In Julia, theArray type holds both "bits" values as well as heap-allocated "boxed" values. The distinction is whether the value itself is stored inline (in the direct allocated memory of the array), or if the memory of the array is simply a collection of pointers to objects allocated elsewhere. In terms of performance, accessing values inline is clearly an advantage over having to follow a pointer to the actual value. The definition of "isbits" generally means any Julia type with a fixed, determinate size, meaning no "pointer" fields, see?isbitstype.
Julia also supports Union types, quite literally the union of a set of types. Custom Union type definitions can be extremely handy for applications wishing to "cut across" the nominal type system (i.e. explicit subtype relationships) and define methods or functionality on these, otherwise unrelated, set of types. A compiler challenge, however, is in determining how to treat these Union types. The naive approach (and indeed, what Julia itself did pre-0.7), is to simply make a "box" and then a pointer in the box to the actual value, similar to the previously mentioned "boxed" values. This is unfortunate, however, because of the number of small, primitive "bits" types (thinkUInt8,Int32,Float64, etc.) that would easily fit themselves inline in this "box" without needing any indirection for value access. There are two main ways Julia can take advantage of this optimization as of 0.7: isbits Union fields in types, and isbits Union Arrays.
Julia now includes an optimization wherein "isbits Union" fields in types (mutable struct,struct, etc.) will be stored inline. This is accomplished by determining the "inline size" of the Union type (e.g.Union{UInt8, Int16} will have a size of two bytes, which represents the size needed of the largest Union typeInt16), and in addition, allocating an extra "type tag byte" (UInt8), whose value signals the type of the actual value stored inline of the "Union bytes". The type tag byte value is the index of the actual value's type in the Union type's order of types. For example, a type tag value of0x02 for a field with typeUnion{Nothing, UInt8, Int16} would indicate that anInt16 value is stored in the 16 bits of the field in the structure's memory; a0x01 value would indicate that aUInt8 value was stored in the first 8 bits of the 16 bits of the field's memory. Lastly, a value of0x00 signals that thenothing value will be returned for this field, even though, as a singleton type with a single type instance, it technically has a size of 0. The type tag byte for a type's Union field is stored directly after the field's computed Union memory.
Julia can now also store "isbits Union" values inline in a Memory, as opposed to requiring an indirection box. The optimization is accomplished by storing an extra "type tag memory" of bytes, one byte per element, alongside the bytes of the actual data. This type tag memory serves the same function as the type field case: its value signals the type of the actual stored Union value. The "type tag memory" directly follows the regular data space. So the formula to access an isbits Union Array's type tag bytes isa->data + a->length * a->elsize.
Settings
This document was generated withDocumenter.jl version 1.8.0 onWednesday 9 July 2025. Using Julia version 1.11.6.