I love design patterns, but they (apart from simple ones like Singleton) definitely add complexity to an application. They add some dimension to a design that is not intuitively obvious to a novice designer (and not part of the features of the programming language).
Some people might feel patterns reduce complexity because of the benefits they bring in terms of the software's non-functional requirements such as maintainability, extendability, reusability, etc. However, I disagree and see the benefits as a return on complexity investment. Perhaps in some cases patterns reduce complexity, but a theoretical discussion like that sheds more heat than light. Almost none of the answers so far used concrete examples, save http://stackoverflow.com/a/760968/1168342.
To be specific, many patterns increase accidental complexity of a design by introducing new structures (interfaces, methods, etc.) that weren't present in the design before the pattern was applied.
Let's use Visitor as an example.
Visitor is a way of separating operations from an object structure on which they operate.
Before the solution with Visitor, the operations are hard-coded into each Element of the object structure. The challenge for the developer is that adding new operations involves modifying the code in the various elements.
After the application of the Visitor pattern, there is an additional class hierarchy of visitors, which encapsulate the operations.
The flow of
control in the solution is definitely more complex, and will be harder
to debug (anyone who has implemented Visitor and tried to follow the
program flow of double-dispatched calls with accept/visit will know this).
Understanding and maintaining Visitor functions in terms of
cohesive units is less complicated than the alternative of coding
functions into each of the Elements in the fixed structure that is
visited. This is the benefit of the pattern.
It's difficult to say quantitatively how much increase there is in accidental complexity or how much easier it is to add new operations. I certainly don't agree with answers that make a blanket statement saying in the long-term, complexity is reduced with applying a pattern. It's not like your design "forgets" the double-dispatch added by Visitor's approach, just because you have code which more easily allows operations to be added. The complexity is a price (or tax) you pay to get the benefit in maintainability.
Patterns still have to be applied
Regardless of one's supposed familiarity with patterns, any given pattern must be applied to a solution. That application is going to be different every time (Martin Fowler said patterns are only half-baked solutions). Developers will always have to understand what classes are playing what roles in the existing design, which is subject to the essential complexity (the application problem's complexity) that is often non-trivial.
In the best case, understanding a design pattern applied in an application that's already complex may be trivial, but it's not 0 effort:
- Patterns aren't always applied the same way. There are many variants of patterns -- Proxy comes to mind. I'm not sure that everyone agrees about how any given pattern should be applied.
- Introducing one pattern (e.g., Strategy to encapsulate algorithms) often leads to other patterns to manage things properly (e.g., Factory to instantiate the concrete Strategies).
- Introducing a pattern often leads to more responsibilities. Object cleanup when a Factory is used is not trivial (and also not documented in GoF). How many know about the so-called Lapsed-listener problem?
- What happens if there is a change in the assumptions made about the need for the pattern (e.g., there is no longer a need to have multiple encapsulated algorithms provided by the Strategy pattern)? It's going to be extra work to remove the pattern later. If you don't remove it, new developers could be duped by its presence when they come on board. Patterns are intertwined between the classes playing the roles in the pattern. Removal is not trivial.
Erich Gamma gave an anecdote at ECOOP 2006 that designers in one case decided to remove the Abstract Factory pattern from a commercial multi-platform GUI widget framework (the classic Abstract Factory example!). It turned out that the multiple-levels of indirection (polymorphic calls) in complex GUIs was a significant performance hit in the client code. Customers complained about GUIs being sluggish, and the "optimization" was to remove the indirections. In this case, performance trumped maintainability; the pattern was only making the coders happy, not the end users.
In terms of the DAO example you cite in the question, if you're coding an application that will never need to run with varying databases, then the DAO pattern is an unneeded level of complexity. In general, if your code doesn't need the benefit that a pattern is supposed to provide, applying that pattern will increase your application's complexity unnecessarily.
Revolving door metaphor
Using buildings as a metaphor, let's consider a revolving door as a building design pattern. The following image comes from Wikipedia:
You can "see" the additional complexity in such a door. The benefits of revolving doors are in energy savings. They attempt to solve the problem where there are people frequently going in and out of a building, and opening/closing a standard door allows too much air to be exchanged between the inside the outside of the building each time.
It probably wouldn't make sense to install a revolving door as the entrance of a two-bedroom house, because there is not enough traffic to justify the additional complexity. The revolving door would still work in a two-bedroom house. The benefits in terms of energy savings would be small (and might actually be worse because of size and air-tightness relative to a conventional door). The door would surely cost more and would take up more space than a traditional door.