// Copyright 2018 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef V8_CODEGEN_MIPS64_REGISTER_MIPS64_H_ #define V8_CODEGEN_MIPS64_REGISTER_MIPS64_H_ #include "src/codegen/mips64/constants-mips64.h" #include "src/codegen/register-base.h" namespace v8 { namespace internal { // clang-format off #define GENERAL_REGISTERS(V) \ V(zero_reg) V(at) V(v0) V(v1) V(a0) V(a1) V(a2) V(a3) \ V(a4) V(a5) V(a6) V(a7) V(t0) V(t1) V(t2) V(t3) \ V(s0) V(s1) V(s2) V(s3) V(s4) V(s5) V(s6) V(s7) V(t8) V(t9) \ V(k0) V(k1) V(gp) V(sp) V(fp) V(ra) #define ALLOCATABLE_GENERAL_REGISTERS(V) \ V(a0) V(a1) V(a2) V(a3) \ V(a4) V(a5) V(a6) V(a7) V(t0) V(t1) V(t2) V(t3) V(s7) \ V(v0) V(v1) #define DOUBLE_REGISTERS(V) \ V(f0) V(f1) V(f2) V(f3) V(f4) V(f5) V(f6) V(f7) \ V(f8) V(f9) V(f10) V(f11) V(f12) V(f13) V(f14) V(f15) \ V(f16) V(f17) V(f18) V(f19) V(f20) V(f21) V(f22) V(f23) \ V(f24) V(f25) V(f26) V(f27) V(f28) V(f29) V(f30) V(f31) // Currently, MIPS64 just use even float point register, except // for C function param registers. #define DOUBLE_USE_REGISTERS(V) \ V(f0) V(f2) V(f4) V(f6) V(f8) V(f10) V(f12) V(f13) \ V(f14) V(f15) V(f16) V(f17) V(f18) V(f19) V(f20) V(f22) \ V(f24) V(f26) V(f28) V(f30) #define FLOAT_REGISTERS DOUBLE_REGISTERS #define SIMD128_REGISTERS(V) \ V(w0) V(w1) V(w2) V(w3) V(w4) V(w5) V(w6) V(w7) \ V(w8) V(w9) V(w10) V(w11) V(w12) V(w13) V(w14) V(w15) \ V(w16) V(w17) V(w18) V(w19) V(w20) V(w21) V(w22) V(w23) \ V(w24) V(w25) V(w26) V(w27) V(w28) V(w29) V(w30) V(w31) #define ALLOCATABLE_DOUBLE_REGISTERS(V) \ V(f0) V(f2) V(f4) V(f6) V(f8) V(f10) V(f12) V(f14) \ V(f16) V(f18) V(f20) V(f22) V(f24) V(f26) // clang-format on // Note that the bit values must match those used in actual instruction // encoding. const int kNumRegs = 32; // CPU Registers. // // 1) We would prefer to use an enum, but enum values are assignment- // compatible with int, which has caused code-generation bugs. // // 2) We would prefer to use a class instead of a struct but we don't like // the register initialization to depend on the particular initialization // order (which appears to be different on OS X, Linux, and Windows for the // installed versions of C++ we tried). Using a struct permits C-style // "initialization". Also, the Register objects cannot be const as this // forces initialization stubs in MSVC, making us dependent on initialization // order. // // 3) By not using an enum, we are possibly preventing the compiler from // doing certain constant folds, which may significantly reduce the // code generated for some assembly instructions (because they boil down // to a few constants). If this is a problem, we could change the code // such that we use an enum in optimized mode, and the struct in debug // mode. This way we get the compile-time error checking in debug mode // and best performance in optimized code. // ----------------------------------------------------------------------------- // Implementation of Register and FPURegister. enum RegisterCode { #define REGISTER_CODE(R) kRegCode_##R, GENERAL_REGISTERS(REGISTER_CODE) #undef REGISTER_CODE kRegAfterLast }; class Register : public RegisterBase { public: #if defined(V8_TARGET_LITTLE_ENDIAN) static constexpr int kMantissaOffset = 0; static constexpr int kExponentOffset = 4; #elif defined(V8_TARGET_BIG_ENDIAN) static constexpr int kMantissaOffset = 4; static constexpr int kExponentOffset = 0; #else #error Unknown endianness #endif private: friend class RegisterBase; explicit constexpr Register(int code) : RegisterBase(code) {} }; // s7: context register // s3: scratch register // s4: scratch register 2 #define DECLARE_REGISTER(R) \ constexpr Register R = Register::from_code(kRegCode_##R); GENERAL_REGISTERS(DECLARE_REGISTER) #undef DECLARE_REGISTER constexpr Register no_reg = Register::no_reg(); int ToNumber(Register reg); Register ToRegister(int num); // Returns the number of padding slots needed for stack pointer alignment. constexpr int ArgumentPaddingSlots(int argument_count) { // No argument padding required. return 0; } constexpr AliasingKind kFPAliasing = AliasingKind::kOverlap; constexpr bool kSimdMaskRegisters = false; enum MSARegisterCode { #define REGISTER_CODE(R) kMsaCode_##R, SIMD128_REGISTERS(REGISTER_CODE) #undef REGISTER_CODE kMsaAfterLast }; // MIPS SIMD (MSA) register class MSARegister : public RegisterBase { friend class RegisterBase; explicit constexpr MSARegister(int code) : RegisterBase(code) {} }; enum DoubleRegisterCode { #define REGISTER_CODE(R) kDoubleCode_##R, DOUBLE_REGISTERS(REGISTER_CODE) #undef REGISTER_CODE kDoubleAfterLast }; // Coprocessor register. class FPURegister : public RegisterBase { public: // TODO(plind): Warning, inconsistent numbering here. kNumFPURegisters refers // to number of 32-bit FPU regs, but kNumAllocatableRegisters refers to // number of Double regs (64-bit regs, or FPU-reg-pairs). FPURegister low() const { // TODO(plind): Create DCHECK for FR=0 mode. This usage suspect for FR=1. // Find low reg of a Double-reg pair, which is the reg itself. DCHECK_EQ(code() % 2, 0); // Specified Double reg must be even. return FPURegister::from_code(code()); } FPURegister high() const { // TODO(plind): Create DCHECK for FR=0 mode. This usage illegal in FR=1. // Find high reg of a Doubel-reg pair, which is reg + 1. DCHECK_EQ(code() % 2, 0); // Specified Double reg must be even. return FPURegister::from_code(code() + 1); } MSARegister toW() const { return MSARegister::from_code(code()); } private: friend class RegisterBase; explicit constexpr FPURegister(int code) : RegisterBase(code) {} }; // A few double registers are reserved: one as a scratch register and one to // hold 0.0. // f28: 0.0 // f30: scratch register. // V8 now supports the O32 ABI, and the FPU Registers are organized as 32 // 32-bit registers, f0 through f31. When used as 'double' they are used // in pairs, starting with the even numbered register. So a double operation // on f0 really uses f0 and f1. // (Modern mips hardware also supports 32 64-bit registers, via setting // (privileged) Status Register FR bit to 1. This is used by the N32 ABI, // but it is not in common use. Someday we will want to support this in v8.) // For O32 ABI, Floats and Doubles refer to same set of 32 32-bit registers. using FloatRegister = FPURegister; using DoubleRegister = FPURegister; #define DECLARE_DOUBLE_REGISTER(R) \ constexpr DoubleRegister R = DoubleRegister::from_code(kDoubleCode_##R); DOUBLE_REGISTERS(DECLARE_DOUBLE_REGISTER) #undef DECLARE_DOUBLE_REGISTER constexpr DoubleRegister no_dreg = DoubleRegister::no_reg(); // SIMD registers. using Simd128Register = MSARegister; #define DECLARE_SIMD128_REGISTER(R) \ constexpr Simd128Register R = Simd128Register::from_code(kMsaCode_##R); SIMD128_REGISTERS(DECLARE_SIMD128_REGISTER) #undef DECLARE_SIMD128_REGISTER const Simd128Register no_msareg = Simd128Register::no_reg(); // Register aliases. // cp is assumed to be a callee saved register. constexpr Register kRootRegister = s6; constexpr Register cp = s7; constexpr Register kScratchReg = s3; constexpr Register kScratchReg2 = s4; constexpr DoubleRegister kScratchDoubleReg = f30; // FPU zero reg is often used to hold 0.0, but it's not hardwired to 0.0. constexpr DoubleRegister kDoubleRegZero = f28; // Used on mips64r6 for compare operations. // We use the last non-callee saved odd register for N64 ABI constexpr DoubleRegister kDoubleCompareReg = f23; // MSA zero and scratch regs must have the same numbers as FPU zero and scratch // MSA zero reg is often used to hold 0, but it's not hardwired to 0. constexpr Simd128Register kSimd128RegZero = w28; constexpr Simd128Register kSimd128ScratchReg = w30; // FPU (coprocessor 1) control registers. // Currently only FCSR (#31) is implemented. struct FPUControlRegister { bool is_valid() const { return reg_code == kFCSRRegister; } bool is(FPUControlRegister creg) const { return reg_code == creg.reg_code; } int code() const { DCHECK(is_valid()); return reg_code; } int bit() const { DCHECK(is_valid()); return 1 << reg_code; } void setcode(int f) { reg_code = f; DCHECK(is_valid()); } // Unfortunately we can't make this private in a struct. int reg_code; }; constexpr FPUControlRegister no_fpucreg = {kInvalidFPUControlRegister}; constexpr FPUControlRegister FCSR = {kFCSRRegister}; // MSA control registers struct MSAControlRegister { bool is_valid() const { return (reg_code == kMSAIRRegister) || (reg_code == kMSACSRRegister); } bool is(MSAControlRegister creg) const { return reg_code == creg.reg_code; } int code() const { DCHECK(is_valid()); return reg_code; } int bit() const { DCHECK(is_valid()); return 1 << reg_code; } void setcode(int f) { reg_code = f; DCHECK(is_valid()); } // Unfortunately we can't make this private in a struct. int reg_code; }; constexpr MSAControlRegister no_msacreg = {kInvalidMSAControlRegister}; constexpr MSAControlRegister MSAIR = {kMSAIRRegister}; constexpr MSAControlRegister MSACSR = {kMSACSRRegister}; // Define {RegisterName} methods for the register types. DEFINE_REGISTER_NAMES(Register, GENERAL_REGISTERS) DEFINE_REGISTER_NAMES(FPURegister, DOUBLE_REGISTERS) DEFINE_REGISTER_NAMES(MSARegister, SIMD128_REGISTERS) // Give alias names to registers for calling conventions. constexpr Register kReturnRegister0 = v0; constexpr Register kReturnRegister1 = v1; constexpr Register kReturnRegister2 = a0; constexpr Register kJSFunctionRegister = a1; constexpr Register kContextRegister = s7; constexpr Register kAllocateSizeRegister = a0; constexpr Register kInterpreterAccumulatorRegister = v0; constexpr Register kInterpreterBytecodeOffsetRegister = t0; constexpr Register kInterpreterBytecodeArrayRegister = t1; constexpr Register kInterpreterDispatchTableRegister = t2; constexpr Register kJavaScriptCallArgCountRegister = a0; constexpr Register kJavaScriptCallCodeStartRegister = a2; constexpr Register kJavaScriptCallTargetRegister = kJSFunctionRegister; constexpr Register kJavaScriptCallNewTargetRegister = a3; constexpr Register kJavaScriptCallExtraArg1Register = a2; constexpr Register kOffHeapTrampolineRegister = at; constexpr Register kRuntimeCallFunctionRegister = a1; constexpr Register kRuntimeCallArgCountRegister = a0; constexpr Register kRuntimeCallArgvRegister = a2; constexpr Register kWasmInstanceRegister = a0; constexpr Register kWasmCompileLazyFuncIndexRegister = t0; constexpr DoubleRegister kFPReturnRegister0 = f0; } // namespace internal } // namespace v8 #endif // V8_CODEGEN_MIPS64_REGISTER_MIPS64_H_