Documentation
will show documentation for the relevant function, macro or string macro respectively. Most Julia environments provide a way to access documentation directly:
- VS Code shows documentation when you hover over a function name. You can also use the Julia panel in the sidebar to search for documentation.
- In , open the “Live Docs” panel on the bottom right.
- In Juno using
Ctrl-J, Ctrl-D
will show the documentation for the object
under the cursor.
Julia enables package developers and users to document functions, types and other objects easily via a built-in documentation system.
The basic syntax is simple: any string appearing just before an object (function, macro, type or instance) will be interpreted as documenting it (these are called docstrings). Note that no blank lines or comments may intervene between a docstring and the documented object. Here is a basic example:
"Tell whether there are too foo items in the array."
foo(xs::Array) = ...
Documentation is interpreted as Markdown, so you can use indentation and code fences to delimit code examples from text. Technically, any object can be associated with any other as metadata; Markdown happens to be the default, but one can construct other string macros and pass them to the @doc
macro just as well.
Note
Markdown support is implemented in the Markdown
standard library and for a full list of supported syntax see the .
Here is a more complex example, still using Markdown:
"""
bar(x[, y])
Compute the Bar index between `x` and `y`.
If `y` is unspecified, compute the Bar index between all pairs of columns of `x`.
# Examples
```julia-repl
julia> bar([1, 2], [1, 2])
1
```
"""
function bar(x, y) ...
As in the example above, we recommend following some simple conventions when writing documentation:
Always show the signature of a function at the top of the documentation, with a four-space indent so that it is printed as Julia code.
This can be identical to the signature present in the Julia code (like
mean(x::AbstractArray)
), or a simplified form. Optional arguments should be represented with their default values (i.e.f(x, y=1)
) when possible, following the actual Julia syntax. Optional arguments which do not have a default value should be put in brackets (i.e.f(x[, y])
andf(x[, y[, z]])
). An alternative solution is to use several lines: one without optional arguments, the other(s) with them. This solution can also be used to document several related methods of a given function. When a function accepts many keyword arguments, only include a<keyword arguments>
placeholder in the signature (i.e.f(x; <keyword arguments>)
), and give the complete list under an# Arguments
section (see point 4 below).Include a single one-line sentence describing what the function does or what the object represents after the simplified signature block. If needed, provide more details in a second paragraph, after a blank line.
The one-line sentence should use the imperative form (“Do this”, “Return that”) instead of the third person (do not write “Returns the length…”) when documenting functions. It should end with a period. If the meaning of a function cannot be summarized easily, splitting it into separate composable parts could be beneficial (this should not be taken as an absolute requirement for every single case though).
Do not repeat yourself.
Since the function name is given by the signature, there is no need to start the documentation with “The function
bar
…”: go straight to the point. Similarly, if the signature specifies the types of the arguments, mentioning them in the description is redundant.Only provide an argument list when really necessary.
For simple functions, it is often clearer to mention the role of the arguments directly in the description of the function’s purpose. An argument list would only repeat information already provided elsewhere. However, providing an argument list can be a good idea for complex functions with many arguments (in particular keyword arguments). In that case, insert it after the general description of the function, under an
# Arguments
header, with one-
bullet for each argument. The list should mention the types and default values (if any) of the arguments:"""
...
# Arguments
- `n::Integer`: the number of elements to compute.
- `dim::Integer=1`: the dimensions along which to perform the computation.
...
"""
Provide hints to related functions.
Sometimes there are functions of related functionality. To increase discoverability please provide a short list of these in a
See also
paragraph.See also [`bar!`](@ref), [`baz`](@ref), [`baaz`](@ref).
Include any code examples in an
# Examples
section.Examples should, whenever possible, be written as doctests. A doctest is a fenced code block (see Code blocks) starting with
```jldoctest
and contains any number ofjulia>
prompts together with inputs and expected outputs that mimic the Julia REPL.Note
Doctests are enabled by . For more detailed documentation see Documenter’s manual.
For example in the following docstring a variable
a
is defined and the expected result, as printed in a Julia REPL, appears afterwards:"""
Some nice documentation here.
# Examples
```jldoctest
julia> a = [1 2; 3 4]
2×2 Array{Int64,2}:
1 2
3 4
```
"""
Warning
Calling
rand
and other RNG-related functions should be avoided in doctests since they will not produce consistent outputs during different Julia sessions. If you would like to show some random number generation related functionality, one option is to explicitly construct and seed your own RNG object (see ) and pass it to the functions you are doctesting.Operating system word size (Int32 or ) as well as path separator differences (
/
or\
) will also affect the reproducibility of some doctests.You can then run
make -C doc doctest=true
to run all the doctests in the Julia Manual and API documentation, which will ensure that your example works.To indicate that the output result is truncated, you may write
[...]
at the line where checking should stop. This is useful to hide a stacktrace (which contains non-permanent references to lines of julia code) when the doctest shows that an exception is thrown, for example:```jldoctest
julia> div(1, 0)
ERROR: DivideError: integer division error
[...]
```
Examples that are untestable should be written within fenced code blocks starting with
```julia
so that they are highlighted correctly in the generated documentation.Tip
Wherever possible examples should be self-contained and runnable so that readers are able to try them out without having to include any dependencies.
Use backticks to identify code and equations.
Julia identifiers and code excerpts should always appear between backticks
`
to enable highlighting. Equations in the LaTeX syntax can be inserted between double backticks``
. Use Unicode characters rather than their LaTeX escape sequence, i.e.``α = 1``
rather than``\\alpha = 1``
.Place the starting and ending
"""
characters on lines by themselves.That is, write:
"""
...
...
"""
f(x, y) = ...
rather than:
"""...
..."""
f(x, y) = ...
This makes it clearer where docstrings start and end.
Provide information allowing custom types to implement the function in an
# Implementation
section. These implementation details are intended for developers rather than users, explaining e.g. which functions should be overridden and which functions automatically use appropriate fallbacks. Such details are best kept separate from the main description of the function’s behavior.For long docstrings, consider splitting the documentation with an
# Extended help
header. The typical help-mode will show only the material above the header; you can access the full help by adding a ‘?’ at the beginning of the expression (i.e., “??foo” rather than “?foo”).
Functions in Julia may have multiple implementations, known as methods. While it’s good practice for generic functions to have a single purpose, Julia allows methods to be documented individually if necessary. In general, only the most generic method should be documented, or even the function itself (i.e. the object created without any methods by function bar end
). Specific methods should only be documented if their behaviour differs from the more generic ones. In any case, they should not repeat the information provided elsewhere. For example:
"""
*(x, y, z...)
Multiplication operator. `x * y * z *...` calls this function with multiple
arguments, i.e. `*(x, y, z...)`.
"""
function *(x, y, z...)
# ... [implementation sold separately] ...
end
"""
*(x::AbstractString, y::AbstractString, z::AbstractString...)
When applied to strings, concatenates them.
"""
function *(x::AbstractString, y::AbstractString, z::AbstractString...)
# ... [insert secret sauce here] ...
end
help?> *
search: * .*
*(x, y, z...)
Multiplication operator. x * y * z *... calls this function with multiple
arguments, i.e. *(x,y,z...).
*(x::AbstractString, y::AbstractString, z::AbstractString...)
When applied to strings, concatenates them.
When retrieving documentation for a generic function, the metadata for each method is concatenated with the catdoc
function, which can of course be overridden for custom types.
The @doc
macro associates its first argument with its second in a per-module dictionary called META
.
To make it easier to write documentation, the parser treats the macro name @doc
specially: if a call to @doc
has one argument, but another expression appears after a single line break, then that additional expression is added as an argument to the macro. Therefore the following syntax is parsed as a 2-argument call to @doc
:
@doc raw"""
...
"""
f(x) = x
This makes it possible to use expressions other than normal string literals (such as the raw""
string macro) as a docstring.
When used for retrieving documentation, the @doc
macro (or equally, the doc
function) will search all META
dictionaries for metadata relevant to the given object and return it. The returned object (some Markdown content, for example) will by default display itself intelligently. This design also makes it easy to use the doc system in a programmatic way; for example, to re-use documentation between different versions of a function:
Or for use with Julia’s metaprogramming functionality:
for (f, op) in ((:add, :+), (:subtract, :-), (:multiply, :*), (:divide, :/))
@eval begin
$f(a,b) = $op(a,b)
end
end
@doc "`add(a,b)` adds `a` and `b` together" add
@doc "`subtract(a,b)` subtracts `b` from `a`" subtract
Documentation written in non-toplevel blocks, such as begin
, if
, for
, and let
, is added to the documentation system as blocks are evaluated. For example:
if condition()
"..."
f(x) = x
end
will add documentation to f(x)
when condition()
is true
. Note that even if f(x)
goes out of scope at the end of the block, its documentation will remain.
It is possible to make use of metaprogramming to assist in the creation of documentation. When using string-interpolation within the docstring you will need to use an extra $
as shown with $($name)
:
for func in (:day, :dayofmonth)
name = string(func)
@eval begin
@doc """
$($name)(dt::TimeType) -> Int64
The day of month of a `Date` or `DateTime` as an `Int64`.
""" $func(dt::Dates.TimeType)
end
end
Sometimes the appropriate documentation for an instance of a type depends on the field values of that instance, rather than just on the type itself. In these cases, you can add a method to Docs.getdoc
for your custom type that returns the documentation on a per-instance basis. For instance,
struct MyType
value::Int
end
Docs.getdoc(t::MyType) = "Documentation for MyType with value $(t.value)"
x = MyType(1)
y = MyType(2)
?x
will display “Documentation for MyType with value 1” while ?y
will display “Documentation for MyType with value 2”.
In the following examples "..."
is used to illustrate an arbitrary docstring.
The $
and \
characters are still parsed as string interpolation or start of an escape sequence in docstrings too. The raw""
string macro together with the @doc
macro can be used to avoid having to escape them. This is handy when the docstrings include LaTeX or Julia source code examples containing interpolation:
@doc raw"""
```math
\LaTeX
```
"""
function f end
"..."
function f end
"..."
Adds docstring "..."
to the function f
. The first version is the preferred syntax, however both are equivalent.
"..."
f(x) = x
"..."
function f(x)
x
end
"..."
f(x)
Adds docstring "..."
to the method f(::Any)
.
"..."
f(x, y = 1) = x + y
Adds docstring "..."
to two Method
s, namely f(::Any)
and f(::Any, ::Any)
.
"..."
macro m(x) end
Adds docstring "..."
to the @m(::Any)
macro definition.
"..."
:(@m)
Adds docstring "..."
to the macro named @m
.
Types
Adds the docstring to types T1
, T2
, and T3
.
"..."
struct T
"x"
x
"y"
y
end
Adds docstring "..."
to type T
, "x"
to field T.x
and "y"
to field T.y
. Also applicable to mutable struct
types.
Modules
"..."
module M end
module M
"..."
M
end
Adds docstring "..."
to the Module
M
. Adding the docstring above the Module
is the preferred syntax, however both are equivalent.
"..."
baremodule M
# ...
end
baremodule M
import Base: @doc
"..."
f(x) = x
end
Documenting a baremodule
by placing a docstring above the expression automatically imports @doc
into the module. These imports must be done manually when the module expression is not documented.
"..."
const a = 1
"..."
b = 2
"..."
global c = 3
Adds docstring "..."
to the Binding
s a
, b
, and c
.
Binding
s are used to store a reference to a particular Symbol
in a Module
without storing the referenced value itself.
Note
When a const
definition is only used to define an alias of another definition, such as is the case with the function div
and its alias ÷
in Base
, do not document the alias and instead document the actual function.
If the alias is documented and not the real definition then the docsystem (?
mode) will not return the docstring attached to the alias when the real definition is searched for.
For example you should write
"..."
f(x) = x + 1
const alias = f
rather than
f(x) = x + 1
"..."
const alias = f
"..."
sym
Adds docstring "..."
to the value associated with sym
. However, it is preferred that sym
is documented where it is defined.
"..."
a, b
Adds docstring "..."
to a
and b
each of which should be a documentable expression. This syntax is equivalent to
"..."
a
"..."
b
Any number of expressions many be documented together in this way. This syntax can be useful when two functions are related, such as non-mutating and mutating versions f
and f!
.
"..."
@m expression
Adds docstring "..."
to the expression generated by expanding @m expression
. This allows for expressions decorated with @inline
, @noinline
, @generated
, or any other macro to be documented in the same way as undecorated expressions.
Macro authors should take note that only macros that generate a single expression will automatically support docstrings. If a macro returns a block containing multiple subexpressions then the subexpression that should be documented must be marked using the @__doc__ macro.
The macro makes use of @__doc__
to allow for documenting Enums. Examining its definition should serve as an example of how to use @__doc__
correctly.
— Macro
Low-level macro used to mark expressions returned by a macro that should be documented. If more than one expression is marked then the same docstring is applied to each expression.
macro example(f)
quote
$(f)() = 0
@__doc__ $(f)(x) = 1
$(f)(x, y) = 2
end
@__doc__
has no effect when a macro that uses it is not documented.