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Τι (ποιος) είναι Z8000 - ορισμός

16-BIT MICROPROCESSOR

Z8000; Z8001; Zilog Z16C01; Zilog Z8001; Zilog Z8002; Zilog Z-8000; U8000; Zilog Enhanced UNIX System; Zilog ZEUS; ZEUS (Zilog); ZEUS (Unix); Zilog System 8000 UNIX

Z8000

Zilog Z8000

Zilog Z8000

<processor> A microprocessor from Zilog introduced not long after the Intel 8086, but with superior features. It was basically a 16-bit processor, but could address up to 23 bits in some versions by using segment registers (to supply the upper 7 bits). There was also an unsegmented version, but both could be extended further with an additional MMU that used 64 segment registers. Internally, the Z8000 had sixteen 16-bit registers, but register size and use were exceedingly flexible. The Z-8000 registers could be used as sixteen 8-bit registers (only the first half were used like this), sixteen 16-bit registers, eight 32-bit registers, or four 64-bit registers, and included 32-bit multiply and divide. They were all general purpose registers - the stack pointer was typically register 15, with register 14 holding the stack segment (both accessed as one 32-bit register for painless address calculations). The Z8000 featured two modes, one for the operating system and one for user programs. The user mode prevented the user from messing about with interrupt handling and other potentially dangerous stuff. Finally, like the Zilog Z80, the Z8000 featured automatic DRAM refresh circuitry. Unfortunately it was somewhat slow, but the features generally made up for that. Initial bugs also hindered its acceptance (partly because it did not use microcode). There was a radiation resistant military version. There was a later 32-bit, pipelined version, the {Zilog Z80000}. (1997-12-16)

Source-to-source compiler

COMPILER THAT TRANSLATES SOURCE CODE TO AN EQUIVALENT VERSION IN A DIFFERENT PROGRAMMING LANGUAGE THAT OPERATE AT A SIMILAR LEVEL OF ABSTRACTION

Transcompiler; Source-to-source translator; Transpiler; Source code translator; Transcompilation; Transpile; Transcompile; Transpiling; Trans-compiled; Trans-compiles; TRANS.COM; TRANS (command); XLT86; XLAT86; Source to source compilation; Source to source compiler; Source-to-source compilation; Source-to-source compilers; Source to source translator; Trans-compiling; Transcompiling; Transcompiled; JavaScript source map; JS source maps; JS source map; JavaScript source maps; Recursive transcompiling; Recursive Transcompiling; Transpilation; TRANS86; Digital Research XLT86; DR XLT86; DRI XLT86; Sorcim TRANS86; CONVERT 86; Intel CONVERT 86; SCP TRANS; Seattle Computer Products TRANS; Microsoft TRANS; SCP TRANS86; Seattle Computer Products TRANS86; Microsoft TRANS86; Source to Source Compiler; S2S compiler; XLT86.COM; Assembly language translator; Trans-86; XLT-86; CONV86; Intel CONV86; CONV-86; Intel CONV-86; Source-level translation; Source-code translator; Assembly-language translation tool; Assembly-language translation; Assembly-language translator; Source-code translation; Source-level translation tool; Source-level translator; Assembly code translator; Assembly Translator; Assembly translator; Source to Source Translator; Source to Source Converter; Source to source converter; Source-to-source converter; Source-to-source translation; Source-to-source conversion; Source to source conversion; ST MIGR2ST7; Migr2st7; MIGR2ST7; MIGR2ST7.EXE; XLT86 1.0; TRANS-86; Translate-86; XLT 86; Convert 86; Intel Convert 86; Sorcim Trans; Assembly language program translation; Assembly Language Program Translation; Source level translator; XLT86 1.1; Z80 to 8086 translator; 8080 to 8086 translator; Z80 to Z8000 translator; 8085 to 8086 translator; TRANS 2.21; 2500 AD Software TRANS; 2500 A.D. Software TRANS; A.D. Software TRANS; AD Software TRANS; 2500 AD Software XASM; 2500 A.D. Software XASM; A.D. Software XASM; AD Software XASM; HC05 to ST7 translator; 68HC05 to ST7 translator; 6805 to ST7 translator; Assembly source translator; Assembly language translation; Transpiled; Transpilable language; 8088ify; 8088IFY; To86.awk; To86; Toz80.awk; Toz80

A source-to-source translator, source-to-source compiler (S2S compiler), transcompiler, or transpiler is a type of translator that takes the source code of a program written in a programming language as its input and produces an equivalent source code in the same or a different programming language. A source-to-source translator converts between programming languages that operate at approximately the same level of abstraction, while a traditional compiler translates from a higher level programming language to a lower level programming language.

https://en.wikipedia.org/wiki/Source-to-source_compiler

Βικιπαίδεια

Zilog Z8000

The Z8000 ("zee- or zed-eight-thousand") is a 16-bit microprocessor introduced by Zilog in early 1979. The architecture was designed by Bernard Peuto while the logic and physical implementation was done by Masatoshi Shima, assisted by a small group of people. In contrast to most designs of the era, the Z8000 did not use microcode which allowed it to be implemented in only 17,500 transistors.

The Z8000 was not Z80-compatible, although it featured many of the well-received design notes that made the Z80 popular. Among these was the ability for its registers to be combined and used as a single larger register - while the Z80 allowed two 8-bit registers to be used as a single 16-bit register, the Z8000 expanded this by allowing two 16-bit registers to operate as a 32-bit register, or four to operate as a 64-bit register. These combined registers were particularly useful for mathematical operations.

Although it was an attractive design for its era, and saw some use in the early 1980s, it was never as popular as the Z80. It was released after the 16-bit Intel 8086 (April 1978) and the same time as the less-expensive Intel 8088, and only months before the Motorola 68000 (September 1979), which had a 32-bit instruction set architecture and was roughly twice as fast.

The Zilog Z80000 was a 32-bit follow-on design, launched in 1986.

https://en.wikipedia.org/wiki/Zilog Z8000