/* disarm -- a simple disassembler for ARM instructions * (c) 2000 Gareth McCaughan * * This file may be distributed and used freely provided: * 1. You do not distribute any version that lacks this * copyright notice (exactly as it appears here, extending * from the start to the end of the C-language comment * containing these words)); and, * 2. If you distribute any modified version, its source * contains a clear description of the ways in which * it differs from the original version, and a clear * indication that the changes are not mine. * There is no restriction on your permission to use and * distribute object code or executable code derived from * this. * * The original version of this file (or perhaps a later * version by the original author) may or may not be * available at http://web.ukonline.co.uk/g.mccaughan/g/software.html . * * Share and enjoy! -- g */ /* (*This* comment is NOT part of the notice mentioned in the * distribution conditions above.) * * The bulk of this code was ripped brutally from the middle * of a much more interesting piece of software whose purpose * is to disassemble object files in the format known as AOF; * it's quite clever at spotting blocks of non-code embedded * in code, identifying labels, and so on. * * This program, on the other hand, is very much simpler. * It simply disassembles one instruction at a time. Some * traces of the original purpose can be seen here and there. * You might want to make this do a two-phase disassembly, * adding labels etc the second time around. I've made this * work by loading the whole file into memory first, partly * because that makes a two-pass approach easier. * * One word of warning: I believe that the syntax this program * uses for the MSR instruction is now obsolete. * * Usage: * disarm * will disassemble every word in . * * should be something understood by strtol. * So you can get hex (which is probably what you want) * by prefixing "0x". * * The -r option will byte-reverse each word before it's * disassembled. * * The code is rather unmaintainable. I'm sorry. * * Changes since original release: * ????-??-?? v0.00 Initial release. * 2007-09-02 v0.11 Change %X to %lX in a format string. * (Thanks to Vincent Zweije for reporting this.) */ #ifdef __clang__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wtautological-compare" //used to avoid warning, force compiler to accept it. #pragma GCC diagnostic ignored "-Wstring-plus-int" #endif #include #include #include #include "base/basictypes.h" #include "Common/ArmEmitter.h" static const char *CCFlagsStr[] = { "EQ", // Equal "NEQ", // Not equal "CS", // Carry Set "CC", // Carry Clear "MI", // Minus (Negative) "PL", // Plus "VS", // Overflow "VC", // No Overflow "HI", // Unsigned higher "LS", // Unsigned lower or same "GE", // Signed greater than or equal "LT", // Signed less than "GT", // Signed greater than "LE", // Signed less than or equal "", // Always (unconditional) 14 }; int GetVd(uint32_t op, bool quad = false, bool dbl = false) { int val; if (!quad && !dbl) { val = ((op >> 22) & 1) | ((op >> 11) & 0x1E); } else { val = ((op >> 18) & 0x10) | ((op >> 12) & 0xF); } if (quad) val >>= 1; return val; } int GetVn(uint32_t op, bool quad = false, bool dbl = false) { int val; if (!quad && !dbl) { val = ((op >> 7) & 1) | ((op >> 15) & 0x1E); } else { val = ((op >> 16) & 0xF) | ((op >> 3) & 0x10); } if (quad) val >>= 1; return val; } int GetVm(uint32_t op, bool quad = false, bool dbl = false) { int val; if (!quad && !dbl) { val = ((op >> 5) & 1) | ((op << 1) & 0x1E); } else { val = ((op >> 1) & 0x10) | (op & 0xF); } if (quad) val >>= 1; return val; } // Modern VFP disassembler, written entirely separately because I can't figure out the old stuff :P // Horrible array of hacks but hey. Can be cleaned up later. bool DisasmVFP(uint32_t op, char *text) { #if defined(ANDROID) && defined(_M_IX86) // Prevent linking errors with ArmEmitter which I've excluded on x86 android. strcpy(text, "ARM disasm not available"); #else const char *cond = CCFlagsStr[op >> 28]; switch ((op >> 24) & 0xF) { case 0xC: // VLDMIA/VSTMIA { bool single_reg = ((op >> 8) & 0xF) == 10; int freg = ((op >> 11) & 0x1E) | ((op >> 22) & 1); int base = (op >> 16) & 0xF; bool load = (op >> 20) & 1; bool writeback = (op >> 21) & 1; int numregs = op & 0xF; bool add = (op >> 23) & 1; if (add && writeback && load && base == 13) { if (single_reg) sprintf(text, "VPOP%s {s%i-s%i}", cond, freg, freg-1+numregs); else sprintf(text, "VPOP%s {d%i-d%i}", cond, freg, freg-1+(numregs/2)); return true; } if (single_reg) sprintf(text, "%s%s r%i%s, {s%i-s%i}", load ? "VLDMIA" : "VSTMIA", cond, base, writeback ? "!":"", freg, freg-1+numregs); else sprintf(text, "%s%s r%i%s, {d%i-d%i}", load ? "VLDMIA" : "VSTMIA", cond, base, writeback ? "!":"", freg, freg-1+(numregs/2)); return true; } case 0xD: // VLDR/VSTR/VLDMDB/VSTMDB { bool single_reg = ((op >> 8) & 0xF) == 10; int freg = ((op >> 11) & 0x1E) | ((op >> 22) & 1); int base = (op >> 16) & 0xF; bool load = (op >> 20) & 1; bool add = (op >> 23) & 1; bool writeback = (op >> 21) & 1; if (writeback) { // Multiple int numregs = op & 0xF; if (!add && !load && base == 13) { if (single_reg) sprintf(text, "VPUSH%s {s%i-s%i}", cond, freg, freg-1+numregs); else sprintf(text, "VPUSH%s {d%i-d%i}", cond, freg, freg-1+(numregs/2)); return true; } if (single_reg) sprintf(text, "%s%s r%i, {s%i-s%i}", load ? "VLDMDB" : "VSTMDB", cond, base, freg, freg-1+numregs); else sprintf(text, "%s%s r%i, {d%i-d%i}", load ? "VLDMDB" : "VSTMDB", cond, base, freg, freg-1+(numregs/2)); } else { int offset = (op & 0xFF) << 2; if (!add) offset = -offset; sprintf(text, "%s%s s%i, [r%i, #%i]", load ? "VLDR" : "VSTR", cond, freg, base, offset); } return true; } case 0xE: { switch ((op >> 20) & 0xF) { case 0xE: // VMSR if ((op & 0xFFF) != 0xA10) break; sprintf(text, "VMSR%s r%i", cond, (op >> 12) & 0xF); return true; case 0xF: // VMRS if ((op & 0xFFF) != 0xA10) break; if (op == 0xEEF1FA10) { sprintf(text, "VMRS%s APSR", cond); } else { sprintf(text, "VMRS%s r%i", cond, (op >> 12) & 0xF); } return true; default: break; } if (((op >> 19) & 0x7) == 0x7) { // VCVT sprintf(text, "VCVT ..."); return true; } int part1 = ((op >> 23) & 0x1F); int part2 = ((op >> 9) & 0x7) ; int part3 = ((op >> 20) & 0x3) ; if (part3 == 3 && part2 == 5 && part1 == 0x1D && (op & (1<<6))) { // VMOV, VCMP int vn = GetVn(op); if (vn != 1 && vn != 3) { int vm = GetVm(op); int vd = GetVd(op); const char *name = "VMOV"; if (op & 0x40000) name = (op & 0x80) ? "VCMPE" : "VCMP"; sprintf(text, "%s%s s%i, s%i", name, cond, vd, vm); return true; } } // Arithmetic (buggy!) bool quad_reg = (op >> 6) & 1; bool double_reg = (op >> 8) & 1; int opnum = -1; int opc1 = (op >> 20) & 0xFB; int opc2 = (op >> 4) & 0xAC; for (int i = 0; i < 16; i++) { // What the hell? int fixed_opc2 = opc2; if (!(ArmGen::VFPOps[i][0].opc2 & 0x8)) fixed_opc2 &= 0xA7; if (ArmGen::VFPOps[i][0].opc1 == opc1 && ArmGen::VFPOps[i][0].opc2 == fixed_opc2) { opnum = i; break; } } if (opnum < 0) return false; char c = double_reg ? 'd' : 's'; switch (opnum) { case 8: case 10: case 11: case 12: case 13: case 14: { quad_reg = false; int vd = GetVd(op, quad_reg, double_reg); int vn = GetVn(op, quad_reg, true); int vm = GetVm(op, quad_reg, double_reg); if (opnum == 8 && vn == 0x11) opnum += 3; sprintf(text, "%s%s %c%i, %c%i", ArmGen::VFPOpNames[opnum], cond, c, vd, c, vm); return true; } default: { quad_reg = false; int vd = GetVd(op, quad_reg, double_reg); int vn = GetVn(op, quad_reg, double_reg); int vm = GetVm(op, quad_reg, double_reg); sprintf(text, "%s%s %c%i, %c%i, %c%i", ArmGen::VFPOpNames[opnum], cond, c, vd, c, vn, c, vm); return true; } } return true; } break; } #endif return false; } static const char *GetSizeString(int sz) { switch (sz) { case 0: return "8"; case 1: return "16"; case 2: return "32"; case 3: return "64"; default: return "(err)"; } } static const char *GetISizeString(int sz) { switch (sz) { case 0: return "i8"; case 1: return "i16"; case 2: return "i32"; case 3: return "i64"; default: return "(err)"; } } static int GetRegCount(int type) { switch (type) { case 7: return 1; case 10: return 2; case 6: return 3; case 4: return 4; default: return 0; } } // VLD1 / VST1 static bool DisasmNeonLDST(uint32_t op, char *text) { bool load = (op >> 21) & 1; int Rn = (op >> 16) & 0xF; int Rm = (op & 0xF); int Vd = GetVd(op, false, true); int sz = (op >> 6) & 3; int regCount = GetRegCount((op >> 8) & 0xF); int startReg = Vd; int endReg = Vd + regCount - 1; if (startReg == endReg) sprintf(text, "V%s1.%s {d%i}, [r%i]", load ? "LD" : "ST", GetSizeString(sz), startReg, Rn); else sprintf(text, "V%s1.%s {d%i-d%i}, [r%i]", load ? "LD" : "ST", GetSizeString(sz), startReg, endReg, Rn); return true; } static bool DisasmNeonF2F3(uint32_t op, char *text) { sprintf(text, "NEON F2"); if (((op >> 20) & 0xFFC) == 0xF20 || ((op >> 20) & 0xFFC) == 0xF30) { bool quad = ((op >> 6) & 1); int size = (op >> 20) & 3; int type = (op >> 8) & 0xF; char r = quad ? 'q' : 'd'; const char *opname = "(unk)"; switch ((op >> 20) & 0xFF) { case 0x20: if (op & 0x10) opname = "MLA"; else opname = "ADD"; break; case 0x22: if (op & 0x10) opname = "MLS"; else opname = "ADD"; break; case 0x31: if (op & 0x100) opname = "MLS"; else opname = "SUB"; break; case 0x30: opname = "MUL"; break; } const char *szname = GetISizeString(size); if (type == 0xD) szname = "f32"; sprintf(text, "V%s.%s %c%i, %c%i, %c%i", opname, szname, r, GetVd(op, quad, true), r, GetVn(op, quad, true), r, GetVm(op, quad, true)); } return true; } static bool DisasmNeon(uint32_t op, char *text) { switch (op >> 24) { case 0xF4: return DisasmNeonLDST(op, text); case 0xF2: case 0xF3: return DisasmNeonF2F3(op, text); } return false; } typedef unsigned int word; typedef unsigned int address; typedef unsigned int addrdiff; #define W(x) ((word*)(x)) #define declstruct(name) typedef struct name s##name, * p##name #define defstruct(name) struct name #define defequiv(new,old) typedef struct old s##new, * p##new declstruct(DisOptions); declstruct(Instruction); typedef enum { target_None, /* instruction doesn't refer to an address */ target_Data, /* instruction refers to address of data */ target_FloatS, /* instruction refers to address of single-float */ target_FloatD, /* instruction refers to address of double-float */ target_FloatE, /* blah blah extended-float */ target_FloatP, /* blah blah packed decimal float */ target_Code, /* instruction refers to address of code */ target_Unknown /* instruction refers to address of *something* */ } eTargetType; defstruct(Instruction) { char text[128]; /* the disassembled instruction */ int undefined; /* non-0 iff it's an undefined instr */ int badbits; /* non-0 iff something reserved has the wrong value */ int oddbits; /* non-0 iff something unspecified isn't 0 */ int is_SWI; /* non-0 iff it's a SWI */ word swinum; /* only set for SWIs */ address target; /* address instr refers to */ eTargetType target_type; /* and what we expect to be there */ int offset; /* offset from register in LDR or STR or similar */ char * addrstart; /* start of address part of instruction, or 0 */ }; #define disopt_SWInames 1 /* use names, not &nnnn */ #define disopt_CommaSpace 2 /* put spaces after commas */ #define disopt_FIXS 4 /* bogus FIX syntax for ObjAsm */ #define disopt_ReverseBytes 8 /* byte-reverse words first */ defstruct(DisOptions) { word flags; const char * * regnames; /* pointer to 16 |char *|s: register names */ }; static pInstruction instr_disassemble(word, address, pDisOptions); #define INSTR_grok_v4 /* Preprocessor defs you can give to affect this stuff: * INSTR_grok_v4 understand ARMv4 instructions (halfword & sign-ext LDR/STR) * INSTR_new_msr be prepared to produce new MSR syntax if asked * The first of these is supported; the second isn't. */ /* Some important single-bit fields. */ #define Sbit (1<<20) /* set condition codes (data processing) */ #define Lbit (1<<20) /* load, not store (data transfer) */ #define Wbit (1<<21) /* writeback (data transfer) */ #define Bbit (1<<22) /* single byte (data transfer, SWP) */ #define Ubit (1<<23) /* up, not down (data transfer) */ #define Pbit (1<<24) /* pre-, not post-, indexed (data transfer) */ #define Ibit (1<<25) /* non-immediate (data transfer) */ /* immediate (data processing) */ #define SPSRbit (1<<22) /* SPSR, not CPSR (MRS, MSR) */ /* Some important 4-bit fields. */ #define RD(x) ((x)<<12) /* destination register */ #define RN(x) ((x)<<16) /* operand/base register */ #define CP(x) ((x)<<8) /* coprocessor number */ #define RDbits RD(15) #define RNbits RN(15) #define CPbits CP(15) #define RD_is(x) ((instr&RDbits)==RD(x)) #define RN_is(x) ((instr&RNbits)==RN(x)) #define CP_is(x) ((instr&CPbits)==CP(x)) /* A slightly efficient way of telling whether two bits are the same * or not. It's assumed that a>(b-a)))&(1<=0; i-=4) *op++ = "0123456789ABCDEF"[(w>>i)&15]; return op; } /* op = reg(op,'x',n) === op += sprintf(op,"x%lu",n&15). */ static char * reg(char * op, char c, word n) { *op++=c; n&=15; if (n>=10) { *op++='1'; n+='0'-10; } else n+='0'; *op++=(char)n; return op; } /* op = num(op,n) appends n in decimal or &n in hex * depending on whether n<100. It's assumed that n>=0. */ static char * num(char * op, word w) { if (w>=100) { int i; word t; *op++='&'; for (i=28; (t=(w>>i)&15)==0; i-=4) ; for (; i>=0; i-=4) *op++ = "0123456789ABCDEF"[(w>>i)&15]; } else { /* divide by 10. You can prove this works by exhaustive search. :-) */ word t = w-(w>>2); t=(t+(t>>4)) >> 3; { word u = w-10*t; if (u==10) { u=0; ++t; } if (t) *op++=(char)(t+'0'); *op++=(char)(u+'0'); } } return op; } /* instr_disassemble * Disassemble a single instruction. * * args: instr a single ARM instruction * addr the address it's presumed to have come from * opts cosmetic preferences for our output * * reqs: opts must be filled in right. In particular, it must contain * a list of register names. * * return: a pointer to a structure containing the disassembled instruction * and some other information about it. * * This is basically a replacement for the SWI Debugger_Disassemble, * but it has the following advantages: * * + it's 3-4 times as fast * + it's better at identifying undefined instructions, * and instructions not invariant under { disassemble; ObjAsm; } * + it provides some other useful information as well * + its output syntax is the same as ObjAsm's input syntax * (where possible) * + it doesn't disassemble FIX incorrectly unless you ask it to * + it's more configurable in some respects * * It also has the following disadvantages: * * - it increases the size of ObjDism * - it doesn't provide so many `helpful' usage comments etc * - it's less configurable in some respects * - it doesn't (yet) know about ARMv4 instructions * * This function proceeds in two phases. The first is very simple: * it works out what sort of instruction it's looking at and sets up * three strings: * - |mnemonic| (the basic mnemonic: LDR or whatever) * - |flagchars| (things to go after the cond code: B or whatever) * - |format| (a string describing how to display the instruction) * The second phase consists of interpreting |format|, character by * character. Some characters (e.g., letters) just mean `append this * character to the output string'; some mean more complicated things * like `append the name of the register whose number is in bits 12..15' * or, worse, `append a description of the field'. * * I'm afraid the magic characters in |format| are rather arbitrary. * One criterion in choosing them was that they should form a contiguous * subrange of the character set! Sorry. * * Things I still want to do: * * - more configurability? * - make it much faster, if possible * - make it much smaller, if possible * * Format characters: * * \01..\05 copro register number from nybble (\001 == nybble 0, sorry) * $ SWI number * % register set for LDM/STM (takes note of bit 22 for ^) * & address for B/BL * ' ! if bit 21 set, else nothing (mnemonic: half a !) * ( #regs for SFM (bits 22,15 = fpn, assumed already tweaked) * ) copro opcode in bits 20..23 (for CDP) * * op2 (takes note of bottom 12 bits, and bit 25) * + FP register or immediate value: bits 0..3 * , comma or comma-space * - copro extra info in bits 5..7 preceded by , omitted if 0 * . address in ADR instruction * / address for LDR/STR (takes note of bit 23 & reg in bits 16..19) * 0..4 register number from nybble * 5..9 FP register number from nybble * : copro opcode in bits 21..23 (for MRC/MCR) * ; copro number in bits 8..11 * * ADDED BY HRYDGARD: * ^ 16-bit immediate * > 5-bit immediate at 11..7 (lsb) * < 5-bit immediate at 20..16 with +1 or -lsb if bit 6 set * * NB that / takes note of bit 22, too, and does its own ! when * appropriate. * * On typical instructions this seems to take about 100us on my ARM6; * that's about 3000 cycles, which seems grossly excessive. I'm not * sure where all those cycles are being spent. Perhaps it's possible * to make it much, much faster. Most of this time is spent on phase 2. */ extern pInstruction instr_disassemble(word instr, address addr, pDisOptions opts) { static char flagchars[4]; static sInstruction result; const char * mnemonic = 0; char * flagp = flagchars; const char * format = 0; word fpn; eTargetType poss_tt = target_None; #ifdef INSTR_grok_v4 int is_v4 = 0; #endif /* PHASE 0. Set up default values for |result|. */ if (opts->flags & disopt_ReverseBytes) { instr = ((instr & 0xFF00FF00) >> 8) | ((instr & 0x00FF00FF) << 8); instr = (instr >> 16) | (instr << 16); } fpn = ((instr>>15)&1) + ((instr>>21)&2); result.undefined = 0; result.badbits = 0; result.oddbits = 0; result.is_SWI = 0; result.target_type = target_None; result.offset = 0x80000000; result.addrstart = 0; /* PHASE 1. Decode and classify instruction. */ switch ((instr>>24)&15) { case 0: /* multiply or data processing, or LDRH etc */ if ((instr&(15<<4))!=(9<<4)) goto lMaybeLDRHetc; /* multiply */ if (instr&(1<<23)) { /* int multiply */ mnemonic = "UMULL\0UMLAL\0SMULL\0SMLAL" + 6*((instr>>21)&3); format = "3,4,0,2"; } else { if (instr&(1<<22)) goto lUndefined; /* "class C" */ /* short multiply */ if (instr&(1<<21)) { mnemonic = "MLA"; format = "4,0,2,3"; } else { mnemonic = "MUL"; format = "4,0,2"; } } if (instr&Sbit) *flagp++='S'; break; case 1: if ((instr & 0x0FFFFFF0) == ((18 << 20) | (0xFFF << 8) | (1 << 4))) { mnemonic = "B"; format = "0"; break; } else if ((instr & 0x0FFFFFF0) == 0x012FFF30) { mnemonic = "BL"; format = "0"; break; } else if ((instr & 0x0FF000F0) == 0x01200070) { int imm = ((instr & 0xFFF00) >> 4) | (instr & 0xF); snprintf(result.text, sizeof(result.text), "BKPT %d", imm); result.undefined = 0; return &result; } case 3: if (instr >> 24 == 0xF3) { if (!DisasmNeon(instr, result.text)) { goto lUndefined; break; } result.undefined = 0; return &result; } /* SWP or MRS/MSR or data processing */ // hrydgard addition: MOVW/MOVT if ((instr & 0x0FF00000) == 0x03000000) { mnemonic = "MOVW"; format = "3,^"; break; } else if ((instr & 0x0FF00000) == 0x03400000) { mnemonic = "MOVT"; format = "3,^"; break; } else if ((instr&0x02B00FF0)==0x00000090) { /* SWP */ mnemonic = "SWP"; format = "3,0,[4]"; if (instr&Bbit) *flagp++='B'; break; } else if ((instr&0x02BF0FFF)==0x000F0000) { /* MRS */ mnemonic = "MRS"; format = (instr&SPSRbit) ? "3,SPSR" : "3,CPSR"; break; } else if ((instr&0x02BFFFF0)==0x0029F000) { /* MSR psr,Rs */ mnemonic = "MSR"; format = (instr&SPSRbit) ? "SPSR,0" : "CPSR,0"; break; } else if ((instr&0x00BFF000)==0x0028F000) { /* MSR {C,S}PSR_flag,op2 */ mnemonic = "MSR"; format = (instr&SPSRbit) ? "SPSR_flg,*" : "CPSR_flg,*"; if (!(instr&Ibit) && (instr&(15<<4))) #ifdef INSTR_grok_v4 goto lMaybeLDRHetc; #else goto lUndefined; /* shifted reg in MSR illegal */ #endif break; } /* fall through here */ lMaybeLDRHetc: #ifdef INSTR_grok_v4 if ((instr&(14<<24))==0 && ((instr&(9<<4))==(9<<4))) { /* Might well be LDRH or similar. */ if ((instr&(Wbit+Pbit))==Wbit) goto lUndefined; /* "class E", case 1 */ if ((instr&(Lbit+(1<<6)))==(1<<6)) goto lUndefined; /* STRSH etc */ mnemonic = "STR\0LDR" + ((instr&Lbit) >> 18); if (instr&(1<<6)) *flagp++='S'; *flagp++ = (instr&(1<<5)) ? 'B' : 'H'; format = "3,/"; /* aargh: */ if (!(instr&(1<<22))) instr |= Ibit; is_v4=1; break; } #endif case 2: if (instr >> 24 == 0xF2) { if (!DisasmNeon(instr, result.text)) { goto lUndefined; break; } result.undefined = 0; return &result; } /* data processing */ { word op21 = instr&(15<<21); if ((op21==(2<<21) || (op21==(4<<21))) /* ADD or SUB */ && ((instr&(RNbits+Ibit+Sbit))==RN(15)+Ibit) /* imm, no S */ /*&& ((instr&(30<<7))==0 || (instr&3))*/) { /* normal rot */ /* ADD ...,pc,#... or SUB ...,pc,#...: turn into ADR */ mnemonic = "ADR"; format = "3,."; if ((instr&(30<<7))!=0 && !(instr&3)) result.oddbits=1; break; } mnemonic = "AND\0EOR\0SUB\0RSB\0ADD\0ADC\0SBC\0RSC\0" "TST\0TEQ\0CMP\0CMN\0ORR\0MOV\0BIC\0MVN" /* \0 */ + (op21 >> 19); /* Rd needed for all but TST,TEQ,CMP,CMN (8..11) */ /* Rn needed for all but MOV,MVN (13,15) */ if (op21 < ( 8<<21)) format = "3,4,*"; else if (op21 < (12<<21)) { format = "4,*"; if (instr&RDbits) { if ((instr&Sbit) && RD_is(15)) *flagp++='P'; else result.oddbits=1; } if (!(instr&Sbit)) goto lUndefined; /* CMP etc, no S bit */ } else if (op21 & (1<<21)) { format = "3,*"; if (instr&RNbits) result.oddbits=1; } else format = "3,4,*"; if (instr&Sbit && (op21<(8<<21) || op21>=(12<<21))) *flagp++='S'; } break; case 4: if (instr >> 24 == 0xF4) { if (!DisasmNeon(instr, result.text)) { goto lUndefined; break; } result.undefined = 0; return &result; } case 5: case 6: case 7: /* STR/LDR/BFI/BFC/UBFX/SBFX or undefined */ if ((instr&Ibit) && (instr&(1<<4))) { switch ((instr >> 21) & 7) { case 5: case 7: /* SBFX/UBFX */ if (((instr>>4) & 7) != 5) { goto lUndefined; } mnemonic = (instr & (1 << 22)) ? "UBFX" : "SBFX"; format = "3,0,>,<"; break; case 6: /* BFI/BFC */ if (((instr>>4) & 7) != 1) { goto lUndefined; } if ((instr & 15) == 15) { mnemonic = "BFC"; format = "3,>,<"; } else { mnemonic = "BFI"; format = "3,0,>,<"; } break; default: goto lUndefined; /* "class A" */ } } else { mnemonic = "STR\0LDR" + ((instr&Lbit) >> 18); format = "3,/"; if (instr&Bbit) *flagp++='B'; if ((instr&(Wbit+Pbit))==Wbit) *flagp++='T'; poss_tt = target_Data; } break; case 8: case 9: /* STM/LDM */ mnemonic = "STM\0LDM" + ((instr&Lbit) >> 18); if (RN_is(13)) { /* r13, so treat as stack */ word x = (instr&(3<<23)) >> 22; if (instr&Lbit) x^=6; { const char * foo = "EDEAFDFA"+x; *flagp++ = *foo++; *flagp++ = *foo; } } else { /* not r13, so don't treat as stack */ *flagp++ = (instr&Ubit) ? 'I' : 'D'; *flagp++ = (instr&Pbit) ? 'B' : 'A'; } format = "4',%"; break; case 10: case 11: /* B or BL */ mnemonic = "B\0BL"+((instr&(1<<24))>>23); format = "&"; break; case 12: case 13: case 14: // FPU { if (!DisasmVFP(instr, result.text)) { goto lUndefined; break; } result.undefined = 0; return &result; } break; case 15: /* SWI */ mnemonic = "SWI"; format = "$"; break; /* Nasty hack: this is code that won't be reached in the normal * course of events, and after the last case of the switch is a * convenient place for it. */ lUndefined: strcpy(result.text, "Undefined instruction"); result.undefined = 1; return &result; } *flagp=0; /* PHASE 2. Produce string. */ { char * op = result.text; /* 2a. Mnemonic. */ op = append(op,mnemonic); /* 2b. Condition code. */ { word cond = instr>>28; if (cond!=14) { const char * ip = "EQNECSCCMIPLVSVCHILSGELTGTLEALNV"+2*cond; *op++ = *ip++; *op++ = *ip; } } /* 2c. Flags. */ { const char * ip = flagchars; while (*ip) *op++ = *ip++; } /* 2d. A tab character. */ *op++ = '\t'; /* 2e. Other stuff, determined by format string. */ { const char * ip = format; char c; const char * * regnames = opts->regnames; word oflags = opts->flags; while ((c=*ip++) != 0) { switch(c) { case '^': // hrydgard addition { unsigned short imm16 = ((instr & 0x000F0000) >> 4) | (instr & 0x0FFF); op += sprintf(op, "%04x", imm16); } break; case '$': result.is_SWI = 1; result.swinum = instr&0x00FFFFFF; result.addrstart = op; op += sprintf(op, "&%X", result.swinum); break; case '%': *op++='{'; { word w = instr&0xFFFF; int i=0; while (w) { int j; while (!(w&(1ul<1) ? '-' : ','; op = append(op, regnames[j]); } i=j; w=(w>>(j+1))<<(j+1); if (w) *op++=','; } } *op++='}'; if (instr&(1<<22)) *op++='^'; break; case '&': { address target = (addr+8 + ((((int)instr)<<8)>>6)) & 0x03FFFFFC; result.addrstart = op; op = hex8(op, target); result.target_type = target_Code; result.target = target; } break; case '\'': lPling: if (instr&Wbit) *op++='!'; break; case '(': *op++ = (char)('0'+fpn); break; case ')': { word w = (instr>>20)&15; if (w>=10) { *op++='1'; *op++=(char)('0'-10+w); } else *op++=(char)(w+'0'); } break; case '*': case '.': if (instr&Ibit) { /* immediate constant */ word imm8 = (instr&255); word rot = (instr>>7)&30; if (rot && !(imm8&3) && c=='*') { /* Funny immediate const. Guaranteed not '.', btw */ *op++='#'; *op++='&'; *op++="0123456789ABCDEF"[imm8>>4]; *op++="0123456789ABCDEF"[imm8&15]; *op++=','; op = num(op, rot); } else { imm8 = (imm8>>rot) | (imm8<<(32-rot)); if (c=='*') { *op++='#'; if (imm8>256 && ((imm8&(imm8-1))==0)) { /* only one bit set, and that later than bit 8. * Represent as 1<<... . */ op = append(op,"1<<"); { int n=0; while (!(imm8&15)) { n+=4; imm8=imm8>>4; } /* Now imm8 is 1, 2, 4 or 8. */ n += (0x30002010 >> 4*(imm8-1))&15; op = num(op, n); } } else { if (((int)imm8)<0 && ((int)imm8)>-100) { *op++='-'; imm8=-(int)imm8; } op = num(op, imm8); } } else { address a = addr+8; if (instr&(1<<22)) a-=imm8; else a+=imm8; result.addrstart=op; op = hex8(op, a); result.target=a; result.target_type=target_Unknown; } } } else { /* rotated register */ const char * rot = "LSL\0LSR\0ASR\0ROR" + ((instr&(3<<5)) >> 3); op = append(op, regnames[instr&15]); if (instr&(1<<4)) { /* register rotation */ if (instr&(1<<7)) goto lUndefined; *op++=','; if (oflags&disopt_CommaSpace) *op++=' '; op = append(op,rot); *op++=' '; op = append(op,regnames[(instr&(15<<8))>>8]); } else { /* constant rotation */ word n = instr&(31<<7); if (!n) { if (!(instr&(3<<5))) break; else if ((instr&(3<<5))==(3<<5)) { op = append(op, ",RRX"); break; } else n=32<<7; } *op++ = ','; if (oflags&disopt_CommaSpace) *op++=' '; op = num(append(append(op,rot)," #"),n>>7); } } break; case '+': if (instr&(1<<3)) { word w = instr&7; *op++='#'; if (w<6) *op++=(char)('0'+w); else op = append(op, w==6 ? "0.5" : "10"); } else { *op++='f'; *op++=(char)('0'+(instr&7)); } break; case ',': *op++=','; if (oflags&disopt_CommaSpace) *op++=' '; break; case '-': { word w = instr&(7<<5); if (w) { *op++=','; if (oflags&disopt_CommaSpace) *op++=' '; *op++ = (char)('0'+(w>>5)); } } break; case '/': result.addrstart = op; *op++='['; op = append(op, regnames[(instr&RNbits)>>16]); if (!(instr&Pbit)) *op++=']'; *op++=','; if (oflags&disopt_CommaSpace) *op++=' '; /* For following, NB that bit 25 is always 0 for LDC, SFM etc */ if (instr&Ibit) { /* shifted offset */ if (!(instr&Ubit)) *op++='-'; /* We're going to transfer to '*', basically. The stupid * thing is that the meaning of bit 25 is reversed there; * I don't know why the designers of the ARM did that. */ instr ^= Ibit; if (instr&(1<<4)) { #ifdef INSTR_grok_v4 if (is_v4 && !(instr&(15<<8))) { ip = (instr&Pbit) ? "0]" : "0"; break; } #else goto lUndefined; /* LSL r3 forbidden */ #endif } /* Need a ] iff it was pre-indexed; and an optional ! iff * it's pre-indexed *or* a copro instruction, * except that FPU operations don't need the !. Bletch. */ if (instr&Pbit) ip="*]'"; else if (instr&(1<<27)) { if (CP_is(1) || CP_is(2)) { if (!(instr&Wbit)) goto lUndefined; ip="*"; } else ip="*'"; } else ip="*"; } else { /* immediate offset */ word offset; if (instr&(1<<27)) { /* LDF or LFM or similar */ offset = (instr&255)<<2; } #ifdef INSTR_grok_v4 else if (is_v4) offset = (instr&15) + ((instr&(15<<8))>>4); #endif else { /* LDR or STR */ offset = instr&0xFFF; } *op++='#'; if (!(instr&Ubit)) { if (offset) *op++='-'; else result.oddbits=1; result.offset = -(int)offset; } else result.offset = offset; op = num(op, offset); if (RN_is(15) && (instr&Pbit)) { /* Immediate, pre-indexed and PC-relative. Set target. */ result.target_type = poss_tt; result.target = (instr&Ubit) ? addr+8 + offset : addr+8 - offset; if (!(instr&Wbit)) { /* no writeback, either. Use friendly form. */ op = hex8(result.addrstart, result.target); break; } } if (instr&Pbit) { *op++=']'; goto lPling; } else if (instr&(1<<27)) { if (CP_is(1) || CP_is(2)) { if (!(instr&Wbit)) goto lUndefined; } else goto lPling; } } break; case '0': case '1': case '2': case '3': case '4': op = append(op, regnames[(instr>>(4*(c-'0')))&15]); break; case '5': case '6': case '7': case '8': case '9': *op++='f'; *op++=(char)('0' + ((instr>>(4*(c-'5')))&7)); break; case ':': *op++ = (char)('0' + ((instr>>21)&7)); break; case ';': op = reg(op, 'p', instr>>8); break; case '>': *op++='#'; op = num(op, (instr >> 7) & 31); break; case '<': *op++='#'; if (instr & (1 << 6)) { op = num(op, ((instr >> 16) & 31) + 1); } else { op = num(op, ((instr >> 16) & 31) + 1 - ((instr >> 7) & 31)); } break; default: if (c<=5) op = reg(op, 'c', instr >> (4*(c-1))); else *op++ = c; } } *op=0; } } /* DONE! */ return &result; } static const char * reg_names[16] = { "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "ip", "sp", "lr", "pc" }; static sDisOptions options = { disopt_CommaSpace, reg_names }; const char *ArmRegName(int r) { return reg_names[r]; } void ArmDis(unsigned int addr, unsigned int w, char *output, int bufsize, bool includeWord) { pInstruction instr = instr_disassemble(w, addr, &options); char temp[256]; if (includeWord) { sprintf(output, "%08x\t%s", w, instr->text); } else { sprintf(output, "%s", instr->text); } if (instr->undefined || instr->badbits || instr->oddbits) { if (instr->undefined) sprintf(output, " [undefined instr %08x]", w); if (instr->badbits) sprintf(output, " [illegal bits %08x]", w); // HUH? LDR and STR gets this a lot // strcat(output, " ? (extra bits)"); if (instr->oddbits) sprintf(temp, " [unexpected bits %08x]", w), strcat(output, temp); } // zap tabs while (*output) { if (*output == '\t') *output = ' '; output++; } } #ifdef __clang__ #pragma GCC diagnostic pop #endif