The Western Design Center (WDC) 65C02 microprocessor is an enhanced CMOS version of the popular NMOS-based MOS Technology 6502 8-bit microprocessor—the CMOS redesign being made by Bill Mensch in 1978. Over various periods of time, the 65C02 has been second-sourced by NCR, GTE, Rockwell, Synertek and Sanyo. The 65C02 has been used in some home computers, as well as in embedded applications, including medical-grade implanted devices.
- 1 Introduction and features
- 2 Comparison with the MOS 6502
- 3 65SC02
- 4 Notable uses of the 65C02
- 5 See also
- 6 References
- 7 External links
Introduction and features
The 65C02 is a low cost, general-purpose 8-bit microprocessor (8-bit registers and data bus) with a 16-bit program counter and address bus. The variable length instruction set and manually optimized core size are intended to make the 65C02 well suited for low power system-on-chip (SoC) designs.
The W65C02S–14 is the production version of the 65C02 microprocessor, and is available in PDIP, PLCC and QFP packages through distribution. The maximum officially supported Ø2 (primary) clock speed is 14MHz, indicated by the –14 part number suffix. The "S" designation indicates that the part has a fully static core, a feature that allows Ø2 to be slowed down or fully stopped in either the high or low state with no loss of data. Typical microprocessors not implemented in CMOS have dynamic cores and will lose their internal register contents (and thus crash) if they are not continuously clocked at a rate between some minimum and maximum specified values.
A Verilog hardware description model is available for designing the W65C02S core into an application-specific integrated circuit (ASIC) or a field-programmable gate array (FPGA). As is common in the semiconductor industry, WDC offers a development system, which includes a developer board, an in-circuit emulator (ICE) and a software development system.
General logic features
- 8-bit data bus
- 16-bit address bus (providing an address space of 64K bytes)
- 8-bit arithmetic logic unit (ALU)
- 8-bit processor registers:
- 16-bit program counter
- 69 instructions, implemented by 212 operation codes
- 16 addressing modes, including zero page addressing
- Vector pull (VPB) output indicates when interrupt vectors are being addressed
- Memory lock (MLB) output indicates to other bus masters when a read-modify-write instruction is being processed
- WAit-for-Interrupt (WAI) and SToP (STP) instructions reduce power consumption, decrease interrupt latency and enable synchronization with external events
- Supply voltage specified at 1.71 V to 5.25 V
- Current consumption (core) of 0.15 and 1.5 mA per MHz at 1.89 V and 5.25 V respectively
- Variable length instruction set, enabling code size optimization over fixed length instruction set processors, results in power savings
- Fully static circuitry allows stopping the clock to conserve power
The W65C02S may be operated at any convenient supply voltage (VDD) between 1.8 and 5 volts (±5%). The data sheet AC characteristics table lists operational characteristics at 5V/14 MHz, 3.3V/8 MHz, 3V/8 MHz, 2.5V/4 MHz, and 1.8V/2 MHz. This information may be an artifact of an earlier data sheet, as a graph indicates that typical devices are capable of operation at higher speeds than suggested by the AC characteristics table, and that reliable operation at 20MHz should be readily attainable with VDD at 5 volts, assuming the supporting hardware will allow it. WDC has reported that FPGA realizations of the W65C02S have been successfully operated at 200MHz.
The W65C02S may also be operated at non-integral clock rates such as 13.5MHz (digital SDTV luma sampling rate), 14.31818MHz (NTSC colour carrier frequency × 4), 14.75MHz (PAL square pixels), 14.7456 (baud rate crystal), etc, as long as VDD is sufficient to support the frequency. Designer Bill Mensch has pointed out that FMAX is affected by off-chip factors, such as the capacitive load on the microprocessor's pins. Minimising load by using short signal tracks and fewest devices helps raise FMAX. The PLCC and QFP packages have less pin-to-pin capacitance than the PDIP package, and are more economical in the use of printed circuit board space.
Comparison with the MOS 6502
The 65C02 shares its predecessor's 8-bit instruction set architecture and 16-bit memory address space $0000 to $FFFF allowing access to a total memory map of 64K. "Zero Page" spans $0000 to $00FF. "Page 1" spans memory address space $0100 to $01FF and is dedicated for the stack. On this processor the stack grows downwards with the stack pointer starting at $01FF and decrementing as the stack grows.
It adds a number of improvements and documented opcodes, the most useful being instructions that can push or pull the X and Y index registers to/from the stack. Undefined opcodes have been converted into NOPs, although of varying instruction lengths.
Significantly, the defective "indirect jump page wrap" instruction (JMP (<ADDR>), where <ADDR> straddles a memory page boundary) has been fixed, eliminating a constant source of trouble for unwary assembly language programmers. This instruction has also been enhanced with .X register indexing, making it possible to code JMP (<ADDR>,X), enabling the development of a simple jump table management methodology.
Some variants of the 65C02 (including the WDC W65C02S and the Rockwell R65C00 family) feature individual bit manipulation operations (RMB, SMB, BBR and BBS). The 65SC02 was also available, which lacked these operations.
Other problems with the 6502, fixed in the 65C02, relate to its program status register, which contains eight system flags. Some flags are set or reset under program control. Others reflect the status of the machine after arithmetic or bit manipulation instructions.
|V||--||Sign bit overflow|
|1||--||Undefined (always set)|
|B||--||Break flag (set by BRK instruction)|
|D||--||Decimal mode enabled|
|C||--||Arithmetic carry (borrow)|
In all NMOS logic forms of the 6502, the decimal flag (D flag) is not initialized to a known state following reset or when an interrupt is processed, which may lead to arbitrary behavior. This forces 6502 programmers to use the CLD instruction early in the reset handler code (it is generally the second instruction executed after SEI), as well as in the front end of the interrupt handler. The 65C02 addresses these problems by causing the D flag to be cleared at reset or upon receipt of an interrupt (after the status register is pushed onto the stack).
Also, in NMOS 6502s, the N flag is invalid when the processor is operating in decimal mode. The 65C02 fixes this problem (at the cost of an additional clock cycle), and thus increases the usefulness of decimal mode.
The 65SC02 is a variant of the WDC 65C02 with additional instructions. The 65C02 is the base for the HuC6280 by NEC used in their video game console TG-16 (PC-Engine). The bit operation capability of the 6502's and the 65C02 were poor which impeded bit-oriented compression or decompression algorithms like Huffman coding and so the 65SC02 got new bit operations.
Notable uses of the 65C02
- Apple IIc portable improved Apple II, by Apple Computer (1.023 MHz)
- Apple Enhanced IIe by Apple Computer (1.023 MHz)
- BBC Master home/educational computer, by Acorn Computers Ltd (2 MHz 65SC12 plus optional 4 MHz 65C102 second processor)
- Replica 1 by Briel Computers, a replica of the Apple I hobbyist computer (1 MHz)
- Laser 128 series clones of Apple II
- KIM-1 Modern Replica of the MOS/CBM KIM-1 by Briel Computing
- Oric 1 and Atmos, computer from Tangerine Computer Systems, also used in the French Oric Telestrat
Video game consoles
- Atari Lynx handheld (65SC02 @ ~4 MHz)
- NEC PC Engine aka TurboGrafx (HuC6280 @ 7.16 MHz)
- GameKing handhelds (6 MHz), by Time Top
- Watara Supervision handhelds (65SC02 @ 4 MHz)
- TurboMaster accelerator cartridge for the Commodore 64 home computer (65C02 @ 4.09 MHz)
- many dedicated chess computers i.e.: Mephisto MMV, Novag Super Constellation, Fidelity Elite and many more (4–20 MHz)
- W65C02S 8–bit Microprocessor – PDF datasheet at WDC's 65xx.com website
- The 6502/65C02/65C816 Instruction Set Decoded – From Neil Parker's Apple II page
- CPU World
- MicroKIM-1 modern replica of the MOS/CBM KIM-1 – Briel Computings modern KIM-1 Replica website.