Concept: Test-first Design
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Concept: Test-first Design
This guideline discusses Test-first Design. Test-first Design is applied by creating a test script first, before writing and testing the code. You continue this technique until there is nothing left to test.
Relationships
Related Elements
Developer Test
Main Description
Introduction
Test designs are created using information from a variety of work products, including design work products such as use
case realizations, design models, or classifier interfaces. Tests are executed after components are created. It's
typical to create the test designs just before the tests are to be executed-well after the software design work
products are created. Figure 1, following, shows an example. Here, test design begins sometime toward the end of
implementation. It draws on the results of component design. The arrow from Implementation to Test Execution indicates
that the tests can't be executed until the implementation is complete.
Fig1: Traditionally, Test Design is performed later in the life-cycle
However, it doesn't have to be this way. Although test execution has to wait until the component has been implemented,
test design can be done earlier. It could be done just after the design work product is completed. It could even be
done in parallel with component design, as shown here:
Fig2: Test-first Design brings test design chronologically in-line with software design
Moving the test effort "upstream" in this way is commonly called "test-first design". What are its advantages?
No matter how carefully you design software, you'll make mistakes. You might be missing a relevant fact. Or you
might have particular habits of thought that make it hard for you to see certain alternatives. Or you might just be
tired and overlook something. Having other people review your design work products helps. They might have the facts
you miss, or they might see what you overlooked. It's best if these people have a different perspective than you
do; by looking at the design differently, they'll see things you missed.
Experience has shown that the testing perspective is an effective one. It's relentlessly concrete. During software
design, it's easy to think of a particular field as "displaying the title of the current customer" and move on
without really thinking about it. During test design, you must decide specifically what that field will show
when a customer who retired from the Navy and then obtained a law degree insists on referring to himself as
"Lieutenant Morton H. Throckbottle (Ret.), Esq." Is his title "Lieutenant" or "Esquire"?
If test design is deferred until just before test execution, as in Figure 1, you'll probably waste money. A
mistake in your software design will remain uncaught until test design, when some tester says, "You know, I knew
this guy from the Navy...", creates the "Morton" test, and discovers the problem. Now a partially or fully complete
implementation has to be rewritten and a design work product has to be updated. It would be cheaper to catch the
problem before implementation begins.
Some mistakes might be caught before test design. Instead, they'll be caught by the Implementer. That's still bad.
Implementation must grind to a halt while the focus switches from how to implement the design to what that design
should be. That's disruptive even when the Implementer and Designer roles are filled by the same person; it's much
more disruptive when they're different people. Preventing this disruption is another way in which test-first design
helps improve efficiency.
Test designs help Implementers in another way--by clarifying design. If there's a question in the Implementer's
mind about what the design meant, the test design might serve as a specific example of the desired behavior. That
will lead to fewer bugs due to Implementer misunderstanding.
There are fewer bugs even if the question wasn't in the Implementer's mind-but should have been. For
example, there might have been an ambiguity that the Designer unconsciously interpreted one way and the Implementer
another. If the Implementer is working from both the design and also from specific instructions about what the
component is supposed to do-from test cases-the component is more likely to actually do what is required.
Examples
Here are some examples to give you the flavor of test-first design.
Suppose you're creating a system to replace the old "ask the secretary" method of assigning meeting rooms. One of the
methods of the MeetingDatabase class is called getMeeting, which has this signature:
Meeting getMeeting(Person, Time);
Given a person and a time, getMeeting returns the meeting that person is scheduled to be in at that time. If the
person isn't scheduled for anything, it returns the special Meeting object unscheduled. There are some
straightforward test cases:
The person isn't in any meeting at the given time. Is the unscheduled meeting returned?
The person is in a meeting at that time. Does the method return the correct meeting?
These test cases are unexciting, but they need to be tried eventually. They might as well be created now, by writing
the actual test code that will someday be run. Java code for the first test might look like this:
// if not in a meeting at given time,
// expect to be unscheduled.
public void testWhenAvailable()
{
Person fred = new Person("fred");
Time now = Time.now();
MeetingDatabase db = new MeetingDatabase();
expect(db.getMeeting(fred, now) == Meeting.unscheduled);
}
But there are more interesting test ideas. For example, this method searches for a match. Whenever a method searches,
it's a good idea to ask what should happen if the search finds more than one match. In this case, that means asking
"Can a person be in two meetings at once?" Seems impossible, but asking the secretary about that case might reveal
something surprising. It turns out that some executives are quite often scheduled into two meetings at once. Their role
is to pop into a meeting, "rally the troops" for some short amount of time, and then move on. A system that didn't
accommodate that behavior would go at least partially unused.
This is an example of test-first design done at the implementation level catching an analysis problem. There are a few
things to note about that:
You would hope that good use-case definition and analysis would have already discovered this requirement. In that
case, the problem would have been avoided "upstream" and getMeeting would have been designed differently.
(It couldn't return a meeting; it would have to return a set of meetings.) But analysis always misses some
problems, and it's better for them to be discovered during implementation than after deployment.
In many cases, Designers and Implementers won't have the domain knowledge to catch such problems-they won't have
the opportunity or time to quiz the secretary. In that case, the person designing tests for getMeeting would
ask, "is there a case in which two meetings should be returned?", think for a while, and conclude that there
wasn't. So test-first design doesn't catch every problem, but the mere fact of asking the right kinds of questions
increases the chance a problem will be found.
Some of the same testing techniques that apply during implementation also apply to analysis. Test-first design can
be done by analysts as well, but that's not the topic of this page.
The second of the three examples is a statechart model for a heating system.
Fig3: HVAC Statechart
A set of tests would traverse all the arcs in the statechart. One test might begin with an idle system, inject a Too
Hot event, fail the system during the Cooling/Running state, clear the failure, inject another Too Hot event, then run
the system back to the Idle state. Since that does not exercise all the arcs, more tests are needed. These kinds of
tests look for various kinds of implementation problems. For example, by traversing every arc, they check whether the
implementation has left one out. By using sequences of events that have failure paths followed by paths that should
successfully complete, they check whether error-handling code fails to clean up partial results that might affect later
computation. (For more about testing statecharts, see Work Product Guideline: Test Ideas for Statechart and Activity Diagrams.)
The final example uses part of a design model. There's an association between a creditor and an invoice, where any
given creditor can have more than one invoice outstanding.
Fig4: Association between Creditor and Invoice Classes
Tests based on this model would exercise the system when a creditor has no invoices, one invoice, and a large number of
invoices. A tester would also ask whether there are situations in which an invoice might need to be associated with
more than one creditor, or where an invoice has no creditor. (Perhaps the people who currently run the paper-based
system the computer system is to replace use creditor-less invoices as a way to keep track of pending work). If so,
that would be another problem that should have been caught in Analysis.
Who does test-first design?
Test-first design can be done by either the author of the design or by someone else. It's common for the author to do
it. The advantage is that it reduces communication overhead. The work product Designer and Test Designer don't have to
explain things to each other. Further, a separate Test Designer would have to spend time learning the design well,
whereas the original Designer already knows it. Finally, many of these questions-like "what happens if the compressor
fails in state X?"-are natural questions to ask during both software work product design and test design, so you might
as well have the same person ask them exactly once and write the answers down in the form of tests.
There are disadvantages, though. The first is that the work product Designer is, to some extent, blind to his or her
own mistakes. The test design process will reveal some of that blindness, but probably not as much as a different
person would find. How much of a problem this is seems to vary widely from person to person and is often related to the
amount of experience the Designer has.
Another disadvantage of having the same person do both software design and test design is that there's no parallelism.
Whereas allocating the roles to separate people will take more total effort, it will probably result in less elapsed
calendar time. If people are itching to move out of design and into implementation, taking time for test design can be
frustrating. More importantly, there's a tendency to skimp on the work in order to move on.
Can all test
design be done at component design time?
No. The reason is that not all decisions are made at design time. Decisions made during implementation won't be
well-tested by tests created from the design. The classic example of this is a routine to sort arrays. There are many
different sorting algorithms with different tradeoffs. Quicksort is usually faster than an insertion sort on large
arrays, but often slower on small arrays. So a sorting algorithm might be implemented to use Quicksort for arrays with
more than 15 elements, but insertion sort otherwise. That division of labor might be invisible from design work
products. You could represent it in a design work product, but the Designer might have decided that the benefit
of making such explicit decisions wasn't worthwhile. Since the size of the array plays no role in the design, the test
design might inadvertently use only small arrays, meaning that none of the Quicksort code would be tested at all.
As another example, consider this fraction of a sequence diagram. It shows a SecurityManager calling the
log() method of StableStore. In this case, though, the log() returns a failure, which causes
SecurityManager to call Connection.close().
Fig5: SecurityManager sequence diagram instance
This is a good reminder to the Implementer. Whenever log() fails, the connection must be closed. The question
for testing to answer is whether the Implementer really did it-and did it correctly-in all cases or just in
some. To answer the question, the Test Designer must find all the calls to StableStore.log() and make
sure each of those call points is given a failure to handle.
It might seem odd to run such a test, given that you've just looked at all the code that calls
StableStore.log(). Can't you just check to see if it handles failure correctly?
Perhaps inspection might be enough. But error-handling code is notoriously error-prone because it often implicitly
depends on assumptions that the existence of the error has violated. The classic example of this is code that handles
allocation failures. Here's an example:
while (true)
{
// top level event loop
try
{
XEvent xe = getEvent();
... // main body of program
} catch (OutOfMemoryError e) { emergencyRestart(); }
}
This code attempts to recover from out of memory errors by cleaning up (thus making memory available) and then
continuing to process events. Let's suppose that's an acceptable design. emergencyRestart takes great care not
to allocate memory. The problem is that emergencyRestart calls some utility routine, which calls some other
utility routine, which calls some other utility routine-which allocates a new object. Except that there's no memory, so
the whole program fails. These kinds of problems are hard to find through inspection.
Test-first design and the phases of RUP
Up to this point, we've implicitly assumed that you'd do as much test design as possible as early as possible. That is,
you'd derive all the tests you could from the design work product, later adding only tests based on implementation
internals. That may not be appropriate in the Elaboration phase, because such complete testing may not be aligned with
an iteration's objectives.
Suppose an architectural prototype is being built to demonstrate product feasibility to investors. It might be based on
a few key use-case instances. Code should be tested to see that it supports them. But is there any harm if further
tests are created? For example, it might be obvious that the prototype ignores important error cases. Why not document
the need for that error handling by writing test cases that will exercise it?
But what if the prototype does its job and reveals that the architectural approach won't work? Then the architecture
will be thrown away - along with all those tests for error-handling. In that case, the effort of designing the tests
will have yielded no value. It would have been better to have waited, and only designed those tests needed to check
whether this proof-of-concept prototype really proves the concept.
This may seem a minor point, but there are strong psychological effects in play. The Elaboration phase is about
addressing major risks. The whole project team should be focused on those risks. Having people concentrating on minor
issues drains focus and energy from the team.
So where might test-first design be used successfully in the Elaboration phase? It can play an important role in
adequately exploring architectural risks. Considering how, precisely, the team will know if a risk has been realized or
avoided will add clarity to the design process and may well result in a better architecture being built the first time.
During the Construction phase, design work products are put into their final form. All the required use case
realizations are implemented, as are the interfaces for all classes. Because the phase objective is completeness,
complete test-first design is appropriate. Later events should invalidate few, if any, tests.
The Inception and Transition phases typically have less focus on design activities for which testing is appropriate.
When it is, test-first design is applicable. For example, it could be used with candidate proof of concept work in
Inception. As with Construction and Elaboration phase testing, it should be aligned with iteration objectives.
© Copyright IBM Corp. 1987, 2006. All Rights Reserved.
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