Essentials
Introduction
The Julia standard library contains a range of functions and macros appropriate for performing scientific and numerical computing, but is also as broad as those of many general purpose programming languages. Additional functionality is available from a growing collection of available packages. Functions are grouped by topic below.
Some general notes:
Except for functions in built-in modules (
Pkg
,Collections
,Test
andProfile
), all functions documented here are directly available for use in programs.To use module functions, use
import Module
to import the module, andModule.fn(x)
to use the functions.Alternatively,
using Module
will import all exportedModule
functions into the current namespace.By convention, function names ending with an exclamation point (
!
) modify their arguments. Some functions have both modifying (e.g.,sort!
) and non-modifying (sort
) versions.
Getting Around
Base.exit
— Function.exit([code])
Quit (or control-D at the prompt). The default exit code is zero, indicating that the processes completed successfully.
Base.quit
— Function.quit()
Quit the program indicating that the processes completed successfully. This function calls exit(0)
(see exit
).
Base.atexit
— Function.atexit(f)
Register a zero-argument function f()
to be called at process exit. atexit()
hooks are called in last in first out (LIFO) order and run before object finalizers.
Base.atreplinit
— Function.atreplinit(f)
Register a one-argument function to be called before the REPL interface is initialized in interactive sessions; this is useful to customize the interface. The argument of f
is the REPL object. This function should be called from within the .juliarc.jl
initialization file.
Base.isinteractive
— Function.isinteractive() -> Bool
Determine whether Julia is running an interactive session.
Base.whos
— Function.whos(io::IO=STDOUT, m::Module=current_module(), pattern::Regex=r"")
Print information about exported global variables in a module, optionally restricted to those matching pattern
.
The memory consumption estimate is an approximate lower bound on the size of the internal structure of the object.
Base.summarysize
— Function.Base.summarysize(obj; exclude=Union{...}, chargeall=Union{...}) -> Int
Compute the amount of memory used by all unique objects reachable from the argument.
Keyword Arguments
exclude
: specifies the types of objects to exclude from the traversal.chargeall
: specifies the types of objects to always charge the size of all of their fields, even if those fields would normally be excluded.
Base.edit
— Method.edit(path::AbstractString, line::Integer=0)
Edit a file or directory optionally providing a line number to edit the file at. Returns to the julia
prompt when you quit the editor. The editor can be changed by setting JULIA_EDITOR
, VISUAL
or EDITOR
as an environment variable.
Base.edit
— Method.edit(function, [types])
Edit the definition of a function, optionally specifying a tuple of types to indicate which method to edit. The editor can be changed by setting JULIA_EDITOR
, VISUAL
or EDITOR
as an environment variable.
Base.@edit
— Macro.@edit
Evaluates the arguments to the function or macro call, determines their types, and calls the edit
function on the resulting expression.
Base.less
— Method.less(file::AbstractString, [line::Integer])
Show a file using the default pager, optionally providing a starting line number. Returns to the julia
prompt when you quit the pager.
Base.less
— Method.less(function, [types])
Show the definition of a function using the default pager, optionally specifying a tuple of types to indicate which method to see.
Base.@less
— Macro.@less
Evaluates the arguments to the function or macro call, determines their types, and calls the less
function on the resulting expression.
Base.clipboard
— Method.clipboard(x)
Send a printed form of x
to the operating system clipboard ("copy").
Base.clipboard
— Method.clipboard() -> AbstractString
Return a string with the contents of the operating system clipboard ("paste").
Base.reload
— Function.reload(name::AbstractString)
Force reloading of a package, even if it has been loaded before. This is intended for use during package development as code is modified.
Base.require
— Function.require(module::Symbol)
This function is part of the implementation of using
/ import
, if a module is not already defined in Main
. It can also be called directly to force reloading a module, regardless of whether it has been loaded before (for example, when interactively developing libraries).
Loads a source file, in the context of the Main
module, on every active node, searching standard locations for files. require
is considered a top-level operation, so it sets the current include
path but does not use it to search for files (see help for include
). This function is typically used to load library code, and is implicitly called by using
to load packages.
When searching for files, require
first looks for package code under Pkg.dir()
, then tries paths in the global array LOAD_PATH
. require
is case-sensitive on all platforms, including those with case-insensitive filesystems like macOS and Windows.
Base.compilecache
— Function.Base.compilecache(module::String)
Creates a precompiled cache file for a module and all of its dependencies. This can be used to reduce package load times. Cache files are stored in LOAD_CACHE_PATH[1]
, which defaults to ~/.julia/lib/VERSION
. See Module initialization and precompilation for important notes.
Base.__precompile__
— Function.__precompile__(isprecompilable::Bool=true)
Specify whether the file calling this function is precompilable. If isprecompilable
is true
, then __precompile__
throws an exception when the file is loaded by using
/import
/require
unless the file is being precompiled, and in a module file it causes the module to be automatically precompiled when it is imported. Typically, __precompile__()
should occur before the module
declaration in the file, or better yet VERSION >= v"0.4" && __precompile__()
in order to be backward-compatible with Julia 0.3.
If a module or file is not safely precompilable, it should call __precompile__(false)
in order to throw an error if Julia attempts to precompile it.
__precompile__()
should not be used in a module unless all of its dependencies are also using __precompile__()
. Failure to do so can result in a runtime error when loading the module.
Base.include
— Function.include(path::AbstractString)
Evaluate the contents of the input source file in the current context. Returns the result of the last evaluated expression of the input file. During including, a task-local include path is set to the directory containing the file. Nested calls to include
will search relative to that path. All paths refer to files on node 1 when running in parallel, and files will be fetched from node 1. This function is typically used to load source interactively, or to combine files in packages that are broken into multiple source files.
Base.include_string
— Function.include_string(code::AbstractString, filename::AbstractString="string")
Like include
, except reads code from the given string rather than from a file. Since there is no file path involved, no path processing or fetching from node 1 is done.
Base.include_dependency
— Function.include_dependency(path::AbstractString)
In a module, declare that the file specified by path
(relative or absolute) is a dependency for precompilation; that is, the module will need to be recompiled if this file changes.
This is only needed if your module depends on a file that is not used via include
. It has no effect outside of compilation.
Base.Docs.apropos
— Function.apropos(string)
Search through all documentation for a string, ignoring case.
Base.which
— Method.which(f, types)
Returns the method of f
(a Method
object) that would be called for arguments of the given types
.
If types
is an abstract type, then the method that would be called by invoke
is returned.
Base.which
— Method.which(symbol)
Return the module in which the binding for the variable referenced by symbol
was created.
Base.@which
— Macro.@which
Applied to a function or macro call, it evaluates the arguments to the specified call, and returns the Method
object for the method that would be called for those arguments. Applied to a variable, it returns the module in which the variable was bound. It calls out to the which
function.
Base.methods
— Function.methods(f, [types])
Returns the method table for f
.
If types
is specified, returns an array of methods whose types match.
Base.methodswith
— Function.methodswith(typ[, module or function][, showparents::Bool=false])
Return an array of methods with an argument of type typ
.
The optional second argument restricts the search to a particular module or function (the default is all modules, starting from Main).
If optional showparents
is true
, also return arguments with a parent type of typ
, excluding type Any
.
Base.@show
— Macro.@show
Show an expression and result, returning the result.
Base.versioninfo
— Function.versioninfo(io::IO=STDOUT, verbose::Bool=false)
Print information about the version of Julia in use. If the verbose
argument is true
, detailed system information is shown as well.
Base.workspace
— Function.workspace()
Replace the top-level module (Main
) with a new one, providing a clean workspace. The previous Main
module is made available as LastMain
. A previously-loaded package can be accessed using a statement such as using LastMain.Package
.
This function should only be used interactively.
ans
— Keyword.ans
A variable referring to the last computed value, automatically set at the interactive prompt.
All Objects
Core.:===
— Function.===(x,y) -> Bool
≡(x,y) -> Bool
Determine whether x
and y
are identical, in the sense that no program could distinguish them. Compares mutable objects by address in memory, and compares immutable objects (such as numbers) by contents at the bit level. This function is sometimes called egal
.
julia> a = [1, 2]; b = [1, 2];
julia> a == b
true
julia> a === b
false
julia> a === a
true
Core.isa
— Function.isa(x, type) -> Bool
Determine whether x
is of the given type
. Can also be used as an infix operator, e.g. x isa type
.
Base.isequal
— Method.isequal(x, y)
Similar to ==
, except treats all floating-point NaN
values as equal to each other, and treats -0.0
as unequal to 0.0
. The default implementation of isequal
calls ==
, so if you have a type that doesn't have these floating-point subtleties then you probably only need to define ==
.
isequal
is the comparison function used by hash tables (Dict
). isequal(x,y)
must imply that hash(x) == hash(y)
.
This typically means that if you define your own ==
function then you must define a corresponding hash
(and vice versa). Collections typically implement isequal
by calling isequal
recursively on all contents.
Scalar types generally do not need to implement isequal
separate from ==
, unless they represent floating-point numbers amenable to a more efficient implementation than that provided as a generic fallback (based on isnan
, signbit
, and ==
).
julia> isequal([1., NaN], [1., NaN])
true
julia> [1., NaN] == [1., NaN]
false
julia> 0.0 == -0.0
true
julia> isequal(0.0, -0.0)
false
Base.isequal
— Method.isequal(x, y)
Similar to ==
, except treats all floating-point NaN
values as equal to each other, and treats -0.0
as unequal to 0.0
. The default implementation of isequal
calls ==
, so if you have a type that doesn't have these floating-point subtleties then you probably only need to define ==
.
isequal
is the comparison function used by hash tables (Dict
). isequal(x,y)
must imply that hash(x) == hash(y)
.
This typically means that if you define your own ==
function then you must define a corresponding hash
(and vice versa). Collections typically implement isequal
by calling isequal
recursively on all contents.
Scalar types generally do not need to implement isequal
separate from ==
, unless they represent floating-point numbers amenable to a more efficient implementation than that provided as a generic fallback (based on isnan
, signbit
, and ==
).
julia> isequal([1., NaN], [1., NaN])
true
julia> [1., NaN] == [1., NaN]
false
julia> 0.0 == -0.0
true
julia> isequal(0.0, -0.0)
false
isequal(x::Nullable, y::Nullable)
If neither x
nor y
is null, compare them according to their values (i.e. isequal(get(x), get(y))
). Else, return true
if both arguments are null, and false
if one is null but not the other: nulls are considered equal.
Base.isless
— Function.isless(x, y)
Test whether x
is less than y
, according to a canonical total order. Values that are normally unordered, such as NaN
, are ordered in an arbitrary but consistent fashion. This is the default comparison used by sort
. Non-numeric types with a canonical total order should implement this function. Numeric types only need to implement it if they have special values such as NaN
.
Base.isless
— Method.isless(x::Nullable, y::Nullable)
If neither x
nor y
is null, compare them according to their values (i.e. isless(get(x), get(y))
). Else, return true
if only y
is null, and false
otherwise: nulls are always considered greater than non-nulls, but not greater than another null.
Base.ifelse
— Function.ifelse(condition::Bool, x, y)
Return x
if condition
is true
, otherwise return y
. This differs from ?
or if
in that it is an ordinary function, so all the arguments are evaluated first. In some cases, using ifelse
instead of an if
statement can eliminate the branch in generated code and provide higher performance in tight loops.
julia> ifelse(1 > 2, 1, 2)
2
Base.lexcmp
— Function.lexcmp(x, y)
Compare x
and y
lexicographically and return -1, 0, or 1 depending on whether x
is less than, equal to, or greater than y
, respectively. This function should be defined for lexicographically comparable types, and lexless
will call lexcmp
by default.
julia> lexcmp("abc", "abd")
-1
julia> lexcmp("abc", "abc")
0
Base.lexless
— Function.lexless(x, y)
Determine whether x
is lexicographically less than y
.
julia> lexless("abc", "abd")
true
Core.typeof
— Function.typeof(x)
Get the concrete type of x
.
Core.tuple
— Function.tuple(xs...)
Construct a tuple of the given objects.
Example
julia> tuple(1, 'a', pi)
(1, 'a', π = 3.1415926535897...)
Base.ntuple
— Function.ntuple(f::Function, n::Integer)
Create a tuple of length n
, computing each element as f(i)
, where i
is the index of the element.
julia> ntuple(i -> 2*i, 4)
(2, 4, 6, 8)
Base.object_id
— Function.object_id(x)
Get a hash value for x
based on object identity. object_id(x)==object_id(y)
if x === y
.
Base.hash
— Function.hash(x[, h::UInt])
Compute an integer hash code such that isequal(x,y)
implies hash(x)==hash(y)
. The optional second argument h
is a hash code to be mixed with the result.
New types should implement the 2-argument form, typically by calling the 2-argument hash
method recursively in order to mix hashes of the contents with each other (and with h
). Typically, any type that implements hash
should also implement its own ==
(hence isequal
) to guarantee the property mentioned above.
Base.finalizer
— Function.finalizer(x, f)
Register a function f(x)
to be called when there are no program-accessible references to x
. The type of x
must be a mutable struct
, otherwise the behavior of this function is unpredictable.
Base.finalize
— Function.finalize(x)
Immediately run finalizers registered for object x
.
Base.copy
— Function.copy(x)
Create a shallow copy of x
: the outer structure is copied, but not all internal values. For example, copying an array produces a new array with identically-same elements as the original.
Base.deepcopy
— Function.deepcopy(x)
Create a deep copy of x
: everything is copied recursively, resulting in a fully independent object. For example, deep-copying an array produces a new array whose elements are deep copies of the original elements. Calling deepcopy
on an object should generally have the same effect as serializing and then deserializing it.
As a special case, functions can only be actually deep-copied if they are anonymous, otherwise they are just copied. The difference is only relevant in the case of closures, i.e. functions which may contain hidden internal references.
While it isn't normally necessary, user-defined types can override the default deepcopy
behavior by defining a specialized version of the function deepcopy_internal(x::T, dict::ObjectIdDict)
(which shouldn't otherwise be used), where T
is the type to be specialized for, and dict
keeps track of objects copied so far within the recursion. Within the definition, deepcopy_internal
should be used in place of deepcopy
, and the dict
variable should be updated as appropriate before returning.
Core.isdefined
— Function.isdefined([m::Module,] s::Symbol)
isdefined(object, s::Symbol)
isdefined(object, index::Int)
Tests whether an assignable location is defined. The arguments can be a module and a symbol or a composite object and field name (as a symbol) or index. With a single symbol argument, tests whether a global variable with that name is defined in current_module()
.
Base.convert
— Function.convert(T, x)
Convert x
to a value of type T
.
If T
is an Integer
type, an InexactError
will be raised if x
is not representable by T
, for example if x
is not integer-valued, or is outside the range supported by T
.
Examples
julia> convert(Int, 3.0)
3
julia> convert(Int, 3.5)
ERROR: InexactError()
Stacktrace:
[1] convert(::Type{Int64}, ::Float64) at ./float.jl:679
If T
is a AbstractFloat
or Rational
type, then it will return the closest value to x
representable by T
.
julia> x = 1/3
0.3333333333333333
julia> convert(Float32, x)
0.33333334f0
julia> convert(Rational{Int32}, x)
1//3
julia> convert(Rational{Int64}, x)
6004799503160661//18014398509481984
If T
is a collection type and x
a collection, the result of convert(T, x)
may alias x
.
julia> x = Int[1,2,3];
julia> y = convert(Vector{Int}, x);
julia> y === x
true
Similarly, if T
is a composite type and x
a related instance, the result of convert(T, x)
may alias part or all of x
.
julia> x = speye(5);
julia> typeof(x)
SparseMatrixCSC{Float64,Int64}
julia> y = convert(SparseMatrixCSC{Float64,Int64}, x);
julia> z = convert(SparseMatrixCSC{Float32,Int64}, y);
julia> y === x
true
julia> z === x
false
julia> z.colptr === x.colptr
true
Base.promote
— Function.promote(xs...)
Convert all arguments to their common promotion type (if any), and return them all (as a tuple).
Example
julia> promote(Int8(1), Float16(4.5), Float32(4.1))
(1.0f0, 4.5f0, 4.1f0)
Base.oftype
— Function.oftype(x, y)
Convert y
to the type of x
(convert(typeof(x), y)
).
Base.widen
— Function.widen(x)
If x
is a type, return a "larger" type (for numeric types, this will be a type with at least as much range and precision as the argument, and usually more). Otherwise x
is converted to widen(typeof(x))
.
Examples
julia> widen(Int32)
Int64
julia> widen(1.5f0)
1.5
Base.identity
— Function.identity(x)
The identity function. Returns its argument.
julia> identity("Well, what did you expect?")
"Well, what did you expect?"
Types
Base.supertype
— Function.supertype(T::DataType)
Return the supertype of DataType T
.
julia> supertype(Int32)
Signed
Core.issubtype
— Function.issubtype(type1, type2)
Return true
if and only if all values of type1
are also of type2
. Can also be written using the <:
infix operator as type1 <: type2
.
Examples
julia> issubtype(Int8, Int32)
false
julia> Int8 <: Integer
true
Base.:<:
— Function.<:(T1, T2)
Subtype operator, equivalent to issubtype(T1, T2)
.
julia> Float64 <: AbstractFloat
true
julia> Vector{Int} <: AbstractArray
true
julia> Matrix{Float64} <: Matrix{AbstractFloat}
false
Base.:>:
— Function.>:(T1, T2)
Supertype operator, equivalent to issubtype(T2, T1)
.
Base.subtypes
— Function.subtypes(T::DataType)
Return a list of immediate subtypes of DataType T
. Note that all currently loaded subtypes are included, including those not visible in the current module.
julia> subtypes(Integer)
4-element Array{Union{DataType, UnionAll},1}:
BigInt
Bool
Signed
Unsigned
Base.typemin
— Function.typemin(T)
The lowest value representable by the given (real) numeric DataType T
.
Examples
julia> typemin(Float16)
-Inf16
julia> typemin(Float32)
-Inf32
Base.typemax
— Function.typemax(T)
The highest value representable by the given (real) numeric DataType
.
Base.realmin
— Function.realmin(T)
The smallest in absolute value non-subnormal value representable by the given floating-point DataType T
.
Base.realmax
— Function.realmax(T)
The highest finite value representable by the given floating-point DataType T
.
Examples
julia> realmax(Float16)
Float16(6.55e4)
julia> realmax(Float32)
3.4028235f38
Base.maxintfloat
— Function.maxintfloat(T)
The largest integer losslessly representable by the given floating-point DataType T
.
maxintfloat(T, S)
The largest integer losslessly representable by the given floating-point DataType T
that also does not exceed the maximum integer representable by the integer DataType S
.
Base.sizeof
— Method.sizeof(T)
Size, in bytes, of the canonical binary representation of the given DataType T
, if any.
Examples
julia> sizeof(Float32)
4
julia> sizeof(Complex128)
16
If T
does not have a specific size, an error is thrown.
julia> sizeof(Base.LinAlg.LU)
ERROR: argument is an abstract type; size is indeterminate
Stacktrace:
[1] sizeof(::Type{T} where T) at ./essentials.jl:159
Base.eps
— Method.eps(::Type{T}) where T<:AbstractFloat
eps()
Returns the machine epsilon of the floating point type T
(T = Float64
by default). This is defined as the gap between 1 and the next largest value representable by T
, and is equivalent to eps(one(T))
.
julia> eps()
2.220446049250313e-16
julia> eps(Float32)
1.1920929f-7
julia> 1.0 + eps()
1.0000000000000002
julia> 1.0 + eps()/2
1.0
Base.eps
— Method.eps(x::AbstractFloat)
Returns the unit in last place (ulp) of x
. This is the distance between consecutive representable floating point values at x
. In most cases, if the distance on either side of x
is different, then the larger of the two is taken, that is
eps(x) == max(x-prevfloat(x), nextfloat(x)-x)
The exceptions to this rule are the smallest and largest finite values (e.g. nextfloat(-Inf)
and prevfloat(Inf)
for Float64
), which round to the smaller of the values.
The rationale for this behavior is that eps
bounds the floating point rounding error. Under the default RoundNearest
rounding mode, if $y$ is a real number and $x$ is the nearest floating point number to $y$, then
julia> eps(1.0)
2.220446049250313e-16
julia> eps(prevfloat(2.0))
2.220446049250313e-16
julia> eps(2.0)
4.440892098500626e-16
julia> x = prevfloat(Inf) # largest finite Float64
1.7976931348623157e308
julia> x + eps(x)/2 # rounds up
Inf
julia> x + prevfloat(eps(x)/2) # rounds down
1.7976931348623157e308
Base.promote_type
— Function.promote_type(type1, type2)
Determine a type big enough to hold values of each argument type without loss, whenever possible. In some cases, where no type exists to which both types can be promoted losslessly, some loss is tolerated; for example, promote_type(Int64, Float64)
returns Float64
even though strictly, not all Int64
values can be represented exactly as Float64
values.
julia> promote_type(Int64, Float64)
Float64
julia> promote_type(Int32, Int64)
Int64
julia> promote_type(Float32, BigInt)
BigFloat
Base.promote_rule
— Function.promote_rule(type1, type2)
Specifies what type should be used by promote
when given values of types type1
and type2
. This function should not be called directly, but should have definitions added to it for new types as appropriate.
Core.getfield
— Function.getfield(value, name::Symbol)
Extract a named field from a value
of composite type. The syntax a.b
calls getfield(a, :b)
.
Example
julia> a = 1//2
1//2
julia> getfield(a, :num)
1
Core.setfield!
— Function.setfield!(value, name::Symbol, x)
Assign x
to a named field in value
of composite type. The syntax a.b = c
calls setfield!(a, :b, c)
.
Base.fieldoffset
— Function.fieldoffset(type, i)
The byte offset of field i
of a type relative to the data start. For example, we could use it in the following manner to summarize information about a struct:
julia> structinfo(T) = [(fieldoffset(T,i), fieldname(T,i), fieldtype(T,i)) for i = 1:nfields(T)];
julia> structinfo(Base.Filesystem.StatStruct)
12-element Array{Tuple{UInt64,Symbol,DataType},1}:
(0x0000000000000000, :device, UInt64)
(0x0000000000000008, :inode, UInt64)
(0x0000000000000010, :mode, UInt64)
(0x0000000000000018, :nlink, Int64)
(0x0000000000000020, :uid, UInt64)
(0x0000000000000028, :gid, UInt64)
(0x0000000000000030, :rdev, UInt64)
(0x0000000000000038, :size, Int64)
(0x0000000000000040, :blksize, Int64)
(0x0000000000000048, :blocks, Int64)
(0x0000000000000050, :mtime, Float64)
(0x0000000000000058, :ctime, Float64)
Core.fieldtype
— Function.fieldtype(T, name::Symbol | index::Int)
Determine the declared type of a field (specified by name or index) in a composite DataType T
.
julia> struct Foo
x::Int64
y::String
end
julia> fieldtype(Foo, :x)
Int64
julia> fieldtype(Foo, 2)
String
Base.isimmutable
— Function.isimmutable(v)
Return true
iff value v
is immutable. See Mutable Composite Types for a discussion of immutability. Note that this function works on values, so if you give it a type, it will tell you that a value of DataType
is mutable.
julia> isimmutable(1)
true
julia> isimmutable([1,2])
false
Base.isbits
— Function.isbits(T)
Return true
if T
is a "plain data" type, meaning it is immutable and contains no references to other values. Typical examples are numeric types such as UInt8
, Float64
, and Complex{Float64}
.
julia> isbits(Complex{Float64})
true
julia> isbits(Complex)
false
Base.isleaftype
— Function.isleaftype(T)
Determine whether T
's only subtypes are itself and Union{}
. This means T
is a concrete type that can have instances.
julia> isleaftype(Complex)
false
julia> isleaftype(Complex{Float32})
true
julia> isleaftype(Vector{Complex})
true
julia> isleaftype(Vector{Complex{Float32}})
true
Base.typejoin
— Function.typejoin(T, S)
Compute a type that contains both T
and S
.
Base.typeintersect
— Function.typeintersect(T, S)
Compute a type that contains the intersection of T
and S
. Usually this will be the smallest such type or one close to it.
Base.Val
— Type.Val{c}
Create a "value type" out of c
, which must be an isbits
value. The intent of this construct is to be able to dispatch on constants, e.g., f(Val{false})
allows you to dispatch directly (at compile-time) to an implementation f(::Type{Val{false}})
, without having to test the boolean value at runtime.
Base.Enums.@enum
— Macro.@enum EnumName[::BaseType] value1[=x] value2[=y]
Create an Enum{BaseType}
subtype with name EnumName
and enum member values of value1
and value2
with optional assigned values of x
and y
, respectively. EnumName
can be used just like other types and enum member values as regular values, such as
julia> @enum Fruit apple=1 orange=2 kiwi=3
julia> f(x::Fruit) = "I'm a Fruit with value: $(Int(x))"
f (generic function with 1 method)
julia> f(apple)
"I'm a Fruit with value: 1"
BaseType
, which defaults to Int32
, must be a primitive subtype of Integer
. Member values can be converted between the enum type and BaseType
. read
and write
perform these conversions automatically.
Base.instances
— Function.instances(T::Type)
Return a collection of all instances of the given type, if applicable. Mostly used for enumerated types (see @enum
).
julia> @enum Color red blue green
julia> instances(Color)
(red::Color = 0, blue::Color = 1, green::Color = 2)
Generic Functions
Core.Function
— Type.Function
Abstract type of all functions.
julia> isa(+, Function)
true
julia> typeof(sin)
Base.#sin
julia> ans <: Function
true
Base.method_exists
— Function.method_exists(f, Tuple type, world=typemax(UInt)) -> Bool
Determine whether the given generic function has a method matching the given Tuple
of argument types with the upper bound of world age given by world
.
julia> method_exists(length, Tuple{Array})
true
Core.applicable
— Function.applicable(f, args...) -> Bool
Determine whether the given generic function has a method applicable to the given arguments.
Examples
julia> function f(x, y)
x + y
end;
julia> applicable(f, 1)
false
julia> applicable(f, 1, 2)
true
Core.invoke
— Function.invoke(f, types <: Tuple, args...)
Invoke a method for the given generic function matching the specified types, on the specified arguments. The arguments must be compatible with the specified types. This allows invoking a method other than the most specific matching method, which is useful when the behavior of a more general definition is explicitly needed (often as part of the implementation of a more specific method of the same function).
Base.invokelatest
— Function.invokelatest(f, args...)
Calls f(args...)
, but guarantees that the most recent method of f
will be executed. This is useful in specialized circumstances, e.g. long-running event loops or callback functions that may call obsolete versions of a function f
. (The drawback is that invokelatest
is somewhat slower than calling f
directly, and the type of the result cannot be inferred by the compiler.)
Base.:|>
— Function.|>(x, f)
Applies a function to the preceding argument. This allows for easy function chaining.
julia> [1:5;] |> x->x.^2 |> sum |> inv
0.01818181818181818
Base.:∘
— Function.f ∘ g
Compose functions: i.e. (f ∘ g)(args...)
means f(g(args...))
. The ∘
symbol can be entered in the Julia REPL (and most editors, appropriately configured) by typing \circ<tab>
. Example:
julia> map(uppercase∘hex, 250:255)
6-element Array{String,1}:
"FA"
"FB"
"FC"
"FD"
"FE"
"FF"
Syntax
Core.eval
— Function.eval([m::Module], expr::Expr)
Evaluate an expression in the given module and return the result. Every Module
(except those defined with baremodule
) has its own 1-argument definition of eval
, which evaluates expressions in that module.
Base.@eval
— Macro.@eval [mod,] ex
Evaluate an expression with values interpolated into it using eval
. If two arguments are provided, the first is the module to evaluate in.
Base.evalfile
— Function.evalfile(path::AbstractString, args::Vector{String}=String[])
Load the file using include
, evaluate all expressions, and return the value of the last one.
Base.esc
— Function.esc(e::ANY)
Only valid in the context of an Expr
returned from a macro. Prevents the macro hygiene pass from turning embedded variables into gensym variables. See the Macros section of the Metaprogramming chapter of the manual for more details and examples.
Base.@inbounds
— Macro.@inbounds(blk)
Eliminates array bounds checking within expressions.
In the example below the bound check of array A is skipped to improve performance.
function sum(A::AbstractArray)
r = zero(eltype(A))
for i = 1:length(A)
@inbounds r += A[i]
end
return r
end
Using @inbounds
may return incorrect results/crashes/corruption for out-of-bounds indices. The user is responsible for checking it manually.
Base.@inline
— Macro.@inline
Give a hint to the compiler that this function is worth inlining.
Small functions typically do not need the @inline
annotation, as the compiler does it automatically. By using @inline
on bigger functions, an extra nudge can be given to the compiler to inline it. This is shown in the following example:
@inline function bigfunction(x)
#=
Function Definition
=#
end
Base.@noinline
— Macro.@noinline
Prevents the compiler from inlining a function.
Small functions are typically inlined automatically. By using @noinline
on small functions, auto-inlining can be prevented. This is shown in the following example:
@noinline function smallfunction(x)
#=
Function Definition
=#
end
Base.gensym
— Function.gensym([tag])
Generates a symbol which will not conflict with other variable names.
Base.@gensym
— Macro.@gensym
Generates a gensym symbol for a variable. For example, @gensym x y
is transformed into x = gensym("x"); y = gensym("y")
.
Base.@polly
— Macro.@polly
Tells the compiler to apply the polyhedral optimizer Polly to a function.
Base.parse
— Method.parse(str, start; greedy=true, raise=true)
Parse the expression string and return an expression (which could later be passed to eval for execution). start
is the index of the first character to start parsing. If greedy
is true
(default), parse
will try to consume as much input as it can; otherwise, it will stop as soon as it has parsed a valid expression. Incomplete but otherwise syntactically valid expressions will return Expr(:incomplete, "(error message)")
. If raise
is true
(default), syntax errors other than incomplete expressions will raise an error. If raise
is false
, parse
will return an expression that will raise an error upon evaluation.
julia> parse("x = 3, y = 5", 7)
(:(y = 5), 13)
julia> parse("x = 3, y = 5", 5)
(:((3, y) = 5), 13)
Base.parse
— Method.parse(str; raise=true)
Parse the expression string greedily, returning a single expression. An error is thrown if there are additional characters after the first expression. If raise
is true
(default), syntax errors will raise an error; otherwise, parse
will return an expression that will raise an error upon evaluation.
julia> parse("x = 3")
:(x = 3)
julia> parse("x = ")
:($(Expr(:incomplete, "incomplete: premature end of input")))
julia> parse("1.0.2")
ERROR: ParseError("invalid numeric constant \"1.0.\"")
Stacktrace:
[...]
julia> parse("1.0.2"; raise = false)
:($(Expr(:error, "invalid numeric constant \"1.0.\"")))
Nullables
Base.Nullable
— Type.Nullable(x, hasvalue::Bool=true)
Wrap value x
in an object of type Nullable
, which indicates whether a value is present. Nullable(x)
yields a non-empty wrapper and Nullable{T}()
yields an empty instance of a wrapper that might contain a value of type T
.
Nullable(x, false)
yields Nullable{typeof(x)}()
with x
stored in the result's value
field.
Examples
julia> Nullable(1)
Nullable{Int64}(1)
julia> Nullable{Int64}()
Nullable{Int64}()
julia> Nullable(1, false)
Nullable{Int64}()
julia> dump(Nullable(1, false))
Nullable{Int64}
hasvalue: Bool false
value: Int64 1
Base.get
— Method.get(x::Nullable[, y])
Attempt to access the value of x
. Returns the value if it is present; otherwise, returns y
if provided, or throws a NullException
if not.
Base.isnull
— Function.isnull(x)
Return whether or not x
is null for Nullable
x
; return false
for all other x
.
Examples
julia> x = Nullable(1, false)
Nullable{Int64}()
julia> isnull(x)
true
julia> x = Nullable(1, true)
Nullable{Int64}(1)
julia> isnull(x)
false
julia> x = 1
1
julia> isnull(x)
false
Base.unsafe_get
— Function.unsafe_get(x)
Return the value of x
for Nullable
x
; return x
for all other x
.
This method does not check whether or not x
is null before attempting to access the value of x
for x::Nullable
(hence "unsafe").
julia> x = Nullable(1)
Nullable{Int64}(1)
julia> unsafe_get(x)
1
julia> x = Nullable{String}()
Nullable{String}()
julia> unsafe_get(x)
ERROR: UndefRefError: access to undefined reference
Stacktrace:
[1] unsafe_get(::Nullable{String}) at ./nullable.jl:125
julia> x = 1
1
julia> unsafe_get(x)
1
System
Base.run
— Function.run(command, args...)
Run a command object, constructed with backticks. Throws an error if anything goes wrong, including the process exiting with a non-zero status.
Base.spawn
— Function.spawn(command)
Run a command object asynchronously, returning the resulting Process
object.
Base.DevNull
— Constant.DevNull
Used in a stream redirect to discard all data written to it. Essentially equivalent to /dev/null on Unix or NUL on Windows. Usage:
run(pipeline(`cat test.txt`, DevNull))
Base.success
— Function.success(command)
Run a command object, constructed with backticks, and tell whether it was successful (exited with a code of 0). An exception is raised if the process cannot be started.
Base.process_running
— Function.process_running(p::Process)
Determine whether a process is currently running.
Base.process_exited
— Function.process_exited(p::Process)
Determine whether a process has exited.
Base.kill
— Method.kill(p::Process, signum=SIGTERM)
Send a signal to a process. The default is to terminate the process.
Base.Sys.set_process_title
— Function.Sys.set_process_title(title::AbstractString)
Set the process title. No-op on some operating systems.
Base.Sys.get_process_title
— Function.Sys.get_process_title()
Get the process title. On some systems, will always return an empty string.
Base.readandwrite
— Function.readandwrite(command)
Starts running a command asynchronously, and returns a tuple (stdout,stdin,process) of the output stream and input stream of the process, and the process object itself.
Base.ignorestatus
— Function.ignorestatus(command)
Mark a command object so that running it will not throw an error if the result code is non-zero.
Base.detach
— Function.detach(command)
Mark a command object so that it will be run in a new process group, allowing it to outlive the julia process, and not have Ctrl-C interrupts passed to it.
Base.Cmd
— Type.Cmd(cmd::Cmd; ignorestatus, detach, windows_verbatim, windows_hide, env, dir)
Construct a new Cmd
object, representing an external program and arguments, from cmd
, while changing the settings of the optional keyword arguments:
ignorestatus::Bool
: Iftrue
(defaults tofalse
), then theCmd
will not throw an error if the return code is nonzero.detach::Bool
: Iftrue
(defaults tofalse
), then theCmd
will be run in a new process group, allowing it to outlive thejulia
process and not have Ctrl-C passed to it.windows_verbatim::Bool
: Iftrue
(defaults tofalse
), then on Windows theCmd
will send a command-line string to the process with no quoting or escaping of arguments, even arguments containing spaces. (On Windows, arguments are sent to a program as a single "command-line" string, and programs are responsible for parsing it into arguments. By default, empty arguments and arguments with spaces or tabs are quoted with double quotes"
in the command line, and\
or"
are preceded by backslashes.windows_verbatim=true
is useful for launching programs that parse their command line in nonstandard ways.) Has no effect on non-Windows systems.windows_hide::Bool
: Iftrue
(defaults tofalse
), then on Windows no new console window is displayed when theCmd
is executed. This has no effect if a console is already open or on non-Windows systems.env
: Set environment variables to use when running theCmd
.env
is either a dictionary mapping strings to strings, an array of strings of the form"var=val"
, an array or tuple of"var"=>val
pairs, ornothing
. In order to modify (rather than replace) the existing environment, createenv
bycopy(ENV)
and then setenv["var"]=val
as desired.dir::AbstractString
: Specify a working directory for the command (instead of the current directory).
For any keywords that are not specified, the current settings from cmd
are used. Normally, to create a Cmd
object in the first place, one uses backticks, e.g.
Cmd(`echo "Hello world"`, ignorestatus=true, detach=false)
Base.setenv
— Function.setenv(command::Cmd, env; dir="")
Set environment variables to use when running the given command
. env
is either a dictionary mapping strings to strings, an array of strings of the form "var=val"
, or zero or more "var"=>val
pair arguments. In order to modify (rather than replace) the existing environment, create env
by copy(ENV)
and then setting env["var"]=val
as desired, or use withenv
.
The dir
keyword argument can be used to specify a working directory for the command.
Base.withenv
— Function.withenv(f::Function, kv::Pair...)
Execute f()
in an environment that is temporarily modified (not replaced as in setenv
) by zero or more "var"=>val
arguments kv
. withenv
is generally used via the withenv(kv...) do ... end
syntax. A value of nothing
can be used to temporarily unset an environment variable (if it is set). When withenv
returns, the original environment has been restored.
Base.pipeline
— Method.pipeline(from, to, ...)
Create a pipeline from a data source to a destination. The source and destination can be commands, I/O streams, strings, or results of other pipeline
calls. At least one argument must be a command. Strings refer to filenames. When called with more than two arguments, they are chained together from left to right. For example pipeline(a,b,c)
is equivalent to pipeline(pipeline(a,b),c)
. This provides a more concise way to specify multi-stage pipelines.
Examples:
run(pipeline(`ls`, `grep xyz`))
run(pipeline(`ls`, "out.txt"))
run(pipeline("out.txt", `grep xyz`))
Base.pipeline
— Method.pipeline(command; stdin, stdout, stderr, append=false)
Redirect I/O to or from the given command
. Keyword arguments specify which of the command's streams should be redirected. append
controls whether file output appends to the file. This is a more general version of the 2-argument pipeline
function. pipeline(from, to)
is equivalent to pipeline(from, stdout=to)
when from
is a command, and to pipeline(to, stdin=from)
when from
is another kind of data source.
Examples:
run(pipeline(`dothings`, stdout="out.txt", stderr="errs.txt"))
run(pipeline(`update`, stdout="log.txt", append=true))
Base.Libc.gethostname
— Function.gethostname() -> AbstractString
Get the local machine's host name.
Base.getipaddr
— Function.getipaddr() -> IPAddr
Get the IP address of the local machine.
Base.Libc.getpid
— Function.getpid() -> Int32
Get Julia's process ID.
Base.Libc.time
— Method.time()
Get the system time in seconds since the epoch, with fairly high (typically, microsecond) resolution.
Base.time_ns
— Function.time_ns()
Get the time in nanoseconds. The time corresponding to 0 is undefined, and wraps every 5.8 years.
Base.tic
— Function.tic()
Set a timer to be read by the next call to toc
or toq
. The macro call @time expr
can also be used to time evaluation.
julia> tic()
0x0000c45bc7abac95
julia> sleep(0.3)
julia> toc()
elapsed time: 0.302745944 seconds
0.302745944
Base.toc
— Function.toc()
Print and return the time elapsed since the last tic
. The macro call @time expr
can also be used to time evaluation.
julia> tic()
0x0000c45bc7abac95
julia> sleep(0.3)
julia> toc()
elapsed time: 0.302745944 seconds
0.302745944
Base.toq
— Function.toq()
Return, but do not print, the time elapsed since the last tic
. The macro calls @timed expr
and @elapsed expr
also return evaluation time.
julia> tic()
0x0000c46477a9675d
julia> sleep(0.3)
julia> toq()
0.302251004
Base.@time
— Macro.@time
A macro to execute an expression, printing the time it took to execute, the number of allocations, and the total number of bytes its execution caused to be allocated, before returning the value of the expression.
See also @timev
, @timed
, @elapsed
, and @allocated
.
julia> @time rand(10^6);
0.001525 seconds (7 allocations: 7.630 MiB)
julia> @time begin
sleep(0.3)
1+1
end
0.301395 seconds (8 allocations: 336 bytes)
Base.@timev
— Macro.@timev
This is a verbose version of the @time
macro. It first prints the same information as @time
, then any non-zero memory allocation counters, and then returns the value of the expression.
See also @time
, @timed
, @elapsed
, and @allocated
.
julia> @timev rand(10^6);
0.001006 seconds (7 allocations: 7.630 MiB)
elapsed time (ns): 1005567
bytes allocated: 8000256
pool allocs: 6
malloc() calls: 1
Base.@timed
— Macro.@timed
A macro to execute an expression, and return the value of the expression, elapsed time, total bytes allocated, garbage collection time, and an object with various memory allocation counters.
See also @time
, @timev
, @elapsed
, and @allocated
.
julia> val, t, bytes, gctime, memallocs = @timed rand(10^6);
julia> t
0.006634834
julia> bytes
8000256
julia> gctime
0.0055765
julia> fieldnames(typeof(memallocs))
9-element Array{Symbol,1}:
:allocd
:malloc
:realloc
:poolalloc
:bigalloc
:freecall
:total_time
:pause
:full_sweep
julia> memallocs.total_time
5576500
Base.@elapsed
— Macro.@elapsed
A macro to evaluate an expression, discarding the resulting value, instead returning the number of seconds it took to execute as a floating-point number.
See also @time
, @timev
, @timed
, and @allocated
.
julia> @elapsed sleep(0.3)
0.301391426
Base.@allocated
— Macro.@allocated
A macro to evaluate an expression, discarding the resulting value, instead returning the total number of bytes allocated during evaluation of the expression. Note: the expression is evaluated inside a local function, instead of the current context, in order to eliminate the effects of compilation, however, there still may be some allocations due to JIT compilation. This also makes the results inconsistent with the @time
macros, which do not try to adjust for the effects of compilation.
See also @time
, @timev
, @timed
, and @elapsed
.
julia> @allocated rand(10^6)
8000080
Base.EnvHash
— Type.EnvHash() -> EnvHash
A singleton of this type provides a hash table interface to environment variables.
Base.ENV
— Constant.ENV
Reference to the singleton EnvHash
, providing a dictionary interface to system environment variables.
Base.is_unix
— Function.is_unix([os])
Predicate for testing if the OS provides a Unix-like interface. See documentation in Handling Operating System Variation.
Base.is_apple
— Function.is_apple([os])
Predicate for testing if the OS is a derivative of Apple Macintosh OS X or Darwin. See documentation in Handling Operating System Variation.
Base.is_linux
— Function.is_linux([os])
Predicate for testing if the OS is a derivative of Linux. See documentation in Handling Operating System Variation.
Base.is_bsd
— Function.is_bsd([os])
Predicate for testing if the OS is a derivative of BSD. See documentation in Handling Operating System Variation.
Base.is_windows
— Function.is_windows([os])
Predicate for testing if the OS is a derivative of Microsoft Windows NT. See documentation in Handling Operating System Variation.
Base.Sys.windows_version
— Function.Sys.windows_version()
Returns the version number for the Windows NT Kernel as a (major, minor) pair, or (0, 0)
if this is not running on Windows.
Base.@static
— Macro.@static
Partially evaluates an expression at parse time.
For example, @static is_windows() ? foo : bar
will evaluate is_windows()
and insert either foo
or bar
into the expression. This is useful in cases where a construct would be invalid on other platforms, such as a ccall
to a non-existent function. @static if is_apple() foo end
and @static foo <&&,||> bar
are also valid syntax.
Errors
Base.error
— Function.error(message::AbstractString)
Raise an ErrorException
with the given message.
Core.throw
— Function.throw(e)
Throw an object as an exception.
Base.rethrow
— Function.rethrow([e])
Throw an object without changing the current exception backtrace. The default argument is the current exception (if called within a catch
block).
Base.backtrace
— Function.backtrace()
Get a backtrace object for the current program point.
Base.catch_backtrace
— Function.catch_backtrace()
Get the backtrace of the current exception, for use within catch
blocks.
Base.assert
— Function.assert(cond)
Throw an AssertionError
if cond
is false
. Also available as the macro @assert expr
.
Base.@assert
— Macro.@assert cond [text]
Throw an AssertionError
if cond
is false
. Preferred syntax for writing assertions. Message text
is optionally displayed upon assertion failure.
Base.ArgumentError
— Type.ArgumentError(msg)
The parameters to a function call do not match a valid signature. Argument msg
is a descriptive error string.
Base.AssertionError
— Type.AssertionError([msg])
The asserted condition did not evaluate to true
. Optional argument msg
is a descriptive error string.
Core.BoundsError
— Type.BoundsError([a],[i])
An indexing operation into an array, a
, tried to access an out-of-bounds element, i
.
Base.DimensionMismatch
— Type.DimensionMismatch([msg])
The objects called do not have matching dimensionality. Optional argument msg
is a descriptive error string.
Core.DivideError
— Type.DivideError()
Integer division was attempted with a denominator value of 0.
Core.DomainError
— Type.DomainError()
The arguments to a function or constructor are outside the valid domain.
Base.EOFError
— Type.EOFError()
No more data was available to read from a file or stream.
Core.ErrorException
— Type.ErrorException(msg)
Generic error type. The error message, in the .msg
field, may provide more specific details.
Core.InexactError
— Type.InexactError()
Type conversion cannot be done exactly.
Core.InterruptException
— Type.InterruptException()
The process was stopped by a terminal interrupt (CTRL+C).
Base.KeyError
— Type.KeyError(key)
An indexing operation into an Associative
(Dict
) or Set
like object tried to access or delete a non-existent element.
Base.LoadError
— Type.LoadError(file::AbstractString, line::Int, error)
An error occurred while include
ing, require
ing, or using
a file. The error specifics should be available in the .error
field.
Base.MethodError
— Type.MethodError(f, args)
A method with the required type signature does not exist in the given generic function. Alternatively, there is no unique most-specific method.
Base.NullException
— Type.NullException()
An attempted access to a Nullable
with no defined value.
Core.OutOfMemoryError
— Type.OutOfMemoryError()
An operation allocated too much memory for either the system or the garbage collector to handle properly.
Core.ReadOnlyMemoryError
— Type.ReadOnlyMemoryError()
An operation tried to write to memory that is read-only.
Core.OverflowError
— Type.OverflowError()
The result of an expression is too large for the specified type and will cause a wraparound.
Base.ParseError
— Type.ParseError(msg)
The expression passed to the parse
function could not be interpreted as a valid Julia expression.
ProcessExitedException()
After a client Julia process has exited, further attempts to reference the dead child will throw this exception.
Core.StackOverflowError
— Type.StackOverflowError()
The function call grew beyond the size of the call stack. This usually happens when a call recurses infinitely.
Base.SystemError
— Type.SystemError(prefix::AbstractString, [errno::Int32])
A system call failed with an error code (in the errno
global variable).
Core.TypeError
— Type.TypeError(func::Symbol, context::AbstractString, expected::Type, got)
A type assertion failure, or calling an intrinsic function with an incorrect argument type.
Core.UndefRefError
— Type.UndefRefError()
The item or field is not defined for the given object.
Core.UndefVarError
— Type.UndefVarError(var::Symbol)
A symbol in the current scope is not defined.
Base.InitError
— Type.InitError(mod::Symbol, error)
An error occurred when running a module's __init__
function. The actual error thrown is available in the .error
field.
Base.retry
— Function.retry(f::Function; delays=ExponentialBackOff(), check=nothing) -> Function
Returns an anonymous function that calls function f
. If an exception arises, f
is repeatedly called again, each time check
returns true
, after waiting the number of seconds specified in delays
. check
should input delays
's current state and the Exception
.
Examples
retry(f, delays=fill(5.0, 3))
retry(f, delays=rand(5:10, 2))
retry(f, delays=Base.ExponentialBackOff(n=3, first_delay=5, max_delay=1000))
retry(http_get, check=(s,e)->e.status == "503")(url)
retry(read, check=(s,e)->isa(e, UVError))(io, 128; all=false)
Base.ExponentialBackOff
— Type.ExponentialBackOff(; n=1, first_delay=0.05, max_delay=10.0, factor=5.0, jitter=0.1)
A Float64
iterator of length n
whose elements exponentially increase at a rate in the interval factor
* (1 ± jitter
). The first element is first_delay
and all elements are clamped to max_delay
.
Events
Base.Timer
— Method.Timer(callback::Function, delay, repeat=0)
Create a timer to call the given callback
function. The callback
is passed one argument, the timer object itself. The callback will be invoked after the specified initial delay
, and then repeating with the given repeat
interval. If repeat
is 0
, the timer is only triggered once. Times are in seconds. A timer is stopped and has its resources freed by calling close
on it.
Base.Timer
— Type.Timer(delay, repeat=0)
Create a timer that wakes up tasks waiting for it (by calling wait
on the timer object) at a specified interval. Times are in seconds. Waiting tasks are woken with an error when the timer is closed (by close
. Use isopen
to check whether a timer is still active.
Base.AsyncCondition
— Type.AsyncCondition()
Create a async condition that wakes up tasks waiting for it (by calling wait
on the object) when notified from C by a call to uv_async_send
. Waiting tasks are woken with an error when the object is closed (by close
. Use isopen
to check whether it is still active.
Base.AsyncCondition
— Method.AsyncCondition(callback::Function)
Create a async condition that calls the given callback
function. The callback
is passed one argument, the async condition object itself.
Reflection
Base.module_name
— Function.module_name(m::Module) -> Symbol
Get the name of a Module
as a Symbol
.
julia> module_name(Base.LinAlg)
:LinAlg
Base.module_parent
— Function.module_parent(m::Module) -> Module
Get a module's enclosing Module
. Main
is its own parent, as is LastMain
after workspace()
.
julia> module_parent(Main)
Main
julia> module_parent(Base.LinAlg.BLAS)
Base.LinAlg
Base.current_module
— Function.current_module() -> Module
Get the dynamically current Module
, which is the Module
code is currently being read from. In general, this is not the same as the module containing the call to this function.
Base.fullname
— Function.fullname(m::Module)
Get the fully-qualified name of a module as a tuple of symbols. For example,
julia> fullname(Base.Pkg)
(:Base, :Pkg)
julia> fullname(Main)
()
Base.names
— Function.names(x::Module, all::Bool=false, imported::Bool=false)
Get an array of the names exported by a Module
, excluding deprecated names. If all
is true, then the list also includes non-exported names defined in the module, deprecated names, and compiler-generated names. If imported
is true, then names explicitly imported from other modules are also included.
As a special case, all names defined in Main
are considered "exported", since it is not idiomatic to explicitly export names from Main
.
Core.nfields
— Function.nfields(x::DataType) -> Int
Get the number of fields of a DataType
.
Base.fieldnames
— Function.fieldnames(x::DataType)
Get an array of the fields of a DataType
.
julia> fieldnames(Hermitian)
2-element Array{Symbol,1}:
:data
:uplo
Base.fieldname
— Function.fieldname(x::DataType, i::Integer)
Get the name of field i
of a DataType
.
julia> fieldname(SparseMatrixCSC,1)
:m
julia> fieldname(SparseMatrixCSC,5)
:nzval
Base.datatype_module
— Function.Base.datatype_module(t::DataType) -> Module
Determine the module containing the definition of a DataType
.
Base.datatype_name
— Function.Base.datatype_name(t) -> Symbol
Get the name of a (potentially UnionAll-wrapped) DataType
(without its parent module) as a symbol.
Base.isconst
— Function.isconst([m::Module], s::Symbol) -> Bool
Determine whether a global is declared const
in a given Module
. The default Module
argument is current_module()
.
Base.function_name
— Function.Base.function_name(f::Function) -> Symbol
Get the name of a generic Function
as a symbol, or :anonymous
.
Base.function_module
— Method.Base.function_module(f::Function) -> Module
Determine the module containing the (first) definition of a generic function.
Base.function_module
— Method.Base.function_module(f::Function, types) -> Module
Determine the module containing a given definition of a generic function.
Base.functionloc
— Method.functionloc(f::Function, types)
Returns a tuple (filename,line)
giving the location of a generic Function
definition.
Base.functionloc
— Method.functionloc(m::Method)
Returns a tuple (filename,line)
giving the location of a Method
definition.
Base.@functionloc
— Macro.@functionloc
Applied to a function or macro call, it evaluates the arguments to the specified call, and returns a tuple (filename,line)
giving the location for the method that would be called for those arguments. It calls out to the functionloc
function.
Internals
Base.gc
— Function.gc()
Perform garbage collection. This should not generally be used.
Base.gc_enable
— Function.gc_enable(on::Bool)
Control whether garbage collection is enabled using a boolean argument (true
for enabled, false
for disabled). Returns previous GC state. Disabling garbage collection should be used only with extreme caution, as it can cause memory use to grow without bound.
Base.macroexpand
— Function.macroexpand(x)
Takes the expression x
and returns an equivalent expression with all macros removed (expanded).
Base.@macroexpand
— Macro.@macroexpand
Return equivalent expression with all macros removed (expanded).
There is a subtle difference between @macroexpand
and macroexpand
in that expansion takes place in different contexts. This is best seen in the following example:
julia> module M
macro m()
1
end
function f()
(@macroexpand(@m), macroexpand(:(@m)))
end
end
M
julia> macro m()
2
end
@m (macro with 1 method)
julia> M.f()
(1, 2)
With @macroexpand
the expression expands where @macroexpand
appears in the code (module M
in the example). With macroexpand
the expression expands in the current module where the code was finally called (REPL in the example). Note that when calling macroexpand
or @macroexpand
directly from the REPL, both of these contexts coincide, hence there is no difference.
Base.expand
— Function.expand(x)
Takes the expression x
and returns an equivalent expression in lowered form. See also code_lowered
.
Base.code_lowered
— Function.code_lowered(f, types)
Returns an array of lowered ASTs for the methods matching the given generic function and type signature.
Base.@code_lowered
— Macro.@code_lowered
Evaluates the arguments to the function or macro call, determines their types, and calls code_lowered
on the resulting expression.
Base.code_typed
— Function.code_typed(f, types; optimize=true)
Returns an array of lowered and type-inferred ASTs for the methods matching the given generic function and type signature. The keyword argument optimize
controls whether additional optimizations, such as inlining, are also applied.
Base.@code_typed
— Macro.@code_typed
Evaluates the arguments to the function or macro call, determines their types, and calls code_typed
on the resulting expression.
Base.code_warntype
— Function.code_warntype([io::IO], f, types)
Prints lowered and type-inferred ASTs for the methods matching the given generic function and type signature to io
which defaults to STDOUT
. The ASTs are annotated in such a way as to cause "non-leaf" types to be emphasized (if color is available, displayed in red). This serves as a warning of potential type instability. Not all non-leaf types are particularly problematic for performance, so the results need to be used judiciously. See @code_warntype
for more information.
Base.@code_warntype
— Macro.@code_warntype
Evaluates the arguments to the function or macro call, determines their types, and calls code_warntype
on the resulting expression.
Base.code_llvm
— Function.code_llvm([io], f, types)
Prints the LLVM bitcodes generated for running the method matching the given generic function and type signature to io
which defaults to STDOUT
.
All metadata and dbg.* calls are removed from the printed bitcode. Use code_llvm_raw for the full IR.
Base.@code_llvm
— Macro.@code_llvm
Evaluates the arguments to the function or macro call, determines their types, and calls code_llvm
on the resulting expression.
Base.code_native
— Function.code_native([io], f, types, [syntax])
Prints the native assembly instructions generated for running the method matching the given generic function and type signature to io
which defaults to STDOUT
. Switch assembly syntax using syntax
symbol parameter set to :att
for AT&T syntax or :intel
for Intel syntax. Output is AT&T syntax by default.
Base.@code_native
— Macro.@code_native
Evaluates the arguments to the function or macro call, determines their types, and calls code_native
on the resulting expression.
Base.precompile
— Function.precompile(f,args::Tuple{Vararg{Any}})
Compile the given function f
for the argument tuple (of types) args
, but do not execute it.