bsnes/higan/sfc/coprocessor/mcc/mcc.cpp

137 lines
3.5 KiB
C++

#include <sfc/sfc.hpp>
namespace SuperFamicom {
#include "serialization.cpp"
MCC mcc;
auto MCC::init() -> void {
}
auto MCC::load() -> void {
}
auto MCC::unload() -> void {
rom.reset();
ram.reset();
}
auto MCC::power() -> void {
}
auto MCC::reset() -> void {
for(auto n : range(16)) r[n] = 0x00;
r[0x07] = 0x80;
r[0x08] = 0x80;
commit();
}
auto MCC::memory_access(bool write, Memory& memory, uint24 addr, uint8 data) -> uint8 {
addr = bus.mirror(addr, memory.size());
if(!write) {
return memory.read(addr, data);
} else {
memory.write(addr, data);
}
}
//map address=00-3f,80-bf:8000-ffff mask=0x408000
//map address=40-7d,c0-ff:0000-ffff
auto MCC::mcu_access(bool write, uint24 addr, uint8 data) -> uint8 {
if(addr < 0x400000) {
//note: manifest maps 00-3f,80-bf:8000-ffff mask=0x408000 => 00-3f:0000-ffff
//the intention is consistency in pre-decoding as much as possible
//however, the MCC code is intended to be rewritten; and is too convoluted
//so for right now, I'm simply transforming it back to its original state
//this is very wasteful; but will be addressed once things are rewritten
addr = ((addr & 0x200000) << 2) | ((addr & 0x1f8000) << 1) | 0x8000 | (addr & 0x7fff);
}
if((addr & 0xe08000) == 0x008000) { //$00-1f:8000-ffff
if(r07 == 1) {
addr = ((addr & 0x1f0000) >> 1) | (addr & 0x7fff);
return memory_access(write, rom, addr, data);
}
}
if((addr & 0xe08000) == 0x808000) { //$80-9f:8000-ffff
if(r08 == 1) {
addr = ((addr & 0x1f0000) >> 1) | (addr & 0x7fff);
return memory_access(write, rom, addr, data);
}
}
if((addr & 0xf00000) == 0x400000) { //$40-4f:0000-ffff
if(r05 == 0) return memory_access(write, ram, addr & 0x0fffff, data);
}
if((addr & 0xf00000) == 0x500000) { //$50-5f:0000-ffff
if(r06 == 0) return memory_access(write, ram, addr & 0x0fffff, data);
}
if((addr & 0xf00000) == 0x600000) { //$60-6f:0000-ffff
if(r03 == 1) return memory_access(write, ram, addr & 0x0fffff, data);
}
if((addr & 0xf80000) == 0x700000) { //$70-77:0000-ffff
return memory_access(write, ram, addr & 0x07ffff, data);
}
if(((addr & 0x408000) == 0x008000) //$00-3f,80-bf:8000-ffff
|| ((addr & 0x400000) == 0x400000) //$40-7f,c0-ff:0000-ffff
) {
if(r02 == 0) addr = ((addr & 0x7f0000) >> 1) | (addr & 0x7fff);
Memory& memory = (r01 == 0 ? (Memory&)bsmemory : (Memory&)ram);
return memory_access(write, memory, addr & 0x7fffff, data);
}
return 0x00;
}
auto MCC::mcu_read(uint24 addr, uint8 data) -> uint8 {
return mcu_access(false, addr, data);
}
auto MCC::mcu_write(uint24 addr, uint8 data) -> void {
mcu_access(true, addr, data);
}
auto MCC::read(uint24 addr, uint8 data) -> uint8 {
if((addr & 0xf0ffff) == 0x005000) { //$00-0f:5000
uint8 n = (addr >> 16) & 15;
return r[n];
}
return data;
}
auto MCC::write(uint24 addr, uint8 data) -> void {
if((addr & 0xf0ffff) == 0x005000) { //$00-0f:5000
uint8 n = (addr >> 16) & 15;
r[n] = data;
if(n == 0x0e && data & 0x80) commit();
return;
}
}
auto MCC::commit() -> void {
r00 = r[0x00] & 0x80;
r01 = r[0x01] & 0x80;
r02 = r[0x02] & 0x80;
r03 = r[0x03] & 0x80;
r04 = r[0x04] & 0x80;
r05 = r[0x05] & 0x80;
r06 = r[0x06] & 0x80;
r07 = r[0x07] & 0x80;
r08 = r[0x08] & 0x80;
r09 = r[0x09] & 0x80;
r0a = r[0x0a] & 0x80;
r0b = r[0x0b] & 0x80;
r0c = r[0x0c] & 0x80;
r0d = r[0x0d] & 0x80;
r0e = r[0x0e] & 0x80;
r0f = r[0x0f] & 0x80;
}
}