymbolStringPtr, JITEvaluatedSymbol ) pairs of length NumPairs. * * If Err is a failure value then Result and Ctx are undefined and should * not be accessed. The Callback is responsible for handling the error * value (e.g. by calling LLVMGetErrorMessage + LLVMDisposeErrorMessage). * * The caller retains ownership of the Result array and will release all * contained symbol names. Clients are responsible for retaining any symbol * names that they wish to hold after the function returns. */ typedef void (*LLVMOrcExecutionSessionLookupHandleResultFunction)( LLVMErrorRef Err, LLVMOrcCSymbolMapPairs Result, size_t NumPairs, void *Ctx); /** * Look up symbols in an execution session. * * This is a wrapper around the general ExecutionSession::lookup function. * * The SearchOrder argument contains a list of (JITDylibs, JITDylibSearchFlags) * pairs that describe the search order. The JITDylibs will be searched in the * given order to try to find the symbols in the Symbols argument. * * The Symbols argument should contain a null-terminated array of * (SymbolStringPtr, SymbolLookupFlags) pairs describing the symbols to be * searched for. This function takes ownership of the elements of the Symbols * array. The Name fields of the Symbols elements are taken to have been * retained by the client for this function. The client should *not* release the * Name fields, but are still responsible for destroying the array itself. * * The HandleResult function will be called once all searched for symbols have * been found, or an error occurs. The HandleResult function will be passed an * LLVMErrorRef indicating success or failure, and (on success) a * null-terminated LLVMOrcCSymbolMapPairs array containing the function result, * and the Ctx value passed to the lookup function. * * The client is fully responsible for managing the lifetime of the Ctx object. * A common idiom is to allocate the context prior to the lookup and deallocate * it in the handler. * * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE! */ void LLVMOrcExecutionSessionLookup( LLVMOrcExecutionSessionRef ES, LLVMOrcLookupKind K, LLVMOrcCJITDylibSearchOrder SearchOrder, size_t SearchOrderSize, LLVMOrcCLookupSet Symbols, size_t SymbolsSize, LLVMOrcExecutionSessionLookupHandleResultFunction HandleResult, void *Ctx); /** * Increments the ref-count for a SymbolStringPool entry. */ void LLVMOrcRetainSymbolStringPoolEntry(LLVMOrcSymbolStringPoolEntryRef S); /** * Reduces the ref-count for of a SymbolStringPool entry. */ void LLVMOrcReleaseSymbolStringPoolEntry(LLVMOrcSymbolStringPoolEntryRef S); /** * Return the c-string for the given symbol. This string will remain valid until * the entry is freed (once all LLVMOrcSymbolStringPoolEntryRefs have been * released). */ const char *LLVMOrcSymbolStringPoolEntryStr(LLVMOrcSymbolStringPoolEntryRef S); /** * Reduces the ref-count of a ResourceTracker. */ void LLVMOrcReleaseResourceTracker(LLVMOrcResourceTrackerRef RT); /** * Transfers tracking of all resources associated with resource tracker SrcRT * to resource tracker DstRT. */ void LLVMOrcResourceTrackerTransferTo(LLVMOrcResourceTrackerRef SrcRT, LLVMOrcResourceTrackerRef DstRT); /** * Remove all resources associated with the given tracker. See * ResourceTracker::remove(). */ LLVMErrorRef LLVMOrcResourceTrackerRemove(LLVMOrcResourceTrackerRef RT); /** * Dispose of a JITDylib::DefinitionGenerator. This should only be called if * ownership has not been passed to a JITDylib (e.g. because some error * prevented the client from calling LLVMOrcJITDylibAddGenerator). */ void LLVMOrcDisposeDefinitionGenerator(LLVMOrcDefinitionGeneratorRef DG); /** * Dispose of a MaterializationUnit. */ void LLVMOrcDisposeMaterializationUnit(LLVMOrcMaterializationUnitRef MU); /** * Create a custom MaterializationUnit. * * Name is a name for this MaterializationUnit to be used for identification * and logging purposes (e.g. if this MaterializationUnit produces an * object buffer then the name of that buffer will be derived from this name). * * The Syms list contains the names and linkages of the symbols provided by this * unit. This function takes ownership of the elements of the Syms array. The * Name fields of the array elements are taken to have been retained for this * function. The client should *not* release the elements of the array, but is * still responsible for destroying the array itself. * * The InitSym argument indicates whether or not this MaterializationUnit * contains static initializers. If three are no static initializers (the common * case) then this argument should be null. If there are static initializers * then InitSym should be set to a unique name that also appears in the Syms * list with the LLVMJITSymbolGenericFlagsMaterializationSideEffectsOnly flag * set. This function takes ownership of the InitSym, which should have been * retained twice on behalf of this function: once for the Syms entry and once * for InitSym. If clients wish to use the InitSym value after this function * returns they must retain it once more for themselves. * * If any of the symbols in the Syms list is looked up then the Materialize * function will be called. * * If any of the symbols in the Syms list is overridden then the Discard * function will be called. * * The caller owns the underling MaterializationUnit and is responsible for * either passing it to a JITDylib (via LLVMOrcJITDylibDefine) or disposing * of it by calling LLVMOrcDisposeMaterializationUnit. */ LLVMOrcMaterializationUnitRef LLVMOrcCreateCustomMaterializationUnit( const char *Name, void *Ctx, LLVMOrcCSymbolFlagsMapPairs Syms, size_t NumSyms, LLVMOrcSymbolStringPoolEntryRef InitSym, LLVMOrcMaterializationUnitMaterializeFunction Materialize, LLVMOrcMaterializationUnitDiscardFunction Discard, LLVMOrcMaterializationUnitDestroyFunction Destroy); /** * Create a MaterializationUnit to define the given symbols as pointing to * the corresponding raw addresses. * * This function takes ownership of the elements of the Syms array. The Name * fields of the array elements are taken to have been retained for this * function. This allows the following pattern... * * size_t NumPairs; * LLVMOrcCSymbolMapPairs Sym; * -- Build Syms array -- * LLVMOrcMaterializationUnitRef MU = * LLVMOrcAbsoluteSymbols(Syms, NumPairs); * * ... without requiring cleanup of the elements of the Sym array afterwards. * * The client is still responsible for deleting the Sym array itself. * * If a client wishes to reuse elements of the Sym array after this call they * must explicitly retain each of the elements for themselves. */ LLVMOrcMaterializationUnitRef LLVMOrcAbsoluteSymbols(LLVMOrcCSymbolMapPairs Syms, size_t NumPairs); /** * Create a MaterializationUnit to define lazy re-expots. These are callable * entry points that call through to the given symbols. * * This function takes ownership of the CallableAliases array. The Name * fields of the array elements are taken to have been retained for this * function. This allows the following pattern... * * size_t NumPairs; * LLVMOrcCSymbolAliasMapPairs CallableAliases; * -- Build CallableAliases array -- * LLVMOrcMaterializationUnitRef MU = * LLVMOrcLazyReexports(LCTM, ISM, JD, CallableAliases, NumPairs); * * ... without requiring cleanup of the elements of the CallableAliases array afterwards. * * The client is still responsible for deleting the CallableAliases array itself. * * If a client wishes to reuse elements of the CallableAliases array after this call they * must explicitly retain each of the elements for themselves. */ LLVMOrcMaterializationUnitRef LLVMOrcLazyReexports( LLVMOrcLazyCallThroughManagerRef LCTM, LLVMOrcIndirectStubsManagerRef ISM, LLVMOrcJITDylibRef SourceRef, LLVMOrcCSymbolAliasMapPairs CallableAliases, size_t NumPairs); // TODO: ImplSymbolMad SrcJDLoc /** * Disposes of the passed MaterializationResponsibility object. * * This should only be done after the symbols covered by the object have either * been resolved and emitted (via * LLVMOrcMaterializationResponsibilityNotifyResolved and * LLVMOrcMaterializationResponsibilityNotifyEmitted) or failed (via * LLVMOrcMaterializationResponsibilityFailMaterialization). */ void LLVMOrcDisposeMaterializationResponsibility( LLVMOrcMaterializationResponsibilityRef MR); /** * Returns the target JITDylib that these symbols are being materialized into. */ LLVMOrcJITDylibRef LLVMOrcMaterializationResponsibilityGetTargetDylib( LLVMOrcMaterializationResponsibilityRef MR); /** * Returns the ExecutionSession for this MaterializationResponsibility. */ LLVMOrcExecutionSessionRef LLVMOrcMaterializationResponsibilityGetExecutionSession( LLVMOrcMaterializationResponsibilityRef MR); /** * Returns the symbol flags map for this responsibility instance. * * The length of the array is returned in NumPairs and the caller is responsible * for the returned memory and needs to call LLVMOrcDisposeCSymbolFlagsMap. * * To use the returned symbols beyond the livetime of the * MaterializationResponsibility requires the caller to retain the symbols * explicitly. */ LLVMOrcCSymbolFlagsMapPairs LLVMOrcMaterializationResponsibilityGetSymbols( LLVMOrcMaterializationResponsibilityRef MR, size_t *NumPairs); /** * Disposes of the passed LLVMOrcCSymbolFlagsMap. * * Does not release the entries themselves. */ void LLVMOrcDisposeCSymbolFlagsMap(LLVMOrcCSymbolFlagsMapPairs Pairs); /** * Returns the initialization pseudo-symbol, if any. This symbol will also * be present in the SymbolFlagsMap for this MaterializationResponsibility * object. * * The returned symbol is not retained over any mutating operation of the * MaterializationResponsbility or beyond the lifetime thereof. */ LLVMOrcSymbolStringPoolEntryRef LLVMOrcMaterializationResponsibilityGetInitializerSymbol( LLVMOrcMaterializationResponsibilityRef MR); /** * Returns the names of any symbols covered by this * MaterializationResponsibility object that have queries pending. This * information can be used to return responsibility for unrequested symbols * back to the JITDylib via the delegate method. */ LLVMOrcSymbolStringPoolEntryRef * LLVMOrcMaterializationResponsibilityGetRequestedSymbols( LLVMOrcMaterializationResponsibilityRef MR, size_t *NumSymbols); /** * Disposes of the passed LLVMOrcSymbolStringPoolEntryRef* . * * Does not release the symbols themselves. */ void LLVMOrcDisposeSymbols(LLVMOrcSymbolStringPoolEntryRef *Symbols); /** * Notifies the target JITDylib that the given symbols have been resolved. * This will update the given symbols' addresses in the JITDylib, and notify * any pending queries on the given symbols of their resolution. The given * symbols must be ones covered by this MaterializationResponsibility * instance. Individual calls to this method may resolve a subset of the * symbols, but all symbols must have been resolved prior to calling emit. * * This method will return an error if any symbols being resolved have been * moved to the error state due to the failure of a dependency. If this * method returns an error then clients should log it and call * LLVMOrcMaterializationResponsibilityFailMaterialization. If no dependencies * have been registered for the symbols covered by this * MaterializationResponsibility then this method is guaranteed to return * LLVMErrorSuccess. */ LLVMErrorRef LLVMOrcMaterializationResponsibilityNotifyResolved( LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcCSymbolMapPairs Symbols, size_t NumPairs); /** * Notifies the target JITDylib (and any pending queries on that JITDylib) * that all symbols covered by this MaterializationResponsibility instance * have been emitted. * * This function takes ownership of the symbols in the Dependencies struct. * This allows the following pattern... * * LLVMOrcSymbolStringPoolEntryRef Names[] = {...}; * LLVMOrcCDependenceMapPair Dependence = {JD, {Names, sizeof(Names)}} * LLVMOrcMaterializationResponsibilityAddDependencies(JD, Name, &Dependence, * 1); * * ... without requiring cleanup of the elements of the Names array afterwards. * * The client is still responsible for deleting the Dependencies.Names arrays, * and the Dependencies array itself. * * This method will return an error if any symbols being resolved have been * moved to the error state due to the failure of a dependency. If this * method returns an error then clients should log it and call * LLVMOrcMaterializationResponsibilityFailMaterialization. * If no dependencies have been registered for the symbols covered by this * MaterializationResponsibility then this method is guaranteed to return * LLVMErrorSuccess. */ LLVMErrorRef LLVMOrcMaterializationResponsibilityNotifyEmitted( LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcCSymbolDependenceGroup *SymbolDepGroups, size_t NumSymbolDepGroups); /** * Attempt to claim responsibility for new definitions. This method can be * used to claim responsibility for symbols that are added to a * materialization unit during the compilation process (e.g. literal pool * symbols). Symbol linkage rules are the same as for symbols that are * defined up front: duplicate strong definitions will result in errors. * Duplicate weak definitions will be discarded (in which case they will * not be added to this responsibility instance). * * This method can be used by materialization units that want to add * additional symbols at materialization time (e.g. stubs, compile * callbacks, metadata) */ LLVMErrorRef LLVMOrcMaterializationResponsibilityDefineMaterializing( LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcCSymbolFlagsMapPairs Pairs, size_t NumPairs); /** * Notify all not-yet-emitted covered by this MaterializationResponsibility * instance that an error has occurred. * This will remove all symbols covered by this MaterializationResponsibility * from the target JITDylib, and send an error to any queries waiting on * these symbols. */ void LLVMOrcMaterializationResponsibilityFailMaterialization( LLVMOrcMaterializationResponsibilityRef MR); /** * Transfers responsibility to the given MaterializationUnit for all * symbols defined by that MaterializationUnit. This allows * materializers to break up work based on run-time information (e.g. * by introspecting which symbols have actually been looked up and * materializing only those). */ LLVMErrorRef LLVMOrcMaterializationResponsibilityReplace( LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcMaterializationUnitRef MU); /** * Delegates responsibility for the given symbols to the returned * materialization responsibility. Useful for breaking up work between * threads, or different kinds of materialization processes. * * The caller retains responsibility of the the passed * MaterializationResponsibility. */ LLVMErrorRef LLVMOrcMaterializationResponsibilityDelegate( LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcSymbolStringPoolEntryRef *Symbols, size_t NumSymbols, LLVMOrcMaterializationResponsibilityRef *Result); /** * Create a "bare" JITDylib. * * The client is responsible for ensuring that the JITDylib's name is unique, * e.g. by calling LLVMOrcExecutionSessionGetJTIDylibByName first. * * This call does not install any library code or symbols into the newly * created JITDylib. The client is responsible for all configuration. */ LLVMOrcJITDylibRef LLVMOrcExecutionSessionCreateBareJITDylib(LLVMOrcExecutionSessionRef ES, const char *Name); /** * Create a JITDylib. * * The client is responsible for ensuring that the JITDylib's name is unique, * e.g. by calling LLVMOrcExecutionSessionGetJTIDylibByName first. * * If a Platform is attached to the ExecutionSession then * Platform::setupJITDylib will be called to install standard platform symbols * (e.g. standard library interposes). If no Platform is installed then this * call is equivalent to LLVMExecutionSessionRefCreateBareJITDylib and will * always return success. */ LLVMErrorRef LLVMOrcExecutionSessionCreateJITDylib(LLVMOrcExecutionSessionRef ES, LLVMOrcJITDylibRef *Result, const char *Name); /** * Returns the JITDylib with the given name, or NULL if no such JITDylib * exists. */ LLVMOrcJITDylibRef LLVMOrcExecutionSessionGetJITDylibByName(LLVMOrcExecutionSessionRef ES, const char *Name); /** * Return a reference to a newly created resource tracker associated with JD. * The tracker is returned with an initial ref-count of 1, and must be released * with LLVMOrcReleaseResourceTracker when no longer needed. */ LLVMOrcResourceTrackerRef LLVMOrcJITDylibCreateResourceTracker(LLVMOrcJITDylibRef JD); /** * Return a reference to the default resource tracker for the given JITDylib. * This operation will increase the retain count of the tracker: Clients should * call LLVMOrcReleaseResourceTracker when the result is no longer needed. */ LLVMOrcResourceTrackerRef LLVMOrcJITDylibGetDefaultResourceTracker(LLVMOrcJITDylibRef JD); /** * Add the given MaterializationUnit to the given JITDylib. * * If this operation succeeds then JITDylib JD will take ownership of MU. * If the operation fails then ownership remains with the caller who should * call LLVMOrcDisposeMaterializationUnit to destroy it. */ LLVMErrorRef LLVMOrcJITDylibDefine(LLVMOrcJITDylibRef JD, LLVMOrcMaterializationUnitRef MU); /** * Calls remove on all trackers associated with this JITDylib, see * JITDylib::clear(). */ LLVMErrorRef LLVMOrcJITDylibClear(LLVMOrcJITDylibRef JD); /** * Add a DefinitionGenerator to the given JITDylib. * * The JITDylib will take ownership of the given generator: The client is no * longer responsible for managing its memory. */ void LLVMOrcJITDylibAddGenerator(LLVMOrcJITDylibRef JD, LLVMOrcDefinitionGeneratorRef DG); /** * Create a custom generator. * * The F argument will be used to implement the DefinitionGenerator's * tryToGenerate method (see * LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction). * * Ctx is a context object that will be passed to F. This argument is * permitted to be null. * * Dispose is the disposal function for Ctx. This argument is permitted to be * null (in which case the client is responsible for the lifetime of Ctx). */ LLVMOrcDefinitionGeneratorRef LLVMOrcCreateCustomCAPIDefinitionGenerator( LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction F, void *Ctx, LLVMOrcDisposeCAPIDefinitionGeneratorFunction Dispose); /** * Continue a lookup that was suspended in a generator (see * LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction). */ void LLVMOrcLookupStateContinueLookup(LLVMOrcLookupStateRef S, LLVMErrorRef Err); /** * Get a DynamicLibrarySearchGenerator that will reflect process symbols into * the JITDylib. On success the resulting generator is owned by the client. * Ownership is typically transferred by adding the instance to a JITDylib * using LLVMOrcJITDylibAddGenerator, * * The GlobalPrefix argument specifies the character that appears on the front * of linker-mangled symbols for the target platform (e.g. '_' on MachO). * If non-null, this character will be stripped from the start of all symbol * strings before passing the remaining substring to dlsym. * * The optional Filter and Ctx arguments can be used to supply a symbol name * filter: Only symbols for which the filter returns true will be visible to * JIT'd code. If the Filter argument is null then all process symbols will * be visible to JIT'd code. Note that the symbol name passed to the Filter * function is the full mangled symbol: The client is responsible for stripping * the global prefix if present. */ LLVMErrorRef LLVMOrcCreateDynamicLibrarySearchGeneratorForProcess( LLVMOrcDefinitionGeneratorRef *Result, char GlobalPrefx, LLVMOrcSymbolPredicate Filter, void *FilterCtx); /** * Get a LLVMOrcCreateDynamicLibararySearchGeneratorForPath that will reflect * library symbols into the JITDylib. On success the resulting generator is * owned by the client. Ownership is typically transferred by adding the * instance to a JITDylib using LLVMOrcJITDylibAddGenerator, * * The GlobalPrefix argument specifies the character that appears on the front * of linker-mangled symbols for the target platform (e.g. '_' on MachO). * If non-null, this character will be stripped from the start of all symbol * strings before passing the remaining substring to dlsym. * * The optional Filter and Ctx arguments can be used to supply a symbol name * filter: Only symbols for which the filter returns true will be visible to * JIT'd code. If the Filter argument is null then all library symbols will * be visible to JIT'd code. Note that the symbol name passed to the Filter * function is the full mangled symbol: The client is responsible for stripping * the global prefix if present. * * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE! * */ LLVMErrorRef LLVMOrcCreateDynamicLibrarySearchGeneratorForPath( LLVMOrcDefinitionGeneratorRef *Result, const char *FileName, char GlobalPrefix, LLVMOrcSymbolPredicate Filter, void *FilterCtx); /** * Get a LLVMOrcCreateStaticLibrarySearchGeneratorForPath that will reflect * static library symbols into the JITDylib. On success the resulting * generator is owned by the client. Ownership is typically transferred by * adding the instance to a JITDylib using LLVMOrcJITDylibAddGenerator, * * Call with the optional TargetTriple argument will succeed if the file at * the given path is a static library or a MachO universal binary containing a * static library that is compatible with the given triple. Otherwise it will * return an error. * * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE! * */ LLVMErrorRef LLVMOrcCreateStaticLibrarySearchGeneratorForPath( LLVMOrcDefinitionGeneratorRef *Result, LLVMOrcObjectLayerRef ObjLayer, const char *FileName, const char *TargetTriple); /** * Create a ThreadSafeContext containing a new LLVMContext. * * Ownership of the underlying ThreadSafeContext data is shared: Clients * can and should dispose of their ThreadSafeContext as soon as they no longer * need to refer to it directly. Other references (e.g. from ThreadSafeModules) * will keep the data alive as long as it is needed. */ LLVMOrcThreadSafeContextRef LLVMOrcCreateNewThreadSafeContext(void); /** * Get a reference to the wrapped LLVMContext. */ LLVMContextRef LLVMOrcThreadSafeContextGetContext(LLVMOrcThreadSafeContextRef TSCtx); /** * Dispose of a ThreadSafeContext. */ void LLVMOrcDisposeThreadSafeContext(LLVMOrcThreadSafeContextRef TSCtx); /** * Create a ThreadSafeModule wrapper around the given LLVM module. This takes * ownership of the M argument which should not be disposed of or referenced * after this function returns. * * Ownership of the ThreadSafeModule is unique: If it is transferred to the JIT * (e.g. by LLVMOrcLLJITAddLLVMIRModule) then the client is no longer * responsible for it. If it is not transferred to the JIT then the client * should call LLVMOrcDisposeThreadSafeModule to dispose of it. */ LLVMOrcThreadSafeModuleRef LLVMOrcCreateNewThreadSafeModule(LLVMModuleRef M, LLVMOrcThreadSafeContextRef TSCtx); /** * Dispose of a ThreadSafeModule. This should only be called if ownership has * not been passed to LLJIT (e.g. because some error prevented the client from * adding this to the JIT). */ void LLVMOrcDisposeThreadSafeModule(LLVMOrcThreadSafeModuleRef TSM); /** * Apply the given function to the module contained in this ThreadSafeModule. */ LLVMErrorRef LLVMOrcThreadSafeModuleWithModuleDo(LLVMOrcThreadSafeModuleRef TSM, LLVMOrcGenericIRModuleOperationFunction F, void *Ctx); /** * Create a JITTargetMachineBuilder by detecting the host. * * On success the client owns the resulting JITTargetMachineBuilder. It must be * passed to a consuming operation (e.g. * LLVMOrcLLJITBuilderSetJITTargetMachineBuilder) or disposed of by calling * LLVMOrcDisposeJITTargetMachineBuilder. */ LLVMErrorRef LLVMOrcJITTargetMachineBuilderDetectHost( LLVMOrcJITTargetMachineBuilderRef *Result); /** * Create a JITTargetMachineBuilder from the given TargetMachine template. * * This operation takes ownership of the given TargetMachine and destroys it * before returing. The resulting JITTargetMachineBuilder is owned by the client * and must be passed to a consuming operation (e.g. * LLVMOrcLLJITBuilderSetJITTargetMachineBuilder) or disposed of by calling * LLVMOrcDisposeJITTargetMachineBuilder. */ LLVMOrcJITTargetMachineBuilderRef LLVMOrcJITTargetMachineBuilderCreateFromTargetMachine(LLVMTargetMachineRef TM); /** * Dispose of a JITTargetMachineBuilder. */ void LLVMOrcDisposeJITTargetMachineBuilder( LLVMOrcJITTargetMachineBuilderRef JTMB); /** * Returns the target triple for the given JITTargetMachineBuilder as a string. * * The caller owns the resulting string as must dispose of it by calling * LLVMDisposeMessage */ char *LLVMOrcJITTargetMachineBuilderGetTargetTriple( LLVMOrcJITTargetMachineBuilderRef JTMB); /** * Sets the target triple for the given JITTargetMachineBuilder to the given * string. */ void LLVMOrcJITTargetMachineBuilderSetTargetTriple( LLVMOrcJITTargetMachineBuilderRef JTMB, const char *TargetTriple); /** * Add an object to an ObjectLayer to the given JITDylib. * * Adds a buffer representing an object file to the given JITDylib using the * given ObjectLayer instance. This operation transfers ownership of the buffer * to the ObjectLayer instance. The buffer should not be disposed of or * referenced once this function returns. * * Resources associated with the given object will be tracked by the given * JITDylib's default ResourceTracker. */ LLVMErrorRef LLVMOrcObjectLayerAddObjectFile(LLVMOrcObjectLayerRef ObjLayer, LLVMOrcJITDylibRef JD, LLVMMemoryBufferRef ObjBuffer); /** * Add an object to an ObjectLayer using the given ResourceTracker. * * Adds a buffer representing an object file to the given ResourceTracker's * JITDylib using the given ObjectLayer instance. This operation transfers * ownership of the buffer to the ObjectLayer instance. The buffer should not * be disposed of or referenced once this function returns. * * Resources associated with the given object will be tracked by * ResourceTracker RT. */ LLVMErrorRef LLVMOrcObjectLayerAddObjectFileWithRT(LLVMOrcObjectLayerRef ObjLayer, LLVMOrcResourceTrackerRef RT, LLVMMemoryBufferRef ObjBuffer); /** * Emit an object buffer to an ObjectLayer. * * Ownership of the responsibility object and object buffer pass to this * function. The client is not responsible for cleanup. */ void LLVMOrcObjectLayerEmit(LLVMOrcObjectLayerRef ObjLayer, LLVMOrcMaterializationResponsibilityRef R, LLVMMemoryBufferRef ObjBuffer); /** * Dispose of an ObjectLayer. */ void LLVMOrcDisposeObjectLayer(LLVMOrcObjectLayerRef ObjLayer); void LLVMOrcIRTransformLayerEmit(LLVMOrcIRTransformLayerRef IRTransformLayer, LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcThreadSafeModuleRef TSM); /** * Set the transform function of the provided transform layer, passing through a * pointer to user provided context. */ void LLVMOrcIRTransformLayerSetTransform( LLVMOrcIRTransformLayerRef IRTransformLayer, LLVMOrcIRTransformLayerTransformFunction TransformFunction, void *Ctx); /** * Set the transform function on an LLVMOrcObjectTransformLayer. */ void LLVMOrcObjectTransformLayerSetTransform( LLVMOrcObjectTransformLayerRef ObjTransformLayer, LLVMOrcObjectTransformLayerTransformFunction TransformFunction, void *Ctx); /** * Create a LocalIndirectStubsManager from the given target triple. * * The resulting IndirectStubsManager is owned by the client * and must be disposed of by calling LLVMOrcDisposeDisposeIndirectStubsManager. */ LLVMOrcIndirectStubsManagerRef LLVMOrcCreateLocalIndirectStubsManager(const char *TargetTriple); /** * Dispose of an IndirectStubsManager. */ void LLVMOrcDisposeIndirectStubsManager(LLVMOrcIndirectStubsManagerRef ISM); LLVMErrorRef LLVMOrcCreateLocalLazyCallThroughManager( const char *TargetTriple, LLVMOrcExecutionSessionRef ES, LLVMOrcJITTargetAddress ErrorHandlerAddr, LLVMOrcLazyCallThroughManagerRef *LCTM); /** * Dispose of an LazyCallThroughManager. */ void LLVMOrcDisposeLazyCallThroughManager( LLVMOrcLazyCallThroughManagerRef LCTM); /** * Create a DumpObjects instance. * * DumpDir specifies the path to write dumped objects to. DumpDir may be empty * in which case files will be dumped to the working directory. * * IdentifierOverride specifies a file name stem to use when dumping objects. * If empty then each MemoryBuffer's identifier will be used (with a .o suffix * added if not already present). If an identifier override is supplied it will * be used instead, along with an incrementing counter (since all buffers will * use the same identifier, the resulting files will be named .o, * .2.o, .3.o, and so on). IdentifierOverride should not contain * an extension, as a .o suffix will be added by DumpObjects. */ LLVMOrcDumpObjectsRef LLVMOrcCreateDumpObjects(const char *DumpDir, const char *IdentifierOverride); /** * Dispose of a DumpObjects instance. */ void LLVMOrcDisposeDumpObjects(LLVMOrcDumpObjectsRef DumpObjects); /** * Dump the contents of the given MemoryBuffer. */ LLVMErrorRef LLVMOrcDumpObjects_CallOperator(LLVMOrcDumpObjectsRef DumpObjects, LLVMMemoryBufferRef *ObjBuffer); /** * @} */ LLVM_C_EXTERN_C_END #endif /* LLVM_C_ORC_H */