/* * Copyright 2010-2012, 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_reflection.h" #include <sys/stat.h> #include <cstdarg> #include <cctype> #include <algorithm> #include <sstream> #include <string> #include <utility> #include "llvm/ADT/APFloat.h" #include "llvm/ADT/StringExtras.h" #include "os_sep.h" #include "slang_rs_context.h" #include "slang_rs_export_var.h" #include "slang_rs_export_foreach.h" #include "slang_rs_export_func.h" #include "slang_rs_reflect_utils.h" #include "slang_version.h" #include "slang_utils.h" #include "slang_rs_reflection_base.h" #define RS_SCRIPT_CLASS_NAME_PREFIX "ScriptC_" #define RS_SCRIPT_CLASS_SUPER_CLASS_NAME "ScriptC" #define RS_TYPE_CLASS_SUPER_CLASS_NAME "android.renderscript.Script.FieldBase" #define RS_TYPE_ITEM_CLASS_NAME "Item" #define RS_TYPE_ITEM_BUFFER_NAME "mItemArray" #define RS_TYPE_ITEM_BUFFER_PACKER_NAME "mIOBuffer" #define RS_TYPE_ELEMENT_REF_NAME "mElementCache" #define RS_EXPORT_VAR_INDEX_PREFIX "mExportVarIdx_" #define RS_EXPORT_VAR_PREFIX "mExportVar_" #define RS_EXPORT_VAR_ELEM_PREFIX "mExportVarElem_" #define RS_EXPORT_VAR_DIM_PREFIX "mExportVarDim_" #define RS_EXPORT_VAR_CONST_PREFIX "const_" #define RS_ELEM_PREFIX "__" #define RS_FP_PREFIX "__rs_fp_" #define RS_RESOURCE_NAME "__rs_resource_name" #define RS_EXPORT_FUNC_INDEX_PREFIX "mExportFuncIdx_" #define RS_EXPORT_FOREACH_INDEX_PREFIX "mExportForEachIdx_" #define RS_EXPORT_VAR_ALLOCATION_PREFIX "mAlloction_" #define RS_EXPORT_VAR_DATA_STORAGE_PREFIX "mData_" namespace slang { // Some utility function using internal in RSReflection static bool GetClassNameFromFileName(const std::string &FileName, std::string &ClassName) { ClassName.clear(); if (FileName.empty() || (FileName == "-")) return true; ClassName = RSSlangReflectUtils::JavaClassNameFromRSFileName(FileName.c_str()); return true; } static const char *GetMatrixTypeName(const RSExportMatrixType *EMT) { static const char *MatrixTypeJavaNameMap[] = { /* 2x2 */ "Matrix2f", /* 3x3 */ "Matrix3f", /* 4x4 */ "Matrix4f", }; unsigned Dim = EMT->getDim(); if ((Dim - 2) < (sizeof(MatrixTypeJavaNameMap) / sizeof(const char*))) return MatrixTypeJavaNameMap[ EMT->getDim() - 2 ]; slangAssert(false && "GetMatrixTypeName : Unsupported matrix dimension"); return NULL; } static const char *GetVectorAccessor(unsigned Index) { static const char *VectorAccessorMap[] = { /* 0 */ "x", /* 1 */ "y", /* 2 */ "z", /* 3 */ "w", }; slangAssert((Index < (sizeof(VectorAccessorMap) / sizeof(const char*))) && "Out-of-bound index to access vector member"); return VectorAccessorMap[Index]; } static const char *GetPackerAPIName(const RSExportPrimitiveType *EPT) { static const char *PrimitiveTypePackerAPINameMap[] = { "", // RSExportPrimitiveType::DataTypeFloat16 "addF32", // RSExportPrimitiveType::DataTypeFloat32 "addF64", // RSExportPrimitiveType::DataTypeFloat64 "addI8", // RSExportPrimitiveType::DataTypeSigned8 "addI16", // RSExportPrimitiveType::DataTypeSigned16 "addI32", // RSExportPrimitiveType::DataTypeSigned32 "addI64", // RSExportPrimitiveType::DataTypeSigned64 "addU8", // RSExportPrimitiveType::DataTypeUnsigned8 "addU16", // RSExportPrimitiveType::DataTypeUnsigned16 "addU32", // RSExportPrimitiveType::DataTypeUnsigned32 "addU64", // RSExportPrimitiveType::DataTypeUnsigned64 "addBoolean", // RSExportPrimitiveType::DataTypeBoolean "addU16", // RSExportPrimitiveType::DataTypeUnsigned565 "addU16", // RSExportPrimitiveType::DataTypeUnsigned5551 "addU16", // RSExportPrimitiveType::DataTypeUnsigned4444 "addMatrix", // RSExportPrimitiveType::DataTypeRSMatrix2x2 "addMatrix", // RSExportPrimitiveType::DataTypeRSMatrix3x3 "addMatrix", // RSExportPrimitiveType::DataTypeRSMatrix4x4 "addObj", // RSExportPrimitiveType::DataTypeRSElement "addObj", // RSExportPrimitiveType::DataTypeRSType "addObj", // RSExportPrimitiveType::DataTypeRSAllocation "addObj", // RSExportPrimitiveType::DataTypeRSSampler "addObj", // RSExportPrimitiveType::DataTypeRSScript "addObj", // RSExportPrimitiveType::DataTypeRSMesh "addObj", // RSExportPrimitiveType::DataTypeRSPath "addObj", // RSExportPrimitiveType::DataTypeRSProgramFragment "addObj", // RSExportPrimitiveType::DataTypeRSProgramVertex "addObj", // RSExportPrimitiveType::DataTypeRSProgramRaster "addObj", // RSExportPrimitiveType::DataTypeRSProgramStore "addObj", // RSExportPrimitiveType::DataTypeRSFont }; unsigned TypeId = EPT->getType(); if (TypeId < (sizeof(PrimitiveTypePackerAPINameMap) / sizeof(const char*))) return PrimitiveTypePackerAPINameMap[ EPT->getType() ]; slangAssert(false && "GetPackerAPIName : Unknown primitive data type"); return NULL; } static std::string GetTypeName(const RSExportType *ET, bool Brackets = true) { switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: { return RSExportPrimitiveType::getRSReflectionType( static_cast<const RSExportPrimitiveType*>(ET))->java_name; } case RSExportType::ExportClassPointer: { const RSExportType *PointeeType = static_cast<const RSExportPointerType*>(ET)->getPointeeType(); if (PointeeType->getClass() != RSExportType::ExportClassRecord) return "Allocation"; else return PointeeType->getElementName(); } case RSExportType::ExportClassVector: { const RSExportVectorType *EVT = static_cast<const RSExportVectorType*>(ET); std::stringstream VecName; VecName << EVT->getRSReflectionType(EVT)->rs_java_vector_prefix << EVT->getNumElement(); return VecName.str(); } case RSExportType::ExportClassMatrix: { return GetMatrixTypeName(static_cast<const RSExportMatrixType*>(ET)); } case RSExportType::ExportClassConstantArray: { const RSExportConstantArrayType* CAT = static_cast<const RSExportConstantArrayType*>(ET); std::string ElementTypeName = GetTypeName(CAT->getElementType()); if (Brackets) { ElementTypeName.append("[]"); } return ElementTypeName; } case RSExportType::ExportClassRecord: { return ET->getElementName() + "."RS_TYPE_ITEM_CLASS_NAME; } default: { slangAssert(false && "Unknown class of type"); } } return ""; } static const char *GetTypeNullValue(const RSExportType *ET) { switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: { const RSExportPrimitiveType *EPT = static_cast<const RSExportPrimitiveType*>(ET); if (EPT->isRSObjectType()) return "null"; else if (EPT->getType() == RSExportPrimitiveType::DataTypeBoolean) return "false"; else return "0"; break; } case RSExportType::ExportClassPointer: case RSExportType::ExportClassVector: case RSExportType::ExportClassMatrix: case RSExportType::ExportClassConstantArray: case RSExportType::ExportClassRecord: { return "null"; break; } default: { slangAssert(false && "Unknown class of type"); } } return ""; } static std::string GetBuiltinElementConstruct(const RSExportType *ET) { if (ET->getClass() == RSExportType::ExportClassPrimitive) { return std::string("Element.") + ET->getElementName(); } else if (ET->getClass() == RSExportType::ExportClassVector) { const RSExportVectorType *EVT = static_cast<const RSExportVectorType*>(ET); if (EVT->getType() == RSExportPrimitiveType::DataTypeFloat32) { if (EVT->getNumElement() == 2) return "Element.F32_2"; else if (EVT->getNumElement() == 3) return "Element.F32_3"; else if (EVT->getNumElement() == 4) return "Element.F32_4"; } else if (EVT->getType() == RSExportPrimitiveType::DataTypeUnsigned8) { if (EVT->getNumElement() == 4) return "Element.U8_4"; } } else if (ET->getClass() == RSExportType::ExportClassMatrix) { const RSExportMatrixType *EMT = static_cast<const RSExportMatrixType *>(ET); switch (EMT->getDim()) { case 2: return "Element.MATRIX_2X2"; case 3: return "Element.MATRIX_3X3"; case 4: return "Element.MATRIX_4X4"; default: slangAssert(false && "Unsupported dimension of matrix"); } } // RSExportType::ExportClassPointer can't be generated in a struct. return ""; } /********************** Methods to generate script class **********************/ bool RSReflection::genScriptClass(Context &C, const std::string &ClassName, std::string &ErrorMsg) { if (!C.startClass(Context::AM_Public, false, ClassName, RS_SCRIPT_CLASS_SUPER_CLASS_NAME, ErrorMsg)) return false; genScriptClassConstructor(C); // Reflect export variable for (RSContext::const_export_var_iterator I = mRSContext->export_vars_begin(), E = mRSContext->export_vars_end(); I != E; I++) genExportVariable(C, *I); // Reflect export for each functions (only available on ICS+) if (mRSContext->getTargetAPI() >= SLANG_ICS_TARGET_API) { for (RSContext::const_export_foreach_iterator I = mRSContext->export_foreach_begin(), E = mRSContext->export_foreach_end(); I != E; I++) genExportForEach(C, *I); } // Reflect export function for (RSContext::const_export_func_iterator I = mRSContext->export_funcs_begin(), E = mRSContext->export_funcs_end(); I != E; I++) genExportFunction(C, *I); C.endClass(); return true; } void RSReflection::genScriptClassConstructor(Context &C) { // Provide a simple way to reference this object. C.indent() << "private static final String " RS_RESOURCE_NAME " = \"" << C.getResourceId() << "\";" << std::endl; // Generate a simple constructor with only a single parameter (the rest // can be inferred from information we already have). C.indent() << "// Constructor" << std::endl; C.startFunction(Context::AM_Public, false, NULL, C.getClassName(), 1, "RenderScript", "rs"); // Call alternate constructor with required parameters. // Look up the proper raw bitcode resource id via the context. C.indent() << "this(rs," << std::endl; C.indent() << " rs.getApplicationContext().getResources()," << std::endl; C.indent() << " rs.getApplicationContext().getResources()." "getIdentifier(" << std::endl; C.indent() << " " RS_RESOURCE_NAME ", \"raw\"," << std::endl; C.indent() << " rs.getApplicationContext().getPackageName()));" << std::endl; C.endFunction(); // Alternate constructor (legacy) with 3 original parameters. C.startFunction(Context::AM_Public, false, NULL, C.getClassName(), 3, "RenderScript", "rs", "Resources", "resources", "int", "id"); // Call constructor of super class C.indent() << "super(rs, resources, id);" << std::endl; // If an exported variable has initial value, reflect it for (RSContext::const_export_var_iterator I = mRSContext->export_vars_begin(), E = mRSContext->export_vars_end(); I != E; I++) { const RSExportVar *EV = *I; if (!EV->getInit().isUninit()) { genInitExportVariable(C, EV->getType(), EV->getName(), EV->getInit()); } else if (EV->getArraySize()) { // Always create an initial zero-init array object. C.indent() << RS_EXPORT_VAR_PREFIX << EV->getName() << " = new " << GetTypeName(EV->getType(), false) << "[" << EV->getArraySize() << "];" << std::endl; size_t NumInits = EV->getNumInits(); const RSExportConstantArrayType *ECAT = static_cast<const RSExportConstantArrayType*>(EV->getType()); const RSExportType *ET = ECAT->getElementType(); for (size_t i = 0; i < NumInits; i++) { std::stringstream Name; Name << EV->getName() << "[" << i << "]"; genInitExportVariable(C, ET, Name.str(), EV->getInitArray(i)); } } if (mRSContext->getTargetAPI() >= SLANG_JB_TARGET_API) { genTypeInstance(C, EV->getType()); } genFieldPackerInstance(C, EV->getType()); } for (RSContext::const_export_foreach_iterator I = mRSContext->export_foreach_begin(), E = mRSContext->export_foreach_end(); I != E; I++) { const RSExportForEach *EF = *I; const RSExportType *IET = EF->getInType(); if (IET) { genTypeInstanceFromPointer(C, IET); } const RSExportType *OET = EF->getOutType(); if (OET) { genTypeInstanceFromPointer(C, OET); } } C.endFunction(); for (std::set<std::string>::iterator I = C.mTypesToCheck.begin(), E = C.mTypesToCheck.end(); I != E; I++) { C.indent() << "private Element " RS_ELEM_PREFIX << *I << ";" << std::endl; } for (std::set<std::string>::iterator I = C.mFieldPackerTypes.begin(), E = C.mFieldPackerTypes.end(); I != E; I++) { C.indent() << "private FieldPacker " RS_FP_PREFIX << *I << ";" << std::endl; } return; } void RSReflection::genInitBoolExportVariable(Context &C, const std::string &VarName, const clang::APValue &Val) { slangAssert(!Val.isUninit() && "Not a valid initializer"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = "; slangAssert((Val.getKind() == clang::APValue::Int) && "Bool type has wrong initial APValue"); C.out() << ((Val.getInt().getSExtValue() == 0) ? "false" : "true") << ";" << std::endl; return; } void RSReflection::genInitPrimitiveExportVariable( Context &C, const std::string &VarName, const clang::APValue &Val) { slangAssert(!Val.isUninit() && "Not a valid initializer"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = "; C.out() << RSReflectionBase::genInitValue(Val); C.out() << ";" << std::endl; return; } void RSReflection::genInitExportVariable(Context &C, const RSExportType *ET, const std::string &VarName, const clang::APValue &Val) { slangAssert(!Val.isUninit() && "Not a valid initializer"); switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: { const RSExportPrimitiveType *EPT = static_cast<const RSExportPrimitiveType*>(ET); if (EPT->getType() == RSExportPrimitiveType::DataTypeBoolean) { genInitBoolExportVariable(C, VarName, Val); } else { genInitPrimitiveExportVariable(C, VarName, Val); } break; } case RSExportType::ExportClassPointer: { if (!Val.isInt() || Val.getInt().getSExtValue() != 0) std::cout << "Initializer which is non-NULL to pointer type variable " "will be ignored" << std::endl; break; } case RSExportType::ExportClassVector: { const RSExportVectorType *EVT = static_cast<const RSExportVectorType*>(ET); switch (Val.getKind()) { case clang::APValue::Int: case clang::APValue::Float: { for (unsigned i = 0; i < EVT->getNumElement(); i++) { std::string Name = VarName + "." + GetVectorAccessor(i); genInitPrimitiveExportVariable(C, Name, Val); } break; } case clang::APValue::Vector: { std::stringstream VecName; VecName << EVT->getRSReflectionType(EVT)->rs_java_vector_prefix << EVT->getNumElement(); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = new " << VecName.str() << "();" << std::endl; unsigned NumElements = std::min(static_cast<unsigned>(EVT->getNumElement()), Val.getVectorLength()); for (unsigned i = 0; i < NumElements; i++) { const clang::APValue &ElementVal = Val.getVectorElt(i); std::string Name = VarName + "." + GetVectorAccessor(i); genInitPrimitiveExportVariable(C, Name, ElementVal); } break; } case clang::APValue::MemberPointer: case clang::APValue::Uninitialized: case clang::APValue::ComplexInt: case clang::APValue::ComplexFloat: case clang::APValue::LValue: case clang::APValue::Array: case clang::APValue::Struct: case clang::APValue::Union: case clang::APValue::AddrLabelDiff: { slangAssert(false && "Unexpected type of value of initializer."); } } break; } // TODO(zonr): Resolving initializer of a record (and matrix) type variable // is complex. It cannot obtain by just simply evaluating the initializer // expression. case RSExportType::ExportClassMatrix: case RSExportType::ExportClassConstantArray: case RSExportType::ExportClassRecord: { #if 0 unsigned InitIndex = 0; const RSExportRecordType *ERT = static_cast<const RSExportRecordType*>(ET); slangAssert((Val.getKind() == clang::APValue::Vector) && "Unexpected type of initializer for record type variable"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = new " << ERT->getElementName() << "."RS_TYPE_ITEM_CLASS_NAME"();" << std::endl; for (RSExportRecordType::const_field_iterator I = ERT->fields_begin(), E = ERT->fields_end(); I != E; I++) { const RSExportRecordType::Field *F = *I; std::string FieldName = VarName + "." + F->getName(); if (InitIndex > Val.getVectorLength()) break; genInitPrimitiveExportVariable(C, FieldName, Val.getVectorElt(InitIndex++)); } #endif slangAssert(false && "Unsupported initializer for record/matrix/constant " "array type variable currently"); break; } default: { slangAssert(false && "Unknown class of type"); } } return; } void RSReflection::genExportVariable(Context &C, const RSExportVar *EV) { const RSExportType *ET = EV->getType(); C.indent() << "private final static int "RS_EXPORT_VAR_INDEX_PREFIX << EV->getName() << " = " << C.getNextExportVarSlot() << ";" << std::endl; switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: { genPrimitiveTypeExportVariable(C, EV); break; } case RSExportType::ExportClassPointer: { genPointerTypeExportVariable(C, EV); break; } case RSExportType::ExportClassVector: { genVectorTypeExportVariable(C, EV); break; } case RSExportType::ExportClassMatrix: { genMatrixTypeExportVariable(C, EV); break; } case RSExportType::ExportClassConstantArray: { genConstantArrayTypeExportVariable(C, EV); break; } case RSExportType::ExportClassRecord: { genRecordTypeExportVariable(C, EV); break; } default: { slangAssert(false && "Unknown class of type"); } } return; } void RSReflection::genExportFunction(Context &C, const RSExportFunc *EF) { C.indent() << "private final static int "RS_EXPORT_FUNC_INDEX_PREFIX << EF->getName() << " = " << C.getNextExportFuncSlot() << ";" << std::endl; // invoke_*() Context::ArgTy Args; if (EF->hasParam()) { for (RSExportFunc::const_param_iterator I = EF->params_begin(), E = EF->params_end(); I != E; I++) { Args.push_back(std::make_pair(GetTypeName((*I)->getType()), (*I)->getName())); } } C.startFunction(Context::AM_Public, false, "void", "invoke_" + EF->getName(/*Mangle=*/ false), // We are using un-mangled name since Java // supports method overloading. Args); if (!EF->hasParam()) { C.indent() << "invoke("RS_EXPORT_FUNC_INDEX_PREFIX << EF->getName() << ");" << std::endl; } else { const RSExportRecordType *ERT = EF->getParamPacketType(); std::string FieldPackerName = EF->getName() + "_fp"; if (genCreateFieldPacker(C, ERT, FieldPackerName.c_str())) genPackVarOfType(C, ERT, NULL, FieldPackerName.c_str()); C.indent() << "invoke("RS_EXPORT_FUNC_INDEX_PREFIX << EF->getName() << ", " << FieldPackerName << ");" << std::endl; } C.endFunction(); return; } void RSReflection::genExportForEach(Context &C, const RSExportForEach *EF) { if (EF->isDummyRoot()) { // Skip reflection for dummy root() kernels. Note that we have to // advance the next slot number for ForEach, however. C.indent() << "//private final static int "RS_EXPORT_FOREACH_INDEX_PREFIX << EF->getName() << " = " << C.getNextExportForEachSlot() << ";" << std::endl; return; } C.indent() << "private final static int "RS_EXPORT_FOREACH_INDEX_PREFIX << EF->getName() << " = " << C.getNextExportForEachSlot() << ";" << std::endl; // forEach_*() Context::ArgTy Args; slangAssert(EF->getNumParameters() > 0 || EF->hasReturn()); if (EF->hasIn()) Args.push_back(std::make_pair("Allocation", "ain")); if (EF->hasOut() || EF->hasReturn()) Args.push_back(std::make_pair("Allocation", "aout")); const RSExportRecordType *ERT = EF->getParamPacketType(); if (ERT) { for (RSExportForEach::const_param_iterator I = EF->params_begin(), E = EF->params_end(); I != E; I++) { Args.push_back(std::make_pair(GetTypeName((*I)->getType()), (*I)->getName())); } } const RSExportType *IET = EF->getInType(); const RSExportType *OET = EF->getOutType(); if (mRSContext->getTargetAPI() >= SLANG_JB_MR1_TARGET_API) { int signature = 0; C.startFunction(Context::AM_Public, false, "Script.KernelID", "getKernelID_" + EF->getName(), 0); if (IET) signature |= 1; if (OET) signature |= 2; //TODO: add element checking C.indent() << "return createKernelID(" << RS_EXPORT_FOREACH_INDEX_PREFIX << EF->getName() << ", " << signature << ", null, null);" << std::endl; C.endFunction(); } C.startFunction(Context::AM_Public, false, "void", "forEach_" + EF->getName(), Args); if (IET) { genTypeCheck(C, IET, "ain"); } if (OET) { genTypeCheck(C, OET, "aout"); } if (EF->hasIn() && (EF->hasOut() || EF->hasReturn())) { C.indent() << "// Verify dimensions" << std::endl; C.indent() << "Type tIn = ain.getType();" << std::endl; C.indent() << "Type tOut = aout.getType();" << std::endl; C.indent() << "if ((tIn.getCount() != tOut.getCount()) ||" << std::endl; C.indent() << " (tIn.getX() != tOut.getX()) ||" << std::endl; C.indent() << " (tIn.getY() != tOut.getY()) ||" << std::endl; C.indent() << " (tIn.getZ() != tOut.getZ()) ||" << std::endl; C.indent() << " (tIn.hasFaces() != tOut.hasFaces()) ||" << std::endl; C.indent() << " (tIn.hasMipmaps() != tOut.hasMipmaps())) {" << std::endl; C.indent() << " throw new RSRuntimeException(\"Dimension mismatch " << "between input and output parameters!\");"; C.out() << std::endl; C.indent() << "}" << std::endl; } std::string FieldPackerName = EF->getName() + "_fp"; if (ERT) { if (genCreateFieldPacker(C, ERT, FieldPackerName.c_str())) { genPackVarOfType(C, ERT, NULL, FieldPackerName.c_str()); } } C.indent() << "forEach("RS_EXPORT_FOREACH_INDEX_PREFIX << EF->getName(); if (EF->hasIn()) C.out() << ", ain"; else C.out() << ", null"; if (EF->hasOut() || EF->hasReturn()) C.out() << ", aout"; else C.out() << ", null"; if (EF->hasUsrData()) C.out() << ", " << FieldPackerName; else C.out() << ", null"; C.out() << ");" << std::endl; C.endFunction(); return; } void RSReflection::genTypeInstanceFromPointer(Context &C, const RSExportType *ET) { if (ET->getClass() == RSExportType::ExportClassPointer) { // For pointer parameters to original forEach kernels. const RSExportPointerType *EPT = static_cast<const RSExportPointerType*>(ET); genTypeInstance(C, EPT->getPointeeType()); } else { // For handling pass-by-value kernel parameters. genTypeInstance(C, ET); } } void RSReflection::genTypeInstance(Context &C, const RSExportType *ET) { switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: case RSExportType::ExportClassVector: case RSExportType::ExportClassConstantArray: { std::string TypeName = ET->getElementName(); if (C.addTypeNameForElement(TypeName)) { C.indent() << RS_ELEM_PREFIX << TypeName << " = Element." << TypeName << "(rs);" << std::endl; } break; } case RSExportType::ExportClassRecord: { std::string ClassName = ET->getElementName(); if (C.addTypeNameForElement(ClassName)) { C.indent() << RS_ELEM_PREFIX << ClassName << " = " << ClassName << ".createElement(rs);" << std::endl; } break; } default: break; } } void RSReflection::genFieldPackerInstance(Context &C, const RSExportType *ET) { switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: case RSExportType::ExportClassVector: case RSExportType::ExportClassConstantArray: case RSExportType::ExportClassRecord: { std::string TypeName = ET->getElementName(); C.addTypeNameForFieldPacker(TypeName); break; } default: break; } } void RSReflection::genTypeCheck(Context &C, const RSExportType *ET, const char *VarName) { C.indent() << "// check " << VarName << std::endl; if (ET->getClass() == RSExportType::ExportClassPointer) { const RSExportPointerType *EPT = static_cast<const RSExportPointerType*>(ET); ET = EPT->getPointeeType(); } std::string TypeName; switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: case RSExportType::ExportClassVector: case RSExportType::ExportClassRecord: { TypeName = ET->getElementName(); break; } default: break; } if (!TypeName.empty()) { C.indent() << "if (!" << VarName << ".getType().getElement().isCompatible(" RS_ELEM_PREFIX << TypeName << ")) {" << std::endl; C.indent() << " throw new RSRuntimeException(\"Type mismatch with " << TypeName << "!\");" << std::endl; C.indent() << "}" << std::endl; } return; } void RSReflection::genPrimitiveTypeExportVariable( Context &C, const RSExportVar *EV) { slangAssert((EV->getType()->getClass() == RSExportType::ExportClassPrimitive) && "Variable should be type of primitive here"); const RSExportPrimitiveType *EPT = static_cast<const RSExportPrimitiveType*>(EV->getType()); std::string TypeName = GetTypeName(EPT); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, EV->getName()); if (EV->isConst()) { C.indent() << "public final static " << TypeName << " " RS_EXPORT_VAR_CONST_PREFIX << VarName << " = "; const clang::APValue &Val = EV->getInit(); C.out() << RSReflectionBase::genInitValue(Val, EPT->getType() == RSExportPrimitiveType::DataTypeBoolean) << ";" << std::endl; } else { // set_*() // This must remain synchronized, since multiple Dalvik threads may // be calling setters. C.startFunction(Context::AM_PublicSynchronized, false, "void", "set_" + VarName, 1, TypeName.c_str(), "v"); if ((EPT->getSize() < 4) || EV->isUnsigned()) { // We create/cache a per-type FieldPacker. This allows us to reuse the // validation logic (for catching negative inputs from Dalvik, as well // as inputs that are too large to be represented in the unsigned type). // Sub-integer types are also handled specially here, so that we don't // overwrite bytes accidentally. std::string ElemName = EPT->getElementName(); std::string FPName; FPName = RS_FP_PREFIX + ElemName; C.indent() << "if (" << FPName << "!= null) {" << std::endl; C.incIndentLevel(); C.indent() << FPName << ".reset();" << std::endl; C.decIndentLevel(); C.indent() << "} else {" << std::endl; C.incIndentLevel(); C.indent() << FPName << " = new FieldPacker(" << EPT->getSize() << ");" << std::endl; C.decIndentLevel(); C.indent() << "}" << std::endl; genPackVarOfType(C, EPT, "v", FPName.c_str()); C.indent() << "setVar("RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", " << FPName << ");" << std::endl; } else { C.indent() << "setVar("RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", v);" << std::endl; } // Dalvik update comes last, since the input may be invalid (and hence // throw an exception). C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = v;" << std::endl; C.endFunction(); } genGetExportVariable(C, TypeName, VarName); genGetFieldID(C, VarName); return; } void RSReflection::genPointerTypeExportVariable(Context &C, const RSExportVar *EV) { const RSExportType *ET = EV->getType(); const RSExportType *PointeeType; slangAssert((ET->getClass() == RSExportType::ExportClassPointer) && "Variable should be type of pointer here"); PointeeType = static_cast<const RSExportPointerType*>(ET)->getPointeeType(); std::string TypeName = GetTypeName(ET); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, VarName); // bind_*() C.startFunction(Context::AM_Public, false, "void", "bind_" + VarName, 1, TypeName.c_str(), "v"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = v;" << std::endl; C.indent() << "if (v == null) bindAllocation(null, "RS_EXPORT_VAR_INDEX_PREFIX << VarName << ");" << std::endl; if (PointeeType->getClass() == RSExportType::ExportClassRecord) C.indent() << "else bindAllocation(v.getAllocation(), " RS_EXPORT_VAR_INDEX_PREFIX << VarName << ");" << std::endl; else C.indent() << "else bindAllocation(v, "RS_EXPORT_VAR_INDEX_PREFIX << VarName << ");" << std::endl; C.endFunction(); genGetExportVariable(C, TypeName, VarName); return; } void RSReflection::genVectorTypeExportVariable(Context &C, const RSExportVar *EV) { slangAssert((EV->getType()->getClass() == RSExportType::ExportClassVector) && "Variable should be type of vector here"); std::string TypeName = GetTypeName(EV->getType()); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, VarName); genSetExportVariable(C, TypeName, EV); genGetExportVariable(C, TypeName, VarName); genGetFieldID(C, VarName); return; } void RSReflection::genMatrixTypeExportVariable(Context &C, const RSExportVar *EV) { slangAssert((EV->getType()->getClass() == RSExportType::ExportClassMatrix) && "Variable should be type of matrix here"); const RSExportType *ET = EV->getType(); std::string TypeName = GetTypeName(ET); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, VarName); // set_*() if (!EV->isConst()) { const char *FieldPackerName = "fp"; C.startFunction(Context::AM_PublicSynchronized, false, "void", "set_" + VarName, 1, TypeName.c_str(), "v"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = v;" << std::endl; if (genCreateFieldPacker(C, ET, FieldPackerName)) genPackVarOfType(C, ET, "v", FieldPackerName); C.indent() << "setVar("RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", " << FieldPackerName << ");" << std::endl; C.endFunction(); } genGetExportVariable(C, TypeName, VarName); genGetFieldID(C, VarName); return; } void RSReflection::genConstantArrayTypeExportVariable( Context &C, const RSExportVar *EV) { slangAssert((EV->getType()->getClass() == RSExportType::ExportClassConstantArray) && "Variable should be type of constant array here"); std::string TypeName = GetTypeName(EV->getType()); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, VarName); genSetExportVariable(C, TypeName, EV); genGetExportVariable(C, TypeName, VarName); genGetFieldID(C, VarName); return; } void RSReflection::genRecordTypeExportVariable(Context &C, const RSExportVar *EV) { slangAssert((EV->getType()->getClass() == RSExportType::ExportClassRecord) && "Variable should be type of struct here"); std::string TypeName = GetTypeName(EV->getType()); std::string VarName = EV->getName(); genPrivateExportVariable(C, TypeName, VarName); genSetExportVariable(C, TypeName, EV); genGetExportVariable(C, TypeName, VarName); genGetFieldID(C, VarName); return; } void RSReflection::genPrivateExportVariable(Context &C, const std::string &TypeName, const std::string &VarName) { C.indent() << "private " << TypeName << " "RS_EXPORT_VAR_PREFIX << VarName << ";" << std::endl; return; } void RSReflection::genSetExportVariable(Context &C, const std::string &TypeName, const RSExportVar *EV) { if (!EV->isConst()) { const char *FieldPackerName = "fp"; std::string VarName = EV->getName(); const RSExportType *ET = EV->getType(); C.startFunction(Context::AM_PublicSynchronized, false, "void", "set_" + VarName, 1, TypeName.c_str(), "v"); C.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = v;" << std::endl; if (genCreateFieldPacker(C, ET, FieldPackerName)) genPackVarOfType(C, ET, "v", FieldPackerName); if (mRSContext->getTargetAPI() < SLANG_JB_TARGET_API) { // Legacy apps must use the old setVar() without Element/dim components. C.indent() << "setVar("RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", " << FieldPackerName << ");" << std::endl; } else { // We only have support for one-dimensional array reflection today, // but the entry point (i.e. setVar()) takes an array of dimensions. C.indent() << "int []__dimArr = new int[1];" << std::endl; C.indent() << "__dimArr[0] = " << ET->getSize() << ";" << std::endl; C.indent() << "setVar("RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", " << FieldPackerName << ", " RS_ELEM_PREFIX << ET->getElementName() << ", __dimArr);" << std::endl; } C.endFunction(); } return; } void RSReflection::genGetExportVariable(Context &C, const std::string &TypeName, const std::string &VarName) { C.startFunction(Context::AM_Public, false, TypeName.c_str(), "get_" + VarName, 0); C.indent() << "return "RS_EXPORT_VAR_PREFIX << VarName << ";" << std::endl; C.endFunction(); } void RSReflection::genGetFieldID(Context &C, const std::string &VarName) { // We only generate getFieldID_*() for non-Pointer (bind) types. if (mRSContext->getTargetAPI() >= SLANG_JB_MR1_TARGET_API) { C.startFunction(Context::AM_Public, false, "Script.FieldID", "getFieldID_" + VarName, 0); C.indent() << "return createFieldID(" << RS_EXPORT_VAR_INDEX_PREFIX << VarName << ", null);" << std::endl; C.endFunction(); } } /******************* Methods to generate script class /end *******************/ bool RSReflection::genCreateFieldPacker(Context &C, const RSExportType *ET, const char *FieldPackerName) { size_t AllocSize = RSExportType::GetTypeAllocSize(ET); if (AllocSize > 0) C.indent() << "FieldPacker " << FieldPackerName << " = new FieldPacker(" << AllocSize << ");" << std::endl; else return false; return true; } void RSReflection::genPackVarOfType(Context &C, const RSExportType *ET, const char *VarName, const char *FieldPackerName) { switch (ET->getClass()) { case RSExportType::ExportClassPrimitive: case RSExportType::ExportClassVector: { C.indent() << FieldPackerName << "." << GetPackerAPIName( static_cast<const RSExportPrimitiveType*>(ET)) << "(" << VarName << ");" << std::endl; break; } case RSExportType::ExportClassPointer: { // Must reflect as type Allocation in Java const RSExportType *PointeeType = static_cast<const RSExportPointerType*>(ET)->getPointeeType(); if (PointeeType->getClass() != RSExportType::ExportClassRecord) C.indent() << FieldPackerName << ".addI32(" << VarName << ".getPtr());" << std::endl; else C.indent() << FieldPackerName << ".addI32(" << VarName << ".getAllocation().getPtr());" << std::endl; break; } case RSExportType::ExportClassMatrix: { C.indent() << FieldPackerName << ".addMatrix(" << VarName << ");" << std::endl; break; } case RSExportType::ExportClassConstantArray: { const RSExportConstantArrayType *ECAT = static_cast<const RSExportConstantArrayType *>(ET); // TODO(zonr): more elegant way. Currently, we obtain the unique index // variable (this method involves recursive call which means // we may have more than one level loop, therefore we can't // always use the same index variable name here) name given // in the for-loop from counting the '.' in @VarName. unsigned Level = 0; size_t LastDotPos = 0; std::string ElementVarName(VarName); while (LastDotPos != std::string::npos) { LastDotPos = ElementVarName.find_first_of('.', LastDotPos + 1); Level++; } std::string IndexVarName("ct"); IndexVarName.append(llvm::utostr_32(Level)); C.indent() << "for (int " << IndexVarName << " = 0; " << IndexVarName << " < " << ECAT->getSize() << "; " << IndexVarName << "++)"; C.startBlock(); ElementVarName.append("[" + IndexVarName + "]"); genPackVarOfType(C, ECAT->getElementType(), ElementVarName.c_str(), FieldPackerName); C.endBlock(); break; } case RSExportType::ExportClassRecord: { const RSExportRecordType *ERT = static_cast<const RSExportRecordType*>(ET); // Relative pos from now on in field packer unsigned Pos = 0; for (RSExportRecordType::const_field_iterator I = ERT->fields_begin(), E = ERT->fields_end(); I != E; I++) { const RSExportRecordType::Field *F = *I; std::string FieldName; size_t FieldOffset = F->getOffsetInParent(); size_t FieldStoreSize = RSExportType::GetTypeStoreSize(F->getType()); size_t FieldAllocSize = RSExportType::GetTypeAllocSize(F->getType()); if (VarName != NULL) FieldName = VarName + ("." + F->getName()); else FieldName = F->getName(); if (FieldOffset > Pos) C.indent() << FieldPackerName << ".skip(" << (FieldOffset - Pos) << ");" << std::endl; genPackVarOfType(C, F->getType(), FieldName.c_str(), FieldPackerName); // There is padding in the field type if (FieldAllocSize > FieldStoreSize) C.indent() << FieldPackerName << ".skip(" << (FieldAllocSize - FieldStoreSize) << ");" << std::endl; Pos = FieldOffset + FieldAllocSize; } // There maybe some padding after the struct if (RSExportType::GetTypeAllocSize(ERT) > Pos) C.indent() << FieldPackerName << ".skip(" << RSExportType::GetTypeAllocSize(ERT) - Pos << ");" << std::endl; break; } default: { slangAssert(false && "Unknown class of type"); } } return; } void RSReflection::genAllocateVarOfType(Context &C, const RSExportType *T, const std::string &VarName) { switch (T->getClass()) { case RSExportType::ExportClassPrimitive: { // Primitive type like int in Java has its own storage once it's declared. // // FIXME: Should we allocate storage for RS object? // if (static_cast<const RSExportPrimitiveType *>(T)->isRSObjectType()) // C.indent() << VarName << " = new " << GetTypeName(T) << "();" // << std::endl; break; } case RSExportType::ExportClassPointer: { // Pointer type is an instance of Allocation or a TypeClass whose value is // expected to be assigned by programmer later in Java program. Therefore // we don't reflect things like [VarName] = new Allocation(); C.indent() << VarName << " = null;" << std::endl; break; } case RSExportType::ExportClassConstantArray: { const RSExportConstantArrayType *ECAT = static_cast<const RSExportConstantArrayType *>(T); const RSExportType *ElementType = ECAT->getElementType(); C.indent() << VarName << " = new " << GetTypeName(ElementType) << "[" << ECAT->getSize() << "];" << std::endl; // Primitive type element doesn't need allocation code. if (ElementType->getClass() != RSExportType::ExportClassPrimitive) { C.indent() << "for (int $ct = 0; $ct < " << ECAT->getSize() << "; " "$ct++)"; C.startBlock(); std::string ElementVarName(VarName); ElementVarName.append("[$ct]"); genAllocateVarOfType(C, ElementType, ElementVarName); C.endBlock(); } break; } case RSExportType::ExportClassVector: case RSExportType::ExportClassMatrix: case RSExportType::ExportClassRecord: { C.indent() << VarName << " = new " << GetTypeName(T) << "();" << std::endl; break; } } return; } void RSReflection::genNewItemBufferIfNull(Context &C, const char *Index) { C.indent() << "if (" RS_TYPE_ITEM_BUFFER_NAME " == null) " RS_TYPE_ITEM_BUFFER_NAME " = " "new " RS_TYPE_ITEM_CLASS_NAME "[getType().getX() /* count */];" << std::endl; if (Index != NULL) C.indent() << "if ("RS_TYPE_ITEM_BUFFER_NAME"[" << Index << "] == null) " RS_TYPE_ITEM_BUFFER_NAME"[" << Index << "] = " "new "RS_TYPE_ITEM_CLASS_NAME"();" << std::endl; return; } void RSReflection::genNewItemBufferPackerIfNull(Context &C) { C.indent() << "if (" RS_TYPE_ITEM_BUFFER_PACKER_NAME " == null) " RS_TYPE_ITEM_BUFFER_PACKER_NAME " = " "new FieldPacker(" RS_TYPE_ITEM_CLASS_NAME ".sizeof * getType().getX()/* count */" ");" << std::endl; return; } /********************** Methods to generate type class **********************/ bool RSReflection::genTypeClass(Context &C, const RSExportRecordType *ERT, std::string &ErrorMsg) { std::string ClassName = ERT->getElementName(); if (!C.startClass(Context::AM_Public, false, ClassName, RS_TYPE_CLASS_SUPER_CLASS_NAME, ErrorMsg)) return false; mGeneratedFileNames->push_back(ClassName); genTypeItemClass(C, ERT); // Declare item buffer and item buffer packer C.indent() << "private "RS_TYPE_ITEM_CLASS_NAME" "RS_TYPE_ITEM_BUFFER_NAME"[]" ";" << std::endl; C.indent() << "private FieldPacker "RS_TYPE_ITEM_BUFFER_PACKER_NAME";" << std::endl; C.indent() << "private static java.lang.ref.WeakReference<Element> " RS_TYPE_ELEMENT_REF_NAME " = new java.lang.ref.WeakReference<Element>(null);" << std::endl; genTypeClassConstructor(C, ERT); genTypeClassCopyToArrayLocal(C, ERT); genTypeClassCopyToArray(C, ERT); genTypeClassItemSetter(C, ERT); genTypeClassItemGetter(C, ERT); genTypeClassComponentSetter(C, ERT); genTypeClassComponentGetter(C, ERT); genTypeClassCopyAll(C, ERT); genTypeClassResize(C); C.endClass(); C.resetFieldIndex(); C.clearFieldIndexMap(); return true; } void RSReflection::genTypeItemClass(Context &C, const RSExportRecordType *ERT) { C.indent() << "static public class "RS_TYPE_ITEM_CLASS_NAME; C.startBlock(); C.indent() << "public static final int sizeof = " << RSExportType::GetTypeAllocSize(ERT) << ";" << std::endl; // Member elements C.out() << std::endl; for (RSExportRecordType::const_field_iterator FI = ERT->fields_begin(), FE = ERT->fields_end(); FI != FE; FI++) { C.indent() << GetTypeName((*FI)->getType()) << " " << (*FI)->getName() << ";" << std::endl; } // Constructor C.out() << std::endl; C.indent() << RS_TYPE_ITEM_CLASS_NAME"()"; C.startBlock(); for (RSExportRecordType::const_field_iterator FI = ERT->fields_begin(), FE = ERT->fields_end(); FI != FE; FI++) { const RSExportRecordType::Field *F = *FI; genAllocateVarOfType(C, F->getType(), F->getName()); } // end Constructor C.endBlock(); // end Item class C.endBlock(); return; } void RSReflection::genTypeClassConstructor(Context &C, const RSExportRecordType *ERT) { const char *RenderScriptVar = "rs"; C.startFunction(Context::AM_Public, true, "Element", "createElement", 1, "RenderScript", RenderScriptVar); // TODO(all): Fix weak-refs + multi-context issue. // C.indent() << "Element e = " << RS_TYPE_ELEMENT_REF_NAME // << ".get();" << std::endl; // C.indent() << "if (e != null) return e;" << std::endl; genBuildElement(C, "eb", ERT, RenderScriptVar, /* IsInline = */true); C.indent() << "return eb.create();" << std::endl; // C.indent() << "e = eb.create();" << std::endl; // C.indent() << RS_TYPE_ELEMENT_REF_NAME // << " = new java.lang.ref.WeakReference<Element>(e);" // << std::endl; // C.indent() << "return e;" << std::endl; C.endFunction(); // private with element C.startFunction(Context::AM_Private, false, NULL, C.getClassName(), 1, "RenderScript", RenderScriptVar); C.indent() << RS_TYPE_ITEM_BUFFER_NAME" = null;" << std::endl; C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME" = null;" << std::endl; C.indent() << "mElement = createElement(" << RenderScriptVar << ");" << std::endl; C.endFunction(); // 1D without usage C.startFunction(Context::AM_Public, false, NULL, C.getClassName(), 2, "RenderScript", RenderScriptVar, "int", "count"); C.indent() << RS_TYPE_ITEM_BUFFER_NAME" = null;" << std::endl; C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME" = null;" << std::endl; C.indent() << "mElement = createElement(" << RenderScriptVar << ");" << std::endl; // Call init() in super class C.indent() << "init(" << RenderScriptVar << ", count);" << std::endl; C.endFunction(); // 1D with usage C.startFunction(Context::AM_Public, false, NULL, C.getClassName(), 3, "RenderScript", RenderScriptVar, "int", "count", "int", "usages"); C.indent() << RS_TYPE_ITEM_BUFFER_NAME" = null;" << std::endl; C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME" = null;" << std::endl; C.indent() << "mElement = createElement(" << RenderScriptVar << ");" << std::endl; // Call init() in super class C.indent() << "init(" << RenderScriptVar << ", count, usages);" << std::endl; C.endFunction(); // create1D with usage C.startFunction(Context::AM_Public, true, C.getClassName().c_str(), "create1D", 3, "RenderScript", RenderScriptVar, "int", "dimX", "int", "usages"); C.indent() << C.getClassName() << " obj = new " << C.getClassName() << "(" << RenderScriptVar << ");" << std::endl; C.indent() << "obj.mAllocation = Allocation.createSized(" "rs, obj.mElement, dimX, usages);" << std::endl; C.indent() << "return obj;" << std::endl; C.endFunction(); // create1D without usage C.startFunction(Context::AM_Public, true, C.getClassName().c_str(), "create1D", 2, "RenderScript", RenderScriptVar, "int", "dimX"); C.indent() << "return create1D(" << RenderScriptVar << ", dimX, Allocation.USAGE_SCRIPT);" << std::endl; C.endFunction(); // create2D without usage C.startFunction(Context::AM_Public, true, C.getClassName().c_str(), "create2D", 3, "RenderScript", RenderScriptVar, "int", "dimX", "int", "dimY"); C.indent() << "return create2D(" << RenderScriptVar << ", dimX, dimY, Allocation.USAGE_SCRIPT);" << std::endl; C.endFunction(); // create2D with usage C.startFunction(Context::AM_Public, true, C.getClassName().c_str(), "create2D", 4, "RenderScript", RenderScriptVar, "int", "dimX", "int", "dimY", "int", "usages"); C.indent() << C.getClassName() << " obj = new " << C.getClassName() << "(" << RenderScriptVar << ");" << std::endl; C.indent() << "Type.Builder b = new Type.Builder(rs, obj.mElement);" << std::endl; C.indent() << "b.setX(dimX);" << std::endl; C.indent() << "b.setY(dimY);" << std::endl; C.indent() << "Type t = b.create();" << std::endl; C.indent() << "obj.mAllocation = Allocation.createTyped(rs, t, usages);" << std::endl; C.indent() << "return obj;" << std::endl; C.endFunction(); // createTypeBuilder C.startFunction(Context::AM_Public, true, "Type.Builder", "createTypeBuilder", 1, "RenderScript", RenderScriptVar); C.indent() << "Element e = createElement(" << RenderScriptVar << ");" << std::endl; C.indent() << "return new Type.Builder(rs, e);" << std::endl; C.endFunction(); // createCustom with usage C.startFunction(Context::AM_Public, true, C.getClassName().c_str(), "createCustom", 3, "RenderScript", RenderScriptVar, "Type.Builder", "tb", "int", "usages"); C.indent() << C.getClassName() << " obj = new " << C.getClassName() << "(" << RenderScriptVar << ");" << std::endl; C.indent() << "Type t = tb.create();" << std::endl; C.indent() << "if (t.getElement() != obj.mElement) {" << std::endl; C.indent() << " throw new RSIllegalArgumentException(" "\"Type.Builder did not match expected element type.\");" << std::endl; C.indent() << "}" << std::endl; C.indent() << "obj.mAllocation = Allocation.createTyped(rs, t, usages);" << std::endl; C.indent() << "return obj;" << std::endl; C.endFunction(); } void RSReflection::genTypeClassCopyToArray(Context &C, const RSExportRecordType *ERT) { C.startFunction(Context::AM_Private, false, "void", "copyToArray", 2, RS_TYPE_ITEM_CLASS_NAME, "i", "int", "index"); genNewItemBufferPackerIfNull(C); C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME ".reset(index * "RS_TYPE_ITEM_CLASS_NAME".sizeof);" << std::endl; C.indent() << "copyToArrayLocal(i, " RS_TYPE_ITEM_BUFFER_PACKER_NAME ");" << std::endl; C.endFunction(); return; } void RSReflection::genTypeClassCopyToArrayLocal(Context &C, const RSExportRecordType *ERT) { C.startFunction(Context::AM_Private, false, "void", "copyToArrayLocal", 2, RS_TYPE_ITEM_CLASS_NAME, "i", "FieldPacker", "fp"); genPackVarOfType(C, ERT, "i", "fp"); C.endFunction(); return; } void RSReflection::genTypeClassItemSetter(Context &C, const RSExportRecordType *ERT) { C.startFunction(Context::AM_PublicSynchronized, false, "void", "set", 3, RS_TYPE_ITEM_CLASS_NAME, "i", "int", "index", "boolean", "copyNow"); genNewItemBufferIfNull(C, NULL); C.indent() << RS_TYPE_ITEM_BUFFER_NAME"[index] = i;" << std::endl; C.indent() << "if (copyNow) "; C.startBlock(); C.indent() << "copyToArray(i, index);" << std::endl; C.indent() << "FieldPacker fp = new FieldPacker(" RS_TYPE_ITEM_CLASS_NAME ".sizeof);" << std::endl; C.indent() << "copyToArrayLocal(i, fp);" << std::endl; C.indent() << "mAllocation.setFromFieldPacker(index, fp);" << std::endl; // End of if (copyNow) C.endBlock(); C.endFunction(); return; } void RSReflection::genTypeClassItemGetter(Context &C, const RSExportRecordType *ERT) { C.startFunction(Context::AM_PublicSynchronized, false, RS_TYPE_ITEM_CLASS_NAME, "get", 1, "int", "index"); C.indent() << "if ("RS_TYPE_ITEM_BUFFER_NAME" == null) return null;" << std::endl; C.indent() << "return "RS_TYPE_ITEM_BUFFER_NAME"[index];" << std::endl; C.endFunction(); return; } void RSReflection::genTypeClassComponentSetter(Context &C, const RSExportRecordType *ERT) { for (RSExportRecordType::const_field_iterator FI = ERT->fields_begin(), FE = ERT->fields_end(); FI != FE; FI++) { const RSExportRecordType::Field *F = *FI; size_t FieldOffset = F->getOffsetInParent(); size_t FieldStoreSize = RSExportType::GetTypeStoreSize(F->getType()); unsigned FieldIndex = C.getFieldIndex(F); C.startFunction(Context::AM_PublicSynchronized, false, "void", "set_" + F->getName(), 3, "int", "index", GetTypeName(F->getType()).c_str(), "v", "boolean", "copyNow"); genNewItemBufferPackerIfNull(C); genNewItemBufferIfNull(C, "index"); C.indent() << RS_TYPE_ITEM_BUFFER_NAME"[index]." << F->getName() << " = v;" << std::endl; C.indent() << "if (copyNow) "; C.startBlock(); if (FieldOffset > 0) C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME ".reset(index * "RS_TYPE_ITEM_CLASS_NAME".sizeof + " << FieldOffset << ");" << std::endl; else C.indent() << RS_TYPE_ITEM_BUFFER_PACKER_NAME ".reset(index * "RS_TYPE_ITEM_CLASS_NAME".sizeof);" << std::endl; genPackVarOfType(C, F->getType(), "v", RS_TYPE_ITEM_BUFFER_PACKER_NAME); C.indent() << "FieldPacker fp = new FieldPacker(" << FieldStoreSize << ");" << std::endl; genPackVarOfType(C, F->getType(), "v", "fp"); C.indent() << "mAllocation.setFromFieldPacker(index, " << FieldIndex << ", fp);" << std::endl; // End of if (copyNow) C.endBlock(); C.endFunction(); } return; } void RSReflection::genTypeClassComponentGetter(Context &C, const RSExportRecordType *ERT) { for (RSExportRecordType::const_field_iterator FI = ERT->fields_begin(), FE = ERT->fields_end(); FI != FE; FI++) { const RSExportRecordType::Field *F = *FI; C.startFunction(Context::AM_PublicSynchronized, false, GetTypeName(F->getType()).c_str(), "get_" + F->getName(), 1, "int", "index"); C.indent() << "if ("RS_TYPE_ITEM_BUFFER_NAME" == null) return " << GetTypeNullValue(F->getType()) << ";" << std::endl; C.indent() << "return "RS_TYPE_ITEM_BUFFER_NAME"[index]." << F->getName() << ";" << std::endl; C.endFunction(); } return; } void RSReflection::genTypeClassCopyAll(Context &C, const RSExportRecordType *ERT) { C.startFunction(Context::AM_PublicSynchronized, false, "void", "copyAll", 0); C.indent() << "for (int ct = 0; ct < "RS_TYPE_ITEM_BUFFER_NAME".length; ct++)" " copyToArray("RS_TYPE_ITEM_BUFFER_NAME"[ct], ct);" << std::endl; C.indent() << "mAllocation.setFromFieldPacker(0, " RS_TYPE_ITEM_BUFFER_PACKER_NAME");" << std::endl; C.endFunction(); return; } void RSReflection::genTypeClassResize(Context &C) { C.startFunction(Context::AM_PublicSynchronized, false, "void", "resize", 1, "int", "newSize"); C.indent() << "if (mItemArray != null) "; C.startBlock(); C.indent() << "int oldSize = mItemArray.length;" << std::endl; C.indent() << "int copySize = Math.min(oldSize, newSize);" << std::endl; C.indent() << "if (newSize == oldSize) return;" << std::endl; C.indent() << "Item ni[] = new Item[newSize];" << std::endl; C.indent() << "System.arraycopy(mItemArray, 0, ni, 0, copySize);" << std::endl; C.indent() << "mItemArray = ni;" << std::endl; C.endBlock(); C.indent() << "mAllocation.resize(newSize);" << std::endl; C.indent() << "if (" RS_TYPE_ITEM_BUFFER_PACKER_NAME " != null) " RS_TYPE_ITEM_BUFFER_PACKER_NAME " = " "new FieldPacker(" RS_TYPE_ITEM_CLASS_NAME ".sizeof * getType().getX()/* count */" ");" << std::endl; C.endFunction(); return; } /******************** Methods to generate type class /end ********************/ /********** Methods to create Element in Java of given record type ***********/ void RSReflection::genBuildElement(Context &C, const char *ElementBuilderName, const RSExportRecordType *ERT, const char *RenderScriptVar, bool IsInline) { C.indent() << "Element.Builder " << ElementBuilderName << " = " "new Element.Builder(" << RenderScriptVar << ");" << std::endl; // eb.add(...) genAddElementToElementBuilder(C, ERT, "", ElementBuilderName, RenderScriptVar, /* ArraySize = */0); if (!IsInline) C.indent() << "return " << ElementBuilderName << ".create();" << std::endl; return; } #define EB_ADD(x) do { \ C.indent() << ElementBuilderName \ << ".add(" << x << ", \"" << VarName << "\""; \ if (ArraySize > 0) \ C.out() << ", " << ArraySize; \ C.out() << ");" << std::endl; \ C.incFieldIndex(); \ } while (false) void RSReflection::genAddElementToElementBuilder(Context &C, const RSExportType *ET, const std::string &VarName, const char *ElementBuilderName, const char *RenderScriptVar, unsigned ArraySize) { std::string ElementConstruct = GetBuiltinElementConstruct(ET); if (ElementConstruct != "") { EB_ADD(ElementConstruct << "(" << RenderScriptVar << ")"); } else { if ((ET->getClass() == RSExportType::ExportClassPrimitive) || (ET->getClass() == RSExportType::ExportClassVector)) { const RSExportPrimitiveType *EPT = static_cast<const RSExportPrimitiveType*>(ET); const char *DataTypeName = RSExportPrimitiveType::getRSReflectionType(EPT)->rs_type; int Size = (ET->getClass() == RSExportType::ExportClassVector) ? static_cast<const RSExportVectorType*>(ET)->getNumElement() : 1; if (EPT->getClass() == RSExportType::ExportClassPrimitive) { // Element.createUser() EB_ADD("Element.createUser(" << RenderScriptVar << ", Element.DataType." << DataTypeName << ")"); } else { slangAssert((ET->getClass() == RSExportType::ExportClassVector) && "Unexpected type."); EB_ADD("Element.createVector(" << RenderScriptVar << ", Element.DataType." << DataTypeName << ", " << Size << ")"); } #ifndef NDEBUG } else if (ET->getClass() == RSExportType::ExportClassPointer) { // Pointer type variable should be resolved in // GetBuiltinElementConstruct() slangAssert(false && "??"); } else if (ET->getClass() == RSExportType::ExportClassMatrix) { // Matrix type variable should be resolved // in GetBuiltinElementConstruct() slangAssert(false && "??"); #endif } else if (ET->getClass() == RSExportType::ExportClassConstantArray) { const RSExportConstantArrayType *ECAT = static_cast<const RSExportConstantArrayType *>(ET); const RSExportType *ElementType = ECAT->getElementType(); if (ElementType->getClass() != RSExportType::ExportClassRecord) { genAddElementToElementBuilder(C, ECAT->getElementType(), VarName, ElementBuilderName, RenderScriptVar, ECAT->getSize()); } else { std::string NewElementBuilderName(ElementBuilderName); NewElementBuilderName.append(1, '_'); genBuildElement(C, NewElementBuilderName.c_str(), static_cast<const RSExportRecordType*>(ElementType), RenderScriptVar, /* IsInline = */true); ArraySize = ECAT->getSize(); EB_ADD(NewElementBuilderName << ".create()"); } } else if (ET->getClass() == RSExportType::ExportClassRecord) { // Simalar to case of RSExportType::ExportClassRecord in genPackVarOfType. // // TODO(zonr): Generalize these two function such that there's no // duplicated codes. const RSExportRecordType *ERT = static_cast<const RSExportRecordType*>(ET); int Pos = 0; // relative pos from now on for (RSExportRecordType::const_field_iterator I = ERT->fields_begin(), E = ERT->fields_end(); I != E; I++) { const RSExportRecordType::Field *F = *I; std::string FieldName; int FieldOffset = F->getOffsetInParent(); int FieldStoreSize = RSExportType::GetTypeStoreSize(F->getType()); int FieldAllocSize = RSExportType::GetTypeAllocSize(F->getType()); if (!VarName.empty()) FieldName = VarName + "." + F->getName(); else FieldName = F->getName(); // Alignment genAddPaddingToElementBuiler(C, (FieldOffset - Pos), ElementBuilderName, RenderScriptVar); // eb.add(...) C.addFieldIndexMapping(F); if (F->getType()->getClass() != RSExportType::ExportClassRecord) { genAddElementToElementBuilder(C, F->getType(), FieldName, ElementBuilderName, RenderScriptVar, 0); } else { std::string NewElementBuilderName(ElementBuilderName); NewElementBuilderName.append(1, '_'); genBuildElement(C, NewElementBuilderName.c_str(), static_cast<const RSExportRecordType*>(F->getType()), RenderScriptVar, /* IsInline = */true); const std::string &VarName = FieldName; // Hack for EB_ADD macro EB_ADD(NewElementBuilderName << ".create()"); } if (mRSContext->getTargetAPI() < SLANG_ICS_TARGET_API) { // There is padding within the field type. This is only necessary // for HC-targeted APIs. genAddPaddingToElementBuiler(C, (FieldAllocSize - FieldStoreSize), ElementBuilderName, RenderScriptVar); } Pos = FieldOffset + FieldAllocSize; } // There maybe some padding after the struct size_t RecordAllocSize = RSExportType::GetTypeAllocSize(ERT); genAddPaddingToElementBuiler(C, RecordAllocSize - Pos, ElementBuilderName, RenderScriptVar); } else { slangAssert(false && "Unknown class of type"); } } } void RSReflection::genAddPaddingToElementBuiler(Context &C, int PaddingSize, const char *ElementBuilderName, const char *RenderScriptVar) { unsigned ArraySize = 0; // Hack the EB_ADD macro while (PaddingSize > 0) { const std::string &VarName = C.createPaddingField(); if (PaddingSize >= 4) { EB_ADD("Element.U32(" << RenderScriptVar << ")"); PaddingSize -= 4; } else if (PaddingSize >= 2) { EB_ADD("Element.U16(" << RenderScriptVar << ")"); PaddingSize -= 2; } else if (PaddingSize >= 1) { EB_ADD("Element.U8(" << RenderScriptVar << ")"); PaddingSize -= 1; } } return; } #undef EB_ADD /******** Methods to create Element in Java of given record type /end ********/ bool RSReflection::reflect(const std::string &OutputPathBase, const std::string &OutputPackageName, const std::string &RSPackageName, const std::string &InputFileName, const std::string &OutputBCFileName) { Context *C = NULL; std::string ResourceId = ""; std::string PaddingPrefix = ""; if (mRSContext->getTargetAPI() < SLANG_ICS_TARGET_API) { PaddingPrefix = "#padding_"; } else { PaddingPrefix = "#rs_padding_"; } if (!GetClassNameFromFileName(OutputBCFileName, ResourceId)) return false; if (ResourceId.empty()) ResourceId = "<Resource ID>"; if (OutputPackageName.empty() || OutputPackageName == "-") C = new Context(OutputPathBase, InputFileName, "<Package Name>", RSPackageName, ResourceId, PaddingPrefix, true); else C = new Context(OutputPathBase, InputFileName, OutputPackageName, RSPackageName, ResourceId, PaddingPrefix, false); if (C != NULL) { std::string ErrorMsg, ScriptClassName; // class ScriptC_<ScriptName> if (!GetClassNameFromFileName(InputFileName, ScriptClassName)) return false; if (ScriptClassName.empty()) ScriptClassName = "<Input Script Name>"; ScriptClassName.insert(0, RS_SCRIPT_CLASS_NAME_PREFIX); if (mRSContext->getLicenseNote() != NULL) { C->setLicenseNote(*(mRSContext->getLicenseNote())); } if (!genScriptClass(*C, ScriptClassName, ErrorMsg)) { std::cerr << "Failed to generate class " << ScriptClassName << " (" << ErrorMsg << ")" << std::endl; return false; } mGeneratedFileNames->push_back(ScriptClassName); // class ScriptField_<TypeName> for (RSContext::const_export_type_iterator TI = mRSContext->export_types_begin(), TE = mRSContext->export_types_end(); TI != TE; TI++) { const RSExportType *ET = TI->getValue(); if (ET->getClass() == RSExportType::ExportClassRecord) { const RSExportRecordType *ERT = static_cast<const RSExportRecordType*>(ET); if (!ERT->isArtificial() && !genTypeClass(*C, ERT, ErrorMsg)) { std::cerr << "Failed to generate type class for struct '" << ERT->getName() << "' (" << ErrorMsg << ")" << std::endl; return false; } } } } return true; } /************************** RSReflection::Context **************************/ const char *const RSReflection::Context::ApacheLicenseNote = "/*\n" " * Copyright (C) 2011-2012 The Android Open Source Project\n" " *\n" " * Licensed under the Apache License, Version 2.0 (the \"License\");\n" " * you may not use this file except in compliance with the License.\n" " * You may obtain a copy of the License at\n" " *\n" " * http://www.apache.org/licenses/LICENSE-2.0\n" " *\n" " * Unless required by applicable law or agreed to in writing, software\n" " * distributed under the License is distributed on an \"AS IS\" BASIS,\n" " * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or " "implied.\n" " * See the License for the specific language governing permissions and\n" " * limitations under the License.\n" " */\n" "\n"; bool RSReflection::Context::openClassFile(const std::string &ClassName, std::string &ErrorMsg) { if (!mUseStdout) { mOF.clear(); std::string Path = RSSlangReflectUtils::ComputePackagedPath(mOutputPathBase.c_str(), mPackageName.c_str()); if (!SlangUtils::CreateDirectoryWithParents(Path, &ErrorMsg)) return false; std::string ClassFile = Path + OS_PATH_SEPARATOR_STR + ClassName + ".java"; mOF.open(ClassFile.c_str()); if (!mOF.good()) { ErrorMsg = "failed to open file '" + ClassFile + "' for write"; return false; } } return true; } const char *RSReflection::Context::AccessModifierStr(AccessModifier AM) { switch (AM) { case AM_Public: return "public"; break; case AM_Protected: return "protected"; break; case AM_Private: return "private"; break; case AM_PublicSynchronized: return "public synchronized"; break; default: return ""; break; } } bool RSReflection::Context::startClass(AccessModifier AM, bool IsStatic, const std::string &ClassName, const char *SuperClassName, std::string &ErrorMsg) { if (mVerbose) std::cout << "Generating " << ClassName << ".java ..." << std::endl; // Open file for class if (!openClassFile(ClassName, ErrorMsg)) return false; // License out() << mLicenseNote; // Notice of generated file out() << "/*" << std::endl; out() << " * This file is auto-generated. DO NOT MODIFY!" << std::endl; out() << " * The source Renderscript file: " << mInputRSFile << std::endl; out() << " */" << std::endl; // Package if (!mPackageName.empty()) out() << "package " << mPackageName << ";" << std::endl; out() << std::endl; // Imports out() << "import " << mRSPackageName << ".*;" << std::endl; out() << "import android.content.res.Resources;" << std::endl; out() << std::endl; // All reflected classes should be annotated as hidden, so that they won't // be exposed in SDK. out() << "/**" << std::endl; out() << " * @hide" << std::endl; out() << " */" << std::endl; out() << AccessModifierStr(AM) << ((IsStatic) ? " static" : "") << " class " << ClassName; if (SuperClassName != NULL) out() << " extends " << SuperClassName; startBlock(); mClassName = ClassName; return true; } void RSReflection::Context::endClass() { endBlock(); if (!mUseStdout) mOF.close(); clear(); return; } void RSReflection::Context::startBlock(bool ShouldIndent) { if (ShouldIndent) indent() << "{" << std::endl; else out() << " {" << std::endl; incIndentLevel(); return; } void RSReflection::Context::endBlock() { decIndentLevel(); indent() << "}" << std::endl << std::endl; return; } void RSReflection::Context::startTypeClass(const std::string &ClassName) { indent() << "public static class " << ClassName; startBlock(); return; } void RSReflection::Context::endTypeClass() { endBlock(); return; } void RSReflection::Context::startFunction(AccessModifier AM, bool IsStatic, const char *ReturnType, const std::string &FunctionName, int Argc, ...) { ArgTy Args; va_list vl; va_start(vl, Argc); for (int i = 0; i < Argc; i++) { const char *ArgType = va_arg(vl, const char*); const char *ArgName = va_arg(vl, const char*); Args.push_back(std::make_pair(ArgType, ArgName)); } va_end(vl); startFunction(AM, IsStatic, ReturnType, FunctionName, Args); return; } void RSReflection::Context::startFunction(AccessModifier AM, bool IsStatic, const char *ReturnType, const std::string &FunctionName, const ArgTy &Args) { indent() << AccessModifierStr(AM) << ((IsStatic) ? " static " : " ") << ((ReturnType) ? ReturnType : "") << " " << FunctionName << "("; bool FirstArg = true; for (ArgTy::const_iterator I = Args.begin(), E = Args.end(); I != E; I++) { if (!FirstArg) out() << ", "; else FirstArg = false; out() << I->first << " " << I->second; } out() << ")"; startBlock(); return; } void RSReflection::Context::endFunction() { endBlock(); return; } bool RSReflection::Context::addTypeNameForElement( const std::string &TypeName) { if (mTypesToCheck.find(TypeName) == mTypesToCheck.end()) { mTypesToCheck.insert(TypeName); return true; } else { return false; } } bool RSReflection::Context::addTypeNameForFieldPacker( const std::string &TypeName) { if (mFieldPackerTypes.find(TypeName) == mFieldPackerTypes.end()) { mFieldPackerTypes.insert(TypeName); return true; } else { return false; } } } // namespace slang