Engineering:Clipper architecture

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Short description: 32-bit RISC-like computing architecture
Clipper
Intergraph Clipper C4.jpg
Intergraph Clipper C4 (C400) CPU
Designer
Bits32-bit
Introduced1986
DesignRISC-like

The Clipper architecture is a 32-bit RISC-like instruction set architecture designed by Fairchild Semiconductor. The architecture never enjoyed much market success, and the only computer manufacturers to create major product lines using Clipper processors were Intergraph and High Level Hardware, although Opus Systems offered a product based on the Clipper as part of its Personal Mainframe range.[1] The first processors using the Clipper architecture were designed and sold by Fairchild, but the division responsible for them was subsequently sold to Intergraph in 1987; Intergraph continued work on Clipper processors for use in its own systems.[2]

The Clipper architecture used a simplified instruction set compared to earlier CISC architectures, but it did incorporate some more complicated instructions than were present in other contemporary RISC processors. These instructions were implemented in a so-called Macro Instruction ROM within the Clipper CPU. This scheme allowed the Clipper to have somewhat higher code density than other RISC CPUs.

Versions

Die of Clipper C100 CPU
Die of Clipper C300 CPU

The initial Clipper microprocessor produced by Fairchild was the C100, which became available in 1986. This was followed by the faster C300 from Intergraph in 1988. The final model of the Clipper was the C400, released in 1990, which was extensively redesigned to be faster and added more floating-point registers. The C400 processor combined two key architectural techniques to achieve a new level of performance — superscalar instruction dispatch and superpipelined operation.

While many processors of the time used either superscalar instruction dispatch or superpipelined operation, the Clipper C400 was the first processor to use both.[3]

Intergraph started work on a subsequent Clipper processor design known as the C5, but this was never completed or released. Nonetheless, some advanced processor design techniques were devised for the C5, and Intergraph was granted patents on these. These patents, along with the original Clipper patents, have been the basis of patent-infringement lawsuits by Intergraph against Intel and other companies.[4]

Die of Clipper C300 CAMMU

Unlike many other microprocessors, the Clipper processors were actually sets of several distinct chips. The C100 and C300 consist of three chips: one central processing unit containing both an integer unit and a floating point unit, and two cache and memory management units (CAMMUs), one responsible for data and one for instructions. The CAMMUs contained caches, translation lookaside buffers, and support for memory protection and virtual memory. The C400 consists of four basic units: an integer CPU, an FPU, an MMU, and a cache unit. The initial version used one chip each for the CPU and FPU and discrete elements for the MMU and cache unit, but in later versions the MMU and cache unit were combined into one CAMMU chip.

Registers and instruction set

The Clipper has 16 integer registers (R15 is used as the stack pointer), 16 floating-point registers (limited to 8 in early implementations), plus a program counter (PC), a processor status word (PSW) containing ALU and FPU status flags and trap enables, and a system status word (SSW) containing external interrupt enable, user/supervisor mode, and address translation control bits.

User and supervisor modes has separate banks of integer registers. Interrupt handling consisted of saving the PC, PSW, and SSW on the stack, clearing the PSW, and loading the PC and SSW from a memory trap vector.

The Clipper is a load/store architecture, where arithmetic operations could only specify register or immediate operands. The basic instruction "parcel" is 16 bits: 8 bits of opcode, 4 bits of source register, and 4 bits of destination register. Immediate-operand forms allow 1 or 2 following instruction parcels to specify a 16-bit (sign-extended) or 32-bit immediate operand. The processor is uniformly little-endian, including immediate operands.

A special "quick" encoding with a 4-bit unsigned operand is provided for add, subtract, load (move quick to register), and not (move complement of quick to register).

Addressing modes for load/store and branch instructions are as follows. All displacements are sign-extended.

  • (Rn), d12(Rn), d32(Rn): Register relative with 0, 12- or 32-bit displacement
  • d16(PC), d32(PC): PC-relative
  • d16, d32: absolute
  • [Rx](Rn), [Rx](PC): Register or PC-relative indexed. The index register is not scaled.

In addition to the usual logical and arithmetic operations, the processor supports:

  • 32×32→32-bit multiply, divide, and remainder (signed and unsigned)
  • 64-bit shifts and rotates, operating on even/odd register pairs
  • 32×32→64-bit extended multiplies
  • Integer register push/pop (store with pre-decrement, load with post-increment)
  • Subroutine call (push PC, move address of operand to PC)
  • Return from subroutine (pop PC from stack)
  • Atomic memory load and set msbit
  • Supervisor trap

More complex macro instructions allow:

  • Push/pop multiple integer registers Rn–R14
  • Push/pop multiple floating-point registers Dn–D7
  • Push/pop user registers R0–R15
  • Return from interrupt (pop SSW, PSW and PC)
  • Initialize string of bytes (store R0 copies of R2 in memory starting at R1)
  • Move characters and compare characters (length in R0, source in R1, destination in R2)

Most instructions allow an arbitrary stack pointer register to be specified, but except for the user register save/restore, the multiple-register operations can use only R15.

Intergraph's Clipper systems

Photograph of an Intergraph CLIX workstation

Intergraph sold several generations of Clipper systems, including both servers and workstations. These systems included the InterAct, InterServe, and InterPro product lines and were targeted largely at the CAD market.

Fairchild promoted the CLIX operating system, a version of UNIX System V, for use with the Clipper. Intergraph adopted CLIX for its Clipper-based systems and continued to develop it; this was the only operating system available for those systems. Intergraph did work on a version of Microsoft Windows NT for Clipper systems and publicly demonstrated it, but this effort was canceled before release.[5] Intergraph decided to discontinue the Clipper line and began selling x86 systems with Windows NT instead.

References

  1. "Opus Systems Unveils Series 300 Unix Workstations". Computerworld: 41. 4 March 1987. https://archive.org/details/sim_computerworld_1987-03-04_21_9a/page/n50/mode/1up. Retrieved 23 June 2022. 
  2. Weisberg, David (2008). "The Engineering Design Revolution: The People, Companies and Computer Systems That Changed Forever the Practice of Engineering" (in English). Chapter 14. http://cadhistory.net/14%20Intergraph.pdf. 
  3. The CPU collection. "Intergraph Clipper C4".
  4. Flynn, Laurie (31 March 2004). "Intergraph And Intel Settle Chip Dispute" (in English). https://www.nytimes.com/2004/03/31/business/technology-intergraph-and-intel-settle-chip-dispute.html. 
  5. Simpson, Nik (January 15, 2000). "Re: Intergraph Interact 340". Newsgroupcomp.sys.intergraph. Usenet: Sg0g4.34$Ek.5695@newsin1.ispchannel.com.