With respect there Carl Manaster's fine answer, there are some drawbacks you should at least consider before embarking on the path Carl suggested.
The most significant of which is this: we use encapsulation to minimise the number of potential dependencies that carry the greatest probability of change propagation. In your case, you have encapsulated private methods inside your class: they are not available to other classes and thus there are no potential dependencies on them: the cost of any changes you make to them is minimised and has a low probablility of propagation to other classes.
It seems that Carl suggests moving some private methods from your class into a new class, and making those methods public (so that you can test them). (Incidentally, why not just make them public in the original class?)
By doing this, you remove the barrier to other classes' forming dependencies on those methods, which will potentially increase the cost of chaging those methods should any other class take to using them.
You may judge this down-side minor and a worthwhile price to pay for being able to test your private methods, but at least be aware of it. In a small number of cases, it may indeed be worthwhile, but if you institute this throughout your code-base then you'll drastically increase the probability that these dependencies will form, increasing the cost of your maintenance cycle to an unknown degree.
For these reasons, I disagree with Carl that his suggestion is, ” … a great example of how TDD improves your design.”
Furthermore, he states, ”In the original class, that extraneous functionality is gone, wrapped within the sprouted class, so the original class' design is simpler, and better conforms to the Single Responsibility Principle.”
I would argue that the functionality being moved is not at all, ”Extraneous.” Also, ”Simpler,” is a not well-defined: it certainly may be the case that a class's simplicity is inversely proportional to its size but that does not mean that a system of simplest-possible classes will be the simplest possible system: if this were the case, all classes would contain only one method and a system would have an enormous number of classes; the removal of this hierarchical layer of multiple-methods-within-classes, it could be argued, would make the system much more complicated.
The Single Responsibility Principle (SRP) is, furthermore, notoriously subjective and entirely dependent on the level of abstraction of the observer. It is not at all the case that removing a method from a class automatically improves its conformity to the SRP. A Printer class, with 10 methods, has the single responsibility of printing at the level of abstraction of the class. One of its methods may be checkPrinterConnected() and one may be checkPaper(); at the method level, these are clearly separate responsibilities, but they do not automatically suggest that the class should be broken down into further classes.
Carl finishes, ”In the sprouted class, the extracted functionality is its raison d'etre, therefore it's appropriate for it to be public, and therefore it's testable without test-only modifications.” A functionality's importance (it's raison-d'etre-ness) is not the basis for the appropriateness of its being public. The basis for the appropriateness of functionality's being public is the minimising of the interface exposed to the client such that the class's functionality is available for use while the client's independence of the functionality's implementation is maximised. Of course, if you are moving just one method into the sprouted class, then it has to be public. If you are moving more than one method, however, you must make those methods public which are essential to the client's successful use of the class: these public methods may be far less important than some of the private methods from which you wish to shield your client. (In any case, I'm not at a fan of this, ”Raison-d'etre,” phrase as the importance of a method is also not well-defined.)
An alternative approach to Carl's suggest depends on how large you envisage your system to grow. If it will grow to fewer than a few thousand classes, then you might consider having a script to copy your source code to a new directory, change all occurances of, ”private” to, ”public” in that copied source and then write your tests against the copied source. This has the down-side of the time it takes to copy the code but the benefit of preserving encapsulation your original source yet making all the methods testable in the copied version.
Below is the script I use for this purpose.
rm -rf code-copy
echo Creating code-copy ...
cp -r ../www code-copy/
for i in
find code-copy -name "*php" -follow; do
sed -i 's/private/public/g' $i