Most of the time, you simply don't want to use separate threads for a simple sequence like tokenizing a string, then converting the tokens to double.
Rather the contrary, when you're splitting a task across threads, you want to find things that don"t need to be done sequentially. Quite the contrary, you generally want to minimize the interactions between your threads as much as possible.
As such, instead of having one thread tokenize, and another convert to double, what you'd generally prefer would be to do the tokenizing and conversion to double together, but break the input up into several large chunks of data, each if which will be processed by a single thread.
Even this may well end up doing little (if any) real good. I'd start by writing the code in a single thread, then do some profiling. Given the small amount of processing involved in tokenizing and converting data, chances are pretty good that a single thread will be able to process fast enough to use all the available memory bandwidth. In such a case, using more threads is unlikely to do an real good unless you're using a system where multiple threads might (for example) be running on entirely separate processors, so your available memory bandwidth scales (to at least some degree) along with the cores you use.
Multiple threads will (at least potentially, and usually also in fact) run on multiple cores.
parallel_for_each are intended to simplify parallel processing for some special cases, so you get the effect of multiple threads without having to jump through nearly as many flaming hoops to ensure correct behavior.
The obvious criteria to qualify good uses of
std::thread instead of parallel_for (or similar) would be when you want the threads to do heterogeneous processing. parallel_for basically just takes iterations of a loop and executes them in parallel. If your processing doesn't (mostly) happen in a single loop like that,
std::thread is likely to yield better results.