# The goal

Given a main interval, `[0,1]` for example, break that interval in any number of subintervals, for example `[0,0.2) , [0.2,0.5) , [0.5,1]`.
Now map different functions to each subinterval generated:

``````[0,0.2)   ~> a( float x )
[0.2,0.5) ~> b( float x )
[0.5,1]   ~> c( float x )
``````

Call that mapping function `map`. The `map` mapping function is dessigned to get a floating-point value on the main interval, and call the corresponding function mapped. That is, given an input value `x = 0.3`, `map` calls `b(0.3)`:

``````map(0.3); //Should call b(0.3)
``````

My question is: What is the proper/best way to implement this on C++?

# Attemped solutions:

I have tried a solution which consists on represent intervals as a pair of float values, i.e. `using interval = std::pair<float,float>;`, and using that interval type as key of a (unordered)map:

``````void map_function( float x )
{
std::map<interval,std::function<void(float)>> map;

map[{0.0,0.2}] = [](float){ ... }; //a
map[{0.2,0.5}] = [](float){ ... }; //b
map[{0.5,1.0}] = [](float){ ... }; //c

auto it = std::find_if( std::begin( map ) ,
std::end( map ) ,
[x]( const interval& interval )
{
return x >= interval.first && x < interval.second;
});

if( it != std::end( map ) )
*it( x );
else
throw "x out of bounds or subintervals ill-formed";
}
``````

This solution seems to work, but has some minnor problems I think:

• It has O(n) complexity, given n subintervals. Is there any way to perform this kind of function in O(1)?
• Is `std::map` the proper container for this work?: The purpose of associative containers is to map from a key to a value, but here the key of the map is not the input itself, is a processed form of the input (The interval which the input value belongs to).
I have tried C++11's `std::unordered_map` too, but seems like there is no standard hash function for float pairs. That surprises me, but falls into another question. Keep on topic :P

# Alternative solutions? Requeriments

I know about interval libraries, like Boost Interval and Boost Interval Container libraries, but I need a solution which relies on Standard Library facilities only.

You can use binary search to O(lg n) complexity. Specifically, the lower bound form #algorithm libary. If you have a vector of `tuple <double, ptr_function>` you can use bitary search for it. If ranges are a specific const length or length is multiple of some number, you can do it in O(1) time. For example:

``````multiple of 0.1
Ranges: [0;0.4) = a, [0.4;0.5) = b, [0.5;1) = c
table = {a,a,a,b,c,c,c,c,c}
Getting for x : table[floor(x*10)]
``````

Edit: If you want to keep map, you can use map's lower bound.

• Std::map is implemented as a binary tree (I.E. it's an ordered map), and has a lower_bound search. No need to reinvent the wheel. I agree with the O(1) case though. Commented Mar 9, 2014 at 14:25
• @aruisdante ok, I wanted to emphasize that the map is not necessary. Maybe I should mention this. However, I added information about it. Thank you. Commented Mar 9, 2014 at 14:35
• Correct, but then you have to self-manage the tree on new element insertion. std::map takes care of that boilerplate for you, and makes the intent of your use immediately clear to anyone working with your code later on. Commented Mar 9, 2014 at 14:59
• You have a point. The map could be a better option. Especially when ranges will change dynamically, but not when the most important is memory. Search complexity is the same, construction could be linear on vector, on map it's O(n lg n). The question of priorities. Commented Mar 9, 2014 at 15:10

If your intervals are adjacent to each other then use just starting points as keys and instead of using `find()` use `lower_bound()`. You cannot make it faster than `log2(N)` in general case. If you know what the maximum decimal precision is I suggest you use int64_t as a key. The transformation is `int64_t ikey = 10eX * dkey`, where `X` is the maximum precision.

• And if they are not adjacent you should be able to get the same result by building your own balanced binary tree and having the nodes have a concept of falling in their interval as their equals case. Commented Mar 9, 2014 at 14:21