/* * Copyright (C) 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 "stub_compiler.h" #include "compilation_unit.h" #include "compiled_method.h" #include "compiler.h" #include "compiler_llvm.h" #include "ir_builder.h" #include "logging.h" #include "object.h" #include "runtime_support_func.h" #include "utils_llvm.h" #include #include #include #include #include #include namespace art { namespace compiler_llvm { using namespace runtime_support; StubCompiler::StubCompiler(CompilationUnit* cunit, Compiler& compiler) : cunit_(cunit), compiler_(&compiler), module_(cunit_->GetModule()), context_(cunit_->GetLLVMContext()), irb_(*cunit_->GetIRBuilder()) { } CompiledInvokeStub* StubCompiler::CreateInvokeStub(bool is_static, char const* shorty) { uint16_t elf_func_idx = cunit_->AcquireUniqueElfFuncIndex(); CHECK(shorty != NULL); size_t shorty_size = strlen(shorty); // Function name std::string func_name(ElfFuncName(elf_func_idx)); // Get argument types llvm::Type* arg_types[] = { irb_.getJObjectTy(), // Method object pointer irb_.getJObjectTy(), // "this" object pointer (NULL for static) irb_.getJObjectTy(), // Thread object pointer irb_.getJValueTy()->getPointerTo(), irb_.getJValueTy()->getPointerTo(), }; // Function type llvm::FunctionType* func_type = llvm::FunctionType::get(irb_.getVoidTy(), arg_types, false); // Create function llvm::Function* func = llvm::Function::Create(func_type, llvm::Function::ExternalLinkage, func_name, module_); // Create basic block for the body of this function llvm::BasicBlock* block_body = llvm::BasicBlock::Create(*context_, "upcall", func); irb_.SetInsertPoint(block_body); // Actual arguments llvm::Function::arg_iterator arg_iter = func->arg_begin(); llvm::Value* method_object_addr = arg_iter++; llvm::Value* callee_this_addr = arg_iter++; llvm::Value* thread_object_addr = arg_iter++; llvm::Value* actual_args_array_addr = arg_iter++; llvm::Value* retval_addr = arg_iter++; // Setup thread pointer llvm::Value* old_thread_register = irb_.Runtime().EmitSetCurrentThread(thread_object_addr); // Accurate function type llvm::Type* accurate_ret_type = irb_.getJType(shorty[0], kAccurate); std::vector accurate_arg_types; accurate_arg_types.push_back(irb_.getJObjectTy()); // method object pointer if (!is_static) { accurate_arg_types.push_back(irb_.getJObjectTy()); } for (size_t i = 1; i < shorty_size; ++i) { accurate_arg_types.push_back(irb_.getJType(shorty[i], kAccurate)); } llvm::FunctionType* accurate_func_type = llvm::FunctionType::get(accurate_ret_type, accurate_arg_types, false); // Load actual arguments std::vector args; args.push_back(method_object_addr); if (!is_static) { args.push_back(callee_this_addr); } for (size_t i = 1; i < shorty_size; ++i) { char arg_shorty = shorty[i]; if (arg_shorty == 'Z' || arg_shorty == 'B' || arg_shorty == 'C' || arg_shorty == 'S' || arg_shorty == 'I' || arg_shorty == 'J' || arg_shorty == 'F' || arg_shorty == 'D' || arg_shorty == 'L') { llvm::Type* arg_type = irb_.getJType(shorty[i], kAccurate)->getPointerTo(); llvm::Value* arg_jvalue_addr = irb_.CreateConstGEP1_32(actual_args_array_addr, i - 1); llvm::Value* arg_addr = irb_.CreateBitCast(arg_jvalue_addr, arg_type); args.push_back(irb_.CreateLoad(arg_addr, kTBAAStackTemp)); } else { LOG(FATAL) << "Unexpected arg shorty for invoke stub: " << shorty[i]; } } // Invoke managed method now! // TODO: If we solve the trampoline related problems, we can just get the code address and call. #if 0 llvm::Value* code_field_offset_value = irb_.getPtrEquivInt(Method::GetCodeOffset().Int32Value()); llvm::Value* code_field_addr = irb_.CreatePtrDisp(method_object_addr, code_field_offset_value, accurate_func_type->getPointerTo()->getPointerTo()); llvm::Value* code_addr = irb_.CreateLoad(code_field_addr, kTBAAJRuntime); #else llvm::Value* result = irb_.CreateCall(irb_.GetRuntime(FixStub), method_object_addr); llvm::Value* code_addr = irb_.CreatePointerCast(result, accurate_func_type->getPointerTo()); // Exception unwind. llvm::Value* exception_pending = irb_.Runtime().EmitIsExceptionPending(); llvm::BasicBlock* block_unwind = llvm::BasicBlock::Create(*context_, "exception_unwind", func); llvm::BasicBlock* block_cont = llvm::BasicBlock::Create(*context_, "cont", func); irb_.CreateCondBr(exception_pending, block_unwind, block_cont); irb_.SetInsertPoint(block_unwind); // Restore thread register irb_.Runtime().EmitSetCurrentThread(old_thread_register); irb_.CreateRetVoid(); irb_.SetInsertPoint(block_cont); #endif llvm::Value* retval = irb_.CreateCall(code_addr, args); // Store the returned value if (shorty[0] != 'V') { llvm::Value* ret_addr = irb_.CreateBitCast(retval_addr, accurate_ret_type->getPointerTo()); irb_.CreateStore(retval, ret_addr, kTBAAStackTemp); } // Restore thread register irb_.Runtime().EmitSetCurrentThread(old_thread_register); irb_.CreateRetVoid(); // Verify the generated function VERIFY_LLVM_FUNCTION(*func); // Add the memory usage approximation of the compilation unit cunit_->AddMemUsageApproximation((shorty_size * 3 + 8) * 50); // NOTE: We will emit 3 LLVM instructions per shorty for the argument, // plus 3 for pointer arithmetic, and 5 for code_addr, retval, ret_addr, // store ret_addr, and ret_void. Beside, we guess that we have to use // 50 bytes to represent one LLVM instruction. return new CompiledInvokeStub(cunit_->GetElfIndex(), elf_func_idx); } CompiledInvokeStub* StubCompiler::CreateProxyStub(char const* shorty) { CHECK(shorty != NULL); size_t shorty_size = strlen(shorty); uint16_t elf_func_idx = cunit_->AcquireUniqueElfFuncIndex(); // Function name std::string func_name(ElfFuncName(elf_func_idx)); // Accurate function type llvm::Type* accurate_ret_type = irb_.getJType(shorty[0], kAccurate); std::vector accurate_arg_types; accurate_arg_types.push_back(irb_.getJObjectTy()); // method accurate_arg_types.push_back(irb_.getJObjectTy()); // this for (size_t i = 1; i < shorty_size; ++i) { accurate_arg_types.push_back(irb_.getJType(shorty[i], kAccurate)); } llvm::FunctionType* accurate_func_type = llvm::FunctionType::get(accurate_ret_type, accurate_arg_types, false); // Create function llvm::Function* func = llvm::Function::Create(accurate_func_type, llvm::Function::ExternalLinkage, func_name, module_); // Create basic block for the body of this function llvm::BasicBlock* block_body = llvm::BasicBlock::Create(*context_, "proxy", func); irb_.SetInsertPoint(block_body); // JValue for proxy return llvm::AllocaInst* jvalue_temp = irb_.CreateAlloca(irb_.getJValueTy()); // Load actual arguments llvm::Function::arg_iterator arg_iter = func->arg_begin(); std::vector args; args.push_back(arg_iter++); // method args.push_back(arg_iter++); // this args.push_back(irb_.Runtime().EmitGetCurrentThread()); // thread for (size_t i = 1; i < shorty_size; ++i) { args.push_back(arg_iter++); } if (shorty[0] != 'V') { args.push_back(jvalue_temp); } // Call ProxyInvokeHandler // TODO: Partial inline ProxyInvokeHandler, don't use VarArg. irb_.CreateCall(irb_.GetRuntime(ProxyInvokeHandler), args); if (shorty[0] != 'V') { llvm::Value* result_addr = irb_.CreateBitCast(jvalue_temp, accurate_ret_type->getPointerTo()); llvm::Value* retval = irb_.CreateLoad(result_addr, kTBAAStackTemp); irb_.CreateRet(retval); } else { irb_.CreateRetVoid(); } // Verify the generated function VERIFY_LLVM_FUNCTION(*func); // Add the memory usage approximation of the compilation unit cunit_->AddMemUsageApproximation((shorty_size + 2) * 50); return new CompiledInvokeStub(cunit_->GetElfIndex(), elf_func_idx); } } // namespace compiler_llvm } // namespace art