Ibm green screen

Ibm green screen DEFAULT

Overview of IBM green screen (5250 Terminal)

The 5250 terminal emulator, or green screen, is your interface when working with an AS/400. Here is its main menu.

Main Menu

Here are some general guidelines about working with this screen:

  • If you enter an illegal keystroke, a red XII appears, as shown in the screen above. Press the Ctrl key to clear it.
  • To use function keys above F12, press the Shift key simultaneously with a function key; for example, for F16 press Shift and F4.
  • All commands are menu driven, or you can enter them on the command line.
  • Use the Tab key to move to the underscored areas that designate input, or click them with your mouse.
  • You will use F3 and F12 quite regularly to back out of a menu, to navigate back, or to “close” the screen you are on.
  • Press F1 on any field for context-sensitive help.
  • If you don’t know the name of a command, type the first few letters followed by an asterisk ( * ); for example, type STR* to list all the commands that start with STR.
  • To list the options of any command, type it and then press F4.
  • The name of the menus will sometimes be listed in blue in the upper-left; to return to them, enter GO MENUNAME.
  • Commands will also sometimes be listed at the top; to use that command again later, just enter the command.
  • To stop a command that is hung, right-click the screen, click SYSREQ, press Enter, and then use the Menu to end the command.

AS/400 sign on screen

Below figure shows a normal Sign-On screen. The upper right corner of the sign-on screen displays information that identifies the system, subsystem, and display device(or display station). A display device is the workstation hardware (monitor and keyboard) that you use to communicate with the system.

sign-on

To sign on and start an interactive job, a user must type his or her username and password. A user name is one to 10 characters long; the security administrator determines its value according to the standards of the installation. The user name may be a simple first initial and last name combination, such as YRANGANA. Or it may be a more symbolic code, perhaps indicating the user’s location or department.


Signing Off

  • Press <F3>until you see a command prompt, ===>.
  • At the command prompt type SIGNOFF or 90.

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Sours: https://as400i.com/2013/03/07/overview-of-the-green-screen-5250-terminal/

Give Your IBM i Green Screens a Modern Web GUI That's Accessible from Any Device


Presto is the fastest way to modernize green screens using the 5250 datastream or RPG OA

In this 5-minute video, you'll see a live example of a modern UI created with Presto as well as its key features.

 

Presto is a web enablement and modernization solution that helps IBM i programmers meet the shortest deadlines by rendering green screens as web pages. Managers and users will love the visually appealing screens that are easier to use, and you'll love how Presto gives you the most flexibility to add new functionality.

"Any IBM i shop that has a need to extend an application or data to the web could use Presto with their in-house RPG developers. Presto allows for the creation of a web application at a fraction of the cost."

Jay Pierce, President, JRP & Associates

Modern Web GUI

  • Quick Results: All of your green screens are instantly accessible as modern web pages.
  • Intuitive Navigation: Menus and function keys are converted to links and buttons.
  • No Source Changes: No source code changes required with the 5250 datastream.
  • 5250 or RPG OA: You can use the 5250 datastream and OA with a single license.
  • Easy Access: Users only need a browser to access the screens from any device.
  • Use Existing Staff: Presto is easy for RPG programmers to learn.

 

Improve Appearance and Functionality

  • Visual Editor: Programmers without HTML experience are productive right away using the Visual Editor to add tabs, charts, images and other UI elements.
  • User Productivity: Users can navigate screens with their mouse and enter data with autocompletes and datepickers.
  • Database-Driven UI Elements: Use SQL to populate dropdown lists and autocompletes and more or access DB2 data.
  • Future-Proof: Optionally integrate Presto screens with other web technologies/apps.

 

Mobile Support

  • Mobile Layout: Presto automatically detects the device type and displays a layout that maximizes screen real estate and optimizes performance.
  • Function Key Support: Presto includes a virtual keyboard for function keys.
  • Mobile App: Optionally access iPhone/iPad device hardware using Presto's iOS app.

 

Ebook: Why Modernize Schedule a Live Demo

 

Request a free trial of Presto


Sours: https://www.bcdsoftware.com/lp/presto/richgui.php
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green screen still actively used

Ever since the nineties, people have been asking if the era of IBM 3270 green screens is coming to an end. To which one may reply that “green screens” already became extinct in the seventies when they began to display multiple colors!

Anyway, back to the question: are IBM 3270 “green screens” coming to an end? Well, while we do admit that IBM 3270 interfaces are quite dated, they are still actively used by companies around the world.

A study by Vanson Bourne, a technology market research company, found that 93% of surveyed large organizations still use text-based user interfaces today.

Banks, airlines, car manufacturers, factories, and other critical aspects of our economy often rely on IBM 3270 interfaces. Yet that same study also points out that these organizations are becoming increasingly frustrated with them, especially on the end user level.

So why is this interface (often announced as dead) so widely used today, and how long will it last?

Why large companies won’t let go of their 3270 legacy applications

If you were to ask me why these 3270 terminal-based applications are still being used, I’d tell you that it is because they simply work. They may be quite bare-boned but that is to be expected from such old technology. Remember that it was designed for less powerful machines and networks at the time.

However primitive they seem today, IBM 3270 interfaces were a major revolution in business processes. There was a time (between the 1960s and 1970s) when punch cards were the only way to communicate with mainframes and inquiries took all night (batch processing).

With the arrival of IBM 3270 mainframe terminals, users could finally experience real-time information management.

IBM personal Computer

IBM 3270 mainframe terminals were rare at first since they were originally meant for big companies to access centralized applications. This made them very expensive and not affordable by the general public or smaller companies.

Nevertheless, 3270 applications quickly managed to become the norm thanks to the emergence of powerful PCs and TN3270 emulators. And although hardware has exponentially evolved since then, IBM 3270 applications have persisted because they have been perfected over the years and have grown in size and complexity.

It would have been extremely difficult and risky to redevelop these applications from scratch, so companies chose to keep them around with the help of TN3270 emulators.

Take the case of Fraikin, an industrial vehicle leasing giant, who decided to modernize their whole IT infrastructure with Chrome devices (Chromebook and Chromebits).

Fraikin got rid of most of their desktop apps. However, their core legacy business applications (such as booking management tools, accounting solutions, and customer databases) remained unchanged. Fraikin simply chose to modernize access to these applications through Chrome browsers thanks to a 2-tier thin client emulator.

download free case study

Adapting the IBM 3270 green screen interface to new generations

Unfortunately, that same study we mentioned states that 45% of the surveyed organizations feel that IBM 3270 green screen interfaces hinder recruitment. Many claim that their end users experience frustration when using these outdated applications.

Understandably, younger generations have trouble adapting to interfaces that are nothing like the GUIs they are used to. However, the technology itself is not the only one to blame. There are efforts to be made on multiple fronts.

For instance, perhaps companies could produce more comprehensive resources online to teach end users how to use these applications.

IBM Mainframe

Training time may be consequent, but the alternative would be a complete overhaul of all 3270 applications. And such drastic modernization efforts are too expensive and risky, at least according to 43% of the IT leaders interviewed in the Vanson Bourne study.

So why not take modernization one step at a time? Leave the trusted applications’ code untouched and focus on the user experience?

That’s what we strive to achieve here at SysperTec. We have been helping our customers progressively modernize their 3270 applications since 1993. We have done this by allowing faster and more secure access to them, integrating them to web application portals, or making them adopt browser-based end user interfaces without touching their core code.

NRB, an IT service provider for an important insurance company in Belgium, is an excellent example of such a progressive modernization. Their TN3270 emulator (Extra! From Microfocus) was about to be decommissioned. At the same time, NRB was also trying to modernize their client’s digital workspace.

The goal was to find a TN3270 emulator that could easily integrate into their new Angular framework, all while gradually modernizing IBM 3270 green screens and improving flexibility (putting an end to mainframe silos).

Eventually, they were drawn to our web modernization solution, Virtel. It allowed them to keep the IBM 3270 look and feel for certain applications while transforming others into proper modern web GUIs.

john-schnobrich-FlPc9_VocJ4-unsplash

3270 applications are still being used today. They are well implemented within multiple companies and getting rid of them will be difficult and costly.

However, user and executive demands make the daunting idea of green screen modernization more and more pressing. But rather than jumping into complex and costly modernization projects, companies can choose a lighter and more pragmatic alternative. Upgrading TN3270 emulators to a web-based solution is a viable way to modernize 3270 applications gradually.

IBM 3270 “green-screens” still have some years left before they disappear, and some of us will be long retired before they do. However, 3270 interfaces will continue to evolve and adapt to the new digital era. Therefore, companies should prepare and equip themselves accordingly.

download free case study

Discover our modernization solution: Virtel

 

Sours: https://blog.virtelweb.com/is-this-the-end-of-ibm3270-green-screen
IBM 3270 compatible terminal playing Infocom games (Informer 207 376/SNA)

IBM 3270

Family of block-oriented display terminals and printers made by IBM

Not to be confused with the IBM 3270 PC.

The IBM 3270 is a family of block oriented display and printer computer terminals introduced by IBM in 1971[2] and normally used to communicate with IBM mainframes. The 3270 was the successor to the IBM 2260 display terminal.[3] Due to the text color on the original models, these terminals are informally known as green screen terminals. Unlike a character-oriented terminal, the 3270 minimizes the number of I/Ointerrupts required by transferring large blocks of data known as data streams, and uses a high speed proprietary communications interface, using coaxial cable.

IBM no longer manufactures 3270 terminals, but the IBM 3270 protocol is still commonly used[4] via TN3270 clients, 3270 terminal emulation or web interfaces to access mainframe-based applications, which are sometimes referred to as green screen applications.

Principles[edit]

The 3270 series was designed to connect with mainframe computers, often at a remote location, using the technology then available in the early 1970s.[2] The main goal of the system was to maximize the number of terminals that could be used on a single mainframe. To do this, the 3270 was designed to minimize the amount of data transmitted, and minimize the frequency of interrupts to the mainframe. By ensuring the CPU is not interrupted at every keystroke, a 1970s-era IBM 3033 mainframe fitted with only 16 MB of main memory was able to support up to 17,500 3270 terminals under CICS.

Sample IBM 3270 cluster with one control unit connected to a printer and two displays

Most 3270 devices are clustered, with one or more displays or printers connected to a control unit (the 3275 and 3276 included an integrated control unit).[6] Originally devices were connected to the control unit over coaxial cable; later Token Ring, twisted pair, or Ethernet connections were available. A local control unit attaches directly to the channel of a nearby mainframe. A remote control unit is connected to a communications line by a modem. Remote 3270 controllers are frequently multi-dropped, with multiple control units on a line.

IBM 3270 devices are connected to a 3299 multiplexer or to the cluster controller, e.g., 3271, 3272, 3274, 3174, using RG-62, 93 ohm, coax cables in a point to point configuration with one dedicated cable per terminal. Data is sent with a bit rate of 2.3587 Mb/s using a slightly modified differential Manchester encoding. Cable runs of up to 1.500 meters are supported. Originally devices were equipped with BNC connectors, which later was replaced with special so-called DPC – Dual Purpose Connectors supporting the IBM Shielded twisted pair cabling system without the need for so-called red baluns.

In a data stream, both text and control (or formatting functions) are interspersed allowing an entire screen to be painted as a single output operation. The concept of formatting in these devices allows the screen to be divided into fields (clusters of contiguous character cells) for which numerous field attributes, e.g., color,[a] highlighting, character set,[a] protection from modification, can be set. A field attribute occupies a physical location on the screen that also determines the beginning and end of a field. There are also[a] character attributes associated with individual screen locations.

Using a technique known as read modified,[7] a single transmission back to the mainframe can contain the changes from any number of formatted fields that have been modified, but without sending any unmodified fields or static data. This technique enhances the terminal throughput of the CPU, and minimizes the data transmitted. Some users familiar with character interrupt-driven terminal interfaces find this technique unusual. There is also a read buffer[8] capability that transfers the entire content of the 3270-screen buffer including field attributes. This is mainly used for debugging purposes to preserve the application program screen contents while replacing it, temporarily, with debugging information.

Early 3270s offered three types of keyboards. The typewriter keyboard came in both a 66 key version, with no programmed function (PF) keys, and a 78 key version with twelve. Both versions had two Program Attention (PA) keys.[9][10] The data entry keyboard had five PF keys and two PA keys. The operator console keyboard had twelve PF keys and two PA keys.[11]: p.19  Later 3270s had an Attention[b] key, a Cursor Select[c] key, a System Request key, twenty-four PF keys and three PA keys. There was also a TEST REQ key. When one of these keys is pressed, it will cause its control unit to generate an I/O interrupt[d] to the host computer and present an Attention ID (AID) identifying which key was pressed. Application program functions such as termination, page-up, page-down, or help can be invoked by a single key press, thereby reducing the load on very busy processors.

A downside to this approach was that vi-like behavior, responding to individual keystrokes, was not possible. For the same reason, a port of Lotus 1-2-3 to mainframes with 3279 screens did not meet with success because its programmers were not able to properly adapt the spreadsheet's user interface to a screen at a time rather than character at a time device. But end-user responsiveness was arguably more predictable with 3270, something users appreciated.

Applications[edit]

Following its introduction the 3270 and compatibles were by far the most commonly used terminals on IBM System/370 and successor systems.[12] IBM and third-party software that included an interactive component took for granted the presence of 3270 terminals and provided a set of ISPFpanels and supporting programs.

Conversational Monitor System (CMS) in VM has support for the 3270[13] continuing to z/VM.

Time Sharing Option (TSO) in OS/360 and successors has line mode command line support and also has facilities for full screen applications, e.g., ISPF.

Device independent Display Operator Console Support (DIDOCS) in Multiple Console Support (MCS) for OS/360 and successors.

The SPF and Program Development Facility (ISPF/PDF) editors for MVS and VM/SP (ISPF/PDF was available for VM, but little used) and the XEDITeditors for VM/SP through z/VM make extensive use of 3270 features.

Customer Information Control System (CICS) has support for 3270 panels.

Various versions of Wylbur have support for 3270, including support for full-screen applications.

The modified data tag is well suited to converting formatted, structured punched card input onto the 3270 display device. With the appropriate programming, any batch program that uses formatted, structured card input can be layered onto a 3270 terminal.

IBM's OfficeVision office productivity software enjoyed great success with 3270 interaction because of its design understanding. And for many years the PROFS calendar was the most commonly displayed screen on office terminals around the world.[citation needed]

A version of the WordPerfectword processor ported to System/370 was designed for the 3270 architecture.

SNA[edit]

3270 devices can be a part of an SNA – System Network Architecture network or non-SNA network. If the controllers are SNA connected, they appear to SNA as PU – Physical Unit type 2.0 (PU2.1 for APPN) nodes typically with LU – Logical Unit type 1, 2, and 3 devices connected. Local, channel attached, controllers are controlled by VTAM – Virtual Telecommunications Access Method. Remote controllers are controlled by the NCP – Network Control Program in the Front End Processor i.e. 3705, 3720, 3725, 3745, and VTAM.

Third parties[edit]

One of the first groups to write and provide operating system support for the 3270 and its early predecessors was the University of Michigan, who created the Michigan Terminal System in order for the hardware to be useful outside of the manufacturer.[clarification needed] MTS was the default OS at Michigan for many years, and was still used at Michigan well into the 1990s. Many manufacturers, such as GTE, Hewlett Packard, Honeywell/Incoterm Div, Memorex, ITT Courier, McData, Harris, Alfaskop and Teletype/AT&T created 3270 compatible[e] terminals, or adapted ASCII terminals such as the HP 2640 series to have a similar block-mode capability that would transmit a screen at a time, with some form validation capability. The industry distinguished between ‘System compatible controllers’ and ‘Plug compatibility controllers’, where ‘System compatibility’ meant that the 3rd party system was compatible with the 3270 data stream terminated in the unit, but not as ‘Plug compatibility’ equipment, also were compatible at the coax level thereby allowing IBM terminals to be connected to a 3rd party controller or visa versa. Modern applications are sometimes built upon legacy 3270 applications, using software utilities to capture (screen scraping) screens and transfer the data to web pages or GUI interfaces.

In the early 1990s a popular solution to link PCs with the mainframes was the Irma board, an expansion card that plugged into a PC and connected to the controller through a coaxial cable. 3270 simulators for IRMA and similar adapters typically provide file transfers between the PC and the mainframe using the same protocol as the IBM 3270 PC.[citation needed]

Models[edit]

The IBM 3270 display terminal subsystem consists of displays, printers and controllers. Optional features for the 3275 and 3277 are the selector-pen or light pen, ASCII rather than EBCDIC character set, an audible alarm, and a keylock for the keyboard. A keyboard numeric lock was available and will lock the keyboard if the operator attempts to enter non-numeric data into a field defined as numeric.[11] Later an Operator Identification Card Reader was added which could read information encoded on a magnetic stripe card.

Displays[edit]

Generally, 3277 models allow only upper-case input, except for the mixed EBCDIC/APL or text keyboards, which have lower case. Lower-case capability and dead keys were available as an RPQ (Request Price Quotation); these were added to the later 3278 & 3279 models.

A version of the IBM PC called the 3270 PC, released in October 1983, includes 3270 terminal emulation. Later, the 3270 PC/G (graphics), 3270 PC/GX (extended graphics), 3270 Personal Computer AT, 3270 PC AT/G (graphics) and 3270 PC AT/GX (extended graphics) followed.

CUT vs. DFT[edit]

There are two types of 3270 displays in respect to where the 3270 data stream terminates. For CUT (Control Unit Terminal) displays, the stream terminates in the display controller, the controller instructs the display to move the cursor, position a character, etc. EBCDIC is translated by the controller into ‘3270 Character Set’, and keyboard scan-codes from the terminal, read by the controller through a poll, is translated by the controller into EBCDIC. For DFT (Distributed Function Terminal) type displays, most of the 3270 data stream is forwarded to the display by the controller. The display interprets the 3270 protocol itself.

In addition to passing the 3270 data stream directly to the terminal, allowing for features like EAB - Extended Attributes, Graphics, etc., DFT also enabled multi sessions (up to 5 simultaneous), featured in the 3290 and 3194 multisession displays. This feature was also widely used in 2nd generation 3270 terminal emulation software.

The MLT - Multiple Logical Terminals feature of the 3174 controller also enabled multiple sessions from a CUT type terminal.

Display Station NameCUT vs. DFT
3178 - all modelsCUT
3179 - Model 1CUT
3179 - Models G1, G2DFT
3180 Model 1CUT
3191 - all modelsCUT
3192 - Models C, D, F, L, WCUT
3192 - Model GDFT
3193 - all modelsDFT
3194 - all modelsDFT
3277 - all modelsCUT
3278 - all modelsCUT
3279 - all modelsCUT
3290 - all modelsDFT
3472 - except model G CUT
3472 - model G DFT
3482 - all models DFT

3277[edit]

  • 3277 model 1: 40×12 terminal
  • 3277 model 2: 80×24 terminal, the biggest success of all[14]
  • 3277 GA: a 3277 with an RS232C I/O, often used to drive a Tektronix 4013 or 4015 graphic screen (monochrome)

3278[edit]

  • 3278 models 1–5: next-generation, with accented characters and dead keys in countries that needed them
    • model 1: 80x12
    • model 2: 80×24
    • model 2A: 80x24 (console) with 4 lines reserved
    • IBM 3278 and 3279 terminals side-to-side
      model 3: 80×32 or 80x24 (switchable)
    • model 4: 80×43 or 80x24 (switchable)
    • model 5: 132×27 or 80×24 (switchable)
  • 3278 PS: programmable characters; able to display monochrome graphics

3279[edit]

IBM 3279 Color Display Terminal
An Informatics General computer programmer using an IBM 3279 terminal

The IBM 3279 was IBM's first color[15] terminal. IBM initially announced four models, and later added a fifth model for use as a processor console.

  • Models
    • model 2A: 80-24 base color
    • model 2B: 80-24 extended color
    • model 2C: 80-24 base color (console) with 4 lines reserved
    • model 3A: 80-32 base color
    • model 3B: 80-32 extended color
  • Base color
    In base color mode the protection and intensity field attributes determine the color:
Protection Intensity Color
Unprotected Normal

Green

Unprotected Intensified

Red

Protected Normal

Blue

Protected Intensified

White

  • Extended color
    In extended color mode the color field and character attributes determine the color as one of
    • Neutral (White)
    • Red
    • Blue
    • Green
    • Pink
    • Yellow
    • Turquoise

The 3279 was introduced in 1979.[16] The 3279 was widely used as an IBM mainframe terminal before PCs became commonly used for the purpose. It was part of the 3270 series, using the 3270 data stream. Terminals could be connected to a 3274 controller, either channel connected to an IBM mainframe or linked via an SDLC (Synchronous Data Link Control) link. In the Systems Network Architecture (SNA) protocol these terminals were logical unit type 2 (LU2). The basic models 2A and 3A used red, green for input fields, and blue and white for output fields. However, the models 2B and 3B supported seven colors, and when equipped with the optional Programmed Symbol Set feature had a loadable character set that could be used to show graphics.

The IBM 3279 with its graphics[f] software support, Graphical Data Display Manager (GDDM), was designed at IBM's Hursley Development Laboratory, near Winchester, England.[18]

3290[edit]

The 3290 Information Panel a 17", amber monochrome plasma display unit announced[19] March 8, 1983, capable of displaying in various modes, including four independent 3278 model 2 terminals, or a single 160×62 terminal; it also supports partitioning.[g] The 3290 supports graphics through the use of programmed symbols. A 3290 application can divide its screen area up into as many as 16 separate explicit partitions (logical screens).

The 3290 is a Distributed Function Terminal (DFT) and requires that the controller do a downstream load (DSL) of microcode from floppy or hard disk.

317x[edit]

  • 3178: lower cost terminal (1983)
  • 3179: low cost color terminal[21] announced March 20, 1984.

3180[edit]

The 3180 was a monochrome display, introduced on March 20, 1984, that the user could configure for several different basic and extended display modes; all of the basic modes have a primary screen size of 24x80. Modes 2 and 2+ have a secondary size of 24x80, 3 and 3+ have a secondary size of 32x80, 4 and 4+ have a secondary size of 43x80 and 5 and 5+ have a secondary size of 27x132. An application can override the primary and alternate screen sizes for the extended mode. The 3180 also supported a single explicit partition that could be reconfigured under application control.

3191[edit]

The IBM 3191 Display Station is an economical monochrome CRT. Models A and B are 1920 characters 12-inch CRTs. Models D, E and L are 1920 or 2560 character 14-inch CRTs.

3192[edit]

  • Model C provides a 7-color 14 inch CRT with 80x24 or 80x32 characters
  • Model D provides a green monochrome 15 inch CRT with 80x24, 80x32, 80x44 or 132x27 characters
  • Model F provides a 7-color high-resolution 14 inch CRT with 80x24, 80x32, 80x44 or 132x27 characters
  • Model G provides a 7-color 14 inch CRT with 80x24 or 80x32 characters
  • Model L provides a green monochrome 15 inch CRT with 80x24, 80x32, 80x44 or 132x27 characters with a selector light pen capability
  • Model W provides a black and while 15 inch CRT with 80x24, 80x32, 80x44 or 132x27 characters

3193[edit]

The IBM 3193 Display Station is a high-resolution, portrait-type, monochrome, 380mm (15 inch) CRT image display providing up to letter or A4 size document display capabilities in addition to alphanumeric data. Compressed images can be sent to the 3193 from a scanner and decompression is performed in the 3193. Image data compression is a technique to save transmission time and reduce storage requirements.

3194[edit]

The IBM 3194 is a Display Station that features a 1.44MB 3.5" floppy drive and IND$FILE transfer.

  • Model C provides a 12 inch color CRT with 80x24 or 80x32 characters
  • Model D provides a 15 inch monochrome CRT with 80x24, 80x31, 80x44 or 132x27 characters
  • Model H provides a 14 inch color CRT with 80x24, 80x31, 80x44 or 132x27 characters

Subsequent[edit]

  • 3104: low-cost R-loop connected terminal for the IBM 8100 system
  • 3472 Infowindow

Non-IBM Displays[edit]

Several third-party manufacturers produced 3270 displays besides IBM.

GTE[edit]

GTE manufactured the IS/7800[22] Video Display System, nominally compatible with IBM 3277 displays attached to a 3271 or 3272. An incompatibility with the RA buffer order broke the logon screen in VM/SE (SEPP).

Harris[edit]

Harris manufactured the 8000[23] Series Terminal Systems, compatible with IBM 3277 displays attached to a 3271 or 3272.

Harris later manufactured the 9100/9200[24] Information Processing Systems, which included

  • 9178
  • 9278
  • 9279-2A
  • 9279-3G
  • 9280
Informer 270 376/SNA[edit]

The Informer company manufactured a special version of their model 270 terminal that was compatible with IBM 3270 and its associated coax port to connect to a 3x74.[25][26]

Memorex Telex[edit]
  • Memorex 1377, compatible with IBM 3277
    Attaches to 1371 or 1372

Documentation for the following is available at [27]

  • Memorex/Telex 2078
  • Memorex/Telex 2079
  • Memorex/Telex 2080
  • Memorex/Telex 2178
  • Memorex/Telex 2179
Nokia/Alfaskop[edit]
  • Alfaskop Display Unit 4110
  • Alfaskop Display Unit 4112
AT&T[edit]

AT&T introduced the Dataspeed 40 terminal/controller, compatible with the IBM 3275, in 1980.[28]

Graphics models[edit]

IBM had two different implementations for supporting graphics. The first was implemented in the optional Programmed Symbol Sets[29] (PSS) of the 3278, 3279 and 3287, which became a standard feature on the later 3279-S3G, a.k.a. 3279G, and was based on piecing together graphics with on-the-fly custom-defined symbols downloaded to the terminal.

The second later implementation provided All Points Addressable (APA) graphics, a.k.a. Vector Graphics, allowing more efficient graphics than the older technique. The first terminal to support APA / Vector graphics was the 3179G terminal that later was replaced by first the 3192G and later the 3472G.

Both implementations are supported by IBM GDDM - Graphical Data Display Manager first released in 1979, and by SAS with their SAS/GRAPH software.

IBM 3279G[edit]

IBM 3279-S3G, a.k.a. 3279G, terminal, announced in 1979, was IBM's graphics replacement for the 3279-3B with PSS. The terminal supported 7 colors and the graphics were made up of Programmable Symbol sets loaded to the terminal by the graphical application GDDM - Graphical Data Display Manager using Write Structured Field command.

Programmable Symbols is an addition to the normal base character set consisting of Latin characters, numbers, etc. hardwired into the terminal. The 3279G supports 6 additional sets of symbols each supporting 190 symbols, resulting in a total of 1.140 programmable symbols. 3 of the Programmable Symbols sets have 3 planes each enabling coloring (red, blue, green) the Programmable Symbols downloaded to those sets, thereby supporting a total of 7 colors.

Each ‘character’ cell consists of a 9x12 or a 9x16 dot matrix depending on the screen model. In order to program a cell with a symbol 18 bytes of data is needed making the data load quite heavy in some instances when compared to classic text screens.

If one for example wishes to draw a hyperbole on the screen, the application must first compute the required Programmable Symbols to make up hyperbole and load them to the terminal. The next step is then for the application to paint the screen by addressing the screen cell position and select the appropriate symbol in one of the Programmable Symbols sets.

The 3279G could be ordered with Attribute Select Keyboard enabling the operator to select attributes, colors and Programmable Symbols sets, making that version of the terminal quite distinctive.

IBM 3179G[edit]

‹ The templateInfobox information appliance is being considered for merging. ›

Also known asIBM 3179G Color Display Station
ManufacturerIBM
Release dateMarch 1984 (1984-03)
Introductory priceUS$2,295 (equivalent to $5,717 in 2020)
SuccessorIBM 3192-G

The IBM 3179G announced June 18, 1985,[30] is an IBM mainframe computer terminal providing 80×24 or 80×32 characters, 16 colors, plus graphics[31][32][33][34][35] and is the first terminal to support the APA graphics apart from the 3270 PC/G, 3270 PC/GX, PC AT/G and PC AT/GX.

3179-G terminals combine text and graphics as separate layers on the screen. Although the text and graphics appear combined on the screen, the text layer actually sits over the graphics layer. The text layer contains the usual 3270-style cells which display characters (letters, numbers, symbols, or invisible control characters).[36] The graphics layer is an area of 720×384 pixels.[37]All Points Addressable or vector graphics is used to paint each pixel in one of sixteen colors. As well as being separate layers on the screen, the text and graphics layers are sent to the display in separate data streams, making them completely independent.

The application i.e. GDDM sends the vector definitions to the 3179-G, and the work of activating the pixels that represent the picture (the vector-to-raster conversion) is done in the terminal itself. The datastream is related to the number of graphics primitives (lines, arcs, and so on) in the picture. Arcs are split into short vectors, that are sent to the 3179-G to be drawn. The 3179-G does not store graphic data, and so cannot offload any manipulation function from GDDM. In particular, with user control, each new viewing operation means that the data has to be regenerated and retransmitted.

The 3179G is a distributed function terminal (DFT) and requires a downstream load (DSL) to load its microcode from the cluster controller's floppy disk or hard drive.

The G10 model is a standard 122-key typewriter keyboard, while the G20 model offers APL on the same layout. Compatible with IBM System/370, IBM 4300 series, 303x, 308x, IBM 3090, and IBM 9370.

IBM 3192G[edit]

1987 successor to 3179G. It featured 16 colors, and support for printers (i.e., IBM Proprinter) for local hardcopy with graphical support, or system printer, text only, implemented as an additional LU.

IBM 3472G[edit]

The IBM 3472G announced in 1989 was the successor to 3192G and featured five concurrent sessions, one of which could be graphics. Unlike the 3192-G, it needed no expansion unit to attach a mouse or color plotter, and it needed no expansion unit to attach a mouse or color plotter and it could also attach a tablet device for digitised input and a bar code reader.

APL / APL2[edit]

Most IBM terminals, starting with the 3277, could be delivered with an APL keyboard, allowing the operator/programmer to enter APL symbolic instructions directly into the editor. In order to display APL symbols on the terminal, it had to be equipped with an APL character set in addition to the normal 3270-character set. The APL character set is addressed with a preceding Graphic Escape X'08' instruction.

With the advent of the graphic terminal 3179G, the APL character set was expandable to 138 characters, called APL2. The added characters were: Diamond, Quad Null, Iota Underbar, Epsilon Underbar, Left Tack, Right Tack, Equal Underbar, Squished Quad, Quad Slope, and Dieresis Dot. Later APL2 symbols were supported by 3191 Models D, E, L, the CUT version of 3192, and 3472.

Please note that IBM’s version’s of APL also is called APL2.

Display-Controller[edit]

  • 3275 remote display with controller function (no additional displays up to one printer)
  • 3276 remote display with controller function. IBM 3276, announced in 1981, was a combined remote controller and display terminal, offering support for up to 8 displays, the 3276 itself included. By default, the 3276 had two type A coax ports, one for its own display, and one free for an additional terminal or printer. Up to three additional adapters, each supporting two coax devices, could be installed. The 3276 could connect to a non-SNA or SNA host using BSC or SDLC with line speed of up to 9.600 bps. The 3276 looked very much like the 3278 terminal, and the terminal feature of the 3276 itself, was more or less identical to those of the 3278.

Printers[edit]

  • 3284 matrix printer
  • 3286 matrix printer
  • 3287 printer, including a color model
  • 3288 line printer
  • 3268-1 : R-loop connected stand-alone printer for the IBM 8100 system
  • 4224 matrix printer

In 1984 announced IPDS – Intelligent Printer Data Stream for online printing of AFP - Advanced Function Presentation documents, using bidirectional communications between the application and the printer. IPDS support among others printing of text, fonts, images, graphics, and barcodes. The IBM 4224 is one of the IPDS capable dot matrix printers.

With the emergence of printers, including laser printers, from HP, Canon, and others, targeted the PC market, 3270 customers got an alternative to IBM 3270 printers by connecting this type of printers through printer protocol converters from manufactures like I-data, MPI Tech, Adacom, and others. The printer protocol converters basically emulate a 3287 type printer, and later extended to support IPDS.

The IBM 3482 terminal, announced in 1992, offered a printer port, which could be used for host addressable printing as well as local screen copy.

In the later versions of 3174 the Asynchronous Emulation Adapter (AEA), supporting async RS-232 character-based type terminals, was enhanced to support printers equipped with a serial interface.

Controllers[edit]

  • 3271 remote controller
  • 3272 local controller
  • 3274 cluster controller (different models could be channel-attached or remote via BSC or SDLC communication lines, and had between eight and 32 co-ax ports)
  • 3174 cluster controller

On the 3274 and 3174, IBM used the term configuration supportletter, sometimes followed by a release number, to designate a list of features together with the hardware and microcode needed to support them.

By 1994 the 3174 Establishment Controller supported features such as attachment to multiple hosts via Token Ring, Ethernet, or X.25 in addition to the standard channel attach or SDLC; terminal attachment via twisted pair, Token Ring or Ethernet in addition to co-ax; and TN3270. They also support attachment of asynchronous ASCII terminals, printers, and plotters alongside 3270 devices.[39]

3274 controller[edit]

IBM introduced the 3274 controller family in 1977, replacing the 3271/2 product line.

Where the features of the 3271/2 was hardcoded, the 3274 was controlled by its microcode that was read from the 3274’s build in 8” floppy drive.

3274 models included 8, 12, 16, and 32 port remote controllers and 32-port local channel attached units. In total 16 different models were over time released to the market. The 3274-1A was an SNA physical Unit type 2.0 (PU2.0), required only a single address on the channel for all 32 devices and was not compatible with the 3272. The 3274-1B and 3274-1D were compatible with the 3272 and were referred to as local non-SNA models.

The 3274 controllers introduced a new generation of the coax protocol, named Category A, to differentiate them from the Category B coax devices, such as the 3277 terminal and the 3284 printer. The first Category A coax devices were the 3278 and the first color terminal, the IBM 3279 Color Display Station.

Enabling backward compatibility, it was possible to install coax boards, so-called ‘panels’, in groups of 4 or 8 supporting the now older Category B coax devices. A maximum of 16 Category B terminals could be supported, and only 8 if the controller were fully loaded with a maximum of 4 panels each supporting 8 Category A devices.

During its life span, the 3274 supported several features including:

  • Programmed Symbol Set (PSS)
  • V.24 interfaces with speed up to 14.4 Kbps
  • V.35 interfaces with speed up to 56 Kbps
  • DFT – Distributed Function Terminal
  • DSL – Downstream load for 3290 and 3179G
  • 9901 and 3299 multiplexer
  • Dual Logic (the feature of having two sessions from a CUT mode display).

3174 controller[edit]

IBM introduced the 3174 Subsystem Control Unit in 1986, replacing the 3274 product line.

The 3174 was designed to enhance the 3270 product line with many new connectivity options and features. Like the 3274, it was customizable, the main difference was that it used smaller (5.25-inch) diskettes than the 3274 (8-inch diskettes), and that the larger floor models had 10 slots for adapters, some of them were per default occupied by channel adapter/serial interface, coax adapter, etc. Unlike the 3274, any local models could be configured as either local SNA or local non-SNA, including PU2.1 (APPN).

The models included: 01L, 01R, 02R, 03R, 51R, 52R, 53R, 81R and 82R.

The 01L were local channel attached, the R models remotely connected, and the x3R Token Ring (upstream) connected. The 0xL/R models were floor units supporting up to 32 coax devices through the use of internal or external multiplexers (TMA/3299). The 5xR, models were shelf units with 9 coax ports, expandable to 16, by the connection of a 3299 multiplexer. The smallest desktop units, 8xR, had 4 coax ports expandable to 8, by the connection of a 3299 multiplexer.

In the 3174 controller line IBM also slightly altered the classical BNC coax connector by changing the BNC connector to DPC – Dual Purpose Connector. The DPC female connector was a few millimeters longer and with a build-in switch that detected if a normal BNC connector were connected or a newer DPC connector was connected, thereby changing the physical layer from 93 ohm unbalanced coax, to 150 ohm balanced twisted-pair, thereby directly supporting the IBM Cabling system without the need for a so-called red balun.

Configuration Support A was the first microcode offered with the 3174. It supported all the hardware modules present at the time, almost all the microcode features found in 3274 and introduced a number of new features including: Intelligent Printer Data Stream (IPDS), Multiple Logical Terminals, Country Extended Code Page (CECP), Response Time Monitor, and Token Ring configured as host interface.

Configuration Support S, strangely following release A, introduced that a local or remote controller could act as 3270 Token-Ring DSPU Gateway, supporting up to 80 Downstream PU’s.

In 1989, IBM introduced a new range of 3174 models and changed the name from 3174 Subsystem Control Unit to 3174 Establishment Controller. The main new feature was support for an additional 32 coax port in floor models.

The models included: 11L, 11R, 12R, 13R, 61R, 62R, 63R, 91R, and 92R.

The new line of controllers came with Configuration Support B release 1, increased the number of supported DSPU on the Token-Ring gateway to 250 units, and introduced at the same time ‘Group Polling’ that offloaded the mainframe/VTAM polling requirement on the channel.

Configuration Support B release 2 to 5, enabled features like: Local Format Storage (CICS Screen Buffer), Type Ahead, Null/Space Processing, ESCON channel support.

In 1990/1991, a total of 7 more models were added: 21R, 21L, 12L, 22L, 22R, 23R, and 90R. The 12L offered ESCON fibreoptic channel attachment. The models with 2xx designation were equal to the 1xx models but repacked for rackmount and offered only 4 adapter slots. The 90R was not intended as a coax controller, it was positioned as a Token Ring 3270 DSPU gateway. However, it did have one coax port for configuring the unit, which with a 3299 multiplexer could be expanded to 8.

The line of controllers came with Configuration Support C to support ISDN, APPN and Peer Communication. The ISDN feature allowed downstream devices, typically PC’s, to connect to the 3174 via the ISDN network. The APPN support enabled the 3174 to be a part of an APPN network, and the Peer Communication allowed coax attached PC’s with ‘Peer Communication Support’ to access resources on the Token-Ring network attached to the 3174.

The subsequent releases 2 to 6 of Configuration Support C enables support for: Split screen, Copy from session to session, Calculator function, Access to AS/400 host and 5250 keyboard emulation, Numerous APPN enhancements, TCP/IP Telnet support that allowed 3270 CUT terminals to communicate with TCP/IP servers using Telnet, and at the same time in another screen to communicate with the mainframe using native 3270. TN3270 support where the 3174 could connect to a TN3270 host/gateway, eliminating SNA, but preserving the 3270 data stream. IP forwarding allowing bridging of LAN (Token-Ring or Ethernet) connected devices downstream to the 3174 to route IP traffic onto the Frame Relay WAN interface.

In 1993, three new models were added with the announcement of Ethernet Adapter (FC 3045). The models were: 14R, 24R, and 64R.

This was also IBM's final hardware announcement of 3174.

The floor models, and the rack-mountable units, could be expanded with a range of special 3174 adapters, that by 1993 included: Channel adapter, ESCON adapter, Serial (V.24/V.35) adapter, Concurrent Communication Adapter, Coax adapter, Fiber optic “coax” adapter, Async adapter, ISDN adapter, Token-Ring adapter, Ethernet adapter, and line encryption adapter.

In 1994, IBM incorporated the functions of RPQ 8Q0935 into Configuration Support-C release 3, including the TN3270 client.[41]

Non-IBM Controllers[edit]

GTE[edit]

The GTE IS/7800 Video Display Systems used one of two nominally IBM compatible controllers:

  • 7801 (remote, 3271 equivalent)
  • 7802 (local, 3277 equivalent)
Harris[edit]

The Harris 8000 Series Terminal Systems used one of four controllers:

  • 8171 (remote, 3271 equivalent)
  • 8172 (local, 3277 equivalent)
  • 8181 (remote, 3271 equivalent)
  • 8182 (local, 3277 equivalent)
Home grown[edit]

An alternative implementation of an establishment controller exists in form of OEC (Open Establishment Controller).[42][43][44][45] It's a combination of an Arduinoshield with a BNC connector and a Python program that runs on a POSIX system. OEC allows to connect a 3270 display to IBM mainframes via TN3270 or to other systems via VT100. Currently only CUT but not DFT displays are supported.

Memorex[edit]

Memorex had two controllers for its 3277-compatible 1377; the 1371 for remote connection and the 1372 for local connection.[46]

Later Memorex offered a series of controllers compatible with the IBM 3274 and 3174

Multiplexers[edit]

IBM offered a device called 3299 that acted as a multiplexer between an accordingly configured 3274 controller, with the 9901 multiplexer feature, and up to 8 displays/printers, thereby reducing the number of coax cables between the 3x74 controller and the displays/printers.

With the introduction of the 3174 controller internal or external multiplexers (3299) became mainstream as the 3174-1L controller was equipped with 4 multiplexed ports each supporting 8 devices. The internal 3174 multiplexer card was named TMA – Terminal Multiplexer adapter 9176.

A number of vendors manufactured 3270 multiplexers before and alongside IBM including Fibronics and Adacom offering multiplexers that supported TTP – Telephone Twisted Pair as an alternative to coax, and fiber-optic links between the multiplexers.

In some instances, the multiplexer worked as an “expansion” unit on smaller remote controllers including the 3174-81R / 91R, where the 3299 expanded the number of coax ports from 4 to 8, or the 3174-51R / 61R, where the 3299 expanded the number of coax ports from 8 to 16.

Manufacture[edit]

The IBM 3270 display terminal subsystem was designed and developed by IBM's Kingston, New York, laboratory (which later closed during IBM's difficult time in the mid-1990s). The printers were developed by the Endicott, New York, laboratory. As the subsystem expanded, the 3276 display-controller was developed by the Fujisawa laboratory, Japan, and later the Yamato laboratory; and the 3279 color display and 3287 color printer by the Hursley, UK, laboratory. The subsystem products were manufactured in Kingston (displays and controllers), Endicott (printers), and Greenock, Scotland, UK, (most products) and shipped to users in U.S. and worldwide. 3278 terminals continued to be manufactured in Hortolândia, near Campinas, Brazil as far as late 1980s, having its internals redesigned by a local engineering team using modern CMOS technology, while retaining its external look and feel.[citation needed]

Telnet 3270[edit]

Telnet 3270, or tn3270 describes both the process of sending and receiving 3270 data streams using the telnet protocol and the software that emulates a 3270 class terminal that communicates using that process. tn3270 allows a 3270 terminal emulator to communicate over a TCP/IP network instead of an SNA network. Telnet 3270 can be used for either terminal or print connections. Standard telnet clients cannot be used as a substitute for tn3270 clients, as they use fundamentally different techniques for exchanging data.

Technical Information[edit]

3270 character set[edit]

The 3270 displays are available with a variety of keyboards and character sets. The following table shows the 3275/3277/3284/3286 character set[50] for US English EBCDIC (optional characters were available for US ASCII, and UK, French, German, and Italian EBCDIC). The numbers are the equivalent Unicode code points.

On the 3275 and 3277 terminals without the a text feature, lower case characters display as uppercase. NL, EM, DUP, and FM control characters display and print as 5, 9, *, and ; characters, respectively, except by the printer when WCC or CCC bits 2 and 3 = '00'b, in which case NL and EM serve their control function and do not print.[11]: p.15 

_0 _1 _2 _3 _4 _5 _6 _7 _8 _9 _A _B _C _D _E _F
0_ NUL
0000
SOH
0001
STX
0002
ETX
0003
PT
 
1_ DLE
0010
SBA
 
EUA
 
IC
 
NL
0085
EM
0019
DUP
 
SF
 
FM
 
ITB
 
2_ ETB
0017
ESC
001B
ENQ
0005
3_ SYN
0016
EOT
0004
RA
 
NAK
0015
SUB
001A
4_ SP
0020
¢
00A2
.
002E
<
003C
(
0028
+
002B
|
007C
5_ &
0026
!
0021
$
0024
*
002A
)
0029
;
003B
¬
00AC
6_ -
002D
/
002F
¦
00A6
,
002C
%
0025
_
005F
>
003E
?
003F
7_ :
003A
#
0023
@
0040
'
0027
=
003D
"
0022
8_ a
0061
b
0062
c
0063
d
0064
e
0065
f
0066
g
0067
h
0068
i
0069
9_ j
006A
k
006B
l
006C
m
006D
n
006E
o
006F
p
0070
q
0071
r
0072
A_ s
0073
t
0074
u
0075
v
0076
w
0077
x
0078
y
0079
z
007A
B_
C_ A
0041
B
0042
C
0043
D
0044
E
0045
F
0046
G
0047
H
0048
I
0049
D_ J
004A
K
004B
L
004C
M
004D
N
004E
O
004F
P
0050
Q
0051
R
0052
E_ S
0053
T
0054
U
0055
V
0056
W
0057
X
0058
Y
0059
Z
005A
F_ 0
0030
1
0031
2
0032
3
0033
4
0034
5
0035
6
0036
7
0037
8
0038
9
0039

  Letter   Number   Punctuation   Symbol   Other   Undefined

Data stream[edit]

Data sent to the 3270 consist of commands, a Copy Control Character (CCC)[h] or Write Control Character (WCC) if appropriate, a device address[h] for copy, orders, character data and[a] structured fields. Commands instruct the 3270 control unit to perform some action on a specified device, such as a read or write. Orders are sent as part of the data stream to control the format of the device buffer. Structured fields are to convey additional control functions and data to or from the terminal.[a]

On a local non-SNA controller, the command is a CCW opcode rather than the first byte of the outbound display stream; on all other controllers, the command is the first byte of the display stream, exclusive of protocol headers.

Commands[edit]

The following table includes datastream commands and CCW opcodes for local non-SNA controllers; it does not include CCW opcodes for local SNA controllers.

Command Hexadecimal Graphic Function
local
non-SNA
EBCDIC ASCII
Copy[h]n/a F7 37 7 Copy from one device buffer to another, e.g., from a display to a printer
Erase All Unprotected[52]0F 6F 3F ? Erase all unprotected fields and reset modified data tags
Erase/Write[53]05 F5 35 5 Erase device buffer, then write WCC folloed by orders and data
Erase/Write Alternate[i][54]0D 7E 3D = Erase device buffer, set alternate size, then write WCC folloed by orders and data
No Operation 03 n/a n/a n/a May be used to retrieve pending status
Read Buffer[55]02 F2 22 2 Read entire device buffer, including attributes
Read Modified[56]06 F6 36 6 Read AID, cursor and, except for short read, modified fields from device
Read Modified All[57]n/a 6E 3E : Read AID, cursor and modified fields from device; no short read
Select[58]0B n/a n/a n/a Transfer data from device to control unit with channel disconnected
Select RB[j][59]1B n/a n/a n/a Select Read Buffer;
may only be chained to Read Buffer
Select RBP[j][60]3B n/a n/a n/a Select Read Buffer from Position;
may only be chained to Read Buffer
Select RM[j][61]DB n/a n/a n/a Select Read Modified
Select RMP[j][62]2B n/a n/a n/a Select Read Modified from Position
Select WRT[j][63]4B n/a n/a n/a Select WRT Command
May only be chained to a Write or Write Structured Field
Sense[64]04 n/a n/a n/a Retrieve error information after unit check
Sense ID[i][65]E4 n/a n/a n/a Retrieve control unit identification
Write[66]01 F1 31 1 Write WCC followed by orders and data
Write Structured Field[i][a][67]11 F3 n/a 3 Write Structured Field
For remote 3270s non-significant bits are set so that the command forms a valid EBCDIC (or ASCII) character.

Write control character[edit]

The data sent by Write or Erase/Write consists of the command code itself followed by a Write Control Character (WCC) optionally followed by a buffer containing orders or data (or both). The WCC controls the operation of the device. Bits may start printer operation and specify a print format. Other bit settings will sound the audible alarm if installed, unlock the keyboard to allow operator entry, or reset all the Modified Data Tags in the device buffer.

Orders[edit]

Orders[68] consist of the order code byte followed by zero to three bytes of variable information.

Order Hexadecimal code (EBCDIC) Description[11]
Byte 1Byte 2Byte 3Byte 4
Start Field (SF)1DAttribute character
(see Attributes)
Indicates the start of a field at the current buffer position and provides its attribute
Set Buffer Address (SBA)11Address byte 1Address byte 2Specifies a buffer address to become the current buffer position
(see Buffer addressing)
Insert Cursor (IC)13Positions the cursor at the current buffer position
Program Tab (PT)05Advances the current buffer address to the first position of the next unprotected field
Repeat to Address (RA)3CAddress byte 1Address byte 2Character to repeatStores the character in byte 4 in all buffer locations starting at the current buffer position up to but not including the specified address and sets the current buffer position to the specified address
Erase Unprotected to Address (EUA)12Address byte 1Address byte 2Fills all unprotected fields with nulls starting at the current buffer position up to but not including the specified address

Attributes[edit]

The 3270 has three kinds of attributes:

Field attributes[edit]

The original 3277 and 3275 displays used an 8-bit field attribute byte of which five bits were used.[11]: p.18 

  • Bits 0 and 1 are set so that the attribute will always be a valid EBCDIC (or ASCII) character.
  • Bit 2 is zero to indicate that the associated field is unprotected (operator could enter data) or one for protected.
  • Bit 3 is zero to indicate that this field, if unprotected, could accept alphanumeric input. One indicates that only numeric input is accepted, and automatically shifts to numeric for some keyboards.
  • Bit 4 and 5 operate in tandem:
    • '00'B indicate that the field is displayed on the screen and is not selector-pen detectable.
    • '01'B indicates that the field is displayable and selector-pen detectable.
    • '10'B indicates that the field is intensified (bright), displayable, and selector-pen detectable.
    • '11'B indicates that the field is non-display, non-printable, and not pen detectable. This last can be used in conjunction with the modified data tag to imbed static data on the screen that will be read each time data was read from the device.
  • Bit 7 is the "Modified Data Tag", where '0' indicates that the associated field has not been modified by the operator and '1' indicates that it has been modified. As noted above, this bit can be set programmatically to cause the field to be treated as modified.

Later models include base color: "Base color (four colors) can be produced on color displays and color printers from current 3270 application programs by use of combinations of the field intensify and field protection attribute bits. For more information on color, refer to IBM 3270 Information System: Color and Programmed Symbols, GA33-3056.": 1–7 

Extended attributes[edit]

The 3278 and 3279 and later models used extended attributes to add support for seven colors, blinking, reverse video, underscoring, field outlining, field validation, and programmed symbols.

Character attributes[edit]

The 3278 and 3279 and later models allowed attributes on individual characters in a field to override the corresponding field attributes.

Buffer addressing[edit]

3270 displays and printers have a buffer containing one byte for every screen position. For example, a 3277 model 2 featured a screen size of 24 rows of 80 columns for a buffer size of 1920 bytes. Bytes are addressed from zero to the screen size minus one, in this example 1919. "There is a fixed relationship between each ... buffer storage location and its position on the display screen."[11]: p.13  Most orders start operation at the "current" buffer address, and executing an order or writing data will update this address. The buffer address can be set directly using the Set Buffer Address (SBA) order, often followed by Start Field or Start Field Extended. For a device with a 1920 character display a twelve bit address is sufficient. Later 3270s with larger screen sizes use fourteen or sixteen bits.

Addresses are encoded within orders in two bytes.[73] For twelve bit addresses the high order two bits of each byte are set to form valid EBCDIC (or ASCII) characters. For example, address 0 is coded as X'4040', or space-space, address 1919 is coded as X'5D7F', or ')"'.[11]: pp.75–90  Programmers hand-coding panels usually keep the table of addresses from the 3270 Component Description or the 3270 Reference Card handy. For fourteen and sixteen-bit address, the address uses contiguous bits in two bytes.

Example[edit]

The following data stream writes an attribute in row 24, column 1, writes the (protected) characters '> ' in row 24, columns 2 and 3, and creates an unprotected field on row 24 from columns 5-79. Because the buffer wraps around an attribute is placed on row 24, column 80 to terminate the input field. This data stream would normally be written using an Erase/Write command which would set undefined positions on the screen to '00'x. Values are given in hexadecimal.

Data Description D3 WCC [reset device + restore (unlock) keyboard + reset MDT] 11 5C F0 SBA Row 24 Column 1 1D F0 SF/Attribute [protected, alphanumeric, display normal intensity, not pen-detectable, MDT off] 6E 40 '> ' 1D 40 SF/Attribute [unprotected, alphanumeric, display normal intensity, not pen-detectable, MDT off] SBA is not required here since this is being written at the current buffer position 13 IC - cursor displays at current position: Row 24, column 5 11 5D 7F SBA Row 24 Column 80 1D F0 SF/Attribute [protected, alphanumeric, display normal intensity, not pen-detectable, MDT off]

Extended Data Stream[edit]

[icon]

This section needs expansion. You can help by adding to it. (September 2020)

Most 3270 terminals newer than the 3275, 3277, 3284 and 3286 Support an extended data stream (EDS) that allows many new capabilities, including:

  • Display buffers larger than 4096 characters
  • Additional field attributes, e.g., color
  • Character attributes within a field
  • Redefining display geometry
  • Querying terminal characteristics
  • Programmed Symbol Sets
  • All Points Addressable (APA) graphics

See also[edit]

Notes[edit]

  1. ^ abcdefghWhen the Structured Field and Attribute Processing Option is available
  2. ^SNA only, causes an expedited flow attention signal even if the keyboard is locked.
  3. ^Pressing Cursoe Select has the same effect as clicking a Selector Pen at the current cursor location.
  4. ^For local non-SNA controllers. If attached to an SNA controller, it initiates a Read Modied or Short AID data transfer. For BSC controllers it causes a positive response to the next poll.
  5. ^Some, such as the GTE IS/7800, were not fully compatible.
  6. ^Models 2B and 3B only.
  7. ^Although the 3290 supports up to 16 explicit partitions, the ISPF SPLIT and SPLITV commands only support 4.
  8. ^ abcBSC only
  9. ^ abcNot available on 3271, 3272 or 3275
  10. ^ abcdeOnly available on 3274 D models and 3174
  11. ^ Later models added
    • Start Field Extended (SFE)
    • Modify Field (MF)
    • Set Attribute (SA)
    • Graphic Escape (GE)

References[edit]

3174Intro
3174 Establishment Controller - Introduction(PDF) (First ed.). IBM. April 1989. GA27-3850-0.
3270ColorPSS
IBM 3270 Information Display System - Color and Programmed Symbols(PDF) (First ed.). IBM. September 1979. GA33-3056-0.
3270Intro
3270 Information Display System Introduction(PDF) (Twenty-Third ed.). IBM. October 1988. GA27-2739-22.
3270DS
3270 Information Display System Data Stream Programmer's Reference(PDF) (Fifth ed.). IBM. December 1988. GA23-0059-4.
3270CS
IBM 3270 Information Display System Character Set Reference(PDF) (Tenth ed.). IBM. April 1987. GA27 -2837-9.
3274Desc
IBM 3270 Information Display System 3274 Control Unit Description and Programmer's Guide(PDF) (Third ed.). IBM. March 1985. GA23-0061-2.
RFC1041
J. Rekhter (January 1988). Telnet 3270 Regime Option. doi:10.17487/RFC1041. RFC1041.
RFC1576
Jon Penner (January 1994). TN3270 Current Practices. doi:10.17487/RFC1576. RFC1576.
RFC2355
Bill Kelly (June 1998). TN3270 Current Practices. doi:10.17487/RFC2355. RFC2355.
RFC6270
Mykyta Yevstifeyev (June 2011). The 'tn3270' URI Scheme. doi:10.17487/RFC6270. RFC6270.
  1. ^ ab"DPD Chronology 1971". ArchiveIETF. IBM. January 23, 2003.
  2. ^"What is 3270 (Information Display System)".
  3. ^"Cleo 3270 Support Documentation".
  4. ^"3270 clusters". Computerworld. May 13, 1985. p. 103.
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  10. ^Klaus Brandstaetter. "3270 -Brief History". HOB Techtalk. Retrieved August 19, 2015.
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  12. ^admin (February 2, 2017). "IBM 3277 Terminal". VintageComputer.ca. Retrieved June 11, 2021.
  13. ^3270ColorPSS, pp. 3-1–3-6, Chapter 3 Color Capability.
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  21. ^"Charcole/Zmachine3270". September 13, 2021.
  22. ^https://www.youtube.com/watch?v=U6nj1dibTCA
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  28. ^Jim Brown (February 16, 1987). "Telex beefs up its lineup". Network World. Vol. 4 no. 7. p. 27.
  29. ^Ken Hornstein (January 10, 1991). "IBM 3179G: To beep or not to beep". Newsgroup: comp.terminals.
  30. ^"Object: 11000554 IBM 3179G, producer: IBM, serial number: 55-N1186, dating: 1985-11-01 - 1985-11-30, received: 2009-11-18, Description: IBM 3179 - Display station (color or graphics) for IBM 3270". Danish Data Historical Society Wiki.
  31. ^"Software & Services:Productivity Aids". Computerworld. Vol. 19 no. 28. July 15, 1985. p. 62.
  32. ^Greg Price (January 2008). "3270 Graphics". Prycroft Six.
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  37. ^"Oec". October 4, 2021.
  38. ^"Coax". October 16, 2021.
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Sours: https://en.wikipedia.org/wiki/IBM_3270

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