//===-- ARMBaseInfo.h - Top level definitions for ARM -------- --*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains small standalone helper functions and enum definitions for // the ARM target useful for the compiler back-end and the MC libraries. // As such, it deliberately does not include references to LLVM core // code gen types, passes, etc.. // //===----------------------------------------------------------------------===// /* Capstone Disassembly Engine */ /* By Nguyen Anh Quynh , 2013-2014 */ #ifndef CS_ARMBASEINFO_H #define CS_ARMBASEINFO_H //#include "ARMMCTargetDesc.h" // Defines symbolic names for ARM registers. This defines a mapping from // register name to register number. // #define GET_REGINFO_ENUM #include "ARMGenRegisterInfo.inc" // Enums corresponding to ARM condition codes // The CondCodes constants map directly to the 4-bit encoding of the // condition field for predicated instructions. typedef enum ARMCC_CondCodes { // Meaning (integer) Meaning (floating-point) ARMCC_EQ, // Equal Equal ARMCC_NE, // Not equal Not equal, or unordered ARMCC_HS, // Carry set >, ==, or unordered ARMCC_LO, // Carry clear Less than ARMCC_MI, // Minus, negative Less than ARMCC_PL, // Plus, positive or zero >, ==, or unordered ARMCC_VS, // Overflow Unordered ARMCC_VC, // No overflow Not unordered ARMCC_HI, // Unsigned higher Greater than, or unordered ARMCC_LS, // Unsigned lower or same Less than or equal ARMCC_GE, // Greater than or equal Greater than or equal ARMCC_LT, // Less than Less than, or unordered ARMCC_GT, // Greater than Greater than ARMCC_LE, // Less than or equal <, ==, or unordered ARMCC_AL // Always (unconditional) Always (unconditional) } ARMCC_CondCodes; inline static ARMCC_CondCodes ARMCC_getOppositeCondition(ARMCC_CondCodes CC) { switch (CC) { case ARMCC_EQ: return ARMCC_NE; case ARMCC_NE: return ARMCC_EQ; case ARMCC_HS: return ARMCC_LO; case ARMCC_LO: return ARMCC_HS; case ARMCC_MI: return ARMCC_PL; case ARMCC_PL: return ARMCC_MI; case ARMCC_VS: return ARMCC_VC; case ARMCC_VC: return ARMCC_VS; case ARMCC_HI: return ARMCC_LS; case ARMCC_LS: return ARMCC_HI; case ARMCC_GE: return ARMCC_LT; case ARMCC_LT: return ARMCC_GE; case ARMCC_GT: return ARMCC_LE; case ARMCC_LE: return ARMCC_GT; default: return ARMCC_AL; } } inline static char *ARMCC_ARMCondCodeToString(ARMCC_CondCodes CC) { switch (CC) { case ARMCC_EQ: return "eq"; case ARMCC_NE: return "ne"; case ARMCC_HS: return "hs"; case ARMCC_LO: return "lo"; case ARMCC_MI: return "mi"; case ARMCC_PL: return "pl"; case ARMCC_VS: return "vs"; case ARMCC_VC: return "vc"; case ARMCC_HI: return "hi"; case ARMCC_LS: return "ls"; case ARMCC_GE: return "ge"; case ARMCC_LT: return "lt"; case ARMCC_GT: return "gt"; case ARMCC_LE: return "le"; case ARMCC_AL: return "al"; default: return ""; } } enum ARM_PROC_IMod { ARM_PROC_IE = 2, ARM_PROC_ID = 3 }; enum ARM_PROC_IFlags { ARM_PROC_F = 1, ARM_PROC_I = 2, ARM_PROC_A = 4 }; inline static char *ARM_PROC_IFlagsToString(unsigned val) { switch (val) { case ARM_PROC_F: return "f"; case ARM_PROC_I: return "i"; case ARM_PROC_A: return "a"; default: return ""; } } inline static char *ARM_PROC_IModToString(unsigned val) { switch (val) { case ARM_PROC_IE: return "ie"; case ARM_PROC_ID: return "id"; default: return ""; } } // The Memory Barrier Option constants map directly to the 4-bit encoding of // the option field for memory barrier operations. enum ARM_MB_MemBOpt { ARM_MB_RESERVED_0 = 0, ARM_MB_OSHLD = 1, ARM_MB_OSHST = 2, ARM_MB_OSH = 3, ARM_MB_RESERVED_4 = 4, ARM_MB_NSHLD = 5, ARM_MB_NSHST = 6, ARM_MB_NSH = 7, ARM_MB_RESERVED_8 = 8, ARM_MB_ISHLD = 9, ARM_MB_ISHST = 10, ARM_MB_ISH = 11, ARM_MB_RESERVED_12 = 12, ARM_MB_LD = 13, ARM_MB_ST = 14, ARM_MB_SY = 15 }; inline static char *ARM_MB_MemBOptToString(unsigned val, bool HasV8) { switch (val) { default: return "BUGBUG"; case ARM_MB_SY: return "sy"; case ARM_MB_ST: return "st"; case ARM_MB_LD: return HasV8 ? "ld" : "#0xd"; case ARM_MB_RESERVED_12: return "#0xc"; case ARM_MB_ISH: return "ish"; case ARM_MB_ISHST: return "ishst"; case ARM_MB_ISHLD: return HasV8 ? "ishld" : "#0x9"; case ARM_MB_RESERVED_8: return "#0x8"; case ARM_MB_NSH: return "nsh"; case ARM_MB_NSHST: return "nshst"; case ARM_MB_NSHLD: return HasV8 ? "nshld" : "#0x5"; case ARM_MB_RESERVED_4: return "#0x4"; case ARM_MB_OSH: return "osh"; case ARM_MB_OSHST: return "oshst"; case ARM_MB_OSHLD: return HasV8 ? "oshld" : "#0x1"; case ARM_MB_RESERVED_0: return "#0x0"; } } enum ARM_ISB_InstSyncBOpt { ARM_ISB_RESERVED_0 = 0, ARM_ISB_RESERVED_1 = 1, ARM_ISB_RESERVED_2 = 2, ARM_ISB_RESERVED_3 = 3, ARM_ISB_RESERVED_4 = 4, ARM_ISB_RESERVED_5 = 5, ARM_ISB_RESERVED_6 = 6, ARM_ISB_RESERVED_7 = 7, ARM_ISB_RESERVED_8 = 8, ARM_ISB_RESERVED_9 = 9, ARM_ISB_RESERVED_10 = 10, ARM_ISB_RESERVED_11 = 11, ARM_ISB_RESERVED_12 = 12, ARM_ISB_RESERVED_13 = 13, ARM_ISB_RESERVED_14 = 14, ARM_ISB_SY = 15 }; inline static char *ARM_ISB_InstSyncBOptToString(unsigned val) { switch (val) { default: // never reach case ARM_ISB_RESERVED_0: return "#0x0"; case ARM_ISB_RESERVED_1: return "#0x1"; case ARM_ISB_RESERVED_2: return "#0x2"; case ARM_ISB_RESERVED_3: return "#0x3"; case ARM_ISB_RESERVED_4: return "#0x4"; case ARM_ISB_RESERVED_5: return "#0x5"; case ARM_ISB_RESERVED_6: return "#0x6"; case ARM_ISB_RESERVED_7: return "#0x7"; case ARM_ISB_RESERVED_8: return "#0x8"; case ARM_ISB_RESERVED_9: return "#0x9"; case ARM_ISB_RESERVED_10: return "#0xa"; case ARM_ISB_RESERVED_11: return "#0xb"; case ARM_ISB_RESERVED_12: return "#0xc"; case ARM_ISB_RESERVED_13: return "#0xd"; case ARM_ISB_RESERVED_14: return "#0xe"; case ARM_ISB_SY: return "sy"; } } /// isARMLowRegister - Returns true if the register is a low register (r0-r7). /// static inline bool isARMLowRegister(unsigned Reg) { //using namespace ARM; switch (Reg) { case ARM_R0: case ARM_R1: case ARM_R2: case ARM_R3: case ARM_R4: case ARM_R5: case ARM_R6: case ARM_R7: return true; default: return false; } } /// ARMII - This namespace holds all of the target specific flags that /// instruction info tracks. /// /// ARM Index Modes enum ARMII_IndexMode { ARMII_IndexModeNone = 0, ARMII_IndexModePre = 1, ARMII_IndexModePost = 2, ARMII_IndexModeUpd = 3 }; /// ARM Addressing Modes typedef enum ARMII_AddrMode { ARMII_AddrModeNone = 0, ARMII_AddrMode1 = 1, ARMII_AddrMode2 = 2, ARMII_AddrMode3 = 3, ARMII_AddrMode4 = 4, ARMII_AddrMode5 = 5, ARMII_AddrMode6 = 6, ARMII_AddrModeT1_1 = 7, ARMII_AddrModeT1_2 = 8, ARMII_AddrModeT1_4 = 9, ARMII_AddrModeT1_s = 10, // i8 * 4 for pc and sp relative data ARMII_AddrModeT2_i12 = 11, ARMII_AddrModeT2_i8 = 12, ARMII_AddrModeT2_so = 13, ARMII_AddrModeT2_pc = 14, // +/- i12 for pc relative data ARMII_AddrModeT2_i8s4 = 15, // i8 * 4 ARMII_AddrMode_i12 = 16 } ARMII_AddrMode; inline static char *ARMII_AddrModeToString(ARMII_AddrMode addrmode) { switch (addrmode) { case ARMII_AddrModeNone: return "AddrModeNone"; case ARMII_AddrMode1: return "AddrMode1"; case ARMII_AddrMode2: return "AddrMode2"; case ARMII_AddrMode3: return "AddrMode3"; case ARMII_AddrMode4: return "AddrMode4"; case ARMII_AddrMode5: return "AddrMode5"; case ARMII_AddrMode6: return "AddrMode6"; case ARMII_AddrModeT1_1: return "AddrModeT1_1"; case ARMII_AddrModeT1_2: return "AddrModeT1_2"; case ARMII_AddrModeT1_4: return "AddrModeT1_4"; case ARMII_AddrModeT1_s: return "AddrModeT1_s"; case ARMII_AddrModeT2_i12: return "AddrModeT2_i12"; case ARMII_AddrModeT2_i8: return "AddrModeT2_i8"; case ARMII_AddrModeT2_so: return "AddrModeT2_so"; case ARMII_AddrModeT2_pc: return "AddrModeT2_pc"; case ARMII_AddrModeT2_i8s4: return "AddrModeT2_i8s4"; case ARMII_AddrMode_i12: return "AddrMode_i12"; } } /// Target Operand Flag enum. enum ARMII_TOF { //===------------------------------------------------------------------===// // ARM Specific MachineOperand flags. ARMII_MO_NO_FLAG, /// MO_LO16 - On a symbol operand, this represents a relocation containing /// lower 16 bit of the address. Used only via movw instruction. ARMII_MO_LO16, /// MO_HI16 - On a symbol operand, this represents a relocation containing /// higher 16 bit of the address. Used only via movt instruction. ARMII_MO_HI16, /// MO_LO16_NONLAZY - On a symbol operand "FOO", this represents a /// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol, /// i.e. "FOO$non_lazy_ptr". /// Used only via movw instruction. ARMII_MO_LO16_NONLAZY, /// MO_HI16_NONLAZY - On a symbol operand "FOO", this represents a /// relocation containing lower 16 bit of the non-lazy-ptr indirect symbol, /// i.e. "FOO$non_lazy_ptr". Used only via movt instruction. ARMII_MO_HI16_NONLAZY, /// MO_LO16_NONLAZY_PIC - On a symbol operand "FOO", this represents a /// relocation containing lower 16 bit of the PC relative address of the /// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL". /// Used only via movw instruction. ARMII_MO_LO16_NONLAZY_PIC, /// MO_HI16_NONLAZY_PIC - On a symbol operand "FOO", this represents a /// relocation containing lower 16 bit of the PC relative address of the /// non-lazy-ptr indirect symbol, i.e. "FOO$non_lazy_ptr - LABEL". /// Used only via movt instruction. ARMII_MO_HI16_NONLAZY_PIC, /// MO_PLT - On a symbol operand, this represents an ELF PLT reference on a /// call operand. ARMII_MO_PLT }; enum { //===------------------------------------------------------------------===// // Instruction Flags. //===------------------------------------------------------------------===// // This four-bit field describes the addressing mode used. ARMII_AddrModeMask = 0x1f, // The AddrMode enums are declared in ARMBaseInfo.h // IndexMode - Unindex, pre-indexed, or post-indexed are valid for load // and store ops only. Generic "updating" flag is used for ld/st multiple. // The index mode enums are declared in ARMBaseInfo.h ARMII_IndexModeShift = 5, ARMII_IndexModeMask = 3 << ARMII_IndexModeShift, //===------------------------------------------------------------------===// // Instruction encoding formats. // ARMII_FormShift = 7, ARMII_FormMask = 0x3f << ARMII_FormShift, // Pseudo instructions ARMII_Pseudo = 0 << ARMII_FormShift, // Multiply instructions ARMII_MulFrm = 1 << ARMII_FormShift, // Branch instructions ARMII_BrFrm = 2 << ARMII_FormShift, ARMII_BrMiscFrm = 3 << ARMII_FormShift, // Data Processing instructions ARMII_DPFrm = 4 << ARMII_FormShift, ARMII_DPSoRegFrm = 5 << ARMII_FormShift, // Load and Store ARMII_LdFrm = 6 << ARMII_FormShift, ARMII_StFrm = 7 << ARMII_FormShift, ARMII_LdMiscFrm = 8 << ARMII_FormShift, ARMII_StMiscFrm = 9 << ARMII_FormShift, ARMII_LdStMulFrm = 10 << ARMII_FormShift, ARMII_LdStExFrm = 11 << ARMII_FormShift, // Miscellaneous arithmetic instructions ARMII_ArithMiscFrm = 12 << ARMII_FormShift, ARMII_SatFrm = 13 << ARMII_FormShift, // Extend instructions ARMII_ExtFrm = 14 << ARMII_FormShift, // VFP formats ARMII_VFPUnaryFrm = 15 << ARMII_FormShift, ARMII_VFPBinaryFrm = 16 << ARMII_FormShift, ARMII_VFPConv1Frm = 17 << ARMII_FormShift, ARMII_VFPConv2Frm = 18 << ARMII_FormShift, ARMII_VFPConv3Frm = 19 << ARMII_FormShift, ARMII_VFPConv4Frm = 20 << ARMII_FormShift, ARMII_VFPConv5Frm = 21 << ARMII_FormShift, ARMII_VFPLdStFrm = 22 << ARMII_FormShift, ARMII_VFPLdStMulFrm = 23 << ARMII_FormShift, ARMII_VFPMiscFrm = 24 << ARMII_FormShift, // Thumb format ARMII_ThumbFrm = 25 << ARMII_FormShift, // Miscelleaneous format ARMII_MiscFrm = 26 << ARMII_FormShift, // NEON formats ARMII_NGetLnFrm = 27 << ARMII_FormShift, ARMII_NSetLnFrm = 28 << ARMII_FormShift, ARMII_NDupFrm = 29 << ARMII_FormShift, ARMII_NLdStFrm = 30 << ARMII_FormShift, ARMII_N1RegModImmFrm= 31 << ARMII_FormShift, ARMII_N2RegFrm = 32 << ARMII_FormShift, ARMII_NVCVTFrm = 33 << ARMII_FormShift, ARMII_NVDupLnFrm = 34 << ARMII_FormShift, ARMII_N2RegVShLFrm = 35 << ARMII_FormShift, ARMII_N2RegVShRFrm = 36 << ARMII_FormShift, ARMII_N3RegFrm = 37 << ARMII_FormShift, ARMII_N3RegVShFrm = 38 << ARMII_FormShift, ARMII_NVExtFrm = 39 << ARMII_FormShift, ARMII_NVMulSLFrm = 40 << ARMII_FormShift, ARMII_NVTBLFrm = 41 << ARMII_FormShift, //===------------------------------------------------------------------===// // Misc flags. // UnaryDP - Indicates this is a unary data processing instruction, i.e. // it doesn't have a Rn operand. ARMII_UnaryDP = 1 << 13, // Xform16Bit - Indicates this Thumb2 instruction may be transformed into // a 16-bit Thumb instruction if certain conditions are met. ARMII_Xform16Bit = 1 << 14, // ThumbArithFlagSetting - The instruction is a 16-bit flag setting Thumb // instruction. Used by the parser to determine whether to require the 'S' // suffix on the mnemonic (when not in an IT block) or preclude it (when // in an IT block). ARMII_ThumbArithFlagSetting = 1 << 18, //===------------------------------------------------------------------===// // Code domain. ARMII_DomainShift = 15, ARMII_DomainMask = 7 << ARMII_DomainShift, ARMII_DomainGeneral = 0 << ARMII_DomainShift, ARMII_DomainVFP = 1 << ARMII_DomainShift, ARMII_DomainNEON = 2 << ARMII_DomainShift, ARMII_DomainNEONA8 = 4 << ARMII_DomainShift, //===------------------------------------------------------------------===// // Field shifts - such shifts are used to set field while generating // machine instructions. // // FIXME: This list will need adjusting/fixing as the MC code emitter // takes shape and the ARMCodeEmitter.cpp bits go away. ARMII_ShiftTypeShift = 4, ARMII_M_BitShift = 5, ARMII_ShiftImmShift = 5, ARMII_ShiftShift = 7, ARMII_N_BitShift = 7, ARMII_ImmHiShift = 8, ARMII_SoRotImmShift = 8, ARMII_RegRsShift = 8, ARMII_ExtRotImmShift = 10, ARMII_RegRdLoShift = 12, ARMII_RegRdShift = 12, ARMII_RegRdHiShift = 16, ARMII_RegRnShift = 16, ARMII_S_BitShift = 20, ARMII_W_BitShift = 21, ARMII_AM3_I_BitShift = 22, ARMII_D_BitShift = 22, ARMII_U_BitShift = 23, ARMII_P_BitShift = 24, ARMII_I_BitShift = 25, ARMII_CondShift = 28 }; #endif