Copyright (c) Hyperion Entertainment and contributors.

Difference between revisions of "User Interface Style Guide"

From AmigaOS Documentation Wiki
Jump to navigation Jump to search
Line 12: Line 12:
   
 
For the serious programmer who wants to take full advantage of the Amiga's impressive capabilities, the '''Amiga User Interface Style Guide''' is the definitive source of information on designing the front end to Amiga applications.
 
For the serious programmer who wants to take full advantage of the Amiga's impressive capabilities, the '''Amiga User Interface Style Guide''' is the definitive source of information on designing the front end to Amiga applications.
  +
  +
[[UI Style Guide Gadgets]]
   
 
[[UI Style Guide Menus]]
 
[[UI Style Guide Menus]]

Revision as of 18:35, 28 June 2012

WIP.png This page is currently being updated to AmigaOS 4.x. Some of the information contained here may not yet be applicable in part or totally.

Contents

Introduction

The Amiga User Interface Style Guide provides an introduction to, and in-depth explanation of, the issues programmers must understand to create the best user interface for Amiga applications. The guide includes:

  • the design principles and metaphors underlying Intuition, the Amiga's graphical user interface;
  • guidelines for programs that use the Amiga's high-performance ARexx and Shell interfaces;
  • detailed specifications on how to arrange the elements of the Amiga's user interface to make applications consistent, powerful, and easy to use.

For the serious programmer who wants to take full advantage of the Amiga's impressive capabilities, the Amiga User Interface Style Guide is the definitive source of information on designing the front end to Amiga applications.

UI Style Guide Gadgets

UI Style Guide Menus

UI Style Guide Workbench

UI Style Guide Shell

UI Style Guide ARexx

UI Style Guide Keyboard

UI Style Guide Data Sharing

UI Style Guide Preferences

UI Style Guide Glossary

Preface

Like any written work with a distribution wider than a personal letter, this style guide attempts to be many things to many readers.

After much deliberation we developed the following profiles of the average reader: a current Amiga developer working alone or with one partner; a developer from another platform who would like to develop for the Amiga; a first-time developer; a graphic artist designing a user interace for a developer; a team of developers working for a medium-sized company...the list goes on.

So our intention was to write a manual that introduced the Amiga from basics - in terms a non-technical reader could understand. The GUI sections were especially targeted for the layman. Other sections, such as the ARexx chapter, were structured more like reference guides since they will likely be used by readers with more of a technical background.

Release 2 Assumed

This book was written with Release 2 of the Amiga operating system in mind. All functions, examples and elements herein refer to Release 2.

Amiga Mail Updates

Of course this manual, especially in its first edition, isn't the final word on style for Amiga applications. Interim updates may be published in Amiga Mail, the bi-monthly newsletter for Amiga developers.

nyone may subscribe to Amiga Mail. If you live in North America and want more subscription information, send a self-addressed stamped envelope to:

   CATS - Information
   1200 Wilson Drive
   West Chester, PA 19380-4231

Elsewhere, write to your local Commodore office.

Introduction

The purpose of this book is to describe how the user interface of a standard Amiga application should look and operate. It is intended to be read by current developers as well as developers who are considering writing and/or designing application software for the Amiga.

This book assumes some familiarity with computers and their interfaces in general, and with the Amiga's graphic user interface (GUI) in particular, but, for the most part, you do not have to be a programmer to understand the material.

Only the behavioural guidelines for an Amiga application are presented here. The details of how to implement them are covered in other volumes of the Amiga [Technical] Reference Series.

What's In This Book

This document provides the following information:

  • the benefits of a standard user interface;
  • an overview of the components of the Amiga user interface;
  • specifications showing how to use the components of the Amiga user interface to create a standard Amiga application.

The Amiga hardware and system software provide the basic building blocks of the user interface: a mouse and pointer, windows and icons, menus and requesters and more. But it is your software that combines these elements and ultimately determines how the machine will be used.

Non-Stifling Standards

In one sense, this style guide can be considered a book of rules for you to follow when designing application software for the Amiga. It describes the best ways to combine and use elements of the Amiga system software to communicate with the user.

Unlike rule books such as a state's driving code or a company's employee handbook, the style guide's originators don't suggest penalties for violators. In fact, penalties of that sort would be counterproductive. The aim of this book is to establish standards for Amiga applications without stifling creativity. New versions of the Amiga and new types of applications will probably require refinement and expansion of these standards in the future.

That's not to say no penalties exist. In a free, competitive market the only real penalties are financial and self-inflicted. This book has been created under this premise: standardized software will be better for reasons described later in this chapter, and thus, in a competitive situation it should sell better.

In short, these standards were devised to improve your program and the Amiga platform in the eyes of the user.

This manual describes the best ways to communicate with the user.

A Point on the Horizon

No one expects every application to conform to every one of the rules and guidelines in this manual.

These rules have not been created in a vacuum. Many of the standards discussed in this manual have been culled from experience - experience gained through the multitudes of Amiga applications released since the Amiga's inception. The writers of this document first looked at what has worked best in specific applications and then tried to transform that raw experience into a standard, efficient and accepted way to do things on the Amiga. The trick was to come up with ideas that worked well and would work well in a variety of situations.

Clearly there will always be exceptions to these rules. Even applications created by Commodore may not comply with every idea in this book.

The hope is that the idealized application described in this manual will be like a point on the horizon you keep in sight throughout the development of your very real program.

The rules in this manual describe an idealized application not yet created.

Some Perspective

The user is the most important part of any application. In the past, improving the speed or increasing the capacity of application software has been a major focus of computer programmers. The idea of emphasizing the user interface of a computer system over its performance and capacity is a relatively recent innovation in computer history.

Historically, most users of computer systems were technical people who could tolerate the exacting requirements of expensive computer hardware and their "unfriendly" application designs. Complex commands had to be remembered and typed into a terminal in the proper sequence and thus required these early computers to have a professional staff in order to run them. This made sense because the computing hardware of that era was much more expensive than human labour. The user was there to serve the needs of these expensive machines.

The advent of microprocessors and the long-term trend to lower-priced computers has changed all that. Today's computer user is trying to get work done. The user probably does not know much about computers and may not even know how to type. The human-machine interface has been reversed, and now computers must serve the needs of the user.

The User's Needs

The user's needs are simple:

  • the operation of the software should be predictable;
  • learning the software should be easy; the software's functions should be easily scannable;
  • the software's operations should be consistent throughout tools, applications and similar objects;
  • feedback should be provided to the user, so he knows what has happened and what he can do;
  • the software should adapt to the users's level of experience.
The user needs: predictability, intuitiveness, accessibility, consistency, feedback, adaptability and simplicity.

Consistency

The user's needs listed above really all combine into one: consistency. If your interface is consistent with the model, it becomes predictable; if it can be scanned easily, it provides feedback; if it provides feedback in a reasonable manner, the user always feels comfortable and can master increasing levels of complexity.

Consistency in a user interface allows the user to apply previously learned knowledge to each new application. The user will spend less time figuring out how to get work done, and can therefore be more productive. Learning a new application is much easier if it works just like one the user already understands.

The Amiga is a multitasking computer that allows the user to run more than one application at a time. This makes consistency even more important because the user can easily switch from one application to another. Consistency between applications allows the user to make this switch without having to make a "mental jump" between one way of working and another.

Following standards also makes new applications more familiar; thus the user will probably be less afraid of inadvertently wiping out data or making other non-recoverable mistakes.

Once again: predictability, intuitiveness, accessibility, consistency, feedback, adaptability and simplicity.

Filling the Needs

A graphic user interface (GUI) is current the best method available for simplifying the user interface and meeting the needs of the user.

Amongst the first computers to use GUIs were the Xerox Star and Apple Lisa. Based on pioneering research performed at the Xerox Palo Alto Research Centre in the 1970s, these computers allow the user to issue commands with a mouse and pointer. Resources represented by graphic icons can be activated by pointing to them with the mouse, and actions can be performed through mouse-activated menus.

GUIs provide immediate feedback and scanning ability, so users can tell what their options are and don't have to memorize commands. They allow for enormous growth and adaptability of an application, because levels of functions and commands can be buried yet still be graphically accessible. In short, they provide a user interface that lets the user operate, without learning, the computer - in much the same way that the average driver doesn't need to be versed in internal combustion.

By utilitizing standardized tools and objects provided in the GUI, programmers are less likely to invent needlessly different ways of doing things. The interface becomes predictable and consistent.

The Amiga

The Commodore Amiga is a further refinement of this philosophy that puts the needs of the user foremost. Like many other systems, the Amiga has a GUI with a mouse, pointer, windows and menus which makes it easier for users - especially beginners.

But the Amiga also offers two other built-in interfaces: a text-oriented interface, the Shell, an an inter-process scripting language, ARexx.

Together, these three interfaces provide a powerful and flexible environment for both the novice and the expert. In fact a philosophy for the design of the Amiga user interface might be "Power to the User".

Developer-Oriented Benefits to Standarsd

The obvious beneficiary of a good user interface design is the user. He can pick up a new application and learn how to use it, scan its functions to see what it does, apply old knowledge to cut the learning curve, and so on.

But a disciplined approach to designing and building an application also has enormous benefits for the software developer.

Market Acceptance

Marketing is simplified when a product "belongs" in a comfortable environment, sharing features and tools with other popular applications. A user trying out a demo version of your software and your competitor's software in a store rarely has the time to learn a new way of doing things. A familiar environment and controls that work in a predictable manner will allow him to experience what you are really selling - how well your application does its job.

Some real market-oriented reasons exist for standards too.

Coexistence

By following the recommended guidelines, applications acquire the ability to inter-operate, thereby increasing each application's value. When applications can inter-operate and share data as well as they can on the Amiga, users can combine in off-the-shelf software packages to create custom solutions for the work they want to do with the Amiga.

Secondly, it is important that applications behave well in a multitasking environment. Sticking to the standards assures peaceful coexistence.

Easier Creation and Maintenance

Design is also simplified when you follow standards.

For one thing, Release 2 of the operating system features toolkits such as GadTools which provide you with pre-coded elements of the GUI. Even when elements aren't provided "prefab", standards allow you to spend less time devising and designing environments and more time working on the actual operations of your program. It also allows you more time for testing. For instance, if you are designing a CAD program, chances are that it is computer-aided design which really interests you. Instead of spending a lot of time working on gadgets to control your application, you could be spending more time working on the actual CAD operations.

Also in the absence of any stanards, progress is more difficult because each application will require an individual upgrade plan.

Power to the User

Clearly, this book was created to sell the idea of standards as much as to simply present those standards. But the reasons for those standards goes beyond an innate need for order originating from some corporate boardroom. The reasons set forth here have been set forth honestly in an attempt to provide more power to the user. This book intends to make clear what features of the user interface will help to make the interface simple - and predicatable - and consistent - and adaptable - and intuitive. This in turn should improve the Amiga market for all of us.

Some Basics

The Amiga is a true multitasking system with three built-in interfaces:

  • a graphic user interface (GUI);
  • a command line interface [CLI] (the Shell);
  • a scripting language that can handle inter-process communication (ARexx).

Of these three interfaces, the GUI dominates. By default, the Amiga presents the user with a graphic interface, Workbench, upon startup. Likewise, even a simple Amiga application will generally present a graphic interface of some sort; text editors, for instance, usually include mouse-driven gadgets and menus.

In addition to the GUI, users can control the Amiga through the Shell. The Shell is a text-based interface that preserves the best features of the "old way" of operating computers - by typing in commands. The Shell trades the GUI's ease of use for a finer level of control and greater power.

The GUI is the Amiga's default interface.

With Release 2 of the operating system came a third way of interfacing with the Amiga: inter-process communication (IPC) via ARexx. Simply put, ARexx is a scripting language, but it also acts as a central hub which applications can use to send data and commands to each other. ARexx allows software created by different companies to interface, letting the user create custom applications by integrating off-the-shelf software products. For example, with ARexx it is possible to set up a telecommunications package to dial an electronic bulletin board, download financial data, and then pass that data to a separate spreadsheet package for statistical analysis - without user intrevention other than the original scripting. Arexx is based on REXX, an IPC language used in various forms across many platforms.

Many users consider the choice of interface to be one of the best features of the Amiga. Not only does it offer the user the freedom to choose his favorite means of interacting with the Amiga and with your program, it's also an effective way to provide the right tool for the job and user's level of expertise. For these reasons, your application should support all three interfaces in the manner described in this manual.

Support all three of the Amiga's interfaces.

Basics of the Operating System

The following are basic concepts to keep in mind throughout your design work on the Amiga:

Design for the Novice

Designing for the lowest common denominator does not mean your application is doomed to mediocrity. In most cases it just means pondering a little longer on how to solve a problem or present a procedure so that almost anyone can grasp it easily. Even power users appreciate it when you give them simple solutions for such things as hard disk installation or navigation through procedural steps. Conserve your user's energy for creative tasks.

Conserve the user's energy for creative tasks.

Let the System Work for You

In general, if the system will do something for you, let it. For example, GadTools provides pre-programmed gadgets for use in your application. If one of these gadgets suits your needs, use it instead of coding your own. Two other examples of using this built-in support are:

  • using Intuition (see #Basics of the Gui) to provide many functions of your application's GUI;
  • using DOS ReadArgs() to provide support for argument passing.
If the system will do something for you... let it.

The Amiga's Resources

Remember that the Amiga is a multitasking system. Any time you allocate a part of the system for your use, you prevent other tasks from using it.

Try your best to economize your use of shared resources. If possible, only obtain a resource when needed and free it as soon as you are done. This applies to just about every computing activity your application can perform. There are only limited amounts of RAM, serial ports, printers and disk drives for all applications to share.

Your application should provide controls that allow the user to temporarily suspend usage of any non-shareable resource it may use, such as the serial or parallel device. For example, a MIDI application should allow the user to suspend serial port usage so he can switch to a terminal package and download a new sample without having to exit the MIDI application.

Speech and Sound

Speech and sound can be excellent ways to provide feedback to the user, especially if the user is visually impaired or if your application includes lengthy processes during which the user might walk away from the system.

However, a significant number of users may be hearing impaired, so don't use sound and speech as the only cue. Use it in conjunction with other cues such as position, size and rendering.

Sounds can be annoying. Provide a means for the user to turn off sound [and/or] speech.

Provide a means for the user to turn off sounds and/or speech.

Controls

It may be a good idea to provide additional controls so the user can modify the speech or sound in your program. Consider this if speech/sound is integral to the application. If they are secondary, you may just be over-complicating the controls in your program.

Closing Down the Workbench

If your application needs more memory than is available, it may attempt to close Workbench.

If your application does this, it should allow the user to re-enable Workbench from a menu item if more memory becomes available. A preference setting should also be made available so the user can specify that Workbench should always be closed (or not) on entry to the application.

If your application closes Workbench, it must reopen it again before exiting.

Defining Your Basename

A basename is a short, one-word name that you assign to your application. It's usually (and preferably) the same word as the name of your program's executable - the word a user types into the Shell in order to run your program.

All user-accessible names from your program should be built from the basename. These include such things as ARexx ports, public screen names, and configuration settings names.

For example, a database program called MondoBase may have the basename of MBase. Users running the program from the Shell would type MBase on the command line. The program may open on a public screen named MBase.1 with an ARexx port of the same name.

Basenames should be logical to the user, easily remembered and short. Making it too short, however, could raise the likelihood of conflicts with other programs. If MondoBase's basename were simply M, it could conflict with MusicBoard's basename.

Basics of the GUI

For a sytem with three interfaces, a relatively large section of this book is devoted to the GUI. This isn't surprising when you think about the popularity of GUIs and the fact that a GUI designer needs to worry as much about form as function.

The Amiga GUI has two parts: Intuition and Workbench. As a developer, you will be more concerned with Intuition. It consists of the function libraries and tools you will use to create and run GUIs for your application.

Before talking specifically about the elements of the Amiga GUI (in the next five chapters), some basic elements and techniques need to be discussed.

Metaphor

One of the reasons for the success of GUIs is that they greatly reduce the need to memorize commands and command structures. One technique used to accomplish this is the use of metaphor - GUIs try to mimic the traditional work world in some way.

By presenting what can be frighteningly complex workings as familiar, real-world objects and activities, even novice users can understand and use a computer quickly. Hierarchical filing systems become drawers. RAM caches that spool to disk become clipboards. Pulling an ASCII clip from a buffer into a document becomes pasting.

To employ a metaphor in your application, look for some common physical system that is analogous to the behaviour of the application.

For example, a 3-D modelling package could be designed to work on wire-frame objects as though they were actually physical objects. The user could rotate the object by "grabbing" a corner of the object and pulling just as one would grab the corner of a real object.

Of course, it is not always necessary or even desirable for every interface to be modelled after some physical object.

Object-Action

Most of the popular GUIs today encourage the use of object-action methodology. This simply means that first the user selects the thing he wants something done to, then he selects what he wants to do with it. For example, first he clicks on the object he wants deleted then he chooses the delete function, rather than choosing delete then clicking on the objects to be deleted.

This is done mainly to prevent modality. Modes are generally avoided in GUIs because they can easily become restrictive and confusing to the user. If the user were to select delete before selecting the object(s), he would be in delete mode and could accidentally delete something he wanted to save - especially if he were to go away and come back later. There is also the problem of how to indicate the last object to delete. In general, any mode is limiting and should be avoided if possible.

Focus

When a user is looking at a computer screen, he is most likely to concentrate his attention on one particular spot. In a word processor, he will most likely be looking at the cursor. Or in a CAD program, the focus may be the currently selected line or polygon. Very often, the pointer itself is the focus.

It's important to identify the user's focus because this can be a very effective channel of information. For example, you can animate or change the appearance of the focus object to indicate some change in the program's state. The wait or busy pointer is an example of this. If the wait pointer's clock imagery appeared in the title bar instead of on the pointer, it would be far less effective.

Feedback

Users expect to see an immediate reaction to every action. Even if the action will take some time, they expect to see some indication of "I'm working on it" such as the normal pointer changing to a wait pointer.

Try to provide feedback through as many appropriate media as you can. For example, when a user drags a note in a music package, he could hear the pitch change as well as see the note move. After all, the visual graphic of the note is only a representation of the sound of the note - and that's what the user is really interested in.

It's usually easy to provide instantaneous feedback to simple actions, but for more complex or time-consuming actions, a surrogate feedback may be necessary. A familiar example of this is the way windows are dragged on the Amiga - you don't drag a window, you drag an outline of it. Another example of feedback on time-consuming activities is the word processor that refreshes just the line being worked on as the user is typing, and the whole display whenever there is some processing time to spare. This gives the illusion of responsiveness, which from the user's point of view is as good as the real thing.

When the user attempts an action, provide feedback.

Color

Color is a very powerful medium of communication. Be conscious of what message you are communicating.

Keep in mind that simple images with fewer colors usually work better than complicated colorful ones. When choosing default colors for an application, do not use intense combinations like blue/yellow, red/green, red/blue or green/blue. Use subdued colors instead of fully saturated colors. Color can set the mood of your program and that mood should be one that the user can live with for extended periods of time.

Give Controls

For all the screens you set up within your application, provide the user with the ability to load, save and edit the colour palette. When the user makes a change to the color palette, examine the new palette to assign the appropriate colors for rendering.

Color as a Cue

Be consistent when using color to indicate meaning. Window backgrounds should be in the background color, text in the text color and headings in highlighted text.

Beware of using color alone to convey information - especially in small areas of the display. Some users may work on a monochrome display. Keep in mind also that many people are color blind. For these reasons, try to reserve the use of color only as an extra cue, used in conjunction with other cues such as position, size and rendering.

Don't use color as the sole cue - some users work in monochrome.

Check Visibility

The Amiga's Preferences editors allow users to run their applications in two colours. Certain high-resolution monitors have only grey-scale displays. Because of these cases, if your application can open on Workbench or a public custom screen, you should check that your graphics and text can be read on a monochrome or grey-scale display.

Elements should be visible, should continue to provide visual feedback, and should be recognizable as the same element whether in color or monochrome. Basically, you should make sure that all your functionally significant colors contrast with adjacent functionally significant colors. It's more a matter of the color's brightness or luminance than the actual color itself.

Commodore's high-resolution grey-scale monitor (A2024), for instance, uses patterns made up of its four basic greys to make more shades when running in medium and low resolutions. At these resolutions, things look best if you choose a color that maps to a solid, not patterned, grey. But these colors are not obvious.

One palette that produces solid greys follows:

   Colour 0:  Light Grey, RGB=10,8,6
   Colour 1:  Black, RGB=0,0,2
   Colour 2:  White, RGB=15,15,15
   Colour 3:  Dark Grey, RGB=7,7,9

Fonts

Users can specify which font the system should use for the Workbench icon font, the screen font (the preferred system font) and the system default font (a default monospaced font). These are selected with the Font Preference editor in the Workbench's Prefs drawer.

Your application should try to adjust itself to whatever size the user may select. Menus, windows, requesters and gadgets must all be adjusted to allow the various text sizes to fit.

Keep in mind that the chosen font may be monospaced or proportionally spaced, and not every application can handle a proportional font. A spreadsheet, for example, depends on the font being monospaced to properly handle the columnar data it manipulates. If your application needs a monospaced font it should honour whatever the user has chosen to be the default system font - that font is guaranteed to be monospaced.

If your application can handle a proportional font, however, it should honour whatever the user has chosen to be the screen font.

Internationalization

Since the Amiga is sold in a world market, internationalization is an important design factor in your application. One of the most important and fundamental issues to consider when thinking about internationalization is the difference in length of the text between English and any other language.

English is one of the most terse language, and when converting English to, say, German the text the text is bound to grow 30-50% in size.

Another thing to keep in mind is the desirability of building a text table that is centrally located so that it can be adjusted by the user. Do not scatter embedded text throughout your application; consider putting it in a file instead. This way, the text can be easily localized by updating one central table, or even by loading a new text table from disk.

Don't make every text item adjustable. For instance, if your application incorporates a procedural language or ARexx keywords, do not allow these special words to be localized. To do so would severely hurt the ability to share scripts between international users.

If your application provides database-like operations that involve money, numbers, telephone numbers and addresses, remember that these sort of fields vary in usage from country to country. The table below lists some of the differences.

International Formats

Language Date Time Hours Decimal Thousands Separator
American English mm/dd/yy hh:mm:ss 12 hr period comma
Australian English dd/mm/yy hh:mm:ss 12 hr period comma
British English dd/mm/yy hh:mm:ss 12 hr period comma
Canadian French dd/mm/yy hh:mm:ss 24 hr comma space
Danish dd/mm/yy hh:mm:ss 24 hr comma period
Dutch dd-mm-yy hh:mm:ss 24 hr comma period
Finnish d.m.yyyy hh.mm.ss 24 hr comma space
Flemish dd-mm-yy hh:mm:ss 24 hr comma period
French dd.mm.yy hh:mm:ss 24 hr comma space
German dd.mm.yy hh:mm:ss 24 hr comma period
Italian dd-mm-yy hh:mm:ss 24 hr comma period
Norwegian dd-mm-yy hh:mm:ss 24 hr comma space
Portuguese yy/mm/dd hh:mm:ss 24 hr comma space
Spanish dd/mm/yy hh:mm:ss 24 hr comma period
Swedish yy-mm-dd hh.mm.ss 24 hr comma space
Swiss French dd.mm.yy hh:mm:ss 24 hr period apostrophe
Swiss German dd.mm.yy hh:mm:ss 24 hr period apostrophe
It is best to build internationalization into your application from the start.

The 3-D Look

Release 2 of the Amiga operating system features a three-dimensional look to its GUI. Whenever possible, elements are drawn so that light appears to come from the upper left of the display with shadows cast to the lower right. This gives the illusion of depth.

The outside border of a raised object has thin lines forming the top and left sides; dark lines for the bottom and right sides. Reverse these colours for a recessed image.

Using this simulated depth, you can make images appear to be standing out or recessed in the display, thus giving the user a context cue at the same time.

Fig 2.1: Raised and recessed images.

Fig 2.2: Closeup view of 3-D box corner with a pixel grid superimposed.

If an icon or gadget appears raised, this means it is available for use or modifiable. If its default appearance is recessed, this means it is unmodifiable or for display purposes only.

Another context cue: when a user clicks on an icon or a button-like gadget, it should change from a raised image to a recessed, highlighted image. This goes along the basic idea of providing feedback that the attempted action (clicking on an action gadget, for example) has worked.

Objects that highlight should show distinctly different imagery between highlighted and non-highlighted states. One convention used by Workbench is to display the image in complementary colors.

Ghosting

When a control is unavailable for selection, it should be obviously unselectable. Do not allow the user to select something that does nothing in response.

Fig 2.3: Examples of non-highlighted and highlighted gadgets.

Intuition will automatically display a ghosting pattern - a grid of dots in the "shadow" colour - over an unavailable control. If, however, you need to do it manually, follow the example shown below:

Fig 2.4: A normal and enlarged view of a ghosted gadget.

GadTools

If you are developing for the Release 2 environment, you don't need to worry about incorporating the 3-D look into your gadgets - GadTools will do it for you. GadTools is a toolkit that supplies pre-programmed, standard application gadgets for use in your application.

Whenever possible you should let GadTools work for you. Even beyond the standardization of function it provides, this tool frees you to spend more time and effort on the crux of your application.

The System as your Guide

In the absence of any system-provided support, or if the special needs of your application require you to build your own elements, use existing system elements as a general guide to style and function.

The Mouse

Having graphics on the screen that represent something to the user is good, but you need a way for the user to interact with those graphics. Although a number of devices can be used to do this on the Amiga (including a touch screen, a joystick or even the keyboard), most often the user will interface with the GUI via a two-button mouse.

Using a mouse can become a seamless, unconscious act for most users in the same way that a typist can type the letter "k" without consciously thinking: "Let's see...right hand, third finger from the right." Typists are able to do that because typewriter manufacturers make their keyboards consistent. Likewise, it is important that your software follows rules of mouse usage so that the GUI is "mechanically" consistent.

The standard Amiga mouse has two buttons: the selection button (left) and the menu button (right). A scroll wheel acts as a middle button as well as vertical scrolling.

Style2.5.png

The selection button (the left mouse button) selects or operates gadgets, icons, windows and screens. It can also be used to select special objects unique to your application (eg. the note object in a music package) or to set the pen "down" in a drawing operation.

The menu button (the right mouse button) actives the menu system and allows the user to choose a menu item. The menu button may also be used to abort a selection button operation. For example, the user is dragging a window around by holding down the selection button and moving the mouse. If he decides that this action was a mistake and wants the window back where it was originally, he can press the menu button and the window should snap back to its original position.

Follow basic rules for the mouse so that its use becomes instinctive.

Activating Tools

Clicking on a tool gadget, such as the Fill tool in a paint package, with the selection button should activate the tool. If appropriate, a double-click could activate a settings editor for the tool so that the user can fine-tune the way the tool works.

Triggering a Process

When the selection of something will trigger a process, the action should occur on the release of the mouse button - not the downpress. This way the user can change his mind about the operation and move the mouse away from the object before he releases the button.

Actions should be triggered on the release of the selection button.

Current Objects

When an object is selected, that object is considered to be the current object. Some examples are: the highlighted section in a CAD program, a note in a music program, or the character under the cursor in a word processor. When the user chooses an action (via a menu item, for example) that action is carried out on the current object. For example, in a desktop publishing program the user can click on a text box and make that the current object. If the user selects an action such as "erase" or "copy", that action is performed on that text box.

Shift Selecting

In some instances, a user can select more than one item at once by using shift selection. The user clicks on an item with the selection button. While holding the Shift key down, the user can then select any number of objects. The result is called a @{i}selected group@{ui}. Some examples of objects that could be grouped are: columnar text boxes in a DTP program, notes in a music program and text items in a list.

Some actions that can be carried out on current objects will still apply to a group, such as copy or delete, but others may not. For example, you can have a requester showing the attributes of a current object but it would be difficult to have such a requester for a group of dissimilar objects.

Dragging

Objects can also be grouped by dragging. Dragging, a common mouse operation on many platforms, involves holding the selection button down while moving the mouse. There are two types of dragging: contiguous and non-contiguous.

A good example of contiguous dragging can be found in a word processor. The user clicks on a letter then, without releasing the selection button, moves the cursor somewhere else in the text. The first letter he clicked on becomes the "anchor" point and all the text between the anchor point and the point where the selection button was released should be highlighted. The highlighted text is now a selected group.

Objects can also be grouped contiguously by the use of the marquee. When the mouse is dragged on Workbench, for example, an animated dotted line, the marquee, marks the area covered by the mouse. All the icons within the marquee will be selected.

Fig 2.6: Grouping by using the marquee.

Less common is non-contiguous dragging. One example of this is a program that allows the user to drag select a section of text and then deselect individual lines by clicking on them. The deselected line can be in between two selected lines.

In both styles of dragging, the display should scroll automatically if the mouse goes beyond the boundaries of the display region.

Four Ways to Highlight Text

There are four methods you can use in your program to highlight text: dragging (see the previous section), extended selection, multiple-clicking and selecting all.

With extended sselection, the user clicks the cursor in the text (this becomes the anchor point), then shift-clicks the cursor at another place in the text. The area between the anchor point and where he shift-clicked will be highlighted. Note that the user can adjust the window's scroll bar between clicks and thus highlight a very wide range.

If you employ the multiple-click method, the user can select a word by double-clicking on it, or select a paragraph by triple-clicking on it. (Note: these are not timed clicks.) A "word" can be defined simply as anything with spaces around it, or you can use a more complex definition. A fourth click should revert back to a normal cursor.

Selecting all would feature a menu item that would select all the characters in the document. This action shouldn't select the document as well; that is, any actions chosen for the selected group should not act upon the document itself. For example, if the user chooses select all and then erase, all the characters should vanish from the document's window but the window should remain.

Current Objects vs. Selected Groups

Current objects and selected groups should not co-exist in the same application. In other words, no matter how many projects your application may run simultaneously, there should be only one current object or one selected group at any one time. If the user has a current object, then creates a group through shift selection, there should no longer be a current object.

There should only be one current object or one selected group at one time.

Selection Context

Confine the user's ability to select to a single context or "level". For example, don't let the user select documents and characters at the same time. You can allow him to select any numbers of characters in a document, or any number of documents, but not both at once.

The Pointer

The Amiga uses a pointer that the user can redesign.

The default pointer looks like this:

Fig 2.7: The default pointer with a superimposed pixel grid.

Your application can use a custom pointer instead of the standard. The arrangement of color intensity in your custom pointer should be consistent with that of the standard pointer - especially since two different applications can share the same screen.

Technical note: here's how the colours should be set up:

   Colour 0   Transparent
   Colour 1   Medium intensity
   Colour 2   Darkest
   Colour 3   Brightest

The pointer should be framed by either color 1 or color 3 to ensure its contrast on most screens.

Waiting

When your application is busy with a task and temporarily cannot accept input, another pointer, known as a wait pointer, appears.

Currently the wait pointer used by Workbench is not accessible by developers. Shown here is a pixel-by-pixel view of Workbench's wait pointer if you want to make yours look similar.

Fig 2.8: Workbench's wait pointer with a superimposed pixel grid.

If the wait is for a measured amount of work, such as in a ray-tracing program, your application should provide a requester that shows the progress of the activity. The progress requester should have a gadget on it allowing the user to stop the activity.

Fig 2.9: A sample progress requester indicating the progress of a time-consuming activity.

Use a progress requester like the one shown on the previous page instead of an animated pointer to indicate that the application is busy. Here's why: A man is rendering a simple object with a ray-tracing package. While waiting for that to finish, he decides to write a letter in a word processing package that opens on the same screen but in a different window. If the ray-tracing program displayed a progress requester, he could see when the rendering was done. But if it used an animated pointer, that pointer would disappear when he clicked in the word processing window.

Don't tie a wait pointer to the progress requester (i.e. when the user clicks on the progress the pointer changes to a wait pointer). If you do, the user may think he can't activate the "Stop" gadget.

Don't show multiple cycles in the same progress bar. For example, if the progress bar reads "Calculating...", fills up and then reads "Rendering...", you've falsely built up the hopes of the user. Instead, use multiple bars if knowing the progress of each task is important to the user, or a single bar that is filled only once if knowing when the job is done is all that is important.

Pointers with Purpose

Pointers can be used to give the user a context cue.

For instance, if your application supports different tools, such as the sketch tool or the fill tool in a paint program, the pointer imagery can reflect the currently selected tool.

Or, if your window is divided into distinct areas with different uses, it might be more appropriate to have the pointer image reflect its current purpose based on its position. The pointer for a CAD program, for example, might be a cross-hair while it is over the drawing area, but turn into the standard arrow when it is over the control panel area.

Resolutions

The Amiga hardware and software offers a variety of resolutions for the user to choose from. The resolution refers to the number of pixels in that mode. For instance, a common Amiga resolution of 640x200 refers to the number of pixels in height and width, respectively.

If you allow the user to choose resolutions, make sure that your GUI fits comfortably on whatever screen the user has chosen. A good way to do this is by checking it on a least common denominator resolution - a non-interlaced, non-overscan NTSC screen (640x200) with a Topaz 8 font. You don't need to set these as defaults; just make sure that what you create will look and function normally when set to these settings.

If your original target audience will most likely be using PAL, it's still a good idea to design with a 640x200 NTSC screen in mind so your distribution isn't limited later.

Respect the choices the user has made in his Preferences setup for resolution and how large a display should be set up.

Design your GUI on a 640x200 screen with the Topaz 8 font.

Technical note: If your application is text-oriented, make sure you use the text overscan setting. If it's graphic-oriented, use the "standard" overscan setting. The user can set both of these by using Workbench's Overscan Preferences editor.

Screens

By organizing raw data into neat and friendly metaphors, GUIs make using a computer more intuitive and comprehensible. Still, sifting through the many possibilities in an effort to get to a desired task can often lead the user to wonder: "Where am I?" and "What should I do next?" The fact that the Amiga multitasks - that is, it allows the user to run a number of applications at the same time - only increases the need for strong context cues.

When your application is run, it indicates the new context by either opening up in a window or on its own screen. Thus, screens and windows provide the main cues that tell the user where they are at any given moment.

Defining Screens

Screens are unique to the Amiga. Other platforms have a single environment filling the monitor view or perhaps extending beyond that in height and width. On the Amiga, a user can have multiple screens, each an environment unto itself with its own palette, resolution and fonts - running at the same time.

Typically, screens are at least as wide as the monitor display and have a single title bar at the top of the screen which is shared by all the applications that operate within that screen. It is possible, however, to have screens that are larger than the display area (known as virtual screens), or to have a screen that is not as tall as the monitor display. Applications will sometimes use the shorter screens as control panels in a different resolution than the display area. Workbench is the default screen a user is presented with upon booting the machine.

Screens cannot be resized. New screens usually appear in front of existing screens. The user can access screens in the back by dragging the front screen down or flipping through the screens by using the screen depth gadget or keyboard combinations.

Fig 3.1: The Workbench Screen.

Types of Screens

Your application can open on one of three types of screens: the Workbench screen, a public custom screen that your application shares with other programs, or your own private custom screen.

When your application uses the Workbench screen, it opens a window on the Workbench, using the palette, resolution and fonts that are defined in the Workbench Prefs.

Fig 3.2: A text editor open on the Workbench screen.

The Workbench screen is a public screen - that is, it can be used by any application. If your program needs a different resolution or palette than the user has chosen for his Workbench preferences, it should open on a public custom screen unless its requirements are restrictive enough to warrant a private custom screen.

By keeping your custom screen public, you allow users to access other, perhaps supportive, applications without having to flip your application to the rear. Or, if the user is already running an application on a public screen with the proper palette and resolution requirements, he can open your program on that screen.

Fig 3.3: A text editor opened on an interlaced public custom screen.

A private custom screen is one that you set up to your specifications and which only your application may use. Private custom screens should be used only when your application has unusual rendering or resolution requirements, or when you need to be able to operate on the whole screen directly. An example of this would be an animation program that needs to switch viewports rapidly in order to get smooth motion.

Technical note: If your application opens a custom screen, make sure you redirect requesters to the custom screen - this applies to relevant DOS requesters as well as your application's requesters.

Respect User Choice

Let the user decide, if possible, whether to open your application on Workbench or on another screen. If he decides to open it on a custom public screen, let him choose whether it will be a new screen or one that has already been created by a different application.

Likewise, respect choices the user has already made. All custom screens, whether public or private, should default to the basic parameters established in Workbench's Preferences, unless your application has special requirements.

If your application provides overscan capabilities you should respect the settings that the user has established in the Overscan editor found in Workbench's Prefs directory.

Screen Design

Screens should have a depth gadget. If you have room, you should try not to obscure the screen depth gadget from view by opening windows that cover up the screen's depth gadget.

The screen your application opens on should open in front of any other screens that are open.

Auto-scrolling

Applications that open screens larger than the display area should provide the ability to auto-scroll. Moving the mouse to any of the display bounds should automatically scroll the screen to show more information in that area.

Screens that open larger than the display area should offer an auto-scrolling function.

Naming Your Public Screens

Public screens are identified by their name. To name a public screen, use your application's basename (see Defining Your Basename) followed by an invocation count. The name should be in upper-case.

For instance, a terminal package with the basename Axelterm that opens its own public screen should name the screen AXELTERM.1. On a system with a multi-serial port card, the user may decide to run a second copy of the package. That second public screen should be named AXELTERM.2.

Some applications may use two screens during the same invocation of the program. For example, a paint program named VanGogh (with the basename VGOGH) may use one screen for the "canvas" and another screen with a different resolution for the control panel. In that case, the screens could be named VGOGHPAD.1 and VGOGHPANEL.1.

Windows and Requesters

The last chapter noted that context cues on the Amiga come in the form of screens, windows and requesters. Whereas screens represent general environments, windows and requesters show the user where he is much more specifically.

A Safe Place to Click

Try to provide a safe place on each window where the user can activate it without altering any previous work. For instance, if the user were to return to a text processor window after checking his email, he should be able to activate the window and not have his cursor move. The title bar is a good area for this.

If your application uses the whole window for operations and has has no window title bar (like some paint packages), let the first click of the mouse on an inactive window activate the window instead of doing an operation.

Fig 4.1: A window.

Size and Position

Each window opened by your application should be able to fit within a medium resolution screen, 640x200, with the Topaz 8 font. These don't need to be the defaults, just a working guideline. See Resolutions for more information on this.

Your application should provide a default location and size for its windows. By default the windows should open within the current view area of the screen (remember that some users work with virtual screens) and should be scaled per the current resolution. You should, however, let the user override these defaults both temporarily and permanently.

For example, if the user moves or resizes a window during a session and later closes the window, your application should remember those settings and use them if the user reopens the window within that session (a "session" being the time between when the user starts the application and when he chooses the Quit Program menu item). In this case, your program should remember the user-specified positions only for the length of the session.

Let the user store his preferred window position "permanently" via the Save Settings menu option (see Menu for more information on menus). Unlike the scenario in the previous paragraph where the position is remembered only for that session, Save Settings saves the position for use each time the application is opened.

The save Settings menu option allows the user to specify a default size and position for windows.

Opening at Different Resolutions

Save Settings should also save the screen width and height so that the window rectangle can be scaled, if necessary, according to the screen size.

For instance, imagine that the user has set his preferred window position to the lower half of a 640x400 screen. If he later runs the same application on a 640x200 screen, the window will have to be adjusted to fit properly on the screen. The first action to take would be to move the window to a place on the screen where it will fit. If this doesn't take care of the problem, the window should be scaled.

In the example above, the screen height was halved, so the position of the window's top edge should be moved up halfway to the top of the screen. If the window has a sizing gadget, the window size should be scaled as well. Be sure to take into consideration the font used in the window title bar when computing the window's maximum/minimum sizes.

If you're window can't be scaled and doesn't fit in a certain resolution, consider restricting the screen's resolution that the window opens on. Try, though, to respect whatever choices the user makes.

Opening on a Virtual Screen

Screens can be many times the size of the actual display area. When opening a window within one of these screens, make sure the window is positioned by default in the onscreen display area, but if the user changes those defaults via the Save Settings menu option, respect the user's settings, even if it causes your window to open offscreen. He may have a reason for wanting the window to appear where it does.

Successive Windows

When your application opens a number of project windows, you may want to position each successive window slightly lower than the previous one - preferably, the height of the title bar plus one pixel. This will leave the window depth arrangement gadget open.

Fig 4.2: Overlapping windows.

Window Gadgets

Here is a specific discussion of when and how to use system gadgets on your windows. More about gadgets can be found in the next chapter.

Fig 4.3: Window gadgets.

Dragging Windows

Whenever possible, windows should be draggable.

Requesters and support windows should always have a title bar that can be used to drag the window. An immovable support window could block important information that relates to it. A Find and Replace window, for example, may obscure the view and thus the spelling of the word the user wants to search for in the document.

Sizing and Scrolling Gadgets

When a window contains a view or editing area, like in a text editor, it should have a sizing gadget so the user can adjust the window to show more information. If the entire window is used as the view area, a scroll gadget should be added in the right-hand border of the window.

Zooming Windows

The first click on the window's zoom gadget changes the window to its alternate size; the next click restores it to the size it was before the gadget was clicked.

You will have to specify what the small size of your window will be; Intuition will handle the rest. If the window is sizable and your application opens full size, the setting should be the minimum size of the window, which can vary according to your application's needs. If your application opens small, the zoom gadget's alternate size should be initialized to full size. If the window isn't sizable, the minimum size should be the height of the title bar and whatever width is necessary to fit the title of the window; or you may choose to omit the zoom gadget altogether.

AppWindows

The active part of an AppWindow (see Chapter 7 for a discussion of AppWindows) should be indicated by an icon drop box gadget. This gadget should be an outlined rectangle. If your AppWindow has different areas that perform different operations, each area should have a separate icon drop box.

Fig 4.4: An icon drop box gadget.

Requesters

Many times when attempting a task, a user will reach a time of choice, a fork in the road. At these junctures, good road signs can be provided by requesters. Requesters can be broadly defined as sub-windows that allow the user to control options, access files and confirm actions.

Types of Requesters

Requesters can be modal or non-modal.

Non-modal requesters, also called support windows, act basically like windows. The choices and/or information are presented to the user, but he can temporarily ignore the requester and continue entering data if he wishes.

Modal requesters block input to the application until options are chosen or actions are confirmed.

Use Non-Modal if Possible

Generally, you should use non-modal requesters unless there is some reason to block further input. Modal requesters confine the user's movements - that is always something to avoid if possible.

However, there are times when a modal requester is preferable. One example is a requester found in the utility HDToolbox. When the user tries to save changes he has made to a hard disk's partitions, a requester appears warning that saving the changes will wipe out all the data on the hard disk. Naturally, this requester should and will block further activity until the user acknowledges the warning.

Use the Wait Pointer with Modal Requesters

While a modal requester is on the screen, the parent window or screen should set its pointer to a wait pointer.

The Modified Project Requester

Whenever the user makes changes to a project currently in memory and subsequently selects an action such as New, Open or Quit, any changes made to the current project will be lost. In that case, a modified project requester similar to the one below should be presented to the user:

Fig 4.5: A requester which should be used if the user tries to leave a file before saving the changes.

Requester Design

If possible, use the standard requesters provided in the ASL library. Requesters are base-level operations and the user shouldn't have to learn new requester operations with each new software package he buys.

If you need to create your own, follow the ASL design. Here's an example of the ASL file requester:

Fig 4.6: The standard ASL file requester shown here is the actual size it would be on a 640x200 screen.

Spend some time on the wording and design of your requesters. Make sure they communicate clearly and succinctly what choices the user has and what will happen as a result of his choice.

Draggable

Both types of requester should be draggable. Even if the user can't enter data to the program, there may be information on the screen that he needs to see and a non-draggable requester may cover that information.

Where to Open Requesters

Requesters should be opened adjoining or within the boundaries of the parent window. Use coordinates relative to the parent window rather than absolute coordinates when positioning a child window.

Fig 4.7: A find and replace support window opening within the boundaries of the parent window.

Positioning is especially important when the user is working with an extremely large virtual screen or a high-resolution monitor such as Commodore's A2024. On a monitor like the A2024, not limiting your requesters to the parent window boundaries can cause an annoying break in the work flow. Here's an example: the user is working in the lower right corner and you open a requester in the upper left. Relatively, that's a lot of screen real estate to move the pointer across. On a virtual screen the requester may not even show up on the current monitor view, leaving the user to wonder if his action had a result at all.

Always Give a Safe Way Out

Operations should always provide a safe way for the user to back out of a requester. Normally this is handled through a "Cancel" action gadget in the lower right of the requester.

Give Directions

When your program produces a requester indicating its failure to find a file, the requester's title bar should name the program that is looking for the file and the specific name of the file should be given in the text of the requester. For instance, getting the following requester at boot up could severely limit any troubleshooting:

Fig 4.8: The wrong way to do a requester stating that a file can't be found.

Fig 4.9: The correct way to tell the user that your application can't find a file.

OK and OK

Don't create requesters with two identical action gadgets, such as OK and OK. A single gadget for each choice will suffice.

Fig 4.10: Another incorrect requester. This one gives two identical action gadgets and no way for the user to back out of the operation.

Gadgets

Gadgets are graphic symbols that represent a specific action or control. They are usually contained in a window or requester.

There are two basic types of gadgets on the Amiga: system gadgets and application gadgets

System Gadgets

System gadgets control aspects of the GUI environment like window size and screen positioning. System gadgets can be thought of basically as environment maintenance tools. This screen's in the way - click it to the back. This window needs to be bigger - click and drag on the sizing gadget.

Fig 5.1: System gadgets.

System gadgets are highly standardized in when and how they are used. Intuition will handle most of their functions. The table that follows lists the gadgets and how they operate. This is mainly for quick reference. Since the gadgets are tied closely to windows and screens, consult those chapters for more detailed information.

Name Description
Close Located on a window's upper left corner, the close gadget removes the window from the screen and quits whatever program or file the window was running
Depth Located on a window or screen's upper right corner, the depth gadget adjusts which window or screen is in front of all the others. For example, if a window is in front of all the other windows on that screen, clicking once on the depth gadget will put it behind all the other windows. Clicking again on that window's depth gadget will bring that window in front of all the other windows.
Sizing Located on a window's lower right corner, the sizing gadget allows the user to resize the window by clicking on the gadget and dragging. Not all windows have or need a sizing gaget although its use and support is strongly encouraged.
Zoom Located on windows next to the depth gadget, the zoom gadget allows users to quickly reduce a window to its minimum size to temporarily get it out of the way. When it is needed again, another click on the zoom gadget will bring the window back to the size it had been. Not all windows have or need a zoom gadget although its use and support is strongly encouraged.

Note: This is only a reference listing of system gadgets. For more information about these see the chapters on Screens and Windows.

Application Gadgets

Application gadgets represent choices the user can make and thus proceed with his task. As a developer, you will have to make more decisions about how and when to use application gadgets than you will with system gadgets.

Design

Like other aspects of the GUI, gadget layout and size should be based on a 640x200 screen resolution with the Topaz 8 font. See @{"Resolutions" link Basi2} for more information.

At run-time, your application should check the size of the font and the screen resolution to determine if the gadgets used will fit in the window with the user's preferred settings. If not, revert to the Topaz 8 font.

Labelling

Put a label on gadgets whose purpose is not immediately obvious. Labels should be terse without being obscure - preferabluy one to three words. Ponder on these a while and test them if possible before incorporating them into your program. Capitalization should follow good grammatical sense for the language being used. If in doubt, refer to a writing or journalism style guide for your language. The Glossary in the back of this manual gives the English capitalization of many Amiga terms.

Ghosting

As with other elements of the GUI, a gadget that is temporarily unavailable for selection should be obviously disabled. Don't allow the user to select something that does nothing in response. Follow the ghosting standard shown in Ghosting.

Fig 5.2: A ghosted text gadget.

Keyboard Equivalents

As a convenience, a key may be bound to each gadget so that its actions can be controlled from the keyboard as well as through the mouse.

Use a logical letter from the gadget label as the key control for the gadget. For instance, a gadget labelled "Spacing" could use "S" as its keyboard control, whereas a gadget labelled "Get Fonts" may use "F". The letter you use should be underlined on the gadget.

Fig 5.3: Gadgets with keyboard equivalents.

Restrictions

Never provide keyboard equivalents for asynchronous requesters. An asynchronous requester is one that occurs due to an action of the application rather than an action of the user. In a hard disk backup program, for example, asynchronous requesters appear asking for a new floppy disk when the current disk is full.

Because asynchronous requesters can appear when the user isn't expecting them, keyboard equivalents can lead to the user choosing an unwanted action. Backup programs, to use that example again, don't require a lot of user attention, so there's a good chance the user will go to another application. If the backup program's requester comes up asking for a new floppy disk while the user is typing in a word processor, unwanted actions could easily occur.

An asynchronous requester will have two default however, that are built into the system. Left-Amiga-V and Left-Amiga-B will, respectively, activate the extreme left and extreme right gadgets at the bottom of a requester.

Another restriction on keyboard equivalents for gadgets: don't use the Return key to activate the OK gadget. This applies to both synchronous and asynchronous requesters.

Left-Amiga-V and Left-Amiga-B will, respectively, activate the extreme left and extreme right gadgets in a requester.

Visual Feedback

Visual feedback should be given when a keyboard equivalent is used. This feedback should be the same as the feedback given when the mouse is used. The specific feedback for each gadget is listed with the gadget description later in this chapter.

Grouping

Gadgets should be grouped logically on your requesters or support windows. Some general premises about grouping follow. Use these premises and your own common sense when grouping elements.

The general rule is that gadgets should be grouped according to function. On a print requester, for example, gadgets controlling text would go in one area, while those affecting graphics would go in another.

Another rule is to place commonly used functions within easy reach, especially on a crowded control panel.

Don't put dangerous controls, such as Delete or Format, near commonly used controls.

Think of the user's work flow when you order the gadgets. Try to emulate a logical and intuitive order. If there is an order of events, start in the upper left and work to the lower right (depending on local language, of course).

Fig 5.4: A requester that has grouped gadgets according to function.

Application Gadgets by Type

Each of the Amiga's application gadgets has a particular use and limitation. This section gives an overview of each type. Each type of gadget can be recognized by its appearance. Do not make gadgets that look like these standard gadgets but act differently.

Action Gadgets

Action gadgets (often referred to as buttons) are graphic rectangles usually containing a few words. Clicking on an action gadget should perform the activity named on the action gadget.

Fig 5.5: An action gadget.

Labels

Make the label descriptive. "OK" and "Cancel" may not always be the best choice. Use friendly, less technical terms (ie. "Stop", rather than "Abort").

The user shouldn't have to read an entire body of text before deciding which action gadget to press. Instead, a carefully selected label should tell the user what the gadget does in one to three words.

Triggering the Action

The action should be triggered on the release of the mouse's select button - not the downpress. This gives the user a chance to "roll off" the gadget before activating it.

More Choices

When an action gadget brings up another window or requester, the label should end in an ellipsis (three periods).

Fig 5.6: A gadget which brings up another window or requester should have a label ending in an ellipsis.

Use of Cancel

An action gadget labelled "Cancel" should only be used if it actually allows the user to back out, leaving the application exactly as it was before the requester appeared. For example, "Cancel" is not appropriate for a gadget on a requester that is displayed while printing is occurring. "Stop" would be a better label.

Gadget Placement

The positive choice, or continuation of the requested action, should be displayed on the lower left side of the requester/window, while the negative choice or discontinuation of the action should be displayed on the lower right.

Fig 5.7: The positive choice should be placed in the lower left, while the negative choice should go in the lower right corner.

Keystroke Activation

If activated through a keystroke, the state of the check mark should toggle within the box.

Scroll Gadget

Scroll gadgets are used to adjust the position of a view. By themselves, scroll gadgets are used to adjust a large display area within a window's view, such as a text file that won't all fit within one window's view. Scroll gadgets are also a component of a scrolling list gadget (see next section).

A scroll gadget is comprised of the scroll bar, scroll box and scroll arrows.

Fig 5.9: A scroll gadget.

Any window that displays only a portion of the file's entire contents should have scroll gadgets. If your application allows the editing of files that are wider than the window, it would be good to have a horizontal scroll gadget as well.

Moving Through in Steps

The display area should be updated immediately as the scroll bar is dragged.

When the user clicks in the scroll box (the rectangle containing the scroll bar) but not directly on the scroll bar, the display should move in viewfuls. For instance, if the user clicks in the scroll box above the scroll bar, the user's view of the list should move up so that the line which was first is now at the bottom of the view. The inverse applies where the user clicks below the scroll bar. This lets the user walk through the list in steps without missing anything on the list. Leaving one line from the previous view assures the user that he hasn't missed anything.

Scrolling List

A scrolling list features a view box showing textual names of files or objects accompanied by a scroll gadget to the right of the view box. If the list is longer than can be accommodated by the view box, the user can move through the list using the scroll gadget.

A scrolling list should be used whenever you need to present the user with a variable list of objects. Probably the most common example is found in the requester presented when a user chooses to open or save a file.

Fig 5.10: A scrolling list.

Custom Scrolling Gadgets

On the Amiga, only one of the items in the system-supplied scrolling list may be selected at a time. Using custom code, it is possible to create a scrolling list gadget that supports multiple selection. If implemented, that gadget should still follow the multiple selection guidelines for text covered in Highlighting Text.

Keystroke Activation

The scrolling list gadget reacts differently to shifted and unshifted keystrokes. An unshifted keystroke should cause the list to scroll forwards through the choices. A shifted keystroke should cause the list to scroll backwards through the choices.

Note: Using the Shift key in tandem with another key should never be the only way to do things since it is usually a choice that is not immediately apparent to the user. In the above case, it is backed up by the mouse.

Radio Buttons

Radio buttons are a group of mutually exclusive gadgets - one and no more than one is always selected. Use this when the user must choose one option from a short list of possibilities.

Fig 5.11: Radio buttons.

Radio buttons are similar to cycle gadgets in functionality. Each has its benefits and drawbacks. See later for a discussion on this subject.

Keystroke Activation

Radio buttons react differently to shifted and unshifted keystrokes. An unshifted keystroke should cause the highlighted button to cycle in one direction. A shifted keystroke should cause the highlighted button to cycle in the opposite direction.

Cycle Gadgets

Like radio buttons, cycle gadgets allow the user to choose one option from several but only the selected option is visible.

Fig 5.12: A cycle gadget.

Cycle gadgets should be used to set attributes, not trigger actions. Never use a cycle gadget for an on/off choice - use a check box instead.

Keystroke Activation

The cycle gadget reacts differently to shifted and unshifted keystrokes. An unshifted keystroke should cause the gadget to cycle forwards through the choices. A shifted keystroke should cause the gadget to cycle backwards through the choices.

Cycle Gadgets vs. Radio Buttons vs. Scrolling Lists

If the user needs to choose one option from a choice of three or more, cycle gadgets, radio buttons and scrolling lists are viable options. Which one you choose to implement depends on your application, your preference and common sense. Consider the following points:

  • A cycle gadget presents a cleaner interface. The selected choice is quickly evident and the unwanted choices are hidden away. Theoretically it's also able to handle a larger number of choices, although users will probably have trouble remembering a really large number of choices. Large numbers of choices may work well in a cycle gadget if they are ordered choices, such as the months of the year.
  • In general though, options with more than about a dozen choices should use a scrolling list.
  • Radio buttons present a clear choice to the user - the possible choices are always visible. Radio buttons work well with a small number of options. They are probably also slightly more intuitive than cycle gadgets.

Color Selection Gadget

The color selection gadget (sometimes referred to as the palette gadget) allows the user to pick a color from a set palette.

Fig. 5.13: A color selection gadget.

Keystroke Activation

The color selection gadget reacts differently to shifted and unshifted keystrokes. An unshifted keystroke should cause the gadget to cycle forwards through the choices. A shifted keystroke should cause the gadget to cycle backwards through the choices.

Slider

Sliders are used to choose a value in a given range. Usually, this value represents a level or an intensity such as volume or color.

Sliders look similar to scrollers without arrows, but when the user clicks in the slider box above or below the slider bar, the slider value should change in single increments rather than entire views.

Fig 5.14: Slider gadgets.

Keystroke Activation

The slider reaacts differently to shifted and unshifted keystrokes. An unshifted keystroke should cause the horizontal bar in the slider to move up. A shifted keystroke should cause the horizontal bar to move down. When the horizontal bar reaches either the top or bottom it should change directions automatically. Don't tie the direction solely to a shifted keystroke.

Text Gadget

Text gadgets (sometimes referred to as string gadgets) are rectangular boxes used to accept keyboard input for alphanumeric fields.

Fig 5.15: A text gadget.

Activating Text Gadgets

When a window or requester appears containing a text gadget, have the gadget immediately activated and ready for keyboard input if:

  • there are no gadgets on the requester that can be activated by the keyboard;
  • the window or requester appeared in direct response to user activity (ie. it is not asynchronous).

If the window or requester has other gadgets that can be activated from the keyboard, the user should also be able to activate the text gadget from the keyboard. In this case, it should not be activated by default.

The user should not have to select the text gadget with the mouse before typing an entry (if he chose an action that directly called that requester up). If may seem like a small delay to go from keyboard to mouse to keyboard, but all breaks in the flow of your program should be minimized.

Ordering of Text Gadgets

When a window contains a series of text gadgets, activate the gadget in the far upper left region of the window first (depending on the scanning direction of the local language).

Moving Through Fields

Let the user move through fields with the Tab key. When the user presses Tab, activate the next text or number gadget in the series. When the user reaches the end of the series and presses Tab, the cursor should return to the first entry gadget. This function is supported by Intuition.

Shift-Tab should activate the previous gadget in the series.

Let the user move through fields with the Tab key.

Display Box

A display box is a rectangle that shows non-editable textual or numeric information.

Display boxes look similar to text gadgets, but since they are read-only, they appear recessed.

Fig 5.16: A display gadget.

Icon Drop Box

Icon drop boxes are used for manipulation of icons. If a user drags an icon to an icon drop box, the image of the icon is copied into the box. Depending on the function assigned to that icon drop box, the icon imagery may then be redrawn or used to represent other files.

Fig 5.17: An icon drop box.

Custom Gadgets

Sometimes a system-supported control does not provide the exact function you need. In that case, you may choose to create a custom gadget.

If a custom gadget is an extension to an existing gadget type, then you should try to emulate the features of the existing gadget.

For example, a custom multi-line text gadget should support the same keyboard functions that the standard single-line text gadget does. Right-Amiga-X should erase the text and Right-Amiga-Q should undo changes. Refer to Keyboard for more information on the keyboard conventions used in text gadgets.

All custom gadgets should support a minimum of three images: normal, selected and disabled. The gadget images must be usable on a monochrome screen.

Custom Icons

Custom icons are application-specific gadgets that can be moved and manipulated. The note object in a music package is one example.

Take care when using custom icons alongside action gadgets that have graphical labels. Since it is not clear which symbols trigger an action when clicked and which symbols move when clicked, users could be triggering unwanted actions. If you use both in the same application, be sure the user can tell at a glance which is which. Grouping them spatially is one possible solution. Colour cues may provide a solution. Boxing them may be a third solution.