[InstCombine] Signed saturation patterns
[llvm-complete.git] / lib / ExecutionEngine / Orc / CompileOnDemandLayer.cpp
blob75ddbc30445d29c350484fbca506b88a51ddae1b
1 //===----- CompileOnDemandLayer.cpp - Lazily emit IR on first call --------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
9 #include "llvm/ExecutionEngine/Orc/CompileOnDemandLayer.h"
10 #include "llvm/IR/Mangler.h"
11 #include "llvm/IR/Module.h"
13 using namespace llvm;
14 using namespace llvm::orc;
16 static ThreadSafeModule extractSubModule(ThreadSafeModule &TSM,
17 StringRef Suffix,
18 GVPredicate ShouldExtract) {
20 auto DeleteExtractedDefs = [](GlobalValue &GV) {
21 // Bump the linkage: this global will be provided by the external module.
22 GV.setLinkage(GlobalValue::ExternalLinkage);
24 // Delete the definition in the source module.
25 if (isa<Function>(GV)) {
26 auto &F = cast<Function>(GV);
27 F.deleteBody();
28 F.setPersonalityFn(nullptr);
29 } else if (isa<GlobalVariable>(GV)) {
30 cast<GlobalVariable>(GV).setInitializer(nullptr);
31 } else if (isa<GlobalAlias>(GV)) {
32 // We need to turn deleted aliases into function or variable decls based
33 // on the type of their aliasee.
34 auto &A = cast<GlobalAlias>(GV);
35 Constant *Aliasee = A.getAliasee();
36 assert(A.hasName() && "Anonymous alias?");
37 assert(Aliasee->hasName() && "Anonymous aliasee");
38 std::string AliasName = A.getName();
40 if (isa<Function>(Aliasee)) {
41 auto *F = cloneFunctionDecl(*A.getParent(), *cast<Function>(Aliasee));
42 A.replaceAllUsesWith(F);
43 A.eraseFromParent();
44 F->setName(AliasName);
45 } else if (isa<GlobalVariable>(Aliasee)) {
46 auto *G = cloneGlobalVariableDecl(*A.getParent(),
47 *cast<GlobalVariable>(Aliasee));
48 A.replaceAllUsesWith(G);
49 A.eraseFromParent();
50 G->setName(AliasName);
51 } else
52 llvm_unreachable("Alias to unsupported type");
53 } else
54 llvm_unreachable("Unsupported global type");
57 auto NewTSM = cloneToNewContext(TSM, ShouldExtract, DeleteExtractedDefs);
58 NewTSM.withModuleDo([&](Module &M) {
59 M.setModuleIdentifier((M.getModuleIdentifier() + Suffix).str());
60 });
62 return NewTSM;
65 namespace llvm {
66 namespace orc {
68 class PartitioningIRMaterializationUnit : public IRMaterializationUnit {
69 public:
70 PartitioningIRMaterializationUnit(ExecutionSession &ES, ThreadSafeModule TSM,
71 VModuleKey K, CompileOnDemandLayer &Parent)
72 : IRMaterializationUnit(ES, std::move(TSM), std::move(K)),
73 Parent(Parent) {}
75 PartitioningIRMaterializationUnit(
76 ThreadSafeModule TSM, SymbolFlagsMap SymbolFlags,
77 SymbolNameToDefinitionMap SymbolToDefinition,
78 CompileOnDemandLayer &Parent)
79 : IRMaterializationUnit(std::move(TSM), std::move(K),
80 std::move(SymbolFlags),
81 std::move(SymbolToDefinition)),
82 Parent(Parent) {}
84 private:
85 void materialize(MaterializationResponsibility R) override {
86 Parent.emitPartition(std::move(R), std::move(TSM),
87 std::move(SymbolToDefinition));
90 void discard(const JITDylib &V, const SymbolStringPtr &Name) override {
91 // All original symbols were materialized by the CODLayer and should be
92 // final. The function bodies provided by M should never be overridden.
93 llvm_unreachable("Discard should never be called on an "
94 "ExtractingIRMaterializationUnit");
97 mutable std::mutex SourceModuleMutex;
98 CompileOnDemandLayer &Parent;
101 Optional<CompileOnDemandLayer::GlobalValueSet>
102 CompileOnDemandLayer::compileRequested(GlobalValueSet Requested) {
103 return std::move(Requested);
106 Optional<CompileOnDemandLayer::GlobalValueSet>
107 CompileOnDemandLayer::compileWholeModule(GlobalValueSet Requested) {
108 return None;
111 CompileOnDemandLayer::CompileOnDemandLayer(
112 ExecutionSession &ES, IRLayer &BaseLayer, LazyCallThroughManager &LCTMgr,
113 IndirectStubsManagerBuilder BuildIndirectStubsManager)
114 : IRLayer(ES), BaseLayer(BaseLayer), LCTMgr(LCTMgr),
115 BuildIndirectStubsManager(std::move(BuildIndirectStubsManager)) {}
117 void CompileOnDemandLayer::setPartitionFunction(PartitionFunction Partition) {
118 this->Partition = std::move(Partition);
121 void CompileOnDemandLayer::setImplMap(ImplSymbolMap *Imp) {
122 this->AliaseeImpls = Imp;
124 void CompileOnDemandLayer::emit(MaterializationResponsibility R,
125 ThreadSafeModule TSM) {
126 assert(TSM && "Null module");
128 auto &ES = getExecutionSession();
130 // Sort the callables and non-callables, build re-exports and lodge the
131 // actual module with the implementation dylib.
132 auto &PDR = getPerDylibResources(R.getTargetJITDylib());
134 SymbolAliasMap NonCallables;
135 SymbolAliasMap Callables;
136 TSM.withModuleDo([&](Module &M) {
137 // First, do some cleanup on the module:
138 cleanUpModule(M);
140 MangleAndInterner Mangle(ES, M.getDataLayout());
141 for (auto &GV : M.global_values()) {
142 if (GV.isDeclaration() || GV.hasLocalLinkage() ||
143 GV.hasAppendingLinkage())
144 continue;
146 auto Name = Mangle(GV.getName());
147 auto Flags = JITSymbolFlags::fromGlobalValue(GV);
148 if (Flags.isCallable())
149 Callables[Name] = SymbolAliasMapEntry(Name, Flags);
150 else
151 NonCallables[Name] = SymbolAliasMapEntry(Name, Flags);
155 // Create a partitioning materialization unit and lodge it with the
156 // implementation dylib.
157 if (auto Err = PDR.getImplDylib().define(
158 std::make_unique<PartitioningIRMaterializationUnit>(
159 ES, std::move(TSM), R.getVModuleKey(), *this))) {
160 ES.reportError(std::move(Err));
161 R.failMaterialization();
162 return;
165 R.replace(reexports(PDR.getImplDylib(), std::move(NonCallables), true));
166 R.replace(lazyReexports(LCTMgr, PDR.getISManager(), PDR.getImplDylib(),
167 std::move(Callables), AliaseeImpls));
170 CompileOnDemandLayer::PerDylibResources &
171 CompileOnDemandLayer::getPerDylibResources(JITDylib &TargetD) {
172 auto I = DylibResources.find(&TargetD);
173 if (I == DylibResources.end()) {
174 auto &ImplD = getExecutionSession().createJITDylib(
175 TargetD.getName() + ".impl", false);
176 TargetD.withSearchOrderDo([&](const JITDylibSearchList &TargetSearchOrder) {
177 auto NewSearchOrder = TargetSearchOrder;
178 assert(!NewSearchOrder.empty() &&
179 NewSearchOrder.front().first == &TargetD &&
180 NewSearchOrder.front().second == true &&
181 "TargetD must be at the front of its own search order and match "
182 "non-exported symbol");
183 NewSearchOrder.insert(std::next(NewSearchOrder.begin()), {&ImplD, true});
184 ImplD.setSearchOrder(std::move(NewSearchOrder), false);
186 PerDylibResources PDR(ImplD, BuildIndirectStubsManager());
187 I = DylibResources.insert(std::make_pair(&TargetD, std::move(PDR))).first;
190 return I->second;
193 void CompileOnDemandLayer::cleanUpModule(Module &M) {
194 for (auto &F : M.functions()) {
195 if (F.isDeclaration())
196 continue;
198 if (F.hasAvailableExternallyLinkage()) {
199 F.deleteBody();
200 F.setPersonalityFn(nullptr);
201 continue;
206 void CompileOnDemandLayer::expandPartition(GlobalValueSet &Partition) {
207 // Expands the partition to ensure the following rules hold:
208 // (1) If any alias is in the partition, its aliasee is also in the partition.
209 // (2) If any aliasee is in the partition, its aliases are also in the
210 // partiton.
211 // (3) If any global variable is in the partition then all global variables
212 // are in the partition.
213 assert(!Partition.empty() && "Unexpected empty partition");
215 const Module &M = *(*Partition.begin())->getParent();
216 bool ContainsGlobalVariables = false;
217 std::vector<const GlobalValue *> GVsToAdd;
219 for (auto *GV : Partition)
220 if (isa<GlobalAlias>(GV))
221 GVsToAdd.push_back(
222 cast<GlobalValue>(cast<GlobalAlias>(GV)->getAliasee()));
223 else if (isa<GlobalVariable>(GV))
224 ContainsGlobalVariables = true;
226 for (auto &A : M.aliases())
227 if (Partition.count(cast<GlobalValue>(A.getAliasee())))
228 GVsToAdd.push_back(&A);
230 if (ContainsGlobalVariables)
231 for (auto &G : M.globals())
232 GVsToAdd.push_back(&G);
234 for (auto *GV : GVsToAdd)
235 Partition.insert(GV);
238 void CompileOnDemandLayer::emitPartition(
239 MaterializationResponsibility R, ThreadSafeModule TSM,
240 IRMaterializationUnit::SymbolNameToDefinitionMap Defs) {
242 // FIXME: Need a 'notify lazy-extracting/emitting' callback to tie the
243 // extracted module key, extracted module, and source module key
244 // together. This could be used, for example, to provide a specific
245 // memory manager instance to the linking layer.
247 auto &ES = getExecutionSession();
248 GlobalValueSet RequestedGVs;
249 for (auto &Name : R.getRequestedSymbols()) {
250 assert(Defs.count(Name) && "No definition for symbol");
251 RequestedGVs.insert(Defs[Name]);
254 /// Perform partitioning with the context lock held, since the partition
255 /// function is allowed to access the globals to compute the partition.
256 auto GVsToExtract =
257 TSM.withModuleDo([&](Module &M) { return Partition(RequestedGVs); });
259 // Take a 'None' partition to mean the whole module (as opposed to an empty
260 // partition, which means "materialize nothing"). Emit the whole module
261 // unmodified to the base layer.
262 if (GVsToExtract == None) {
263 Defs.clear();
264 BaseLayer.emit(std::move(R), std::move(TSM));
265 return;
268 // If the partition is empty, return the whole module to the symbol table.
269 if (GVsToExtract->empty()) {
270 R.replace(std::make_unique<PartitioningIRMaterializationUnit>(
271 std::move(TSM), R.getSymbols(), std::move(Defs), *this));
272 return;
275 // Ok -- we actually need to partition the symbols. Promote the symbol
276 // linkages/names, expand the partition to include any required symbols
277 // (i.e. symbols that can't be separated from our partition), and
278 // then extract the partition.
280 // FIXME: We apply this promotion once per partitioning. It's safe, but
281 // overkill.
283 auto ExtractedTSM =
284 TSM.withModuleDo([&](Module &M) -> Expected<ThreadSafeModule> {
285 auto PromotedGlobals = PromoteSymbols(M);
286 if (!PromotedGlobals.empty()) {
287 MangleAndInterner Mangle(ES, M.getDataLayout());
288 SymbolFlagsMap SymbolFlags;
289 for (auto &GV : PromotedGlobals)
290 SymbolFlags[Mangle(GV->getName())] =
291 JITSymbolFlags::fromGlobalValue(*GV);
292 if (auto Err = R.defineMaterializing(SymbolFlags))
293 return std::move(Err);
296 expandPartition(*GVsToExtract);
298 // Extract the requested partiton (plus any necessary aliases) and
299 // put the rest back into the impl dylib.
300 auto ShouldExtract = [&](const GlobalValue &GV) -> bool {
301 return GVsToExtract->count(&GV);
304 return extractSubModule(TSM, ".submodule", ShouldExtract);
307 if (!ExtractedTSM) {
308 ES.reportError(ExtractedTSM.takeError());
309 R.failMaterialization();
310 return;
313 R.replace(std::make_unique<PartitioningIRMaterializationUnit>(
314 ES, std::move(TSM), R.getVModuleKey(), *this));
315 BaseLayer.emit(std::move(R), std::move(*ExtractedTSM));
318 } // end namespace orc
319 } // end namespace llvm