Mercurial > vba-linux

     1 #ifdef BKPT_SUPPORT

     2 #define CONSOLE_OUTPUT(a, b) \

     3     extern void (*dbgOutput)(char *, u32); \

     4     if ((opcode == 0xe0000000) && (reg[0].I == 0xC0DED00D)) { \

     5 		dbgOutput((a), (b)); \

     6 	}

     7 #else

     8 #define CONSOLE_OUTPUT(a, b)

     9 #endif

    10 

    11 #define OP_AND \

    12     reg[dest].I = reg[(opcode >> 16) & 15].I & value; \

    13     CONSOLE_OUTPUT(NULL, reg[2].I);

    14 

    15 #define OP_ANDS \

    16     reg[dest].I = reg[(opcode >> 16) & 15].I & value; \

    17       \

    18     N_FLAG = (reg[dest].I & 0x80000000) ? true : false; \

    19     Z_FLAG = (reg[dest].I) ? false : true; \

    20     C_FLAG = C_OUT;

    21 

    22 #define OP_EOR \

    23     reg[dest].I = reg[(opcode >> 16) & 15].I ^ value;

    24 

    25 #define OP_EORS \

    26     reg[dest].I = reg[(opcode >> 16) & 15].I ^ value; \

    27       \

    28     N_FLAG = (reg[dest].I & 0x80000000) ? true : false; \

    29     Z_FLAG = (reg[dest].I) ? false : true; \

    30     C_FLAG = C_OUT;

    31 #ifdef C_CORE

    32 #define NEG(i) ((i) >> 31)

    33 #define POS(i) ((~(i)) >> 31)

    34 #define ADDCARRY(a, b, c) \

    35     C_FLAG = ((NEG(a) & NEG(b)) | \

    36               (NEG(a) & POS(c)) | \

    37               (NEG(b) & POS(c))) ? true : false;

    38 #define ADDOVERFLOW(a, b, c) \

    39     V_FLAG = ((NEG(a) & NEG(b) & POS(c)) | \

    40               (POS(a) & POS(b) & NEG(c))) ? true : false;

    41 #define SUBCARRY(a, b, c) \

    42     C_FLAG = ((NEG(a) & POS(b)) | \

    43               (NEG(a) & POS(c)) | \

    44               (POS(b) & POS(c))) ? true : false;

    45 #define SUBOVERFLOW(a, b, c) \

    46     V_FLAG = ((NEG(a) & POS(b) & POS(c)) | \

    47               (POS(a) & NEG(b) & NEG(c))) ? true : false;

    48 #define OP_SUB \

    49 	{ \

    50 		reg[dest].I = reg[base].I - value; \

    51 	}

    52 #define OP_SUBS \

    53 	{ \

    54 		u32 lhs = reg[base].I; \

    55 		u32 rhs = value; \

    56 		u32 res = lhs - rhs; \

    57 		reg[dest].I = res; \

    58 		Z_FLAG		= (res == 0) ? true : false; \

    59 		N_FLAG		= NEG(res) ? true : false; \

    60 		SUBCARRY(lhs, rhs, res); \

    61 		SUBOVERFLOW(lhs, rhs, res); \

    62 	}

    63 #define OP_RSB \

    64 	{ \

    65 		reg[dest].I = value - reg[base].I; \

    66 	}

    67 #define OP_RSBS \

    68 	{ \

    69 		u32 lhs = reg[base].I; \

    70 		u32 rhs = value; \

    71 		u32 res = rhs - lhs; \

    72 		reg[dest].I = res; \

    73 		Z_FLAG		= (res == 0) ? true : false; \

    74 		N_FLAG		= NEG(res) ? true : false; \

    75 		SUBCARRY(rhs, lhs, res); \

    76 		SUBOVERFLOW(rhs, lhs, res); \

    77 	}

    78 #define OP_ADD \

    79 	{ \

    80 		reg[dest].I = reg[base].I + value; \

    81 	}

    82 #define OP_ADDS \

    83 	{ \

    84 		u32 lhs = reg[base].I; \

    85 		u32 rhs = value; \

    86 		u32 res = lhs + rhs; \

    87 		reg[dest].I = res; \

    88 		Z_FLAG		= (res == 0) ? true : false; \

    89 		N_FLAG		= NEG(res) ? true : false; \

    90 		ADDCARRY(lhs, rhs, res); \

    91 		ADDOVERFLOW(lhs, rhs, res); \

    92 	}

    93 #define OP_ADC \

    94 	{ \

    95 		reg[dest].I = reg[base].I + value + (u32)C_FLAG; \

    96 	}

    97 #define OP_ADCS \

    98 	{ \

    99 		u32 lhs = reg[base].I; \

   100 		u32 rhs = value; \

   101 		u32 res = lhs + rhs + (u32)C_FLAG; \

   102 		reg[dest].I = res; \

   103 		Z_FLAG		= (res == 0) ? true : false; \

   104 		N_FLAG		= NEG(res) ? true : false; \

   105 		ADDCARRY(lhs, rhs, res); \

   106 		ADDOVERFLOW(lhs, rhs, res); \

   107 	}

   108 #define OP_SBC \

   109 	{ \

   110 		reg[dest].I = reg[base].I - value - !((u32)C_FLAG); \

   111 	}

   112 #define OP_SBCS \

   113 	{ \

   114 		u32 lhs = reg[base].I; \

   115 		u32 rhs = value; \

   116 		u32 res = lhs - rhs - !((u32)C_FLAG); \

   117 		reg[dest].I = res; \

   118 		Z_FLAG		= (res == 0) ? true : false; \

   119 		N_FLAG		= NEG(res) ? true : false; \

   120 		SUBCARRY(lhs, rhs, res); \

   121 		SUBOVERFLOW(lhs, rhs, res); \

   122 	}

   123 #define OP_RSC \

   124 	{ \

   125 		reg[dest].I = value - reg[base].I - !((u32)C_FLAG); \

   126 	}

   127 #define OP_RSCS \

   128 	{ \

   129 		u32 lhs = reg[base].I; \

   130 		u32 rhs = value; \

   131 		u32 res = rhs - lhs - !((u32)C_FLAG); \

   132 		reg[dest].I = res; \

   133 		Z_FLAG		= (res == 0) ? true : false; \

   134 		N_FLAG		= NEG(res) ? true : false; \

   135 		SUBCARRY(rhs, lhs, res); \

   136 		SUBOVERFLOW(rhs, lhs, res); \

   137 	}

   138 #define OP_CMP \

   139 	{ \

   140 		u32 lhs = reg[base].I; \

   141 		u32 rhs = value; \

   142 		u32 res = lhs - rhs; \

   143 		Z_FLAG = (res == 0) ? true : false; \

   144 		N_FLAG = NEG(res) ? true : false; \

   145 		SUBCARRY(lhs, rhs, res); \

   146 		SUBOVERFLOW(lhs, rhs, res); \

   147 	}

   148 #define OP_CMN \

   149 	{ \

   150 		u32 lhs = reg[base].I; \

   151 		u32 rhs = value; \

   152 		u32 res = lhs + rhs; \

   153 		Z_FLAG = (res == 0) ? true : false; \

   154 		N_FLAG = NEG(res) ? true : false; \

   155 		ADDCARRY(lhs, rhs, res); \

   156 		ADDOVERFLOW(lhs, rhs, res); \

   157 	}

   158 

   159 #define LOGICAL_LSL_REG \

   160 	{ \

   161 		u32 v = reg[opcode & 0x0f].I; \

   162 		C_OUT = (v >> (32 - shift)) & 1 ? true : false; \

   163 		value = v << shift; \

   164 	}

   165 #define LOGICAL_LSR_REG \

   166 	{ \

   167 		u32 v = reg[opcode & 0x0f].I; \

   168 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   169 		value = v >> shift; \

   170 	}

   171 #define LOGICAL_ASR_REG \

   172 	{ \

   173 		u32 v = reg[opcode & 0x0f].I; \

   174 		C_OUT = ((s32)v >> (int)(shift - 1)) & 1 ? true : false; \

   175 		value = (s32)v >> (int)shift; \

   176 	}

   177 #define LOGICAL_ROR_REG \

   178 	{ \

   179 		u32 v = reg[opcode & 0x0f].I; \

   180 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   181 		value = ((v << (32 - shift)) | \

   182 		         (v >> shift)); \

   183 	}

   184 #define LOGICAL_RRX_REG \

   185 	{ \

   186 		u32 v = reg[opcode & 0x0f].I; \

   187 		shift = (int)C_FLAG; \

   188 		C_OUT = (v  & 1) ? true : false; \

   189 		value = ((v >> 1) | \

   190 		         (shift << 31)); \

   191 	}

   192 #define LOGICAL_ROR_IMM \

   193 	{ \

   194 		u32 v = opcode & 0xff; \

   195 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   196 		value = ((v << (32 - shift)) | \

   197 		         (v >> shift)); \

   198 	}

   199 #define ARITHMETIC_LSL_REG \

   200 	{ \

   201 		u32 v = reg[opcode & 0x0f].I; \

   202 		value = v << shift; \

   203 	}

   204 #define ARITHMETIC_LSR_REG \

   205 	{ \

   206 		u32 v = reg[opcode & 0x0f].I; \

   207 		value = v >> shift; \

   208 	}

   209 #define ARITHMETIC_ASR_REG \

   210 	{ \

   211 		u32 v = reg[opcode & 0x0f].I; \

   212 		value = (s32)v >> (int)shift; \

   213 	}

   214 #define ARITHMETIC_ROR_REG \

   215 	{ \

   216 		u32 v = reg[opcode & 0x0f].I; \

   217 		value = ((v << (32 - shift)) | \

   218 		         (v >> shift)); \

   219 	}

   220 #define ARITHMETIC_RRX_REG \

   221 	{ \

   222 		u32 v = reg[opcode & 0x0f].I; \

   223 		shift = (int)C_FLAG; \

   224 		value = ((v >> 1) | \

   225 		         (shift << 31)); \

   226 	}

   227 #define ARITHMETIC_ROR_IMM \

   228 	{ \

   229 		u32 v = opcode & 0xff; \

   230 		value = ((v << (32 - shift)) | \

   231 		         (v >> shift)); \

   232 	}

   233 #define ROR_IMM_MSR \

   234 	{ \

   235 		u32 v = opcode & 0xff; \

   236 		value = ((v << (32 - shift)) | \

   237 		         (v >> shift)); \

   238 	}

   239 #define ROR_VALUE \

   240 	{ \

   241 		value = ((value << (32 - shift)) | \

   242 		         (value >> shift)); \

   243 	}

   244 #define RCR_VALUE \

   245 	{ \

   246 		shift = (int)C_FLAG; \

   247 		value = ((value >> 1) | \

   248 		         (shift << 31)); \

   249 	}

   250 #else

   251 #ifdef __GNUC__

   252 		#ifdef __POWERPC__

   253 			#define OP_SUB \

   254 	{ \

   255 		reg[dest].I = reg[base].I - value; \

   256 	}

   257 			#define OP_SUBS \

   258 	{ \

   259 		register int Flags;                             \

   260 		register int Result;                            \

   261 		asm volatile ("subco. %0, %2, %3\n"              \

   262 		              "mcrxr cr1\n"                       \

   263 		              "mfcr %1\n"                         \

   264 					  : "=r" (Result),                    \

   265 		              "=r" (Flags)                      \

   266 					  : "r" (reg[base].I),                \

   267 		              "r" (value)                       \

   268 		              );                                  \

   269 		reg[dest].I = Result;                           \

   270 		Z_FLAG		= (Flags >> 29) & 1;                     \

   271 		N_FLAG		= (Flags >> 31) & 1;                     \

   272 		C_FLAG		= (Flags >> 25) & 1;                     \

   273 		V_FLAG		= (Flags >> 26) & 1;                     \

   274 	}

   275 			#define OP_RSB \

   276 	{ \

   277 		reg[dest].I = value - reg[base].I; \

   278 	}

   279 			#define OP_RSBS \

   280 	{ \

   281 		register int Flags;                             \

   282 		register int Result;                            \

   283 		asm volatile ("subfco. %0, %2, %3\n"             \

   284 		              "mcrxr cr1\n"                       \

   285 		              "mfcr %1\n"                         \

   286 					  : "=r" (Result),                    \

   287 		              "=r" (Flags)                      \

   288 					  : "r" (reg[base].I),                \

   289 		              "r" (value)                       \

   290 		              );                                  \

   291 		reg[dest].I = Result;                           \

   292 		Z_FLAG		= (Flags >> 29) & 1;                     \

   293 		N_FLAG		= (Flags >> 31) & 1;                     \

   294 		C_FLAG		= (Flags >> 25) & 1;                     \

   295 		V_FLAG		= (Flags >> 26) & 1;                     \

   296 	}

   297 			#define OP_ADD \

   298 	{ \

   299 		reg[dest].I = reg[base].I + value; \

   300 	}

   301 

   302 			#define OP_ADDS \

   303 	{ \

   304 		register int Flags;                             \

   305 		register int Result;                            \

   306 		asm volatile ("addco. %0, %2, %3\n"              \

   307 		              "mcrxr cr1\n"                       \

   308 		              "mfcr %1\n"                         \

   309 					  : "=r" (Result),                    \

   310 		              "=r" (Flags)                      \

   311 					  : "r" (reg[base].I),                \

   312 		              "r" (value)                       \

   313 		              );                                  \

   314 		reg[dest].I = Result;                           \

   315 		Z_FLAG		= (Flags >> 29) & 1;                     \

   316 		N_FLAG		= (Flags >> 31) & 1;                     \

   317 		C_FLAG		= (Flags >> 25) & 1;                     \

   318 		V_FLAG		= (Flags >> 26) & 1;                     \

   319 	}

   320 			#define OP_ADC \

   321 	{ \

   322 		reg[dest].I = reg[base].I + value + (u32)C_FLAG; \

   323 	}

   324 			#define OP_ADCS \

   325 	{ \

   326 		register int Flags;                             \

   327 		register int Result;                            \

   328 		asm volatile ("mtspr xer, %4\n"                  \

   329 		              "addeo. %0, %2, %3\n"              \

   330 		              "mcrxr cr1\n"                      \

   331 		              "mfcr      %1\n"                   \

   332 					  : "=r" (Result),                   \

   333 		              "=r" (Flags)                     \

   334 					  : "r" (reg[base].I),               \

   335 		              "r" (value),                     \

   336 		              "r" (C_FLAG << 29)               \

   337 		              );                                 \

   338 		reg[dest].I = Result;                           \

   339 		Z_FLAG		= (Flags >> 29) & 1;                     \

   340 		N_FLAG		= (Flags >> 31) & 1;                     \

   341 		C_FLAG		= (Flags >> 25) & 1;                     \

   342 		V_FLAG		= (Flags >> 26) & 1;                     \

   343 	}

   344 			#define OP_SBC \

   345 	{ \

   346 		reg[dest].I = reg[base].I - value - (C_FLAG ^ 1); \

   347 	}

   348 			#define OP_SBCS \

   349 	{ \

   350 		register int Flags;                             \

   351 		register int Result;                            \

   352 		asm volatile ("mtspr xer, %4\n"                  \

   353 		              "subfeo. %0, %3, %2\n"             \

   354 		              "mcrxr cr1\n"                      \

   355 		              "mfcr      %1\n"                   \

   356 					  : "=r" (Result),                   \

   357 		              "=r" (Flags)                     \

   358 					  : "r" (reg[base].I),               \

   359 		              "r" (value),                     \

   360 		              "r" (C_FLAG << 29)               \

   361 		              );                                 \

   362 		reg[dest].I = Result;                           \

   363 		Z_FLAG		= (Flags >> 29) & 1;                     \

   364 		N_FLAG		= (Flags >> 31) & 1;                     \

   365 		C_FLAG		= (Flags >> 25) & 1;                     \

   366 		V_FLAG		= (Flags >> 26) & 1;                     \

   367 	}

   368 			#define OP_RSC \

   369 	{ \

   370 		reg[dest].I = value - reg[base].I - (C_FLAG ^ 1); \

   371 	}

   372 			#define OP_RSCS \

   373 	{ \

   374 		register int Flags;                             \

   375 		register int Result;                            \

   376 		asm volatile ("mtspr xer, %4\n"                  \

   377 		              "subfeo. %0, %2, %3\n"             \

   378 		              "mcrxr cr1\n"                      \

   379 		              "mfcr      %1\n"                   \

   380 					  : "=r" (Result),                   \

   381 		              "=r" (Flags)                     \

   382 					  : "r" (reg[base].I),               \

   383 		              "r" (value),                     \

   384 		              "r" (C_FLAG << 29)               \

   385 		              );                                 \

   386 		reg[dest].I = Result;                           \

   387 		Z_FLAG		= (Flags >> 29) & 1;                     \

   388 		N_FLAG		= (Flags >> 31) & 1;                     \

   389 		C_FLAG		= (Flags >> 25) & 1;                     \

   390 		V_FLAG		= (Flags >> 26) & 1;                     \

   391 	}

   392 			#define OP_CMP \

   393 	{ \

   394 		register int Flags;                             \

   395 		register int Result;                            \

   396 		asm volatile ("subco. %0, %2, %3\n"              \

   397 		              "mcrxr cr1\n"                       \

   398 		              "mfcr %1\n"                         \

   399 					  : "=r" (Result),                    \

   400 		              "=r" (Flags)                      \

   401 					  : "r" (reg[base].I),                \

   402 		              "r" (value)                       \

   403 		              );                                  \

   404 		Z_FLAG = (Flags >> 29) & 1;                     \

   405 		N_FLAG = (Flags >> 31) & 1;                     \

   406 		C_FLAG = (Flags >> 25) & 1;                     \

   407 		V_FLAG = (Flags >> 26) & 1;                     \

   408 	}

   409 			#define OP_CMN \

   410 	{ \

   411 		register int Flags;                             \

   412 		register int Result;                            \

   413 		asm volatile ("addco. %0, %2, %3\n"              \

   414 		              "mcrxr cr1\n"                       \

   415 		              "mfcr %1\n"                         \

   416 					  : "=r" (Result),                    \

   417 		              "=r" (Flags)                      \

   418 					  : "r" (reg[base].I),                \

   419 		              "r" (value)                       \

   420 		              );                                  \

   421 		Z_FLAG = (Flags >> 29) & 1;                     \

   422 		N_FLAG = (Flags >> 31) & 1;                     \

   423 		C_FLAG = (Flags >> 25) & 1;                     \

   424 		V_FLAG = (Flags >> 26) & 1;                     \

   425 	}

   426 

   427 			#define LOGICAL_LSL_REG \

   428 	{ \

   429 		u32 v = reg[opcode & 0x0f].I; \

   430 		C_OUT = (v >> (32 - shift)) & 1 ? true : false; \

   431 		value = v << shift; \

   432 	}

   433 			#define LOGICAL_LSR_REG \

   434 	{ \

   435 		u32 v = reg[opcode & 0x0f].I; \

   436 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   437 		value = v >> shift; \

   438 	}

   439 			#define LOGICAL_ASR_REG \

   440 	{ \

   441 		u32 v = reg[opcode & 0x0f].I; \

   442 		C_OUT = ((s32)v >> (int)(shift - 1)) & 1 ? true : false; \

   443 		value = (s32)v >> (int)shift; \

   444 	}

   445 			#define LOGICAL_ROR_REG \

   446 	{ \

   447 		u32 v = reg[opcode & 0x0f].I; \

   448 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   449 		value = ((v << (32 - shift)) | \

   450 		         (v >> shift)); \

   451 	}

   452 			#define LOGICAL_RRX_REG \

   453 	{ \

   454 		u32 v = reg[opcode & 0x0f].I; \

   455 		shift = (int)C_FLAG; \

   456 		C_OUT = (v  & 1) ? true : false; \

   457 		value = ((v >> 1) | \

   458 		         (shift << 31)); \

   459 	}

   460 			#define LOGICAL_ROR_IMM \

   461 	{ \

   462 		u32 v = opcode & 0xff; \

   463 		C_OUT = (v >> (shift - 1)) & 1 ? true : false; \

   464 		value = ((v << (32 - shift)) | \

   465 		         (v >> shift)); \

   466 	}

   467 			#define ARITHMETIC_LSL_REG \

   468 	{ \

   469 		u32 v = reg[opcode & 0x0f].I; \

   470 		value = v << shift; \

   471 	}

   472 			#define ARITHMETIC_LSR_REG \

   473 	{ \

   474 		u32 v = reg[opcode & 0x0f].I; \

   475 		value = v >> shift; \

   476 	}

   477 			#define ARITHMETIC_ASR_REG \

   478 	{ \

   479 		u32 v = reg[opcode & 0x0f].I; \

   480 		value = (s32)v >> (int)shift; \

   481 	}

   482 			#define ARITHMETIC_ROR_REG \

   483 	{ \

   484 		u32 v = reg[opcode & 0x0f].I; \

   485 		value = ((v << (32 - shift)) | \

   486 		         (v >> shift)); \

   487 	}

   488 			#define ARITHMETIC_RRX_REG \

   489 	{ \

   490 		u32 v = reg[opcode & 0x0f].I; \

   491 		shift = (int)C_FLAG; \

   492 		value = ((v >> 1) | \

   493 		         (shift << 31)); \

   494 	}

   495 			#define ARITHMETIC_ROR_IMM \

   496 	{ \

   497 		u32 v = opcode & 0xff; \

   498 		value = ((v << (32 - shift)) | \

   499 		         (v >> shift)); \

   500 	}

   501 			#define ROR_IMM_MSR \

   502 	{ \

   503 		u32 v = opcode & 0xff; \

   504 		value = ((v << (32 - shift)) | \

   505 		         (v >> shift)); \

   506 	}

   507 			#define ROR_VALUE \

   508 	{ \

   509 		value = ((value << (32 - shift)) | \

   510 		         (value >> shift)); \

   511 	}

   512 			#define RCR_VALUE \

   513 	{ \

   514 		shift = (int)C_FLAG; \

   515 		value = ((value >> 1) | \

   516 		         (shift << 31)); \

   517 	}

   518 #else

   519 #define OP_SUB \

   520     asm ("sub %1, %%ebx;" \

   521 		 : "=b" (reg[dest].I) \

   522 		 : "r" (value), "b" (reg[base].I));

   523 

   524 #define OP_SUBS \

   525     asm ("sub %1, %%ebx;" \

   526          "setsb N_FLAG;" \

   527          "setzb Z_FLAG;" \

   528          "setncb C_FLAG;" \

   529          "setob V_FLAG;" \

   530 		 : "=b" (reg[dest].I) \

   531 		 : "r" (value), "b" (reg[base].I));

   532 

   533 #define OP_RSB \

   534     asm  ("sub %1, %%ebx;" \

   535 		  : "=b" (reg[dest].I) \

   536 		  : "r" (reg[base].I), "b" (value));

   537 

   538 #define OP_RSBS \

   539     asm  ("sub %1, %%ebx;" \

   540           "setsb N_FLAG;" \

   541           "setzb Z_FLAG;" \

   542           "setncb C_FLAG;" \

   543           "setob V_FLAG;" \

   544 		  : "=b" (reg[dest].I) \

   545 		  : "r" (reg[base].I), "b" (value));

   546 

   547 #define OP_ADD \

   548     asm  ("add %1, %%ebx;" \

   549 		  : "=b" (reg[dest].I) \

   550 		  : "r" (value), "b" (reg[base].I));

   551 

   552 #define OP_ADDS \

   553     asm  ("add %1, %%ebx;" \

   554           "setsb N_FLAG;" \

   555           "setzb Z_FLAG;" \

   556           "setcb C_FLAG;" \

   557           "setob V_FLAG;" \

   558 		  : "=b" (reg[dest].I) \

   559 		  : "r" (value), "b" (reg[base].I));

   560 

   561 #define OP_ADC \

   562     asm  ("bt $0, C_FLAG;" \

   563           "adc %1, %%ebx;" \

   564 		  : "=b" (reg[dest].I) \

   565 		  : "r" (value), "b" (reg[base].I));

   566 

   567 #define OP_ADCS \

   568     asm  ("bt $0, C_FLAG;" \

   569           "adc %1, %%ebx;" \

   570           "setsb N_FLAG;" \

   571           "setzb Z_FLAG;" \

   572           "setcb C_FLAG;" \

   573           "setob V_FLAG;" \

   574 		  : "=b" (reg[dest].I) \

   575 		  : "r" (value), "b" (reg[base].I));

   576 

   577 #define OP_SBC \

   578     asm  ("bt $0, C_FLAG;" \

   579           "cmc;" \

   580           "sbb %1, %%ebx;" \

   581 		  : "=b" (reg[dest].I) \

   582 		  : "r" (value), "b" (reg[base].I));

   583 

   584 #define OP_SBCS \

   585     asm  ("bt $0, C_FLAG;" \

   586           "cmc;" \

   587           "sbb %1, %%ebx;" \

   588           "setsb N_FLAG;" \

   589           "setzb Z_FLAG;" \

   590           "setncb C_FLAG;" \

   591           "setob V_FLAG;" \

   592 		  : "=b" (reg[dest].I) \

   593 		  : "r" (value), "b" (reg[base].I));

   594 #define OP_RSC \

   595     asm  ("bt $0, C_FLAG;" \

   596           "cmc;" \

   597           "sbb %1, %%ebx;" \

   598 		  : "=b" (reg[dest].I) \

   599 		  : "r" (reg[base].I), "b" (value));

   600 

   601 #define OP_RSCS \

   602     asm  ("bt $0, C_FLAG;" \

   603           "cmc;" \

   604           "sbb %1, %%ebx;" \

   605           "setsb N_FLAG;" \

   606           "setzb Z_FLAG;" \

   607           "setncb C_FLAG;" \

   608           "setob V_FLAG;" \

   609 		  : "=b" (reg[dest].I) \

   610 		  : "r" (reg[base].I), "b" (value));

   611 #define OP_CMP \

   612     asm  ("sub %0, %1;" \

   613           "setsb N_FLAG;" \

   614           "setzb Z_FLAG;" \

   615           "setncb C_FLAG;" \

   616           "setob V_FLAG;" \

   617 		  : \

   618 		  : "r" (value), "r" (reg[base].I));

   619 

   620 #define OP_CMN \

   621     asm  ("add %0, %1;" \

   622           "setsb N_FLAG;" \

   623           "setzb Z_FLAG;" \

   624           "setcb C_FLAG;" \

   625           "setob V_FLAG;" \

   626 		  : \

   627 		  : "r" (value), "r" (reg[base].I));

   628 #define LOGICAL_LSL_REG \

   629     asm ("shl %%cl, %%eax;" \

   630          "setcb %%cl;" \

   631 		 : "=a" (value), "=c" (C_OUT) \

   632 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   633 

   634 #define LOGICAL_LSR_REG \

   635     asm ("shr %%cl, %%eax;" \

   636          "setcb %%cl;" \

   637 		 : "=a" (value), "=c" (C_OUT) \

   638 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   639 

   640 #define LOGICAL_ASR_REG \

   641     asm ("sar %%cl, %%eax;" \

   642          "setcb %%cl;" \

   643 		 : "=a" (value), "=c" (C_OUT) \

   644 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   645 

   646 #define LOGICAL_ROR_REG \

   647     asm ("ror %%cl, %%eax;" \

   648          "setcb %%cl;" \

   649 		 : "=a" (value), "=c" (C_OUT) \

   650 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   651 

   652 #define LOGICAL_RRX_REG \

   653     asm ("bt $0, C_FLAG;" \

   654          "rcr $1, %%eax;" \

   655          "setcb %%cl;" \

   656 		 : "=a" (value), "=c" (C_OUT) \

   657 		 : "a" (reg[opcode & 0x0f].I));

   658 

   659 #define LOGICAL_ROR_IMM \

   660     asm ("ror %%cl, %%eax;" \

   661          "setcb %%cl;" \

   662 		 : "=a" (value), "=c" (C_OUT) \

   663 		 : "a" (opcode & 0xff), "c" (shift));

   664 #define ARITHMETIC_LSL_REG \

   665     asm ("\

   666              shl %%cl, %%eax;" \

   667 		 : "=a" (value) \

   668 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   669 

   670 #define ARITHMETIC_LSR_REG \

   671     asm ("\

   672              shr %%cl, %%eax;" \

   673 		 : "=a" (value) \

   674 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   675 

   676 #define ARITHMETIC_ASR_REG \

   677     asm ("\

   678              sar %%cl, %%eax;" \

   679 		 : "=a" (value) \

   680 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   681 

   682 #define ARITHMETIC_ROR_REG \

   683     asm ("\

   684              ror %%cl, %%eax;" \

   685 		 : "=a" (value) \

   686 		 : "a" (reg[opcode & 0x0f].I), "c" (shift));

   687 

   688 #define ARITHMETIC_RRX_REG \

   689     asm ("\

   690              bt $0, C_FLAG;\

   691              rcr $1, %%eax;" \

   692 		 : "=a" (value) \

   693 		 : "a" (reg[opcode & 0x0f].I));

   694 

   695 #define ARITHMETIC_ROR_IMM \

   696     asm ("\

   697              ror %%cl, %%eax;" \

   698 		 : "=a" (value) \

   699 		 : "a" (opcode & 0xff), "c" (shift));

   700 #define ROR_IMM_MSR \

   701     asm ("ror %%cl, %%eax;" \

   702 		 : "=a" (value) \

   703 		 : "a" (opcode & 0xFF), "c" (shift));

   704 #define ROR_VALUE \

   705     asm ("ror %%cl, %0" \

   706 		 : "=r" (value) \

   707 		 : "r" (value), "c" (shift));

   708 #define RCR_VALUE \

   709     asm ("bt $0, C_FLAG;" \

   710          "rcr $1, %0" \

   711 		 : "=r" (value) \

   712 		 : "r" (value));

   713 #endif

   714 #else

   715 #define OP_SUB \

   716 	{ \

   717 		__asm mov ebx, base \

   718 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   719 		__asm sub ebx, value \

   720 		__asm mov eax, dest \

   721 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   722 	}

   723 

   724 #define OP_SUBS \

   725 	{ \

   726 		__asm mov ebx, base \

   727 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   728 		__asm sub ebx, value \

   729 		__asm mov eax, dest \

   730 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   731 		__asm sets byte ptr N_FLAG \

   732 		__asm setz byte ptr Z_FLAG \

   733 		__asm setnc byte ptr C_FLAG \

   734 		__asm seto byte ptr V_FLAG \

   735 	}

   736 

   737 #define OP_RSB \

   738 	{ \

   739 		__asm mov ebx, base \

   740 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   741 		__asm mov eax, value \

   742 		__asm sub eax, ebx \

   743 		__asm mov ebx, dest \

   744 		__asm mov dword ptr [OFFSET reg + 4 * ebx], eax \

   745 	}

   746 

   747 #define OP_RSBS \

   748 	{ \

   749 		__asm mov ebx, base \

   750 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   751 		__asm mov eax, value \

   752 		__asm sub eax, ebx \

   753 		__asm mov ebx, dest \

   754 		__asm mov dword ptr [OFFSET reg + 4 * ebx], eax \

   755 		__asm sets byte ptr N_FLAG \

   756 		__asm setz byte ptr Z_FLAG \

   757 		__asm setnc byte ptr C_FLAG \

   758 		__asm seto byte ptr V_FLAG \

   759 	}

   760 

   761 #define OP_ADD \

   762 	{ \

   763 		__asm mov ebx, base \

   764 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   765 		__asm add ebx, value \

   766 		__asm mov eax, dest \

   767 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   768 	}

   769 

   770 #define OP_ADDS \

   771 	{ \

   772 		__asm mov ebx, base \

   773 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   774 		__asm add ebx, value \

   775 		__asm mov eax, dest \

   776 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   777 		__asm sets byte ptr N_FLAG \

   778 		__asm setz byte ptr Z_FLAG \

   779 		__asm setc byte ptr C_FLAG \

   780 		__asm seto byte ptr V_FLAG \

   781 	}

   782 

   783 #define OP_ADC \

   784 	{ \

   785 		__asm mov ebx, base \

   786 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   787 		__asm bt word ptr C_FLAG, 0 \

   788 		__asm adc ebx, value \

   789 		__asm mov eax, dest \

   790 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   791 	}

   792 

   793 #define OP_ADCS \

   794 	{ \

   795 		__asm mov ebx, base \

   796 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   797 		__asm bt word ptr C_FLAG, 0 \

   798 		__asm adc ebx, value \

   799 		__asm mov eax, dest \

   800 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   801 		__asm sets byte ptr N_FLAG \

   802 		__asm setz byte ptr Z_FLAG \

   803 		__asm setc byte ptr C_FLAG \

   804 		__asm seto byte ptr V_FLAG \

   805 	}

   806 

   807 #define OP_SBC \

   808 	{ \

   809 		__asm mov ebx, base \

   810 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   811 		__asm mov eax, value \

   812 		__asm bt word ptr C_FLAG, 0 \

   813 		__asm cmc \

   814 		__asm sbb ebx, eax \

   815 		__asm mov eax, dest \

   816 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   817 	}

   818 

   819 #define OP_SBCS \

   820 	{ \

   821 		__asm mov ebx, base \

   822 		__asm mov ebx, dword ptr [OFFSET reg + 4 * ebx] \

   823 		__asm mov eax, value \

   824 		__asm bt word ptr C_FLAG, 0 \

   825 		__asm cmc \

   826 		__asm sbb ebx, eax \

   827 		__asm mov eax, dest \

   828 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   829 		__asm sets byte ptr N_FLAG \

   830 		__asm setz byte ptr Z_FLAG \

   831 		__asm setnc byte ptr C_FLAG \

   832 		__asm seto byte ptr V_FLAG \

   833 	}

   834 #define OP_RSC \

   835 	{ \

   836 		__asm mov ebx, value \

   837 		__asm mov eax, base \

   838 		__asm mov eax, dword ptr[OFFSET reg + 4 * eax] \

   839 		__asm bt word ptr C_FLAG, 0 \

   840 		__asm cmc \

   841 		__asm sbb ebx, eax \

   842 		__asm mov eax, dest \

   843 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   844 	}

   845 

   846 #define OP_RSCS \

   847 	{ \

   848 		__asm mov ebx, value \

   849 		__asm mov eax, base \

   850 		__asm mov eax, dword ptr[OFFSET reg + 4 * eax] \

   851 		__asm bt word ptr C_FLAG, 0 \

   852 		__asm cmc \

   853 		__asm sbb ebx, eax \

   854 		__asm mov eax, dest \

   855 		__asm mov dword ptr [OFFSET reg + 4 * eax], ebx \

   856 		__asm sets byte ptr N_FLAG \

   857 		__asm setz byte ptr Z_FLAG \

   858 		__asm setnc byte ptr C_FLAG \

   859 		__asm seto byte ptr V_FLAG \

   860 	}

   861 #define OP_CMP \

   862 	{ \

   863 		__asm mov eax, base \

   864 		__asm mov ebx, dword ptr [OFFSET reg + 4 * eax] \

   865 		__asm sub ebx, value \

   866 		__asm sets byte ptr N_FLAG \

   867 		__asm setz byte ptr Z_FLAG \

   868 		__asm setnc byte ptr C_FLAG \

   869 		__asm seto byte ptr V_FLAG \

   870 	}

   871 

   872 #define OP_CMN \

   873 	{ \

   874 		__asm mov eax, base \

   875 		__asm mov ebx, dword ptr [OFFSET reg + 4 * eax] \

   876 		__asm add ebx, value \

   877 		__asm sets byte ptr N_FLAG \

   878 		__asm setz byte ptr Z_FLAG \

   879 		__asm setc byte ptr C_FLAG \

   880 		__asm seto byte ptr V_FLAG \

   881 	}

   882 #define LOGICAL_LSL_REG \

   883     __asm mov eax, opcode \

   884     __asm and eax, 0x0f \

   885     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   886     __asm mov cl, byte ptr shift \

   887     __asm shl eax, cl \

   888     __asm mov value, eax \

   889     __asm setc byte ptr C_OUT

   890 

   891 #define LOGICAL_LSR_REG \

   892     __asm mov eax, opcode \

   893     __asm and eax, 0x0f \

   894     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   895     __asm mov cl, byte ptr shift \

   896     __asm shr eax, cl \

   897     __asm mov value, eax \

   898     __asm setc byte ptr C_OUT

   899 

   900 #define LOGICAL_ASR_REG \

   901     __asm mov eax, opcode \

   902     __asm and eax, 0x0f \

   903     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   904     __asm mov cl, byte ptr shift \

   905     __asm sar eax, cl \

   906     __asm mov value, eax \

   907     __asm setc byte ptr C_OUT

   908 

   909 #define LOGICAL_ROR_REG \

   910     __asm mov eax, opcode \

   911     __asm and eax, 0x0F \

   912     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   913     __asm mov cl, byte ptr shift \

   914     __asm ror eax, cl \

   915     __asm mov value, eax \

   916     __asm setc byte ptr C_OUT

   917 

   918 #define LOGICAL_RRX_REG \

   919     __asm mov eax, opcode \

   920     __asm and eax, 0x0F \

   921     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   922     __asm bt word ptr C_OUT, 0 \

   923     __asm rcr eax, 1 \

   924     __asm mov value, eax \

   925     __asm setc byte ptr C_OUT

   926 

   927 #define LOGICAL_ROR_IMM \

   928     __asm mov eax, opcode \

   929     __asm and eax, 0xff \

   930     __asm mov cl, byte ptr shift \

   931     __asm ror eax, cl \

   932     __asm mov value, eax \

   933     __asm setc byte ptr C_OUT

   934 #define ARITHMETIC_LSL_REG \

   935     __asm mov eax, opcode \

   936     __asm and eax, 0x0f \

   937     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   938     __asm mov cl, byte ptr shift \

   939     __asm shl eax, cl \

   940     __asm mov value, eax

   941 

   942 #define ARITHMETIC_LSR_REG \

   943     __asm mov eax, opcode \

   944     __asm and eax, 0x0f \

   945     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   946     __asm mov cl, byte ptr shift \

   947     __asm shr eax, cl \

   948     __asm mov value, eax

   949 

   950 #define ARITHMETIC_ASR_REG \

   951     __asm mov eax, opcode \

   952     __asm and eax, 0x0f \

   953     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   954     __asm mov cl, byte ptr shift \

   955     __asm sar eax, cl \

   956     __asm mov value, eax

   957 

   958 #define ARITHMETIC_ROR_REG \

   959     __asm mov eax, opcode \

   960     __asm and eax, 0x0F \

   961     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   962     __asm mov cl, byte ptr shift \

   963     __asm ror eax, cl \

   964     __asm mov value, eax

   965 

   966 #define ARITHMETIC_RRX_REG \

   967     __asm mov eax, opcode \

   968     __asm and eax, 0x0F \

   969     __asm mov eax, dword ptr [OFFSET reg + 4 * eax] \

   970     __asm bt word ptr C_FLAG, 0 \

   971     __asm rcr eax, 1 \

   972     __asm mov value, eax

   973 

   974 #define ARITHMETIC_ROR_IMM \

   975     __asm mov eax, opcode \

   976     __asm and eax, 0xff \

   977     __asm mov cl, byte ptr shift \

   978     __asm ror eax, cl \

   979     __asm mov value, eax

   980 #define ROR_IMM_MSR \

   981 	{ \

   982 		__asm mov eax, opcode \

   983 		          __asm and eax, 0xff \

   984 		__asm mov cl, byte ptr shift \

   985 		__asm ror eax, CL \

   986 		__asm mov value, eax \

   987 	}

   988 #define ROR_VALUE \

   989 	{ \

   990 		__asm mov cl, byte ptr shift \

   991 		__asm ror dword ptr value, cl \

   992 	}

   993 #define RCR_VALUE \

   994 	{ \

   995 		__asm mov cl, byte ptr shift \

   996 		__asm bt word ptr C_FLAG, 0 \

   997 		__asm rcr dword ptr value, 1 \

   998 	}

   999 #endif

  1000 #endif

  1001 

  1002 #define OP_TST \

  1003     u32 res = reg[base].I & value; \

  1004     N_FLAG	= (res & 0x80000000) ? true : false; \

  1005     Z_FLAG	= (res) ? false : true; \

  1006     C_FLAG	= C_OUT;

  1007 

  1008 #define OP_TEQ \

  1009     u32 res = reg[base].I ^ value; \

  1010     N_FLAG	= (res & 0x80000000) ? true : false; \

  1011     Z_FLAG	= (res) ? false : true; \

  1012     C_FLAG	= C_OUT;

  1013 

  1014 #define OP_ORR \

  1015     reg[dest].I = reg[base].I | value;

  1016 

  1017 #define OP_ORRS \

  1018     reg[dest].I = reg[base].I | value; \

  1019     N_FLAG		= (reg[dest].I & 0x80000000) ? true : false; \

  1020     Z_FLAG		= (reg[dest].I) ? false : true; \

  1021     C_FLAG		= C_OUT;

  1022 

  1023 #define OP_MOV \

  1024     reg[dest].I = value;

  1025 

  1026 #define OP_MOVS \

  1027     reg[dest].I = value; \

  1028     N_FLAG		= (reg[dest].I & 0x80000000) ? true : false; \

  1029     Z_FLAG		= (reg[dest].I) ? false : true; \

  1030     C_FLAG		= C_OUT;

  1031 

  1032 #define OP_BIC \

  1033     reg[dest].I = reg[base].I & (~value);

  1034 

  1035 #define OP_BICS \

  1036     reg[dest].I = reg[base].I & (~value); \

  1037     N_FLAG		= (reg[dest].I & 0x80000000) ? true : false; \

  1038     Z_FLAG		= (reg[dest].I) ? false : true; \

  1039     C_FLAG		= C_OUT;

  1040 

  1041 #define OP_MVN \

  1042     reg[dest].I = ~value;

  1043 

  1044 #define OP_MVNS \

  1045     reg[dest].I = ~value; \

  1046     N_FLAG		= (reg[dest].I & 0x80000000) ? true : false; \

  1047     Z_FLAG		= (reg[dest].I) ? false : true; \

  1048     C_FLAG		= C_OUT;

  1049 

  1050 #define CASE_16(BASE) \

  1051 case BASE: \

  1052 case BASE + 1: \

  1053 case BASE + 2: \

  1054 case BASE + 3: \

  1055 case BASE + 4: \

  1056 case BASE + 5: \

  1057 case BASE + 6: \

  1058 case BASE + 7: \

  1059 case BASE + 8: \

  1060 case BASE + 9: \

  1061 case BASE + 10: \

  1062 case BASE + 11: \

  1063 case BASE + 12: \

  1064 case BASE + 13: \

  1065 case BASE + 14: \

  1066 case BASE + 15:

  1067 

  1068 #define CASE_256(BASE) \

  1069     CASE_16(BASE) \

  1070     CASE_16(BASE + 0x10) \

  1071     CASE_16(BASE + 0x20) \

  1072     CASE_16(BASE + 0x30) \

  1073     CASE_16(BASE + 0x40) \

  1074     CASE_16(BASE + 0x50) \

  1075     CASE_16(BASE + 0x60) \

  1076     CASE_16(BASE + 0x70) \

  1077     CASE_16(BASE + 0x80) \

  1078     CASE_16(BASE + 0x90) \

  1079     CASE_16(BASE + 0xa0) \

  1080     CASE_16(BASE + 0xb0) \

  1081     CASE_16(BASE + 0xc0) \

  1082     CASE_16(BASE + 0xd0) \

  1083     CASE_16(BASE + 0xe0) \

  1084     CASE_16(BASE + 0xf0)

  1085 

  1086 #define LOGICAL_DATA_OPCODE(OPCODE, OPCODE2, BASE) \

  1087 case BASE: \

  1088 case BASE + 8: \

  1089 { \

  1090 	/* OP Rd,Rb,Rm LSL # */ \

  1091 	int	 base  = (opcode >> 16) & 0x0F; \

  1092 	int	 shift = (opcode >> 7) & 0x1F; \

  1093 	int	 dest  = (opcode >> 12) & 15; \

  1094 	bool C_OUT = C_FLAG; \

  1095 	u32	 value; \

  1096       \

  1097 	if (shift) { \

  1098 		LOGICAL_LSL_REG \

  1099 	} else { \

  1100 		value = reg[opcode & 0x0F].I; \

  1101 	} \

  1102 	if (dest == 15) { \

  1103 		OPCODE2 \

  1104 		/* todo */ \

  1105 		if (opcode & 0x00100000) { \

  1106 			clockTicks++; \

  1107 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1108 		} \

  1109 		if (armState) { \

  1110 			reg[15].I &= 0xFFFFFFFC; \

  1111 			armNextPC  = reg[15].I; \

  1112 			reg[15].I += 4; \

  1113 		} else { \

  1114 			reg[15].I &= 0xFFFFFFFE; \

  1115 			armNextPC  = reg[15].I; \

  1116 			reg[15].I += 2; \

  1117 		} \

  1118 	} else { \

  1119 		OPCODE \

  1120 	} \

  1121 } \

  1122 break; \

  1123 case BASE + 2: \

  1124 case BASE + 10: \

  1125 { \

  1126 	/* OP Rd,Rb,Rm LSR # */ \

  1127 	int	 base  = (opcode >> 16) & 0x0F; \

  1128 	int	 shift = (opcode >> 7) & 0x1F; \

  1129 	int	 dest  = (opcode >> 12) & 15; \

  1130 	bool C_OUT = C_FLAG; \

  1131 	u32	 value; \

  1132 	if (shift) { \

  1133 		LOGICAL_LSR_REG \

  1134 	} else { \

  1135 		value = 0; \

  1136 		C_OUT = (reg[opcode & 0x0F].I & 0x80000000) ? true : false; \

  1137 	} \

  1138       \

  1139 	if (dest == 15) { \

  1140 		OPCODE2 \

  1141 		/* todo */ \

  1142 		if (opcode & 0x00100000) { \

  1143 			clockTicks++; \

  1144 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1145 		} \

  1146 		if (armState) { \

  1147 			reg[15].I &= 0xFFFFFFFC; \

  1148 			armNextPC  = reg[15].I; \

  1149 			reg[15].I += 4; \

  1150 		} else { \

  1151 			reg[15].I &= 0xFFFFFFFE; \

  1152 			armNextPC  = reg[15].I; \

  1153 			reg[15].I += 2; \

  1154 		} \

  1155 	} else { \

  1156 		OPCODE \

  1157 	} \

  1158 } \

  1159 break; \

  1160 case BASE + 4: \

  1161 case BASE + 12: \

  1162 { \

  1163 	/* OP Rd,Rb,Rm ASR # */ \

  1164 	int	 base  = (opcode >> 16) & 0x0F; \

  1165 	int	 shift = (opcode >> 7) & 0x1F; \

  1166 	int	 dest  = (opcode >> 12) & 15; \

  1167 	bool C_OUT = C_FLAG; \

  1168 	u32	 value; \

  1169 	if (shift) { \

  1170 		LOGICAL_ASR_REG \

  1171 	} else { \

  1172 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  1173 			value = 0xFFFFFFFF; \

  1174 			C_OUT = true; \

  1175 		} else { \

  1176 			value = 0; \

  1177 			C_OUT = false; \

  1178 		}                   \

  1179 	} \

  1180       \

  1181 	if (dest == 15) { \

  1182 		OPCODE2 \

  1183 		/* todo */ \

  1184 		if (opcode & 0x00100000) { \

  1185 			clockTicks++; \

  1186 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1187 		} \

  1188 		if (armState) { \

  1189 			reg[15].I &= 0xFFFFFFFC; \

  1190 			armNextPC  = reg[15].I; \

  1191 			reg[15].I += 4; \

  1192 		} else { \

  1193 			reg[15].I &= 0xFFFFFFFE; \

  1194 			armNextPC  = reg[15].I; \

  1195 			reg[15].I += 2; \

  1196 		} \

  1197 	} else { \

  1198 		OPCODE \

  1199 	} \

  1200 } \

  1201 break; \

  1202 case BASE + 6: \

  1203 case BASE + 14: \

  1204 { \

  1205 	/* OP Rd,Rb,Rm ROR # */ \

  1206 	int	 base  = (opcode >> 16) & 0x0F; \

  1207 	int	 shift = (opcode >> 7) & 0x1F; \

  1208 	int	 dest  = (opcode >> 12) & 15; \

  1209 	bool C_OUT = C_FLAG; \

  1210 	u32	 value; \

  1211 	if (shift) { \

  1212 		LOGICAL_ROR_REG \

  1213 	} else { \

  1214 		LOGICAL_RRX_REG \

  1215 	} \

  1216 	if (dest == 15) { \

  1217 		OPCODE2 \

  1218 		/* todo */ \

  1219 		if (opcode & 0x00100000) { \

  1220 			clockTicks++; \

  1221 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1222 		} \

  1223 		if (armState) { \

  1224 			reg[15].I &= 0xFFFFFFFC; \

  1225 			armNextPC  = reg[15].I; \

  1226 			reg[15].I += 4; \

  1227 		} else { \

  1228 			reg[15].I &= 0xFFFFFFFE; \

  1229 			armNextPC  = reg[15].I; \

  1230 			reg[15].I += 2; \

  1231 		} \

  1232 	} else { \

  1233 		OPCODE \

  1234 	} \

  1235 } \

  1236 break; \

  1237 case BASE + 1: \

  1238 { \

  1239 	/* OP Rd,Rb,Rm LSL Rs */ \

  1240 	clockTicks++; \

  1241 	int	 base  = (opcode >> 16) & 0x0F; \

  1242 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1243 	int	 dest  = (opcode >> 12) & 15; \

  1244 	bool C_OUT = C_FLAG; \

  1245 	u32	 value; \

  1246 	if (shift) { \

  1247 		if (shift == 32) { \

  1248 			value = 0; \

  1249 			C_OUT = (reg[opcode & 0x0F].I & 1 ? true : false); \

  1250 		} else if (shift < 32) { \

  1251 			LOGICAL_LSL_REG \

  1252 		} else { \

  1253 			value = 0; \

  1254 			C_OUT = false; \

  1255 		} \

  1256 	} else { \

  1257 		value = reg[opcode & 0x0F].I; \

  1258 	} \

  1259 	if (dest == 15) { \

  1260 		OPCODE2 \

  1261 		/* todo */ \

  1262 		if (opcode & 0x00100000) { \

  1263 			clockTicks++; \

  1264 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1265 		} \

  1266 		if (armState) { \

  1267 			reg[15].I &= 0xFFFFFFFC; \

  1268 			armNextPC  = reg[15].I; \

  1269 			reg[15].I += 4; \

  1270 		} else { \

  1271 			reg[15].I &= 0xFFFFFFFE; \

  1272 			armNextPC  = reg[15].I; \

  1273 			reg[15].I += 2; \

  1274 		} \

  1275 	} else { \

  1276 		OPCODE \

  1277 	} \

  1278 } \

  1279 break; \

  1280 case BASE + 3: \

  1281 { \

  1282 	/* OP Rd,Rb,Rm LSR Rs */ \

  1283 	clockTicks++; \

  1284 	int	 base  = (opcode >> 16) & 0x0F; \

  1285 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1286 	int	 dest  = (opcode >> 12) & 15; \

  1287 	bool C_OUT = C_FLAG; \

  1288 	u32	 value; \

  1289 	if (shift) { \

  1290 		if (shift == 32) { \

  1291 			value = 0; \

  1292 			C_OUT = (reg[opcode & 0x0F].I & 0x80000000 ? true : false); \

  1293 		} else if (shift < 32) { \

  1294 			LOGICAL_LSR_REG \

  1295 		} else { \

  1296 			value = 0; \

  1297 			C_OUT = false; \

  1298 		} \

  1299 	} else { \

  1300 		value = reg[opcode & 0x0F].I; \

  1301 	} \

  1302 	if (dest == 15) { \

  1303 		OPCODE2 \

  1304 		/* todo */ \

  1305 		if (opcode & 0x00100000) { \

  1306 			clockTicks++; \

  1307 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1308 		} \

  1309 		if (armState) { \

  1310 			reg[15].I &= 0xFFFFFFFC; \

  1311 			armNextPC  = reg[15].I; \

  1312 			reg[15].I += 4; \

  1313 		} else { \

  1314 			reg[15].I &= 0xFFFFFFFE; \

  1315 			armNextPC  = reg[15].I; \

  1316 			reg[15].I += 2; \

  1317 		} \

  1318 	} else { \

  1319 		OPCODE \

  1320 	} \

  1321 } \

  1322 break; \

  1323 case BASE + 5: \

  1324 { \

  1325 	/* OP Rd,Rb,Rm ASR Rs */ \

  1326 	clockTicks++; \

  1327 	int	 base  = (opcode >> 16) & 0x0F; \

  1328 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1329 	int	 dest  = (opcode >> 12) & 15; \

  1330 	bool C_OUT = C_FLAG; \

  1331 	u32	 value; \

  1332 	if (shift < 32) { \

  1333 		if (shift) { \

  1334 			LOGICAL_ASR_REG \

  1335 		} else { \

  1336 			value = reg[opcode & 0x0F].I; \

  1337 		} \

  1338 	} else { \

  1339 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  1340 			value = 0xFFFFFFFF; \

  1341 			C_OUT = true; \

  1342 		} else { \

  1343 			value = 0; \

  1344 			C_OUT = false; \

  1345 		} \

  1346 	} \

  1347 	if (dest == 15) { \

  1348 		OPCODE2 \

  1349 		/* todo */ \

  1350 		if (opcode & 0x00100000) { \

  1351 			clockTicks++; \

  1352 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1353 		} \

  1354 		if (armState) { \

  1355 			reg[15].I &= 0xFFFFFFFC; \

  1356 			armNextPC  = reg[15].I; \

  1357 			reg[15].I += 4; \

  1358 		} else { \

  1359 			reg[15].I &= 0xFFFFFFFE; \

  1360 			armNextPC  = reg[15].I; \

  1361 			reg[15].I += 2; \

  1362 		} \

  1363 	} else { \

  1364 		OPCODE \

  1365 	} \

  1366 } \

  1367 break; \

  1368 case BASE + 7: \

  1369 { \

  1370 	/* OP Rd,Rb,Rm ROR Rs */ \

  1371 	clockTicks++; \

  1372 	int	 base  = (opcode >> 16) & 0x0F; \

  1373 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1374 	int	 dest  = (opcode >> 12) & 15; \

  1375 	bool C_OUT = C_FLAG; \

  1376 	u32	 value; \

  1377 	if (shift) { \

  1378 		shift &= 0x1f; \

  1379 		if (shift) { \

  1380 			LOGICAL_ROR_REG \

  1381 		} else { \

  1382 			value = reg[opcode & 0x0F].I; \

  1383 			C_OUT = (value & 0x80000000 ? true : false); \

  1384 		} \

  1385 	} else { \

  1386 		value = reg[opcode & 0x0F].I; \

  1387 		C_OUT = (value & 0x80000000 ? true : false); \

  1388 	} \

  1389 	if (dest == 15) { \

  1390 		OPCODE2 \

  1391 		/* todo */ \

  1392 		if (opcode & 0x00100000) { \

  1393 			clockTicks++; \

  1394 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1395 		} \

  1396 		if (armState) { \

  1397 			reg[15].I &= 0xFFFFFFFC; \

  1398 			armNextPC  = reg[15].I; \

  1399 			reg[15].I += 4; \

  1400 		} else { \

  1401 			reg[15].I &= 0xFFFFFFFE; \

  1402 			armNextPC  = reg[15].I; \

  1403 			reg[15].I += 2; \

  1404 		} \

  1405 	} else { \

  1406 		OPCODE \

  1407 	} \

  1408 } \

  1409 break; \

  1410 case BASE + 0x200: \

  1411 case BASE + 0x201: \

  1412 case BASE + 0x202: \

  1413 case BASE + 0x203: \

  1414 case BASE + 0x204: \

  1415 case BASE + 0x205: \

  1416 case BASE + 0x206: \

  1417 case BASE + 0x207: \

  1418 case BASE + 0x208: \

  1419 case BASE + 0x209: \

  1420 case BASE + 0x20a: \

  1421 case BASE + 0x20b: \

  1422 case BASE + 0x20c: \

  1423 case BASE + 0x20d: \

  1424 case BASE + 0x20e: \

  1425 case BASE + 0x20f: \

  1426 { \

  1427 	int	 shift = (opcode & 0xF00) >> 7; \

  1428 	int	 base  = (opcode >> 16) & 0x0F; \

  1429 	int	 dest  = (opcode >> 12) & 0x0F; \

  1430 	bool C_OUT = C_FLAG; \

  1431 	u32	 value; \

  1432 	if (shift) { \

  1433 		LOGICAL_ROR_IMM \

  1434 	} else { \

  1435 		value = opcode & 0xff; \

  1436 	} \

  1437 	if (dest == 15) { \

  1438 		OPCODE2 \

  1439 		/* todo */ \

  1440 		if (opcode & 0x00100000) { \

  1441 			clockTicks++; \

  1442 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1443 		} \

  1444 		if (armState) { \

  1445 			reg[15].I &= 0xFFFFFFFC; \

  1446 			armNextPC  = reg[15].I; \

  1447 			reg[15].I += 4; \

  1448 		} else { \

  1449 			reg[15].I &= 0xFFFFFFFE; \

  1450 			armNextPC  = reg[15].I; \

  1451 			reg[15].I += 2; \

  1452 		} \

  1453 	} else { \

  1454 		OPCODE \

  1455 	} \

  1456 } \

  1457 break;

  1458 

  1459 #define LOGICAL_DATA_OPCODE_WITHOUT_base(OPCODE, OPCODE2, BASE) \

  1460 case BASE: \

  1461 case BASE + 8: \

  1462 { \

  1463 	/* OP Rd,Rb,Rm LSL # */ \

  1464 	int	 shift = (opcode >> 7) & 0x1F; \

  1465 	int	 dest  = (opcode >> 12) & 15; \

  1466 	bool C_OUT = C_FLAG; \

  1467 	u32	 value; \

  1468       \

  1469 	if (shift) { \

  1470 		LOGICAL_LSL_REG \

  1471 	} else { \

  1472 		value = reg[opcode & 0x0F].I; \

  1473 	} \

  1474 	if (dest == 15) { \

  1475 		OPCODE2 \

  1476 		/* todo */ \

  1477 		if (opcode & 0x00100000) { \

  1478 			clockTicks++; \

  1479 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1480 		} \

  1481 		if (armState) { \

  1482 			reg[15].I &= 0xFFFFFFFC; \

  1483 			armNextPC  = reg[15].I; \

  1484 			reg[15].I += 4; \

  1485 		} else { \

  1486 			reg[15].I &= 0xFFFFFFFE; \

  1487 			armNextPC  = reg[15].I; \

  1488 			reg[15].I += 2; \

  1489 		} \

  1490 	} else { \

  1491 		OPCODE \

  1492 	} \

  1493 } \

  1494 break; \

  1495 case BASE + 2: \

  1496 case BASE + 10: \

  1497 { \

  1498 	/* OP Rd,Rb,Rm LSR # */ \

  1499 	int	 shift = (opcode >> 7) & 0x1F; \

  1500 	int	 dest  = (opcode >> 12) & 15; \

  1501 	bool C_OUT = C_FLAG; \

  1502 	u32	 value; \

  1503 	if (shift) { \

  1504 		LOGICAL_LSR_REG \

  1505 	} else { \

  1506 		value = 0; \

  1507 		C_OUT = (reg[opcode & 0x0F].I & 0x80000000) ? true : false; \

  1508 	} \

  1509       \

  1510 	if (dest == 15) { \

  1511 		OPCODE2 \

  1512 		/* todo */ \

  1513 		if (opcode & 0x00100000) { \

  1514 			clockTicks++; \

  1515 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1516 		} \

  1517 		if (armState) { \

  1518 			reg[15].I &= 0xFFFFFFFC; \

  1519 			armNextPC  = reg[15].I; \

  1520 			reg[15].I += 4; \

  1521 		} else { \

  1522 			reg[15].I &= 0xFFFFFFFE; \

  1523 			armNextPC  = reg[15].I; \

  1524 			reg[15].I += 2; \

  1525 		} \

  1526 	} else { \

  1527 		OPCODE \

  1528 	} \

  1529 } \

  1530 break; \

  1531 case BASE + 4: \

  1532 case BASE + 12: \

  1533 { \

  1534 	/* OP Rd,Rb,Rm ASR # */ \

  1535 	int	 shift = (opcode >> 7) & 0x1F; \

  1536 	int	 dest  = (opcode >> 12) & 15; \

  1537 	bool C_OUT = C_FLAG; \

  1538 	u32	 value; \

  1539 	if (shift) { \

  1540 		LOGICAL_ASR_REG \

  1541 	} else { \

  1542 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  1543 			value = 0xFFFFFFFF; \

  1544 			C_OUT = true; \

  1545 		} else { \

  1546 			value = 0; \

  1547 			C_OUT = false; \

  1548 		}                   \

  1549 	} \

  1550       \

  1551 	if (dest == 15) { \

  1552 		OPCODE2 \

  1553 		/* todo */ \

  1554 		if (opcode & 0x00100000) { \

  1555 			clockTicks++; \

  1556 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1557 		} \

  1558 		if (armState) { \

  1559 			reg[15].I &= 0xFFFFFFFC; \

  1560 			armNextPC  = reg[15].I; \

  1561 			reg[15].I += 4; \

  1562 		} else { \

  1563 			reg[15].I &= 0xFFFFFFFE; \

  1564 			armNextPC  = reg[15].I; \

  1565 			reg[15].I += 2; \

  1566 		} \

  1567 	} else { \

  1568 		OPCODE \

  1569 	} \

  1570 } \

  1571 break; \

  1572 case BASE + 6: \

  1573 case BASE + 14: \

  1574 { \

  1575 	/* OP Rd,Rb,Rm ROR # */ \

  1576 	int	 shift = (opcode >> 7) & 0x1F; \

  1577 	int	 dest  = (opcode >> 12) & 15; \

  1578 	bool C_OUT = C_FLAG; \

  1579 	u32	 value; \

  1580 	if (shift) { \

  1581 		LOGICAL_ROR_REG \

  1582 	} else { \

  1583 		LOGICAL_RRX_REG \

  1584 	} \

  1585 	if (dest == 15) { \

  1586 		OPCODE2 \

  1587 		/* todo */ \

  1588 		if (opcode & 0x00100000) { \

  1589 			clockTicks++; \

  1590 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1591 		} \

  1592 		if (armState) { \

  1593 			reg[15].I &= 0xFFFFFFFC; \

  1594 			armNextPC  = reg[15].I; \

  1595 			reg[15].I += 4; \

  1596 		} else { \

  1597 			reg[15].I &= 0xFFFFFFFE; \

  1598 			armNextPC  = reg[15].I; \

  1599 			reg[15].I += 2; \

  1600 		} \

  1601 	} else { \

  1602 		OPCODE \

  1603 	} \

  1604 } \

  1605 break; \

  1606 case BASE + 1: \

  1607 { \

  1608 	/* OP Rd,Rb,Rm LSL Rs */ \

  1609 	clockTicks++; \

  1610 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1611 	int	 dest  = (opcode >> 12) & 15; \

  1612 	bool C_OUT = C_FLAG; \

  1613 	u32	 value; \

  1614 	if (shift) { \

  1615 		if (shift == 32) { \

  1616 			value = 0; \

  1617 			C_OUT = (reg[opcode & 0x0F].I & 1 ? true : false); \

  1618 		} else if (shift < 32) { \

  1619 			LOGICAL_LSL_REG \

  1620 		} else { \

  1621 			value = 0; \

  1622 			C_OUT = false; \

  1623 		} \

  1624 	} else { \

  1625 		value = reg[opcode & 0x0F].I; \

  1626 	} \

  1627 	if (dest == 15) { \

  1628 		OPCODE2 \

  1629 		/* todo */ \

  1630 		if (opcode & 0x00100000) { \

  1631 			clockTicks++; \

  1632 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1633 		} \

  1634 		if (armState) { \

  1635 			reg[15].I &= 0xFFFFFFFC; \

  1636 			armNextPC  = reg[15].I; \

  1637 			reg[15].I += 4; \

  1638 		} else { \

  1639 			reg[15].I &= 0xFFFFFFFE; \

  1640 			armNextPC  = reg[15].I; \

  1641 			reg[15].I += 2; \

  1642 		} \

  1643 	} else { \

  1644 		OPCODE \

  1645 	} \

  1646 } \

  1647 break; \

  1648 case BASE + 3: \

  1649 { \

  1650 	/* OP Rd,Rb,Rm LSR Rs */ \

  1651 	clockTicks++; \

  1652 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1653 	int	 dest  = (opcode >> 12) & 15; \

  1654 	bool C_OUT = C_FLAG; \

  1655 	u32	 value; \

  1656 	if (shift) { \

  1657 		if (shift == 32) { \

  1658 			value = 0; \

  1659 			C_OUT = (reg[opcode & 0x0F].I & 0x80000000 ? true : false); \

  1660 		} else if (shift < 32) { \

  1661 			LOGICAL_LSR_REG \

  1662 		} else { \

  1663 			value = 0; \

  1664 			C_OUT = false; \

  1665 		} \

  1666 	} else { \

  1667 		value = reg[opcode & 0x0F].I; \

  1668 	} \

  1669 	if (dest == 15) { \

  1670 		OPCODE2 \

  1671 		/* todo */ \

  1672 		if (opcode & 0x00100000) { \

  1673 			clockTicks++; \

  1674 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1675 		} \

  1676 		if (armState) { \

  1677 			reg[15].I &= 0xFFFFFFFC; \

  1678 			armNextPC  = reg[15].I; \

  1679 			reg[15].I += 4; \

  1680 		} else { \

  1681 			reg[15].I &= 0xFFFFFFFE; \

  1682 			armNextPC  = reg[15].I; \

  1683 			reg[15].I += 2; \

  1684 		} \

  1685 	} else { \

  1686 		OPCODE \

  1687 	} \

  1688 } \

  1689 break; \

  1690 case BASE + 5: \

  1691 { \

  1692 	/* OP Rd,Rb,Rm ASR Rs */ \

  1693 	clockTicks++; \

  1694 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1695 	int	 dest  = (opcode >> 12) & 15; \

  1696 	bool C_OUT = C_FLAG; \

  1697 	u32	 value; \

  1698 	if (shift < 32) { \

  1699 		if (shift) { \

  1700 			LOGICAL_ASR_REG \

  1701 		} else { \

  1702 			value = reg[opcode & 0x0F].I; \

  1703 		} \

  1704 	} else { \

  1705 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  1706 			value = 0xFFFFFFFF; \

  1707 			C_OUT = true; \

  1708 		} else { \

  1709 			value = 0; \

  1710 			C_OUT = false; \

  1711 		} \

  1712 	} \

  1713 	if (dest == 15) { \

  1714 		OPCODE2 \

  1715 		/* todo */ \

  1716 		if (opcode & 0x00100000) { \

  1717 			clockTicks++; \

  1718 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1719 		} \

  1720 		if (armState) { \

  1721 			reg[15].I &= 0xFFFFFFFC; \

  1722 			armNextPC  = reg[15].I; \

  1723 			reg[15].I += 4; \

  1724 		} else { \

  1725 			reg[15].I &= 0xFFFFFFFE; \

  1726 			armNextPC  = reg[15].I; \

  1727 			reg[15].I += 2; \

  1728 		} \

  1729 	} else { \

  1730 		OPCODE \

  1731 	} \

  1732 } \

  1733 break; \

  1734 case BASE + 7: \

  1735 { \

  1736 	/* OP Rd,Rb,Rm ROR Rs */ \

  1737 	clockTicks++; \

  1738 	int	 shift = reg[(opcode >> 8) & 15].B.B0; \

  1739 	int	 dest  = (opcode >> 12) & 15; \

  1740 	bool C_OUT = C_FLAG; \

  1741 	u32	 value; \

  1742 	if (shift) { \

  1743 		shift &= 0x1f; \

  1744 		if (shift) { \

  1745 			LOGICAL_ROR_REG \

  1746 		} else { \

  1747 			value = reg[opcode & 0x0F].I; \

  1748 			C_OUT = (value & 0x80000000 ? true : false); \

  1749 		} \

  1750 	} else { \

  1751 		value = reg[opcode & 0x0F].I; \

  1752 		C_OUT = (value & 0x80000000 ? true : false); \

  1753 	} \

  1754 	if (dest == 15) { \

  1755 		OPCODE2 \

  1756 		/* todo */ \

  1757 		if (opcode & 0x00100000) { \

  1758 			clockTicks++; \

  1759 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1760 		} \

  1761 		if (armState) { \

  1762 			reg[15].I &= 0xFFFFFFFC; \

  1763 			armNextPC  = reg[15].I; \

  1764 			reg[15].I += 4; \

  1765 		} else { \

  1766 			reg[15].I &= 0xFFFFFFFE; \

  1767 			armNextPC  = reg[15].I; \

  1768 			reg[15].I += 2; \

  1769 		} \

  1770 	} else { \

  1771 		OPCODE \

  1772 	} \

  1773 } \

  1774 break; \

  1775 case BASE + 0x200: \

  1776 case BASE + 0x201: \

  1777 case BASE + 0x202: \

  1778 case BASE + 0x203: \

  1779 case BASE + 0x204: \

  1780 case BASE + 0x205: \

  1781 case BASE + 0x206: \

  1782 case BASE + 0x207: \

  1783 case BASE + 0x208: \

  1784 case BASE + 0x209: \

  1785 case BASE + 0x20a: \

  1786 case BASE + 0x20b: \

  1787 case BASE + 0x20c: \

  1788 case BASE + 0x20d: \

  1789 case BASE + 0x20e: \

  1790 case BASE + 0x20f: \

  1791 { \

  1792 	int	 shift = (opcode & 0xF00) >> 7; \

  1793 	int	 dest  = (opcode >> 12) & 0x0F; \

  1794 	bool C_OUT = C_FLAG; \

  1795 	u32	 value; \

  1796 	if (shift) { \

  1797 		LOGICAL_ROR_IMM \

  1798 	} else { \

  1799 		value = opcode & 0xff; \

  1800 	} \

  1801 	if (dest == 15) { \

  1802 		OPCODE2 \

  1803 		/* todo */ \

  1804 		if (opcode & 0x00100000) { \

  1805 			clockTicks++; \

  1806 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1807 		} \

  1808 		if (armState) { \

  1809 			reg[15].I &= 0xFFFFFFFC; \

  1810 			armNextPC  = reg[15].I; \

  1811 			reg[15].I += 4; \

  1812 		} else { \

  1813 			reg[15].I &= 0xFFFFFFFE; \

  1814 			armNextPC  = reg[15].I; \

  1815 			reg[15].I += 2; \

  1816 		} \

  1817 	} else { \

  1818 		OPCODE \

  1819 	} \

  1820 } \

  1821 break;

  1822 

  1823 #define ARITHMETIC_DATA_OPCODE(OPCODE, OPCODE2, BASE) \

  1824 case BASE: \

  1825 case BASE + 8: \

  1826 { \

  1827 	/* OP Rd,Rb,Rm LSL # */ \

  1828 	int base  = (opcode >> 16) & 0x0F; \

  1829 	int shift = (opcode >> 7) & 0x1F; \

  1830 	int dest  = (opcode >> 12) & 15; \

  1831 	u32 value; \

  1832 	if (shift) { \

  1833 		ARITHMETIC_LSL_REG \

  1834 	} else { \

  1835 		value = reg[opcode & 0x0F].I; \

  1836 	} \

  1837 	if (dest == 15) { \

  1838 		OPCODE2 \

  1839 		/* todo */ \

  1840 		if (opcode & 0x00100000) { \

  1841 			clockTicks++; \

  1842 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1843 		} \

  1844 		if (armState) { \

  1845 			reg[15].I &= 0xFFFFFFFC; \

  1846 			armNextPC  = reg[15].I; \

  1847 			reg[15].I += 4; \

  1848 		} else { \

  1849 			reg[15].I &= 0xFFFFFFFE; \

  1850 			armNextPC  = reg[15].I; \

  1851 			reg[15].I += 2; \

  1852 		} \

  1853 	} else { \

  1854 		OPCODE \

  1855 	} \

  1856 } \

  1857 break; \

  1858 case BASE + 2: \

  1859 case BASE + 10: \

  1860 { \

  1861 	/* OP Rd,Rb,Rm LSR # */ \

  1862 	int base  = (opcode >> 16) & 0x0F; \

  1863 	int shift = (opcode >> 7) & 0x1F; \

  1864 	int dest  = (opcode >> 12) & 15; \

  1865 	u32 value; \

  1866 	if (shift) { \

  1867 		ARITHMETIC_LSR_REG \

  1868 	} else { \

  1869 		value = 0; \

  1870 	} \

  1871 	if (dest == 15) { \

  1872 		OPCODE2 \

  1873 		/* todo */ \

  1874 		if (opcode & 0x00100000) { \

  1875 			clockTicks++; \

  1876 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1877 		} \

  1878 		if (armState) { \

  1879 			reg[15].I &= 0xFFFFFFFC; \

  1880 			armNextPC  = reg[15].I; \

  1881 			reg[15].I += 4; \

  1882 		} else { \

  1883 			reg[15].I &= 0xFFFFFFFE; \

  1884 			armNextPC  = reg[15].I; \

  1885 			reg[15].I += 2; \

  1886 		} \

  1887 	} else { \

  1888 		OPCODE \

  1889 	} \

  1890 } \

  1891 break; \

  1892 case BASE + 4: \

  1893 case BASE + 12: \

  1894 { \

  1895 	/* OP Rd,Rb,Rm ASR # */ \

  1896 	int base  = (opcode >> 16) & 0x0F; \

  1897 	int shift = (opcode >> 7) & 0x1F; \

  1898 	int dest  = (opcode >> 12) & 15; \

  1899 	u32 value; \

  1900 	if (shift) { \

  1901 		ARITHMETIC_ASR_REG \

  1902 	} else { \

  1903 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  1904 			value = 0xFFFFFFFF; \

  1905 		} else value = 0; \

  1906 	} \

  1907 	if (dest == 15) { \

  1908 		OPCODE2 \

  1909 		/* todo */ \

  1910 		if (opcode & 0x00100000) { \

  1911 			clockTicks++; \

  1912 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1913 		} \

  1914 		if (armState) { \

  1915 			reg[15].I &= 0xFFFFFFFC; \

  1916 			armNextPC  = reg[15].I; \

  1917 			reg[15].I += 4; \

  1918 		} else { \

  1919 			reg[15].I &= 0xFFFFFFFE; \

  1920 			armNextPC  = reg[15].I; \

  1921 			reg[15].I += 2; \

  1922 		} \

  1923 	} else { \

  1924 		OPCODE \

  1925 	} \

  1926 } \

  1927 break; \

  1928 case BASE + 6: \

  1929 case BASE + 14: \

  1930 { \

  1931 	/* OP Rd,Rb,Rm ROR # */ \

  1932 	int base  = (opcode >> 16) & 0x0F; \

  1933 	int shift = (opcode >> 7) & 0x1F; \

  1934 	int dest  = (opcode >> 12) & 15; \

  1935 	u32 value; \

  1936 	if (shift) { \

  1937 		ARITHMETIC_ROR_REG \

  1938 	} else { \

  1939 		ARITHMETIC_RRX_REG \

  1940 	} \

  1941 	if (dest == 15) { \

  1942 		OPCODE2 \

  1943 		/* todo */ \

  1944 		if (opcode & 0x00100000) { \

  1945 			clockTicks++; \

  1946 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1947 		} \

  1948 		if (armState) { \

  1949 			reg[15].I &= 0xFFFFFFFC; \

  1950 			armNextPC  = reg[15].I; \

  1951 			reg[15].I += 4; \

  1952 		} else { \

  1953 			reg[15].I &= 0xFFFFFFFE; \

  1954 			armNextPC  = reg[15].I; \

  1955 			reg[15].I += 2; \

  1956 		} \

  1957 	} else { \

  1958 		OPCODE \

  1959 	} \

  1960 } \

  1961 break; \

  1962 case BASE + 1: \

  1963 { \

  1964 	/* OP Rd,Rb,Rm LSL Rs */ \

  1965 	clockTicks++; \

  1966 	int base  = (opcode >> 16) & 0x0F; \

  1967 	int shift = reg[(opcode >> 8) & 15].B.B0; \

  1968 	int dest  = (opcode >> 12) & 15; \

  1969 	u32 value; \

  1970 	if (shift) { \

  1971 		if (shift == 32) { \

  1972 			value = 0; \

  1973 		} else if (shift < 32) { \

  1974 			ARITHMETIC_LSL_REG \

  1975 		} else value = 0; \

  1976 	} else { \

  1977 		value = reg[opcode & 0x0F].I; \

  1978 	} \

  1979 	if (dest == 15) { \

  1980 		OPCODE2 \

  1981 		/* todo */ \

  1982 		if (opcode & 0x00100000) { \

  1983 			clockTicks++; \

  1984 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  1985 		} \

  1986 		if (armState) { \

  1987 			reg[15].I &= 0xFFFFFFFC; \

  1988 			armNextPC  = reg[15].I; \

  1989 			reg[15].I += 4; \

  1990 		} else { \

  1991 			reg[15].I &= 0xFFFFFFFE; \

  1992 			armNextPC  = reg[15].I; \

  1993 			reg[15].I += 2; \

  1994 		} \

  1995 	} else { \

  1996 		OPCODE \

  1997 	} \

  1998 } \

  1999 break; \

  2000 case BASE + 3: \

  2001 { \

  2002 	/* OP Rd,Rb,Rm LSR Rs */ \

  2003 	clockTicks++; \

  2004 	int base  = (opcode >> 16) & 0x0F; \

  2005 	int shift = reg[(opcode >> 8) & 15].B.B0; \

  2006 	int dest  = (opcode >> 12) & 15; \

  2007 	u32 value; \

  2008 	if (shift) { \

  2009 		if (shift == 32) { \

  2010 			value = 0; \

  2011 		} else if (shift < 32) { \

  2012 			ARITHMETIC_LSR_REG \

  2013 		} else value = 0; \

  2014 	} else { \

  2015 		value = reg[opcode & 0x0F].I; \

  2016 	} \

  2017 	if (dest == 15) { \

  2018 		OPCODE2 \

  2019 		/* todo */ \

  2020 		if (opcode & 0x00100000) { \

  2021 			clockTicks++; \

  2022 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  2023 		} \

  2024 		if (armState) { \

  2025 			reg[15].I &= 0xFFFFFFFC; \

  2026 			armNextPC  = reg[15].I; \

  2027 			reg[15].I += 4; \

  2028 		} else { \

  2029 			reg[15].I &= 0xFFFFFFFE; \

  2030 			armNextPC  = reg[15].I; \

  2031 			reg[15].I += 2; \

  2032 		} \

  2033 	} else { \

  2034 		OPCODE \

  2035 	} \

  2036 } \

  2037 break; \

  2038 case BASE + 5: \

  2039 { \

  2040 	/* OP Rd,Rb,Rm ASR Rs */ \

  2041 	clockTicks++; \

  2042 	int base  = (opcode >> 16) & 0x0F; \

  2043 	int shift = reg[(opcode >> 8) & 15].B.B0; \

  2044 	int dest  = (opcode >> 12) & 15; \

  2045 	u32 value; \

  2046 	if (shift < 32) { \

  2047 		if (shift) { \

  2048 			ARITHMETIC_ASR_REG \

  2049 		} else { \

  2050 			value = reg[opcode & 0x0F].I; \

  2051 		} \

  2052 	} else { \

  2053 		if (reg[opcode & 0x0F].I & 0x80000000) { \

  2054 			value = 0xFFFFFFFF; \

  2055 		} else value = 0; \

  2056 	} \

  2057 	if (dest == 15) { \

  2058 		OPCODE2 \

  2059 		/* todo */ \

  2060 		if (opcode & 0x00100000) { \

  2061 			clockTicks++; \

  2062 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  2063 		} \

  2064 		if (armState) { \

  2065 			reg[15].I &= 0xFFFFFFFC; \

  2066 			armNextPC  = reg[15].I; \

  2067 			reg[15].I += 4; \

  2068 		} else { \

  2069 			reg[15].I &= 0xFFFFFFFE; \

  2070 			armNextPC  = reg[15].I; \

  2071 			reg[15].I += 2; \

  2072 		} \

  2073 	} else { \

  2074 		OPCODE \

  2075 	} \

  2076 } \

  2077 break; \

  2078 case BASE + 7: \

  2079 { \

  2080 	/* OP Rd,Rb,Rm ROR Rs */ \

  2081 	clockTicks++; \

  2082 	int base  = (opcode >> 16) & 0x0F; \

  2083 	int shift = reg[(opcode >> 8) & 15].B.B0; \

  2084 	int dest  = (opcode >> 12) & 15; \

  2085 	u32 value; \

  2086 	if (shift) { \

  2087 		shift &= 0x1f; \

  2088 		if (shift) { \

  2089 			ARITHMETIC_ROR_REG \

  2090 		} else { \

  2091 			value = reg[opcode & 0x0F].I; \

  2092 		} \

  2093 	} else { \

  2094 		value = reg[opcode & 0x0F].I; \

  2095 	} \

  2096 	if (dest == 15) { \

  2097 		OPCODE2 \

  2098 		/* todo */ \

  2099 		if (opcode & 0x00100000) { \

  2100 			clockTicks++; \

  2101 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  2102 		} \

  2103 		if (armState) { \

  2104 			reg[15].I &= 0xFFFFFFFC; \

  2105 			armNextPC  = reg[15].I; \

  2106 			reg[15].I += 4; \

  2107 		} else { \

  2108 			reg[15].I &= 0xFFFFFFFE; \

  2109 			armNextPC  = reg[15].I; \

  2110 			reg[15].I += 2; \

  2111 		} \

  2112 	} else { \

  2113 		OPCODE \

  2114 	} \

  2115 } \

  2116 break; \

  2117 case BASE + 0x200: \

  2118 case BASE + 0x201: \

  2119 case BASE + 0x202: \

  2120 case BASE + 0x203: \

  2121 case BASE + 0x204: \

  2122 case BASE + 0x205: \

  2123 case BASE + 0x206: \

  2124 case BASE + 0x207: \

  2125 case BASE + 0x208: \

  2126 case BASE + 0x209: \

  2127 case BASE + 0x20a: \

  2128 case BASE + 0x20b: \

  2129 case BASE + 0x20c: \

  2130 case BASE + 0x20d: \

  2131 case BASE + 0x20e: \

  2132 case BASE + 0x20f: \

  2133 { \

  2134 	int shift = (opcode & 0xF00) >> 7; \

  2135 	int base  = (opcode >> 16) & 0x0F; \

  2136 	int dest  = (opcode >> 12) & 0x0F; \

  2137 	u32 value; \

  2138 	{ \

  2139 		ARITHMETIC_ROR_IMM \

  2140 	} \

  2141 	if (dest == 15) { \

  2142 		OPCODE2 \

  2143 		/* todo */ \

  2144 		if (opcode & 0x00100000) { \

  2145 			clockTicks++; \

  2146 			CPUSwitchMode(reg[17].I & 0x1f, false); \

  2147 		} \

  2148 		if (armState) { \

  2149 			reg[15].I &= 0xFFFFFFFC; \

  2150 			armNextPC  = reg[15].I; \

  2151 			reg[15].I += 4; \

  2152 		} else { \

  2153 			reg[15].I &= 0xFFFFFFFE; \

  2154 			armNextPC  = reg[15].I; \

  2155 			reg[15].I += 2; \

  2156 		} \

  2157 	} else { \

  2158 		OPCODE \

  2159 	} \

  2160 } \

  2161 break;

  2162 

  2163 u32 opcode = CPUReadMemoryQuick(armNextPC);

  2164 

  2165 clockTicks = memoryWaitFetch32[(armNextPC >> 24) & 15];

  2166 

  2167 #ifndef FINAL_VERSION

  2168 if (armNextPC == stop)

  2169 {

  2170 	armNextPC++;

  2171 }

  2172 #endif

  2173 

  2174 armNextPC  = reg[15].I;

  2175 reg[15].I += 4;

  2176 int cond = opcode >> 28;

  2177 // suggested optimization for frequent cases

  2178 bool cond_res;

  2179 if (cond == 0x0e)

  2180 {

  2181 	cond_res = true;

  2182 }

  2183 else

  2184 {

  2185 	switch (cond)

  2186 	{

  2187 	case 0x00: // EQ

  2188 		cond_res = Z_FLAG;

  2189 		break;

  2190 	case 0x01: // NE

  2191 		cond_res = !Z_FLAG;

  2192 		break;

  2193 	case 0x02: // CS

  2194 		cond_res = C_FLAG;

  2195 		break;

  2196 	case 0x03: // CC

  2197 		cond_res = !C_FLAG;

  2198 		break;

  2199 	case 0x04: // MI

  2200 		cond_res = N_FLAG;

  2201 		break;

  2202 	case 0x05: // PL

  2203 		cond_res = !N_FLAG;

  2204 		break;

  2205 	case 0x06: // VS

  2206 		cond_res = V_FLAG;

  2207 		break;

  2208 	case 0x07: // VC

  2209 		cond_res = !V_FLAG;

  2210 		break;

  2211 	case 0x08: // HI

  2212 		cond_res = C_FLAG && !Z_FLAG;

  2213 		break;

  2214 	case 0x09: // LS

  2215 		cond_res = !C_FLAG || Z_FLAG;

  2216 		break;

  2217 	case 0x0A: // GE

  2218 		cond_res = N_FLAG == V_FLAG;

  2219 		break;

  2220 	case 0x0B: // LT

  2221 		cond_res = N_FLAG != V_FLAG;

  2222 		break;

  2223 	case 0x0C: // GT

  2224 		cond_res = !Z_FLAG && (N_FLAG == V_FLAG);

  2225 		break;

  2226 	case 0x0D: // LE

  2227 		cond_res = Z_FLAG || (N_FLAG != V_FLAG);

  2228 		break;

  2229 	case 0x0E:

  2230 		cond_res = true;

  2231 		break;

  2232 	case 0x0F:

  2233 	default:

  2234 		// ???

  2235 		cond_res = false;

  2236 		break;

  2237 	}

  2238 }

  2239 

  2240 if (cond_res)

  2241 {

  2242 	switch (((opcode >> 16) & 0xFF0) | ((opcode >> 4) & 0x0F))

  2243 	{

  2244 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_AND,  OP_AND, 0x000);

  2245 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_ANDS, OP_AND, 0x010);

  2246 	case 0x009:

  2247 	{

  2248 		// MUL Rd, Rm, Rs

  2249 		int dest = (opcode >> 16) & 0x0F;

  2250 		int mult = (opcode & 0x0F);

  2251 		u32 rs	 = reg[(opcode >> 8) & 0x0F].I;

  2252 		reg[dest].I = reg[mult].I * rs;

  2253 		if (((s32)rs) < 0)

  2254 			rs = ~rs;

  2255 		if ((rs & 0xFFFFFF00) == 0)

  2256 			clockTicks += 2;

  2257 		else if ((rs & 0xFFFF0000) == 0)

  2258 			clockTicks += 3;

  2259 		else if ((rs & 0xFF000000) == 0)

  2260 			clockTicks += 4;

  2261 		else

  2262 			clockTicks += 5;

  2263 	}

  2264 	break;

  2265 	case 0x019:

  2266 	{

  2267 		// MULS Rd, Rm, Rs

  2268 		int dest = (opcode >> 16) & 0x0F;

  2269 		int mult = (opcode & 0x0F);

  2270 		u32 rs	 = reg[(opcode >> 8) & 0x0F].I;

  2271 		reg[dest].I = reg[mult].I * rs;

  2272 		N_FLAG		= (reg[dest].I & 0x80000000) ? true : false;

  2273 		Z_FLAG		= (reg[dest].I) ? false : true;

  2274 		if (((s32)rs) < 0)

  2275 			rs = ~rs;

  2276 		if ((rs & 0xFFFFFF00) == 0)

  2277 			clockTicks += 2;

  2278 		else if ((rs & 0xFFFF0000) == 0)

  2279 			clockTicks += 3;

  2280 		else if ((rs & 0xFF000000) == 0)

  2281 			clockTicks += 4;

  2282 		else

  2283 			clockTicks += 5;

  2284 	}

  2285 	break;

  2286 	case 0x00b:

  2287 	case 0x02b:

  2288 	{

  2289 		// STRH Rd, [Rn], -Rm

  2290 		int base	= (opcode >> 16) & 0x0F;

  2291 		int dest	= (opcode >> 12) & 0x0F;

  2292 		u32 address = reg[base].I;

  2293 		int offset	= reg[opcode & 0x0F].I;

  2294 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2295 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2296 		address	   -= offset;

  2297 		reg[base].I = address;

  2298 	}

  2299 	break;

  2300 	case 0x04b:

  2301 	case 0x06b:

  2302 	{

  2303 		// STRH Rd, [Rn], #-offset

  2304 		int base	= (opcode >> 16) & 0x0F;

  2305 		int dest	= (opcode >> 12) & 0x0F;

  2306 		u32 address = reg[base].I;

  2307 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2308 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2309 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2310 		address	   -= offset;

  2311 		reg[base].I = address;

  2312 	}

  2313 	break;

  2314 	case 0x08b:

  2315 	case 0x0ab:

  2316 	{

  2317 		// STRH Rd, [Rn], Rm

  2318 		int base	= (opcode >> 16) & 0x0F;

  2319 		int dest	= (opcode >> 12) & 0x0F;

  2320 		u32 address = reg[base].I;

  2321 		int offset	= reg[opcode & 0x0F].I;

  2322 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2323 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2324 		address	   += offset;

  2325 		reg[base].I = address;

  2326 	}

  2327 	break;

  2328 	case 0x0cb:

  2329 	case 0x0eb:

  2330 	{

  2331 		// STRH Rd, [Rn], #offset

  2332 		int base	= (opcode >> 16) & 0x0F;

  2333 		int dest	= (opcode >> 12) & 0x0F;

  2334 		u32 address = reg[base].I;

  2335 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2336 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2337 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2338 		address	   += offset;

  2339 		reg[base].I = address;

  2340 	}

  2341 	break;

  2342 	case 0x10b:

  2343 	{

  2344 		// STRH Rd, [Rn, -Rm]

  2345 		int base	= (opcode >> 16) & 0x0F;

  2346 		int dest	= (opcode >> 12) & 0x0F;

  2347 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2348 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2349 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2350 	}

  2351 	break;

  2352 	case 0x12b:

  2353 	{

  2354 		// STRH Rd, [Rn, -Rm]!

  2355 		int base	= (opcode >> 16) & 0x0F;

  2356 		int dest	= (opcode >> 12) & 0x0F;

  2357 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2358 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2359 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2360 		reg[base].I = address;

  2361 	}

  2362 	break;

  2363 	case 0x14b:

  2364 	{

  2365 		// STRH Rd, [Rn, -#offset]

  2366 		int base	= (opcode >> 16) & 0x0F;

  2367 		int dest	= (opcode >> 12) & 0x0F;

  2368 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2369 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2370 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2371 	}

  2372 	break;

  2373 	case 0x16b:

  2374 	{

  2375 		// STRH Rd, [Rn, -#offset]!

  2376 		int base	= (opcode >> 16) & 0x0F;

  2377 		int dest	= (opcode >> 12) & 0x0F;

  2378 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2379 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2380 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2381 		reg[base].I = address;

  2382 	}

  2383 	break;

  2384 	case 0x18b:

  2385 	{

  2386 		// STRH Rd, [Rn, Rm]

  2387 		int base	= (opcode >> 16) & 0x0F;

  2388 		int dest	= (opcode >> 12) & 0x0F;

  2389 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2390 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2391 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2392 	}

  2393 	break;

  2394 	case 0x1ab:

  2395 	{

  2396 		// STRH Rd, [Rn, Rm]!

  2397 		int base	= (opcode >> 16) & 0x0F;

  2398 		int dest	= (opcode >> 12) & 0x0F;

  2399 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2400 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2401 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2402 		reg[base].I = address;

  2403 	}

  2404 	break;

  2405 	case 0x1cb:

  2406 	{

  2407 		// STRH Rd, [Rn, #offset]

  2408 		int base	= (opcode >> 16) & 0x0F;

  2409 		int dest	= (opcode >> 12) & 0x0F;

  2410 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2411 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2412 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2413 	}

  2414 	break;

  2415 	case 0x1eb:

  2416 	{

  2417 		// STRH Rd, [Rn, #offset]!

  2418 		int base	= (opcode >> 16) & 0x0F;

  2419 		int dest	= (opcode >> 12) & 0x0F;

  2420 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2421 		clockTicks += 4 + CPUUpdateTicksAccess16(address);

  2422 		CPUWriteHalfWord(address, reg[dest].W.W0);

  2423 		reg[base].I = address;

  2424 	}

  2425 	break;

  2426 	case 0x01b:

  2427 	case 0x03b:

  2428 	{

  2429 		// LDRH Rd, [Rn], -Rm

  2430 		int base	= (opcode >> 16) & 0x0F;

  2431 		int dest	= (opcode >> 12) & 0x0F;

  2432 		u32 address = reg[base].I;

  2433 		int offset	= reg[opcode & 0x0F].I;

  2434 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2435 		reg[dest].I = CPUReadHalfWord(address);

  2436 		if (dest != base)

  2437 		{

  2438 			address	   -= offset;

  2439 			reg[base].I = address;

  2440 		}

  2441 	}

  2442 	break;

  2443 	case 0x05b:

  2444 	case 0x07b:

  2445 	{

  2446 		// LDRH Rd, [Rn], #-offset

  2447 		int base	= (opcode >> 16) & 0x0F;

  2448 		int dest	= (opcode >> 12) & 0x0F;

  2449 		u32 address = reg[base].I;

  2450 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2451 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2452 		reg[dest].I = CPUReadHalfWord(address);

  2453 		if (dest != base)

  2454 		{

  2455 			address	   -= offset;

  2456 			reg[base].I = address;

  2457 		}

  2458 	}

  2459 	break;

  2460 	case 0x09b:

  2461 	case 0x0bb:

  2462 	{

  2463 		// LDRH Rd, [Rn], Rm

  2464 		int base	= (opcode >> 16) & 0x0F;

  2465 		int dest	= (opcode >> 12) & 0x0F;

  2466 		u32 address = reg[base].I;

  2467 		int offset	= reg[opcode & 0x0F].I;

  2468 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2469 		reg[dest].I = CPUReadHalfWord(address);

  2470 		if (dest != base)

  2471 		{

  2472 			address	   += offset;

  2473 			reg[base].I = address;

  2474 		}

  2475 	}

  2476 	break;

  2477 	case 0x0db:

  2478 	case 0x0fb:

  2479 	{

  2480 		// LDRH Rd, [Rn], #offset

  2481 		int base	= (opcode >> 16) & 0x0F;

  2482 		int dest	= (opcode >> 12) & 0x0F;

  2483 		u32 address = reg[base].I;

  2484 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2485 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2486 		reg[dest].I = CPUReadHalfWord(address);

  2487 		if (dest != base)

  2488 		{

  2489 			address	   += offset;

  2490 			reg[base].I = address;

  2491 		}

  2492 	}

  2493 	break;

  2494 	case 0x11b:

  2495 	{

  2496 		// LDRH Rd, [Rn, -Rm]

  2497 		int base	= (opcode >> 16) & 0x0F;

  2498 		int dest	= (opcode >> 12) & 0x0F;

  2499 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2500 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2501 		reg[dest].I = CPUReadHalfWord(address);

  2502 	}

  2503 	break;

  2504 	case 0x13b:

  2505 	{

  2506 		// LDRH Rd, [Rn, -Rm]!

  2507 		int base	= (opcode >> 16) & 0x0F;

  2508 		int dest	= (opcode >> 12) & 0x0F;

  2509 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2510 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2511 		reg[dest].I = CPUReadHalfWord(address);

  2512 		if (dest != base)

  2513 			reg[base].I = address;

  2514 	}

  2515 	break;

  2516 	case 0x15b:

  2517 	{

  2518 		// LDRH Rd, [Rn, -#offset]

  2519 		int base	= (opcode >> 16) & 0x0F;

  2520 		int dest	= (opcode >> 12) & 0x0F;

  2521 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2522 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2523 		reg[dest].I = CPUReadHalfWord(address);

  2524 	}

  2525 	break;

  2526 	case 0x17b:

  2527 	{

  2528 		// LDRH Rd, [Rn, -#offset]!

  2529 		int base	= (opcode >> 16) & 0x0F;

  2530 		int dest	= (opcode >> 12) & 0x0F;

  2531 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2532 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2533 		reg[dest].I = CPUReadHalfWord(address);

  2534 		if (dest != base)

  2535 			reg[base].I = address;

  2536 	}

  2537 	break;

  2538 	case 0x19b:

  2539 	{

  2540 		// LDRH Rd, [Rn, Rm]

  2541 		int base	= (opcode >> 16) & 0x0F;

  2542 		int dest	= (opcode >> 12) & 0x0F;

  2543 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2544 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2545 		reg[dest].I = CPUReadHalfWord(address);

  2546 	}

  2547 	break;

  2548 	case 0x1bb:

  2549 	{

  2550 		// LDRH Rd, [Rn, Rm]!

  2551 		int base	= (opcode >> 16) & 0x0F;

  2552 		int dest	= (opcode >> 12) & 0x0F;

  2553 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2554 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2555 		reg[dest].I = CPUReadHalfWord(address);

  2556 		if (dest != base)

  2557 			reg[base].I = address;

  2558 	}

  2559 	break;

  2560 	case 0x1db:

  2561 	{

  2562 		// LDRH Rd, [Rn, #offset]

  2563 		int base	= (opcode >> 16) & 0x0F;

  2564 		int dest	= (opcode >> 12) & 0x0F;

  2565 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2566 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2567 		reg[dest].I = CPUReadHalfWord(address);

  2568 	}

  2569 	break;

  2570 	case 0x1fb:

  2571 	{

  2572 		// LDRH Rd, [Rn, #offset]!

  2573 		int base	= (opcode >> 16) & 0x0F;

  2574 		int dest	= (opcode >> 12) & 0x0F;

  2575 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2576 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2577 		reg[dest].I = CPUReadHalfWord(address);

  2578 		if (dest != base)

  2579 			reg[base].I = address;

  2580 	}

  2581 	break;

  2582 	case 0x01d:

  2583 	case 0x03d:

  2584 	{

  2585 		// LDRSB Rd, [Rn], -Rm

  2586 		int base	= (opcode >> 16) & 0x0F;

  2587 		int dest	= (opcode >> 12) & 0x0F;

  2588 		u32 address = reg[base].I;

  2589 		int offset	= reg[opcode & 0x0F].I;

  2590 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2591 		reg[dest].I = (s8)CPUReadByte(address);

  2592 		if (dest != base)

  2593 		{

  2594 			address	   -= offset;

  2595 			reg[base].I = address;

  2596 		}

  2597 	}

  2598 	break;

  2599 	case 0x05d:

  2600 	case 0x07d:

  2601 	{

  2602 		// LDRSB Rd, [Rn], #-offset

  2603 		int base	= (opcode >> 16) & 0x0F;

  2604 		int dest	= (opcode >> 12) & 0x0F;

  2605 		u32 address = reg[base].I;

  2606 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2607 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2608 		reg[dest].I = (s8)CPUReadByte(address);

  2609 		if (dest != base)

  2610 		{

  2611 			address	   -= offset;

  2612 			reg[base].I = address;

  2613 		}

  2614 	}

  2615 	break;

  2616 	case 0x09d:

  2617 	case 0x0bd:

  2618 	{

  2619 		// LDRSB Rd, [Rn], Rm

  2620 		int base	= (opcode >> 16) & 0x0F;

  2621 		int dest	= (opcode >> 12) & 0x0F;

  2622 		u32 address = reg[base].I;

  2623 		int offset	= reg[opcode & 0x0F].I;

  2624 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2625 		reg[dest].I = (s8)CPUReadByte(address);

  2626 		if (dest != base)

  2627 		{

  2628 			address	   += offset;

  2629 			reg[base].I = address;

  2630 		}

  2631 	}

  2632 	break;

  2633 	case 0x0dd:

  2634 	case 0x0fd:

  2635 	{

  2636 		// LDRSB Rd, [Rn], #offset

  2637 		int base	= (opcode >> 16) & 0x0F;

  2638 		int dest	= (opcode >> 12) & 0x0F;

  2639 		u32 address = reg[base].I;

  2640 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2641 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2642 		reg[dest].I = (s8)CPUReadByte(address);

  2643 		if (dest != base)

  2644 		{

  2645 			address	   += offset;

  2646 			reg[base].I = address;

  2647 		}

  2648 	}

  2649 	break;

  2650 	case 0x11d:

  2651 	{

  2652 		// LDRSB Rd, [Rn, -Rm]

  2653 		int base	= (opcode >> 16) & 0x0F;

  2654 		int dest	= (opcode >> 12) & 0x0F;

  2655 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2656 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2657 		reg[dest].I = (s8)CPUReadByte(address);

  2658 	}

  2659 	break;

  2660 	case 0x13d:

  2661 	{

  2662 		// LDRSB Rd, [Rn, -Rm]!

  2663 		int base	= (opcode >> 16) & 0x0F;

  2664 		int dest	= (opcode >> 12) & 0x0F;

  2665 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2666 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2667 		reg[dest].I = (s8)CPUReadByte(address);

  2668 		if (dest != base)

  2669 			reg[base].I = address;

  2670 	}

  2671 	break;

  2672 	case 0x15d:

  2673 	{

  2674 		// LDRSB Rd, [Rn, -#offset]

  2675 		int base	= (opcode >> 16) & 0x0F;

  2676 		int dest	= (opcode >> 12) & 0x0F;

  2677 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2678 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2679 		reg[dest].I = (s8)CPUReadByte(address);

  2680 	}

  2681 	break;

  2682 	case 0x17d:

  2683 	{

  2684 		// LDRSB Rd, [Rn, -#offset]!

  2685 		int base	= (opcode >> 16) & 0x0F;

  2686 		int dest	= (opcode >> 12) & 0x0F;

  2687 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2688 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2689 		reg[dest].I = (s8)CPUReadByte(address);

  2690 		if (dest != base)

  2691 			reg[base].I = address;

  2692 	}

  2693 	break;

  2694 	case 0x19d:

  2695 	{

  2696 		// LDRSB Rd, [Rn, Rm]

  2697 		int base	= (opcode >> 16) & 0x0F;

  2698 		int dest	= (opcode >> 12) & 0x0F;

  2699 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2700 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2701 		reg[dest].I = (s8)CPUReadByte(address);

  2702 	}

  2703 	break;

  2704 	case 0x1bd:

  2705 	{

  2706 		// LDRSB Rd, [Rn, Rm]!

  2707 		int base	= (opcode >> 16) & 0x0F;

  2708 		int dest	= (opcode >> 12) & 0x0F;

  2709 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2710 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2711 		reg[dest].I = (s8)CPUReadByte(address);

  2712 		if (dest != base)

  2713 			reg[base].I = address;

  2714 	}

  2715 	break;

  2716 	case 0x1dd:

  2717 	{

  2718 		// LDRSB Rd, [Rn, #offset]

  2719 		int base	= (opcode >> 16) & 0x0F;

  2720 		int dest	= (opcode >> 12) & 0x0F;

  2721 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2722 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2723 		reg[dest].I = (s8)CPUReadByte(address);

  2724 	}

  2725 	break;

  2726 	case 0x1fd:

  2727 	{

  2728 		// LDRSB Rd, [Rn, #offset]!

  2729 		int base	= (opcode >> 16) & 0x0F;

  2730 		int dest	= (opcode >> 12) & 0x0F;

  2731 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2732 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2733 		reg[dest].I = (s8)CPUReadByte(address);

  2734 		if (dest != base)

  2735 			reg[base].I = address;

  2736 	}

  2737 	break;

  2738 	case 0x01f:

  2739 	case 0x03f:

  2740 	{

  2741 		// LDRSH Rd, [Rn], -Rm

  2742 		int base	= (opcode >> 16) & 0x0F;

  2743 		int dest	= (opcode >> 12) & 0x0F;

  2744 		u32 address = reg[base].I;

  2745 		int offset	= reg[opcode & 0x0F].I;

  2746 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2747 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2748 		if (dest != base)

  2749 		{

  2750 			address	   -= offset;

  2751 			reg[base].I = address;

  2752 		}

  2753 	}

  2754 	break;

  2755 	case 0x05f:

  2756 	case 0x07f:

  2757 	{

  2758 		// LDRSH Rd, [Rn], #-offset

  2759 		int base	= (opcode >> 16) & 0x0F;

  2760 		int dest	= (opcode >> 12) & 0x0F;

  2761 		u32 address = reg[base].I;

  2762 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2763 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2764 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2765 		if (dest != base)

  2766 		{

  2767 			address	   -= offset;

  2768 			reg[base].I = address;

  2769 		}

  2770 	}

  2771 	break;

  2772 	case 0x09f:

  2773 	case 0x0bf:

  2774 	{

  2775 		// LDRSH Rd, [Rn], Rm

  2776 		int base	= (opcode >> 16) & 0x0F;

  2777 		int dest	= (opcode >> 12) & 0x0F;

  2778 		u32 address = reg[base].I;

  2779 		int offset	= reg[opcode & 0x0F].I;

  2780 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2781 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2782 		if (dest != base)

  2783 		{

  2784 			address	   += offset;

  2785 			reg[base].I = address;

  2786 		}

  2787 	}

  2788 	break;

  2789 	case 0x0df:

  2790 	case 0x0ff:

  2791 	{

  2792 		// LDRSH Rd, [Rn], #offset

  2793 		int base	= (opcode >> 16) & 0x0F;

  2794 		int dest	= (opcode >> 12) & 0x0F;

  2795 		u32 address = reg[base].I;

  2796 		int offset	= (opcode & 0x0F) | ((opcode >> 4) & 0xF0);

  2797 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2798 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2799 		if (dest != base)

  2800 		{

  2801 			address	   += offset;

  2802 			reg[base].I = address;

  2803 		}

  2804 	}

  2805 	break;

  2806 	case 0x11f:

  2807 	{

  2808 		// LDRSH Rd, [Rn, -Rm]

  2809 		int base	= (opcode >> 16) & 0x0F;

  2810 		int dest	= (opcode >> 12) & 0x0F;

  2811 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2812 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2813 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2814 	}

  2815 	break;

  2816 	case 0x13f:

  2817 	{

  2818 		// LDRSH Rd, [Rn, -Rm]!

  2819 		int base	= (opcode >> 16) & 0x0F;

  2820 		int dest	= (opcode >> 12) & 0x0F;

  2821 		u32 address = reg[base].I - reg[opcode & 0x0F].I;

  2822 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2823 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2824 		if (dest != base)

  2825 			reg[base].I = address;

  2826 	}

  2827 	break;

  2828 	case 0x15f:

  2829 	{

  2830 		// LDRSH Rd, [Rn, -#offset]

  2831 		int base	= (opcode >> 16) & 0x0F;

  2832 		int dest	= (opcode >> 12) & 0x0F;

  2833 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2834 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2835 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2836 	}

  2837 	break;

  2838 	case 0x17f:

  2839 	{

  2840 		// LDRSH Rd, [Rn, -#offset]!

  2841 		int base	= (opcode >> 16) & 0x0F;

  2842 		int dest	= (opcode >> 12) & 0x0F;

  2843 		u32 address = reg[base].I - ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2844 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2845 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2846 		if (dest != base)

  2847 			reg[base].I = address;

  2848 	}

  2849 	break;

  2850 	case 0x19f:

  2851 	{

  2852 		// LDRSH Rd, [Rn, Rm]

  2853 		int base	= (opcode >> 16) & 0x0F;

  2854 		int dest	= (opcode >> 12) & 0x0F;

  2855 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2856 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2857 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2858 	}

  2859 	break;

  2860 	case 0x1bf:

  2861 	{

  2862 		// LDRSH Rd, [Rn, Rm]!

  2863 		int base	= (opcode >> 16) & 0x0F;

  2864 		int dest	= (opcode >> 12) & 0x0F;

  2865 		u32 address = reg[base].I + reg[opcode & 0x0F].I;

  2866 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2867 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2868 		if (dest != base)

  2869 			reg[base].I = address;

  2870 	}

  2871 	break;

  2872 	case 0x1df:

  2873 	{

  2874 		// LDRSH Rd, [Rn, #offset]

  2875 		int base	= (opcode >> 16) & 0x0F;

  2876 		int dest	= (opcode >> 12) & 0x0F;

  2877 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2878 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2879 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2880 	}

  2881 	break;

  2882 	case 0x1ff:

  2883 	{

  2884 		// LDRSH Rd, [Rn, #offset]!

  2885 		int base	= (opcode >> 16) & 0x0F;

  2886 		int dest	= (opcode >> 12) & 0x0F;

  2887 		u32 address = reg[base].I + ((opcode & 0x0F) | ((opcode >> 4) & 0xF0));

  2888 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  2889 		reg[dest].I = (s16)CPUReadHalfWordSigned(address);

  2890 		if (dest != base)

  2891 			reg[base].I = address;

  2892 	}

  2893 	break;

  2894 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_EOR,  OP_EOR, 0x020);

  2895 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_EORS, OP_EOR, 0x030);

  2896 	case 0x029:

  2897 	{

  2898 		// MLA Rd, Rm, Rs, Rn

  2899 		int dest = (opcode >> 16) & 0x0F;

  2900 		int mult = (opcode & 0x0F);

  2901 		u32 rs	 = reg[(opcode >> 8) & 0x0F].I;

  2902 		reg[dest].I = reg[mult].I * rs + reg[(opcode >> 12) & 0x0f].I;

  2903 		if (((s32)rs) < 0)

  2904 			rs = ~rs;

  2905 		if ((rs & 0xFFFFFF00) == 0)

  2906 			clockTicks += 3;

  2907 		else if ((rs & 0xFFFF0000) == 0)

  2908 			clockTicks += 4;

  2909 		else if ((rs & 0xFF000000) == 0)

  2910 			clockTicks += 5;

  2911 		else

  2912 			clockTicks += 6;

  2913 	}

  2914 	break;

  2915 	case 0x039:

  2916 	{

  2917 		// MLAS Rd, Rm, Rs, Rn

  2918 		int dest = (opcode >> 16) & 0x0F;

  2919 		int mult = (opcode & 0x0F);

  2920 		u32 rs	 = reg[(opcode >> 8) & 0x0F].I;

  2921 		reg[dest].I = reg[mult].I * rs + reg[(opcode >> 12) & 0x0f].I;

  2922 		N_FLAG		= (reg[dest].I & 0x80000000) ? true : false;

  2923 		Z_FLAG		= (reg[dest].I) ? false : true;

  2924 		if (((s32)rs) < 0)

  2925 			rs = ~rs;

  2926 		if ((rs & 0xFFFFFF00) == 0)

  2927 			clockTicks += 3;

  2928 		else if ((rs & 0xFFFF0000) == 0)

  2929 			clockTicks += 4;

  2930 		else if ((rs & 0xFF000000) == 0)

  2931 			clockTicks += 5;

  2932 		else

  2933 			clockTicks += 6;

  2934 	}

  2935 	break;

  2936 		ARITHMETIC_DATA_OPCODE(OP_SUB,  OP_SUB, 0x040);

  2937 		ARITHMETIC_DATA_OPCODE(OP_SUBS, OP_SUB, 0x050);

  2938 		ARITHMETIC_DATA_OPCODE(OP_RSB,  OP_RSB, 0x060);

  2939 		ARITHMETIC_DATA_OPCODE(OP_RSBS, OP_RSB, 0x070);

  2940 		ARITHMETIC_DATA_OPCODE(OP_ADD,  OP_ADD, 0x080);

  2941 		ARITHMETIC_DATA_OPCODE(OP_ADDS, OP_ADD, 0x090);

  2942 	case 0x089:

  2943 	{

  2944 		// UMULL RdLo, RdHi, Rn, Rs

  2945 		u32 umult	= reg[(opcode & 0x0F)].I;

  2946 		u32 usource = reg[(opcode >> 8) & 0x0F].I;

  2947 		int destLo	= (opcode >> 12) & 0x0F;

  2948 		int destHi	= (opcode >> 16) & 0x0F;

  2949 		u64 uTemp	= ((u64)umult) * ((u64)usource);

  2950 		reg[destLo].I = (u32)(uTemp & 0xFFFFFFFF);

  2951 		reg[destHi].I = (u32)(uTemp >> 32);

  2952 		if ((usource & 0xFFFFFF00) == 0)

  2953 			clockTicks += 2;

  2954 		else if ((usource & 0xFFFF0000) == 0)

  2955 			clockTicks += 3;

  2956 		else if ((usource & 0xFF000000) == 0)

  2957 			clockTicks += 4;

  2958 		else

  2959 			clockTicks += 5;

  2960 	}

  2961 	break;

  2962 	case 0x099:

  2963 	{

  2964 		// UMULLS RdLo, RdHi, Rn, Rs

  2965 		u32 umult	= reg[(opcode & 0x0F)].I;

  2966 		u32 usource = reg[(opcode >> 8) & 0x0F].I;

  2967 		int destLo	= (opcode >> 12) & 0x0F;

  2968 		int destHi	= (opcode >> 16) & 0x0F;

  2969 		u64 uTemp	= ((u64)umult) * ((u64)usource);

  2970 		reg[destLo].I = (u32)(uTemp & 0xFFFFFFFF);

  2971 		reg[destHi].I = (u32)(uTemp >> 32);

  2972 		Z_FLAG		  = (uTemp) ? false : true;

  2973 		N_FLAG		  = (reg[destHi].I & 0x80000000) ? true : false;

  2974 		if ((usource & 0xFFFFFF00) == 0)

  2975 			clockTicks += 2;

  2976 		else if ((usource & 0xFFFF0000) == 0)

  2977 			clockTicks += 3;

  2978 		else if ((usource & 0xFF000000) == 0)

  2979 			clockTicks += 4;

  2980 		else

  2981 			clockTicks += 5;

  2982 	}

  2983 	break;

  2984 		ARITHMETIC_DATA_OPCODE(OP_ADC,  OP_ADC, 0x0a0);

  2985 		ARITHMETIC_DATA_OPCODE(OP_ADCS, OP_ADC, 0x0b0);

  2986 	case 0x0a9:

  2987 	{

  2988 		// UMLAL RdLo, RdHi, Rn, Rs

  2989 		u32 umult	= reg[(opcode & 0x0F)].I;

  2990 		u32 usource = reg[(opcode >> 8) & 0x0F].I;

  2991 		int destLo	= (opcode >> 12) & 0x0F;

  2992 		int destHi	= (opcode >> 16) & 0x0F;

  2993 		u64 uTemp	= (u64)reg[destHi].I;

  2994 		uTemp		<<= 32;

  2995 		uTemp		 |= (u64)reg[destLo].I;

  2996 		uTemp		 += ((u64)umult) * ((u64)usource);

  2997 		reg[destLo].I = (u32)(uTemp & 0xFFFFFFFF);

  2998 		reg[destHi].I = (u32)(uTemp >> 32);

  2999 		if ((usource & 0xFFFFFF00) == 0)

  3000 			clockTicks += 3;

  3001 		else if ((usource & 0xFFFF0000) == 0)

  3002 			clockTicks += 4;

  3003 		else if ((usource & 0xFF000000) == 0)

  3004 			clockTicks += 5;

  3005 		else

  3006 			clockTicks += 6;

  3007 	}

  3008 	break;

  3009 	case 0x0b9:

  3010 	{

  3011 		// UMLALS RdLo, RdHi, Rn, Rs

  3012 		u32 umult	= reg[(opcode & 0x0F)].I;

  3013 		u32 usource = reg[(opcode >> 8) & 0x0F].I;

  3014 		int destLo	= (opcode >> 12) & 0x0F;

  3015 		int destHi	= (opcode >> 16) & 0x0F;

  3016 		u64 uTemp	= (u64)reg[destHi].I;

  3017 		uTemp		<<= 32;

  3018 		uTemp		 |= (u64)reg[destLo].I;

  3019 		uTemp		 += ((u64)umult) * ((u64)usource);

  3020 		reg[destLo].I = (u32)(uTemp & 0xFFFFFFFF);

  3021 		reg[destHi].I = (u32)(uTemp >> 32);

  3022 		Z_FLAG		  = (uTemp) ? false : true;

  3023 		N_FLAG		  = (reg[destHi].I & 0x80000000) ? true : false;

  3024 		if ((usource & 0xFFFFFF00) == 0)

  3025 			clockTicks += 3;

  3026 		else if ((usource & 0xFFFF0000) == 0)

  3027 			clockTicks += 4;

  3028 		else if ((usource & 0xFF000000) == 0)

  3029 			clockTicks += 5;

  3030 		else

  3031 			clockTicks += 6;

  3032 	}

  3033 	break;

  3034 		ARITHMETIC_DATA_OPCODE(OP_SBC,  OP_SBC, 0x0c0);

  3035 		ARITHMETIC_DATA_OPCODE(OP_SBCS, OP_SBC, 0x0d0);

  3036 	case 0x0c9:

  3037 	{

  3038 		// SMULL RdLo, RdHi, Rm, Rs

  3039 		int destLo = (opcode >> 12) & 0x0F;

  3040 		int destHi = (opcode >> 16) & 0x0F;

  3041 		u32 rs	   = reg[(opcode >> 8) & 0x0F].I;

  3042 		s64 m	   = (s32)reg[(opcode & 0x0F)].I;

  3043 		s64 s	   = (s32)rs;

  3044 		s64 sTemp  = m * s;

  3045 		reg[destLo].I = (u32)(sTemp & 0xFFFFFFFF);

  3046 		reg[destHi].I = (u32)(sTemp >> 32);

  3047 		if (((s32)rs) < 0)

  3048 			rs = ~rs;

  3049 		if ((rs & 0xFFFFFF00) == 0)

  3050 			clockTicks += 2;

  3051 		else if ((rs & 0xFFFF0000) == 0)

  3052 			clockTicks += 3;

  3053 		else if ((rs & 0xFF000000) == 0)

  3054 			clockTicks += 4;

  3055 		else

  3056 			clockTicks += 5;

  3057 	}

  3058 	break;

  3059 	case 0x0d9:

  3060 	{

  3061 		// SMULLS RdLo, RdHi, Rm, Rs

  3062 		int destLo = (opcode >> 12) & 0x0F;

  3063 		int destHi = (opcode >> 16) & 0x0F;

  3064 		u32 rs	   = reg[(opcode >> 8) & 0x0F].I;

  3065 		s64 m	   = (s32)reg[(opcode & 0x0F)].I;

  3066 		s64 s	   = (s32)rs;

  3067 		s64 sTemp  = m * s;

  3068 		reg[destLo].I = (u32)(sTemp & 0xFFFFFFFF);

  3069 		reg[destHi].I = (u32)(sTemp >> 32);

  3070 		Z_FLAG		  = (sTemp) ? false : true;

  3071 		N_FLAG		  = (sTemp < 0) ? true : false;

  3072 		if (((s32)rs) < 0)

  3073 			rs = ~rs;

  3074 		if ((rs & 0xFFFFFF00) == 0)

  3075 			clockTicks += 2;

  3076 		else if ((rs & 0xFFFF0000) == 0)

  3077 			clockTicks += 3;

  3078 		else if ((rs & 0xFF000000) == 0)

  3079 			clockTicks += 4;

  3080 		else

  3081 			clockTicks += 5;

  3082 	}

  3083 	break;

  3084 		ARITHMETIC_DATA_OPCODE(OP_RSC,  OP_RSC, 0x0e0);

  3085 		ARITHMETIC_DATA_OPCODE(OP_RSCS, OP_RSC, 0x0f0);

  3086 	case 0x0e9:

  3087 	{

  3088 		// SMLAL RdLo, RdHi, Rm, Rs

  3089 		int destLo = (opcode >> 12) & 0x0F;

  3090 		int destHi = (opcode >> 16) & 0x0F;

  3091 		u32 rs	   = reg[(opcode >> 8) & 0x0F].I;

  3092 		s64 m	   = (s32)reg[(opcode & 0x0F)].I;

  3093 		s64 s	   = (s32)rs;

  3094 		s64 sTemp  = (u64)reg[destHi].I;

  3095 		sTemp		<<= 32;

  3096 		sTemp		 |= (u64)reg[destLo].I;

  3097 		sTemp		 += m * s;

  3098 		reg[destLo].I = (u32)(sTemp & 0xFFFFFFFF);

  3099 		reg[destHi].I = (u32)(sTemp >> 32);

  3100 		if (((s32)rs) < 0)

  3101 			rs = ~rs;

  3102 		if ((rs & 0xFFFFFF00) == 0)

  3103 			clockTicks += 3;

  3104 		else if ((rs & 0xFFFF0000) == 0)

  3105 			clockTicks += 4;

  3106 		else if ((rs & 0xFF000000) == 0)

  3107 			clockTicks += 5;

  3108 		else

  3109 			clockTicks += 6;

  3110 	}

  3111 	break;

  3112 	case 0x0f9:

  3113 	{

  3114 		// SMLALS RdLo, RdHi, Rm, Rs

  3115 		int destLo = (opcode >> 12) & 0x0F;

  3116 		int destHi = (opcode >> 16) & 0x0F;

  3117 		u32 rs	   = reg[(opcode >> 8) & 0x0F].I;

  3118 		s64 m	   = (s32)reg[(opcode & 0x0F)].I;

  3119 		s64 s	   = (s32)rs;

  3120 		s64 sTemp  = (u64)reg[destHi].I;

  3121 		sTemp		<<= 32;

  3122 		sTemp		 |= (u64)reg[destLo].I;

  3123 		sTemp		 += m * s;

  3124 		reg[destLo].I = (u32)(sTemp & 0xFFFFFFFF);

  3125 		reg[destHi].I = (u32)(sTemp >> 32);

  3126 		Z_FLAG		  = (sTemp) ? false : true;

  3127 		N_FLAG		  = (sTemp < 0) ? true : false;

  3128 		if (((s32)rs) < 0)

  3129 			rs = ~rs;

  3130 		if ((rs & 0xFFFFFF00) == 0)

  3131 			clockTicks += 3;

  3132 		else if ((rs & 0xFFFF0000) == 0)

  3133 			clockTicks += 4;

  3134 		else if ((rs & 0xFF000000) == 0)

  3135 			clockTicks += 5;

  3136 		else

  3137 			clockTicks += 6;

  3138 	}

  3139 	break;

  3140 		LOGICAL_DATA_OPCODE(OP_TST, OP_TST, 0x110);

  3141 	case 0x100:

  3142 		// MRS Rd, CPSR

  3143 		// TODO: check if right instruction....

  3144 		CPUUpdateCPSR();

  3145 		reg[(opcode >> 12) & 0x0F].I = reg[16].I;

  3146 		break;

  3147 	case 0x109:

  3148 	{

  3149 		// SWP Rd, Rm, [Rn]

  3150 		u32 address = reg[(opcode >> 16) & 15].I;

  3151 		u32 temp	= CPUReadMemory(address);

  3152 		CPUWriteMemory(address, reg[opcode & 15].I);

  3153 		reg[(opcode >> 12) & 15].I = temp;

  3154 	}

  3155 	break;

  3156 		LOGICAL_DATA_OPCODE(OP_TEQ, OP_TEQ, 0x130);

  3157 	case 0x120:

  3158 	{

  3159 		// MSR CPSR_fields, Rm

  3160 		CPUUpdateCPSR();

  3161 		u32 value	 = reg[opcode & 15].I;

  3162 		u32 newValue = reg[16].I;

  3163 		if (armMode > 0x10)

  3164 		{

  3165 			if (opcode & 0x00010000)

  3166 				newValue = (newValue & 0xFFFFFF00) | (value & 0x000000FF);

  3167 			if (opcode & 0x00020000)

  3168 				newValue = (newValue & 0xFFFF00FF) | (value & 0x0000FF00);

  3169 			if (opcode & 0x00040000)

  3170 				newValue = (newValue & 0xFF00FFFF) | (value & 0x00FF0000);

  3171 		}

  3172 		if (opcode & 0x00080000)

  3173 			newValue = (newValue & 0x00FFFFFF) | (value & 0xFF000000);

  3174 		newValue |= 0x10;

  3175 		CPUSwitchMode(newValue & 0x1f, false);

  3176 		reg[16].I = newValue;

  3177 		CPUUpdateFlags();

  3178 	}

  3179 	break;

  3180 	case 0x121:

  3181 	{

  3182 		// BX Rm

  3183 		// TODO: check if right instruction...

  3184 		clockTicks += 3;

  3185 		int base = opcode & 0x0F;

  3186 		armState = reg[base].I & 1 ? false : true;

  3187 		if (armState)

  3188 		{

  3189 			reg[15].I  = reg[base].I & 0xFFFFFFFC;

  3190 			armNextPC  = reg[15].I;

  3191 			reg[15].I += 4;

  3192 		}

  3193 		else

  3194 		{

  3195 			reg[15].I  = reg[base].I & 0xFFFFFFFE;

  3196 			armNextPC  = reg[15].I;

  3197 			reg[15].I += 2;

  3198 		}

  3199 	}

  3200 	break;

  3201 		ARITHMETIC_DATA_OPCODE(OP_CMP, OP_CMP, 0x150);

  3202 	case 0x140:

  3203 		// MRS Rd, SPSR

  3204 		// TODO: check if right instruction...

  3205 		reg[(opcode >> 12) & 0x0F].I = reg[17].I;

  3206 		break;

  3207 	case 0x149:

  3208 	{

  3209 		// SWPB Rd, Rm, [Rn]

  3210 		u32 address = reg[(opcode >> 16) & 15].I;

  3211 		u32 temp	= CPUReadByte(address);

  3212 		CPUWriteByte(address, reg[opcode & 15].B.B0);

  3213 		reg[(opcode >> 12) & 15].I = temp;

  3214 	}

  3215 	break;

  3216 		ARITHMETIC_DATA_OPCODE(OP_CMN, OP_CMN, 0x170);

  3217 	case 0x160:

  3218 	{

  3219 		// MSR SPSR_fields, Rm

  3220 		u32 value = reg[opcode & 15].I;

  3221 		if (armMode > 0x10 && armMode < 0x1f)

  3222 		{

  3223 			if (opcode & 0x00010000)

  3224 				reg[17].I = (reg[17].I & 0xFFFFFF00) | (value & 0x000000FF);

  3225 			if (opcode & 0x00020000)

  3226 				reg[17].I = (reg[17].I & 0xFFFF00FF) | (value & 0x0000FF00);

  3227 			if (opcode & 0x00040000)

  3228 				reg[17].I = (reg[17].I & 0xFF00FFFF) | (value & 0x00FF0000);

  3229 			if (opcode & 0x00080000)

  3230 				reg[17].I = (reg[17].I & 0x00FFFFFF) | (value & 0xFF000000);

  3231 		}

  3232 	}

  3233 	break;

  3234 		LOGICAL_DATA_OPCODE(OP_ORR,  OP_ORR, 0x180);

  3235 		LOGICAL_DATA_OPCODE(OP_ORRS, OP_ORR, 0x190);

  3236 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_MOV,  OP_MOV, 0x1a0);

  3237 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_MOVS, OP_MOV, 0x1b0);

  3238 		LOGICAL_DATA_OPCODE(OP_BIC,  OP_BIC, 0x1c0);

  3239 		LOGICAL_DATA_OPCODE(OP_BICS, OP_BIC, 0x1d0);

  3240 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_MVN,  OP_MVN, 0x1e0);

  3241 		LOGICAL_DATA_OPCODE_WITHOUT_base(OP_MVNS, OP_MVN, 0x1f0);

  3242 #ifdef BKPT_SUPPORT

  3243 	case 0x127:

  3244 	case 0x7ff: // for GDB support

  3245 		extern void (*dbgSignal)(int, int);

  3246 		reg[15].I -= 4;

  3247 		armNextPC -= 4;

  3248 		dbgSignal(5, (opcode & 0x0f) | ((opcode >> 4) & 0xfff0));

  3249 		return;

  3250 #endif

  3251 	case 0x320:

  3252 	case 0x321:

  3253 	case 0x322:

  3254 	case 0x323:

  3255 	case 0x324:

  3256 	case 0x325:

  3257 	case 0x326:

  3258 	case 0x327:

  3259 	case 0x328:

  3260 	case 0x329:

  3261 	case 0x32a:

  3262 	case 0x32b:

  3263 	case 0x32c:

  3264 	case 0x32d:

  3265 	case 0x32e:

  3266 	case 0x32f:

  3267 	{

  3268 		// MSR CPSR_fields, #

  3269 		CPUUpdateCPSR();

  3270 		u32 value = opcode & 0xFF;

  3271 		int shift = (opcode & 0xF00) >> 7;

  3272 		if (shift)

  3273 		{

  3274 			ROR_IMM_MSR;

  3275 		}

  3276 		u32 newValue = reg[16].I;

  3277 		if (armMode > 0x10)

  3278 		{

  3279 			if (opcode & 0x00010000)

  3280 				newValue = (newValue & 0xFFFFFF00) | (value & 0x000000FF);

  3281 			if (opcode & 0x00020000)

  3282 				newValue = (newValue & 0xFFFF00FF) | (value & 0x0000FF00);

  3283 			if (opcode & 0x00040000)

  3284 				newValue = (newValue & 0xFF00FFFF) | (value & 0x00FF0000);

  3285 		}

  3286 		if (opcode & 0x00080000)

  3287 			newValue = (newValue & 0x00FFFFFF) | (value & 0xFF000000);

  3288 

  3289 		newValue |= 0x10;

  3290 

  3291 		CPUSwitchMode(newValue & 0x1f, false);

  3292 		reg[16].I = newValue;

  3293 		CPUUpdateFlags();

  3294 	}

  3295 	break;

  3296 	case 0x360:

  3297 	case 0x361:

  3298 	case 0x362:

  3299 	case 0x363:

  3300 	case 0x364:

  3301 	case 0x365:

  3302 	case 0x366:

  3303 	case 0x367:

  3304 	case 0x368:

  3305 	case 0x369:

  3306 	case 0x36a:

  3307 	case 0x36b:

  3308 	case 0x36c:

  3309 	case 0x36d:

  3310 	case 0x36e:

  3311 	case 0x36f:

  3312 	{

  3313 		// MSR SPSR_fields, #

  3314 		if (armMode > 0x10 && armMode < 0x1f)

  3315 		{

  3316 			u32 value = opcode & 0xFF;

  3317 			int shift = (opcode & 0xF00) >> 7;

  3318 			if (shift)

  3319 			{

  3320 				ROR_IMM_MSR;

  3321 			}

  3322 			if (opcode & 0x00010000)

  3323 				reg[17].I = (reg[17].I & 0xFFFFFF00) | (value & 0x000000FF);

  3324 			if (opcode & 0x00020000)

  3325 				reg[17].I = (reg[17].I & 0xFFFF00FF) | (value & 0x0000FF00);

  3326 			if (opcode & 0x00040000)

  3327 				reg[17].I = (reg[17].I & 0xFF00FFFF) | (value & 0x00FF0000);

  3328 			if (opcode & 0x00080000)

  3329 				reg[17].I = (reg[17].I & 0x00FFFFFF) | (value & 0xFF000000);

  3330 		}

  3331 	}

  3332 	break;

  3333 		CASE_16(0x400)

  3334 		// T versions shouldn't be different on GBA

  3335 		CASE_16(0x420)

  3336 		{

  3337 			// STR Rd, [Rn], -#

  3338 			int offset	= opcode & 0xFFF;

  3339 			int dest	= (opcode >> 12) & 15;

  3340 			int base	= (opcode >> 16) & 15;

  3341 			u32 address = reg[base].I;

  3342 			CPUWriteMemory(address, reg[dest].I);

  3343 			reg[base].I = address - offset;

  3344 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3345 		}

  3346 		break;

  3347 		CASE_16(0x480)

  3348 		// T versions shouldn't be different on GBA

  3349 		CASE_16(0x4a0)

  3350 		{

  3351 			// STR Rd, [Rn], #

  3352 			int offset	= opcode & 0xFFF;

  3353 			int dest	= (opcode >> 12) & 15;

  3354 			int base	= (opcode >> 16) & 15;

  3355 			u32 address = reg[base].I;

  3356 			CPUWriteMemory(address, reg[dest].I);

  3357 			reg[base].I = address + offset;

  3358 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3359 		}

  3360 		break;

  3361 		CASE_16(0x500)

  3362 		{

  3363 			// STR Rd, [Rn, -#]

  3364 			int offset	= opcode & 0xFFF;

  3365 			int dest	= (opcode >> 12) & 15;

  3366 			int base	= (opcode >> 16) & 15;

  3367 			u32 address = reg[base].I - offset;

  3368 			CPUWriteMemory(address, reg[dest].I);

  3369 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3370 		}

  3371 		break;

  3372 		CASE_16(0x520)

  3373 		{

  3374 			// STR Rd, [Rn, -#]!

  3375 			int offset	= opcode & 0xFFF;

  3376 			int dest	= (opcode >> 12) & 15;

  3377 			int base	= (opcode >> 16) & 15;

  3378 			u32 address = reg[base].I - offset;

  3379 			reg[base].I = address;

  3380 			CPUWriteMemory(address, reg[dest].I);

  3381 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3382 		}

  3383 		break;

  3384 		CASE_16(0x580)

  3385 		{

  3386 			// STR Rd, [Rn, #]

  3387 			int offset	= opcode & 0xFFF;

  3388 			int dest	= (opcode >> 12) & 15;

  3389 			int base	= (opcode >> 16) & 15;

  3390 			u32 address = reg[base].I + offset;

  3391 			CPUWriteMemory(address, reg[dest].I);

  3392 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3393 		}

  3394 		break;

  3395 		CASE_16(0x5a0)

  3396 		{

  3397 			// STR Rd, [Rn, #]!

  3398 			int offset	= opcode & 0xFFF;

  3399 			int dest	= (opcode >> 12) & 15;

  3400 			int base	= (opcode >> 16) & 15;

  3401 			u32 address = reg[base].I + offset;

  3402 			reg[base].I = address;

  3403 			CPUWriteMemory(address, reg[dest].I);

  3404 			clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3405 		}

  3406 		break;

  3407 		CASE_16(0x410)

  3408 		{

  3409 			// LDR Rd, [Rn], -#

  3410 			int offset	= opcode & 0xFFF;

  3411 			int dest	= (opcode >> 12) & 15;

  3412 			int base	= (opcode >> 16) & 15;

  3413 			u32 address = reg[base].I;

  3414 			reg[dest].I = CPUReadMemory(address);

  3415 			if (dest != base)

  3416 				reg[base].I -= offset;

  3417 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3418 			if (dest == 15)

  3419 			{

  3420 				clockTicks += 2;

  3421 				reg[15].I  &= 0xFFFFFFFC;

  3422 				armNextPC	= reg[15].I;

  3423 				reg[15].I  += 4;

  3424 			}

  3425 		}

  3426 		break;

  3427 		CASE_16(0x430)

  3428 		{

  3429 			// LDRT Rd, [Rn], -#

  3430 			int offset	= opcode & 0xFFF;

  3431 			int dest	= (opcode >> 12) & 15;

  3432 			int base	= (opcode >> 16) & 15;

  3433 			u32 address = reg[base].I;

  3434 			reg[dest].I = CPUReadMemory(address);

  3435 			if (dest != base)

  3436 				reg[base].I -= offset;

  3437 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3438 		}

  3439 		break;

  3440 		CASE_16(0x490)

  3441 		{

  3442 			// LDR Rd, [Rn], #

  3443 			int offset	= opcode & 0xFFF;

  3444 			int dest	= (opcode >> 12) & 15;

  3445 			int base	= (opcode >> 16) & 15;

  3446 			u32 address = reg[base].I;

  3447 			reg[dest].I = CPUReadMemory(address);

  3448 			if (dest != base)

  3449 				reg[base].I += offset;

  3450 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3451 			if (dest == 15)

  3452 			{

  3453 				clockTicks += 2;

  3454 				reg[15].I  &= 0xFFFFFFFC;

  3455 				armNextPC	= reg[15].I;

  3456 				reg[15].I  += 4;

  3457 			}

  3458 		}

  3459 		break;

  3460 		CASE_16(0x4b0)

  3461 		{

  3462 			// LDRT Rd, [Rn], #

  3463 			int offset	= opcode & 0xFFF;

  3464 			int dest	= (opcode >> 12) & 15;

  3465 			int base	= (opcode >> 16) & 15;

  3466 			u32 address = reg[base].I;

  3467 			reg[dest].I = CPUReadMemory(address);

  3468 			if (dest != base)

  3469 				reg[base].I += offset;

  3470 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3471 		}

  3472 		break;

  3473 		CASE_16(0x510)

  3474 		{

  3475 			// LDR Rd, [Rn, -#]

  3476 			int offset	= opcode & 0xFFF;

  3477 			int dest	= (opcode >> 12) & 15;

  3478 			int base	= (opcode >> 16) & 15;

  3479 			u32 address = reg[base].I - offset;

  3480 			reg[dest].I = CPUReadMemory(address);

  3481 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3482 			if (dest == 15)

  3483 			{

  3484 				clockTicks += 2;

  3485 				reg[15].I  &= 0xFFFFFFFC;

  3486 				armNextPC	= reg[15].I;

  3487 				reg[15].I  += 4;

  3488 			}

  3489 		}

  3490 		break;

  3491 		CASE_16(0x530)

  3492 		{

  3493 			// LDR Rd, [Rn, -#]!

  3494 			int offset	= opcode & 0xFFF;

  3495 			int dest	= (opcode >> 12) & 15;

  3496 			int base	= (opcode >> 16) & 15;

  3497 			u32 address = reg[base].I - offset;

  3498 			reg[dest].I = CPUReadMemory(address);

  3499 			if (dest != base)

  3500 				reg[base].I = address;

  3501 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3502 			if (dest == 15)

  3503 			{

  3504 				clockTicks += 2;

  3505 				reg[15].I  &= 0xFFFFFFFC;

  3506 				armNextPC	= reg[15].I;

  3507 				reg[15].I  += 4;

  3508 			}

  3509 		}

  3510 		break;

  3511 		CASE_16(0x590)

  3512 		{

  3513 			// LDR Rd, [Rn, #]

  3514 			int offset	= opcode & 0xFFF;

  3515 			int dest	= (opcode >> 12) & 15;

  3516 			int base	= (opcode >> 16) & 15;

  3517 			u32 address = reg[base].I + offset;

  3518 			reg[dest].I = CPUReadMemory(address);

  3519 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3520 			if (dest == 15)

  3521 			{

  3522 				clockTicks += 2;

  3523 				reg[15].I  &= 0xFFFFFFFC;

  3524 				armNextPC	= reg[15].I;

  3525 				reg[15].I  += 4;

  3526 			}

  3527 		}

  3528 		break;

  3529 		CASE_16(0x5b0)

  3530 		{

  3531 			// LDR Rd, [Rn, #]!

  3532 			int offset	= opcode & 0xFFF;

  3533 			int dest	= (opcode >> 12) & 15;

  3534 			int base	= (opcode >> 16) & 15;

  3535 			u32 address = reg[base].I + offset;

  3536 			reg[dest].I = CPUReadMemory(address);

  3537 			if (dest != base)

  3538 				reg[base].I = address;

  3539 			clockTicks += 3 + CPUUpdateTicksAccess32(address);

  3540 			if (dest == 15)

  3541 			{

  3542 				clockTicks += 2;

  3543 				reg[15].I  &= 0xFFFFFFFC;

  3544 				armNextPC	= reg[15].I;

  3545 				reg[15].I  += 4;

  3546 			}

  3547 		}

  3548 		break;

  3549 		CASE_16(0x440)

  3550 		// T versions shouldn't be different on GBA

  3551 		CASE_16(0x460)

  3552 		{

  3553 			// STRB Rd, [Rn], -#

  3554 			int offset	= opcode & 0xFFF;

  3555 			int dest	= (opcode >> 12) & 15;

  3556 			int base	= (opcode >> 16) & 15;

  3557 			u32 address = reg[base].I;

  3558 			CPUWriteByte(address, reg[dest].B.B0);

  3559 			reg[base].I = address - offset;

  3560 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3561 		}

  3562 		break;

  3563 		CASE_16(0x4c0)

  3564 		// T versions shouldn't be different on GBA

  3565 		CASE_16(0x4e0)

  3566 		// STRB Rd, [Rn], #

  3567 		{

  3568 			int offset	= opcode & 0xFFF;

  3569 			int dest	= (opcode >> 12) & 15;

  3570 			int base	= (opcode >> 16) & 15;

  3571 			u32 address = reg[base].I;

  3572 			CPUWriteByte(address, reg[dest].B.B0);

  3573 			reg[base].I = address + offset;

  3574 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3575 		}

  3576 		break;

  3577 		CASE_16(0x540)

  3578 		{

  3579 			// STRB Rd, [Rn, -#]

  3580 			int offset	= opcode & 0xFFF;

  3581 			int dest	= (opcode >> 12) & 15;

  3582 			int base	= (opcode >> 16) & 15;

  3583 			u32 address = reg[base].I - offset;

  3584 			CPUWriteByte(address, reg[dest].B.B0);

  3585 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3586 		}

  3587 		break;

  3588 		CASE_16(0x560)

  3589 		{

  3590 			// STRB Rd, [Rn, -#]!

  3591 			int offset	= opcode & 0xFFF;

  3592 			int dest	= (opcode >> 12) & 15;

  3593 			int base	= (opcode >> 16) & 15;

  3594 			u32 address = reg[base].I - offset;

  3595 			reg[base].I = address;

  3596 			CPUWriteByte(address, reg[dest].B.B0);

  3597 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3598 		}

  3599 		break;

  3600 		CASE_16(0x5c0)

  3601 		{

  3602 			// STRB Rd, [Rn, #]

  3603 			int offset	= opcode & 0xFFF;

  3604 			int dest	= (opcode >> 12) & 15;

  3605 			int base	= (opcode >> 16) & 15;

  3606 			u32 address = reg[base].I + offset;

  3607 			CPUWriteByte(address, reg[dest].B.B0);

  3608 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3609 		}

  3610 		break;

  3611 		CASE_16(0x5e0)

  3612 		{

  3613 			// STRB Rd, [Rn, #]!

  3614 			int offset	= opcode & 0xFFF;

  3615 			int dest	= (opcode >> 12) & 15;

  3616 			int base	= (opcode >> 16) & 15;

  3617 			u32 address = reg[base].I + offset;

  3618 			reg[base].I = address;

  3619 			CPUWriteByte(address, reg[dest].I);

  3620 			clockTicks += 2 + CPUUpdateTicksAccess16(address);

  3621 		}

  3622 		break;

  3623 		CASE_16(0x450)

  3624 		// T versions shouldn't be different

  3625 		CASE_16(0x470)

  3626 		{

  3627 			// LDRB Rd, [Rn], -#

  3628 			int offset	= opcode & 0xFFF;

  3629 			int dest	= (opcode >> 12) & 15;

  3630 			int base	= (opcode >> 16) & 15;

  3631 			u32 address = reg[base].I;

  3632 			reg[dest].I = CPUReadByte(address);

  3633 			if (dest != base)

  3634 				reg[base].I -= offset;

  3635 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3636 		}

  3637 		break;

  3638 		CASE_16(0x4d0)

  3639 		CASE_16(0x4f0) // T versions should not be different

  3640 		{

  3641 			// LDRB Rd, [Rn], #

  3642 			int offset	= opcode & 0xFFF;

  3643 			int dest	= (opcode >> 12) & 15;

  3644 			int base	= (opcode >> 16) & 15;

  3645 			u32 address = reg[base].I;

  3646 			reg[dest].I = CPUReadByte(address);

  3647 			if (dest != base)

  3648 				reg[base].I += offset;

  3649 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3650 		}

  3651 		break;

  3652 		CASE_16(0x550)

  3653 		{

  3654 			// LDRB Rd, [Rn, -#]

  3655 			int offset	= opcode & 0xFFF;

  3656 			int dest	= (opcode >> 12) & 15;

  3657 			int base	= (opcode >> 16) & 15;

  3658 			u32 address = reg[base].I - offset;

  3659 			reg[dest].I = CPUReadByte(address);

  3660 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3661 		}

  3662 		break;

  3663 		CASE_16(0x570)

  3664 		{

  3665 			// LDRB Rd, [Rn, -#]!

  3666 			int offset	= opcode & 0xFFF;

  3667 			int dest	= (opcode >> 12) & 15;

  3668 			int base	= (opcode >> 16) & 15;

  3669 			u32 address = reg[base].I - offset;

  3670 			reg[dest].I = CPUReadByte(address);

  3671 			if (dest != base)

  3672 				reg[base].I = address;

  3673 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3674 		}

  3675 		break;

  3676 		CASE_16(0x5d0)

  3677 		{

  3678 			// LDRB Rd, [Rn, #]

  3679 			int offset	= opcode & 0xFFF;

  3680 			int dest	= (opcode >> 12) & 15;

  3681 			int base	= (opcode >> 16) & 15;

  3682 			u32 address = reg[base].I + offset;

  3683 			reg[dest].I = CPUReadByte(address);

  3684 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3685 		}

  3686 		break;

  3687 		CASE_16(0x5f0)

  3688 		{

  3689 			// LDRB Rd, [Rn, #]!

  3690 			int offset	= opcode & 0xFFF;

  3691 			int dest	= (opcode >> 12) & 15;

  3692 			int base	= (opcode >> 16) & 15;

  3693 			u32 address = reg[base].I + offset;

  3694 			reg[dest].I = CPUReadByte(address);

  3695 			if (dest != base)

  3696 				reg[base].I = address;

  3697 			clockTicks += 3 + CPUUpdateTicksAccess16(address);

  3698 		}

  3699 		break;

  3700 	case 0x600:

  3701 	case 0x608:

  3702 	// T versions are the same

  3703 	case 0x620:

  3704 	case 0x628:

  3705 	{

  3706 		// STR Rd, [Rn], -Rm, LSL #

  3707 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  3708 		int dest	= (opcode >> 12) & 15;

  3709 		int base	= (opcode >> 16) & 15;

  3710 		u32 address = reg[base].I;

  3711 		CPUWriteMemory(address, reg[dest].I);

  3712 		reg[base].I = address - offset;

  3713 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3714 	}

  3715 	break;

  3716 	case 0x602:

  3717 	case 0x60a:

  3718 	// T versions are the same

  3719 	case 0x622:

  3720 	case 0x62a:

  3721 	{

  3722 		// STR Rd, [Rn], -Rm, LSR #

  3723 		int shift	= (opcode >> 7) & 31;

  3724 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  3725 		int dest	= (opcode >> 12) & 15;

  3726 		int base	= (opcode >> 16) & 15;

  3727 		u32 address = reg[base].I;

  3728 		CPUWriteMemory(address, reg[dest].I);

  3729 		reg[base].I = address - offset;

  3730 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3731 	}

  3732 	break;

  3733 	case 0x604:

  3734 	case 0x60c:

  3735 	// T versions are the same

  3736 	case 0x624:

  3737 	case 0x62c:

  3738 	{

  3739 		// STR Rd, [Rn], -Rm, ASR #

  3740 		int shift = (opcode >> 7) & 31;

  3741 		int offset;

  3742 		if (shift)

  3743 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  3744 		else if (reg[opcode & 15].I & 0x80000000)

  3745 			offset = 0xFFFFFFFF;

  3746 		else

  3747 			offset = 0;

  3748 		int dest	= (opcode >> 12) & 15;

  3749 		int base	= (opcode >> 16) & 15;

  3750 		u32 address = reg[base].I;

  3751 		CPUWriteMemory(address, reg[dest].I);

  3752 		reg[base].I = address - offset;

  3753 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3754 	}

  3755 	break;

  3756 	case 0x606:

  3757 	case 0x60e:

  3758 	// T versions are the same

  3759 	case 0x626:

  3760 	case 0x62e:

  3761 	{

  3762 		// STR Rd, [Rn], -Rm, ROR #

  3763 		int shift = (opcode >> 7) & 31;

  3764 		u32 value = reg[opcode & 15].I;

  3765 		if (shift)

  3766 		{

  3767 			ROR_VALUE;

  3768 		}

  3769 		else

  3770 		{

  3771 			RCR_VALUE;

  3772 		}

  3773 		int dest	= (opcode >> 12) & 15;

  3774 		int base	= (opcode >> 16) & 15;

  3775 		u32 address = reg[base].I;

  3776 		CPUWriteMemory(address, reg[dest].I);

  3777 		reg[base].I = address - value;

  3778 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3779 	}

  3780 	break;

  3781 	case 0x680:

  3782 	case 0x688:

  3783 	// T versions are the same

  3784 	case 0x6a0:

  3785 	case 0x6a8:

  3786 	{

  3787 		// STR Rd, [Rn], Rm, LSL #

  3788 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  3789 		int dest	= (opcode >> 12) & 15;

  3790 		int base	= (opcode >> 16) & 15;

  3791 		u32 address = reg[base].I;

  3792 		CPUWriteMemory(address, reg[dest].I);

  3793 		reg[base].I = address + offset;

  3794 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3795 	}

  3796 	break;

  3797 	case 0x682:

  3798 	case 0x68a:

  3799 	// T versions are the same

  3800 	case 0x6a2:

  3801 	case 0x6aa:

  3802 	{

  3803 		// STR Rd, [Rn], Rm, LSR #

  3804 		int shift	= (opcode >> 7) & 31;

  3805 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  3806 		int dest	= (opcode >> 12) & 15;

  3807 		int base	= (opcode >> 16) & 15;

  3808 		u32 address = reg[base].I;

  3809 		CPUWriteMemory(address, reg[dest].I);

  3810 		reg[base].I = address + offset;

  3811 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3812 	}

  3813 	break;

  3814 	case 0x684:

  3815 	case 0x68c:

  3816 	// T versions are the same

  3817 	case 0x6a4:

  3818 	case 0x6ac:

  3819 	{

  3820 		// STR Rd, [Rn], Rm, ASR #

  3821 		int shift = (opcode >> 7) & 31;

  3822 		int offset;

  3823 		if (shift)

  3824 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  3825 		else if (reg[opcode & 15].I & 0x80000000)

  3826 			offset = 0xFFFFFFFF;

  3827 		else

  3828 			offset = 0;

  3829 		int dest	= (opcode >> 12) & 15;

  3830 		int base	= (opcode >> 16) & 15;

  3831 		u32 address = reg[base].I;

  3832 		CPUWriteMemory(address, reg[dest].I);

  3833 		reg[base].I = address + offset;

  3834 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3835 	}

  3836 	break;

  3837 	case 0x686:

  3838 	case 0x68e:

  3839 	// T versions are the same

  3840 	case 0x6a6:

  3841 	case 0x6ae:

  3842 	{

  3843 		// STR Rd, [Rn], Rm, ROR #

  3844 		int shift = (opcode >> 7) & 31;

  3845 		u32 value = reg[opcode & 15].I;

  3846 		if (shift)

  3847 		{

  3848 			ROR_VALUE;

  3849 		}

  3850 		else

  3851 		{

  3852 			RCR_VALUE;

  3853 		}

  3854 		int dest	= (opcode >> 12) & 15;

  3855 		int base	= (opcode >> 16) & 15;

  3856 		u32 address = reg[base].I;

  3857 		CPUWriteMemory(address, reg[dest].I);

  3858 		reg[base].I = address + value;

  3859 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3860 	}

  3861 	break;

  3862 	case 0x700:

  3863 	case 0x708:

  3864 	{

  3865 		// STR Rd, [Rn, -Rm, LSL #]

  3866 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  3867 		int dest	= (opcode >> 12) & 15;

  3868 		int base	= (opcode >> 16) & 15;

  3869 		u32 address = reg[base].I - offset;

  3870 		CPUWriteMemory(address, reg[dest].I);

  3871 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3872 	}

  3873 	break;

  3874 	case 0x702:

  3875 	case 0x70a:

  3876 	{

  3877 		// STR Rd, [Rn, -Rm, LSR #]

  3878 		int shift	= (opcode >> 7) & 31;

  3879 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  3880 		int dest	= (opcode >> 12) & 15;

  3881 		int base	= (opcode >> 16) & 15;

  3882 		u32 address = reg[base].I - offset;

  3883 		CPUWriteMemory(address, reg[dest].I);

  3884 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3885 	}

  3886 	break;

  3887 	case 0x704:

  3888 	case 0x70c:

  3889 	{

  3890 		// STR Rd, [Rn, -Rm, ASR #]

  3891 		int shift = (opcode >> 7) & 31;

  3892 		int offset;

  3893 		if (shift)

  3894 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  3895 		else if (reg[opcode & 15].I & 0x80000000)

  3896 			offset = 0xFFFFFFFF;

  3897 		else

  3898 			offset = 0;

  3899 		int dest	= (opcode >> 12) & 15;

  3900 		int base	= (opcode >> 16) & 15;

  3901 		u32 address = reg[base].I - offset;

  3902 		CPUWriteMemory(address, reg[dest].I);

  3903 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3904 	}

  3905 	break;

  3906 	case 0x706:

  3907 	case 0x70e:

  3908 	{

  3909 		// STR Rd, [Rn, -Rm, ROR #]

  3910 		int shift = (opcode >> 7) & 31;

  3911 		u32 value = reg[opcode & 15].I;

  3912 		if (shift)

  3913 		{

  3914 			ROR_VALUE;

  3915 		}

  3916 		else

  3917 		{

  3918 			RCR_VALUE;

  3919 		}

  3920 		int dest	= (opcode >> 12) & 15;

  3921 		int base	= (opcode >> 16) & 15;

  3922 		u32 address = reg[base].I - value;

  3923 		CPUWriteMemory(address, reg[dest].I);

  3924 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3925 	}

  3926 	break;

  3927 	case 0x720:

  3928 	case 0x728:

  3929 	{

  3930 		// STR Rd, [Rn, -Rm, LSL #]!

  3931 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  3932 		int dest	= (opcode >> 12) & 15;

  3933 		int base	= (opcode >> 16) & 15;

  3934 		u32 address = reg[base].I - offset;

  3935 		reg[base].I = address;

  3936 		CPUWriteMemory(address, reg[dest].I);

  3937 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3938 	}

  3939 	break;

  3940 	case 0x722:

  3941 	case 0x72a:

  3942 	{

  3943 		// STR Rd, [Rn, -Rm, LSR #]!

  3944 		int shift	= (opcode >> 7) & 31;

  3945 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  3946 		int dest	= (opcode >> 12) & 15;

  3947 		int base	= (opcode >> 16) & 15;

  3948 		u32 address = reg[base].I - offset;

  3949 		reg[base].I = address;

  3950 		CPUWriteMemory(address, reg[dest].I);

  3951 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3952 	}

  3953 	break;

  3954 	case 0x724:

  3955 	case 0x72c:

  3956 	{

  3957 		// STR Rd, [Rn, -Rm, ASR #]!

  3958 		int shift = (opcode >> 7) & 31;

  3959 		int offset;

  3960 		if (shift)

  3961 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  3962 		else if (reg[opcode & 15].I & 0x80000000)

  3963 			offset = 0xFFFFFFFF;

  3964 		else

  3965 			offset = 0;

  3966 		int dest	= (opcode >> 12) & 15;

  3967 		int base	= (opcode >> 16) & 15;

  3968 		u32 address = reg[base].I - offset;

  3969 		reg[base].I = address;

  3970 		CPUWriteMemory(address, reg[dest].I);

  3971 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3972 	}

  3973 	break;

  3974 	case 0x726:

  3975 	case 0x72e:

  3976 	{

  3977 		// STR Rd, [Rn, -Rm, ROR #]!

  3978 		int shift = (opcode >> 7) & 31;

  3979 		u32 value = reg[opcode & 15].I;

  3980 		if (shift)

  3981 		{

  3982 			ROR_VALUE;

  3983 		}

  3984 		else

  3985 		{

  3986 			RCR_VALUE;

  3987 		}

  3988 		int dest	= (opcode >> 12) & 15;

  3989 		int base	= (opcode >> 16) & 15;

  3990 		u32 address = reg[base].I - value;

  3991 		reg[base].I = address;

  3992 		CPUWriteMemory(address, reg[dest].I);

  3993 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  3994 	}

  3995 	break;

  3996 	case 0x780:

  3997 	case 0x788:

  3998 	{

  3999 		// STR Rd, [Rn, Rm, LSL #]

  4000 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4001 		int dest	= (opcode >> 12) & 15;

  4002 		int base	= (opcode >> 16) & 15;

  4003 		u32 address = reg[base].I + offset;

  4004 		CPUWriteMemory(address, reg[dest].I);

  4005 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4006 	}

  4007 	break;

  4008 	case 0x782:

  4009 	case 0x78a:

  4010 	{

  4011 		// STR Rd, [Rn, Rm, LSR #]

  4012 		int shift	= (opcode >> 7) & 31;

  4013 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4014 		int dest	= (opcode >> 12) & 15;

  4015 		int base	= (opcode >> 16) & 15;

  4016 		u32 address = reg[base].I + offset;

  4017 		CPUWriteMemory(address, reg[dest].I);

  4018 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4019 	}

  4020 	break;

  4021 	case 0x784:

  4022 	case 0x78c:

  4023 	{

  4024 		// STR Rd, [Rn, Rm, ASR #]

  4025 		int shift = (opcode >> 7) & 31;

  4026 		int offset;

  4027 		if (shift)

  4028 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4029 		else if (reg[opcode & 15].I & 0x80000000)

  4030 			offset = 0xFFFFFFFF;

  4031 		else

  4032 			offset = 0;

  4033 		int dest	= (opcode >> 12) & 15;

  4034 		int base	= (opcode >> 16) & 15;

  4035 		u32 address = reg[base].I + offset;

  4036 		CPUWriteMemory(address, reg[dest].I);

  4037 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4038 	}

  4039 	break;

  4040 	case 0x786:

  4041 	case 0x78e:

  4042 	{

  4043 		// STR Rd, [Rn, Rm, ROR #]

  4044 		int shift = (opcode >> 7) & 31;

  4045 		u32 value = reg[opcode & 15].I;

  4046 		if (shift)

  4047 		{

  4048 			ROR_VALUE;

  4049 		}

  4050 		else

  4051 		{

  4052 			RCR_VALUE;

  4053 		}

  4054 		int dest	= (opcode >> 12) & 15;

  4055 		int base	= (opcode >> 16) & 15;

  4056 		u32 address = reg[base].I + value;

  4057 		CPUWriteMemory(address, reg[dest].I);

  4058 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4059 	}

  4060 	break;

  4061 	case 0x7a0:

  4062 	case 0x7a8:

  4063 	{

  4064 		// STR Rd, [Rn, Rm, LSL #]!

  4065 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4066 		int dest	= (opcode >> 12) & 15;

  4067 		int base	= (opcode >> 16) & 15;

  4068 		u32 address = reg[base].I + offset;

  4069 		reg[base].I = address;

  4070 		CPUWriteMemory(address, reg[dest].I);

  4071 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4072 	}

  4073 	break;

  4074 	case 0x7a2:

  4075 	case 0x7aa:

  4076 	{

  4077 		// STR Rd, [Rn, Rm, LSR #]!

  4078 		int shift	= (opcode >> 7) & 31;

  4079 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4080 		int dest	= (opcode >> 12) & 15;

  4081 		int base	= (opcode >> 16) & 15;

  4082 		u32 address = reg[base].I + offset;

  4083 		reg[base].I = address;

  4084 		CPUWriteMemory(address, reg[dest].I);

  4085 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4086 	}

  4087 	break;

  4088 	case 0x7a4:

  4089 	case 0x7ac:

  4090 	{

  4091 		// STR Rd, [Rn, Rm, ASR #]!

  4092 		int shift = (opcode >> 7) & 31;

  4093 		int offset;

  4094 		if (shift)

  4095 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4096 		else if (reg[opcode & 15].I & 0x80000000)

  4097 			offset = 0xFFFFFFFF;

  4098 		else

  4099 			offset = 0;

  4100 		int dest	= (opcode >> 12) & 15;

  4101 		int base	= (opcode >> 16) & 15;

  4102 		u32 address = reg[base].I + offset;

  4103 		reg[base].I = address;

  4104 		CPUWriteMemory(address, reg[dest].I);

  4105 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4106 	}

  4107 	break;

  4108 	case 0x7a6:

  4109 	case 0x7ae:

  4110 	{

  4111 		// STR Rd, [Rn, Rm, ROR #]!

  4112 		int shift = (opcode >> 7) & 31;

  4113 		u32 value = reg[opcode & 15].I;

  4114 		if (shift)

  4115 		{

  4116 			ROR_VALUE;

  4117 		}

  4118 		else

  4119 		{

  4120 			RCR_VALUE;

  4121 		}

  4122 		int dest	= (opcode >> 12) & 15;

  4123 		int base	= (opcode >> 16) & 15;

  4124 		u32 address = reg[base].I + value;

  4125 		reg[base].I = address;

  4126 		CPUWriteMemory(address, reg[dest].I);

  4127 		clockTicks += 2 + CPUUpdateTicksAccess32(address);

  4128 	}

  4129 	break;

  4130 	case 0x610:

  4131 	case 0x618:

  4132 	// T versions are the same

  4133 	case 0x630:

  4134 	case 0x638:

  4135 	{

  4136 		// LDR Rd, [Rn], -Rm, LSL #

  4137 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4138 		int dest	= (opcode >> 12) & 15;

  4139 		int base	= (opcode >> 16) & 15;

  4140 		u32 address = reg[base].I;

  4141 		reg[dest].I = CPUReadMemory(address);

  4142 		if (dest != base)

  4143 			reg[base].I = address - offset;

  4144 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4145 		if (dest == 15)

  4146 		{

  4147 			clockTicks += 2;

  4148 			reg[15].I  &= 0xFFFFFFFC;

  4149 			armNextPC	= reg[15].I;

  4150 			reg[15].I  += 4;

  4151 		}

  4152 	}

  4153 	break;

  4154 	case 0x612:

  4155 	case 0x61a:

  4156 	// T versions are the same

  4157 	case 0x632:

  4158 	case 0x63a:

  4159 	{

  4160 		// LDR Rd, [Rn], -Rm, LSR #

  4161 		int shift	= (opcode >> 7) & 31;

  4162 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4163 		int dest	= (opcode >> 12) & 15;

  4164 		int base	= (opcode >> 16) & 15;

  4165 		u32 address = reg[base].I;

  4166 		reg[dest].I = CPUReadMemory(address);

  4167 		if (dest != base)

  4168 			reg[base].I = address - offset;

  4169 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4170 		if (dest == 15)

  4171 		{

  4172 			clockTicks += 2;

  4173 			reg[15].I  &= 0xFFFFFFFC;

  4174 			armNextPC	= reg[15].I;

  4175 			reg[15].I  += 4;

  4176 		}

  4177 	}

  4178 	break;

  4179 	case 0x614:

  4180 	case 0x61c:

  4181 	// T versions are the same

  4182 	case 0x634:

  4183 	case 0x63c:

  4184 	{

  4185 		// LDR Rd, [Rn], -Rm, ASR #

  4186 		int shift = (opcode >> 7) & 31;

  4187 		int offset;

  4188 		if (shift)

  4189 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4190 		else if (reg[opcode & 15].I & 0x80000000)

  4191 			offset = 0xFFFFFFFF;

  4192 		else

  4193 			offset = 0;

  4194 		int dest	= (opcode >> 12) & 15;

  4195 		int base	= (opcode >> 16) & 15;

  4196 		u32 address = reg[base].I;

  4197 		reg[dest].I = CPUReadMemory(address);

  4198 		if (dest != base)

  4199 			reg[base].I = address - offset;

  4200 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4201 		if (dest == 15)

  4202 		{

  4203 			clockTicks += 2;

  4204 			reg[15].I  &= 0xFFFFFFFC;

  4205 			armNextPC	= reg[15].I;

  4206 			reg[15].I  += 4;

  4207 		}

  4208 	}

  4209 	break;

  4210 	case 0x616:

  4211 	case 0x61e:

  4212 	// T versions are the same

  4213 	case 0x636:

  4214 	case 0x63e:

  4215 	{

  4216 		// LDR Rd, [Rn], -Rm, ROR #

  4217 		int shift = (opcode >> 7) & 31;

  4218 		u32 value = reg[opcode & 15].I;

  4219 		if (shift)

  4220 		{

  4221 			ROR_VALUE;

  4222 		}

  4223 		else

  4224 		{

  4225 			RCR_VALUE;

  4226 		}

  4227 		int dest	= (opcode >> 12) & 15;

  4228 		int base	= (opcode >> 16) & 15;

  4229 		u32 address = reg[base].I;

  4230 		reg[dest].I = CPUReadMemory(address);

  4231 		if (dest != base)

  4232 			reg[base].I = address - value;

  4233 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4234 		if (dest == 15)

  4235 		{

  4236 			clockTicks += 2;

  4237 			reg[15].I  &= 0xFFFFFFFC;

  4238 			armNextPC	= reg[15].I;

  4239 			reg[15].I  += 4;

  4240 		}

  4241 	}

  4242 	break;

  4243 	case 0x690:

  4244 	case 0x698:

  4245 	// T versions are the same

  4246 	case 0x6b0:

  4247 	case 0x6b8:

  4248 	{

  4249 		// LDR Rd, [Rn], Rm, LSL #

  4250 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4251 		int dest	= (opcode >> 12) & 15;

  4252 		int base	= (opcode >> 16) & 15;

  4253 		u32 address = reg[base].I;

  4254 		reg[dest].I = CPUReadMemory(address);

  4255 		if (dest != base)

  4256 			reg[base].I = address + offset;

  4257 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4258 		if (dest == 15)

  4259 		{

  4260 			clockTicks += 2;

  4261 			reg[15].I  &= 0xFFFFFFFC;

  4262 			armNextPC	= reg[15].I;

  4263 			reg[15].I  += 4;

  4264 		}

  4265 	}

  4266 	break;

  4267 	case 0x692:

  4268 	case 0x69a:

  4269 	// T versions are the same

  4270 	case 0x6b2:

  4271 	case 0x6ba:

  4272 	{

  4273 		// LDR Rd, [Rn], Rm, LSR #

  4274 		int shift	= (opcode >> 7) & 31;

  4275 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4276 		int dest	= (opcode >> 12) & 15;

  4277 		int base	= (opcode >> 16) & 15;

  4278 		u32 address = reg[base].I;

  4279 		reg[dest].I = CPUReadMemory(address);

  4280 		if (dest != base)

  4281 			reg[base].I = address + offset;

  4282 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4283 		if (dest == 15)

  4284 		{

  4285 			clockTicks += 2;

  4286 			reg[15].I  &= 0xFFFFFFFC;

  4287 			armNextPC	= reg[15].I;

  4288 			reg[15].I  += 4;

  4289 		}

  4290 	}

  4291 	break;

  4292 	case 0x694:

  4293 	case 0x69c:

  4294 	// T versions are the same

  4295 	case 0x6b4:

  4296 	case 0x6bc:

  4297 	{

  4298 		// LDR Rd, [Rn], Rm, ASR #

  4299 		int shift = (opcode >> 7) & 31;

  4300 		int offset;

  4301 		if (shift)

  4302 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4303 		else if (reg[opcode & 15].I & 0x80000000)

  4304 			offset = 0xFFFFFFFF;

  4305 		else

  4306 			offset = 0;

  4307 		int dest	= (opcode >> 12) & 15;

  4308 		int base	= (opcode >> 16) & 15;

  4309 		u32 address = reg[base].I;

  4310 		reg[dest].I = CPUReadMemory(address);

  4311 		if (dest != base)

  4312 			reg[base].I = address + offset;

  4313 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4314 		if (dest == 15)

  4315 		{

  4316 			clockTicks += 2;

  4317 			reg[15].I  &= 0xFFFFFFFC;

  4318 			armNextPC	= reg[15].I;

  4319 			reg[15].I  += 4;

  4320 		}

  4321 	}

  4322 	break;

  4323 	case 0x696:

  4324 	case 0x69e:

  4325 	// T versions are the same

  4326 	case 0x6b6:

  4327 	case 0x6be:

  4328 	{

  4329 		// LDR Rd, [Rn], Rm, ROR #

  4330 		int shift = (opcode >> 7) & 31;

  4331 		u32 value = reg[opcode & 15].I;

  4332 		if (shift)

  4333 		{

  4334 			ROR_VALUE;

  4335 		}

  4336 		else

  4337 		{

  4338 			RCR_VALUE;

  4339 		}

  4340 		int dest	= (opcode >> 12) & 15;

  4341 		int base	= (opcode >> 16) & 15;

  4342 		u32 address = reg[base].I;

  4343 		reg[dest].I = CPUReadMemory(address);

  4344 		if (dest != base)

  4345 			reg[base].I = address + value;

  4346 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4347 		if (dest == 15)

  4348 		{

  4349 			clockTicks += 2;

  4350 			reg[15].I  &= 0xFFFFFFFC;

  4351 			armNextPC	= reg[15].I;

  4352 			reg[15].I  += 4;

  4353 		}

  4354 	}

  4355 	break;

  4356 	case 0x710:

  4357 	case 0x718:

  4358 	{

  4359 		// LDR Rd, [Rn, -Rm, LSL #]

  4360 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4361 		int dest	= (opcode >> 12) & 15;

  4362 		int base	= (opcode >> 16) & 15;

  4363 		u32 address = reg[base].I - offset;

  4364 		reg[dest].I = CPUReadMemory(address);

  4365 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4366 		if (dest == 15)

  4367 		{

  4368 			clockTicks += 2;

  4369 			reg[15].I  &= 0xFFFFFFFC;

  4370 			armNextPC	= reg[15].I;

  4371 			reg[15].I  += 4;

  4372 		}

  4373 	}

  4374 	break;

  4375 	case 0x712:

  4376 	case 0x71a:

  4377 	{

  4378 		// LDR Rd, [Rn, -Rm, LSR #]

  4379 		int shift	= (opcode >> 7) & 31;

  4380 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4381 		int dest	= (opcode >> 12) & 15;

  4382 		int base	= (opcode >> 16) & 15;

  4383 		u32 address = reg[base].I - offset;

  4384 		reg[dest].I = CPUReadMemory(address);

  4385 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4386 		if (dest == 15)

  4387 		{

  4388 			clockTicks += 2;

  4389 			reg[15].I  &= 0xFFFFFFFC;

  4390 			armNextPC	= reg[15].I;

  4391 			reg[15].I  += 4;

  4392 		}

  4393 	}

  4394 	break;

  4395 	case 0x714:

  4396 	case 0x71c:

  4397 	{

  4398 		// LDR Rd, [Rn, -Rm, ASR #]

  4399 		int shift = (opcode >> 7) & 31;

  4400 		int offset;

  4401 		if (shift)

  4402 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4403 		else if (reg[opcode & 15].I & 0x80000000)

  4404 			offset = 0xFFFFFFFF;

  4405 		else

  4406 			offset = 0;

  4407 		int dest	= (opcode >> 12) & 15;

  4408 		int base	= (opcode >> 16) & 15;

  4409 		u32 address = reg[base].I - offset;

  4410 		reg[dest].I = CPUReadMemory(address);

  4411 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4412 		if (dest == 15)

  4413 		{

  4414 			clockTicks += 2;

  4415 			reg[15].I  &= 0xFFFFFFFC;

  4416 			armNextPC	= reg[15].I;

  4417 			reg[15].I  += 4;

  4418 		}

  4419 	}

  4420 	break;

  4421 	case 0x716:

  4422 	case 0x71e:

  4423 	{

  4424 		// LDR Rd, [Rn, -Rm, ROR #]

  4425 		int shift = (opcode >> 7) & 31;

  4426 		u32 value = reg[opcode & 15].I;

  4427 		if (shift)

  4428 		{

  4429 			ROR_VALUE;

  4430 		}

  4431 		else

  4432 		{

  4433 			RCR_VALUE;

  4434 		}

  4435 		int dest	= (opcode >> 12) & 15;

  4436 		int base	= (opcode >> 16) & 15;

  4437 		u32 address = reg[base].I - value;

  4438 		reg[dest].I = CPUReadMemory(address);

  4439 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4440 		if (dest == 15)

  4441 		{

  4442 			clockTicks += 2;

  4443 			reg[15].I  &= 0xFFFFFFFC;

  4444 			armNextPC	= reg[15].I;

  4445 			reg[15].I  += 4;

  4446 		}

  4447 	}

  4448 	break;

  4449 	case 0x730:

  4450 	case 0x738:

  4451 	{

  4452 		// LDR Rd, [Rn, -Rm, LSL #]!

  4453 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4454 		int dest	= (opcode >> 12) & 15;

  4455 		int base	= (opcode >> 16) & 15;

  4456 		u32 address = reg[base].I - offset;

  4457 		reg[dest].I = CPUReadMemory(address);

  4458 		if (dest != base)

  4459 			reg[base].I = address;

  4460 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4461 		if (dest == 15)

  4462 		{

  4463 			clockTicks += 2;

  4464 			reg[15].I  &= 0xFFFFFFFC;

  4465 			armNextPC	= reg[15].I;

  4466 			reg[15].I  += 4;

  4467 		}

  4468 	}

  4469 	break;

  4470 	case 0x732:

  4471 	case 0x73a:

  4472 	{

  4473 		// LDR Rd, [Rn, -Rm, LSR #]!

  4474 		int shift	= (opcode >> 7) & 31;

  4475 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4476 		int dest	= (opcode >> 12) & 15;

  4477 		int base	= (opcode >> 16) & 15;

  4478 		u32 address = reg[base].I - offset;

  4479 		reg[dest].I = CPUReadMemory(address);

  4480 		if (dest != base)

  4481 			reg[base].I = address;

  4482 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4483 		if (dest == 15)

  4484 		{

  4485 			clockTicks += 2;

  4486 			reg[15].I  &= 0xFFFFFFFC;

  4487 			armNextPC	= reg[15].I;

  4488 			reg[15].I  += 4;

  4489 		}

  4490 	}

  4491 	break;

  4492 	case 0x734:

  4493 	case 0x73c:

  4494 	{

  4495 		// LDR Rd, [Rn, -Rm, ASR #]!

  4496 		int shift = (opcode >> 7) & 31;

  4497 		int offset;

  4498 		if (shift)

  4499 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4500 		else if (reg[opcode & 15].I & 0x80000000)

  4501 			offset = 0xFFFFFFFF;

  4502 		else

  4503 			offset = 0;

  4504 		int dest	= (opcode >> 12) & 15;

  4505 		int base	= (opcode >> 16) & 15;

  4506 		u32 address = reg[base].I - offset;

  4507 		reg[dest].I = CPUReadMemory(address);

  4508 		if (dest != base)

  4509 			reg[base].I = address;

  4510 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4511 		if (dest == 15)

  4512 		{

  4513 			clockTicks += 2;

  4514 			reg[15].I  &= 0xFFFFFFFC;

  4515 			armNextPC	= reg[15].I;

  4516 			reg[15].I  += 4;

  4517 		}

  4518 	}

  4519 	break;

  4520 	case 0x736:

  4521 	case 0x73e:

  4522 	{

  4523 		// LDR Rd, [Rn, -Rm, ROR #]!

  4524 		int shift = (opcode >> 7) & 31;

  4525 		u32 value = reg[opcode & 15].I;

  4526 		if (shift)

  4527 		{

  4528 			ROR_VALUE;

  4529 		}

  4530 		else

  4531 		{

  4532 			RCR_VALUE;

  4533 		}

  4534 		int dest	= (opcode >> 12) & 15;

  4535 		int base	= (opcode >> 16) & 15;

  4536 		u32 address = reg[base].I - value;

  4537 		reg[dest].I = CPUReadMemory(address);

  4538 		if (dest != base)

  4539 			reg[base].I = address;

  4540 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4541 		if (dest == 15)

  4542 		{

  4543 			clockTicks += 2;

  4544 			reg[15].I  &= 0xFFFFFFFC;

  4545 			armNextPC	= reg[15].I;

  4546 			reg[15].I  += 4;

  4547 		}

  4548 	}

  4549 	break;

  4550 	case 0x790:

  4551 	case 0x798:

  4552 	{

  4553 		// LDR Rd, [Rn, Rm, LSL #]

  4554 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4555 		int dest	= (opcode >> 12) & 15;

  4556 		int base	= (opcode >> 16) & 15;

  4557 		u32 address = reg[base].I + offset;

  4558 		reg[dest].I = CPUReadMemory(address);

  4559 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4560 		if (dest == 15)

  4561 		{

  4562 			clockTicks += 2;

  4563 			reg[15].I  &= 0xFFFFFFFC;

  4564 			armNextPC	= reg[15].I;

  4565 			reg[15].I  += 4;

  4566 		}

  4567 	}

  4568 	break;

  4569 	case 0x792:

  4570 	case 0x79a:

  4571 	{

  4572 		// LDR Rd, [Rn, Rm, LSR #]

  4573 		int shift	= (opcode >> 7) & 31;

  4574 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4575 		int dest	= (opcode >> 12) & 15;

  4576 		int base	= (opcode >> 16) & 15;

  4577 		u32 address = reg[base].I + offset;

  4578 		reg[dest].I = CPUReadMemory(address);

  4579 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4580 		if (dest == 15)

  4581 		{

  4582 			clockTicks += 2;

  4583 			reg[15].I  &= 0xFFFFFFFC;

  4584 			armNextPC	= reg[15].I;

  4585 			reg[15].I  += 4;

  4586 		}

  4587 	}

  4588 	break;

  4589 	case 0x794:

  4590 	case 0x79c:

  4591 	{

  4592 		// LDR Rd, [Rn, Rm, ASR #]

  4593 		int shift = (opcode >> 7) & 31;

  4594 		int offset;

  4595 		if (shift)

  4596 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4597 		else if (reg[opcode & 15].I & 0x80000000)

  4598 			offset = 0xFFFFFFFF;

  4599 		else

  4600 			offset = 0;

  4601 		int dest	= (opcode >> 12) & 15;

  4602 		int base	= (opcode >> 16) & 15;

  4603 		u32 address = reg[base].I + offset;

  4604 		reg[dest].I = CPUReadMemory(address);

  4605 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4606 		if (dest == 15)

  4607 		{

  4608 			clockTicks += 2;

  4609 			reg[15].I  &= 0xFFFFFFFC;

  4610 			armNextPC	= reg[15].I;

  4611 			reg[15].I  += 4;

  4612 		}

  4613 	}

  4614 	break;

  4615 	case 0x796:

  4616 	case 0x79e:

  4617 	{

  4618 		// LDR Rd, [Rn, Rm, ROR #]

  4619 		int shift = (opcode >> 7) & 31;

  4620 		u32 value = reg[opcode & 15].I;

  4621 		if (shift)

  4622 		{

  4623 			ROR_VALUE;

  4624 		}

  4625 		else

  4626 		{

  4627 			RCR_VALUE;

  4628 		}

  4629 		int dest	= (opcode >> 12) & 15;

  4630 		int base	= (opcode >> 16) & 15;

  4631 		u32 address = reg[base].I + value;

  4632 		reg[dest].I = CPUReadMemory(address);

  4633 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4634 		if (dest == 15)

  4635 		{

  4636 			clockTicks += 2;

  4637 			reg[15].I  &= 0xFFFFFFFC;

  4638 			armNextPC	= reg[15].I;

  4639 			reg[15].I  += 4;

  4640 		}

  4641 	}

  4642 	break;

  4643 	case 0x7b0:

  4644 	case 0x7b8:

  4645 	{

  4646 		// LDR Rd, [Rn, Rm, LSL #]!

  4647 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4648 		int dest	= (opcode >> 12) & 15;

  4649 		int base	= (opcode >> 16) & 15;

  4650 		u32 address = reg[base].I + offset;

  4651 		reg[dest].I = CPUReadMemory(address);

  4652 		if (dest != base)

  4653 			reg[base].I = address;

  4654 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4655 		if (dest == 15)

  4656 		{

  4657 			clockTicks += 2;

  4658 			reg[15].I  &= 0xFFFFFFFC;

  4659 			armNextPC	= reg[15].I;

  4660 			reg[15].I  += 4;

  4661 		}

  4662 	}

  4663 	break;

  4664 	case 0x7b2:

  4665 	case 0x7ba:

  4666 	{

  4667 		// LDR Rd, [Rn, Rm, LSR #]!

  4668 		int shift	= (opcode >> 7) & 31;

  4669 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4670 		int dest	= (opcode >> 12) & 15;

  4671 		int base	= (opcode >> 16) & 15;

  4672 		u32 address = reg[base].I + offset;

  4673 		reg[dest].I = CPUReadMemory(address);

  4674 		if (dest != base)

  4675 			reg[base].I = address;

  4676 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4677 		if (dest == 15)

  4678 		{

  4679 			clockTicks += 2;

  4680 			reg[15].I  &= 0xFFFFFFFC;

  4681 			armNextPC	= reg[15].I;

  4682 			reg[15].I  += 4;

  4683 		}

  4684 	}

  4685 	break;

  4686 	case 0x7b4:

  4687 	case 0x7bc:

  4688 	{

  4689 		// LDR Rd, [Rn, Rm, ASR #]!

  4690 		int shift = (opcode >> 7) & 31;

  4691 		int offset;

  4692 		if (shift)

  4693 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4694 		else if (reg[opcode & 15].I & 0x80000000)

  4695 			offset = 0xFFFFFFFF;

  4696 		else

  4697 			offset = 0;

  4698 		int dest	= (opcode >> 12) & 15;

  4699 		int base	= (opcode >> 16) & 15;

  4700 		u32 address = reg[base].I + offset;

  4701 		reg[dest].I = CPUReadMemory(address);

  4702 		if (dest != base)

  4703 			reg[base].I = address;

  4704 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4705 		if (dest == 15)

  4706 		{

  4707 			clockTicks += 2;

  4708 			reg[15].I  &= 0xFFFFFFFC;

  4709 			armNextPC	= reg[15].I;

  4710 			reg[15].I  += 4;

  4711 		}

  4712 	}

  4713 	break;

  4714 	case 0x7b6:

  4715 	case 0x7be:

  4716 	{

  4717 		// LDR Rd, [Rn, Rm, ROR #]!

  4718 		int shift = (opcode >> 7) & 31;

  4719 		u32 value = reg[opcode & 15].I;

  4720 		if (shift)

  4721 		{

  4722 			ROR_VALUE;

  4723 		}

  4724 		else

  4725 		{

  4726 			RCR_VALUE;

  4727 		}

  4728 		int dest	= (opcode >> 12) & 15;

  4729 		int base	= (opcode >> 16) & 15;

  4730 		u32 address = reg[base].I + value;

  4731 		reg[dest].I = CPUReadMemory(address);

  4732 		if (dest != base)

  4733 			reg[base].I = address;

  4734 		clockTicks += 3 + CPUUpdateTicksAccess32(address);

  4735 		if (dest == 15)

  4736 		{

  4737 			clockTicks += 2;

  4738 			reg[15].I  &= 0xFFFFFFFC;

  4739 			armNextPC	= reg[15].I;

  4740 			reg[15].I  += 4;

  4741 		}

  4742 	}

  4743 	break;

  4744 	case 0x640:

  4745 	case 0x648:

  4746 	// T versions are the same

  4747 	case 0x660:

  4748 	case 0x668:

  4749 	{

  4750 		// STRB Rd, [Rn], -Rm, LSL #

  4751 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4752 		int dest	= (opcode >> 12) & 15;

  4753 		int base	= (opcode >> 16) & 15;

  4754 		u32 address = reg[base].I;

  4755 		CPUWriteByte(address, reg[dest].B.B0);

  4756 		reg[base].I = address - offset;

  4757 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4758 	}

  4759 	break;

  4760 	case 0x642:

  4761 	case 0x64a:

  4762 	// T versions are the same

  4763 	case 0x662:

  4764 	case 0x66a:

  4765 	{

  4766 		// STRB Rd, [Rn], -Rm, LSR #

  4767 		int shift	= (opcode >> 7) & 31;

  4768 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4769 		int dest	= (opcode >> 12) & 15;

  4770 		int base	= (opcode >> 16) & 15;

  4771 		u32 address = reg[base].I;

  4772 		CPUWriteByte(address, reg[dest].B.B0);

  4773 		reg[base].I = address - offset;

  4774 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4775 	}

  4776 	break;

  4777 	case 0x644:

  4778 	case 0x64c:

  4779 	// T versions are the same

  4780 	case 0x664:

  4781 	case 0x66c:

  4782 	{

  4783 		// STRB Rd, [Rn], -Rm, ASR #

  4784 		int shift = (opcode >> 7) & 31;

  4785 		int offset;

  4786 		if (shift)

  4787 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4788 		else if (reg[opcode & 15].I & 0x80000000)

  4789 			offset = 0xFFFFFFFF;

  4790 		else

  4791 			offset = 0;

  4792 		int dest	= (opcode >> 12) & 15;

  4793 		int base	= (opcode >> 16) & 15;

  4794 		u32 address = reg[base].I;

  4795 		CPUWriteByte(address, reg[dest].B.B0);

  4796 		reg[base].I = address - offset;

  4797 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4798 	}

  4799 	break;

  4800 	case 0x646:

  4801 	case 0x64e:

  4802 	// T versions are the same

  4803 	case 0x666:

  4804 	case 0x66e:

  4805 	{

  4806 		// STRB Rd, [Rn], -Rm, ROR #

  4807 		int shift = (opcode >> 7) & 31;

  4808 		u32 value = reg[opcode & 15].I;

  4809 		if (shift)

  4810 		{

  4811 			ROR_VALUE;

  4812 		}

  4813 		else

  4814 		{

  4815 			RCR_VALUE;

  4816 		}

  4817 		int dest	= (opcode >> 12) & 15;

  4818 		int base	= (opcode >> 16) & 15;

  4819 		u32 address = reg[base].I;

  4820 		CPUWriteByte(address, reg[dest].B.B0);

  4821 		reg[base].I = address - value;

  4822 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4823 	}

  4824 	break;

  4825 	case 0x6c0:

  4826 	case 0x6c8:

  4827 	// T versions are the same

  4828 	case 0x6e0:

  4829 	case 0x6e8:

  4830 	{

  4831 		// STRB Rd, [Rn], Rm, LSL #

  4832 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4833 		int dest	= (opcode >> 12) & 15;

  4834 		int base	= (opcode >> 16) & 15;

  4835 		u32 address = reg[base].I;

  4836 		CPUWriteByte(address, reg[dest].B.B0);

  4837 		reg[base].I = address + offset;

  4838 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4839 	}

  4840 	break;

  4841 	case 0x6c2:

  4842 	case 0x6ca:

  4843 	// T versions are the same

  4844 	case 0x6e2:

  4845 	case 0x6ea:

  4846 	{

  4847 		// STRB Rd, [Rn], Rm, LSR #

  4848 		int shift	= (opcode >> 7) & 31;

  4849 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4850 		int dest	= (opcode >> 12) & 15;

  4851 		int base	= (opcode >> 16) & 15;

  4852 		u32 address = reg[base].I;

  4853 		CPUWriteByte(address, reg[dest].B.B0);

  4854 		reg[base].I = address + offset;

  4855 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4856 	}

  4857 	break;

  4858 	case 0x6c4:

  4859 	case 0x6cc:

  4860 	// T versions are the same

  4861 	case 0x6e4:

  4862 	case 0x6ec:

  4863 	{

  4864 		// STR Rd, [Rn], Rm, ASR #

  4865 		int shift = (opcode >> 7) & 31;

  4866 		int offset;

  4867 		if (shift)

  4868 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4869 		else if (reg[opcode & 15].I & 0x80000000)

  4870 			offset = 0xFFFFFFFF;

  4871 		else

  4872 			offset = 0;

  4873 		int dest	= (opcode >> 12) & 15;

  4874 		int base	= (opcode >> 16) & 15;

  4875 		u32 address = reg[base].I;

  4876 		CPUWriteByte(address, reg[dest].B.B0);

  4877 		reg[base].I = address + offset;

  4878 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4879 	}

  4880 	break;

  4881 	case 0x6c6:

  4882 	case 0x6ce:

  4883 	// T versions are the same

  4884 	case 0x6e6:

  4885 	case 0x6ee:

  4886 	{

  4887 		// STRB Rd, [Rn], Rm, ROR #

  4888 		int shift = (opcode >> 7) & 31;

  4889 		u32 value = reg[opcode & 15].I;

  4890 		if (shift)

  4891 		{

  4892 			ROR_VALUE;

  4893 		}

  4894 		else

  4895 		{

  4896 			RCR_VALUE;

  4897 		}

  4898 		int dest	= (opcode >> 12) & 15;

  4899 		int base	= (opcode >> 16) & 15;

  4900 		u32 address = reg[base].I;

  4901 		CPUWriteByte(address, reg[dest].B.B0);

  4902 		reg[base].I = address + value;

  4903 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4904 	}

  4905 	break;

  4906 	case 0x740:

  4907 	case 0x748:

  4908 	{

  4909 		// STRB Rd, [Rn, -Rm, LSL #]

  4910 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4911 		int dest	= (opcode >> 12) & 15;

  4912 		int base	= (opcode >> 16) & 15;

  4913 		u32 address = reg[base].I - offset;

  4914 		CPUWriteByte(address, reg[dest].B.B0);

  4915 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4916 	}

  4917 	break;

  4918 	case 0x742:

  4919 	case 0x74a:

  4920 	{

  4921 		// STRB Rd, [Rn, -Rm, LSR #]

  4922 		int shift	= (opcode >> 7) & 31;

  4923 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4924 		int dest	= (opcode >> 12) & 15;

  4925 		int base	= (opcode >> 16) & 15;

  4926 		u32 address = reg[base].I - offset;

  4927 		CPUWriteByte(address, reg[dest].B.B0);

  4928 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4929 	}

  4930 	break;

  4931 	case 0x744:

  4932 	case 0x74c:

  4933 	{

  4934 		// STRB Rd, [Rn, -Rm, ASR #]

  4935 		int shift = (opcode >> 7) & 31;

  4936 		int offset;

  4937 		if (shift)

  4938 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  4939 		else if (reg[opcode & 15].I & 0x80000000)

  4940 			offset = 0xFFFFFFFF;

  4941 		else

  4942 			offset = 0;

  4943 		int dest	= (opcode >> 12) & 15;

  4944 		int base	= (opcode >> 16) & 15;

  4945 		u32 address = reg[base].I - offset;

  4946 		CPUWriteByte(address, reg[dest].B.B0);

  4947 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4948 	}

  4949 	break;

  4950 	case 0x746:

  4951 	case 0x74e:

  4952 	{

  4953 		// STRB Rd, [Rn, -Rm, ROR #]

  4954 		int shift = (opcode >> 7) & 31;

  4955 		u32 value = reg[opcode & 15].I;

  4956 		if (shift)

  4957 		{

  4958 			ROR_VALUE;

  4959 		}

  4960 		else

  4961 		{

  4962 			RCR_VALUE;

  4963 		}

  4964 		int dest	= (opcode >> 12) & 15;

  4965 		int base	= (opcode >> 16) & 15;

  4966 		u32 address = reg[base].I - value;

  4967 		CPUWriteByte(address, reg[dest].B.B0);

  4968 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4969 	}

  4970 	break;

  4971 	case 0x760:

  4972 	case 0x768:

  4973 	{

  4974 		// STRB Rd, [Rn, -Rm, LSL #]!

  4975 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  4976 		int dest	= (opcode >> 12) & 15;

  4977 		int base	= (opcode >> 16) & 15;

  4978 		u32 address = reg[base].I - offset;

  4979 		reg[base].I = address;

  4980 		CPUWriteByte(address, reg[dest].B.B0);

  4981 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4982 	}

  4983 	break;

  4984 	case 0x762:

  4985 	case 0x76a:

  4986 	{

  4987 		// STRB Rd, [Rn, -Rm, LSR #]!

  4988 		int shift	= (opcode >> 7) & 31;

  4989 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  4990 		int dest	= (opcode >> 12) & 15;

  4991 		int base	= (opcode >> 16) & 15;

  4992 		u32 address = reg[base].I - offset;

  4993 		reg[base].I = address;

  4994 		CPUWriteByte(address, reg[dest].B.B0);

  4995 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  4996 	}

  4997 	break;

  4998 	case 0x764:

  4999 	case 0x76c:

  5000 	{

  5001 		// STRB Rd, [Rn, -Rm, ASR #]!

  5002 		int shift = (opcode >> 7) & 31;

  5003 		int offset;

  5004 		if (shift)

  5005 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5006 		else if (reg[opcode & 15].I & 0x80000000)

  5007 			offset = 0xFFFFFFFF;

  5008 		else

  5009 			offset = 0;

  5010 		int dest	= (opcode >> 12) & 15;

  5011 		int base	= (opcode >> 16) & 15;

  5012 		u32 address = reg[base].I - offset;

  5013 		reg[base].I = address;

  5014 		CPUWriteByte(address, reg[dest].B.B0);

  5015 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5016 	}

  5017 	break;

  5018 	case 0x766:

  5019 	case 0x76e:

  5020 	{

  5021 		// STRB Rd, [Rn, -Rm, ROR #]!

  5022 		int shift = (opcode >> 7) & 31;

  5023 		u32 value = reg[opcode & 15].I;

  5024 		if (shift)

  5025 		{

  5026 			ROR_VALUE;

  5027 		}

  5028 		else

  5029 		{

  5030 			RCR_VALUE;

  5031 		}

  5032 		int dest	= (opcode >> 12) & 15;

  5033 		int base	= (opcode >> 16) & 15;

  5034 		u32 address = reg[base].I - value;

  5035 		reg[base].I = address;

  5036 		CPUWriteByte(address, reg[dest].B.B0);

  5037 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5038 	}

  5039 	break;

  5040 	case 0x7c0:

  5041 	case 0x7c8:

  5042 	{

  5043 		// STRB Rd, [Rn, Rm, LSL #]

  5044 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5045 		int dest	= (opcode >> 12) & 15;

  5046 		int base	= (opcode >> 16) & 15;

  5047 		u32 address = reg[base].I + offset;

  5048 		CPUWriteByte(address, reg[dest].B.B0);

  5049 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5050 	}

  5051 	break;

  5052 	case 0x7c2:

  5053 	case 0x7ca:

  5054 	{

  5055 		// STRB Rd, [Rn, Rm, LSR #]

  5056 		int shift	= (opcode >> 7) & 31;

  5057 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5058 		int dest	= (opcode >> 12) & 15;

  5059 		int base	= (opcode >> 16) & 15;

  5060 		u32 address = reg[base].I + offset;

  5061 		CPUWriteByte(address, reg[dest].B.B0);

  5062 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5063 	}

  5064 	break;

  5065 	case 0x7c4:

  5066 	case 0x7cc:

  5067 	{

  5068 		// STRB Rd, [Rn, Rm, ASR #]

  5069 		int shift = (opcode >> 7) & 31;

  5070 		int offset;

  5071 		if (shift)

  5072 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5073 		else if (reg[opcode & 15].I & 0x80000000)

  5074 			offset = 0xFFFFFFFF;

  5075 		else

  5076 			offset = 0;

  5077 		int dest	= (opcode >> 12) & 15;

  5078 		int base	= (opcode >> 16) & 15;

  5079 		u32 address = reg[base].I + offset;

  5080 		CPUWriteByte(address, reg[dest].B.B0);

  5081 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5082 	}

  5083 	break;

  5084 	case 0x7c6:

  5085 	case 0x7ce:

  5086 	{

  5087 		// STRB Rd, [Rn, Rm, ROR #]

  5088 		int shift = (opcode >> 7) & 31;

  5089 		u32 value = reg[opcode & 15].I;

  5090 		if (shift)

  5091 		{

  5092 			ROR_VALUE;

  5093 		}

  5094 		else

  5095 		{

  5096 			RCR_VALUE;

  5097 		}

  5098 		int dest	= (opcode >> 12) & 15;

  5099 		int base	= (opcode >> 16) & 15;

  5100 		u32 address = reg[base].I + value;

  5101 		CPUWriteByte(address, reg[dest].B.B0);

  5102 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5103 	}

  5104 	break;

  5105 	case 0x7e0:

  5106 	case 0x7e8:

  5107 	{

  5108 		// STRB Rd, [Rn, Rm, LSL #]!

  5109 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5110 		int dest	= (opcode >> 12) & 15;

  5111 		int base	= (opcode >> 16) & 15;

  5112 		u32 address = reg[base].I + offset;

  5113 		reg[base].I = address;

  5114 		CPUWriteByte(address, reg[dest].B.B0);

  5115 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5116 	}

  5117 	break;

  5118 	case 0x7e2:

  5119 	case 0x7ea:

  5120 	{

  5121 		// STRB Rd, [Rn, Rm, LSR #]!

  5122 		int shift	= (opcode >> 7) & 31;

  5123 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5124 		int dest	= (opcode >> 12) & 15;

  5125 		int base	= (opcode >> 16) & 15;

  5126 		u32 address = reg[base].I + offset;

  5127 		reg[base].I = address;

  5128 		CPUWriteByte(address, reg[dest].B.B0);

  5129 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5130 	}

  5131 	break;

  5132 	case 0x7e4:

  5133 	case 0x7ec:

  5134 	{

  5135 		// STRB Rd, [Rn, Rm, ASR #]!

  5136 		int shift = (opcode >> 7) & 31;

  5137 		int offset;

  5138 		if (shift)

  5139 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5140 		else if (reg[opcode & 15].I & 0x80000000)

  5141 			offset = 0xFFFFFFFF;

  5142 		else

  5143 			offset = 0;

  5144 		int dest	= (opcode >> 12) & 15;

  5145 		int base	= (opcode >> 16) & 15;

  5146 		u32 address = reg[base].I + offset;

  5147 		reg[base].I = address;

  5148 		CPUWriteByte(address, reg[dest].B.B0);

  5149 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5150 	}

  5151 	break;

  5152 	case 0x7e6:

  5153 	case 0x7ee:

  5154 	{

  5155 		// STRB Rd, [Rn, Rm, ROR #]!

  5156 		int shift = (opcode >> 7) & 31;

  5157 		u32 value = reg[opcode & 15].I;

  5158 		if (shift)

  5159 		{

  5160 			ROR_VALUE;

  5161 		}

  5162 		else

  5163 		{

  5164 			RCR_VALUE;

  5165 		}

  5166 		int dest	= (opcode >> 12) & 15;

  5167 		int base	= (opcode >> 16) & 15;

  5168 		u32 address = reg[base].I + value;

  5169 		reg[base].I = address;

  5170 		CPUWriteByte(address, reg[dest].B.B0);

  5171 		clockTicks += 2 + CPUUpdateTicksAccess16(address);

  5172 	}

  5173 	break;

  5174 	case 0x650:

  5175 	case 0x658:

  5176 	// T versions are the same

  5177 	case 0x670:

  5178 	case 0x678:

  5179 	{

  5180 		// LDRB Rd, [Rn], -Rm, LSL #

  5181 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5182 		int dest	= (opcode >> 12) & 15;

  5183 		int base	= (opcode >> 16) & 15;

  5184 		u32 address = reg[base].I;

  5185 		reg[dest].I = CPUReadByte(address);

  5186 		if (dest != base)

  5187 			reg[base].I = address - offset;

  5188 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5189 	}

  5190 	break;

  5191 	case 0x652:

  5192 	case 0x65a:

  5193 	// T versions are the same

  5194 	case 0x672:

  5195 	case 0x67a:

  5196 	{

  5197 		// LDRB Rd, [Rn], -Rm, LSR #

  5198 		int shift	= (opcode >> 7) & 31;

  5199 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5200 		int dest	= (opcode >> 12) & 15;

  5201 		int base	= (opcode >> 16) & 15;

  5202 		u32 address = reg[base].I;

  5203 		reg[dest].I = CPUReadByte(address);

  5204 		if (dest != base)

  5205 			reg[base].I = address - offset;

  5206 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5207 	}

  5208 	break;

  5209 	case 0x654:

  5210 	case 0x65c:

  5211 	// T versions are the same

  5212 	case 0x674:

  5213 	case 0x67c:

  5214 	{

  5215 		// LDRB Rd, [Rn], -Rm, ASR #

  5216 		int shift = (opcode >> 7) & 31;

  5217 		int offset;

  5218 		if (shift)

  5219 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5220 		else if (reg[opcode & 15].I & 0x80000000)

  5221 			offset = 0xFFFFFFFF;

  5222 		else

  5223 			offset = 0;

  5224 		int dest	= (opcode >> 12) & 15;

  5225 		int base	= (opcode >> 16) & 15;

  5226 		u32 address = reg[base].I;

  5227 		reg[dest].I = CPUReadByte(address);

  5228 		if (dest != base)

  5229 			reg[base].I = address - offset;

  5230 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5231 	}

  5232 	break;

  5233 	case 0x656:

  5234 	case 0x65e:

  5235 	// T versions are the same

  5236 	case 0x676:

  5237 	case 0x67e:

  5238 	{

  5239 		// LDRB Rd, [Rn], -Rm, ROR #

  5240 		int shift = (opcode >> 7) & 31;

  5241 		u32 value = reg[opcode & 15].I;

  5242 		if (shift)

  5243 		{

  5244 			ROR_VALUE;

  5245 		}

  5246 		else

  5247 		{

  5248 			RCR_VALUE;

  5249 		}

  5250 		int dest	= (opcode >> 12) & 15;

  5251 		int base	= (opcode >> 16) & 15;

  5252 		u32 address = reg[base].I;

  5253 		reg[dest].I = CPUReadByte(address);

  5254 		if (dest != base)

  5255 			reg[base].I = address - value;

  5256 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5257 	}

  5258 	break;

  5259 	case 0x6d0:

  5260 	case 0x6d8:

  5261 	// T versions are the same

  5262 	case 0x6f0:

  5263 	case 0x6f8:

  5264 	{

  5265 		// LDRB Rd, [Rn], Rm, LSL #

  5266 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5267 		int dest	= (opcode >> 12) & 15;

  5268 		int base	= (opcode >> 16) & 15;

  5269 		u32 address = reg[base].I;

  5270 		reg[dest].I = CPUReadByte(address);

  5271 		if (dest != base)

  5272 			reg[base].I = address + offset;

  5273 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5274 	}

  5275 	break;

  5276 	case 0x6d2:

  5277 	case 0x6da:

  5278 	// T versions are the same

  5279 	case 0x6f2:

  5280 	case 0x6fa:

  5281 	{

  5282 		// LDRB Rd, [Rn], Rm, LSR #

  5283 		int shift	= (opcode >> 7) & 31;

  5284 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5285 		int dest	= (opcode >> 12) & 15;

  5286 		int base	= (opcode >> 16) & 15;

  5287 		u32 address = reg[base].I;

  5288 		reg[dest].I = CPUReadByte(address);

  5289 		if (dest != base)

  5290 			reg[base].I = address + offset;

  5291 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5292 	}

  5293 	break;

  5294 	case 0x6d4:

  5295 	case 0x6dc:

  5296 	// T versions are the same

  5297 	case 0x6f4:

  5298 	case 0x6fc:

  5299 	{

  5300 		// LDRB Rd, [Rn], Rm, ASR #

  5301 		int shift = (opcode >> 7) & 31;

  5302 		int offset;

  5303 		if (shift)

  5304 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5305 		else if (reg[opcode & 15].I & 0x80000000)

  5306 			offset = 0xFFFFFFFF;

  5307 		else

  5308 			offset = 0;

  5309 		int dest	= (opcode >> 12) & 15;

  5310 		int base	= (opcode >> 16) & 15;

  5311 		u32 address = reg[base].I;

  5312 		reg[dest].I = CPUReadByte(address);

  5313 		if (dest != base)

  5314 			reg[base].I = address + offset;

  5315 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5316 	}

  5317 	break;

  5318 	case 0x6d6:

  5319 	case 0x6de:

  5320 	// T versions are the same

  5321 	case 0x6f6:

  5322 	case 0x6fe:

  5323 	{

  5324 		// LDRB Rd, [Rn], Rm, ROR #

  5325 		int shift = (opcode >> 7) & 31;

  5326 		u32 value = reg[opcode & 15].I;

  5327 		if (shift)

  5328 		{

  5329 			ROR_VALUE;

  5330 		}

  5331 		else

  5332 		{

  5333 			RCR_VALUE;

  5334 		}

  5335 		int dest	= (opcode >> 12) & 15;

  5336 		int base	= (opcode >> 16) & 15;

  5337 		u32 address = reg[base].I;

  5338 		reg[dest].I = CPUReadByte(address);

  5339 		if (dest != base)

  5340 			reg[base].I = address + value;

  5341 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5342 	}

  5343 	break;

  5344 	case 0x750:

  5345 	case 0x758:

  5346 	{

  5347 		// LDRB Rd, [Rn, -Rm, LSL #]

  5348 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5349 		int dest	= (opcode >> 12) & 15;

  5350 		int base	= (opcode >> 16) & 15;

  5351 		u32 address = reg[base].I - offset;

  5352 		reg[dest].I = CPUReadByte(address);

  5353 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5354 	}

  5355 	break;

  5356 	case 0x752:

  5357 	case 0x75a:

  5358 	{

  5359 		// LDRB Rd, [Rn, -Rm, LSR #]

  5360 		int shift	= (opcode >> 7) & 31;

  5361 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5362 		int dest	= (opcode >> 12) & 15;

  5363 		int base	= (opcode >> 16) & 15;

  5364 		u32 address = reg[base].I - offset;

  5365 		reg[dest].I = CPUReadByte(address);

  5366 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5367 	}

  5368 	break;

  5369 	case 0x754:

  5370 	case 0x75c:

  5371 	{

  5372 		// LDRB Rd, [Rn, -Rm, ASR #]

  5373 		int shift = (opcode >> 7) & 31;

  5374 		int offset;

  5375 		if (shift)

  5376 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5377 		else if (reg[opcode & 15].I & 0x80000000)

  5378 			offset = 0xFFFFFFFF;

  5379 		else

  5380 			offset = 0;

  5381 		int dest	= (opcode >> 12) & 15;

  5382 		int base	= (opcode >> 16) & 15;

  5383 		u32 address = reg[base].I - offset;

  5384 		reg[dest].I = CPUReadByte(address);

  5385 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5386 	}

  5387 	break;

  5388 	case 0x756:

  5389 	case 0x75e:

  5390 	{

  5391 		// LDRB Rd, [Rn, -Rm, ROR #]

  5392 		int shift = (opcode >> 7) & 31;

  5393 		u32 value = reg[opcode & 15].I;

  5394 		if (shift)

  5395 		{

  5396 			ROR_VALUE;

  5397 		}

  5398 		else

  5399 		{

  5400 			RCR_VALUE;

  5401 		}

  5402 		int dest	= (opcode >> 12) & 15;

  5403 		int base	= (opcode >> 16) & 15;

  5404 		u32 address = reg[base].I - value;

  5405 		reg[dest].I = CPUReadByte(address);

  5406 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5407 	}

  5408 	break;

  5409 	case 0x770:

  5410 	case 0x778:

  5411 	{

  5412 		// LDRB Rd, [Rn, -Rm, LSL #]!

  5413 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5414 		int dest	= (opcode >> 12) & 15;

  5415 		int base	= (opcode >> 16) & 15;

  5416 		u32 address = reg[base].I - offset;

  5417 		reg[dest].I = CPUReadByte(address);

  5418 		if (dest != base)

  5419 			reg[base].I = address;

  5420 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5421 	}

  5422 	break;

  5423 	case 0x772:

  5424 	case 0x77a:

  5425 	{

  5426 		// LDRB Rd, [Rn, -Rm, LSR #]!

  5427 		int shift	= (opcode >> 7) & 31;

  5428 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5429 		int dest	= (opcode >> 12) & 15;

  5430 		int base	= (opcode >> 16) & 15;

  5431 		u32 address = reg[base].I - offset;

  5432 		reg[dest].I = CPUReadByte(address);

  5433 		if (dest != base)

  5434 			reg[base].I = address;

  5435 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5436 	}

  5437 	break;

  5438 	case 0x774:

  5439 	case 0x77c:

  5440 	{

  5441 		// LDRB Rd, [Rn, -Rm, ASR #]!

  5442 		int shift = (opcode >> 7) & 31;

  5443 		int offset;

  5444 		if (shift)

  5445 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5446 		else if (reg[opcode & 15].I & 0x80000000)

  5447 			offset = 0xFFFFFFFF;

  5448 		else

  5449 			offset = 0;

  5450 		int dest	= (opcode >> 12) & 15;

  5451 		int base	= (opcode >> 16) & 15;

  5452 		u32 address = reg[base].I - offset;

  5453 		reg[dest].I = CPUReadByte(address);

  5454 		if (dest != base)

  5455 			reg[base].I = address;

  5456 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5457 	}

  5458 	break;

  5459 	case 0x776:

  5460 	case 0x77e:

  5461 	{

  5462 		// LDRB Rd, [Rn, -Rm, ROR #]!

  5463 		int shift = (opcode >> 7) & 31;

  5464 		u32 value = reg[opcode & 15].I;

  5465 		if (shift)

  5466 		{

  5467 			ROR_VALUE;

  5468 		}

  5469 		else

  5470 		{

  5471 			RCR_VALUE;

  5472 		}

  5473 		int dest	= (opcode >> 12) & 15;

  5474 		int base	= (opcode >> 16) & 15;

  5475 		u32 address = reg[base].I - value;

  5476 		reg[dest].I = CPUReadByte(address);

  5477 		if (dest != base)

  5478 			reg[base].I = address;

  5479 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5480 	}

  5481 	break;

  5482 	case 0x7d0:

  5483 	case 0x7d8:

  5484 	{

  5485 		// LDRB Rd, [Rn, Rm, LSL #]

  5486 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5487 		int dest	= (opcode >> 12) & 15;

  5488 		int base	= (opcode >> 16) & 15;

  5489 		u32 address = reg[base].I + offset;

  5490 		reg[dest].I = CPUReadByte(address);

  5491 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5492 	}

  5493 	break;

  5494 	case 0x7d2:

  5495 	case 0x7da:

  5496 	{

  5497 		// LDRB Rd, [Rn, Rm, LSR #]

  5498 		int shift	= (opcode >> 7) & 31;

  5499 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5500 		int dest	= (opcode >> 12) & 15;

  5501 		int base	= (opcode >> 16) & 15;

  5502 		u32 address = reg[base].I + offset;

  5503 		reg[dest].I = CPUReadByte(address);

  5504 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5505 	}

  5506 	break;

  5507 	case 0x7d4:

  5508 	case 0x7dc:

  5509 	{

  5510 		// LDRB Rd, [Rn, Rm, ASR #]

  5511 		int shift = (opcode >> 7) & 31;

  5512 		int offset;

  5513 		if (shift)

  5514 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5515 		else if (reg[opcode & 15].I & 0x80000000)

  5516 			offset = 0xFFFFFFFF;

  5517 		else

  5518 			offset = 0;

  5519 		int dest	= (opcode >> 12) & 15;

  5520 		int base	= (opcode >> 16) & 15;

  5521 		u32 address = reg[base].I + offset;

  5522 		reg[dest].I = CPUReadByte(address);

  5523 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5524 	}

  5525 	break;

  5526 	case 0x7d6:

  5527 	case 0x7de:

  5528 	{

  5529 		// LDRB Rd, [Rn, Rm, ROR #]

  5530 		int shift = (opcode >> 7) & 31;

  5531 		u32 value = reg[opcode & 15].I;

  5532 		if (shift)

  5533 		{

  5534 			ROR_VALUE;

  5535 		}

  5536 		else

  5537 		{

  5538 			RCR_VALUE;

  5539 		}

  5540 		int dest	= (opcode >> 12) & 15;

  5541 		int base	= (opcode >> 16) & 15;

  5542 		u32 address = reg[base].I + value;

  5543 		reg[dest].I = CPUReadByte(address);

  5544 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5545 	}

  5546 	break;

  5547 	case 0x7f0:

  5548 	case 0x7f8:

  5549 	{

  5550 		// LDRB Rd, [Rn, Rm, LSL #]!

  5551 		int offset	= reg[opcode & 15].I << ((opcode >> 7) & 31);

  5552 		int dest	= (opcode >> 12) & 15;

  5553 		int base	= (opcode >> 16) & 15;

  5554 		u32 address = reg[base].I + offset;

  5555 		reg[dest].I = CPUReadByte(address);

  5556 		if (dest != base)

  5557 			reg[base].I = address;

  5558 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5559 	}

  5560 	break;

  5561 	case 0x7f2:

  5562 	case 0x7fa:

  5563 	{

  5564 		// LDRB Rd, [Rn, Rm, LSR #]!

  5565 		int shift	= (opcode >> 7) & 31;

  5566 		int offset	= shift ? reg[opcode & 15].I >> shift : 0;

  5567 		int dest	= (opcode >> 12) & 15;

  5568 		int base	= (opcode >> 16) & 15;

  5569 		u32 address = reg[base].I + offset;

  5570 		reg[dest].I = CPUReadByte(address);

  5571 		if (dest != base)

  5572 			reg[base].I = address;

  5573 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5574 	}

  5575 	break;

  5576 	case 0x7f4:

  5577 	case 0x7fc:

  5578 	{

  5579 		// LDRB Rd, [Rn, Rm, ASR #]!

  5580 		int shift = (opcode >> 7) & 31;

  5581 		int offset;

  5582 		if (shift)

  5583 			offset = (int)((s32)reg[opcode & 15].I >> shift);

  5584 		else if (reg[opcode & 15].I & 0x80000000)

  5585 			offset = 0xFFFFFFFF;

  5586 		else

  5587 			offset = 0;

  5588 		int dest	= (opcode >> 12) & 15;

  5589 		int base	= (opcode >> 16) & 15;

  5590 		u32 address = reg[base].I + offset;

  5591 		reg[dest].I = CPUReadByte(address);

  5592 		if (dest != base)

  5593 			reg[base].I = address;

  5594 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5595 	}

  5596 	break;

  5597 	case 0x7f6:

  5598 	case 0x7fe:

  5599 	{

  5600 		// LDRB Rd, [Rn, Rm, ROR #]!

  5601 		int shift = (opcode >> 7) & 31;

  5602 		u32 value = reg[opcode & 15].I;

  5603 		if (shift)

  5604 		{

  5605 			ROR_VALUE;

  5606 		}

  5607 		else

  5608 		{

  5609 			RCR_VALUE;

  5610 		}

  5611 		int dest	= (opcode >> 12) & 15;

  5612 		int base	= (opcode >> 16) & 15;

  5613 		u32 address = reg[base].I + value;

  5614 		reg[dest].I = CPUReadByte(address);

  5615 		if (dest != base)

  5616 			reg[base].I = address;

  5617 		clockTicks += 3 + CPUUpdateTicksAccess16(address);

  5618 	}

  5619 	break;

  5620 #define STMW_REG(val, num) \

  5621 	if (opcode & (val)) { \

  5622 		CPUWriteMemory(address, reg[(num)].I); \

  5623 		if (!offset) { \

  5624 			reg[base].I = temp; \

  5625 			clockTicks += 1 + CPUUpdateTicksAccess32(address); \

  5626 			offset		= 1; \

  5627 		} else { \

  5628 			clockTicks += 1 + CPUUpdateTicksAccessSeq32(address); \

  5629 		} \

  5630 		address += 4; \

  5631 	}

  5632 #define STM_REG(val, num) \

  5633 	if (opcode & (val)) { \

  5634 		CPUWriteMemory(address, reg[(num)].I); \

  5635 		if (!offset) { \

  5636 			clockTicks += 1 + CPUUpdateTicksAccess32(address); \

  5637 			offset		= 1; \

  5638 		} else { \

  5639 			clockTicks += 1 + CPUUpdateTicksAccessSeq32(address); \

  5640 		} \

  5641 		address += 4; \

  5642 	}

  5643 

  5644 		CASE_16(0x800)

  5645 		// STMDA Rn, {Rlist}

  5646 		{

  5647 			int base = (opcode & 0x000F0000) >> 16;

  5648 			u32 temp = reg[base].I -

  5649 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  5650 			u32 address = (temp + 4) & 0xFFFFFFFC;

  5651 			clockTicks += 2;

  5652 			int offset = 0;

  5653 			STM_REG(1, 0);

  5654 			STM_REG(2, 1);

  5655 			STM_REG(4, 2);

  5656 			STM_REG(8, 3);

  5657 			STM_REG(16, 4);

  5658 			STM_REG(32, 5);

  5659 			STM_REG(64, 6);

  5660 			STM_REG(128, 7);

  5661 			STM_REG(256, 8);

  5662 			STM_REG(512, 9);

  5663 			STM_REG(1024, 10);

  5664 			STM_REG(2048, 11);

  5665 			STM_REG(4096, 12);

  5666 			STM_REG(8192, 13);

  5667 			STM_REG(16384, 14);

  5668 			if (opcode & 32768)

  5669 			{

  5670 				CPUWriteMemory(address, reg[15].I + 4);

  5671 				if (!offset)

  5672 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5673 				else

  5674 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5675 			}

  5676 		}

  5677 		break;

  5678 		CASE_16(0x820)

  5679 		{

  5680 			// STMDA Rn!, {Rlist}

  5681 			int base = (opcode & 0x000F0000) >> 16;

  5682 			u32 temp = reg[base].I -

  5683 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  5684 			u32 address = (temp + 4) & 0xFFFFFFFC;

  5685 			clockTicks += 2;

  5686 			int offset = 0;

  5687 

  5688 			STMW_REG(1, 0);

  5689 			STMW_REG(2, 1);

  5690 			STMW_REG(4, 2);

  5691 			STMW_REG(8, 3);

  5692 			STMW_REG(16, 4);

  5693 			STMW_REG(32, 5);

  5694 			STMW_REG(64, 6);

  5695 			STMW_REG(128, 7);

  5696 			STMW_REG(256, 8);

  5697 			STMW_REG(512, 9);

  5698 			STMW_REG(1024, 10);

  5699 			STMW_REG(2048, 11);

  5700 			STMW_REG(4096, 12);

  5701 			STMW_REG(8192, 13);

  5702 			STMW_REG(16384, 14);

  5703 			if (opcode & 32768)

  5704 			{

  5705 				CPUWriteMemory(address, reg[15].I + 4);

  5706 				if (!offset)

  5707 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5708 				else

  5709 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5710 				reg[base].I = temp;

  5711 			}

  5712 		}

  5713 		break;

  5714 		CASE_16(0x840)

  5715 		{

  5716 			// STMDA Rn, {Rlist}^

  5717 			int base = (opcode & 0x000F0000) >> 16;

  5718 			u32 temp = reg[base].I -

  5719 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  5720 			u32 address = (temp + 4) & 0xFFFFFFFC;

  5721 			clockTicks += 2;

  5722 			int offset = 0;

  5723 

  5724 			STM_REG(1, 0);

  5725 			STM_REG(2, 1);

  5726 			STM_REG(4, 2);

  5727 			STM_REG(8, 3);

  5728 			STM_REG(16, 4);

  5729 			STM_REG(32, 5);

  5730 			STM_REG(64, 6);

  5731 			STM_REG(128, 7);

  5732 

  5733 			if (armMode == 0x11)

  5734 			{

  5735 				STM_REG(256, R8_FIQ);

  5736 				STM_REG(512, R9_FIQ);

  5737 				STM_REG(1024, R10_FIQ);

  5738 				STM_REG(2048, R11_FIQ);

  5739 				STM_REG(4096, R12_FIQ);

  5740 			}

  5741 			else

  5742 			{

  5743 				STM_REG(256, 8);

  5744 				STM_REG(512, 9);

  5745 				STM_REG(1024, 10);

  5746 				STM_REG(2048, 11);

  5747 				STM_REG(4096, 12);

  5748 			}

  5749 

  5750 			if (armMode != 0x10 && armMode != 0x1f)

  5751 			{

  5752 				STM_REG(8192, R13_USR);

  5753 				STM_REG(16384, R14_USR);

  5754 			}

  5755 			else

  5756 			{

  5757 				STM_REG(8192, 13);

  5758 				STM_REG(16384, 14);

  5759 			}

  5760 

  5761 			if (opcode & 32768)

  5762 			{

  5763 				CPUWriteMemory(address, reg[15].I + 4);

  5764 				if (!offset)

  5765 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5766 				else

  5767 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5768 			}

  5769 		}

  5770 		break;

  5771 		CASE_16(0x860)

  5772 		{

  5773 			// STMDA Rn!, {Rlist}^

  5774 			int base = (opcode & 0x000F0000) >> 16;

  5775 			u32 temp = reg[base].I -

  5776 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  5777 			u32 address = (temp + 4) & 0xFFFFFFFC;

  5778 			clockTicks += 2;

  5779 			int offset = 0;

  5780 

  5781 			STMW_REG(1, 0);

  5782 			STMW_REG(2, 1);

  5783 			STMW_REG(4, 2);

  5784 			STMW_REG(8, 3);

  5785 			STMW_REG(16, 4);

  5786 			STMW_REG(32, 5);

  5787 			STMW_REG(64, 6);

  5788 			STMW_REG(128, 7);

  5789 

  5790 			if (armMode == 0x11)

  5791 			{

  5792 				STMW_REG(256, R8_FIQ);

  5793 				STMW_REG(512, R9_FIQ);

  5794 				STMW_REG(1024, R10_FIQ);

  5795 				STMW_REG(2048, R11_FIQ);

  5796 				STMW_REG(4096, R12_FIQ);

  5797 			}

  5798 			else

  5799 			{

  5800 				STMW_REG(256, 8);

  5801 				STMW_REG(512, 9);

  5802 				STMW_REG(1024, 10);

  5803 				STMW_REG(2048, 11);

  5804 				STMW_REG(4096, 12);

  5805 			}

  5806 

  5807 			if (armMode != 0x10 && armMode != 0x1f)

  5808 			{

  5809 				STMW_REG(8192, R13_USR);

  5810 				STMW_REG(16384, R14_USR);

  5811 			}

  5812 			else

  5813 			{

  5814 				STMW_REG(8192, 13);

  5815 				STMW_REG(16384, 14);

  5816 			}

  5817 

  5818 			if (opcode & 32768)

  5819 			{

  5820 				CPUWriteMemory(address, reg[15].I + 4);

  5821 				if (!offset)

  5822 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5823 				else

  5824 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5825 				reg[base].I = temp;

  5826 			}

  5827 		}

  5828 		break;

  5829 

  5830 		CASE_16(0x880)

  5831 		{

  5832 			// STMIA Rn, {Rlist}

  5833 			int base	= (opcode & 0x000F0000) >> 16;

  5834 			u32 address = reg[base].I & 0xFFFFFFFC;

  5835 			clockTicks += 2;

  5836 			int offset = 0;

  5837 			STM_REG(1, 0);

  5838 			STM_REG(2, 1);

  5839 			STM_REG(4, 2);

  5840 			STM_REG(8, 3);

  5841 			STM_REG(16, 4);

  5842 			STM_REG(32, 5);

  5843 			STM_REG(64, 6);

  5844 			STM_REG(128, 7);

  5845 			STM_REG(256, 8);

  5846 			STM_REG(512, 9);

  5847 			STM_REG(1024, 10);

  5848 			STM_REG(2048, 11);

  5849 			STM_REG(4096, 12);

  5850 			STM_REG(8192, 13);

  5851 			STM_REG(16384, 14);

  5852 			if (opcode & 32768)

  5853 			{

  5854 				CPUWriteMemory(address, reg[15].I + 4);

  5855 				if (!offset)

  5856 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5857 				else

  5858 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5859 			}

  5860 		}

  5861 		break;

  5862 		CASE_16(0x8a0)

  5863 		{

  5864 			// STMIA Rn!, {Rlist}

  5865 			int base	= (opcode & 0x000F0000) >> 16;

  5866 			u32 address = reg[base].I & 0xFFFFFFFC;

  5867 			clockTicks += 2;

  5868 			int offset = 0;

  5869 			u32 temp   = reg[base].I + 4 * (cpuBitsSet[opcode & 0xFF] +

  5870 			                                cpuBitsSet[(opcode >> 8) & 255]);

  5871 			STMW_REG(1, 0);

  5872 			STMW_REG(2, 1);

  5873 			STMW_REG(4, 2);

  5874 			STMW_REG(8, 3);

  5875 			STMW_REG(16, 4);

  5876 			STMW_REG(32, 5);

  5877 			STMW_REG(64, 6);

  5878 			STMW_REG(128, 7);

  5879 			STMW_REG(256, 8);

  5880 			STMW_REG(512, 9);

  5881 			STMW_REG(1024, 10);

  5882 			STMW_REG(2048, 11);

  5883 			STMW_REG(4096, 12);

  5884 			STMW_REG(8192, 13);

  5885 			STMW_REG(16384, 14);

  5886 			if (opcode & 32768)

  5887 			{

  5888 				CPUWriteMemory(address, reg[15].I + 4);

  5889 				if (!offset)

  5890 				{

  5891 					reg[base].I = temp;

  5892 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5893 				}

  5894 				else

  5895 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5896 			}

  5897 		}

  5898 		break;

  5899 		CASE_16(0x8c0)

  5900 		{

  5901 			// STMIA Rn, {Rlist}^

  5902 			int base	= (opcode & 0x000F0000) >> 16;

  5903 			u32 address = reg[base].I & 0xFFFFFFFC;

  5904 			clockTicks += 2;

  5905 			int offset = 0;

  5906 			STM_REG(1, 0);

  5907 			STM_REG(2, 1);

  5908 			STM_REG(4, 2);

  5909 			STM_REG(8, 3);

  5910 			STM_REG(16, 4);

  5911 			STM_REG(32, 5);

  5912 			STM_REG(64, 6);

  5913 			STM_REG(128, 7);

  5914 			if (armMode == 0x11)

  5915 			{

  5916 				STM_REG(256, R8_FIQ);

  5917 				STM_REG(512, R9_FIQ);

  5918 				STM_REG(1024, R10_FIQ);

  5919 				STM_REG(2048, R11_FIQ);

  5920 				STM_REG(4096, R12_FIQ);

  5921 			}

  5922 			else

  5923 			{

  5924 				STM_REG(256, 8);

  5925 				STM_REG(512, 9);

  5926 				STM_REG(1024, 10);

  5927 				STM_REG(2048, 11);

  5928 				STM_REG(4096, 12);

  5929 			}

  5930 			if (armMode != 0x10 && armMode != 0x1f)

  5931 			{

  5932 				STM_REG(8192, R13_USR);

  5933 				STM_REG(16384, R14_USR);

  5934 			}

  5935 			else

  5936 			{

  5937 				STM_REG(8192, 13);

  5938 				STM_REG(16384, 14);

  5939 			}

  5940 			if (opcode & 32768)

  5941 			{

  5942 				CPUWriteMemory(address, reg[15].I + 4);

  5943 				if (!offset)

  5944 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  5945 				else

  5946 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  5947 			}

  5948 		}

  5949 		break;

  5950 		CASE_16(0x8e0)

  5951 		{

  5952 			// STMIA Rn!, {Rlist}^

  5953 			int base	= (opcode & 0x000F0000) >> 16;

  5954 			u32 address = reg[base].I & 0xFFFFFFFC;

  5955 			clockTicks += 2;

  5956 			int offset = 0;

  5957 			u32 temp   = reg[base].I + 4 * (cpuBitsSet[opcode & 0xFF] +

  5958 			                                cpuBitsSet[(opcode >> 8) & 255]);

  5959 			STMW_REG(1, 0);

  5960 			STMW_REG(2, 1);

  5961 			STMW_REG(4, 2);

  5962 			STMW_REG(8, 3);

  5963 			STMW_REG(16, 4);

  5964 			STMW_REG(32, 5);

  5965 			STMW_REG(64, 6);

  5966 			STMW_REG(128, 7);

  5967 			if (armMode == 0x11)

  5968 			{

  5969 				STMW_REG(256, R8_FIQ);

  5970 				STMW_REG(512, R9_FIQ);

  5971 				STMW_REG(1024, R10_FIQ);

  5972 				STMW_REG(2048, R11_FIQ);

  5973 				STMW_REG(4096, R12_FIQ);

  5974 			}

  5975 			else

  5976 			{

  5977 				STMW_REG(256, 8);

  5978 				STMW_REG(512, 9);

  5979 				STMW_REG(1024, 10);

  5980 				STMW_REG(2048, 11);

  5981 				STMW_REG(4096, 12);

  5982 			}

  5983 			if (armMode != 0x10 && armMode != 0x1f)

  5984 			{

  5985 				STMW_REG(8192, R13_USR);

  5986 				STMW_REG(16384, R14_USR);

  5987 			}

  5988 			else

  5989 			{

  5990 				STMW_REG(8192, 13);

  5991 				STMW_REG(16384, 14);

  5992 			}

  5993 			if (opcode & 32768)

  5994 			{

  5995 				CPUWriteMemory(address, reg[15].I + 4);

  5996 				if (!offset)

  5997 				{

  5998 					reg[base].I = temp;

  5999 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6000 				}

  6001 				else

  6002 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6003 			}

  6004 		}

  6005 		break;

  6006 

  6007 		CASE_16(0x900)

  6008 		{

  6009 			// STMDB Rn, {Rlist}

  6010 			int base = (opcode & 0x000F0000) >> 16;

  6011 			u32 temp = reg[base].I -

  6012 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6013 			u32 address = temp & 0xFFFFFFFC;

  6014 			clockTicks += 2;

  6015 			int offset = 0;

  6016 			STM_REG(1, 0);

  6017 			STM_REG(2, 1);

  6018 			STM_REG(4, 2);

  6019 			STM_REG(8, 3);

  6020 			STM_REG(16, 4);

  6021 			STM_REG(32, 5);

  6022 			STM_REG(64, 6);

  6023 			STM_REG(128, 7);

  6024 			STM_REG(256, 8);

  6025 			STM_REG(512, 9);

  6026 			STM_REG(1024, 10);

  6027 			STM_REG(2048, 11);

  6028 			STM_REG(4096, 12);

  6029 			STM_REG(8192, 13);

  6030 			STM_REG(16384, 14);

  6031 			if (opcode & 32768)

  6032 			{

  6033 				CPUWriteMemory(address, reg[15].I + 4);

  6034 				if (!offset)

  6035 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6036 				else

  6037 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6038 			}

  6039 		}

  6040 		break;

  6041 		CASE_16(0x920)

  6042 		{

  6043 			// STMDB Rn!, {Rlist}

  6044 			int base = (opcode & 0x000F0000) >> 16;

  6045 			u32 temp = reg[base].I -

  6046 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6047 			u32 address = temp & 0xFFFFFFFC;

  6048 			clockTicks += 2;

  6049 			int offset = 0;

  6050 

  6051 			STMW_REG(1, 0);

  6052 			STMW_REG(2, 1);

  6053 			STMW_REG(4, 2);

  6054 			STMW_REG(8, 3);

  6055 			STMW_REG(16, 4);

  6056 			STMW_REG(32, 5);

  6057 			STMW_REG(64, 6);

  6058 			STMW_REG(128, 7);

  6059 			STMW_REG(256, 8);

  6060 			STMW_REG(512, 9);

  6061 			STMW_REG(1024, 10);

  6062 			STMW_REG(2048, 11);

  6063 			STMW_REG(4096, 12);

  6064 			STMW_REG(8192, 13);

  6065 			STMW_REG(16384, 14);

  6066 			if (opcode & 32768)

  6067 			{

  6068 				CPUWriteMemory(address, reg[15].I + 4);

  6069 				if (!offset)

  6070 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6071 				else

  6072 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6073 				reg[base].I = temp;

  6074 			}

  6075 		}

  6076 		break;

  6077 		CASE_16(0x940)

  6078 		{

  6079 			// STMDB Rn, {Rlist}^

  6080 			int base = (opcode & 0x000F0000) >> 16;

  6081 			u32 temp = reg[base].I -

  6082 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6083 			u32 address = temp & 0xFFFFFFFC;

  6084 			clockTicks += 2;

  6085 			int offset = 0;

  6086 

  6087 			STM_REG(1, 0);

  6088 			STM_REG(2, 1);

  6089 			STM_REG(4, 2);

  6090 			STM_REG(8, 3);

  6091 			STM_REG(16, 4);

  6092 			STM_REG(32, 5);

  6093 			STM_REG(64, 6);

  6094 			STM_REG(128, 7);

  6095 

  6096 			if (armMode == 0x11)

  6097 			{

  6098 				STM_REG(256, R8_FIQ);

  6099 				STM_REG(512, R9_FIQ);

  6100 				STM_REG(1024, R10_FIQ);

  6101 				STM_REG(2048, R11_FIQ);

  6102 				STM_REG(4096, R12_FIQ);

  6103 			}

  6104 			else

  6105 			{

  6106 				STM_REG(256, 8);

  6107 				STM_REG(512, 9);

  6108 				STM_REG(1024, 10);

  6109 				STM_REG(2048, 11);

  6110 				STM_REG(4096, 12);

  6111 			}

  6112 

  6113 			if (armMode != 0x10 && armMode != 0x1f)

  6114 			{

  6115 				STM_REG(8192, R13_USR);

  6116 				STM_REG(16384, R14_USR);

  6117 			}

  6118 			else

  6119 			{

  6120 				STM_REG(8192, 13);

  6121 				STM_REG(16384, 14);

  6122 			}

  6123 

  6124 			if (opcode & 32768)

  6125 			{

  6126 				CPUWriteMemory(address, reg[15].I + 4);

  6127 				if (!offset)

  6128 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6129 				else

  6130 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6131 			}

  6132 		}

  6133 		break;

  6134 		CASE_16(0x960)

  6135 		{

  6136 			// STMDB Rn!, {Rlist}^

  6137 			int base = (opcode & 0x000F0000) >> 16;

  6138 			u32 temp = reg[base].I -

  6139 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6140 			u32 address = temp & 0xFFFFFFFC;

  6141 			clockTicks += 2;

  6142 			int offset = 0;

  6143 

  6144 			STMW_REG(1, 0);

  6145 			STMW_REG(2, 1);

  6146 			STMW_REG(4, 2);

  6147 			STMW_REG(8, 3);

  6148 			STMW_REG(16, 4);

  6149 			STMW_REG(32, 5);

  6150 			STMW_REG(64, 6);

  6151 			STMW_REG(128, 7);

  6152 

  6153 			if (armMode == 0x11)

  6154 			{

  6155 				STMW_REG(256, R8_FIQ);

  6156 				STMW_REG(512, R9_FIQ);

  6157 				STMW_REG(1024, R10_FIQ);

  6158 				STMW_REG(2048, R11_FIQ);

  6159 				STMW_REG(4096, R12_FIQ);

  6160 			}

  6161 			else

  6162 			{

  6163 				STMW_REG(256, 8);

  6164 				STMW_REG(512, 9);

  6165 				STMW_REG(1024, 10);

  6166 				STMW_REG(2048, 11);

  6167 				STMW_REG(4096, 12);

  6168 			}

  6169 

  6170 			if (armMode != 0x10 && armMode != 0x1f)

  6171 			{

  6172 				STMW_REG(8192, R13_USR);

  6173 				STMW_REG(16384, R14_USR);

  6174 			}

  6175 			else

  6176 			{

  6177 				STMW_REG(8192, 13);

  6178 				STMW_REG(16384, 14);

  6179 			}

  6180 

  6181 			if (opcode & 32768)

  6182 			{

  6183 				CPUWriteMemory(address, reg[15].I + 4);

  6184 				if (!offset)

  6185 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6186 				else

  6187 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6188 				reg[base].I = temp;

  6189 			}

  6190 		}

  6191 		break;

  6192 

  6193 		CASE_16(0x980)

  6194 		// STMIB Rn, {Rlist}

  6195 		{

  6196 			int base	= (opcode & 0x000F0000) >> 16;

  6197 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  6198 			clockTicks += 2;

  6199 			int offset = 0;

  6200 			STM_REG(1, 0);

  6201 			STM_REG(2, 1);

  6202 			STM_REG(4, 2);

  6203 			STM_REG(8, 3);

  6204 			STM_REG(16, 4);

  6205 			STM_REG(32, 5);

  6206 			STM_REG(64, 6);

  6207 			STM_REG(128, 7);

  6208 			STM_REG(256, 8);

  6209 			STM_REG(512, 9);

  6210 			STM_REG(1024, 10);

  6211 			STM_REG(2048, 11);

  6212 			STM_REG(4096, 12);

  6213 			STM_REG(8192, 13);

  6214 			STM_REG(16384, 14);

  6215 			if (opcode & 32768)

  6216 			{

  6217 				CPUWriteMemory(address, reg[15].I + 4);

  6218 				if (!offset)

  6219 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6220 				else

  6221 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6222 			}

  6223 		}

  6224 		break;

  6225 		CASE_16(0x9a0)

  6226 		{

  6227 			// STMIB Rn!, {Rlist}

  6228 			int base	= (opcode & 0x000F0000) >> 16;

  6229 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  6230 			clockTicks += 2;

  6231 			int offset = 0;

  6232 			u32 temp   = reg[base].I + 4 * (cpuBitsSet[opcode & 0xFF] +

  6233 			                                cpuBitsSet[(opcode >> 8) & 255]);

  6234 			STMW_REG(1, 0);

  6235 			STMW_REG(2, 1);

  6236 			STMW_REG(4, 2);

  6237 			STMW_REG(8, 3);

  6238 			STMW_REG(16, 4);

  6239 			STMW_REG(32, 5);

  6240 			STMW_REG(64, 6);

  6241 			STMW_REG(128, 7);

  6242 			STMW_REG(256, 8);

  6243 			STMW_REG(512, 9);

  6244 			STMW_REG(1024, 10);

  6245 			STMW_REG(2048, 11);

  6246 			STMW_REG(4096, 12);

  6247 			STMW_REG(8192, 13);

  6248 			STMW_REG(16384, 14);

  6249 			if (opcode & 32768)

  6250 			{

  6251 				CPUWriteMemory(address, reg[15].I + 4);

  6252 				if (!offset)

  6253 				{

  6254 					reg[base].I = temp;

  6255 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6256 				}

  6257 				else

  6258 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6259 			}

  6260 		}

  6261 		break;

  6262 		CASE_16(0x9c0)

  6263 		{

  6264 			// STMIB Rn, {Rlist}^

  6265 			int base	= (opcode & 0x000F0000) >> 16;

  6266 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  6267 			clockTicks += 2;

  6268 			int offset = 0;

  6269 			STM_REG(1, 0);

  6270 			STM_REG(2, 1);

  6271 			STM_REG(4, 2);

  6272 			STM_REG(8, 3);

  6273 			STM_REG(16, 4);

  6274 			STM_REG(32, 5);

  6275 			STM_REG(64, 6);

  6276 			STM_REG(128, 7);

  6277 			if (armMode == 0x11)

  6278 			{

  6279 				STM_REG(256, R8_FIQ);

  6280 				STM_REG(512, R9_FIQ);

  6281 				STM_REG(1024, R10_FIQ);

  6282 				STM_REG(2048, R11_FIQ);

  6283 				STM_REG(4096, R12_FIQ);

  6284 			}

  6285 			else

  6286 			{

  6287 				STM_REG(256, 8);

  6288 				STM_REG(512, 9);

  6289 				STM_REG(1024, 10);

  6290 				STM_REG(2048, 11);

  6291 				STM_REG(4096, 12);

  6292 			}

  6293 			if (armMode != 0x10 && armMode != 0x1f)

  6294 			{

  6295 				STM_REG(8192, R13_USR);

  6296 				STM_REG(16384, R14_USR);

  6297 			}

  6298 			else

  6299 			{

  6300 				STM_REG(8192, 13);

  6301 				STM_REG(16384, 14);

  6302 			}

  6303 			if (opcode & 32768)

  6304 			{

  6305 				CPUWriteMemory(address, reg[15].I + 4);

  6306 				if (!offset)

  6307 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6308 				else

  6309 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6310 			}

  6311 		}

  6312 		break;

  6313 		CASE_16(0x9e0)

  6314 		{

  6315 			// STMIB Rn!, {Rlist}^

  6316 			int base	= (opcode & 0x000F0000) >> 16;

  6317 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  6318 			clockTicks += 2;

  6319 			int offset = 0;

  6320 			u32 temp   = reg[base].I + 4 * (cpuBitsSet[opcode & 0xFF] +

  6321 			                                cpuBitsSet[(opcode >> 8) & 255]);

  6322 			STMW_REG(1, 0);

  6323 			STMW_REG(2, 1);

  6324 			STMW_REG(4, 2);

  6325 			STMW_REG(8, 3);

  6326 			STMW_REG(16, 4);

  6327 			STMW_REG(32, 5);

  6328 			STMW_REG(64, 6);

  6329 			STMW_REG(128, 7);

  6330 			if (armMode == 0x11)

  6331 			{

  6332 				STMW_REG(256, R8_FIQ);

  6333 				STMW_REG(512, R9_FIQ);

  6334 				STMW_REG(1024, R10_FIQ);

  6335 				STMW_REG(2048, R11_FIQ);

  6336 				STMW_REG(4096, R12_FIQ);

  6337 			}

  6338 			else

  6339 			{

  6340 				STMW_REG(256, 8);

  6341 				STMW_REG(512, 9);

  6342 				STMW_REG(1024, 10);

  6343 				STMW_REG(2048, 11);

  6344 				STMW_REG(4096, 12);

  6345 			}

  6346 			if (armMode != 0x10 && armMode != 0x1f)

  6347 			{

  6348 				STMW_REG(8192, R13_USR);

  6349 				STMW_REG(16384, R14_USR);

  6350 			}

  6351 			else

  6352 			{

  6353 				STMW_REG(8192, 13);

  6354 				STMW_REG(16384, 14);

  6355 			}

  6356 			if (opcode & 32768)

  6357 			{

  6358 				CPUWriteMemory(address, reg[15].I + 4);

  6359 				if (!offset)

  6360 				{

  6361 					reg[base].I = temp;

  6362 					clockTicks += 1 + CPUUpdateTicksAccess32(address);

  6363 				}

  6364 				else

  6365 					clockTicks += 1 + CPUUpdateTicksAccessSeq32(address);

  6366 			}

  6367 		}

  6368 		break;

  6369 

  6370 #define LDM_REG(val, num) \

  6371 	if (opcode & (val)) { \

  6372 		reg[(num)].I = CPUReadMemory(address); \

  6373 		if (offset) \

  6374 			clockTicks += 1 + CPUUpdateTicksAccessSeq32(address); \

  6375 		else { \

  6376 			clockTicks += 1 + CPUUpdateTicksAccess32(address); \

  6377 			offset		= 1; \

  6378 		} \

  6379 		address += 4; \

  6380 	}

  6381 

  6382 		CASE_16(0x810)

  6383 		{

  6384 			// LDMDA Rn, {Rlist}

  6385 			int base = (opcode & 0x000F0000) >> 16;

  6386 			u32 temp = reg[base].I -

  6387 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6388 			u32 address = (temp + 4) & 0xFFFFFFFC;

  6389 			clockTicks += 2;

  6390 			int offset = 0;

  6391 			LDM_REG(1, 0);

  6392 			LDM_REG(2, 1);

  6393 			LDM_REG(4, 2);

  6394 			LDM_REG(8, 3);

  6395 			LDM_REG(16, 4);

  6396 			LDM_REG(32, 5);

  6397 			LDM_REG(64, 6);

  6398 			LDM_REG(128, 7);

  6399 			LDM_REG(256, 8);

  6400 			LDM_REG(512, 9);

  6401 			LDM_REG(1024, 10);

  6402 			LDM_REG(2048, 11);

  6403 			LDM_REG(4096, 12);

  6404 			LDM_REG(8192, 13);

  6405 			LDM_REG(16384, 14);

  6406 			if (opcode & 32768)

  6407 			{

  6408 				reg[15].I = CPUReadMemory(address);

  6409 				if (!offset)

  6410 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6411 				else

  6412 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6413 				armNextPC  = reg[15].I;

  6414 				reg[15].I += 4;

  6415 			}

  6416 		}

  6417 		break;

  6418 		CASE_16(0x830)

  6419 		{

  6420 			// LDMDA Rn!, {Rlist}

  6421 			int base = (opcode & 0x000F0000) >> 16;

  6422 			u32 temp = reg[base].I -

  6423 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6424 			u32 address = (temp + 4) & 0xFFFFFFFC;

  6425 			clockTicks += 2;

  6426 			int offset = 0;

  6427 			LDM_REG(1, 0);

  6428 			LDM_REG(2, 1);

  6429 			LDM_REG(4, 2);

  6430 			LDM_REG(8, 3);

  6431 			LDM_REG(16, 4);

  6432 			LDM_REG(32, 5);

  6433 			LDM_REG(64, 6);

  6434 			LDM_REG(128, 7);

  6435 			LDM_REG(256, 8);

  6436 			LDM_REG(512, 9);

  6437 			LDM_REG(1024, 10);

  6438 			LDM_REG(2048, 11);

  6439 			LDM_REG(4096, 12);

  6440 			LDM_REG(8192, 13);

  6441 			LDM_REG(16384, 14);

  6442 			if (opcode & 32768)

  6443 			{

  6444 				reg[15].I = CPUReadMemory(address);

  6445 				if (!offset)

  6446 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6447 				else

  6448 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6449 				armNextPC  = reg[15].I;

  6450 				reg[15].I += 4;

  6451 			}

  6452 			if (!(opcode & (1 << base)))

  6453 				reg[base].I = temp;

  6454 		}

  6455 		break;

  6456 		CASE_16(0x850)

  6457 		{

  6458 			// LDMDA Rn, {Rlist}^

  6459 			int base = (opcode & 0x000F0000) >> 16;

  6460 			u32 temp = reg[base].I -

  6461 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6462 			u32 address = (temp + 4) & 0xFFFFFFFC;

  6463 			clockTicks += 2;

  6464 			int offset = 0;

  6465 			if (opcode & 0x8000)

  6466 			{

  6467 				LDM_REG(1, 0);

  6468 				LDM_REG(2, 1);

  6469 				LDM_REG(4, 2);

  6470 				LDM_REG(8, 3);

  6471 				LDM_REG(16, 4);

  6472 				LDM_REG(32, 5);

  6473 				LDM_REG(64, 6);

  6474 				LDM_REG(128, 7);

  6475 				LDM_REG(256, 8);

  6476 				LDM_REG(512, 9);

  6477 				LDM_REG(1024, 10);

  6478 				LDM_REG(2048, 11);

  6479 				LDM_REG(4096, 12);

  6480 				LDM_REG(8192, 13);

  6481 				LDM_REG(16384, 14);

  6482 

  6483 				reg[15].I = CPUReadMemory(address);

  6484 				if (!offset)

  6485 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6486 				else

  6487 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6488 

  6489 				CPUSwitchMode(reg[17].I & 0x1f, false);

  6490 				if (armState)

  6491 				{

  6492 					armNextPC = reg[15].I & 0xFFFFFFFC;

  6493 					reg[15].I = armNextPC + 4;

  6494 				}

  6495 				else

  6496 				{

  6497 					armNextPC = reg[15].I & 0xFFFFFFFE;

  6498 					reg[15].I = armNextPC + 2;

  6499 				}

  6500 			}

  6501 			else

  6502 			{

  6503 				LDM_REG(1, 0);

  6504 				LDM_REG(2, 1);

  6505 				LDM_REG(4, 2);

  6506 				LDM_REG(8, 3);

  6507 				LDM_REG(16, 4);

  6508 				LDM_REG(32, 5);

  6509 				LDM_REG(64, 6);

  6510 				LDM_REG(128, 7);

  6511 

  6512 				if (armMode == 0x11)

  6513 				{

  6514 					LDM_REG(256, R8_FIQ);

  6515 					LDM_REG(512, R9_FIQ);

  6516 					LDM_REG(1024, R10_FIQ);

  6517 					LDM_REG(2048, R11_FIQ);

  6518 					LDM_REG(4096, R12_FIQ);

  6519 				}

  6520 				else

  6521 				{

  6522 					LDM_REG(256, 8);

  6523 					LDM_REG(512, 9);

  6524 					LDM_REG(1024, 10);

  6525 					LDM_REG(2048, 11);

  6526 					LDM_REG(4096, 12);

  6527 				}

  6528 

  6529 				if (armMode != 0x10 && armMode != 0x1f)

  6530 				{

  6531 					LDM_REG(8192, R13_USR);

  6532 					LDM_REG(16384, R14_USR);

  6533 				}

  6534 				else

  6535 				{

  6536 					LDM_REG(8192, 13);

  6537 					LDM_REG(16384, 14);

  6538 				}

  6539 			}

  6540 		}

  6541 		break;

  6542 		CASE_16(0x870)

  6543 		{

  6544 			// LDMDA Rn!, {Rlist}^

  6545 			int base = (opcode & 0x000F0000) >> 16;

  6546 			u32 temp = reg[base].I -

  6547 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6548 			u32 address = (temp + 4) & 0xFFFFFFFC;

  6549 			clockTicks += 2;

  6550 			int offset = 0;

  6551 			if (opcode & 0x8000)

  6552 			{

  6553 				LDM_REG(1, 0);

  6554 				LDM_REG(2, 1);

  6555 				LDM_REG(4, 2);

  6556 				LDM_REG(8, 3);

  6557 				LDM_REG(16, 4);

  6558 				LDM_REG(32, 5);

  6559 				LDM_REG(64, 6);

  6560 				LDM_REG(128, 7);

  6561 				LDM_REG(256, 8);

  6562 				LDM_REG(512, 9);

  6563 				LDM_REG(1024, 10);

  6564 				LDM_REG(2048, 11);

  6565 				LDM_REG(4096, 12);

  6566 				LDM_REG(8192, 13);

  6567 				LDM_REG(16384, 14);

  6568 

  6569 				reg[15].I = CPUReadMemory(address);

  6570 				if (!offset)

  6571 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6572 				else

  6573 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6574 

  6575 				if (!(opcode & (1 << base)))

  6576 					reg[base].I = temp;

  6577 

  6578 				CPUSwitchMode(reg[17].I & 0x1f, false);

  6579 				if (armState)

  6580 				{

  6581 					armNextPC = reg[15].I & 0xFFFFFFFC;

  6582 					reg[15].I = armNextPC + 4;

  6583 				}

  6584 				else

  6585 				{

  6586 					armNextPC = reg[15].I & 0xFFFFFFFE;

  6587 					reg[15].I = armNextPC + 2;

  6588 				}

  6589 			}

  6590 			else

  6591 			{

  6592 				LDM_REG(1, 0);

  6593 				LDM_REG(2, 1);

  6594 				LDM_REG(4, 2);

  6595 				LDM_REG(8, 3);

  6596 				LDM_REG(16, 4);

  6597 				LDM_REG(32, 5);

  6598 				LDM_REG(64, 6);

  6599 				LDM_REG(128, 7);

  6600 

  6601 				if (armMode == 0x11)

  6602 				{

  6603 					LDM_REG(256, R8_FIQ);

  6604 					LDM_REG(512, R9_FIQ);

  6605 					LDM_REG(1024, R10_FIQ);

  6606 					LDM_REG(2048, R11_FIQ);

  6607 					LDM_REG(4096, R12_FIQ);

  6608 				}

  6609 				else

  6610 				{

  6611 					LDM_REG(256, 8);

  6612 					LDM_REG(512, 9);

  6613 					LDM_REG(1024, 10);

  6614 					LDM_REG(2048, 11);

  6615 					LDM_REG(4096, 12);

  6616 				}

  6617 

  6618 				if (armMode != 0x10 && armMode != 0x1f)

  6619 				{

  6620 					LDM_REG(8192, R13_USR);

  6621 					LDM_REG(16384, R14_USR);

  6622 				}

  6623 				else

  6624 				{

  6625 					LDM_REG(8192, 13);

  6626 					LDM_REG(16384, 14);

  6627 				}

  6628 

  6629 				if (!(opcode & (1 << base)))

  6630 					reg[base].I = temp;

  6631 			}

  6632 		}

  6633 		break;

  6634 

  6635 		CASE_16(0x890)

  6636 		{

  6637 			// LDMIA Rn, {Rlist}

  6638 			int base	= (opcode & 0x000F0000) >> 16;

  6639 			u32 address = reg[base].I & 0xFFFFFFFC;

  6640 			clockTicks += 2;

  6641 			int offset = 0;

  6642 			LDM_REG(1, 0);

  6643 			LDM_REG(2, 1);

  6644 			LDM_REG(4, 2);

  6645 			LDM_REG(8, 3);

  6646 			LDM_REG(16, 4);

  6647 			LDM_REG(32, 5);

  6648 			LDM_REG(64, 6);

  6649 			LDM_REG(128, 7);

  6650 			LDM_REG(256, 8);

  6651 			LDM_REG(512, 9);

  6652 			LDM_REG(1024, 10);

  6653 			LDM_REG(2048, 11);

  6654 			LDM_REG(4096, 12);

  6655 			LDM_REG(8192, 13);

  6656 			LDM_REG(16384, 14);

  6657 			if (opcode & 32768)

  6658 			{

  6659 				reg[15].I = CPUReadMemory(address);

  6660 				if (!offset)

  6661 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6662 				else

  6663 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6664 				armNextPC  = reg[15].I;

  6665 				reg[15].I += 4;

  6666 			}

  6667 		}

  6668 		break;

  6669 		CASE_16(0x8b0)

  6670 		{

  6671 			// LDMIA Rn!, {Rlist}

  6672 			int base = (opcode & 0x000F0000) >> 16;

  6673 			u32 temp = reg[base].I +

  6674 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6675 			u32 address = reg[base].I & 0xFFFFFFFC;

  6676 			clockTicks += 2;

  6677 			int offset = 0;

  6678 			LDM_REG(1, 0);

  6679 			LDM_REG(2, 1);

  6680 			LDM_REG(4, 2);

  6681 			LDM_REG(8, 3);

  6682 			LDM_REG(16, 4);

  6683 			LDM_REG(32, 5);

  6684 			LDM_REG(64, 6);

  6685 			LDM_REG(128, 7);

  6686 			LDM_REG(256, 8);

  6687 			LDM_REG(512, 9);

  6688 			LDM_REG(1024, 10);

  6689 			LDM_REG(2048, 11);

  6690 			LDM_REG(4096, 12);

  6691 			LDM_REG(8192, 13);

  6692 			LDM_REG(16384, 14);

  6693 			if (opcode & 32768)

  6694 			{

  6695 				reg[15].I = CPUReadMemory(address);

  6696 				if (!offset)

  6697 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6698 				else

  6699 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6700 				armNextPC  = reg[15].I;

  6701 				reg[15].I += 4;

  6702 			}

  6703 			if (!(opcode & (1 << base)))

  6704 				reg[base].I = temp;

  6705 		}

  6706 		break;

  6707 		CASE_16(0x8d0)

  6708 		{

  6709 			// LDMIA Rn, {Rlist}^

  6710 			int base	= (opcode & 0x000F0000) >> 16;

  6711 			u32 address = reg[base].I & 0xFFFFFFFC;

  6712 			clockTicks += 2;

  6713 			int offset = 0;

  6714 			if (opcode & 0x8000)

  6715 			{

  6716 				LDM_REG(1, 0);

  6717 				LDM_REG(2, 1);

  6718 				LDM_REG(4, 2);

  6719 				LDM_REG(8, 3);

  6720 				LDM_REG(16, 4);

  6721 				LDM_REG(32, 5);

  6722 				LDM_REG(64, 6);

  6723 				LDM_REG(128, 7);

  6724 				LDM_REG(256, 8);

  6725 				LDM_REG(512, 9);

  6726 				LDM_REG(1024, 10);

  6727 				LDM_REG(2048, 11);

  6728 				LDM_REG(4096, 12);

  6729 				LDM_REG(8192, 13);

  6730 				LDM_REG(16384, 14);

  6731 

  6732 				reg[15].I = CPUReadMemory(address);

  6733 				if (!offset)

  6734 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6735 				else

  6736 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6737 

  6738 				CPUSwitchMode(reg[17].I & 0x1f, false);

  6739 				if (armState)

  6740 				{

  6741 					armNextPC = reg[15].I & 0xFFFFFFFC;

  6742 					reg[15].I = armNextPC + 4;

  6743 				}

  6744 				else

  6745 				{

  6746 					armNextPC = reg[15].I & 0xFFFFFFFE;

  6747 					reg[15].I = armNextPC + 2;

  6748 				}

  6749 			}

  6750 			else

  6751 			{

  6752 				LDM_REG(1, 0);

  6753 				LDM_REG(2, 1);

  6754 				LDM_REG(4, 2);

  6755 				LDM_REG(8, 3);

  6756 				LDM_REG(16, 4);

  6757 				LDM_REG(32, 5);

  6758 				LDM_REG(64, 6);

  6759 				LDM_REG(128, 7);

  6760 

  6761 				if (armMode == 0x11)

  6762 				{

  6763 					LDM_REG(256, R8_FIQ);

  6764 					LDM_REG(512, R9_FIQ);

  6765 					LDM_REG(1024, R10_FIQ);

  6766 					LDM_REG(2048, R11_FIQ);

  6767 					LDM_REG(4096, R12_FIQ);

  6768 				}

  6769 				else

  6770 				{

  6771 					LDM_REG(256, 8);

  6772 					LDM_REG(512, 9);

  6773 					LDM_REG(1024, 10);

  6774 					LDM_REG(2048, 11);

  6775 					LDM_REG(4096, 12);

  6776 				}

  6777 

  6778 				if (armMode != 0x10 && armMode != 0x1f)

  6779 				{

  6780 					LDM_REG(8192, R13_USR);

  6781 					LDM_REG(16384, R14_USR);

  6782 				}

  6783 				else

  6784 				{

  6785 					LDM_REG(8192, 13);

  6786 					LDM_REG(16384, 14);

  6787 				}

  6788 			}

  6789 		}

  6790 		break;

  6791 		CASE_16(0x8f0)

  6792 		{

  6793 			// LDMIA Rn!, {Rlist}^

  6794 			int base = (opcode & 0x000F0000) >> 16;

  6795 			u32 temp = reg[base].I +

  6796 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6797 			u32 address = reg[base].I & 0xFFFFFFFC;

  6798 			clockTicks += 2;

  6799 			int offset = 0;

  6800 			if (opcode & 0x8000)

  6801 			{

  6802 				LDM_REG(1, 0);

  6803 				LDM_REG(2, 1);

  6804 				LDM_REG(4, 2);

  6805 				LDM_REG(8, 3);

  6806 				LDM_REG(16, 4);

  6807 				LDM_REG(32, 5);

  6808 				LDM_REG(64, 6);

  6809 				LDM_REG(128, 7);

  6810 				LDM_REG(256, 8);

  6811 				LDM_REG(512, 9);

  6812 				LDM_REG(1024, 10);

  6813 				LDM_REG(2048, 11);

  6814 				LDM_REG(4096, 12);

  6815 				LDM_REG(8192, 13);

  6816 				LDM_REG(16384, 14);

  6817 

  6818 				reg[15].I = CPUReadMemory(address);

  6819 				if (!offset)

  6820 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6821 				else

  6822 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6823 

  6824 				if (!(opcode & (1 << base)))

  6825 					reg[base].I = temp;

  6826 

  6827 				CPUSwitchMode(reg[17].I & 0x1f, false);

  6828 				if (armState)

  6829 				{

  6830 					armNextPC = reg[15].I & 0xFFFFFFFC;

  6831 					reg[15].I = armNextPC + 4;

  6832 				}

  6833 				else

  6834 				{

  6835 					armNextPC = reg[15].I & 0xFFFFFFFE;

  6836 					reg[15].I = armNextPC + 2;

  6837 				}

  6838 			}

  6839 			else

  6840 			{

  6841 				LDM_REG(1, 0);

  6842 				LDM_REG(2, 1);

  6843 				LDM_REG(4, 2);

  6844 				LDM_REG(8, 3);

  6845 				LDM_REG(16, 4);

  6846 				LDM_REG(32, 5);

  6847 				LDM_REG(64, 6);

  6848 				LDM_REG(128, 7);

  6849 

  6850 				if (armMode == 0x11)

  6851 				{

  6852 					LDM_REG(256, R8_FIQ);

  6853 					LDM_REG(512, R9_FIQ);

  6854 					LDM_REG(1024, R10_FIQ);

  6855 					LDM_REG(2048, R11_FIQ);

  6856 					LDM_REG(4096, R12_FIQ);

  6857 				}

  6858 				else

  6859 				{

  6860 					LDM_REG(256, 8);

  6861 					LDM_REG(512, 9);

  6862 					LDM_REG(1024, 10);

  6863 					LDM_REG(2048, 11);

  6864 					LDM_REG(4096, 12);

  6865 				}

  6866 

  6867 				if (armMode != 0x10 && armMode != 0x1f)

  6868 				{

  6869 					LDM_REG(8192, R13_USR);

  6870 					LDM_REG(16384, R14_USR);

  6871 				}

  6872 				else

  6873 				{

  6874 					LDM_REG(8192, 13);

  6875 					LDM_REG(16384, 14);

  6876 				}

  6877 

  6878 				if (!(opcode & (1 << base)))

  6879 					reg[base].I = temp;

  6880 			}

  6881 		}

  6882 		break;

  6883 

  6884 		CASE_16(0x910)

  6885 		{

  6886 			// LDMDB Rn, {Rlist}

  6887 			int base = (opcode & 0x000F0000) >> 16;

  6888 			u32 temp = reg[base].I -

  6889 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6890 			u32 address = temp & 0xFFFFFFFC;

  6891 			clockTicks += 2;

  6892 			int offset = 0;

  6893 			LDM_REG(1, 0);

  6894 			LDM_REG(2, 1);

  6895 			LDM_REG(4, 2);

  6896 			LDM_REG(8, 3);

  6897 			LDM_REG(16, 4);

  6898 			LDM_REG(32, 5);

  6899 			LDM_REG(64, 6);

  6900 			LDM_REG(128, 7);

  6901 			LDM_REG(256, 8);

  6902 			LDM_REG(512, 9);

  6903 			LDM_REG(1024, 10);

  6904 			LDM_REG(2048, 11);

  6905 			LDM_REG(4096, 12);

  6906 			LDM_REG(8192, 13);

  6907 			LDM_REG(16384, 14);

  6908 			if (opcode & 32768)

  6909 			{

  6910 				reg[15].I = CPUReadMemory(address);

  6911 				if (!offset)

  6912 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6913 				else

  6914 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6915 				armNextPC  = reg[15].I;

  6916 				reg[15].I += 4;

  6917 			}

  6918 		}

  6919 		break;

  6920 		CASE_16(0x930)

  6921 		{

  6922 			// LDMDB Rn!, {Rlist}

  6923 			int base = (opcode & 0x000F0000) >> 16;

  6924 			u32 temp = reg[base].I -

  6925 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6926 			u32 address = temp & 0xFFFFFFFC;

  6927 			clockTicks += 2;

  6928 			int offset = 0;

  6929 			LDM_REG(1, 0);

  6930 			LDM_REG(2, 1);

  6931 			LDM_REG(4, 2);

  6932 			LDM_REG(8, 3);

  6933 			LDM_REG(16, 4);

  6934 			LDM_REG(32, 5);

  6935 			LDM_REG(64, 6);

  6936 			LDM_REG(128, 7);

  6937 			LDM_REG(256, 8);

  6938 			LDM_REG(512, 9);

  6939 			LDM_REG(1024, 10);

  6940 			LDM_REG(2048, 11);

  6941 			LDM_REG(4096, 12);

  6942 			LDM_REG(8192, 13);

  6943 			LDM_REG(16384, 14);

  6944 			if (opcode & 32768)

  6945 			{

  6946 				reg[15].I = CPUReadMemory(address);

  6947 				if (!offset)

  6948 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6949 				else

  6950 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6951 				armNextPC  = reg[15].I;

  6952 				reg[15].I += 4;

  6953 			}

  6954 			if (!(opcode & (1 << base)))

  6955 				reg[base].I = temp;

  6956 		}

  6957 		break;

  6958 		CASE_16(0x950)

  6959 		{

  6960 			// LDMDB Rn, {Rlist}^

  6961 			int base = (opcode & 0x000F0000) >> 16;

  6962 			u32 temp = reg[base].I -

  6963 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  6964 			u32 address = temp & 0xFFFFFFFC;

  6965 			clockTicks += 2;

  6966 			int offset = 0;

  6967 			if (opcode & 0x8000)

  6968 			{

  6969 				LDM_REG(1, 0);

  6970 				LDM_REG(2, 1);

  6971 				LDM_REG(4, 2);

  6972 				LDM_REG(8, 3);

  6973 				LDM_REG(16, 4);

  6974 				LDM_REG(32, 5);

  6975 				LDM_REG(64, 6);

  6976 				LDM_REG(128, 7);

  6977 				LDM_REG(256, 8);

  6978 				LDM_REG(512, 9);

  6979 				LDM_REG(1024, 10);

  6980 				LDM_REG(2048, 11);

  6981 				LDM_REG(4096, 12);

  6982 				LDM_REG(8192, 13);

  6983 				LDM_REG(16384, 14);

  6984 

  6985 				reg[15].I = CPUReadMemory(address);

  6986 				if (!offset)

  6987 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  6988 				else

  6989 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  6990 

  6991 				CPUSwitchMode(reg[17].I & 0x1f, false);

  6992 				if (armState)

  6993 				{

  6994 					armNextPC = reg[15].I & 0xFFFFFFFC;

  6995 					reg[15].I = armNextPC + 4;

  6996 				}

  6997 				else

  6998 				{

  6999 					armNextPC = reg[15].I & 0xFFFFFFFE;

  7000 					reg[15].I = armNextPC + 2;

  7001 				}

  7002 			}

  7003 			else

  7004 			{

  7005 				LDM_REG(1, 0);

  7006 				LDM_REG(2, 1);

  7007 				LDM_REG(4, 2);

  7008 				LDM_REG(8, 3);

  7009 				LDM_REG(16, 4);

  7010 				LDM_REG(32, 5);

  7011 				LDM_REG(64, 6);

  7012 				LDM_REG(128, 7);

  7013 

  7014 				if (armMode == 0x11)

  7015 				{

  7016 					LDM_REG(256, R8_FIQ);

  7017 					LDM_REG(512, R9_FIQ);

  7018 					LDM_REG(1024, R10_FIQ);

  7019 					LDM_REG(2048, R11_FIQ);

  7020 					LDM_REG(4096, R12_FIQ);

  7021 				}

  7022 				else

  7023 				{

  7024 					LDM_REG(256, 8);

  7025 					LDM_REG(512, 9);

  7026 					LDM_REG(1024, 10);

  7027 					LDM_REG(2048, 11);

  7028 					LDM_REG(4096, 12);

  7029 				}

  7030 

  7031 				if (armMode != 0x10 && armMode != 0x1f)

  7032 				{

  7033 					LDM_REG(8192, R13_USR);

  7034 					LDM_REG(16384, R14_USR);

  7035 				}

  7036 				else

  7037 				{

  7038 					LDM_REG(8192, 13);

  7039 					LDM_REG(16384, 14);

  7040 				}

  7041 			}

  7042 		}

  7043 		break;

  7044 		CASE_16(0x970)

  7045 		{

  7046 			// LDMDB Rn!, {Rlist}^

  7047 			int base = (opcode & 0x000F0000) >> 16;

  7048 			u32 temp = reg[base].I -

  7049 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  7050 			u32 address = temp & 0xFFFFFFFC;

  7051 			clockTicks += 2;

  7052 			int offset = 0;

  7053 			if (opcode & 0x8000)

  7054 			{

  7055 				LDM_REG(1, 0);

  7056 				LDM_REG(2, 1);

  7057 				LDM_REG(4, 2);

  7058 				LDM_REG(8, 3);

  7059 				LDM_REG(16, 4);

  7060 				LDM_REG(32, 5);

  7061 				LDM_REG(64, 6);

  7062 				LDM_REG(128, 7);

  7063 				LDM_REG(256, 8);

  7064 				LDM_REG(512, 9);

  7065 				LDM_REG(1024, 10);

  7066 				LDM_REG(2048, 11);

  7067 				LDM_REG(4096, 12);

  7068 				LDM_REG(8192, 13);

  7069 				LDM_REG(16384, 14);

  7070 

  7071 				reg[15].I = CPUReadMemory(address);

  7072 				if (!offset)

  7073 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  7074 				else

  7075 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  7076 

  7077 				if (!(opcode & (1 << base)))

  7078 					reg[base].I = temp;

  7079 

  7080 				CPUSwitchMode(reg[17].I & 0x1f, false);

  7081 				if (armState)

  7082 				{

  7083 					armNextPC = reg[15].I & 0xFFFFFFFC;

  7084 					reg[15].I = armNextPC + 4;

  7085 				}

  7086 				else

  7087 				{

  7088 					armNextPC = reg[15].I & 0xFFFFFFFE;

  7089 					reg[15].I = armNextPC + 2;

  7090 				}

  7091 			}

  7092 			else

  7093 			{

  7094 				LDM_REG(1, 0);

  7095 				LDM_REG(2, 1);

  7096 				LDM_REG(4, 2);

  7097 				LDM_REG(8, 3);

  7098 				LDM_REG(16, 4);

  7099 				LDM_REG(32, 5);

  7100 				LDM_REG(64, 6);

  7101 				LDM_REG(128, 7);

  7102 

  7103 				if (armMode == 0x11)

  7104 				{

  7105 					LDM_REG(256, R8_FIQ);

  7106 					LDM_REG(512, R9_FIQ);

  7107 					LDM_REG(1024, R10_FIQ);

  7108 					LDM_REG(2048, R11_FIQ);

  7109 					LDM_REG(4096, R12_FIQ);

  7110 				}

  7111 				else

  7112 				{

  7113 					LDM_REG(256, 8);

  7114 					LDM_REG(512, 9);

  7115 					LDM_REG(1024, 10);

  7116 					LDM_REG(2048, 11);

  7117 					LDM_REG(4096, 12);

  7118 				}

  7119 

  7120 				if (armMode != 0x10 && armMode != 0x1f)

  7121 				{

  7122 					LDM_REG(8192, R13_USR);

  7123 					LDM_REG(16384, R14_USR);

  7124 				}

  7125 				else

  7126 				{

  7127 					LDM_REG(8192, 13);

  7128 					LDM_REG(16384, 14);

  7129 				}

  7130 

  7131 				if (!(opcode & (1 << base)))

  7132 					reg[base].I = temp;

  7133 			}

  7134 		}

  7135 		break;

  7136 

  7137 		CASE_16(0x990)

  7138 		{

  7139 			// LDMIB Rn, {Rlist}

  7140 			int base	= (opcode & 0x000F0000) >> 16;

  7141 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  7142 			clockTicks += 2;

  7143 			int offset = 0;

  7144 			LDM_REG(1, 0);

  7145 			LDM_REG(2, 1);

  7146 			LDM_REG(4, 2);

  7147 			LDM_REG(8, 3);

  7148 			LDM_REG(16, 4);

  7149 			LDM_REG(32, 5);

  7150 			LDM_REG(64, 6);

  7151 			LDM_REG(128, 7);

  7152 			LDM_REG(256, 8);

  7153 			LDM_REG(512, 9);

  7154 			LDM_REG(1024, 10);

  7155 			LDM_REG(2048, 11);

  7156 			LDM_REG(4096, 12);

  7157 			LDM_REG(8192, 13);

  7158 			LDM_REG(16384, 14);

  7159 			if (opcode & 32768)

  7160 			{

  7161 				reg[15].I = CPUReadMemory(address);

  7162 				if (!offset)

  7163 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  7164 				else

  7165 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  7166 				armNextPC  = reg[15].I;

  7167 				reg[15].I += 4;

  7168 			}

  7169 		}

  7170 		break;

  7171 		CASE_16(0x9b0)

  7172 		{

  7173 			// LDMIB Rn!, {Rlist}

  7174 			int base = (opcode & 0x000F0000) >> 16;

  7175 			u32 temp = reg[base].I +

  7176 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  7177 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  7178 			clockTicks += 2;

  7179 			int offset = 0;

  7180 			LDM_REG(1, 0);

  7181 			LDM_REG(2, 1);

  7182 			LDM_REG(4, 2);

  7183 			LDM_REG(8, 3);

  7184 			LDM_REG(16, 4);

  7185 			LDM_REG(32, 5);

  7186 			LDM_REG(64, 6);

  7187 			LDM_REG(128, 7);

  7188 			LDM_REG(256, 8);

  7189 			LDM_REG(512, 9);

  7190 			LDM_REG(1024, 10);

  7191 			LDM_REG(2048, 11);

  7192 			LDM_REG(4096, 12);

  7193 			LDM_REG(8192, 13);

  7194 			LDM_REG(16384, 14);

  7195 			if (opcode & 32768)

  7196 			{

  7197 				reg[15].I = CPUReadMemory(address);

  7198 				if (!offset)

  7199 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  7200 				else

  7201 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  7202 				armNextPC  = reg[15].I;

  7203 				reg[15].I += 4;

  7204 			}

  7205 			if (!(opcode & (1 << base)))

  7206 				reg[base].I = temp;

  7207 		}

  7208 		break;

  7209 		CASE_16(0x9d0)

  7210 		{

  7211 			// LDMIB Rn, {Rlist}^

  7212 			int base	= (opcode & 0x000F0000) >> 16;

  7213 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  7214 			clockTicks += 2;

  7215 			int offset = 0;

  7216 			if (opcode & 0x8000)

  7217 			{

  7218 				LDM_REG(1, 0);

  7219 				LDM_REG(2, 1);

  7220 				LDM_REG(4, 2);

  7221 				LDM_REG(8, 3);

  7222 				LDM_REG(16, 4);

  7223 				LDM_REG(32, 5);

  7224 				LDM_REG(64, 6);

  7225 				LDM_REG(128, 7);

  7226 				LDM_REG(256, 8);

  7227 				LDM_REG(512, 9);

  7228 				LDM_REG(1024, 10);

  7229 				LDM_REG(2048, 11);

  7230 				LDM_REG(4096, 12);

  7231 				LDM_REG(8192, 13);

  7232 				LDM_REG(16384, 14);

  7233 

  7234 				reg[15].I = CPUReadMemory(address);

  7235 				if (!offset)

  7236 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  7237 				else

  7238 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  7239 

  7240 				CPUSwitchMode(reg[17].I & 0x1f, false);

  7241 				if (armState)

  7242 				{

  7243 					armNextPC = reg[15].I & 0xFFFFFFFC;

  7244 					reg[15].I = armNextPC + 4;

  7245 				}

  7246 				else

  7247 				{

  7248 					armNextPC = reg[15].I & 0xFFFFFFFE;

  7249 					reg[15].I = armNextPC + 2;

  7250 				}

  7251 			}

  7252 			else

  7253 			{

  7254 				LDM_REG(1, 0);

  7255 				LDM_REG(2, 1);

  7256 				LDM_REG(4, 2);

  7257 				LDM_REG(8, 3);

  7258 				LDM_REG(16, 4);

  7259 				LDM_REG(32, 5);

  7260 				LDM_REG(64, 6);

  7261 				LDM_REG(128, 7);

  7262 

  7263 				if (armMode == 0x11)

  7264 				{

  7265 					LDM_REG(256, R8_FIQ);

  7266 					LDM_REG(512, R9_FIQ);

  7267 					LDM_REG(1024, R10_FIQ);

  7268 					LDM_REG(2048, R11_FIQ);

  7269 					LDM_REG(4096, R12_FIQ);

  7270 				}

  7271 				else

  7272 				{

  7273 					LDM_REG(256, 8);

  7274 					LDM_REG(512, 9);

  7275 					LDM_REG(1024, 10);

  7276 					LDM_REG(2048, 11);

  7277 					LDM_REG(4096, 12);

  7278 				}

  7279 

  7280 				if (armMode != 0x10 && armMode != 0x1f)

  7281 				{

  7282 					LDM_REG(8192, R13_USR);

  7283 					LDM_REG(16384, R14_USR);

  7284 				}

  7285 				else

  7286 				{

  7287 					LDM_REG(8192, 13);

  7288 					LDM_REG(16384, 14);

  7289 				}

  7290 			}

  7291 		}

  7292 		break;

  7293 		CASE_16(0x9f0)

  7294 		{

  7295 			// LDMIB Rn!, {Rlist}^

  7296 			int base = (opcode & 0x000F0000) >> 16;

  7297 			u32 temp = reg[base].I +

  7298 			           4 * (cpuBitsSet[opcode & 255] + cpuBitsSet[(opcode >> 8) & 255]);

  7299 			u32 address = (reg[base].I + 4) & 0xFFFFFFFC;

  7300 			clockTicks += 2;

  7301 			int offset = 0;

  7302 			if (opcode & 0x8000)

  7303 			{

  7304 				LDM_REG(1, 0);

  7305 				LDM_REG(2, 1);

  7306 				LDM_REG(4, 2);

  7307 				LDM_REG(8, 3);

  7308 				LDM_REG(16, 4);

  7309 				LDM_REG(32, 5);

  7310 				LDM_REG(64, 6);

  7311 				LDM_REG(128, 7);

  7312 				LDM_REG(256, 8);

  7313 				LDM_REG(512, 9);

  7314 				LDM_REG(1024, 10);

  7315 				LDM_REG(2048, 11);

  7316 				LDM_REG(4096, 12);

  7317 				LDM_REG(8192, 13);

  7318 				LDM_REG(16384, 14);

  7319 

  7320 				reg[15].I = CPUReadMemory(address);

  7321 				if (!offset)

  7322 					clockTicks += 2 + CPUUpdateTicksAccess32(address);

  7323 				else

  7324 					clockTicks += 2 + CPUUpdateTicksAccessSeq32(address);

  7325 

  7326 				if (!(opcode & (1 << base)))

  7327 					reg[base].I = temp;

  7328 

  7329 				CPUSwitchMode(reg[17].I & 0x1f, false);

  7330 				if (armState)

  7331 				{

  7332 					armNextPC = reg[15].I & 0xFFFFFFFC;

  7333 					reg[15].I = armNextPC + 4;

  7334 				}

  7335 				else

  7336 				{

  7337 					armNextPC = reg[15].I & 0xFFFFFFFE;

  7338 					reg[15].I = armNextPC + 2;

  7339 				}

  7340 			}

  7341 			else

  7342 			{

  7343 				LDM_REG(1, 0);

  7344 				LDM_REG(2, 1);

  7345 				LDM_REG(4, 2);

  7346 				LDM_REG(8, 3);

  7347 				LDM_REG(16, 4);

  7348 				LDM_REG(32, 5);

  7349 				LDM_REG(64, 6);

  7350 				LDM_REG(128, 7);

  7351 

  7352 				if (armMode == 0x11)

  7353 				{

  7354 					LDM_REG(256, R8_FIQ);

  7355 					LDM_REG(512, R9_FIQ);

  7356 					LDM_REG(1024, R10_FIQ);

  7357 					LDM_REG(2048, R11_FIQ);

  7358 					LDM_REG(4096, R12_FIQ);

  7359 				}

  7360 				else

  7361 				{

  7362 					LDM_REG(256, 8);

  7363 					LDM_REG(512, 9);

  7364 					LDM_REG(1024, 10);

  7365 					LDM_REG(2048, 11);

  7366 					LDM_REG(4096, 12);

  7367 				}

  7368 

  7369 				if (armMode != 0x10 && armMode != 0x1f)

  7370 				{

  7371 					LDM_REG(8192, R13_USR);

  7372 					LDM_REG(16384, R14_USR);

  7373 				}

  7374 				else

  7375 				{

  7376 					LDM_REG(8192, 13);

  7377 					LDM_REG(16384, 14);

  7378 				}

  7379 

  7380 				if (!(opcode & (1 << base)))

  7381 					reg[base].I = temp;

  7382 			}

  7383 		}

  7384 		break;

  7385 		CASE_256(0xa00)

  7386 		{

  7387 			// B <offset>

  7388 			clockTicks += 3;

  7389 			int offset = opcode & 0x00FFFFFF;

  7390 			if (offset & 0x00800000)

  7391 			{

  7392 				offset |= 0xFF000000;

  7393 			}

  7394 			offset	 <<= 2;

  7395 			reg[15].I += offset;

  7396 			armNextPC  = reg[15].I;

  7397 			reg[15].I += 4;

  7398 		}

  7399 		break;

  7400 		CASE_256(0xb00)

  7401 		{

  7402 			// BL <offset>

  7403 			clockTicks += 3;

  7404 			int offset = opcode & 0x00FFFFFF;

  7405 			if (offset & 0x00800000)

  7406 			{

  7407 				offset |= 0xFF000000;

  7408 			}

  7409 			offset	 <<= 2;

  7410 			reg[14].I  = reg[15].I - 4;

  7411 			reg[15].I += offset;

  7412 			armNextPC  = reg[15].I;

  7413 			reg[15].I += 4;

  7414 		}

  7415 		break;

  7416 		CASE_256(0xf00)

  7417 		// SWI <comment>

  7418 		clockTicks += 3;

  7419 		CPUSoftwareInterrupt(opcode & 0x00FFFFFF);

  7420 		break;

  7421 #ifdef GP_SUPPORT

  7422 	case 0xe11:

  7423 	case 0xe13:

  7424 	case 0xe15:

  7425 	case 0xe17:

  7426 	case 0xe19:

  7427 	case 0xe1b:

  7428 	case 0xe1d:

  7429 	case 0xe1f:

  7430 		// MRC

  7431 		break;

  7432 	case 0xe01:

  7433 	case 0xe03:

  7434 	case 0xe05:

  7435 	case 0xe07:

  7436 	case 0xe09:

  7437 	case 0xe0b:

  7438 	case 0xe0d:

  7439 	case 0xe0f:

  7440 		// MRC

  7441 		break;

  7442 #endif

  7443 	default:

  7444 #ifdef GBA_LOGGING

  7445 		if (systemVerbose & VERBOSE_UNDEFINED)

  7446 			log("Undefined ARM instruction %08x at %08x\n", opcode,

  7447 			    armNextPC - 4);

  7448 #endif

  7449 		CPUUndefinedException();

  7450 		break;

  7451 		// END

  7452 	}

  7453 }
author	Robert McIntyre <rlm@mit.edu>
date	Sun, 04 Mar 2012 14:33:52 -0600
parents	f9f4f1b99eed
children