/* * Copyright 2011-2012, The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "slang_rs_export_foreach.h" #include #include "clang/AST/ASTContext.h" #include "clang/AST/Attr.h" #include "clang/AST/Decl.h" #include "clang/AST/TypeLoc.h" #include "llvm/IR/DerivedTypes.h" #include "bcinfo/MetadataExtractor.h" #include "slang_assert.h" #include "slang_rs_context.h" #include "slang_rs_export_type.h" #include "slang_rs_special_func.h" #include "slang_rs_special_kernel_param.h" #include "slang_version.h" namespace { const size_t RS_KERNEL_INPUT_LIMIT = 8; // see frameworks/base/libs/rs/cpu_ref/rsCpuCoreRuntime.h bool isRootRSFunc(const clang::FunctionDecl *FD) { if (!FD) { return false; } return FD->getName().equals("root"); } } // end anonymous namespace namespace slang { // This function takes care of additional validation and construction of // parameters related to forEach_* reflection. bool RSExportForEach::validateAndConstructParams( RSContext *Context, const clang::FunctionDecl *FD) { slangAssert(Context && FD); bool valid = true; numParams = FD->getNumParams(); if (Context->getTargetAPI() < SLANG_JB_TARGET_API) { // Before JellyBean, we allowed only one kernel per file. It must be called "root". if (!isRootRSFunc(FD)) { Context->ReportError(FD->getLocation(), "Non-root compute kernel %0() is " "not supported in SDK levels %1-%2") << FD->getName() << SLANG_MINIMUM_TARGET_API << (SLANG_JB_TARGET_API - 1); return false; } } mResultType = FD->getReturnType().getCanonicalType(); // Compute kernel functions are defined differently when the // "__attribute__((kernel))" is set. if (FD->hasAttr()) { valid &= validateAndConstructKernelParams(Context, FD); } else { valid &= validateAndConstructOldStyleParams(Context, FD); } valid &= setSignatureMetadata(Context, FD); return valid; } bool RSExportForEach::validateAndConstructOldStyleParams( RSContext *Context, const clang::FunctionDecl *FD) { slangAssert(Context && FD); // If numParams is 0, we already marked this as a graphics root(). slangAssert(numParams > 0); bool valid = true; // Compute kernel functions of this style are required to return a void type. clang::ASTContext &C = Context->getASTContext(); if (mResultType != C.VoidTy) { Context->ReportError(FD->getLocation(), "Compute kernel %0() is required to return a " "void type") << FD->getName(); valid = false; } // Validate remaining parameter types size_t IndexOfFirstSpecialParameter = numParams; valid &= processSpecialParameters(Context, FD, &IndexOfFirstSpecialParameter); // Validate the non-special parameters, which should all be found before the // first special parameter. for (size_t i = 0; i < IndexOfFirstSpecialParameter; i++) { const clang::ParmVarDecl *PVD = FD->getParamDecl(i); clang::QualType QT = PVD->getType().getCanonicalType(); if (!QT->isPointerType()) { Context->ReportError(PVD->getLocation(), "Compute kernel %0() cannot have non-pointer " "parameters besides special parameters (%1). Parameter '%2' is " "of type: '%3'") << FD->getName() << listSpecialKernelParameters(Context->getTargetAPI()) << PVD->getName() << PVD->getType().getAsString(); valid = false; continue; } // The only non-const pointer should be out. if (!QT->getPointeeType().isConstQualified()) { if (mOut == nullptr) { mOut = PVD; } else { Context->ReportError(PVD->getLocation(), "Compute kernel %0() can only have one non-const " "pointer parameter. Parameters '%1' and '%2' are " "both non-const.") << FD->getName() << mOut->getName() << PVD->getName(); valid = false; } } else { if (mIns.empty() && mOut == nullptr) { mIns.push_back(PVD); } else if (mUsrData == nullptr) { mUsrData = PVD; } else { Context->ReportError( PVD->getLocation(), "Unexpected parameter '%0' for compute kernel %1()") << PVD->getName() << FD->getName(); valid = false; } } } if (mIns.empty() && !mOut) { Context->ReportError(FD->getLocation(), "Compute kernel %0() must have at least one " "parameter for in or out") << FD->getName(); valid = false; } return valid; } bool RSExportForEach::validateAndConstructKernelParams( RSContext *Context, const clang::FunctionDecl *FD) { slangAssert(Context && FD); bool valid = true; clang::ASTContext &C = Context->getASTContext(); if (Context->getTargetAPI() < SLANG_JB_MR1_TARGET_API) { Context->ReportError(FD->getLocation(), "Compute kernel %0() targeting SDK levels " "%1-%2 may not use pass-by-value with " "__attribute__((kernel))") << FD->getName() << SLANG_MINIMUM_TARGET_API << (SLANG_JB_MR1_TARGET_API - 1); return false; } // Denote that we are indeed a pass-by-value kernel. mIsKernelStyle = true; mHasReturnType = (mResultType != C.VoidTy); if (mResultType->isPointerType()) { Context->ReportError( FD->getTypeSpecStartLoc(), "Compute kernel %0() cannot return a pointer type: '%1'") << FD->getName() << mResultType.getAsString(); valid = false; } // Validate remaining parameter types size_t IndexOfFirstSpecialParameter = numParams; valid &= processSpecialParameters(Context, FD, &IndexOfFirstSpecialParameter); // Validate the non-special parameters, which should all be found before the // first special. for (size_t i = 0; i < IndexOfFirstSpecialParameter; i++) { const clang::ParmVarDecl *PVD = FD->getParamDecl(i); if (Context->getTargetAPI() >= SLANG_M_TARGET_API || i == 0) { if (i >= RS_KERNEL_INPUT_LIMIT) { Context->ReportError(PVD->getLocation(), "Invalid parameter '%0' for compute kernel %1(). " "Kernels targeting SDK levels %2+ may not use " "more than %3 input parameters.") << PVD->getName() << FD->getName() << SLANG_M_TARGET_API << int(RS_KERNEL_INPUT_LIMIT); } else { mIns.push_back(PVD); } } else { Context->ReportError(PVD->getLocation(), "Invalid parameter '%0' for compute kernel %1(). " "Kernels targeting SDK levels %2-%3 may not use " "multiple input parameters.") << PVD->getName() << FD->getName() << SLANG_MINIMUM_TARGET_API << (SLANG_M_TARGET_API - 1); valid = false; } clang::QualType QT = PVD->getType().getCanonicalType(); if (QT->isPointerType()) { Context->ReportError(PVD->getLocation(), "Compute kernel %0() cannot have " "parameter '%1' of pointer type: '%2'") << FD->getName() << PVD->getName() << PVD->getType().getAsString(); valid = false; } } // Check that we have at least one allocation to use for dimensions. if (valid && mIns.empty() && !mHasReturnType && Context->getTargetAPI() < SLANG_M_TARGET_API) { Context->ReportError(FD->getLocation(), "Compute kernel %0() targeting SDK levels " "%1-%2 must have at least one " "input parameter or a non-void return " "type") << FD->getName() << SLANG_MINIMUM_TARGET_API << (SLANG_M_TARGET_API - 1); valid = false; } return valid; } // Process the optional special parameters: // - Sets *IndexOfFirstSpecialParameter to the index of the first special parameter, or // FD->getNumParams() if none are found. // - Add bits to mSpecialParameterSignatureMetadata for the found special parameters. // Returns true if no errors. bool RSExportForEach::processSpecialParameters( RSContext *Context, const clang::FunctionDecl *FD, size_t *IndexOfFirstSpecialParameter) { auto DiagnosticCallback = [FD] { std::ostringstream DiagnosticDescription; DiagnosticDescription << "compute kernel " << FD->getName().str() << "()"; return DiagnosticDescription.str(); }; return slang::processSpecialKernelParameters(Context, DiagnosticCallback, FD, IndexOfFirstSpecialParameter, &mSpecialParameterSignatureMetadata); } bool RSExportForEach::setSignatureMetadata(RSContext *Context, const clang::FunctionDecl *FD) { mSignatureMetadata = 0; bool valid = true; if (mIsKernelStyle) { slangAssert(mOut == nullptr); slangAssert(mUsrData == nullptr); } else { slangAssert(!mHasReturnType); } // Set up the bitwise metadata encoding for runtime argument passing. const bool HasOut = mOut || mHasReturnType; mSignatureMetadata |= (hasIns() ? bcinfo::MD_SIG_In : 0); mSignatureMetadata |= (HasOut ? bcinfo::MD_SIG_Out : 0); mSignatureMetadata |= (mUsrData ? bcinfo::MD_SIG_Usr : 0); mSignatureMetadata |= (mIsKernelStyle ? bcinfo::MD_SIG_Kernel : 0); // pass-by-value mSignatureMetadata |= mSpecialParameterSignatureMetadata; if (Context->getTargetAPI() < SLANG_ICS_TARGET_API) { // APIs before ICS cannot skip between parameters. It is ok, however, for // them to omit further parameters (i.e. skipping X is ok if you skip Y). if (mSignatureMetadata != (bcinfo::MD_SIG_In | bcinfo::MD_SIG_Out | bcinfo::MD_SIG_Usr | bcinfo::MD_SIG_X | bcinfo::MD_SIG_Y) && mSignatureMetadata != (bcinfo::MD_SIG_In | bcinfo::MD_SIG_Out | bcinfo::MD_SIG_Usr | bcinfo::MD_SIG_X) && mSignatureMetadata != (bcinfo::MD_SIG_In | bcinfo::MD_SIG_Out | bcinfo::MD_SIG_Usr) && mSignatureMetadata != (bcinfo::MD_SIG_In | bcinfo::MD_SIG_Out) && mSignatureMetadata != (bcinfo::MD_SIG_In)) { Context->ReportError(FD->getLocation(), "Compute kernel %0() targeting SDK levels " "%1-%2 may not skip parameters") << FD->getName() << SLANG_MINIMUM_TARGET_API << (SLANG_ICS_TARGET_API - 1); valid = false; } } return valid; } RSExportForEach *RSExportForEach::Create(RSContext *Context, const clang::FunctionDecl *FD) { slangAssert(Context && FD); llvm::StringRef Name = FD->getName(); RSExportForEach *FE; slangAssert(!Name.empty() && "Function must have a name"); FE = new RSExportForEach(Context, Name); if (!FE->validateAndConstructParams(Context, FD)) { return nullptr; } clang::ASTContext &Ctx = Context->getASTContext(); std::string Id = CreateDummyName("helper_foreach_param", FE->getName()); // Extract the usrData parameter (if we have one) if (FE->mUsrData) { const clang::ParmVarDecl *PVD = FE->mUsrData; clang::QualType QT = PVD->getType().getCanonicalType(); slangAssert(QT->isPointerType() && QT->getPointeeType().isConstQualified()); const clang::ASTContext &C = Context->getASTContext(); if (QT->getPointeeType().getCanonicalType().getUnqualifiedType() == C.VoidTy) { // In the case of using const void*, we can't reflect an appopriate // Java type, so we fall back to just reflecting the ain/aout parameters FE->mUsrData = nullptr; } else { clang::RecordDecl *RD = clang::RecordDecl::Create(Ctx, clang::TTK_Struct, Ctx.getTranslationUnitDecl(), clang::SourceLocation(), clang::SourceLocation(), &Ctx.Idents.get(Id)); clang::FieldDecl *FD = clang::FieldDecl::Create(Ctx, RD, clang::SourceLocation(), clang::SourceLocation(), PVD->getIdentifier(), QT->getPointeeType(), nullptr, /* BitWidth = */ nullptr, /* Mutable = */ false, /* HasInit = */ clang::ICIS_NoInit); RD->addDecl(FD); RD->completeDefinition(); // Create an export type iff we have a valid usrData type clang::QualType T = Ctx.getTagDeclType(RD); slangAssert(!T.isNull()); RSExportType *ET = RSExportType::Create(Context, T.getTypePtr(), LegacyKernelArgument); slangAssert(ET && "Failed to export a kernel"); slangAssert((ET->getClass() == RSExportType::ExportClassRecord) && "Parameter packet must be a record"); FE->mParamPacketType = static_cast(ET); } } // Construct type information about inputs and outputs. Return null when // there is an error exporting types. bool TypeExportError = false; if (FE->hasIns()) { for (InIter BI = FE->mIns.begin(), EI = FE->mIns.end(); BI != EI; BI++) { const clang::Type *T = (*BI)->getType().getCanonicalType().getTypePtr(); ExportKind EK = (FE->mIsKernelStyle ? NotLegacyKernelArgument : LegacyKernelArgument); RSExportType *InExportType = RSExportType::Create(Context, T, EK); // It is not an error if we don't export an input type for legacy // kernel arguments. This can happen in the case of a void pointer. if (FE->mIsKernelStyle && !InExportType) { TypeExportError = true; } FE->mInTypes.push_back(InExportType); } } if (FE->mIsKernelStyle && FE->mHasReturnType) { const clang::Type *ReturnType = FE->mResultType.getTypePtr(); FE->mOutType = RSExportType::Create(Context, ReturnType, NotLegacyKernelArgument); TypeExportError |= !FE->mOutType; } else if (FE->mOut) { const clang::Type *OutType = FE->mOut->getType().getCanonicalType().getTypePtr(); FE->mOutType = RSExportType::Create(Context, OutType, LegacyKernelArgument); // It is not an error if we don't export an output type. // This can happen in the case of a void pointer. } if (TypeExportError) { slangAssert(Context->getDiagnostics()->hasErrorOccurred() && "Error exporting type but no diagnostic message issued!"); return nullptr; } return FE; } RSExportForEach *RSExportForEach::CreateDummyRoot(RSContext *Context) { slangAssert(Context); llvm::StringRef Name = "root"; RSExportForEach *FE = new RSExportForEach(Context, Name); FE->mDummyRoot = true; return FE; } bool RSExportForEach::isRSForEachFunc(unsigned int targetAPI, const clang::FunctionDecl *FD) { if (!FD) { return false; } // Anything tagged as a kernel("") is definitely used with ForEach. if (auto *Kernel = FD->getAttr()) { return Kernel->getKernelKind().empty(); } if (RSSpecialFunc::isGraphicsRootRSFunc(targetAPI, FD)) { return false; } // Check if first parameter is a pointer (which is required for ForEach). unsigned int numParams = FD->getNumParams(); if (numParams > 0) { const clang::ParmVarDecl *PVD = FD->getParamDecl(0); clang::QualType QT = PVD->getType().getCanonicalType(); if (QT->isPointerType()) { return true; } // Any non-graphics root() is automatically a ForEach candidate. // At this point, however, we know that it is not going to be a valid // compute root() function (due to not having a pointer parameter). We // still want to return true here, so that we can issue appropriate // diagnostics. if (isRootRSFunc(FD)) { return true; } } return false; } unsigned RSExportForEach::getNumInputs(unsigned int targetAPI, const clang::FunctionDecl *FD) { unsigned numInputs = 0; for (const clang::ParmVarDecl* param : FD->params()) { if (!isSpecialKernelParameter(param->getName())) { numInputs++; } } return numInputs; } } // namespace slang