Linux Bible. Christopher Negus. Читать онлайн. Newlib. NEWLIB.NET

Автор: Christopher Negus
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Зарубежная компьютерная литература
Год издания: 0
isbn: 9781119578895
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we wanted to preserve was not just a good environment in which to do programming, but a system around which a fellowship could form. We knew from experience that the essence of communal computing as supplied by remote-access, time-shared machines is not just to type programs into a terminal instead of a keypunch, but to encourage close communication.

      The simplicity and power of the UNIX design began breaking down barriers that, until this point, had impeded software developers. The foundation of UNIX was set with several key elements:

       The UNIX filesystem: Because it included a structure that allowed levels of subdirectories (which, for today's desktop users, look like folders inside of folders), UNIX could be used to organize the files and directories in intuitive ways. Furthermore, complex methods of accessing disks, tapes, and other devices were greatly simplified by representing those devices as individual device files that you could also access as items in a directory.

       Input/output redirection: Early UNIX systems also included input redirection and pipes. From a command line, UNIX users could direct the output of a command to a file using a right-arrow key (>). Later, the concept of pipes (|) was added where the output of one command could be directed to the input of another command. For example, the following command line concatenates (cat) file1 and file2, sorts (sort) the lines in those files alphabetically, paginates the sorted text for printing (pr), and directs the output to the computer's default printer (lpr): $ cat file1 file2 | sort | pr | lprThis method of directing input and output enabled developers to create their own specialized utilities that could be joined with existing utilities. This modularity made it possible for lots of code to be developed by lots of different people. A user could just put together the pieces they needed.

       Portability: Simplifying the experience of using UNIX also led to it becoming extraordinarily portable to run on different computer hardware. By having device drivers (represented by files in the filesystem tree), UNIX could present an interface to applications in such a way that the programs didn't have to know about the details of the underlying hardware. To port UNIX later to another system, developers had only to change the drivers. The application programs didn't have to change for different hardware!

      To make portability a reality, however, a high-level programming language was needed to implement the software needed. To that end, Brian Kernighan and Dennis Ritchie created the C programming language. In 1973, UNIX was rewritten in C. Today, C is still the primary language used to create the UNIX (and Linux) operating system kernels.

      As Ritchie went on to say in a 1979 lecture (https://www.bell-labs.com/usr/dmr/www/hist.html):

      Today, the only important UNIX program still written in assembler is the assembler itself; virtually all the utility programs are in C, and so are most of the application's programs, although there are sites with many in Fortran, Pascal, and Algol 68 as well. It seems certain that much of the success of UNIX follows from the readability, modifiability, and portability of its software that in turn follows from its expression in high-level languages.

      If you are a Linux enthusiast and are interested in what features from the early days of Linux have survived, an interesting read is Dennis Ritchie's reprint of the first UNIX programmer's manual (dated November 3, 1971). You can find it at Dennis Ritchie's website: https://www.bell-labs.com/usr/dmr/www/1stEdman.html. The form of this documentation is UNIX man pages, which is still the primary format for documenting UNIX and Linux operating system commands and programming tools today.

      What's clear as you read through the early documentation and accounts of the UNIX system is that the development was a free-flowing process, lacked ego, and was dedicated to making UNIX excellent. This process led to a sharing of code (both inside and outside of Bell Labs), which allowed rapid development of a high-quality UNIX operating system. It also led to an operating system that AT&T would find difficult to reel back in later.

      Commercial UNIX

      Before the AT&T divestiture in 1984, when it was split up into AT&T and seven “Baby Bell” companies, AT&T was forbidden to sell computer systems. Companies that would later become Verizon, Qwest, Nokia, and Alcatel-Lucent were all part of AT&T. As a result of AT&T's monopoly of the telephone system, the US government was concerned that an unrestricted AT&T might dominate the fledgling computer industry.

      Because AT&T was restricted from selling computers directly to customers before its divestiture, UNIX source code was licensed to universities for a nominal fee. This allowed UNIX installations to grow in size and mindshare among top universities. However, there was still no UNIX operating system for sale from AT&T that you didn't have to compile yourself.

      Berkeley Software Distribution arrives

      For most of the next decade, the BSD and Bell Labs versions of UNIX headed off in separate directions. BSD continued forward in the free-flowing, share-the-code manner that was the hallmark of the early Bell Labs UNIX, whereas AT&T started steering UNIX toward commercialization. With the formation of a separate UNIX Laboratory, which moved out of Murray Hill and down the road to Summit, New Jersey, AT&T began its attempts to commercialize UNIX. By 1984, divestiture was behind AT&T and it was really ready to start selling UNIX.

      UNIX Laboratory and commercialization

      The UNIX Laboratory was considered a jewel that couldn't quite find a home or a way to make a profit. As it moved between Bell Laboratories and other areas of AT&T, its name changed several times. It is probably best remembered by the name it had as it began its spin-off from AT&T: UNIX System Laboratories (USL).

      The UNIX source code that came out of USL, the legacy of which was sold in part to Santa Cruz Operation (SCO), was used for a time as the basis for ever-dwindling lawsuits by SCO against major Linux vendors (such as IBM and Red Hat, Inc.). Because of that, I think the efforts from USL that have contributed to the success of Linux are lost on most people.

      During the 1980s, of course, many computer companies were afraid that a newly divested AT&T would pose more of a threat to controlling the computer industry than would an upstart company in Redmond, Washington. To calm the fears of IBM, Intel, Digital Equipment Corporation, and other computer companies, the UNIX Lab made the following commitments to ensure a level playing field:

       Source code only: Instead of producing its own boxed set of UNIX, AT&T continued to sell source code only and to make it available equally to all licensees. Each company would then port UNIX to its own equipment. It wasn't until about 1992, when the lab was spun off as a joint venture with Novell (called Univel), and then eventually sold to Novell, that a commercial boxed set of UNIX (called UnixWare) was produced directly from that source code.

       Published interfaces: To create an environment of fairness and community to its OEMs (original equipment manufacturers), AT&T began standardizing what different ports of UNIX had to be able to do to still be called UNIX. To that end, Portable Operating System Interface (POSIX) standards and the AT&T UNIX System V Interface Definition (SVID) were specifications UNIX vendors could use to create compliant UNIX systems. Those same documents also served as road maps for the creation of Linux.NOTEIn an early email newsgroup post, Linus Torvalds made a request for a copy, preferably online, of the POSIX standard. I think that no one from AT&T expected someone actually to be able to write their own clone of UNIX from those interfaces without using any of its UNIX source code.

       Technical approach: Again, until the very end of USL, most decisions on the direction of UNIX were made based on technical considerations. Management was promoted up through the technical ranks, and to my knowledge there was never any talk of writing software to break other companies' software or otherwise restrict the success of USL's partners.

      When