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Lime3DS/src/core/arm/interpreter/armemu.cpp
Lioncash 09a66860e2 arm: Throw out a lot of unnecessary code
2015-01-30 13:32:03 -05:00

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/* armemu.c -- Main instruction emulation: ARM7 Instruction Emulator.
Copyright (C) 1994 Advanced RISC Machines Ltd.
Modifications to add arch. v4 support by <jsmith@cygnus.com>.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
#include "core/arm/skyeye_common/arm_regformat.h"
#include "core/arm/skyeye_common/armdefs.h"
#include "core/arm/skyeye_common/armemu.h"
#include "core/hle/hle.h"
static ARMword GetDPRegRHS (ARMul_State *, ARMword);
static ARMword GetDPSRegRHS (ARMul_State *, ARMword);
static void WriteR15 (ARMul_State *, ARMword);
static void WriteSR15 (ARMul_State *, ARMword);
static void WriteR15Branch (ARMul_State *, ARMword);
static ARMword GetLSRegRHS (ARMul_State *, ARMword);
static ARMword GetLS7RHS (ARMul_State *, ARMword);
static unsigned LoadWord (ARMul_State *, ARMword, ARMword);
static unsigned LoadHalfWord (ARMul_State *, ARMword, ARMword, int);
static unsigned LoadByte (ARMul_State *, ARMword, ARMword, int);
static unsigned StoreWord (ARMul_State *, ARMword, ARMword);
static unsigned StoreHalfWord (ARMul_State *, ARMword, ARMword);
static unsigned StoreByte (ARMul_State *, ARMword, ARMword);
static void LoadMult (ARMul_State *, ARMword, ARMword, ARMword);
static void StoreMult (ARMul_State *, ARMword, ARMword, ARMword);
static void LoadSMult (ARMul_State *, ARMword, ARMword, ARMword);
static void StoreSMult (ARMul_State *, ARMword, ARMword, ARMword);
static unsigned Multiply64 (ARMul_State *, ARMword, int, int);
static unsigned MultiplyAdd64 (ARMul_State *, ARMword, int, int);
static void Handle_Load_Double (ARMul_State *, ARMword);
static void Handle_Store_Double (ARMul_State *, ARMword);
static int handle_v6_insn (ARMul_State * state, ARMword instr);
#define LUNSIGNED (0) /* unsigned operation */
#define LSIGNED (1) /* signed operation */
#define LDEFAULT (0) /* default : do nothing */
#define LSCC (1) /* set condition codes on result */
/* Short-hand macros for LDR/STR. */
/* Store post decrement writeback. */
#define SHDOWNWB() \
lhs = LHS ; \
if (StoreHalfWord (state, instr, lhs)) \
LSBase = lhs - GetLS7RHS (state, instr);
/* Store post increment writeback. */
#define SHUPWB() \
lhs = LHS ; \
if (StoreHalfWord (state, instr, lhs)) \
LSBase = lhs + GetLS7RHS (state, instr);
/* Store pre decrement. */
#define SHPREDOWN() \
(void)StoreHalfWord (state, instr, LHS - GetLS7RHS (state, instr));
/* Store pre decrement writeback. */
#define SHPREDOWNWB() \
temp = LHS - GetLS7RHS (state, instr); \
if (StoreHalfWord (state, instr, temp)) \
LSBase = temp;
/* Store pre increment. */
#define SHPREUP() \
(void)StoreHalfWord (state, instr, LHS + GetLS7RHS (state, instr));
/* Store pre increment writeback. */
#define SHPREUPWB() \
temp = LHS + GetLS7RHS (state, instr); \
if (StoreHalfWord (state, instr, temp)) \
LSBase = temp;
/* Load post decrement writeback. */
#define LHPOSTDOWN() \
{ \
int done = 1; \
lhs = LHS; \
temp = lhs - GetLS7RHS (state, instr); \
\
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
if (LoadHalfWord (state, instr, lhs, LUNSIGNED)) \
LSBase = temp; \
break; \
case 2: /* SB */ \
if (LoadByte (state, instr, lhs, LSIGNED)) \
LSBase = temp; \
break; \
case 3: /* SH */ \
if (LoadHalfWord (state, instr, lhs, LSIGNED)) \
LSBase = temp; \
break; \
case 0: /* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* Load post increment writeback. */
#define LHPOSTUP() \
{ \
int done = 1; \
lhs = LHS; \
temp = lhs + GetLS7RHS (state, instr); \
\
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
if (LoadHalfWord (state, instr, lhs, LUNSIGNED)) \
LSBase = temp; \
break; \
case 2: /* SB */ \
if (LoadByte (state, instr, lhs, LSIGNED)) \
LSBase = temp; \
break; \
case 3: /* SH */ \
if (LoadHalfWord (state, instr, lhs, LSIGNED)) \
LSBase = temp; \
break; \
case 0: /* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* Load pre decrement. */
#define LHPREDOWN() \
{ \
int done = 1; \
\
temp = LHS - GetLS7RHS (state, instr); \
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
(void) LoadHalfWord (state, instr, temp, LUNSIGNED); \
break; \
case 2: /* SB */ \
(void) LoadByte (state, instr, temp, LSIGNED); \
break; \
case 3: /* SH */ \
(void) LoadHalfWord (state, instr, temp, LSIGNED); \
break; \
case 0: \
/* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* Load pre decrement writeback. */
#define LHPREDOWNWB() \
{ \
int done = 1; \
\
temp = LHS - GetLS7RHS (state, instr); \
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
if (LoadHalfWord (state, instr, temp, LUNSIGNED)) \
LSBase = temp; \
break; \
case 2: /* SB */ \
if (LoadByte (state, instr, temp, LSIGNED)) \
LSBase = temp; \
break; \
case 3: /* SH */ \
if (LoadHalfWord (state, instr, temp, LSIGNED)) \
LSBase = temp; \
break; \
case 0: \
/* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* Load pre increment. */
#define LHPREUP() \
{ \
int done = 1; \
\
temp = LHS + GetLS7RHS (state, instr); \
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
(void) LoadHalfWord (state, instr, temp, LUNSIGNED); \
break; \
case 2: /* SB */ \
(void) LoadByte (state, instr, temp, LSIGNED); \
break; \
case 3: /* SH */ \
(void) LoadHalfWord (state, instr, temp, LSIGNED); \
break; \
case 0: \
/* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* Load pre increment writeback. */
#define LHPREUPWB() \
{ \
int done = 1; \
\
temp = LHS + GetLS7RHS (state, instr); \
switch (BITS (5, 6)) \
{ \
case 1: /* H */ \
if (LoadHalfWord (state, instr, temp, LUNSIGNED)) \
LSBase = temp; \
break; \
case 2: /* SB */ \
if (LoadByte (state, instr, temp, LSIGNED)) \
LSBase = temp; \
break; \
case 3: /* SH */ \
if (LoadHalfWord (state, instr, temp, LSIGNED)) \
LSBase = temp; \
break; \
case 0: \
/* SWP handled elsewhere. */ \
default: \
done = 0; \
break; \
} \
if (done) \
break; \
}
/* EMULATION of ARM6. */
int ARMul_ICE_debug(ARMul_State *state,ARMword instr,ARMword addr);
#ifdef MODE32
//chy 2006-04-12, for ICE debug
int ARMul_ICE_debug(ARMul_State *state,ARMword instr,ARMword addr)
{
return 0;
}
ARMword ARMul_Debug(ARMul_State * state, ARMword pc, ARMword instr)
{
return 0;
}
ARMword ARMul_Emulate32(ARMul_State* state)
#else
ARMword ARMul_Emulate26(ARMul_State* state)
#endif
{
/* The PC pipeline value depends on whether ARM
or Thumb instructions are being
d. */
ARMword isize;
ARMword instr; /* The current instruction. */
ARMword dest = 0; /* Almost the DestBus. */
ARMword temp; /* Ubiquitous third hand. */
ARMword pc = 0; /* The address of the current instruction. */
ARMword lhs; /* Almost the ABus and BBus. */
ARMword rhs;
ARMword decoded = 0; /* Instruction pipeline. */
ARMword loaded = 0;
ARMword decoded_addr=0;
ARMword loaded_addr=0;
ARMword have_bp=0;
/* Execute the next instruction. */
if (state->NextInstr < PRIMEPIPE) {
decoded = state->decoded;
loaded = state->loaded;
pc = state->pc;
//chy 2006-04-12, for ICE debug
decoded_addr=state->decoded_addr;
loaded_addr=state->loaded_addr;
}
do {
//print_func_name(state->pc);
/* Just keep going. */
isize = INSN_SIZE;
switch (state->NextInstr) {
case SEQ:
/* Advance the pipeline, and an S cycle. */
state->Reg[15] += isize;
pc += isize;
instr = decoded;
//chy 2006-04-12, for ICE debug
have_bp = ARMul_ICE_debug(state,instr,decoded_addr);
decoded = loaded;
decoded_addr=loaded_addr;
//loaded = ARMul_LoadInstrS (state, pc + (isize * 2),
// isize);
loaded_addr=pc + (isize * 2);
if (have_bp) goto TEST_EMULATE;
break;
case NONSEQ:
/* Advance the pipeline, and an N cycle. */
state->Reg[15] += isize;
pc += isize;
instr = decoded;
//chy 2006-04-12, for ICE debug
have_bp=ARMul_ICE_debug(state,instr,decoded_addr);
decoded = loaded;
decoded_addr=loaded_addr;
//loaded = ARMul_LoadInstrN (state, pc + (isize * 2),
// isize);
loaded_addr=pc + (isize * 2);
NORMALCYCLE;
if (have_bp) goto TEST_EMULATE;
break;
case PCINCEDSEQ:
/* Program counter advanced, and an S cycle. */
pc += isize;
instr = decoded;
//chy 2006-04-12, for ICE debug
have_bp=ARMul_ICE_debug(state,instr,decoded_addr);
decoded = loaded;
decoded_addr=loaded_addr;
//loaded = ARMul_LoadInstrS (state, pc + (isize * 2),
// isize);
loaded_addr=pc + (isize * 2);
NORMALCYCLE;
if (have_bp) goto TEST_EMULATE;
break;
case PCINCEDNONSEQ:
/* Program counter advanced, and an N cycle. */
pc += isize;
instr = decoded;
//chy 2006-04-12, for ICE debug
have_bp=ARMul_ICE_debug(state,instr,decoded_addr);
decoded = loaded;
decoded_addr=loaded_addr;
//loaded = ARMul_LoadInstrN (state, pc + (isize * 2),
// isize);
loaded_addr=pc + (isize * 2);
NORMALCYCLE;
if (have_bp) goto TEST_EMULATE;
break;
case RESUME:
/* The program counter has been changed. */
pc = state->Reg[15];
#ifndef MODE32
pc = pc & R15PCBITS;
#endif
state->Reg[15] = pc + (isize * 2);
state->Aborted = 0;
//chy 2004-05-25, fix bug provided by Carl van Schaik<cvansch@cse.unsw.EDU.AU>
state->AbortAddr = 1;
instr = ARMul_LoadInstrN (state, pc, isize);
//instr = ARMul_ReLoadInstr (state, pc, isize);
//chy 2006-04-12, for ICE debug
have_bp=ARMul_ICE_debug(state,instr,pc);
//decoded =
// ARMul_ReLoadInstr (state, pc + isize, isize);
decoded_addr=pc+isize;
//loaded = ARMul_ReLoadInstr (state, pc + isize * 2,
// isize);
loaded_addr=pc + isize * 2;
NORMALCYCLE;
if (have_bp) goto TEST_EMULATE;
break;
default:
/* The program counter has been changed. */
pc = state->Reg[15];
#ifndef MODE32
pc = pc & R15PCBITS;
#endif
state->Reg[15] = pc + (isize * 2);
state->Aborted = 0;
//chy 2004-05-25, fix bug provided by Carl van Schaik<cvansch@cse.unsw.EDU.AU>
state->AbortAddr = 1;
instr = ARMul_LoadInstrN (state, pc, isize);
//chy 2006-04-12, for ICE debug
have_bp=ARMul_ICE_debug(state,instr,pc);
decoded_addr=pc+isize;
loaded_addr=pc + isize * 2;
NORMALCYCLE;
if (have_bp) goto TEST_EMULATE;
break;
}
instr = ARMul_LoadInstrN (state, pc, isize);
state->last_instr = state->CurrInstr;
state->CurrInstr = instr;
ARMul_Debug(state, pc, instr);
/* Any exceptions ? */
if (state->NresetSig == LOW) {
ARMul_Abort (state, ARMul_ResetV);
break;
} else if (!state->NfiqSig && !FFLAG) {
ARMul_Abort (state, ARMul_FIQV);
break;
} else if (!state->NirqSig && !IFLAG) {
ARMul_Abort (state, ARMul_IRQV);
break;
}
if (state->Emulate < ONCE) {
state->NextInstr = RESUME;
break;
}
state->NumInstrs++;
#ifdef MODET
/* Provide Thumb instruction decoding. If the processor is in Thumb
mode, then we can simply decode the Thumb instruction, and map it
to the corresponding ARM instruction (by directly loading the
instr variable, and letting the normal ARM simulator
execute). There are some caveats to ensure that the correct
pipelined PC value is used when executing Thumb code, and also for
dealing with the BL instruction. */
if (TFLAG) {
ARMword armOp = 0;
/* Check if in Thumb mode. */
switch (ARMul_ThumbDecode(state, pc, instr, &armOp)) {
case t_undefined:
/* This is a Thumb instruction. */
ARMul_UndefInstr (state, instr);
goto donext;
case t_branch:
/* Already processed. */
//pc = state->Reg[15] - 2;
//state->pc = state->Reg[15] - 2; //ichfly why do I need that
goto donext;
case t_decoded:
/* ARM instruction available. */
//printf("t decode %04lx -> %08lx\n", instr & 0xffff, armOp);
if (armOp == 0xDEADC0DE) {
LOG_ERROR(Core_ARM11, "Failed to decode thumb opcode %04X at %08X", instr, pc);
}
instr = armOp;
/* So continue instruction decoding. */
break;
default:
break;
}
}
#endif
/* Check the condition codes. */
if ((temp = TOPBITS (28)) == AL) {
/* Vile deed in the need for speed. */
goto mainswitch;
}
/* Check the condition code. */
switch ((int) TOPBITS (28)) {
case AL:
temp = TRUE;
break;
case NV:
/* shenoubang add for armv7 instr dmb 2012-3-11 */
if (state->is_v7) {
if ((instr & 0x0fffff00) == 0x057ff000) {
switch((instr >> 4) & 0xf) {
case 4: /* dsb */
case 5: /* dmb */
case 6: /* isb */
// TODO: do no implemented thes instr
goto donext;
}
}
}
/* dyf add for armv6 instruct CPS 2010.9.17 */
if (state->is_v6) {
/* clrex do nothing here temporary */
if (instr == 0xf57ff01f) {
//printf("clrex \n");
/* shenoubang 2012-3-14 refer the dyncom_interpreter */
state->exclusive_tag_array[0] = 0xFFFFFFFF;
state->exclusive_access_state = 0;
goto donext;
}
if (BITS(20, 27) == 0x10) {
if (BIT(19)) {
if (BIT(8)) {
if (BIT(18))
state->Cpsr |= 1<<8;
else
state->Cpsr &= ~(1<<8);
}
if (BIT(7)) {
if (BIT(18))
state->Cpsr |= 1<<7;
else
state->Cpsr &= ~(1<<7);
ASSIGNINT (state->Cpsr & INTBITS);
}
if (BIT(6)) {
if (BIT(18))
state->Cpsr |= 1<<6;
else
state->Cpsr &= ~(1<<6);
ASSIGNINT (state->Cpsr & INTBITS);
}
}
if (BIT(17)) {
state->Cpsr |= BITS(0, 4);
printf("skyeye test state->Mode\n");
if (state->Mode != (state->Cpsr & MODEBITS)) {
state->Mode = ARMul_SwitchMode (state, state->Mode, state->Cpsr & MODEBITS);
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
}
}
goto donext;
}
}
if (state->is_v5) {
if (BITS (25, 27) == 5) { /* BLX(1) */
ARMword dest;
state->Reg[14] = pc + 4;
/* Force entry into Thumb mode. */
dest = pc + 8 + 1;
if (BIT (23))
dest += (NEGBRANCH +
(BIT (24) << 1));
else
dest += POSBRANCH +
(BIT (24) << 1);
WriteR15Branch (state, dest);
goto donext;
} else if ((instr & 0xFC70F000) == 0xF450F000) {
/* The PLD instruction. Ignored. */
goto donext;
} else if (((instr & 0xfe500f00) == 0xfc100100)
|| ((instr & 0xfe500f00) ==
0xfc000100)) {
/* wldrw and wstrw are unconditional. */
goto mainswitch;
} else {
/* UNDEFINED in v5, UNPREDICTABLE in v3, v4, non executed in v1, v2. */
ARMul_UndefInstr (state, instr);
}
}
temp = FALSE;
break;
case EQ:
temp = ZFLAG;
break;
case NE:
temp = !ZFLAG;
break;
case VS:
temp = VFLAG;
break;
case VC:
temp = !VFLAG;
break;
case MI:
temp = NFLAG;
break;
case PL:
temp = !NFLAG;
break;
case CS:
temp = CFLAG;
break;
case CC:
temp = !CFLAG;
break;
case HI:
temp = (CFLAG && !ZFLAG);
break;
case LS:
temp = (!CFLAG || ZFLAG);
break;
case GE:
temp = ((!NFLAG && !VFLAG) || (NFLAG && VFLAG));
break;
case LT:
temp = ((NFLAG && !VFLAG) || (!NFLAG && VFLAG));
break;
case GT:
temp = ((!NFLAG && !VFLAG && !ZFLAG)
|| (NFLAG && VFLAG && !ZFLAG));
break;
case LE:
temp = ((NFLAG && !VFLAG) || (!NFLAG && VFLAG))
|| ZFLAG;
break;
} /* cc check */
//chy 2003-08-24 now #if 0 .... #endif process cp14, cp15.reg14, I disable it...
/* Actual execution of instructions begins here. */
/* If the condition codes don't match, stop here. */
if (temp) {
mainswitch:
/* shenoubang sbfx and ubfx instr 2012-3-16 */
if (state->is_v6) {
unsigned int m, lsb, width, Rd, Rn, data;
Rd = Rn = lsb = width = data = m = 0;
//printf("helloworld\n");
if ((((int) BITS (21, 27)) == 0x3f) && (((int) BITS (4, 6)) == 0x5)) {
m = (unsigned)BITS(7, 11);
width = (unsigned)BITS(16, 20);
Rd = (unsigned)BITS(12, 15);
Rn = (unsigned)BITS(0, 3);
if ((Rd == 15) || (Rn == 15)) {
ARMul_UndefInstr (state, instr);
} else if ((m + width) < 32) {
data = state->Reg[Rn];
state->Reg[Rd] ^= state->Reg[Rd];
state->Reg[Rd] = ((ARMword)(data << (31 -(m + width))) >> ((31 - (m + width)) + (m)));
//SKYEYE_LOG_IN_CLR(RED, "UBFX: In %s, line = %d, Reg_src[%d] = 0x%x, Reg_d[%d] = 0x%x, m = %d, width = %d, Rd = %d, Rn = %d\n",
// __FUNCTION__, __LINE__, Rn, data, Rd, state->Reg[Rd], m, width + 1, Rd, Rn);
goto donext;
}
} // ubfx instr
else if ((((int) BITS (21, 27)) == 0x3d) && (((int) BITS (4, 6)) == 0x5)) {
int tmp = 0;
Rd = BITS(12, 15);
Rn = BITS(0, 3);
lsb = BITS(7, 11);
width = BITS(16, 20);
if ((Rd == 15) || (Rn == 15)) {
ARMul_UndefInstr (state, instr);
} else if ((lsb + width) < 32) {
state->Reg[Rd] ^= state->Reg[Rd];
data = state->Reg[Rn];
tmp = (data << (32 - (lsb + width + 1)));
state->Reg[Rd] = (tmp >> (32 - (lsb + width + 1)));
//SKYEYE_LOG_IN_CLR(RED, "sbfx: In %s, line = %d, pc = 0x%x, instr = 0x%x,Rd = 0x%x, Rn = 0x%x, lsb = %d, width = %d, Rs[%d] = 0x%x, Rd[%d] = 0x%x\n",
// __func__, __LINE__, pc, instr, Rd, Rn, lsb, width + 1, Rn, state->Reg[Rn], Rd, state->Reg[Rd]);
goto donext;
}
} // sbfx instr
else if ((((int)BITS(21, 27)) == 0x3e) && ((int)BITS(4, 6) == 0x1)) {
//(ARMword)(instr<<(31-(n))) >> ((31-(n))+(m))
unsigned msb ,tmp_rn, tmp_rd, dst;
tmp_rd = tmp_rn = dst = 0;
Rd = BITS(12, 15);
Rn = BITS(0, 3);
lsb = BITS(7, 11);
msb = BITS(16, 20); //-V519
if (Rd == 15) {
ARMul_UndefInstr (state, instr);
} else if (Rn == 15) {
data = state->Reg[Rd];
tmp_rd = ((ARMword)(data << (31 - lsb)) >> (31 - lsb));
dst = ((data >> msb) << (msb - lsb));
dst = (dst << lsb) | tmp_rd;
goto donext;
} // bfc instr
else if (((msb >= lsb) && (msb < 32))) {
data = state->Reg[Rn];
tmp_rn = ((ARMword)(data << (31 - (msb - lsb))) >> (31 - (msb - lsb)));
data = state->Reg[Rd];
tmp_rd = ((ARMword)(data << (31 - lsb)) >> (31 - lsb));
dst = ((data >> msb) << (msb - lsb)) | tmp_rn;
dst = (dst << lsb) | tmp_rd;
goto donext;
} // bfi instr
}
}
switch ((int) BITS (20, 27)) {
/* Data Processing Register RHS Instructions. */
case 0x00: /* AND reg and MUL */
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, no write-back, down, post indexed. */
SHDOWNWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
if (BITS (4, 7) == 9) {
/* MUL */
rhs = state->Reg[MULRHSReg];
//if (MULLHSReg == MULDESTReg) {
if(0) { /* For armv6, the restriction is removed */
UNDEF_MULDestEQOp1;
state->Reg[MULDESTReg] = 0;
} else if (MULDESTReg != 15)
state->Reg[MULDESTReg] = state->Reg[MULLHSReg] * rhs;
else
UNDEF_MULPCDest;
for (dest = 0, temp = 0; dest < 32;
dest++)
if (rhs & (1L << dest))
temp = dest;
/* Mult takes this many/2 I cycles. */
ARMul_Icycles (state, ARMul_MultTable[temp], 0L);
} else {
/* AND reg. */
rhs = DPRegRHS;
dest = LHS & rhs;
WRITEDEST (dest);
}
break;
case 0x01: /* ANDS reg and MULS */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, no write-back, down, post indexed. */
LHPOSTDOWN ();
/* Fall through to rest of decoding. */
#endif
if (BITS (4, 7) == 9) {
/* MULS */
rhs = state->Reg[MULRHSReg];
//if (MULLHSReg == MULDESTReg) {
if(0) {
printf("Something in %d line\n", __LINE__);
UNDEF_WARNING;
UNDEF_MULDestEQOp1;
state->Reg[MULDESTReg] = 0;
CLEARN;
SETZ;
} else if (MULDESTReg != 15) {
dest = state->Reg[MULLHSReg] * rhs;
ARMul_NegZero (state, dest);
state->Reg[MULDESTReg] = dest;
} else
UNDEF_MULPCDest;
for (dest = 0, temp = 0; dest < 32;
dest++)
if (rhs & (1L << dest))
temp = dest;
/* Mult takes this many/2 I cycles. */
ARMul_Icycles (state, ARMul_MultTable[temp], 0L);
} else {
/* ANDS reg. */
rhs = DPSRegRHS;
dest = LHS & rhs;
WRITESDEST (dest);
}
break;
case 0x02: /* EOR reg and MLA */
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, write-back, down, post indexed. */
SHDOWNWB ();
break;
}
#endif
if (BITS (4, 7) == 9) { /* MLA */
rhs = state->Reg[MULRHSReg];
#if 0
if (MULLHSReg == MULDESTReg) {
UNDEF_MULDestEQOp1;
state->Reg[MULDESTReg] = state->Reg[MULACCReg];
} else if (MULDESTReg != 15) {
#endif
if (MULDESTReg != 15) {
state->Reg[MULDESTReg] = state->Reg[MULLHSReg] * rhs + state->Reg[MULACCReg];
} else
UNDEF_MULPCDest;
for (dest = 0, temp = 0; dest < 32;
dest++)
if (rhs & (1L << dest))
temp = dest;
/* Mult takes this many/2 I cycles. */
ARMul_Icycles (state, ARMul_MultTable[temp], 0L);
} else {
rhs = DPRegRHS;
dest = LHS ^ rhs;
WRITEDEST (dest);
}
break;
case 0x03: /* EORS reg and MLAS */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, write-back, down, post-indexed. */
LHPOSTDOWN ();
/* Fall through to rest of the decoding. */
#endif
if (BITS (4, 7) == 9) {
/* MLAS */
rhs = state->Reg[MULRHSReg];
//if (MULLHSReg == MULDESTReg) {
if (0) {
UNDEF_MULDestEQOp1;
dest = state->Reg[MULACCReg];
ARMul_NegZero (state, dest);
state->Reg[MULDESTReg] = dest;
} else if (MULDESTReg != 15) {
dest = state->Reg[MULLHSReg] * rhs + state->Reg[MULACCReg];
ARMul_NegZero (state, dest);
state->Reg[MULDESTReg] = dest;
} else
UNDEF_MULPCDest;
for (dest = 0, temp = 0; dest < 32;
dest++)
if (rhs & (1L << dest))
temp = dest;
/* Mult takes this many/2 I cycles. */
ARMul_Icycles (state, ARMul_MultTable[temp], 0L);
} else {
/* EORS Reg. */
rhs = DPSRegRHS;
dest = LHS ^ rhs;
WRITESDEST (dest);
}
break;
case 0x04: /* SUB reg */
// Signifies UMAAL
if (state->is_v6 && BITS(4, 7) == 0x09) {
if (handle_v6_insn(state, instr))
break;
}
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, no write-back, down, post indexed. */
SHDOWNWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS - rhs;
WRITEDEST (dest);
break;
case 0x05: /* SUBS reg */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, no write-back, down, post indexed. */
LHPOSTDOWN ();
/* Fall through to the rest of the instruction decoding. */
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = lhs - rhs;
if ((lhs >= rhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x06: /* RSB reg */
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, write-back, down, post indexed. */
SHDOWNWB ();
break;
}
#endif
rhs = DPRegRHS;
dest = rhs - LHS;
WRITEDEST (dest);
break;
case 0x07: /* RSBS reg */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, write-back, down, post indexed. */
LHPOSTDOWN ();
/* Fall through to remainder of instruction decoding. */
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = rhs - lhs;
if ((rhs >= lhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, rhs, lhs, dest);
ARMul_SubOverflow (state, rhs, lhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x08: /* ADD reg */
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, no write-back, up, post indexed. */
SHUPWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
#ifdef MODET
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32 = 64 */
ARMul_Icycles (state, Multiply64 (state, instr, LUNSIGNED, LDEFAULT), 0L);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS + rhs;
WRITEDEST (dest);
break;
case 0x09: /* ADDS reg */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, no write-back, up, post indexed. */
LHPOSTUP ();
/* Fall through to remaining instruction decoding. */
#endif
#ifdef MODET
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, Multiply64 (state, instr, LUNSIGNED, LSCC), 0L);
break;
}
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = lhs + rhs;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x0a: /* ADC reg */
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, write-back, up, post-indexed. */
SHUPWB ();
break;
}
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, MultiplyAdd64 (state, instr, LUNSIGNED, LDEFAULT), 0L);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS + rhs + CFLAG;
WRITEDEST (dest);
break;
case 0x0b: /* ADCS reg */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, write-back, up, post indexed. */
LHPOSTUP ();
/* Fall through to remaining instruction decoding. */
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, MultiplyAdd64 (state, instr, LUNSIGNED, LSCC), 0L);
break;
}
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = lhs + rhs + CFLAG;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x0c: /* SBC reg */
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, no write-back, up post indexed. */
SHUPWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, Multiply64 (state, instr, LSIGNED, LDEFAULT), 0L);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS - rhs - !CFLAG;
WRITEDEST (dest);
break;
case 0x0d: /* SBCS reg */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, no write-back, up, post indexed. */
LHPOSTUP ();
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, Multiply64 (state, instr, LSIGNED, LSCC), 0L);
break;
}
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = lhs - rhs - !CFLAG;
if ((lhs >= rhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x0e: /* RSC reg */
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, write-back, up, post indexed. */
SHUPWB ();
break;
}
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, MultiplyAdd64 (state, instr, LSIGNED, LDEFAULT), 0L);
break;
}
#endif
rhs = DPRegRHS;
dest = rhs - LHS - !CFLAG;
WRITEDEST (dest);
break;
case 0x0f: /* RSCS reg */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, write-back, up, post indexed. */
LHPOSTUP ();
/* Fall through to remaining instruction decoding. */
if (BITS (4, 7) == 0x9) {
/* MULL */
/* 32x32=64 */
ARMul_Icycles (state, MultiplyAdd64 (state, instr, LSIGNED, LSCC), 0L);
break;
}
#endif
lhs = LHS;
rhs = DPRegRHS;
dest = rhs - lhs - !CFLAG;
if ((rhs >= lhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, rhs, lhs, dest);
ARMul_SubOverflow (state, rhs, lhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x10: /* TST reg and MRS CPSR and SWP word. */
if (state->is_v5e) {
if (BIT (4) == 0 && BIT (7) == 1) {
/* ElSegundo SMLAxy insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (8, 11)];
ARMword Rn = state->Reg[BITS (12, 15)];
if (BIT (5))
op1 >>= 16;
if (BIT (6))
op2 >>= 16;
op1 &= 0xFFFF;
op2 &= 0xFFFF;
if (op1 & 0x8000)
op1 -= 65536;
if (op2 & 0x8000)
op2 -= 65536;
op1 *= op2;
//printf("SMLA_INST:BB,op1=0x%x, op2=0x%x. Rn=0x%x\n", op1, op2, Rn);
if (AddOverflow(op1, Rn, op1 + Rn))
SETQ;
state->Reg[BITS (16, 19)] = op1 + Rn;
break;
}
if (BITS (4, 11) == 5) {
/* ElSegundo QADD insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (16, 19)];
ARMword result = op1 + op2;
if (AddOverflow(op1, op2, result)) {
result = POS (result) ? 0x80000000 : 0x7fffffff;
SETQ;
}
state->Reg[BITS (12, 15)] = result;
break;
}
}
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, no write-back, down, pre indexed. */
SHPREDOWN ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
if (BITS (4, 11) == 9) {
/* SWP */
UNDEF_SWPPC;
temp = LHS;
BUSUSEDINCPCS;
#ifndef MODE32
if (VECTORACCESS (temp) || ADDREXCEPT (temp)) {
INTERNALABORT (temp);
(void) ARMul_LoadWordN (state, temp);
(void) ARMul_LoadWordN (state, temp);
} else
#endif
dest = ARMul_SwapWord (state, temp, state->Reg[RHSReg]);
if (temp & 3)
DEST = ARMul_Align (state, temp, dest);
else
DEST = dest;
if (state->abortSig || state->Aborted)
TAKEABORT;
} else if ((BITS (0, 11) == 0) && (LHSReg == 15)) { /* MRS CPSR */
UNDEF_MRSPC;
DEST = ARMul_GetCPSR(state);
} else {
UNDEF_Test;
}
break;
case 0x11: /* TSTP reg */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, no write-back, down, pre indexed. */
LHPREDOWN ();
/* Continue with remaining instruction decode. */
#endif
if (DESTReg == 15) {
/* TSTP reg */
#ifdef MODE32
//chy 2006-02-15 if in user mode, can not set cpsr 0:23
//from p165 of ARMARM book
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
rhs = DPRegRHS;
temp = LHS & rhs;
SETR15PSR (temp);
#endif
} else {
/* TST reg */
rhs = DPSRegRHS;
dest = LHS & rhs;
ARMul_NegZero (state, dest);
}
break;
case 0x12: /* TEQ reg and MSR reg to CPSR (ARM6). */
if (state->is_v5) {
if (BITS (4, 7) == 3) {
/* BLX(2) */
ARMword temp;
if (TFLAG)
temp = (pc + 2) | 1;
else
temp = pc + 4;
WriteR15Branch (state, state->Reg[RHSReg]);
state->Reg[14] = temp;
break;
}
}
if (state->is_v5e) {
if (BIT (4) == 0 && BIT (7) == 1 && (BIT (5) == 0 || BITS (12, 15) == 0)) {
/* ElSegundo SMLAWy/SMULWy insn. */
unsigned long long op1 = state->Reg[BITS (0, 3)];
unsigned long long op2 = state->Reg[BITS (8, 11)];
unsigned long long result;
if (BIT (6))
op2 >>= 16;
if (op1 & 0x80000000)
op1 -= 1ULL << 32;
op2 &= 0xFFFF;
if (op2 & 0x8000)
op2 -= 65536;
result = (op1 * op2) >> 16;
if (BIT (5) == 0) {
ARMword Rn = state->Reg[BITS(12, 15)];
if (AddOverflow((ARMword)result, Rn, (ARMword)(result + Rn)))
SETQ;
result += Rn;
}
state->Reg[BITS (16, 19)] = (ARMword)result;
break;
}
if (BITS (4, 11) == 5) {
/* ElSegundo QSUB insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (16, 19)];
ARMword result = op1 - op2;
if (SubOverflow
(op1, op2, result)) {
result = POS (result) ? 0x80000000 : 0x7fffffff;
SETQ;
}
state->Reg[BITS (12, 15)] = result;
break;
}
}
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, write-back, down, pre indexed. */
SHPREDOWNWB ();
break;
}
if (BITS (4, 27) == 0x12FFF1) {
/* BX */
WriteR15Branch (state, state->Reg[RHSReg]);
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
if (state->is_v5) {
if (BITS (4, 7) == 0x7) {
//ARMword value;
//extern int SWI_vector_installed;
/* Hardware is allowed to optionally override this
instruction and treat it as a breakpoint. Since
this is a simulator not hardware, we take the position
that if a SWI vector was not installed, then an Abort
vector was probably not installed either, and so
normally this instruction would be ignored, even if an
Abort is generated. This is a bad thing, since GDB
uses this instruction for its breakpoints (at least in
Thumb mode it does). So intercept the instruction here
and generate a breakpoint SWI instead. */
/* Force the next instruction to be refetched. */
state->NextInstr = RESUME;
break;
}
}
if (DESTReg == 15) {
/* MSR reg to CPSR. */
UNDEF_MSRPC;
temp = DPRegRHS;
#ifdef MODET
/* Don't allow TBIT to be set by MSR. */
temp &= ~TBIT;
#endif
ARMul_FixCPSR (state, instr, temp);
} else
UNDEF_Test;
break;
case 0x13: /* TEQP reg */
#ifdef MODET
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, write-back, down, pre indexed. */
LHPREDOWNWB ();
/* Continue with remaining instruction decode. */
#endif
if (DESTReg == 15) {
/* TEQP reg */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
rhs = DPRegRHS;
temp = LHS ^ rhs;
SETR15PSR (temp);
#endif
} else {
/* TEQ Reg. */
rhs = DPSRegRHS;
dest = LHS ^ rhs;
ARMul_NegZero (state, dest);
}
break;
case 0x14: /* CMP reg and MRS SPSR and SWP byte. */
if (state->is_v5e) {
if (BIT (4) == 0 && BIT (7) == 1) {
/* ElSegundo SMLALxy insn. */
unsigned long long op1 = state->Reg[BITS (0, 3)];
unsigned long long op2 = state->Reg[BITS (8, 11)];
unsigned long long dest;
//unsigned long long result;
if (BIT (5))
op1 >>= 16;
if (BIT (6))
op2 >>= 16;
op1 &= 0xFFFF;
if (op1 & 0x8000)
op1 -= 65536;
op2 &= 0xFFFF;
if (op2 & 0x8000)
op2 -= 65536;
dest = (unsigned long long) state->Reg[BITS (16, 19)] << 32;
dest |= state->Reg[BITS (12, 15)];
dest += op1 * op2;
state->Reg[BITS(12, 15)] = (ARMword)dest;
state->Reg[BITS(16, 19)] = (ARMword)(dest >> 32);
break;
}
if (BITS (4, 11) == 5) {
/* ElSegundo QDADD insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (16, 19)];
ARMword op2d = op2 + op2;
ARMword result;
if (AddOverflow
(op2, op2, op2d)) {
SETQ;
op2d = POS (op2d) ? 0x80000000 : 0x7fffffff;
}
result = op1 + op2d;
if (AddOverflow(op1, op2d, result)) {
SETQ;
result = POS (result) ? 0x80000000 : 0x7fffffff;
}
state->Reg[BITS (12, 15)] = result;
break;
}
}
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, no write-back, down, pre indexed. */
SHPREDOWN ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
if (BITS (4, 11) == 9) {
/* SWP */
UNDEF_SWPPC;
temp = LHS;
BUSUSEDINCPCS;
#ifndef MODE32
if (VECTORACCESS (temp) || ADDREXCEPT (temp)) {
INTERNALABORT (temp);
(void) ARMul_LoadByte (state, temp);
(void) ARMul_LoadByte (state, temp);
} else
#endif
DEST = ARMul_SwapByte (state, temp, state->Reg[RHSReg]);
if (state->abortSig || state->Aborted)
TAKEABORT;
} else if ((BITS (0, 11) == 0)
&& (LHSReg == 15)) {
/* MRS SPSR */
UNDEF_MRSPC;
DEST = GETSPSR (state->Bank);
} else
UNDEF_Test;
break;
case 0x15: /* CMPP reg. */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, no write-back, down, pre indexed. */
LHPREDOWN ();
/* Continue with remaining instruction decode. */
#endif
if (DESTReg == 15) {
/* CMPP reg. */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
rhs = DPRegRHS;
temp = LHS - rhs;
SETR15PSR (temp);
#endif
} else {
/* CMP reg. */
lhs = LHS;
rhs = DPRegRHS;
dest = lhs - rhs;
ARMul_NegZero (state, dest);
if ((lhs >= rhs)
|| ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
}
break;
case 0x16: /* CMN reg and MSR reg to SPSR */
if (state->is_v5e) {
if (BIT (4) == 0 && BIT (7) == 1 && BITS (12, 15) == 0) {
/* ElSegundo SMULxy insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (8, 11)];
ARMword Rn = state->Reg[BITS (12, 15)];
if (BIT (5))
op1 >>= 16;
if (BIT (6))
op2 >>= 16;
op1 &= 0xFFFF;
op2 &= 0xFFFF;
if (op1 & 0x8000)
op1 -= 65536;
if (op2 & 0x8000)
op2 -= 65536;
state->Reg[BITS (16, 19)] = op1 * op2;
break;
}
if (BITS (4, 11) == 5) {
/* ElSegundo QDSUB insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
ARMword op2 = state->Reg[BITS (16, 19)];
ARMword op2d = op2 + op2;
ARMword result;
if (AddOverflow(op2, op2, op2d)) {
SETQ;
op2d = POS (op2d) ? 0x80000000 : 0x7fffffff;
}
result = op1 - op2d;
if (SubOverflow(op1, op2d, result)) {
SETQ;
result = POS (result) ? 0x80000000 : 0x7fffffff;
}
state->Reg[BITS (12, 15)] = result;
break;
}
}
if (state->is_v5) {
if (BITS (4, 11) == 0xF1
&& BITS (16, 19) == 0xF) {
/* ARM5 CLZ insn. */
ARMword op1 = state->Reg[BITS (0, 3)];
int result = 32;
if (op1)
for (result = 0; (op1 & 0x80000000) == 0; op1 <<= 1)
result++;
state->Reg[BITS (12, 15)] = result;
break;
}
}
#ifdef MODET
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, write-back, down, pre indexed. */
SHPREDOWNWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
if (DESTReg == 15) {
/* MSR */
UNDEF_MSRPC;
/*ARMul_FixSPSR (state, instr,
DPRegRHS);*/
} else {
UNDEF_Test;
}
break;
case 0x17: /* CMNP reg */
#ifdef MODET
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, write-back, down, pre indexed. */
LHPREDOWNWB ();
/* Continue with remaining instruction decoding. */
#endif
if (DESTReg == 15) {
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
rhs = DPRegRHS;
temp = LHS + rhs;
SETR15PSR (temp);
#endif
break;
} else {
/* CMN reg. */
lhs = LHS;
rhs = DPRegRHS;
dest = lhs + rhs;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
}
break;
case 0x18: /* ORR reg */
#ifdef MODET
/* dyf add armv6 instr strex 2010.9.17 */
if (state->is_v6) {
if (BITS (4, 7) == 0x9)
if (handle_v6_insn (state, instr))
break;
}
if (BITS (4, 11) == 0xB) {
/* STRH register offset, no write-back, up, pre indexed. */
SHPREUP ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS | rhs;
WRITEDEST (dest);
break;
case 0x19: /* ORRS reg */
#ifdef MODET
/* dyf add armv6 instr ldrex */
if (state->is_v6) {
if (BITS (4, 7) == 0x9) {
if (handle_v6_insn (state, instr))
break;
}
}
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, no write-back, up, pre indexed. */
LHPREUP ();
/* Continue with remaining instruction decoding. */
#endif
rhs = DPSRegRHS;
dest = LHS | rhs;
WRITESDEST (dest);
break;
case 0x1a: /* MOV reg */
#ifdef MODET
if (BITS (4, 11) == 0xB) {
/* STRH register offset, write-back, up, pre indexed. */
SHPREUPWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
if (BITS(4, 11) == 0xF9) { //strexd
u32 l = LHSReg;
bool enter = false;
if (state->currentexval == (u32)ARMul_ReadWord(state, state->currentexaddr)&&
state->currentexvald == (u32)ARMul_ReadWord(state, state->currentexaddr + 4))
enter = true;
//todo bug this and STREXD and LDREXD http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0360e/CHDGJGGC.html
if (enter) {
ARMul_StoreWordN(state, LHS, state->Reg[RHSReg]);
ARMul_StoreWordN(state,LHS + 4 , state->Reg[RHSReg + 1]);
state->Reg[DESTReg] = 0;
} else {
state->Reg[DESTReg] = 1;
}
break;
}
#endif
dest = DPRegRHS;
WRITEDEST (dest);
break;
case 0x1B: /* MOVS reg */
#ifdef MODET
/* ldrexd ichfly */
if (BITS(0, 11) == 0xF9F) { //strexd
lhs = LHS;
state->currentexaddr = lhs;
state->currentexval = (u32)ARMul_ReadWord(state, lhs);
state->currentexvald = (u32)ARMul_ReadWord(state, lhs + 4);
state->Reg[DESTReg] = ARMul_LoadWordN(state, lhs);
state->Reg[DESTReg] = ARMul_LoadWordN(state, lhs + 4);
break;
}
if ((BITS (4, 11) & 0xF9) == 0x9)
/* LDR register offset, write-back, up, pre indexed. */
LHPREUPWB ();
/* Continue with remaining instruction decoding. */
#endif
dest = DPSRegRHS;
WRITESDEST (dest);
break;
case 0x1c: /* BIC reg */
#ifdef MODET
/* dyf add for STREXB */
if (state->is_v6) {
if (BITS (4, 7) == 0x9) {
if (handle_v6_insn (state, instr))
break;
}
}
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, no write-back, up, pre indexed. */
SHPREUP ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
} else if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
rhs = DPRegRHS;
dest = LHS & ~rhs;
WRITEDEST (dest);
break;
case 0x1d: /* BICS reg */
#ifdef MODET
/* ladsh P=1 U=1 W=0 L=1 S=1 H=1 */
if (BITS(4, 7) == 0xF) {
temp = LHS + GetLS7RHS (state, instr);
LoadHalfWord (state, instr, temp, LSIGNED);
break;
}
if (BITS (4, 7) == 0xb) {
/* LDRH immediate offset, no write-back, up, pre indexed. */
temp = LHS + GetLS7RHS (state, instr);
LoadHalfWord (state, instr, temp, LUNSIGNED);
break;
}
if (BITS (4, 7) == 0xd) {
// alex-ykl fix: 2011-07-20 missing ldrsb instruction
temp = LHS + GetLS7RHS (state, instr);
LoadByte (state, instr, temp, LSIGNED);
break;
}
/* Continue with instruction decoding. */
/*if ((BITS (4, 7) & 0x9) == 0x9) */
if ((BITS (4, 7)) == 0x9) {
/* ldrexb */
if (state->is_v6) {
if (handle_v6_insn (state, instr))
break;
}
/* LDR immediate offset, no write-back, up, pre indexed. */
LHPREUP ();
}
#endif
rhs = DPSRegRHS;
dest = LHS & ~rhs;
WRITESDEST (dest);
break;
case 0x1e: /* MVN reg */
#ifdef MODET
if ((instr & 0x00000FF0) == 0x00000F90) { //if ((instr & 0x0FF00FF0) == 0x01e00f90) { //todo make that better ichfly
/* strexh ichfly */
u32 l = LHSReg;
u32 r = RHSReg;
lhs = LHS;
bool enter = false;
if (state->currentexval == (u32)ARMul_LoadHalfWord(state, state->currentexaddr))enter = true;
//StoreWord(state, lhs, RHS)
if (state->Aborted) {
TAKEABORT;
}
if (enter) {
ARMul_StoreHalfWord(state, lhs, RHS);
state->Reg[DESTReg] = 0;
} else {
state->Reg[DESTReg] = 1;
}
break;
}
if (BITS (4, 7) == 0xB) {
/* STRH immediate offset, write-back, up, pre indexed. */
SHPREUPWB ();
break;
}
if (BITS (4, 7) == 0xD) {
Handle_Load_Double (state, instr);
break;
}
if (BITS (4, 7) == 0xF) {
Handle_Store_Double (state, instr);
break;
}
#endif
dest = ~DPRegRHS;
WRITEDEST (dest);
break;
case 0x1f: /* MVNS reg */
#ifdef MODET
if ((instr & 0x00000FF0) == 0x00000F90) { //(instr & 0x0FF00FF0) == 0x01f00f90)//if ((instr & 0x0FF00FF0) == 0x01f00f90) {
/* ldrexh ichfly */
lhs = LHS;
state->currentexaddr = lhs;
state->currentexval = (u32)ARMul_LoadHalfWord(state, lhs);
LoadHalfWord(state, instr, lhs,0);
break;
}
if ((BITS (4, 7) & 0x9) == 0x9)
/* LDR immediate offset, write-back, up, pre indexed. */
LHPREUPWB ();
/* Continue instruction decoding. */
#endif
dest = ~DPSRegRHS;
WRITESDEST (dest);
break;
/* Data Processing Immediate RHS Instructions. */
case 0x20: /* AND immed */
dest = LHS & DPImmRHS;
WRITEDEST (dest);
break;
case 0x21: /* ANDS immed */
DPSImmRHS;
dest = LHS & rhs;
WRITESDEST (dest);
break;
case 0x22: /* EOR immed */
dest = LHS ^ DPImmRHS;
WRITEDEST (dest);
break;
case 0x23: /* EORS immed */
DPSImmRHS;
dest = LHS ^ rhs;
WRITESDEST (dest);
break;
case 0x24: /* SUB immed */
dest = LHS - DPImmRHS;
WRITEDEST (dest);
break;
case 0x25: /* SUBS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs - rhs;
if ((lhs >= rhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x26: /* RSB immed */
dest = DPImmRHS - LHS;
WRITEDEST (dest);
break;
case 0x27: /* RSBS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = rhs - lhs;
if ((rhs >= lhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, rhs, lhs, dest);
ARMul_SubOverflow (state, rhs, lhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x28: /* ADD immed */
dest = LHS + DPImmRHS;
WRITEDEST (dest);
break;
case 0x29: /* ADDS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs + rhs;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x2a: /* ADC immed */
dest = LHS + DPImmRHS + CFLAG;
WRITEDEST (dest);
break;
case 0x2b: /* ADCS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs + rhs + CFLAG;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x2c: /* SBC immed */
dest = LHS - DPImmRHS - !CFLAG;
WRITEDEST (dest);
break;
case 0x2d: /* SBCS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs - rhs - !CFLAG;
if ((lhs >= rhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x2e: /* RSC immed */
dest = DPImmRHS - LHS - !CFLAG;
WRITEDEST (dest);
break;
case 0x2f: /* RSCS immed */
lhs = LHS;
rhs = DPImmRHS;
dest = rhs - lhs - !CFLAG;
if ((rhs >= lhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, rhs, lhs, dest);
ARMul_SubOverflow (state, rhs, lhs, dest);
} else {
CLEARC;
CLEARV;
}
WRITESDEST (dest);
break;
case 0x30: /* TST immed */
/* shenoubang 2012-3-14*/
if (state->is_v6) { /* movw, ARMV6, ARMv7 */
dest ^= dest;
dest = BITS(16, 19);
dest = ((dest<<12) | BITS(0, 11));
WRITEDEST(dest);
break;
} else {
UNDEF_Test;
break;
}
case 0x31: /* TSTP immed */
if (DESTReg == 15) {
/* TSTP immed. */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
temp = LHS & DPImmRHS;
SETR15PSR (temp);
#endif
} else {
/* TST immed. */
DPSImmRHS;
dest = LHS & rhs;
ARMul_NegZero (state, dest);
}
break;
case 0x32: /* TEQ immed and MSR immed to CPSR */
if (DESTReg == 15)
/* MSR immed to CPSR. */
ARMul_FixCPSR (state, instr,
DPImmRHS);
else
UNDEF_Test;
break;
case 0x33: /* TEQP immed */
if (DESTReg == 15) {
/* TEQP immed. */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
temp = LHS ^ DPImmRHS;
SETR15PSR (temp);
#endif
} else {
DPSImmRHS; /* TEQ immed */
dest = LHS ^ rhs;
ARMul_NegZero (state, dest);
}
break;
case 0x34: /* CMP immed */
UNDEF_Test;
break;
case 0x35: /* CMPP immed */
if (DESTReg == 15) {
/* CMPP immed. */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
temp = LHS - DPImmRHS;
SETR15PSR (temp);
#endif
break;
} else {
/* CMP immed. */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs - rhs;
ARMul_NegZero (state, dest);
if ((lhs >= rhs) || ((rhs | lhs) >> 31)) {
ARMul_SubCarry (state, lhs, rhs, dest);
ARMul_SubOverflow (state, lhs, rhs, dest);
} else {
CLEARC;
CLEARV;
}
}
break;
case 0x36: /* CMN immed and MSR immed to SPSR */
//if (DESTReg == 15)
/*ARMul0_FixSPSR (state, instr,
DPImmRHS);*/
//else
UNDEF_Test;
break;
case 0x37: /* CMNP immed. */
if (DESTReg == 15) {
/* CMNP immed. */
#ifdef MODE32
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
#else
temp = LHS + DPImmRHS;
SETR15PSR (temp);
#endif
break;
} else {
/* CMN immed. */
lhs = LHS;
rhs = DPImmRHS;
dest = lhs + rhs;
ASSIGNZ (dest == 0);
if ((lhs | rhs) >> 30) {
/* Possible C,V,N to set. */
ASSIGNN (NEG (dest));
ARMul_AddCarry (state, lhs, rhs, dest);
ARMul_AddOverflow (state, lhs, rhs, dest);
} else {
CLEARN;
CLEARC;
CLEARV;
}
}
break;
case 0x38: /* ORR immed. */
dest = LHS | DPImmRHS;
WRITEDEST (dest);
break;
case 0x39: /* ORRS immed. */
DPSImmRHS;
dest = LHS | rhs;
WRITESDEST (dest);
break;
case 0x3a: /* MOV immed. */
dest = DPImmRHS;
WRITEDEST (dest);
break;
case 0x3b: /* MOVS immed. */
DPSImmRHS;
WRITESDEST (rhs);
break;
case 0x3c: /* BIC immed. */
dest = LHS & ~DPImmRHS;
WRITEDEST (dest);
break;
case 0x3d: /* BICS immed. */
DPSImmRHS;
dest = LHS & ~rhs;
WRITESDEST (dest);
break;
case 0x3e: /* MVN immed. */
dest = ~DPImmRHS;
WRITEDEST (dest);
break;
case 0x3f: /* MVNS immed. */
DPSImmRHS;
WRITESDEST (~rhs);
break;
/* Single Data Transfer Immediate RHS Instructions. */
case 0x40: /* Store Word, No WriteBack, Post Dec, Immed. */
lhs = LHS;
if (StoreWord (state, instr, lhs))
LSBase = lhs - LSImmRHS;
break;
case 0x41: /* Load Word, No WriteBack, Post Dec, Immed. */
lhs = LHS;
if (LoadWord (state, instr, lhs))
LSBase = lhs - LSImmRHS;
break;
case 0x42: /* Store Word, WriteBack, Post Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
temp = lhs - LSImmRHS;
state->NtransSig = LOW;
if (StoreWord (state, instr, lhs))
LSBase = temp;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x43: /* Load Word, WriteBack, Post Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (LoadWord (state, instr, lhs))
LSBase = lhs - LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x44: /* Store Byte, No WriteBack, Post Dec, Immed. */
lhs = LHS;
if (StoreByte (state, instr, lhs))
LSBase = lhs - LSImmRHS;
break;
case 0x45: /* Load Byte, No WriteBack, Post Dec, Immed. */
lhs = LHS;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = lhs - LSImmRHS;
break;
case 0x46: /* Store Byte, WriteBack, Post Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreByte (state, instr, lhs))
LSBase = lhs - LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x47: /* Load Byte, WriteBack, Post Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = lhs - LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x48: /* Store Word, No WriteBack, Post Inc, Immed. */
lhs = LHS;
if (StoreWord (state, instr, lhs))
LSBase = lhs + LSImmRHS;
break;
case 0x49: /* Load Word, No WriteBack, Post Inc, Immed. */
lhs = LHS;
if (LoadWord (state, instr, lhs))
LSBase = lhs + LSImmRHS;
break;
case 0x4a: /* Store Word, WriteBack, Post Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreWord (state, instr, lhs))
LSBase = lhs + LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x4b: /* Load Word, WriteBack, Post Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (LoadWord (state, instr, lhs))
LSBase = lhs + LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x4c: /* Store Byte, No WriteBack, Post Inc, Immed. */
lhs = LHS;
if (StoreByte (state, instr, lhs))
LSBase = lhs + LSImmRHS;
break;
case 0x4d: /* Load Byte, No WriteBack, Post Inc, Immed. */
lhs = LHS;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = lhs + LSImmRHS;
break;
case 0x4e: /* Store Byte, WriteBack, Post Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreByte (state, instr, lhs))
LSBase = lhs + LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x4f: /* Load Byte, WriteBack, Post Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
lhs = LHS;
state->NtransSig = LOW;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = lhs + LSImmRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x50: /* Store Word, No WriteBack, Pre Dec, Immed. */
(void) StoreWord (state, instr, LHS - LSImmRHS);
break;
case 0x51: /* Load Word, No WriteBack, Pre Dec, Immed. */
(void) LoadWord (state, instr, LHS - LSImmRHS);
break;
case 0x52: /* Store Word, WriteBack, Pre Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS - LSImmRHS;
if (StoreWord (state, instr, temp))
LSBase = temp;
break;
case 0x53: /* Load Word, WriteBack, Pre Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS - LSImmRHS;
if (LoadWord (state, instr, temp))
LSBase = temp;
break;
case 0x54: /* Store Byte, No WriteBack, Pre Dec, Immed. */
(void) StoreByte (state, instr, LHS - LSImmRHS);
break;
case 0x55: /* Load Byte, No WriteBack, Pre Dec, Immed. */
(void) LoadByte (state, instr, LHS - LSImmRHS, LUNSIGNED);
break;
case 0x56: /* Store Byte, WriteBack, Pre Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS - LSImmRHS;
if (StoreByte (state, instr, temp))
LSBase = temp;
break;
case 0x57: /* Load Byte, WriteBack, Pre Dec, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS - LSImmRHS;
if (LoadByte (state, instr, temp, LUNSIGNED))
LSBase = temp;
break;
case 0x58: /* Store Word, No WriteBack, Pre Inc, Immed. */
(void) StoreWord (state, instr, LHS + LSImmRHS);
break;
case 0x59: /* Load Word, No WriteBack, Pre Inc, Immed. */
(void) LoadWord (state, instr, LHS + LSImmRHS);
break;
case 0x5a: /* Store Word, WriteBack, Pre Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS + LSImmRHS;
if (StoreWord (state, instr, temp))
LSBase = temp;
break;
case 0x5b: /* Load Word, WriteBack, Pre Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS + LSImmRHS;
if (LoadWord (state, instr, temp))
LSBase = temp;
break;
case 0x5c: /* Store Byte, No WriteBack, Pre Inc, Immed. */
(void) StoreByte (state, instr, LHS + LSImmRHS);
break;
case 0x5d: /* Load Byte, No WriteBack, Pre Inc, Immed. */
(void) LoadByte (state, instr, LHS + LSImmRHS, LUNSIGNED);
break;
case 0x5e: /* Store Byte, WriteBack, Pre Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS + LSImmRHS;
if (StoreByte (state, instr, temp))
LSBase = temp;
break;
case 0x5f: /* Load Byte, WriteBack, Pre Inc, Immed. */
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
temp = LHS + LSImmRHS;
if (LoadByte (state, instr, temp, LUNSIGNED))
LSBase = temp;
break;
/* Single Data Transfer Register RHS Instructions. */
case 0x60: /* Store Word, No WriteBack, Post Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
if (StoreWord (state, instr, lhs))
LSBase = lhs - LSRegRHS;
break;
case 0x61: /* Load Word, No WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs - LSRegRHS;
if (LoadWord (state, instr, lhs))
LSBase = temp;
break;
case 0x62: /* Store Word, WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreWord (state, instr, lhs))
LSBase = lhs - LSRegRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x63: /* Load Word, WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs - LSRegRHS;
state->NtransSig = LOW;
if (LoadWord (state, instr, lhs))
LSBase = temp;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x64: /* Store Byte, No WriteBack, Post Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
if (StoreByte (state, instr, lhs))
LSBase = lhs - LSRegRHS;
break;
case 0x65: /* Load Byte, No WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs - LSRegRHS;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = temp;
break;
case 0x66: /* Store Byte, WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreByte (state, instr, lhs))
LSBase = lhs - LSRegRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x67: /* Load Byte, WriteBack, Post Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs - LSRegRHS;
state->NtransSig = LOW;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = temp;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x68: /* Store Word, No WriteBack, Post Inc, Reg. */
if ((instr & 0x70) == 0x10) { //pkhbt
u8 idest = BITS(12, 15);
u8 rfis = BITS(16, 19);
u8 rlast = BITS(0, 3);
u8 ishi = BITS(7,11);
state->Reg[idest] = (state->Reg[rfis] & 0xFFFF) | ((state->Reg[rlast] << ishi) & 0xFFFF0000);
break;
} else if ((instr & 0x70) == 0x50) { //pkhtb
u8 rd_idx = BITS(12, 15);
u8 rn_idx = BITS(16, 19);
u8 rm_idx = BITS(0, 3);
u8 imm5 = BITS(7, 11) ? BITS(7, 11) : 31;
state->Reg[rd_idx] = ((static_cast<s32>(state->Reg[rm_idx]) >> imm5) & 0xFFFF) | ((state->Reg[rn_idx]) & 0xFFFF0000);
break;
} else if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
if (StoreWord (state, instr, lhs))
LSBase = lhs + LSRegRHS;
break;
case 0x69: /* Load Word, No WriteBack, Post Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs + LSRegRHS;
if (LoadWord (state, instr, lhs))
LSBase = temp;
break;
case 0x6a: /* Store Word, WriteBack, Post Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreWord (state, instr, lhs))
LSBase = lhs + LSRegRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x6b: /* Load Word, WriteBack, Post Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs + LSRegRHS;
state->NtransSig = LOW;
if (LoadWord (state, instr, lhs))
LSBase = temp;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x6c: /* Store Byte, No WriteBack, Post Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
if (StoreByte (state, instr, lhs))
LSBase = lhs + LSRegRHS;
break;
case 0x6d: /* Load Byte, No WriteBack, Post Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs + LSRegRHS;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = temp;
break;
case 0x6e: /* Store Byte, WriteBack, Post Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
state->NtransSig = LOW;
if (StoreByte (state, instr, lhs))
LSBase = lhs + LSRegRHS;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x6f: /* Load Byte, WriteBack, Post Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6
&& handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
lhs = LHS;
temp = lhs + LSRegRHS;
state->NtransSig = LOW;
if (LoadByte (state, instr, lhs, LUNSIGNED))
LSBase = temp;
state->NtransSig = (state->Mode & 3) ? HIGH : LOW;
break;
case 0x70: /* Store Word, No WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
(void) StoreWord (state, instr, LHS - LSRegRHS);
break;
case 0x71: /* Load Word, No WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
(void) LoadWord (state, instr, LHS - LSRegRHS);
break;
case 0x72: /* Store Word, WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS - LSRegRHS;
if (StoreWord (state, instr, temp))
LSBase = temp;
break;
case 0x73: /* Load Word, WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS - LSRegRHS;
if (LoadWord (state, instr, temp))
LSBase = temp;
break;
case 0x74: /* Store Byte, No WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
(void) StoreByte (state, instr, LHS - LSRegRHS);
break;
case 0x75: /* Load Byte, No WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
(void) LoadByte (state, instr, LHS - LSRegRHS, LUNSIGNED);
break;
case 0x76: /* Store Byte, WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS - LSRegRHS;
if (StoreByte (state, instr, temp))
LSBase = temp;
break;
case 0x77: /* Load Byte, WriteBack, Pre Dec, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS - LSRegRHS;
if (LoadByte (state, instr, temp, LUNSIGNED))
LSBase = temp;
break;
case 0x78: /* Store Word, No WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
(void) StoreWord (state, instr, LHS + LSRegRHS);
break;
case 0x79: /* Load Word, No WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
(void) LoadWord (state, instr, LHS + LSRegRHS);
break;
case 0x7a: /* Store Word, WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS + LSRegRHS;
if (StoreWord (state, instr, temp))
LSBase = temp;
break;
case 0x7b: /* Load Word, WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS + LSRegRHS;
if (LoadWord (state, instr, temp))
LSBase = temp;
break;
case 0x7c: /* Store Byte, No WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
#ifdef MODE32
if (state->is_v6 && handle_v6_insn (state, instr))
break;
#endif
ARMul_UndefInstr (state, instr);
break;
}
(void) StoreByte (state, instr, LHS + LSRegRHS);
break;
case 0x7d: /* Load Byte, No WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
(void) LoadByte (state, instr, LHS + LSRegRHS, LUNSIGNED);
break;
case 0x7e: /* Store Byte, WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
ARMul_UndefInstr (state, instr);
break;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS + LSRegRHS;
if (StoreByte (state, instr, temp))
LSBase = temp;
break;
case 0x7f: /* Load Byte, WriteBack, Pre Inc, Reg. */
if (BIT (4)) {
LOG_DEBUG(Core_ARM11, "got unhandled special breakpoint");
return 1;
}
UNDEF_LSRBaseEQOffWb;
UNDEF_LSRBaseEQDestWb;
UNDEF_LSRPCBaseWb;
UNDEF_LSRPCOffWb;
temp = LHS + LSRegRHS;
if (LoadByte (state, instr, temp, LUNSIGNED))
LSBase = temp;
break;
/* Multiple Data Transfer Instructions. */
case 0x80: /* Store, No WriteBack, Post Dec. */
STOREMULT (instr, LSBase - LSMNumRegs + 4L, 0L);
break;
case 0x81: /* Load, No WriteBack, Post Dec. */
LOADMULT (instr, LSBase - LSMNumRegs + 4L, 0L);
break;
case 0x82: /* Store, WriteBack, Post Dec. */
temp = LSBase - LSMNumRegs;
STOREMULT (instr, temp + 4L, temp);
break;
case 0x83: /* Load, WriteBack, Post Dec. */
temp = LSBase - LSMNumRegs;
LOADMULT (instr, temp + 4L, temp);
break;
case 0x84: /* Store, Flags, No WriteBack, Post Dec. */
STORESMULT (instr, LSBase - LSMNumRegs + 4L, 0L);
break;
case 0x85: /* Load, Flags, No WriteBack, Post Dec. */
LOADSMULT (instr, LSBase - LSMNumRegs + 4L, 0L);
break;
case 0x86: /* Store, Flags, WriteBack, Post Dec. */
temp = LSBase - LSMNumRegs;
STORESMULT (instr, temp + 4L, temp);
break;
case 0x87: /* Load, Flags, WriteBack, Post Dec. */
temp = LSBase - LSMNumRegs;
LOADSMULT (instr, temp + 4L, temp);
break;
case 0x88: /* Store, No WriteBack, Post Inc. */
STOREMULT (instr, LSBase, 0L);
break;
case 0x89: /* Load, No WriteBack, Post Inc. */
LOADMULT (instr, LSBase, 0L);
break;
case 0x8a: /* Store, WriteBack, Post Inc. */
temp = LSBase;
STOREMULT (instr, temp, temp + LSMNumRegs);
break;
case 0x8b: /* Load, WriteBack, Post Inc. */
temp = LSBase;
LOADMULT (instr, temp, temp + LSMNumRegs);
break;
case 0x8c: /* Store, Flags, No WriteBack, Post Inc. */
STORESMULT (instr, LSBase, 0L);
break;
case 0x8d: /* Load, Flags, No WriteBack, Post Inc. */
LOADSMULT (instr, LSBase, 0L);
break;
case 0x8e: /* Store, Flags, WriteBack, Post Inc. */
temp = LSBase;
STORESMULT (instr, temp, temp + LSMNumRegs);
break;
case 0x8f: /* Load, Flags, WriteBack, Post Inc. */
temp = LSBase;
LOADSMULT (instr, temp, temp + LSMNumRegs);
break;
case 0x90: /* Store, No WriteBack, Pre Dec. */
STOREMULT (instr, LSBase - LSMNumRegs, 0L);
break;
case 0x91: /* Load, No WriteBack, Pre Dec. */
LOADMULT (instr, LSBase - LSMNumRegs, 0L);
break;
case 0x92: /* Store, WriteBack, Pre Dec. */
temp = LSBase - LSMNumRegs;
STOREMULT (instr, temp, temp);
break;
case 0x93: /* Load, WriteBack, Pre Dec. */
temp = LSBase - LSMNumRegs;
LOADMULT (instr, temp, temp);
break;
case 0x94: /* Store, Flags, No WriteBack, Pre Dec. */
STORESMULT (instr, LSBase - LSMNumRegs, 0L);
break;
case 0x95: /* Load, Flags, No WriteBack, Pre Dec. */
LOADSMULT (instr, LSBase - LSMNumRegs, 0L);
break;
case 0x96: /* Store, Flags, WriteBack, Pre Dec. */
temp = LSBase - LSMNumRegs;
STORESMULT (instr, temp, temp);
break;
case 0x97: /* Load, Flags, WriteBack, Pre Dec. */
temp = LSBase - LSMNumRegs;
LOADSMULT (instr, temp, temp);
break;
case 0x98: /* Store, No WriteBack, Pre Inc. */
STOREMULT (instr, LSBase + 4L, 0L);
break;
case 0x99: /* Load, No WriteBack, Pre Inc. */
LOADMULT (instr, LSBase + 4L, 0L);
break;
case 0x9a: /* Store, WriteBack, Pre Inc. */
temp = LSBase;
STOREMULT (instr, temp + 4L, temp + LSMNumRegs);
break;
case 0x9b: /* Load, WriteBack, Pre Inc. */
temp = LSBase;
LOADMULT (instr, temp + 4L, temp + LSMNumRegs);
break;
case 0x9c: /* Store, Flags, No WriteBack, Pre Inc. */
STORESMULT (instr, LSBase + 4L, 0L);
break;
case 0x9d: /* Load, Flags, No WriteBack, Pre Inc. */
LOADSMULT (instr, LSBase + 4L, 0L);
break;
case 0x9e: /* Store, Flags, WriteBack, Pre Inc. */
temp = LSBase;
STORESMULT (instr, temp + 4L, temp + LSMNumRegs);
break;
case 0x9f: /* Load, Flags, WriteBack, Pre Inc. */
temp = LSBase;
LOADSMULT (instr, temp + 4L, temp + LSMNumRegs);
break;
/* Branch forward. */
case 0xa0:
case 0xa1:
case 0xa2:
case 0xa3:
case 0xa4:
case 0xa5:
case 0xa6:
case 0xa7:
state->Reg[15] = pc + 8 + POSBRANCH;
FLUSHPIPE;
break;
/* Branch backward. */
case 0xa8:
case 0xa9:
case 0xaa:
case 0xab:
case 0xac:
case 0xad:
case 0xae:
case 0xaf:
state->Reg[15] = pc + 8 + NEGBRANCH;
FLUSHPIPE;
break;
/* Branch and Link forward. */
case 0xb0:
case 0xb1:
case 0xb2:
case 0xb3:
case 0xb4:
case 0xb5:
case 0xb6:
case 0xb7:
/* Put PC into Link. */
#ifdef MODE32
state->Reg[14] = pc + 4;
#else
state->Reg[14] = (pc + 4) | ECC | ER15INT | EMODE;
#endif
state->Reg[15] = pc + 8 + POSBRANCH;
FLUSHPIPE;
break;
/* Branch and Link backward. */
case 0xb8:
case 0xb9:
case 0xba:
case 0xbb:
case 0xbc:
case 0xbd:
case 0xbe:
case 0xbf:
/* Put PC into Link. */
#ifdef MODE32
state->Reg[14] = pc + 4;
#else
state->Reg[14] = (pc + 4) | ECC | ER15INT | EMODE;
#endif
state->Reg[15] = pc + 8 + NEGBRANCH;
FLUSHPIPE;
break;
/* Co-Processor Data Transfers. */
case 0xc4:
if ((instr & 0x0FF00FF0) == 0xC400B10) { //vmov BIT(0-3), BIT(12-15), BIT(16-20), vmov d0, r0, r0
state->ExtReg[BITS(0, 3) << 1] = state->Reg[BITS(12, 15)];
state->ExtReg[(BITS(0, 3) << 1) + 1] = state->Reg[BITS(16, 20)];
break;
} else if (state->is_v5) {
/* Reading from R15 is UNPREDICTABLE. */
if (BITS (12, 15) == 15 || BITS (16, 19) == 15)
ARMul_UndefInstr (state, instr);
/* Is access to coprocessor 0 allowed ? */
else if (!CP_ACCESS_ALLOWED(state, CPNum))
ARMul_UndefInstr (state, instr);
else {
/* MCRR, ARMv5TE and up */
ARMul_MCRR (state, instr, DEST, state->Reg[LHSReg]);
break;
}
}
/* Drop through. */
case 0xc0: /* Store , No WriteBack , Post Dec. */
ARMul_STC (state, instr, LHS);
break;
case 0xc5:
if ((instr & 0x00000FF0) == 0xB10) { //vmov BIT(12-15), BIT(16-20), BIT(0-3) vmov r0, r0, d0
state->Reg[BITS(12, 15)] = state->ExtReg[BITS(0, 3) << 1];
state->Reg[BITS(16, 19)] = state->ExtReg[(BITS(0, 3) << 1) + 1];
break;
} else if (state->is_v5) {
/* Writes to R15 are UNPREDICATABLE. */
if (DESTReg == 15 || LHSReg == 15)
ARMul_UndefInstr (state, instr);
/* Is access to the coprocessor allowed ? */
else if (!CP_ACCESS_ALLOWED(state, CPNum)) {
ARMul_UndefInstr(state, instr);
} else {
/* MRRC, ARMv5TE and up */
ARMul_MRRC (state, instr, &DEST, &(state->Reg[LHSReg]));
break;
}
}
/* Drop through. */
case 0xc1: /* Load , No WriteBack , Post Dec. */
ARMul_LDC (state, instr, LHS);
break;
case 0xc2:
case 0xc6: /* Store , WriteBack , Post Dec. */
lhs = LHS;
state->Base = lhs - LSCOff;
ARMul_STC (state, instr, lhs);
break;
case 0xc3:
case 0xc7: /* Load , WriteBack , Post Dec. */
lhs = LHS;
state->Base = lhs - LSCOff;
ARMul_LDC (state, instr, lhs);
break;
case 0xc8:
case 0xcc: /* Store , No WriteBack , Post Inc. */
ARMul_STC (state, instr, LHS);
break;
case 0xc9:
case 0xcd: /* Load , No WriteBack , Post Inc. */
ARMul_LDC (state, instr, LHS);
break;
case 0xca:
case 0xce: /* Store , WriteBack , Post Inc. */
lhs = LHS;
state->Base = lhs + LSCOff;
ARMul_STC (state, instr, LHS);
break;
case 0xcb:
case 0xcf: /* Load , WriteBack , Post Inc. */
lhs = LHS;
state->Base = lhs + LSCOff;
ARMul_LDC (state, instr, LHS);
break;
case 0xd0:
case 0xd4: /* Store , No WriteBack , Pre Dec. */
ARMul_STC (state, instr, LHS - LSCOff);
break;
case 0xd1:
case 0xd5: /* Load , No WriteBack , Pre Dec. */
ARMul_LDC (state, instr, LHS - LSCOff);
break;
case 0xd2:
case 0xd6: /* Store , WriteBack , Pre Dec. */
lhs = LHS - LSCOff;
state->Base = lhs;
ARMul_STC (state, instr, lhs);
break;
case 0xd3:
case 0xd7: /* Load , WriteBack , Pre Dec. */
lhs = LHS - LSCOff;
state->Base = lhs;
ARMul_LDC (state, instr, lhs);
break;
case 0xd8:
case 0xdc: /* Store , No WriteBack , Pre Inc. */
ARMul_STC (state, instr, LHS + LSCOff);
break;
case 0xd9:
case 0xdd: /* Load , No WriteBack , Pre Inc. */
ARMul_LDC (state, instr, LHS + LSCOff);
break;
case 0xda:
case 0xde: /* Store , WriteBack , Pre Inc. */
lhs = LHS + LSCOff;
state->Base = lhs;
ARMul_STC (state, instr, lhs);
break;
case 0xdb:
case 0xdf: /* Load , WriteBack , Pre Inc. */
lhs = LHS + LSCOff;
state->Base = lhs;
ARMul_LDC (state, instr, lhs);
break;
/* Co-Processor Register Transfers (MCR) and Data Ops. */
case 0xe2:
/*if (!CP_ACCESS_ALLOWED (state, CPNum)) {
ARMul_UndefInstr (state, instr);
break;
}*/
case 0xe0:
case 0xe4:
case 0xe6:
case 0xe8:
case 0xea:
case 0xec:
case 0xee:
if (BIT (4)) {
/* MCR. */
if (DESTReg == 15) {
UNDEF_MCRPC;
#ifdef MODE32
ARMul_MCR (state, instr, state->Reg[15] + isize);
#else
ARMul_MCR (state, instr, ECC | ER15INT | EMODE | ((state->Reg[15] + isize) & R15PCBITS));
#endif
} else
ARMul_MCR (state, instr, DEST);
} else
/* CDP Part 1. */
ARMul_CDP (state, instr);
break;
/* Co-Processor Register Transfers (MRC) and Data Ops. */
case 0xe1:
case 0xe3:
case 0xe5:
case 0xe7:
case 0xe9:
case 0xeb:
case 0xed:
case 0xef:
if (BIT (4)) {
/* MRC */
temp = ARMul_MRC (state, instr);
if (DESTReg == 15) {
ASSIGNN ((temp & NBIT) != 0);
ASSIGNZ ((temp & ZBIT) != 0);
ASSIGNC ((temp & CBIT) != 0);
ASSIGNV ((temp & VBIT) != 0);
} else
DEST = temp;
} else
/* CDP Part 2. */
ARMul_CDP (state, instr);
break;
/* SWI instruction. */
case 0xf0:
case 0xf1:
case 0xf2:
case 0xf3:
case 0xf4:
case 0xf5:
case 0xf6:
case 0xf7:
case 0xf8:
case 0xf9:
case 0xfa:
case 0xfb:
case 0xfc:
case 0xfd:
case 0xfe:
case 0xff:
//svc_Execute(state, BITS(0, 23));
HLE::CallSVC(instr);
break;
}
}
#ifdef MODET
donext:
#endif
state->pc = pc;
/* jump out every time */
//state->EndCondition = 0;
//state->Emulate = STOP;
//chy 2006-04-12 for ICE debug
TEST_EMULATE:
if (state->Emulate == ONCE)
state->Emulate = STOP;
else if (state->Emulate != RUN)
break;
}
while (state->NumInstrsToExecute);
exit:
state->decoded = decoded;
state->loaded = loaded;
state->pc = pc;
//chy 2006-04-12, for ICE debug
state->decoded_addr=decoded_addr;
state->loaded_addr=loaded_addr;
return pc;
}
static volatile void (*gen_func) (void);
static volatile uint32_t tmp_st;
static volatile uint32_t save_st;
static volatile uint32_t save_T0;
static volatile uint32_t save_T1;
static volatile uint32_t save_T2;
/* This routine evaluates most Data Processing register RHS's with the S
bit clear. It is intended to be called from the macro DPRegRHS, which
filters the common case of an unshifted register with in line code. */
static ARMword
GetDPRegRHS (ARMul_State * state, ARMword instr) {
ARMword shamt, base;
base = RHSReg;
if (BIT (4)) {
/* Shift amount in a register. */
UNDEF_Shift;
INCPC;
#ifndef MODE32
if (base == 15)
base = ECC | ER15INT | R15PC | EMODE;
else
#endif
base = state->Reg[base];
ARMul_Icycles (state, 1, 0L);
shamt = state->Reg[BITS (8, 11)] & 0xff;
switch ((int) BITS (5, 6)) {
case LSL:
if (shamt == 0)
return (base);
else if (shamt >= 32)
return (0);
else
return (base << shamt);
case LSR:
if (shamt == 0)
return (base);
else if (shamt >= 32)
return (0);
else
return (base >> shamt);
case ASR:
if (shamt == 0)
return (base);
else if (shamt >= 32)
return ((ARMword) ((int) base >> 31L));
else
return ((ARMword)
(( int) base >> (int) shamt));
case ROR:
shamt &= 0x1f;
if (shamt == 0)
return (base);
else
return ((base << (32 - shamt)) |
(base >> shamt));
}
} else {
/* Shift amount is a constant. */
#ifndef MODE32
if (base == 15)
base = ECC | ER15INT | R15PC | EMODE;
else
#endif
base = state->Reg[base];
shamt = BITS (7, 11);
switch ((int) BITS (5, 6)) {
case LSL:
return (base << shamt);
case LSR:
if (shamt == 0)
return (0);
else
return (base >> shamt);
case ASR:
if (shamt == 0)
return ((ARMword) (( int) base >> 31L));
else
return ((ARMword)
(( int) base >> (int) shamt));
case ROR:
if (shamt == 0)
/* It's an RRX. */
return ((base >> 1) | (CFLAG << 31));
else
return ((base << (32 - shamt)) |
(base >> shamt));
}
}
return 0;
}
/* This routine evaluates most Logical Data Processing register RHS's
with the S bit set. It is intended to be called from the macro
DPSRegRHS, which filters the common case of an unshifted register
with in line code. */
static ARMword
GetDPSRegRHS (ARMul_State * state, ARMword instr) {
ARMword shamt, base;
base = RHSReg;
if (BIT (4)) {
/* Shift amount in a register. */
UNDEF_Shift;
INCPC;
#ifndef MODE32
if (base == 15)
base = ECC | ER15INT | R15PC | EMODE;
else
#endif
base = state->Reg[base];
ARMul_Icycles (state, 1, 0L);
shamt = state->Reg[BITS (8, 11)] & 0xff;
switch ((int) BITS (5, 6)) {
case LSL:
if (shamt == 0)
return (base);
else if (shamt == 32) {
ASSIGNC (base & 1);
return (0);
} else if (shamt > 32) {
CLEARC;
return (0);
} else {
ASSIGNC ((base >> (32 - shamt)) & 1);
return (base << shamt);
}
case LSR:
if (shamt == 0)
return (base);
else if (shamt == 32) {
ASSIGNC (base >> 31);
return (0);
} else if (shamt > 32) {
CLEARC;
return (0);
} else {
ASSIGNC ((base >> (shamt - 1)) & 1);
return (base >> shamt);
}
case ASR:
if (shamt == 0)
return (base);
else if (shamt >= 32) {
ASSIGNC (base >> 31L);
return ((ARMword) (( int) base >> 31L));
} else {
ASSIGNC ((ARMword)
(( int) base >>
(int) (shamt - 1)) & 1);
return ((ARMword)
((int) base >> (int) shamt));
}
case ROR:
if (shamt == 0)
return (base);
shamt &= 0x1f;
if (shamt == 0) {
ASSIGNC (base >> 31);
return (base);
} else {
ASSIGNC ((base >> (shamt - 1)) & 1);
return ((base << (32 - shamt)) |
(base >> shamt));
}
}
} else {
/* Shift amount is a constant. */
#ifndef MODE32
if (base == 15)
base = ECC | ER15INT | R15PC | EMODE;
else
#endif
base = state->Reg[base];
shamt = BITS (7, 11);
switch ((int) BITS (5, 6)) {
case LSL:
ASSIGNC ((base >> (32 - shamt)) & 1);
return (base << shamt);
case LSR:
if (shamt == 0) {
ASSIGNC (base >> 31);
return (0);
} else {
ASSIGNC ((base >> (shamt - 1)) & 1);
return (base >> shamt);
}
case ASR:
if (shamt == 0) {
ASSIGNC (base >> 31L);
return ((ARMword) ((int) base >> 31L));
} else {
ASSIGNC ((ARMword)
((int) base >>
(int) (shamt - 1)) & 1);
return ((ARMword)
(( int) base >> (int) shamt));
}
case ROR:
if (shamt == 0) {
/* It's an RRX. */
shamt = CFLAG;
ASSIGNC (base & 1);
return ((base >> 1) | (shamt << 31));
} else {
ASSIGNC ((base >> (shamt - 1)) & 1);
return ((base << (32 - shamt)) |
(base >> shamt));
}
}
}
return 0;
}
/* This routine handles writes to register 15 when the S bit is not set. */
static void
WriteR15 (ARMul_State * state, ARMword src) {
/* The ARM documentation states that the two least significant bits
are discarded when setting PC, except in the cases handled by
WriteR15Branch() below. It's probably an oversight: in THUMB
mode, the second least significant bit should probably not be
discarded. */
#ifdef MODET
if (TFLAG)
src &= 0xfffffffe;
else
#endif
src &= 0xfffffffc;
#ifdef MODE32
state->Reg[15] = src & PCBITS;
#else
state->Reg[15] = (src & R15PCBITS) | ECC | ER15INT | EMODE;
ARMul_R15Altered (state);
#endif
FLUSHPIPE;
}
/* This routine handles writes to register 15 when the S bit is set. */
static void
WriteSR15 (ARMul_State * state, ARMword src) {
#ifdef MODE32
if (state->Bank > 0) {
state->Cpsr = state->Spsr[state->Bank];
ARMul_CPSRAltered (state);
}
#ifdef MODET
if (TFLAG)
src &= 0xfffffffe;
else
#endif
src &= 0xfffffffc;
state->Reg[15] = src & PCBITS;
#else
#ifdef MODET
if (TFLAG)
/* ARMul_R15Altered would have to support it. */
abort ();
else
#endif
src &= 0xfffffffc;
if (state->Bank == USERBANK)
state->Reg[15] =
(src & (CCBITS | R15PCBITS)) | ER15INT | EMODE;
else
state->Reg[15] = src;
ARMul_R15Altered (state);
#endif
FLUSHPIPE;
}
/* In machines capable of running in Thumb mode, BX, BLX, LDR and LDM
will switch to Thumb mode if the least significant bit is set. */
static void
WriteR15Branch (ARMul_State * state, ARMword src) {
#ifdef MODET
if (src & 1) {
/* Thumb bit. */
SETT;
state->Reg[15] = src & 0xfffffffe;
} else {
CLEART;
state->Reg[15] = src & 0xfffffffc;
}
state->Cpsr = ARMul_GetCPSR (state);
FLUSHPIPE;
#else
WriteR15 (state, src);
#endif
}
/* This routine evaluates most Load and Store register RHS's. It is
intended to be called from the macro LSRegRHS, which filters the
common case of an unshifted register with in line code. */
static ARMword
GetLSRegRHS (ARMul_State * state, ARMword instr) {
ARMword shamt, base;
base = RHSReg;
#ifndef MODE32
if (base == 15)
/* Now forbidden, but ... */
base = ECC | ER15INT | R15PC | EMODE;
else
#endif
base = state->Reg[base];
shamt = BITS (7, 11);
switch ((int) BITS (5, 6)) {
case LSL:
return (base << shamt);
case LSR:
if (shamt == 0)
return (0);
else
return (base >> shamt);
case ASR:
if (shamt == 0)
return ((ARMword) (( int) base >> 31L));
else
return ((ARMword) (( int) base >> (int) shamt));
case ROR:
if (shamt == 0)
/* It's an RRX. */
return ((base >> 1) | (CFLAG << 31));
else
return ((base << (32 - shamt)) | (base >> shamt));
default:
break;
}
return 0;
}
/* This routine evaluates the ARM7T halfword and signed transfer RHS's. */
static ARMword
GetLS7RHS (ARMul_State * state, ARMword instr) {
if (BIT (22) == 0) {
/* Register. */
#ifndef MODE32
if (RHSReg == 15)
/* Now forbidden, but ... */
return ECC | ER15INT | R15PC | EMODE;
#endif
return state->Reg[RHSReg];
}
/* Immediate. */
return BITS (0, 3) | (BITS (8, 11) << 4);
}
static unsigned
LoadWord (ARMul_State * state, ARMword instr, ARMword address) {
ARMword dest;
BUSUSEDINCPCS;
#ifndef MODE32
if (ADDREXCEPT (address))
INTERNALABORT (address);
#endif
dest = ARMul_LoadWordN (state, address);
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
if (address & 3)
dest = ARMul_Align (state, address, dest);
WRITEDESTB (dest);
ARMul_Icycles (state, 1, 0L);
return (DESTReg != LHSReg);
}
#ifdef MODET
/* This function does the work of loading a halfword. */
static unsigned
LoadHalfWord (ARMul_State * state, ARMword instr, ARMword address,
int signextend) {
ARMword dest;
BUSUSEDINCPCS;
#ifndef MODE32
if (ADDREXCEPT (address))
INTERNALABORT (address);
#endif
dest = ARMul_LoadHalfWord (state, address);
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
UNDEF_LSRBPC;
if (signextend)
if (dest & 1 << (16 - 1))
dest = (dest & ((1 << 16) - 1)) - (1 << 16);
WRITEDEST (dest);
ARMul_Icycles (state, 1, 0L);
return (DESTReg != LHSReg);
}
#endif /* MODET */
/* This function does the work of loading a byte for a LDRB instruction. */
static unsigned
LoadByte (ARMul_State * state, ARMword instr, ARMword address, int signextend) {
ARMword dest;
BUSUSEDINCPCS;
#ifndef MODE32
if (ADDREXCEPT (address))
INTERNALABORT (address);
#endif
dest = ARMul_LoadByte (state, address);
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
UNDEF_LSRBPC;
if (signextend)
if (dest & 1 << (8 - 1))
dest = (dest & ((1 << 8) - 1)) - (1 << 8);
WRITEDEST (dest);
ARMul_Icycles (state, 1, 0L);
return (DESTReg != LHSReg);
}
/* This function does the work of loading two words for a LDRD instruction. */
static void
Handle_Load_Double (ARMul_State * state, ARMword instr) {
ARMword dest_reg;
ARMword addr_reg;
ARMword write_back = BIT (21);
ARMword immediate = BIT (22);
ARMword add_to_base = BIT (23);
ARMword pre_indexed = BIT (24);
ARMword offset;
ARMword addr;
ARMword sum;
ARMword base;
ARMword value1;
ARMword value2;
BUSUSEDINCPCS;
/* If the writeback bit is set, the pre-index bit must be clear. */
if (write_back && !pre_indexed) {
ARMul_UndefInstr (state, instr);
return;
}
/* Extract the base address register. */
addr_reg = LHSReg;
/* Extract the destination register and check it. */
dest_reg = DESTReg;
/* Destination register must be even. */
if ((dest_reg & 1)
/* Destination register cannot be LR. */
|| (dest_reg == 14)) {
ARMul_UndefInstr (state, instr);
return;
}
/* Compute the base address. */
base = state->Reg[addr_reg];
/* Compute the offset. */
offset = immediate ? ((BITS (8, 11) << 4) | BITS (0, 3)) : state->
Reg[RHSReg];
/* Compute the sum of the two. */
if (add_to_base)
sum = base + offset;
else
sum = base - offset;
/* If this is a pre-indexed mode use the sum. */
if (pre_indexed)
addr = sum;
else
addr = base;
/* The address must be aligned on a 8 byte boundary. */
/*if (addr & 0x7) {
#ifdef ABORTS
ARMul_DATAABORT (addr);
#else
ARMul_UndefInstr (state, instr);
#endif
return;
}*/
/* Lets just forcibly align it for now */
//addr = (addr + 7) & ~7;
/* For pre indexed or post indexed addressing modes,
check that the destination registers do not overlap
the address registers. */
if ((!pre_indexed || write_back)
&& (addr_reg == dest_reg || addr_reg == dest_reg + 1)) {
ARMul_UndefInstr (state, instr);
return;
}
/* Load the words. */
value1 = ARMul_LoadWordN (state, addr);
value2 = ARMul_LoadWordN (state, addr + 4);
/* Check for data aborts. */
if (state->Aborted) {
TAKEABORT;
return;
}
ARMul_Icycles (state, 2, 0L);
/* Store the values. */
state->Reg[dest_reg] = value1;
state->Reg[dest_reg + 1] = value2;
/* Do the post addressing and writeback. */
if (!pre_indexed)
addr = sum;
if (!pre_indexed || write_back)
state->Reg[addr_reg] = addr;
}
/* This function does the work of storing two words for a STRD instruction. */
static void
Handle_Store_Double (ARMul_State * state, ARMword instr) {
ARMword src_reg;
ARMword addr_reg;
ARMword write_back = BIT (21);
ARMword immediate = BIT (22);
ARMword add_to_base = BIT (23);
ARMword pre_indexed = BIT (24);
ARMword offset;
ARMword addr;
ARMword sum;
ARMword base;
BUSUSEDINCPCS;
/* If the writeback bit is set, the pre-index bit must be clear. */
if (write_back && !pre_indexed) {
ARMul_UndefInstr (state, instr);
return;
}
/* Extract the base address register. */
addr_reg = LHSReg;
/* Base register cannot be PC. */
if (addr_reg == 15) {
ARMul_UndefInstr (state, instr);
return;
}
/* Extract the source register. */
src_reg = DESTReg;
/* Source register must be even. */
if (src_reg & 1) {
ARMul_UndefInstr (state, instr);
return;
}
/* Compute the base address. */
base = state->Reg[addr_reg];
/* Compute the offset. */
offset = immediate ? ((BITS (8, 11) << 4) | BITS (0, 3)) : state->
Reg[RHSReg];
/* Compute the sum of the two. */
if (add_to_base)
sum = base + offset;
else
sum = base - offset;
/* If this is a pre-indexed mode use the sum. */
if (pre_indexed)
addr = sum;
else
addr = base;
/* The address must be aligned on a 8 byte boundary. */
/*if (addr & 0x7) {
#ifdef ABORTS
ARMul_DATAABORT (addr);
#else
ARMul_UndefInstr (state, instr);
#endif
return;
}*/
/* Lets just forcibly align it for now */
//addr = (addr + 7) & ~7;
/* For pre indexed or post indexed addressing modes,
check that the destination registers do not overlap
the address registers. */
if ((!pre_indexed || write_back)
&& (addr_reg == src_reg || addr_reg == src_reg + 1)) {
ARMul_UndefInstr (state, instr);
return;
}
/* Load the words. */
ARMul_StoreWordN (state, addr, state->Reg[src_reg]);
ARMul_StoreWordN (state, addr + 4, state->Reg[src_reg + 1]);
if (state->Aborted) {
TAKEABORT;
return;
}
/* Do the post addressing and writeback. */
if (!pre_indexed)
addr = sum;
if (!pre_indexed || write_back)
state->Reg[addr_reg] = addr;
}
/* This function does the work of storing a word from a STR instruction. */
static unsigned
StoreWord (ARMul_State * state, ARMword instr, ARMword address) {
BUSUSEDINCPCN;
#ifndef MODE32
if (DESTReg == 15)
state->Reg[15] = ECC | ER15INT | R15PC | EMODE;
#endif
#ifdef MODE32
ARMul_StoreWordN (state, address, DEST);
#else
if (VECTORACCESS (address) || ADDREXCEPT (address)) {
INTERNALABORT (address);
(void) ARMul_LoadWordN (state, address);
} else
ARMul_StoreWordN (state, address, DEST);
#endif
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
return TRUE;
}
#ifdef MODET
/* This function does the work of storing a byte for a STRH instruction. */
static unsigned
StoreHalfWord (ARMul_State * state, ARMword instr, ARMword address) {
BUSUSEDINCPCN;
#ifndef MODE32
if (DESTReg == 15)
state->Reg[15] = ECC | ER15INT | R15PC | EMODE;
#endif
#ifdef MODE32
ARMul_StoreHalfWord (state, address, DEST);
#else
if (VECTORACCESS (address) || ADDREXCEPT (address)) {
INTERNALABORT (address);
(void) ARMul_LoadHalfWord (state, address);
} else
ARMul_StoreHalfWord (state, address, DEST);
#endif
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
return TRUE;
}
#endif /* MODET */
/* This function does the work of storing a byte for a STRB instruction. */
static unsigned
StoreByte (ARMul_State * state, ARMword instr, ARMword address) {
BUSUSEDINCPCN;
#ifndef MODE32
if (DESTReg == 15)
state->Reg[15] = ECC | ER15INT | R15PC | EMODE;
#endif
#ifdef MODE32
ARMul_StoreByte (state, address, DEST);
#else
if (VECTORACCESS (address) || ADDREXCEPT (address)) {
INTERNALABORT (address);
(void) ARMul_LoadByte (state, address);
} else
ARMul_StoreByte (state, address, DEST);
#endif
if (state->Aborted) {
TAKEABORT;
return state->lateabtSig;
}
//UNDEF_LSRBPC;
return TRUE;
}
/* This function does the work of loading the registers listed in an LDM
instruction, when the S bit is clear. The code here is always increment
after, it's up to the caller to get the input address correct and to
handle base register modification. */
static void
LoadMult (ARMul_State * state, ARMword instr, ARMword address, ARMword WBBase) {
ARMword dest, temp;
//UNDEF_LSMNoRegs;
//UNDEF_LSMPCBase;
//UNDEF_LSMBaseInListWb;
BUSUSEDINCPCS;
#ifndef MODE32
if (ADDREXCEPT (address))
INTERNALABORT (address);
#endif
/*chy 2004-05-23 may write twice
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
*/
/* N cycle first. */
for (temp = 0; !BIT (temp); temp++);
dest = ARMul_LoadWordN (state, address);
if (!state->abortSig && !state->Aborted)
state->Reg[temp++] = dest;
else if (!state->Aborted) {
//XScale_set_fsr_far (state, ARMul_CP15_R5_ST_ALIGN, address);
state->Aborted = ARMul_DataAbortV;
}
/*chy 2004-05-23 chy goto end*/
if (state->Aborted)
goto L_ldm_makeabort;
/* S cycles from here on. */
for (; temp < 16; temp++)
if (BIT (temp)) {
/* Load this register. */
address += 4;
dest = ARMul_LoadWordS (state, address);
if (!state->abortSig && !state->Aborted)
state->Reg[temp] = dest;
else if (!state->Aborted) {
/*XScale_set_fsr_far (state,
ARMul_CP15_R5_ST_ALIGN,
address);*/
state->Aborted = ARMul_DataAbortV;
}
/*chy 2004-05-23 chy goto end */
if (state->Aborted)
goto L_ldm_makeabort;
}
if (BIT (15) && !state->Aborted)
/* PC is in the reg list. */
WriteR15Branch (state, PC);
/* To write back the final register. */
/* ARMul_Icycles (state, 1, 0L);*/
/*chy 2004-05-23, see below
if (state->Aborted)
{
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
TAKEABORT;
}
*/
/*chy 2004-05-23 should compare the Abort Models*/
L_ldm_makeabort:
/* To write back the final register. */
ARMul_Icycles (state, 1, 0L);
/* chy 2005-11-24, bug found by benjl@cse.unsw.edu.au, etc */
/*
if (state->Aborted)
{
if (BIT (21) && LHSReg != 15)
if (!(state->abortSig && state->Aborted && state->lateabtSig == LOW))
LSBase = WBBase;
TAKEABORT;
}else if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
*/
if (state->Aborted) {
if (BIT (21) && LHSReg != 15) {
if (!(state->abortSig)) {
}
}
TAKEABORT;
} else if (BIT (21) && LHSReg != 15) {
LSBase = WBBase;
}
/* chy 2005-11-24, over */
}
/* This function does the work of loading the registers listed in an LDM
instruction, when the S bit is set. The code here is always increment
after, it's up to the caller to get the input address correct and to
handle base register modification. */
static void
LoadSMult (ARMul_State * state,
ARMword instr, ARMword address, ARMword WBBase) {
ARMword dest, temp;
//UNDEF_LSMNoRegs;
//UNDEF_LSMPCBase;
//UNDEF_LSMBaseInListWb;
BUSUSEDINCPCS;
#ifndef MODE32
if (ADDREXCEPT (address))
INTERNALABORT (address);
#endif
/* chy 2004-05-23, may write twice
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
*/
if (!BIT (15) && state->Bank != USERBANK) {
/* Temporary reg bank switch. */
(void) ARMul_SwitchMode (state, state->Mode, USER26MODE);
UNDEF_LSMUserBankWb;
}
/* N cycle first. */
for (temp = 0; !BIT (temp); temp++);
dest = ARMul_LoadWordN (state, address);
if (!state->abortSig)
state->Reg[temp++] = dest;
else if (!state->Aborted) {
//XScale_set_fsr_far (state, ARMul_CP15_R5_ST_ALIGN, address);
state->Aborted = ARMul_DataAbortV;
}
/*chy 2004-05-23 chy goto end*/
if (state->Aborted)
goto L_ldm_s_makeabort;
/* S cycles from here on. */
for (; temp < 16; temp++)
if (BIT (temp)) {
/* Load this register. */
address += 4;
dest = ARMul_LoadWordS (state, address);
if (!state->abortSig && !state->Aborted)
state->Reg[temp] = dest;
else if (!state->Aborted) {
/*XScale_set_fsr_far (state,
ARMul_CP15_R5_ST_ALIGN,
address);*/
state->Aborted = ARMul_DataAbortV;
}
/*chy 2004-05-23 chy goto end */
if (state->Aborted)
goto L_ldm_s_makeabort;
}
/*chy 2004-05-23 label of ldm_s_makeabort*/
L_ldm_s_makeabort:
/*chy 2004-06-06 LSBase process should be here, not in the end of this function. Because ARMul_CPSRAltered maybe change R13(SP) R14(lr). If not, simulate INSTR ldmia sp!,[....pc]^ error.*/
/*chy 2004-05-23 should compare the Abort Models*/
if (state->Aborted) {
if (BIT (21) && LHSReg != 15)
if (!
(state->abortSig && state->Aborted
&& state->lateabtSig == LOW))
LSBase = WBBase;
TAKEABORT;
} else if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
if (BIT (15) && !state->Aborted) {
/* PC is in the reg list. */
#ifdef MODE32
//chy 2006-02-16 , should not consider system mode, don't conside 26bit mode
if (state->Mode != USER26MODE && state->Mode != USER32MODE ) {
state->Cpsr = GETSPSR (state->Bank);
ARMul_CPSRAltered (state);
}
WriteR15 (state, PC);
#else
//chy 2006-02-16 , should not consider system mode, don't conside 26bit mode
if (state->Mode == USER26MODE || state->Mode == USER32MODE ) {
/* Protect bits in user mode. */
ASSIGNN ((state->Reg[15] & NBIT) != 0);
ASSIGNZ ((state->Reg[15] & ZBIT) != 0);
ASSIGNC ((state->Reg[15] & CBIT) != 0);
ASSIGNV ((state->Reg[15] & VBIT) != 0);
} else
ARMul_R15Altered (state);
FLUSHPIPE;
#endif
}
//chy 2006-02-16 , should not consider system mode, don't conside 26bit mode
if (!BIT (15) && state->Mode != USER26MODE
&& state->Mode != USER32MODE )
/* Restore the correct bank. */
(void) ARMul_SwitchMode (state, USER26MODE, state->Mode);
/* To write back the final register. */
ARMul_Icycles (state, 1, 0L);
/* chy 2004-05-23, see below
if (state->Aborted)
{
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
TAKEABORT;
}
*/
}
/* This function does the work of storing the registers listed in an STM
instruction, when the S bit is clear. The code here is always increment
after, it's up to the caller to get the input address correct and to
handle base register modification. */
static void
StoreMult (ARMul_State * state,
ARMword instr, ARMword address, ARMword WBBase) {
ARMword temp;
UNDEF_LSMNoRegs;
UNDEF_LSMPCBase;
UNDEF_LSMBaseInListWb;
if (!TFLAG)
/* N-cycle, increment the PC and update the NextInstr state. */
BUSUSEDINCPCN;
#ifndef MODE32
if (VECTORACCESS (address) || ADDREXCEPT (address))
INTERNALABORT (address);
if (BIT (15))
PATCHR15;
#endif
/* N cycle first. */
for (temp = 0; !BIT (temp); temp++);
#ifdef MODE32
ARMul_StoreWordN (state, address, state->Reg[temp++]);
#else
if (state->Aborted) {
(void) ARMul_LoadWordN (state, address);
/* Fake the Stores as Loads. */
for (; temp < 16; temp++)
if (BIT (temp)) {
/* Save this register. */
address += 4;
(void) ARMul_LoadWordS (state, address);
}
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
TAKEABORT;
return;
} else
ARMul_StoreWordN (state, address, state->Reg[temp++]);
#endif
if (state->abortSig && !state->Aborted) {
//XScale_set_fsr_far (state, ARMul_CP15_R5_ST_ALIGN, address);
state->Aborted = ARMul_DataAbortV;
}
//chy 2004-05-23, needn't store other when aborted
if (state->Aborted)
goto L_stm_takeabort;
/* S cycles from here on. */
for (; temp < 16; temp++)
if (BIT (temp)) {
/* Save this register. */
address += 4;
ARMul_StoreWordS (state, address, state->Reg[temp]);
if (state->abortSig && !state->Aborted) {
/*XScale_set_fsr_far (state,
ARMul_CP15_R5_ST_ALIGN,
address);*/
state->Aborted = ARMul_DataAbortV;
}
//chy 2004-05-23, needn't store other when aborted
if (state->Aborted)
goto L_stm_takeabort;
}
//chy 2004-05-23,should compare the Abort Models
L_stm_takeabort:
if (BIT (21) && LHSReg != 15) {
if (!
(state->abortSig && state->Aborted
&& state->lateabtSig == LOW))
LSBase = WBBase;
}
if (state->Aborted)
TAKEABORT;
}
/* This function does the work of storing the registers listed in an STM
instruction when the S bit is set. The code here is always increment
after, it's up to the caller to get the input address correct and to
handle base register modification. */
static void
StoreSMult (ARMul_State * state,
ARMword instr, ARMword address, ARMword WBBase) {
ARMword temp;
UNDEF_LSMNoRegs;
UNDEF_LSMPCBase;
UNDEF_LSMBaseInListWb;
BUSUSEDINCPCN;
#ifndef MODE32
if (VECTORACCESS (address) || ADDREXCEPT (address))
INTERNALABORT (address);
if (BIT (15))
PATCHR15;
#endif
if (state->Bank != USERBANK) {
/* Force User Bank. */
(void) ARMul_SwitchMode (state, state->Mode, USER26MODE);
UNDEF_LSMUserBankWb;
}
for (temp = 0; !BIT (temp); temp++); /* N cycle first. */
#ifdef MODE32
ARMul_StoreWordN (state, address, state->Reg[temp++]);
#else
if (state->Aborted) {
(void) ARMul_LoadWordN (state, address);
for (; temp < 16; temp++)
/* Fake the Stores as Loads. */
if (BIT (temp)) {
/* Save this register. */
address += 4;
(void) ARMul_LoadWordS (state, address);
}
if (BIT (21) && LHSReg != 15)
LSBase = WBBase;
TAKEABORT;
return;
} else
ARMul_StoreWordN (state, address, state->Reg[temp++]);
#endif
if (state->abortSig && !state->Aborted) {
//XScale_set_fsr_far (state, ARMul_CP15_R5_ST_ALIGN, address);
state->Aborted = ARMul_DataAbortV;
}
//chy 2004-05-23, needn't store other when aborted
if (state->Aborted)
goto L_stm_s_takeabort;
/* S cycles from here on. */
for (; temp < 16; temp++)
if (BIT (temp)) {
/* Save this register. */
address += 4;
ARMul_StoreWordS (state, address, state->Reg[temp]);
if (state->abortSig && !state->Aborted) {
/*XScale_set_fsr_far (state,
ARMul_CP15_R5_ST_ALIGN,
address);*/
state->Aborted = ARMul_DataAbortV;
}
//chy 2004-05-23, needn't store other when aborted
if (state->Aborted)
goto L_stm_s_takeabort;
}
//chy 2006-02-16 , should not consider system mode, don't conside 26bit mode
if (state->Mode != USER26MODE && state->Mode != USER32MODE )
/* Restore the correct bank. */
(void) ARMul_SwitchMode (state, USER26MODE, state->Mode);
//chy 2004-05-23,should compare the Abort Models
L_stm_s_takeabort:
if (BIT (21) && LHSReg != 15) {
if (!
(state->abortSig && state->Aborted
&& state->lateabtSig == LOW))
LSBase = WBBase;
}
if (state->Aborted)
TAKEABORT;
}
/* This function does the work of adding two 32bit values
together, and calculating if a carry has occurred. */
static ARMword
Add32 (ARMword a1, ARMword a2, int *carry) {
ARMword result = (a1 + a2);
unsigned int uresult = (unsigned int) result;
unsigned int ua1 = (unsigned int) a1;
/* If (result == RdLo) and (state->Reg[nRdLo] == 0),
or (result > RdLo) then we have no carry. */
if ((uresult == ua1) ? (a2 != 0) : (uresult < ua1))
*carry = 1;
else
*carry = 0;
return result;
}
/* This function does the work of multiplying
two 32bit values to give a 64bit result. */
static unsigned
Multiply64 (ARMul_State * state, ARMword instr, int msigned, int scc) {
/* Operand register numbers. */
int nRdHi, nRdLo, nRs, nRm;
ARMword RdHi = 0, RdLo = 0, Rm;
/* Cycle count. */
int scount;
nRdHi = BITS (16, 19);
nRdLo = BITS (12, 15);
nRs = BITS (8, 11);
nRm = BITS (0, 3);
/* Needed to calculate the cycle count. */
Rm = state->Reg[nRm];
/* Check for illegal operand combinations first. */
if (nRdHi != 15
&& nRdLo != 15
&& nRs != 15
//&& nRm != 15 && nRdHi != nRdLo && nRdHi != nRm && nRdLo != nRm) {
&& nRm != 15 && nRdHi != nRdLo ) {
/* Intermediate results. */
ARMword lo, mid1, mid2, hi;
int carry;
ARMword Rs = state->Reg[nRs];
int sign = 0;
if (msigned) {
/* Compute sign of result and adjust operands if necessary. */
sign = (Rm ^ Rs) & 0x80000000;
if (((signed int) Rm) < 0)
Rm = -Rm;
if (((signed int) Rs) < 0)
Rs = -Rs;
}
/* We can split the 32x32 into four 16x16 operations. This
ensures that we do not lose precision on 32bit only hosts. */
lo = ((Rs & 0xFFFF) * (Rm & 0xFFFF));
mid1 = ((Rs & 0xFFFF) * ((Rm >> 16) & 0xFFFF));
mid2 = (((Rs >> 16) & 0xFFFF) * (Rm & 0xFFFF));
hi = (((Rs >> 16) & 0xFFFF) * ((Rm >> 16) & 0xFFFF));
/* We now need to add all of these results together, taking
care to propogate the carries from the additions. */
RdLo = Add32 (lo, (mid1 << 16), &carry);
RdHi = carry;
RdLo = Add32 (RdLo, (mid2 << 16), &carry);
RdHi += (carry + ((mid1 >> 16) & 0xFFFF) +
((mid2 >> 16) & 0xFFFF) + hi);
if (sign) {
/* Negate result if necessary. */
RdLo = ~RdLo;
RdHi = ~RdHi;
if (RdLo == 0xFFFFFFFF) {
RdLo = 0;
RdHi += 1;
} else
RdLo += 1;
}
state->Reg[nRdLo] = RdLo;
state->Reg[nRdHi] = RdHi;
} else {
fprintf (stderr, "sim: MULTIPLY64 - INVALID ARGUMENTS, instr=0x%x\n", instr);
}
if (scc)
/* Ensure that both RdHi and RdLo are used to compute Z,
but don't let RdLo's sign bit make it to N. */
ARMul_NegZero (state, RdHi | (RdLo >> 16) | (RdLo & 0xFFFF));
/* The cycle count depends on whether the instruction is a signed or
unsigned multiply, and what bits are clear in the multiplier. */
if (msigned && (Rm & ((unsigned) 1 << 31)))
/* Invert the bits to make the check against zero. */
Rm = ~Rm;
if ((Rm & 0xFFFFFF00) == 0)
scount = 1;
else if ((Rm & 0xFFFF0000) == 0)
scount = 2;
else if ((Rm & 0xFF000000) == 0)
scount = 3;
else
scount = 4;
return 2 + scount;
}
/* This function does the work of multiplying two 32bit
values and adding a 64bit value to give a 64bit result. */
static unsigned
MultiplyAdd64 (ARMul_State * state, ARMword instr, int msigned, int scc) {
unsigned scount;
ARMword RdLo, RdHi;
int nRdHi, nRdLo;
int carry = 0;
nRdHi = BITS (16, 19);
nRdLo = BITS (12, 15);
RdHi = state->Reg[nRdHi];
RdLo = state->Reg[nRdLo];
scount = Multiply64 (state, instr, msigned, LDEFAULT);
RdLo = Add32 (RdLo, state->Reg[nRdLo], &carry);
RdHi = (RdHi + state->Reg[nRdHi]) + carry;
state->Reg[nRdLo] = RdLo;
state->Reg[nRdHi] = RdHi;
if (scc)
/* Ensure that both RdHi and RdLo are used to compute Z,
but don't let RdLo's sign bit make it to N. */
ARMul_NegZero (state, RdHi | (RdLo >> 16) | (RdLo & 0xFFFF));
/* Extra cycle for addition. */
return scount + 1;
}
/* Attempt to emulate an ARMv6 instruction.
Returns non-zero upon success. */
static int handle_v6_insn(ARMul_State* state, ARMword instr) {
switch (BITS(20, 27)) {
case 0x03:
printf ("Unhandled v6 insn: ldr\n");
break;
case 0x04: // UMAAL
{
const u8 rm_idx = BITS(8, 11);
const u8 rn_idx = BITS(0, 3);
const u8 rd_lo_idx = BITS(12, 15);
const u8 rd_hi_idx = BITS(16, 19);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
const u32 rd_lo_val = state->Reg[rd_lo_idx];
const u32 rd_hi_val = state->Reg[rd_hi_idx];
const u64 result = (rn_val * rm_val) + rd_lo_val + rd_hi_val;
state->Reg[rd_lo_idx] = (result & 0xFFFFFFFF);
state->Reg[rd_hi_idx] = ((result >> 32) & 0xFFFFFFFF);
return 1;
}
break;
case 0x06:
printf ("Unhandled v6 insn: mls/str\n");
break;
case 0x16:
printf ("Unhandled v6 insn: smi\n");
break;
case 0x18:
if (BITS(4, 7) == 0x9) {
/* strex */
u32 l = LHSReg;
u32 r = RHSReg;
u32 lhs = LHS;
bool enter = false;
if (state->currentexval == (u32)ARMul_ReadWord(state, state->currentexaddr))enter = true;
//StoreWord(state, lhs, RHS)
if (state->Aborted) {
TAKEABORT;
}
if (enter) {
ARMul_StoreWordS(state, lhs, RHS);
state->Reg[DESTReg] = 0;
}
else {
state->Reg[DESTReg] = 1;
}
return 1;
}
printf ("Unhandled v6 insn: strex\n");
break;
case 0x19:
/* ldrex */
if (BITS(4, 7) == 0x9) {
u32 lhs = LHS;
state->currentexaddr = lhs;
state->currentexval = ARMul_ReadWord(state, lhs);
LoadWord(state, instr, lhs);
return 1;
}
printf ("Unhandled v6 insn: ldrex\n");
break;
case 0x1a:
printf ("Unhandled v6 insn: strexd\n");
break;
case 0x1b:
printf ("Unhandled v6 insn: ldrexd\n");
break;
case 0x1c:
if (BITS(4, 7) == 0x9) {
/* strexb */
u32 lhs = LHS;
bool enter = false;
if (state->currentexval == (u32)ARMul_ReadByte(state, state->currentexaddr))enter = true;
BUSUSEDINCPCN;
if (state->Aborted) {
TAKEABORT;
}
if (enter) {
ARMul_StoreByte(state, lhs, RHS);
state->Reg[DESTReg] = 0;
}
else {
state->Reg[DESTReg] = 1;
}
//printf("In %s, strexb not implemented\n", __FUNCTION__);
UNDEF_LSRBPC;
/* WRITESDEST (dest); */
return 1;
}
printf ("Unhandled v6 insn: strexb\n");
break;
case 0x1d:
if ((BITS(4, 7)) == 0x9) {
/* ldrexb */
u32 lhs = LHS;
LoadByte(state, instr, lhs, LUNSIGNED);
state->currentexaddr = lhs;
state->currentexval = (u32)ARMul_ReadByte(state, lhs);
//state->Reg[BITS(12, 15)] = ARMul_LoadByte(state, state->Reg[BITS(16, 19)]);
//printf("ldrexb\n");
//printf("instr is %x rm is %d\n", instr, BITS(16, 19));
//exit(-1);
//printf("In %s, ldrexb not implemented\n", __FUNCTION__);
return 1;
}
printf ("Unhandled v6 insn: ldrexb\n");
break;
case 0x1e:
printf ("Unhandled v6 insn: strexh\n");
break;
case 0x1f:
printf ("Unhandled v6 insn: ldrexh\n");
break;
case 0x30:
printf ("Unhandled v6 insn: movw\n");
break;
case 0x32:
printf ("Unhandled v6 insn: nop/sev/wfe/wfi/yield\n");
break;
case 0x34:
printf ("Unhandled v6 insn: movt\n");
break;
case 0x3f:
printf ("Unhandled v6 insn: rbit\n");
break;
case 0x61: // SADD16, SASX, SSAX, and SSUB16
if ((instr & 0xFF0) == 0xf10 || (instr & 0xFF0) == 0xf30 ||
(instr & 0xFF0) == 0xf50 || (instr & 0xFF0) == 0xf70)
{
const u8 rd_idx = BITS(12, 15);
const u8 rm_idx = BITS(0, 3);
const u8 rn_idx = BITS(16, 19);
const s16 rn_lo = (state->Reg[rn_idx] & 0xFFFF);
const s16 rn_hi = ((state->Reg[rn_idx] >> 16) & 0xFFFF);
const s16 rm_lo = (state->Reg[rm_idx] & 0xFFFF);
const s16 rm_hi = ((state->Reg[rm_idx] >> 16) & 0xFFFF);
s32 lo_result;
s32 hi_result;
// SADD16
if ((instr & 0xFF0) == 0xf10) {
lo_result = (rn_lo + rm_lo);
hi_result = (rn_hi + rm_hi);
}
// SASX
else if ((instr & 0xFF0) == 0xf30) {
lo_result = (rn_lo - rm_hi);
hi_result = (rn_hi + rm_lo);
}
// SSAX
else if ((instr & 0xFF0) == 0xf50) {
lo_result = (rn_lo + rm_hi);
hi_result = (rn_hi - rm_lo);
}
// SSUB16
else {
lo_result = (rn_lo - rm_lo);
hi_result = (rn_hi - rm_hi);
}
state->Reg[rd_idx] = (lo_result & 0xFFFF) | ((hi_result & 0xFFFF) << 16);
if (lo_result >= 0) {
state->GEFlag |= (1 << 16);
state->GEFlag |= (1 << 17);
} else {
state->GEFlag &= ~(1 << 16);
state->GEFlag &= ~(1 << 17);
}
if (hi_result >= 0) {
state->GEFlag |= (1 << 18);
state->GEFlag |= (1 << 19);
} else {
state->GEFlag &= ~(1 << 18);
state->GEFlag &= ~(1 << 19);
}
return 1;
}
// SADD8/SSUB8
else if ((instr & 0xFF0) == 0xf90 || (instr & 0xFF0) == 0xff0)
{
const u8 rd_idx = BITS(12, 15);
const u8 rm_idx = BITS(0, 3);
const u8 rn_idx = BITS(16, 19);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
s32 lo_val1, lo_val2;
s32 hi_val1, hi_val2;
// SADD8
if ((instr & 0xFF0) == 0xf90) {
lo_val1 = (s32)(s8)(rn_val & 0xFF) + (s32)(s8)(rm_val & 0xFF);
lo_val2 = (s32)(s8)((rn_val >> 8) & 0xFF) + (s32)(s8)((rm_val >> 8) & 0xFF);
hi_val1 = (s32)(s8)((rn_val >> 16) & 0xFF) + (s32)(s8)((rm_val >> 16) & 0xFF);
hi_val2 = (s32)(s8)((rn_val >> 24) & 0xFF) + (s32)(s8)((rm_val >> 24) & 0xFF);
}
// SSUB8
else {
lo_val1 = (s32)(s8)(rn_val & 0xFF) - (s32)(s8)(rm_val & 0xFF);
lo_val2 = (s32)(s8)((rn_val >> 8) & 0xFF) - (s32)(s8)((rm_val >> 8) & 0xFF);
hi_val1 = (s32)(s8)((rn_val >> 16) & 0xFF) - (s32)(s8)((rm_val >> 16) & 0xFF);
hi_val2 = (s32)(s8)((rn_val >> 24) & 0xFF) - (s32)(s8)((rm_val >> 24) & 0xFF);
}
if (lo_val1 >= 0)
state->GEFlag |= (1 << 16);
else
state->GEFlag &= ~(1 << 16);
if (lo_val2 >= 0)
state->GEFlag |= (1 << 17);
else
state->GEFlag &= ~(1 << 17);
if (hi_val1 >= 0)
state->GEFlag |= (1 << 18);
else
state->GEFlag &= ~(1 << 18);
if (hi_val2 >= 0)
state->GEFlag |= (1 << 19);
else
state->GEFlag &= ~(1 << 19);
state->Reg[rd_idx] = ((lo_val1 & 0xFF) | ((lo_val2 & 0xFF) << 8) | ((hi_val1 & 0xFF) << 16) | ((hi_val2 & 0xFF) << 24));
return 1;
}
else {
printf("Unhandled v6 insn: %08x", instr);
}
break;
case 0x62: // QADD16, QASX, QSAX, QSUB16, QADD8, and QSUB8
{
const u8 op2 = BITS(5, 7);
const u8 rd_idx = BITS(12, 15);
const u8 rn_idx = BITS(16, 19);
const u8 rm_idx = BITS(0, 3);
const u16 rm_lo = (state->Reg[rm_idx] & 0xFFFF);
const u16 rm_hi = ((state->Reg[rm_idx] >> 0x10) & 0xFFFF);
const u16 rn_lo = (state->Reg[rn_idx] & 0xFFFF);
const u16 rn_hi = ((state->Reg[rn_idx] >> 0x10) & 0xFFFF);
u16 lo_result = 0;
u16 hi_result = 0;
// QADD16
if (op2 == 0x00) {
lo_result = ARMul_SignedSaturatedAdd16(rn_lo, rm_lo);
hi_result = ARMul_SignedSaturatedAdd16(rn_hi, rm_hi);
}
// QASX
else if (op2 == 0x01) {
lo_result = ARMul_SignedSaturatedSub16(rn_lo, rm_hi);
hi_result = ARMul_SignedSaturatedAdd16(rn_hi, rm_lo);
}
// QSAX
else if (op2 == 0x02) {
lo_result = ARMul_SignedSaturatedAdd16(rn_lo, rm_hi);
hi_result = ARMul_SignedSaturatedSub16(rn_hi, rm_lo);
}
// QSUB16
else if (op2 == 0x03) {
lo_result = ARMul_SignedSaturatedSub16(rn_lo, rm_lo);
hi_result = ARMul_SignedSaturatedSub16(rn_hi, rm_hi);
}
// QADD8
else if (op2 == 0x04) {
lo_result = ARMul_SignedSaturatedAdd8(rn_lo & 0xFF, rm_lo & 0xFF) |
ARMul_SignedSaturatedAdd8(rn_lo >> 8, rm_lo >> 8) << 8;
hi_result = ARMul_SignedSaturatedAdd8(rn_hi & 0xFF, rm_hi & 0xFF) |
ARMul_SignedSaturatedAdd8(rn_hi >> 8, rm_hi >> 8) << 8;
}
// QSUB8
else if (op2 == 0x07) {
lo_result = ARMul_SignedSaturatedSub8(rn_lo & 0xFF, rm_lo & 0xFF) |
ARMul_SignedSaturatedSub8(rn_lo >> 8, rm_lo >> 8) << 8;
hi_result = ARMul_SignedSaturatedSub8(rn_hi & 0xFF, rm_hi & 0xFF) |
ARMul_SignedSaturatedSub8(rn_hi >> 8, rm_hi >> 8) << 8;
}
state->Reg[rd_idx] = (lo_result & 0xFFFF) | ((hi_result & 0xFFFF) << 16);
return 1;
}
break;
case 0x63:
printf ("Unhandled v6 insn: shadd/shsub\n");
break;
case 0x65:
{
u32 rd = (instr >> 12) & 0xF;
u32 rn = (instr >> 16) & 0xF;
u32 rm = (instr >> 0) & 0xF;
u32 from = state->Reg[rn];
u32 to = state->Reg[rm];
if ((instr & 0xFF0) == 0xF10 || (instr & 0xFF0) == 0xF70) { // UADD16/USUB16
u32 h1, h2;
state->Cpsr &= 0xfff0ffff;
if ((instr & 0x0F0) == 0x070) { // USUB16
h1 = ((u16)from - (u16)to);
h2 = ((u16)(from >> 16) - (u16)(to >> 16));
if (!(h1 & 0xffff0000))
state->GEFlag |= (3 << 16);
else
state->GEFlag &= ~(3 << 16);
if (!(h2 & 0xffff0000))
state->GEFlag |= (3 << 18);
else
state->GEFlag &= ~(3 << 18);
}
else { // UADD16
h1 = ((u16)from + (u16)to);
h2 = ((u16)(from >> 16) + (u16)(to >> 16));
if (h1 & 0xffff0000)
state->GEFlag |= (3 << 16);
else
state->GEFlag &= ~(3 << 16);
if (h2 & 0xffff0000)
state->GEFlag |= (3 << 18);
else
state->GEFlag &= ~(3 << 18);
}
state->Reg[rd] = (u32)((h1 & 0xffff) | ((h2 & 0xffff) << 16));
return 1;
}
else
if ((instr & 0xFF0) == 0xF90 || (instr & 0xFF0) == 0xFF0) { // UADD8/USUB8
u32 b1, b2, b3, b4;
state->Cpsr &= 0xfff0ffff;
if ((instr & 0x0F0) == 0x0F0) { // USUB8
b1 = ((u8)from - (u8)to);
b2 = ((u8)(from >> 8) - (u8)(to >> 8));
b3 = ((u8)(from >> 16) - (u8)(to >> 16));
b4 = ((u8)(from >> 24) - (u8)(to >> 24));
if (!(b1 & 0xffffff00))
state->GEFlag |= (1 << 16);
else
state->GEFlag &= ~(1 << 16);
if (!(b2 & 0xffffff00))
state->GEFlag |= (1 << 17);
else
state->GEFlag &= ~(1 << 17);
if (!(b3 & 0xffffff00))
state->GEFlag |= (1 << 18);
else
state->GEFlag &= ~(1 << 18);
if (!(b4 & 0xffffff00))
state->GEFlag |= (1 << 19);
else
state->GEFlag &= ~(1 << 19);
}
else { // UADD8
b1 = ((u8)from + (u8)to);
b2 = ((u8)(from >> 8) + (u8)(to >> 8));
b3 = ((u8)(from >> 16) + (u8)(to >> 16));
b4 = ((u8)(from >> 24) + (u8)(to >> 24));
if (b1 & 0xffffff00)
state->GEFlag |= (1 << 16);
else
state->GEFlag &= ~(1 << 16);
if (b2 & 0xffffff00)
state->GEFlag |= (1 << 17);
else
state->GEFlag &= ~(1 << 17);
if (b3 & 0xffffff00)
state->GEFlag |= (1 << 18);
else
state->GEFlag &= ~(1 << 18);
if (b4 & 0xffffff00)
state->GEFlag |= (1 << 19);
else
state->GEFlag &= ~(1 << 19);
}
state->Reg[rd] = (u32)(b1 | (b2 & 0xff) << 8 | (b3 & 0xff) << 16 | (b4 & 0xff) << 24);
return 1;
}
}
printf("Unhandled v6 insn: uasx/usax\n");
break;
case 0x66: // UQADD16, UQASX, UQSAX, UQSUB16, UQADD8, and UQSUB8
{
const u8 rd_idx = BITS(12, 15);
const u8 rm_idx = BITS(0, 3);
const u8 rn_idx = BITS(16, 19);
const u8 op2 = BITS(5, 7);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
u16 lo_val = 0;
u16 hi_val = 0;
// UQADD16
if (op2 == 0x00) {
lo_val = ARMul_UnsignedSaturatedAdd16(rn_val & 0xFFFF, rm_val & 0xFFFF);
hi_val = ARMul_UnsignedSaturatedAdd16((rn_val >> 16) & 0xFFFF, (rm_val >> 16) & 0xFFFF);
}
// UQASX
else if (op2 == 0x01) {
lo_val = ARMul_UnsignedSaturatedSub16(rn_val & 0xFFFF, (rm_val >> 16) & 0xFFFF);
hi_val = ARMul_UnsignedSaturatedAdd16((rn_val >> 16) & 0xFFFF, rm_val & 0xFFFF);
}
// UQSAX
else if (op2 == 0x02) {
lo_val = ARMul_UnsignedSaturatedAdd16(rn_val & 0xFFFF, (rm_val >> 16) & 0xFFFF);
hi_val = ARMul_UnsignedSaturatedSub16((rn_val >> 16) & 0xFFFF, rm_val & 0xFFFF);
}
// UQSUB16
else if (op2 == 0x03) {
lo_val = ARMul_UnsignedSaturatedSub16(rn_val & 0xFFFF, rm_val & 0xFFFF);
hi_val = ARMul_UnsignedSaturatedSub16((rn_val >> 16) & 0xFFFF, (rm_val >> 16) & 0xFFFF);
}
// UQADD8
else if (op2 == 0x04) {
lo_val = ARMul_UnsignedSaturatedAdd8(rn_val, rm_val) |
ARMul_UnsignedSaturatedAdd8(rn_val >> 8, rm_val >> 8) << 8;
hi_val = ARMul_UnsignedSaturatedAdd8(rn_val >> 16, rm_val >> 16) |
ARMul_UnsignedSaturatedAdd8(rn_val >> 24, rm_val >> 24) << 8;
}
// UQSUB8
else {
lo_val = ARMul_UnsignedSaturatedSub8(rn_val, rm_val) |
ARMul_UnsignedSaturatedSub8(rn_val >> 8, rm_val >> 8) << 8;
hi_val = ARMul_UnsignedSaturatedSub8(rn_val >> 16, rm_val >> 16) |
ARMul_UnsignedSaturatedSub8(rn_val >> 24, rm_val >> 24) << 8;
}
state->Reg[rd_idx] = ((lo_val & 0xFFFF) | hi_val << 16);
return 1;
}
break;
case 0x67: // UHADD16, UHASX, UHSAX, UHSUB16, UHADD8, and UHSUB8.
{
const u8 op2 = BITS(5, 7);
const u8 rm_idx = BITS(0, 3);
const u8 rn_idx = BITS(16, 19);
const u8 rd_idx = BITS(12, 15);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
if (op2 == 0x00 || op2 == 0x01 || op2 == 0x02 || op2 == 0x03)
{
u32 lo_val = 0;
u32 hi_val = 0;
// UHADD16
if (op2 == 0x00) {
lo_val = (rn_val & 0xFFFF) + (rm_val & 0xFFFF);
hi_val = ((rn_val >> 16) & 0xFFFF) + ((rm_val >> 16) & 0xFFFF);
}
// UHASX
else if (op2 == 0x01) {
lo_val = (rn_val & 0xFFFF) - ((rm_val >> 16) & 0xFFFF);
hi_val = ((rn_val >> 16) & 0xFFFF) + (rm_val & 0xFFFF);
}
// UHSAX
else if (op2 == 0x02) {
lo_val = (rn_val & 0xFFFF) + ((rm_val >> 16) & 0xFFFF);
hi_val = ((rn_val >> 16) & 0xFFFF) - (rm_val & 0xFFFF);
}
// UHSUB16
else if (op2 == 0x03) {
lo_val = (rn_val & 0xFFFF) - (rm_val & 0xFFFF);
hi_val = ((rn_val >> 16) & 0xFFFF) - ((rm_val >> 16) & 0xFFFF);
}
lo_val >>= 1;
hi_val >>= 1;
state->Reg[rd_idx] = (lo_val & 0xFFFF) | ((hi_val & 0xFFFF) << 16);
return 1;
}
else if (op2 == 0x04 || op2 == 0x07) {
u32 sum1;
u32 sum2;
u32 sum3;
u32 sum4;
// UHADD8
if (op2 == 0x04) {
sum1 = (rn_val & 0xFF) + (rm_val & 0xFF);
sum2 = ((rn_val >> 8) & 0xFF) + ((rm_val >> 8) & 0xFF);
sum3 = ((rn_val >> 16) & 0xFF) + ((rm_val >> 16) & 0xFF);
sum4 = ((rn_val >> 24) & 0xFF) + ((rm_val >> 24) & 0xFF);
}
// UHSUB8
else {
sum1 = (rn_val & 0xFF) - (rm_val & 0xFF);
sum2 = ((rn_val >> 8) & 0xFF) - ((rm_val >> 8) & 0xFF);
sum3 = ((rn_val >> 16) & 0xFF) - ((rm_val >> 16) & 0xFF);
sum4 = ((rn_val >> 24) & 0xFF) - ((rm_val >> 24) & 0xFF);
}
sum1 >>= 1;
sum2 >>= 1;
sum3 >>= 1;
sum4 >>= 1;
state->Reg[rd_idx] = (sum1 & 0xFF) | ((sum2 & 0xFF) << 8) | ((sum3 & 0xFF) << 16) | ((sum4 & 0xFF) << 24);
return 1;
}
}
break;
case 0x68:
{
u32 rd = (instr >> 12) & 0xF;
u32 rn = (instr >> 16) & 0xF;
u32 rm = (instr >> 0) & 0xF;
u32 from = state->Reg[rn];
u32 to = state->Reg[rm];
u32 cpsr = ARMul_GetCPSR(state);
if ((instr & 0xFF0) == 0xFB0) { // SEL
u32 result;
if (cpsr & (1 << 16))
result = from & 0xff;
else
result = to & 0xff;
if (cpsr & (1 << 17))
result |= from & 0x0000ff00;
else
result |= to & 0x0000ff00;
if (cpsr & (1 << 18))
result |= from & 0x00ff0000;
else
result |= to & 0x00ff0000;
if (cpsr & (1 << 19))
result |= from & 0xff000000;
else
result |= to & 0xff000000;
state->Reg[rd] = result;
return 1;
}
}
printf("Unhandled v6 insn: pkh/sxtab/selsxtb\n");
break;
case 0x6a: // SSAT, SSAT16, SXTB, and SXTAB
{
const u8 op2 = BITS(5, 7);
// SSAT16
if (op2 == 0x01) {
const u8 rd_idx = BITS(12, 15);
const u8 rn_idx = BITS(0, 3);
const u8 num_bits = BITS(16, 19) + 1;
const s16 min = -(0x8000 >> (16 - num_bits));
const s16 max = (0x7FFF >> (16 - num_bits));
s16 rn_lo = (state->Reg[rn_idx]);
s16 rn_hi = (state->Reg[rn_idx] >> 16);
if (rn_lo > max) {
rn_lo = max;
SETQ;
} else if (rn_lo < min) {
rn_lo = min;
SETQ;
}
if (rn_hi > max) {
rn_hi = max;
SETQ;
} else if (rn_hi < min) {
rn_hi = min;
SETQ;
}
state->Reg[rd_idx] = (rn_lo & 0xFFFF) | ((rn_hi & 0xFFFF) << 16);
return 1;
}
else if (op2 == 0x03) {
const u8 rotation = BITS(10, 11) * 8;
u32 rm = ((state->Reg[BITS(0, 3)] >> rotation) & 0xFF) | (((state->Reg[BITS(0, 3)] << (32 - rotation)) & 0xFF) & 0xFF);
if (rm & 0x80)
rm |= 0xffffff00;
// SXTB, otherwise SXTAB
if (BITS(16, 19) == 0xf)
state->Reg[BITS(12, 15)] = rm;
else
state->Reg[BITS(12, 15)] = state->Reg[BITS(16, 19)] + rm;
return 1;
}
else {
printf("Unimplemented op: SSAT");
}
}
break;
case 0x6b: // REV, REV16, SXTH, and SXTAH
{
const u8 op2 = BITS(5, 7);
// REV
if (op2 == 0x01) {
DEST = ((RHS & 0xFF) << 24) | ((RHS & 0xFF00)) << 8 | ((RHS & 0xFF0000) >> 8) | ((RHS & 0xFF000000) >> 24);
return 1;
}
// REV16
else if (op2 == 0x05) {
DEST = ((RHS & 0xFF) << 8) | ((RHS & 0xFF00)) >> 8 | ((RHS & 0xFF0000) << 8) | ((RHS & 0xFF000000) >> 8);
return 1;
}
else if (op2 == 0x03) {
const u8 rotate = BITS(10, 11) * 8;
u32 rm = ((state->Reg[BITS(0, 3)] >> rotate) & 0xFFFF) | (((state->Reg[BITS(0, 3)] << (32 - rotate)) & 0xFFFF) & 0xFFFF);
if (rm & 0x8000)
rm |= 0xffff0000;
// SXTH, otherwise SXTAH
if (BITS(16, 19) == 15)
state->Reg[BITS(12, 15)] = rm;
else
state->Reg[BITS(12, 15)] = state->Reg[BITS(16, 19)] + rm;
return 1;
}
}
break;
case 0x6c: // UXTB16 and UXTAB16
{
const u8 rm_idx = BITS(0, 3);
const u8 rn_idx = BITS(16, 19);
const u8 rd_idx = BITS(12, 15);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
const u32 rotation = BITS(10, 11) * 8;
const u32 rotated_rm = ((rm_val << (32 - rotation)) | (rm_val >> rotation));
// UXTB16
if ((instr & 0xf03f0) == 0xf0070) {
state->Reg[rd_idx] = rotated_rm & 0x00FF00FF;
}
else { // UXTAB16
const u8 lo_rotated = (rotated_rm & 0xFF);
const u16 lo_result = (rn_val & 0xFFFF) + (u16)lo_rotated;
const u8 hi_rotated = (rotated_rm >> 16) & 0xFF;
const u16 hi_result = (rn_val >> 16) + (u16)hi_rotated;
state->Reg[rd_idx] = ((hi_result << 16) | (lo_result & 0xFFFF));
}
return 1;
}
break;
case 0x6e: // USAT, USAT16, UXTB, and UXTAB
{
const u8 op2 = BITS(5, 7);
// USAT16
if (op2 == 0x01) {
const u8 rd_idx = BITS(12, 15);
const u8 rn_idx = BITS(0, 3);
const u8 num_bits = BITS(16, 19);
const s16 max = 0xFFFF >> (16 - num_bits);
s16 rn_lo = (state->Reg[rn_idx]);
s16 rn_hi = (state->Reg[rn_idx] >> 16);
if (max < rn_lo) {
rn_lo = max;
SETQ;
} else if (rn_lo < 0) {
rn_lo = 0;
SETQ;
}
if (max < rn_hi) {
rn_hi = max;
SETQ;
} else if (rn_hi < 0) {
rn_hi = 0;
SETQ;
}
state->Reg[rd_idx] = (rn_lo & 0xFFFF) | ((rn_hi << 16) & 0xFFFF);
return 1;
}
else if (op2 == 0x03) {
const u8 rotate = BITS(10, 11) * 8;
const u32 rm = ((state->Reg[BITS(0, 3)] >> rotate) & 0xFF) | (((state->Reg[BITS(0, 3)] << (32 - rotate)) & 0xFF) & 0xFF);
if (BITS(16, 19) == 0xf)
/* UXTB */
state->Reg[BITS(12, 15)] = rm;
else
/* UXTAB */
state->Reg[BITS(12, 15)] = state->Reg[BITS(16, 19)] + rm;
return 1;
}
else {
printf("Unimplemented op: USAT");
}
}
break;
case 0x6f: // UXTH, UXTAH, and REVSH.
{
const u8 op2 = BITS(5, 7);
// REVSH
if (op2 == 0x05) {
DEST = ((RHS & 0xFF) << 8) | ((RHS & 0xFF00) >> 8);
if (DEST & 0x8000)
DEST |= 0xffff0000;
return 1;
}
// UXTH and UXTAH
else if (op2 == 0x03) {
const u8 rotate = BITS(10, 11) * 8;
const ARMword rm = ((state->Reg[BITS(0, 3)] >> rotate) & 0xFFFF) | (((state->Reg[BITS(0, 3)] << (32 - rotate)) & 0xFFFF) & 0xFFFF);
// UXTH
if (BITS(16, 19) == 0xf) {
state->Reg[BITS(12, 15)] = rm;
}
// UXTAH
else {
state->Reg[BITS(12, 15)] = state->Reg[BITS(16, 19)] + rm;
}
return 1;
}
}
case 0x70:
// ichfly
// SMUAD, SMUSD, SMLAD, and SMLSD
if ((instr & 0xf0d0) == 0xf010 || (instr & 0xf0d0) == 0xf050 ||
(instr & 0xd0) == 0x10 || (instr & 0xd0) == 0x50)
{
const u8 rd_idx = BITS(16, 19);
const u8 rn_idx = BITS(0, 3);
const u8 rm_idx = BITS(8, 11);
const u8 ra_idx = BITS(12, 15);
const bool do_swap = (BIT(5) == 1);
u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
if (do_swap)
rm_val = (((rm_val & 0xFFFF) << 16) | (rm_val >> 16));
const s16 rm_lo = (rm_val & 0xFFFF);
const s16 rm_hi = ((rm_val >> 16) & 0xFFFF);
const s16 rn_lo = (rn_val & 0xFFFF);
const s16 rn_hi = ((rn_val >> 16) & 0xFFFF);
const u32 product1 = (rn_lo * rm_lo);
const u32 product2 = (rn_hi * rm_hi);
// SMUAD and SMLAD
if (BIT(6) == 0) {
state->Reg[rd_idx] = product1 + product2;
if (BITS(12, 15) != 15) {
state->Reg[rd_idx] += state->Reg[ra_idx];
if (ARMul_AddOverflowQ(product1 + product2, state->Reg[ra_idx]))
SETQ;
}
if (ARMul_AddOverflowQ(product1, product2))
SETQ;
}
// SMUSD and SMLSD
else {
state->Reg[rd_idx] = product1 - product2;
if (BITS(12, 15) != 15) {
state->Reg[rd_idx] += state->Reg[ra_idx];
if (ARMul_AddOverflowQ(product1 - product2, state->Reg[ra_idx]))
SETQ;
}
}
return 1;
}
break;
case 0x74: // SMLALD and SMLSLD
{
const u8 rm_idx = BITS(8, 11);
const u8 rn_idx = BITS(0, 3);
const u8 rdlo_idx = BITS(12, 15);
const u8 rdhi_idx = BITS(16, 19);
const bool do_swap = (BIT(5) == 1);
const u32 rdlo_val = state->Reg[rdlo_idx];
const u32 rdhi_val = state->Reg[rdhi_idx];
const u32 rn_val = state->Reg[rn_idx];
u32 rm_val = state->Reg[rm_idx];
if (do_swap)
rm_val = (((rm_val & 0xFFFF) << 16) | (rm_val >> 16));
const s32 product1 = (s16)(rn_val & 0xFFFF) * (s16)(rm_val & 0xFFFF);
const s32 product2 = (s16)((rn_val >> 16) & 0xFFFF) * (s16)((rm_val >> 16) & 0xFFFF);
s64 result;
// SMLALD
if (BIT(6) == 0) {
result = (product1 + product2) + (s64)(rdlo_val | ((s64)rdhi_val << 32));
}
// SMLSLD
else {
result = (product1 - product2) + (s64)(rdlo_val | ((s64)rdhi_val << 32));
}
state->Reg[rdlo_idx] = (result & 0xFFFFFFFF);
state->Reg[rdhi_idx] = ((result >> 32) & 0xFFFFFFFF);
return 1;
}
break;
case 0x75: // SMMLA, SMMUL, and SMMLS
{
const u8 rm_idx = BITS(8, 11);
const u8 rn_idx = BITS(0, 3);
const u8 ra_idx = BITS(12, 15);
const u8 rd_idx = BITS(16, 19);
const bool do_round = (BIT(5) == 1);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
// Assume SMMUL by default.
s64 result = (s64)(s32)rn_val * (s64)(s32)rm_val;
if (ra_idx != 15) {
const u32 ra_val = state->Reg[ra_idx];
// SMMLA, otherwise SMMLS
if (BIT(6) == 0)
result += ((s64)ra_val << 32);
else
result = ((s64)ra_val << 32) - result;
}
if (do_round)
result += 0x80000000;
state->Reg[rd_idx] = ((result >> 32) & 0xFFFFFFFF);
return 1;
}
break;
case 0x78:
if (BITS(20, 24) == 0x18)
{
const u8 rm_idx = BITS(8, 11);
const u8 rn_idx = BITS(0, 3);
const u8 rd_idx = BITS(16, 19);
const u32 rm_val = state->Reg[rm_idx];
const u32 rn_val = state->Reg[rn_idx];
const u8 diff1 = ARMul_UnsignedAbsoluteDifference(rn_val & 0xFF, rm_val & 0xFF);
const u8 diff2 = ARMul_UnsignedAbsoluteDifference((rn_val >> 8) & 0xFF, (rm_val >> 8) & 0xFF);
const u8 diff3 = ARMul_UnsignedAbsoluteDifference((rn_val >> 16) & 0xFF, (rm_val >> 16) & 0xFF);
const u8 diff4 = ARMul_UnsignedAbsoluteDifference((rn_val >> 24) & 0xFF, (rm_val >> 24) & 0xFF);
u32 finalDif = (diff1 + diff2 + diff3 + diff4);
// Op is USADA8 if true.
const u8 ra_idx = BITS(12, 15);
if (ra_idx != 15)
finalDif += state->Reg[ra_idx];
state->Reg[rd_idx] = finalDif;
return 1;
}
break;
case 0x7a:
printf ("Unhandled v6 insn: usbfx\n");
break;
case 0x7c:
printf ("Unhandled v6 insn: bfc/bfi\n");
break;
case 0x84:
printf ("Unhandled v6 insn: srs\n");
break;
default:
break;
}
printf("Unhandled v6 insn: UNKNOWN: %08x %08X\n", instr, BITS(20, 27));
return 0;
}
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