This is my implementation of the MOS6502 processor emulator

• libs:

  • doctest.h: C++ test framework

• resources:

  • hex_to_bin.py: Python3 script that take in input a hex formatted file and translate it into a binary file ignoring special characters. To run is type: python3 hex_to_bin.py my_hex_file.hex and teh output will be in my_hex_file.bin. You can load the binary directly int the emu.

  • nestest.log: Nintendulator logs of the execution of nestest.nes. It is used to test my processor.

  • nestest.nes: NES Cartridge with the test almost all of the mos6502 functionalities. Also include tests of the unofficial opcodes

  • program.hex: this is the example program to run on the emu. The source is:

    LDX #10
    STX $0000
    LDX #3
    STX $0001
    LDY $0000
    LDA #0
    CLC
    loop
    ADC $0001
    DEY
    BNE loop
    STA $0002
    NOP
    NOP
    NOP

  • program.bin: This is the binary version of the program.hex

• common: Contains some common data types that a potential user of MOS6502 class will need

• console: This is a console program called EMU that allow to use the mos6502 emulator and perform debug step by step. To run it with a sample program just first build the project and then run ./emu resources/program.bin

• mos6502: Contains the implementation of the mos6502 emulator

• opcode: Contains the opcode table that map the instruction code to the addressing mode, operation, size of operation, num of clocks needed ad the mnemonic of the operation. The mnemonic prefixed by the * are unofficial operations.

• test: This is the file used to test the emulator. It loads the NES Cartridge nestest.nes

TODO

• To run the console cpu controller nicely named EMU ./emu name_of_the_binary, like ./emu resources/program.bin

First of all you need to set you terminal size at least to 95x30.

In the left corner you will see the current memory page printed in hex.

In the MOS6502 a memory page is a chunk of memory of the size of 256 bytes and start at the address 0xHH00 and continue up to 0xHHFF.

The First page is called Zero Page (from 0x0000 to 0x00FF) and is special. The processor have shortcut to access this page and have his own addressing mode. The Zero Page is used often like registers.

The second page (from 0x0100 t 0x01FF) is used for the stack. By reference the stack pointer is set to 0x01FD and decreases during the use.

The * near the byte in the memory corner means the Program counter currently point here. The $ is the current address selected on the data bus (this is the address where the current data is read or written). The # means that * and $ point to the same memory location.

In the right corner are printed all processor states like the register A, the indexes X and Y, the Stack Pointer, the Program Counter and some more information not present in the real processor but used by me for the inner logic.

Under below you can find a line with the information about the current instruction.

Then we have 5 lines used for print logs.

The EMU is case insensitive for now

• b: show previous memory page
• c: perform one clock cycle
• l: print some test log (currently used for debug the log functionality)
• n: show next memory page
• q: quit

• Fix NOP timing
• Replace tmp_buff uint16_t with tmp_h and tmp_l uint8_t
• Rewrite all casts from C style to static_cast C++ like
• Check the timing of the composed illegal opcodes
• Implement decimal mode
• Test the interrupts
• Implement clock
• Test speed on ARMs processors (like raspberry or BeagleBone or TechNexion)

• In EMU set the current according on the status of the processor. This feature should be turned on and off by the user
• Better interface for the EMU
• More user friendly and complex commands for the EMU
• Introduce some other tests beside the nestest.nes
• Will be nice to find more logs of nestest.nes and test against it too
• Integrate into EMU the program loader directly from hex formatted file
• Maybe also integrate (or maybe write) some assembler into EMU

• doctest: It's one header C++ fast test framework

• nestest.nes: Used with the Nintendulator logs to test the processor. The test consist in compare the log from the my mos6502 after each instruction with the log from the Nintendulator. The nestest.nes can be used with and without graphical mode. To perform all test without ppu (like my test) you need to load the cartridge and set the program counter to address 0xC000, like described in this doc. NOTE(max): this will test also the illegal opcodes.

• Javidx9's NES Emulator videos and repo. Used like reference for:

  • The opcode table
  • Nes cartridge loader and memory management used for execute the nestest.nes cartridge for test the processor
  • Reference for most of the addressing mode and operations implementation

• Gianluca Ghettini website for some information

• visual6502.org for documentation, technical and general purpose information. Also the FANTASTIC simulator for general debug and behavior comparison. This is the BEST place if you need information about mos6502

• Obviously wikipedia

• Nice speech about the mos6502 reverse engineering

• Some details about the addressing modes at the emulator101

• Online mos6502 assembler

• 6502 instruction set information

• Test reference at nesdev,com

• 6502.org for detailed information about addressing modes and operations

• Easy6502 for debug

• Information at pagetable.com about BRK, IRQ, NMI and RESET

• Nice emulator/debugger used for debugging

• Unofficial opcodes information

• More unofficial opcodes information

• Detailed document about the processor behavior

• Synertek programming manual

• Synertek hardware manual

• Datasheet

• Rockwell Datasheet with opcode matrix

• Document used for timing in the cycle-precise version. It is about 6510 but the instructions set should be the same as the 6502

• Nice Instruction timing description and more info

Copyright (c) 2019 Maksym Bodnar aka Mazerfaker

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.