android-4.2.0_r1.0/s

/*
 * Copyright (C) 2009 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 DALVIK_VM_COMPILER_CODEGEN_MIPS_MIPSLIR_H_
#define DALVIK_VM_COMPILER_CODEGEN_MIPS_MIPSLIR_H_

#include "Dalvik.h"
#include "compiler/CompilerInternals.h"

/*
 * zero is always the value 0
 * at is scratch for Jit (normally used as temp reg by assembler)
 * v0, v1 are scratch for Jit (normally hold subroutine return values)
 * a0-a3 are scratch for Jit (normally hold subroutine arguments)
 * t0-t7 are scratch for Jit
 * t8 is scratch for Jit
 * t9 is scratch for Jit (normally used for function calls)
 * s0 (rFP) is reserved [holds Dalvik frame pointer]
 * s1 (rSELF) is reserved [holds current &Thread]
 * s2 (rINST) is scratch for Jit
 * s3 (rIBASE) is scratch for Jit
 * s4-s7 are scratch for Jit
 * k0, k1 are reserved for use by interrupt handlers
 * gp is reserved for global pointer
 * sp is reserved
 * s8 is scratch for Jit
 * ra is scratch for Jit (normally holds the return addr)
 *
 * Preserved across C calls: s0-s8
 * Trashed across C calls: at, v0-v1, a0-a3, t0-t9, gp, ra
 *
 * Floating pointer registers
 * NOTE: there are 32 fp registers (16 df pairs), but current Jit code
 *       only support 16 fp registers (8 df pairs).
 * f0-f15
 * df0-df7, where df0={f0,f1}, df1={f2,f3}, ... , df7={f14,f15}
 *
 * f0-f15 (df0-df7) trashed across C calls
 *
 * For mips32 code use:
 *      a0-a3 to hold operands
 *      v0-v1 to hold results
 *      t0-t9 for temps
 *
 * All jump/branch instructions have a delay slot after it.
 *
 */

/* Offset to distingish FP regs */
#define FP_REG_OFFSET 32
/* Offset to distinguish DP FP regs */
#define FP_DOUBLE 64
/* Offset to distingish the extra regs */
#define EXTRA_REG_OFFSET 128
/* Reg types */
#define REGTYPE(x) (x & (FP_REG_OFFSET | FP_DOUBLE))
#define FPREG(x) ((x & FP_REG_OFFSET) == FP_REG_OFFSET)
#define EXTRAREG(x) ((x & EXTRA_REG_OFFSET) == EXTRA_REG_OFFSET)
#define LOWREG(x) ((x & 0x1f) == x)
#define DOUBLEREG(x) ((x & FP_DOUBLE) == FP_DOUBLE)
#define SINGLEREG(x) (FPREG(x) && !DOUBLEREG(x))
/*
 * Note: the low register of a floating point pair is sufficient to
 * create the name of a double, but require both names to be passed to
 * allow for asserts to verify that the pair is consecutive if significant
 * rework is done in this area.  Also, it is a good reminder in the calling
 * code that reg locations always describe doubles as a pair of singles.
 */
#define S2D(x,y) ((x) | FP_DOUBLE)
/* Mask to strip off fp flags */
#define FP_REG_MASK (FP_REG_OFFSET-1)
/* non-existent Dalvik register */
#define vNone   (-1)
/* non-existant physical register */
#define rNone   (-1)

#ifdef HAVE_LITTLE_ENDIAN
#define LOWORD_OFFSET 0
#define HIWORD_OFFSET 4
#define r_ARG0 r_A0
#define r_ARG1 r_A1
#define r_ARG2 r_A2
#define r_ARG3 r_A3
#define r_RESULT0 r_V0
#define r_RESULT1 r_V1
#else
#define LOWORD_OFFSET 4
#define HIWORD_OFFSET 0
#define r_ARG0 r_A1
#define r_ARG1 r_A0
#define r_ARG2 r_A3
#define r_ARG3 r_A2
#define r_RESULT0 r_V1
#define r_RESULT1 r_V0
#endif

/* These are the same for both big and little endian. */
#define r_FARG0 r_F12
#define r_FARG1 r_F13
#define r_FRESULT0 r_F0
#define r_FRESULT1 r_F1

/* RegisterLocation templates return values (r_V0, or r_V0/r_V1) */
#define LOC_C_RETURN {kLocPhysReg, 0, 0, r_V0, 0, -1}
#define LOC_C_RETURN_WIDE {kLocPhysReg, 1, 0, r_RESULT0, r_RESULT1, -1}
#define LOC_C_RETURN_ALT {kLocPhysReg, 0, 1, r_F0, 0, -1}
#define LOC_C_RETURN_WIDE_ALT {kLocPhysReg, 1, 1, r_FRESULT0, r_FRESULT1, -1}
/* RegisterLocation templates for interpState->retVal; */
#define LOC_DALVIK_RETURN_VAL {kLocRetval, 0, 0, 0, 0, -1}
#define LOC_DALVIK_RETURN_VAL_WIDE {kLocRetval, 1, 0, 0, 0, -1}

 /*
 * Data structure tracking the mapping between a Dalvik register (pair) and a
 * native register (pair). The idea is to reuse the previously loaded value
 * if possible, otherwise to keep the value in a native register as long as
 * possible.
 */
typedef struct RegisterInfo {
    int reg;                    // Reg number
    bool inUse;                 // Has it been allocated?
    bool pair;                  // Part of a register pair?
    int partner;                // If pair, other reg of pair
    bool live;                  // Is there an associated SSA name?
    bool dirty;                 // If live, is it dirty?
    int sReg;                   // Name of live value
    struct LIR *defStart;       // Starting inst in last def sequence
    struct LIR *defEnd;         // Ending inst in last def sequence
} RegisterInfo;

typedef struct RegisterPool {
    BitVector *nullCheckedRegs; // Track which registers have been null-checked
    int numCoreTemps;
    RegisterInfo *coreTemps;
    int nextCoreTemp;
    int numFPTemps;
    RegisterInfo *FPTemps;
    int nextFPTemp;
} RegisterPool;

typedef enum ResourceEncodingPos {
    kGPReg0     = 0,
    kRegSP      = 29,
    kRegLR      = 31,
    kFPReg0     = 32, /* only 16 fp regs supported currently */
    kFPRegEnd   = 48,
    kRegHI      = kFPRegEnd,
    kRegLO,
    kRegPC,
    kRegEnd     = 51,
    kCCode      = kRegEnd,
    kFPStatus,          // FP status word
    // The following four bits are for memory disambiguation
    kDalvikReg,         // 1 Dalvik Frame (can be fully disambiguated)
    kLiteral,           // 2 Literal pool (can be fully disambiguated)
    kHeapRef,           // 3 Somewhere on the heap (alias with any other heap)
    kMustNotAlias,      // 4 Guaranteed to be non-alias (eg *(r6+x))
} ResourceEncodingPos;

#define ENCODE_REG_LIST(N)      ((u8) N)
#define ENCODE_REG_SP           (1ULL << kRegSP)
#define ENCODE_REG_LR           (1ULL << kRegLR)
#define ENCODE_REG_PC           (1ULL << kRegPC)
#define ENCODE_CCODE            (1ULL << kCCode)
#define ENCODE_FP_STATUS        (1ULL << kFPStatus)

/* Abstract memory locations */
#define ENCODE_DALVIK_REG       (1ULL << kDalvikReg)
#define ENCODE_LITERAL          (1ULL << kLiteral)
#define ENCODE_HEAP_REF         (1ULL << kHeapRef)
#define ENCODE_MUST_NOT_ALIAS   (1ULL << kMustNotAlias)

#define ENCODE_ALL              (~0ULL)
#define ENCODE_MEM              (ENCODE_DALVIK_REG | ENCODE_LITERAL | \
                                 ENCODE_HEAP_REF | ENCODE_MUST_NOT_ALIAS)

#define DECODE_ALIAS_INFO_REG(X)        (X & 0xffff)
#define DECODE_ALIAS_INFO_WIDE(X)       ((X & 0x80000000) ? 1 : 0)

typedef enum OpSize {
    kWord,
    kLong,
    kSingle,
    kDouble,
    kUnsignedHalf,
    kSignedHalf,
    kUnsignedByte,
    kSignedByte,
} OpSize;

typedef enum OpKind {
    kOpMov,
    kOpMvn,
    kOpCmp,
    kOpLsl,
    kOpLsr,
    kOpAsr,
    kOpRor,
    kOpNot,
    kOpAnd,
    kOpOr,
    kOpXor,
    kOpNeg,
    kOpAdd,
    kOpAdc,
    kOpSub,
    kOpSbc,
    kOpRsub,
    kOpMul,
    kOpDiv,
    kOpRem,
    kOpBic,
    kOpCmn,
    kOpTst,
    kOpBkpt,
    kOpBlx,
    kOpPush,
    kOpPop,
    kOp2Char,
    kOp2Short,
    kOp2Byte,
    kOpCondBr,
    kOpUncondBr,
} OpKind;

/*
 * Annotate special-purpose core registers:
 *
 * rPC, rFP, and rSELF are for architecture-independent code to use.
 */
typedef enum NativeRegisterPool {
    r_ZERO = 0,
    r_AT = 1,
    r_V0 = 2,
    r_V1 = 3,
    r_A0 = 4,
    r_A1 = 5,
    r_A2 = 6,
    r_A3 = 7,
    r_T0 = 8,
    r_T1 = 9,
    r_T2 = 10,
    r_T3 = 11,
    r_T4 = 12,
    r_T5 = 13,
    r_T6 = 14,
    r_T7 = 15,
    r_S0 = 16,
    r_S1 = 17,
    r_S2 = 18,
    r_S3 = 19,
    r_S4 = 20,
    r_S5 = 21,
    r_S6 = 22,
    r_S7 = 23,
    r_T8 = 24,
    r_T9 = 25,
    r_K0 = 26,
    r_K1 = 27,
    r_GP = 28,
    r_SP = 29,
    r_FP = 30,
    r_RA = 31,

    r_F0 = 0 + FP_REG_OFFSET,
    r_F1,
    r_F2,
    r_F3,
    r_F4,
    r_F5,
    r_F6,
    r_F7,
    r_F8,
    r_F9,
    r_F10,
    r_F11,
    r_F12,
    r_F13,
    r_F14,
    r_F15,
#if 0 /* only 16 fp regs supported currently */
    r_F16,
    r_F17,
    r_F18,
    r_F19,
    r_F20,
    r_F21,
    r_F22,
    r_F23,
    r_F24,
    r_F25,
    r_F26,
    r_F27,
    r_F28,
    r_F29,
    r_F30,
    r_F31,
#endif
    r_DF0 = r_F0 + FP_DOUBLE,
    r_DF1 = r_F2 + FP_DOUBLE,
    r_DF2 = r_F4 + FP_DOUBLE,
    r_DF3 = r_F6 + FP_DOUBLE,
    r_DF4 = r_F8 + FP_DOUBLE,
    r_DF5 = r_F10 + FP_DOUBLE,
    r_DF6 = r_F12 + FP_DOUBLE,
    r_DF7 = r_F14 + FP_DOUBLE,
#if 0 /* only 16 fp regs supported currently */
    r_DF8 = r_F16 + FP_DOUBLE,
    r_DF9 = r_F18 + FP_DOUBLE,
    r_DF10 = r_F20 + FP_DOUBLE,
    r_DF11 = r_F22 + FP_DOUBLE,
    r_DF12 = r_F24 + FP_DOUBLE,
    r_DF13 = r_F26 + FP_DOUBLE,
    r_DF14 = r_F28 + FP_DOUBLE,
    r_DF15 = r_F30 + FP_DOUBLE,
#endif
    r_HI = EXTRA_REG_OFFSET,
    r_LO,
    r_PC,
} NativeRegisterPool;


/* must match gp offset used mterp/mips files */
#define STACK_OFFSET_GP 84

/* MIPSTODO: properly remap arm regs (dPC, dFP, dGLUE) and remove these mappings */
#define r4PC r_S0
#define rFP r_S1
#define rSELF r_S2
#define rINST r_S4

/* Shift encodings */
typedef enum MipsShiftEncodings {
    kMipsLsl = 0x0,
    kMipsLsr = 0x1,
    kMipsAsr = 0x2,
    kMipsRor = 0x3
} MipsShiftEncodings;

/* condition encodings */
typedef enum MipsConditionCode {
    kMipsCondEq = 0x0,    /* 0000 */
    kMipsCondNe = 0x1,    /* 0001 */
    kMipsCondCs = 0x2,    /* 0010 */
    kMipsCondCc = 0x3,    /* 0011 */
    kMipsCondMi = 0x4,    /* 0100 */
    kMipsCondPl = 0x5,    /* 0101 */
    kMipsCondVs = 0x6,    /* 0110 */
    kMipsCondVc = 0x7,    /* 0111 */
    kMipsCondHi = 0x8,    /* 1000 */
    kMipsCondLs = 0x9,    /* 1001 */
    kMipsCondGe = 0xa,    /* 1010 */
    kMipsCondLt = 0xb,    /* 1011 */
    kMipsCondGt = 0xc,    /* 1100 */
    kMipsCondLe = 0xd,    /* 1101 */
    kMipsCondAl = 0xe,    /* 1110 */
    kMipsCondNv = 0xf,    /* 1111 */
} MipsConditionCode;

#define isPseudoOpCode(opCode) ((int)(opCode) < 0)

/*
 * The following enum defines the list of supported Thumb instructions by the
 * assembler. Their corresponding snippet positions will be defined in
 * Assemble.c.
 */
typedef enum MipsOpCode {
    kMipsChainingCellBottom = -18,
    kMipsPseudoBarrier = -17,
    kMipsPseudoExtended = -16,
    kMipsPseudoSSARep = -15,
    kMipsPseudoEntryBlock = -14,
    kMipsPseudoExitBlock = -13,
    kMipsPseudoTargetLabel = -12,
    kMipsPseudoChainingCellBackwardBranch = -11,
    kMipsPseudoChainingCellHot = -10,
    kMipsPseudoChainingCellInvokePredicted = -9,
    kMipsPseudoChainingCellInvokeSingleton = -8,
    kMipsPseudoChainingCellNormal = -7,
    kMipsPseudoDalvikByteCodeBoundary = -6,
    kMipsPseudoPseudoAlign4 = -5,
    kMipsPseudoPCReconstructionCell = -4,
    kMipsPseudoPCReconstructionBlockLabel = -3,
    kMipsPseudoEHBlockLabel = -2,
    kMipsPseudoNormalBlockLabel = -1,

    kMipsFirst,
    kMips32BitData = kMipsFirst, /* data [31..0] */
    kMipsAddiu,   /* addiu t,s,imm16 [001001] s[25..21] t[20..16] imm16[15..0] */
    kMipsAddu,    /* add d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100001] */
    kMipsAnd,     /* and d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100100] */
    kMipsAndi,    /* andi t,s,imm16 [001100] s[25..21] t[20..16] imm16[15..0] */
    kMipsB,       /* b o   [0001000000000000] o[15..0] */
    kMipsBal,     /* bal o [0000010000010001] o[15..0] */
    /* NOTE: the code tests the range kMipsBeq thru kMipsBne, so
             adding an instruction in this range may require updates */
    kMipsBeq,     /* beq s,t,o [000100] s[25..21] t[20..16] o[15..0] */
    kMipsBeqz,    /* beqz s,o [000100] s[25..21] [00000] o[15..0] */
    kMipsBgez,    /* bgez s,o [000001] s[25..21] [00001] o[15..0] */
    kMipsBgtz,    /* bgtz s,o [000111] s[25..21] [00000] o[15..0] */
    kMipsBlez,    /* blez s,o [000110] s[25..21] [00000] o[15..0] */
    kMipsBltz,    /* bltz s,o [000001] s[25..21] [00000] o[15..0] */
    kMipsBnez,    /* bnez s,o [000101] s[25..21] [00000] o[15..0] */
    kMipsBne,     /* bne s,t,o [000101] s[25..21] t[20..16] o[15..0] */
    kMipsDiv,     /* div s,t [000000] s[25..21] t[20..16] [0000000000011010] */
#if __mips_isa_rev>=2
    kMipsExt,     /* ext t,s,p,z [011111] s[25..21] t[20..16] z[15..11] p[10..6] [000000] */
#endif
    kMipsJal,     /* jal t [000011] t[25..0] */
    kMipsJalr,    /* jalr d,s [000000] s[25..21] [00000] d[15..11]
                                  hint[10..6] [001001] */
    kMipsJr,      /* jr s [000000] s[25..21] [0000000000] hint[10..6] [001000] */
    kMipsLahi,    /* lui t,imm16 [00111100000] t[20..16] imm16[15..0] load addr hi */
    kMipsLalo,    /* ori t,s,imm16 [001001] s[25..21] t[20..16] imm16[15..0] load addr lo */
    kMipsLui,     /* lui t,imm16 [00111100000] t[20..16] imm16[15..0] */
    kMipsLb,      /* lb t,o(b) [100000] b[25..21] t[20..16] o[15..0] */
    kMipsLbu,     /* lbu t,o(b) [100100] b[25..21] t[20..16] o[15..0] */
    kMipsLh,      /* lh t,o(b) [100001] b[25..21] t[20..16] o[15..0] */
    kMipsLhu,     /* lhu t,o(b) [100101] b[25..21] t[20..16] o[15..0] */
    kMipsLw,      /* lw t,o(b) [100011] b[25..21] t[20..16] o[15..0] */
    kMipsMfhi,    /* mfhi d [0000000000000000] d[15..11] [00000010000] */
    kMipsMflo,    /* mflo d [0000000000000000] d[15..11] [00000010010] */
    kMipsMove,    /* move d,s [000000] s[25..21] [00000] d[15..11] [00000100101] */
    kMipsMovz,    /* movz d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000001010] */
    kMipsMul,     /* mul d,s,t [011100] s[25..21] t[20..16] d[15..11] [00000000010] */
    kMipsNop,     /* nop [00000000000000000000000000000000] */
    kMipsNor,     /* nor d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100111] */
    kMipsOr,      /* or d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100101] */
    kMipsOri,     /* ori t,s,imm16 [001001] s[25..21] t[20..16] imm16[15..0] */
    kMipsPref,    /* pref h,o(b) [101011] b[25..21] h[20..16] o[15..0] */
    kMipsSb,      /* sb t,o(b) [101000] b[25..21] t[20..16] o[15..0] */
#if __mips_isa_rev>=2
    kMipsSeb,     /* seb d,t [01111100000] t[20..16] d[15..11] [10000100000] */
    kMipsSeh,     /* seh d,t [01111100000] t[20..16] d[15..11] [11000100000] */
#endif
    kMipsSh,      /* sh t,o(b) [101001] b[25..21] t[20..16] o[15..0] */
    kMipsSll,     /* sll d,t,a [00000000000] t[20..16] d[15..11] a[10..6] [000000] */
    kMipsSllv,    /* sllv d,t,s [000000] s[25..21] t[20..16] d[15..11] [00000000100] */
    kMipsSlt,     /* slt d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000101010] */
    kMipsSlti,    /* slti t,s,imm16 [001010] s[25..21] t[20..16] imm16[15..0] */
    kMipsSltu,    /* sltu d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000101011] */
    kMipsSra,     /* sra d,s,imm5 [00000000000] t[20..16] d[15..11] imm5[10..6] [000011] */
    kMipsSrav,    /* srav d,t,s [000000] s[25..21] t[20..16] d[15..11] [00000000111] */
    kMipsSrl,     /* srl d,t,a [00000000000] t[20..16] d[20..16] a[10..6] [000010] */
    kMipsSrlv,    /* srlv d,t,s [000000] s[25..21] t[20..16] d[15..11] [00000000110] */
    kMipsSubu,    /* subu d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100011] */
    kMipsSw,      /* sw t,o(b) [101011] b[25..21] t[20..16] o[15..0] */
    kMipsXor,     /* xor d,s,t [000000] s[25..21] t[20..16] d[15..11] [00000100110] */
    kMipsXori,    /* xori t,s,imm16 [001110] s[25..21] t[20..16] imm16[15..0] */
#ifdef __mips_hard_float
    kMipsFadds,   /* add.s d,s,t [01000110000] t[20..16] s[15..11] d[10..6] [000000] */
    kMipsFsubs,   /* sub.s d,s,t [01000110000] t[20..16] s[15..11] d[10..6] [000001] */
    kMipsFmuls,   /* mul.s d,s,t [01000110000] t[20..16] s[15..11] d[10..6] [000010] */
    kMipsFdivs,   /* div.s d,s,t [01000110000] t[20..16] s[15..11] d[10..6] [000011] */
    kMipsFaddd,   /* add.d d,s,t [01000110001] t[20..16] s[15..11] d[10..6] [000000] */
    kMipsFsubd,   /* sub.d d,s,t [01000110001] t[20..16] s[15..11] d[10..6] [000001] */
    kMipsFmuld,   /* mul.d d,s,t [01000110001] t[20..16] s[15..11] d[10..6] [000010] */
    kMipsFdivd,   /* div.d d,s,t [01000110001] t[20..16] s[15..11] d[10..6] [000011] */
    kMipsFcvtsd,  /* cvt.s.d d,s [01000110001] [00000] s[15..11] d[10..6] [100000] */
    kMipsFcvtsw,  /* cvt.s.w d,s [01000110100] [00000] s[15..11] d[10..6] [100000] */
    kMipsFcvtds,  /* cvt.d.s d,s [01000110000] [00000] s[15..11] d[10..6] [100001] */
    kMipsFcvtdw,  /* cvt.d.w d,s [01000110100] [00000] s[15..11] d[10..6] [100001] */
    kMipsFcvtws,  /* cvt.w.d d,s [01000110000] [00000] s[15..11] d[10..6] [100100] */
    kMipsFcvtwd,  /* cvt.w.d d,s [01000110001] [00000] s[15..11] d[10..6] [100100] */
    kMipsFmovs,   /* mov.s d,s [01000110000] [00000] s[15..11] d[10..6] [000110] */
    kMipsFmovd,   /* mov.d d,s [01000110001] [00000] s[15..11] d[10..6] [000110] */
    kMipsFlwc1,   /* lwc1 t,o(b) [110001] b[25..21] t[20..16] o[15..0] */
    kMipsFldc1,   /* ldc1 t,o(b) [110101] b[25..21] t[20..16] o[15..0] */
    kMipsFswc1,   /* swc1 t,o(b) [111001] b[25..21] t[20..16] o[15..0] */
    kMipsFsdc1,   /* sdc1 t,o(b) [111101] b[25..21] t[20..16] o[15..0] */
    kMipsMfc1,    /* mfc1 t,s [01000100000] t[20..16] s[15..11] [00000000000] */
    kMipsMtc1,    /* mtc1 t,s [01000100100] t[20..16] s[15..11] [00000000000] */
#endif
    kMipsUndefined,  /* undefined [011001xxxxxxxxxxxxxxxx] */
    kMipsLast
} MipsOpCode;

/* Bit flags describing the behavior of each native opcode */
typedef enum MipsOpFeatureFlags {
    kIsBranch = 0,
    kRegDef0,
    kRegDef1,
    kRegDefSP,
    kRegDefLR,
    kRegDefList0,
    kRegDefList1,
    kRegUse0,
    kRegUse1,
    kRegUse2,
    kRegUse3,
    kRegUseSP,
    kRegUsePC,
    kRegUseList0,
    kRegUseList1,
    kNoOperand,
    kIsUnaryOp,
    kIsBinaryOp,
    kIsTertiaryOp,
    kIsQuadOp,
    kIsIT,
    kSetsCCodes,
    kUsesCCodes,
    kMemLoad,
    kMemStore,
} MipsOpFeatureFlags;

#define IS_LOAD         (1 << kMemLoad)
#define IS_STORE        (1 << kMemStore)
#define IS_BRANCH       (1 << kIsBranch)
#define REG_DEF0        (1 << kRegDef0)
#define REG_DEF1        (1 << kRegDef1)
#define REG_DEF_SP      (1 << kRegDefSP)
#define REG_DEF_LR      (1 << kRegDefLR)
#define REG_DEF_LIST0   (1 << kRegDefList0)
#define REG_DEF_LIST1   (1 << kRegDefList1)
#define REG_USE0        (1 << kRegUse0)
#define REG_USE1        (1 << kRegUse1)
#define REG_USE2        (1 << kRegUse2)
#define REG_USE3        (1 << kRegUse3)
#define REG_USE_SP      (1 << kRegUseSP)
#define REG_USE_PC      (1 << kRegUsePC)
#define REG_USE_LIST0   (1 << kRegUseList0)
#define REG_USE_LIST1   (1 << kRegUseList1)
#define NO_OPERAND      (1 << kNoOperand)
#define IS_UNARY_OP     (1 << kIsUnaryOp)
#define IS_BINARY_OP    (1 << kIsBinaryOp)
#define IS_TERTIARY_OP  (1 << kIsTertiaryOp)
#define IS_QUAD_OP      (1 << kIsQuadOp)
#define IS_IT           (1 << kIsIT)
#define SETS_CCODES     (1 << kSetsCCodes)
#define USES_CCODES     (1 << kUsesCCodes)

/* Common combo register usage patterns */
#define REG_USE01       (REG_USE0 | REG_USE1)
#define REG_USE02       (REG_USE0 | REG_USE2)
#define REG_USE012      (REG_USE01 | REG_USE2)
#define REG_USE12       (REG_USE1 | REG_USE2)
#define REG_USE23       (REG_USE2 | REG_USE3)
#define REG_DEF01       (REG_DEF0 | REG_DEF1)
#define REG_DEF0_USE0   (REG_DEF0 | REG_USE0)
#define REG_DEF0_USE1   (REG_DEF0 | REG_USE1)
#define REG_DEF0_USE2   (REG_DEF0 | REG_USE2)
#define REG_DEF0_USE01  (REG_DEF0 | REG_USE01)
#define REG_DEF0_USE12  (REG_DEF0 | REG_USE12)
#define REG_DEF01_USE2  (REG_DEF0 | REG_DEF1 | REG_USE2)

/* Instruction assembly fieldLoc kind */
typedef enum MipsEncodingKind {
    kFmtUnused,
    kFmtBitBlt,        /* Bit string using end/start */
    kFmtDfp,           /* Double FP reg */
    kFmtSfp,           /* Single FP reg */
} MipsEncodingKind;

/* Struct used to define the snippet positions for each Thumb opcode */
typedef struct MipsEncodingMap {
    u4 skeleton;
    struct {
        MipsEncodingKind kind;
        int end;   /* end for kFmtBitBlt, 1-bit slice end for FP regs */
        int start; /* start for kFmtBitBlt, 4-bit slice end for FP regs */
    } fieldLoc[4];
    MipsOpCode opcode;
    int flags;
    const char *name;
    const char* fmt;
    int size;
} MipsEncodingMap;

/* Keys for target-specific scheduling and other optimization hints */
typedef enum MipsTargetOptHints {
    kMaxHoistDistance,
} MipsTargetOptHints;

extern MipsEncodingMap EncodingMap[kMipsLast];

/*
 * Each instance of this struct holds a pseudo or real LIR instruction:
 * - pseudo ones (eg labels and marks) and will be discarded by the assembler.
 * - real ones will be assembled into Thumb instructions.
 *
 * Machine resources are encoded into a 64-bit vector, where the encodings are
 * as following:
 * - [ 0..15]: general purpose registers including PC, SP, and LR
 * - [16..47]: floating-point registers where d0 is expanded to s[01] and s0
 *   starts at bit 16
 * - [48]: IT block
 * - [49]: integer condition code
 * - [50]: floatint-point status word
 */
typedef struct MipsLIR {
    LIR generic;
    MipsOpCode opcode;
    int operands[4];            // [0..3] = [dest, src1, src2, extra]
    struct {
        bool isNop:1;           // LIR is optimized away
        bool insertWrapper:1;   // insert branch to emulate memory accesses
        unsigned int age:4;     // default is 0, set lazily by the optimizer
        unsigned int size:3;    // bytes (2 for thumb, 2/4 for thumb2)
        unsigned int unused:23;
    } flags;
    int aliasInfo;              // For Dalvik register access & litpool disambiguation
    u8 useMask;                 // Resource mask for use
    u8 defMask;                 // Resource mask for def
} MipsLIR;

/* Init values when a predicted chain is initially assembled */
/* E7FE is branch to self */
#define PREDICTED_CHAIN_BX_PAIR_INIT     0xe7fe
#define PREDICTED_CHAIN_DELAY_SLOT_INIT  0
#define PREDICTED_CHAIN_CLAZZ_INIT       0
#define PREDICTED_CHAIN_METHOD_INIT      0
#define PREDICTED_CHAIN_COUNTER_INIT     0

/* Utility macros to traverse the LIR/MipsLIR list */
#define NEXT_LIR(lir) ((MipsLIR *) lir->generic.next)
#define PREV_LIR(lir) ((MipsLIR *) lir->generic.prev)

#define NEXT_LIR_LVALUE(lir) (lir)->generic.next
#define PREV_LIR_LVALUE(lir) (lir)->generic.prev

#define CHAIN_CELL_OFFSET_TAG   0xcdabcdabL

#define IS_UIMM16(v) ((0 <= (v)) && ((v) <= 65535))
#define IS_SIMM16(v) ((-32768 <= (v)) && ((v) <= 32766))
#define IS_SIMM16_2WORD(v) ((-32764 <= (v)) && ((v) <= 32763)) /* 2 offsets must fit */

#define CHAIN_CELL_NORMAL_SIZE    16
#define CHAIN_CELL_PREDICTED_SIZE 20


#endif  // DALVIK_VM_COMPILER_CODEGEN_MIPS_MIPSLIR_H_