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// DGen v1.13+
// Megadrive's VDP C++ module
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "md.h"
int md_vdp::get_screen_info(struct dgen_sinfo *si)
{
// Release the pointers to vdp Data to an external function
si->vram=vram; si->cram=cram; si->vsram=vsram;
si->vdp_reg=reg;
// NB - if you change anything, remember to set 'dirt' accordingly
return 0;
}
int md_vdp::reset()
{
if (!ok) return 1;
rw_mode=0x00; rw_addr=0; rw_dma=0;
memset(mem,0,0x10100);
memset(reg,0,0x20);
memset(dirt,0xff,0x35); // mark everything as changed
return 0;
}
md_vdp::md_vdp()
{
ok=0;
belongs=0; // Don't know which megadrive vdp belongs to yet
mem=vram=cram=vsram=NULL;
mem=new unsigned char[0x10100+0x35]; //0x20+0x10+0x4+1 for dirt
if (mem==0) return;
vram=mem+0x00000; cram=mem+0x10000; vsram=mem+0x10080;
dirt=mem+0x10100; // VRAM/CRAM/Reg dirty buffer bitfield
// Also in 0x34 are global dirt flags (inclduing VSRAM this time)
highpal=new unsigned int[64]; if (highpal==0) return;
Bpp = Bpp_times8 = 0;
ok=1;
reset();
}
md_vdp::~md_vdp()
{
free(mem);
mem=vram=cram=vsram=NULL;
ok=0;
}
int md_vdp::dma_len()
{ return (reg[0x14]<<8)+reg[0x13]; }
int md_vdp::dma_addr()
{
int addr=0;
addr=(reg[0x17]&0x7f)<<17;
addr+=reg[0x16]<<9;
addr+=reg[0x15]<<1;
return addr;
}
// DMA can read from anywhere
unsigned char md_vdp::dma_mem_read(int addr)
{
return belongs->misc_readbyte(addr);
}
// Must go through these calls to update the dirty flags
int md_vdp::poke_vram(int addr,unsigned char d)
{
// Keeping GCC happy over unused vars. [PKH]
// int diff=0;
addr&=0xffff;
if (vram[addr]!=d)
{
// Store dirty information down to 256 byte level in bits
int byt,bit;
byt=addr>>8; bit=byt&7; byt>>=3; byt&=0x1f;
dirt[0x00+byt]|=(1<<bit); dirt[0x34]|=1;
vram[addr]=d;
}
return 0;
}
int md_vdp::poke_cram(int addr,unsigned char d)
{
// int diff=0;
addr&=0x007f;
if (cram[addr]!=d)
{
// Store dirty information down to 1byte level in bits
int byt,bit;
byt=addr; bit=byt&7; byt>>=3; byt&=0x0f;
dirt[0x20+byt]|=(1<<bit); dirt[0x34]|=2;
cram[addr]=d;
}
return 0;
}
int md_vdp::poke_vsram(int addr,unsigned char d)
{
// int diff=0;
addr&=0x007f;
if (vsram[addr]!=d)
{ dirt[0x34]|=4; vsram[addr]=d; }
return 0;
}
int md_vdp::putword(unsigned short d)
{
// int diff=0;
// Called by dma or a straight write
switch(rw_mode)
{
case 0x04: poke_vram (rw_addr+0,d>>8); poke_vram (rw_addr+1,d&0xff); break;
case 0x0c: poke_cram (rw_addr+0,d>>8); poke_cram (rw_addr+1,d&0xff); break;
case 0x14: poke_vsram(rw_addr+0,d>>8); poke_vsram(rw_addr+1,d&0xff); break;
}
rw_addr+=reg[15];
return 0;
}
int md_vdp::putbyte(unsigned char d)
{
// int diff=0;
// Called by dma or a straight write
switch(rw_mode)
{
case 0x04: poke_vram (rw_addr,d>>8); break;
case 0x0c: poke_cram (rw_addr,d>>8); break;
case 0x14: poke_vsram(rw_addr,d>>8); break;
}
rw_addr+=reg[15];
return 0;
}
#undef MAYCHANGE
unsigned short md_vdp::readword()
{
// Called by a straight read only
unsigned short result=0x0000;
switch(rw_mode)
{
case 0x00: result=( vram[(rw_addr+0)&0xffff]<<8)+
vram[(rw_addr+1)&0xffff]; break;
case 0x20: result=( cram[(rw_addr+0)&0x007f]<<8)+
cram[(rw_addr+1)&0x007f]; break;
case 0x10: result=(vsram[(rw_addr+0)&0x007f]<<8)+
vsram[(rw_addr+1)&0x007f]; break;
}
rw_addr+=reg[15];
return result;
}
unsigned char md_vdp::readbyte()
{
// Called by a straight read only
unsigned char result=0x00;
switch(rw_mode)
{
case 0x00: result= vram[(rw_addr+0)&0xffff]; break;
case 0x20: result= cram[(rw_addr+0)&0x007f]; break;
case 0x10: result=vsram[(rw_addr+0)&0x007f]; break;
}
rw_addr+=reg[15];
return result;
}
int md_vdp::command(unsigned int cmd)
{
// Decode 32-bit VDP command
rw_dma=((cmd&0x80)==0x80);
rw_mode= cmd&0x00000070;
rw_mode|=(cmd&0xc0000000)>>28;
// mode writes: 04=VRAM 0C=CRAM 14=VSRAM
// mode reads: 00=VRAM 20=CRAM 10=VSRAM
rw_addr= (cmd&0x00000003)<<14;
rw_addr|=(cmd&0x3fff0000)>>16;
// If not dma (or we need a fill),
// we are set up to write any data sent to vdp data reg
// if it's a dma request do it straight away
if (rw_dma)
{
int mode=(reg[0x17]>>6)&3;
int s=0,d=0,i=0,len=0;
s=dma_addr(); d=rw_addr; len=dma_len();
switch (mode)
{
case 0: case 1:
for (i=0;i<len;i++)
{
unsigned short val;
val= dma_mem_read(s++); val<<=8;
val|=dma_mem_read(s++); putword(val);
}
break;
case 2:
// Done later on
break;
case 3:
for (i=0;i<len;i++)
{
unsigned short val;
val= vram[(s++)&0xffff]; val<<=8;
val|=vram[(s++)&0xffff]; putword(val);
}
break;
}
}
return 0;
}
int md_vdp::writeword(unsigned short d)
{
if (rw_dma)
{
// This is the 'done later on' bit for words
// Do a dma fill if it's set up:
if (((reg[0x17]>>6)&3)==2)
{
int i,len;
len=dma_len();
for (i=0;i<len;i++)
putword(d);
return 0;
}
}
else
{
putword(d);
return 0;
}
return 0;
}
int md_vdp::writebyte(unsigned char d)
{
if (rw_dma)
{
// This is the 'done later on' bit for bytes
// Do a dma fill if it's set up:
if (((reg[0x17]>>6)&3)==2)
{
int i,len;
len=dma_len();
for (i=0;i<len;i++)
putbyte(d);
return 0;
}
}
else
{
putbyte(d);
return 0;
}
return 0;
}
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