xref: /freebsd/contrib/llvm-project/llvm/include/llvm-c/Orc.h (revision 02e9120893770924227138ba49df1edb3896112a)
1 /*===---------------- llvm-c/Orc.h - OrcV2 C bindings -----------*- C++ -*-===*\
2 |*                                                                            *|
3 |* Part of the LLVM Project, under the Apache License v2.0 with LLVM          *|
4 |* Exceptions.                                                                *|
5 |* See https://llvm.org/LICENSE.txt for license information.                  *|
6 |* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception                    *|
7 |*                                                                            *|
8 |*===----------------------------------------------------------------------===*|
9 |*                                                                            *|
10 |* This header declares the C interface to libLLVMOrcJIT.a, which implements  *|
11 |* JIT compilation of LLVM IR. Minimal documentation of C API specific issues *|
12 |* (especially memory ownership rules) is provided. Core Orc concepts are     *|
13 |* documented in llvm/docs/ORCv2.rst and APIs are documented in the C++       *|
14 |* headers                                                                    *|
15 |*                                                                            *|
16 |* Many exotic languages can interoperate with C code but have a harder time  *|
17 |* with C++ due to name mangling. So in addition to C, this interface enables *|
18 |* tools written in such languages.                                           *|
19 |*                                                                            *|
20 |* Note: This interface is experimental. It is *NOT* stable, and may be       *|
21 |*       changed without warning. Only C API usage documentation is           *|
22 |*       provided. See the C++ documentation for all higher level ORC API     *|
23 |*       details.                                                             *|
24 |*                                                                            *|
25 \*===----------------------------------------------------------------------===*/
26 
27 #ifndef LLVM_C_ORC_H
28 #define LLVM_C_ORC_H
29 
30 #include "llvm-c/Error.h"
31 #include "llvm-c/TargetMachine.h"
32 #include "llvm-c/Types.h"
33 
34 LLVM_C_EXTERN_C_BEGIN
35 
36 /**
37  * @defgroup LLVMCExecutionEngineORC On-Request-Compilation
38  * @ingroup LLVMCExecutionEngine
39  *
40  * @{
41  */
42 
43 /**
44  * Represents an address in the executor process.
45  */
46 typedef uint64_t LLVMOrcJITTargetAddress;
47 
48 /**
49  * Represents an address in the executor process.
50  */
51 typedef uint64_t LLVMOrcExecutorAddress;
52 
53 /**
54  * Represents generic linkage flags for a symbol definition.
55  */
56 typedef enum {
57   LLVMJITSymbolGenericFlagsNone = 0,
58   LLVMJITSymbolGenericFlagsExported = 1U << 0,
59   LLVMJITSymbolGenericFlagsWeak = 1U << 1,
60   LLVMJITSymbolGenericFlagsCallable = 1U << 2,
61   LLVMJITSymbolGenericFlagsMaterializationSideEffectsOnly = 1U << 3
62 } LLVMJITSymbolGenericFlags;
63 
64 /**
65  * Represents target specific flags for a symbol definition.
66  */
67 typedef uint8_t LLVMJITSymbolTargetFlags;
68 
69 /**
70  * Represents the linkage flags for a symbol definition.
71  */
72 typedef struct {
73   uint8_t GenericFlags;
74   uint8_t TargetFlags;
75 } LLVMJITSymbolFlags;
76 
77 /**
78  * Represents an evaluated symbol address and flags.
79  */
80 typedef struct {
81   LLVMOrcExecutorAddress Address;
82   LLVMJITSymbolFlags Flags;
83 } LLVMJITEvaluatedSymbol;
84 
85 /**
86  * A reference to an orc::ExecutionSession instance.
87  */
88 typedef struct LLVMOrcOpaqueExecutionSession *LLVMOrcExecutionSessionRef;
89 
90 /**
91  * Error reporter function.
92  */
93 typedef void (*LLVMOrcErrorReporterFunction)(void *Ctx, LLVMErrorRef Err);
94 
95 /**
96  * A reference to an orc::SymbolStringPool.
97  */
98 typedef struct LLVMOrcOpaqueSymbolStringPool *LLVMOrcSymbolStringPoolRef;
99 
100 /**
101  * A reference to an orc::SymbolStringPool table entry.
102  */
103 typedef struct LLVMOrcOpaqueSymbolStringPoolEntry
104     *LLVMOrcSymbolStringPoolEntryRef;
105 
106 /**
107  * Represents a pair of a symbol name and LLVMJITSymbolFlags.
108  */
109 typedef struct {
110   LLVMOrcSymbolStringPoolEntryRef Name;
111   LLVMJITSymbolFlags Flags;
112 } LLVMOrcCSymbolFlagsMapPair;
113 
114 /**
115  * Represents a list of (SymbolStringPtr, JITSymbolFlags) pairs that can be used
116  * to construct a SymbolFlagsMap.
117  */
118 typedef LLVMOrcCSymbolFlagsMapPair *LLVMOrcCSymbolFlagsMapPairs;
119 
120 /**
121  * Represents a pair of a symbol name and an evaluated symbol.
122  */
123 typedef struct {
124   LLVMOrcSymbolStringPoolEntryRef Name;
125   LLVMJITEvaluatedSymbol Sym;
126 } LLVMOrcCSymbolMapPair;
127 
128 /**
129  * Represents a list of (SymbolStringPtr, JITEvaluatedSymbol) pairs that can be
130  * used to construct a SymbolMap.
131  */
132 typedef LLVMOrcCSymbolMapPair *LLVMOrcCSymbolMapPairs;
133 
134 /**
135  * Represents a SymbolAliasMapEntry
136  */
137 typedef struct {
138   LLVMOrcSymbolStringPoolEntryRef Name;
139   LLVMJITSymbolFlags Flags;
140 } LLVMOrcCSymbolAliasMapEntry;
141 
142 /**
143  * Represents a pair of a symbol name and SymbolAliasMapEntry.
144  */
145 typedef struct {
146   LLVMOrcSymbolStringPoolEntryRef Name;
147   LLVMOrcCSymbolAliasMapEntry Entry;
148 } LLVMOrcCSymbolAliasMapPair;
149 
150 /**
151  * Represents a list of (SymbolStringPtr, (SymbolStringPtr, JITSymbolFlags))
152  * pairs that can be used to construct a SymbolFlagsMap.
153  */
154 typedef LLVMOrcCSymbolAliasMapPair *LLVMOrcCSymbolAliasMapPairs;
155 
156 /**
157  * A reference to an orc::JITDylib instance.
158  */
159 typedef struct LLVMOrcOpaqueJITDylib *LLVMOrcJITDylibRef;
160 
161 /**
162  * Represents a list of LLVMOrcSymbolStringPoolEntryRef and the associated
163  * length.
164  */
165 typedef struct {
166   LLVMOrcSymbolStringPoolEntryRef *Symbols;
167   size_t Length;
168 } LLVMOrcCSymbolsList;
169 
170 /**
171  * Represents a pair of a JITDylib and LLVMOrcCSymbolsList.
172  */
173 typedef struct {
174   LLVMOrcJITDylibRef JD;
175   LLVMOrcCSymbolsList Names;
176 } LLVMOrcCDependenceMapPair;
177 
178 /**
179  * Represents a list of (JITDylibRef, (LLVMOrcSymbolStringPoolEntryRef*,
180  * size_t)) pairs that can be used to construct a SymbolDependenceMap.
181  */
182 typedef LLVMOrcCDependenceMapPair *LLVMOrcCDependenceMapPairs;
183 
184 /**
185  * Lookup kind. This can be used by definition generators when deciding whether
186  * to produce a definition for a requested symbol.
187  *
188  * This enum should be kept in sync with llvm::orc::LookupKind.
189  */
190 typedef enum {
191   LLVMOrcLookupKindStatic,
192   LLVMOrcLookupKindDLSym
193 } LLVMOrcLookupKind;
194 
195 /**
196  * JITDylib lookup flags. This can be used by definition generators when
197  * deciding whether to produce a definition for a requested symbol.
198  *
199  * This enum should be kept in sync with llvm::orc::JITDylibLookupFlags.
200  */
201 typedef enum {
202   LLVMOrcJITDylibLookupFlagsMatchExportedSymbolsOnly,
203   LLVMOrcJITDylibLookupFlagsMatchAllSymbols
204 } LLVMOrcJITDylibLookupFlags;
205 
206 /**
207  * An element type for a JITDylib search order.
208  */
209 typedef struct {
210   LLVMOrcJITDylibRef JD;
211   LLVMOrcJITDylibLookupFlags JDLookupFlags;
212 } LLVMOrcCJITDylibSearchOrderElement;
213 
214 /**
215  * A JITDylib search order.
216  *
217  * The list is terminated with an element containing a null pointer for the JD
218  * field.
219  */
220 typedef LLVMOrcCJITDylibSearchOrderElement *LLVMOrcCJITDylibSearchOrder;
221 
222 /**
223  * Symbol lookup flags for lookup sets. This should be kept in sync with
224  * llvm::orc::SymbolLookupFlags.
225  */
226 typedef enum {
227   LLVMOrcSymbolLookupFlagsRequiredSymbol,
228   LLVMOrcSymbolLookupFlagsWeaklyReferencedSymbol
229 } LLVMOrcSymbolLookupFlags;
230 
231 /**
232  * An element type for a symbol lookup set.
233  */
234 typedef struct {
235   LLVMOrcSymbolStringPoolEntryRef Name;
236   LLVMOrcSymbolLookupFlags LookupFlags;
237 } LLVMOrcCLookupSetElement;
238 
239 /**
240  * A set of symbols to look up / generate.
241  *
242  * The list is terminated with an element containing a null pointer for the
243  * Name field.
244  *
245  * If a client creates an instance of this type then they are responsible for
246  * freeing it, and for ensuring that all strings have been retained over the
247  * course of its life. Clients receiving a copy from a callback are not
248  * responsible for managing lifetime or retain counts.
249  */
250 typedef LLVMOrcCLookupSetElement *LLVMOrcCLookupSet;
251 
252 /**
253  * A reference to a uniquely owned orc::MaterializationUnit instance.
254  */
255 typedef struct LLVMOrcOpaqueMaterializationUnit *LLVMOrcMaterializationUnitRef;
256 
257 /**
258  * A reference to a uniquely owned orc::MaterializationResponsibility instance.
259  *
260  * Ownership must be passed to a lower-level layer in a JIT stack.
261  */
262 typedef struct LLVMOrcOpaqueMaterializationResponsibility
263     *LLVMOrcMaterializationResponsibilityRef;
264 
265 /**
266  * A MaterializationUnit materialize callback.
267  *
268  * Ownership of the Ctx and MR arguments passes to the callback which must
269  * adhere to the LLVMOrcMaterializationResponsibilityRef contract (see comment
270  * for that type).
271  *
272  * If this callback is called then the LLVMOrcMaterializationUnitDestroy
273  * callback will NOT be called.
274  */
275 typedef void (*LLVMOrcMaterializationUnitMaterializeFunction)(
276     void *Ctx, LLVMOrcMaterializationResponsibilityRef MR);
277 
278 /**
279  * A MaterializationUnit discard callback.
280  *
281  * Ownership of JD and Symbol remain with the caller: These arguments should
282  * not be disposed of or released.
283  */
284 typedef void (*LLVMOrcMaterializationUnitDiscardFunction)(
285     void *Ctx, LLVMOrcJITDylibRef JD, LLVMOrcSymbolStringPoolEntryRef Symbol);
286 
287 /**
288  * A MaterializationUnit destruction callback.
289  *
290  * If a custom MaterializationUnit is destroyed before its Materialize
291  * function is called then this function will be called to provide an
292  * opportunity for the underlying program representation to be destroyed.
293  */
294 typedef void (*LLVMOrcMaterializationUnitDestroyFunction)(void *Ctx);
295 
296 /**
297  * A reference to an orc::ResourceTracker instance.
298  */
299 typedef struct LLVMOrcOpaqueResourceTracker *LLVMOrcResourceTrackerRef;
300 
301 /**
302  * A reference to an orc::DefinitionGenerator.
303  */
304 typedef struct LLVMOrcOpaqueDefinitionGenerator
305     *LLVMOrcDefinitionGeneratorRef;
306 
307 /**
308  * An opaque lookup state object. Instances of this type can be captured to
309  * suspend a lookup while a custom generator function attempts to produce a
310  * definition.
311  *
312  * If a client captures a lookup state object then they must eventually call
313  * LLVMOrcLookupStateContinueLookup to restart the lookup. This is required
314  * in order to release memory allocated for the lookup state, even if errors
315  * have occurred while the lookup was suspended (if these errors have made the
316  * lookup impossible to complete then it will issue its own error before
317  * destruction).
318  */
319 typedef struct LLVMOrcOpaqueLookupState *LLVMOrcLookupStateRef;
320 
321 /**
322  * A custom generator function. This can be used to create a custom generator
323  * object using LLVMOrcCreateCustomCAPIDefinitionGenerator. The resulting
324  * object can be attached to a JITDylib, via LLVMOrcJITDylibAddGenerator, to
325  * receive callbacks when lookups fail to match existing definitions.
326  *
327  * GeneratorObj will contain the address of the custom generator object.
328  *
329  * Ctx will contain the context object passed to
330  * LLVMOrcCreateCustomCAPIDefinitionGenerator.
331  *
332  * LookupState will contain a pointer to an LLVMOrcLookupStateRef object. This
333  * can optionally be modified to make the definition generation process
334  * asynchronous: If the LookupStateRef value is copied, and the original
335  * LLVMOrcLookupStateRef set to null, the lookup will be suspended. Once the
336  * asynchronous definition process has been completed clients must call
337  * LLVMOrcLookupStateContinueLookup to continue the lookup (this should be
338  * done unconditionally, even if errors have occurred in the mean time, to
339  * free the lookup state memory and notify the query object of the failures).
340  * If LookupState is captured this function must return LLVMErrorSuccess.
341  *
342  * The Kind argument can be inspected to determine the lookup kind (e.g.
343  * as-if-during-static-link, or as-if-during-dlsym).
344  *
345  * The JD argument specifies which JITDylib the definitions should be generated
346  * into.
347  *
348  * The JDLookupFlags argument can be inspected to determine whether the original
349  * lookup included non-exported symobls.
350  *
351  * Finally, the LookupSet argument contains the set of symbols that could not
352  * be found in JD already (the set of generation candidates).
353  */
354 typedef LLVMErrorRef (*LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction)(
355     LLVMOrcDefinitionGeneratorRef GeneratorObj, void *Ctx,
356     LLVMOrcLookupStateRef *LookupState, LLVMOrcLookupKind Kind,
357     LLVMOrcJITDylibRef JD, LLVMOrcJITDylibLookupFlags JDLookupFlags,
358     LLVMOrcCLookupSet LookupSet, size_t LookupSetSize);
359 
360 /**
361  * Disposer for a custom generator.
362  *
363  * Will be called by ORC when the JITDylib that the generator is attached to
364  * is destroyed.
365  */
366 typedef void (*LLVMOrcDisposeCAPIDefinitionGeneratorFunction)(void *Ctx);
367 
368 /**
369  * Predicate function for SymbolStringPoolEntries.
370  */
371 typedef int (*LLVMOrcSymbolPredicate)(void *Ctx,
372                                       LLVMOrcSymbolStringPoolEntryRef Sym);
373 
374 /**
375  * A reference to an orc::ThreadSafeContext instance.
376  */
377 typedef struct LLVMOrcOpaqueThreadSafeContext *LLVMOrcThreadSafeContextRef;
378 
379 /**
380  * A reference to an orc::ThreadSafeModule instance.
381  */
382 typedef struct LLVMOrcOpaqueThreadSafeModule *LLVMOrcThreadSafeModuleRef;
383 
384 /**
385  * A function for inspecting/mutating IR modules, suitable for use with
386  * LLVMOrcThreadSafeModuleWithModuleDo.
387  */
388 typedef LLVMErrorRef (*LLVMOrcGenericIRModuleOperationFunction)(
389     void *Ctx, LLVMModuleRef M);
390 
391 /**
392  * A reference to an orc::JITTargetMachineBuilder instance.
393  */
394 typedef struct LLVMOrcOpaqueJITTargetMachineBuilder
395     *LLVMOrcJITTargetMachineBuilderRef;
396 
397 /**
398  * A reference to an orc::ObjectLayer instance.
399  */
400 typedef struct LLVMOrcOpaqueObjectLayer *LLVMOrcObjectLayerRef;
401 
402 /**
403  * A reference to an orc::ObjectLinkingLayer instance.
404  */
405 typedef struct LLVMOrcOpaqueObjectLinkingLayer *LLVMOrcObjectLinkingLayerRef;
406 
407 /**
408  * A reference to an orc::IRTransformLayer instance.
409  */
410 typedef struct LLVMOrcOpaqueIRTransformLayer *LLVMOrcIRTransformLayerRef;
411 
412 /**
413  * A function for applying transformations as part of an transform layer.
414  *
415  * Implementations of this type are responsible for managing the lifetime
416  * of the Module pointed to by ModInOut: If the LLVMModuleRef value is
417  * overwritten then the function is responsible for disposing of the incoming
418  * module. If the module is simply accessed/mutated in-place then ownership
419  * returns to the caller and the function does not need to do any lifetime
420  * management.
421  *
422  * Clients can call LLVMOrcLLJITGetIRTransformLayer to obtain the transform
423  * layer of a LLJIT instance, and use LLVMOrcIRTransformLayerSetTransform
424  * to set the function. This can be used to override the default transform
425  * layer.
426  */
427 typedef LLVMErrorRef (*LLVMOrcIRTransformLayerTransformFunction)(
428     void *Ctx, LLVMOrcThreadSafeModuleRef *ModInOut,
429     LLVMOrcMaterializationResponsibilityRef MR);
430 
431 /**
432  * A reference to an orc::ObjectTransformLayer instance.
433  */
434 typedef struct LLVMOrcOpaqueObjectTransformLayer
435     *LLVMOrcObjectTransformLayerRef;
436 
437 /**
438  * A function for applying transformations to an object file buffer.
439  *
440  * Implementations of this type are responsible for managing the lifetime
441  * of the memory buffer pointed to by ObjInOut: If the LLVMMemoryBufferRef
442  * value is overwritten then the function is responsible for disposing of the
443  * incoming buffer. If the buffer is simply accessed/mutated in-place then
444  * ownership returns to the caller and the function does not need to do any
445  * lifetime management.
446  *
447  * The transform is allowed to return an error, in which case the ObjInOut
448  * buffer should be disposed of and set to null.
449  */
450 typedef LLVMErrorRef (*LLVMOrcObjectTransformLayerTransformFunction)(
451     void *Ctx, LLVMMemoryBufferRef *ObjInOut);
452 
453 /**
454  * A reference to an orc::IndirectStubsManager instance.
455  */
456 typedef struct LLVMOrcOpaqueIndirectStubsManager
457     *LLVMOrcIndirectStubsManagerRef;
458 
459 /**
460  * A reference to an orc::LazyCallThroughManager instance.
461  */
462 typedef struct LLVMOrcOpaqueLazyCallThroughManager
463     *LLVMOrcLazyCallThroughManagerRef;
464 
465 /**
466  * A reference to an orc::DumpObjects object.
467  *
468  * Can be used to dump object files to disk with unique names. Useful as an
469  * ObjectTransformLayer transform.
470  */
471 typedef struct LLVMOrcOpaqueDumpObjects *LLVMOrcDumpObjectsRef;
472 
473 /**
474  * Attach a custom error reporter function to the ExecutionSession.
475  *
476  * The error reporter will be called to deliver failure notices that can not be
477  * directly reported to a caller. For example, failure to resolve symbols in
478  * the JIT linker is typically reported via the error reporter (callers
479  * requesting definitions from the JIT will typically be delivered a
480  * FailureToMaterialize error instead).
481  */
482 void LLVMOrcExecutionSessionSetErrorReporter(
483     LLVMOrcExecutionSessionRef ES, LLVMOrcErrorReporterFunction ReportError,
484     void *Ctx);
485 
486 /**
487  * Return a reference to the SymbolStringPool for an ExecutionSession.
488  *
489  * Ownership of the pool remains with the ExecutionSession: The caller is
490  * not required to free the pool.
491  */
492 LLVMOrcSymbolStringPoolRef
493 LLVMOrcExecutionSessionGetSymbolStringPool(LLVMOrcExecutionSessionRef ES);
494 
495 /**
496  * Clear all unreferenced symbol string pool entries.
497  *
498  * This can be called at any time to release unused entries in the
499  * ExecutionSession's string pool. Since it locks the pool (preventing
500  * interning of any new strings) it is recommended that it only be called
501  * infrequently, ideally when the caller has reason to believe that some
502  * entries will have become unreferenced, e.g. after removing a module or
503  * closing a JITDylib.
504  */
505 void LLVMOrcSymbolStringPoolClearDeadEntries(LLVMOrcSymbolStringPoolRef SSP);
506 
507 /**
508  * Intern a string in the ExecutionSession's SymbolStringPool and return a
509  * reference to it. This increments the ref-count of the pool entry, and the
510  * returned value should be released once the client is done with it by
511  * calling LLVMOrReleaseSymbolStringPoolEntry.
512  *
513  * Since strings are uniqued within the SymbolStringPool
514  * LLVMOrcSymbolStringPoolEntryRefs can be compared by value to test string
515  * equality.
516  *
517  * Note that this function does not perform linker-mangling on the string.
518  */
519 LLVMOrcSymbolStringPoolEntryRef
520 LLVMOrcExecutionSessionIntern(LLVMOrcExecutionSessionRef ES, const char *Name);
521 
522 /**
523  * Callback type for ExecutionSession lookups.
524  *
525  * If Err is LLVMErrorSuccess then Result will contain a pointer to a
526  * list of ( SymbolStringPtr, JITEvaluatedSymbol ) pairs of length NumPairs.
527  *
528  * If Err is a failure value then Result and Ctx are undefined and should
529  * not be accessed. The Callback is responsible for handling the error
530  * value (e.g. by calling LLVMGetErrorMessage + LLVMDisposeErrorMessage).
531  *
532  * The caller retains ownership of the Result array and will release all
533  * contained symbol names. Clients are responsible for retaining any symbol
534  * names that they wish to hold after the function returns.
535  */
536 typedef void (*LLVMOrcExecutionSessionLookupHandleResultFunction)(
537     LLVMErrorRef Err, LLVMOrcCSymbolMapPairs Result, size_t NumPairs,
538     void *Ctx);
539 
540 /**
541  * Look up symbols in an execution session.
542  *
543  * This is a wrapper around the general ExecutionSession::lookup function.
544  *
545  * The SearchOrder argument contains a list of (JITDylibs, JITDylibSearchFlags)
546  * pairs that describe the search order. The JITDylibs will be searched in the
547  * given order to try to find the symbols in the Symbols argument.
548  *
549  * The Symbols argument should contain a null-terminated array of
550  * (SymbolStringPtr, SymbolLookupFlags) pairs describing the symbols to be
551  * searched for. This function takes ownership of the elements of the Symbols
552  * array. The Name fields of the Symbols elements are taken to have been
553  * retained by the client for this function. The client should *not* release the
554  * Name fields, but are still responsible for destroying the array itself.
555  *
556  * The HandleResult function will be called once all searched for symbols have
557  * been found, or an error occurs. The HandleResult function will be passed an
558  * LLVMErrorRef indicating success or failure, and (on success) a
559  * null-terminated LLVMOrcCSymbolMapPairs array containing the function result,
560  * and the Ctx value passed to the lookup function.
561  *
562  * The client is fully responsible for managing the lifetime of the Ctx object.
563  * A common idiom is to allocate the context prior to the lookup and deallocate
564  * it in the handler.
565  *
566  * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE!
567  */
568 void LLVMOrcExecutionSessionLookup(
569     LLVMOrcExecutionSessionRef ES, LLVMOrcLookupKind K,
570     LLVMOrcCJITDylibSearchOrder SearchOrder, size_t SearchOrderSize,
571     LLVMOrcCLookupSet Symbols, size_t SymbolsSize,
572     LLVMOrcExecutionSessionLookupHandleResultFunction HandleResult, void *Ctx);
573 
574 /**
575  * Increments the ref-count for a SymbolStringPool entry.
576  */
577 void LLVMOrcRetainSymbolStringPoolEntry(LLVMOrcSymbolStringPoolEntryRef S);
578 
579 /**
580  * Reduces the ref-count for of a SymbolStringPool entry.
581  */
582 void LLVMOrcReleaseSymbolStringPoolEntry(LLVMOrcSymbolStringPoolEntryRef S);
583 
584 /**
585  * Return the c-string for the given symbol. This string will remain valid until
586  * the entry is freed (once all LLVMOrcSymbolStringPoolEntryRefs have been
587  * released).
588  */
589 const char *LLVMOrcSymbolStringPoolEntryStr(LLVMOrcSymbolStringPoolEntryRef S);
590 
591 /**
592  * Reduces the ref-count of a ResourceTracker.
593  */
594 void LLVMOrcReleaseResourceTracker(LLVMOrcResourceTrackerRef RT);
595 
596 /**
597  * Transfers tracking of all resources associated with resource tracker SrcRT
598  * to resource tracker DstRT.
599  */
600 void LLVMOrcResourceTrackerTransferTo(LLVMOrcResourceTrackerRef SrcRT,
601                                       LLVMOrcResourceTrackerRef DstRT);
602 
603 /**
604  * Remove all resources associated with the given tracker. See
605  * ResourceTracker::remove().
606  */
607 LLVMErrorRef LLVMOrcResourceTrackerRemove(LLVMOrcResourceTrackerRef RT);
608 
609 /**
610  * Dispose of a JITDylib::DefinitionGenerator. This should only be called if
611  * ownership has not been passed to a JITDylib (e.g. because some error
612  * prevented the client from calling LLVMOrcJITDylibAddGenerator).
613  */
614 void LLVMOrcDisposeDefinitionGenerator(LLVMOrcDefinitionGeneratorRef DG);
615 
616 /**
617  * Dispose of a MaterializationUnit.
618  */
619 void LLVMOrcDisposeMaterializationUnit(LLVMOrcMaterializationUnitRef MU);
620 
621 /**
622  * Create a custom MaterializationUnit.
623  *
624  * Name is a name for this MaterializationUnit to be used for identification
625  * and logging purposes (e.g. if this MaterializationUnit produces an
626  * object buffer then the name of that buffer will be derived from this name).
627  *
628  * The Syms list contains the names and linkages of the symbols provided by this
629  * unit. This function takes ownership of the elements of the Syms array. The
630  * Name fields of the array elements are taken to have been retained for this
631  * function. The client should *not* release the elements of the array, but is
632  * still responsible for destroying the array itself.
633  *
634  * The InitSym argument indicates whether or not this MaterializationUnit
635  * contains static initializers. If three are no static initializers (the common
636  * case) then this argument should be null. If there are static initializers
637  * then InitSym should be set to a unique name that also appears in the Syms
638  * list with the LLVMJITSymbolGenericFlagsMaterializationSideEffectsOnly flag
639  * set. This function takes ownership of the InitSym, which should have been
640  * retained twice on behalf of this function: once for the Syms entry and once
641  * for InitSym. If clients wish to use the InitSym value after this function
642  * returns they must retain it once more for themselves.
643  *
644  * If any of the symbols in the Syms list is looked up then the Materialize
645  * function will be called.
646  *
647  * If any of the symbols in the Syms list is overridden then the Discard
648  * function will be called.
649  *
650  * The caller owns the underling MaterializationUnit and is responsible for
651  * either passing it to a JITDylib (via LLVMOrcJITDylibDefine) or disposing
652  * of it by calling LLVMOrcDisposeMaterializationUnit.
653  */
654 LLVMOrcMaterializationUnitRef LLVMOrcCreateCustomMaterializationUnit(
655     const char *Name, void *Ctx, LLVMOrcCSymbolFlagsMapPairs Syms,
656     size_t NumSyms, LLVMOrcSymbolStringPoolEntryRef InitSym,
657     LLVMOrcMaterializationUnitMaterializeFunction Materialize,
658     LLVMOrcMaterializationUnitDiscardFunction Discard,
659     LLVMOrcMaterializationUnitDestroyFunction Destroy);
660 
661 /**
662  * Create a MaterializationUnit to define the given symbols as pointing to
663  * the corresponding raw addresses.
664  *
665  * This function takes ownership of the elements of the Syms array. The Name
666  * fields of the array elements are taken to have been retained for this
667  * function. This allows the following pattern...
668  *
669  *   size_t NumPairs;
670  *   LLVMOrcCSymbolMapPairs Sym;
671  *   -- Build Syms array --
672  *   LLVMOrcMaterializationUnitRef MU =
673  *       LLVMOrcAbsoluteSymbols(Syms, NumPairs);
674  *
675  * ... without requiring cleanup of the elements of the Sym array afterwards.
676  *
677  * The client is still responsible for deleting the Sym array itself.
678  *
679  * If a client wishes to reuse elements of the Sym array after this call they
680  * must explicitly retain each of the elements for themselves.
681  */
682 LLVMOrcMaterializationUnitRef
683 LLVMOrcAbsoluteSymbols(LLVMOrcCSymbolMapPairs Syms, size_t NumPairs);
684 
685 /**
686  * Create a MaterializationUnit to define lazy re-expots. These are callable
687  * entry points that call through to the given symbols.
688  *
689  * This function takes ownership of the CallableAliases array. The Name
690  * fields of the array elements are taken to have been retained for this
691  * function. This allows the following pattern...
692  *
693  *   size_t NumPairs;
694  *   LLVMOrcCSymbolAliasMapPairs CallableAliases;
695  *   -- Build CallableAliases array --
696  *   LLVMOrcMaterializationUnitRef MU =
697  *      LLVMOrcLazyReexports(LCTM, ISM, JD, CallableAliases, NumPairs);
698  *
699  * ... without requiring cleanup of the elements of the CallableAliases array afterwards.
700  *
701  * The client is still responsible for deleting the CallableAliases array itself.
702  *
703  * If a client wishes to reuse elements of the CallableAliases array after this call they
704  * must explicitly retain each of the elements for themselves.
705  */
706 LLVMOrcMaterializationUnitRef LLVMOrcLazyReexports(
707     LLVMOrcLazyCallThroughManagerRef LCTM, LLVMOrcIndirectStubsManagerRef ISM,
708     LLVMOrcJITDylibRef SourceRef, LLVMOrcCSymbolAliasMapPairs CallableAliases,
709     size_t NumPairs);
710 // TODO: ImplSymbolMad SrcJDLoc
711 
712 /**
713  * Disposes of the passed MaterializationResponsibility object.
714  *
715  * This should only be done after the symbols covered by the object have either
716  * been resolved and emitted (via
717  * LLVMOrcMaterializationResponsibilityNotifyResolved and
718  * LLVMOrcMaterializationResponsibilityNotifyEmitted) or failed (via
719  * LLVMOrcMaterializationResponsibilityFailMaterialization).
720  */
721 void LLVMOrcDisposeMaterializationResponsibility(
722     LLVMOrcMaterializationResponsibilityRef MR);
723 
724 /**
725  * Returns the target JITDylib that these symbols are being materialized into.
726  */
727 LLVMOrcJITDylibRef LLVMOrcMaterializationResponsibilityGetTargetDylib(
728     LLVMOrcMaterializationResponsibilityRef MR);
729 
730 /**
731  * Returns the ExecutionSession for this MaterializationResponsibility.
732  */
733 LLVMOrcExecutionSessionRef
734 LLVMOrcMaterializationResponsibilityGetExecutionSession(
735     LLVMOrcMaterializationResponsibilityRef MR);
736 
737 /**
738  * Returns the symbol flags map for this responsibility instance.
739  *
740  * The length of the array is returned in NumPairs and the caller is responsible
741  * for the returned memory and needs to call LLVMOrcDisposeCSymbolFlagsMap.
742  *
743  * To use the returned symbols beyond the livetime of the
744  * MaterializationResponsibility requires the caller to retain the symbols
745  * explicitly.
746  */
747 LLVMOrcCSymbolFlagsMapPairs LLVMOrcMaterializationResponsibilityGetSymbols(
748     LLVMOrcMaterializationResponsibilityRef MR, size_t *NumPairs);
749 
750 /**
751  * Disposes of the passed LLVMOrcCSymbolFlagsMap.
752  *
753  * Does not release the entries themselves.
754  */
755 void LLVMOrcDisposeCSymbolFlagsMap(LLVMOrcCSymbolFlagsMapPairs Pairs);
756 
757 /**
758  * Returns the initialization pseudo-symbol, if any. This symbol will also
759  * be present in the SymbolFlagsMap for this MaterializationResponsibility
760  * object.
761  *
762  * The returned symbol is not retained over any mutating operation of the
763  * MaterializationResponsbility or beyond the lifetime thereof.
764  */
765 LLVMOrcSymbolStringPoolEntryRef
766 LLVMOrcMaterializationResponsibilityGetInitializerSymbol(
767     LLVMOrcMaterializationResponsibilityRef MR);
768 
769 /**
770  * Returns the names of any symbols covered by this
771  * MaterializationResponsibility object that have queries pending. This
772  * information can be used to return responsibility for unrequested symbols
773  * back to the JITDylib via the delegate method.
774  */
775 LLVMOrcSymbolStringPoolEntryRef *
776 LLVMOrcMaterializationResponsibilityGetRequestedSymbols(
777     LLVMOrcMaterializationResponsibilityRef MR, size_t *NumSymbols);
778 
779 /**
780  * Disposes of the passed LLVMOrcSymbolStringPoolEntryRef* .
781  *
782  * Does not release the symbols themselves.
783  */
784 void LLVMOrcDisposeSymbols(LLVMOrcSymbolStringPoolEntryRef *Symbols);
785 
786 /**
787  * Notifies the target JITDylib that the given symbols have been resolved.
788  * This will update the given symbols' addresses in the JITDylib, and notify
789  * any pending queries on the given symbols of their resolution. The given
790  * symbols must be ones covered by this MaterializationResponsibility
791  * instance. Individual calls to this method may resolve a subset of the
792  * symbols, but all symbols must have been resolved prior to calling emit.
793  *
794  * This method will return an error if any symbols being resolved have been
795  * moved to the error state due to the failure of a dependency. If this
796  * method returns an error then clients should log it and call
797  * LLVMOrcMaterializationResponsibilityFailMaterialization. If no dependencies
798  * have been registered for the symbols covered by this
799  * MaterializationResponsibiility then this method is guaranteed to return
800  * LLVMErrorSuccess.
801  */
802 LLVMErrorRef LLVMOrcMaterializationResponsibilityNotifyResolved(
803     LLVMOrcMaterializationResponsibilityRef MR, LLVMOrcCSymbolMapPairs Symbols,
804     size_t NumPairs);
805 
806 /**
807  * Notifies the target JITDylib (and any pending queries on that JITDylib)
808  * that all symbols covered by this MaterializationResponsibility instance
809  * have been emitted.
810  *
811  * This method will return an error if any symbols being resolved have been
812  * moved to the error state due to the failure of a dependency. If this
813  * method returns an error then clients should log it and call
814  * LLVMOrcMaterializationResponsibilityFailMaterialization.
815  * If no dependencies have been registered for the symbols covered by this
816  * MaterializationResponsibiility then this method is guaranteed to return
817  * LLVMErrorSuccess.
818  */
819 LLVMErrorRef LLVMOrcMaterializationResponsibilityNotifyEmitted(
820     LLVMOrcMaterializationResponsibilityRef MR);
821 
822 /**
823  * Attempt to claim responsibility for new definitions. This method can be
824  * used to claim responsibility for symbols that are added to a
825  * materialization unit during the compilation process (e.g. literal pool
826  * symbols). Symbol linkage rules are the same as for symbols that are
827  * defined up front: duplicate strong definitions will result in errors.
828  * Duplicate weak definitions will be discarded (in which case they will
829  * not be added to this responsibility instance).
830  *
831  * This method can be used by materialization units that want to add
832  * additional symbols at materialization time (e.g. stubs, compile
833  * callbacks, metadata)
834  */
835 LLVMErrorRef LLVMOrcMaterializationResponsibilityDefineMaterializing(
836     LLVMOrcMaterializationResponsibilityRef MR,
837     LLVMOrcCSymbolFlagsMapPairs Pairs, size_t NumPairs);
838 
839 /**
840  * Notify all not-yet-emitted covered by this MaterializationResponsibility
841  * instance that an error has occurred.
842  * This will remove all symbols covered by this MaterializationResponsibilty
843  * from the target JITDylib, and send an error to any queries waiting on
844  * these symbols.
845  */
846 void LLVMOrcMaterializationResponsibilityFailMaterialization(
847     LLVMOrcMaterializationResponsibilityRef MR);
848 
849 /**
850  * Transfers responsibility to the given MaterializationUnit for all
851  * symbols defined by that MaterializationUnit. This allows
852  * materializers to break up work based on run-time information (e.g.
853  * by introspecting which symbols have actually been looked up and
854  * materializing only those).
855  */
856 LLVMErrorRef LLVMOrcMaterializationResponsibilityReplace(
857     LLVMOrcMaterializationResponsibilityRef MR,
858     LLVMOrcMaterializationUnitRef MU);
859 
860 /**
861  * Delegates responsibility for the given symbols to the returned
862  * materialization responsibility. Useful for breaking up work between
863  * threads, or different kinds of materialization processes.
864  *
865  * The caller retains responsibility of the the passed
866  * MaterializationResponsibility.
867  */
868 LLVMErrorRef LLVMOrcMaterializationResponsibilityDelegate(
869     LLVMOrcMaterializationResponsibilityRef MR,
870     LLVMOrcSymbolStringPoolEntryRef *Symbols, size_t NumSymbols,
871     LLVMOrcMaterializationResponsibilityRef *Result);
872 
873 /**
874  * Adds dependencies to a symbol that the MaterializationResponsibility is
875  * responsible for.
876  *
877  * This function takes ownership of Dependencies struct. The Names
878  * array have been retained for this function. This allows the following
879  * pattern...
880  *
881  *   LLVMOrcSymbolStringPoolEntryRef Names[] = {...};
882  *   LLVMOrcCDependenceMapPair Dependence = {JD, {Names, sizeof(Names)}}
883  *   LLVMOrcMaterializationResponsibilityAddDependencies(JD, Name, &Dependence,
884  * 1);
885  *
886  * ... without requiring cleanup of the elements of the Names array afterwards.
887  *
888  * The client is still responsible for deleting the Dependencies.Names array
889  * itself.
890  */
891 void LLVMOrcMaterializationResponsibilityAddDependencies(
892     LLVMOrcMaterializationResponsibilityRef MR,
893     LLVMOrcSymbolStringPoolEntryRef Name,
894     LLVMOrcCDependenceMapPairs Dependencies, size_t NumPairs);
895 
896 /**
897  * Adds dependencies to all symbols that the MaterializationResponsibility is
898  * responsible for. See LLVMOrcMaterializationResponsibilityAddDependencies for
899  * notes about memory responsibility.
900  */
901 void LLVMOrcMaterializationResponsibilityAddDependenciesForAll(
902     LLVMOrcMaterializationResponsibilityRef MR,
903     LLVMOrcCDependenceMapPairs Dependencies, size_t NumPairs);
904 
905 /**
906  * Create a "bare" JITDylib.
907  *
908  * The client is responsible for ensuring that the JITDylib's name is unique,
909  * e.g. by calling LLVMOrcExecutionSessionGetJTIDylibByName first.
910  *
911  * This call does not install any library code or symbols into the newly
912  * created JITDylib. The client is responsible for all configuration.
913  */
914 LLVMOrcJITDylibRef
915 LLVMOrcExecutionSessionCreateBareJITDylib(LLVMOrcExecutionSessionRef ES,
916                                           const char *Name);
917 
918 /**
919  * Create a JITDylib.
920  *
921  * The client is responsible for ensuring that the JITDylib's name is unique,
922  * e.g. by calling LLVMOrcExecutionSessionGetJTIDylibByName first.
923  *
924  * If a Platform is attached to the ExecutionSession then
925  * Platform::setupJITDylib will be called to install standard platform symbols
926  * (e.g. standard library interposes). If no Platform is installed then this
927  * call is equivalent to LLVMExecutionSessionRefCreateBareJITDylib and will
928  * always return success.
929  */
930 LLVMErrorRef
931 LLVMOrcExecutionSessionCreateJITDylib(LLVMOrcExecutionSessionRef ES,
932                                       LLVMOrcJITDylibRef *Result,
933                                       const char *Name);
934 
935 /**
936  * Returns the JITDylib with the given name, or NULL if no such JITDylib
937  * exists.
938  */
939 LLVMOrcJITDylibRef
940 LLVMOrcExecutionSessionGetJITDylibByName(LLVMOrcExecutionSessionRef ES,
941                                          const char *Name);
942 
943 /**
944  * Return a reference to a newly created resource tracker associated with JD.
945  * The tracker is returned with an initial ref-count of 1, and must be released
946  * with LLVMOrcReleaseResourceTracker when no longer needed.
947  */
948 LLVMOrcResourceTrackerRef
949 LLVMOrcJITDylibCreateResourceTracker(LLVMOrcJITDylibRef JD);
950 
951 /**
952  * Return a reference to the default resource tracker for the given JITDylib.
953  * This operation will increase the retain count of the tracker: Clients should
954  * call LLVMOrcReleaseResourceTracker when the result is no longer needed.
955  */
956 LLVMOrcResourceTrackerRef
957 LLVMOrcJITDylibGetDefaultResourceTracker(LLVMOrcJITDylibRef JD);
958 
959 /**
960  * Add the given MaterializationUnit to the given JITDylib.
961  *
962  * If this operation succeeds then JITDylib JD will take ownership of MU.
963  * If the operation fails then ownership remains with the caller who should
964  * call LLVMOrcDisposeMaterializationUnit to destroy it.
965  */
966 LLVMErrorRef LLVMOrcJITDylibDefine(LLVMOrcJITDylibRef JD,
967                                    LLVMOrcMaterializationUnitRef MU);
968 
969 /**
970  * Calls remove on all trackers associated with this JITDylib, see
971  * JITDylib::clear().
972  */
973 LLVMErrorRef LLVMOrcJITDylibClear(LLVMOrcJITDylibRef JD);
974 
975 /**
976  * Add a DefinitionGenerator to the given JITDylib.
977  *
978  * The JITDylib will take ownership of the given generator: The client is no
979  * longer responsible for managing its memory.
980  */
981 void LLVMOrcJITDylibAddGenerator(LLVMOrcJITDylibRef JD,
982                                  LLVMOrcDefinitionGeneratorRef DG);
983 
984 /**
985  * Create a custom generator.
986  *
987  * The F argument will be used to implement the DefinitionGenerator's
988  * tryToGenerate method (see
989  * LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction).
990  *
991  * Ctx is a context object that will be passed to F. This argument is
992  * permitted to be null.
993  *
994  * Dispose is the disposal function for Ctx. This argument is permitted to be
995  * null (in which case the client is responsible for the lifetime of Ctx).
996  */
997 LLVMOrcDefinitionGeneratorRef LLVMOrcCreateCustomCAPIDefinitionGenerator(
998     LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction F, void *Ctx,
999     LLVMOrcDisposeCAPIDefinitionGeneratorFunction Dispose);
1000 
1001 /**
1002  * Continue a lookup that was suspended in a generator (see
1003  * LLVMOrcCAPIDefinitionGeneratorTryToGenerateFunction).
1004  */
1005 void LLVMOrcLookupStateContinueLookup(LLVMOrcLookupStateRef S,
1006                                       LLVMErrorRef Err);
1007 
1008 /**
1009  * Get a DynamicLibrarySearchGenerator that will reflect process symbols into
1010  * the JITDylib. On success the resulting generator is owned by the client.
1011  * Ownership is typically transferred by adding the instance to a JITDylib
1012  * using LLVMOrcJITDylibAddGenerator,
1013  *
1014  * The GlobalPrefix argument specifies the character that appears on the front
1015  * of linker-mangled symbols for the target platform (e.g. '_' on MachO).
1016  * If non-null, this character will be stripped from the start of all symbol
1017  * strings before passing the remaining substring to dlsym.
1018  *
1019  * The optional Filter and Ctx arguments can be used to supply a symbol name
1020  * filter: Only symbols for which the filter returns true will be visible to
1021  * JIT'd code. If the Filter argument is null then all process symbols will
1022  * be visible to JIT'd code. Note that the symbol name passed to the Filter
1023  * function is the full mangled symbol: The client is responsible for stripping
1024  * the global prefix if present.
1025  */
1026 LLVMErrorRef LLVMOrcCreateDynamicLibrarySearchGeneratorForProcess(
1027     LLVMOrcDefinitionGeneratorRef *Result, char GlobalPrefx,
1028     LLVMOrcSymbolPredicate Filter, void *FilterCtx);
1029 
1030 /**
1031  * Get a LLVMOrcCreateDynamicLibararySearchGeneratorForPath that will reflect
1032  * library symbols into the JITDylib. On success the resulting generator is
1033  * owned by the client. Ownership is typically transferred by adding the
1034  * instance to a JITDylib using LLVMOrcJITDylibAddGenerator,
1035  *
1036  * The GlobalPrefix argument specifies the character that appears on the front
1037  * of linker-mangled symbols for the target platform (e.g. '_' on MachO).
1038  * If non-null, this character will be stripped from the start of all symbol
1039  * strings before passing the remaining substring to dlsym.
1040  *
1041  * The optional Filter and Ctx arguments can be used to supply a symbol name
1042  * filter: Only symbols for which the filter returns true will be visible to
1043  * JIT'd code. If the Filter argument is null then all library symbols will
1044  * be visible to JIT'd code. Note that the symbol name passed to the Filter
1045  * function is the full mangled symbol: The client is responsible for stripping
1046  * the global prefix if present.
1047  *
1048  * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE!
1049  *
1050  */
1051 LLVMErrorRef LLVMOrcCreateDynamicLibrarySearchGeneratorForPath(
1052     LLVMOrcDefinitionGeneratorRef *Result, const char *FileName,
1053     char GlobalPrefix, LLVMOrcSymbolPredicate Filter, void *FilterCtx);
1054 
1055 /**
1056  * Get a LLVMOrcCreateStaticLibrarySearchGeneratorForPath that will reflect
1057  * static library symbols into the JITDylib. On success the resulting
1058  * generator is owned by the client. Ownership is typically transferred by
1059  * adding the instance to a JITDylib using LLVMOrcJITDylibAddGenerator,
1060  *
1061  * Call with the optional TargetTriple argument will succeed if the file at
1062  * the given path is a static library or a MachO universal binary containing a
1063  * static library that is compatible with the given triple. Otherwise it will
1064  * return an error.
1065  *
1066  * THIS API IS EXPERIMENTAL AND LIKELY TO CHANGE IN THE NEAR FUTURE!
1067  *
1068  */
1069 LLVMErrorRef LLVMOrcCreateStaticLibrarySearchGeneratorForPath(
1070     LLVMOrcDefinitionGeneratorRef *Result, LLVMOrcObjectLayerRef ObjLayer,
1071     const char *FileName, const char *TargetTriple);
1072 
1073 /**
1074  * Create a ThreadSafeContext containing a new LLVMContext.
1075  *
1076  * Ownership of the underlying ThreadSafeContext data is shared: Clients
1077  * can and should dispose of their ThreadSafeContext as soon as they no longer
1078  * need to refer to it directly. Other references (e.g. from ThreadSafeModules)
1079  * will keep the data alive as long as it is needed.
1080  */
1081 LLVMOrcThreadSafeContextRef LLVMOrcCreateNewThreadSafeContext(void);
1082 
1083 /**
1084  * Get a reference to the wrapped LLVMContext.
1085  */
1086 LLVMContextRef
1087 LLVMOrcThreadSafeContextGetContext(LLVMOrcThreadSafeContextRef TSCtx);
1088 
1089 /**
1090  * Dispose of a ThreadSafeContext.
1091  */
1092 void LLVMOrcDisposeThreadSafeContext(LLVMOrcThreadSafeContextRef TSCtx);
1093 
1094 /**
1095  * Create a ThreadSafeModule wrapper around the given LLVM module. This takes
1096  * ownership of the M argument which should not be disposed of or referenced
1097  * after this function returns.
1098  *
1099  * Ownership of the ThreadSafeModule is unique: If it is transferred to the JIT
1100  * (e.g. by LLVMOrcLLJITAddLLVMIRModule) then the client is no longer
1101  * responsible for it. If it is not transferred to the JIT then the client
1102  * should call LLVMOrcDisposeThreadSafeModule to dispose of it.
1103  */
1104 LLVMOrcThreadSafeModuleRef
1105 LLVMOrcCreateNewThreadSafeModule(LLVMModuleRef M,
1106                                  LLVMOrcThreadSafeContextRef TSCtx);
1107 
1108 /**
1109  * Dispose of a ThreadSafeModule. This should only be called if ownership has
1110  * not been passed to LLJIT (e.g. because some error prevented the client from
1111  * adding this to the JIT).
1112  */
1113 void LLVMOrcDisposeThreadSafeModule(LLVMOrcThreadSafeModuleRef TSM);
1114 
1115 /**
1116  * Apply the given function to the module contained in this ThreadSafeModule.
1117  */
1118 LLVMErrorRef
1119 LLVMOrcThreadSafeModuleWithModuleDo(LLVMOrcThreadSafeModuleRef TSM,
1120                                     LLVMOrcGenericIRModuleOperationFunction F,
1121                                     void *Ctx);
1122 
1123 /**
1124  * Create a JITTargetMachineBuilder by detecting the host.
1125  *
1126  * On success the client owns the resulting JITTargetMachineBuilder. It must be
1127  * passed to a consuming operation (e.g.
1128  * LLVMOrcLLJITBuilderSetJITTargetMachineBuilder) or disposed of by calling
1129  * LLVMOrcDisposeJITTargetMachineBuilder.
1130  */
1131 LLVMErrorRef LLVMOrcJITTargetMachineBuilderDetectHost(
1132     LLVMOrcJITTargetMachineBuilderRef *Result);
1133 
1134 /**
1135  * Create a JITTargetMachineBuilder from the given TargetMachine template.
1136  *
1137  * This operation takes ownership of the given TargetMachine and destroys it
1138  * before returing. The resulting JITTargetMachineBuilder is owned by the client
1139  * and must be passed to a consuming operation (e.g.
1140  * LLVMOrcLLJITBuilderSetJITTargetMachineBuilder) or disposed of by calling
1141  * LLVMOrcDisposeJITTargetMachineBuilder.
1142  */
1143 LLVMOrcJITTargetMachineBuilderRef
1144 LLVMOrcJITTargetMachineBuilderCreateFromTargetMachine(LLVMTargetMachineRef TM);
1145 
1146 /**
1147  * Dispose of a JITTargetMachineBuilder.
1148  */
1149 void LLVMOrcDisposeJITTargetMachineBuilder(
1150     LLVMOrcJITTargetMachineBuilderRef JTMB);
1151 
1152 /**
1153  * Returns the target triple for the given JITTargetMachineBuilder as a string.
1154  *
1155  * The caller owns the resulting string as must dispose of it by calling
1156  * LLVMDisposeMessage
1157  */
1158 char *LLVMOrcJITTargetMachineBuilderGetTargetTriple(
1159     LLVMOrcJITTargetMachineBuilderRef JTMB);
1160 
1161 /**
1162  * Sets the target triple for the given JITTargetMachineBuilder to the given
1163  * string.
1164  */
1165 void LLVMOrcJITTargetMachineBuilderSetTargetTriple(
1166     LLVMOrcJITTargetMachineBuilderRef JTMB, const char *TargetTriple);
1167 
1168 /**
1169  * Add an object to an ObjectLayer to the given JITDylib.
1170  *
1171  * Adds a buffer representing an object file to the given JITDylib using the
1172  * given ObjectLayer instance. This operation transfers ownership of the buffer
1173  * to the ObjectLayer instance. The buffer should not be disposed of or
1174  * referenced once this function returns.
1175  *
1176  * Resources associated with the given object will be tracked by the given
1177  * JITDylib's default ResourceTracker.
1178  */
1179 LLVMErrorRef LLVMOrcObjectLayerAddObjectFile(LLVMOrcObjectLayerRef ObjLayer,
1180                                              LLVMOrcJITDylibRef JD,
1181                                              LLVMMemoryBufferRef ObjBuffer);
1182 
1183 /**
1184  * Add an object to an ObjectLayer using the given ResourceTracker.
1185  *
1186  * Adds a buffer representing an object file to the given ResourceTracker's
1187  * JITDylib using the given ObjectLayer instance. This operation transfers
1188  * ownership of the buffer to the ObjectLayer instance. The buffer should not
1189  * be disposed of or referenced once this function returns.
1190  *
1191  * Resources associated with the given object will be tracked by
1192  * ResourceTracker RT.
1193  */
1194 LLVMErrorRef
1195 LLVMOrcObjectLayerAddObjectFileWithRT(LLVMOrcObjectLayerRef ObjLayer,
1196                                       LLVMOrcResourceTrackerRef RT,
1197                                       LLVMMemoryBufferRef ObjBuffer);
1198 
1199 /**
1200  * Emit an object buffer to an ObjectLayer.
1201  *
1202  * Ownership of the responsibility object and object buffer pass to this
1203  * function. The client is not responsible for cleanup.
1204  */
1205 void LLVMOrcObjectLayerEmit(LLVMOrcObjectLayerRef ObjLayer,
1206                             LLVMOrcMaterializationResponsibilityRef R,
1207                             LLVMMemoryBufferRef ObjBuffer);
1208 
1209 /**
1210  * Dispose of an ObjectLayer.
1211  */
1212 void LLVMOrcDisposeObjectLayer(LLVMOrcObjectLayerRef ObjLayer);
1213 
1214 void LLVMOrcIRTransformLayerEmit(LLVMOrcIRTransformLayerRef IRTransformLayer,
1215                                  LLVMOrcMaterializationResponsibilityRef MR,
1216                                  LLVMOrcThreadSafeModuleRef TSM);
1217 
1218 /**
1219  * Set the transform function of the provided transform layer, passing through a
1220  * pointer to user provided context.
1221  */
1222 void LLVMOrcIRTransformLayerSetTransform(
1223     LLVMOrcIRTransformLayerRef IRTransformLayer,
1224     LLVMOrcIRTransformLayerTransformFunction TransformFunction, void *Ctx);
1225 
1226 /**
1227  * Set the transform function on an LLVMOrcObjectTransformLayer.
1228  */
1229 void LLVMOrcObjectTransformLayerSetTransform(
1230     LLVMOrcObjectTransformLayerRef ObjTransformLayer,
1231     LLVMOrcObjectTransformLayerTransformFunction TransformFunction, void *Ctx);
1232 
1233 /**
1234  * Create a LocalIndirectStubsManager from the given target triple.
1235  *
1236  * The resulting IndirectStubsManager is owned by the client
1237  * and must be disposed of by calling LLVMOrcDisposeDisposeIndirectStubsManager.
1238  */
1239 LLVMOrcIndirectStubsManagerRef
1240 LLVMOrcCreateLocalIndirectStubsManager(const char *TargetTriple);
1241 
1242 /**
1243  * Dispose of an IndirectStubsManager.
1244  */
1245 void LLVMOrcDisposeIndirectStubsManager(LLVMOrcIndirectStubsManagerRef ISM);
1246 
1247 LLVMErrorRef LLVMOrcCreateLocalLazyCallThroughManager(
1248     const char *TargetTriple, LLVMOrcExecutionSessionRef ES,
1249     LLVMOrcJITTargetAddress ErrorHandlerAddr,
1250     LLVMOrcLazyCallThroughManagerRef *LCTM);
1251 
1252 /**
1253  * Dispose of an LazyCallThroughManager.
1254  */
1255 void LLVMOrcDisposeLazyCallThroughManager(
1256     LLVMOrcLazyCallThroughManagerRef LCTM);
1257 
1258 /**
1259  * Create a DumpObjects instance.
1260  *
1261  * DumpDir specifies the path to write dumped objects to. DumpDir may be empty
1262  * in which case files will be dumped to the working directory.
1263  *
1264  * IdentifierOverride specifies a file name stem to use when dumping objects.
1265  * If empty then each MemoryBuffer's identifier will be used (with a .o suffix
1266  * added if not already present). If an identifier override is supplied it will
1267  * be used instead, along with an incrementing counter (since all buffers will
1268  * use the same identifier, the resulting files will be named <ident>.o,
1269  * <ident>.2.o, <ident>.3.o, and so on). IdentifierOverride should not contain
1270  * an extension, as a .o suffix will be added by DumpObjects.
1271  */
1272 LLVMOrcDumpObjectsRef LLVMOrcCreateDumpObjects(const char *DumpDir,
1273                                                const char *IdentifierOverride);
1274 
1275 /**
1276  * Dispose of a DumpObjects instance.
1277  */
1278 void LLVMOrcDisposeDumpObjects(LLVMOrcDumpObjectsRef DumpObjects);
1279 
1280 /**
1281  * Dump the contents of the given MemoryBuffer.
1282  */
1283 LLVMErrorRef LLVMOrcDumpObjects_CallOperator(LLVMOrcDumpObjectsRef DumpObjects,
1284                                              LLVMMemoryBufferRef *ObjBuffer);
1285 
1286 /**
1287  * @}
1288  */
1289 
1290 LLVM_C_EXTERN_C_END
1291 
1292 #endif /* LLVM_C_ORC_H */
1293