/* * Copyright (C) 2011 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 "compiled_method.h" #include "driver/compiler_driver.h" namespace art { CompiledCode::CompiledCode(CompilerDriver* compiler_driver, InstructionSet instruction_set, const std::vector& quick_code) : compiler_driver_(compiler_driver), instruction_set_(instruction_set), portable_code_(nullptr), quick_code_(nullptr) { SetCode(&quick_code, nullptr); } CompiledCode::CompiledCode(CompilerDriver* compiler_driver, InstructionSet instruction_set, const std::string& elf_object, const std::string& symbol) : compiler_driver_(compiler_driver), instruction_set_(instruction_set), portable_code_(nullptr), quick_code_(nullptr), symbol_(symbol) { CHECK_NE(elf_object.size(), 0U); CHECK_NE(symbol.size(), 0U); std::vector temp_code(elf_object.size()); for (size_t i = 0; i < elf_object.size(); ++i) { temp_code[i] = elf_object[i]; } // TODO: we shouldn't just shove ELF objects in as "code" but // change to have different kinds of compiled methods. This is // being deferred until we work on hybrid execution or at least // until we work on batch compilation. SetCode(nullptr, &temp_code); } void CompiledCode::SetCode(const std::vector* quick_code, const std::vector* portable_code) { if (portable_code != nullptr) { CHECK(!portable_code->empty()); portable_code_ = compiler_driver_->DeduplicateCode(*portable_code); } if (quick_code != nullptr) { CHECK(!quick_code->empty()); quick_code_ = compiler_driver_->DeduplicateCode(*quick_code); } } bool CompiledCode::operator==(const CompiledCode& rhs) const { if (quick_code_ != nullptr) { if (rhs.quick_code_ == nullptr) { return false; } else if (quick_code_->size() != rhs.quick_code_->size()) { return false; } else { return std::equal(quick_code_->begin(), quick_code_->end(), rhs.quick_code_->begin()); } } else if (portable_code_ != nullptr) { if (rhs.portable_code_ == nullptr) { return false; } else if (portable_code_->size() != rhs.portable_code_->size()) { return false; } else { return std::equal(portable_code_->begin(), portable_code_->end(), rhs.portable_code_->begin()); } } return (rhs.quick_code_ == nullptr) && (rhs.portable_code_ == nullptr); } uint32_t CompiledCode::AlignCode(uint32_t offset) const { return AlignCode(offset, instruction_set_); } uint32_t CompiledCode::AlignCode(uint32_t offset, InstructionSet instruction_set) { switch (instruction_set) { case kArm: case kThumb2: return RoundUp(offset, kArmAlignment); case kArm64: return RoundUp(offset, kArm64Alignment); case kMips: return RoundUp(offset, kMipsAlignment); case kX86: // Fall-through. case kX86_64: return RoundUp(offset, kX86Alignment); default: LOG(FATAL) << "Unknown InstructionSet: " << instruction_set; return 0; } } size_t CompiledCode::CodeDelta() const { switch (instruction_set_) { case kArm: case kArm64: case kMips: case kX86: case kX86_64: return 0; case kThumb2: { // +1 to set the low-order bit so a BLX will switch to Thumb mode return 1; } default: LOG(FATAL) << "Unknown InstructionSet: " << instruction_set_; return 0; } } const void* CompiledCode::CodePointer(const void* code_pointer, InstructionSet instruction_set) { switch (instruction_set) { case kArm: case kArm64: case kMips: case kX86: case kX86_64: return code_pointer; case kThumb2: { uintptr_t address = reinterpret_cast(code_pointer); // Set the low-order bit so a BLX will switch to Thumb mode address |= 0x1; return reinterpret_cast(address); } default: LOG(FATAL) << "Unknown InstructionSet: " << instruction_set; return NULL; } } const std::string& CompiledCode::GetSymbol() const { CHECK_NE(0U, symbol_.size()); return symbol_; } const std::vector& CompiledCode::GetOatdataOffsetsToCompliledCodeOffset() const { CHECK_NE(0U, oatdata_offsets_to_compiled_code_offset_.size()) << symbol_; return oatdata_offsets_to_compiled_code_offset_; } void CompiledCode::AddOatdataOffsetToCompliledCodeOffset(uint32_t offset) { oatdata_offsets_to_compiled_code_offset_.push_back(offset); } CompiledMethod::CompiledMethod(CompilerDriver& driver, InstructionSet instruction_set, const std::vector& quick_code, const size_t frame_size_in_bytes, const uint32_t core_spill_mask, const uint32_t fp_spill_mask, const std::vector& mapping_table, const std::vector& vmap_table, const std::vector& native_gc_map, const std::vector* cfi_info) : CompiledCode(&driver, instruction_set, quick_code), frame_size_in_bytes_(frame_size_in_bytes), core_spill_mask_(core_spill_mask), fp_spill_mask_(fp_spill_mask), mapping_table_(driver.DeduplicateMappingTable(mapping_table)), vmap_table_(driver.DeduplicateVMapTable(vmap_table)), gc_map_(driver.DeduplicateGCMap(native_gc_map)), cfi_info_(driver.DeduplicateCFIInfo(cfi_info)) { } CompiledMethod::CompiledMethod(CompilerDriver& driver, InstructionSet instruction_set, const std::vector& code, const size_t frame_size_in_bytes, const uint32_t core_spill_mask, const uint32_t fp_spill_mask) : CompiledCode(&driver, instruction_set, code), frame_size_in_bytes_(frame_size_in_bytes), core_spill_mask_(core_spill_mask), fp_spill_mask_(fp_spill_mask), mapping_table_(driver.DeduplicateMappingTable(std::vector())), vmap_table_(driver.DeduplicateVMapTable(std::vector())), gc_map_(driver.DeduplicateGCMap(std::vector())), cfi_info_(nullptr) { } // Constructs a CompiledMethod for the Portable compiler. CompiledMethod::CompiledMethod(CompilerDriver& driver, InstructionSet instruction_set, const std::string& code, const std::vector& gc_map, const std::string& symbol) : CompiledCode(&driver, instruction_set, code, symbol), frame_size_in_bytes_(kStackAlignment), core_spill_mask_(0), fp_spill_mask_(0), gc_map_(driver.DeduplicateGCMap(gc_map)) { mapping_table_ = driver.DeduplicateMappingTable(std::vector()); vmap_table_ = driver.DeduplicateVMapTable(std::vector()); } CompiledMethod::CompiledMethod(CompilerDriver& driver, InstructionSet instruction_set, const std::string& code, const std::string& symbol) : CompiledCode(&driver, instruction_set, code, symbol), frame_size_in_bytes_(kStackAlignment), core_spill_mask_(0), fp_spill_mask_(0) { mapping_table_ = driver.DeduplicateMappingTable(std::vector()); vmap_table_ = driver.DeduplicateVMapTable(std::vector()); gc_map_ = driver.DeduplicateGCMap(std::vector()); } } // namespace art