lower_bound == upper_bound

EDIT: It was too many negations in the docs which made me confused. The problem was that I got the same iterator. I solved it by subtracting 1 from lower_bound return value. I use it for interpolation:

float operator()(double f)
{
SpectrumPoint* l=std::lower_bound(beginGet(),endGet(),(SpectrumPoint){float(f),0.0f}
,SpectrumPoint::CompareFreqLessThan);
if(l>beginGet())
{--l;}

SpectrumPoint* u=std::lower_bound(beginGet(),endGet(),(SpectrumPoint){float(f),0.0f}
,SpectrumPoint::CompareFreqLessThan);

if(u==endGet())
{u=beginGet();}

if(l==u)
{
if(u==endGet())
{return u->amp;}
return l->amp;
}

double f_min=l->freq;
double A_min=l->amp;
double f_max=u->freq;
double A_max=u->amp;

double delta_f=f_max-f_min;
double delta_A=A_max-A_min;

return A_min + delta_A*(f-f_min)/delta_f;
}

I am sorry for this confusion :-(

What does lower_bound mean. If I had to guess I would answer that this function returns the iterator at the last element that is less than the value asked for. But I see that lower_bound is almost the same as upper_bound. The only difference is strict inequality in the case of upper_bound. Is there a true lower bound selection function in stl that agrees with the normal definition of lower bound.

• Are you asking why it returns the iterator after the bound (which is guaranteed to exist, due to the C++ convention of using half-open ranges), rather than the iterator before the bound (which is not guaranteed to exist)? Or do you have some other notion of where the bound should be? – Mike Seymour Aug 28 '12 at 12:21
• I don't quite see how this is not a real question. Agreed that there are no question marks, but there seem to be some valid concerns in the text. – David Rodríguez - dribeas Aug 28 '12 at 12:35
• Yes, the name is incorrect. A better name would be least_upper_bound, but that would probably confuse most non-mathematically minded folk. A mathematically correct lower_bound function template would have to return a reverse iterator. This would be much less useful than the current scheme of returning a forward iterator to the least upper bound. The name of the function is technically incorrect, but it is still meaningful. – David Hammen Aug 28 '12 at 12:42
• Please put some effort into this question: Give it a meaningful title, and edit the body to phrase questions as proper English (including a question mark!). The question certainly has merit, but the poor presentation may be putting people off. – Kerrek SB Aug 28 '12 at 12:55
• I find the title rather useful. I was in great confusion and repeating the title (but with question marks) in my head. – tartaruga_casco_mole Oct 5 '17 at 20:51

• Lower bound: first element that is greater-or-equal.

• Upper bound: first element that is strictly greater.

Example:

+- lb(2) == ub(2)       +- lb(6)        +- lb(8)
|        == begin()     |  == ub(6)     |   +- ub(8) == end()
V                       V               V   V
+---+---+---+---+---+---+---+---+---+---+---+
| 3 | 4 | 4 | 4 | 4 | 5 | 7 | 7 | 7 | 7 | 8 |
+---+---+---+---+---+---+---+---+---+---+---+
^               ^                       ^
|               |                       |
+- lb(4)        +- ub(4)                +- lb(9) == ub(9) == end()

|- eq-range(4) -|

As you can see, the half-open equal-range for n is [lb(n), ub(n)).

Note that both bounds give you meaningful insertion locations for an element of the desired value so that the ordering is maintained, but lower_bound has the distinguishing feature that if the element already exists, then you get an iterator which actually points to that element. Thus you can use lower_bound on an ordered range to implement your own unique-membership or multiple-membership container.

void insert(Container & c, T const & t)
{
auto it = std::lower_bound(c.begin(), c.end(), t);

// if unique container:
if (it != c.end() && *it == t) { /* error, element exists! */ return; }

c.insert(it, t);
}
• It just dawned on me that lower_bound uses the order-comparison operator (like <), and so the existence condition should be rewritten as !(t < *it) in order to not require unnecessary constraints. – Kerrek SB Apr 29 '13 at 7:54
• There are no "between" pointers/iterators. Arrows in your diagram should point to actual elements and not between them. – AmokHuginnsson Dec 24 '14 at 10:22
• @AmokHuginnsson: The arrows point to the beginning of the element which the corresponding iterator would dereference. That way I don't need to invent a fictitious past-the-end element :-) – Kerrek SB Dec 24 '14 at 11:43
• @KerrekSB: Well, IMO, adding past-the-end element is better then missing important information that lower_bound and upper_bound returns iterators that point to some actual elements. Besides, for collection of simple ints, what do you mean by "beginning of the element"? - some few first bits of given int? First bit of an int? or maybe whole int? For collection of any complex type, say std::string, the iterator returned by lb or ub points to first characters of the string or to the string as whole? What I say is - your diagram can be misleading. – AmokHuginnsson Dec 26 '14 at 14:37
• Thinking of iterators as a valid location for insertion of a new element, it makes good sense for the iterators to point in between elements or better in front of an element as depicted. – YoungJohn Jun 7 '16 at 17:55

It returns the iterator one past the last element that is less than the value asked for. This is useful as an insertion position (and that's why the function returns that iterator). It's also useful that the half-open range first, lower_bound(first, last, value) specifies all values less than value.

upper_bound returns the iterator one past the last element [less than or equal to / not greater than] the value asked for. Or strictly: the last element which the value is not less than, since both algorithms deal exclusively in less-than comparators.

If you want the iterator before the iterator returned by lower_bound, you can subtract 1 (for a random access iterator), decrement (for a bidirectional iterator), or do a linear search instead of using lower_bound (for a forward iterator that is none of those).

Beware the edge case that there is no element less than the value asked for, in which case you can't have what you want, because it doesn't exist. lower_bound of course returns the beginning of the range in that case, so doesn't need a special-case return value.

• "lower_bound of course returns the beginning of the range in that case" << This bit is wrong: std::lower_bound returns the end of the range if the element doesn't exist. (and std::upper_bound does the same). – Nawaz Jul 7 '18 at 13:39
• @Nawaz I think he means the case where lower_bound == begin() – smoothware Apr 10 at 18:03

Since this has been reopened, I'll try to make my comment an answer.

The name lower_bound is mathematically incorrect. A better name might be least_upper_bound, but that would probably confuse most non-mathematically minded folk. (And then what do you call upper_bound? almost_least_upper_bound? Yech!)

My advice: Get over the fact that the names lower_bound and upper_bound are technically incorrect. The two functions as defined are quite useful. Think of those functions as a useful abuse of notation.

To make a mathematically correct lower_bound function that conforms with the C++ concept of an iterator, the function would have to return a reverse iterator rather than a forward iterator. Returning a reverse iterator is not nearly as useful as the approach taken by the perhaps misnamed lower_bound and upper_bound, and the concept of returning a reverse iterator runs afoul of the fact that not all containers are reversible.

Why a reverse iterator? Just as there is no guarantee that an upper bound exists in the container, there similarly is no guarantee that a lower bound will exist. The existing lower_bound and upper_bound return end() to indicate that the searched-for value is off-scale high. A true lower bound would need to return rend() to indicate that the searched-for value is off-scale low.

There is a way to implement a true lower bound in the form of a forward iterator, but it comes at the price of abusing the meaning of end() to mean "there is no lower bound". The problem with this abuse of notation is that some user of the function might do something equivalent to true_lower_bound(off_scale_low_search_value)-1 and voila! one has a pointer to the largest element in the set.

That said, here's how to do it. Have the true lower bound function return end() if the container is empty or if the searched-for value is smaller than the first value in the container. Otherwise return upper_bound()-1.

• I don't see why the names lower_bound and upper_bound are necessarily incorrect. The meaning is clear for me: for any value x, they give the lower and upper bounds of the range where you can insert x and not break the order of the given range. Or alternatively, all values in [begin, lower_bound) are less than x, values in [lower_bound, upper_bound) are equal to x, and [upper_bound, end) are greater than x. – musiphil Aug 28 '15 at 22:24
• Full set of good names is implemented in Java - {ceiling,floor,lower,higher}Entry() and, another, but still good, in C5 library for C# - [Weak]{Predecessor,Successor}. But they are devoted to the practical map search itself, not an abstract mathematical iterating concept around an abstract sequence. – Netch May 27 '16 at 8:08
• @musiphil I explained why by making an answer. stackoverflow.com/a/56770542/893406 – v.oddou Jun 26 at 10:26

lower_bound, upper_bound and equal_range are functions which perform binary search in a sorted sequence. The need for three functions comes from the fact that elements may be repeated in the sequence:

1, 2, 3, 4, 4, 4, 5, 6, 7

In this case, when searching for the value 4, lower_bound will return an iterator pointing to the first of the three elements with value 4, upper_bound will return an iterator pointing to the element with value 5, and equal_range will return a pair containing these two iterators.

Auch!

Did you change the original code or is the copy-paste error in there since day one?

float operator()(double f)
{
SpectrumPoint* l=std::lower_bound//...
...
SpectrumPoint* u=std::lower_bound//...
...
}

In the code I read today you are assigning lower_bound to both 'l' and 'u'.

Following David Hammen's answer, I attempted to explain why we often don't feel the names of lower_bound/upper_bound to be correct, or at least intuitive.

It's because we are looking for an element immediately lower than the query. I made a drawing and a use case: Code:

template< typename T, typename U >
auto infimum(std::map<T,U> const& ctr, T query)
{
auto it = ctr.upper_bound(query);
return it == ctr.begin() ? ctr.cend() : --it;
}

template< typename T, typename U >
bool is_in_interval(std::map<T,U> const& ctr, T query)
{
auto inf = infimum(ctr, query);
return inf == ctr.end() ? false : query <= inf->second;
}

https://ideone.com/jM8pt3

Basically to get the behavior of the "grey arrows", we need upper_bound - 1 which is why it's weird.

Let me rephrase that slightly: from the name lower_bound we instinctively expect returns-first-immediately-inferior-element (like the grey arrows). But we get returns-first-immediately-superior-element for lower_bound; and first-immediately-strictly-superior-element for upper_bound. That's what is surprising.

It's surprising in the hypothesis that you work with a sparse sequence like my thought experiment in the picture above. But it makes wonderful sense when you think of it in terms of «bounds of an equal_range» in a dense sequence, populated with plateaus, like Kerrek SB beautifully pictured.

Test code:

#include <map>
#include <cassert>
#include <iostream>

// .. paste infimum and is_in_interval here

int main()
{
using std::cout;
using Map = std::map<int,int>;
Map intervals{{2,5}, {8,9}};

auto red = infimum(intervals, 4);
assert(red->first == 2);
cout << "red->first " << red->first << "\n";

auto green = infimum(intervals, 6);
assert(green->first == 2);
cout << "green->first " << green->first << "\n";

auto pink = infimum(intervals, 8);
assert(pink->first == 8);
cout << "pink->first " << pink->first << "\n";

auto yellow = infimum(intervals, 1);
assert(yellow == intervals.cend());

auto larger_than_all = infimum(intervals, 15);
assert(larger_than_all->first == 8);

bool red_is = is_in_interval(intervals, 4);
cout << "red is in " << red_is << "\n";

bool green_is = is_in_interval(intervals, 6);
cout << "green is in " << green_is << "\n";

bool pink_is = is_in_interval(intervals, 8);
cout << "pink is in " << pink_is << "\n";

bool yellow_is = is_in_interval(intervals, 1);
cout << "yellow is in " << yellow_is << "\n";
}

results in

red->first 2
green->first 2
pink->first 8
red is in 1
green is in 0
pink is in 1
yellow is in 0

seems ok.

So of course the utility functions are not very good, they should be designed with a range API, so we can work with any collection or sub-range, or reverse iterators, or filtered views and whatnot. We can get that when we have C++20. In the meantime, I just made a simple educative map-taking API.

play with it:
https://ideone.com/jM8pt3

• I'm not sure if I understand. To begin with, why are you using std::map<int, int> to represent a set of intervals (which I believe should be something like std::set<std::pair<int, int>>)? Do the upper endpoints 5 and 9 in intervals have any significance? And what is infimum(c, q) supposed to mean? I understand the infimum of a set in mathematics, but is there a widely accepted definition of the infimum of a set and a query point? – musiphil Aug 13 at 22:40
• @musiphil all excellent sounding questions; the pair stuff offers a bit more flexibility that I didn't need in that particular example, no strong reason. And yes 5 and 9 have significance, I'm testing against "0,1,inf". It's a sort of recurrence proofing, the 5 is far away enough from 2 to test "inf" and the 9 is just 1 away from 8 so it tests "1". So indeed the function infimum is based the math definition, but loosely. I thought it would be enough to separate from the "lower_bound" terminology to fix the issue pointed by Hammem. – v.oddou Aug 26 at 5:50

Another usage of lower_bound and upper_bound is to find a range of equal elements in a container, e.g.

std::vector<int> data = { 1, 1, 2, 3, 3, 3, 3, 4, 4, 4, 5, 5, 6 };

auto lower = std::lower_bound(data.begin(), data.end(), 4);
auto upper = std::upper_bound(lower, data.end(), 4);

std::copy(lower, upper, std::ostream_iterator<int>(std::cout, " "));
• equal_range does that too, and at least shouldn't be slower than calling both lower_bound and upper_bound. – Steve Jessop Aug 28 '12 at 12:20
• in your example, wouldn't it make more sense to start the search for upper bound from lower instead of data.begin()? – Fiktik Aug 28 '12 at 12:23
• @Fiktik: Yes, indeed – Andrey Aug 28 '12 at 12:25