Mercurial > vba-clojure

     1 #ifdef C_CORE

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

    18 #define ADD_RD_RS_RN \

    19 	{ \

    20 		u32 lhs = reg[source].I; \

    21 		u32 rhs = value; \

    22 		u32 res = lhs + rhs; \

    23 		reg[dest].I = res; \

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

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

    26 		ADDCARRY(lhs, rhs, res); \

    27 		ADDOVERFLOW(lhs, rhs, res); \

    28 	}

    29 #define ADD_RD_RS_O3 \

    30 	{ \

    31 		u32 lhs = reg[source].I; \

    32 		u32 rhs = value; \

    33 		u32 res = lhs + rhs; \

    34 		reg[dest].I = res; \

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

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

    37 		ADDCARRY(lhs, rhs, res); \

    38 		ADDOVERFLOW(lhs, rhs, res); \

    39 	}

    40 #define ADD_RN_O8(d) \

    41 	{ \

    42 		u32 lhs = reg[(d)].I; \

    43 		u32 rhs = (opcode & 255); \

    44 		u32 res = lhs + rhs; \

    45 		reg[(d)].I = res; \

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

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

    48 		ADDCARRY(lhs, rhs, res); \

    49 		ADDOVERFLOW(lhs, rhs, res); \

    50 	}

    51 #define CMN_RD_RS \

    52 	{ \

    53 		u32 lhs = reg[dest].I; \

    54 		u32 rhs = value; \

    55 		u32 res = lhs + rhs; \

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

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

    58 		ADDCARRY(lhs, rhs, res); \

    59 		ADDOVERFLOW(lhs, rhs, res); \

    60 	}

    61 #define ADC_RD_RS \

    62 	{ \

    63 		u32 lhs = reg[dest].I; \

    64 		u32 rhs = value; \

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

    66 		reg[dest].I = res; \

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

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

    69 		ADDCARRY(lhs, rhs, res); \

    70 		ADDOVERFLOW(lhs, rhs, res); \

    71 	}

    72 #define SUB_RD_RS_RN \

    73 	{ \

    74 		u32 lhs = reg[source].I; \

    75 		u32 rhs = value; \

    76 		u32 res = lhs - rhs; \

    77 		reg[dest].I = res; \

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

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

    80 		SUBCARRY(lhs, rhs, res); \

    81 		SUBOVERFLOW(lhs, rhs, res); \

    82 	}

    83 #define SUB_RD_RS_O3 \

    84 	{ \

    85 		u32 lhs = reg[source].I; \

    86 		u32 rhs = value; \

    87 		u32 res = lhs - rhs; \

    88 		reg[dest].I = res; \

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

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

    91 		SUBCARRY(lhs, rhs, res); \

    92 		SUBOVERFLOW(lhs, rhs, res); \

    93 	}

    94 #define SUB_RN_O8(d) \

    95 	{ \

    96 		u32 lhs = reg[(d)].I; \

    97 		u32 rhs = (opcode & 255); \

    98 		u32 res = lhs - rhs; \

    99 		reg[(d)].I = res; \

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

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

   102 		SUBCARRY(lhs, rhs, res); \

   103 		SUBOVERFLOW(lhs, rhs, res); \

   104 	}

   105 #define CMP_RN_O8(d) \

   106 	{ \

   107 		u32 lhs = reg[(d)].I; \

   108 		u32 rhs = (opcode & 255); \

   109 		u32 res = lhs - rhs; \

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

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

   112 		SUBCARRY(lhs, rhs, res); \

   113 		SUBOVERFLOW(lhs, rhs, res); \

   114 	}

   115 #define SBC_RD_RS \

   116 	{ \

   117 		u32 lhs = reg[dest].I; \

   118 		u32 rhs = value; \

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

   120 		reg[dest].I = res; \

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

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

   123 		SUBCARRY(lhs, rhs, res); \

   124 		SUBOVERFLOW(lhs, rhs, res); \

   125 	}

   126 #define LSL_RD_RM_I5 \

   127 	{ \

   128 		C_FLAG = (reg[source].I >> (32 - shift)) & 1 ? true : false; \

   129 		value  = reg[source].I << shift; \

   130 	}

   131 #define LSL_RD_RS \

   132 	{ \

   133 		C_FLAG = (reg[dest].I >> (32 - value)) & 1 ? true : false; \

   134 		value  = reg[dest].I << value; \

   135 	}

   136 #define LSR_RD_RM_I5 \

   137 	{ \

   138 		C_FLAG = (reg[source].I >> (shift - 1)) & 1 ? true : false; \

   139 		value  = reg[source].I >> shift; \

   140 	}

   141 #define LSR_RD_RS \

   142 	{ \

   143 		C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false; \

   144 		value  = reg[dest].I >> value; \

   145 	}

   146 #define ASR_RD_RM_I5 \

   147 	{ \

   148 		C_FLAG = ((s32)reg[source].I >> (int)(shift - 1)) & 1 ? true : false; \

   149 		value  = (s32)reg[source].I >> (int)shift; \

   150 	}

   151 #define ASR_RD_RS \

   152 	{ \

   153 		C_FLAG = ((s32)reg[dest].I >> (int)(value - 1)) & 1 ? true : false; \

   154 		value  = (s32)reg[dest].I >> (int)value; \

   155 	}

   156 #define ROR_RD_RS \

   157 	{ \

   158 		C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false; \

   159 		value  = ((reg[dest].I << (32 - value)) | \

   160 		          (reg[dest].I >> value)); \

   161 	}

   162 #define NEG_RD_RS \

   163 	{ \

   164 		u32 lhs = reg[source].I; \

   165 		u32 rhs = 0; \

   166 		u32 res = rhs - lhs; \

   167 		reg[dest].I = res; \

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

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

   170 		SUBCARRY(rhs, lhs, res); \

   171 		SUBOVERFLOW(rhs, lhs, res); \

   172 	}

   173 #define CMP_RD_RS \

   174 	{ \

   175 		u32 lhs = reg[dest].I; \

   176 		u32 rhs = value; \

   177 		u32 res = lhs - rhs; \

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

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

   180 		SUBCARRY(lhs, rhs, res); \

   181 		SUBOVERFLOW(lhs, rhs, res); \

   182 	}

   183 #else

   184 #ifdef __GNUC__

   185 #ifdef __POWERPC__

   186 			#define ADD_RD_RS_RN \

   187 	{                                       \

   188 		register int Flags;                 \

   189 		register int Result;                \

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

   191 		              "mcrxr cr1\n"           \

   192 		              "mfcr %1\n"             \

   193 					  : "=r" (Result),        \

   194 		              "=r" (Flags)          \

   195 					  : "r" (reg[source].I),  \

   196 		              "r" (value)           \

   197 		              );                      \

   198 		reg[dest].I = Result;               \

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

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

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

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

   203 	}

   204 			#define ADD_RD_RS_O3 ADD_RD_RS_RN

   205 			#define ADD_RN_O8(d) \

   206 	{ \

   207 		register int Flags;                 \

   208 		register int Result;                \

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

   210 		              "mcrxr cr1\n"           \

   211 		              "mfcr %1\n"             \

   212 					  : "=r" (Result),        \

   213 		              "=r" (Flags)          \

   214 					  : "r" (reg[(d)].I),     \

   215 		              "r" (opcode & 255)    \

   216 		              );                      \

   217 		reg[(d)].I = Result;                \

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

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

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

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

   222 	}

   223 			#define CMN_RD_RS \

   224 	{ \

   225 		register int Flags;                 \

   226 		register int Result;                \

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

   228 		              "mcrxr cr1\n"           \

   229 		              "mfcr %1\n"             \

   230 					  : "=r" (Result),        \

   231 		              "=r" (Flags)          \

   232 					  : "r" (reg[dest].I),    \

   233 		              "r" (value)           \

   234 		              );                      \

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

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

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

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

   239 	}

   240 			#define ADC_RD_RS \

   241 	{ \

   242 		register int Flags;                 \

   243 		register int Result;                \

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

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

   246 		              "mcrxr cr1\n"          \

   247 		              "mfcr	%1\n"            \

   248 					  : "=r" (Result),       \

   249 		              "=r" (Flags)         \

   250 					  : "r" (reg[dest].I),   \

   251 		              "r" (value),         \

   252 		              "r" (C_FLAG << 29)   \

   253 		              );                     \

   254 		reg[dest].I = Result;               \

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

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

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

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

   259 	}

   260 			#define SUB_RD_RS_RN \

   261 	{ \

   262 		register int Flags;                 \

   263 		register int Result;                \

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

   265 		              "mcrxr cr1\n"           \

   266 		              "mfcr %1\n"             \

   267 					  : "=r" (Result),        \

   268 		              "=r" (Flags)          \

   269 					  : "r" (reg[source].I),  \

   270 		              "r" (value)           \

   271 		              );                      \

   272 		reg[dest].I = Result;               \

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

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

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

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

   277 	}

   278 			#define SUB_RD_RS_O3 SUB_RD_RS_RN

   279 			#define SUB_RN_O8(d) \

   280 	{ \

   281 		register int Flags;                 \

   282 		register int Result;                \

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

   284 		              "mcrxr cr1\n"           \

   285 		              "mfcr %1\n"             \

   286 					  : "=r" (Result),        \

   287 		              "=r" (Flags)          \

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

   289 		              "r" (opcode & 255)    \

   290 		              );                      \

   291 		reg[(d)].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 CMP_RN_O8(d) \

   298 	{ \

   299 		register int Flags;                 \

   300 		register int Result;                \

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

   302 		              "mcrxr cr1\n"           \

   303 		              "mfcr %1\n"             \

   304 					  : "=r" (Result),        \

   305 		              "=r" (Flags)          \

   306 					  : "r" (reg[(d)].I),     \

   307 		              "r" (opcode & 255)    \

   308 		              );                      \

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

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

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

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

   313 	}

   314 			#define SBC_RD_RS \

   315 	{ \

   316 		register int Flags;                 \

   317 		register int Result;                \

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

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

   320 		              "mcrxr cr1\n"          \

   321 		              "mfcr	%1\n"            \

   322 					  : "=r" (Result),       \

   323 		              "=r" (Flags)         \

   324 					  : "r" (reg[dest].I),   \

   325 		              "r" (value),         \

   326 		              "r" (C_FLAG << 29)   \

   327 		              );                     \

   328 		reg[dest].I = Result;               \

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

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

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

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

   333 	}

   334 			#define LSL_RD_RM_I5 \

   335 	{ \

   336 		C_FLAG = (reg[source].I >> (32 - shift)) & 1 ? true : false; \

   337 		value  = reg[source].I << shift; \

   338 	}

   339 			#define LSL_RD_RS \

   340 	{ \

   341 		C_FLAG = (reg[dest].I >> (32 - value)) & 1 ? true : false; \

   342 		value  = reg[dest].I << value; \

   343 	}

   344 			#define LSR_RD_RM_I5 \

   345 	{ \

   346 		C_FLAG = (reg[source].I >> (shift - 1)) & 1 ? true : false; \

   347 		value  = reg[source].I >> shift; \

   348 	}

   349 			#define LSR_RD_RS \

   350 	{ \

   351 		C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false; \

   352 		value  = reg[dest].I >> value; \

   353 	}

   354 			#define ASR_RD_RM_I5 \

   355 	{ \

   356 		C_FLAG = ((s32)reg[source].I >> (int)(shift - 1)) & 1 ? true : false; \

   357 		value  = (s32)reg[source].I >> (int)shift; \

   358 	}

   359 			#define ASR_RD_RS \

   360 	{ \

   361 		C_FLAG = ((s32)reg[dest].I >> (int)(value - 1)) & 1 ? true : false; \

   362 		value  = (s32)reg[dest].I >> (int)value; \

   363 	}

   364 			#define ROR_RD_RS \

   365 	{ \

   366 		C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false; \

   367 		value  = ((reg[dest].I << (32 - value)) | \

   368 		          (reg[dest].I >> value)); \

   369 	}

   370 			#define NEG_RD_RS \

   371 	{ \

   372 		register int Flags;                 \

   373 		register int Result;                \

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

   375 		              "mcrxr cr1\n"           \

   376 		              "mfcr %1\n"             \

   377 					  : "=r" (Result),        \

   378 		              "=r" (Flags)          \

   379 					  : "r" (reg[source].I),  \

   380 		              "r" (0)               \

   381 		              );                      \

   382 		reg[dest].I = Result;               \

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

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

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

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

   387 	}

   388 			#define CMP_RD_RS \

   389 	{ \

   390 		register int Flags;                 \

   391 		register int Result;                \

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

   393 		              "mcrxr cr1\n"           \

   394 		              "mfcr %1\n"             \

   395 					  : "=r" (Result),        \

   396 		              "=r" (Flags)          \

   397 					  : "r" (reg[dest].I),    \

   398 		              "r" (value)           \

   399 		              );                      \

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

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

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

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

   404 	}

   405 #else

   406 #define ADD_RD_RS_RN \

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

   408          "setsb N_FLAG;" \

   409          "setzb Z_FLAG;" \

   410          "setcb C_FLAG;" \

   411          "setob V_FLAG;" \

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

   413 		 : "r" (value), "b" (reg[source].I));

   414 #define ADD_RD_RS_O3 \

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

   416          "setsb N_FLAG;" \

   417          "setzb Z_FLAG;" \

   418          "setcb C_FLAG;" \

   419          "setob V_FLAG;" \

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

   421 		 : "r" (value), "b" (reg[source].I));

   422 #define ADD_RN_O8(d) \

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

   424          "setsb N_FLAG;" \

   425          "setzb Z_FLAG;" \

   426          "setcb C_FLAG;" \

   427          "setob V_FLAG;" \

   428 		 : "=b" (reg[(d)].I) \

   429 		 : "r" (opcode & 255), "b" (reg[(d)].I));

   430 #define CMN_RD_RS \

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

   432          "setsb N_FLAG;" \

   433          "setzb Z_FLAG;" \

   434          "setcb C_FLAG;" \

   435          "setob V_FLAG;" \

   436 		 : \

   437 		 : "r" (value), "r" (reg[dest].I) : "1");

   438 #define ADC_RD_RS \

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

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

   441          "setsb N_FLAG;" \

   442          "setzb Z_FLAG;" \

   443          "setcb C_FLAG;" \

   444          "setob V_FLAG;" \

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

   446 		 : "r" (value), "b" (reg[dest].I));

   447 #define SUB_RD_RS_RN \

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

   449          "setsb N_FLAG;" \

   450          "setzb Z_FLAG;" \

   451          "setncb C_FLAG;" \

   452          "setob V_FLAG;" \

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

   454 		 : "r" (value), "b" (reg[source].I));

   455 #define SUB_RD_RS_O3 \

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

   457          "setsb N_FLAG;" \

   458          "setzb Z_FLAG;" \

   459          "setncb C_FLAG;" \

   460          "setob V_FLAG;" \

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

   462 		 : "r" (value), "b" (reg[source].I));

   463 #define SUB_RN_O8(d) \

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

   465          "setsb N_FLAG;" \

   466          "setzb Z_FLAG;" \

   467          "setncb C_FLAG;" \

   468          "setob V_FLAG;" \

   469 		 : "=b" (reg[(d)].I) \

   470 		 : "r" (opcode & 255), "b" (reg[(d)].I));

   471 #define CMP_RN_O8(d) \

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

   473          "setsb N_FLAG;" \

   474          "setzb Z_FLAG;" \

   475          "setncb C_FLAG;" \

   476          "setob V_FLAG;" \

   477 		 : \

   478 		 : "r" (opcode & 255), "r" (reg[(d)].I) : "1");

   479 #define SBC_RD_RS \

   480     asm volatile ("bt $0, C_FLAG;" \

   481                   "cmc;" \

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

   483                   "setsb N_FLAG;" \

   484                   "setzb Z_FLAG;" \

   485                   "setncb C_FLAG;" \

   486                   "setob V_FLAG;" \

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

   488 				  : "r" (value), "b" (reg[dest].I) : "cc", "memory");

   489 #define LSL_RD_RM_I5 \

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

   491          "setcb C_FLAG;" \

   492 		 : "=a" (value) \

   493 		 : "a" (reg[source].I), "c" (shift));

   494 #define LSL_RD_RS \

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

   496          "setcb C_FLAG;" \

   497 		 : "=a" (value) \

   498 		 : "a" (reg[dest].I), "c" (value));

   499 #define LSR_RD_RM_I5 \

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

   501          "setcb C_FLAG;" \

   502 		 : "=a" (value) \

   503 		 : "a" (reg[source].I), "c" (shift));

   504 #define LSR_RD_RS \

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

   506          "setcb C_FLAG;" \

   507 		 : "=a" (value) \

   508 		 : "a" (reg[dest].I), "c" (value));

   509 #define ASR_RD_RM_I5 \

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

   511          "setcb C_FLAG;" \

   512 		 : "=a" (value) \

   513 		 : "a" (reg[source].I), "c" (shift));

   514 #define ASR_RD_RS \

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

   516          "setcb C_FLAG;" \

   517 		 : "=a" (value) \

   518 		 : "a" (reg[dest].I), "c" (value));

   519 #define ROR_RD_RS \

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

   521          "setcb C_FLAG;" \

   522 		 : "=a" (value) \

   523 		 : "a" (reg[dest].I), "c" (value));

   524 #define NEG_RD_RS \

   525     asm ("neg %%ebx;" \

   526          "setsb N_FLAG;" \

   527          "setzb Z_FLAG;" \

   528          "setncb C_FLAG;" \

   529          "setob V_FLAG;" \

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

   531 		 : "b" (reg[source].I));

   532 #define CMP_RD_RS \

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

   534          "setsb N_FLAG;" \

   535          "setzb Z_FLAG;" \

   536          "setncb C_FLAG;" \

   537          "setob V_FLAG;" \

   538 		 : \

   539 		 : "r" (value), "r" (reg[dest].I) : "1");

   540 #endif

   541 #else

   542 #define ADD_RD_RS_RN \

   543 	{ \

   544 		__asm mov eax, source \

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

   546 		__asm add ebx, value \

   547 		__asm mov eax, dest \

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

   549 		__asm sets byte ptr N_FLAG \

   550 		__asm setz byte ptr Z_FLAG \

   551 		__asm setc byte ptr C_FLAG \

   552 		__asm seto byte ptr V_FLAG \

   553 	}

   554 #define ADD_RD_RS_O3 \

   555 	{ \

   556 		__asm mov eax, source \

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

   558 		__asm add ebx, value \

   559 		__asm mov eax, dest \

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

   561 		__asm sets byte ptr N_FLAG \

   562 		__asm setz byte ptr Z_FLAG \

   563 		__asm setc byte ptr C_FLAG \

   564 		__asm seto byte ptr V_FLAG \

   565 	}

   566 #define ADD_RN_O8(d) \

   567 	{ \

   568 		__asm mov ebx, opcode \

   569 		          __asm and ebx, 255 \

   570 		__asm add dword ptr [OFFSET reg + 4 * (d)], ebx \

   571 		__asm sets byte ptr N_FLAG \

   572 		__asm setz byte ptr Z_FLAG \

   573 		__asm setc byte ptr C_FLAG \

   574 		__asm seto byte ptr V_FLAG \

   575 	}

   576 #define CMN_RD_RS \

   577 	{ \

   578 		__asm mov eax, dest \

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

   580 		__asm add ebx, value \

   581 		__asm sets byte ptr N_FLAG \

   582 		__asm setz byte ptr Z_FLAG \

   583 		__asm setc byte ptr C_FLAG \

   584 		__asm seto byte ptr V_FLAG \

   585 	}

   586 #define ADC_RD_RS \

   587 	{ \

   588 		__asm mov ebx, dest \

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

   590 		__asm bt word ptr C_FLAG, 0 \

   591 		__asm adc ebx, value \

   592 		__asm mov eax, dest \

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

   594 		__asm sets byte ptr N_FLAG \

   595 		__asm setz byte ptr Z_FLAG \

   596 		__asm setc byte ptr C_FLAG \

   597 		__asm seto byte ptr V_FLAG \

   598 	}

   599 #define SUB_RD_RS_RN \

   600 	{ \

   601 		__asm mov eax, source \

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

   603 		__asm sub ebx, value \

   604 		__asm mov eax, dest \

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

   606 		__asm sets byte ptr N_FLAG \

   607 		__asm setz byte ptr Z_FLAG \

   608 		__asm setnc byte ptr C_FLAG \

   609 		__asm seto byte ptr V_FLAG \

   610 	}

   611 #define SUB_RD_RS_O3 \

   612 	{ \

   613 		__asm mov eax, source \

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

   615 		__asm sub ebx, value \

   616 		__asm mov eax, dest \

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

   618 		__asm sets byte ptr N_FLAG \

   619 		__asm setz byte ptr Z_FLAG \

   620 		__asm setnc byte ptr C_FLAG \

   621 		__asm seto byte ptr V_FLAG \

   622 	}

   623 #define SUB_RN_O8(d) \

   624 	{ \

   625 		__asm mov ebx, opcode \

   626 		          __asm and ebx, 255 \

   627 		__asm sub dword ptr [OFFSET reg + 4 * (d)], ebx \

   628 		__asm sets byte ptr N_FLAG \

   629 		__asm setz byte ptr Z_FLAG \

   630 		__asm setnc byte ptr C_FLAG \

   631 		__asm seto byte ptr V_FLAG \

   632 	}

   633 #define CMP_RN_O8(d) \

   634 	{ \

   635 		__asm mov eax, dword ptr [OFFSET reg + 4 * (d)] \

   636 		__asm mov ebx, opcode \

   637 		          __asm and ebx, 255 \

   638 		__asm sub eax, ebx \

   639 		__asm sets byte ptr N_FLAG \

   640 		__asm setz byte ptr Z_FLAG \

   641 		__asm setnc byte ptr C_FLAG \

   642 		__asm seto byte ptr V_FLAG \

   643 	}

   644 #define SBC_RD_RS \

   645 	{ \

   646 		__asm mov ebx, dest \

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

   648 		__asm mov eax, value \

   649 		__asm bt word ptr C_FLAG, 0 \

   650 		__asm cmc \

   651 		__asm sbb ebx, eax \

   652 		__asm mov eax, dest \

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

   654 		__asm sets byte ptr N_FLAG \

   655 		__asm setz byte ptr Z_FLAG \

   656 		__asm setnc byte ptr C_FLAG \

   657 		__asm seto byte ptr V_FLAG \

   658 	}

   659 #define LSL_RD_RM_I5 \

   660 	{ \

   661 		__asm mov eax, source \

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

   663 		__asm mov cl, byte ptr shift \

   664 		__asm shl eax, cl \

   665 		__asm mov value, eax \

   666 		__asm setc byte ptr C_FLAG \

   667 	}

   668 #define LSL_RD_RS \

   669 	{ \

   670 		__asm mov eax, dest \

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

   672 		__asm mov cl, byte ptr value \

   673 		__asm shl eax, cl \

   674 		__asm mov value, eax \

   675 		__asm setc byte ptr C_FLAG \

   676 	}

   677 #define LSR_RD_RM_I5 \

   678 	{ \

   679 		__asm mov eax, source \

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

   681 		__asm mov cl, byte ptr shift \

   682 		__asm shr eax, cl \

   683 		__asm mov value, eax \

   684 		__asm setc byte ptr C_FLAG \

   685 	}

   686 #define LSR_RD_RS \

   687 	{ \

   688 		__asm mov eax, dest \

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

   690 		__asm mov cl, byte ptr value \

   691 		__asm shr eax, cl \

   692 		__asm mov value, eax \

   693 		__asm setc byte ptr C_FLAG \

   694 	}

   695 #define ASR_RD_RM_I5 \

   696 	{ \

   697 		__asm mov eax, source \

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

   699 		__asm mov cl, byte ptr shift \

   700 		__asm sar eax, cl \

   701 		__asm mov value, eax \

   702 		__asm setc byte ptr C_FLAG \

   703 	}

   704 #define ASR_RD_RS \

   705 	{ \

   706 		__asm mov eax, dest \

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

   708 		__asm mov cl, byte ptr value \

   709 		__asm sar eax, cl \

   710 		__asm mov value, eax \

   711 		__asm setc byte ptr C_FLAG \

   712 	}

   713 #define ROR_RD_RS \

   714 	{ \

   715 		__asm mov eax, dest \

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

   717 		__asm mov cl, byte ptr value \

   718 		__asm ror eax, cl \

   719 		__asm mov value, eax \

   720 		__asm setc byte ptr C_FLAG \

   721 	}

   722 #define NEG_RD_RS \

   723 	{ \

   724 		__asm mov ebx, source \

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

   726 		__asm neg ebx \

   727 		__asm mov eax, dest \

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

   729 		__asm sets byte ptr N_FLAG \

   730 		__asm setz byte ptr Z_FLAG \

   731 		__asm setnc byte ptr C_FLAG \

   732 		__asm seto byte ptr V_FLAG \

   733 	}

   734 #define CMP_RD_RS \

   735 	{ \

   736 		__asm mov eax, dest \

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

   738 		__asm sub ebx, value \

   739 		__asm sets byte ptr N_FLAG \

   740 		__asm setz byte ptr Z_FLAG \

   741 		__asm setnc byte ptr C_FLAG \

   742 		__asm seto byte ptr V_FLAG \

   743 	}

   744 #endif

   745 #endif

   746 

   747 u32 opcode = CPUReadHalfWordQuick(armNextPC);

   748 clockTicks = thumbCycles[opcode >> 8] + memoryWaitFetch[(armNextPC >> 24) & 15];

   749 #ifndef FINAL_VERSION

   750 if (armNextPC == stop)

   751 {

   752 	armNextPC = armNextPC++;

   753 }

   754 #endif

   755 

   756 armNextPC  = reg[15].I;

   757 reg[15].I += 2;

   758 

   759 switch (opcode >> 8)

   760 {

   761 case 0x00:

   762 case 0x01:

   763 case 0x02:

   764 case 0x03:

   765 case 0x04:

   766 case 0x05:

   767 case 0x06:

   768 case 0x07:

   769 {

   770 	// LSL Rd, Rm, #Imm 5

   771 	int dest   = opcode & 0x07;

   772 	int source = (opcode >> 3) & 0x07;

   773 	int shift  = (opcode >> 6) & 0x1f;

   774 	u32 value;

   775 

   776 	if (shift)

   777 	{

   778 		LSL_RD_RM_I5;

   779 	}

   780 	else

   781 	{

   782 		value = reg[source].I;

   783 	}

   784 	reg[dest].I = value;

   785 	// C_FLAG set above

   786 	N_FLAG = (value & 0x80000000 ? true : false);

   787 	Z_FLAG = (value ? false : true);

   788 }

   789 break;

   790 case 0x08:

   791 case 0x09:

   792 case 0x0a:

   793 case 0x0b:

   794 case 0x0c:

   795 case 0x0d:

   796 case 0x0e:

   797 case 0x0f:

   798 {

   799 	// LSR Rd, Rm, #Imm 5

   800 	int dest   = opcode & 0x07;

   801 	int source = (opcode >> 3) & 0x07;

   802 	int shift  = (opcode >> 6) & 0x1f;

   803 	u32 value;

   804 

   805 	if (shift)

   806 	{

   807 		LSR_RD_RM_I5;

   808 	}

   809 	else

   810 	{

   811 		C_FLAG = reg[source].I & 0x80000000 ? true : false;

   812 		value  = 0;

   813 	}

   814 	reg[dest].I = value;

   815 	// C_FLAG set above

   816 	N_FLAG = (value & 0x80000000 ? true : false);

   817 	Z_FLAG = (value ? false : true);

   818 }

   819 break;

   820 case 0x10:

   821 case 0x11:

   822 case 0x12:

   823 case 0x13:

   824 case 0x14:

   825 case 0x15:

   826 case 0x16:

   827 case 0x17:

   828 {

   829 	// ASR Rd, Rm, #Imm 5

   830 	int dest   = opcode & 0x07;

   831 	int source = (opcode >> 3) & 0x07;

   832 	int shift  = (opcode >> 6) & 0x1f;

   833 	u32 value;

   834 

   835 	if (shift)

   836 	{

   837 		ASR_RD_RM_I5;

   838 	}

   839 	else

   840 	{

   841 		if (reg[source].I & 0x80000000)

   842 		{

   843 			value  = 0xFFFFFFFF;

   844 			C_FLAG = true;

   845 		}

   846 		else

   847 		{

   848 			value  = 0;

   849 			C_FLAG = false;

   850 		}

   851 	}

   852 	reg[dest].I = value;

   853 	// C_FLAG set above

   854 	N_FLAG = (value & 0x80000000 ? true : false);

   855 	Z_FLAG = (value ? false : true);

   856 }

   857 break;

   858 case 0x18:

   859 case 0x19:

   860 {

   861 	// ADD Rd, Rs, Rn

   862 	int dest   = opcode & 0x07;

   863 	int source = (opcode >> 3) & 0x07;

   864 	u32 value  = reg[(opcode >> 6) & 0x07].I;

   865 	ADD_RD_RS_RN;

   866 }

   867 break;

   868 case 0x1a:

   869 case 0x1b:

   870 {

   871 	// SUB Rd, Rs, Rn

   872 	int dest   = opcode & 0x07;

   873 	int source = (opcode >> 3) & 0x07;

   874 	u32 value  = reg[(opcode >> 6) & 0x07].I;

   875 	SUB_RD_RS_RN;

   876 }

   877 break;

   878 case 0x1c:

   879 case 0x1d:

   880 {

   881 	// ADD Rd, Rs, #Offset3

   882 	int dest   = opcode & 0x07;

   883 	int source = (opcode >> 3) & 0x07;

   884 	u32 value  = (opcode >> 6) & 7;

   885 	ADD_RD_RS_O3;

   886 }

   887 break;

   888 case 0x1e:

   889 case 0x1f:

   890 {

   891 	// SUB Rd, Rs, #Offset3

   892 	int dest   = opcode & 0x07;

   893 	int source = (opcode >> 3) & 0x07;

   894 	u32 value  = (opcode >> 6) & 7;

   895 	SUB_RD_RS_O3;

   896 }

   897 break;

   898 case 0x20:

   899 	// MOV R0, #Offset8

   900 	reg[0].I = opcode & 255;

   901 	N_FLAG	 = false;

   902 	Z_FLAG	 = (reg[0].I ? false : true);

   903 	break;

   904 case 0x21:

   905 	// MOV R1, #Offset8

   906 	reg[1].I = opcode & 255;

   907 	N_FLAG	 = false;

   908 	Z_FLAG	 = (reg[1].I ? false : true);

   909 	break;

   910 case 0x22:

   911 	// MOV R2, #Offset8

   912 	reg[2].I = opcode & 255;

   913 	N_FLAG	 = false;

   914 	Z_FLAG	 = (reg[2].I ? false : true);

   915 	break;

   916 case 0x23:

   917 	// MOV R3, #Offset8

   918 	reg[3].I = opcode & 255;

   919 	N_FLAG	 = false;

   920 	Z_FLAG	 = (reg[3].I ? false : true);

   921 	break;

   922 case 0x24:

   923 	// MOV R4, #Offset8

   924 	reg[4].I = opcode & 255;

   925 	N_FLAG	 = false;

   926 	Z_FLAG	 = (reg[4].I ? false : true);

   927 	break;

   928 case 0x25:

   929 	// MOV R5, #Offset8

   930 	reg[5].I = opcode & 255;

   931 	N_FLAG	 = false;

   932 	Z_FLAG	 = (reg[5].I ? false : true);

   933 	break;

   934 case 0x26:

   935 	// MOV R6, #Offset8

   936 	reg[6].I = opcode & 255;

   937 	N_FLAG	 = false;

   938 	Z_FLAG	 = (reg[6].I ? false : true);

   939 	break;

   940 case 0x27:

   941 	// MOV R7, #Offset8

   942 	reg[7].I = opcode & 255;

   943 	N_FLAG	 = false;

   944 	Z_FLAG	 = (reg[7].I ? false : true);

   945 	break;

   946 case 0x28:

   947 	// CMP R0, #Offset8

   948 	CMP_RN_O8(0);

   949 	break;

   950 case 0x29:

   951 	// CMP R1, #Offset8

   952 	CMP_RN_O8(1);

   953 	break;

   954 case 0x2a:

   955 	// CMP R2, #Offset8

   956 	CMP_RN_O8(2);

   957 	break;

   958 case 0x2b:

   959 	// CMP R3, #Offset8

   960 	CMP_RN_O8(3);

   961 	break;

   962 case 0x2c:

   963 	// CMP R4, #Offset8

   964 	CMP_RN_O8(4);

   965 	break;

   966 case 0x2d:

   967 	// CMP R5, #Offset8

   968 	CMP_RN_O8(5);

   969 	break;

   970 case 0x2e:

   971 	// CMP R6, #Offset8

   972 	CMP_RN_O8(6);

   973 	break;

   974 case 0x2f:

   975 	// CMP R7, #Offset8

   976 	CMP_RN_O8(7);

   977 	break;

   978 case 0x30:

   979 	// ADD R0,#Offset8

   980 	ADD_RN_O8(0);

   981 	break;

   982 case 0x31:

   983 	// ADD R1,#Offset8

   984 	ADD_RN_O8(1);

   985 	break;

   986 case 0x32:

   987 	// ADD R2,#Offset8

   988 	ADD_RN_O8(2);

   989 	break;

   990 case 0x33:

   991 	// ADD R3,#Offset8

   992 	ADD_RN_O8(3);

   993 	break;

   994 case 0x34:

   995 	// ADD R4,#Offset8

   996 	ADD_RN_O8(4);

   997 	break;

   998 case 0x35:

   999 	// ADD R5,#Offset8

  1000 	ADD_RN_O8(5);

  1001 	break;

  1002 case 0x36:

  1003 	// ADD R6,#Offset8

  1004 	ADD_RN_O8(6);

  1005 	break;

  1006 case 0x37:

  1007 	// ADD R7,#Offset8

  1008 	ADD_RN_O8(7);

  1009 	break;

  1010 case 0x38:

  1011 	// SUB R0,#Offset8

  1012 	SUB_RN_O8(0);

  1013 	break;

  1014 case 0x39:

  1015 	// SUB R1,#Offset8

  1016 	SUB_RN_O8(1);

  1017 	break;

  1018 case 0x3a:

  1019 	// SUB R2,#Offset8

  1020 	SUB_RN_O8(2);

  1021 	break;

  1022 case 0x3b:

  1023 	// SUB R3,#Offset8

  1024 	SUB_RN_O8(3);

  1025 	break;

  1026 case 0x3c:

  1027 	// SUB R4,#Offset8

  1028 	SUB_RN_O8(4);

  1029 	break;

  1030 case 0x3d:

  1031 	// SUB R5,#Offset8

  1032 	SUB_RN_O8(5);

  1033 	break;

  1034 case 0x3e:

  1035 	// SUB R6,#Offset8

  1036 	SUB_RN_O8(6);

  1037 	break;

  1038 case 0x3f:

  1039 	// SUB R7,#Offset8

  1040 	SUB_RN_O8(7);

  1041 	break;

  1042 case 0x40:

  1043 	switch ((opcode >> 6) & 3)

  1044 	{

  1045 	case 0x00:

  1046 	{

  1047 		// AND Rd, Rs

  1048 		int dest = opcode & 7;

  1049 		reg[dest].I &= reg[(opcode >> 3) & 7].I;

  1050 		N_FLAG		 = reg[dest].I & 0x80000000 ? true : false;

  1051 		Z_FLAG		 = reg[dest].I ? false : true;

  1052 #ifdef BKPT_SUPPORT

  1053 #define THUMB_CONSOLE_OUTPUT(a, b) \

  1054 	if ((opcode == 0x4000) && (reg[0].I == 0xC0DED00D)) { \

  1055 		extern void (*dbgOutput)(char *, u32); \

  1056 		dbgOutput((a), (b)); \

  1057 	}

  1058 #else

  1059 #define THUMB_CONSOLE_OUTPUT(a, b)

  1060 #endif

  1061 		THUMB_CONSOLE_OUTPUT(NULL, reg[2].I);

  1062 	}

  1063 	break;

  1064 	case 0x01:

  1065 		// EOR Rd, Rs

  1066 	{

  1067 		int dest = opcode & 7;

  1068 		reg[dest].I ^= reg[(opcode >> 3) & 7].I;

  1069 		N_FLAG		 = reg[dest].I & 0x80000000 ? true : false;

  1070 		Z_FLAG		 = reg[dest].I ? false : true;

  1071 	}

  1072 	break;

  1073 	case 0x02:

  1074 		// LSL Rd, Rs

  1075 	{

  1076 		int dest  = opcode & 7;

  1077 		u32 value = reg[(opcode >> 3) & 7].B.B0;

  1078 		if (value)

  1079 		{

  1080 			if (value == 32)

  1081 			{

  1082 				value  = 0;

  1083 				C_FLAG = (reg[dest].I & 1 ? true : false);

  1084 			}

  1085 			else if (value < 32)

  1086 			{

  1087 				LSL_RD_RS;

  1088 			}

  1089 			else

  1090 			{

  1091 				value  = 0;

  1092 				C_FLAG = false;

  1093 			}

  1094 			reg[dest].I = value;

  1095 		}

  1096 		N_FLAG = reg[dest].I & 0x80000000 ? true : false;

  1097 		Z_FLAG = reg[dest].I ? false : true;

  1098 		clockTicks++;

  1099 	}

  1100 	break;

  1101 	case 0x03:

  1102 	{

  1103 		// LSR Rd, Rs

  1104 		int dest  = opcode & 7;

  1105 		u32 value = reg[(opcode >> 3) & 7].B.B0;

  1106 		if (value)

  1107 		{

  1108 			if (value == 32)

  1109 			{

  1110 				value  = 0;

  1111 				C_FLAG = (reg[dest].I & 0x80000000 ? true : false);

  1112 			}

  1113 			else if (value < 32)

  1114 			{

  1115 				LSR_RD_RS;

  1116 			}

  1117 			else

  1118 			{

  1119 				value  = 0;

  1120 				C_FLAG = false;

  1121 			}

  1122 			reg[dest].I = value;

  1123 		}

  1124 		N_FLAG = reg[dest].I & 0x80000000 ? true : false;

  1125 		Z_FLAG = reg[dest].I ? false : true;

  1126 		clockTicks++;

  1127 	}

  1128 	break;

  1129 	}

  1130 	break;

  1131 case 0x41:

  1132 	switch ((opcode >> 6) & 3)

  1133 	{

  1134 	case 0x00:

  1135 	{

  1136 		// ASR Rd, Rs

  1137 		int dest  = opcode & 7;

  1138 		u32 value = reg[(opcode >> 3) & 7].B.B0;

  1139 		// ASR

  1140 		if (value)

  1141 		{

  1142 			if (value < 32)

  1143 			{

  1144 				ASR_RD_RS;

  1145 				reg[dest].I = value;

  1146 			}

  1147 			else

  1148 			{

  1149 				if (reg[dest].I & 0x80000000)

  1150 				{

  1151 					reg[dest].I = 0xFFFFFFFF;

  1152 					C_FLAG		= true;

  1153 				}

  1154 				else

  1155 				{

  1156 					reg[dest].I = 0x00000000;

  1157 					C_FLAG		= false;

  1158 				}

  1159 			}

  1160 		}

  1161 		N_FLAG = reg[dest].I & 0x80000000 ? true : false;

  1162 		Z_FLAG = reg[dest].I ? false : true;

  1163 		clockTicks++;

  1164 	}

  1165 	break;

  1166 	case 0x01:

  1167 	{

  1168 		// ADC Rd, Rs

  1169 		int dest  = opcode & 0x07;

  1170 		u32 value = reg[(opcode >> 3) & 7].I;

  1171 		// ADC

  1172 		ADC_RD_RS;

  1173 	}

  1174 	break;

  1175 	case 0x02:

  1176 	{

  1177 		// SBC Rd, Rs

  1178 		int dest  = opcode & 0x07;

  1179 		u32 value = reg[(opcode >> 3) & 7].I;

  1180 

  1181 		// SBC

  1182 		SBC_RD_RS;

  1183 	}

  1184 	break;

  1185 	case 0x03:

  1186 		// ROR Rd, Rs

  1187 	{

  1188 		int dest  = opcode & 7;

  1189 		u32 value = reg[(opcode >> 3) & 7].B.B0;

  1190 

  1191 		if (value)

  1192 		{

  1193 			value = value & 0x1f;

  1194 			if (value == 0)

  1195 			{

  1196 				C_FLAG = (reg[dest].I & 0x80000000 ? true : false);

  1197 			}

  1198 			else

  1199 			{

  1200 				ROR_RD_RS;

  1201 				reg[dest].I = value;

  1202 			}

  1203 		}

  1204 		clockTicks++;

  1205 		N_FLAG = reg[dest].I & 0x80000000 ? true : false;

  1206 		Z_FLAG = reg[dest].I ? false : true;

  1207 	}

  1208 	break;

  1209 	}

  1210 	break;

  1211 case 0x42:

  1212 	switch ((opcode >> 6) & 3)

  1213 	{

  1214 	case 0x00:

  1215 	{

  1216 		// TST Rd, Rs

  1217 		u32 value = reg[opcode & 7].I & reg[(opcode >> 3) & 7].I;

  1218 		N_FLAG = value & 0x80000000 ? true : false;

  1219 		Z_FLAG = value ? false : true;

  1220 	}

  1221 	break;

  1222 	case 0x01:

  1223 	{

  1224 		// NEG Rd, Rs

  1225 		int dest   = opcode & 7;

  1226 		int source = (opcode >> 3) & 7;

  1227 		NEG_RD_RS;

  1228 	}

  1229 	break;

  1230 	case 0x02:

  1231 	{

  1232 		// CMP Rd, Rs

  1233 		int dest  = opcode & 7;

  1234 		u32 value = reg[(opcode >> 3) & 7].I;

  1235 		CMP_RD_RS;

  1236 	}

  1237 	break;

  1238 	case 0x03:

  1239 	{

  1240 		// CMN Rd, Rs

  1241 		int dest  = opcode & 7;

  1242 		u32 value = reg[(opcode >> 3) & 7].I;

  1243 		// CMN

  1244 		CMN_RD_RS;

  1245 	}

  1246 	break;

  1247 	}

  1248 	break;

  1249 case 0x43:

  1250 	switch ((opcode >> 6) & 3)

  1251 	{

  1252 	case 0x00:

  1253 	{

  1254 		// ORR Rd, Rs

  1255 		int dest = opcode & 7;

  1256 		reg[dest].I |= reg[(opcode >> 3) & 7].I;

  1257 		Z_FLAG		 = reg[dest].I ? false : true;

  1258 		N_FLAG		 = reg[dest].I & 0x80000000 ? true : false;

  1259 	}

  1260 	break;

  1261 	case 0x01:

  1262 	{

  1263 		// MUL Rd, Rs

  1264 		int dest = opcode & 7;

  1265 		u32 rm	 = reg[(opcode >> 3) & 7].I;

  1266 		reg[dest].I = reg[dest].I * rm;

  1267 		if (((s32)rm) < 0)

  1268 			rm = ~rm;

  1269 		if ((rm & 0xFFFFFF00) == 0)

  1270 			clockTicks += 1;

  1271 		else if ((rm & 0xFFFF0000) == 0)

  1272 			clockTicks += 2;

  1273 		else if ((rm & 0xFF000000) == 0)

  1274 			clockTicks += 3;

  1275 		else

  1276 			clockTicks += 4;

  1277 		Z_FLAG = reg[dest].I ? false : true;

  1278 		N_FLAG = reg[dest].I & 0x80000000 ? true : false;

  1279 	}

  1280 	break;

  1281 	case 0x02:

  1282 	{

  1283 		// BIC Rd, Rs

  1284 		int dest = opcode & 7;

  1285 		reg[dest].I &= (~reg[(opcode >> 3) & 7].I);

  1286 		Z_FLAG		 = reg[dest].I ? false : true;

  1287 		N_FLAG		 = reg[dest].I & 0x80000000 ? true : false;

  1288 	}

  1289 	break;

  1290 	case 0x03:

  1291 	{

  1292 		// MVN Rd, Rs

  1293 		int dest = opcode & 7;

  1294 		reg[dest].I = ~reg[(opcode >> 3) & 7].I;

  1295 		Z_FLAG		= reg[dest].I ? false : true;

  1296 		N_FLAG		= reg[dest].I & 0x80000000 ? true : false;

  1297 	}

  1298 	break;

  1299 	}

  1300 	break;

  1301 case 0x44:

  1302 {

  1303 	int dest = opcode & 7;

  1304 	int base = (opcode >> 3) & 7;

  1305 	switch ((opcode >> 6) & 3)

  1306 	{

  1307 	default:

  1308 		goto unknown_thumb;

  1309 	case 1:

  1310 		// ADD Rd, Hs

  1311 		reg[dest].I += reg[base + 8].I;

  1312 		break;

  1313 	case 2:

  1314 		// ADD Hd, Rs

  1315 		reg[dest + 8].I += reg[base].I;

  1316 		if (dest == 7)

  1317 		{

  1318 			reg[15].I &= 0xFFFFFFFE;

  1319 			armNextPC  = reg[15].I;

  1320 			reg[15].I += 2;

  1321 			clockTicks++;

  1322 		}

  1323 		break;

  1324 	case 3:

  1325 		// ADD Hd, Hs

  1326 		reg[dest + 8].I += reg[base + 8].I;

  1327 		if (dest == 7)

  1328 		{

  1329 			reg[15].I &= 0xFFFFFFFE;

  1330 			armNextPC  = reg[15].I;

  1331 			reg[15].I += 2;

  1332 			clockTicks++;

  1333 		}

  1334 		break;

  1335 	}

  1336 }

  1337 break;

  1338 case 0x45:

  1339 {

  1340 	int dest = opcode & 7;

  1341 	int base = (opcode >> 3) & 7;

  1342 	u32 value;

  1343 	switch ((opcode >> 6) & 3)

  1344 	{

  1345 	case 0:

  1346 		// CMP Rd, Hs

  1347 		value = reg[base].I;

  1348 		CMP_RD_RS;

  1349 		break;

  1350 	case 1:

  1351 		// CMP Rd, Hs

  1352 		value = reg[base + 8].I;

  1353 		CMP_RD_RS;

  1354 		break;

  1355 	case 2:

  1356 		// CMP Hd, Rs

  1357 		value = reg[base].I;

  1358 		dest += 8;

  1359 		CMP_RD_RS;

  1360 		break;

  1361 	case 3:

  1362 		// CMP Hd, Hs

  1363 		value = reg[base + 8].I;

  1364 		dest += 8;

  1365 		CMP_RD_RS;

  1366 		break;

  1367 	}

  1368 }

  1369 break;

  1370 case 0x46:

  1371 {

  1372 	int dest = opcode & 7;

  1373 	int base = (opcode >> 3) & 7;

  1374 	switch ((opcode >> 6) & 3)

  1375 	{

  1376 	case 0:

  1377 		// this form should not be used...

  1378 		// MOV Rd, Rs

  1379 		reg[dest].I = reg[base].I;

  1380 		break;

  1381 	case 1:

  1382 		// MOV Rd, Hs

  1383 		reg[dest].I = reg[base + 8].I;

  1384 		break;

  1385 	case 2:

  1386 		// MOV Hd, Rs

  1387 		reg[dest + 8].I = reg[base].I;

  1388 		if (dest == 7)

  1389 		{

  1390 			reg[15].I &= 0xFFFFFFFE;

  1391 			armNextPC  = reg[15].I;

  1392 			reg[15].I += 2;

  1393 			clockTicks++;

  1394 		}

  1395 		break;

  1396 	case 3:

  1397 		// MOV Hd, Hs

  1398 		reg[dest + 8].I = reg[base + 8].I;

  1399 		if (dest == 7)

  1400 		{

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

  1402 			armNextPC  = reg[15].I;

  1403 			reg[15].I += 2;

  1404 			clockTicks++;

  1405 		}

  1406 		break;

  1407 	}

  1408 }

  1409 break;

  1410 case 0x47:

  1411 {

  1412 	int base = (opcode >> 3) & 7;

  1413 	switch ((opcode >> 6) & 3)

  1414 	{

  1415 	case 0:

  1416 		// BX Rs

  1417 		reg[15].I = (reg[base].I) & 0xFFFFFFFE;

  1418 		if (reg[base].I & 1)

  1419 		{

  1420 			armState   = false;

  1421 			armNextPC  = reg[15].I;

  1422 			reg[15].I += 2;

  1423 		}

  1424 		else

  1425 		{

  1426 			armState   = true;

  1427 			reg[15].I &= 0xFFFFFFFC;

  1428 			armNextPC  = reg[15].I;

  1429 			reg[15].I += 4;

  1430 		}

  1431 		break;

  1432 	case 1:

  1433 		// BX Hs

  1434 		reg[15].I = (reg[8 + base].I) & 0xFFFFFFFE;

  1435 		if (reg[8 + base].I & 1)

  1436 		{

  1437 			armState   = false;

  1438 			armNextPC  = reg[15].I;

  1439 			reg[15].I += 2;

  1440 		}

  1441 		else

  1442 		{

  1443 			armState   = true;

  1444 			reg[15].I &= 0xFFFFFFFC;

  1445 			armNextPC  = reg[15].I;

  1446 			reg[15].I += 4;

  1447 		}

  1448 		break;

  1449 	default:

  1450 		goto unknown_thumb;

  1451 	}

  1452 }

  1453 break;

  1454 case 0x48:

  1455 	// LDR R0,[PC, #Imm]

  1456 {

  1457 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1458 	reg[0].I	= CPUReadMemoryQuick(address);

  1459 	clockTicks += CPUUpdateTicksAccess32(address);

  1460 }

  1461 break;

  1462 case 0x49:

  1463 	// LDR R1,[PC, #Imm]

  1464 {

  1465 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1466 	reg[1].I	= CPUReadMemoryQuick(address);

  1467 	clockTicks += CPUUpdateTicksAccess32(address);

  1468 }

  1469 break;

  1470 case 0x4a:

  1471 	// LDR R2,[PC, #Imm]

  1472 {

  1473 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1474 	reg[2].I	= CPUReadMemoryQuick(address);

  1475 	clockTicks += CPUUpdateTicksAccess32(address);

  1476 }

  1477 break;

  1478 case 0x4b:

  1479 	// LDR R3,[PC, #Imm]

  1480 {

  1481 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1482 	reg[3].I	= CPUReadMemoryQuick(address);

  1483 	clockTicks += CPUUpdateTicksAccess32(address);

  1484 }

  1485 break;

  1486 case 0x4c:

  1487 	// LDR R4,[PC, #Imm]

  1488 {

  1489 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1490 	reg[4].I	= CPUReadMemoryQuick(address);

  1491 	clockTicks += CPUUpdateTicksAccess32(address);

  1492 }

  1493 break;

  1494 case 0x4d:

  1495 	// LDR R5,[PC, #Imm]

  1496 {

  1497 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1498 	reg[5].I	= CPUReadMemoryQuick(address);

  1499 	clockTicks += CPUUpdateTicksAccess32(address);

  1500 }

  1501 break;

  1502 case 0x4e:

  1503 	// LDR R6,[PC, #Imm]

  1504 {

  1505 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1506 	reg[6].I	= CPUReadMemoryQuick(address);

  1507 	clockTicks += CPUUpdateTicksAccess32(address);

  1508 }

  1509 break;

  1510 case 0x4f:

  1511 	// LDR R7,[PC, #Imm]

  1512 {

  1513 	u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);

  1514 	reg[7].I	= CPUReadMemoryQuick(address);

  1515 	clockTicks += CPUUpdateTicksAccess32(address);

  1516 }

  1517 break;

  1518 case 0x50:

  1519 case 0x51:

  1520 	// STR Rd, [Rs, Rn]

  1521 {

  1522 	u32

  1523 	    address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1524 	CPUWriteMemory(address,

  1525 	               reg[opcode & 7].I);

  1526 	clockTicks += CPUUpdateTicksAccess32(address);

  1527 }

  1528 break;

  1529 case 0x52:

  1530 case 0x53:

  1531 	// STRH Rd, [Rs, Rn]

  1532 {

  1533 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1534 	CPUWriteHalfWord(address,

  1535 	                 reg[opcode & 7].W.W0);

  1536 	clockTicks += CPUUpdateTicksAccess16(address);

  1537 }

  1538 break;

  1539 case 0x54:

  1540 case 0x55:

  1541 	// STRB Rd, [Rs, Rn]

  1542 {

  1543 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1544 	CPUWriteByte(address,

  1545 	             reg[opcode & 7].B.B0);

  1546 	clockTicks += CPUUpdateTicksAccess16(address);

  1547 }

  1548 break;

  1549 case 0x56:

  1550 case 0x57:

  1551 	// LDSB Rd, [Rs, Rn]

  1552 {

  1553 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1554 	reg[opcode & 7].I = (s8)CPUReadByte(address);

  1555 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1556 }

  1557 break;

  1558 case 0x58:

  1559 case 0x59:

  1560 	// LDR Rd, [Rs, Rn]

  1561 {

  1562 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1563 	reg[opcode & 7].I = CPUReadMemory(address);

  1564 	clockTicks		 += CPUUpdateTicksAccess32(address);

  1565 }

  1566 break;

  1567 case 0x5a:

  1568 case 0x5b:

  1569 	// LDRH Rd, [Rs, Rn]

  1570 {

  1571 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1572 	reg[opcode & 7].I = CPUReadHalfWord(address);

  1573 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1574 }

  1575 break;

  1576 case 0x5c:

  1577 case 0x5d:

  1578 	// LDRB Rd, [Rs, Rn]

  1579 {

  1580 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1581 	reg[opcode & 7].I = CPUReadByte(address);

  1582 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1583 }

  1584 break;

  1585 case 0x5e:

  1586 case 0x5f:

  1587 	// LDSH Rd, [Rs, Rn]

  1588 {

  1589 	u32 address = reg[(opcode >> 3) & 7].I + reg[(opcode >> 6) & 7].I;

  1590 	reg[opcode & 7].I = (s16)CPUReadHalfWordSigned(address);

  1591 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1592 }

  1593 break;

  1594 case 0x60:

  1595 case 0x61:

  1596 case 0x62:

  1597 case 0x63:

  1598 case 0x64:

  1599 case 0x65:

  1600 case 0x66:

  1601 case 0x67:

  1602 	// STR Rd, [Rs, #Imm]

  1603 {

  1604 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31) << 2);

  1605 	CPUWriteMemory(address,

  1606 	               reg[opcode & 7].I);

  1607 	clockTicks += CPUUpdateTicksAccess32(address);

  1608 }

  1609 break;

  1610 case 0x68:

  1611 case 0x69:

  1612 case 0x6a:

  1613 case 0x6b:

  1614 case 0x6c:

  1615 case 0x6d:

  1616 case 0x6e:

  1617 case 0x6f:

  1618 	// LDR Rd, [Rs, #Imm]

  1619 {

  1620 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31) << 2);

  1621 	reg[opcode & 7].I = CPUReadMemory(address);

  1622 	clockTicks		 += CPUUpdateTicksAccess32(address);

  1623 }

  1624 break;

  1625 case 0x70:

  1626 case 0x71:

  1627 case 0x72:

  1628 case 0x73:

  1629 case 0x74:

  1630 case 0x75:

  1631 case 0x76:

  1632 case 0x77:

  1633 	// STRB Rd, [Rs, #Imm]

  1634 {

  1635 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31));

  1636 	CPUWriteByte(address,

  1637 	             reg[opcode & 7].B.B0);

  1638 	clockTicks += CPUUpdateTicksAccess16(address);

  1639 }

  1640 break;

  1641 case 0x78:

  1642 case 0x79:

  1643 case 0x7a:

  1644 case 0x7b:

  1645 case 0x7c:

  1646 case 0x7d:

  1647 case 0x7e:

  1648 case 0x7f:

  1649 	// LDRB Rd, [Rs, #Imm]

  1650 {

  1651 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31));

  1652 	reg[opcode & 7].I = CPUReadByte(address);

  1653 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1654 }

  1655 break;

  1656 case 0x80:

  1657 case 0x81:

  1658 case 0x82:

  1659 case 0x83:

  1660 case 0x84:

  1661 case 0x85:

  1662 case 0x86:

  1663 case 0x87:

  1664 	// STRH Rd, [Rs, #Imm]

  1665 {

  1666 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31) << 1);

  1667 	CPUWriteHalfWord(address,

  1668 	                 reg[opcode & 7].W.W0);

  1669 	clockTicks += CPUUpdateTicksAccess16(address);

  1670 }

  1671 break;

  1672 case 0x88:

  1673 case 0x89:

  1674 case 0x8a:

  1675 case 0x8b:

  1676 case 0x8c:

  1677 case 0x8d:

  1678 case 0x8e:

  1679 case 0x8f:

  1680 	// LDRH Rd, [Rs, #Imm]

  1681 {

  1682 	u32 address = reg[(opcode >> 3) & 7].I + (((opcode >> 6) & 31) << 1);

  1683 	reg[opcode & 7].I = CPUReadHalfWord(address);

  1684 	clockTicks		 += CPUUpdateTicksAccess16(address);

  1685 }

  1686 break;

  1687 case 0x90:

  1688 	// STR R0, [SP, #Imm]

  1689 {

  1690 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1691 	CPUWriteMemory(address, reg[0].I);

  1692 	clockTicks += CPUUpdateTicksAccess32(address);

  1693 }

  1694 break;

  1695 case 0x91:

  1696 	// STR R1, [SP, #Imm]

  1697 {

  1698 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1699 	CPUWriteMemory(address, reg[1].I);

  1700 	clockTicks += CPUUpdateTicksAccess32(address);

  1701 }

  1702 break;

  1703 case 0x92:

  1704 	// STR R2, [SP, #Imm]

  1705 {

  1706 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1707 	CPUWriteMemory(address, reg[2].I);

  1708 	clockTicks += CPUUpdateTicksAccess32(address);

  1709 }

  1710 break;

  1711 case 0x93:

  1712 	// STR R3, [SP, #Imm]

  1713 {

  1714 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1715 	CPUWriteMemory(address, reg[3].I);

  1716 	clockTicks += CPUUpdateTicksAccess32(address);

  1717 }

  1718 break;

  1719 case 0x94:

  1720 	// STR R4, [SP, #Imm]

  1721 {

  1722 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1723 	CPUWriteMemory(address, reg[4].I);

  1724 	clockTicks += CPUUpdateTicksAccess32(address);

  1725 }

  1726 break;

  1727 case 0x95:

  1728 	// STR R5, [SP, #Imm]

  1729 {

  1730 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1731 	CPUWriteMemory(address, reg[5].I);

  1732 	clockTicks += CPUUpdateTicksAccess32(address);

  1733 }

  1734 break;

  1735 case 0x96:

  1736 	// STR R6, [SP, #Imm]

  1737 {

  1738 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1739 	CPUWriteMemory(address, reg[6].I);

  1740 	clockTicks += CPUUpdateTicksAccess32(address);

  1741 }

  1742 break;

  1743 case 0x97:

  1744 	// STR R7, [SP, #Imm]

  1745 {

  1746 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1747 	CPUWriteMemory(address, reg[7].I);

  1748 	clockTicks += CPUUpdateTicksAccess32(address);

  1749 }

  1750 break;

  1751 case 0x98:

  1752 	// LDR R0, [SP, #Imm]

  1753 {

  1754 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1755 	reg[0].I	= CPUReadMemoryQuick(address);

  1756 	clockTicks += CPUUpdateTicksAccess32(address);

  1757 }

  1758 break;

  1759 case 0x99:

  1760 	// LDR R1, [SP, #Imm]

  1761 {

  1762 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1763 	reg[1].I	= CPUReadMemoryQuick(address);

  1764 	clockTicks += CPUUpdateTicksAccess32(address);

  1765 }

  1766 break;

  1767 case 0x9a:

  1768 	// LDR R2, [SP, #Imm]

  1769 {

  1770 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1771 	reg[2].I	= CPUReadMemoryQuick(address);

  1772 	clockTicks += CPUUpdateTicksAccess32(address);

  1773 }

  1774 break;

  1775 case 0x9b:

  1776 	// LDR R3, [SP, #Imm]

  1777 {

  1778 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1779 	reg[3].I	= CPUReadMemoryQuick(address);

  1780 	clockTicks += CPUUpdateTicksAccess32(address);

  1781 }

  1782 break;

  1783 case 0x9c:

  1784 	// LDR R4, [SP, #Imm]

  1785 {

  1786 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1787 	reg[4].I	= CPUReadMemoryQuick(address);

  1788 	clockTicks += CPUUpdateTicksAccess32(address);

  1789 }

  1790 break;

  1791 case 0x9d:

  1792 	// LDR R5, [SP, #Imm]

  1793 {

  1794 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1795 	reg[5].I	= CPUReadMemoryQuick(address);

  1796 	clockTicks += CPUUpdateTicksAccess32(address);

  1797 }

  1798 break;

  1799 case 0x9e:

  1800 	// LDR R6, [SP, #Imm]

  1801 {

  1802 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1803 	reg[6].I	= CPUReadMemoryQuick(address);

  1804 	clockTicks += CPUUpdateTicksAccess32(address);

  1805 }

  1806 break;

  1807 case 0x9f:

  1808 	// LDR R7, [SP, #Imm]

  1809 {

  1810 	u32 address = reg[13].I + ((opcode & 255) << 2);

  1811 	reg[7].I	= CPUReadMemoryQuick(address);

  1812 	clockTicks += CPUUpdateTicksAccess32(address);

  1813 }

  1814 break;

  1815 case 0xa0:

  1816 	// ADD R0, PC, Imm

  1817 	reg[0].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1818 	break;

  1819 case 0xa1:

  1820 	// ADD R1, PC, Imm

  1821 	reg[1].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1822 	break;

  1823 case 0xa2:

  1824 	// ADD R2, PC, Imm

  1825 	reg[2].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1826 	break;

  1827 case 0xa3:

  1828 	// ADD R3, PC, Imm

  1829 	reg[3].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1830 	break;

  1831 case 0xa4:

  1832 	// ADD R4, PC, Imm

  1833 	reg[4].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1834 	break;

  1835 case 0xa5:

  1836 	// ADD R5, PC, Imm

  1837 	reg[5].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1838 	break;

  1839 case 0xa6:

  1840 	// ADD R6, PC, Imm

  1841 	reg[6].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1842 	break;

  1843 case 0xa7:

  1844 	// ADD R7, PC, Imm

  1845 	reg[7].I = (reg[15].I & 0xFFFFFFFC) + ((opcode & 255) << 2);

  1846 	break;

  1847 case 0xa8:

  1848 	// ADD R0, SP, Imm

  1849 	reg[0].I = reg[13].I + ((opcode & 255) << 2);

  1850 	break;

  1851 case 0xa9:

  1852 	// ADD R1, SP, Imm

  1853 	reg[1].I = reg[13].I + ((opcode & 255) << 2);

  1854 	break;

  1855 case 0xaa:

  1856 	// ADD R2, SP, Imm

  1857 	reg[2].I = reg[13].I + ((opcode & 255) << 2);

  1858 	break;

  1859 case 0xab:

  1860 	// ADD R3, SP, Imm

  1861 	reg[3].I = reg[13].I + ((opcode & 255) << 2);

  1862 	break;

  1863 case 0xac:

  1864 	// ADD R4, SP, Imm

  1865 	reg[4].I = reg[13].I + ((opcode & 255) << 2);

  1866 	break;

  1867 case 0xad:

  1868 	// ADD R5, SP, Imm

  1869 	reg[5].I = reg[13].I + ((opcode & 255) << 2);

  1870 	break;

  1871 case 0xae:

  1872 	// ADD R6, SP, Imm

  1873 	reg[6].I = reg[13].I + ((opcode & 255) << 2);

  1874 	break;

  1875 case 0xaf:

  1876 	// ADD R7, SP, Imm

  1877 	reg[7].I = reg[13].I + ((opcode & 255) << 2);

  1878 	break;

  1879 case 0xb0:

  1880 {

  1881 	// ADD SP, Imm

  1882 	int offset = (opcode & 127) << 2;

  1883 	if (opcode & 0x80)

  1884 		offset = -offset;

  1885 	reg[13].I += offset;

  1886 }

  1887 break;

  1888 #define PUSH_REG(val, r) \

  1889 	if (opcode & (val)) { \

  1890 		CPUWriteMemory(address, reg[(r)].I); \

  1891 		if (offset) \

  1892 			clockTicks += 1 + CPUUpdateTicksAccessSeq32(address); \

  1893 		else \

  1894 			clockTicks += 1 + CPUUpdateTicksAccess32(address); \

  1895 		offset	 = 1; \

  1896 		address += 4; \

  1897 	}

  1898 case 0xb4:

  1899 	// PUSH {Rlist}

  1900 {

  1901 	int offset	= 0;

  1902 	u32 temp	= reg[13].I - 4 * cpuBitsSet[opcode & 0xff];

  1903 	u32 address = temp & 0xFFFFFFFC;

  1904 	PUSH_REG(1, 0);

  1905 	PUSH_REG(2, 1);

  1906 	PUSH_REG(4, 2);

  1907 	PUSH_REG(8, 3);

  1908 	PUSH_REG(16, 4);

  1909 	PUSH_REG(32, 5);

  1910 	PUSH_REG(64, 6);

  1911 	PUSH_REG(128, 7);

  1912 	reg[13].I = temp;

  1913 }

  1914 break;

  1915 case 0xb5:

  1916 	// PUSH {Rlist, LR}

  1917 {

  1918 	int offset	= 0;

  1919 	u32 temp	= reg[13].I - 4 - 4 * cpuBitsSet[opcode & 0xff];

  1920 	u32 address = temp & 0xFFFFFFFC;

  1921 	PUSH_REG(1, 0);

  1922 	PUSH_REG(2, 1);

  1923 	PUSH_REG(4, 2);

  1924 	PUSH_REG(8, 3);

  1925 	PUSH_REG(16, 4);

  1926 	PUSH_REG(32, 5);

  1927 	PUSH_REG(64, 6);

  1928 	PUSH_REG(128, 7);

  1929 	PUSH_REG(256, 14);

  1930 	reg[13].I = temp;

  1931 }

  1932 break;

  1933 #define POP_REG(val, r) \

  1934 	if (opcode & (val)) { \

  1935 		reg[(r)].I = CPUReadMemory(address); \

  1936 		if (offset) \

  1937 			clockTicks += 2 + CPUUpdateTicksAccessSeq32(address); \

  1938 		else \

  1939 			clockTicks += 2 + CPUUpdateTicksAccess32(address); \

  1940 		offset	 = 1; \

  1941 		address += 4; \

  1942 	}

  1943 case 0xbc:

  1944 	// POP {Rlist}

  1945 {

  1946 	int offset	= 0;

  1947 	u32 address = reg[13].I & 0xFFFFFFFC;

  1948 	u32 temp	= reg[13].I + 4 * cpuBitsSet[opcode & 0xFF];

  1949 	POP_REG(1, 0);

  1950 	POP_REG(2, 1);

  1951 	POP_REG(4, 2);

  1952 	POP_REG(8, 3);

  1953 	POP_REG(16, 4);

  1954 	POP_REG(32, 5);

  1955 	POP_REG(64, 6);

  1956 	POP_REG(128, 7);

  1957 	reg[13].I = temp;

  1958 }

  1959 break;

  1960 case 0xbd:

  1961 	// POP {Rlist, PC}

  1962 {

  1963 	int offset	= 0;

  1964 	u32 address = reg[13].I & 0xFFFFFFFC;

  1965 	u32 temp	= reg[13].I + 4 + 4 * cpuBitsSet[opcode & 0xFF];

  1966 	POP_REG(1, 0);

  1967 	POP_REG(2, 1);

  1968 	POP_REG(4, 2);

  1969 	POP_REG(8, 3);

  1970 	POP_REG(16, 4);

  1971 	POP_REG(32, 5);

  1972 	POP_REG(64, 6);

  1973 	POP_REG(128, 7);

  1974 	reg[15].I = (CPUReadMemory(address) & 0xFFFFFFFE);

  1975 	if (offset)

  1976 		clockTicks += CPUUpdateTicksAccessSeq32(address);

  1977 	else

  1978 		clockTicks += CPUUpdateTicksAccess32(address);

  1979 	armNextPC  = reg[15].I;

  1980 	reg[15].I += 2;

  1981 	reg[13].I  = temp;

  1982 }

  1983 break;

  1984 #define THUMB_STM_REG(val, r, b) \

  1985 	if (opcode & (val)) { \

  1986 		CPUWriteMemory(address, reg[(r)].I); \

  1987 		if (!offset) { \

  1988 			reg[(b)].I	= temp; \

  1989 			clockTicks += 1 + CPUUpdateTicksAccess32(address); \

  1990 		} else \

  1991 			clockTicks += 1 + CPUUpdateTicksAccessSeq32(address); \

  1992 		offset	 = 1; \

  1993 		address += 4; \

  1994 	}

  1995 case 0xc0:

  1996 {

  1997 	// STM R0!, {Rlist}

  1998 	u32 address = reg[0].I & 0xFFFFFFFC;

  1999 	u32 temp	= reg[0].I + 4 * cpuBitsSet[opcode & 0xff];

  2000 	int offset	= 0;

  2001 	// store

  2002 	THUMB_STM_REG(1, 0, 0);

  2003 	THUMB_STM_REG(2, 1, 0);

  2004 	THUMB_STM_REG(4, 2, 0);

  2005 	THUMB_STM_REG(8, 3, 0);

  2006 	THUMB_STM_REG(16, 4, 0);

  2007 	THUMB_STM_REG(32, 5, 0);

  2008 	THUMB_STM_REG(64, 6, 0);

  2009 	THUMB_STM_REG(128, 7, 0);

  2010 }

  2011 break;

  2012 case 0xc1:

  2013 {

  2014 	// STM R1!, {Rlist}

  2015 	u32 address = reg[1].I & 0xFFFFFFFC;

  2016 	u32 temp	= reg[1].I + 4 * cpuBitsSet[opcode & 0xff];

  2017 	int offset	= 0;

  2018 	// store

  2019 	THUMB_STM_REG(1, 0, 1);

  2020 	THUMB_STM_REG(2, 1, 1);

  2021 	THUMB_STM_REG(4, 2, 1);

  2022 	THUMB_STM_REG(8, 3, 1);

  2023 	THUMB_STM_REG(16, 4, 1);

  2024 	THUMB_STM_REG(32, 5, 1);

  2025 	THUMB_STM_REG(64, 6, 1);

  2026 	THUMB_STM_REG(128, 7, 1);

  2027 }

  2028 break;

  2029 case 0xc2:

  2030 {

  2031 	// STM R2!, {Rlist}

  2032 	u32 address = reg[2].I & 0xFFFFFFFC;

  2033 	u32 temp	= reg[2].I + 4 * cpuBitsSet[opcode & 0xff];

  2034 	int offset	= 0;

  2035 	// store

  2036 	THUMB_STM_REG(1, 0, 2);

  2037 	THUMB_STM_REG(2, 1, 2);

  2038 	THUMB_STM_REG(4, 2, 2);

  2039 	THUMB_STM_REG(8, 3, 2);

  2040 	THUMB_STM_REG(16, 4, 2);

  2041 	THUMB_STM_REG(32, 5, 2);

  2042 	THUMB_STM_REG(64, 6, 2);

  2043 	THUMB_STM_REG(128, 7, 2);

  2044 }

  2045 break;

  2046 case 0xc3:

  2047 {

  2048 	// STM R3!, {Rlist}

  2049 	u32 address = reg[3].I & 0xFFFFFFFC;

  2050 	u32 temp	= reg[3].I + 4 * cpuBitsSet[opcode & 0xff];

  2051 	int offset	= 0;

  2052 	// store

  2053 	THUMB_STM_REG(1, 0, 3);

  2054 	THUMB_STM_REG(2, 1, 3);

  2055 	THUMB_STM_REG(4, 2, 3);

  2056 	THUMB_STM_REG(8, 3, 3);

  2057 	THUMB_STM_REG(16, 4, 3);

  2058 	THUMB_STM_REG(32, 5, 3);

  2059 	THUMB_STM_REG(64, 6, 3);

  2060 	THUMB_STM_REG(128, 7, 3);

  2061 }

  2062 break;

  2063 case 0xc4:

  2064 {

  2065 	// STM R4!, {Rlist}

  2066 	u32 address = reg[4].I & 0xFFFFFFFC;

  2067 	u32 temp	= reg[4].I + 4 * cpuBitsSet[opcode & 0xff];

  2068 	int offset	= 0;

  2069 	// store

  2070 	THUMB_STM_REG(1, 0, 4);

  2071 	THUMB_STM_REG(2, 1, 4);

  2072 	THUMB_STM_REG(4, 2, 4);

  2073 	THUMB_STM_REG(8, 3, 4);

  2074 	THUMB_STM_REG(16, 4, 4);

  2075 	THUMB_STM_REG(32, 5, 4);

  2076 	THUMB_STM_REG(64, 6, 4);

  2077 	THUMB_STM_REG(128, 7, 4);

  2078 }

  2079 break;

  2080 case 0xc5:

  2081 {

  2082 	// STM R5!, {Rlist}

  2083 	u32 address = reg[5].I & 0xFFFFFFFC;

  2084 	u32 temp	= reg[5].I + 4 * cpuBitsSet[opcode & 0xff];

  2085 	int offset	= 0;

  2086 	// store

  2087 	THUMB_STM_REG(1, 0, 5);

  2088 	THUMB_STM_REG(2, 1, 5);

  2089 	THUMB_STM_REG(4, 2, 5);

  2090 	THUMB_STM_REG(8, 3, 5);

  2091 	THUMB_STM_REG(16, 4, 5);

  2092 	THUMB_STM_REG(32, 5, 5);

  2093 	THUMB_STM_REG(64, 6, 5);

  2094 	THUMB_STM_REG(128, 7, 5);

  2095 }

  2096 break;

  2097 case 0xc6:

  2098 {

  2099 	// STM R6!, {Rlist}

  2100 	u32 address = reg[6].I & 0xFFFFFFFC;

  2101 	u32 temp	= reg[6].I + 4 * cpuBitsSet[opcode & 0xff];

  2102 	int offset	= 0;

  2103 	// store

  2104 	THUMB_STM_REG(1, 0, 6);

  2105 	THUMB_STM_REG(2, 1, 6);

  2106 	THUMB_STM_REG(4, 2, 6);

  2107 	THUMB_STM_REG(8, 3, 6);

  2108 	THUMB_STM_REG(16, 4, 6);

  2109 	THUMB_STM_REG(32, 5, 6);

  2110 	THUMB_STM_REG(64, 6, 6);

  2111 	THUMB_STM_REG(128, 7, 6);

  2112 }

  2113 break;

  2114 case 0xc7:

  2115 {

  2116 	// STM R7!, {Rlist}

  2117 	u32 address = reg[7].I & 0xFFFFFFFC;

  2118 	u32 temp	= reg[7].I + 4 * cpuBitsSet[opcode & 0xff];

  2119 	int offset	= 0;

  2120 	// store

  2121 	THUMB_STM_REG(1, 0, 7);

  2122 	THUMB_STM_REG(2, 1, 7);

  2123 	THUMB_STM_REG(4, 2, 7);

  2124 	THUMB_STM_REG(8, 3, 7);

  2125 	THUMB_STM_REG(16, 4, 7);

  2126 	THUMB_STM_REG(32, 5, 7);

  2127 	THUMB_STM_REG(64, 6, 7);

  2128 	THUMB_STM_REG(128, 7, 7);

  2129 }

  2130 break;

  2131 #define THUMB_LDM_REG(val, r) \

  2132 	if (opcode & (val)) { \

  2133 		reg[(r)].I = CPUReadMemory(address); \

  2134 		if (offset) \

  2135 			clockTicks += 2 + CPUUpdateTicksAccessSeq32(address); \

  2136 		else \

  2137 			clockTicks += 2 + CPUUpdateTicksAccess32(address); \

  2138 		offset	 = 1; \

  2139 		address += 4; \

  2140 	}

  2141 case 0xc8:

  2142 {

  2143 	// LDM R0!, {Rlist}

  2144 	u32 address = reg[0].I & 0xFFFFFFFC;

  2145 	u32 temp	= reg[0].I + 4 * cpuBitsSet[opcode & 0xFF];

  2146 	int offset	= 0;

  2147 	// load

  2148 	THUMB_LDM_REG(1, 0);

  2149 	THUMB_LDM_REG(2, 1);

  2150 	THUMB_LDM_REG(4, 2);

  2151 	THUMB_LDM_REG(8, 3);

  2152 	THUMB_LDM_REG(16, 4);

  2153 	THUMB_LDM_REG(32, 5);

  2154 	THUMB_LDM_REG(64, 6);

  2155 	THUMB_LDM_REG(128, 7);

  2156 	if (!(opcode & 1))

  2157 		reg[0].I = temp;

  2158 }

  2159 break;

  2160 case 0xc9:

  2161 {

  2162 	// LDM R1!, {Rlist}

  2163 	u32 address = reg[1].I & 0xFFFFFFFC;

  2164 	u32 temp	= reg[1].I + 4 * cpuBitsSet[opcode & 0xFF];

  2165 	int offset	= 0;

  2166 	// load

  2167 	THUMB_LDM_REG(1, 0);

  2168 	THUMB_LDM_REG(2, 1);

  2169 	THUMB_LDM_REG(4, 2);

  2170 	THUMB_LDM_REG(8, 3);

  2171 	THUMB_LDM_REG(16, 4);

  2172 	THUMB_LDM_REG(32, 5);

  2173 	THUMB_LDM_REG(64, 6);

  2174 	THUMB_LDM_REG(128, 7);

  2175 	if (!(opcode & 2))

  2176 		reg[1].I = temp;

  2177 }

  2178 break;

  2179 case 0xca:

  2180 {

  2181 	// LDM R2!, {Rlist}

  2182 	u32 address = reg[2].I & 0xFFFFFFFC;

  2183 	u32 temp	= reg[2].I + 4 * cpuBitsSet[opcode & 0xFF];

  2184 	int offset	= 0;

  2185 	// load

  2186 	THUMB_LDM_REG(1, 0);

  2187 	THUMB_LDM_REG(2, 1);

  2188 	THUMB_LDM_REG(4, 2);

  2189 	THUMB_LDM_REG(8, 3);

  2190 	THUMB_LDM_REG(16, 4);

  2191 	THUMB_LDM_REG(32, 5);

  2192 	THUMB_LDM_REG(64, 6);

  2193 	THUMB_LDM_REG(128, 7);

  2194 	if (!(opcode & 4))

  2195 		reg[2].I = temp;

  2196 }

  2197 break;

  2198 case 0xcb:

  2199 {

  2200 	// LDM R3!, {Rlist}

  2201 	u32 address = reg[3].I & 0xFFFFFFFC;

  2202 	u32 temp	= reg[3].I + 4 * cpuBitsSet[opcode & 0xFF];

  2203 	int offset	= 0;

  2204 	// load

  2205 	THUMB_LDM_REG(1, 0);

  2206 	THUMB_LDM_REG(2, 1);

  2207 	THUMB_LDM_REG(4, 2);

  2208 	THUMB_LDM_REG(8, 3);

  2209 	THUMB_LDM_REG(16, 4);

  2210 	THUMB_LDM_REG(32, 5);

  2211 	THUMB_LDM_REG(64, 6);

  2212 	THUMB_LDM_REG(128, 7);

  2213 	if (!(opcode & 8))

  2214 		reg[3].I = temp;

  2215 }

  2216 break;

  2217 case 0xcc:

  2218 {

  2219 	// LDM R4!, {Rlist}

  2220 	u32 address = reg[4].I & 0xFFFFFFFC;

  2221 	u32 temp	= reg[4].I + 4 * cpuBitsSet[opcode & 0xFF];

  2222 	int offset	= 0;

  2223 	// load

  2224 	THUMB_LDM_REG(1, 0);

  2225 	THUMB_LDM_REG(2, 1);

  2226 	THUMB_LDM_REG(4, 2);

  2227 	THUMB_LDM_REG(8, 3);

  2228 	THUMB_LDM_REG(16, 4);

  2229 	THUMB_LDM_REG(32, 5);

  2230 	THUMB_LDM_REG(64, 6);

  2231 	THUMB_LDM_REG(128, 7);

  2232 	if (!(opcode & 16))

  2233 		reg[4].I = temp;

  2234 }

  2235 break;

  2236 case 0xcd:

  2237 {

  2238 	// LDM R5!, {Rlist}

  2239 	u32 address = reg[5].I & 0xFFFFFFFC;

  2240 	u32 temp	= reg[5].I + 4 * cpuBitsSet[opcode & 0xFF];

  2241 	int offset	= 0;

  2242 	// load

  2243 	THUMB_LDM_REG(1, 0);

  2244 	THUMB_LDM_REG(2, 1);

  2245 	THUMB_LDM_REG(4, 2);

  2246 	THUMB_LDM_REG(8, 3);

  2247 	THUMB_LDM_REG(16, 4);

  2248 	THUMB_LDM_REG(32, 5);

  2249 	THUMB_LDM_REG(64, 6);

  2250 	THUMB_LDM_REG(128, 7);

  2251 	if (!(opcode & 32))

  2252 		reg[5].I = temp;

  2253 }

  2254 break;

  2255 case 0xce:

  2256 {

  2257 	// LDM R6!, {Rlist}

  2258 	u32 address = reg[6].I & 0xFFFFFFFC;

  2259 	u32 temp	= reg[6].I + 4 * cpuBitsSet[opcode & 0xFF];

  2260 	int offset	= 0;

  2261 	// load

  2262 	THUMB_LDM_REG(1, 0);

  2263 	THUMB_LDM_REG(2, 1);

  2264 	THUMB_LDM_REG(4, 2);

  2265 	THUMB_LDM_REG(8, 3);

  2266 	THUMB_LDM_REG(16, 4);

  2267 	THUMB_LDM_REG(32, 5);

  2268 	THUMB_LDM_REG(64, 6);

  2269 	THUMB_LDM_REG(128, 7);

  2270 	if (!(opcode & 64))

  2271 		reg[6].I = temp;

  2272 }

  2273 break;

  2274 case 0xcf:

  2275 {

  2276 	// LDM R7!, {Rlist}

  2277 	u32 address = reg[7].I & 0xFFFFFFFC;

  2278 	u32 temp	= reg[7].I + 4 * cpuBitsSet[opcode & 0xFF];

  2279 	int offset	= 0;

  2280 	// load

  2281 	THUMB_LDM_REG(1, 0);

  2282 	THUMB_LDM_REG(2, 1);

  2283 	THUMB_LDM_REG(4, 2);

  2284 	THUMB_LDM_REG(8, 3);

  2285 	THUMB_LDM_REG(16, 4);

  2286 	THUMB_LDM_REG(32, 5);

  2287 	THUMB_LDM_REG(64, 6);

  2288 	THUMB_LDM_REG(128, 7);

  2289 	if (!(opcode & 128))

  2290 		reg[7].I = temp;

  2291 }

  2292 break;

  2293 case 0xd0:

  2294 	// BEQ offset

  2295 	if (Z_FLAG)

  2296 	{

  2297 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2298 		armNextPC  = reg[15].I;

  2299 		reg[15].I += 2;

  2300 		clockTicks = 3;

  2301 	}

  2302 	break;

  2303 case 0xd1:

  2304 	// BNE offset

  2305 	if (!Z_FLAG)

  2306 	{

  2307 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2308 		armNextPC  = reg[15].I;

  2309 		reg[15].I += 2;

  2310 		clockTicks = 3;

  2311 	}

  2312 	break;

  2313 case 0xd2:

  2314 	// BCS offset

  2315 	if (C_FLAG)

  2316 	{

  2317 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2318 		armNextPC  = reg[15].I;

  2319 		reg[15].I += 2;

  2320 		clockTicks = 3;

  2321 	}

  2322 	break;

  2323 case 0xd3:

  2324 	// BCC offset

  2325 	if (!C_FLAG)

  2326 	{

  2327 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2328 		armNextPC  = reg[15].I;

  2329 		reg[15].I += 2;

  2330 		clockTicks = 3;

  2331 	}

  2332 	break;

  2333 case 0xd4:

  2334 	// BMI offset

  2335 	if (N_FLAG)

  2336 	{

  2337 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2338 		armNextPC  = reg[15].I;

  2339 		reg[15].I += 2;

  2340 		clockTicks = 3;

  2341 	}

  2342 	break;

  2343 case 0xd5:

  2344 	// BPL offset

  2345 	if (!N_FLAG)

  2346 	{

  2347 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2348 		armNextPC  = reg[15].I;

  2349 		reg[15].I += 2;

  2350 		clockTicks = 3;

  2351 	}

  2352 	break;

  2353 case 0xd6:

  2354 	// BVS offset

  2355 	if (V_FLAG)

  2356 	{

  2357 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2358 		armNextPC  = reg[15].I;

  2359 		reg[15].I += 2;

  2360 		clockTicks = 3;

  2361 	}

  2362 	break;

  2363 case 0xd7:

  2364 	// BVC offset

  2365 	if (!V_FLAG)

  2366 	{

  2367 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2368 		armNextPC  = reg[15].I;

  2369 		reg[15].I += 2;

  2370 		clockTicks = 3;

  2371 	}

  2372 	break;

  2373 case 0xd8:

  2374 	// BHI offset

  2375 	if (C_FLAG && !Z_FLAG)

  2376 	{

  2377 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2378 		armNextPC  = reg[15].I;

  2379 		reg[15].I += 2;

  2380 		clockTicks = 3;

  2381 	}

  2382 	break;

  2383 case 0xd9:

  2384 	// BLS offset

  2385 	if (!C_FLAG || Z_FLAG)

  2386 	{

  2387 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2388 		armNextPC  = reg[15].I;

  2389 		reg[15].I += 2;

  2390 		clockTicks = 3;

  2391 	}

  2392 	break;

  2393 case 0xda:

  2394 	// BGE offset

  2395 	if (N_FLAG == V_FLAG)

  2396 	{

  2397 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2398 		armNextPC  = reg[15].I;

  2399 		reg[15].I += 2;

  2400 		clockTicks = 3;

  2401 	}

  2402 	break;

  2403 case 0xdb:

  2404 	// BLT offset

  2405 	if (N_FLAG != V_FLAG)

  2406 	{

  2407 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2408 		armNextPC  = reg[15].I;

  2409 		reg[15].I += 2;

  2410 		clockTicks = 3;

  2411 	}

  2412 	break;

  2413 case 0xdc:

  2414 	// BGT offset

  2415 	if (!Z_FLAG && (N_FLAG == V_FLAG))

  2416 	{

  2417 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2418 		armNextPC  = reg[15].I;

  2419 		reg[15].I += 2;

  2420 		clockTicks = 3;

  2421 	}

  2422 	break;

  2423 case 0xdd:

  2424 	// BLE offset

  2425 	if (Z_FLAG || (N_FLAG != V_FLAG))

  2426 	{

  2427 		reg[15].I += ((s8)(opcode & 0xFF)) << 1;

  2428 		armNextPC  = reg[15].I;

  2429 		reg[15].I += 2;

  2430 		clockTicks = 3;

  2431 	}

  2432 	break;

  2433 case 0xdf:

  2434 	// SWI #comment

  2435 	CPUSoftwareInterrupt(opcode & 0xFF);

  2436 	break;

  2437 case 0xe0:

  2438 case 0xe1:

  2439 case 0xe2:

  2440 case 0xe3:

  2441 case 0xe4:

  2442 case 0xe5:

  2443 case 0xe6:

  2444 case 0xe7:

  2445 {

  2446 	// B offset

  2447 	int offset = (opcode & 0x3FF) << 1;

  2448 	if (opcode & 0x0400)

  2449 		offset |= 0xFFFFF800;

  2450 	reg[15].I += offset;

  2451 	armNextPC  = reg[15].I;

  2452 	reg[15].I += 2;

  2453 }

  2454 break;

  2455 case 0xf0:

  2456 case 0xf1:

  2457 case 0xf2:

  2458 case 0xf3:

  2459 {

  2460 	// BLL #offset

  2461 	int offset = (opcode & 0x7FF);

  2462 	reg[14].I = reg[15].I + (offset << 12);

  2463 }

  2464 break;

  2465 case 0xf4:

  2466 case 0xf5:

  2467 case 0xf6:

  2468 case 0xf7:

  2469 {

  2470 	// BLL #offset

  2471 	int offset = (opcode & 0x7FF);

  2472 	reg[14].I = reg[15].I + ((offset << 12) | 0xFF800000);

  2473 }

  2474 break;

  2475 case 0xf8:

  2476 case 0xf9:

  2477 case 0xfa:

  2478 case 0xfb:

  2479 case 0xfc:

  2480 case 0xfd:

  2481 case 0xfe:

  2482 case 0xff:

  2483 {

  2484 	// BLH #offset

  2485 	int offset = (opcode & 0x7FF);

  2486 	u32 temp   = reg[15].I - 2;

  2487 	reg[15].I  = (reg[14].I + (offset << 1)) & 0xFFFFFFFE;

  2488 	armNextPC  = reg[15].I;

  2489 	reg[15].I += 2;

  2490 	reg[14].I  = temp | 1;

  2491 }

  2492 break;

  2493 #ifdef BKPT_SUPPORT

  2494 case 0xbe:

  2495 	// BKPT #comment

  2496 	extern void (*dbgSignal)(int, int);

  2497 	reg[15].I -= 2;

  2498 	armNextPC -= 2;

  2499 	dbgSignal(5, opcode & 255);

  2500 	return;

  2501 #endif

  2502 case 0xb1:

  2503 case 0xb2:

  2504 case 0xb3:

  2505 case 0xb6:

  2506 case 0xb7:

  2507 case 0xb8:

  2508 case 0xb9:

  2509 case 0xba:

  2510 case 0xbb:

  2511 #ifndef BKPT_SUPPORT

  2512 case 0xbe:

  2513 #endif

  2514 case 0xbf:

  2515 case 0xde:

  2516 default:

  2517 unknown_thumb:

  2518 #ifdef GBA_LOGGING

  2519 	if (systemVerbose & VERBOSE_UNDEFINED)

  2520 		log("Undefined THUMB instruction %04x at %08x\n", opcode, armNextPC - 2);

  2521 #endif

  2522 	CPUUndefinedException();

  2523 	break;

  2524 }
author	Robert McIntyre <rlm@mit.edu>
date	Mon, 25 Jun 2012 14:55:55 -0500
parents	f9f4f1b99eed
children