In certain optimization algorithms, the choice between `double`

and `float`

is *not* made more on space demands than speed. For example, with penalty or barrier methods that are used for interior point methods in nonlinear optimization, a `float`

has insufficient precision compared to a `double`

, and using `float`

s in the algorithm will yield garbage. For this reason, penalty and barrier methods were not used in the 1960s, but were rediscovered later on with the advent of the double precision data type. (For more on these methods, consult *Nonlinear Programming: Sequential Unconstrained Minimization Techniques (Classics in Applied Mathematics)* by Fiacco and McCormick.)

Another consideration is the conditioning of the underlying linear systems solved in many optimization algorithms. If the linear systems you're solving in something like a Newton iteration are sufficiently ill-conditioned, you will not be able to obtain an accurate solution to those systems.

Only if the loss in precision will not jeopardize your numerics should you consider replacing `double`

s with `float`

s; even if space constraints force you to do so, you should make sure that the accuracy of your numerical results is not compromised. Once sufficient accuracy is assured for the problems you're working on, you can then worry about space and performance optimizations. You can use the CUTEr test set to validate your optimization routines.