I would like to understand what shall I put instead of xxxxx to have a 1000 items array initialized with structs where a goes from 2000 to 3000 (i.e., index 1 of the array means a is 2000, index 2 of the array means a is 2001, and so on) and b is always zero.
struct MyStruct
a
b
end
myArray = Vector{MyStruct}( xxxxx , 1000)
I understand I can make a loop and individually assign the values, I am just wondering if there is something faster in Julia.
Just collecting the answers and comments from other users in a single post:
Unlike other scripting languages like Python and R, loops are fast in Julia. In fact, other "vectorized" operations, like broadcasting, are implemented in terms of Julia loops themselves. Thus, a fast solution could be:
function initialize_vector(range::AbstractRange)
v = Vector{MyStruct}(undef, length(range))
@inbounds for i in eachindex(range)
v[i] = MyStruct(range[i], 0)
end
return v
end
Broadcasting is almost, or sometimes just as fast as looping, and can often be more terse and convenient. In this case, the function initialize_vector above can be written:
initialize_vector(range::AbstractRange) = MyStruct.(range, 0)
Benchmarking shows that the two functions are almost the same in speed.
Julia relies on accurate inference of types to create fast, specialized code. If the types of MyStruct.a and MyStruct.b can be anything, it's generally not possible to infer exactly what kind of operations should be performed on a MyStruct. Even in this case, where the compiler is able to infer that the types are Int, each MyStruct has to contain references to heap-allocated Ints instead of being stack-allocated. Thus, a 10x speedup is obtained from simply changing
struct MyStruct
a
b
end
to
struct MyStruct
a::Int
b::Int
end
If you want to the type of Mystruct.a and MyStruct.b to be able to vary, you can create a parametric MyStruct, like so:
struct MyStruct{T}
a::T
b::T
end
c which is a String, would it make this faster if the String is fixed length? Is that possible in Julia? If so, how?
UInt64 as backing storage, and if it's larger (up to say, 100 bytes), I'd use a SArray{Tuple{3},UInt8,1,3} from the package StaticArrays.
Oct 28, 2019 at 9:07
Broadcasting via the . works nicely here. You could also provide a vector/collection for b:
struct MyStruct
a
b
end
struct_vec = [MyStruct.(2000:3000, 0)...]
struct_vec2 = [MyStruct.(2000:3000, 0:1000)...]
Which results in a 1001-element Array{MyStruct,1}.
Edit
As mentioned in the comments, the ... splatting and the [] are not necessary. Furthermore, to improve the performance of your struct, you could specify type information of its fields:
struct MyEfficientStruct{T}
a::T
b::T
end
struct_vec = MyEfficientStruct.(2000:3000, 0)
struct_vec2 = MyEfficientStruct.(2000:3000, 0:1000)
Finally, while the broadcasting syntax is more terse than a loop, a big advantage of Julia is that the loop is just as fast (and sometimes faster) than the vectorized operation.
a go from 200 to 100 using 5 as step. (i.e. 200, 95, 90, 85, 80....)
vec = [MyStruct.(200:-5:100, 0)]
..., and then collecting it back into an array again. That's highly redundant. Just do MyStruct.(2000:3000, 0).
MyStruct.(2000:3000, 0).