My algorithm needs to iteratively shrink a set by removing an element, and do something with the element removed and with the shrinking set in each iteration. And:

  • I need a genuine set with fast lookup, not just a vector containing unique elements.
  • The choice of element is arbitrary: the outcome of the algorithm doesn't depend on the order visited. The performance probably varies greatly with that choice, but let's say I want the simplest code and leave it up to the set itself to pick the element it can remove efficiently.
  • The elements are cheap to clone (very likely copyable, integers in reality, but let's be explicit about cloning in the examples here).

By the way, the algorithm is the basic form of the Bron–Kerbosch algorithm. Smarter versions of that algorithm work faster (mostly) because they don't leave the choice of element arbitrary and I'd like to learn how much that effort pays off, compared to optimizing the pop operation.

Python sets have a pop member that pretty much does that. In Scala and Go, picking and removing the "first" element of a hash set seems to work fine (where "first" corresponds to the iterator). In Rust, that is something like:

// split off an arbitrary element from a (non-empty) set
pub fn pop<T>(set: &mut HashSet<T>) -> T
    T: Eq + Clone + std::hash::Hash,
    let elt = set.iter().next().cloned().unwrap();

This seems to be a performance bottleneck compared to other languages, but even to a seemingly naive way do this kind of iteration in Rust: copying the sequence, then popping elements in sequence. I benchmarked some implementations of a pop-like function on the playground but none perform well compared to the naive way.

At first, I thought I saw that removing an element is not expensive, but picking one with iter().next() is. But on closer examination, that's not true, at least compared to other languages (*).

Using retain understandably doesn't help: it always iterates the whole set. Are there any other alternatives?

(*) On closer examination, iter().next() is quite cheap, as far as microbenchmarking can be trusted. Separate microbenchmarks say that picking an arbitrary element from a set costs (in nanoseconds on my system):

| Type of set      | Number of elements in set instance
|                  | 100 | 10,000 | 1,000,000
| Rust HashSet     |   2 |      2 |         2
| Rust BTreeSet    |  11 |     12 |        13
| Go map[]struct{} |  27 |     31 |        94
| Python set       | 125 |    125 |       125
  • Note that the set I'm using has integers, so I haven't considering memory management - I guess no cloning is necessary at all to move an element out of a set.
    – Stein
    Feb 15, 2019 at 16:12
  • Running benchmarks on the playground is a pretty terrible idea. It's a single shared EC2 instance for everyone. There are a number of reasons that any numbers from there are suspect.
    – Shepmaster
    Feb 15, 2019 at 16:29
  • @Shepmaster that's why it takes a few samples; nevertheless the result is quite consistent in my experience
    – Stein
    Feb 15, 2019 at 16:42
  • "This turns out to be a performance bottleneck compared to the other languages." you didn't prove that. And I really doubt of that too.
    – Stargateur
    Feb 15, 2019 at 16:50
  • @Stargateur I didn't prove it because I don't know if I'm doing it right, but I do have evidence at github.com/ssomers/Bron-Kerbosch.
    – Stein
    Feb 15, 2019 at 17:03

3 Answers 3


the set I'm using has integers

Don't use a HashSet; A BTreeSet has better and more consistent performance.

For N = 100000...


sequenced : 3065.098µs
pop_1     : 2941.876µs
pop_2     : 2927.429µs


sequenced : 3091.454µs
pop_1     : 172547.080µs
pop_2     : 807182.085µs
  • 1
    Unforunately I'm not seeing better performance replacing HashSet with BTreeSet. In the benchmark above, that only shrinks the set, BTreeSet is a champion indeed. But the complete algorithm is worse off on small sets and orders of magnitude slower on big sets (of a million integers). Profiling suggests it's the intersections done every iteration. Maybe because the sets intersected are typically very asymmetric: HashSet.intersection does the intersection of a small set with a big set quite efficiently.
    – Stein
    Feb 15, 2019 at 21:06
  • WIth a performance-savvier implementation of intersection, BTreeSet scales as good as HashSet, and better, for some uses at least. Still up to 50% slower for small sets, but faster on huge sets for some algorithms. The intersection implementation is on github and hopefully one day in Rust itself.
    – Stein
    Feb 17, 2019 at 11:44
  • 1
    An even more performance-savvy implementation of BTreeSet intersection has been merged in
    – Stein
    Apr 3, 2019 at 8:47

I guess the same advice applies as in Can I randomly sample from a HashSet efficiently?: copy the set as a vector just to iterate over it as shown in the "sequenced" solution in the benchmark:

let seq: Vec<u32> = set.iter().cloned().collect();
for elt in seq {

That means this answer is not applicable if you need to shrink the set (pick an arbitrary element) only once or a few times, or if the set contents cannot be cheaply cloned.


Your code can be simplified a bit:

let elt = set.iter().next().cloned().unwrap();

If you want to remove all elements from a HashSet then you should use the drain iterator - it is very efficient.

HashSet from the Rust standard library is not that fast. Try replacing it with one from the hashbrown crate.

  • 1
    drain does not allow using the shrinking set, right? It immediately makes the set inaccessible and/or empty.
    – Stein
    Feb 16, 2019 at 14:49
  • is not that fast — this is an very misleading statement. The insinuation is that the current implementation of HashMap is always slow, but the new implementation in hashbrown just happens to be faster. There's even work to replace the standard library implementation with that from hashbrown, which will likely make this point moot eventually.
    – Shepmaster
    Feb 18, 2019 at 15:17
  • I disagree that the proposed code is any simpler. It now has two potential panics as opposed to the original one.
    – Shepmaster
    Feb 18, 2019 at 15:20
  • The proposed code isn't simpler because the code I listed also panics on an empty set, unlike the "better" alternatives on the playground comparison. In proper Rust style, returning an Option, and once you're familiar with it, it is indeed a bit simpler. I wondered if there is a runtime performance difference but my benchmark on github says they're the same.
    – Stein
    Mar 12, 2019 at 13:58
  • For the use in the question here, the hashbron implementation is better than the standard HashSet and than the fnv crate's FnvHashSet, but still much less scalable than the standard BTreeSet. For the other set usage I evaluated (mainly intersection), they're all equally scalable, hashbrown being the slowest and FnvHashSet the fastest.
    – Stein
    Apr 4, 2019 at 14:04

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