The CDC Cyber range of mainframe-class supercomputers were the primary products of Control Data Corporation (CDC) during the 1970s and 1980s. In their day, they were the computer architecture of choice for scientific and mathematically intensive computing. They were used for modeling fluid flow, material science stress analysis, electrochemical machining analysis, probabilistic analysis, energy and academic computing, radiation shielding modeling, and other applications. The lineup also included the Cyber 18 and Cyber 1000 minicomputers. Like their predecessor, the CDC 6600, they were unusual in using the ones' complement binary representation.
The Cyber line included five different series of computers:
- The 70 and 170 series based on the architecture of the CDC 6600 and CDC 7600 supercomputers, respectively
- The 200 series based on the CDC STAR-100 - released in the 1970s.
- The 180 series developed by a team in Canada - released in the 1980s (after the 200 series)
- The Cyberplus or Advanced Flexible Processor (AFP)
- The Cyber 18 minicomputer based on the CDC 1700
Primarily aimed at large office applications instead of the traditional supercomputer tasks, some of the Cyber machines nevertheless included basic vector instructions for added performance in traditional CDC roles.
Cyber 70 and 170 series
The Cyber 70 and 170 architectures were successors to the earlier CDC 6600 and CDC 7600 series and therefore shared almost all of the earlier architecture's characteristics. The Cyber-70 series is a minor upgrade from the earlier systems. The Cyber-170 series represented CDCs move from discrete electronic components and core memory to integrated circuits and semiconductor memory. The 172, 173, and 174 use integrated circuits and semiconductor memory whereas the 175 uses high-speed discrete transistors. The Cyber-170/700 series is a late-1970s refresh of the Cyber-170 line.
The central processor (CPU) and central memory (CM) operated in units of 60-bit words. In CDC lingo, the term "byte" referred to 12-bit entities (which coincided with the word size used by the peripheral processors). Characters were six bits, operation codes were six bits, and central memory addresses were 18 bits. Central processor instructions were either 15 bits or 30 bits. The 18-bit addressing inherent to the Cyber 170 series imposed a limit of 262,144 (256K) words of main memory, which is semiconductor memory in this series. The central processor has no I/O instructions, relying upon the peripheral processor (PP) units to do I/O.
A Cyber 170-series system consists of one or two CPUs that run at either 25 or 40 MHz, and is equipped with 10, 14, 17, or 20 peripheral processors (PP), and up to 24 high-performance channels for high-speed I/O. Due to the relatively slow memory reference times of the CPU (in some models, memory reference instructions were slower than floating-point divides), the higher-end CPUs (e.g., Cyber-74, Cyber-76, Cyber-175, and Cyber-176) are equipped with eight or twelve words of high-speed memory used as an instruction cache. Any loop that fit into the cache (which is usually called in-stack) runs very fast, without referencing main memory for instruction fetch. The lower-end models do not contain an instruction stack. However, since up to four instructions are packed into each 60-bit word, some degree of prefetching is inherent in the design.
As with predecessor systems, the Cyber 170 series has eight 18-bit address registers (A0 through A7), eight 18-bit index registers (B0 through B7), and eight 60-bit operand registers (X0 through X7). Seven of the A registers are tied to their corresponding X register. Setting A1 through A5 reads that address and fetches it into the corresponding X1 through X5 register. Likewise, setting register A6 or A7 writes the corresponding X6 or X7 register to central memory at the address written to the A register. A0 is effectively a scratch register.
The higher-end CPUs consisted of multiple functional units (e.g., shift, increment, floating add) which allowed some degree of parallel execution of instructions. This parallelism allows assembly programmers to minimize the effects of the system's slow memory fetch time by pre-fetching data from central memory well before that data is needed. By interleaving independent instructions between the memory fetch instruction and the instructions manipulating the fetched operand, the time occupied by the memory fetch can be used for other computation. With this technique, coupled with the handcrafting of tight loops that fit within the instruction stack, a skilled Cyber assembly programmer can write extremely efficient code that makes the most of the power of the hardware.
The peripheral processor subsystem uses a technique known as barrel and slot to share the execution unit; each PP had its own memory and registers, but the processor (the slot) itself executed one instruction from each PP in turn (the barrel). This is a crude form of hardware multiprogramming. The peripheral processors have 4096 bytes of 12-bit memory words and an 18-bit accumulator register. Each PP has access to all I/O channels and all of the system's central memory (CM) in addition to the PP's own memory. The PP instruction set lacks, for example, extensive arithmetic capabilities and does not run user code; the peripheral processor subsystem's purpose is to process I/O and thereby free the more powerful central processor unit(s) to running user computations.
A feature of the lower Cyber CPUs is the Compare Move Unit (CMU). It provides four additional instructions intended to aid text processing applications. In an unusual departure from the rest of the 15- and 30-bit instructions, these are 60-bit instructions (three actually use all 60 bits, the other use 30 bits, but its alignment requires 60 bits to be used). The instructions are: move a short string, move a long string, compare strings, and compare a collated string. They operate on six-bit fields (numbered 1 through 10) in central memory. For example, a single instruction can specify "move the 72 character string starting at word 1000 character 3 to location 2000 character 9". The CMU hardware is not included in the higher-end Cyber CPUs, because handcoded loops could run as fast or faster than the CMU instructions.
Later systems typically run CDC's NOS (Network Operating System). Version 1 of NOS continued to be updated until about 1981; NOS version 2 was released early 1982. Besides NOS, the only other operating systems commonly used on the 170 series was NOS/BE or its predecessor SCOPE, a product of CDC's Sunnyvale division. These operating systems provide time-sharing of batch and interactive applications. The predecessor to NOS was Kronos which was in common use up until 1975 or so. Due to the strong dependency of developed applications on the particular installation's character set, many installations chose to run the older operating systems rather than convert their applications. Other installations would patch newer versions of the operating system to use the older character set to maintain application compatibility.
Cyber 180 series
Cyber 180 development began in the Advanced Systems Laboratory, a joint CDC/NCR development venture started in 1973 and located in Escondido, California. The machine family was originally called Integrated Product Line (IPL) and was intended to be a virtual memory replacement for the NCR 6150 and CDC Cyber 70 product lines. The IPL system was also called the Cyber 80 in development documents. The Software Writer's Language (SWL), a high-level Pascal-like language, was developed for the project with the intent that all languages and the operating system (IPLOS) were going to be written in SWL. SWL was later renamed PASCAL-X and eventually became Cybil. The joint venture was abandoned in 1976, with CDC continuing system development and renaming the Cyber 80 as Cyber 180. The first machines of the series were announced in 1982 and the product announcement for the NOS/VE operating system occurred in 1983.
As the computing world standardized to an eight-bit byte size, CDC customers started pushing for the Cyber machines to do the same. The result was a new series of systems that could operate in both 60- and 64-bit modes. The 64-bit operating system was called NOS/VE, and supported the virtual memory capabilities of the hardware. The older 60-bit operating systems, NOS and NOS/BE, could run in a special address space for compatibility with the older systems.
The true 180-mode machines are microcoded processors that can support both instruction sets simultaneously. Their hardware is completely different from the earlier 6000/70/170 machines. The small 170-mode exchange package was mapped into the much larger 180-mode exchange package; within the 180-mode exchange package, there is a virtual machine identifier (VMID) that determines whether the 8/16/64-bit two's complement 180 instruction set or the 12/60-bit one's complement 170 instruction set is executed.
There were three true 180s in the initial lineup, codenamed P1, P2, P3. P2 and P3 were larger water-cooled designs. The P2 was designed in Mississauga, Ontario, by the same team that later designed the smaller P1, and the P3 was designed in Arden Hills, Minnesota. The P1 was a novel air-cooled, 60-board cabinet designed by a group in Mississauga; the P1 ran on 60 Hz current (no motor-generator sets needed). A fourth high-end 180 model 990 (codenamed THETA) was also under development in Arden Hills.
The 180s were initially marketed as 170/8xx machines with no mention of the new 8/64-bit system inside. However, the primary control program is a 180-mode program known as Environmental Interface (EI). The 170 operating system (NOS) used a single, large, fixed page within the main memory. There were a few clues that an alert user could pick up on, such as the "building page tables" message that flashed on the operator's console at startup and deadstart panels with 16 (instead of 12) toggle switches per PP word on the P2 and P3.
The peripheral processors in the true 180s are always 16-bit machines with the sign bit determining whether a 16/64 bit or 12/60 bit PP instruction is being executed. The single word I/O instructions in the PPs are always 16-bit instructions, so at deadstart the PPs can set up the proper environment to run both EI plus NOS and the customer's existing 170-mode software. To hide this process from the customer, earlier in the 1980s CDC had ceased distribution of the source code for its Deadstart Diagnostic Sequence (DDS) package and turned it into the proprietary Common Tests & Initialization (CTI) package.
The initial 170/800 lineup was: 170/825 (P1), 170/835 (P2), 170/855 (P3), 170/865 and 170/875. The 825 was released initially after some delay loops had been added to its microcode; it seemed the design folks in Toronto had done a little too well and it was too close to the P2 in performance. The 865 and 875 models were revamped 170/760 heads (one or two processors with 6600/7600-style parallel functional units) with larger memories. The 865 used normal 170 memory; the 875 took its faster main processor memory from the Cyber 205 line.
A year or two after the initial release, CDC announced the 800-series' true capabilities to its customers, and the true 180s were relabeled as the 180/825 (P1), 180/835 (P2), and 180/855 (P3). At some point, the model 815 was introduced with the delayed microcode and the faster microcode was restored to the model 825. Eventually the THETA was released as the Cyber 990.
Cyber 200 series
In 1974 CDC introduced the STAR architecture. The STAR is an entirely new 64-bit design with virtual memory and vector processing instructions added for high performance on a certain class of math tasks. The STAR's vector pipeline is a memory to memory pipe, which supports vector lengths of up to 65,536 elements. Unfortunately, the latencies of the vector pipeline are very long, so peak speed is approached only when very long vectors are used. The scalar processor was deliberately simplified to provide room for the vector processor and is relatively slow in comparison to the CDC 7600. As such, the original STAR proved to be a great disappointment when it was released (see Amdahl's Law). Best estimates claim that three STAR-100 systems were delivered.
It appeared that all of the problems in the STAR were solvable. In the late 1970s, CDC addressed some of these issues with the Cyber 203. The new name kept with their new branding, and perhaps to distance itself from the STAR's failure. The Cyber 203 contains redesigned scalar processing and loosely coupled I/O design,[a] but retains the STAR's vector pipeline. Best estimates claim that two Cyber 203s were delivered or upgraded from STAR-100s.
In 1980, the successor to the Cyber 203, the Cyber 205 was announced. The UK Meteorological Office at Bracknell, England was the first customer and they received their Cyber 205 in 1981. The Cyber 205 replaces the STAR vector pipeline with redesigned vector pipelines: both scalar and vector units utilized ECL gate array ICs and are cooled with Freon. Cyber 205 systems were available with two or four vector pipelines, with the four-pipe version theoretically delivering 400 64-bit MFLOPs and 800 32-bit MFLOPs. These speeds are rarely seen in practice other than by handcrafted assembly language. The ECL gate array ICs contain 168 logic gates each, with the clock tree networks being tuned by hand-crafted coax length adjustment. The instruction set would be considered V-CISC (very complex instruction set) among modern processors. Many specialized operations facilitate hardware searches, matrix mathematics, and special instructions that enable decryption.
The original Cyber 205 was renamed to Cyber 205 Series 400 in 1983 when the Cyber 205 Series 600 was introduced. The Series 600 differs in memory technology and packaging but is otherwise the same. A single four-pipe Cyber 205 was installed. All other sites appear to be two-pipe installations with final count to be determined.
The Cyber 205 architecture evolved into the ETA10 as the design team spun off into ETA Systems in September 1983. A final development was the Cyber 250, which was scheduled for release in 1987 priced at $20 million; it was later renamed the ETA30 after ETA Systems was absorbed back into CDC.
Cyberplus or Advanced Flexible Processor (AFP)
Each Cyberplus (aka Advanced Flexible Processor, AFP) is a 16-bit processor with optional 64-bit floating point capabilities and has 256 K or 512 K words of 64-bit memory. The AFP was the successor to the Flexible Processor (FP), whose design development started in 1972 under black-project circumstances targeted at processing radar and photo image data. The FP control unit had a hardware network for conditional microinstruction execution, with four mask registers and a condition-hold register; three bits in the microinstruction format select among nearly 50 conditions for determining execution, including result sign and overflow, I/O conditions, and loop control.
At least 21 Cyberplus multiprocessor installations were operational in 1986. These parallel processing systems include from 1 to 256 Cyberplus processors providing 250 MFLOPS each, which are connected to an existing Cyber system via a direct memory interconnect architecture (MIA), this was available on NOS 2.2 for the Cyber 170/835, 845, 855 and 180/990 models.
Physically, each Cyberplus processor unit was of typical mainframe module size, similar to the Cyber 180 systems, with the exact width dependent on whether the optional FPU was installed, and weighed approximately 1 tonne.
- Software that was bundled with the Cyberplus was
- System software
- FORTRAN cross compiler
- MICA (Machine Instruction Cross Assembler)
- Load File Builder Utility
- ECHOS (simulator)
- Debug facility
- Dump utility
- Dump analyzer utility
- Maintenance software
Some sites using the Cyberplus were the University of Georgia and the Gesellschaft für Trendanalysen (GfTA) (Association for Trend Analyses) in Germany.
A fully configured 256 processor Cyberplus system would have a theoretical performance of 64 GFLOPS, and weigh around 256 tonnes. A nine-unit system was reputedly capable of performing comparative analysis (including pre-processing convolutions) on 1 megapixel images at a rate of one image pair per second.
The Cyber 18 is a 16-bit minicomputer which was a successor to the CDC 1700 minicomputer. It was mostly used in real-time environments. One noteworthy application is as the basis of the 2550—a communications processor used by CDC 6000 series and Cyber 70/Cyber 170 mainframes. The 2550 was a product of CDC's Communications Systems Division, in Santa Ana, California (STAOPS). STAOPS also produced another communication processor (CP), used in networks hosted by IBM mainframes. This M1000 CP, later renamed C1000, came from an acquisition of Marshall MDM Communications. A three-board set was added to the Cyber 18 to create the 2550.
The Cyber 18 was generally programmed in Pascal and assembly language; FORTRAN, BASIC, and RPG II were also available. Operating systems included RTOS (Real-Time Operating System), MSOS 5 (Mass Storage Operating System), and TIMESHARE 3 (time-sharing system).
"Cyber 18-17" was just a new name for the System 17, based on the 1784 processor. Other Cyber 18s (Cyber 18-05, 18-10, 18-20, and 18-30) had microprogrammable processors with up to 128K words of memory, four additional general registers, and an enhanced instruction set. The Cyber 18-30 had dual processors. A special version of the Cyber 18, known as the MP32, that was 32-bit instead of 16-bit was created for the National Security Agency for crypto-analysis work. The MP32 had the Fortran math runtime library package built into its microcode. The Soviet Union tried to buy several of these systems and they were being built when the U.S. Government cancelled the order. The parts for the MP32 were absorbed into the Cyber 18 production. One of the uses of the Cyber 18 was monitoring the Alaskan Pipeline.
The M1000 / C1000, later renamed Cyber 1000, was used as a message store and forward system used by the Federal Reserve System. A version of the Cyber 1000 with its hard drive removed was used by Bell Telephone. This was a RISC processor (Reduced Instruction Set Computer). An improved version known as the Cyber 1000-2 with the Line Termination Sub-System added 256 Zilog Z80 microprocessors. The Bell Operating Companies purchased large numbers of these systems in the mid to late 1980s for data communications. In the late 1980s the XN10 was released with an improved processor (a direct memory access instruction was added) as well as a size reduction from two cabinets to one. The XN20 was an improved version of the XN10 with a much smaller footprint. The Line Termination Sub-System was redesigned to use the improved Z180 microprocessor (the Buffer Controller card, Programmable Line Controller card and two Communication Line Interface cards were incorporated on to a single card). The XN20 was in pre-production stage when the Communication Systems Division was shut down in 1992.
Jack Ralph was the chief architect of the Cyber 1000-2, XN-10 and XN-20 systems. Dan Nay was the chief engineer of the XN-20.
- CDC 6000 - contains several predecessors to the Cyber 70 series
- Compared to the tightly coupled I/O used on previous designs.
- "(search for Cyber terms)". IMA Journal of Applied Mathematics. Oxford University Press. Retrieved 2008-07-01.
- Rajani R. Joshi (9 June 1998). "A new heuristic algorithm for probabilistic optimization". Department of Mathematics and School of Biomedical Engineering, Indian Institute of Technology Powai, Bombay, India. doi:10.1016/S0305-0548(96)00056-1. Cite journal requires
|journal=(help) (requires subscription)
- Jeff Bauer (1991). "A History of Supercomputing at Florida State University". Retrieved 2008-07-01.
- "Abstract for SAMSY - Shielding Analysis Modular System". OECD Nuclear Energy Agency, Issy-les-Moulineaux, France. Retrieved 2008-07-01.
- Computerworld, November 19, 1975, p. 47
- Hockney, R. W.; Jesshope, C. R. (1988). Parallel Computers 2: Architecture, Programming and Algorithms. Philadelphia: Adam Hilger. pp. 155–185. ISBN 0852748116.
- Lincoln, N. R. (1982). "Technology and Design Tradeoffs in the Creation of a Modern Supercomputer". IEEE Trans. Comput. C-31 (5): 349–362. doi:10.1109/TC.1982.1676013.
- Allen, G. (1982). "A Reconfigurable Architecture for Arrays of Microprogrammable Processor". In Fu, K. S.; Ichikawa, Tadao (eds.). Special Computer Architectures for Pattern Processing. Boca Raton, Florida: CRC Press. pp. 157–189. ISBN 0849361001.
- Mark Smotherman (October 2009). "CDC Advanced Flexible Processor (AFP)".
- Ahrendt, Gunter. "Usenet post to "Re: 11! CDC/Cyberplus " thread, 24th December 1991". comp.sys.super. Google Groups. Retrieved 6 February 2014.