In C++ if you want to take a square root of an unsigned long long and only care about the integer portion, what's the best method to use? I know there's sqrtl which returns long double, but not sure if it will get messed up converting from signed to unsigned.
@ratchetfreak according to here the data range of double is the same as long double. According to here it's compiler dependent. My question is, since I only care about the integer portion, does it make sense to use sqrtl or just sqrt?
Like does double reserved a portion for before the decimal point and a portion for after, or is that not how it works?
@northerner The first source you link is from a Microsoft reference, so it is likely true for a Windows platform. The second link is a more general answer about C++ in general. long double may or may not be larger than double, depending on the target platform.
Hi, I have a loop that produces a value at every iteration, and I need to stop the loop when a value is equal to a precedently produced value. How can I do this without storing all the values?
I remember of reading about a way to do this some time ago, but I can't find the explanation anymore.
@PeterT I need to check for all the precedently produced values, not just the previus one. I remember of reading about a matematical technique to do this without storing all the values, saving a lot of memory, but I don't remember what it was called.
@ThePirate42 If the numbers that are generated are effectively random, then you need some sort of state to store which numbers have been generated. Depending on the distribution, you can either store all numbers that have been generated or create some flag set to when if a number has been generated or not.
If you are asking for "any solution that does not store the values generated" then a bitset with a number of bits equal to the number of possible values is one alternative.
@ThePirate42 The key to your issue is your specific definition of "values". For example, if your situation has "value" that are constraints to always be integers in the range [0,49], and your loop is generating millions upon millions of them, then instead of storing all millions of results, you should just use a wasGenerated[i] array of 50 booleans.
If your specific definition of "value" is even further constrained to be integers in the range [0,7], then you could further extend this idea to have memory needs of only one byte (instead of setting a boolean array element, you are setting an one bit within that byte) -- this is essentially @Francois' bitset idea.
On the other hand, if your definition of "values" is each loop iteration might be generating any arbitrary 32-bit number, for example, then you're not going to be able to get away from storing them all.
except of course if there's some constraints you're willing to make like Francois suggested. I.e. make a bitmap that's sampling the space in some grid-like structure
@ThePirate42: For scientific applications that manipulate floating point data, there's often the concept of an epsilon. So in some situations, even with complex<double>, the space of possible data might be constrained such that you could group the potentially-generated data into "bins", and still do a wasGenerated[i] type of idea.
But since your application is fractals, I'm assuming that's not gunna be the case for you
That is, is it okay for 1.5+1.5i and 2+2i to be considered the "same" ?
Or if those two points should be "different", but okay for 1.9+1.9i and 2+2i to be considered the "same"?
For example, if a precision of 0.5 in each dimension is acceptable, then you only have 25 possible points, which means you could use a bitset type of approach
oops, make that more like 100 possible points, but I think you get the idea
Are you aware of the fact that when you have two floating point (double) values (stored in two double variables x and y), that it is inherently unsafe in C++ to test an expression like if (x == y) {...}
@PeterT, true enough, I'm just concerned that @ThePirate42 might be relying on an incorrect assumption about the representation of computed floating point value, and how to determine "sameness"
@CowCorporation I didn't think of that, but now that I think about it what I was trying to do doesn't make sense without an exact representation of rational numbers
@CowCorporation Guess I'll have to use another approach. Anyway, thank you for the time and the help!