//===--- SILGenAvailability.cpp - SILGen for availability queries ---------===// // // This source file is part of the Swift.org open source project // // Copyright (c) 2022 - 2025 Apple Inc. and the Swift project authors // Licensed under Apache License v2.0 with Runtime Library Exception // // See https://swift.org/LICENSE.txt for license information // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors // //===----------------------------------------------------------------------===// #include "SILGenFunction.h" #include "SILGenFunctionBuilder.h" #include "Scope.h" #include "swift/Basic/Assertions.h" #include "swift/Basic/Platform.h" #include "swift/SIL/SILDeclRef.h" using namespace swift; using namespace Lowering; /// Emit literals for each of element in `values`, populating `results` with the /// corresponding `SILValue`. static void emitIntegerLiterals(SILLocation loc, SILGenBuilder &B, ASTContext &ctx, ArrayRef values, llvm::SmallVectorImpl &results) { SILType wordType = SILType::getBuiltinWordType(ctx); for (auto value : values) { results.emplace_back(B.createIntegerLiteral(loc, wordType, value)); } } static SILValue emitAvailabilityCheck(SILGenFunction &SGF, SILLocation loc, const AvailabilityQuery &query) { auto &ctx = SGF.getASTContext(); SILType i1 = SILType::getBuiltinIntegerType(1, SGF.getASTContext()); auto &B = SGF.B; // If the query's result is known at compile time, emit a constant. if (auto constantResult = query.getConstantResult()) return B.createIntegerLiteral(loc, i1, *constantResult); llvm::SmallVector rawArgs; auto queryDecl = query.getDynamicQueryDeclAndArguments(rawArgs, ctx); // FIXME: [availability] Once dynamic custom domains have decls, DEBUG_ASSERT. if (!queryDecl) return B.createIntegerLiteral(loc, i1, !query.isUnavailability()); auto queryType = queryDecl->getInterfaceType()->getAs(); ASSERT(queryType); ASSERT(queryType->getResult()->getAs()); auto queryParams = queryType->getParams(); ASSERT(rawArgs.size() == queryParams.size()); llvm::SmallVector silArgs; emitIntegerLiterals(loc, B, ctx, rawArgs, silArgs); auto declRef = SILDeclRef(queryDecl); SILValue availabilityGTEFn = SGF.emitGlobalFunctionRef( loc, declRef, SGF.getConstantInfo(SGF.getTypeExpansionContext(), declRef)); SILValue result = B.createApply(loc, availabilityGTEFn, SubstitutionMap(), silArgs); // If this is an unavailability check, invert the result using 1-bit xor // with 1. if (query.isUnavailability()) { SILType i1 = SILType::getBuiltinIntegerType(1, ctx); SILValue one = B.createIntegerLiteral(loc, i1, 1); result = B.createBuiltinBinaryFunction(loc, "xor", i1, i1, {result, one}); } return result; } /// Given a value, extracts all elements to `result` from this value if it's a /// tuple. Otherwise, add this value directly to `result`. static void extractAllElements(SILValue val, SILLocation loc, SILBuilder &builder, SmallVectorImpl &result) { auto &fn = builder.getFunction(); auto tupleType = val->getType().getAs(); if (!tupleType) { result.push_back(val); return; } if (!fn.hasOwnership()) { for (auto i : range(tupleType->getNumElements())) result.push_back(builder.createTupleExtract(loc, val, i)); return; } if (tupleType->getNumElements() == 0) return; builder.emitDestructureValueOperation(loc, val, result); } static Type getResultInterfaceType(AbstractFunctionDecl *AFD) { if (auto *FD = dyn_cast(AFD)) return FD->getResultInterfaceType(); if (auto *CD = dyn_cast(AFD)) return CD->getResultInterfaceType(); llvm_unreachable("Unhandled AbstractFunctionDecl type"); } static std::optional getAvailabilityQueryForBackDeployment(AbstractFunctionDecl *AFD) { auto &ctx = AFD->getASTContext(); if (ctx.LangOpts.TargetVariant) { auto primaryAttrAndRange = AFD->getBackDeployedAttrAndRange(ctx); auto variantAttrAndRange = AFD->getBackDeployedAttrAndRange(ctx, /*forTargetVariant=*/true); if (!primaryAttrAndRange && !variantAttrAndRange) return std::nullopt; auto attr = primaryAttrAndRange ? primaryAttrAndRange->first : variantAttrAndRange->first; std::optional primaryRange; if (primaryAttrAndRange) primaryRange = primaryAttrAndRange->second; std::optional variantRange; if (variantAttrAndRange) variantRange = variantAttrAndRange->second; return AvailabilityQuery::dynamic(attr->getAvailabilityDomain(), primaryRange, variantRange); } if (auto primaryAttrAndRange = AFD->getBackDeployedAttrAndRange(ctx)) return AvailabilityQuery::dynamic( primaryAttrAndRange->first->getAvailabilityDomain(), primaryAttrAndRange->second, std::nullopt); return std::nullopt; } /// Emit the following branch SIL instruction: /// \verbatim /// if #available(OSVersion) { /// /// } else { /// /// } /// \endverbatim static void emitBackDeployIfAvailableCondition(SILGenFunction &SGF, AbstractFunctionDecl *AFD, SILLocation loc, SILBasicBlock *availableBB, SILBasicBlock *unavailableBB) { auto &B = SGF.B; SILValue booleanTestValue; if (auto query = getAvailabilityQueryForBackDeployment(AFD)) { booleanTestValue = emitAvailabilityCheck(SGF, loc, *query); } else { // Some logic has gone wrong if we've gotten here but lets fail gracefully // and emit a branch that always succeeds. SILType i1 = SILType::getBuiltinIntegerType(1, SGF.getASTContext()); booleanTestValue = B.createIntegerLiteral(loc, i1, true); } B.createCondBranch(loc, booleanTestValue, availableBB, unavailableBB); } /// Emits a function or method application, forwarding parameters. static void emitBackDeployForwardApplyAndReturnOrThrow( SILGenFunction &SGF, AbstractFunctionDecl *AFD, SILLocation loc, SILDeclRef function, SmallVector ¶ms) { // Only statically dispatched class methods are supported. if (auto classDecl = dyn_cast(AFD->getDeclContext())) { assert(classDecl->isFinal() || AFD->isFinal() || AFD->hasForcedStaticDispatch()); } TypeExpansionContext TEC = SGF.getTypeExpansionContext(); auto fnType = SGF.SGM.Types.getConstantOverrideType(TEC, function); auto silFnType = SILType::getPrimitiveObjectType(fnType).castTo(); SILFunctionConventions fnConv(silFnType, SGF.SGM.M); SILValue functionRef = SGF.emitGlobalFunctionRef(loc, function); auto subs = SGF.F.getForwardingSubstitutionMap(); SmallVector directResults; // If the function is a coroutine, we need to use 'begin_apply'. if (silFnType->isCoroutine()) { assert(!silFnType->hasErrorResult() && "throwing coroutine?"); // Apply the coroutine, yield the result, and finally branch to either the // terminal return or unwind basic block via intermediate basic blocks. The // intermediates are needed to avoid forming critical edges. SILBasicBlock *resumeBB = SGF.createBasicBlock(); SILBasicBlock *unwindBB = SGF.createBasicBlock(); auto *apply = SGF.B.createBeginApply(loc, functionRef, subs, params); SmallVector rawResults; for (auto result : apply->getAllResults()) rawResults.push_back(result); auto token = rawResults.pop_back_val(); SGF.B.createYield(loc, rawResults, resumeBB, unwindBB); // Emit resume block. SGF.B.emitBlock(resumeBB); SGF.B.createEndApply(loc, token, SILType::getEmptyTupleType(SGF.getASTContext())); SGF.B.createBranch(loc, SGF.ReturnDest.getBlock()); // Emit unwind block. SGF.B.emitBlock(unwindBB); SGF.B.createEndApply(loc, token, SILType::getEmptyTupleType(SGF.getASTContext())); SGF.B.createBranch(loc, SGF.CoroutineUnwindDest.getBlock()); return; } // Use try_apply for functions that throw. if (silFnType->hasErrorResult()) { // Apply the throwing function and forward the results and the error to the // return/throw blocks via intermediate basic blocks. The intermediates // are needed to avoid forming critical edges. SILBasicBlock *normalBB = SGF.createBasicBlock(); SILBasicBlock *errorBB = SGF.createBasicBlock(); SGF.B.createTryApply(loc, functionRef, subs, params, normalBB, errorBB); // Emit error block. SGF.B.emitBlock(errorBB); ManagedValue error = SGF.B.createPhi(SGF.F.mapTypeIntoContext(fnConv.getSILErrorType(TEC)), OwnershipKind::Owned); SGF.B.createBranch(loc, SGF.ThrowDest.getBlock(), {error}); // Emit normal block. SGF.B.emitBlock(normalBB); SILValue result = normalBB->createPhiArgument( SGF.F.mapTypeIntoContext(fnConv.getSILResultType(TEC)), OwnershipKind::Owned); SmallVector directResults; extractAllElements(result, loc, SGF.B, directResults); SGF.B.createBranch(loc, SGF.ReturnDest.getBlock(), directResults); return; } // The original function is neither throwing nor a coroutine. Apply it and // forward its results straight to the return block. auto *apply = SGF.B.createApply(loc, functionRef, subs, params); extractAllElements(apply, loc, SGF.B, directResults); SGF.B.createBranch(loc, SGF.ReturnDest.getBlock(), directResults); } SILValue SILGenFunction::emitIfAvailableQuery(SILLocation loc, PoundAvailableInfo *availability) { auto &ctx = getASTContext(); SILType i1 = SILType::getBuiltinIntegerType(1, ctx); auto query = availability->getAvailabilityQuery(); // The query may not have been computed by Sema under the following // conditions: // - Availability checking was disabled (-disable-availability-checking). // - The query was marked invalid in the AST for a non-fatal reason. // // Otherwise, there's a bug in Sema. DEBUG_ASSERT(query || availability->isInvalid() || ctx.LangOpts.DisableAvailabilityChecking); // If Sema skipped the query then treat the condition as if it always // evaluates true. if (!query) return B.createIntegerLiteral(loc, i1, !availability->isUnavailability()); return emitAvailabilityCheck(*this, loc, *query); } bool SILGenModule::requiresBackDeploymentThunk(ValueDecl *decl, ResilienceExpansion expansion) { auto &ctx = getASTContext(); auto attrAndRange = decl->getBackDeployedAttrAndRange(ctx); if (!attrAndRange) return false; switch (expansion) { case ResilienceExpansion::Minimal: // In a minimal resilience expansion we must always call the back deployment // thunk since we can't predict the deployment targets of the modules that // might inline the call. return true; case ResilienceExpansion::Maximal: // FIXME: We can skip thunking if we're in the same module. break; } // Use of a back deployment thunk is unnecessary if the deployment target is // high enough that the ABI implementation of the back deployed declaration is // guaranteed to be available. auto deploymentAvailability = AvailabilityRange::forDeploymentTarget(ctx); if (deploymentAvailability.isContainedIn(attrAndRange->second)) return false; return true; } void SILGenFunction::emitBackDeploymentThunk(SILDeclRef thunk) { // Generate code equivalent to: // // func X_thunk(...) async throws -> ... { // if #available(...) { // return try await X(...) // } else { // return try await X_fallback(...) // } // } assert(thunk.isBackDeploymentThunk()); auto loc = thunk.getAsRegularLocation(); loc.markAutoGenerated(); Scope scope(Cleanups, CleanupLocation(loc)); auto AFD = cast(thunk.getDecl()); F.setGenericEnvironment(SGM.Types.getConstantGenericEnvironment(thunk)); // Generate the thunk prolog by collecting parameters. SmallVector params; SmallVector indirectParams; SmallVector indirectErrorResults; ManagedValue implicitIsolationParam; collectThunkParams(loc, params, &indirectParams, &indirectErrorResults, &implicitIsolationParam); // Build up the list of arguments that we're going to invoke the real // function with. SmallVector paramsForForwarding; for (auto indirectParam : indirectParams) { paramsForForwarding.emplace_back(indirectParam.getLValueAddress()); } for (auto indirectErrorResult : indirectErrorResults) { paramsForForwarding.emplace_back(indirectErrorResult.getLValueAddress()); } if (implicitIsolationParam) { paramsForForwarding.emplace_back(implicitIsolationParam.forward(*this)); } for (auto param : params) { // We're going to directly call either the original function or the fallback // function with these arguments and then return. Therefore we just forward // the arguments instead of handling their ownership conventions. paramsForForwarding.emplace_back(param.forward(*this)); } prepareEpilog(AFD, getResultInterfaceType(AFD), AFD->getEffectiveThrownErrorType(), CleanupLocation(AFD)); SILBasicBlock *availableBB = createBasicBlock("availableBB"); SILBasicBlock *unavailableBB = createBasicBlock("unavailableBB"); // if #available(...) { // // } else { // // } emitBackDeployIfAvailableCondition(*this, AFD, loc, availableBB, unavailableBB); // : // return (try)? (await)? (self.)?X(...) { B.emitBlock(availableBB); SILDeclRef original = thunk.asBackDeploymentKind(SILDeclRef::BackDeploymentKind::None); emitBackDeployForwardApplyAndReturnOrThrow(*this, AFD, loc, original, paramsForForwarding); } // : // return (try)? (await)? (self.)?X_fallback(...) { B.emitBlock(unavailableBB); SILDeclRef fallback = thunk.asBackDeploymentKind(SILDeclRef::BackDeploymentKind::Fallback); emitBackDeployForwardApplyAndReturnOrThrow(*this, AFD, loc, fallback, paramsForForwarding); } emitEpilog(AFD); }