cartreader/Cart_Reader/NES.ino
nsx0r d30be9dc29
Update NES.ino
fix mapper 52
2024-12-15 12:58:19 +00:00

4752 lines
153 KiB
C++

//******************************************
// NES MODULE
//******************************************
// mostly copy&pasted from "Famicom Dumper" 2019-08-31 by skaman
// also based on "CoolArduino" by HardWareMan
// Pinout changes: LED and CIRAM_A10
#ifdef ENABLE_NES
//Line Content
//37 Supported Mappers
//185 Defines
//211 Variables
//242 Menus
//456 Setup
//486 No-Intro SD Database Functions
//803 Low Level Functions
//1012 File Functions
//1083 Config Functions
//1701 ROM Functions
//3666 RAM Functions
//4066 Eeprom Functions
//4254 NESmaker Flash Cart Functions
struct mapper_NES {
uint16_t mapper;
uint8_t prglo;
uint8_t prghi;
uint8_t chrlo;
uint8_t chrhi;
uint8_t ramlo;
uint8_t ramhi;
};
/******************************************
Supported Mappers
*****************************************/
// Supported Mapper Array (iNES Mapper #s)
// Format = {mapper,prglo,prghi,chrlo,chrhi,ramlo,ramhi}
static const struct mapper_NES PROGMEM mapsize[] = {
{ 0, 0, 1, 0, 1, 0, 2 }, // nrom [sram r/w]
{ 1, 1, 5, 0, 5, 0, 3 }, // mmc1 [sram r/w]
{ 2, 2, 4, 0, 0, 0, 0 }, // uxrom
{ 3, 0, 1, 0, 3, 0, 0 }, // cnrom
{ 4, 1, 5, 0, 6, 0, 1 }, // mmc3/mmc6 [sram/prgram r/w]
{ 5, 3, 5, 5, 7, 0, 3 }, // mmc5 [sram r/w]
{ 7, 2, 4, 0, 0, 0, 0 }, // axrom
{ 9, 3, 3, 5, 5, 0, 0 }, // mmc2 (punch out)
{ 10, 3, 4, 4, 5, 1, 1 }, // mmc4 [sram r/w]
{ 11, 1, 3, 1, 5, 0, 0 }, // Color Dreams [UNLICENSED]
{ 13, 1, 1, 0, 0, 0, 0 }, // cprom (videomation)
{ 15, 6, 6, 0, 0, 0, 0 }, // K-1029/K-1030P [UNLICENSED]
{ 16, 3, 4, 5, 6, 0, 1 }, // bandai x24c02 [eep r/w]
{ 18, 3, 4, 5, 6, 0, 1 }, // jaleco ss8806 [sram r/w]
{ 19, 3, 4, 5, 6, 0, 1 }, // namco 106/163 [sram/prgram r/w]
// 20 - bad mapper, not used
{ 21, 4, 4, 5, 6, 0, 1 }, // vrc4a/vrc4c [sram r/w]
{ 22, 3, 3, 5, 5, 0, 0 }, // vrc2a
{ 23, 3, 3, 5, 6, 0, 0 }, // vrc2b/vrc4e
{ 24, 4, 4, 5, 5, 0, 0 }, // vrc6a (akumajou densetsu)
{ 25, 3, 4, 5, 6, 0, 1 }, // vrc2c/vrc4b/vrc4d [sram r/w]
{ 26, 4, 4, 5, 6, 1, 1 }, // vrc6b [sram r/w]
{ 28, 5, 7, 0, 0, 0, 0 }, // Action 53 [UNLICENSED]
{ 30, 4, 5, 0, 0, 0, 0 }, // unrom 512 (NESmaker) [UNLICENSED]
{ 31, 6, 6, 0, 0, 0, 0 }, // NSF music compilations [UNLICENSED]
{ 32, 3, 4, 5, 5, 0, 0 }, // irem g-101
{ 33, 3, 4, 5, 6, 0, 0 }, // taito tc0190
{ 34, 1, 8, 0, 4, 0, 0 }, // BxROM & NINA
{ 35, 0, 7, 1, 8, 0, 0 }, // J.Y. Company ASIC [UNLICENSED]
{ 36, 0, 3, 1, 5, 0, 0 }, // TXC 01-22000-400 Board [UNLICENSED]
{ 37, 4, 4, 6, 6, 0, 0 }, // (super mario bros + tetris + world cup)
{ 38, 1, 3, 0, 3, 0, 0 }, // Crime Busters [UNLICENSED]
{ 42, 0, 3, 0, 5, 0, 0 }, // hacked FDS games converted to cartridge [UNLICENSED]
{ 45, 3, 6, 0, 8, 0, 0 }, // ga23c asic multicart [UNLICENSED]
{ 46, 1, 6, 0, 8, 0, 0 }, // Rumble Station [UNLICENSED]
{ 47, 4, 4, 6, 6, 0, 0 }, // (super spike vball + world cup)
{ 48, 3, 4, 6, 6, 0, 0 }, // taito tc0690
{ 52, 0, 5, 0, 7, 0, 0 }, // Realtec 8213 [UNLICENSED]
{ 56, 0, 7, 0, 6, 0, 0 }, // KS202 [UNLICENSED]
{ 57, 0, 3, 0, 5, 0, 0 }, // BMC-GKA [UNLICENSED]
{ 58, 1, 6, 1, 6, 0, 0 }, // BMC-GKB (C)NROM-based multicarts, duplicate of mapper 213 [UNLICENSED]
{ 59, 0, 3, 0, 4, 0, 0 }, // BMC-T3H53 & BMC-D1038 [UNLICENSED]
{ 60, 2, 2, 3, 3, 0, 0 }, // Reset-based NROM-128 4-in-1 multicarts [UNLICENSED]
{ 62, 7, 7, 8, 8, 0, 0 }, // K-1017P [UNLICENSED]
{ 63, 8, 8, 0, 0, 0, 0 }, // NTDEC "Powerful" multicart, 3072K [UNLICENSED]
{ 64, 2, 3, 4, 5, 0, 0 }, // tengen rambo-1 [UNLICENSED]
{ 65, 3, 4, 5, 6, 0, 0 }, // irem h-3001
{ 66, 2, 3, 2, 3, 0, 0 }, // gxrom/mhrom
{ 67, 3, 3, 5, 5, 0, 0 }, // sunsoft 3
{ 68, 3, 3, 5, 6, 0, 1 }, // sunsoft 4 [sram r/w]
{ 69, 3, 4, 5, 6, 0, 1 }, // sunsoft fme-7/5a/5b [sram r/w]
{ 70, 3, 3, 5, 5, 0, 0 }, // bandai
{ 71, 2, 4, 0, 0, 0, 0 }, // camerica/codemasters [UNLICENSED]
{ 72, 3, 3, 5, 5, 0, 0 }, // jaleco jf-17
{ 73, 3, 3, 0, 0, 0, 0 }, // vrc3 (salamander)
{ 75, 3, 3, 5, 5, 0, 0 }, // vrc1
{ 76, 3, 3, 5, 5, 0, 0 }, // namco 109 variant (megami tensei: digital devil story)
{ 77, 3, 3, 3, 3, 0, 0 }, // (napoleon senki)
{ 78, 3, 3, 5, 5, 0, 0 }, // irem 74hc161/32
{ 79, 1, 2, 2, 3, 0, 0 }, // NINA-03/06 by AVE [UNLICENSED]
{ 80, 3, 3, 5, 6, 0, 1 }, // taito x1-005 [prgram r/w]
{ 82, 3, 3, 5, 6, 0, 1 }, // taito x1-017 wrong bank order [prgram r/w]
// 84 - bad mapper, not used
{ 85, 3, 5, 0, 5, 0, 1 }, // vrc7 [sram r/w]
{ 86, 3, 3, 4, 4, 0, 0 }, // jaleco jf-13 (moero pro yakyuu)
{ 87, 0, 1, 2, 3, 0, 0 }, // Jaleco/Konami CNROM (DIS_74X139X74)
{ 88, 3, 3, 5, 5, 0, 0 }, // namco (dxrom variant)
{ 89, 3, 3, 5, 5, 0, 0 }, // sunsoft 2 variant (tenka no goikenban: mito koumon)
{ 90, 0, 7, 1, 8, 0, 0 }, // J.Y. Company ASIC [UNLICENSED]
{ 91, 3, 5, 7, 8, 0, 0 }, // JY830623C/YY840238C boards [UNLICENSED]
{ 92, 4, 4, 5, 5, 0, 0 }, // jaleco jf-19/jf-21
{ 93, 3, 3, 0, 0, 0, 0 }, // sunsoft 2
{ 94, 3, 3, 0, 0, 0, 0 }, // hvc-un1rom (senjou no ookami)
{ 95, 3, 3, 3, 3, 0, 0 }, // namcot-3425 (dragon buster)
{ 96, 3, 3, 0, 0, 0, 0 }, // (oeka kids)
{ 97, 4, 4, 0, 0, 0, 0 }, // irem tam-s1 (kaiketsu yanchamaru)
// 100 - bad mapper, not used
// 101 - bad mapper, not used
{ 105, 4, 4, 0, 0, 0, 0 }, // (nintendo world Championships 1990) [UNTESTED]
{ 111, 5, 5, 0, 0, 0, 0 }, // GTROM [UNLICENSED]
{ 113, 1, 4, 0, 5, 0, 0 }, // NINA-03/06 [UNLICENSED]
{ 114, 3, 4, 5, 6, 0, 0 }, // SuperGame MMC3-clone [UNLICENSED]
{ 118, 3, 4, 5, 5, 0, 1 }, // txsrom/mmc3 [sram r/w]
{ 119, 3, 3, 4, 4, 0, 0 }, // tqrom/mmc3
{ 126, 1, 8, 0, 8, 0, 0 }, // MMC3-based multicart (PJ-008, AT-207) [UNLICENSED]
{ 134, 1, 8, 0, 8, 0, 0 }, // T4A54A, WX-KB4K, or BS-5652 [UNLICENSED]
{ 140, 3, 3, 3, 5, 0, 0 }, // jaleco jf-11/jf-14
{ 142, 1, 3, 0, 0, 0, 0 }, // UNL-KS7032 [UNLICENSED]
{ 146, 1, 2, 2, 3, 0, 0 }, // Sachen 3015 [UNLICENSED]
{ 148, 1, 2, 0, 4, 0, 0 }, // Sachen SA-0037 & Tengen 800008 [UNLICENSED]
// 151 - bad mapper, not used
{ 152, 2, 3, 5, 5, 0, 0 }, // BANDAI-74*161/161/32
{ 153, 5, 5, 0, 0, 1, 1 }, // (famicom jump ii) [sram r/w]
{ 154, 3, 3, 5, 5, 0, 0 }, // namcot-3453 (devil man)
{ 155, 3, 3, 3, 5, 0, 1 }, // mmc1 variant [sram r/w]
{ 157, 4, 4, 0, 0, 0, 0 }, // Datach
{ 158, 3, 3, 5, 5, 0, 0 }, // tengen rambo-1 variant (alien syndrome (u)) [UNLICENSED]
{ 159, 3, 4, 5, 6, 1, 1 }, // bandai x24c01 [eep r/w]
{ 162, 6, 7, 0, 0, 0, 0 }, // Waixing FS304 [UNLICENSED]
{ 163, 6, 7, 0, 0, 0, 0 }, // Nanjing FC-001 [UNLICENSED]
{ 174, 3, 3, 4, 4, 0, 0 }, // NTDEC 5-in-1 [UNLICENSED]
{ 176, 4, 4, 5, 5, 0, 0 }, // 8025 enhanced MMC3 [UNLICENSED]
{ 177, 1, 7, 0, 0, 0, 0 }, // Henggedianzi Super Rich PCB [UNLICENSED]
{ 178, 5, 5, 0, 0, 0, 0 }, // some Waixing PCBs [UNLICENSED]
{ 180, 3, 3, 0, 0, 0, 0 }, // unrom variant (crazy climber)
{ 184, 1, 1, 2, 3, 0, 0 }, // sunsoft 1
{ 185, 0, 1, 1, 1, 0, 0 }, // cnrom lockout
// 186 - bad mapper, not used
{ 200, 1, 4, 1, 4, 0, 0 }, // HN-02 multicarts [UNLICENSED]
{ 201, 1, 8, 1, 9, 0, 0 }, // NROM-256 multicarts [UNLICENSED]
{ 202, 0, 3, 1, 4, 0, 0 }, // BMC-150IN1 multicarts [UNLICENSED]
{ 203, 1, 4, 1, 4, 0, 0 }, // various NROM-128 multicarts [UNLICENSED]
{ 206, 1, 3, 2, 4, 0, 0 }, // dxrom
{ 207, 4, 4, 5, 5, 0, 0 }, // taito x1-005 variant (fudou myouou den)
{ 209, 0, 7, 1, 8, 0, 0 }, // J.Y. Company ASIC [UNLICENSED]
{ 210, 3, 5, 5, 6, 0, 0 }, // namco 175/340
{ 211, 0, 7, 1, 8, 0, 0 }, // J.Y. Company ASIC [UNLICENSED]
{ 212, 0, 3, 0, 4, 0, 0 }, // BMC Super HiK 300-in-1 [UNLICENSED]
{ 213, 1, 6, 1, 6, 0, 0 }, // BMC-GKB (C)NROM-based multicarts, duplicate of mapper 58 [UNLICENSED]
{ 214, 0, 3, 0, 4, 0, 0 }, // BMC-SUPERGUN-20IN1, BMC-190IN1 [UNLICENSED]
{ 225, 4, 7, 5, 8, 0, 0 }, // ET-4310 (FC) + K-1010 (NES) [UNLICENSED]
{ 226, 6, 7, 0, 0, 0, 0 }, // BMC-76IN1, BMC-SUPER42IN1, BMC-GHOSTBUSTERS63IN1 [UNLICENSED]
{ 227, 1, 5, 0, 0, 0, 0 }, // 810449-C-A1 / FW-01 [UNLICENSED]
{ 228, 4, 7, 5, 7, 0, 0 }, // Action 52 + Cheetahmen II [UNLICENSED]
{ 229, 5, 5, 6, 6, 0, 0 }, // BMC 31-IN-1 [UNLICENSED]
{ 232, 4, 4, 0, 0, 0, 0 }, // Camerica/Codemasters "Quattro" cartridges [UNLICENSED]
{ 235, 6, 8, 0, 0, 0, 0 }, // "Golden Game" multicarts [UNLICENSED]
{ 236, 0, 6, 0, 5, 0, 0 }, // Realtec 8031, 8099, 8106, 8155 [UNLICENSED]
{ 240, 1, 5, 1, 5, 0, 3 }, // C&E Bootleg Board (Sheng Huo Lie Zhuan, Jing Ke Xin Zhuan) [UNLICENSED]
{ 241, 3, 5, 0, 0, 0, 0 }, // BxROM with WRAM [UNLICENSED]
{ 242, 5, 5, 0, 0, 0, 0 }, // ET-113 [UNLICENSED]
{ 246, 5, 5, 7, 7, 0, 0 }, // C&E Feng Shen Bang [UNLICENSED]
// 248 - bad mapper, not used
{ 255, 4, 7, 5, 8, 0, 0 }, // 110-in-1 multicart (same as 225) [UNLICENSED]
{ 268, 0, 11, 0, 8, 0, 0 }, // 268.0 MindKids/CoolGirl [UNLICENSED]
{ 315, 0, 5, 0, 7, 0, 0 }, // BMC-830134C [UNLICENSED]
{ 329, 1, 7, 0, 0, 0, 3 }, // UNL-EDU2000, same as 177 [UNLICENSED]
{ 366, 0, 6, 0, 8, 0, 0 }, // GN-45 [UNLICENSED]
{ 446, 0, 8, 0, 0, 0, 0 }, // Mindkids SMD172B_FGPA submapper 0 & 1
{ 552, 0, 5, 0, 6, 0, 0 } // Taito X1-017 actual bank order
};
const char _file_name_no_number_fmt[] PROGMEM = "%s.%s";
const char _file_name_with_number_fmt[] PROGMEM = "%s.%02d.%s";
/******************************************
Defines
*****************************************/
#define ROMSEL_HI PORTF |= (1 << 1)
#define ROMSEL_LOW PORTF &= ~(1 << 1)
#define PHI2_HI PORTF |= (1 << 0)
#define PHI2_LOW PORTF &= ~(1 << 0)
#define PRG_READ PORTF |= (1 << 7)
#define PRG_WRITE PORTF &= ~(1 << 7)
#define CHR_READ_HI PORTF |= (1 << 5)
#define CHR_READ_LOW PORTF &= ~(1 << 5)
#define CHR_WRITE_HI PORTF |= (1 << 2)
#define CHR_WRITE_LOW PORTF &= ~(1 << 2)
#define MODE_READ \
{ \
PORTK = 0xFF; \
DDRK = 0; \
}
#define MODE_WRITE DDRK = 0xFF
#define press 1
#define doubleclick 2
#define hold 3
#define longhold 4
/******************************************
Variables
*****************************************/
// Mapper
uint8_t mapcount = (sizeof(mapsize) / sizeof(mapsize[0]));
uint16_t mapselect;
const uint16_t PRG[] PROGMEM = { 16, 32, 64, 128, 256, 512, 1024, 2048, 4096, 8192, 16384, 32768 };
uint8_t prglo = 0; // Lowest Entry
uint8_t prghi = 11; // Highest Entry
const uint16_t CHR[] PROGMEM = { 0, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 4096 };
uint8_t chrlo = 0; // Lowest Entry
uint8_t chrhi = 10; // Highest Entry
const uint8_t RAM[] PROGMEM = { 0, 8, 16, 32 };
uint8_t ramlo = 0; // Lowest Entry
uint8_t ramhi = 3; // Highest Entry
uint16_t prg;
uint16_t chr;
uint8_t ram;
bool mmc6 = false;
bool flashfound = false; // NESmaker 39SF040 Flash Cart
// Cartridge Config
uint16_t mapper;
uint8_t prgsize;
uint8_t chrsize;
uint8_t ramsize;
/******************************************
Menus
*****************************************/
// NES start menu
static const char nesMenuItem1[] PROGMEM = "Read iNES Rom";
static const char nesMenuItem2[] PROGMEM = "Read PRG/CHR";
static const char nesMenuItem5[] PROGMEM = "Change Mapper";
static const char nesMenuItem6[] PROGMEM = "Flash Repro";
static const char* const menuOptionsNES[] PROGMEM = { nesMenuItem1, nesMenuItem2, FSTRING_READ_SAVE, FSTRING_WRITE_SAVE, nesMenuItem5, nesMenuItem6, FSTRING_RESET };
// NES chips menu
static const char nesChipsMenuItem1[] PROGMEM = "Combined PRG+CHR";
static const char nesChipsMenuItem2[] PROGMEM = "Read only PRG";
static const char nesChipsMenuItem3[] PROGMEM = "Read only CHR";
static const char nesChipsMenuItem4[] PROGMEM = "Back";
static const char* const menuOptionsNESChips[] PROGMEM = { nesChipsMenuItem1, nesChipsMenuItem2, nesChipsMenuItem3, nesChipsMenuItem4 };
#if defined(ENABLE_FLASH)
// Repro Writer Menu
static const char nesFlashMenuItem1[] PROGMEM = "Flash NesMaker";
static const char nesFlashMenuItem2[] PROGMEM = "Flash A29040B-MAPPER0";
static const char nesFlashMenuItem3[] PROGMEM = "Back";
static const char* const menuOptionsNESFlash[] PROGMEM = { nesFlashMenuItem1, nesFlashMenuItem2, nesFlashMenuItem3 };
#endif
// NES start menu
void nesMenu() {
unsigned char answer;
// create menu with title "NES CART READER" and 7 options to choose from
convertPgm(menuOptionsNES, 7);
answer = question_box(F("NES CART READER"), menuOptions, 7, 0);
// wait for user choice to come back from the question box menu
switch (answer) {
// Read Rom
case 0:
display_Clear();
// Change working dir to root
sd.chdir("/");
readRom_NES();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
#ifdef ENABLE_GLOBAL_LOG
save_log();
#endif
display_Update();
wait();
break;
// Read single chip
case 1:
nesChipMenu();
break;
// Read RAM
case 2:
sd.chdir();
sprintf(folder, "NES/SAVE");
sd.mkdir(folder, true);
sd.chdir(folder);
readRAM();
resetROM();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
break;
// Write RAM
case 3:
writeRAM();
resetROM();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
break;
// Change Mapper
case 4:
setDefaultRomName();
setMapper();
checkMapperSize();
setPRGSize();
setCHRSize();
setRAMSize();
checkStatus_NES();
break;
#if defined(ENABLE_FLASH)
// Write FLASH
case 5:
nesFlashMenu();
break;
#endif
// Reset
case 6:
resetArduino();
break;
default:
print_MissingModule(); // does not return
}
}
void nesChipMenu() {
// create menu with title "Select NES Chip" and 4 options to choose from
convertPgm(menuOptionsNESChips, 4);
unsigned char answer = question_box(F("Select NES Chip"), menuOptions, 4, 0);
// wait for user choice to come back from the question box menu
switch (answer) {
// Read combined PRG/CHR
case 0:
display_Clear();
// Change working dir to root
sd.chdir("/");
readRaw_NES();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
#ifdef ENABLE_GLOBAL_LOG
save_log();
#endif
display_Update();
wait();
break;
// Read PRG
case 1:
CreateROMFolderInSD();
readPRG(false);
resetROM();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
break;
// Read CHR
case 2:
CreateROMFolderInSD();
readCHR(false);
resetROM();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
break;
// Return to Main Menu
case 3:
nesMenu();
wait();
break;
}
}
#if defined(ENABLE_FLASH)
void nesFlashMenu() {
// create menu with title "Select NES Flash Repro" and 3 options to choose from
convertPgm(menuOptionsNESFlash, 3);
unsigned char answer = question_box(F("Select Flash Writer"), menuOptions, 3, 0);
switch (answer) {
case 0:
if (mapper == 30) {
writeFLASH();
resetROM();
} else {
display_Clear();
println_Msg(FS(string_error5));
println_Msg(F("Can't write to this cartridge"));
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
}
wait();
break;
case 1:
if (mapper == 0) {
display_Clear();
A29040B_writeFLASH();
display_Update();
wait();
} else {
display_Clear();
println_Msg(FS(string_error5));
println_Msg(F("Can't write to this cartridge"));
println_Msg(mapper);
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
}
break;
// Return to Main Menu
case 2:
nesMenu();
wait();
break;
}
}
#endif
/******************************************
Setup
*****************************************/
void setup_NES() {
// Request 5V
setVoltage(VOLTS_SET_5V);
// CPU R/W, IRQ, PPU /RD, PPU /A13, CIRAM /CE, PPU /WR, /ROMSEL, PHI2
DDRF = 0b10110111;
// CPU R/W, IRQ, PPU /RD, PPU /A13, CIRAM /CE, PPU /WR, /ROMSEL, PHI2
PORTF = 0b11111111;
// A0-A7 to Output
DDRL = 0xFF;
// A8-A14 to Output
DDRA = 0xFF;
// Set CIRAM A10 to Input
DDRC &= ~(1 << 2);
// Activate Internal Pullup Resistors
PORTC |= (1 << 2);
// Set D0-D7 to Input
PORTK = 0xFF;
DDRK = 0;
set_address(0);
rgbLed(black_color);
}
/******************************************
Get Mapping from SD database
*****************************************/
uint32_t uppow2(uint32_t n) {
for (int8_t x = 31; x >= 0; x--)
if (n & (1u << x)) {
if ((1u << x) != n)
return (1u << (x + 1));
break;
}
return n;
}
struct database_entry {
char filename[128];
char crc_str[8 + 1 + 8 + 1 + 32 + 1];
uint32_t crc;
char* crc512_str;
uint32_t crc512;
char* iNES_str;
};
void printPRG(unsigned long myOffset) {
display_Clear();
print_Msg(F("Printing PRG at "));
println_Msg(myOffset);
char myBuffer[3];
for (size_t currLine = 0; currLine < 512; currLine += 16) {
for (uint8_t currByte = 0; currByte < 16; currByte++) {
itoa(read_prg_byte(myOffset + currLine + currByte), myBuffer, 16);
for (size_t i = 0; i < 2 - strlen(myBuffer); i++) {
print_Msg(F("0"));
}
// Now print the significant bits
print_Msg(myBuffer);
print_Msg(" ");
}
println_Msg("");
}
display_Update();
}
void setDefaultRomName() {
romName[0] = 'C';
romName[1] = 'A';
romName[2] = 'R';
romName[3] = 'T';
romName[4] = '\0';
}
void setRomnameFromString(const char* input) {
uint8_t myLength = 0;
for (uint8_t i = 0; i < 20 && myLength < 15; i++) {
// Stop at first "(" to remove "(Country)"
if (input[i] == '(') {
break;
}
if (
(input[i] >= '0' && input[i] <= '9') || (input[i] >= 'A' && input[i] <= 'Z') || (input[i] >= 'a' && input[i] <= 'z')) {
romName[myLength++] = input[i];
}
}
// If name consists out of all japanese characters use CART as name
if (myLength == 0) {
setDefaultRomName();
}
}
void printDataLine_NES(void* entry) {
struct database_entry* castEntry = (struct database_entry*)entry;
uint8_t iNES[16];
uint8_t* output;
char* input;
input = castEntry->iNES_str;
output = iNES;
for (uint8_t i = 0; i < sizeof(iNES); i++) {
unsigned int buf;
sscanf(input, "%2X", &buf);
*(output++) = buf;
input += 2;
}
mapper = (iNES[6] >> 4) | (iNES[7] & 0xF0) | ((iNES[8] & 0x0F) << 8);
if ((iNES[9] & 0x0F) != 0x0F) {
// simple notation
prgsize = (iNES[4] | ((iNES[9] & 0x0F) << 8)); //*16
} else {
// exponent-multiplier notation
prgsize = (((1 << (iNES[4] >> 2)) * ((iNES[4] & 0b11) * 2 + 1)) >> 14); //*16
}
if (prgsize != 0)
prgsize = (int(log(prgsize) / log(2)));
if ((iNES[9] & 0xF0) != 0xF0) {
// simple notation
chrsize = (uppow2(iNES[5] | ((iNES[9] & 0xF0) << 4))) * 2; //*4
} else {
// exponent-multiplier notation
chrsize = (((1 << (iNES[5] >> 2)) * ((iNES[5] & 0b11) * 2 + 1)) >> 13) * 2; //*4
}
if (chrsize != 0)
chrsize = (int(log(chrsize) / log(2)));
ramsize = ((iNES[10] & 0xF0) ? (64 << ((iNES[10] & 0xF0) >> 4)) : 0) / 4096; //*4
if (ramsize != 0)
ramsize = (int(log(ramsize) / log(2)));
prg = (int_pow(2, prgsize)) * 16;
if (chrsize == 0)
chr = 0; // 0K
else
chr = (int_pow(2, chrsize)) * 4;
if (ramsize == 0)
ram = 0; // 0K
else if (mapper == 82)
ram = 5; // 5K
else
ram = (int_pow(2, ramsize)) * 4;
// Mapper Variants
// Identify variant for use across multiple functions
if (mapper == 4) { // Check for MMC6/MMC3
checkMMC6();
if (mmc6) {
ram = 1; // 1K
ramsize = 1; // Must be a non-zero value
}
}
printNESSettings();
}
void getMapping() {
FsFile database;
uint32_t oldcrc32 = 0xFFFFFFFF;
uint32_t oldcrc32MMC3 = 0xFFFFFFFF;
char crcStr[9];
display_Clear();
sd.chdir();
if (!database.open("nes.txt", O_READ)) {
print_FatalError(FS(FSTRING_DATABASE_FILE_NOT_FOUND));
// never reached
}
// Read first 512 bytes of first and last block of PRG ROM and compute CRC32
// MMC3 maps the last 8KB block of PRG ROM to 0xE000 while 0x8000 can contain random data after bootup
for (size_t c = 0; c < 512; c++) {
UPDATE_CRC(oldcrc32, read_prg_byte(0x8000 + c));
UPDATE_CRC(oldcrc32MMC3, read_prg_byte(0xE000 + c));
}
oldcrc32 = ~oldcrc32;
oldcrc32MMC3 = ~oldcrc32MMC3;
bool browseDatabase;
// Filter out all 0xFF checksums at 0x8000 and 0xE000
if (oldcrc32 == 0xBD7BC39F && oldcrc32MMC3 == 0xBD7BC39F) {
println_Msg(F("No data found."));
println_Msg(F("Using manual selection"));
display_Update();
delay(500);
setDefaultRomName();
browseDatabase = selectMapping(database);
} else {
println_Msg(F("Searching database"));
print_Msg(F("for "));
sprintf(crcStr, "%08lX", oldcrc32);
print_Msg(crcStr);
if (oldcrc32 != oldcrc32MMC3) {
print_Msg(F(" or "));
sprintf(crcStr, "%08lX", oldcrc32MMC3);
print_Msg(crcStr);
}
println_Msg(F("..."));
display_Update();
while (database.available()) {
struct database_entry entry;
readDatabaseEntry(database, &entry);
//if checksum search was successful set mapper and end search, also filter out 0xFF checksum
if (
entry.crc512 != 0xBD7BC39F && (entry.crc512 == oldcrc32 || entry.crc512 == oldcrc32MMC3)) {
// Rewind to start of entry
rewind_line(database, 3);
break;
}
}
if (database.available()) {
browseDatabase = true;
} else {
// File searched until end but nothing found
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("CRC not found in database"));
println_Msg(F("Using manual selection"));
display_Update();
delay(500);
// Print content of PRG for debugging
//printPRG(0x8000);
//printPRG(0xE000);
// Change ROM name to CART
setDefaultRomName();
browseDatabase = selectMapping(database);
}
}
if (browseDatabase) {
struct database_entry entry;
if (checkCartSelection(database, &readDataLine_NES, &entry, &printDataLine_NES, &setRomnameFromString)) {
// anything else: select current record
// Save Mapper
EEPROM_writeAnything(7, mapper);
EEPROM_writeAnything(9, prgsize);
EEPROM_writeAnything(10, chrsize);
EEPROM_writeAnything(11, ramsize);
}
}
database.close();
}
static void readDatabaseEntry(FsFile& database, struct database_entry* entry) {
get_line(entry->filename, &database, sizeof(entry->filename));
readDataLine_NES(database, entry);
skip_line(&database);
}
void readDataLine_NES(FsFile& database, void* e) {
struct database_entry* entry = (database_entry*)e;
get_line(entry->crc_str, &database, sizeof(entry->crc_str));
entry->crc_str[8] = 0;
entry->crc512_str = &entry->crc_str[8 + 1];
entry->crc512_str[8] = 0;
entry->iNES_str = &entry->crc_str[8 + 1 + 8 + 1];
// Convert "4E4553" to (0x4E, 0x45, 0x53)
unsigned int iNES_BUF;
for (uint8_t j = 0; j < 16; j++) {
sscanf(entry->iNES_str + j * 2, "%2X", &iNES_BUF);
iNES_HEADER[j] = iNES_BUF;
}
entry->crc = strtoul(entry->crc_str, NULL, 16);
entry->crc512 = strtoul(entry->crc512_str, NULL, 16);
}
bool selectMapping(FsFile& database) {
// Select starting letter
byte myLetter = starting_letter();
if (myLetter == 27) {
// Change Mapper
setMapper();
checkMapperSize();
setPRGSize();
setCHRSize();
setRAMSize();
return 0;
} else {
seek_first_letter_in_database(database, myLetter);
}
return 1;
}
void read_NES(const char* fileSuffix, const byte* header, const uint8_t headersize, const boolean renamerom) {
// Get name, add extension and convert to char array for sd lib
createFolderAndOpenFile("NES", "ROM", romName, fileSuffix);
//Initialize progress bar
uint32_t processedProgressBar = 0;
uint32_t totalProgressBar = (uint32_t)(headersize + prgsize * 16 * 1024 + chrsize * 4 * 1024);
draw_progressbar(0, totalProgressBar);
//Write header
if (headersize > 0) {
myFile.write(header, headersize);
// update progress bar
processedProgressBar += headersize;
draw_progressbar(processedProgressBar, totalProgressBar);
}
//Write PRG
readPRG(true);
// update progress bar
processedProgressBar += prgsize * 16 * 1024;
draw_progressbar(processedProgressBar, totalProgressBar);
//Write CHR
readCHR(true);
// update progress bar
processedProgressBar += chrsize * 4 * 1024;
draw_progressbar(processedProgressBar, totalProgressBar);
// Close the file:
myFile.close();
// Compare CRC32 with database
compareCRC("nes.txt", 0, renamerom, headersize);
}
void readRom_NES() {
read_NES("nes", iNES_HEADER, 16, true);
}
void readRaw_NES() {
read_NES("bin", NULL, 0, false);
}
/******************************************
Low Level Functions
*****************************************/
static void set_address(unsigned int address) {
unsigned char l = address & 0xFF;
unsigned char h = address >> 8;
PORTL = l;
PORTA = h;
// PPU /A13
if ((address >> 13) & 1)
PORTF &= ~(1 << 4);
else
PORTF |= 1 << 4;
}
static void set_romsel(unsigned int address) {
if (address & 0x8000) {
ROMSEL_LOW;
} else {
ROMSEL_HI;
}
}
static unsigned char read_prg_byte(unsigned int address) {
MODE_READ;
PRG_READ;
set_address(address);
PHI2_HI;
set_romsel(address);
_delay_us(1);
return PINK;
}
static unsigned char read_chr_byte(unsigned int address) {
MODE_READ;
PHI2_HI;
ROMSEL_HI;
set_address(address);
CHR_READ_LOW;
_delay_us(1);
uint8_t result = PINK;
CHR_READ_HI;
return result;
}
static void write_prg_byte(unsigned int address, uint8_t data) {
PHI2_LOW;
ROMSEL_HI;
MODE_WRITE;
PRG_WRITE;
PORTK = data;
set_address(address); // PHI2 low, ROMSEL always HIGH
// _delay_us(1);
PHI2_HI;
//_delay_us(10);
set_romsel(address); // ROMSEL is low if need, PHI2 high
_delay_us(1); // WRITING
//_delay_ms(1); // WRITING
// PHI2 low, ROMSEL high
PHI2_LOW;
_delay_us(1);
ROMSEL_HI;
// Back to read mode
// _delay_us(1);
PRG_READ;
MODE_READ;
set_address(0);
// Set phi2 to high state to keep cartridge unreseted
// _delay_us(1);
PHI2_HI;
// _delay_us(1);
}
#if defined(ENABLE_FLASH)
static void write_chr_byte(unsigned int address, uint8_t data) {
PHI2_LOW;
ROMSEL_HI;
MODE_WRITE;
PORTK = data;
set_address(address); // PHI2 low, ROMSEL always HIGH
_delay_us(1);
CHR_WRITE_LOW;
_delay_us(1); // WRITING
CHR_WRITE_HI;
_delay_us(1);
MODE_READ;
set_address(0);
PHI2_HI;
//_delay_us(1);
}
#endif
void resetROM() {
set_address(0);
PHI2_HI;
ROMSEL_HI;
}
void write_mmc1_byte(unsigned int address, uint8_t data) { // write loop for 5 bit register
if (address >= 0xE000) {
for (uint8_t i = 0; i < 5; i++) {
write_reg_byte(address, data >> i); // shift 1 bit into temp register [WRITE RAM SAFE]
}
} else {
for (uint8_t j = 0; j < 5; j++) {
write_prg_byte(address, data >> j); // shift 1 bit into temp register
}
}
}
// REFERENCE FOR REGISTER WRITE TO 0xE000/0xF000
// PORTF 7 = CPU R/W = 0
// PORTF 6 = /IRQ = 1
// PORTF 5 = PPU /RD = 1
// PORTF 4 = PPU /A13 = 1
// PORTF 3 = CIRAM /CE = 1
// PORTF 2 = PPU /WR = 1
// PORTF 1 = /ROMSEL
// PORTF 0 = PHI2 (M2)
// WRITE RAM SAFE TO REGISTERS 0xE000/0xF000
static void write_reg_byte(unsigned int address, uint8_t data) { // FIX FOR MMC1 RAM CORRUPTION
PHI2_LOW;
ROMSEL_HI; // A15 HI = E000
MODE_WRITE;
PRG_WRITE; // CPU R/W LO
PORTK = data;
set_address(address); // PHI2 low, ROMSEL always HIGH
// DIRECT PIN TO PREVENT RAM CORRUPTION
// DIFFERENCE BETWEEN M2 LO AND ROMSEL HI MUST BE AROUND 33ns
// IF TIME IS GREATER THAN 33ns THEN WRITES TO 0xE000/0xF000 WILL CORRUPT RAM AT 0x6000/0x7000
PORTF = 0b01111101; // ROMSEL LO/M2 HI
PORTF = 0b01111110; // ROMSEL HI/M2 LO
_delay_us(1);
// Back to read mode
PRG_READ;
MODE_READ;
set_address(0);
// Set phi2 to high state to keep cartridge unreseted
PHI2_HI;
}
static void write_ram_byte(unsigned int address, uint8_t data) { // Mapper 19 (Namco 106/163) WRITE RAM SAFE ($E000-$FFFF)
PHI2_LOW;
ROMSEL_HI;
MODE_WRITE;
PRG_WRITE;
PORTK = data;
set_address(address); // PHI2 low, ROMSEL always HIGH
PHI2_HI;
ROMSEL_LOW; // SET /ROMSEL LOW OTHERWISE CORRUPTS RAM
_delay_us(1); // WRITING
// PHI2 low, ROMSEL high
PHI2_LOW;
_delay_us(1);
ROMSEL_HI;
// Back to read mode
PRG_READ;
MODE_READ;
set_address(0);
// Set phi2 to high state to keep cartridge unreseted
PHI2_HI;
}
static void write_wram_byte(unsigned int address, uint8_t data) { // Mapper 5 (MMC5) RAM
PHI2_LOW;
ROMSEL_HI;
set_address(address);
PORTK = data;
_delay_us(1);
MODE_WRITE;
PRG_WRITE;
PHI2_HI;
_delay_us(1); // WRITING
PHI2_LOW;
ROMSEL_HI;
// Back to read mode
PRG_READ;
MODE_READ;
set_address(0);
// Set phi2 to high state to keep cartridge unreseted
PHI2_HI;
}
// Pirate Mapper 59
static void write_reg_m59(unsigned int address) {
ROMSEL_HI;
MODE_WRITE;
PRG_WRITE;
set_address(address);
set_romsel(address);
_delay_us(1); // WRITING
ROMSEL_HI;
PRG_READ;
MODE_READ;
set_address(0);
}
/******************************************
File Functions
*****************************************/
void CreateROMFolderInSD() {
sd.chdir();
sprintf(folder, "NES/ROM");
sd.mkdir(folder, true);
sd.chdir(folder);
}
FsFile createNewFile(const char* prefix, const char* extension) {
char filename[FILENAME_LENGTH];
snprintf_P(filename, sizeof(filename), _file_name_no_number_fmt, prefix, extension);
for (uint8_t i = 0; i < 100; i++) {
if (!sd.exists(filename)) {
return sd.open(fileName, O_RDWR | O_CREAT);
}
snprintf_P(filename, sizeof(filename), _file_name_with_number_fmt, prefix, i, extension);
}
// Could not find an available name, recompose the original name and error out.
snprintf_P(filename, sizeof(filename), _file_name_no_number_fmt, prefix, extension);
rgbLed(red_color);
display_Clear();
print_Msg(filename);
println_Msg(F(": no available name"));
display_Update();
print_FatalError(sd_error_STR);
rgbLed(black_color);
}
void CreatePRGFileInSD() {
myFile = createNewFile("PRG", "bin");
}
void CreateCHRFileInSD() {
myFile = createNewFile("CHR", "bin");
}
//createNewFile fails to dump RAM if ROM isn't dumped first
//void CreateRAMFileInSD() {
//myFile = createNewFile("RAM", "bin");
//}
//Temporary fix
void CreateRAMFileInSD() {
char fileCount[3];
strcpy(fileName, "RAM");
strcat(fileName, ".bin");
for (uint8_t i = 0; i < 100; i++) {
if (!sd.exists(fileName)) {
myFile = sd.open(fileName, O_RDWR | O_CREAT);
break;
}
sprintf(fileCount, "%02d", i);
strcpy(fileName, "RAM.");
strcat(fileName, fileCount);
strcat(fileName, ".bin");
}
if (!myFile) {
rgbLed(red_color);
display_Clear();
println_Msg(F("RAM FILE FAILED!"));
display_Update();
//print_Error(F("SD Error"), true);
rgbLed(black_color);
}
}
/******************************************
Config Functions
*****************************************/
#if defined(ENABLE_LCD)
void printMapperSelection_NES(int index) {
display_Clear();
mapselect = pgm_read_word(mapsize + index);
print_Msg(FS(FSTRING_MAPPER));
println_Msg(mapselect);
}
#endif
void setMapper() {
uint16_t newmapper;
#ifdef ENABLE_GLOBAL_LOG
// Disable log to prevent unnecessary logging
println_Log(F("Set Mapper manually"));
dont_log = true;
#endif
// OLED
#if defined(ENABLE_OLED)
chooseMapper:
// Read stored mapper
EEPROM_readAnything(7, newmapper);
if (newmapper > 220)
newmapper = 0;
// Split into digits
uint8_t hundreds = newmapper / 100;
uint8_t tens = newmapper / 10 - hundreds * 10;
uint8_t units = newmapper - hundreds * 100 - tens * 10;
// Cycle through all 3 digits
uint8_t digit = 0;
while (digit < 3) {
display_Clear();
println_Msg(F("Select Mapper:"));
display.setCursor(23, 20);
println_Msg(hundreds);
display.setCursor(43, 20);
println_Msg(tens);
display.setCursor(63, 20);
println_Msg(units);
println_Msg("");
println_Msg("");
println_Msg("");
print_STR(press_to_change_STR, 1);
println_Msg(F("Press right to select"));
if (digit == 0) {
display.setDrawColor(1);
display.drawLine(20, 30, 30, 30);
display.setDrawColor(0);
display.drawLine(40, 30, 50, 30);
display.drawLine(60, 30, 70, 30);
display.setDrawColor(1);
} else if (digit == 1) {
display.setDrawColor(0);
display.drawLine(20, 30, 30, 30);
display.setDrawColor(1);
display.drawLine(40, 30, 50, 30);
display.setDrawColor(0);
display.drawLine(60, 30, 70, 30);
display.setDrawColor(1);
} else if (digit == 2) {
display.setDrawColor(0);
display.drawLine(20, 30, 30, 30);
display.drawLine(40, 30, 50, 30);
display.setDrawColor(1);
display.drawLine(60, 30, 70, 30);
}
display.updateDisplay();
while (1) {
/* Check Button
1 click
2 doubleClick
3 hold
4 longHold */
uint8_t b = checkButton();
if (b == 1) {
if (digit == 0) {
if (hundreds < 2)
hundreds++;
else
hundreds = 0;
} else if (digit == 1) {
if (hundreds == 2) {
if (tens < 1)
tens++;
else
tens = 0;
} else {
if (tens < 9)
tens++;
else
tens = 0;
}
} else if (digit == 2) {
if (units < 9)
units++;
else
units = 0;
}
break;
} else if (b == 2) {
if (digit == 0) {
if (hundreds > 0)
hundreds--;
else
hundreds = 2;
} else if (digit == 1) {
if (hundreds == 2) {
if (tens > 0)
tens--;
else
tens = 1;
} else {
if (tens > 0)
tens--;
else
tens = 9;
}
} else if (digit == 2) {
if (units > 0)
units--;
else
units = 9;
}
break;
} else if (b == 3) {
digit++;
break;
}
}
}
display_Clear();
newmapper = hundreds * 100 + tens * 10 + units;
// Check if valid
bool validMapper = 0;
for (uint8_t currMaplist = 0; currMaplist < mapcount; currMaplist++) {
if (pgm_read_word(mapsize + currMaplist) == newmapper)
validMapper = 1;
}
if (!validMapper) {
errorLvl = 1;
display.println(F("Mapper not supported"));
display.updateDisplay();
wait();
goto chooseMapper;
}
// LCD
#elif defined(ENABLE_LCD)
navigateMenu(0, mapcount - 1, &printMapperSelection_NES);
newmapper = mapselect;
display.setCursor(0, 56 + 8);
print_Msg(F("MAPPER "));
print_Msg(newmapper);
println_Msg(F(" SELECTED"));
display_Update();
delay(500);
// Serial Monitor
#elif defined(ENABLE_SERIAL)
setmapper:
String newmap;
bool mapfound = false;
Serial.println(F("SUPPORTED MAPPERS:"));
for (int i = 0; i < mapcount; i++) {
mapselect = pgm_read_word(mapsize + i);
Serial.print("[");
Serial.print(mapselect);
Serial.print("]");
if (i < mapcount - 1) {
if ((i != 0) && ((i + 1) % 10 == 0))
Serial.println(FS(FSTRING_EMPTY));
else
Serial.print(F("\t"));
} else
Serial.println(FS(FSTRING_EMPTY));
}
Serial.print(F("Enter Mapper: "));
while (Serial.available() == 0) {}
newmap = Serial.readStringUntil('\n');
Serial.println(newmap);
newmapper = newmap.toInt();
for (uint8_t i = 0; i < mapcount; i++) {
mapselect = pgm_read_word(mapsize + i);
if (newmapper == mapselect)
mapfound = true;
}
if (mapfound == false) {
Serial.println(F("MAPPER NOT SUPPORTED!"));
Serial.println(FS(FSTRING_EMPTY));
newmapper = 0;
goto setmapper;
}
#endif
EEPROM_writeAnything(7, newmapper);
mapper = newmapper;
#ifdef ENABLE_GLOBAL_LOG
// Enable log again
dont_log = false;
#endif
}
void checkMapperSize() {
mapper_NES v;
for (uint8_t i = 0; i < mapcount; i++) {
memcpy_P(&v, mapsize + i, sizeof(v));
if (mapper == v.mapper) {
prglo = v.prglo;
prghi = v.prghi;
chrlo = v.chrlo;
chrhi = v.chrhi;
ramlo = v.ramlo;
ramhi = v.ramhi;
break;
}
}
}
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
void printPrgSize_NES(int index) {
display_Clear();
print_Msg(F("PRG Size: "));
println_Msg(pgm_read_word(&(PRG[index])));
}
#endif
void setPRGSize() {
uint8_t newprgsize;
#ifdef ENABLE_GLOBAL_LOG
// Disable log to prevent unnecessary logging
println_Log(F("Set PRG Size"));
dont_log = true;
#endif
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
display_Clear();
if (prglo == prghi)
newprgsize = prglo;
else {
newprgsize = navigateMenu(prglo, prghi, &printPrgSize_NES);
display.setCursor(0, 56); // Display selection at bottom
}
print_Msg(F("PRG SIZE "));
print_Msg(pgm_read_word(&(PRG[newprgsize])));
println_Msg(F("K"));
display_Update();
delay(500);
#elif defined(ENABLE_SERIAL)
if (prglo == prghi)
newprgsize = prglo;
else {
setprg:
String sizePRG;
for (int i = 0; i < (prghi - prglo + 1); i++) {
Serial.print(F("Select PRG Size: "));
Serial.print(i);
Serial.print(F(" = "));
Serial.print(pgm_read_word(&(PRG[i + prglo])));
Serial.println(F("K"));
}
Serial.print(F("Enter PRG Size: "));
while (Serial.available() == 0) {}
sizePRG = Serial.readStringUntil('\n');
Serial.println(sizePRG);
newprgsize = sizePRG.toInt() + prglo;
if (newprgsize > prghi) {
Serial.println(F("SIZE NOT SUPPORTED"));
Serial.println(FS(FSTRING_EMPTY));
goto setprg;
}
}
Serial.print(F("PRG Size = "));
Serial.print(pgm_read_word(&(PRG[newprgsize])));
Serial.println(F("K"));
#endif
EEPROM_writeAnything(9, newprgsize);
prgsize = newprgsize;
#ifdef ENABLE_GLOBAL_LOG
// Enable log again
dont_log = false;
#endif
}
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
void printChrSize_NES(int index) {
display_Clear();
print_Msg(F("CHR Size: "));
println_Msg(pgm_read_word(&(CHR[index])));
}
#endif
void setCHRSize() {
uint8_t newchrsize;
#ifdef ENABLE_GLOBAL_LOG
// Disable log to prevent unnecessary logging
println_Log(F("Set CHR Size"));
dont_log = true;
#endif
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
display_Clear();
if (chrlo == chrhi)
newchrsize = chrlo;
else {
newchrsize = navigateMenu(chrlo, chrhi, &printChrSize_NES);
display.setCursor(0, 56); // Display selection at bottom
}
print_Msg(F("CHR SIZE "));
print_Msg(pgm_read_word(&(CHR[newchrsize])));
println_Msg(F("K"));
display_Update();
delay(500);
#elif defined(ENABLE_SERIAL)
if (chrlo == chrhi)
newchrsize = chrlo;
else {
setchr:
String sizeCHR;
for (int i = 0; i < (chrhi - chrlo + 1); i++) {
Serial.print(F("Select CHR Size: "));
Serial.print(i);
Serial.print(F(" = "));
Serial.print(pgm_read_word(&(CHR[i + chrlo])));
Serial.println(F("K"));
}
Serial.print(F("Enter CHR Size: "));
while (Serial.available() == 0) {}
sizeCHR = Serial.readStringUntil('\n');
Serial.println(sizeCHR);
newchrsize = sizeCHR.toInt() + chrlo;
if (newchrsize > chrhi) {
Serial.println(F("SIZE NOT SUPPORTED"));
Serial.println(FS(FSTRING_EMPTY));
goto setchr;
}
}
Serial.print(F("CHR Size = "));
Serial.print(pgm_read_word(&(CHR[newchrsize])));
Serial.println(F("K"));
#endif
EEPROM_writeAnything(10, newchrsize);
chrsize = newchrsize;
#ifdef ENABLE_GLOBAL_LOG
// Enable log again
dont_log = false;
#endif
}
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
void printRamSize_NES(int index) {
display_Clear();
print_Msg(F("RAM Size: "));
if (mapper == 0)
println_Msg(pgm_read_byte(&(RAM[index])) / 4);
else if (mapper == 16)
println_Msg(pgm_read_byte(&(RAM[index])) * 32);
else if (mapper == 19) {
if (index == 2)
println_Msg(F("128"));
else
println_Msg(pgm_read_byte(&(RAM[index])));
} else if ((mapper == 159) || (mapper == 80))
println_Msg(pgm_read_byte(&(RAM[index])) * 16);
else if (mapper == 82)
println_Msg(index * 5);
else
println_Msg(pgm_read_byte(&(RAM[index])));
}
#endif
void setRAMSize() {
uint8_t newramsize;
#ifdef ENABLE_GLOBAL_LOG
// Disable log to prevent unnecessary logging
println_Log(F("Set RAM Size"));
dont_log = true;
#endif
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
display_Clear();
if (ramlo == ramhi)
newramsize = ramlo;
else {
newramsize = navigateMenu(0, ramhi, &printRamSize_NES);
display.setCursor(0, 56); // Display selection at bottom
}
if ((mapper == 16) || (mapper == 159)) {
int sizeEEP = 0;
print_Msg(F("EEPROM SIZE "));
if (mapper == 16)
sizeEEP = pgm_read_byte(&(RAM[newramsize])) * 32;
else
sizeEEP = pgm_read_byte(&(RAM[newramsize])) * 16;
print_Msg(sizeEEP);
println_Msg(F("B"));
} else if (mapper == 19) {
print_Msg(F("RAM SIZE "));
if (newramsize == 2)
println_Msg(F("128B"));
else {
print_Msg(pgm_read_byte(&(RAM[newramsize])));
println_Msg(F("K"));
}
} else if (mapper == 80) {
print_Msg(F("RAM SIZE "));
print_Msg(pgm_read_byte(&(RAM[newramsize])) * 16);
println_Msg(F("B"));
} else {
print_Msg(F("RAM SIZE "));
if (mapper == 0)
print_Msg(newramsize * 2);
else if (mapper == 82)
print_Msg(newramsize * 5);
else
print_Msg(pgm_read_byte(&(RAM[newramsize])));
println_Msg(F("K"));
}
display_Update();
delay(500);
#elif defined(ENABLE_SERIAL)
if (ramlo == ramhi)
newramsize = ramlo;
else {
setram:
String sizeRAM;
for (int i = 0; i < (ramhi - ramlo + 1); i++) {
Serial.print(F("Select RAM Size: "));
Serial.print(i);
Serial.print(F(" = "));
if (mapper == 0) {
Serial.print(pgm_read_byte(&(RAM[i])) / 4);
Serial.println(F("K"));
} else if ((mapper == 16) || (mapper == 159)) {
if (mapper == 16)
Serial.print(pgm_read_byte(&(RAM[i + ramlo])) * 32);
else
Serial.print(pgm_read_byte(&(RAM[i + ramlo])) * 16);
Serial.println(F("B"));
} else if (mapper == 19) {
if (i == 2)
Serial.println(F("128B"));
else {
Serial.print(pgm_read_byte(&(RAM[i + ramlo])));
Serial.println(F("K"));
}
} else {
Serial.print(pgm_read_byte(&(RAM[i + ramlo])));
Serial.println(F("K"));
}
}
Serial.print(F("Enter RAM Size: "));
while (Serial.available() == 0) {}
sizeRAM = Serial.readStringUntil('\n');
Serial.println(sizeRAM);
newramsize = sizeRAM.toInt() + ramlo;
if (newramsize > ramhi) {
Serial.println(F("SIZE NOT SUPPORTED"));
Serial.println(FS(FSTRING_EMPTY));
goto setram;
}
}
if ((mapper == 16) || (mapper == 159)) {
int sizeEEP = 0;
Serial.print(F("EEPROM Size = "));
if (mapper == 16)
sizeEEP = pgm_read_byte(&(RAM[newramsize])) * 32;
else
sizeEEP = pgm_read_byte(&(RAM[newramsize])) * 16;
Serial.print(sizeEEP);
Serial.println(F("B"));
Serial.println(FS(FSTRING_EMPTY));
} else if (mapper == 19) {
Serial.print(F("RAM Size = "));
if (newramsize == 2)
Serial.println(F("128B"));
else {
Serial.print(pgm_read_byte(&(RAM[newramsize])));
Serial.println(F("K"));
}
Serial.println(FS(FSTRING_EMPTY));
} else if (mapper == 80) {
Serial.print(F("RAM Size = "));
Serial.print(pgm_read_byte(&(RAM[newramsize])) * 16);
Serial.println(F("B"));
Serial.println(FS(FSTRING_EMPTY));
} else {
Serial.print(F("RAM Size = "));
if (mapper == 0)
Serial.print(newramsize * 2);
else if (mapper == 82)
Serial.print(newramsize * 5);
else
Serial.print(pgm_read_byte(&(RAM[newramsize])));
Serial.println(F("K"));
Serial.println(FS(FSTRING_EMPTY));
}
#endif
EEPROM_writeAnything(11, newramsize);
ramsize = newramsize;
#ifdef ENABLE_GLOBAL_LOG
// Enable log again
dont_log = false;
#endif
}
// MMC6 Detection
// Mapper 4 includes both MMC3 AND MMC6
// RAM is mapped differently between MMC3 and MMC6
void checkMMC6() { // Detect MMC6 Carts - read PRG 0x3E00A ("STARTROPICS")
write_prg_byte(0x8000, 6); // PRG Bank 0 ($8000-$9FFF)
write_prg_byte(0x8001, 0x1F); // 0x3E000
uint8_t prgchk0 = read_prg_byte(0x800A);
uint8_t prgchk1 = read_prg_byte(0x800B);
uint8_t prgchk2 = read_prg_byte(0x800C);
uint8_t prgchk3 = read_prg_byte(0x800D);
if ((prgchk0 == 0x53) && (prgchk1 == 0x54) && (prgchk2 == 0x41) && (prgchk3 == 0x52))
mmc6 = true; // MMC6 Cart
}
void checkStatus_NES() {
EEPROM_readAnything(7, mapper);
EEPROM_readAnything(9, prgsize);
EEPROM_readAnything(10, chrsize);
EEPROM_readAnything(11, ramsize);
prg = (int_pow(2, prgsize)) * 16;
if (chrsize == 0)
chr = 0; // 0K
else
chr = (int_pow(2, chrsize)) * 4;
if (ramsize == 0)
ram = 0; // 0K
else if (mapper == 82)
ram = 5; // 5K
else
ram = (int_pow(2, ramsize)) * 4;
// Mapper Variants
// Identify variant for use across multiple functions
if (mapper == 4) { // Check for MMC6/MMC3
checkMMC6();
if (mmc6) {
ram = 1; // 1K
ramsize = 1; // Must be a non-zero value
}
} else if (mapper == 30) { // Check for Flashable/Non-Flashable
#if defined(ENABLE_FLASH)
NESmaker_ID(); // Flash ID
#endif
}
display_Clear();
println_Msg(F("NES CART READER"));
println_Msg(FS(FSTRING_EMPTY));
println_Msg(FS(FSTRING_CURRENT_SETTINGS));
println_Msg(FS(FSTRING_EMPTY));
printNESSettings();
println_Msg(FS(FSTRING_EMPTY));
// Prints string out of the common strings array either with or without newline
print_STR(press_button_STR, 1);
display_Update();
wait();
}
static void printNESSettings(void) {
print_Msg(F("MAPPER: "));
println_Msg(mapper);
print_Msg(F("PRG SIZE: "));
print_Msg(prg);
println_Msg(F("K"));
print_Msg(F("CHR SIZE: "));
print_Msg(chr);
println_Msg(F("K"));
print_Msg(F("RAM SIZE: "));
if (mapper == 0) {
print_Msg(ram / 4);
println_Msg(F("K"));
} else if ((mapper == 16) || (mapper == 80) || (mapper == 159)) {
if (mapper == 16)
print_Msg(ram * 32);
else
print_Msg(ram * 16);
println_Msg(F("B"));
} else if (mapper == 19) {
if (ramsize == 2)
println_Msg(F("128B"));
else {
print_Msg(ram);
println_Msg(F("K"));
}
} else {
print_Msg(ram);
println_Msg(F("K"));
}
}
/******************************************
ROM Functions
*****************************************/
void dumpPRG(word base, word address) {
for (size_t x = 0; x < 512; x++) {
sdBuffer[x] = read_prg_byte(base + address + x);
}
myFile.write(sdBuffer, 512);
}
void dumpCHR(word address) {
for (size_t x = 0; x < 512; x++) {
sdBuffer[x] = read_chr_byte(address + x);
}
myFile.write(sdBuffer, 512);
}
void dumpCHR_M2(word address) { // MAPPER 45 - PULSE M2 LO/HI
for (size_t x = 0; x < 512; x++) {
PHI2_LOW;
sdBuffer[x] = read_chr_byte(address + x);
}
myFile.write(sdBuffer, 512);
}
void dumpMMC5RAM(word base, word address) { // MMC5 SRAM DUMP - PULSE M2 LO/HI
for (size_t x = 0; x < 512; x++) {
PHI2_LOW;
sdBuffer[x] = read_prg_byte(base + address + x);
}
myFile.write(sdBuffer, 512);
}
void writeMMC5RAM(word base, word address) { // MMC5 SRAM WRITE
uint8_t bytecheck;
myFile.read(sdBuffer, 512);
for (size_t x = 0; x < 512; x++) {
do {
write_prg_byte(0x5102, 2); // PRG RAM PROTECT1
write_prg_byte(0x5103, 1); // PRG RAM PROTECT2
write_wram_byte(base + address + x, sdBuffer[x]);
bytecheck = read_prg_byte(base + address + x);
} while (bytecheck != sdBuffer[x]); // CHECK WRITTEN BYTE
}
write_prg_byte(0x5102, 0); // PRG RAM PROTECT1
write_prg_byte(0x5103, 0); // PRG RAM PROTECT2
}
void dumpBankPRG(const size_t from, const size_t to, const size_t base) {
for (size_t address = from; address < to; address += 512) {
dumpPRG(base, address);
}
}
void dumpBankCHR(const size_t from, const size_t to) {
for (size_t address = from; address < to; address += 512) {
dumpCHR(address);
}
}
void readPRG(bool readrom) {
if (!readrom) {
display_Clear();
display_Update();
rgbLed(blue_color);
set_address(0);
_delay_us(1);
CreatePRGFileInSD();
} else {
set_address(0);
_delay_us(1);
}
word base = 0x8000;
bool busConflict = false;
uint16_t banks;
if (myFile) {
switch (mapper) {
case 0:
case 3:
case 13:
case 87: // 16K/32K
case 184: // 32K
case 185: // 16K/32K
dumpBankPRG(0, (((word)prgsize) * 0x4000) + 0x4000, base); // 16K or 32K
break;
case 1:
case 155: // 32K/64K/128K/256K/512K
banks = int_pow(2, prgsize) - 1;
for (size_t i = 0; i < banks; i++) { // 16K Banks ($8000-$BFFF)
write_prg_byte(0x8000, 0x80); // Clear Register
write_mmc1_byte(0x8000, 0x0C); // Switch 16K Bank ($8000-$BFFF) + Fixed Last Bank ($C000-$FFFF)
if (prgsize > 4) // 512K
write_mmc1_byte(0xA000, 0x00); // Reset 512K Flag for Lower 256K
if (i > 15) // Switch Upper 256K
write_mmc1_byte(0xA000, 0x10); // Set 512K Flag
write_mmc1_byte(0xE000, i);
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base); // Final Bank ($C000-$FFFF)
break;
case 2: // bus conflicts - fixed last bank
case 30: // bus conflicts in non-flashable configuration
banks = int_pow(2, prgsize);
busConflict = true;
for (size_t i = 0; i < banks - 1; i++) {
for (size_t x = 0; x < 0x4000; x++) {
if (read_prg_byte(0xC000 + x) == i) {
write_prg_byte(0xC000 + x, i);
busConflict = false;
break;
}
}
if (busConflict) {
write_prg_byte(0xC000 + i, i);
}
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base);
break;
case 4:
case 47:
case 64:
case 118:
case 119:
case 158:
banks = ((int_pow(2, prgsize) * 2)) - 2; // Set Number of Banks
if (mapper == 47)
write_prg_byte(0xA001, 0x80); // Block Register - PRG RAM Chip Enable, Writable
for (size_t i = 0; i < banks; i += 2) { // 32K/64K/128K/256K/512K
if (mapper == 47) {
if (i == 0)
write_prg_byte(0x6000, 0); // Switch to Lower Block
else if (i == 16)
write_prg_byte(0x6000, 1); // Switch to Upper Block
}
write_prg_byte(0x8000, 6); // PRG Bank 0 ($8000-$9FFF)
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7); // PRG Bank 1 ($A000-$BFFF)
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
if ((mapper == 64) || (mapper == 158)) {
write_prg_byte(0x8000, 15); // PRG Bank 2 ($C000-$DFFF)
write_prg_byte(0x8001, banks);
}
dumpBankPRG(0x4000, 0x8000, base); // Final 2 Banks ($C000-$FFFF)
break;
case 5: // 128K/256K/512K
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x5100, 3); // 8K PRG Banks
for (size_t i = 0; i < banks; i += 2) { // 128K/256K/512K
write_prg_byte(0x5114, i | 0x80);
write_prg_byte(0x5115, (i + 1) | 0x80);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 7: // 128K/256K
case 77:
case 96: // 128K
case 177: // up to 1024K
case 241:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) { // 32K Banks
write_prg_byte(0x8000, i);
dumpBankPRG(0x0, 0x8000, base); // 32K Banks ($8000-$FFFF)
}
break;
case 9: // 128K
for (size_t i = 0; i < 13; i++) { // 16-3 = 13 = 128K
write_prg_byte(0xA000, i); // $8000-$9FFF
dumpBankPRG(0x0, 0x2000, base); // Switch Bank ($8000-$9FFF)
}
dumpBankPRG(0x2000, 0x8000, base); // Final 3 Banks ($A000-$FFFF)
break;
case 10: // 128K/256K
for (size_t i = 0; i < (unsigned)(((prgsize - 3) * 8) + 7); i++) {
write_prg_byte(0xA000, i); // $8000-$BFFF
dumpBankPRG(0x0, 0x4000, base); // Switch Bank ($8000-$BFFF)
}
dumpBankPRG(0x4000, 0x8000, base); // Final Bank ($C000-$FFFF)
break;
case 11:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xFFB0 + i, i);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 15:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000, i);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 16:
case 159: // 128K/256K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6008, i); // Submapper 4
write_prg_byte(0x8008, i); // Submapper 5
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 18: // 128K/256K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000, i & 0xF);
write_prg_byte(0x8001, (i >> 4) & 0xF);
write_prg_byte(0x8002, (i + 1) & 0xF);
write_prg_byte(0x8003, ((i + 1) >> 4) & 0xF);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 19: // 128K/256K
for (size_t j = 0; j < 64; j++) { // Init Register
write_ram_byte(0xE000, 0); // PRG Bank 0 ($8000-$9FFF)
}
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_ram_byte(0xE000, i); // PRG Bank 0 ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 21: // 256K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xA000, i);
dumpBankPRG(0x2000, 0x4000, base);
}
break;
case 22:
case 25:
case 65:
case 75: // 128K/256K
banks = int_pow(2, prgsize) * 2;
// set vrc4 swap setting for TMNT2
if (mapper == 25)
write_prg_byte(0x9005, 0x00);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000, i);
write_prg_byte(0xA000, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 23:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x9002, 0);
write_prg_byte(0x9008, 0);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 24:
case 26: // 256K
case 78: // 128K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) { // 128K
write_prg_byte(0x8000, i);
dumpBankPRG(0x2000, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 28: // using 32k mode for inner and outer banks, switching only with outer
banks = int_pow(2, prgsize) / 2;
write_prg_byte(0x5000, 0x81);
write_prg_byte(0x8000, 0);
write_prg_byte(0x5000, 0x80);
write_prg_byte(0x8000, 0);
write_prg_byte(0x5000, 0x01);
write_prg_byte(0x8000, 0);
write_prg_byte(0x5000, 0x00);
write_prg_byte(0x8000, 0);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5000, 0x81);
write_prg_byte(0x8000, i);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 31:
banks = int_pow(2, prgsize) * 4;
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0x5FF8, i);
write_prg_byte(0x5FF9, i + 1);
write_prg_byte(0x5FFA, i + 2);
write_prg_byte(0x5FFB, i + 3);
write_prg_byte(0x5FFC, i + 4);
write_prg_byte(0x5FFD, i + 5);
write_prg_byte(0x5FFE, i + 6);
write_prg_byte(0x5FFF, i + 7);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 32: // 128K/256K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) { // 128K/256K
write_prg_byte(0x9000, 1); // PRG Mode 0 - Read $A000-$BFFF to avoid difference between Modes 0 and 1
write_prg_byte(0xA000, i); // PRG Bank
dumpBankPRG(0x2000, 0x4000, base); // 8K Banks ($A000-$BFFF)
}
break;
case 33:
case 48: // 128K/256K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000, i); // PRG Bank 0 ($8000-$9FFF)
write_prg_byte(0x8001, i + 1); // PRG Bank 1 ($A000-$BFFF)
dumpBankPRG(0x0, 0x4000, base); // 8K Banks ($A000-$BFFF)
}
break;
case 34: // BxROM/NINA
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7FFD, i); // NINA Bank select
write_prg_byte(0x8000, i); // BxROM bank select
delay(200); // NINA seems slow to switch banks
dumpBankPRG(0x0, 0x8000, base); // 32K Banks ($8000-$FFFF)
}
break;
case 35:
case 90:
case 209:
case 211:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0xD000, 0x02);
for (uint8_t i = 0; i < banks; i++) {
write_prg_byte(0xD003, (((i >> 5) & 0x06) | 0x20));
write_prg_byte(0x8000, (i & 0x3f));
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 36:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xFFA0 + i, (i << 4));
write_prg_byte(0x4101, 0);
write_prg_byte(0x4102, (i << 4));
write_prg_byte(0x4103, 0);
write_prg_byte(0x4100, 0);
write_prg_byte(0x4103, 0xFF);
write_prg_byte(0xFFFF, 0xFF);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 37:
banks = ((int_pow(2, prgsize) * 2)) - 2; // Set Number of Banks
write_prg_byte(0xA001, 0x80); // Block Register - PRG RAM Chip Enable, Writable
for (size_t i = 0; i < banks; i += 2) { // 256K
if (i == 0)
write_prg_byte(0x6000, 0); // Switch to Lower Block ($0000-$FFFF)
else if (i == 8)
write_prg_byte(0x6000, 3); // Switch to 2nd 64K Block ($10000-$1FFFF)
else if (i == 16)
write_prg_byte(0x6000, 4); // Switch to 128K Block ($20000-$3FFFF)
write_prg_byte(0x8000, 6); // PRG Bank 0 ($8000-$9FFF)
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7); // PRG Bank 1 ($A000-$BFFF)
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base); // Final 2 Banks ($C000-$FFFF)
break;
case 38:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7000, i);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 42:
banks = int_pow(2, prgsize) * 2;
base = 0x6000; // 8k switchable PRG ROM bank at $6000-$7FFF
for (size_t i = 0; i < banks - 4; i++) {
write_prg_byte(0xE000, i & 0x0F);
dumpBankPRG(0x0, 0x2000, base);
}
base = 0x8000; // last 32k fixed to $8000-$FFFF
dumpBankPRG(0x0, 0x8000, base);
break;
case 45: // MMC3 Clone with Outer Registers
banks = ((int_pow(2, prgsize) * 2)) - 2; // Set Number of Banks
for (size_t i = 0; i < banks; i += 2) { // 128K/256K/512K/1024K
// set outer bank registers
write_prg_byte(0x6000, 0x00); // CHR-OR
write_prg_byte(0x6000, (i & 0xC0)); // PRG-OR
write_prg_byte(0x6000, ((i >> 2) & 0xC0)); // CHR-AND,CHR-OR/PRG-OR
write_prg_byte(0x6000, 0x80); // PRG-AND
// set inner bank registers
write_prg_byte(0x8000, 6); // PRG Bank 0 ($8000-$9FFF)
write_prg_byte(0x8001, i);
dumpBankPRG(0x0, 0x2000, base);
// set outer bank registers
write_prg_byte(0x6000, 0x00); // CHR-OR
write_prg_byte(0x6000, ((i + 1) & 0xC0)); // PRG-OR
write_prg_byte(0x6000, (((i + 1) >> 2) & 0xC0)); // CHR-AND,CHR-OR/PRG-OR
write_prg_byte(0x6000, 0x80); // PRG-AND
// set inner bank registers
write_prg_byte(0x8000, 7); // PRG Bank 1 ($A000-$BFFF)
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x2000, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base); // Final 2 Banks ($C000-$FFFF)
break;
case 46:
banks = int_pow(2, prgsize) / 2; // 32k banks
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, (i & 0x1E) >> 1); // high bits
write_prg_byte(0x8000, i & 0x01); // low bit
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 52:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0xA001, 0x80); // enable WRAM write
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, (i & 0x07) >> 4);
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 56:
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xE000, 1);
write_prg_byte(0xF000, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 57:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8800, (i & 0x07) << 5);
write_prg_byte(0x8000, 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 58:
case 213:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000 + (i & 0x07), 0x00);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 59:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i += 2) {
write_reg_m59(0x8000 + ((i & 0x07) << 4));
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 60:
dumpBankPRG(0x0, 0x4000, base);
for (size_t i = 0; i < 3; i++) {
write_prg_byte(0x8D8D, i);
delay(500);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 62:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i * 512) + ((i & 32) << 1), 0x00);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 66: // 64K/128K
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) { // 64K/128K
write_prg_byte(0x8000, i << 4); // bits 4-5
dumpBankPRG(0x0, 0x8000, base); // 32K Banks ($8000-$FFFF)
}
break;
case 63: // 3072K total
banks = int_pow(2, prgsize);
for (size_t i = 0; i < 192; i++) {
write_prg_byte(0x8000 + (i << 2), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 67: // 128K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) { // 128K
write_reg_byte(0xF800, i); // [WRITE RAM SAFE]
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 68:
case 73: // 128K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) { // 128K
write_prg_byte(0xF000, i);
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 69: // 128K/256K
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x8000, 8); // Command Register - PRG Bank 0
write_prg_byte(0xA000, 0); // Parameter Register - PRG RAM Disabled, PRG ROM, Bank 0 to $6000-$7FFF
for (size_t i = 0; i < banks; i++) { // 128K/256K
write_prg_byte(0x8000, 9); // Command Register - PRG Bank 1
write_prg_byte(0xA000, i); // Parameter Register - ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base); // 8K Banks ($8000-$9FFF)
}
break;
case 70:
case 89:
case 152: // 64K/128K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) { // 128K
write_prg_byte(0x8000, i << 4);
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 71: // 64K/128K/256K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xC000, i);
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 72: // 128K
banks = int_pow(2, prgsize);
write_prg_byte(0x8000, 0); // Reset Register
for (size_t i = 0; i < banks; i++) { // 128K
write_prg_byte(0x8000, i | 0x80); // PRG Command + Bank
write_prg_byte(0x8000, i); // PRG Bank
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 76:
case 88:
case 95:
case 154: // 128K
case 206: // 32/64/128K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks - 2; i += 2) {
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7);
write_prg_byte(0x8001, i | 1);
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base);
break;
case 79:
case 146:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x4100, i << 3);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 80: // 128K
case 207: // 256K [CART SOMETIMES NEEDS POWERCYCLE]
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7EFA, i); // PRG Bank 0 ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 82: // 128K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7EFA, i << 2); // PRG Bank 0 ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base); // 8K Banks ($8000-$BFFF)
}
break;
case 85: // 128K/512K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, i); // PRG Bank 0 ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base); // 8K Banks ($8000-$9FFF)
}
break;
case 86:
case 140: // 128K
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) { // 128K
write_prg_byte(0x6000, i << 4); // bits 4-5
dumpBankPRG(0x0, 0x8000, base); // 32K Banks ($8000-$FFFF)
}
break;
case 91:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < (banks - 2); i += 2) {
write_prg_byte(0x7000, (i | 0));
write_prg_byte(0x7001, (i | 1));
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base);
break;
case 92: // 256K
banks = int_pow(2, prgsize);
write_prg_byte(0x8000, 0); // Reset Register
for (size_t i = 0; i < banks; i++) { // 256K
write_prg_byte(0x8000, i | 0x80); // PRG Command + Bank
write_prg_byte(0x8000, i); // PRG Bank
dumpBankPRG(0x4000, 0x8000, base); // 16K Banks ($C000-$FFFF)
}
break;
case 93:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, i);
write_prg_byte(0x8000, i << 4 | 0x01);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 94: // bus conflicts - fixed last bank
banks = int_pow(2, prgsize);
busConflict = true;
for (size_t i = 0; i < banks - 1; i++) {
for (size_t x = 0; x < 0x4000; x++) {
if (read_prg_byte(0xC000 + x) == (i << 2)) {
write_prg_byte(0xC000 + x, i << 2);
busConflict = false;
break;
}
}
if (busConflict) {
write_prg_byte(0x8000 + i, i << 2);
}
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base);
break;
case 97: // fixed first bank
case 180: // bus conflicts - fixed fist bank
banks = int_pow(2, prgsize);
busConflict = true;
dumpBankPRG(0x0, 0x4000, base);
for (size_t i = 1; i < banks; i++) {
for (size_t x = 0; x < 0x4000; x++) {
if (read_prg_byte(0x8000 + x) == i) {
write_prg_byte(0x8000 + x, i);
busConflict = false;
break;
}
}
if (busConflict) {
write_prg_byte(0x8000 + i, i);
}
dumpBankPRG(0x4000, 0x8000, base);
}
break;
case 105: // 256K
write_mmc1_byte(0xA000, 0x00); // Clear PRG Init/IRQ (Bit 4)
write_mmc1_byte(0xA000, 0x10); // Set PRG Init/IRQ (Bit 4) to enable bank swapping
for (size_t i = 0; i < 4; i++) { // PRG CHIP 1 128K
write_mmc1_byte(0xA000, i << 1);
dumpBankPRG(0x0, 0x8000, base); // 32K Banks ($8000-$FFFF)
}
write_mmc1_byte(0x8000, 0x0C); // Switch 16K Bank ($8000-$BFFF) + Fixed Last Bank ($C000-$FFFF)
write_mmc1_byte(0xA000, 0x08); // Select PRG CHIP 2 (Bit 3)
for (size_t j = 0; j < 8; j++) { // PRG CHIP 2 128K
write_mmc1_byte(0xE000, j);
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 111:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5000, i);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 113:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x4100, (i & 0x07) << 3);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 114: // Submapper 0
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x6000, 0);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xA000, 4);
write_prg_byte(0xC000, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 126:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0xA001, 0x80); // enable WRAM
write_prg_byte(0x6003, 0x00); // set MMC3 banking mode
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x6000, (i & 0x180) >> 3 | (i & 0x70) >> 4); // select outer bank
write_prg_byte(0x8000, 6); // 8k bank 0 at $8000
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7); // 8k bank 1 at $A000
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 134:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x6000, 0x00); // set MMC3 banking mode
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x6001, (i & 0x30) >> 4); // select outer bank
write_prg_byte(0x8000, 6); // 8k bank 0 at $8000
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7); // 8k bank 1 at $A000
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 142:
banks = int_pow(2, prgsize) * 2;
base = 0x6000; // 4x 8k switchable PRG ROM banks at $6000-$DFFF
for (size_t i = 0; i < banks; i += 4) {
write_prg_byte(0xE000, 4); // Select 8 KB PRG bank at CPU $6000-$7FFF
write_prg_byte(0xF000, i);
write_prg_byte(0xE000, 1); // Select 8 KB PRG bank at CPU $8000-$9FFF
write_prg_byte(0xF000, i + 1);
write_prg_byte(0xE000, 2); // Select 8 KB PRG bank at CPU $A000-$BFFF
write_prg_byte(0xF000, i + 2);
write_prg_byte(0xE000, 3); // Select 8 KB PRG bank at CPU $C000-$DFFF
write_prg_byte(0xF000, i + 3);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 148: // Sachen SA-008-A and Tengen 800008 -- Bus conflicts
banks = int_pow(2, prgsize) / 2;
busConflict = true;
for (size_t i = 0; i < banks; i++) {
for (size_t x = 0; x < 0x8000; x++) {
if (read_prg_byte(0x8000 + x) == i) {
write_prg_byte(0x8000 + x, i << 3);
busConflict = false;
break;
}
}
if (busConflict) {
write_prg_byte(0x8000 + i, i << 3);
}
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 153: // 512K
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) { // 512K
write_prg_byte(0x8000, i >> 4); // PRG Outer Bank (Documentation says duplicate over $8000-$8003 registers)
write_prg_byte(0x8001, i >> 4); // PRG Outer Bank
write_prg_byte(0x8002, i >> 4); // PRG Outer Bank
write_prg_byte(0x8003, i >> 4); // PRG Outer Bank
write_prg_byte(0x8008, i & 0xF); // PRG Inner Bank
dumpBankPRG(0x0, 0x4000, base); // 16K Banks ($8000-$BFFF)
}
break;
case 157:
for (size_t i = 0; i < 15; i++) {
write_prg_byte(0x8008, i); // select 16k bank at $8000-$BFFF
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base); // last 16k bank fixed at $C000-$FFFF
break;
case 162:
banks = int_pow(2, prgsize) / 2;
write_prg_byte(0x5300, 0x07); // A16-A15 controlled by $5000
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5200, (i & 0x30) >> 4); // A20-A19
write_prg_byte(0x5000, i & 0x0F); // A18-A15
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 163:
banks = int_pow(2, prgsize) / 2;
write_prg_byte(0x5300, 0x04); // disable bit swap on writes to $5000-$5200
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5200, (i & 0x30) >> 4); // A20-A19
write_prg_byte(0x5000, i & 0x0F); // A18-A15
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 174: // 128k
for (size_t i = 0; i < 8; i++) {
write_prg_byte(0xFF00 + (i << 4), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 176:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x5FF3, 0); // extended MMC3 mode: disabled
write_prg_byte(0x5FF0, 1); // 256K outer bank mode
for (size_t i = 0; i < banks - 3; i += 2) {
write_prg_byte(0x5FF1, (i & 0xE0) >> 1); // outer bank select
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 7);
write_prg_byte(0x8001, i + 1);
dumpBankPRG(0x0, 0x4000, base);
}
dumpBankPRG(0x4000, 0x8000, base);
break;
case 178:
banks = int_pow(2, prgsize);
write_prg_byte(0x4800, 0); // NROM-256 mode
write_prg_byte(0x4803, 0); // set PRG-RAM
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x4802, i >> 3); // high PRG (up to 8 bits?!)
write_prg_byte(0x4801, i & 0x07); // low PRG (3 bits)
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 200:
case 212:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i & 0x07), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 201:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i & 0xFF), 0);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 202:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | (i << 1), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 203:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, (i & 0x1F) << 2);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 210: // 128K/256K
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0xE000, i); // PRG Bank 0 ($8000-$9FFF) [WRITE NO RAM]
write_prg_byte(0xE800, i + 1); // PRG Bank 1 ($A000-$BFFF) [WRITE NO RAM]
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 214:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | (i << 2), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 225:
case 255:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8000 + (((i & 0x40) << 8) | ((i & 0x3F) << 6)), 0);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 226:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x8001, (i & 0x40) >> 6);
write_prg_byte(0x8000, ((i & 0x20) << 2) | (i & 0x1F));
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 227:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8083 + ((i & 0xF) << 3), 0);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 228:
banks = int_pow(2, prgsize);
write_prg_byte(0x8000, 0);
for (size_t i = 0; i < banks; i += 2) { // up to 1024k PRG
write_prg_byte(0x8000 + ((i & 0x3F) << 6), 0);
dumpBankPRG(0x0, 0x8000, base);
}
if (prgsize > 5) { // reading the 3rd 512k PRG chip (Action 52)
for (size_t i = 0; i < 32; i += 2) {
write_prg_byte(0x9800 + ((i & 0x1F) << 6), 0);
dumpBankPRG(0x0, 0x8000, base);
}
}
break;
case 229:
write_prg_byte(0x8000, 0);
dumpBankPRG(0x0, 0x8000, base);
for (size_t i = 2; i < 32; i++) {
write_prg_byte(0x8000 + i, i);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 232:
banks = int_pow(2, prgsize) / 4;
for (size_t outerbank = 0; outerbank < 4; outerbank++) {
write_prg_byte(0x8000, outerbank << 3);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xC000, i);
dumpBankPRG(0x0, 0x4000, base);
}
}
break;
case 235:
for (size_t i = 0; i < 32; i++) {
write_prg_byte(0x8000 + i, 0);
dumpBankPRG(0x0, 0x8000, base);
}
if (prgsize > 6) {
for (size_t i = 32; i < 64; i++) {
write_prg_byte(0x80E0 + i, 0);
dumpBankPRG(0x0, 0x8000, base);
}
if (prgsize > 7) {
for (size_t i = 64; i < 96; i++) {
write_prg_byte(0x81E0 + i, 0);
dumpBankPRG(0x0, 0x8000, base);
}
for (size_t i = 96; i < 128; i++) {
write_prg_byte(0x82E0 + i, 0);
dumpBankPRG(0x0, 0x8000, base);
}
}
}
break;
case 236:
banks = int_pow(2, prgsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | ((i & 0x38) >> 3), 0); // A19-A17
write_prg_byte(0xC030 | (i & 0x0F), 0); // A17-A14
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 240:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5FFF, (i & 0xF) << 4);
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 242: // total size is 640k THIS IS NORMAL
for (size_t i = 0; i < 32; i++) { // dump 1st chip of 512k
write_prg_byte(0x8400 + (i * 4), 0);
dumpBankPRG(0x0, 0x4000, base);
}
for (size_t i = 0; i < 8; i++) { // dump 2nd chip of 128k
write_prg_byte(0x8000 + (i * 4), 0);
dumpBankPRG(0x0, 0x4000, base);
}
break;
case 246:
banks = int_pow(2, prgsize) / 2;
for (size_t i = 0; i < banks; i += 4) {
write_prg_byte(0x6000, (i | 0));
write_prg_byte(0x6001, (i | 1));
write_prg_byte(0x6002, (i | 2));
write_prg_byte(0x6003, (i | 3));
dumpBankPRG(0x0, 0x8000, base);
}
break;
case 268: // submapper 0
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, ((i & 0x70) >> 4) | ((i & 0xC00) >> 6));
write_prg_byte(0x6001, ((i & 0x80) >> 3) | ((i & 0x300) >> 6) | 0x60);
write_prg_byte(0x6002, 0x00);
write_prg_byte(0x6003, 0x00);
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 315:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0xA001, 0x80);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6800, (i & 30) >> 3);
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 366:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0xA001, 0x80);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6800 + (i & 0x70), i);
write_prg_byte(0x8000, 6);
write_prg_byte(0x8001, i);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 446:
banks = int_pow(2, prgsize) * 2;
write_prg_byte(0x5003, 0);
write_prg_byte(0x5005, 0);
for (uint8_t i = 0; i < banks; i++) { // 8192 for 64MiB
write_prg_byte(0x5002, i >> 8); // outer bank LSB
write_prg_byte(0x5001, i); // outer bank MSB
write_prg_byte(0x8000, 0);
dumpBankPRG(0x0, 0x2000, base);
}
break;
case 552:
banks = int_pow(2, prgsize) * 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7EFA, ((i & 0x01) << 5) | ((i & 0x02) << 3) | ((i & 0x04) << 1) | ((i & 0x08) >> 1) | ((i & 0x10) >> 3) | ((i & 0x20) >> 5)); // PRG Bank 0 ($8000-$9FFF)
dumpBankPRG(0x0, 0x2000, base); // 8K Banks ($8000-$BFFF)
}
break;
}
if (!readrom) {
myFile.flush();
myFile.close();
println_Msg(F("PRG FILE DUMPED!"));
println_Msg(FS(FSTRING_EMPTY));
display_Update();
}
}
set_address(0);
PHI2_HI;
ROMSEL_HI;
rgbLed(black_color);
}
void readCHR(bool readrom) {
if (!readrom) {
display_Clear();
display_Update();
}
uint16_t banks;
rgbLed(green_color);
set_address(0);
_delay_us(1);
if (chrsize == 0) {
println_Msg(F("CHR SIZE 0K"));
display_Update();
} else {
if (!readrom) {
CreateCHRFileInSD();
}
if (myFile) {
switch (mapper) {
case 0: // 8K
dumpBankCHR(0x0, 0x2000);
break;
case 1:
case 155:
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i += 2) { // 8K/16K/32K/64K/128K (Bank #s are based on 4K Banks)
write_prg_byte(0x8000, 0x80); // Clear Register
write_mmc1_byte(0xA000, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 3: // 8K/16K/32K - bus conflicts
case 148: // Sachen SA-008-A and Tengen 800008 - Bus conflicts
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
for (size_t x = 0; x < 0x8000; x++) {
if (read_prg_byte(0x8000 + x) == i) {
write_prg_byte(0x8000 + x, i);
break;
}
}
dumpBankCHR(0x0, 0x2000);
}
break;
case 4:
case 47:
case 64:
case 118:
case 119:
case 158:
banks = int_pow(2, chrsize) * 4;
if (mapper == 47)
write_prg_byte(0xA001, 0x80); // Block Register - PRG RAM Chip Enable, Writable
for (size_t i = 0; i < banks; i += 4) { // 8K/16K/32K/64K/128K/256K
if (mapper == 47) {
if (i == 0)
write_prg_byte(0x6000, 0); // Switch to Lower Block
else if (i == 128)
write_prg_byte(0x6000, 1); // Switch to Upper Block
}
write_prg_byte(0x8000, 0); // CHR Bank 0 ($0000-$07FF)
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 1); // CHR Bank 1 ($0800-$0FFF)
write_prg_byte(0x8001, i + 2);
dumpBankCHR(0x0, 0x1000);
}
break;
case 5: // 128K/256K/512K
banks = int_pow(2, chrsize) / 2;
write_prg_byte(0x5101, 0); // 8K CHR Banks
for (size_t i = 0; i < banks; i++) {
if (i == 0)
write_prg_byte(0x5130, 0); // Set Upper 2 bits
else if (i == 8)
write_prg_byte(0x5130, 1); // Set Upper 2 bits
else if (i == 16)
write_prg_byte(0x5130, 2); // Set Upper 2 bits
else if (i == 24)
write_prg_byte(0x5130, 3); // Set Upper 2 bits
write_prg_byte(0x5127, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 9:
case 10: // Mapper 9: 128K, Mapper 10: 64K/128K
if (mapper == 9)
banks = 32;
else // Mapper 10
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i++) { // 64K/128K
write_prg_byte(0xB000, i);
write_prg_byte(0xC000, i);
dumpBankCHR(0x0, 0x1000);
}
break;
case 11:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xFFB0 + i, i << 4);
dumpBankCHR(0x0, 0x2000);
}
break;
case 16:
case 159: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, i); // Submapper 4
write_prg_byte(0x8000, i); // Submapper 5
dumpBankCHR(0x0, 0x400);
}
break;
case 18: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xA000, i & 0xF); // CHR Bank Lower 4 bits
write_prg_byte(0xA001, (i >> 4) & 0xF); // CHR Bank Upper 4 bits
dumpBankCHR(0x0, 0x400);
}
break;
case 19: // 128K/256K
for (size_t j = 0; j < 64; j++) { // Init Register
write_ram_byte(0xE800, 0xC0); // CHR RAM High/Low Disable (ROM Enable)
}
banks = int_pow(2, chrsize) * 4;
write_ram_byte(0xE800, 0xC0); // CHR RAM High/Low Disable (ROM Enable)
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0x8000, i); // CHR Bank 0
write_prg_byte(0x8800, i + 1); // CHR Bank 1
write_prg_byte(0x9000, i + 2); // CHR Bank 2
write_prg_byte(0x9800, i + 3); // CHR Bank 3
write_prg_byte(0xA000, i + 4); // CHR Bank 4
write_prg_byte(0xA800, i + 5); // CHR Bank 5
write_prg_byte(0xB000, i + 6); // CHR Bank 6
write_prg_byte(0xB800, i + 7); // CHR Bank 7
dumpBankCHR(0x0, 0x2000);
}
break;
case 21: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xB000, i & 0xF); // CHR Bank Lower 4 bits
if (chrsize == 5) // Check CHR Size to determine VRC4a (128K) or VRC4c (256K)
write_prg_byte(0xB002, (i >> 4) & 0xF); // CHR Bank Upper 4 bits VRC4a (Wai Wai World 2)
else // banks == 256
write_prg_byte(0xB040, (i >> 4) & 0xF); // CHR Bank Upper 4 bits VRC4c (Ganbare Goemon Gaiden 2)
dumpBankCHR(0x0, 0x400);
}
break;
case 22: // 128K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xB000, (i << 1) & 0xF); // CHR Bank Lower 4 bits
write_prg_byte(0xB002, (i >> 3) & 0xF); // CHR Bank Upper 4 bits
dumpBankCHR(0x0, 0x400);
}
break;
case 23:
{ // 128K
banks = int_pow(2, chrsize) * 4;
// Detect VRC4e Carts - read PRG 0x1FFF6 (DATE)
// Boku Dracula-kun = 890810, Tiny Toon = 910809
// Crisis Force = 910701, Parodius Da! = 900916
write_prg_byte(0x8000, 15);
uint8_t prgchk0 = read_prg_byte(0x9FF6);
if (prgchk0 == 0x30) { // Check for "0" in middle of date. If true, assume VRC4e Cart
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xB000, i & 0xF); // CHR Bank Lower 4 bits
write_prg_byte(0xB004, (i >> 4) & 0xF); // CHR Bank Upper 4 bits VRC4e
dumpBankCHR(0x0, 0x400);
}
break;
}
// VRC2b/VRC4f - See https://www.nesdev.org/wiki/VRC2_and_VRC4
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0xB000, i & 0xF); // CHR Bank 0: Lower 4 bits
write_prg_byte(0xB001, (i >> 4) & 0xF); // CHR Bank 0: Upper 4 bits
write_prg_byte(0xB002, (i + 1) & 0xF); // CHR Bank 1: Lower 4 bits
write_prg_byte(0xB003, ((i + 1) >> 4) & 0xF); // CHR Bank 1: Upper 4 bits
write_prg_byte(0xC000, (i + 2) & 0xF); // CHR Bank 2: Lower 4 bits
write_prg_byte(0xC001, ((i + 2) >> 4) & 0xF); // CHR Bank 2: Upper 4 bits
write_prg_byte(0xC002, (i + 3) & 0xF); // CHR Bank 3: Lower 4 bits
write_prg_byte(0xC003, ((i + 3) >> 4) & 0xF); // CHR Bank 3: Upper 4 bits
write_prg_byte(0xD000, (i + 4) & 0xF); // CHR Bank 4: Lower 4 bits
write_prg_byte(0xD001, ((i + 4) >> 4) & 0xF); // CHR Bank 4: Upper 4 bits
write_prg_byte(0xD002, (i + 5) & 0xF); // CHR Bank 5: Lower 4 bits
write_prg_byte(0xD003, ((i + 5) >> 4) & 0xF); // CHR Bank 5: Upper 4 bits
write_prg_byte(0xE000, (i + 6) & 0xF); // CHR Bank 6: Lower 4 bits
write_prg_byte(0xE001, ((i + 6) >> 4) & 0xF); // CHR Bank 6: Upper 4 bits
write_prg_byte(0xE002, (i + 7) & 0xF); // CHR Bank 7: Lower 4 bits
write_prg_byte(0xE003, ((i + 7) >> 4) & 0xF); // CHR Bank 7: Upper 4 bits
dumpBankCHR(0x0, 0x2000); // 8 Banks for a total of 8 KiB
}
break;
}
case 24: // 128K
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xB003, 0); // PPU Banking Mode 0
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0xD000, i); // CHR Bank 0
write_prg_byte(0xD001, i + 1); // CHR Bank 1
write_prg_byte(0xD002, i + 2); // CHR Bank 2
write_prg_byte(0xD003, i + 3); // CHR Bank 3
write_prg_byte(0xE000, i + 4); // CHR Bank 4 [WRITE NO RAM]
write_prg_byte(0xE001, i + 5); // CHR Bank 5 [WRITE NO RAM]
write_prg_byte(0xE002, i + 6); // CHR Bank 6 [WRITE NO RAM]
write_prg_byte(0xE003, i + 7); // CHR Bank 7 [WRITE NO RAM]
dumpBankCHR(0x0, 0x2000); // 1K Banks
}
break;
case 25: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xB000, i & 0xF); // CHR Bank Lower 4 bits
write_prg_byte(0xB00A, (i >> 4) & 0xF); // Combine VRC2c and VRC4b, VRC4d reg
dumpBankCHR(0x0, 0x400);
}
break;
case 26: // 128K/256K
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xB003, 0x00);
for (size_t i = 0; i < banks; i += 4) {
write_prg_byte(0xD000, i + 0); // CHR Bank 0
write_prg_byte(0xD002, i + 1); // CHR Bank 1
write_prg_byte(0xD001, i + 2); // CHR Bank 2
write_prg_byte(0xD003, i + 3); // CHR Bank 3
dumpBankCHR(0x0, 0x1000); // 1K Banks
}
break;
case 32: // 128K
case 65: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0xB000, i); // CHR Bank 0
write_prg_byte(0xB001, i + 1); // CHR Bank 1
write_prg_byte(0xB002, i + 2); // CHR Bank 2
write_prg_byte(0xB003, i + 3); // CHR Bank 3
write_prg_byte(0xB004, i + 4); // CHR Bank 4
write_prg_byte(0xB005, i + 5); // CHR Bank 5
write_prg_byte(0xB006, i + 6); // CHR Bank 6
write_prg_byte(0xB007, i + 7); // CHR Bank 7
dumpBankCHR(0x0, 0x2000);
}
break;
case 33: // 128K/256K
case 48: // 256K
banks = int_pow(2, chrsize) * 2;
for (size_t i = 0; i < banks; i += 2) { // 2K Banks
write_prg_byte(0x8002, i); // CHR Bank 0
write_prg_byte(0x8003, i + 1); // CHR Bank 1
dumpBankCHR(0x0, 0x1000);
}
break;
case 34: // NINA
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x7FFE, i); // Select 4 KB CHR bank at $0000
write_prg_byte(0x7FFF, i + 1); // Select 4 KB CHR bank at $1000
dumpBankCHR(0x0, 0x2000);
}
break;
case 35:
case 90:
case 209:
case 211:
banks = int_pow(2, chrsize) / 2;
write_prg_byte(0xD000, 0x02);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xD003, (((i >> 3) & 0x18) | 0x20));
write_prg_byte(0x9000, (i & 0x3f));
dumpBankCHR(0x0, 0x2000);
}
break;
case 36:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x4200, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 37:
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80); // Block Register - PRG RAM Chip Enable, Writable
for (size_t i = 0; i < banks; i += 4) { // 256K
if (i == 0)
write_prg_byte(0x6000, 0); // Switch to Lower Block ($00000-$1FFFF)
else if (i == 128)
write_prg_byte(0x6000, 4); // Switch to Upper Block ($20000-$3FFFF)
write_prg_byte(0x8000, 0); // CHR Bank 0 ($0000-$07FF)
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 1); // CHR Bank 1 ($0800-$0FFF)
write_prg_byte(0x8001, i + 2);
dumpBankCHR(0x0, 0x1000);
}
break;
case 38:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x7000, i << 2);
dumpBankCHR(0x0, 0x2000);
}
break;
case 42:
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, i & 0x0F);
dumpBankCHR(0x0, 0x1000);
}
break;
case 45: // 128K/256K/512K/1024K
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80); // Unlock Write Protection - not used by some carts
for (size_t i = 0; i < banks; i++) {
// set outer bank registers
write_prg_byte(0x6000, 0x00); // CHR-OR
write_prg_byte(0x6000, 0x00); // PRG-OR
write_prg_byte(0x6000, (((i / 256) << 4) | 0x0F)); // CHR-AND,CHR-OR/PRG-OR
write_prg_byte(0x6000, 0x80); // PRG-AND
// set inner bank registers
write_prg_byte(0x8000, 0x2); // CHR Bank 2 ($1000-$13FF)
write_prg_byte(0x8001, i);
for (size_t address = 0x1000; address < 0x1200; address += 512) {
dumpCHR_M2(address); // Read CHR with M2 Pulse
}
// set outer bank registers
write_prg_byte(0x6000, 0x00); // CHR-OR
write_prg_byte(0x6000, 0x00); // PRG-OR
write_prg_byte(0x6000, (((i / 256) << 4) | 0x0F)); // CHR-AND,CHR-OR/PRG-OR
write_prg_byte(0x6000, 0x80); // PRG-AND
// set inner bank registers
write_prg_byte(0x8000, 0x2); // CHR Bank 2 ($1000-$13FF)
write_prg_byte(0x8001, i);
for (size_t address = 0x1200; address < 0x1400; address += 512) {
dumpCHR_M2(address); // Read CHR with M2 Pulse
}
}
break;
case 46:
banks = int_pow(2, chrsize); // 8k banks
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, (i & 0x78) << 1); // high bits
write_prg_byte(0x8000, (i & 0x07) << 4); // low bits
dumpBankCHR(0x0, 0x2000);
}
break;
case 52:
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80); // enable WRAM write
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, (i & 0x180) >> 3 | (i & 0x200) >> 7);
write_prg_byte(0x8000, 0x02);
write_prg_byte(0x8001, i);
dumpBankCHR(0x1000, 0x1400);
}
break;
case 56:
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0xFC00, i);
dumpBankCHR(0x0, 0x400);
}
break;
case 57:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8800, i & 0x07); // A15-A13
write_prg_byte(0x8000, 0x80 | ((i & 0x08) << 3)); // A16
dumpBankCHR(0x0, 0x2000);
}
break;
case 58:
case 213:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + ((i & 0x07) << 3), 0x00);
dumpBankCHR(0x0, 0x2000);
}
break;
case 59:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_reg_m59(0x8000 + (i & 0x07));
dumpBankCHR(0x0, 0x2000);
}
break;
case 60:
for (size_t i = 0; i < 4; i++) {
write_prg_byte(0x8D8D, i);
delay(500);
dumpBankCHR(0x0, 0x2000);
}
break;
case 62:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i / 4), i & 3);
dumpBankCHR(0x0, 0x2000);
}
break;
case 66: // 16K/32K
case 70:
case 152: // 128K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 8K Banks
write_prg_byte(0x8000, i); // CHR Bank 0
dumpBankCHR(0x0, 0x2000);
}
break;
case 67: // 128K
banks = int_pow(2, chrsize) * 2;
for (size_t i = 0; i < banks; i += 4) { // 2K Banks
write_prg_byte(0x8800, i); // CHR Bank 0
write_prg_byte(0x9800, i + 1); // CHR Bank 1
write_prg_byte(0xA800, i + 2); // CHR Bank 2
write_prg_byte(0xB800, i + 3); // CHR Bank 3
dumpBankCHR(0x0, 0x2000);
}
break;
case 68: // 128K/256K
banks = int_pow(2, chrsize) * 2;
for (size_t i = 0; i < banks; i += 4) { // 2K Banks
write_prg_byte(0x8000, i); // CHR Bank 0
write_prg_byte(0x9000, i + 1); // CHR Bank 1
write_prg_byte(0xA000, i + 2); // CHR Bank 2
write_prg_byte(0xB000, i + 3); // CHR Bank 3
dumpBankCHR(0x0, 0x2000);
}
break;
case 69: // 128K/256K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, 0); // Command Register - CHR Bank 0
write_prg_byte(0xA000, i); // Parameter Register - ($0000-$03FF)
dumpBankCHR(0x0, 0x400); // 1K Banks
}
break;
case 72: // 128K
banks = int_pow(2, chrsize) / 2;
write_prg_byte(0x8000, 0); // Reset Register
for (size_t i = 0; i < banks; i++) { // 8K Banks
write_prg_byte(0x8000, i | 0x40); // CHR Command + Bank
write_prg_byte(0x8000, i); // CHR Bank
dumpBankCHR(0x0, 0x2000);
}
break;
case 75: // 128K
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i++) { // 4K Banks
write_reg_byte(0xE000, i); // CHR Bank Low Bits [WRITE RAM SAFE]
write_prg_byte(0x9000, (i & 0x10) >> 3); // High Bit
dumpBankCHR(0x0, 0x1000);
}
break;
case 76: // 128K
banks = int_pow(2, chrsize) * 2;
for (size_t i = 0; i < banks; i += 2) { // 2K Banks
write_prg_byte(0x8000, 2); // CHR Command ($0000-$07FF) 2K Bank
write_prg_byte(0x8001, i); // CHR Bank
write_prg_byte(0x8000, 3); // CHR Command ($0800-$0FFF) 2K Bank
write_prg_byte(0x8001, i + 1); // CHR Bank
dumpBankCHR(0x0, 0x1000);
}
break;
case 77: // 32K
banks = int_pow(2, chrsize) * 2;
for (size_t i = 0; i < banks; i++) { // 2K Banks
write_prg_byte(0x8000, i << 4); // CHR Bank 0
dumpBankCHR(0x0, 0x800);
}
break;
case 78: // 128K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 8K Banks
write_prg_byte(0x8000, i << 4); // CHR Bank 0
dumpBankCHR(0x0, 0x2000); // 8K Banks ($0000-$1FFF)
}
break;
case 79:
case 146:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x4100, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 80: // 128K/256K
case 82: // 128K/256K
case 207: // 128K [CART SOMETIMES NEEDS POWERCYCLE]
case 552:
banks = int_pow(2, chrsize) * 2;
write_prg_byte(0x7EF6, 0x00); // CHR mode [2x 2KiB banks at $0000-$0FFF]
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x7EF0, i << 1);
write_prg_byte(0x7EF1, (i + 1) << 1);
dumpBankCHR(0x0, 0x1000);
}
break;
case 85: // 128K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0xA000, i); // CHR Bank 0
write_prg_byte(0xA008, i + 1); // CHR Bank 1
write_prg_byte(0xB000, i + 2); // CHR Bank 2
write_prg_byte(0xB008, i + 3); // CHR Bank 3
write_prg_byte(0xC000, i + 4); // CHR Bank 4
write_prg_byte(0xC008, i + 5); // CHR Bank 5
write_prg_byte(0xD000, i + 6); // CHR Bank 6
write_prg_byte(0xD008, i + 7); // CHR Bank 7
dumpBankCHR(0x0, 0x2000);
}
break;
case 86: // 64K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 8K Banks
if (i < 4)
write_prg_byte(0x6000, i & 0x3);
else
write_prg_byte(0x6000, (i | 0x40) & 0x43);
dumpBankCHR(0x0, 0x2000);
}
break;
case 87: // 16K/32K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 16K/32K
write_prg_byte(0x6000, (((i & 0x1) << 1) | ((i & 0x2) >> 1)));
dumpBankCHR(0x0, 0x2000);
}
break;
case 88: // 128K
case 95: // 32K
case 154: // 128K
case 206: // 16K/32K/64K
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i += 2) { // 1K Banks
if (i < 64) {
write_prg_byte(0x8000, 0); // CHR Command ($0000-$07FF) 2K Bank
write_prg_byte(0x8001, i & 0x3F); // CHR Bank
dumpBankCHR(0x0, 0x800);
} else {
write_prg_byte(0x8000, 2); // CHR Command ($1000-$13FF) 1K Bank
write_prg_byte(0x8001, i); // CHR Bank
write_prg_byte(0x8000, 3); // CHR Command ($1400-$17FF) 1K Bank
write_prg_byte(0x8001, i + 1); // CHR Bank
dumpBankCHR(0x1000, 0x1800);
}
}
break;
case 89: // 128K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 8K Banks
if (i < 8)
write_prg_byte(0x8000, i & 0x7);
else
write_prg_byte(0x8000, (i | 0x80) & 0x87);
dumpBankCHR(0x0, 0x2000);
}
break;
case 91:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0x6000, (i / 2) | 0);
write_prg_byte(0x6001, (i / 2) | 1);
write_prg_byte(0x6002, (i / 2) | 2);
write_prg_byte(0x6003, (i / 2) | 3);
dumpBankCHR(0x0, 0x2000);
}
break;
case 92: // 128K
banks = int_pow(2, chrsize) / 2;
write_prg_byte(0x8000, 0); // Reset Register
for (size_t i = 0; i < banks; i++) { // 8K Banks
write_prg_byte(0x8000, i | 0x40); // CHR Command + Bank
write_prg_byte(0x8000, i); // CHR Bank
dumpBankCHR(0x0, 0x2000);
}
break;
case 113:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x4100, (i & 0x08) << 3 | (i & 0x07));
dumpBankCHR(0x0, 0x2000);
}
break;
case 114: // Submapper 0
banks = int_pow(2, chrsize) * 4;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, (i & 0x80) >> 7);
write_prg_byte(0xA000, 6);
write_prg_byte(0xC000, i);
dumpBankCHR(0x1000, 0x1400);
}
break;
case 126:
banks = int_pow(2, chrsize) * 2;
write_prg_byte(0xA001, 0x80); // enable WRAM
write_prg_byte(0x6003, 0x00); // set MMC3 banking mode
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x6000, (i & 0x200) >> 5 | (i & 0x100) >> 3); // select outer bank
write_prg_byte(0x8000, 0); // 2k bank 0 at $0000
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 1); // 2k bank 1 at $0800
write_prg_byte(0x8001, i + 2);
dumpBankCHR(0x0, 0x1000);
}
break;
case 134:
banks = int_pow(2, chrsize) * 2;
write_prg_byte(0x6000, 0x00); // set MMC3 banking mode
for (size_t i = 0; i < banks; i += 2) {
write_prg_byte(0x6001, (i & 0x180) >> 3); // select outer bank
write_prg_byte(0x8000, 0); // 2k bank 0 at $0000
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 1); // 2k bank 1 at $0800
write_prg_byte(0x8001, i + 2);
dumpBankCHR(0x0, 0x1000);
}
break;
case 140: // 32K/128K
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) { // 8K Banks
write_prg_byte(0x6000, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 174: // 64k
for (size_t i = 0; i < 8; i++) {
write_prg_byte(0xFF00 + (i << 1), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 176:
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0x5FF3, 0); // extended MMC3 mode: disabled
write_prg_byte(0x5FF0, 1); // 256K outer bank mode
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0x5FF2, (i & 0x700) >> 3); // outer 256k bank
write_prg_byte(0x8000, 0);
write_prg_byte(0x8001, i);
write_prg_byte(0x8000, 0x0A);
write_prg_byte(0x8001, i + 1);
write_prg_byte(0x8000, 1);
write_prg_byte(0x8001, i + 2);
write_prg_byte(0x8000, 0x0B);
write_prg_byte(0x8001, i + 3);
write_prg_byte(0x8000, 2);
write_prg_byte(0x8001, i + 4);
write_prg_byte(0x8000, 3);
write_prg_byte(0x8001, i + 5);
write_prg_byte(0x8000, 4);
write_prg_byte(0x8001, i + 6);
write_prg_byte(0x8000, 5);
write_prg_byte(0x8001, i + 7);
dumpBankCHR(0x0, 0x2000);
}
break;
case 184: // 16K/32K
banks = int_pow(2, chrsize);
for (size_t i = 0; i < banks; i++) { // 4K Banks
write_prg_byte(0x6000, i); // CHR LOW (Bits 0-2) ($0000-$0FFF)
dumpBankCHR(0x0, 0x1000); // 4K Banks ($0000-$0FFF)
}
break;
case 185: // 8K [READ 32K TO OVERRIDE LOCKOUT]
for (size_t i = 0; i < 4; i++) { // Read 32K to locate valid 8K
write_prg_byte(0x8000, i);
uint8_t chrcheck = read_chr_byte(0);
for (size_t address = 0x0; address < 0x2000; address += 512) {
for (size_t x = 0; x < 512; x++) {
sdBuffer[x] = read_chr_byte(address + x);
}
if (chrcheck != 0xFF)
myFile.write(sdBuffer, 512);
}
}
break;
case 200:
case 212:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i & 0x07), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 201:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (i & 0xFF), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 202:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | (i << 1), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 203:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000, (i & 0x03));
dumpBankCHR(0x0, 0x2000);
}
break;
case 210: // 128K/256K
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xE800, 0xC0); // CHR RAM DISABLE (Bit 6 and 7) [WRITE NO RAM]
for (size_t i = 0; i < banks; i += 8) {
write_prg_byte(0x8000, i); // CHR Bank 0
write_prg_byte(0x8800, i + 1); // CHR Bank 1
write_prg_byte(0x9000, i + 2); // CHR Bank 2
write_prg_byte(0x9800, i + 3); // CHR Bank 3
write_prg_byte(0xA000, i + 4); // CHR Bank 4
write_prg_byte(0xA800, i + 5); // CHR Bank 5
write_prg_byte(0xB000, i + 6); // CHR Bank 6
write_prg_byte(0xB800, i + 7); // CHR Bank 7
dumpBankCHR(0x0, 0x2000);
}
break;
case 214:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | (i << 2), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 225:
case 255:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + (((i & 0x40) << 8) | (i & 0x3F)), 0);
dumpBankCHR(0x0, 0x2000);
}
break;
case 228:
banks = int_pow(2, chrsize) / 2;
write_prg_byte(0x8000, 0);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 + ((i & 0x3C) >> 2), i & 0x03);
dumpBankCHR(0x0, 0x2000);
}
break;
case 229:
for (size_t i = 0; i < 32; i++) {
write_prg_byte(0x8000 + i, i);
dumpBankCHR(0x0, 0x2000);
}
break;
case 236:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x8000 | (i & 0x0F), 0); // A16-A13
dumpBankCHR(0x0, 0x2000);
}
break;
case 240:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x5FFF, (i & 0xF));
dumpBankCHR(0x0, 0x2000);
}
break;
case 246:
banks = int_pow(2, chrsize) / 2;
for (size_t i = 0; i < banks; i += 4) {
write_prg_byte(0x6004, (i | 0));
write_prg_byte(0x6005, (i | 1));
write_prg_byte(0x6006, (i | 2));
write_prg_byte(0x6007, (i | 3));
dumpBankCHR(0x0, 0x2000);
}
break;
case 268: // mapper 268.0
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6000, ((i & 0x380) >> 4) | ((i & 0xC00) >> 9));
write_prg_byte(0x8000, 0x02);
write_prg_byte(0x8001, i);
dumpBankCHR(0x1000, 0x1400);
}
break;
case 315:
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6800, ((i & 0x100) >> 8) | ((i & 0x80) >> 6) | ((i & 0x40) >> 3));
write_prg_byte(0x8000, 0x02);
write_prg_byte(0x8001, i);
dumpBankCHR(0x1000, 0x1400);
}
break;
case 366:
banks = int_pow(2, chrsize) * 4;
write_prg_byte(0xA001, 0x80);
for (size_t i = 0; i < banks; i++) {
write_prg_byte(0x6800 + ((i & 0x380) >> 3), i);
write_prg_byte(0x8000, 0x02);
write_prg_byte(0x8001, i);
dumpBankCHR(0x1000, 0x1400);
}
break;
}
if (!readrom) {
myFile.flush();
myFile.close();
println_Msg(F("CHR FILE DUMPED!"));
println_Msg(FS(FSTRING_EMPTY));
display_Update();
}
}
}
set_address(0);
PHI2_HI;
ROMSEL_HI;
rgbLed(black_color);
}
/******************************************
RAM Functions
*****************************************/
void readRAM() {
display_Clear();
display_Update();
uint16_t banks;
rgbLed(turquoise_color);
set_address(0);
_delay_us(1);
if (ramsize == 0) {
println_Msg(F("RAM SIZE 0K"));
display_Update();
} else {
CreateRAMFileInSD();
word base = 0x6000;
if (myFile) {
switch (mapper) {
case 0: // 2K/4K
dumpBankPRG(0x0, (0x800 * ramsize), base); // 2K/4K
break; // SWITCH MUST BE IN OFF POSITION
case 1:
case 155: // 8K/16K/32K
banks = int_pow(2, ramsize) / 2; // banks = 1,2,4
for (size_t i = 0; i < banks; i++) { // 8K Banks ($6000-$7FFF)
write_prg_byte(0x8000, 0x80); // Clear Register
write_mmc1_byte(0x8000, 1 << 3);
write_mmc1_byte(0xE000, 0);
if (banks == 4) // 32K
write_mmc1_byte(0xA000, i << 2);
else
write_mmc1_byte(0xA000, i << 3);
dumpBankPRG(0x0, 0x2000, base); // 8K
}
break;
case 4: // 1K/8K (MMC6/MMC3)
if (mmc6) { // MMC6 1K
write_prg_byte(0x8000, 0x20); // PRG RAM ENABLE
write_prg_byte(0xA001, 0x20); // PRG RAM PROTECT - Enable reading RAM at $7000-$71FF
for (size_t address = 0x1000; address < 0x1200; address += 512) { // 512B
dumpMMC5RAM(base, address);
}
write_prg_byte(0x8000, 0x20); // PRG RAM ENABLE
write_prg_byte(0xA001, 0x80); // PRG RAM PROTECT - Enable reading RAM at $7200-$73FF
for (size_t address = 0x1200; address < 0x1400; address += 512) { // 512B
dumpMMC5RAM(base, address);
}
write_prg_byte(0x8000, 6); // PRG RAM DISABLE
} else { // MMC3 8K
write_prg_byte(0xA001, 0xC0); // PRG RAM CHIP ENABLE - Chip Enable, Write Protect
dumpBankPRG(0x0, 0x2000, base); // 8K
}
break;
case 5: // 8K/16K/32K
write_prg_byte(0x5100, 3); // 8K PRG Banks
banks = int_pow(2, ramsize) / 2; // banks = 1,2,4
if (banks == 2) { // 16K - Split SRAM Chips 8K/8K
for (size_t i = 0; i < (banks / 2); i++) { // Chip 1
write_prg_byte(0x5113, i);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
dumpMMC5RAM(base, address);
}
}
for (size_t j = 4; j < (banks / 2) + 4; j++) { // Chip 2
write_prg_byte(0x5113, j);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
dumpMMC5RAM(base, address);
}
}
} else { // 8K/32K Single SRAM Chip
for (size_t i = 0; i < banks; i++) { // banks = 1 or 4
write_prg_byte(0x5113, i);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
dumpMMC5RAM(base, address);
}
}
}
break;
case 16: // 256-byte EEPROM 24C02
case 159:
{ // 128-byte EEPROM 24C01 [Little Endian]
size_t eepsize;
if (mapper == 159)
eepsize = 128;
else
eepsize = 256;
for (size_t address = 0; address < eepsize; address++) {
EepromREAD(address);
}
myFile.write(sdBuffer, eepsize);
// display_Clear(); // TEST PURPOSES - DISPLAY EEPROM DATA
break;
}
case 19:
if (ramsize == 2) { // PRG RAM 128B
for (size_t x = 0; x < 128; x++) {
write_ram_byte(0xF800, x); // PRG RAM ENABLE
sdBuffer[x] = read_prg_byte(0x4800); // DATA PORT
}
myFile.write(sdBuffer, 128);
} else { // SRAM 8K
for (size_t i = 0; i < 64; i++) { // Init Register
write_ram_byte(0xE000, 0);
}
dumpBankPRG(0x0, 0x2000, base); // 8K
}
break;
case 80: // 1K
write_prg_byte(0x7EF8, 0xA3); // PRG RAM ENABLE 0
write_prg_byte(0x7EF9, 0xA3); // PRG RAM ENABLE 1
for (size_t x = 0; x < 128; x++) { // PRG RAM 1K ($7F00-$7FFF) MIRRORED ONCE
sdBuffer[x] = read_prg_byte(0x7F00 + x);
}
myFile.write(sdBuffer, 128);
write_prg_byte(0x7EF8, 0xFF); // PRG RAM DISABLE 0
write_prg_byte(0x7EF9, 0xFF); // PRG RAM DISABLE 1
break;
case 82: // 5K
write_prg_byte(0x7EF7, 0xCA); // PRG RAM ENABLE 0 ($6000-$67FF)
write_prg_byte(0x7EF8, 0x69); // PRG RAM ENABLE 1 ($6800-$6FFF)
write_prg_byte(0x7EF9, 0x84); // PRG RAM ENABLE 2 ($7000-$73FF)
for (size_t address = 0x0; address < 0x1400; address += 512) { // PRG RAM 5K ($6000-$73FF)
dumpMMC5RAM(base, address);
}
write_prg_byte(0x7EF7, 0xFF); // PRG RAM DISABLE 0 ($6000-$67FF)
write_prg_byte(0x7EF8, 0xFF); // PRG RAM DISABLE 1 ($6800-$6FFF)
write_prg_byte(0x7EF9, 0xFF); // PRG RAM DISABLE 2 ($7000-$73FF)
break;
default:
if (mapper == 118) // 8K
write_prg_byte(0xA001, 0xC0); // PRG RAM CHIP ENABLE - Chip Enable, Write Protect
else if (mapper == 19) {
for (size_t i = 0; i < 64; i++) { // Init Register
write_ram_byte(0xE000, 0);
}
} else if ((mapper == 21) || (mapper == 25)) // 8K
write_prg_byte(0x8000, 0);
else if (mapper == 26) // 8K
write_prg_byte(0xB003, 0x80); // PRG RAM ENABLE
else if (mapper == 68) // 8K
write_reg_byte(0xF000, 0x10); // PRG RAM ENABLE [WRITE RAM SAFE]
else if (mapper == 69) { // 8K
write_prg_byte(0x8000, 8); // Command Register - PRG Bank 0
write_prg_byte(0xA000, 0xC0); // Parameter Register - PRG RAM Enabled, PRG RAM, Bank 0 to $6000-$7FFF
} else if (mapper == 85) // 8K
write_ram_byte(0xE000, 0x80); // PRG RAM ENABLE
else if (mapper == 153) // 8K
write_prg_byte(0x800D, 0x20); // PRG RAM Chip Enable
dumpBankPRG(0x0, 0x2000, base); // 8K
if (mapper == 85) // 8K
write_reg_byte(0xE000, 0); // PRG RAM DISABLE [WRITE RAM SAFE]
break;
}
myFile.flush();
myFile.close();
println_Msg(F("RAM FILE DUMPED!"));
println_Msg(FS(FSTRING_EMPTY));
display_Update();
if ((mapper == 16) || (mapper == 159))
printCRC(fileName, NULL, 0);
else
printCRC(fileName, NULL, 0);
}
}
set_address(0);
PHI2_HI;
ROMSEL_HI;
rgbLed(black_color);
}
void writeBankPRG(const size_t from, const size_t to, const size_t base) {
for (size_t address = from; address < to; address += 512) {
myFile.read(sdBuffer, 512);
for (size_t x = 0; x < 512; x++) {
write_prg_byte(base + address + x, sdBuffer[x]);
}
}
}
void writeBankWRAM(const size_t from, const size_t to, const size_t base) {
for (size_t address = from; address < to; address += 512) {
myFile.read(sdBuffer, 512);
for (size_t x = 0; x < 512; x++) {
write_wram_byte(base + address + x, sdBuffer[x]);
}
}
}
void writeRAM() {
display_Clear();
if (ramsize == 0) {
print_Error(F("RAM SIZE 0K"));
} else {
fileBrowser(F("Select RAM File"));
word base = 0x6000;
uint16_t banks;
sd.chdir();
sprintf(filePath, "%s/%s", filePath, fileName);
display_Clear();
println_Msg(F("Writing File: "));
println_Msg(filePath);
println_Msg(fileName);
display_Update();
//open file on sd card
if (myFile.open(filePath, O_READ)) {
switch (mapper) {
case 0: // 2K/4K
writeBankPRG(0x0, (0x800 * ramsize), base); // 2K/4K
break; // SWITCH MUST BE IN OFF POSITION
case 1:
case 155:
banks = int_pow(2, ramsize) / 2; // banks = 1,2,4
for (size_t i = 0; i < banks; i++) { // 8K Banks ($6000-$7FFF)
write_prg_byte(0x8000, 0x80); // Clear Register
write_mmc1_byte(0x8000, 1 << 3); // PRG ROM MODE 32K
write_mmc1_byte(0xE000, 0); // PRG RAM ENABLED
if (banks == 4) // 32K
write_mmc1_byte(0xA000, i << 2);
else
write_mmc1_byte(0xA000, i << 3);
writeBankPRG(0x0, 0x2000, base); // 8K
}
break;
case 4: // 1K/8K (MMC6/MMC3)
if (mmc6) { // MMC6 1K
write_prg_byte(0x8000, 0x20); // PRG RAM ENABLE
write_prg_byte(0xA001, 0x30); // PRG RAM PROTECT - Enable reading/writing to RAM at $7000-$71FF
writeBankWRAM(0x1000, 0x1200, base); // 512B
write_prg_byte(0x8000, 0x20); // PRG RAM ENABLE
write_prg_byte(0xA001, 0xC0); // PRG RAM PROTECT - Enable reading/writing to RAM at $7200-$73FF
writeBankWRAM(0x1200, 0x1400, base); // 512B
write_prg_byte(0x8000, 0x6); // PRG RAM DISABLE
} else { // MMC3 8K
write_prg_byte(0xA001, 0x80); // PRG RAM CHIP ENABLE - Chip Enable, Allow Writes
writeBankPRG(0x0, 0x2000, base); // 8K
write_prg_byte(0xA001, 0xC0); // PRG RAM CHIP ENABLE - Chip Enable, Write Protect
}
break;
case 5: // 8K/16K/32K
write_prg_byte(0x5100, 3); // 8K PRG Banks
banks = int_pow(2, ramsize) / 2; // banks = 1,2,4
if (banks == 2) { // 16K - Split SRAM Chips 8K/8K [ETROM = 16K (ONLY 1ST 8K BATTERY BACKED)]
for (size_t i = 0; i < (banks / 2); i++) { // Chip 1
write_prg_byte(0x5113, i);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
writeMMC5RAM(base, address);
}
}
for (size_t j = 4; j < (banks / 2) + 4; j++) { // Chip 2
write_prg_byte(0x5113, j);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
writeMMC5RAM(base, address);
}
}
} else { // 8K/32K Single SRAM Chip [EKROM = 8K BATTERY BACKED, EWROM = 32K BATTERY BACKED]
for (size_t i = 0; i < banks; i++) { // banks = 1 or 4
write_prg_byte(0x5113, i);
for (size_t address = 0; address < 0x2000; address += 512) { // 8K
writeMMC5RAM(base, address);
}
}
}
break;
case 16: // 256-byte EEPROM 24C02
case 159:
{ // 128-byte EEPROM 24C01 [Little Endian]
size_t eepsize;
if (mapper == 159)
eepsize = 128;
else
eepsize = 256;
myFile.read(sdBuffer, eepsize);
for (size_t address = 0; address < eepsize; address++) {
EepromWRITE(address);
if ((address % 128) == 0)
display_Clear();
print_Msg(F("."));
display_Update();
}
break;
}
case 19:
if (ramsize == 2) { // PRG RAM 128B
myFile.read(sdBuffer, 128);
for (size_t x = 0; x < 128; x++) {
write_ram_byte(0xF800, x); // PRG RAM ENABLE
write_prg_byte(0x4800, sdBuffer[x]); // DATA PORT
}
} else { // SRAM 8K
for (size_t i = 0; i < 64; i++) { // Init Register
write_ram_byte(0xF800, 0x40); // PRG RAM WRITE ENABLE
}
write_ram_byte(0xF800, 0x40); // PRG RAM WRITE ENABLE
writeBankPRG(0x0, 0x2000, base); // 8K
write_ram_byte(0xF800, 0x0F); // PRG RAM WRITE PROTECT
}
break;
case 80: // 1K
write_prg_byte(0x7EF8, 0xA3); // PRG RAM ENABLE 0
write_prg_byte(0x7EF9, 0xA3); // PRG RAM ENABLE 1
for (size_t address = 0x1F00; address < 0x2000; address += 512) { // PRG RAM 1K ($7F00-$7FFF)
myFile.read(sdBuffer, 128);
for (size_t x = 0; x < 128; x++) {
write_prg_byte(base + address + x, sdBuffer[x]);
}
}
write_prg_byte(0x7EF8, 0xFF); // PRG RAM DISABLE 0
write_prg_byte(0x7EF9, 0xFF); // PRG RAM DISABLE 1
break;
case 82: // 5K
write_prg_byte(0x7EF7, 0xCA); // PRG RAM ENABLE 0 ($6000-$67FF)
write_prg_byte(0x7EF8, 0x69); // PRG RAM ENABLE 1 ($6800-$6FFF)
write_prg_byte(0x7EF9, 0x84); // PRG RAM ENABLE 2 ($7000-$73FF)
for (size_t address = 0x0; address < 0x1400; address += 1024) { // PRG RAM 5K ($6000-$73FF)
myFile.read(sdBuffer, 512);
uint8_t firstbyte = sdBuffer[0];
for (size_t x = 0; x < 512; x++)
write_prg_byte(base + address + x, sdBuffer[x]);
myFile.read(sdBuffer, 512);
for (size_t x = 0; x < 512; x++)
write_prg_byte(base + address + x + 512, sdBuffer[x]);
write_prg_byte(base + address, firstbyte); // REWRITE 1ST BYTE
}
write_prg_byte(0x7EF7, 0xFF); // PRG RAM DISABLE 0 ($6000-$67FF)
write_prg_byte(0x7EF8, 0xFF); // PRG RAM DISABLE 1 ($6800-$6FFF)
write_prg_byte(0x7EF9, 0xFF); // PRG RAM DISABLE 2 ($7000-$73FF)
break;
default:
if (mapper == 118) // 8K
write_prg_byte(0xA001, 0x80); // PRG RAM CHIP ENABLE - Chip Enable, Allow Writes
else if ((mapper == 21) || (mapper == 25)) // 8K
write_prg_byte(0x8000, 0);
else if (mapper == 26) // 8K
write_prg_byte(0xB003, 0x80); // PRG RAM ENABLE
// else if (mapper == 68) // 8K
// write_reg_byte(0xF000, 0x10); // PRG RAM ENABLE [WRITE RAM SAFE]
else if (mapper == 69) { // 8K
write_prg_byte(0x8000, 8); // Command Register - PRG Bank 0
write_prg_byte(0xA000, 0xC0); // Parameter Register - PRG RAM Enabled, PRG RAM, Bank 0 to $6000-$7FFF
} else if (mapper == 85) // 8K
write_ram_byte(0xE000, 0x80); // PRG RAM ENABLE
else if (mapper == 153) // 8K
write_prg_byte(0x800D, 0x20); // PRG RAM Chip Enable
writeBankPRG(0x0, 0x2000, base);
if (mapper == 118) // 8K
write_prg_byte(0xA001, 0xC0); // PRG RAM CHIP ENABLE - Chip Enable, Write Protect
else if (mapper == 26) // 8K
write_prg_byte(0xB003, 0); // PRG RAM DISABLE
// else if (mapper == 68) // 8K
// write_reg_byte(0xF000, 0x00); // PRG RAM DISABLE [WRITE RAM SAFE]
else if (mapper == 69) { // 8K
write_prg_byte(0x8000, 8); // Command Register - PRG Bank 0
write_prg_byte(0xA000, 0); // Parameter Register - PRG RAM Disabled, PRG ROM, Bank 0 to $6000-$7FFF
} else if (mapper == 85) // 8K
write_reg_byte(0xE000, 0); // PRG RAM DISABLE [WRITE RAM SAFE]
break;
}
myFile.close();
rgbLed(green_color);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("RAM FILE WRITTEN!"));
display_Update();
} else {
print_FatalError(sd_error_STR);
}
}
rgbLed(black_color);
sd.chdir(); // root
filePath[0] = '\0'; // Reset filePath
}
/******************************************
Eeprom Functions
*****************************************/
// EEPROM MAPPING
// 00-01 FOLDER #
// 02-05 SNES/GB READER SETTINGS
// 06 LED - ON/OFF [SNES/GB]
// 07 MAPPER
// 08 PRG SIZE
// 09 CHR SIZE
// 10 RAM SIZE
void resetEEPROM() {
EEPROM_writeAnything(0, 0); // FOLDER #
EEPROM_writeAnything(2, 0); // CARTMODE
EEPROM_writeAnything(3, 0); // RETRY
EEPROM_writeAnything(4, 0); // STATUS
EEPROM_writeAnything(5, 0); // UNKNOWNCRC
EEPROM_writeAnything(6, 1); // LED (RESET TO ON)
EEPROM_writeAnything(7, 0); // MAPPER
EEPROM_writeAnything(9, 0); // PRG SIZE
EEPROM_writeAnything(10, 0); // CHR SIZE
EEPROM_writeAnything(11, 0); // RAM SIZE
}
void EepromStart_NES() {
write_prg_byte(0x800D, 0x00); // sda low, scl low
write_prg_byte(0x800D, 0x60); // sda, scl high
write_prg_byte(0x800D, 0x20); // sda low, scl high
write_prg_byte(0x800D, 0x00); // START
}
void EepromStop_NES() {
write_prg_byte(0x800D, 0x00); // sda, scl low
write_prg_byte(0x800D, 0x20); // sda low, scl high
write_prg_byte(0x800D, 0x60); // sda, scl high
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x00); // STOP
}
void EepromSet0_NES() {
write_prg_byte(0x800D, 0x00); // sda low, scl low
write_prg_byte(0x800D, 0x20); // sda low, scl high // 0
write_prg_byte(0x800D, 0x00); // sda low, scl low
}
void EepromSet1_NES() {
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x60); // sda high, scl high // 1
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x00); // sda low, scl low
}
void EepromStatus_NES() { // ACK
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x60); // sda high, scl high
write_prg_byte(0x800D, 0xE0); // sda high, scl high, read high
uint8_t eepStatus = 1;
do {
eepStatus = (read_prg_byte(0x6000) & 0x10) >> 4;
delayMicroseconds(4);
} while (eepStatus == 1);
write_prg_byte(0x800D, 0x40); // sda high, scl low
}
void EepromReadData_NES() {
// read serial data into buffer
for (uint8_t i = 0; i < 8; i++) {
write_prg_byte(0x800D, 0x60); // sda high, scl high, read low
write_prg_byte(0x800D, 0xE0); // sda high, scl high, read high
eepbit[i] = (read_prg_byte(0x6000) & 0x10) >> 4; // Read 0x6000 with Mask 0x10 (bit 4)
write_prg_byte(0x800D, 0x40); // sda high, scl low
}
}
void EepromDevice_NES() { // 24C02 ONLY
EepromSet1_NES();
EepromSet0_NES();
EepromSet1_NES();
EepromSet0_NES();
EepromSet0_NES(); // A2
EepromSet0_NES(); // A1
EepromSet0_NES(); // A0
}
void EepromReadMode_NES() {
EepromSet1_NES(); // READ
EepromStatus_NES(); // ACK
}
void EepromWriteMode_NES() {
EepromSet0_NES(); // WRITE
EepromStatus_NES(); // ACK
}
void EepromFinish_NES() {
write_prg_byte(0x800D, 0x00); // sda low, scl low
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x60); // sda high, scl high
write_prg_byte(0x800D, 0x40); // sda high, scl low
write_prg_byte(0x800D, 0x00); // sda low, scl low
}
void EepromSetAddress01(uint8_t address) { // 24C01 [Little Endian]
for (uint8_t i = 0; i < 7; i++) {
if (address & 0x1) // Bit is HIGH
EepromSet1_NES();
else // Bit is LOW
EepromSet0_NES();
address >>= 1; // rotate to the next bit
}
}
void EepromSetAddress02(uint8_t address) { // 24C02
for (uint8_t i = 0; i < 8; i++) {
if ((address >> 7) & 0x1) // Bit is HIGH
EepromSet1_NES();
else // Bit is LOW
EepromSet0_NES();
address <<= 1; // rotate to the next bit
}
EepromStatus_NES(); // ACK
}
void EepromWriteData01() { // 24C01 [Little Endian]
for (uint8_t i = 0; i < 8; i++) {
if (eeptemp & 0x1) // Bit is HIGH
EepromSet1_NES();
else // Bit is LOW
EepromSet0_NES();
eeptemp >>= 1; // rotate to the next bit
}
EepromStatus_NES(); // ACK
}
void EepromWriteData02() { // 24C02
for (uint8_t i = 0; i < 8; i++) {
if ((eeptemp >> 7) & 0x1) // Bit is HIGH
EepromSet1_NES();
else // Bit is LOW
EepromSet0_NES();
eeptemp <<= 1; // rotate to the next bit
}
EepromStatus_NES(); // ACK
}
void EepromREAD(uint8_t address) {
EepromStart_NES(); // START
if (mapper == 159) { // 24C01
EepromSetAddress01(address); // 24C01 [Little Endian]
EepromReadMode_NES();
EepromReadData_NES();
EepromFinish_NES();
EepromStop_NES(); // STOP
// OR 8 bits into byte
eeptemp = eepbit[7] << 7 | eepbit[6] << 6 | eepbit[5] << 5 | eepbit[4] << 4 | eepbit[3] << 3 | eepbit[2] << 2 | eepbit[1] << 1 | eepbit[0];
} else { // 24C02
EepromDevice_NES(); // DEVICE [1010] + ADDR [A2-A0]
EepromWriteMode_NES();
EepromSetAddress02(address);
EepromStart_NES(); // START
EepromDevice_NES(); // DEVICE [1010] + ADDR [A2-A0]
EepromReadMode_NES();
EepromReadData_NES();
EepromFinish_NES();
EepromStop_NES(); // STOP
// OR 8 bits into byte
eeptemp = eepbit[0] << 7 | eepbit[1] << 6 | eepbit[2] << 5 | eepbit[3] << 4 | eepbit[4] << 3 | eepbit[5] << 2 | eepbit[6] << 1 | eepbit[7];
}
sdBuffer[address] = eeptemp;
}
void EepromWRITE(uint8_t address) {
eeptemp = sdBuffer[address];
EepromStart_NES(); // START
if (mapper == 159) { // 24C01
EepromSetAddress01(address); // 24C01 [Little Endian]
EepromWriteMode_NES();
EepromWriteData01(); // 24C01 [Little Endian]
} else { // 24C02
EepromDevice_NES(); // DEVICE [1010] + ADDR [A2-A0]
EepromWriteMode_NES();
EepromSetAddress02(address);
EepromWriteData02();
}
EepromStop_NES(); // STOP
}
#if defined(ENABLE_FLASH)
/******************************************
NESmaker Flash Cart [SST 39SF40]
*****************************************/
void NESmaker_Cmd(byte cmd) {
write_prg_byte(0xC000, 0x01);
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xC000, 0x00);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0xC000, 0x01);
write_prg_byte(0x9555, cmd);
}
// SST 39SF040 Software ID
void NESmaker_ID() { // Read Flash ID
NESmaker_Cmd(0xFF); // Reset
NESmaker_Cmd(0x90); // Software ID Entry
flashid = read_prg_byte(0x8000) << 8;
flashid |= read_prg_byte(0x8001);
sprintf(flashid_str, "%04X", flashid);
NESmaker_Cmd(0xF0); // Software ID Exit
if (flashid == 0xBFB7) // SST 39SF040
flashfound = 1;
}
void NESmaker_SectorErase(uint8_t bank, word address) {
NESmaker_Cmd(0x80);
write_prg_byte(0xC000, 0x01);
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xC000, 0x00);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0xC000, bank); // $00-$1F
write_prg_byte(address, 0x30); // Sector Erase ($8000/$9000/$A000/$B000)
}
void NESmaker_ByteProgram(uint8_t bank, word address, uint8_t data) {
NESmaker_Cmd(0xA0);
write_prg_byte(0xC000, bank); // $00-$1F
write_prg_byte(address, data); // $8000-$BFFF
}
// SST 39SF040 Chip Erase [NOT IMPLEMENTED]
void NESmaker_ChipErase() { // Typical 70ms
NESmaker_Cmd(0x80);
NESmaker_Cmd(0x10); // Chip Erase
}
void writeFLASH() {
display_Clear();
if (!flashfound) {
rgbLed(red_color);
println_Msg(F("FLASH NOT DETECTED"));
display_Update();
} else {
print_Msg(F("Flash ID: "));
println_Msg(flashid_str);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("NESmaker Flash Found"));
println_Msg(FS(FSTRING_EMPTY));
display_Update();
delay(100);
fileBrowser(F("Select FLASH File"));
word base = 0x8000;
sd.chdir();
sprintf(filePath, "%s/%s", filePath, fileName);
rgbLed(red_color);
display_Clear();
println_Msg(F("Writing File: "));
println_Msg(filePath);
println_Msg(fileName);
display_Update();
uint8_t bytecheck;
uint16_t banks;
//open file on sd card
if (myFile.open(filePath, O_READ)) {
banks = int_pow(2, prgsize); // 256K/512K
for (size_t i = 0; i < banks; i++) { // 16K Banks
for (size_t sector = 0; sector < 0x4000; sector += 0x1000) { // 4K Sectors ($8000/$9000/$A000/$B000)
// Sector Erase
NESmaker_SectorErase(i, base + sector);
delay(18); // Typical 18ms
for (uint8_t j = 0; j < 2; j++) { // Confirm erase twice
do {
bytecheck = read_prg_byte(base + sector);
delay(18);
} while (bytecheck != 0xFF);
}
// Program Byte
for (size_t addr = 0x0; addr < 0x1000; addr += 512) {
myFile.read(sdBuffer, 512);
for (size_t x = 0; x < 512; x++) {
word location = base + sector + addr + x;
NESmaker_ByteProgram(i, location, sdBuffer[x]);
delayMicroseconds(14); // Typical 14us
for (uint8_t k = 0; k < 2; k++) { // Confirm write twice
do {
bytecheck = read_prg_byte(location);
delayMicroseconds(14);
} while (bytecheck != sdBuffer[x]);
}
}
}
}
#if (defined(ENABLE_LCD) || defined(ENABLE_OLED))
display.print(F("*"));
display.updateDisplay();
#else
Serial.print(F("*"));
if ((i != 0) && ((i + 1) % 16 == 0))
Serial.println(FS(FSTRING_EMPTY));
#endif
}
myFile.close();
rgbLed(green_color);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("FLASH FILE WRITTEN!"));
display_Update();
} else {
rgbLed(red_color);
println_Msg(F("SD ERROR"));
display_Update();
}
}
display_Clear();
rgbLed(black_color);
sd.chdir(); // root
filePath[0] = '\0'; // Reset filePath
}
/******************************************
A29040B Flash Cart [A29040B]
*****************************************/
// A29040B Software ID
void A29040B_ID() { // Read Flash ID
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0x90);
flashid = read_prg_byte(0x8000) << 8;
flashid |= read_prg_byte(0x8001);
sprintf(flashid_str, "%04X", flashid);
if (flashid == 0x3786) // A29040B
flashfound = 1;
A29040B_PRG_ResetFlash();
}
void A29040B_PRG_ResetFlash() { // Reset Flash
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0xF0); // Reset
delayMicroseconds(14); // Typical 14us
}
void A29040B_PRG_Write(uint16_t address, uint8_t data) {
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0xA0);
write_prg_byte(address, data); // $8000-$BFFF
delayMicroseconds(20); // Typical 14us
}
void A29040B_PRG_SectorErase(uint16_t sec) {
if (flashfound) {
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0x80); //->setup
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(sec, 0x30); //->erase
delay(1000); // WAIT MORE
} else {
println_Msg(F("FLASH NOT DETECTED OR SECTOR PROTECTED"));
}
}
void A29040B_PRG_ChipErase() {
if (flashfound) {
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0x80); //->setup
write_prg_byte(0x9555, 0xAA);
write_prg_byte(0xAAAA, 0x55);
write_prg_byte(0x9555, 0x10); //->erase
delay(8000); // WAIT MORE
} else {
println_Msg(F("FLASH NOT DETECTED OR SECTOR PROTECTED"));
}
}
// CHR ================================================
void A29040B_CHR_ResetFlash() { // Reset Flash
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(0x0555, 0xF0); // Reset command with original address
delayMicroseconds(14); // Typical 14us
}
void A29040B_CHR_Write(uint16_t address, uint8_t data) {
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(0x0555, 0xA0); // Program command with original address
write_chr_byte(address, data); // CHR address range (0x0000 - 0x1FFF)
delayMicroseconds(20); // Typical 14us
}
void A29040B_CHR_SectorErase(uint16_t sec) {
if (flashfound) {
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(0x0555, 0x80); // Erase Setup with original address
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(sec, 0x30); // Sector Erase Command with sector address
delay(1000); // WAIT MORE
} else {
println_Msg(F("FLASH NOT DETECTED OR SECTOR PROTECTED"));
}
}
void A29040B_CHR_ChipErase() {
if (flashfound) {
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(0x0555, 0x80); // Erase Setup with original address
write_chr_byte(0x0555, 0xAA); // Original address for CHR
write_chr_byte(0x02AA, 0x55); // Original address for CHR
write_chr_byte(0x0555, 0x10); // Chip Erase Command with original address
delay(8000); // WAIT MORE
} else {
println_Msg(F("FLASH NOT DETECTED OR SECTOR PROTECTED"));
}
}
#define A29040B_TITLE "FLASH A29040B MAPPER 0"
void A29040B_writeFLASH() {
display_Clear();
A29040B_ID();
char data_str[10];
uint32_t prgSize = 0;
uint32_t chrSize = 0;
if (!flashfound) {
rgbLed(red_color);
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
print_Msg(F("Flash ID: "));
println_Msg(flashid_str);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("FLASH NOT FOUND"));
display_Update();
wait();
} else {
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
print_Msg(F("Flash ID: "));
println_Msg(flashid_str);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("Flash Found"));
println_Msg(FS(FSTRING_EMPTY));
display_Update();
delay(3000);
fileBrowser(F("Select FLASH File"));
sd.chdir();
sprintf(filePath, "%s/%s", filePath, fileName);
if (myFile.open(filePath, O_READ)) {
// Step 1: Read the header and extract PRG and CHR sizes
uint8_t header[16];
myFile.read(header, 16); // Read the 16-byte header
uint32_t prgAddress = 0x8000;
prgSize = (uint32_t)header[4] * 16384; // PRG size in bytes (header[4] gives size in 16 KB units)
chrSize = (uint32_t)header[5] * 8192; // CHR size in bytes (header[5] gives size in 8 KB units)
// Output the sizes for verification
display_Clear();
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("PRG Size:"));
sprintf(data_str, "%lu", prgSize);
println_Msg(data_str);
println_Msg(F("CHR Size:"));
sprintf(data_str, "%lu", chrSize);
println_Msg(data_str);
display_Update();
delay(3000);
// Step 2: Erase the entire PRG space
rgbLed(red_color);
display_Clear();
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
A29040B_PRG_ResetFlash();
println_Msg(F("ERASING PRG..."));
display_Update();
A29040B_PRG_ChipErase();
uint8_t readByte = read_prg_byte(prgAddress);
if (readByte != 0xFF) {
println_Msg(F("Erase Error!"));
} else {
println_Msg(F("Erase OK!"));
}
display_Update();
// Verify that the first byte has been erased
uint8_t erase_check = read_prg_byte(0x8000);
if (erase_check != 0xFF) {
println_Msg(F("SECTOR NOT ERASED"));
sprintf(data_str, "%02X", erase_check);
println_Msg(data_str);
return;
}
delay(18); // Adjust delay as needed
rgbLed(red_color);
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("Writing PRG Data..."));
display_Update();
A29040B_PRG_ResetFlash();
// Step 3: Write PRG data
uint32_t bytesProcessed = 0;
uint8_t buffer[512];
myFile.seek(16); // Skip header to start of PRG data
while (bytesProcessed < prgSize) {
int bytesRead = myFile.read(buffer, sizeof(buffer));
if (bytesRead <= 0) break;
for (int i = 0; i < bytesRead; i++) {
A29040B_PRG_Write(prgAddress++, buffer[i]);
delayMicroseconds(14); // Typical 14us
uint8_t readByte = read_prg_byte(prgAddress - 1);
delayMicroseconds(14); // Typical 14us
if (readByte != buffer[i]) {
println_Msg(F("Write Error!"));
sprintf(data_str, "%02X", readByte);
println_Msg(data_str);
myFile.close();
break;
}
}
bytesProcessed += bytesRead;
}
// Step 4: Erase and Write CHR data
A29040B_CHR_ResetFlash();
display_Clear();
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("ERASING CHR..."));
display_Update();
A29040B_CHR_ChipErase();
delay(20);
display_Clear();
uint32_t chrAddress = 0x0000;
bytesProcessed = 0;
myFile.seek(16 + prgSize); // Seek to the start of CHR data
readByte = read_chr_byte(chrAddress);
if (readByte != 0xFF) {
println_Msg(F("Erase Error!"));
} else {
println_Msg(F("Erase OK!"));
}
display_Update();
println_Msg(F("Writing CHR Data..."));
display_Update();
while (bytesProcessed < chrSize) {
int bytesRead = myFile.read(buffer, sizeof(buffer));
if (bytesRead <= 0) break;
for (int i = 0; i < bytesRead; i++) {
A29040B_CHR_Write(chrAddress++, buffer[i]);
delayMicroseconds(14); // Typical 14us
uint8_t readByte = read_chr_byte(chrAddress - 1);
delayMicroseconds(14); // Typical 14us
if (readByte != buffer[i]) {
println_Msg(F("Write Error!"));
sprintf(data_str, "%02X", readByte);
println_Msg(data_str);
myFile.close();
break;
}
}
bytesProcessed += bytesRead;
}
delay(3000);
myFile.close();
rgbLed(green_color);
display_Clear();
println_Msg(F(A29040B_TITLE));
println_Msg(FS(FSTRING_EMPTY));
println_Msg(F("FLASH FILE WRITTEN!"));
display_Update();
} else {
rgbLed(red_color);
println_Msg(F("SD ERROR"));
display_Update();
}
display_Update();
}
}
#endif
// avoid warnings
#undef MODE_READ
#undef MODE_WRITE
#endif
//******************************************
// End of File
//******************************************