np2/i386c/ia32/ia32.mcr - diff

Return to ia32.mcr CVS log

Up to [RetroPC.NET] / np2 / i386c / ia32

Diff for /np2/i386c/ia32/ia32.mcr between versions 1.14 and 1.29

version 1.14, 2004/03/05 14:17:35	version 1.29, 2011/12/21 18:07:57
Line 1	Line 1
/* $Id$ */

/*	/*
* Copyright (c) 2002-2003 NONAKA Kimihiro	* Copyright (c) 2002-2003 NONAKA Kimihiro
* All rights reserved.	* All rights reserved.
Line 12	Line 10
* 2. Redistributions in binary form must reproduce the above copyright	* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the	* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.	* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*	*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
Line 37	Line 33
#define __CBD(src) ((UINT32)((SINT8)(src)))	#define __CBD(src) ((UINT32)((SINT8)(src)))
#define __CWDE(src) ((SINT16)(src))	#define __CWDE(src) ((SINT16)(src))

	#ifndef PTR_TO_UINT32
	#define PTR_TO_UINT32(p) ((UINT32)((unsigned long)(p)))
	#endif
	#ifndef UINT32_TO_PTR
	#define UINT32_TO_PTR(v) ((void *)((unsigned long)(UINT32)(v)))
	#endif

#define SWAP_BYTE(p, q) \	#define SWAP_BYTE(p, q) \
do { \	do { \
UINT8 __tmp = (p); \	UINT8 __tmp = (p); \
Line 69 do { \	Line 72 do { \

#define CPU_HALT() \	#define CPU_HALT() \
do { \	do { \
CPU_REMCLOCK = -1; \	CPU_REMCLOCK = -1; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define IRQCHECKTERM() \	#define IRQCHECKTERM() \
Line 84 do { \	Line 87 do { \
/*	/*
* instruction pointer	* instruction pointer
*/	*/
#define SET_EIP(v) \	/* コードフェッチに使用するので、OpSize の影響を受けてはいけない */
do { \	#define _ADD_EIP(v) \
UINT32 __new_ip = (v); \
if (__new_ip > CPU_STAT_CS_LIMIT) { \
VERBOSE(("SET_EIP: new_ip = %08x, limit = %08x", __new_ip, CPU_STAT_CS_LIMIT)); \
EXCEPTION(GP_EXCEPTION, 0); \
} \
CPU_EIP = __new_ip; \
CPU_PREFETCH_CLEAR(); \
} while (/CONSTCOND/ 0)

#define ADD_EIP(v) \
do { \	do { \
UINT32 __tmp_ip = CPU_EIP + (v); \	UINT32 __tmp_ip = CPU_EIP + (v); \
if (!CPU_STATSAVE.cpu_inst_default.op_32) { \	if (!CPU_STATSAVE.cpu_inst_default.op_32) { \
Line 104 do { \	Line 97 do { \
CPU_EIP = __tmp_ip; \	CPU_EIP = __tmp_ip; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)


#define GET_PCBYTE(v) \	#define GET_PCBYTE(v) \
do { \	do { \
(v) = cpu_codefetch(CPU_EIP); \	(v) = cpu_codefetch(CPU_EIP); \
ADD_EIP(1); \	_ADD_EIP(1); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define GET_PCBYTES(v) \	#define GET_PCBYTES(v) \
do { \	do { \
(v) = __CBW(cpu_codefetch(CPU_EIP)); \	(v) = __CBW(cpu_codefetch(CPU_EIP)); \
ADD_EIP(1); \	_ADD_EIP(1); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define GET_PCBYTESD(v) \	#define GET_PCBYTESD(v) \
do { \	do { \
(v) = __CBD(cpu_codefetch(CPU_EIP)); \	(v) = __CBD(cpu_codefetch(CPU_EIP)); \
ADD_EIP(1); \	_ADD_EIP(1); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define GET_PCWORD(v) \	#define GET_PCWORD(v) \
do { \	do { \
(v) = cpu_codefetch_w(CPU_EIP); \	(v) = cpu_codefetch_w(CPU_EIP); \
ADD_EIP(2); \	_ADD_EIP(2); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define GET_PCWORDS(v) \	#define GET_PCWORDS(v) \
do { \	do { \
(v) = __CWDE(cpu_codefetch_w(CPU_EIP)); \	(v) = __CWDE(cpu_codefetch_w(CPU_EIP)); \
ADD_EIP(2); \	_ADD_EIP(2); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define GET_PCDWORD(v) \	#define GET_PCDWORD(v) \
do { \	do { \
(v) = cpu_codefetch_d(CPU_EIP); \	(v) = cpu_codefetch_d(CPU_EIP); \
ADD_EIP(4); \	_ADD_EIP(4); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define PREPART_EA_REG8(b, d_s) \	#define PREPART_EA_REG8(b, d_s) \
Line 682 do { \	Line 674 do { \
(s) = __b; \	(s) = __b; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

	#define BYTE_NOT(s) \
	do { \
	(s) ^= 0xff; \
	} while (/CONSTCOND/ 0)

	#define WORD_NOT(s) \
	do { \
	(s) ^= 0xffff; \
	} while (/CONSTCOND/ 0)

	#define DWORD_NOT(s) \
	do { \
	(s) ^= 0xffffffff; \
	} while (/CONSTCOND/ 0)


/*	/*
* stack	* stack
*/	*/
#define REGPUSH(reg, clock) \	#define REGPUSH(reg, clock) \
do { \	do { \
CPU_SP -= 2; \	UINT16 __new_sp = CPU_SP - 2; \
cpu_vmemorywrite_w(CPU_SS_INDEX, CPU_SP, reg); \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
	cpu_vmemorywrite_w(CPU_SS_INDEX, __new_sp, reg); \
	CPU_SP = __new_sp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define REGPUSH_32(reg, clock) \	#define REGPUSH_32(reg, clock) \
do { \	do { \
CPU_ESP -= 4; \	UINT32 __new_esp = CPU_ESP - 4; \
cpu_vmemorywrite_d(CPU_SS_INDEX, CPU_ESP, reg); \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
	cpu_vmemorywrite_d(CPU_SS_INDEX, __new_esp, reg); \
	CPU_ESP = __new_esp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define REGPUSH0(reg) \	#define REGPUSH0(reg) \
do { \	do { \
CPU_SP -= 2; \	UINT16 __new_sp = CPU_SP - 2; \
cpu_vmemorywrite_w(CPU_SS_INDEX, CPU_SP, (UINT16)reg); \	cpu_vmemorywrite_w(CPU_SS_INDEX, __new_sp, (UINT16)reg); \
	CPU_SP = __new_sp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

/* Operand Size == 16 && Stack Size == 32 */	/* Operand Size == 16 && Stack Size == 32 */
#define REGPUSH0_16_32(reg) \	#define REGPUSH0_16_32(reg) \
do { \	do { \
CPU_ESP -= 2; \	UINT32 __new_esp = CPU_ESP - 2; \
cpu_vmemorywrite_w(CPU_SS_INDEX, CPU_ESP, (UINT16)reg); \	cpu_vmemorywrite_w(CPU_SS_INDEX, __new_esp, (UINT16)reg); \
	CPU_ESP = __new_esp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

/* Operand Size == 32 && Stack Size == 16 */	/* Operand Size == 32 && Stack Size == 16 */
#define REGPUSH0_32_16(reg) \	#define REGPUSH0_32_16(reg) \
do { \	do { \
CPU_SP -= 4; \	UINT16 __new_sp = CPU_SP - 4; \
cpu_vmemorywrite_d(CPU_SS_INDEX, CPU_SP, reg); \	cpu_vmemorywrite_d(CPU_SS_INDEX, __new_sp, reg); \
	CPU_SP = __new_sp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define REGPUSH0_32(reg) \	#define REGPUSH0_32(reg) \
do { \	do { \
CPU_ESP -= 4; \	UINT32 __new_esp = CPU_ESP - 4; \
cpu_vmemorywrite_d(CPU_SS_INDEX, CPU_ESP, reg); \	cpu_vmemorywrite_d(CPU_SS_INDEX, __new_esp, reg); \
	CPU_ESP = __new_esp; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define PUSH0_16(reg) \	#define PUSH0_16(reg) \
Line 755 do { \	Line 768 do { \

#define REGPOP(reg, clock) \	#define REGPOP(reg, clock) \
do { \	do { \
	CPU_WORKCLOCK(clock); \
(reg) = cpu_vmemoryread_w(CPU_SS_INDEX, CPU_SP); \	(reg) = cpu_vmemoryread_w(CPU_SS_INDEX, CPU_SP); \
CPU_SP += 2; \	CPU_SP += 2; \
CPU_WORKCLOCK(clock); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define REGPOP_32(reg, clock) \	#define REGPOP_32(reg, clock) \
do { \	do { \
	CPU_WORKCLOCK(clock); \
(reg) = cpu_vmemoryread_d(CPU_SS_INDEX, CPU_ESP); \	(reg) = cpu_vmemoryread_d(CPU_SS_INDEX, CPU_ESP); \
CPU_ESP += 4; \	CPU_ESP += 4; \
CPU_WORKCLOCK(clock); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define REGPOP0(reg) \	#define REGPOP0(reg) \
Line 814 do { \	Line 827 do { \
*/	*/
#define SP_PUSH_16(reg) \	#define SP_PUSH_16(reg) \
do { \	do { \
UINT16 sp = CPU_SP; \	UINT16 __sp = CPU_SP; \
if (!CPU_STAT_SS32) { \	if (!CPU_STAT_SS32) { \
REGPUSH0(sp); \	REGPUSH0(__sp); \
} else { \	} else { \
REGPUSH0_16_32(sp); \	REGPUSH0_16_32(__sp); \
} \	} \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define ESP_PUSH_32(reg) \	#define ESP_PUSH_32(reg) \
do { \	do { \
UINT32 sp = CPU_ESP; \	UINT32 __esp = CPU_ESP; \
if (!CPU_STAT_SS32) { \	if (!CPU_STAT_SS32) { \
REGPUSH0_32_16(sp); \	REGPUSH0_32_16(__esp); \
} else { \	} else { \
REGPUSH0_32(sp); \	REGPUSH0_32(__esp); \
} \	} \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define SP_POP_16(reg) \	#define SP_POP_16(reg) \
do { \	do { \
UINT32 sp; \	UINT32 __sp; \
if (!CPU_STAT_SS32) { \	if (!CPU_STAT_SS32) { \
sp = CPU_SP; \	__sp = CPU_SP; \
} else { \	} else { \
sp = CPU_ESP; \	__sp = CPU_ESP; \
} \	} \
CPU_SP = cpu_vmemoryread_w(CPU_SS_INDEX, sp); \	CPU_SP = cpu_vmemoryread_w(CPU_SS_INDEX, __sp); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define ESP_POP_32(reg) \	#define ESP_POP_32(reg) \
do { \	do { \
UINT32 sp; \	UINT32 __esp; \
if (!CPU_STAT_SS32) { \	if (!CPU_STAT_SS32) { \
sp = CPU_SP; \	__esp = CPU_SP; \
} else { \	} else { \
sp = CPU_ESP; \	__esp = CPU_ESP; \
} \	} \
CPU_ESP = cpu_vmemoryread_d(CPU_SS_INDEX, sp); \	CPU_ESP = cpu_vmemoryread_d(CPU_SS_INDEX, __esp); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)


Line 860 do { \	Line 873 do { \
*/	*/
#define JMPSHORT(clock) \	#define JMPSHORT(clock) \
do { \	do { \
UINT32 __ip; \	UINT32 __new_ip; \
	UINT32 __dest; \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
__ip = __CBD(cpu_codefetch(CPU_EIP)); \	GET_PCBYTESD(__dest); \
__ip++; \	__new_ip = CPU_EIP + __dest; \
ADD_EIP(__ip); \	if (!CPU_INST_OP32) { \
CPU_PREFETCH_CLEAR(); \	__new_ip &= 0xffff; \
	} \
	if (__new_ip > CPU_STAT_CS_LIMIT) { \
	EXCEPTION(GP_EXCEPTION, 0); \
	} \
	CPU_EIP = __new_ip; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define JMPNEAR(clock) \	#define JMPNEAR(clock) \
do { \	do { \
UINT32 __ip; \	UINT16 __new_ip; \
	SINT16 __dest; \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
__ip = __CWDE(cpu_codefetch_w(CPU_EIP)); \	GET_PCWORDS(__dest); \
__ip += 2; \	__new_ip = CPU_IP + __dest; \
ADD_EIP(__ip); \	if (__new_ip > CPU_STAT_CS_LIMIT) { \
CPU_PREFETCH_CLEAR(); \	EXCEPTION(GP_EXCEPTION, 0); \
	} \
	CPU_EIP = __new_ip; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#define JMPNEAR_4(clock) \	#define JMPNEAR32(clock) \
do { \	do { \
UINT32 __ip; \	UINT32 __new_ip; \
	UINT32 __dest; \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
__ip = cpu_codefetch_d(CPU_EIP); \	GET_PCDWORD(__dest); \
__ip += 4; \	__new_ip = CPU_EIP + __dest; \
ADD_EIP(__ip); \	if (__new_ip > CPU_STAT_CS_LIMIT) { \
CPU_PREFETCH_CLEAR(); \	EXCEPTION(GP_EXCEPTION, 0); \
	} \
	CPU_EIP = __new_ip; \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)

#if !defined(IA32_SUPPORT_PREFETCH_QUEUE)
#define JMPNOP(clock, d) \
do { \
CPU_WORKCLOCK(clock); \
ADD_EIP((d)); \
} while (/CONSTCOND/ 0)
#else
#define JMPNOP(clock, d) \	#define JMPNOP(clock, d) \
do { \	do { \
CPU_WORKCLOCK(clock); \	CPU_WORKCLOCK(clock); \
if (CPU_PREFETCHQ_REMAIN > (d)) { \	_ADD_EIP((d)); \
CPU_PREFETCHQ_REMAIN -= (d); \
} else { \
CPU_PREFETCHQ_REMAIN = 0; \
} \
ADD_EIP((d)); \
} while (/CONSTCOND/ 0)	} while (/CONSTCOND/ 0)
#endif

	/*
	* conditions
	*/
	#define CC_O (CPU_OV)
	#define CC_NO (!CPU_OV)
	#define CC_C (CPU_FLAGL & C_FLAG)
	#define CC_NC (!(CPU_FLAGL & C_FLAG))
	#define CC_Z (CPU_FLAGL & Z_FLAG)
	#define CC_NZ (!(CPU_FLAGL & Z_FLAG))
	#define CC_NA (CPU_FLAGL & (Z_FLAG \| C_FLAG))
	#define CC_A (!(CPU_FLAGL & (Z_FLAG \| C_FLAG)))
	#define CC_S (CPU_FLAGL & S_FLAG)
	#define CC_NS (!(CPU_FLAGL & S_FLAG))
	#define CC_P (CPU_FLAGL & P_FLAG)
	#define CC_NP (!(CPU_FLAGL & P_FLAG))
	#define CC_L (((CPU_FLAGL & S_FLAG) == 0) != (CPU_OV == 0))
	#define CC_NL (((CPU_FLAGL & S_FLAG) == 0) == (CPU_OV == 0))
	#define CC_LE ((CPU_FLAGL & Z_FLAG) \|\| \
	(((CPU_FLAGL & S_FLAG) == 0) != (CPU_OV == 0)))
	#define CC_NLE ((!(CPU_FLAGL & Z_FLAG)) && \
	(((CPU_FLAGL & S_FLAG) == 0) == (CPU_OV == 0)))


/*	/*

RetroPC.NET-CVS <cvs@retropc.net>

Removed from v.1.14
changed lines
	Added in v.1.29