dosbox-wii/src/cpu/core_prefetch.cpp

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/*
* Copyright (C) 2002-2008 The DOSBox Team
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
/* $Id: core_prefetch.cpp,v 1.1 2008/05/21 21:29:32 c2woody Exp $ */
#include <stdio.h>
#include "dosbox.h"
#include "mem.h"
#include "cpu.h"
#include "lazyflags.h"
#include "inout.h"
#include "callback.h"
#include "pic.h"
#include "fpu.h"
#include "paging.h"
#if C_DEBUG
#include "debug.h"
#endif
#if (!C_CORE_INLINE)
#define LoadMb(off) mem_readb(off)
#define LoadMw(off) mem_readw(off)
#define LoadMd(off) mem_readd(off)
#define SaveMb(off,val) mem_writeb(off,val)
#define SaveMw(off,val) mem_writew(off,val)
#define SaveMd(off,val) mem_writed(off,val)
#else
#include "paging.h"
#define LoadMb(off) mem_readb_inline(off)
#define LoadMw(off) mem_readw_inline(off)
#define LoadMd(off) mem_readd_inline(off)
#define SaveMb(off,val) mem_writeb_inline(off,val)
#define SaveMw(off,val) mem_writew_inline(off,val)
#define SaveMd(off,val) mem_writed_inline(off,val)
#endif
extern Bitu cycle_count;
#if C_FPU
#define CPU_FPU 1 //Enable FPU escape instructions
#endif
#define CPU_PIC_CHECK 1
#define CPU_TRAP_CHECK 1
#define OPCODE_NONE 0x000
#define OPCODE_0F 0x100
#define OPCODE_SIZE 0x200
#define PREFIX_ADDR 0x1
#define PREFIX_REP 0x2
#define TEST_PREFIX_ADDR (core.prefixes & PREFIX_ADDR)
#define TEST_PREFIX_REP (core.prefixes & PREFIX_REP)
#define DO_PREFIX_SEG(_SEG) \
BaseDS=SegBase(_SEG); \
BaseSS=SegBase(_SEG); \
core.base_val_ds=_SEG; \
goto restart_opcode;
#define DO_PREFIX_ADDR() \
core.prefixes=(core.prefixes & ~PREFIX_ADDR) | \
(cpu.code.big ^ PREFIX_ADDR); \
core.ea_table=&EATable[(core.prefixes&1) * 256]; \
goto restart_opcode;
#define DO_PREFIX_REP(_ZERO) \
core.prefixes|=PREFIX_REP; \
core.rep_zero=_ZERO; \
goto restart_opcode;
typedef PhysPt (*GetEAHandler)(void);
static const Bit32u AddrMaskTable[2]={0x0000ffff,0xffffffff};
static struct {
Bitu opcode_index;
PhysPt cseip;
PhysPt base_ds,base_ss;
SegNames base_val_ds;
bool rep_zero;
Bitu prefixes;
GetEAHandler * ea_table;
} core;
#define GETIP (core.cseip-SegBase(cs))
#define SAVEIP reg_eip=GETIP;
#define LOADIP core.cseip=(SegBase(cs)+reg_eip);
#define SegBase(c) SegPhys(c)
#define BaseDS core.base_ds
#define BaseSS core.base_ss
#define MAX_PQ_SIZE 32
static Bit8u prefetch_buffer[MAX_PQ_SIZE];
static bool pq_valid=false;
static Bitu pq_start;
static INLINE Bit8u Fetchb() {
Bit8u temp;
if (pq_valid && (core.cseip>=pq_start) && (core.cseip<pq_start+CPU_PrefetchQueueSize)) {
temp=prefetch_buffer[core.cseip-pq_start];
if ((core.cseip+1>=pq_start+CPU_PrefetchQueueSize-4) &&
(core.cseip+1<pq_start+CPU_PrefetchQueueSize)) {
Bitu remaining_bytes=pq_start+CPU_PrefetchQueueSize-(core.cseip+1);
for (Bitu i=0; i<remaining_bytes; i++) prefetch_buffer[i]=prefetch_buffer[core.cseip+1-pq_start+i];
for (Bitu i=remaining_bytes; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+1+i);
pq_start=core.cseip+1;
pq_valid=true;
}
} else {
for (Bitu i=0; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+i);
pq_start=core.cseip;
pq_valid=true;
temp=prefetch_buffer[0];
}
/* if (temp!=LoadMb(core.cseip)) {
LOG_MSG("prefetch queue content!=memory at %x:%x",SegValue(cs),reg_eip);
} */
core.cseip+=1;
return temp;
}
static INLINE Bit16u Fetchw() {
Bit16u temp;
if (pq_valid && (core.cseip>=pq_start) && (core.cseip+2<pq_start+CPU_PrefetchQueueSize)) {
temp=prefetch_buffer[core.cseip-pq_start]|
(prefetch_buffer[core.cseip-pq_start+1]<<8);
if ((core.cseip+2>=pq_start+CPU_PrefetchQueueSize-4) &&
(core.cseip+2<pq_start+CPU_PrefetchQueueSize)) {
Bitu remaining_bytes=pq_start+CPU_PrefetchQueueSize-(core.cseip+2);
for (Bitu i=0; i<remaining_bytes; i++) prefetch_buffer[i]=prefetch_buffer[core.cseip+2-pq_start+i];
for (Bitu i=remaining_bytes; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+2+i);
pq_start=core.cseip+2;
pq_valid=true;
}
} else {
for (Bitu i=0; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+i);
pq_start=core.cseip;
pq_valid=true;
temp=prefetch_buffer[0] | (prefetch_buffer[1]<<8);
}
/* if (temp!=LoadMw(core.cseip)) {
LOG_MSG("prefetch queue content!=memory at %x:%x",SegValue(cs),reg_eip);
} */
core.cseip+=2;
return temp;
}
static INLINE Bit32u Fetchd() {
Bit32u temp;
if (pq_valid && (core.cseip>=pq_start) && (core.cseip+4<pq_start+CPU_PrefetchQueueSize)) {
temp=prefetch_buffer[core.cseip-pq_start]|
(prefetch_buffer[core.cseip-pq_start+1]<<8)|
(prefetch_buffer[core.cseip-pq_start+2]<<16)|
(prefetch_buffer[core.cseip-pq_start+3]<<24);
if ((core.cseip+4>=pq_start+CPU_PrefetchQueueSize-4) &&
(core.cseip+4<pq_start+CPU_PrefetchQueueSize)) {
Bitu remaining_bytes=pq_start+CPU_PrefetchQueueSize-(core.cseip+4);
for (Bitu i=0; i<remaining_bytes; i++) prefetch_buffer[i]=prefetch_buffer[core.cseip+4-pq_start+i];
for (Bitu i=remaining_bytes; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+4+i);
pq_start=core.cseip+4;
pq_valid=true;
}
} else {
for (Bitu i=0; i<CPU_PrefetchQueueSize; i++) prefetch_buffer[i]=LoadMb(core.cseip+i);
pq_start=core.cseip;
pq_valid=true;
temp=prefetch_buffer[0] | (prefetch_buffer[1]<<8) |
(prefetch_buffer[2]<<16) | (prefetch_buffer[3]<<24);
}
/* if (temp!=LoadMd(core.cseip)) {
LOG_MSG("prefetch queue content!=memory at %x:%x",SegValue(cs),reg_eip);
} */
core.cseip+=4;
return temp;
}
#define Push_16 CPU_Push16
#define Push_32 CPU_Push32
#define Pop_16 CPU_Pop16
#define Pop_32 CPU_Pop32
#include "instructions.h"
#include "core_normal/support.h"
#include "core_normal/string.h"
#define EALookupTable (core.ea_table)
Bits CPU_Core_Prefetch_Run(void) {
bool invalidate_pq=false;
while (CPU_Cycles-->0) {
if (invalidate_pq) {
pq_valid=false;
invalidate_pq=false;
}
LOADIP;
core.opcode_index=cpu.code.big*0x200;
core.prefixes=cpu.code.big;
core.ea_table=&EATable[cpu.code.big*256];
BaseDS=SegBase(ds);
BaseSS=SegBase(ss);
core.base_val_ds=ds;
#if C_DEBUG
#if C_HEAVY_DEBUG
if (DEBUG_HeavyIsBreakpoint()) {
FillFlags();
return debugCallback;
};
#endif
cycle_count++;
#endif
restart_opcode:
Bit8u next_opcode=Fetchb();
invalidate_pq=false;
if (core.opcode_index&OPCODE_0F) invalidate_pq=true;
else switch (next_opcode) {
case 0x70: case 0x71: case 0x72: case 0x73:
case 0x74: case 0x75: case 0x76: case 0x77:
case 0x78: case 0x79: case 0x7a: case 0x7b:
case 0x7c: case 0x7d: case 0x7e: case 0x7f: // jcc
case 0x9a: // call
case 0xc2: case 0xc3: // retn
case 0xc8: // enter
case 0xc9: // leave
case 0xca: case 0xcb: // retf
case 0xcc: // int3
case 0xcd: // int
case 0xce: // into
case 0xcf: // iret
case 0xe0: // loopnz
case 0xe1: // loopz
case 0xe2: // loop
case 0xe3: // jcxz
case 0xe8: // call
case 0xe9: case 0xea: case 0xeb: // jmp
case 0xff:
invalidate_pq=true;
break;
default:
break;
}
switch (core.opcode_index+next_opcode) {
#include "core_normal/prefix_none.h"
#include "core_normal/prefix_0f.h"
#include "core_normal/prefix_66.h"
#include "core_normal/prefix_66_0f.h"
default:
illegal_opcode:
#if C_DEBUG
{
Bitu len=(GETIP-reg_eip);
LOADIP;
if (len>16) len=16;
char tempcode[16*2+1];char * writecode=tempcode;
for (;len>0;len--) {
sprintf(writecode,"%X",mem_readb(core.cseip++));
writecode+=2;
}
LOG(LOG_CPU,LOG_NORMAL)("Illegal/Unhandled opcode %s",tempcode);
}
#endif
CPU_Exception(6,0);
invalidate_pq=true;
continue;
}
SAVEIP;
}
FillFlags();
return CBRET_NONE;
decode_end:
SAVEIP;
FillFlags();
return CBRET_NONE;
}
Bits CPU_Core_Prefetch_Trap_Run(void) {
Bits oldCycles = CPU_Cycles;
CPU_Cycles = 1;
cpu.trap_skip = false;
Bits ret=CPU_Core_Prefetch_Run();
if (!cpu.trap_skip) CPU_HW_Interrupt(1);
CPU_Cycles = oldCycles-1;
cpudecoder = &CPU_Core_Prefetch_Run;
return ret;
}
void CPU_Core_Prefetch_Init(void) {
}