vbagx/source/vba/gba/GBA-thumb.cpp
2023-03-22 13:12:50 -06:00

2330 lines
77 KiB
C++

#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include "GBA.h"
#include "GBAcpu.h"
#include "GBAinline.h"
#include "Globals.h"
#include "EEprom.h"
#include "Flash.h"
#include "Sound.h"
#include "Sram.h"
#include "bios.h"
#include "Cheats.h"
#include "../NLS.h"
#include "elf.h"
#include "../Util.h"
#include "../System.h"
#include "agbprint.h"
#ifdef PROFILING
#include "prof/prof.h"
#endif
#ifdef _MSC_VER
#define snprintf _snprintf
#endif
///////////////////////////////////////////////////////////////////////////
static int clockTicks;
static INSN_REGPARM void thumbUnknownInsn(u32 opcode)
{
#ifdef GBA_LOGGING
if(systemVerbose & VERBOSE_UNDEFINED)
log("Undefined THUMB instruction %04x at %08x\n", opcode, armNextPC-2);
#endif
CPUUndefinedException();
}
#ifdef BKPT_SUPPORT
static INSN_REGPARM void thumbBreakpoint(u32 opcode)
{
reg[15].I -= 2;
armNextPC -= 2;
dbgSignal(5, opcode & 255);
clockTicks = -1;
}
#endif
// Common macros //////////////////////////////////////////////////////////
#ifdef BKPT_SUPPORT
# define THUMB_CONSOLE_OUTPUT(a,b) do { \
if ((opcode == 0x4000) && (reg[0].I == 0xC0DED00D)) { \
dbgOutput((a), (b)); \
} \
} while (0)
# define UPDATE_OLDREG do { \
if (debugger_last) { \
snprintf(oldbuffer, sizeof(oldbuffer), "%08X", \
armState ? reg[15].I - 4 : reg[15].I - 2); \
int i; \
for (i = 0; i < 18; i++) { \
oldreg[i] = reg[i].I; \
} \
} \
} while (0)
#else
# define THUMB_CONSOLE_OUTPUT(a,b)
# define UPDATE_OLDREG
#endif
#define NEG(i) ((i) >> 31)
#define POS(i) ((~(i)) >> 31)
#ifndef C_CORE
#ifdef __GNUC__
#ifdef __POWERPC__
#define ADD_RD_RS_RN(N) \
{ \
int Flags; \
int Result; \
asm volatile("addco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[source].I), \
"r" (reg[N].I) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define ADD_RD_RS_O3(N) \
{ \
int Flags; \
int Result; \
asm volatile("addco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[source].I), \
"r" (N) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define ADD_RD_RS_O3_0 ADD_RD_RS_O3
#define ADD_RN_O8(d) \
{\
int Flags; \
int Result; \
asm volatile("addco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[(d)].I), \
"r" (opcode & 255) \
); \
reg[(d)].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define CMN_RD_RS \
{\
int Flags; \
int Result; \
asm volatile("addco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[dest].I), \
"r" (value) \
); \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define ADC_RD_RS \
{\
int Flags; \
int Result; \
asm volatile("mtspr 1, %4\n" \ /* reg 1 is xer */
"addeo. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[dest].I), \
"r" (value), \
"r" (C_FLAG << 29) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define SUB_RD_RS_RN(N) \
{\
int Flags; \
int Result; \
asm volatile("subco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[source].I), \
"r" (reg[N].I) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define SUB_RD_RS_O3(N) \
{\
int Flags; \
int Result; \
asm volatile("subco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[source].I), \
"r" (N) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define SUB_RD_RS_O3_0 SUB_RD_RS_O3
#define SUB_RN_O8(d) \
{\
int Flags; \
int Result; \
asm volatile("subco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[(d)].I), \
"r" (opcode & 255) \
); \
reg[(d)].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define CMP_RN_O8(d) \
{\
int Flags; \
int Result; \
asm volatile("subco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[(d)].I), \
"r" (opcode & 255) \
); \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define SBC_RD_RS \
{\
int Flags; \
int Result; \
asm volatile("mtspr 1, %4\n" \ /* reg 1 is xer */
"subfeo. %0, %3, %2\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[dest].I), \
"r" (value), \
"r" (C_FLAG << 29) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define NEG_RD_RS \
{\
int Flags; \
int Result; \
asm volatile("subfco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[source].I), \
"r" (0) \
); \
reg[dest].I = Result; \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#define CMP_RD_RS \
{\
int Flags; \
int Result; \
asm volatile("subco. %0, %2, %3\n" \
"mcrxr cr1\n" \
"mfcr %1\n" \
: "=r" (Result), \
"=r" (Flags) \
: "r" (reg[dest].I), \
"r" (value) \
); \
Z_FLAG = (Flags >> 29) & 1; \
N_FLAG = (Flags >> 31) & 1; \
C_FLAG = (Flags >> 25) & 1; \
V_FLAG = (Flags >> 26) & 1; \
}
#else
#define EMIT1(op,arg) #op" "arg"; "
#define EMIT2(op,src,dest) #op" "src", "dest"; "
#define KONST(val) "$"#val
#define ASMVAR(cvar) ASMVAR2 (__USER_LABEL_PREFIX__, cvar)
#define ASMVAR2(prefix,cvar) STRING (prefix) cvar
#define STRING(x) #x
#define VAR(var) ASMVAR(#var)
#define REGREF1(index) ASMVAR("reg("index")")
#define REGREF2(index,scale) ASMVAR("reg(,"index","#scale")")
#define eax "%%eax"
#define ecx "%%ecx"
#define edx "%%edx"
#define ADD_RN_O8(d) \
asm ("andl $0xFF, %%eax;"\
"addl %%eax, %0;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setcb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: "=m" (reg[(d)].I));
#define CMN_RD_RS \
asm ("add %0, %1;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setcb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: \
: "r" (value), "r" (reg[dest].I):"1");
#define ADC_RD_RS \
asm (EMIT2(bt,KONST(0),VAR(C_FLAG)) \
"adc %1, %%ebx;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setcb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: "=b" (reg[dest].I)\
: "r" (value), "b" (reg[dest].I));
#define SUB_RN_O8(d) \
asm ("andl $0xFF, %%eax;"\
"subl %%eax, %0;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: "=m" (reg[(d)].I));
#define MOV_RN_O8(d) \
asm ("andl $0xFF, %%eax;"\
EMIT2(movb,KONST(0),VAR(N_FLAG)) \
"movl %%eax, %0;"\
EMIT1(setzb, VAR(Z_FLAG)) \
: "=m" (reg[(d)].I));
#define CMP_RN_O8(d) \
asm ("andl $0xFF, %%eax;"\
"cmpl %%eax, %0;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: \
: "m" (reg[(d)].I));
#define SBC_RD_RS \
asm volatile (EMIT2(bt,KONST(0),VAR(C_FLAG)) \
"cmc;"\
"sbb %1, %%ebx;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: "=b" (reg[dest].I)\
: "r" (value), "b" (reg[dest].I) : "cc", "memory");
#define LSL_RD_RS \
asm ("shl %%cl, %%eax;"\
EMIT1(setcb, VAR(C_FLAG)) \
: "=a" (value)\
: "a" (reg[dest].I), "c" (value));
#define LSR_RD_RS \
asm ("shr %%cl, %%eax;"\
EMIT1(setcb, VAR(C_FLAG)) \
: "=a" (value)\
: "a" (reg[dest].I), "c" (value));
#define ASR_RD_RS \
asm ("sar %%cl, %%eax;"\
EMIT1(setcb, VAR(C_FLAG)) \
: "=a" (value)\
: "a" (reg[dest].I), "c" (value));
#define ROR_RD_RS \
asm ("ror %%cl, %%eax;"\
EMIT1(setcb, VAR(C_FLAG)) \
: "=a" (value)\
: "a" (reg[dest].I), "c" (value));
#define NEG_RD_RS \
asm ("neg %%ebx;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: "=b" (reg[dest].I)\
: "b" (reg[source].I));
#define CMP_RD_RS \
asm ("sub %0, %1;"\
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG)) \
: \
: "r" (value), "r" (reg[dest].I):"1");
#define IMM5_INSN(OP,N) \
asm("movl %%eax,%%ecx;" \
"shrl $1,%%eax;" \
"andl $7,%%ecx;" \
"andl $0x1C,%%eax;" \
EMIT2(movl, REGREF1(eax), edx) \
OP \
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT2(movl, edx, REGREF2(ecx,4)) \
: : "i" (N))
#define IMM5_INSN_0(OP) \
asm("movl %%eax,%%ecx;" \
"shrl $1,%%eax;" \
"andl $7,%%ecx;" \
"andl $0x1C,%%eax;" \
EMIT2(movl, REGREF1(eax), edx) \
OP \
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT2(movl, edx, REGREF2(ecx,4)) \
: : )
#define IMM5_LSL \
"shll %0,%%edx;"\
EMIT1(setcb, VAR(C_FLAG))
#define IMM5_LSL_0 \
"testl %%edx,%%edx;"
#define IMM5_LSR \
"shrl %0,%%edx;"\
EMIT1(setcb, VAR(C_FLAG))
#define IMM5_LSR_0 \
"testl %%edx,%%edx;"\
EMIT1(setsb, VAR(C_FLAG)) \
"xorl %%edx,%%edx;"
#define IMM5_ASR \
"sarl %0,%%edx;"\
EMIT1(setcb, VAR(C_FLAG))
#define IMM5_ASR_0 \
"sarl $31,%%edx;"\
EMIT1(setsb, VAR(C_FLAG))
#define THREEARG_INSN(OP,N) \
asm("movl %%eax,%%edx;" \
"shrl $1,%%edx;" \
"andl $0x1C,%%edx;" \
"andl $7,%%eax;" \
EMIT2(movl, REGREF1(edx), ecx) \
OP(N) \
EMIT1(setsb, VAR(N_FLAG)) \
EMIT1(setzb, VAR(Z_FLAG)) \
EMIT2(movl, ecx, REGREF2(eax,4)) \
: : )
#define ADD_RD_RS_RN(N) \
EMIT2(add,VAR(reg)"+"#N"*4",ecx) \
EMIT1(setcb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG))
#define ADD_RD_RS_O3(N) \
"add $"#N",%%ecx;" \
EMIT1(setcb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG))
#define ADD_RD_RS_O3_0(N) \
EMIT2(movb,KONST(0),VAR(C_FLAG)) \
"add $0,%%ecx;" \
EMIT2(movb,KONST(0),VAR(V_FLAG))
#define SUB_RD_RS_RN(N) \
EMIT2(sub,VAR(reg)"+"#N"*4",ecx) \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG))
#define SUB_RD_RS_O3(N) \
"sub $"#N",%%ecx;" \
EMIT1(setncb, VAR(C_FLAG)) \
EMIT1(setob, VAR(V_FLAG))
#define SUB_RD_RS_O3_0(N) \
EMIT2(movb,KONST(1),VAR(C_FLAG)) \
"sub $0,%%ecx;" \
EMIT2(movb,KONST(0),VAR(V_FLAG))
#endif
#else // !__GNUC__
#define ADD_RD_RS_RN(N) \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm add ebx, dword ptr [OFFSET reg+4*N]\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define ADD_RD_RS_O3(N) \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm add ebx, N\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define ADD_RD_RS_O3_0 \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm add ebx, 0\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm mov byte ptr C_FLAG, 0\
__asm mov byte ptr V_FLAG, 0\
}
#define ADD_RN_O8(d) \
{\
__asm mov ebx, opcode\
__asm and ebx, 255\
__asm add dword ptr [OFFSET reg+4*(d)], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define CMN_RD_RS \
{\
__asm mov eax, dest\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm add ebx, value\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define ADC_RD_RS \
{\
__asm mov ebx, dest\
__asm mov ebx, dword ptr [OFFSET reg+4*ebx]\
__asm bt word ptr C_FLAG, 0\
__asm adc ebx, value\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define SUB_RD_RS_RN(N) \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm sub ebx, dword ptr [OFFSET reg+4*N]\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define SUB_RD_RS_O3(N) \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm sub ebx, N\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define SUB_RD_RS_O3_0 \
{\
__asm mov eax, source\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm sub ebx, 0\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm mov byte ptr C_FLAG, 1\
__asm mov byte ptr V_FLAG, 0\
}
#define SUB_RN_O8(d) \
{\
__asm mov ebx, opcode\
__asm and ebx, 255\
__asm sub dword ptr [OFFSET reg + 4*(d)], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define MOV_RN_O8(d) \
{\
__asm mov eax, opcode\
__asm and eax, 255\
__asm mov dword ptr [OFFSET reg+4*(d)], eax\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
}
#define CMP_RN_O8(d) \
{\
__asm mov eax, dword ptr [OFFSET reg+4*(d)]\
__asm mov ebx, opcode\
__asm and ebx, 255\
__asm sub eax, ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define SBC_RD_RS \
{\
__asm mov ebx, dest\
__asm mov ebx, dword ptr [OFFSET reg + 4*ebx]\
__asm mov eax, value\
__asm bt word ptr C_FLAG, 0\
__asm cmc\
__asm sbb ebx, eax\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg + 4*eax], ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define LSL_RD_RM_I5 \
{\
__asm mov eax, source\
__asm mov eax, dword ptr [OFFSET reg + 4 * eax]\
__asm mov cl, byte ptr shift\
__asm shl eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define LSL_RD_RS \
{\
__asm mov eax, dest\
__asm mov eax, dword ptr [OFFSET reg + 4 * eax]\
__asm mov cl, byte ptr value\
__asm shl eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define LSR_RD_RM_I5 \
{\
__asm mov eax, source\
__asm mov eax, dword ptr [OFFSET reg + 4 * eax]\
__asm mov cl, byte ptr shift\
__asm shr eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define LSR_RD_RS \
{\
__asm mov eax, dest\
__asm mov eax, dword ptr [OFFSET reg + 4 * eax]\
__asm mov cl, byte ptr value\
__asm shr eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define ASR_RD_RM_I5 \
{\
__asm mov eax, source\
__asm mov eax, dword ptr [OFFSET reg + 4*eax]\
__asm mov cl, byte ptr shift\
__asm sar eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define ASR_RD_RS \
{\
__asm mov eax, dest\
__asm mov eax, dword ptr [OFFSET reg + 4*eax]\
__asm mov cl, byte ptr value\
__asm sar eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define ROR_RD_RS \
{\
__asm mov eax, dest\
__asm mov eax, dword ptr [OFFSET reg + 4*eax]\
__asm mov cl, byte ptr value\
__asm ror eax, cl\
__asm mov value, eax\
__asm setc byte ptr C_FLAG\
}
#define NEG_RD_RS \
{\
__asm mov ebx, source\
__asm mov ebx, dword ptr [OFFSET reg+4*ebx]\
__asm neg ebx\
__asm mov eax, dest\
__asm mov dword ptr [OFFSET reg+4*eax],ebx\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#define CMP_RD_RS \
{\
__asm mov eax, dest\
__asm mov ebx, dword ptr [OFFSET reg+4*eax]\
__asm sub ebx, value\
__asm sets byte ptr N_FLAG\
__asm setz byte ptr Z_FLAG\
__asm setnc byte ptr C_FLAG\
__asm seto byte ptr V_FLAG\
}
#endif
#endif
// C core
#ifndef ADDCARRY
#define ADDCARRY(a, b, c) \
C_FLAG = ((NEG(a) & NEG(b)) |\
(NEG(a) & POS(c)) |\
(NEG(b) & POS(c))) ? true : false;
#endif
#ifndef ADDOVERFLOW
#define ADDOVERFLOW(a, b, c) \
V_FLAG = ((NEG(a) & NEG(b) & POS(c)) |\
(POS(a) & POS(b) & NEG(c))) ? true : false;
#endif
#ifndef SUBCARRY
#define SUBCARRY(a, b, c) \
C_FLAG = ((NEG(a) & POS(b)) |\
(NEG(a) & POS(c)) |\
(POS(b) & POS(c))) ? true : false;
#endif
#ifndef SUBOVERFLOW
#define SUBOVERFLOW(a, b, c)\
V_FLAG = ((NEG(a) & POS(b) & POS(c)) |\
(POS(a) & NEG(b) & NEG(c))) ? true : false;
#endif
#ifndef ADD_RD_RS_RN
#define ADD_RD_RS_RN(N) \
{\
u32 lhs = reg[source].I;\
u32 rhs = reg[N].I;\
u32 res = lhs + rhs;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
ADDCARRY(lhs, rhs, res);\
ADDOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef ADD_RD_RS_O3
#define ADD_RD_RS_O3(N) \
{\
u32 lhs = reg[source].I;\
u32 rhs = N;\
u32 res = lhs + rhs;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
ADDCARRY(lhs, rhs, res);\
ADDOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef ADD_RD_RS_O3_0
# define ADD_RD_RS_O3_0 ADD_RD_RS_O3
#endif
#ifndef ADD_RN_O8
#define ADD_RN_O8(d) \
{\
u32 lhs = reg[(d)].I;\
u32 rhs = (opcode & 255);\
u32 res = lhs + rhs;\
reg[(d)].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
ADDCARRY(lhs, rhs, res);\
ADDOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef CMN_RD_RS
#define CMN_RD_RS \
{\
u32 lhs = reg[dest].I;\
u32 rhs = value;\
u32 res = lhs + rhs;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
ADDCARRY(lhs, rhs, res);\
ADDOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef ADC_RD_RS
#define ADC_RD_RS \
{\
u32 lhs = reg[dest].I;\
u32 rhs = value;\
u32 res = lhs + rhs + (u32)C_FLAG;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
ADDCARRY(lhs, rhs, res);\
ADDOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef SUB_RD_RS_RN
#define SUB_RD_RS_RN(N) \
{\
u32 lhs = reg[source].I;\
u32 rhs = reg[N].I;\
u32 res = lhs - rhs;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef SUB_RD_RS_O3
#define SUB_RD_RS_O3(N) \
{\
u32 lhs = reg[source].I;\
u32 rhs = N;\
u32 res = lhs - rhs;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef SUB_RD_RS_O3_0
# define SUB_RD_RS_O3_0 SUB_RD_RS_O3
#endif
#ifndef SUB_RN_O8
#define SUB_RN_O8(d) \
{\
u32 lhs = reg[(d)].I;\
u32 rhs = (opcode & 255);\
u32 res = lhs - rhs;\
reg[(d)].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef MOV_RN_O8
#define MOV_RN_O8(d) \
{\
reg[d].I = opcode & 255;\
N_FLAG = false;\
Z_FLAG = (reg[d].I ? false : true);\
}
#endif
#ifndef CMP_RN_O8
#define CMP_RN_O8(d) \
{\
u32 lhs = reg[(d)].I;\
u32 rhs = (opcode & 255);\
u32 res = lhs - rhs;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef SBC_RD_RS
#define SBC_RD_RS \
{\
u32 lhs = reg[dest].I;\
u32 rhs = value;\
u32 res = lhs - rhs - !((u32)C_FLAG);\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef LSL_RD_RM_I5
#define LSL_RD_RM_I5 \
{\
C_FLAG = (reg[source].I >> (32 - shift)) & 1 ? true : false;\
value = reg[source].I << shift;\
}
#endif
#ifndef LSL_RD_RS
#define LSL_RD_RS \
{\
C_FLAG = (reg[dest].I >> (32 - value)) & 1 ? true : false;\
value = reg[dest].I << value;\
}
#endif
#ifndef LSR_RD_RM_I5
#define LSR_RD_RM_I5 \
{\
C_FLAG = (reg[source].I >> (shift - 1)) & 1 ? true : false;\
value = reg[source].I >> shift;\
}
#endif
#ifndef LSR_RD_RS
#define LSR_RD_RS \
{\
C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false;\
value = reg[dest].I >> value;\
}
#endif
#ifndef ASR_RD_RM_I5
#define ASR_RD_RM_I5 \
{\
C_FLAG = ((s32)reg[source].I >> (int)(shift - 1)) & 1 ? true : false;\
value = (s32)reg[source].I >> (int)shift;\
}
#endif
#ifndef ASR_RD_RS
#define ASR_RD_RS \
{\
C_FLAG = ((s32)reg[dest].I >> (int)(value - 1)) & 1 ? true : false;\
value = (s32)reg[dest].I >> (int)value;\
}
#endif
#ifndef ROR_RD_RS
#define ROR_RD_RS \
{\
C_FLAG = (reg[dest].I >> (value - 1)) & 1 ? true : false;\
value = ((reg[dest].I << (32 - value)) |\
(reg[dest].I >> value));\
}
#endif
#ifndef NEG_RD_RS
#define NEG_RD_RS \
{\
u32 lhs = reg[source].I;\
u32 rhs = 0;\
u32 res = rhs - lhs;\
reg[dest].I = res;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(rhs, lhs, res);\
SUBOVERFLOW(rhs, lhs, res);\
}
#endif
#ifndef CMP_RD_RS
#define CMP_RD_RS \
{\
u32 lhs = reg[dest].I;\
u32 rhs = value;\
u32 res = lhs - rhs;\
Z_FLAG = (res == 0) ? true : false;\
N_FLAG = NEG(res) ? true : false;\
SUBCARRY(lhs, rhs, res);\
SUBOVERFLOW(lhs, rhs, res);\
}
#endif
#ifndef IMM5_INSN
#define IMM5_INSN(OP,N) \
int dest = opcode & 0x07;\
int source = (opcode >> 3) & 0x07;\
u32 value;\
OP(N);\
reg[dest].I = value;\
N_FLAG = (value & 0x80000000 ? true : false);\
Z_FLAG = (value ? false : true);
#define IMM5_INSN_0(OP) \
int dest = opcode & 0x07;\
int source = (opcode >> 3) & 0x07;\
u32 value;\
OP;\
reg[dest].I = value;\
N_FLAG = (value & 0x80000000 ? true : false);\
Z_FLAG = (value ? false : true);
#define IMM5_LSL(N) \
int shift = N;\
LSL_RD_RM_I5;
#define IMM5_LSL_0 \
value = reg[source].I;
#define IMM5_LSR(N) \
int shift = N;\
LSR_RD_RM_I5;
#define IMM5_LSR_0 \
C_FLAG = reg[source].I & 0x80000000 ? true : false;\
value = 0;
#define IMM5_ASR(N) \
int shift = N;\
ASR_RD_RM_I5;
#define IMM5_ASR_0 \
if(reg[source].I & 0x80000000) {\
value = 0xFFFFFFFF;\
C_FLAG = true;\
} else {\
value = 0;\
C_FLAG = false;\
}
#endif
#ifndef THREEARG_INSN
#define THREEARG_INSN(OP,N) \
int dest = opcode & 0x07; \
int source = (opcode >> 3) & 0x07; \
OP(N);
#endif
// Shift instructions /////////////////////////////////////////////////////
#define DEFINE_IMM5_INSN(OP,BASE) \
static INSN_REGPARM void thumb##BASE##_00(u32 opcode) { IMM5_INSN_0(OP##_0); } \
static INSN_REGPARM void thumb##BASE##_01(u32 opcode) { IMM5_INSN(OP, 1); } \
static INSN_REGPARM void thumb##BASE##_02(u32 opcode) { IMM5_INSN(OP, 2); } \
static INSN_REGPARM void thumb##BASE##_03(u32 opcode) { IMM5_INSN(OP, 3); } \
static INSN_REGPARM void thumb##BASE##_04(u32 opcode) { IMM5_INSN(OP, 4); } \
static INSN_REGPARM void thumb##BASE##_05(u32 opcode) { IMM5_INSN(OP, 5); } \
static INSN_REGPARM void thumb##BASE##_06(u32 opcode) { IMM5_INSN(OP, 6); } \
static INSN_REGPARM void thumb##BASE##_07(u32 opcode) { IMM5_INSN(OP, 7); } \
static INSN_REGPARM void thumb##BASE##_08(u32 opcode) { IMM5_INSN(OP, 8); } \
static INSN_REGPARM void thumb##BASE##_09(u32 opcode) { IMM5_INSN(OP, 9); } \
static INSN_REGPARM void thumb##BASE##_0A(u32 opcode) { IMM5_INSN(OP,10); } \
static INSN_REGPARM void thumb##BASE##_0B(u32 opcode) { IMM5_INSN(OP,11); } \
static INSN_REGPARM void thumb##BASE##_0C(u32 opcode) { IMM5_INSN(OP,12); } \
static INSN_REGPARM void thumb##BASE##_0D(u32 opcode) { IMM5_INSN(OP,13); } \
static INSN_REGPARM void thumb##BASE##_0E(u32 opcode) { IMM5_INSN(OP,14); } \
static INSN_REGPARM void thumb##BASE##_0F(u32 opcode) { IMM5_INSN(OP,15); } \
static INSN_REGPARM void thumb##BASE##_10(u32 opcode) { IMM5_INSN(OP,16); } \
static INSN_REGPARM void thumb##BASE##_11(u32 opcode) { IMM5_INSN(OP,17); } \
static INSN_REGPARM void thumb##BASE##_12(u32 opcode) { IMM5_INSN(OP,18); } \
static INSN_REGPARM void thumb##BASE##_13(u32 opcode) { IMM5_INSN(OP,19); } \
static INSN_REGPARM void thumb##BASE##_14(u32 opcode) { IMM5_INSN(OP,20); } \
static INSN_REGPARM void thumb##BASE##_15(u32 opcode) { IMM5_INSN(OP,21); } \
static INSN_REGPARM void thumb##BASE##_16(u32 opcode) { IMM5_INSN(OP,22); } \
static INSN_REGPARM void thumb##BASE##_17(u32 opcode) { IMM5_INSN(OP,23); } \
static INSN_REGPARM void thumb##BASE##_18(u32 opcode) { IMM5_INSN(OP,24); } \
static INSN_REGPARM void thumb##BASE##_19(u32 opcode) { IMM5_INSN(OP,25); } \
static INSN_REGPARM void thumb##BASE##_1A(u32 opcode) { IMM5_INSN(OP,26); } \
static INSN_REGPARM void thumb##BASE##_1B(u32 opcode) { IMM5_INSN(OP,27); } \
static INSN_REGPARM void thumb##BASE##_1C(u32 opcode) { IMM5_INSN(OP,28); } \
static INSN_REGPARM void thumb##BASE##_1D(u32 opcode) { IMM5_INSN(OP,29); } \
static INSN_REGPARM void thumb##BASE##_1E(u32 opcode) { IMM5_INSN(OP,30); } \
static INSN_REGPARM void thumb##BASE##_1F(u32 opcode) { IMM5_INSN(OP,31); }
// LSL Rd, Rm, #Imm 5
DEFINE_IMM5_INSN(IMM5_LSL,00)
// LSR Rd, Rm, #Imm 5
DEFINE_IMM5_INSN(IMM5_LSR,08)
// ASR Rd, Rm, #Imm 5
DEFINE_IMM5_INSN(IMM5_ASR,10)
// 3-argument ADD/SUB /////////////////////////////////////////////////////
#define DEFINE_REG3_INSN(OP,BASE) \
static INSN_REGPARM void thumb##BASE##_0(u32 opcode) { THREEARG_INSN(OP,0); } \
static INSN_REGPARM void thumb##BASE##_1(u32 opcode) { THREEARG_INSN(OP,1); } \
static INSN_REGPARM void thumb##BASE##_2(u32 opcode) { THREEARG_INSN(OP,2); } \
static INSN_REGPARM void thumb##BASE##_3(u32 opcode) { THREEARG_INSN(OP,3); } \
static INSN_REGPARM void thumb##BASE##_4(u32 opcode) { THREEARG_INSN(OP,4); } \
static INSN_REGPARM void thumb##BASE##_5(u32 opcode) { THREEARG_INSN(OP,5); } \
static INSN_REGPARM void thumb##BASE##_6(u32 opcode) { THREEARG_INSN(OP,6); } \
static INSN_REGPARM void thumb##BASE##_7(u32 opcode) { THREEARG_INSN(OP,7); }
#define DEFINE_IMM3_INSN(OP,BASE) \
static INSN_REGPARM void thumb##BASE##_0(u32 opcode) { THREEARG_INSN(OP##_0,0); } \
static INSN_REGPARM void thumb##BASE##_1(u32 opcode) { THREEARG_INSN(OP,1); } \
static INSN_REGPARM void thumb##BASE##_2(u32 opcode) { THREEARG_INSN(OP,2); } \
static INSN_REGPARM void thumb##BASE##_3(u32 opcode) { THREEARG_INSN(OP,3); } \
static INSN_REGPARM void thumb##BASE##_4(u32 opcode) { THREEARG_INSN(OP,4); } \
static INSN_REGPARM void thumb##BASE##_5(u32 opcode) { THREEARG_INSN(OP,5); } \
static INSN_REGPARM void thumb##BASE##_6(u32 opcode) { THREEARG_INSN(OP,6); } \
static INSN_REGPARM void thumb##BASE##_7(u32 opcode) { THREEARG_INSN(OP,7); }
// ADD Rd, Rs, Rn
DEFINE_REG3_INSN(ADD_RD_RS_RN,18)
// SUB Rd, Rs, Rn
DEFINE_REG3_INSN(SUB_RD_RS_RN,1A)
// ADD Rd, Rs, #Offset3
DEFINE_IMM3_INSN(ADD_RD_RS_O3,1C)
// SUB Rd, Rs, #Offset3
DEFINE_IMM3_INSN(SUB_RD_RS_O3,1E)
// MOV/CMP/ADD/SUB immediate //////////////////////////////////////////////
// MOV R0, #Offset8
static INSN_REGPARM void thumb20(u32 opcode) { MOV_RN_O8(0); }
// MOV R1, #Offset8
static INSN_REGPARM void thumb21(u32 opcode) { MOV_RN_O8(1); }
// MOV R2, #Offset8
static INSN_REGPARM void thumb22(u32 opcode) { MOV_RN_O8(2); }
// MOV R3, #Offset8
static INSN_REGPARM void thumb23(u32 opcode) { MOV_RN_O8(3); }
// MOV R4, #Offset8
static INSN_REGPARM void thumb24(u32 opcode) { MOV_RN_O8(4); }
// MOV R5, #Offset8
static INSN_REGPARM void thumb25(u32 opcode) { MOV_RN_O8(5); }
// MOV R6, #Offset8
static INSN_REGPARM void thumb26(u32 opcode) { MOV_RN_O8(6); }
// MOV R7, #Offset8
static INSN_REGPARM void thumb27(u32 opcode) { MOV_RN_O8(7); }
// CMP R0, #Offset8
static INSN_REGPARM void thumb28(u32 opcode) { CMP_RN_O8(0); }
// CMP R1, #Offset8
static INSN_REGPARM void thumb29(u32 opcode) { CMP_RN_O8(1); }
// CMP R2, #Offset8
static INSN_REGPARM void thumb2A(u32 opcode) { CMP_RN_O8(2); }
// CMP R3, #Offset8
static INSN_REGPARM void thumb2B(u32 opcode) { CMP_RN_O8(3); }
// CMP R4, #Offset8
static INSN_REGPARM void thumb2C(u32 opcode) { CMP_RN_O8(4); }
// CMP R5, #Offset8
static INSN_REGPARM void thumb2D(u32 opcode) { CMP_RN_O8(5); }
// CMP R6, #Offset8
static INSN_REGPARM void thumb2E(u32 opcode) { CMP_RN_O8(6); }
// CMP R7, #Offset8
static INSN_REGPARM void thumb2F(u32 opcode) { CMP_RN_O8(7); }
// ADD R0,#Offset8
static INSN_REGPARM void thumb30(u32 opcode) { ADD_RN_O8(0); }
// ADD R1,#Offset8
static INSN_REGPARM void thumb31(u32 opcode) { ADD_RN_O8(1); }
// ADD R2,#Offset8
static INSN_REGPARM void thumb32(u32 opcode) { ADD_RN_O8(2); }
// ADD R3,#Offset8
static INSN_REGPARM void thumb33(u32 opcode) { ADD_RN_O8(3); }
// ADD R4,#Offset8
static INSN_REGPARM void thumb34(u32 opcode) { ADD_RN_O8(4); }
// ADD R5,#Offset8
static INSN_REGPARM void thumb35(u32 opcode) { ADD_RN_O8(5); }
// ADD R6,#Offset8
static INSN_REGPARM void thumb36(u32 opcode) { ADD_RN_O8(6); }
// ADD R7,#Offset8
static INSN_REGPARM void thumb37(u32 opcode) { ADD_RN_O8(7); }
// SUB R0,#Offset8
static INSN_REGPARM void thumb38(u32 opcode) { SUB_RN_O8(0); }
// SUB R1,#Offset8
static INSN_REGPARM void thumb39(u32 opcode) { SUB_RN_O8(1); }
// SUB R2,#Offset8
static INSN_REGPARM void thumb3A(u32 opcode) { SUB_RN_O8(2); }
// SUB R3,#Offset8
static INSN_REGPARM void thumb3B(u32 opcode) { SUB_RN_O8(3); }
// SUB R4,#Offset8
static INSN_REGPARM void thumb3C(u32 opcode) { SUB_RN_O8(4); }
// SUB R5,#Offset8
static INSN_REGPARM void thumb3D(u32 opcode) { SUB_RN_O8(5); }
// SUB R6,#Offset8
static INSN_REGPARM void thumb3E(u32 opcode) { SUB_RN_O8(6); }
// SUB R7,#Offset8
static INSN_REGPARM void thumb3F(u32 opcode) { SUB_RN_O8(7); }
// ALU operations /////////////////////////////////////////////////////////
// AND Rd, Rs
static INSN_REGPARM void thumb40_0(u32 opcode)
{
int dest = opcode & 7;
reg[dest].I &= reg[(opcode >> 3)&7].I;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
THUMB_CONSOLE_OUTPUT(NULL, reg[2].I);
}
// EOR Rd, Rs
static INSN_REGPARM void thumb40_1(u32 opcode)
{
int dest = opcode & 7;
reg[dest].I ^= reg[(opcode >> 3)&7].I;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
}
// LSL Rd, Rs
static INSN_REGPARM void thumb40_2(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].B.B0;
if(value) {
if(value == 32) {
value = 0;
C_FLAG = (reg[dest].I & 1 ? true : false);
} else if(value < 32) {
LSL_RD_RS;
} else {
value = 0;
C_FLAG = false;
}
reg[dest].I = value;
}
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
clockTicks = codeTicksAccess16(armNextPC)+2;
}
// LSR Rd, Rs
static INSN_REGPARM void thumb40_3(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].B.B0;
if(value) {
if(value == 32) {
value = 0;
C_FLAG = (reg[dest].I & 0x80000000 ? true : false);
} else if(value < 32) {
LSR_RD_RS;
} else {
value = 0;
C_FLAG = false;
}
reg[dest].I = value;
}
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
clockTicks = codeTicksAccess16(armNextPC)+2;
}
// ASR Rd, Rs
static INSN_REGPARM void thumb41_0(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].B.B0;
if(value) {
if(value < 32) {
ASR_RD_RS;
reg[dest].I = value;
} else {
if(reg[dest].I & 0x80000000){
reg[dest].I = 0xFFFFFFFF;
C_FLAG = true;
} else {
reg[dest].I = 0x00000000;
C_FLAG = false;
}
}
}
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
clockTicks = codeTicksAccess16(armNextPC)+2;
}
// ADC Rd, Rs
static INSN_REGPARM void thumb41_1(u32 opcode)
{
int dest = opcode & 0x07;
u32 value = reg[(opcode >> 3)&7].I;
ADC_RD_RS;
}
// SBC Rd, Rs
static INSN_REGPARM void thumb41_2(u32 opcode)
{
int dest = opcode & 0x07;
u32 value = reg[(opcode >> 3)&7].I;
SBC_RD_RS;
}
// ROR Rd, Rs
static INSN_REGPARM void thumb41_3(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].B.B0;
if(value) {
value = value & 0x1f;
if(value == 0) {
C_FLAG = (reg[dest].I & 0x80000000 ? true : false);
} else {
ROR_RD_RS;
reg[dest].I = value;
}
}
clockTicks = codeTicksAccess16(armNextPC)+2;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
Z_FLAG = reg[dest].I ? false : true;
}
// TST Rd, Rs
static INSN_REGPARM void thumb42_0(u32 opcode)
{
u32 value = reg[opcode & 7].I & reg[(opcode >> 3) & 7].I;
N_FLAG = value & 0x80000000 ? true : false;
Z_FLAG = value ? false : true;
}
// NEG Rd, Rs
static INSN_REGPARM void thumb42_1(u32 opcode)
{
int dest = opcode & 7;
int source = (opcode >> 3) & 7;
NEG_RD_RS;
}
// CMP Rd, Rs
static INSN_REGPARM void thumb42_2(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].I;
CMP_RD_RS;
}
// CMN Rd, Rs
static INSN_REGPARM void thumb42_3(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[(opcode >> 3)&7].I;
CMN_RD_RS;
}
// ORR Rd, Rs
static INSN_REGPARM void thumb43_0(u32 opcode)
{
int dest = opcode & 7;
reg[dest].I |= reg[(opcode >> 3) & 7].I;
Z_FLAG = reg[dest].I ? false : true;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
}
// MUL Rd, Rs
static INSN_REGPARM void thumb43_1(u32 opcode)
{
clockTicks = 1;
int dest = opcode & 7;
u32 rm = reg[dest].I;
reg[dest].I = reg[(opcode >> 3) & 7].I * rm;
if (((s32)rm) < 0)
rm = ~rm;
if ((rm & 0xFFFFFF00) == 0)
clockTicks += 0;
else if ((rm & 0xFFFF0000) == 0)
clockTicks += 1;
else if ((rm & 0xFF000000) == 0)
clockTicks += 2;
else
clockTicks += 3;
busPrefetchCount = (busPrefetchCount<<clockTicks) | (0xFF>>(8-clockTicks));
clockTicks += codeTicksAccess16(armNextPC) + 1;
Z_FLAG = reg[dest].I ? false : true;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
}
// BIC Rd, Rs
static INSN_REGPARM void thumb43_2(u32 opcode)
{
int dest = opcode & 7;
reg[dest].I &= (~reg[(opcode >> 3) & 7].I);
Z_FLAG = reg[dest].I ? false : true;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
}
// MVN Rd, Rs
static INSN_REGPARM void thumb43_3(u32 opcode)
{
int dest = opcode & 7;
reg[dest].I = ~reg[(opcode >> 3) & 7].I;
Z_FLAG = reg[dest].I ? false : true;
N_FLAG = reg[dest].I & 0x80000000 ? true : false;
}
// High-register instructions and BX //////////////////////////////////////
// ADD Rd, Hs
static INSN_REGPARM void thumb44_1(u32 opcode)
{
reg[opcode&7].I += reg[((opcode>>3)&7)+8].I;
}
// ADD Hd, Rs
static INSN_REGPARM void thumb44_2(u32 opcode)
{
reg[(opcode&7)+8].I += reg[(opcode>>3)&7].I;
if((opcode&7) == 7) {
reg[15].I &= 0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2
+ codeTicksAccess16(armNextPC) + 3;
}
}
// ADD Hd, Hs
static INSN_REGPARM void thumb44_3(u32 opcode)
{
reg[(opcode&7)+8].I += reg[((opcode>>3)&7)+8].I;
if((opcode&7) == 7) {
reg[15].I &= 0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2
+ codeTicksAccess16(armNextPC) + 3;
}
}
// CMP Rd, Hs
static INSN_REGPARM void thumb45_1(u32 opcode)
{
int dest = opcode & 7;
u32 value = reg[((opcode>>3)&7)+8].I;
CMP_RD_RS;
}
// CMP Hd, Rs
static INSN_REGPARM void thumb45_2(u32 opcode)
{
int dest = (opcode & 7) + 8;
u32 value = reg[(opcode>>3)&7].I;
CMP_RD_RS;
}
// CMP Hd, Hs
static INSN_REGPARM void thumb45_3(u32 opcode)
{
int dest = (opcode & 7) + 8;
u32 value = reg[((opcode>>3)&7)+8].I;
CMP_RD_RS;
}
// MOV Rd, Rs
static INSN_REGPARM void thumb46_0(u32 opcode)
{
reg[opcode&7].I = reg[((opcode>>3)&7)].I;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
}
// MOV Rd, Hs
static INSN_REGPARM void thumb46_1(u32 opcode)
{
reg[opcode&7].I = reg[((opcode>>3)&7)+8].I;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
}
// MOV Hd, Rs
static INSN_REGPARM void thumb46_2(u32 opcode)
{
reg[(opcode&7)+8].I = reg[(opcode>>3)&7].I;
if((opcode&7) == 7) {
UPDATE_OLDREG;
reg[15].I &= 0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2
+ codeTicksAccess16(armNextPC) + 3;
}
}
// MOV Hd, Hs
static INSN_REGPARM void thumb46_3(u32 opcode)
{
reg[(opcode&7)+8].I = reg[((opcode>>3)&7)+8].I;
if((opcode&7) == 7) {
UPDATE_OLDREG;
reg[15].I &= 0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2
+ codeTicksAccess16(armNextPC) + 3;
}
}
// BX Rs
static INSN_REGPARM void thumb47(u32 opcode)
{
int base = (opcode >> 3) & 15;
busPrefetchCount=0;
UPDATE_OLDREG;
reg[15].I = reg[base].I;
if(reg[base].I & 1) {
armState = false;
reg[15].I &= 0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2 + codeTicksAccess16(armNextPC) + 3;
} else {
armState = true;
reg[15].I &= 0xFFFFFFFC;
armNextPC = reg[15].I;
reg[15].I += 4;
ARM_PREFETCH;
clockTicks = codeTicksAccessSeq32(armNextPC)*2 + codeTicksAccess32(armNextPC) + 3;
}
}
// Load/store instructions ////////////////////////////////////////////////
// LDR R0~R7,[PC, #Imm]
static INSN_REGPARM void thumb48(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = (reg[15].I & 0xFFFFFFFC) + ((opcode & 0xFF) << 2);
reg[regist].I = CPUReadMemoryQuick(address);
busPrefetchCount=0;
clockTicks = 3 + dataTicksAccess32(address) + codeTicksAccess16(armNextPC);
}
// STR Rd, [Rs, Rn]
static INSN_REGPARM void thumb50(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
CPUWriteMemory(address, reg[opcode & 7].I);
clockTicks = dataTicksAccess32(address) + codeTicksAccess16(armNextPC) + 2;
}
// STRH Rd, [Rs, Rn]
static INSN_REGPARM void thumb52(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
CPUWriteHalfWord(address, reg[opcode&7].W.W0);
clockTicks = dataTicksAccess16(address) + codeTicksAccess16(armNextPC) + 2;
}
// STRB Rd, [Rs, Rn]
static INSN_REGPARM void thumb54(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode >>6)&7].I;
CPUWriteByte(address, reg[opcode & 7].B.B0);
clockTicks = dataTicksAccess16(address) + codeTicksAccess16(armNextPC) + 2;
}
// LDSB Rd, [Rs, Rn]
static INSN_REGPARM void thumb56(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
reg[opcode&7].I = (s8)CPUReadByte(address);
clockTicks = 3 + dataTicksAccess16(address) + codeTicksAccess16(armNextPC);
}
// LDR Rd, [Rs, Rn]
static INSN_REGPARM void thumb58(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
reg[opcode&7].I = CPUReadMemory(address);
clockTicks = 3 + dataTicksAccess32(address) + codeTicksAccess16(armNextPC);
}
// LDRH Rd, [Rs, Rn]
static INSN_REGPARM void thumb5A(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
reg[opcode&7].I = CPUReadHalfWord(address);
clockTicks = 3 + dataTicksAccess32(address) + codeTicksAccess16(armNextPC);
}
// LDRB Rd, [Rs, Rn]
static INSN_REGPARM void thumb5C(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
reg[opcode&7].I = CPUReadByte(address);
clockTicks = 3 + dataTicksAccess16(address) + codeTicksAccess16(armNextPC);
}
// LDSH Rd, [Rs, Rn]
static INSN_REGPARM void thumb5E(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + reg[(opcode>>6)&7].I;
reg[opcode&7].I = (u32)CPUReadHalfWordSigned(address);
clockTicks = 3 + dataTicksAccess16(address) + codeTicksAccess16(armNextPC);
}
// STR Rd, [Rs, #Imm]
static INSN_REGPARM void thumb60(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31)<<2);
CPUWriteMemory(address, reg[opcode&7].I);
clockTicks = dataTicksAccess32(address) + codeTicksAccess16(armNextPC) + 2;
}
// LDR Rd, [Rs, #Imm]
static INSN_REGPARM void thumb68(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31)<<2);
reg[opcode&7].I = CPUReadMemory(address);
clockTicks = 3 + dataTicksAccess32(address) + codeTicksAccess16(armNextPC);
}
// STRB Rd, [Rs, #Imm]
static INSN_REGPARM void thumb70(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31));
CPUWriteByte(address, reg[opcode&7].B.B0);
clockTicks = dataTicksAccess16(address) + codeTicksAccess16(armNextPC) + 2;
}
// LDRB Rd, [Rs, #Imm]
static INSN_REGPARM void thumb78(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31));
reg[opcode&7].I = CPUReadByte(address);
clockTicks = 3 + dataTicksAccess16(address) + codeTicksAccess16(armNextPC);
}
// STRH Rd, [Rs, #Imm]
static INSN_REGPARM void thumb80(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31)<<1);
CPUWriteHalfWord(address, reg[opcode&7].W.W0);
clockTicks = dataTicksAccess16(address) + codeTicksAccess16(armNextPC) + 2;
}
// LDRH Rd, [Rs, #Imm]
static INSN_REGPARM void thumb88(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[(opcode>>3)&7].I + (((opcode>>6)&31)<<1);
reg[opcode&7].I = CPUReadHalfWord(address);
clockTicks = 3 + dataTicksAccess16(address) + codeTicksAccess16(armNextPC);
}
// STR R0~R7, [SP, #Imm]
static INSN_REGPARM void thumb90(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[13].I + ((opcode&255)<<2);
CPUWriteMemory(address, reg[regist].I);
clockTicks = dataTicksAccess32(address) + codeTicksAccess16(armNextPC) + 2;
}
// LDR R0~R7, [SP, #Imm]
static INSN_REGPARM void thumb98(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[13].I + ((opcode&255)<<2);
reg[regist].I = CPUReadMemoryQuick(address);
clockTicks = 3 + dataTicksAccess32(address) + codeTicksAccess16(armNextPC);
}
// PC/stack-related ///////////////////////////////////////////////////////
// ADD R0~R7, PC, Imm
static INSN_REGPARM void thumbA0(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
reg[regist].I = (reg[15].I & 0xFFFFFFFC) + ((opcode&255)<<2);
clockTicks = 1 + codeTicksAccess16(armNextPC);
}
// ADD R0~R7, SP, Imm
static INSN_REGPARM void thumbA8(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
reg[regist].I = reg[13].I + ((opcode&255)<<2);
clockTicks = 1 + codeTicksAccess16(armNextPC);
}
// ADD SP, Imm
static INSN_REGPARM void thumbB0(u32 opcode)
{
int offset = (opcode & 127) << 2;
if(opcode & 0x80)
offset = -offset;
reg[13].I += offset;
clockTicks = 1 + codeTicksAccess16(armNextPC);
}
// Push and pop ///////////////////////////////////////////////////////////
#define PUSH_REG(val, r) \
if (opcode & (val)) { \
CPUWriteMemory(address, reg[(r)].I); \
if (!count) { \
clockTicks += 1 + dataTicksAccess32(address); \
} else { \
clockTicks += 1 + dataTicksAccessSeq32(address); \
} \
count++; \
address += 4; \
}
#define POP_REG(val, r) \
if (opcode & (val)) { \
reg[(r)].I = CPUReadMemory(address); \
if (!count) { \
clockTicks += 1 + dataTicksAccess32(address); \
} else { \
clockTicks += 1 + dataTicksAccessSeq32(address); \
} \
count++; \
address += 4; \
}
// PUSH {Rlist}
static INSN_REGPARM void thumbB4(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
int count = 0;
u32 temp = reg[13].I - 4 * cpuBitsSet[opcode & 0xff];
u32 address = temp & 0xFFFFFFFC;
PUSH_REG(1, 0);
PUSH_REG(2, 1);
PUSH_REG(4, 2);
PUSH_REG(8, 3);
PUSH_REG(16, 4);
PUSH_REG(32, 5);
PUSH_REG(64, 6);
PUSH_REG(128, 7);
clockTicks += 1 + codeTicksAccess16(armNextPC);
reg[13].I = temp;
}
// PUSH {Rlist, LR}
static INSN_REGPARM void thumbB5(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
int count = 0;
u32 temp = reg[13].I - 4 - 4 * cpuBitsSet[opcode & 0xff];
u32 address = temp & 0xFFFFFFFC;
PUSH_REG(1, 0);
PUSH_REG(2, 1);
PUSH_REG(4, 2);
PUSH_REG(8, 3);
PUSH_REG(16, 4);
PUSH_REG(32, 5);
PUSH_REG(64, 6);
PUSH_REG(128, 7);
PUSH_REG(256, 14);
clockTicks += 1 + codeTicksAccess16(armNextPC);
reg[13].I = temp;
}
// POP {Rlist}
static INSN_REGPARM void thumbBC(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
int count = 0;
u32 address = reg[13].I & 0xFFFFFFFC;
u32 temp = reg[13].I + 4*cpuBitsSet[opcode & 0xFF];
POP_REG(1, 0);
POP_REG(2, 1);
POP_REG(4, 2);
POP_REG(8, 3);
POP_REG(16, 4);
POP_REG(32, 5);
POP_REG(64, 6);
POP_REG(128, 7);
reg[13].I = temp;
clockTicks = 2 + codeTicksAccess16(armNextPC);
}
// POP {Rlist, PC}
static INSN_REGPARM void thumbBD(u32 opcode)
{
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
int count = 0;
u32 address = reg[13].I & 0xFFFFFFFC;
u32 temp = reg[13].I + 4 + 4*cpuBitsSet[opcode & 0xFF];
POP_REG(1, 0);
POP_REG(2, 1);
POP_REG(4, 2);
POP_REG(8, 3);
POP_REG(16, 4);
POP_REG(32, 5);
POP_REG(64, 6);
POP_REG(128, 7);
reg[15].I = (CPUReadMemory(address) & 0xFFFFFFFE);
if (!count) {
clockTicks += 1 + dataTicksAccess32(address);
} else {
clockTicks += 1 + dataTicksAccessSeq32(address);
}
count++;
armNextPC = reg[15].I;
reg[15].I += 2;
reg[13].I = temp;
THUMB_PREFETCH;
busPrefetchCount = 0;
clockTicks += 3 + codeTicksAccess16(armNextPC) + codeTicksAccess16(armNextPC);
}
// Load/store multiple ////////////////////////////////////////////////////
#define THUMB_STM_REG(val,r,b) \
if(opcode & (val)) { \
CPUWriteMemory(address, reg[(r)].I); \
reg[(b)].I = temp; \
if (!count) { \
clockTicks += 1 + dataTicksAccess32(address); \
} else { \
clockTicks += 1 + dataTicksAccessSeq32(address); \
} \
count++; \
address += 4; \
}
#define THUMB_LDM_REG(val,r) \
if(opcode & (val)) { \
reg[(r)].I = CPUReadMemory(address); \
if (!count) { \
clockTicks += 1 + dataTicksAccess32(address); \
} else { \
clockTicks += 1 + dataTicksAccessSeq32(address); \
} \
count++; \
address += 4; \
}
// STM R0~7!, {Rlist}
static INSN_REGPARM void thumbC0(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[regist].I & 0xFFFFFFFC;
u32 temp = reg[regist].I + 4*cpuBitsSet[opcode & 0xff];
int count = 0;
// store
THUMB_STM_REG(1, 0, regist);
THUMB_STM_REG(2, 1, regist);
THUMB_STM_REG(4, 2, regist);
THUMB_STM_REG(8, 3, regist);
THUMB_STM_REG(16, 4, regist);
THUMB_STM_REG(32, 5, regist);
THUMB_STM_REG(64, 6, regist);
THUMB_STM_REG(128, 7, regist);
clockTicks = 1 + codeTicksAccess16(armNextPC);
}
// LDM R0~R7!, {Rlist}
static INSN_REGPARM void thumbC8(u32 opcode)
{
u8 regist = (opcode >> 8) & 7;
if (busPrefetchCount == 0)
busPrefetch = busPrefetchEnable;
u32 address = reg[regist].I & 0xFFFFFFFC;
u32 temp = reg[regist].I + 4*cpuBitsSet[opcode & 0xFF];
int count = 0;
// load
THUMB_LDM_REG(1, 0);
THUMB_LDM_REG(2, 1);
THUMB_LDM_REG(4, 2);
THUMB_LDM_REG(8, 3);
THUMB_LDM_REG(16, 4);
THUMB_LDM_REG(32, 5);
THUMB_LDM_REG(64, 6);
THUMB_LDM_REG(128, 7);
clockTicks = 2 + codeTicksAccess16(armNextPC);
if(!(opcode & (1<<regist)))
reg[regist].I = temp;
}
// Conditional branches ///////////////////////////////////////////////////
// BEQ offset
static INSN_REGPARM void thumbD0(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(Z_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BNE offset
static INSN_REGPARM void thumbD1(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!Z_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BCS offset
static INSN_REGPARM void thumbD2(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(C_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BCC offset
static INSN_REGPARM void thumbD3(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!C_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BMI offset
static INSN_REGPARM void thumbD4(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(N_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BPL offset
static INSN_REGPARM void thumbD5(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!N_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BVS offset
static INSN_REGPARM void thumbD6(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(V_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BVC offset
static INSN_REGPARM void thumbD7(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!V_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BHI offset
static INSN_REGPARM void thumbD8(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(C_FLAG && !Z_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BLS offset
static INSN_REGPARM void thumbD9(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!C_FLAG || Z_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BGE offset
static INSN_REGPARM void thumbDA(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(N_FLAG == V_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BLT offset
static INSN_REGPARM void thumbDB(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(N_FLAG != V_FLAG) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BGT offset
static INSN_REGPARM void thumbDC(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
if(!Z_FLAG && (N_FLAG == V_FLAG)) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// BLE offset
static INSN_REGPARM void thumbDD(u32 opcode)
{
UPDATE_OLDREG;
clockTicks = codeTicksAccessSeq16(armNextPC);
if(Z_FLAG || (N_FLAG != V_FLAG)) {
reg[15].I += ((s8)(opcode & 0xFF)) << 1;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks += codeTicksAccessSeq16(armNextPC) + codeTicksAccess16(armNextPC) + 2;
busPrefetchCount=0;
}
}
// SWI, B, BL /////////////////////////////////////////////////////////////
// SWI #comment
static INSN_REGPARM void thumbDF(u32 opcode)
{
u32 address = 0;
//clockTicks = codeTicksAccessSeq16(address)*2 + codeTicksAccess16(address)+3;
clockTicks = 3;
busPrefetchCount=0;
CPUSoftwareInterrupt(opcode & 0xFF);
}
// B offset
static INSN_REGPARM void thumbE0(u32 opcode)
{
int offset = (opcode & 0x3FF) << 1;
if(opcode & 0x0400)
offset |= 0xFFFFF800;
reg[15].I += offset;
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2 + codeTicksAccess16(armNextPC)+3;
busPrefetchCount=0;
}
// BLL #offset (forward)
static INSN_REGPARM void thumbF0(u32 opcode)
{
int offset = (opcode & 0x7FF);
reg[14].I = reg[15].I + (offset << 12);
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
}
// BLL #offset (backward)
static INSN_REGPARM void thumbF4(u32 opcode)
{
int offset = (opcode & 0x7FF);
reg[14].I = reg[15].I + ((offset << 12) | 0xFF800000);
clockTicks = codeTicksAccessSeq16(armNextPC) + 1;
}
// BLH #offset
static INSN_REGPARM void thumbF8(u32 opcode)
{
int offset = (opcode & 0x7FF);
u32 temp = reg[15].I-2;
reg[15].I = (reg[14].I + (offset<<1))&0xFFFFFFFE;
armNextPC = reg[15].I;
reg[15].I += 2;
reg[14].I = temp|1;
THUMB_PREFETCH;
clockTicks = codeTicksAccessSeq16(armNextPC)*2 + codeTicksAccess16(armNextPC) + 3;
busPrefetchCount = 0;
}
// Instruction table //////////////////////////////////////////////////////
typedef INSN_REGPARM void (*insnfunc_t)(u32 opcode);
#define thumbUI thumbUnknownInsn
#ifdef BKPT_SUPPORT
#define thumbBP thumbBreakpoint
#else
#define thumbBP thumbUnknownInsn
#endif
static insnfunc_t thumbInsnTable[1024] = {
thumb00_00,thumb00_01,thumb00_02,thumb00_03,thumb00_04,thumb00_05,thumb00_06,thumb00_07, // 00
thumb00_08,thumb00_09,thumb00_0A,thumb00_0B,thumb00_0C,thumb00_0D,thumb00_0E,thumb00_0F,
thumb00_10,thumb00_11,thumb00_12,thumb00_13,thumb00_14,thumb00_15,thumb00_16,thumb00_17,
thumb00_18,thumb00_19,thumb00_1A,thumb00_1B,thumb00_1C,thumb00_1D,thumb00_1E,thumb00_1F,
thumb08_00,thumb08_01,thumb08_02,thumb08_03,thumb08_04,thumb08_05,thumb08_06,thumb08_07, // 08
thumb08_08,thumb08_09,thumb08_0A,thumb08_0B,thumb08_0C,thumb08_0D,thumb08_0E,thumb08_0F,
thumb08_10,thumb08_11,thumb08_12,thumb08_13,thumb08_14,thumb08_15,thumb08_16,thumb08_17,
thumb08_18,thumb08_19,thumb08_1A,thumb08_1B,thumb08_1C,thumb08_1D,thumb08_1E,thumb08_1F,
thumb10_00,thumb10_01,thumb10_02,thumb10_03,thumb10_04,thumb10_05,thumb10_06,thumb10_07, // 10
thumb10_08,thumb10_09,thumb10_0A,thumb10_0B,thumb10_0C,thumb10_0D,thumb10_0E,thumb10_0F,
thumb10_10,thumb10_11,thumb10_12,thumb10_13,thumb10_14,thumb10_15,thumb10_16,thumb10_17,
thumb10_18,thumb10_19,thumb10_1A,thumb10_1B,thumb10_1C,thumb10_1D,thumb10_1E,thumb10_1F,
thumb18_0,thumb18_1,thumb18_2,thumb18_3,thumb18_4,thumb18_5,thumb18_6,thumb18_7, // 18
thumb1A_0,thumb1A_1,thumb1A_2,thumb1A_3,thumb1A_4,thumb1A_5,thumb1A_6,thumb1A_7,
thumb1C_0,thumb1C_1,thumb1C_2,thumb1C_3,thumb1C_4,thumb1C_5,thumb1C_6,thumb1C_7,
thumb1E_0,thumb1E_1,thumb1E_2,thumb1E_3,thumb1E_4,thumb1E_5,thumb1E_6,thumb1E_7,
thumb20,thumb20,thumb20,thumb20,thumb21,thumb21,thumb21,thumb21, // 20
thumb22,thumb22,thumb22,thumb22,thumb23,thumb23,thumb23,thumb23,
thumb24,thumb24,thumb24,thumb24,thumb25,thumb25,thumb25,thumb25,
thumb26,thumb26,thumb26,thumb26,thumb27,thumb27,thumb27,thumb27,
thumb28,thumb28,thumb28,thumb28,thumb29,thumb29,thumb29,thumb29, // 28
thumb2A,thumb2A,thumb2A,thumb2A,thumb2B,thumb2B,thumb2B,thumb2B,
thumb2C,thumb2C,thumb2C,thumb2C,thumb2D,thumb2D,thumb2D,thumb2D,
thumb2E,thumb2E,thumb2E,thumb2E,thumb2F,thumb2F,thumb2F,thumb2F,
thumb30,thumb30,thumb30,thumb30,thumb31,thumb31,thumb31,thumb31, // 30
thumb32,thumb32,thumb32,thumb32,thumb33,thumb33,thumb33,thumb33,
thumb34,thumb34,thumb34,thumb34,thumb35,thumb35,thumb35,thumb35,
thumb36,thumb36,thumb36,thumb36,thumb37,thumb37,thumb37,thumb37,
thumb38,thumb38,thumb38,thumb38,thumb39,thumb39,thumb39,thumb39, // 38
thumb3A,thumb3A,thumb3A,thumb3A,thumb3B,thumb3B,thumb3B,thumb3B,
thumb3C,thumb3C,thumb3C,thumb3C,thumb3D,thumb3D,thumb3D,thumb3D,
thumb3E,thumb3E,thumb3E,thumb3E,thumb3F,thumb3F,thumb3F,thumb3F,
thumb40_0,thumb40_1,thumb40_2,thumb40_3,thumb41_0,thumb41_1,thumb41_2,thumb41_3, // 40
thumb42_0,thumb42_1,thumb42_2,thumb42_3,thumb43_0,thumb43_1,thumb43_2,thumb43_3,
thumbUI,thumb44_1,thumb44_2,thumb44_3,thumbUI,thumb45_1,thumb45_2,thumb45_3,
thumb46_0,thumb46_1,thumb46_2,thumb46_3,thumb47,thumb47,thumbUI,thumbUI,
thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48, // 48
thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,
thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,
thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,thumb48,
thumb50,thumb50,thumb50,thumb50,thumb50,thumb50,thumb50,thumb50, // 50
thumb52,thumb52,thumb52,thumb52,thumb52,thumb52,thumb52,thumb52,
thumb54,thumb54,thumb54,thumb54,thumb54,thumb54,thumb54,thumb54,
thumb56,thumb56,thumb56,thumb56,thumb56,thumb56,thumb56,thumb56,
thumb58,thumb58,thumb58,thumb58,thumb58,thumb58,thumb58,thumb58, // 58
thumb5A,thumb5A,thumb5A,thumb5A,thumb5A,thumb5A,thumb5A,thumb5A,
thumb5C,thumb5C,thumb5C,thumb5C,thumb5C,thumb5C,thumb5C,thumb5C,
thumb5E,thumb5E,thumb5E,thumb5E,thumb5E,thumb5E,thumb5E,thumb5E,
thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60, // 60
thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,
thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,
thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,thumb60,
thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68, // 68
thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,
thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,
thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,thumb68,
thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70, // 70
thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,
thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,
thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,thumb70,
thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78, // 78
thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,
thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,
thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,thumb78,
thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80, // 80
thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,
thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,
thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,thumb80,
thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88, // 88
thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,
thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,
thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,thumb88,
thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90, // 90
thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,
thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,
thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,thumb90,
thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98, // 98
thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,
thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,
thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,thumb98,
thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0, // A0
thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,
thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,
thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,thumbA0,
thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8, // A8
thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,
thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,
thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,thumbA8,
thumbB0,thumbB0,thumbB0,thumbB0,thumbUI,thumbUI,thumbUI,thumbUI, // B0
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbB4,thumbB4,thumbB4,thumbB4,thumbB5,thumbB5,thumbB5,thumbB5,
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI, // B8
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbBC,thumbBC,thumbBC,thumbBC,thumbBD,thumbBD,thumbBD,thumbBD,
thumbBP,thumbBP,thumbBP,thumbBP,thumbUI,thumbUI,thumbUI,thumbUI,
thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0, // C0
thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,
thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,
thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,thumbC0,
thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8, // C8
thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,
thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,
thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,thumbC8,
thumbD0,thumbD0,thumbD0,thumbD0,thumbD1,thumbD1,thumbD1,thumbD1, // D0
thumbD2,thumbD2,thumbD2,thumbD2,thumbD3,thumbD3,thumbD3,thumbD3,
thumbD4,thumbD4,thumbD4,thumbD4,thumbD5,thumbD5,thumbD5,thumbD5,
thumbD6,thumbD6,thumbD6,thumbD6,thumbD7,thumbD7,thumbD7,thumbD7,
thumbD8,thumbD8,thumbD8,thumbD8,thumbD9,thumbD9,thumbD9,thumbD9, // D8
thumbDA,thumbDA,thumbDA,thumbDA,thumbDB,thumbDB,thumbDB,thumbDB,
thumbDC,thumbDC,thumbDC,thumbDC,thumbDD,thumbDD,thumbDD,thumbDD,
thumbUI,thumbUI,thumbUI,thumbUI,thumbDF,thumbDF,thumbDF,thumbDF,
thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0, // E0
thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,
thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,
thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,thumbE0,
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI, // E8
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,thumbUI,
thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0, // F0
thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,thumbF0,
thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,
thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,thumbF4,
thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8, // F8
thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,
thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,
thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,thumbF8,
};
// Wrapper routine (execution loop) ///////////////////////////////////////
int thumbExecute()
{
do {
if( cheatsEnabled ) {
cpuMasterCodeCheck();
}
//if ((armNextPC & 0x0803FFFF) == 0x08020000)
// busPrefetchCount=0x100;
u32 opcode = cpuPrefetch[0];
cpuPrefetch[0] = cpuPrefetch[1];
busPrefetch = false;
if (busPrefetchCount & 0xFFFFFF00)
busPrefetchCount = 0x100 | (busPrefetchCount & 0xFF);
clockTicks = 0;
u32 oldArmNextPC = armNextPC;
#ifndef FINAL_VERSION
if(armNextPC == stop) {
armNextPC++;
}
#endif
armNextPC = reg[15].I;
reg[15].I += 2;
THUMB_PREFETCH_NEXT;
(*thumbInsnTable[opcode>>6])(opcode);
if (clockTicks < 0)
return 0;
if (clockTicks==0)
clockTicks = codeTicksAccessSeq16(oldArmNextPC) + 1;
cpuTotalTicks += clockTicks;
} while (cpuTotalTicks < cpuNextEvent && !armState && !holdState && !SWITicks);
return 1;
}