/* * Copyright (C) 2011, 2013-2016 Apple Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifndef GPRInfo_h #define GPRInfo_h #include "MacroAssembler.h" #include #include namespace JSC { // We use the same conventions in the basline JIT as in the LLint. If you // change mappings in the GPRInfo, you should change them in the offlineasm // compiler adequately. The register naming conventions are described at the // top of the LowLevelInterpreter.asm file. typedef MacroAssembler::RegisterID GPRReg; #define InvalidGPRReg ((::JSC::GPRReg)-1) #if ENABLE(JIT) #if USE(JSVALUE64) class JSValueRegs { public: JSValueRegs() : m_gpr(InvalidGPRReg) { } explicit JSValueRegs(GPRReg gpr) : m_gpr(gpr) { } static JSValueRegs payloadOnly(GPRReg gpr) { return JSValueRegs(gpr); } static JSValueRegs withTwoAvailableRegs(GPRReg gpr, GPRReg) { return JSValueRegs(gpr); } bool operator!() const { return m_gpr == InvalidGPRReg; } explicit operator bool() const { return m_gpr != InvalidGPRReg; } bool operator==(JSValueRegs other) { return m_gpr == other.m_gpr; } bool operator!=(JSValueRegs other) { return !(*this == other); } GPRReg gpr() const { return m_gpr; } GPRReg tagGPR() const { return InvalidGPRReg; } GPRReg payloadGPR() const { return m_gpr; } bool uses(GPRReg gpr) const { return m_gpr == gpr; } void dump(PrintStream&) const; private: GPRReg m_gpr; }; class JSValueSource { public: JSValueSource() : m_offset(notAddress()) , m_base(InvalidGPRReg) { } JSValueSource(JSValueRegs regs) : m_offset(notAddress()) , m_base(regs.gpr()) { } explicit JSValueSource(GPRReg gpr) : m_offset(notAddress()) , m_base(gpr) { } JSValueSource(MacroAssembler::Address address) : m_offset(address.offset) , m_base(address.base) { ASSERT(m_offset != notAddress()); ASSERT(m_base != InvalidGPRReg); } static JSValueSource unboxedCell(GPRReg payloadGPR) { return JSValueSource(payloadGPR); } bool operator!() const { return m_base == InvalidGPRReg; } explicit operator bool() const { return m_base != InvalidGPRReg; } bool isAddress() const { return m_offset != notAddress(); } int32_t offset() const { ASSERT(isAddress()); return m_offset; } GPRReg base() const { ASSERT(isAddress()); return m_base; } GPRReg gpr() const { ASSERT(!isAddress()); return m_base; } JSValueRegs regs() const { return JSValueRegs(gpr()); } MacroAssembler::Address asAddress() const { return MacroAssembler::Address(base(), offset()); } private: static inline int32_t notAddress() { return 0x80000000; } int32_t m_offset; GPRReg m_base; }; #endif // USE(JSVALUE64) #if USE(JSVALUE32_64) class JSValueRegs { public: JSValueRegs() : m_tagGPR(static_cast(InvalidGPRReg)) , m_payloadGPR(static_cast(InvalidGPRReg)) { } JSValueRegs(GPRReg tagGPR, GPRReg payloadGPR) : m_tagGPR(tagGPR) , m_payloadGPR(payloadGPR) { } static JSValueRegs withTwoAvailableRegs(GPRReg gpr1, GPRReg gpr2) { return JSValueRegs(gpr1, gpr2); } static JSValueRegs payloadOnly(GPRReg gpr) { return JSValueRegs(InvalidGPRReg, gpr); } bool operator!() const { return !static_cast(*this); } explicit operator bool() const { return static_cast(m_tagGPR) != InvalidGPRReg || static_cast(m_payloadGPR) != InvalidGPRReg; } bool operator==(JSValueRegs other) const { return m_tagGPR == other.m_tagGPR && m_payloadGPR == other.m_payloadGPR; } bool operator!=(JSValueRegs other) const { return !(*this == other); } GPRReg tagGPR() const { return static_cast(m_tagGPR); } GPRReg payloadGPR() const { return static_cast(m_payloadGPR); } GPRReg gpr(WhichValueWord which) const { switch (which) { case TagWord: return tagGPR(); case PayloadWord: return payloadGPR(); } ASSERT_NOT_REACHED(); return tagGPR(); } bool uses(GPRReg gpr) const { return m_tagGPR == gpr || m_payloadGPR == gpr; } void dump(PrintStream&) const; private: int8_t m_tagGPR; int8_t m_payloadGPR; }; class JSValueSource { public: JSValueSource() : m_offset(notAddress()) , m_baseOrTag(static_cast(InvalidGPRReg)) , m_payload(static_cast(InvalidGPRReg)) , m_tagType(0) { } JSValueSource(JSValueRegs regs) : m_offset(notAddress()) , m_baseOrTag(regs.tagGPR()) , m_payload(regs.payloadGPR()) , m_tagType(0) { } JSValueSource(GPRReg tagGPR, GPRReg payloadGPR) : m_offset(notAddress()) , m_baseOrTag(static_cast(tagGPR)) , m_payload(static_cast(payloadGPR)) , m_tagType(0) { } JSValueSource(MacroAssembler::Address address) : m_offset(address.offset) , m_baseOrTag(static_cast(address.base)) , m_payload(static_cast(InvalidGPRReg)) , m_tagType(0) { ASSERT(m_offset != notAddress()); ASSERT(static_cast(m_baseOrTag) != InvalidGPRReg); } static JSValueSource unboxedCell(GPRReg payloadGPR) { JSValueSource result; result.m_offset = notAddress(); result.m_baseOrTag = static_cast(InvalidGPRReg); result.m_payload = static_cast(payloadGPR); result.m_tagType = static_cast(JSValue::CellTag); return result; } bool operator!() const { return !static_cast(*this); } explicit operator bool() const { return static_cast(m_baseOrTag) != InvalidGPRReg || static_cast(m_payload) != InvalidGPRReg; } bool isAddress() const { ASSERT(!!*this); return m_offset != notAddress(); } int32_t offset() const { ASSERT(isAddress()); return m_offset; } GPRReg base() const { ASSERT(isAddress()); return static_cast(m_baseOrTag); } GPRReg tagGPR() const { ASSERT(!isAddress() && static_cast(m_baseOrTag) != InvalidGPRReg); return static_cast(m_baseOrTag); } GPRReg payloadGPR() const { ASSERT(!isAddress()); return static_cast(m_payload); } bool hasKnownTag() const { ASSERT(!!*this); ASSERT(!isAddress()); return static_cast(m_baseOrTag) == InvalidGPRReg; } uint32_t tag() const { return static_cast(m_tagType); } JSValueRegs regs() const { return JSValueRegs(tagGPR(), payloadGPR()); } MacroAssembler::Address asAddress(unsigned additionalOffset = 0) const { return MacroAssembler::Address(base(), offset() + additionalOffset); } private: static inline int32_t notAddress() { return 0x80000000; } int32_t m_offset; int8_t m_baseOrTag; int8_t m_payload; int8_t m_tagType; // Contains the low bits of the tag. }; #endif // USE(JSVALUE32_64) #if CPU(X86) #define NUMBER_OF_ARGUMENT_REGISTERS 0u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 0u class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 6; static const unsigned numberOfArgumentRegisters = NUMBER_OF_ARGUMENT_REGISTERS; // Temporary registers. static const GPRReg regT0 = X86Registers::eax; static const GPRReg regT1 = X86Registers::edx; static const GPRReg regT2 = X86Registers::ecx; static const GPRReg regT3 = X86Registers::ebx; // Callee-save static const GPRReg regT4 = X86Registers::esi; // Callee-save static const GPRReg regT5 = X86Registers::edi; // Callee-save static const GPRReg callFrameRegister = X86Registers::ebp; // These constants provide the names for the general purpose argument & return value registers. static const GPRReg argumentGPR0 = X86Registers::ecx; // regT2 static const GPRReg argumentGPR1 = X86Registers::edx; // regT1 static const GPRReg argumentGPR2 = X86Registers::eax; // regT0 static const GPRReg argumentGPR3 = X86Registers::ebx; // regT3 static const GPRReg nonArgGPR0 = X86Registers::esi; // regT4 static const GPRReg returnValueGPR = X86Registers::eax; // regT0 static const GPRReg returnValueGPR2 = X86Registers::edx; // regT1 static const GPRReg nonPreservedNonReturnGPR = X86Registers::ecx; static GPRReg toRegister(unsigned index) { ASSERT(index < numberOfRegisters); static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5 }; return registerForIndex[index]; } static GPRReg toArgumentRegister(unsigned) { UNREACHABLE_FOR_PLATFORM(); return InvalidGPRReg; } static unsigned toIndex(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 8); static const unsigned indexForRegister[8] = { 0, 2, 1, 3, InvalidIndex, InvalidIndex, 4, 5 }; unsigned result = indexForRegister[reg]; return result; } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 8); static const char* nameForRegister[8] = { "eax", "ecx", "edx", "ebx", "esp", "ebp", "esi", "edi", }; return nameForRegister[reg]; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(X86) #if CPU(X86_64) #if !OS(WINDOWS) #define NUMBER_OF_ARGUMENT_REGISTERS 6u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 5u #else #define NUMBER_OF_ARGUMENT_REGISTERS 4u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 7u #endif class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 11; static const unsigned numberOfArgumentRegisters = NUMBER_OF_ARGUMENT_REGISTERS; // These registers match the baseline JIT. static const GPRReg callFrameRegister = X86Registers::ebp; static const GPRReg tagTypeNumberRegister = X86Registers::r14; static const GPRReg tagMaskRegister = X86Registers::r15; // Temporary registers. static const GPRReg regT0 = X86Registers::eax; #if !OS(WINDOWS) static const GPRReg regT1 = X86Registers::esi; static const GPRReg regT2 = X86Registers::edx; static const GPRReg regT3 = X86Registers::ecx; static const GPRReg regT4 = X86Registers::r8; static const GPRReg regT5 = X86Registers::r10; static const GPRReg regT6 = X86Registers::edi; static const GPRReg regT7 = X86Registers::r9; #else static const GPRReg regT1 = X86Registers::edx; static const GPRReg regT2 = X86Registers::r8; static const GPRReg regT3 = X86Registers::r9; static const GPRReg regT4 = X86Registers::r10; static const GPRReg regT5 = X86Registers::ecx; #endif static const GPRReg regCS0 = X86Registers::ebx; #if !OS(WINDOWS) static const GPRReg regCS1 = X86Registers::r12; static const GPRReg regCS2 = X86Registers::r13; static const GPRReg regCS3 = X86Registers::r14; static const GPRReg regCS4 = X86Registers::r15; #else static const GPRReg regCS1 = X86Registers::esi; static const GPRReg regCS2 = X86Registers::edi; static const GPRReg regCS3 = X86Registers::r12; static const GPRReg regCS4 = X86Registers::r13; static const GPRReg regCS5 = X86Registers::r14; static const GPRReg regCS6 = X86Registers::r15; #endif // These constants provide the names for the general purpose argument & return value registers. #if !OS(WINDOWS) static const GPRReg argumentGPR0 = X86Registers::edi; // regT6 static const GPRReg argumentGPR1 = X86Registers::esi; // regT1 static const GPRReg argumentGPR2 = X86Registers::edx; // regT2 static const GPRReg argumentGPR3 = X86Registers::ecx; // regT3 static const GPRReg argumentGPR4 = X86Registers::r8; // regT4 static const GPRReg argumentGPR5 = X86Registers::r9; // regT7 #else static const GPRReg argumentGPR0 = X86Registers::ecx; // regT5 static const GPRReg argumentGPR1 = X86Registers::edx; // regT1 static const GPRReg argumentGPR2 = X86Registers::r8; // regT2 static const GPRReg argumentGPR3 = X86Registers::r9; // regT3 #endif static const GPRReg nonArgGPR0 = X86Registers::r10; // regT5 (regT4 on Windows) static const GPRReg returnValueGPR = X86Registers::eax; // regT0 static const GPRReg returnValueGPR2 = X86Registers::edx; // regT1 or regT2 static const GPRReg nonPreservedNonReturnGPR = X86Registers::r10; // regT5 (regT4 on Windows) static const GPRReg nonPreservedNonArgumentGPR = X86Registers::r10; // regT5 (regT4 on Windows) // FIXME: I believe that all uses of this are dead in the sense that it just causes the scratch // register allocator to select a different register and potentially spill things. It would be better // if we instead had a more explicit way of saying that we don't have a scratch register. static const GPRReg patchpointScratchRegister; static GPRReg toRegister(unsigned index) { ASSERT(index < numberOfRegisters); #if !OS(WINDOWS) static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5, regT6, regT7, regCS0, regCS1, regCS2 }; #else static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5, regCS0, regCS1, regCS2, regCS3, regCS4 }; #endif return registerForIndex[index]; } static GPRReg toArgumentRegister(unsigned index) { ASSERT(index < numberOfArgumentRegisters); #if !OS(WINDOWS) static const GPRReg registerForIndex[numberOfArgumentRegisters] = { argumentGPR0, argumentGPR1, argumentGPR2, argumentGPR3, argumentGPR4, argumentGPR5 }; #else static const GPRReg registerForIndex[numberOfArgumentRegisters] = { argumentGPR0, argumentGPR1, argumentGPR2, argumentGPR3 }; #endif return registerForIndex[index]; } static unsigned toIndex(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 16); #if !OS(WINDOWS) static const unsigned indexForRegister[16] = { 0, 3, 2, 8, InvalidIndex, InvalidIndex, 1, 6, 4, 7, 5, InvalidIndex, 9, 10, InvalidIndex, InvalidIndex }; #else static const unsigned indexForRegister[16] = { 0, 5, 1, 6, InvalidIndex, InvalidIndex, 7, 8, 2, 3, 4, InvalidIndex, 9, 10, InvalidIndex, InvalidIndex }; #endif return indexForRegister[reg]; } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 16); static const char* nameForRegister[16] = { "rax", "rcx", "rdx", "rbx", "rsp", "rbp", "rsi", "rdi", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15" }; return nameForRegister[reg]; } static const std::array& reservedRegisters() { static const std::array reservedRegisters { { MacroAssembler::s_scratchRegister, tagTypeNumberRegister, tagMaskRegister, } }; return reservedRegisters; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(X86_64) #if CPU(ARM) #define NUMBER_OF_ARGUMENT_REGISTERS 4u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 0u class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 9; static const unsigned numberOfArgumentRegisters = NUMBER_OF_ARGUMENT_REGISTERS; // Temporary registers. static const GPRReg regT0 = ARMRegisters::r0; static const GPRReg regT1 = ARMRegisters::r1; static const GPRReg regT2 = ARMRegisters::r2; static const GPRReg regT3 = ARMRegisters::r3; static const GPRReg regT4 = ARMRegisters::r8; static const GPRReg regT5 = ARMRegisters::r9; static const GPRReg regT6 = ARMRegisters::r10; #if CPU(ARM_THUMB2) static const GPRReg regT7 = ARMRegisters::r11; #else static const GPRReg regT7 = ARMRegisters::r7; #endif static const GPRReg regT8 = ARMRegisters::r4; // These registers match the baseline JIT. static const GPRReg callFrameRegister = ARMRegisters::fp; // These constants provide the names for the general purpose argument & return value registers. static const GPRReg argumentGPR0 = ARMRegisters::r0; // regT0 static const GPRReg argumentGPR1 = ARMRegisters::r1; // regT1 static const GPRReg argumentGPR2 = ARMRegisters::r2; // regT2 static const GPRReg argumentGPR3 = ARMRegisters::r3; // regT3 static const GPRReg nonArgGPR0 = ARMRegisters::r4; // regT8 static const GPRReg nonArgGPR1 = ARMRegisters::r8; // regT4 static const GPRReg returnValueGPR = ARMRegisters::r0; // regT0 static const GPRReg returnValueGPR2 = ARMRegisters::r1; // regT1 static const GPRReg nonPreservedNonReturnGPR = ARMRegisters::r5; static GPRReg toRegister(unsigned index) { ASSERT(index < numberOfRegisters); static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5, regT6, regT7, regT8 }; return registerForIndex[index]; } static GPRReg toArgumentRegister(unsigned index) { ASSERT(index < numberOfArgumentRegisters); static const GPRReg registerForIndex[numberOfArgumentRegisters] = { argumentGPR0, argumentGPR1, argumentGPR2, argumentGPR3 }; return registerForIndex[index]; } static unsigned toIndex(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 16); static const unsigned indexForRegister[16] = #if CPU(ARM_THUMB2) { 0, 1, 2, 3, 8, InvalidIndex, InvalidIndex, InvalidIndex, 4, 5, 6, 7, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex }; #else { 0, 1, 2, 3, 8, InvalidIndex, InvalidIndex, 7, 4, 5, 6, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex }; #endif unsigned result = indexForRegister[reg]; return result; } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 16); static const char* nameForRegister[16] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15" }; return nameForRegister[reg]; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(ARM) #if CPU(ARM64) #define NUMBER_OF_ARGUMENT_REGISTERS 8u // Callee Saves includes x19..x28 and FP registers q8..q15 #define NUMBER_OF_CALLEE_SAVES_REGISTERS 18u class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 16; static const unsigned numberOfArgumentRegisters = 8; // These registers match the baseline JIT. static const GPRReg callFrameRegister = ARM64Registers::fp; static const GPRReg tagTypeNumberRegister = ARM64Registers::x27; static const GPRReg tagMaskRegister = ARM64Registers::x28; static const GPRReg dataTempRegister = MacroAssembler::dataTempRegister; static const GPRReg memoryTempRegister = MacroAssembler::memoryTempRegister; // Temporary registers. static const GPRReg regT0 = ARM64Registers::x0; static const GPRReg regT1 = ARM64Registers::x1; static const GPRReg regT2 = ARM64Registers::x2; static const GPRReg regT3 = ARM64Registers::x3; static const GPRReg regT4 = ARM64Registers::x4; static const GPRReg regT5 = ARM64Registers::x5; static const GPRReg regT6 = ARM64Registers::x6; static const GPRReg regT7 = ARM64Registers::x7; static const GPRReg regT8 = ARM64Registers::x8; static const GPRReg regT9 = ARM64Registers::x9; static const GPRReg regT10 = ARM64Registers::x10; static const GPRReg regT11 = ARM64Registers::x11; static const GPRReg regT12 = ARM64Registers::x12; static const GPRReg regT13 = ARM64Registers::x13; static const GPRReg regT14 = ARM64Registers::x14; static const GPRReg regT15 = ARM64Registers::x15; static const GPRReg regCS0 = ARM64Registers::x19; // Used by FTL only static const GPRReg regCS1 = ARM64Registers::x20; // Used by FTL only static const GPRReg regCS2 = ARM64Registers::x21; // Used by FTL only static const GPRReg regCS3 = ARM64Registers::x22; // Used by FTL only static const GPRReg regCS4 = ARM64Registers::x23; // Used by FTL only static const GPRReg regCS5 = ARM64Registers::x24; // Used by FTL only static const GPRReg regCS6 = ARM64Registers::x25; // Used by FTL only static const GPRReg regCS7 = ARM64Registers::x26; static const GPRReg regCS8 = ARM64Registers::x27; // tagTypeNumber static const GPRReg regCS9 = ARM64Registers::x28; // tagMask // These constants provide the names for the general purpose argument & return value registers. static const GPRReg argumentGPR0 = ARM64Registers::x0; // regT0 static const GPRReg argumentGPR1 = ARM64Registers::x1; // regT1 static const GPRReg argumentGPR2 = ARM64Registers::x2; // regT2 static const GPRReg argumentGPR3 = ARM64Registers::x3; // regT3 static const GPRReg argumentGPR4 = ARM64Registers::x4; // regT4 static const GPRReg argumentGPR5 = ARM64Registers::x5; // regT5 static const GPRReg argumentGPR6 = ARM64Registers::x6; // regT6 static const GPRReg argumentGPR7 = ARM64Registers::x7; // regT7 static const GPRReg nonArgGPR0 = ARM64Registers::x8; // regT8 static const GPRReg nonArgGPR1 = ARM64Registers::x9; // regT9 static const GPRReg returnValueGPR = ARM64Registers::x0; // regT0 static const GPRReg returnValueGPR2 = ARM64Registers::x1; // regT1 static const GPRReg nonPreservedNonReturnGPR = ARM64Registers::x2; static const GPRReg nonPreservedNonArgumentGPR = ARM64Registers::x8; static const GPRReg patchpointScratchRegister; // GPRReg mapping is direct, the machine register numbers can // be used directly as indices into the GPR RegisterBank. COMPILE_ASSERT(ARM64Registers::q0 == 0, q0_is_0); COMPILE_ASSERT(ARM64Registers::q1 == 1, q1_is_1); COMPILE_ASSERT(ARM64Registers::q2 == 2, q2_is_2); COMPILE_ASSERT(ARM64Registers::q3 == 3, q3_is_3); COMPILE_ASSERT(ARM64Registers::q4 == 4, q4_is_4); COMPILE_ASSERT(ARM64Registers::q5 == 5, q5_is_5); COMPILE_ASSERT(ARM64Registers::q6 == 6, q6_is_6); COMPILE_ASSERT(ARM64Registers::q7 == 7, q7_is_7); COMPILE_ASSERT(ARM64Registers::q8 == 8, q8_is_8); COMPILE_ASSERT(ARM64Registers::q9 == 9, q9_is_9); COMPILE_ASSERT(ARM64Registers::q10 == 10, q10_is_10); COMPILE_ASSERT(ARM64Registers::q11 == 11, q11_is_11); COMPILE_ASSERT(ARM64Registers::q12 == 12, q12_is_12); COMPILE_ASSERT(ARM64Registers::q13 == 13, q13_is_13); COMPILE_ASSERT(ARM64Registers::q14 == 14, q14_is_14); COMPILE_ASSERT(ARM64Registers::q15 == 15, q15_is_15); static GPRReg toRegister(unsigned index) { return (GPRReg)index; } static unsigned toIndex(GPRReg reg) { if (reg > regT15) return InvalidIndex; return (unsigned)reg; } static GPRReg toArgumentRegister(unsigned index) { ASSERT(index < numberOfArgumentRegisters); return toRegister(index); } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(static_cast(reg) < 32); static const char* nameForRegister[32] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23", "r24", "r25", "r26", "r27", "r28", "fp", "lr", "sp" }; return nameForRegister[reg]; } static const std::array& reservedRegisters() { static const std::array reservedRegisters { { dataTempRegister, memoryTempRegister, tagTypeNumberRegister, tagMaskRegister, } }; return reservedRegisters; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(ARM64) #if CPU(MIPS) #define NUMBER_OF_ARGUMENT_REGISTERS 4u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 0u class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 7; static const unsigned numberOfArgumentRegisters = NUMBER_OF_ARGUMENT_REGISTERS; // regT0 must be v0 for returning a 32-bit value. // regT1 must be v1 for returning a pair of 32-bit value. // Temporary registers. static const GPRReg regT0 = MIPSRegisters::v0; static const GPRReg regT1 = MIPSRegisters::v1; static const GPRReg regT2 = MIPSRegisters::t2; static const GPRReg regT3 = MIPSRegisters::t3; static const GPRReg regT4 = MIPSRegisters::t4; static const GPRReg regT5 = MIPSRegisters::t5; static const GPRReg regT6 = MIPSRegisters::t6; // These registers match the baseline JIT. static const GPRReg callFrameRegister = MIPSRegisters::fp; // These constants provide the names for the general purpose argument & return value registers. static const GPRReg argumentGPR0 = MIPSRegisters::a0; static const GPRReg argumentGPR1 = MIPSRegisters::a1; static const GPRReg argumentGPR2 = MIPSRegisters::a2; static const GPRReg argumentGPR3 = MIPSRegisters::a3; static const GPRReg nonArgGPR0 = regT4; static const GPRReg returnValueGPR = regT0; static const GPRReg returnValueGPR2 = regT1; static const GPRReg nonPreservedNonReturnGPR = regT2; static GPRReg toRegister(unsigned index) { ASSERT(index < numberOfRegisters); static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5, regT6 }; return registerForIndex[index]; } static GPRReg toArgumentRegister(unsigned index) { ASSERT(index < numberOfArgumentRegisters); static const GPRReg registerForIndex[numberOfArgumentRegisters] = { argumentGPR0, argumentGPR1, argumentGPR2, argumentGPR3 }; return registerForIndex[index]; } static unsigned toIndex(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(reg < 32); static const unsigned indexForRegister[32] = { InvalidIndex, InvalidIndex, 0, 1, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, 2, 3, 4, 5, 6, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex }; unsigned result = indexForRegister[reg]; return result; } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(reg < 16); static const char* nameForRegister[16] = { "zero", "at", "v0", "v1", "a0", "a1", "a2", "a3", "t0", "t1", "t2", "t3", "t4", "t5", "t6", "t7" }; return nameForRegister[reg]; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(MIPS) #if CPU(SH4) #define NUMBER_OF_ARGUMENT_REGISTERS 4u #define NUMBER_OF_CALLEE_SAVES_REGISTERS 0u class GPRInfo { public: typedef GPRReg RegisterType; static const unsigned numberOfRegisters = 10; // Note: regT3 is required to be callee-preserved. // Temporary registers. static const GPRReg regT0 = SH4Registers::r0; static const GPRReg regT1 = SH4Registers::r1; static const GPRReg regT2 = SH4Registers::r6; static const GPRReg regT3 = SH4Registers::r7; static const GPRReg regT4 = SH4Registers::r2; static const GPRReg regT5 = SH4Registers::r3; static const GPRReg regT6 = SH4Registers::r4; static const GPRReg regT7 = SH4Registers::r5; static const GPRReg regT8 = SH4Registers::r8; static const GPRReg regT9 = SH4Registers::r9; // These registers match the baseline JIT. static const GPRReg cachedResultRegister = regT0; static const GPRReg cachedResultRegister2 = regT1; static const GPRReg callFrameRegister = SH4Registers::fp; // These constants provide the names for the general purpose argument & return value registers. static const GPRReg argumentGPR0 = SH4Registers::r4; // regT6 static const GPRReg argumentGPR1 = SH4Registers::r5; // regT7 static const GPRReg argumentGPR2 = SH4Registers::r6; // regT2 static const GPRReg argumentGPR3 = SH4Registers::r7; // regT3 static const GPRReg nonArgGPR0 = regT4; static const GPRReg returnValueGPR = regT0; static const GPRReg returnValueGPR2 = regT1; static const GPRReg nonPreservedNonReturnGPR = regT2; static GPRReg toRegister(unsigned index) { ASSERT(index < numberOfRegisters); static const GPRReg registerForIndex[numberOfRegisters] = { regT0, regT1, regT2, regT3, regT4, regT5, regT6, regT7, regT8, regT9 }; return registerForIndex[index]; } static unsigned toIndex(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(reg < 14); static const unsigned indexForRegister[14] = { 0, 1, 4, 5, 6, 7, 2, 3, 8, 9, InvalidIndex, InvalidIndex, InvalidIndex, InvalidIndex }; unsigned result = indexForRegister[reg]; return result; } static const char* debugName(GPRReg reg) { ASSERT(reg != InvalidGPRReg); ASSERT(reg < 16); static const char* nameForRegister[16] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15" }; return nameForRegister[reg]; } static const unsigned InvalidIndex = 0xffffffff; }; #endif // CPU(SH4) // The baseline JIT uses "accumulator" style execution with regT0 (for 64-bit) // and regT0 + regT1 (for 32-bit) serving as the accumulator register(s) for // passing results of one opcode to the next. Hence: COMPILE_ASSERT(GPRInfo::regT0 == GPRInfo::returnValueGPR, regT0_must_equal_returnValueGPR); #if USE(JSVALUE32_64) COMPILE_ASSERT(GPRInfo::regT1 == GPRInfo::returnValueGPR2, regT1_must_equal_returnValueGPR2); #endif #endif // ENABLE(JIT) } // namespace JSC namespace WTF { inline void printInternal(PrintStream& out, JSC::GPRReg reg) { #if ENABLE(JIT) out.print("%", JSC::GPRInfo::debugName(reg)); #else out.printf("%%r%d", reg); #endif } } // namespace WTF #endif