/* * 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. */ #ifndef ART_RUNTIME_ARCH_INSTRUCTION_SET_H_ #define ART_RUNTIME_ARCH_INSTRUCTION_SET_H_ #include #include #include "base/logging.h" // Logging is required for FATAL in the helper functions. namespace art { enum InstructionSet { kNone, kArm, kArm64, kThumb2, kX86, kX86_64, kMips, kMips64 }; std::ostream& operator<<(std::ostream& os, const InstructionSet& rhs); #if defined(__arm__) static constexpr InstructionSet kRuntimeISA = kArm; #elif defined(__aarch64__) static constexpr InstructionSet kRuntimeISA = kArm64; #elif defined(__mips__) && !defined(__LP64__) static constexpr InstructionSet kRuntimeISA = kMips; #elif defined(__mips__) && defined(__LP64__) static constexpr InstructionSet kRuntimeISA = kMips64; #elif defined(__i386__) static constexpr InstructionSet kRuntimeISA = kX86; #elif defined(__x86_64__) static constexpr InstructionSet kRuntimeISA = kX86_64; #else static constexpr InstructionSet kRuntimeISA = kNone; #endif // Architecture-specific pointer sizes static constexpr size_t kArmPointerSize = 4; static constexpr size_t kArm64PointerSize = 8; static constexpr size_t kMipsPointerSize = 4; static constexpr size_t kMips64PointerSize = 8; static constexpr size_t kX86PointerSize = 4; static constexpr size_t kX86_64PointerSize = 8; // ARM instruction alignment. ARM processors require code to be 4-byte aligned, // but ARM ELF requires 8.. static constexpr size_t kArmAlignment = 8; // ARM64 instruction alignment. This is the recommended alignment for maximum performance. static constexpr size_t kArm64Alignment = 16; // MIPS instruction alignment. MIPS processors require code to be 4-byte aligned. // TODO: Can this be 4? static constexpr size_t kMipsAlignment = 8; // X86 instruction alignment. This is the recommended alignment for maximum performance. static constexpr size_t kX86Alignment = 16; const char* GetInstructionSetString(InstructionSet isa); // Note: Returns kNone when the string cannot be parsed to a known value. InstructionSet GetInstructionSetFromString(const char* instruction_set); InstructionSet GetInstructionSetFromELF(uint16_t e_machine, uint32_t e_flags); static inline size_t GetInstructionSetPointerSize(InstructionSet isa) { switch (isa) { case kArm: // Fall-through. case kThumb2: return kArmPointerSize; case kArm64: return kArm64PointerSize; case kX86: return kX86PointerSize; case kX86_64: return kX86_64PointerSize; case kMips: return kMipsPointerSize; case kMips64: return kMips64PointerSize; case kNone: LOG(FATAL) << "ISA kNone does not have pointer size."; UNREACHABLE(); default: LOG(FATAL) << "Unknown ISA " << isa; UNREACHABLE(); } } static inline bool IsValidInstructionSet(InstructionSet isa) { switch (isa) { case kArm: case kThumb2: case kArm64: case kX86: case kX86_64: case kMips: case kMips64: return true; case kNone: default: return false; } } size_t GetInstructionSetAlignment(InstructionSet isa); static inline bool Is64BitInstructionSet(InstructionSet isa) { switch (isa) { case kArm: case kThumb2: case kX86: case kMips: return false; case kArm64: case kX86_64: case kMips64: return true; case kNone: LOG(FATAL) << "ISA kNone does not have bit width."; UNREACHABLE(); default: LOG(FATAL) << "Unknown ISA " << isa; UNREACHABLE(); } } static inline size_t InstructionSetPointerSize(InstructionSet isa) { return Is64BitInstructionSet(isa) ? 8U : 4U; } static inline size_t GetBytesPerGprSpillLocation(InstructionSet isa) { switch (isa) { case kArm: // Fall-through. case kThumb2: return 4; case kArm64: return 8; case kX86: return 4; case kX86_64: return 8; case kMips: return 4; case kMips64: return 8; case kNone: LOG(FATAL) << "ISA kNone does not have spills."; UNREACHABLE(); default: LOG(FATAL) << "Unknown ISA " << isa; UNREACHABLE(); } } static inline size_t GetBytesPerFprSpillLocation(InstructionSet isa) { switch (isa) { case kArm: // Fall-through. case kThumb2: return 4; case kArm64: return 8; case kX86: return 8; case kX86_64: return 8; case kMips: return 4; case kMips64: return 8; case kNone: LOG(FATAL) << "ISA kNone does not have spills."; UNREACHABLE(); default: LOG(FATAL) << "Unknown ISA " << isa; UNREACHABLE(); } } size_t GetStackOverflowReservedBytes(InstructionSet isa); // The following definitions create return types for two word-sized entities that will be passed // in registers so that memory operations for the interface trampolines can be avoided. The entities // are the resolved method and the pointer to the code to be invoked. // // On x86, ARM32 and MIPS, this is given for a *scalar* 64bit value. The definition thus *must* be // uint64_t or long long int. // // On x86_64, ARM64 and MIPS64, structs are decomposed for allocation, so we can create a structs of // two size_t-sized values. // // We need two operations: // // 1) A flag value that signals failure. The assembly stubs expect the lower part to be "0". // GetTwoWordFailureValue() will return a value that has lower part == 0. // // 2) A value that combines two word-sized values. // GetTwoWordSuccessValue() constructs this. // // IMPORTANT: If you use this to transfer object pointers, it is your responsibility to ensure // that the object does not move or the value is updated. Simple use of this is NOT SAFE // when the garbage collector can move objects concurrently. Ensure that required locks // are held when using! #if defined(__i386__) || defined(__arm__) || (defined(__mips__) && !defined(__LP64__)) typedef uint64_t TwoWordReturn; // Encodes method_ptr==nullptr and code_ptr==nullptr static inline constexpr TwoWordReturn GetTwoWordFailureValue() { return 0; } // Use the lower 32b for the method pointer and the upper 32b for the code pointer. static inline TwoWordReturn GetTwoWordSuccessValue(uintptr_t hi, uintptr_t lo) { static_assert(sizeof(uint32_t) == sizeof(uintptr_t), "Unexpected size difference"); uint32_t lo32 = lo; uint64_t hi64 = static_cast(hi); return ((hi64 << 32) | lo32); } #elif defined(__x86_64__) || defined(__aarch64__) || (defined(__mips__) && defined(__LP64__)) struct TwoWordReturn { uintptr_t lo; uintptr_t hi; }; // Encodes method_ptr==nullptr. Leaves random value in code pointer. static inline TwoWordReturn GetTwoWordFailureValue() { TwoWordReturn ret; ret.lo = 0; return ret; } // Write values into their respective members. static inline TwoWordReturn GetTwoWordSuccessValue(uintptr_t hi, uintptr_t lo) { TwoWordReturn ret; ret.lo = lo; ret.hi = hi; return ret; } #else #error "Unsupported architecture" #endif } // namespace art #endif // ART_RUNTIME_ARCH_INSTRUCTION_SET_H_