// Licensed to the .NET Foundation under one or more agreements. // The .NET Foundation licenses this file to you under the MIT license. // See the LICENSE file in the project root for more information. // // This class contains all the data & functionality for code generation // of a method, except for the target-specific elements, which are // primarily in the Target class. // #ifndef _CODEGEN_H_ #define _CODEGEN_H_ #include "compiler.h" // temporary?? #include "codegeninterface.h" #include "regset.h" #include "jitgcinfo.h" #if defined(_TARGET_AMD64_) || defined(_TARGET_ARM64_) || defined(_TARGET_ARM_) #define FOREACH_REGISTER_FILE(file) \ for ((file) = &(this->intRegState); (file) != NULL; \ (file) = ((file) == &(this->intRegState)) ? &(this->floatRegState) : NULL) #else #define FOREACH_REGISTER_FILE(file) (file) = &(this->intRegState); #endif class CodeGen : public CodeGenInterface { friend class emitter; friend class DisAssembler; public: // This could use further abstraction CodeGen(Compiler* theCompiler); virtual void genGenerateCode(void** codePtr, ULONG* nativeSizeOfCode); // TODO-Cleanup: Abstract out the part of this that finds the addressing mode, and // move it to Lower virtual bool genCreateAddrMode(GenTreePtr addr, int mode, bool fold, regMaskTP regMask, bool* revPtr, GenTreePtr* rv1Ptr, GenTreePtr* rv2Ptr, #if SCALED_ADDR_MODES unsigned* mulPtr, #endif unsigned* cnsPtr, bool nogen = false); private: #if defined(_TARGET_XARCH_) && !FEATURE_STACK_FP_X87 // Bit masks used in negating a float or double number. // The below gentrees encapsulate the data offset to the bitmasks as GT_CLS_VAR nodes. // This is to avoid creating more than one data constant for these bitmasks when a // method has more than one GT_NEG operation on floating point values. GenTreePtr negBitmaskFlt; GenTreePtr negBitmaskDbl; // Bit masks used in computing Math.Abs() of a float or double number. GenTreePtr absBitmaskFlt; GenTreePtr absBitmaskDbl; // Bit mask used in U8 -> double conversion to adjust the result. GenTreePtr u8ToDblBitmask; // Generates SSE2 code for the given tree as "Operand BitWiseOp BitMask" void genSSE2BitwiseOp(GenTreePtr treeNode); #endif // defined(_TARGET_XARCH_) && !FEATURE_STACK_FP_X87 void genPrepForCompiler(); void genPrepForEHCodegen(); inline RegState* regStateForType(var_types t) { return varTypeIsFloating(t) ? &floatRegState : &intRegState; } inline RegState* regStateForReg(regNumber reg) { return genIsValidFloatReg(reg) ? &floatRegState : &intRegState; } regNumber genFramePointerReg() { if (isFramePointerUsed()) { return REG_FPBASE; } else { return REG_SPBASE; } } enum CompareKind { CK_SIGNED, CK_UNSIGNED, CK_LOGICAL }; static emitJumpKind genJumpKindForOper(genTreeOps cmp, CompareKind compareKind); // For a given compare oper tree, returns the conditions to use with jmp/set in 'jmpKind' array. // The corresponding elements of jmpToTrueLabel indicate whether the target of the jump is to the // 'true' label or a 'false' label. // // 'true' label corresponds to jump target of the current basic block i.e. the target to // branch to on compare condition being true. 'false' label corresponds to the target to // branch to on condition being false. static void genJumpKindsForTree(GenTreePtr cmpTree, emitJumpKind jmpKind[2], bool jmpToTrueLabel[2]); #if !defined(_TARGET_64BIT_) static void genJumpKindsForTreeLongHi(GenTreePtr cmpTree, emitJumpKind jmpKind[2]); #endif //! defined(_TARGET_64BIT_) static bool genShouldRoundFP(); GenTreeIndir indirForm(var_types type, GenTree* base); GenTreeIntCon intForm(var_types type, ssize_t value); void genRangeCheck(GenTree* node); void genLockedInstructions(GenTreeOp* node); //------------------------------------------------------------------------- // Register-related methods void rsInit(); #ifdef REG_OPT_RSVD // On some targets such as the ARM we may need to have an extra reserved register // that is used when addressing stack based locals and stack based temps. // This method returns the regNumber that should be used when an extra register // is needed to access the stack based locals and stack based temps. // regNumber rsGetRsvdReg() { // We should have already added this register to the mask // of reserved registers in regSet.rdMaskResvd noway_assert((regSet.rsMaskResvd & RBM_OPT_RSVD) != 0); return REG_OPT_RSVD; } #endif // REG_OPT_RSVD regNumber findStkLclInReg(unsigned lclNum) { #ifdef DEBUG genInterruptibleUsed = true; #endif return regTracker.rsLclIsInReg(lclNum); } //------------------------------------------------------------------------- bool genUseBlockInit; // true if we plan to block-initialize the local stack frame unsigned genInitStkLclCnt; // The count of local variables that we need to zero init // Keeps track of how many bytes we've pushed on the processor's stack. // unsigned genStackLevel; #if STACK_PROBES // Stack Probes bool genNeedPrologStackProbe; void genGenerateStackProbe(); #endif #ifdef LEGACY_BACKEND regMaskTP genNewLiveRegMask(GenTreePtr first, GenTreePtr second); // During codegen, determine the LiveSet after tree. // Preconditions: must be called during codegen, when compCurLife and // compCurLifeTree are being maintained, and tree must occur in the current // statement. VARSET_VALRET_TP genUpdateLiveSetForward(GenTreePtr tree); #endif //------------------------------------------------------------------------- void genReportEH(); // Allocates storage for the GC info, writes the GC info into that storage, records the address of the // GC info of the method with the EE, and returns a pointer to the "info" portion (just post-header) of // the GC info. Requires "codeSize" to be the size of the generated code, "prologSize" and "epilogSize" // to be the sizes of the prolog and epilog, respectively. In DEBUG, makes a check involving the // "codePtr", assumed to be a pointer to the start of the generated code. CLANG_FORMAT_COMMENT_ANCHOR; #ifdef JIT32_GCENCODER void* genCreateAndStoreGCInfo(unsigned codeSize, unsigned prologSize, unsigned epilogSize DEBUGARG(void* codePtr)); void* genCreateAndStoreGCInfoJIT32(unsigned codeSize, unsigned prologSize, unsigned epilogSize DEBUGARG(void* codePtr)); #else // !JIT32_GCENCODER void genCreateAndStoreGCInfo(unsigned codeSize, unsigned prologSize, unsigned epilogSize DEBUGARG(void* codePtr)); void genCreateAndStoreGCInfoX64(unsigned codeSize, unsigned prologSize DEBUGARG(void* codePtr)); #endif // !JIT32_GCENCODER /************************************************************************** * PROTECTED *************************************************************************/ protected: // the current (pending) label ref, a label which has been referenced but not yet seen BasicBlock* genPendingCallLabel; #ifdef DEBUG // Last instr we have displayed for dspInstrs unsigned genCurDispOffset; static const char* genInsName(instruction ins); #endif // DEBUG //------------------------------------------------------------------------- // JIT-time constants for use in multi-dimensional array code generation. unsigned genOffsetOfMDArrayLowerBound(var_types elemType, unsigned rank, unsigned dimension); unsigned genOffsetOfMDArrayDimensionSize(var_types elemType, unsigned rank, unsigned dimension); #ifdef DEBUG static const char* genSizeStr(emitAttr size); void genStressRegs(GenTreePtr tree); #endif // DEBUG void genCodeForBBlist(); public: #ifndef LEGACY_BACKEND // genSpillVar is called by compUpdateLifeVar in the !LEGACY_BACKEND case void genSpillVar(GenTreePtr tree); #endif // !LEGACY_BACKEND protected: #ifndef LEGACY_BACKEND void genEmitHelperCall(unsigned helper, int argSize, emitAttr retSize, regNumber callTarget = REG_NA); #else void genEmitHelperCall(unsigned helper, int argSize, emitAttr retSize); #endif void genGCWriteBarrier(GenTreePtr tree, GCInfo::WriteBarrierForm wbf); BasicBlock* genCreateTempLabel(); void genDefineTempLabel(BasicBlock* label); void genAdjustSP(ssize_t delta); void genAdjustStackLevel(BasicBlock* block); void genExitCode(BasicBlock* block); //------------------------------------------------------------------------- GenTreePtr genMakeConst(const void* cnsAddr, var_types cnsType, GenTreePtr cnsTree, bool dblAlign); //------------------------------------------------------------------------- void genJumpToThrowHlpBlk(emitJumpKind jumpKind, SpecialCodeKind codeKind, GenTreePtr failBlk = nullptr); void genCheckOverflow(GenTreePtr tree); //------------------------------------------------------------------------- // // Prolog/epilog generation // //------------------------------------------------------------------------- // // Prolog functions and data (there are a few exceptions for more generally used things) // void genEstablishFramePointer(int delta, bool reportUnwindData); void genFnPrologCalleeRegArgs(regNumber xtraReg, bool* pXtraRegClobbered, RegState* regState); void genEnregisterIncomingStackArgs(); void genCheckUseBlockInit(); #if defined(FEATURE_UNIX_AMD64_STRUCT_PASSING) && defined(FEATURE_SIMD) void genClearStackVec3ArgUpperBits(); #endif // FEATURE_UNIX_AMD64_STRUCT_PASSING && FEATURE_SIMD #if defined(_TARGET_ARM64_) bool genInstrWithConstant(instruction ins, emitAttr attr, regNumber reg1, regNumber reg2, ssize_t imm, regNumber tmpReg, bool inUnwindRegion = false); void genStackPointerAdjustment(ssize_t spAdjustment, regNumber tmpReg, bool* pTmpRegIsZero); void genPrologSaveRegPair(regNumber reg1, regNumber reg2, int spOffset, int spDelta, bool lastSavedWasPreviousPair, regNumber tmpReg, bool* pTmpRegIsZero); void genPrologSaveReg(regNumber reg1, int spOffset, int spDelta, regNumber tmpReg, bool* pTmpRegIsZero); void genEpilogRestoreRegPair( regNumber reg1, regNumber reg2, int spOffset, int spDelta, regNumber tmpReg, bool* pTmpRegIsZero); void genEpilogRestoreReg(regNumber reg1, int spOffset, int spDelta, regNumber tmpReg, bool* pTmpRegIsZero); void genSaveCalleeSavedRegistersHelp(regMaskTP regsToSaveMask, int lowestCalleeSavedOffset, int spDelta); void genRestoreCalleeSavedRegistersHelp(regMaskTP regsToRestoreMask, int lowestCalleeSavedOffset, int spDelta); void genPushCalleeSavedRegisters(regNumber initReg, bool* pInitRegZeroed); #else void genPushCalleeSavedRegisters(); #endif void genAllocLclFrame(unsigned frameSize, regNumber initReg, bool* pInitRegZeroed, regMaskTP maskArgRegsLiveIn); #if defined(_TARGET_ARM_) void genPushFltRegs(regMaskTP regMask); void genPopFltRegs(regMaskTP regMask); regMaskTP genStackAllocRegisterMask(unsigned frameSize, regMaskTP maskCalleeSavedFloat); regMaskTP genJmpCallArgMask(); void genFreeLclFrame(unsigned frameSize, /* IN OUT */ bool* pUnwindStarted, bool jmpEpilog); bool genUsedPopToReturn; // True if we use the pop into PC to return, // False if we didn't and must branch to LR to return. // A set of information that is used by funclet prolog and epilog generation. It is collected once, before // funclet prologs and epilogs are generated, and used by all funclet prologs and epilogs, which must all be the // same. struct FuncletFrameInfoDsc { regMaskTP fiSaveRegs; // Set of registers saved in the funclet prolog (includes LR) unsigned fiFunctionCallerSPtoFPdelta; // Delta between caller SP and the frame pointer unsigned fiSpDelta; // Stack pointer delta unsigned fiPSP_slot_SP_offset; // PSP slot offset from SP int fiPSP_slot_CallerSP_offset; // PSP slot offset from Caller SP }; FuncletFrameInfoDsc genFuncletInfo; #elif defined(_TARGET_ARM64_) // A set of information that is used by funclet prolog and epilog generation. It is collected once, before // funclet prologs and epilogs are generated, and used by all funclet prologs and epilogs, which must all be the // same. struct FuncletFrameInfoDsc { regMaskTP fiSaveRegs; // Set of callee-saved registers saved in the funclet prolog (includes LR) int fiFunction_CallerSP_to_FP_delta; // Delta between caller SP and the frame pointer in the parent function // (negative) int fiSP_to_FPLR_save_delta; // FP/LR register save offset from SP (positive) int fiSP_to_PSP_slot_delta; // PSP slot offset from SP (positive) int fiSP_to_CalleeSave_delta; // First callee-saved register slot offset from SP (positive) int fiCallerSP_to_PSP_slot_delta; // PSP slot offset from Caller SP (negative) int fiFrameType; // Funclet frame types are numbered. See genFuncletProlog() for details. int fiSpDelta1; // Stack pointer delta 1 (negative) int fiSpDelta2; // Stack pointer delta 2 (negative) }; FuncletFrameInfoDsc genFuncletInfo; #elif defined(_TARGET_AMD64_) // A set of information that is used by funclet prolog and epilog generation. It is collected once, before // funclet prologs and epilogs are generated, and used by all funclet prologs and epilogs, which must all be the // same. struct FuncletFrameInfoDsc { unsigned fiFunction_InitialSP_to_FP_delta; // Delta between Initial-SP and the frame pointer unsigned fiSpDelta; // Stack pointer delta int fiPSP_slot_InitialSP_offset; // PSP slot offset from Initial-SP }; FuncletFrameInfoDsc genFuncletInfo; #endif // _TARGET_AMD64_ #if defined(_TARGET_XARCH_) && !FEATURE_STACK_FP_X87 // Save/Restore callee saved float regs to stack void genPreserveCalleeSavedFltRegs(unsigned lclFrameSize); void genRestoreCalleeSavedFltRegs(unsigned lclFrameSize); // Generate VZeroupper instruction to avoid AVX/SSE transition penalty void genVzeroupperIfNeeded(bool check256bitOnly = true); #endif // _TARGET_XARCH_ && FEATURE_STACK_FP_X87 #if !FEATURE_STACK_FP_X87 void genZeroInitFltRegs(const regMaskTP& initFltRegs, const regMaskTP& initDblRegs, const regNumber& initReg); #endif // !FEATURE_STACK_FP_X87 regNumber genGetZeroReg(regNumber initReg, bool* pInitRegZeroed); void genZeroInitFrame(int untrLclHi, int untrLclLo, regNumber initReg, bool* pInitRegZeroed); void genReportGenericContextArg(regNumber initReg, bool* pInitRegZeroed); void genSetGSSecurityCookie(regNumber initReg, bool* pInitRegZeroed); void genFinalizeFrame(); #ifdef PROFILING_SUPPORTED void genProfilingEnterCallback(regNumber initReg, bool* pInitRegZeroed); void genProfilingLeaveCallback(unsigned helper = CORINFO_HELP_PROF_FCN_LEAVE); #endif // PROFILING_SUPPORTED void genPrologPadForReJit(); // clang-format off void genEmitCall(int callType, CORINFO_METHOD_HANDLE methHnd, INDEBUG_LDISASM_COMMA(CORINFO_SIG_INFO* sigInfo) void* addr X86_ARG(ssize_t argSize), emitAttr retSize MULTIREG_HAS_SECOND_GC_RET_ONLY_ARG(emitAttr secondRetSize), IL_OFFSETX ilOffset, regNumber base = REG_NA, bool isJump = false, bool isNoGC = false); // clang-format on // clang-format off void genEmitCall(int callType, CORINFO_METHOD_HANDLE methHnd, INDEBUG_LDISASM_COMMA(CORINFO_SIG_INFO* sigInfo) GenTreeIndir* indir X86_ARG(ssize_t argSize), emitAttr retSize MULTIREG_HAS_SECOND_GC_RET_ONLY_ARG(emitAttr secondRetSize), IL_OFFSETX ilOffset); // clang-format on // // Epilog functions // CLANG_FORMAT_COMMENT_ANCHOR; #if defined(_TARGET_ARM_) bool genCanUsePopToReturn(regMaskTP maskPopRegsInt, bool jmpEpilog); #endif #if defined(_TARGET_ARM64_) void genPopCalleeSavedRegistersAndFreeLclFrame(bool jmpEpilog); #else // !defined(_TARGET_ARM64_) void genPopCalleeSavedRegisters(bool jmpEpilog = false); #endif // !defined(_TARGET_ARM64_) // // Common or driving functions // void genReserveProlog(BasicBlock* block); // currently unused void genReserveEpilog(BasicBlock* block); void genFnProlog(); void genFnEpilog(BasicBlock* block); #if FEATURE_EH_FUNCLETS void genReserveFuncletProlog(BasicBlock* block); void genReserveFuncletEpilog(BasicBlock* block); void genFuncletProlog(BasicBlock* block); void genFuncletEpilog(); void genCaptureFuncletPrologEpilogInfo(); void genSetPSPSym(regNumber initReg, bool* pInitRegZeroed); void genUpdateCurrentFunclet(BasicBlock* block); #if defined(_TARGET_ARM_) void genInsertNopForUnwinder(BasicBlock* block); #endif #else // FEATURE_EH_FUNCLETS // This is a no-op when there are no funclets! void genUpdateCurrentFunclet(BasicBlock* block) { return; } #if defined(_TARGET_ARM_) void genInsertNopForUnwinder(BasicBlock* block) { return; } #endif #endif // FEATURE_EH_FUNCLETS void genGeneratePrologsAndEpilogs(); #if defined(DEBUG) && defined(_TARGET_ARM64_) void genArm64EmitterUnitTests(); #endif #if defined(DEBUG) && defined(LATE_DISASM) && defined(_TARGET_AMD64_) void genAmd64EmitterUnitTests(); #endif //------------------------------------------------------------------------- // // End prolog/epilog generation // //------------------------------------------------------------------------- void genSinglePush(); void genSinglePop(); regMaskTP genPushRegs(regMaskTP regs, regMaskTP* byrefRegs, regMaskTP* noRefRegs); void genPopRegs(regMaskTP regs, regMaskTP byrefRegs, regMaskTP noRefRegs); /* XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Debugging Support XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #ifdef DEBUG void genIPmappingDisp(unsigned mappingNum, Compiler::IPmappingDsc* ipMapping); void genIPmappingListDisp(); #endif // DEBUG void genIPmappingAdd(IL_OFFSETX offset, bool isLabel); void genIPmappingAddToFront(IL_OFFSETX offset); void genIPmappingGen(); void genEnsureCodeEmitted(IL_OFFSETX offsx); //------------------------------------------------------------------------- // scope info for the variables void genSetScopeInfo(unsigned which, UNATIVE_OFFSET startOffs, UNATIVE_OFFSET length, unsigned varNum, unsigned LVnum, bool avail, Compiler::siVarLoc& loc); void genSetScopeInfo(); void genRemoveBBsection(BasicBlock* head, BasicBlock* tail); protected: /* XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX ScopeInfo XX XX XX XX Keeps track of the scopes during code-generation. XX XX This is used to translate the local-variable debugging information XX XX from IL offsets to native code offsets. XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ /*****************************************************************************/ /***************************************************************************** * ScopeInfo * * This class is called during code gen at block-boundaries, and when the * set of live variables changes. It keeps track of the scope of the variables * in terms of the native code PC. */ public: void siInit(); void siBeginBlock(BasicBlock* block); void siEndBlock(BasicBlock* block); virtual void siUpdate(); void siCheckVarScope(unsigned varNum, IL_OFFSET offs); void siCloseAllOpenScopes(); #ifdef DEBUG void siDispOpenScopes(); #endif /************************************************************************** * PROTECTED *************************************************************************/ protected: struct siScope { emitLocation scStartLoc; // emitter location of start of scope emitLocation scEndLoc; // emitter location of end of scope unsigned scVarNum; // index into lvaTable unsigned scLVnum; // 'which' in eeGetLVinfo() unsigned scStackLevel; // Only for stk-vars bool scAvailable : 1; // It has a home / Home recycled - TODO-Cleanup: it appears this is unused (always true) siScope* scPrev; siScope* scNext; }; siScope siOpenScopeList, siScopeList, *siOpenScopeLast, *siScopeLast; unsigned siScopeCnt; VARSET_TP siLastLife; // Life at last call to siUpdate() // Tracks the last entry for each tracked register variable siScope* siLatestTrackedScopes[lclMAX_TRACKED]; IL_OFFSET siLastEndOffs; // IL offset of the (exclusive) end of the last block processed #if FEATURE_EH_FUNCLETS bool siInFuncletRegion; // Have we seen the start of the funclet region? #endif // FEATURE_EH_FUNCLETS // Functions siScope* siNewScope(unsigned LVnum, unsigned varNum); void siRemoveFromOpenScopeList(siScope* scope); void siEndTrackedScope(unsigned varIndex); void siEndScope(unsigned varNum); void siEndScope(siScope* scope); #ifdef DEBUG bool siVerifyLocalVarTab(); #endif #ifdef LATE_DISASM public: /* virtual */ const char* siRegVarName(size_t offs, size_t size, unsigned reg); /* virtual */ const char* siStackVarName(size_t offs, size_t size, unsigned reg, unsigned stkOffs); #endif // LATE_DISASM public: /* XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX PrologScopeInfo XX XX XX XX We need special handling in the prolog block, as the parameter variables XX XX may not be in the same position described by genLclVarTable - they all XX XX start out on the stack XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ public: void psiBegProlog(); void psiAdjustStackLevel(unsigned size); void psiMoveESPtoEBP(); void psiMoveToReg(unsigned varNum, regNumber reg = REG_NA, regNumber otherReg = REG_NA); void psiMoveToStack(unsigned varNum); void psiEndProlog(); /************************************************************************** * PROTECTED *************************************************************************/ protected: struct psiScope { emitLocation scStartLoc; // emitter location of start of scope emitLocation scEndLoc; // emitter location of end of scope unsigned scSlotNum; // index into lclVarTab unsigned scLVnum; // 'which' in eeGetLVinfo() bool scRegister; union { struct { regNumberSmall scRegNum; // Used for: // - "other half" of long var on architectures with 32 bit size registers - x86. // - for System V structs it stores the second register // used to pass a register passed struct. regNumberSmall scOtherReg; } u1; struct { regNumberSmall scBaseReg; NATIVE_OFFSET scOffset; } u2; }; psiScope* scPrev; psiScope* scNext; }; psiScope psiOpenScopeList, psiScopeList, *psiOpenScopeLast, *psiScopeLast; unsigned psiScopeCnt; // Implementation Functions psiScope* psiNewPrologScope(unsigned LVnum, unsigned slotNum); void psiEndPrologScope(psiScope* scope); void psSetScopeOffset(psiScope* newScope, LclVarDsc* lclVarDsc1); /***************************************************************************** * TrnslLocalVarInfo * * This struct holds the LocalVarInfo in terms of the generated native code * after a call to genSetScopeInfo() */ #ifdef DEBUG struct TrnslLocalVarInfo { unsigned tlviVarNum; unsigned tlviLVnum; VarName tlviName; UNATIVE_OFFSET tlviStartPC; size_t tlviLength; bool tlviAvailable; Compiler::siVarLoc tlviVarLoc; }; // Array of scopes of LocalVars in terms of native code TrnslLocalVarInfo* genTrnslLocalVarInfo; unsigned genTrnslLocalVarCount; #endif #ifndef LEGACY_BACKEND #include "codegenlinear.h" #else // LEGACY_BACKEND #include "codegenclassic.h" #endif // LEGACY_BACKEND /* XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Instruction XX XX XX XX The interface to generate a machine-instruction. XX XX Currently specific to x86 XX XX TODO-Cleanup: Consider factoring this out of CodeGen XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ public: void instInit(); regNumber genGetZeroRegister(); void instGen(instruction ins); #ifdef _TARGET_XARCH_ void instNop(unsigned size); #endif void inst_JMP(emitJumpKind jmp, BasicBlock* tgtBlock); void inst_SET(emitJumpKind condition, regNumber reg); void inst_RV(instruction ins, regNumber reg, var_types type, emitAttr size = EA_UNKNOWN); void inst_RV_RV(instruction ins, regNumber reg1, regNumber reg2, var_types type = TYP_I_IMPL, emitAttr size = EA_UNKNOWN, insFlags flags = INS_FLAGS_DONT_CARE); void inst_RV_RV_RV(instruction ins, regNumber reg1, regNumber reg2, regNumber reg3, emitAttr size, insFlags flags = INS_FLAGS_DONT_CARE); void inst_IV(instruction ins, int val); void inst_IV_handle(instruction ins, int val); void inst_FS(instruction ins, unsigned stk = 0); void inst_RV_IV(instruction ins, regNumber reg, ssize_t val, emitAttr size, insFlags flags = INS_FLAGS_DONT_CARE); void inst_ST_RV(instruction ins, TempDsc* tmp, unsigned ofs, regNumber reg, var_types type); void inst_ST_IV(instruction ins, TempDsc* tmp, unsigned ofs, int val, var_types type); void inst_SA_RV(instruction ins, unsigned ofs, regNumber reg, var_types type); void inst_SA_IV(instruction ins, unsigned ofs, int val, var_types type); void inst_RV_ST( instruction ins, regNumber reg, TempDsc* tmp, unsigned ofs, var_types type, emitAttr size = EA_UNKNOWN); void inst_FS_ST(instruction ins, emitAttr size, TempDsc* tmp, unsigned ofs); void instEmit_indCall(GenTreePtr call, size_t argSize, emitAttr retSize MULTIREG_HAS_SECOND_GC_RET_ONLY_ARG(emitAttr secondRetSize)); void instEmit_RM(instruction ins, GenTreePtr tree, GenTreePtr addr, unsigned offs); void instEmit_RM_RV(instruction ins, emitAttr size, GenTreePtr tree, regNumber reg, unsigned offs); void instEmit_RV_RM(instruction ins, emitAttr size, regNumber reg, GenTreePtr tree, unsigned offs); void instEmit_RV_RIA(instruction ins, regNumber reg1, regNumber reg2, unsigned offs); void inst_TT(instruction ins, GenTreePtr tree, unsigned offs = 0, int shfv = 0, emitAttr size = EA_UNKNOWN); void inst_TT_RV(instruction ins, GenTreePtr tree, regNumber reg, unsigned offs = 0, emitAttr size = EA_UNKNOWN, insFlags flags = INS_FLAGS_DONT_CARE); void inst_TT_IV(instruction ins, GenTreePtr tree, ssize_t val, unsigned offs = 0, emitAttr size = EA_UNKNOWN, insFlags flags = INS_FLAGS_DONT_CARE); void inst_RV_AT(instruction ins, emitAttr size, var_types type, regNumber reg, GenTreePtr tree, unsigned offs = 0, insFlags flags = INS_FLAGS_DONT_CARE); void inst_AT_IV(instruction ins, emitAttr size, GenTreePtr baseTree, int icon, unsigned offs = 0); void inst_RV_TT(instruction ins, regNumber reg, GenTreePtr tree, unsigned offs = 0, emitAttr size = EA_UNKNOWN, insFlags flags = INS_FLAGS_DONT_CARE); void inst_RV_TT_IV(instruction ins, regNumber reg, GenTreePtr tree, int val); void inst_FS_TT(instruction ins, GenTreePtr tree); void inst_RV_SH(instruction ins, emitAttr size, regNumber reg, unsigned val, insFlags flags = INS_FLAGS_DONT_CARE); void inst_TT_SH(instruction ins, GenTreePtr tree, unsigned val, unsigned offs = 0); void inst_RV_CL(instruction ins, regNumber reg, var_types type = TYP_I_IMPL); void inst_TT_CL(instruction ins, GenTreePtr tree, unsigned offs = 0); #if defined(_TARGET_XARCH_) void inst_RV_RV_IV(instruction ins, emitAttr size, regNumber reg1, regNumber reg2, unsigned ival); #endif void inst_RV_RR(instruction ins, emitAttr size, regNumber reg1, regNumber reg2); void inst_RV_ST(instruction ins, emitAttr size, regNumber reg, GenTreePtr tree); void inst_mov_RV_ST(regNumber reg, GenTreePtr tree); void instGetAddrMode(GenTreePtr addr, regNumber* baseReg, unsigned* indScale, regNumber* indReg, unsigned* cns); void inst_set_SV_var(GenTreePtr tree); #ifdef _TARGET_ARM_ bool arm_Valid_Imm_For_Instr(instruction ins, ssize_t imm, insFlags flags); bool arm_Valid_Disp_For_LdSt(ssize_t disp, var_types type); bool arm_Valid_Imm_For_Alu(ssize_t imm); bool arm_Valid_Imm_For_Mov(ssize_t imm); bool arm_Valid_Imm_For_Small_Mov(regNumber reg, ssize_t imm, insFlags flags); bool arm_Valid_Imm_For_Add(ssize_t imm, insFlags flag); bool arm_Valid_Imm_For_Add_SP(ssize_t imm); bool arm_Valid_Imm_For_BL(ssize_t addr); bool ins_Writes_Dest(instruction ins); #endif bool isMoveIns(instruction ins); instruction ins_Move_Extend(var_types srcType, bool srcInReg); instruction ins_Copy(var_types dstType); instruction ins_CopyIntToFloat(var_types srcType, var_types dstTyp); instruction ins_CopyFloatToInt(var_types srcType, var_types dstTyp); static instruction ins_FloatStore(var_types type = TYP_DOUBLE); static instruction ins_FloatCopy(var_types type = TYP_DOUBLE); instruction ins_FloatConv(var_types to, var_types from); instruction ins_FloatCompare(var_types type); instruction ins_MathOp(genTreeOps oper, var_types type); instruction ins_FloatSqrt(var_types type); void instGen_Return(unsigned stkArgSize); void instGen_MemoryBarrier(); void instGen_Set_Reg_To_Zero(emitAttr size, regNumber reg, insFlags flags = INS_FLAGS_DONT_CARE); void instGen_Set_Reg_To_Imm(emitAttr size, regNumber reg, ssize_t imm, insFlags flags = INS_FLAGS_DONT_CARE); void instGen_Compare_Reg_To_Zero(emitAttr size, regNumber reg); void instGen_Compare_Reg_To_Reg(emitAttr size, regNumber reg1, regNumber reg2); void instGen_Compare_Reg_To_Imm(emitAttr size, regNumber reg, ssize_t imm); void instGen_Load_Reg_From_Lcl(var_types srcType, regNumber dstReg, int varNum, int offs); void instGen_Store_Reg_Into_Lcl(var_types dstType, regNumber srcReg, int varNum, int offs); void instGen_Store_Imm_Into_Lcl( var_types dstType, emitAttr sizeAttr, ssize_t imm, int varNum, int offs, regNumber regToUse = REG_NA); #ifdef DEBUG void __cdecl instDisp(instruction ins, bool noNL, const char* fmt, ...); #endif #ifdef _TARGET_XARCH_ instruction genMapShiftInsToShiftByConstantIns(instruction ins, int shiftByValue); #endif // _TARGET_XARCH_ }; /*XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XX XX XX Instruction XX XX Inline functions XX XX XX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX */ #ifdef _TARGET_XARCH_ /***************************************************************************** * * Generate a floating-point instruction that has one operand given by * a tree (which has been made addressable). */ inline void CodeGen::inst_FS_TT(instruction ins, GenTreePtr tree) { assert(instIsFP(ins)); assert(varTypeIsFloating(tree->gtType)); inst_TT(ins, tree, 0); } #endif /***************************************************************************** * * Generate a "shift reg, cl" instruction. */ inline void CodeGen::inst_RV_CL(instruction ins, regNumber reg, var_types type) { inst_RV(ins, reg, type); } #endif // _CODEGEN_H_