@Wes is right, never assume you know what you need to fix until you have proof.
Where I differ is on the method of finding out.
I and others use random pausing which works for these reasons, and here's a short slide show demo & C++ code so you can see how it works, if you want.
The thing about printf (or any output) function is it spends A) a certain number of CPU cycles creating a buffer to be output, and then it spends B) a certain amount of time waiting while the system and/or auxiliary hardware actually moves the data out.
That's maybe a bit over-simplified, but if you randomly pause and examine the state, that's what you see.
What you've done by using large buffers and an SSD drive is reduce B, and that's good.
That means of the time remaining, A is a larger fraction.
You know that.
Now of the samples you find in A, you might get a hint of what's happening if you see what subordinate routines inside printf are showing up.
Usually printf calls something like
vprintf to get rid of the variable argument list, which then cycles over the format string to figure out what to do, including things like parsing precision specifiers.
If it looks like that's what it's doing, then you know about how much time goes into parsing the format.
On the other hand, if you see it inside a routine that is copying a string, or formatting an integer (along with dealing with leading/trailing characters, etc.) then you know to concentrate on that.
On yet another hand, if you see it inside a routine that looks like it's formatting a floating point number (which is actually quite complicated), you know to concentrate on that.
Given all that, you want to know what I do?
First, I ask who is going to read this anyway?
If nobody really needs to read all this text, why not pump it out in binary? Or failing that, in hex?
If you simply write binary, A shrinks to nothing, and when you read it back in with another program, guess what?
No Lost Bits!