dosbox-wii/src/hardware/memory.cpp

614 lines
16 KiB
C++

/*
* 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: memory.cpp,v 1.55 2008/10/27 11:02:41 c2woody Exp $ */
#include "dosbox.h"
#include "mem.h"
#include "inout.h"
#include "setup.h"
#include "paging.h"
#include "regs.h"
#include <string.h>
#define PAGES_IN_BLOCK ((1024*1024)/MEM_PAGE_SIZE)
#define SAFE_MEMORY 32
#define MAX_MEMORY 64
#define MAX_PAGE_ENTRIES (MAX_MEMORY*1024*1024/4096)
#define LFB_PAGES 512
#define MAX_LINKS ((MAX_MEMORY*1024/4)+4096) //Hopefully enough
struct LinkBlock {
Bitu used;
Bit32u pages[MAX_LINKS];
};
static struct MemoryBlock {
Bitu pages;
PageHandler * * phandlers;
MemHandle * mhandles;
LinkBlock links;
struct {
Bitu start_page;
Bitu end_page;
Bitu pages;
PageHandler *handler;
PageHandler *mmiohandler;
} lfb;
struct {
bool enabled;
Bit8u controlport;
} a20;
} memory;
HostPt MemBase;
class IllegalPageHandler : public PageHandler {
public:
IllegalPageHandler() {
flags=PFLAG_INIT|PFLAG_NOCODE;
}
Bitu readb(PhysPt addr) {
#if C_DEBUG
LOG_MSG("Illegal read from %x, CS:IP %8x:%8x",addr,SegValue(cs),reg_eip);
#else
static Bits lcount=0;
if (lcount<1000) {
lcount++;
LOG_MSG("Illegal read from %x, CS:IP %8x:%8x",addr,SegValue(cs),reg_eip);
}
#endif
return 0;
}
void writeb(PhysPt addr,Bitu val) {
#if C_DEBUG
LOG_MSG("Illegal write to %x, CS:IP %8x:%8x",addr,SegValue(cs),reg_eip);
#else
static Bits lcount=0;
if (lcount<1000) {
lcount++;
LOG_MSG("Illegal write to %x, CS:IP %8x:%8x",addr,SegValue(cs),reg_eip);
}
#endif
}
};
class RAMPageHandler : public PageHandler {
public:
RAMPageHandler() {
flags=PFLAG_READABLE|PFLAG_WRITEABLE;
}
HostPt GetHostReadPt(Bitu phys_page) {
return MemBase+phys_page*MEM_PAGESIZE;
}
HostPt GetHostWritePt(Bitu phys_page) {
return MemBase+phys_page*MEM_PAGESIZE;
}
};
class ROMPageHandler : public RAMPageHandler {
public:
ROMPageHandler() {
flags=PFLAG_READABLE|PFLAG_HASROM;
}
void writeb(PhysPt addr,Bitu val){
LOG(LOG_CPU,LOG_ERROR)("Write %x to rom at %x",val,addr);
}
void writew(PhysPt addr,Bitu val){
LOG(LOG_CPU,LOG_ERROR)("Write %x to rom at %x",val,addr);
}
void writed(PhysPt addr,Bitu val){
LOG(LOG_CPU,LOG_ERROR)("Write %x to rom at %x",val,addr);
}
};
static IllegalPageHandler illegal_page_handler;
static RAMPageHandler ram_page_handler;
static ROMPageHandler rom_page_handler;
void MEM_SetLFB(Bitu page, Bitu pages, PageHandler *handler, PageHandler *mmiohandler) {
memory.lfb.handler=handler;
memory.lfb.mmiohandler=mmiohandler;
memory.lfb.start_page=page;
memory.lfb.end_page=page+pages;
memory.lfb.pages=pages;
PAGING_ClearTLB();
}
PageHandler * MEM_GetPageHandler(Bitu phys_page) {
if (phys_page<memory.pages) {
return memory.phandlers[phys_page];
} else if ((phys_page>=memory.lfb.start_page) && (phys_page<memory.lfb.end_page)) {
return memory.lfb.handler;
} else if ((phys_page>=memory.lfb.start_page+0x01000000/4096) &&
(phys_page<memory.lfb.start_page+0x01000000/4096+16)) {
return memory.lfb.mmiohandler;
}
return &illegal_page_handler;
}
void MEM_SetPageHandler(Bitu phys_page,Bitu pages,PageHandler * handler) {
for (;pages>0;pages--) {
memory.phandlers[phys_page]=handler;
phys_page++;
}
}
void MEM_ResetPageHandler(Bitu phys_page, Bitu pages) {
for (;pages>0;pages--) {
memory.phandlers[phys_page]=&ram_page_handler;
phys_page++;
}
}
Bitu mem_strlen(PhysPt pt) {
Bitu x=0;
while (x<1024) {
if (!mem_readb_inline(pt+x)) return x;
x++;
}
return 0; //Hope this doesn't happen
}
void mem_strcpy(PhysPt dest,PhysPt src) {
Bit8u r;
while ( (r = mem_readb(src++)) ) mem_writeb_inline(dest++,r);
mem_writeb_inline(dest,0);
}
void mem_memcpy(PhysPt dest,PhysPt src,Bitu size) {
while (size--) mem_writeb_inline(dest++,mem_readb_inline(src++));
}
void MEM_BlockRead(PhysPt pt,void * data,Bitu size) {
Bit8u * write=reinterpret_cast<Bit8u *>(data);
while (size--) {
*write++=mem_readb_inline(pt++);
}
}
void MEM_BlockWrite(PhysPt pt,void const * const data,Bitu size) {
Bit8u const * read = reinterpret_cast<Bit8u const * const>(data);
while (size--) {
mem_writeb_inline(pt++,*read++);
}
}
void MEM_BlockCopy(PhysPt dest,PhysPt src,Bitu size) {
mem_memcpy(dest,src,size);
}
void MEM_StrCopy(PhysPt pt,char * data,Bitu size) {
while (size--) {
Bit8u r=mem_readb_inline(pt++);
if (!r) break;
*data++=r;
}
*data=0;
}
Bitu MEM_TotalPages(void) {
return memory.pages;
}
Bitu MEM_FreeLargest(void) {
Bitu size=0;Bitu largest=0;
Bitu index=XMS_START;
while (index<memory.pages) {
if (!memory.mhandles[index]) {
size++;
} else {
if (size>largest) largest=size;
size=0;
}
index++;
}
if (size>largest) largest=size;
return largest;
}
Bitu MEM_FreeTotal(void) {
Bitu free=0;
Bitu index=XMS_START;
while (index<memory.pages) {
if (!memory.mhandles[index]) free++;
index++;
}
return free;
}
Bitu MEM_AllocatedPages(MemHandle handle)
{
Bitu pages = 0;
while (handle>0) {
pages++;
handle=memory.mhandles[handle];
}
return pages;
}
//TODO Maybe some protection for this whole allocation scheme
INLINE Bitu BestMatch(Bitu size) {
Bitu index=XMS_START;
Bitu first=0;
Bitu best=0xfffffff;
Bitu best_first=0;
while (index<memory.pages) {
/* Check if we are searching for first free page */
if (!first) {
/* Check if this is a free page */
if (!memory.mhandles[index]) {
first=index;
}
} else {
/* Check if this still is used page */
if (memory.mhandles[index]) {
Bitu pages=index-first;
if (pages==size) {
return first;
} else if (pages>size) {
if (pages<best) {
best=pages;
best_first=first;
}
}
first=0; //Always reset for new search
}
}
index++;
}
/* Check for the final block if we can */
if (first && (index-first>=size) && (index-first<best)) {
return first;
}
return best_first;
}
MemHandle MEM_AllocatePages(Bitu pages,bool sequence) {
MemHandle ret;
if (!pages) return 0;
if (sequence) {
Bitu index=BestMatch(pages);
if (!index) return 0;
MemHandle * next=&ret;
while (pages) {
*next=index;
next=&memory.mhandles[index];
index++;pages--;
}
*next=-1;
} else {
if (MEM_FreeTotal()<pages) return 0;
MemHandle * next=&ret;
while (pages) {
Bitu index=BestMatch(1);
if (!index) E_Exit("MEM:corruption during allocate");
while (pages && (!memory.mhandles[index])) {
*next=index;
next=&memory.mhandles[index];
index++;pages--;
}
*next=-1; //Invalidate it in case we need another match
}
}
return ret;
}
MemHandle MEM_GetNextFreePage(void) {
return (MemHandle)BestMatch(1);
}
void MEM_ReleasePages(MemHandle handle) {
while (handle>0) {
MemHandle next=memory.mhandles[handle];
memory.mhandles[handle]=0;
handle=next;
}
}
bool MEM_ReAllocatePages(MemHandle & handle,Bitu pages,bool sequence) {
if (handle<=0) {
if (!pages) return true;
handle=MEM_AllocatePages(pages,sequence);
return (handle>0);
}
if (!pages) {
MEM_ReleasePages(handle);
handle=-1;
return true;
}
MemHandle index=handle;
MemHandle last;Bitu old_pages=0;
while (index>0) {
old_pages++;
last=index;
index=memory.mhandles[index];
}
if (old_pages == pages) return true;
if (old_pages > pages) {
/* Decrease size */
pages--;index=handle;old_pages--;
while (pages) {
index=memory.mhandles[index];
pages--;old_pages--;
}
MemHandle next=memory.mhandles[index];
memory.mhandles[index]=-1;
index=next;
while (old_pages) {
next=memory.mhandles[index];
memory.mhandles[index]=0;
index=next;
old_pages--;
}
return true;
} else {
/* Increase size, check for enough free space */
Bitu need=pages-old_pages;
if (sequence) {
index=last+1;
Bitu free=0;
while ((index<(MemHandle)memory.pages) && !memory.mhandles[index]) {
index++;free++;
}
if (free>=need) {
/* Enough space allocate more pages */
index=last;
while (need) {
memory.mhandles[index]=index+1;
need--;index++;
}
memory.mhandles[index]=-1;
return true;
} else {
/* Not Enough space allocate new block and copy */
MemHandle newhandle=MEM_AllocatePages(pages,true);
if (!newhandle) return false;
MEM_BlockCopy(newhandle*4096,handle*4096,old_pages*4096);
MEM_ReleasePages(handle);
handle=newhandle;
return true;
}
} else {
MemHandle rem=MEM_AllocatePages(need,false);
if (!rem) return false;
memory.mhandles[last]=rem;
return true;
}
}
return 0;
}
MemHandle MEM_NextHandle(MemHandle handle) {
return memory.mhandles[handle];
}
MemHandle MEM_NextHandleAt(MemHandle handle,Bitu where) {
while (where) {
where--;
handle=memory.mhandles[handle];
}
return handle;
}
/*
A20 line handling,
Basically maps the 4 pages at the 1mb to 0mb in the default page directory
*/
bool MEM_A20_Enabled(void) {
return memory.a20.enabled;
}
void MEM_A20_Enable(bool enabled) {
Bitu phys_base=enabled ? (1024/4) : 0;
for (Bitu i=0;i<16;i++) PAGING_MapPage((1024/4)+i,phys_base+i);
memory.a20.enabled=enabled;
}
/* Memory access functions */
Bit16u mem_unalignedreadw(PhysPt address) {
return mem_readb_inline(address) |
mem_readb_inline(address+1) << 8;
}
Bit32u mem_unalignedreadd(PhysPt address) {
return mem_readb_inline(address) |
(mem_readb_inline(address+1) << 8) |
(mem_readb_inline(address+2) << 16) |
(mem_readb_inline(address+3) << 24);
}
void mem_unalignedwritew(PhysPt address,Bit16u val) {
mem_writeb_inline(address,(Bit8u)val);val>>=8;
mem_writeb_inline(address+1,(Bit8u)val);
}
void mem_unalignedwrited(PhysPt address,Bit32u val) {
mem_writeb_inline(address,(Bit8u)val);val>>=8;
mem_writeb_inline(address+1,(Bit8u)val);val>>=8;
mem_writeb_inline(address+2,(Bit8u)val);val>>=8;
mem_writeb_inline(address+3,(Bit8u)val);
}
bool mem_unalignedreadw_checked(PhysPt address, Bit16u * val) {
Bit8u rval1,rval2;
if (mem_readb_checked(address+0, &rval1)) return true;
if (mem_readb_checked(address+1, &rval2)) return true;
*val=(Bit16u)(((Bit8u)rval1) | (((Bit8u)rval2) << 8));
return false;
}
bool mem_unalignedreadd_checked(PhysPt address, Bit32u * val) {
Bit8u rval1,rval2,rval3,rval4;
if (mem_readb_checked(address+0, &rval1)) return true;
if (mem_readb_checked(address+1, &rval2)) return true;
if (mem_readb_checked(address+2, &rval3)) return true;
if (mem_readb_checked(address+3, &rval4)) return true;
*val=(Bit32u)(((Bit8u)rval1) | (((Bit8u)rval2) << 8) | (((Bit8u)rval3) << 16) | (((Bit8u)rval4) << 24));
return false;
}
bool mem_unalignedwritew_checked(PhysPt address,Bit16u val) {
if (mem_writeb_checked(address,(Bit8u)(val & 0xff))) return true;val>>=8;
if (mem_writeb_checked(address+1,(Bit8u)(val & 0xff))) return true;
return false;
}
bool mem_unalignedwrited_checked(PhysPt address,Bit32u val) {
if (mem_writeb_checked(address,(Bit8u)(val & 0xff))) return true;val>>=8;
if (mem_writeb_checked(address+1,(Bit8u)(val & 0xff))) return true;val>>=8;
if (mem_writeb_checked(address+2,(Bit8u)(val & 0xff))) return true;val>>=8;
if (mem_writeb_checked(address+3,(Bit8u)(val & 0xff))) return true;
return false;
}
Bit8u mem_readb(PhysPt address) {
return mem_readb_inline(address);
}
Bit16u mem_readw(PhysPt address) {
return mem_readw_inline(address);
}
Bit32u mem_readd(PhysPt address) {
return mem_readd_inline(address);
}
void mem_writeb(PhysPt address,Bit8u val) {
mem_writeb_inline(address,val);
}
void mem_writew(PhysPt address,Bit16u val) {
mem_writew_inline(address,val);
}
void mem_writed(PhysPt address,Bit32u val) {
mem_writed_inline(address,val);
}
static void write_p92(Bitu port,Bitu val,Bitu iolen) {
// Bit 0 = system reset (switch back to real mode)
if (val&1) E_Exit("XMS: CPU reset via port 0x92 not supported.");
memory.a20.controlport = val & ~2;
MEM_A20_Enable((val & 2)>0);
}
static Bitu read_p92(Bitu port,Bitu iolen) {
return memory.a20.controlport | (memory.a20.enabled ? 0x02 : 0);
}
void RemoveEMSPageFrame(void) {
/* Setup rom at 0xe0000-0xf0000 */
for (Bitu ct=0xe0;ct<0xf0;ct++) {
memory.phandlers[ct] = &rom_page_handler;
}
}
void PreparePCJRCartRom(void) {
/* Setup rom at 0xd0000-0xe0000 */
for (Bitu ct=0xd0;ct<0xe0;ct++) {
memory.phandlers[ct] = &rom_page_handler;
}
}
HostPt GetMemBase(void) { return MemBase; }
class MEMORY:public Module_base{
private:
IO_ReadHandleObject ReadHandler;
IO_WriteHandleObject WriteHandler;
public:
MEMORY(Section* configuration):Module_base(configuration){
Bitu i;
Section_prop * section=static_cast<Section_prop *>(configuration);
/* Setup the Physical Page Links */
Bitu memsize=section->Get_int("memsize");
if (memsize < 1) memsize = 1;
/* max 63 to solve problems with certain xms handlers */
if (memsize > MAX_MEMORY-1) {
LOG_MSG("Maximum memory size is %d MB",MAX_MEMORY - 1);
memsize = MAX_MEMORY-1;
}
if (memsize > SAFE_MEMORY-1) {
LOG_MSG("Memory sizes above %d MB are NOT recommended.",SAFE_MEMORY - 1);
LOG_MSG("Stick with the default values unless you are absolutely certain.");
}
MemBase = new Bit8u[memsize*1024*1024];
if (!MemBase) E_Exit("Can't allocate main memory of %d MB",memsize);
/* Clear the memory, as new doesn't always give zeroed memory
* (Visual C debug mode). We want zeroed memory though. */
memset((void*)MemBase,0,memsize*1024*1024);
memory.pages = (memsize*1024*1024)/4096;
/* Allocate the data for the different page information blocks */
memory.phandlers=new PageHandler * [memory.pages];
memory.mhandles=new MemHandle [memory.pages];
for (i = 0;i < memory.pages;i++) {
memory.phandlers[i] = &ram_page_handler;
memory.mhandles[i] = 0; //Set to 0 for memory allocation
}
/* Setup rom at 0xc0000-0xc8000 */
for (i=0xc0;i<0xc8;i++) {
memory.phandlers[i] = &rom_page_handler;
}
/* Setup rom at 0xf0000-0x100000 */
for (i=0xf0;i<0x100;i++) {
memory.phandlers[i] = &rom_page_handler;
}
if (machine==MCH_PCJR) {
/* Setup cartridge rom at 0xe0000-0xf0000 */
for (i=0xe0;i<0xf0;i++) {
memory.phandlers[i] = &rom_page_handler;
}
}
/* Reset some links */
memory.links.used = 0;
// A20 Line - PS/2 system control port A
WriteHandler.Install(0x92,write_p92,IO_MB);
ReadHandler.Install(0x92,read_p92,IO_MB);
MEM_A20_Enable(false);
}
~MEMORY(){
delete [] MemBase;
delete [] memory.phandlers;
delete [] memory.mhandles;
}
};
static MEMORY* test;
static void MEM_ShutDown(Section * sec) {
delete test;
}
void MEM_Init(Section * sec) {
/* shutdown function */
test = new MEMORY(sec);
sec->AddDestroyFunction(&MEM_ShutDown);
}