-- create the module's table local mapper30v2 = {} -- import required modules local dict = require "scripts.app.dict" local nes = require "scripts.app.nes" local dump = require "scripts.app.dump" local flash = require "scripts.app.flash" local time = require "scripts.app.time" local files = require "scripts.app.files" local ciccom = require "scripts.app.ciccom" local time = require "scripts.app.time" local swim = require "scripts.app.swim" local mapper30_legacy = require "scripts.nes.mapper30" -- file constants & variables local mapname = "MAP30" -- local functions --read PRG-ROM flash ID local function prgrom_manf_id( debug ) if debug then print("reading PRG-ROM manf ID") end --no bus conflicts --$8000-BFFF writes to flash --$C000-FFFF writes to mapper --ROM A14 is mapper controlled -- --A15 14 - 13 12 -- 1 1 0 1 : 0x5555 -> bank1, $9555 -- 1 0 1 0 : 0x2AAA -> bank0, $AAAA dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0xAA) dict.nes("NES_CPU_WR", 0xC000, 0x00) dict.nes("NES_CPU_WR", 0xAAAA, 0x55) dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0x90) rv = dict.nes("NES_CPU_RD", 0x8000) if debug then print("attempted read PRG-ROM manf ID:", string.format("%X", rv)) end rv = dict.nes("NES_CPU_RD", 0x8001) if debug then print("attempted read PRG-ROM prod ID:", string.format("%X", rv)) end --exit software dict.nes("NES_CPU_WR", 0x8000, 0xF0) end --select different chr-ram banks and verify all 4 banks are present local function map30_chrbank_test() dict.nes("NES_CPU_WR", 0xC000, 0x00) --CHR bank 0 dict.nes("NES_PPU_WR", 0x0000, 0xAA) dict.nes("NES_CPU_WR", 0xC000, 0x20) --CHR bank 1 dict.nes("NES_PPU_WR", 0x0000, 0x55) dict.nes("NES_CPU_WR", 0xC000, 0x40) --CHR bank 2 dict.nes("NES_PPU_WR", 0x0000, 0xCC) dict.nes("NES_CPU_WR", 0xC000, 0x60) --CHR bank 3 dict.nes("NES_PPU_WR", 0x0000, 0x33) --read back local test = true dict.nes("NES_CPU_WR", 0xC000, 0x00) --CHR bank 0 rv = dict.nes("NES_PPU_RD", 0x0000) if rv ~= 0xAA then print( "\nFAIL CHR-RAM BANKING TEST!!!\n") print("bank0 read:", string.format("%X", rv)) test = false end dict.nes("NES_CPU_WR", 0xC000, 0x20) --CHR bank 1 rv = dict.nes("NES_PPU_RD", 0x0000) if rv ~= 0x55 then print( "\nFAIL CHR-RAM BANKING TEST!!!\n") print("bank1 read:", string.format("%X", rv)) test = false end dict.nes("NES_CPU_WR", 0xC000, 0x40) --CHR bank 2 rv = dict.nes("NES_PPU_RD", 0x0000) if rv ~= 0xCC then print( "\nFAIL CHR-RAM BANKING TEST!!!\n") print("bank2 read:", string.format("%X", rv)) test = false end dict.nes("NES_CPU_WR", 0xC000, 0x60) --CHR bank 3 rv = dict.nes("NES_PPU_RD", 0x0000) if rv ~= 0x33 then print( "\nFAIL CHR-RAM BANKING TEST!!!\n") print("bank3 read:", string.format("%X", rv)) test = false end if test then print("CHR-RAM BANKING TEST PASSED") return true else print("CHR-RAM BANKING TEST FAILED") return false end end --dump the CHR ROM local function dump_chrrom( file, rom_size_KB, debug ) --CHR-ROM dump all 8KB, most of this code is overkill for NROM. -- but follows same format as banked mappers local KB_per_read = 8 local num_reads = rom_size_KB / KB_per_read local read_count = 0 local addr_base = 0x00 -- $0000 while ( read_count < num_reads ) do if debug then print( "dump CHR part ", read_count, " of ", num_reads) end dump.dumptofile( file, KB_per_read, addr_base, "NESPPU_PAGE", false ) read_count = read_count + 1 end end local function exercise_chrram(debug) if debug then print("exercising CHR-RAM") end dict.stuff("RESET_LFSR") --sets it to 1 -- dict.stuff("SET_LFSR_L", 0) --lock it up to clear ram -- dict.stuff("SET_LFSR_L", 2) --give different seed for testing fails --write random data to all 4 banks local bank = 0x00 while (bank<=0x60) do --select the bank dict.nes("NES_CPU_WR", 0xC000, bank ) bank = bank + 0x20 local addr = 0x0000 while (addr<0x2000) do dict.nes("PPU_PAGE_WR_LFSR", addr) addr = addr + 256 end end local filename = "ignore/chrramdump.bin" local file = assert(io.open(filename, "wb")) bank = 0x00 while (bank<=0x60) do --select the bank dict.nes("NES_CPU_WR", 0xC000, bank ) bank = bank + 0x20 dump_chrrom(file, 8) end --close the file assert(file:close()) --re-open & compare dump with known lsfr bitstream local goodfile = "ignore/lfsr_32KB.bin" --compare the flash file vs post dump file if ( files.compare( filename, goodfile, true ) ) then print("CHR-RAM test verified") return true else print("FAILURE! CHR-RAM test failed") return false end end local function test_soft_mir_switch( debug ) --set to Horiz if debug then print("test setting soft mir switch to Horiz") end ciccom.start() ciccom.set_opcode("M") --now send operand "V" (0x56) or "H" (0x48) ciccom.write("H") dict.io("IO_RESET") time.sleep(0.05) --10msec to be overly safe --the CIC won't update the H/V stack flag unless it's reset --reset caused during swim init doesn't count either bc it halts at reset vector --test reading back CIC version dict.io("SWIM_INIT", "SWIM_ON_A0") --dict.io("SWIM_INIT", "SWIM_ON_EXP0") if swim.start() then swim.read_stack() else print("ERROR trying to read back CIC signature stack data") end swim.stop_and_reset() time.sleep(0.05) --10msec to be overly safe dict.io("NES_INIT") if ( nes.detect_mapper_mirroring() == "HORZ" ) then if debug then print("pass Horiz soft mirror switch") end else print("\n\n\nFAIL HORZ SOFT MIRROR SWITCH TEST!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n\n\n") --don't continue return false end dict.io("IO_RESET") --set to Vert ciccom.start() ciccom.set_opcode("M") --now send operand "V" (0x56) or "H" (0x48) ciccom.write("V") dict.io("IO_RESET") time.sleep(0.05) --10msec to be overly safe --the CIC won't update the H/V stack flag unless it's reset --reset caused during swim init doesn't count either bc it halts at reset vector --test reading back CIC version dict.io("SWIM_INIT", "SWIM_ON_A0") --dict.io("SWIM_INIT", "SWIM_ON_EXP0") if swim.start() then swim.read_stack() else print("ERROR trying to read back CIC signature stack data") end swim.stop_and_reset() --print("done reading STM8 stack on A0\n") dict.io("NES_INIT") if ( nes.detect_mapper_mirroring() == "VERT" ) then if debug then print("pass Vert soft mirror switch") end else print("\n\n\nFAIL VERT SOFT MIRROR SWITCH TEST!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n\n\n") --don't continue return false end dict.io("IO_RESET") dict.io("NES_INIT") print("Software mirroring switch operation verified working") return true end --dump the PRG ROM local function dump_prgrom( file, rom_size_KB, debug ) local KB_per_read = 16 local num_reads = rom_size_KB / KB_per_read local read_count = 0 local addr_base = 0x80 -- $8000 while ( read_count < num_reads ) do if debug then print( "dump PRG part ", read_count, " of ", num_reads) end --select desired bank(s) to dump --mapper 30 bank register is $C000-FFFF dict.nes("NES_CPU_WR", 0xFC80, read_count) --16KB @ CPU $8000 dump.dumptofile( file, KB_per_read, addr_base, "NESCPU_PAGE", false ) read_count = read_count + 1 end end --REQ: addr must be in the first bank $8000-BFFF local function wr_prg_flash_byte(addr, value, bank, debug) if (addr < 0x8000 or addr > 0xBFFF) then print("\n ERROR! flash write to PRG-ROM", string.format("$%X", addr), "must be $8000-BFFF \n\n") return end dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0xAA) dict.nes("NES_CPU_WR", 0xC000, 0x00) dict.nes("NES_CPU_WR", 0xAAAA, 0x55) dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0xA0) dict.nes("NES_CPU_WR", 0xC000, bank) dict.nes("NES_CPU_WR", addr, value) local rv = dict.nes("NES_CPU_RD", addr) local i = 0 while ( rv ~= value ) do rv = dict.nes("NES_CPU_RD", addr) i = i + 1 end if debug then print(i, "naks, done writing byte.") end --TODO report error if write failed end --this is controlled from the host side one bank at a time --but requires mapper specific firmware flashing functions local function flash_prgrom(file, rom_size_KB, debug) --init_mapper() --test some bytes --wr_prg_flash_byte(0x0000, 0xA5, 0, true) --wr_prg_flash_byte(0xFFFF, 0x5A, 1, true) print("\nProgramming PRG-ROM flash") local base_addr = 0x8000 --writes occur $8000-9FFF local bank_size = 16*1024 --UNROM 16KByte per PRG bank local buff_size = 1 --number of bytes to write at a time local cur_bank = 0 local total_banks = rom_size_KB*1024/bank_size local byte_num --byte number gets reset for each bank local byte_str, data, readdata --set the bank table address dict.nes("SET_BANK_TABLE", banktable_base) if debug then print("get banktable:", string.format("%X", dict.nes("GET_BANK_TABLE"))) end while cur_bank < total_banks do if (cur_bank %4 == 0) then print("writting PRG bank: ", cur_bank, " of ", total_banks-1) end --select bank to flash dict.nes("SET_CUR_BANK", cur_bank) if debug then print("get bank:", dict.nes("GET_CUR_BANK")) end --program the entire bank's worth of data --[[ This version of the code programs a single byte at a time but doesn't require -- mapper specific functions in the firmware print("This is slow as molasses, but gets the job done") byte_num = 0 --current byte within the bank while byte_num < bank_size do --read next byte from the file and convert to binary byte_str = file:read(buff_size) data = string.unpack("B", byte_str, 1) --write the data --SLOWEST OPTION: no firmware MMC3 specific functions 100% host flash algo: --wr_prg_flash_byte(base_addr+byte_num, data, cur_bank, false) --0.7KBps --EASIEST FIRMWARE SPEEDUP: 5x faster, create MMC3 write byte function: --can use same write function as NROM dict.nes("MAP30_PRG_FLASH_WR", base_addr+byte_num, data) --3.8KBps (5.5x faster than above) if (verify) then readdata = dict.nes("NES_CPU_RD", base_addr+byte_num) if readdata ~= data then print("ERROR flashing byte number", byte_num, " in bank",cur_bank, " to flash ", data, readdata) end end byte_num = byte_num + 1 end --]] --Have the device write a banks worth of data flash.write_file( file, bank_size/1024, mapname, "PRGROM", false ) cur_bank = cur_bank + 1 end print("Done Programming PRG-ROM flash") end local function is_old_firmware( debug ) if debug then print("checking for old firmware") end --check if CIRAM_A10_MIRRORING opcode is present --this was cut from later versions local rv rv = dict.nes("CIRAM_A10_MIRROR", nil, nil, nil, true) if debug then if rv then print("old firmware sensed, running legacy mode") else print("later firmware sensed, running default scripts") end end return rv end --Cart should be in reset state upon calling this function --this function processes all user requests for this specific board/mapper local function process(process_opts, console_opts) local test = process_opts["test"] local read = process_opts["read"] local erase = process_opts["erase"] local program = process_opts["program"] local verify = process_opts["verify"] local dumpfile = process_opts["dump_filename"] local flashfile = process_opts["flash_filename"] local verifyfile = process_opts["verify_filename"] local rv = nil local file -- TODO: Cleanup needed here, support chrrom, make this look more like other mapper scripts. local prg_size = console_opts["prg_rom_size_kb"] local filetype = "nes" --local filetype = "bin" if is_old_firmware(true) then --call legacy mapper30 script --local mapper30_legacy = require "scripts.nes.mapper30" mapper30_legacy.process(process_opts, console_opts) return end --initialize device i/o for NES dict.io("IO_RESET") dict.io("NES_INIT") --test cart by reading manf/prod ID if test then print("Testing ", mapname) nes.detect_mapper_mirroring(true) nes.ppu_ram_sense(0x1000, true) print("EXP0 pull-up test:", dict.io("EXP0_PULLUP_TEST")) prgrom_manf_id( debug ) --test CHR-RAM banking rv = map30_chrbank_test() --exit script if test fails if not rv then return end --test CHR-RAM rv = exercise_chrram() --exit script if test fails if not rv then return end --test software mirroring switch --rv = test_soft_mir_switch() --if not rv then return end end --dump the cart to dumpfile if read then print("\nDumping PRG-ROM...") file = assert(io.open(dumpfile, "wb")) --dump cart into file time.start() dump_prgrom(file, prg_size, false) time.report(prg_size) --close file assert(file:close()) print("DONE Dumping PRG-ROM") end --erase the cart if erase then print("\nerasing", mapname); dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0xAA) dict.nes("NES_CPU_WR", 0xC000, 0x00) dict.nes("NES_CPU_WR", 0xAAAA, 0x55) dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0x80) dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0xAA) dict.nes("NES_CPU_WR", 0xC000, 0x00) dict.nes("NES_CPU_WR", 0xAAAA, 0x55) dict.nes("NES_CPU_WR", 0xC000, 0x01) dict.nes("NES_CPU_WR", 0x9555, 0x10) local i = 0 --TODO create some function to pass the read value --that's smart enough to figure out if the board is actually erasing or not rv = 0xFF while ( rv ~= dict.nes("NES_CPU_RD", 0x8000)) do rv = dict.nes("NES_CPU_RD", 0x8000) i = i + 1 end --TODO verify erase --for now we'll just report an error if naks isn't sizable --AVR is slower so naks are lower, tested was ~60 if (i < 10) then print("ERROR flash did not appear to accept erase command, naks:", i) return else print(i, "naks, done erasing prg."); end end --program flashfile to the cart if program then --open file file = assert(io.open(flashfile, "rb")) --determine if auto-doubling, deinterleaving, etc, --needs done to make board compatible with rom if filetype == "nes" then --advance past the 16byte header --TODO set mirroring bit via ciccom local buffsize = 1 local byte local count = 1 for byte in file:lines(buffsize) do local data = string.unpack("B", byte, 1) --print(string.format("%X", data)) count = count + 1 if count == 17 then break end end end --flash cart time.start() flash_prgrom(file, prg_size, false) time.report(prg_size) --close file assert(file:close()) end --verify flashfile is on the cart if verify then file = assert(io.open(verifyfile, "wb")) --dump cart into file time.start() dump_prgrom(file, prg_size, false) time.report(prg_size) --close file assert(file:close()) --compare the flash file vs post dump file if (files.compare( verifyfile, flashfile, true ) ) then print("\nSUCCESS! Flash verified") else print("\n\n\n FAILURE! Flash verification did not match") end end dict.io("IO_RESET") return end -- global variables so other modules can use them -- call functions desired to run when script is called/imported -- functions other modules are able to call mapper30v2.process = process -- return the module's table return mapper30v2