mirror of
https://github.com/makarcz/vm6502.git
synced 2024-11-16 05:05:20 +00:00
Virtual Machine, MOS 6502 emulator.
174f8ce1a6
Upgraded mingw to 8.1.0, added mingw-w64.bat to setup compilation environment / console and updated makefile.mingw. |
||
---|---|---|
.gitattributes | ||
.gitignore | ||
6502_func_test.bin | ||
6502_func_test.dat | ||
6502_func_test.lst | ||
6502_functional_test.asm | ||
bcd.c | ||
BCDCodes.dev | ||
BCDCodes.layout | ||
benchmarks.txt | ||
bin2hex.c | ||
Bin2Hex.dev | ||
Bin2Hex.layout | ||
c64_char.dat | ||
ConsoleIO.cpp | ||
ConsoleIO.h | ||
DevJournal.txt | ||
Display.cpp | ||
Display.h | ||
dummy.ram | ||
dummy.rom | ||
eh_basic_kow.asm | ||
eh_basic_mk.asm | ||
eh_basic.asm | ||
ehbas_grdemo_loop.snap | ||
ehbas_grdemo.snap | ||
ehbas_nogrdev.dat | ||
ehbas_xx.dat | ||
ehbas.dat | ||
GraphDisp.cpp | ||
GraphDisp.h | ||
grdevdemo.bas | ||
hello_world.bas | ||
main.cpp | ||
makefile | ||
makefile.mingw | ||
Makefile.win | ||
makeming.bat | ||
MassStorage.cpp | ||
MassStorage.h | ||
MemMapDev.cpp | ||
MemMapDev.h | ||
Memory.cpp | ||
Memory.h | ||
microchess.asm | ||
microchess.bin | ||
microchess.cfg | ||
microchess.dat | ||
microchess.lst | ||
mingw-w64.bat | ||
MKBasic.cpp | ||
MKBasic.dev | ||
MKBasic.h | ||
MKBasic.layout | ||
MKCpu.cpp | ||
MKCpu.h | ||
MKGenException.cpp | ||
MKGenException.h | ||
Notes.txt | ||
numbers.bas | ||
ProgrammersReferenceManual.txt | ||
ReadMe.txt | ||
system.h | ||
t_adc_bcd_01.65s | ||
t_adc_bcd_01.dat | ||
t_sbc_bcd_01.65s | ||
t_sbc_bcd_01.dat | ||
tall.bin | ||
tall.dat | ||
tb.asm | ||
tb.dat | ||
tb.snap | ||
tbe.dat | ||
test_char_io_01.65s | ||
test_char_io_01.dat | ||
test_grtxt.bas | ||
testall_cl65.cfg | ||
testall.asm | ||
testall.dat | ||
testall.lst | ||
testall.o | ||
TestBCD.65s | ||
testbcd.dat | ||
tinybasic.asm | ||
tinybasic.cfg | ||
tinybasic.dat | ||
VMachine.cpp | ||
VMachine.h |
Project: MKBasic (a.k.a. VM6502, a.k.a. VM65, I just can't decide how to name it :-)). Author: Copyright (C) Marek Karcz 2016. All rights reserved. Free for personal and non-commercial use. Code can be distributed and included in derivative work under condition that the original copyright notice is preserved. For use in commercial product, please contact me to obtain permission and discuss possible fees, at: makarcz@yahoo.com This software is provided with no warranty. Purpose: MOS 6502 emulator, Virtual CPU/Machine and potentially retro-style 8-bit computer emulator. MOS-6502-compatible virtual computer featuring BASIC interpreter, machine code monitor, input/output device emulation etc. Main UI of the program works in DOS/shell console. Graphics display emulation requires SDL2. The best way is to download source code of SDL2 and build it. Makefile-s are included to build under Windows 32/64 (mingw compiler required) and under Linux Ubuntu or Ubuntu based distro (GNU make). SDL2 library must be on your execution path in order to run program. E.g.: set PATH=C:\src\SDL\lib\x64;%PATH% To build under Windows 32/64: * Install MINGW64 under C:\mingw-w64\x86_64-5.3.0 folder. * Run mingw terminal. * Build SDL2 library. * Change current directory to that of this project. * Set environment variable SDLDIR. (E.g.: set SDLDIR=C:\src\SDL) * Run: makeming.bat To build under Linux: * Make sure C++11 compliant version of GCC compiler is installed. NOTE: Under older distros, e.g.: Ubuntu Server 12.04, the newest c++ compiler installed may not be modern enough. Follow instructions for your distro to install compatible c++ compiler. E.g.: https://gist.github.com/application2000/73fd6f4bf1be6600a2cf9f56315a2d91 * Build SDL2 library (make, make install) or download C/C++ headers and install SDL2 from binary installation package. * Change current directory to that of this project. * Set environment variable SDLDIR. Your C/C++ headers for SDL2 should exist in $SDLDIR/include folder. * Run: make clean all NOTE: To run the emulator under Linux, it may be necessary to set env. variable LD_LIBRARY_PATH, e.g.: export LD_LIBRARY_PATH=/usr/local/lib Program passed following tests: * 6502 functional test by Klaus Dormann * AllSuiteA.asm from project hmc-6502 1. Credits/attributions: Parts of this project is based on or contains 3-rd party work: - Tiny Basic. - Enhanced Basic by Lee Davison. - Microchess by Peter Jennings (http://www.benlo.com/microchess/index.html). - 6502 functional test by Klaus Dormann. - All Suite test from project hmc-6502. 2. Format of the memory image definition file. Emulator recognizes 4 formats of memory image: - raw binary, no header, up to 64 kB of raw data, - binary image with a configuration/snapshot header, - Intel HEX format, - plain text memory image definition file. Please see detailed description of each format below: Program can load raw binary image of data and MOS 6502 opcodes. Binary image is always loaded from address $0000 and can be up to 64 kB long, so the code must be properly located inside that image. Image can be shorter than 64 kB, user will receive warning in such case, but it will be loaded. Binary image may have header attached at the top. Older version of header consists of magic keyword 'SNAPSHOT' followed by 15 bytes of data - this format had no space for expansion and will be removed in future version. All new snapshots are saved in newest format. Current version of header consists of magic keyword 'SNAPSHOT2' followed by 128 bytes of data. Not all of the 128 bytes are used, so there is a space for expansion without the need of changing the file format. The header data saves the status of CPU and emulation facilities like character I/O address and enable flag, ROM boundaries and enable flag etc. This header is added when user saves snapshot of the VM from debug console menu with command: Y [file_name]. Below is the full detailed description of the header format: * MAGIC_KEYWORD * aabbccddefghijklmm[remaining unused bytes] * * Where: * MAGIC_KEYWORD - text string indicating header, may vary between * versions thus rendering headers from previous * versions incompatible - currently: "SNAPSHOT2" * * Data: * * aa - low and hi bytes of execute address (PC) * bb - low and hi bytes of char IO address * cc - low and hi bytes of ROM begin address * dd - low and hi bytes of ROM end address * e - 0 if char IO is disabled, 1 if enabled * f - 0 if ROM is disabled, 1 if enabled * g - value in CPU Acc (accumulator) register * h - value in CPU X (X index) register * i - value in CPU Y (Y index) register * j - value in CPU PS (processor status/flags) * k - value in CPU SP (stack pointer) register * l - 0 if generic graphics display device is disabled, * 1 if graphics display is enabled * mm - low and hi bytes of graphics display base address * [remaining unused bytes are filled with 0-s] Header is not mandatory, so the binary image created outside application can also be used. User will receive warning at startup during image load if header is missing, but image will be loaded. In this case, user may need to configure necessary emulation facilities manually in debug console before executing native 6502 code. When binary image with a header is loaded, user can continue executing the program from the place where it was saved by executing command from debug console of the emulator: X pc_value Where: pc_value - the address currently showing in CPU's PC register. If the reset vector is set right, execute the 6502 code right from command line: vm65 -r image_name Above will execute the code set in reset vector without having to start it from debug console. If 6502 code requires character I/O and/or ROM facilities then image should include header with proper setup. Depending on your favorite 6502 assembler, you may need to use proper command line arguments or configuration to achieve properly formatted binary file. E.g.: if using CL65 from CC65 package, create configuration file that defines memory segments that your 6502 code uses, then all of the segments (except the last one) must have attribute 'fill' set to 'yes' so the unsused areas are filled with 0-s. Two CFG files, one for microchess and one for All Suite from hmc-6502 project are supplied with this project and assembler source code adapted to be compiled with CL65. Other assemblers may need a different approach or may not be able to generate binary images in format required for this emulator. In such case you may need to design your own custom conversion tools to generate such images. NOTE: Simple conversion utility is supplied with this project (bin2hex), which is described later in this file. Emulator recognizes Intel HEX format file. It recognizes properly data records and end-of-file record only at this time. Similar to binary image with no header, when Intel HEX file is loaded, user may need to configure necessary emulation facilities manually in debug console before executing native 6502 code. Program can also load memory image definition file (plain text), which is a format developed especially for this project. The format of the plain text memory image definition file is described below: ; comments ADDR address data ORG address data IOADDR address ROMBEGIN address ROMEND address ENROM ENIO EXEC address ENGRAPH GRAPHADDR address RESET Where: ADDR - label indicating that starting and run address will follow in the next line ORG - label indicating that the address counter will change to the value provided in next line IOADDR - label indicating that character I/O emulation trap address will follow in the next line ROMBEGIN - label indicating that the emulated read-only memory start address will follow in the next line ROMEND - label indicating that the emulated read-only memory end address will follow in the next line ENROM - enable read-only memory emulation ENIO - enable character I/O emulation EXEC - label indicating that the auto-execute address will follow in the next line, 6502 program will auto-execute from that address after memory definition file is done loading ENGRAPH - enable generic graphics display device emulation with default base address GRAPHADDR - label indicating that base address for generic graphics display device will follow in next line, also enables generic graphics device emulation, but with the customized base address RESET - initiate CPU reset sequence after loading memory definition file address - decimal or hexadecimal (prefix $) address in memory E.g: ADDR $0200 or ADDR 512 changes the default start address (256) to 512. ORG 49152 moves address counter to address 49152, following data will be loaded from that address forward data - the multi-line stream of decimal of hexadecimal ($xx) values of size unsigned char (byte: 0-255) separated with spaces or commas. E.g.: $00 $00 $00 $00 $00 $00 $00 $00 or $00,$00,$00,$00 or 0 0 0 0 or 0,0,0,0 0 0 0 0 Each described above element of the memory image definition file is optional. 3. Character I/O emulation. Emulator has ability to simulate a 80x25 text output display device and rudimentary character I/O functions. The emulation is implemented by the means of trapping memory locations defined to be designated I/O emulation addresses. The default memory location is $E000 and also by default, the character I/O is disabled. It can be enabled from the debug console with 'I' command: I hexaddr E.g.: I E000 or I FE00 or by putting optional statements in the memory image dedinition file: ENIO or IOADDR address ENIO Where: address - decimal or hexadecimal (with prefix '$') address in memory $0000 - $FFFF. The same address is used for both, input and output operations. Reading from IOADDR inside the 6502 code invokes a blocking character input function from user's DOS/shell session. After user enters the character, the memory location contains the character code and also emulated CPU Acc register contains the same code. Reading from IOADDR+1 inside 6502 code invokes a non-blocking character input function from user's DOS/shell session. The difference between blocking and non-blocking character input from 6502 code perspective: - blocking Just read from the address. Emulated device will wait for the character input. The 6502 code does not need to be polling the address for a keystroke. - non-blocking If there is no character/keystroke in the keyboard buffer, the function will move on returning the value of 0. If implementing waiting character input in 6502 code with this function, the 6502 code needs to be polling the value returned from this address in a loop until it is different than 0. Note that there is no clearly distinguished prompt generated by emulator when there is character input operation performed. It is designed like that to avoid interfering with the character I/O performed by native 6502 code. Therefore if user performs multi-step debugging in the debug console and program suddenly stops, it is likely waiting for character input. This is more clear when running the native 6502 code in non-debug execute mode. In this case the I/O operations are represented on the screen instantly and 6502 code may also produce prompts so user is aware when to enter data to the program. Writing to IOADDR inside the 6502 code will result in character code being put in the IOADDR memory location and also written to the character output buffer of the emulated display device. When VM is running in one of the debug modes, like step-by-step mode (S - step, N - go number of steps) or one of the debug code execution modes (C- continue or G - go/cont. from new address), that character is not immediately transferred to the user's DOS/shell session. It is only written to the emulated display's text memory. When VM is running in non-debug code execution mode (X - execute from new address), the character is also output to the native DOS/shell console (user's screen, a.k.a. standard output). The character output history is therefore always kept in the memory of the emulated text display device and can be recalled to the screen in debug console with command 'T'. There are 2 reasons for this: * Performance. In previous version only the emulated text display device approach was used. That meant that each time there was a new character in the emulated display buffer, the entire emulated text output device screen had to be refreshed on the DOS/shell console. That was slow and caused screen flicker when characters were output at high rate of speed. * Record of character I/O operation. During step-by-step debugging or multiple-step animated registers mode, any characters output is immediately replaced by the registers and stack status on the screen and is not visible on the screen. However user, while debugging must be able to recall the history of the characters output to the emulated text display device if user's program uses character I/O, for normal operation or diagnostic purposes. This is when shadow copy of character I/O comes handy. In real life, text output devices like text terminals, serial terminals, especially the software emulated ones also offer the facilities to buffer the output to memory for later review (history). 4. ROM (read-only memory) emulation. This facility provides very basic means for memory mapping of the read-only area. This may be required by some 6502 programs that check for non-writable memory to establish the bounds of memory that can be used for data and code. One good example is Tiny Basic. By default the ROM emulation is disabled and the memory range of ROM is defined as $D000 - $DFFF. ROM emulation can be enabled (and the memory range defined) using debug console's command 'K': K [rombegin] [romend] - to enable or K - to disable The ROM emulation can also be defined and enabled in the memory image definition file with following statements: ROMBEGIN address ROMEND address ENROM For more sophisticated memory mapping schemes including multiple ROM ranges and/or MMU-s that allow to read from ROM, write to RAM in the same range etc. I suggest to write your ROM device emulating code and use it to expand the functionality of this emulator using memory Mapped Devices framework, explained later in this document and in the programmer's reference manual document included with this project. 5. Additional comments and remarks. IOADDR is permitted to be located in the emulated ROM memory range. The writing to IOADDR is trapped first before checking ROM range and writing to it is permitted when character I/O emulation and ROM are enabled at the same time. It is a good idea in fact to put the IOADDR inside ROM range, otherwise memory scanning routines like the one in Tiny Basic may trigger unexpected character input because of the reading from IOADDR during the scan. If you experience unexpected character input prompt while emulating 6502 code, this may be the case. Reconfigure your IOADDR to be inside ROM in such case and try again. Emulator is "cycle accurate" but not time or speed accurate. This means that each call to MKCpu::ExecOpcode() method is considered a single CPU cycle, so depending on the executed opcode, multiple calls (# varies per opcode and other conditions) are needed to complete the opcode execution and proceed to the next one. Method returns pointer to the virtual CPU registers. One of the members of this structure is named CyclesLeft. When this variable reaches 0, the opcode execution is considered complete. The VMachine class calls the ExecOpcode() method as fast as possible, so it is not real-time accurate, as already mentioned. To implement real-time accurate emulation, the MKCpu::ExecOpcode() method calls would have to be synchronized to some fairly accurate time scale (some kind of timer thread or a different solution) to emulate the timing on the bus signals level. This emulator does not implement such level of accuracy. 6. Debugger Console Command Reference. S - step Executes single opcode at current address. C - continue Continues code execution from current address until BRK. M - dump memory Usage: M [startaddr] [endaddr] Where: startaddr,endaddr - memory addr. in hexadecimal format [0000..FFFF]. Dumps contents of memory, hexadecimal and ASCII formats." G - go/continue from new address until BRK Usage: G [address] Where: address - memory addr. in hexadecimal format [0000.FFFF]. Executes code at provided address, interrupted by BRK opcode. X - execute code from new address until RTS Usage: X [address] Where: address - memory addr. in hexadecimal format [0000.FFFF]. Executes code at provided address, until RTS (last one). Q - quit Exits from the emulator/debugger. A - set address for next step Usage: A [address] Where: address - memory addr. in hexadecimal format [0000.FFFF]. Sets current address to a new value. N - go number of steps Usage: N [steps] Where: steps - number of steps in decimal format Execute number of opcodes provided in steps argument starting from current address. P - IRQ Send maskable interrupt request to CPU (set the IRQ line LOW). W - write to memory Usage: W [address] [hexval] [hexval] ... 100 Where: address - memory addr. in hexadecimal format [0000.FFFF], hexval - byte value in hexadecimal format [00.FF]. Writes provided values to memory starting at specified address. I - toggle char I/O emulation Usage: I [address] Where: address - memory addr. in hexadecimal format [0000.FFFF], Toggles basic character I/O emulation. When enabled, all writes to the specified memory address also writes a character code to to a virtual console. All reads from specified memory address are interpreted as console character input. V - toggle graphics display (video) emulation Usage: V [address] Where: address - memory addr. in hexadecimal format [0000.FFFF], Toggles basic raster (pixel) based RGB graphics display emulation. When enabled, window with graphics screen will open and several registers are available to control the device starting at provided base address. Read programmers reference for detailed documentation regarding the available registers and their functions. R - show registers Displays CPU registers, flags and stack. Y - snapshot Usage: Y [file_name] Where: file_name - the name of the output file. Save snapshot of current CPU and memory in a binary file. T - show I/O console Displays/prints the contents of the virtual console screen. Note that in run mode (commands X, G or C), virtual screen is displayed automatically in real-time if I/O emulation is enabled. E - toggle I/O local echo Toggles local echo on/off when I/O emulation is enabled. B - blank (clear) screen Clears the screen, useful when after exiting I/O emulation or registers animation (long stack) your screen is messed up. F - toggle registers animation mode When in multi-step debug mode (command: N), displaying registers can be suppressed or, when animation mode is enabled - they will be continuously displayed after each executed step. J - set registers status animation delay Usage: J [delay] Where: delay - time of delay in milliseconds, Sets the time added at the end of each execution step in multi step mode (command: N). The default value is 250 ms. K - toggle ROM emulation Usage: K [rombegin] [romend] - to enable, K - to disable, (OR just use 'K' in both cases and be prompted for arguments.) Where: rombegin - hexadecimal address [0200..FFFF], romend - hexadecimal address [rombegin+1..FFFF]. Enable/disable ROM emulation and define address range to which the ROM (read-only memory) will be mapped. Default range: $D000-$DFFF. L - load memory image Usage: L [image_type] [image_name] Where: image_type - A - (auto), B (binary), H (Intel HEX) OR D (definition), image_name - name of the image file. This function allows to load new memory image from either binary image file, Intel HEX format file or the ASCII definition file. With option 'A' selected, automatic input format detection will be attempted. The binary image is always loaded from address 0x0000 and can be up to 64kB long. The definition file format is a plain text file that can contain following keywords and data: ADDR This keyword defines the run address of the executable code. It is optional, but if exists, it must be the 1-st keyword in the definition file. Address in decimal or hexadecimal ($xxxx) format must follow in the next line. ORG Changes the current address counter. The line that follows sets the new address in decimal or hexadecimal format. Data that follows will be put in memory starting from that address. This keyword is optional and can be used multiple times in the definition file. IOADDR Defines the address of the character I/O emulation. The next line sets the address of I/O emulation in decimal or hexadecimal format. If the I/O emulation is enabled (see ENIO keyword), then any character written to this address will be sent to the virtual console. The reading from that address will invoke character input from the emulated console. That input procedure is of blocking type. To invoke non-blocking character procedure, reading should be performed from IOADDR+1. ROMBEGIN Defines the address in memory where the beginning of the Read Only memory is mapped. The next line that follows this keyword sets the address in decimal or hexadecimal format. ROMEND Defines the address in memory where the end of the Read Only Memory is mapped. The next line that follows this keyword sets the address in decimal or hexadecimal format. ENIO Putting this keyword in memory definition file enables rudimentary character I/O emulation and virtual console emulation. ENROM Putting this keyword in memory definition file enables emulation of Read Only Memory, in range of addresses defined by ROMBEGIN and ROMEND keywords. EXEC Define starting address of code which will be automatically executed after the memory image is loaded. The next line that follows this keyword sets the address in decimal or hexadecimal format. RESET Enables auto-reset of the CPU. After loading the memory definition file, the CPU reset sequence will be initiated. ENGRAPH Enables raster graphics device emulation. GRAPHADDR Defines the base address of raster graphics device. The next line that follows sets the address in decimal or hexadecimal format. NOTE: The binary image file can contain a header which contains definitions corresponding to the above parameters at fixed positions. This header is created when user saves the snapshot of current emulator memory image and status. Example use scenario: * User loads the image definition file. * User adjusts various parameters of the emulator (enables/disables devices, sets addresses, changes memory contents). * User saves the snapshot with 'Y' command. * Next time user loads the snapshot image, all the parameters and memory contents stick. This way game status can be saved or a BASIC interpreter with BASIC program in it. See command 'Y' for details. O - display op-codes history Show the history of last executed op-codes/instructions, full with disassembled mnemonic, argument and CPU registers and status. NOTE: op-codes execute history must be enabled, see command 'U'. D - diassemble code in memory Usage: D [startaddr] [endaddr] Where: startaddr,endaddr - hexadecimal address [0000..FFFF]. Attempt to disassemble code in specified address range and display the results (print) on the screen in symbolic form. 0 - reset Run the processor initialization sequence, just like the real CPU when its RTS signal is set to LOW and HIGH again. CPU will disable interrupts, copy address from vector $FFFC to processors PC and will start executing code. Programmer must put initialization routine under address pointed by $FFFC vector, which will set the arithmetic mode, initialize stack, I/O devices and enable IRQ if needed before jumping to main loop. The reset routine disables trapping last RTS opcode if stack is empty, so the VM will never return from opcodes execution loop unless user interrupts with CTRL-C or CTRL-Break. ? - display commands menu Display the menu of all available in Debug Console commands. U - enable/disable exec. history Toggle enable/disable of op-codes execute history. Disabling this feature improves performance. Z - enable/disable debug traces Toggle enable/disable of debug traces. 2 - display debug traces Display recent debug traces. 1 - enable/disable performance stats Toggle enable/disable emulation speed measurement. NOTE: 1. If no arguments provided, each command will prompt user to enter missing data. 2. It is possible to exit from running program to debugger console by pressing CTRL-C or CTRL-Pause/Break, which will generate a "Operator Interrupt". However in the character input mode use CTRL-Y combination or CTRL-Break (DOS), CTRL-C (Linux). You may need to press ENTER after that in input mode (DOS). 7. Command line usage. D:\src\wrk\mkbasic>vm65 -h Virtual Machine/CPU Emulator (MOS 6502) and Debugger. Copyright (C) by Marek Karcz 2016. All rights reserved. Usage: vm65 [-h] | [ramdeffile] [-b | -x] [-r] Where: ramdeffile - RAM definition file name -b - specify input format as binary -x - specify input format as Intel HEX -r - after loading, perform CPU RESET -h - print this help screen When ran with no arguments, program will load default memory definition files: default.rom, default.ram and will enter the debug console menu. When ramdeffile argument is provided with no input format specified, program will attempt to automatically detect input format and load the memory definition from the file, set the flags and parameters depending on the contents of the memory definition file and enter the corresponding mode of operation as defined in that file. If input format is specified (-b|-x), program will load memory from the provided image file and enter the debug console menu. 8. Utilities. Utility bin2hex is supplied with the project to aid in conversion from raw binary memory image to one of the plain text formats recognized by emulator NOTE: In current version, emulator can load raw binary format directly, so usefulness of this utility is somewhat deprecated. D:\src\wrk\mkbasic>bin2hex -h Program: bin2hex Convert binary file to Intel HEX format. OR Convert binary file to memory image definition for MKBASIC (VM65) emulator. Copyright: Marek Karcz 2016. All rights reserved. Free for personal and educational use. Usage: bin2hex -f input -o output [-w addr] [-x exec] [[-s] [-z] | -i] Where: input - binary file name output - output file name addr - starting address to load data (default: 2048) exec - address to auto-execute code from (default: 2048) -s - suppress auto-execute statement in output -z - suppress data blocks with 0-s only -i - convert to Intel HEX format NOTE: When this switch is used, addr, exec, -s, -z are ignored, addr = 0, exec is not set and data blocks with 0-s only are always suppressed. 9. Memory Mapped Device abstraction layer. In microprocessor based systems in majority of cases communication with peripheral devices is done via registers which in turn are located under specific memory addresses. Programming API responsible for modeling this functionality is implemented in Memory and MemMapDev classes. The Memory class implements access to specific memory locations and maintains the memory image. The MemMapDev class implements specific device address spaces and handling methods that are triggered when addresses that belong to the device are accessed by the microprocessor. Programmers can expand the functionality of this emulator by adding necessary code emulating specific devices in MemMapDev and Memory classes implementation and header files. In current version, two basic devices are implemented: character I/O and raster (pixel based) graphics display. Both can be activated or inactivated at will and provide simple register based interface that requires no extra memory space use for data. E.g.: Character I/O device uses just 2 memory locations, one for non-blocking I/O and one for blocking I/O. Writing to location causes character output, while reading from location waits for character input (blocking mode) or reads the character from keyboard buffer if available (non-blocking mode) or returns 0. The graphics display can be accessed by writing to multiple memory locations. If we assume that GRDEVBASE is the base address of the Graphics Device, there are following registers: Offset Register Description ---------------------------------------------------------------------------- 0 GRAPHDEVREG_X_LO Least significant part of pixel's X (column) coordinate or begin of line coord. (0-255) 1 GRAPHDEVREG_X_HI Most significant part of pixel's X (column) coordinate or begin of line coord. (0-1) 2 GRAPHDEVREG_Y Pixel's Y (row) coordinate (0-199) 3 GRAPHDEVREG_PXCOL_R Pixel's RGB color component - Red (0-255) 4 GRAPHDEVREG_PXCOL_G Pixel's RGB color component - Green (0-255) 5 GRAPHDEVREG_PXCOL_B Pixel's RGB color component - Blue (0-255) 6 GRAPHDEVREG_BGCOL_R Backgr. RGB color component - Red (0-255) 7 GRAPHDEVREG_BGCOL_G Backgr. RGB color component - Green (0-255) 8 GRAPHDEVREG_BGCOL_B Backgr. RGB color component - Blue (0-255) 9 GRAPHDEVREG_CMD Command code 10 GRAPHDEVREG_X2_LO Least significant part of end of line's X coordinate 11 GRAPHDEVREG_X2_HI Most significant part of end of line's X coordinate 12 GRAPHDEVREG_Y2 End of line's Y (row) coordinate (0-199) 13 GRAPHDEVREG_CHRTBL Set the 2 kB bank where char. table resides 14 GRAPHDEVREG_TXTCURX Set text cursor position (column) 15 GRAPHDEVREG_TXTCURY Set text cursor position (row) 16 GRAPHDEVREG_PUTC Output char. to current pos. and move cursor 17 GRAPHDEVREG_CRSMODE Set cursor mode : 0 - not visible, 1 - block 18 GRAPHDEVREG_TXTMODE Set text mode : 0 - normal, 1 - reverse NOTE: Functionality maintaining text cursor is not yet implemented. Writing values to above memory locations when Graphics Device is enabled allows to set the corresponding parameters of the device, while writing to command register executes corresponding command (performs action) per codes listed below: Command code Command description ------------------------------------------------------------------------------ GRAPHDEVCMD_CLRSCR = 0 Clear screen GRAPHDEVCMD_SETPXL = 1 Set the pixel location to pixel color GRAPHDEVCMD_CLRPXL = 2 Clear the pixel location (set to bg color) GRAPHDEVCMD_SETBGC = 3 Set the background color GRAPHDEVCMD_SETFGC = 4 Set the foreground (pixel) color GRAPHDEVCMD_DRAWLN = 5 Draw line GRAPHDEVCMD_ERASLN = 6 Erase line Reading from registers has no effect (returns 0). Above method of interfacing GD requires no dedicated graphics memory space in VM's RAM. It is also simple to implement. The downside - slower performance (multiple memory writes to select/unselect a pixel or set color). I plan to add graphics frame buffer in the VM's RAM address space in future release. Simple demo program written in EhBasic that shows how to drive the graphics screen is included: grdevdemo.bas. 10. Performance considerations. Program measures the emulation performance and displays it in the Debug Console. It uses a 1 MHz CPU as a reference to return % of speed compared to assumed 1,000,000 CPU cycles or clock ticks per second - which is considered a 100 % speed. Performance is measured during the whole execution cycle and calculated at the end of the run. Captured speed is summed with previous result and divided by 2 to produce average emulation speed during single session. This emulator has been optimized for performance. I had issues with emulation speed in previous version, mostly because it was a prototype with many debugging aids enabled by default and not yet optimized for speed. I took a good look at all the critical parts of code and fixed the problems. I am sure there is still space for improvement, but now the emulation speed leaves good margin for expansion with new emulated peripherals and still should compare well to the model 1 MHz CPU. Emulating of pure 6502 machine code with all peripherals (memory mapped devices, I/O etc.) emulation disabled and time critical debugging facility, the op-codes execute history also disabled, returns performance in range of 646 % (PC1) and 468 % (PC2) (* see annotation below). Enabling the op-code execute history drops the performance. With all peripherals disabled and op-code history enabled we are down to 411 % on PC1 and 312 % on PC2. Enabling and adding the emulated memory mapped devices to the pool may cause the emulation speed to drop as well. However even with currently implemented peripherals (char I/O, graphics raster device) enabled and actively used and op-codes execute history enabled the performance is still well above 300 % on both PC1 and on PC2 (* see annotations for PC configurations/specs). The same case but with op-code execute history disabled - performance exceeds 400 % on both PC configurations. Currently the main emulation loop is not synchronized to an accurate clock tick or raster synchronization signal but just runs as fast as it can. Therefore emulation speed may vary per PC and per current load on the system. If this code is to be used as a template to implement emulator of a real-world machine, like C-64 or Apple I, it may need some work to improve performance, but I think is leaves a pretty good margin for expansion as it is. On a fast PC (* see annotation) the emulation speed above 600 % with basically nothing but CPU emulated and op-codes execute history disabled (which should be disabled by default as it is needed for debugging purposes only) is IMO decent if we don't want to emulate MOS 6502 machine with clock much faster than 1 MHz. Annotations to 'Performance considerations': *) PC1 stats: Type: Desktop CPU: 2.49 GHz (64-bit Quad-core Q8300) RAM: 4,060 MB OS: Windows 10 Pro (no SP) [6.2.9200] PC2 stats: Type: Laptop CPU: 2.3 GHz (64-bit Quad-core i5-6300HQ) RAM: 15.9 GB OS: Win 10 Home. 11. Problems, issues, bugs. * Regaining focus of the graphics window when it is not being written to by the 6502 code is somewhat flakey. Since the window has no title bar, user can only switch to it by ALT-TAB (windows) or clicking on the corresponding icon on the task bar. However it doesn't always work. Switching to the DOS console of emulator while in emulation mode should bring the graphics window back to front. 12. Warranty and License Agreement. This software is provided with No Warranty. I (The Author) will not be held responsible for any damage to computer systems, data or user's health resulting from using this software. Please use responsibly. This software is provided in hope that it will be be useful and free of charge for non-commercial and educational use. Distribution of this software in non-commercial and educational derivative work is permitted under condition that original copyright notices and comments are preserved. Some 3-rd party work included with this project may require separate application for permission from their respective authors/copyright owners.