Ziglang-Set: a generic and general-purpose Set implementation for Zig.
🚧 PRE-ALPHA 🚧
Zig currently does not have a built-in, general purpose Set data structure at this point in time. Until it does, try this!
Rationale: It may be common knowledge that a dictionary or map or hashset can be used as a set where the value is basically void. While this is true, there's a lot to think about in terms of supporting all the common set operations in a performant and correct way and there's no good reason why a common module for this can't exist. After studying the Zig stdlib, I'm hoping this implementation can fill that gap and provide some value.
This module offers a Set implementation built in the same vein and spirit of the other data structures within the Zig standard library. This is my attempt to model one that can get better over time and grow with community interest and support. See a problem, file a bug! Or better yet contribute and let's build the best implementation together.
I am the original author of the popular Go based set package: golang-set that is used by software components built by Docker, 1Password, Ethereum, SendGrid, CrowdStrike and HashiCorp. At just shy of 4k stars
, I figured I'd take a crack at building a comprehensive and generic Zig-based set that goes above and beyond the original Go implementation. After using Zig for over 2.5 years on personal projects, I thought it was time that Zig had a robust Set implementation for itself.
This implementation gives credit and acknowledgement to the Zig language and powerful Std Library HashMap data structure of which this set implementation is built on top of. Without that, this probably wouldn't exist. Efforts will be made to keep the Ziglang Set code fast and straightforward but this Set's raw speed will largely be bounded by the performance of the Zig HashMap of which it is built on top of.
- Offers idiomatic, generic-based Zig API - allocators, iterators, capacity hints, clearing, resizing, etc.
- A few flavors to choose from
- Hash-based: everyday usecase, optimized for lookups primarily, insertion/removal secondarily - further reading
- HashSetManaged - initializes with an allocator and holds it internally (built on top of unmanaged)
- HashSetUnmanaged - does not hold an allocator, smaller footprint
- Array-based: more specialized, iteration much faster, insertion order preserved, indexing into underylying data - further reading
- ArrayHashSetManaged - initializes with an allocator and holds it internally (built on top of unmanaged)
- ArrayHashSetUnmanaged - does not hold an allocator, smaller footprint
- Hash-based: everyday usecase, optimized for lookups primarily, insertion/removal secondarily - further reading
- Common set operations
- add, append, appendSlice
- remove, removeAll
- containsOne, containsAny, containsAll
- clone, cloneWithAllocator
- equals, isEmpty, cardinality
- intersection, intersectionUpdate (in-place variant)
- union, unionUpdate (in-place variant)
- difference, differenceUpdate (in-place variant)
- symmetricDifference, symmetricDifferenceUpdate (in-place variant)
- isSubset
- isSuperset
- isProperSubset
- isProperSuperset
- pop
- Fully documented and robustly tested - in progress
- Performance aware to minimize unecessary allocs/iteration internally
- "string" support - coming soon
- Benchmarks - coming soon
- A set offers a fast way to manipulate data and avoid excessive looping. Look into it as there is already tons of literature on the advantages of having a set in your arsenal of tools.
// import the namespace.
const set = @import("ziglangSet");
// Create a set of u32s called A
var A = set.Set(u32).init(std.testing.allocator);
defer A.deinit();
// Add some data
_ = try A.add(5);
_ = try A.add(6);
_ = try A.add(7);
// Add more data; single shot, duplicate data is ignored.
_ = try A.appendSlice(&.{ 5, 3, 0, 9 });
// Create another set called B
var B = set.Set(u32).init(std.testing.allocator);
defer B.deinit();
// Add data to B
_ = try B.appendSlice(&.{ 50, 30, 20 });
// Get the union of A | B
var un = try A.unionOf(B);
defer un.deinit();
// Grab an iterator and dump the contents.
var iter = un.iterator();
while (iter.next()) |el| {
std.log.debug("element: {d}", .{el.*});
}
Output of A | B
- the union of A and B (order is not guaranteed)
> element: 5
> element: 6
> element: 7
> element: 3
> element: 0
> element: 9
> element: 50
> element: 30
> element: 20
To add this module, update your applications build.zig.zon file by adding the .ziglang-set
dependency definition.
.{
.name = "your-app",
.version = "0.1.0",
.dependencies = .{
.ziglangSet = .{
.url = "https://github.com/deckarep/ziglang-set/archive/$COMMIT_YOU_WANT_TO_USE.tar.gz",
},
},
}
When running zig build now, Zig will tell you you need a hash for the dependency and provide one. Put it in your dependency so it looks like:
.{
.ziglangSet = .{
.url = "https://github.com/deckarep/ziglang-set/archive/$COMMIT_YOU_WANT_TO_USE.tar.gz",
.hash = "$HASH_ZIG_GAVE_YOU",
},
}
With the dependency in place, you can now put the following in your build.zig file:
const ziglangSet = b.dependency("ziglangSet", .{});
exe.root_module.addImport("ziglangSet", ziglangSet.module("ziglangSet"));
In the above change exe
to whatever CompileStep you are using. For an executable it will
probably be exe, but main_tests
or lib are also common.
With the build file in order, you can now use the module in your zig source. For example:
const std = @import("std");
const set = @import("ziglangSet");
pub fn main() void {
// 1. This datastructure requires an allocator.
// Setup and choose your respective allocator.
// See: https://zig.guide/standard-library/allocators
// 2. Go to town!
var A = set.Set(u32).init(allocator);
defer A.deinit();
// Now do something cool with your set!
// ...
}
Check the tests for more comprehensive examples on how to use this package.
zig build test