Motorola 68000 (original) (raw)
The Motorola 68000 is a CISC microprocessor, the first member of a successful family of microprocessors, which were all mostly software compatible. The entire series was often referred to as the m68k, or simply 68k
The 68000 family
Motorola 68EC000
Motorola 68HC000
Motorola CPU32 (aka Motorola 68330)
Motorola Coldfire
People who are familiar with the PDP-11 or VAX usually feel comfortable with the 68000. With the exception of the split of general purpose registers into specialized data and address registers, the 68000 architechture is in many ways a 32-bit PDP-11.
History
Originally, the MC68000 was designed for use in household products (at least, that is what an internal memo from Motorola claimed). Luckily it was used for the design of homecomputers like the Amiga and Atari. It was also used in the Sega Genesis/MegaDrive, NeoGeo and several Arcade Machines as their main CPU. In the Sega Saturn, the 68000 was used as the sound processor, and in the Atari Jaguar they were used as a main controller for all the other dedicated hardware IC's.
Notable design wins include the Amiga, the Apple Macintosh, and the original Sun Microsystems and SGI UNIX machines. 68000 derivatives persisted in the UNIX market for many years, because the architecture so strongly resembles the Digital PDP-11 and VAX, and is an excellent computer for running C code. The 68000 eventually saw its greatest success as a controller. Thousands of HP, Printronix and Adobe printers used it. Its derivative microcontrollers, the CPU32 and Coldfire processors have been manufactured in the millions as automotive engine controllers. It also sees use by medical manufacturers and many printer manufacturers because of its low cost, convenience, and good stability. As of 2001, the Dragonball versions of the processor are used in the popular Palm series of PDAs from Palm Computing and Handspring's Visor, though the architecture is being phased out in favor of the ARM processor core.
The Voyage 200 PLT
The Motorola 68000 is also used in Texas Instruments' latest line of calculators. These four calculators (the TI-89, TI-92, TI-92 Plus, and Voyage 200 PLT) are the highest-end calculators. The TI-92 had a 10 MHz processor and 68KB RAM, and was released in 1995. It was upgraded to the TI-92 Plus (in 1998) with 188KB RAM, 384KB Flash ROM, and the same 10 MHz processor. Also released in that year was the TI-89, identical except it was in a more traditionally shaped case. Around 2000, the TI-92 Plus and the TI-89 were upgraded to Hardware Version 2, and gaines a 12 MHz processor and a few other hidden upgrades. In 2002, Texas Instruments relaeased its latest �ber-calculator: the Voyage 200 PLT. This had the Hardware Version 2 12MHz processor, 188 KB RAM, and a whopping 3.7 MB Flash ROM. It also had a clock and an Apps Desktop, both of which were summarily released as Flash ROM updates for the TI-92 Plus and TI-89.
Initial samples of the 68000 were released in 1982, and competed against the Intel 8086 and Intel 80286 with some success. Initial clock rates were a then-blisteringly fast 8MHz, with a rather slow seven or eight clocks per instruction. However, the instructions did more than Intel processors. Motorola ceased production of the 68000 in 2000, although derivatives, notably the CPU32 family, continue in production. As of 2001, Hitachi continued to manufacture the 68000 under license.
Architecture
Address bus
The 68000 was a clever compromise. When the 68000 was introduced, 16-bit busses were really the most practical size. However, the 68000 was designed with 32-bit registers and address spaces, on the assumption that hardware prices would fall. To address the perceived markets, the actual 68000 was designed in three forms. The base-form had a 24-bit address, and a 16-bit data bus. The short form, the 68008, had an 18-bit address (possibly 19 or 20 bits, at least one firm addressed 512KBytes with 68008s), and an 8-bit data bus. A planned future form (later the 68020) had a 32-bit data and address bus.
Internal registers
The CPU had 8 general-purpose data registers (D0-D7), and 8 address registers (A0-A7). The last address register was also the standard stack pointer, and could be called either A7 or SP. This was a good number of registers in many ways. It was small enough to make the 68000 respond quickly to interrupts (because only 15 or 16 had to be saved), and yet large enough to make most calculations fast.
Having two types of registers was mildly annoying at times, but really not hard to use in practice. Reportedly, it allowed the CPU designers to achieve a higher degree of parallelism, by using an auxiliary execution unit for the address registers.
Status register
The 68000 comparison, arithmetic and logic operations set bits in a status register to record their results for use by later conditional jumps. The bits were "Z"ero, "C"arry, e"X"tend, and "N"egative. The eXtend bit deserves special mention, because it was separated from the Carry. This permitted the extra bit from arithmetic, logic and shift operations to be separated from the carry for flow-of-control and linkage.
The instruction set
The designers attempted to make the assembly language orthogonal. That is, instructions were divided into operations and address modes. Almost all address modes were available for almost all instructions. Many programmers disliked the "near" orthogonality, while others were grateful for the attempt.
At the bit level, the person writing the assembler would clearly see that these "instructions" could become any of several different op-codes. It was quite a good compromise because it gave almost the same convenience as a truly orthogonal machine, and yet also gave the CPU designers freedom to fill in the op-code table.
The minimal instruction size was huge for its day at 16 bits. Furthermore, many instructions and addressing modes added extra words on the back for addresses, more address-mode bits, etc.
Many designers believed that the M68000 architecture had compact code for its cost, especially when produced by compilers. This belief in more compact code led to many of its design wins, and much of its longevity as an architecture.
Most embedded system designers are acutely aware of the costs of memory.
This belief (or feature, depending on the designer) continued to make design wins for the instruction set (with updated CPUs) up until the ARM architecture introduced compressed Thumb op-codes that were more compact.
Privilege levels
The CPU, and later the whole family, implemented exactly two levels of privilege. User mode gave access to everything except the interrupt level control. Supervisor privilege gave access to everything. An interrupt always became supervisory. The supervisor bit was stored in the status register, and visible to user programs.
A real advantage of this system was that the supervisor level had a separate stack pointer. This permitted a multitasking system to use very small stacks for tasks, because the designers did not have to allocate the memory required to hold the stack frames of a maximum stack-up of interrupts.
Interrupts
The CPU recognized 8 interrupt levels. Levels 0 through 7 were strictly prioritized. That is, a higher-numbered interrupt could always interrupt a lower-numbered interrupt. In the status register, a privileged instruction allowed one to set the current minimum interrupt level, blocking lower priority interrupts. Level 7 was not maskable. Level 0 could be interrupted by any higher level. The level was stored in the status register, and was visible to user-level programs.
The "exception table" (interrupt vector addresses) was fixed at addresses 0 through 1023, permitting 256 32-bit vectors. The first vector was the starting stack address, and the second was the starting code address. Vectors 3..15 were used to report various errors: bus error, address error, illegal instruction, zero division, CH1 & CHK2 vector, privilige violation, and some reserved vectors that became line 1010 emulator, line 1111 emulator, and hardware breakpoint. Vector 24 started the real interrupts: spurious interrupt (i.e. it wasn't properly hand-shaken), and level 1 .. level 7 autovectors, then the 15 TRAP vectors, then some more reserved vectors, then the user defined vectors.
The interrupt controller was originally a separate IC, the 68901. This chip performed a rather complicated dance on the bus to translate the seven pull-down interrupt lines into vectored interrupts (level 1 through 7). The 68901 also provided a basic UART and (if memory serves) a periodic interrupt timer. The Motorola 68901 had a number of severe defects, including the ability to lose the highest-priority interrupt if it and the clock interrupt happened within some window of each other. The Mostek part was superior.
The fixed exception table was screamingly annoying for hardware designers.
One wants a ROM bootstrap, but then once the OS is up, one wants installable vectors.
A lot of effort went into circumventing the fixed vectors, either through trampolines (tables addressed to RAM) in ROM or through bank-switchable memory.
Another problem was the "privilege" logic. The designers had clearly planned on having a minimal, but adequate, two-tiered security system to support something like a UNIX kernel. This would limit the ability of user programs to access hardware and interrupts. The design had security holes, which were fixed in later processor models.
The 68000 was also unable to correctly return from an exception on a failing memory access, a crucial feature to enable true virtual memory. To simulate unlimited RAM, one wants to interrupt when a memory access fails, and then the interrupt routine will allocate a block of real RAM and read a piece of data on disk into it. Several companies did succeed in making 68000 based Unix workstations with virtual memory that worked, by using two 68000 chips running in parallel on different phased clocks. When the "leading" 68000 encountered a bad memory access, extra hardware would interrupt the "main" 68000 to prevent it from also encountering the bad memory access. This interrupt routine would handle the virtual memory functions and restart the "leading" 68000 in the correct state to continue properly synchronized operation when the "main" 68000 returned from the interrupt. Obviously this is an expensive, tricky, and very inconvenient technique, and they upgraded to the 68010 as quickly as possible.
A more subtle problem was that the 68000 could not easily run a virtual image of itself without simulating a large number of instructions. This problem persists in many modern versions of the architecture, which is rarely used in these applications. This lack caused the later versions of the Intel 80386 to win designs in avionic control, where software reliability was achieved by executing software virtual machines.
In the next major revision, the 68010, most of these problems were fixed.
Instruction set details
The standard address modes were:
- Register direct
- data register, e.g. "D0"
- address register, e.g. "A6"
- Register indirect
- Simple address, e.g. (A0)
- Address with post-increment, e.g. (A0)+
- Address with pre-decrement, e.g. -(A0)
- Address with a 16-bit signed offset, e.g. 16(A0)
- Note that the actual increment or decrement size was dependent on the operand request: a byte read instruction incremented the address register by 1, a word read by 2, and a long read by 4.
- Register indirect with an Index
- 8-bit signed offset, e.g. 8(A0, D0) or 8(A0, A1)
- PC (program counter) relative with displacement
- 16-bit signed offset, e.g. 16(PC). This mode was very useful.
- 8-bit signed offset with index, e.g. 8(PC, D2)
- Absolute memory location
- Either a numer, e.g. "$4000", or a symbolic name translated by the assembler
- Most 68000 assemblers used the "$" symbol for hexadecimal, instead of "0x".
- Immediate mode
- Stored in the instruction, e.g. "#400".
Plus: access to the status register, and, in later models, other special registers.
Most instructions had dot-letter suffixes, permitting operations to occur on 8-bit bytes (".b"), 16-bit words (".w"), and 32-bit longs (".l").
Most instructions are dyadic, that is, the operation has a source, and a destination, and the destination is changed. Notable instructions were:
- Arithmetic: ADD, SUB, MULU (unsigned multiply), MULS (signed multiply), DIVU, DIVS, NEG (additive negation), and CMP (a sort of subtract that set the status bits, but did not store the result)
- Binary Coded Decimal Arithmetic: ABCD, and SBCD
- Logic: EOR (exclusive or), AND, NOT (logical not)
- Shifting: (logical, i.e. right shifts put zero in the most significant bit) LSL, LSR, (arithmetic shifts, i.e. sign-extend the most significant bit) ASR, ASL, (Rotates through eXtend and not:) ROXL, ROXR, ROL, ROR
- Bit manipulation in memory: BSET (to 1), BCLR (to 0), and BTST (set the Zero bit)
- Multiprocessing control: TAS, test-and-set, performed an indivisible bus operation, permitting semaphores to be used to synchronize several processors sharing a single memory
- Flow of control: JMP (jump), JSR (jump to subroutine), BSR (relative address jump to subroutine), RTS (return from subroutine), RTE (return from exception, i.e. an interrupt), TRAP (trigger a software exception similar to software interrupt), (CHK a conditional software exception)
- Decision: Bcc (a branch where the "cc" specified one of 16 tests of the condition codes in the status register: equal, greater than, less-than, cary, and most combinations and logical inversions, available form the status register).