IBM System/36

IBM 5360 System Unit
IBM 5362 System Unit

The IBM System/36 (often abbreviated as S/36) was a small computer system marketed by IBM from 1983 to 2000 - a multi-user, multi-tasking successor to the System/34.

Like the System/34 and the older System/32, the System/36 was primarily programmed in the RPG II language. One of the machine's more interesting optional features was an off-line storage mechanism (on the 5360 model) that utilized "magazines" – boxes of 8-inch floppies that the machine could load and eject in a nonsequential fashion. The System/36 also had many mainframe features such as programmable job queues and scheduling priority levels.

While these systems were similar to other manufacturer's minicomputers, IBM themselves described the System/32, System/34 and System/36 as "small systems"[1] and later as "midrange" computers along with the System/38 and succeeding AS/400 range.

Overview of the IBM System/36

Front of a 5363 prior to IPL

The IBM System/36 was a simple and popular small business computer system, first announced on 16 May 1983[2] and shipped later that year. It had a 17-year product lifespan.

The first model of the System/36 was the 5360. It weighed 700 lb (318 kg), cost (US) $100,000 and up, and is believed to have had processor speeds of about 2 MHz and 8 MHz for its two processors, which in 1983 was faster than the "Personal Computers" on the market. The 5362 weighed only 150 pounds (68 kg) and cost (US) $20,000.

In the 1970s, the US Department of Justice brought an antitrust lawsuit against IBM, claiming it was using unlawful practices to knock out competitors. At this time, IBM had been about to consolidate its entire line (System/370, 4300, System/32, System/34, System/38) into one "family" of computers with the same ISAM database technology, programming languages, and hardware architecture. But after the lawsuit was filed, IBM decided it would have two families: the System/38 line, intended for large companies and representing IBM's future direction, and the System/36 line, intended for small companies who had used the company's legacy System/32/34 computers.

The System/36 used virtually the same RPG II, SDA, OCL, and other technologies that the System/34 used, though it was object-code incompatible. Its original displays (at 24×80) were the most popular, and used the same basic screen size used on a number of computer terminals, such as the ADM-3A, VT52, and VT100. A 27×132 display was supported c.1987, but never quite caught on. The S/36 was a small business computer; it had an 8-inch diskette drive, between one and four hard drives in sizes of 30 to 716 MB, and memory from 128K up to 7MB. Tape drives were available as backup devices; the 6157 QIC (quarter-inch cartridge) and the reel-to-reel 8809 both had capacities of roughly 60MB. The Advanced/36 9402 tape drive, c.1994, had a capacity of 2.5GB.

The System/36 used a command-line environment, but it was simpler than the System/34 because of 100 or so menus that simplified the command process. Instead of typing "BLDLIBR MYLIB,100,30" to create a user program library, an operator could use menus to find the description "Create a user library" and fill in a form to accomplish the same goal. RPG II was modified from the System/3 days to allow access to the "WORKSTN file" to allow a punched card-based language to interact with a person sitting at a keyboard and monitor. A WORKSTN file was an output file (it wrote to the monitor) and also an input file (because it accepted the user's keyboard input). Thus it was labeled a combined-primary file or a combined-demand file.

Command keys became RPG indicators KA-KY, and different on-screen forms were recognized by different invisible control characters hidden in the forms themselves. Interestingly, since the user had to display a form on the screen in order to type, RPG II provided a way for a program to write output before accepting input. Many successful programmers moved from using the combined-primary WORKSTN file to using a combined-demand file, which had operation codes to read and write the display. There was even a way to code for multiple WORKSTNs; several people could sign on to the same copy of the same program in memory. The largest program size was 64k.

A company called Amalgamated Software of North America (ASNA) produced a third-party compiler for the System/36 in the late 1980s called 400RPG. Another company called BPS created a third-party pre-processor called RPG II-1/2. Both of these products allowed users to write RPG II programs with RPG III opcodes. ASNA also produced an improved file access algorithm called ACCELER8 and a program-canceling utility called TERMIN8. Other third-party companies produced RPG subroutines that greatly enhanced the abilities of RPG. There were at least 230 commercially available subroutines.

There were a few holdovers from the days of the System/32 (the "Bionic Desk" of 1975): the KEYBOARD, CONSOLE, and DISPLAY files which provided unformatted access to the monitor and keyboard. (CONSOLE came from the System/3 days). Clever System/36 programmers could use a KEYBOARD file to accept commands from the procedure (the "system input file") meaning that a program could be customized at run time without a recompilation.

// LOAD MYPROG
// FILE NAME-INPUT
// RUN
THIS IS CUSTOM DATA
SO IS THIS
/* (means end of data)

Features

The System/36 was flexible and powerful for its time:

Successor

In the late 1980s the US Department of Justice ended its case against IBM, and so IBM went forward with a system named the AS/400. The new system was a smaller and less-expensive S/38 with a more powerful database, and so was instantly popular among the 20,000 S/38 customers. But the company had trouble convincing the 300,000 S/34 and S/36 customers to migrate; people who paid $20k for their S/36 didn't want to pay $40k for the AS/400 even though IBM did offer a very easy migration path that could be handled by the customer themselves.

Terminals, displays, screens, workstations and monitors

At that time, the terms terminal, display, screen, workstation and monitor were used interchangeably to describe the same thing, although today only the first one is considered the appropriate one (other ones evolved to reflect other uses). Although not consistently in any manner, IBM preferred term at that moment was monitor.

An operator basically sat in front of this device that vaguely resembled today's PC, except the monitor was smaller, the device was more expensive (US$2,000), it featured a text-only (24×80) interface and the available colors for the screen were only green and bright green, although a seven-color IBM Color Monitors later became available. Some purists refer to a printer as one type of workstation.

5250 compatible terminals

By the mid-1980s, third-party companies have made compatible devices (based on what would become IBM 5250 standard, today mostly served by terminal emulators). Prices plummeted and new features appeared – for example, Decision Data terminals allowed operators to choose the seven colors from a 64-color palette; there was an optional time display; and setup was accomplished through onscreen menus rather than DIP switches.

IBM colors

Prior to 1984, the 5251 monitor predominated – it was US$2,000 and what IBM called "dual color" (green and white). However, by 1984, the IBM 3180 terminal helped usher in the grand new age of IBM Color – seven colors (pink, red, blue, yellow, green, white, and turquoise.) For those who wished to "keep it cheap" but eschew the omnipresent green, there were also amber and white selections as early as 1986. By 1984, the price of the 3180 terminals was under US$2,000, though there was a graphics-capable terminal that sold poorly.

Interestingly, programming colors did not require a new screen programming language, because the implementation was completely at the hardware level. A protocol called the IBM 5250 Data Stream interpreted field attributes such as blinking, non-display, high intensity, reverse image, underline, and column separators and was used in combination to create colors. Normal text was presented as green on a 3180 color terminal, but high intensity became white. Column separators became yellow. Blinking became red. Underlined text was presented as blue. High intensity blinking became pink. High intensity column separators became turquoise.

Unfortunately, extensive use of colors became confusing when using the less expensive dual-color terminals.

The five terminal lights

On a 5251 type terminal (aka "Concrete Block",) there were five lights to watch for:

(1) System Available light. If lit, this terminal is connected to the S/36 and is receiving information from it.

(2) Message Waiting light. Other users, and the system itself, can send messages to workstations. If lit, there is at least one message that has not been seen yet. When a program ends or when the user signs on, the message(s) will be shown.

(3) Insert. The Insert key has been pressed. Characters after the cursor will shift right when text is keyed. Press Insert again to cease Insert Mode.

(4) Caps Lock light. The Caps Lock key has been pressed. All keys pressed will be uppercase. Press Caps Lock again to unlock.

(5) Keyboard Shift light. The Shift key is being pressed. The key pressed simultaneously will be uppercase.

Keyboards

The standard US keyboard was heavy, clunky, featured 122 keys, and weighed approximately 10 pounds. (On the positive side it had a cent-sign key and a HELP key. The PRINT key did what it was supposed to do; it printed the screen.) There was a special terminal and keyboard for Katakana.

Printers

Typical System/36 installations would include one of these printers.:

Configuring devices

DIP switches

Early 1980s-era printers and workstations had a series of binary switches known as "DIP switches" for configuration. For example, U.S. English and UK English, where the British use the pound sterling ("£") and the Americans use the dollar ("$"). A switch could be set up on printers and monitors where in the zero position the British value would display or print. In the one position the American value would display or print.

Online setup

By the mid-1980s the DIP switches were gone and the status quo became online setup. The technical person would hold down a certain key while powering up the device. A "test mode" display would appear, and a menu option would allow the operator to choose the addresses for the devices. Sometimes an emulated terminal would have a PC-style printer port. Sometimes the emulation would allow you to configure as many as seven devices.

Setting the address

Up to 40 local devices could be configured on a System/36, using eight lines numbered from 0 to 7. A line was defined as a series of twinaxial cables attached to devices with IN and OUT ports. Three binary switches on every device were used for the terminal's address (the physical designation of a particular terminal on a particular line.) Two devices can not have the same address on the same line. Once the addresses were set, the system could be configured to use them. A workstation expansion gave you ports 8 through 15, and another 40 devices.

Auto-configure

The System/36 had a feature called auto-configure. This allowed configuration merely by setting the addresses on the devices, turning off the S/36, connecting the devices to the S/36, and restarting the S/36. The system would configure the devices, including assigning workstation IDs, and so forth.

Configuring using CNFIGSSP

The CNFIGSSP procedure was used to configure the system, including the devices. Each device is assigned a two-character ID. The first letter must be alphabetic; the second must be alphanumeric. The system also reserved certain IDs; you could not call your device I1 or F1, for example. I1 is the name of the diskette drive; F1 is what the system calls the hard drive (stands for "fixed disk," since it is not a removable disk pack.)

CNFIGSSP is used to place devices on the line/address map; identify the particular IBM printer or terminal model; assign characteristics such as console, alternate console, subconsole; and to name the printer's subconsole. To apply CNFIGSSP, the system must be dedicated (no other users logged on or programs running.) The system must then be IPLed (rebooted.) When IPL finishes, the newly configured devices will appear on the status display.

System architecture

Processors

S/36s had two sixteen-bit processors, the CSP or Control Storage Processor, and the MSP or Main Storage Processor. The MSP was the workhorse; it performed the instructions in the computer programs. The CSP was the governor; it performed system functions in the background. Special utility programs were able to make direct calls to the CSP to perform certain functions; these are usually system programs like $CNFIG which was used to configure the computer system. These two processors worked in tandem, and it's one reason the S/36 worked so well.

The primary purpose of the CSP was to keep the MSP busy; as such, it ran at slightly more than 4X the speed of the MSP. The first System/36 models (the 5360-A) had a 4 MHz CSP and a 1 MHz MSP. The CSP would load code and data into main storage behind the MSP's program counter. As the MSP was working on one process, the CSP was filling storage for the next process.

The 5360 processors came in four models, labeled 5360-A through 5360-D. The later "D" model was about 60 percent faster than the "A" model.

Front panel

The 5360, 5362, and 5363 processors had a front panel display with four hexadecimal LEDs. If the operator "dialed up" the combination F-F-0-0 before performing an IPL, many diagnostics were skipped, causing the duration of the IPL to be about a minute instead of about 10 minutes. Of course part of the IPL was typically keysorting the indexed files and if the machine had been shut down without a "keysort" (performed part of the P S (or STOP SYSTEM) then depending on the number of indexed files (and their sizes) it could take upwards of an hour to come back up.

Memory and disk

The smallest S/36 had 128K of RAM and a 30 MB hard drive.

The largest configured S/36 could support 7MB of RAM and 1478MB of disk space. This cost over US$200,000 back in the early 1980s. S/36 hard drives contained a feature called "the extra cylinder," so that bad spots on the drive were detected and dynamically mapped out to good spots on the extra cylinder. It is therefore possible for the S/36 to use more space than it can technically address. Disk address sizes limit the size of the active S/36 partition to about 2GB; however, the Advanced/36 Large Package had a 4GB hard drive which could contain up to three (emulated) S/36s, and Advanced/36 computers had more memory than SSP could address (32MB to 96MB) which was used to increase disk caching.

Disk space on the System/36 was organized by "blocks." One block = 2560 bytes. A high-end 5360 system would ship with about 550,000 blocks of disk space available. System objects could be allocated in blocks or records, but internally it was always blocks.

Program sizes

The S/36 could compile and run programs up to 64 kB in size, although most were not this large. This became a bottleneck issue only for the largest screen programs. With the Advanced/36, there were features added to the SSP operating system including the ability to call other programs from within. So a program that was say 60 kB could call another program that was 30kB or 40KB. This call/parm had been available with third-party packages on the System/36 but not widely used until the feature was put in 7.1 and 7.5 of SSP on the Advanced/36.

Virtual memory

IBM developed a form of virtual memory in 1960, which the S/36 used in a similar manner to "swap" space on modern computers. Like the modern equivalent, the system uses a cache or workspace on the hard drive to contain portions of the program(s) currently running, allowing programs larger than the amount of physical RAM (48KB in the case of the S/36) to be run. Loading the whole program into the cache area and then moving it piecemeal in and out of storage was a system function performed by the CSP, while the MSP executed the instructions in the computer program. As with modern computers, paging data between system memory and a hard disk is inherently slower than using an equivalent amount of physical RAM, an effect which was compounded by the lack of "burst" transfer modes and overall slower performance on the hard disks of that era.

SSP, the System/36 operating system

SSP ("System Support Program") was the only operating system of the S/36. It contained support for multiprogramming, multiple processors, 80 devices, job queues, printer queues, security, indexed file support, and fully installed, it was about 10MB. On the advanced/36, the number of workstations/printers was increased to 160. And with the "guest/36" which was the SSP operating system operating as a "guest" on OS/400 (V3R6 thru V4R4), you could have up to 216 devices.

System security

There are four types of System/36 security:

  1. Badge security.
  2. Password security.
  3. Resource security.
  4. Menu security.

Badge security is implemented using a stripe reader device attached to the System/36 terminal. In order to log on, the user not only typed the user/password information but also swiped the badge through the reader.

Password security was used to begin a session at a computer terminal. Unless security was inactive, a correct password must be entered to begin.

The System/36 sign on looked like this:

   SIGN ON                                W1

   User ID......... ________
   Password........ ____
   Menu (Optional). ______
   Library......... ________
   Procedure....... ________

Entering a zero ("0") for menu meant that no menu would be displayed. The S/36 "command display" would appear with no menu options. Entering a zero for library would override the default library and use the system library (#LIBRARY.) Entering a zero for procedure would override the default sign-on procedure and no procedure would run at sign-on. Mandatory menus cannot be overridden or respecified in libraries other than the named library.

SECEDIT

The SECEDIT procedure was used to work with User IDs and passwords. The user profile contains a 1-to-8 character alphanumeric User ID, a 4 character alphanumeric password, a code for the user's security rating – M (Master Security Officer), S (Security Officer), O (System Operator), C (Subconsole Operator), or D (Display Station Operator) – and a number of other default settings.

The SECEDIT RESOURCE procedure was used to establish security ratings for file, library, folder, and group objects. Access levels of O (Owner), C (Change), U (Update), R (Read), E (Execute) or N (None) could be granted for a user to a particular resource. A group object was a sort of holding company that owned one or more lower objects. For example, granting access to the group ACCOUNTG made it easier to establish access to all of the accounting files. Group objects could also reference group files; the group UB referenced UB.OLD, UB.NEW, UB.01, or any filename with the embedded period.

SECEDIT USERID was also used to confine a user's operational authority to a specific menu. By entering a Y for Mandatory Menu and specifying a default sign-on menu, the security officer could prevent the user from any program access not found on that sign-on menu. A user so confined could only run menu options, send messages, and sign off the system.

NOTE: The printed disk catalog (VTOC, Volume Table of Contents) originally displayed all secured objects with the notation 3 as being secured. By Release 4 of SSP in 1985 this notation was changed to a 4.

Files, libraries, and folders

SSP provides for two different data objects called files and libraries. Files contain records, almost always with a fixed record length. Libraries contain programs which can reference and access these files. SSP contained more than 80 different commands that allowed operators to create, delete, copy, edit/change, and secure files and libraries. Early in the System/36 development cycle, this was seriously improved to incorporate the folder object, which can have tremendous size, numerous extents, and contain subfolders.

A library or a file must exist in a contiguous organization on one fixed disk (however, a library may contain one "extent" of roughly 50 blocks which must be reorganized, and it cannot be extended if allocated to other users). A file may be organized with an EXTEND value or it may be allocated with FILE OCL to automatically extend. All record adds/updates/deletes wait while the file is being extended. It is good sense policy to create extend values large enough to minimize the frequency of extends. Libraries could have "extents" that were not contigious. At times, when compiling a program, an extent would be created and by doing a "CONDENSE", it was removed if there was enough room in the main allocation for it. Otherwise one did an ALOCLIBR to reallocate the library to a bigger size.

Files on the S/36 may be Sequential (S), Direct (D), or Indexed (I). An indexed file can have multiple alternate indexes (X), and in fact, a sequential file may have alternate indexes placed on it so there is no primary index. An indexed file contains a key, which must be contiguous and may be up to 60 characters long; however, alternate indexes may have three-part keys which are not contiguous with one another. Duplicate keys in indexed or alternate index files may be allowed or disallowed. A file with direct organization is built with all records added and cannot auto-extend. A file with sequential or indexed organization is built with no records added. An alternate index always has as many records as its parent, as opposed to a System/38-style logical file which is built with conditions to filter records from the parent.

System/36 distributed file services

In 1986, System/36 announced support for Distributed Data Management Architecture (DDM). This enabled System/36 programs to create, manage, and access record-oriented files on remote System/36, System/38, and IBM mainframe systems running CICS. It also enabled programs on remote System/36 and System/38 computers to create, access, and manage files on a System/36. The initial record-oriented file models defined by DDM were based on the System/36 file system.

SSP compared to Windows

When moving between these operating systems, some things to consider include the following:

First, the SSP user interface is command-based rather than graphical user interfaces like Windows; interacting with the computer is about what commands are typed and what keys are pressed, rather than the mouse click.

Keys F1-F12 are also called Cmd ("command") keys. Most standard S/36 keyboards have 24 Cmd keys (on some models, shifted F1-F12 keys are called F13-F24.)

SSP menus associate a number, not an icon, with a desired function or application. The Windows Control Panel is similar to the SSP Main System Menu which is accessible from an application menu by pressing Cmd5.

Windows uses point and click; with SSP, the most important function is Enter/Rec Adv, also known as Enter. Under Windows, the operator moves from field to field with the mouse click or by pressing the Tab key; with SSP, Field Exit and Field Backspace are also important.

Keyboard tricks

Experienced Windows users know that using the ALT key in combination with up to four digits on the keypad can produce characters that are otherwise unavailable on standard PC keyboards (such as accented vowels, graphic box drawing characters, and so on). Similarly, Shift+Tilde along with two hexadecimal characters will accomplish the same task on the S/36.

Spooling (printing)

SPOOL is an acronym for Simultaneous Peripheral Operations On Line.

As with some modern machines, computer printers made during the S/36 era were very slow, to the point that it was possible for the S/36 or other computers to write data to the printer faster than it can print. Spooling was used on the S/36 to deal with this issue, with the added benefit that multiple programs could write to the printer concurrently, without waiting for each other to finish.

To allow the system to manage the problem, system components called "writers" and "spool files" were developed. A writer is a small system program that reads the spool file, matches a particular printer with a ready-to-print spool object, and begins sending instructions to the printer. It's a two-way process; the printer sends a signal back to the system when it is ready for more work. In order to avoid mixing up data from two spool files, the first report to finish and close is traditionally printed first.

Forms

When the operator prints paychecks, it is vitally important that paycheck information prints on check forms and not on plain paper; likewise, a regular printout should never print on expensive check forms. Therefore, forms numbers were created. A forms number is a one-to-four-character alphameric field that programs and operators use to straighten out this problem. Programmers use the PRINTER OCL statement as follows:

// PRINTER NAME-PAYCHECK, FORMS-BUXX, DEVICE-P1

When the spool writer is ready to process the checks spool entry, this message appears at the subconsole:

SYS-1404 Options (012 )
On printer P1, change to forms number BUXX

By replying 1 to this message AFTER changing the forms, the operator could be sure that no other reports on standard stock would print on the checks.

Form alignment

Check forms must be perfectly aligned or all of the numbers won't fit in the little boxes, wasting an expensive form. Therefore, an alignment can be performed using the PRINTER OCL statement:

// PRINTER NAME-PAYCHECK, FORMS-BUXX, DEVICE-P1,ALIGN-YES

The subconsole will now get this message when ready to print checks:

SYS-5825 Options (012 )
Align the forms in printer P1

By replying this message AFTER aligning the forms, the operator could be sure that the check information didn't print until the forms were properly aligned.

Language support

The S/36 had four compilers: RPG II, COBOL, BASIC, and FORTRAN. An assembler was also available. RPG was cheaper, created compact code sizes, and became by far the best-seller. Cobol's popularity in the larger business community made it popular on the S/36 as well. Fortran is not very practical for data processing purposes, and while BASIC was powerful and easily portable to other IBM computers, it was limited by being implemented as an interactive 40K session.

One feature of the S/36 was that Basic and Fortran were exclusive. One could not run a Fortran program on the system when running Basic, nor vice versa. Fortran was certainly not a popular language, so one would suppose this microcode-level problem was only annoying to academia.

Other object types

Cobol, Fortran, and RPG generated object code (type O). Basic was interpreted only; a compilation utility called BASICS created subroutine code (type R). BASIC programs could be saved as sources for compatibility with other computers, but the project's text was preserved in the subroutine (unless the programmer used the LOCK command to keep it private.)

Procedures, which use OCL to start programs and assign resources to them, are type P.

Source members for all objects are type S, with the exception of Basic as specified above.

DFU programs generated subroutine (R) code, as did WSU programs.

Screen formats generated object code.

Menus generated object code. A menu is simply a very specific screen format with a companion message member suffixed with two pound signs ("##") to contain the action to be taken when the associated number was chosen. System/36 menus allowed the operator to choose numbers between 1 and 24. On the System/36, a programmer could customize a menu using screen format language, but calling a customized menu that did not conform to exacting system requirements could cause a program error.

Message members generated object code that could be called by a program using the MEMBER OCL statement:

// MEMBER USER1-PROGMSG

Passing a four-digit code to an assembler routine returned the associated text. It was also a way for the programmer to push up to 10,000 74-byte constants out of program space.

Programming ability was not essential. A short sequence of file and input specifications could be created and stored as a source member. A component called Data File Utility (DFU) could then be used to generate on-screen displays that could be used to create and edit files and print reports.

System/36 magazines

A number of publications were available covering the System/36, such as DataNetwork (which became Midrange Computing) and News 34/38 (which became News 3X/400, News/400, and iSeries Magazine.) Subscription prices ranged from US$8 to US$12 per copy. Others included Tips 'n' Techniques (TNT), and SCOPE/36, whose publishers distributed a newsletter format and a library of utilities and source code on diskette media. In the latter years of the S/36, registered subscribers could download source code from the Internet.

Prominent books by System/36 authors

Hardware models

System/36 Model 5360

The System/36 5360 System Unit vaguely resembled a huge washer-dryer in appearance, but unlike its predecessor, it ran on 220 volts AC. At 700 pounds (318 kg) this was still not quite a Pocket PC. Conventional wisdom called for the system to be kept in its own air-conditioned room. Conventional wisdom was, actually, very wise about this, since the system cost around US$140,000.

The five red lights on the System/36 were as follows: (1) Power check. (2) Processor check. (3) Program check. (4) Console check. (5) Temperature check.

If any light other than #4 ever came on, the system needed to be IPLed. Console can be restored if it has been powered off, but the other conditions are unrecoverable.

There were various models of the 5360, including a C and D model that dealt with speed and the ability to support an additional frame to house two additional drives.

System/36 Model 5362

IBM 5362 System Unit

IBM introduced the 5362 or "Compact 36" in 1984[3] as a system targeted at the lower end of their market. It had a deskside tower form factor (albeit a bulky one). It was designed to operate in a normal office environment, requiring little special consideration. It differed from the 5360 in by having a more limited card cage, capable of fewer peripherals. It used 14" fixed disks (30 or 60MB) and could support up to two; RAM (main storage) ranged from 128KB to 512 KB.[2] One 8" floppy diskette drive was built in.

The 5362 also allowed the use of a channel attached external desktop 9332-200, 400, & 600 DASD, effectively allowing a maximum of 720MB.

System/36 Model 5364

IBM 5364 System Unit

The model 5364 was called the "System/36 PC" or "Desktop 36" (and also, informally, the "Baby/36" by some – but this name was later attached to a software program produced by California Software Products, Inc.). The 5364 was a June 1985[4] attempt by IBM to implement a System/36 on PC-sized hardware. Inside, there were IBM chips, but the cabinet size was reminiscent of an IBM PC-AT of the period. The machine had a 1.2 MB 5.25-inch diskette drive,[3] which was incompatible with PCs and with other S/36s. The control panel/system console (connected via an expansion card) was an IBM PC with at least 256KB RAM.

System/36 Model 5363

Front of a 5363 prior to IPL.

The model 5363 was positioned as a replacement for the 5364, and was announced in October 1987.[5] It used a deskside tower style enclosure like that of the 5362, but was only 2/3 the size. It featured updated hardware using newer, smaller hard drive platters, a 514" diskette drive, and a revised distribution of the SSP.

The AS/Entry (9401)

The AS/Entry was just a stripped-down AS/400. The operating system was SSP Release 6. This machine was offered c.1991 to target customers who had a S/36 and wanted to one day migrate to an AS/400, but didn't want a massive investment in an AS/400. In this regard, the AS/Entry was a failure because IBM decided the machine's architecture was not economically feasible and the older model 5363 that the 9401 was based on was a much more reliable system.

System/36 Environment Mode of OS/400

System/36 environment Mode is a feature on the AS/400 that is used to run OCL and RPG II programs on OS/400. The operating system of the AS/400, OS/400, is contained in a library called QSYS. This was augmented for the S/36 folks with a library called QSSP so that many SSP commands could be in some way supported. To start the S/36E on OS/400 enter the command strs36.

The Advanced/36 (9402-236/9402-436)

In 1994, IBM released the AS/400 Advanced/36.[6] Priced as low as $7995, it was a machine that allowed System/36 users to get faster and more modern hardware while "staying 36." Based on standard AS/400 hardware, the Advanced/36 could run SSP, the operating system of the System/36, alone, or within AS/400's OS/400 as a "virtual machine"[7] so that it could be upgraded to a full-blown AS/400 for just extra licensing costs. The A/36 was slightly larger than a common PC cabinet and could easily be mistaken for a 1990s-era tower PC. System/36 cabinets were white (actually "off-white") and the Advanced/36 was black.

The Advanced/36 bought the world of System/36 and SSP about five more years in the marketplace, but by the end of the 20th century, the marketplace for the System/36 was almost unrecognizable. The IBM printers and displays that had completely dominated the marketplace in the 80s were replaced by a PC or a third-party monitor with an attached PC-type printer that effectively shaved 70 to 90 percent off of IBM list for the same goods. Twinaxial cable had disappeared in favor of cheap adapters and standard telephone wire. The System/36 market was eventually devoured by AS/400s at the high end and PCs at the low end. Personal computers were not nearly the database equal of SSP, but time and technology had taken their toll on a system that had remained basically unchanged since 1983. By 2000, the Advanced/36 was withdrawn from marketing.

The AS/400 Model 150, 170, etc.

By 2000, IBM offered certain AS/400 models that could run SSP as a "main" operating system or as a "guest." These were the Model 150 and Model 170 System Units. Actually any AS/400 that ran V3R6 through V4R4 could run the "guest". Up to three guest/36 virtual machines could be on one AS/400.

See also

References

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