Difference between revisions of "Whirlwind"
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'''Whirlwind''' was one of the very first computers; it was enormously influential, for several reasons. It was the first [[real-time]] computer, unlike all the other first-generation computers, which were intended only for large-scale computations for numerical [[application]]s. It was also the first computer with [[core memory]], which was invented for it (some time after it had first come into service; it initially used [[Williams tube|electrostatic]] [[vacuum tube]] [[main memory]]). | '''Whirlwind''' was one of the very first computers; it was enormously influential, for several reasons. It was the first [[real-time]] computer, unlike all the other first-generation computers, which were intended only for large-scale computations for numerical [[application]]s. It was also the first computer with [[core memory]], which was invented for it (some time after it had first come into service; it initially used [[Williams tube|electrostatic]] [[vacuum tube]] [[main memory]]). | ||
| − | Whirlwind was built at [[MIT]] (MIT's first computer), originally for use in a flight simulator, but wound up being used to prototype the [[SAGE]] air defence system. | + | Whirlwind was built at [[Massachusetts Institute of Technology|MIT]] (MIT's first computer), originally for use in a flight simulator, but wound up being used to prototype the [[SAGE]] air defence system. |
| − | It was built out of vacuum tubes, and had a [[word]] size of 16 bits. It used a predecessor to [[microcode]] for internal control [[logic]] (it used a sequence of hard-wired control words for control, effectively [[read-only memory|ROM]], but did not include any ability to alter the order of execution thereof.) | + | It was built out of vacuum tubes, and had a [[word]] size of 16 bits. It used a predecessor to [[microcode]] for internal control [[logic]] (it used a sequence of hard-wired control words for control, effectively [[read-only memory|ROM]], but did not include any ability to alter the order of [[execute|execution]] thereof.) |
[[Instruction]]s included a 12-bit [[absolute address]]; when its [[main memory]] later exceeded that size, a [[bank switching]] mechanism had to be added. It had only a single [[register|accumulator]], and no [[index register]]s. | [[Instruction]]s included a 12-bit [[absolute address]]; when its [[main memory]] later exceeded that size, a [[bank switching]] mechanism had to be added. It had only a single [[register|accumulator]], and no [[index register]]s. | ||
Latest revision as of 16:56, 9 April 2025
Whirlwind was one of the very first computers; it was enormously influential, for several reasons. It was the first real-time computer, unlike all the other first-generation computers, which were intended only for large-scale computations for numerical applications. It was also the first computer with core memory, which was invented for it (some time after it had first come into service; it initially used electrostatic vacuum tube main memory).
Whirlwind was built at MIT (MIT's first computer), originally for use in a flight simulator, but wound up being used to prototype the SAGE air defence system.
It was built out of vacuum tubes, and had a word size of 16 bits. It used a predecessor to microcode for internal control logic (it used a sequence of hard-wired control words for control, effectively ROM, but did not include any ability to alter the order of execution thereof.)
Instructions included a 12-bit absolute address; when its main memory later exceeded that size, a bank switching mechanism had to be added. It had only a single accumulator, and no index registers.
In common with other very early machines, its architecture was somewhat peculiar (by current standards). Its control flow capabilities were limited and primitive; it had conditional branching, but almost no support of any kind for subroutines (it did have a 'jump and save the old PC in the accumulator' instruction), and no provision for stacks. As a result of all that, extensive use was made of self-modifying code (including to return from a subroutine). It had neither interrupts or traps (but could be caused to halt on an arithmetic overflow).
The standard input/output device was a Flexowriter (very similar to a Teletype); it functioned as a printing terminal (initially only for output), and could also read and punch paper tapes. (A high-speed Ferranti photo-electric paper tape reader was also added later, as was a line printer.) Eventually, the system was enhanced with a magnetic tape drive and a drum. A vector video display and a light pen input pointing device were also added.
See also
Further reading
- Kent C. Redmond, Thomas M. Smith, Project Whirlwind: The History of a Computer Pioneer, Digital Press, Bedford, 1980
External links
- Bitsavers - large collection of material
- Whirlwind Programming Manual
- Whirlwind I Computer Block Diagrams
- Whirlwind I Operation Logic - good, detailed overview of the internal architecture
- Project Whirlwind - large collection of contemporary documents; e.g. bi-weekly progress reports
- MIT/CHM Whirlwind Software Recovery - Many links to other sites
- The Whirlwind Computer at CHM
- Gambling on Whirlwind: How the US Navy Spent $3M and got a Computer Game
- Computer-Aided Design’s Strong Roots at MIT - has a fair amount about Whirlwind
