Noteworthy Differences from other Languages
Noteworthy differences from MATLAB
Although MATLAB users may find Julia's syntax familiar, Julia is not a MATLAB clone. There are major syntactic and functional differences. The following are some noteworthy differences that may trip up Julia users accustomed to MATLAB:
- Julia arrays are indexed with square brackets,
A[i,j]
. - Julia arrays are not copied when assigned to another variable. After
A = B
, changing elements ofB
will modifyA
as well. - Julia values are not copied when passed to a function. If a function modifies an array, the changes will be visible in the caller.
- Julia does not automatically grow arrays in an assignment statement. Whereas in MATLAB
a(4) = 3.2
can create the arraya = [0 0 0 3.2]
anda(5) = 7
can grow it intoa = [0 0 0 3.2 7]
, the corresponding Julia statementa[5] = 7
throws an error if the length ofa
is less than 5 or if this statement is the first use of the identifiera
. Julia haspush!
andappend!
, which growVector
s much more efficiently than MATLAB'sa(end+1) = val
. - The imaginary unit
sqrt(-1)
is represented in Julia asim
, noti
orj
as in MATLAB. - In Julia, literal numbers without a decimal point (such as
42
) create integers instead of floating point numbers. As a result, some operations can throw a domain error if they expect a float; for example,julia> a = -1; 2^a
throws a domain error, as the result is not an integer (see the FAQ entry on domain errors for details). - In Julia, multiple values are returned and assigned as tuples, e.g.
(a, b) = (1, 2)
ora, b = 1, 2
. MATLAB'snargout
, which is often used in MATLAB to do optional work based on the number of returned values, does not exist in Julia. Instead, users can use optional and keyword arguments to achieve similar capabilities. - Julia has true one-dimensional arrays. Column vectors are of size
N
, notNx1
. For example,rand(N)
makes a 1-dimensional array. - In Julia,
[x,y,z]
will always construct a 3-element array containingx
,y
andz
.- To concatenate in the first ("vertical") dimension use either
vcat(x,y,z)
or separate with semicolons ([x; y; z]
). - To concatenate in the second ("horizontal") dimension use either
hcat(x,y,z)
or separate with spaces ([x y z]
). - To construct block matrices (concatenating in the first two dimensions), use either
hvcat
or combine spaces and semicolons ([a b; c d]
).
- To concatenate in the first ("vertical") dimension use either
- In Julia,
a:b
anda:b:c
constructAbstractRange
objects. To construct a full vector like in MATLAB, usecollect(a:b)
. Generally, there is no need to callcollect
though. AnAbstractRange
object will act like a normal array in most cases but is more efficient because it lazily computes its values. This pattern of creating specialized objects instead of full arrays is used frequently, and is also seen in functions such asrange
, or with iterators such asenumerate
, andzip
. The special objects can mostly be used as if they were normal arrays. - Functions in Julia return values from their last expression or the
return
keyword instead of listing the names of variables to return in the function definition (see The return Keyword for details). - A Julia script may contain any number of functions, and all definitions will be externally visible when the file is loaded. Function definitions can be loaded from files outside the current working directory.
- In Julia, reductions such as
sum
,prod
, andmax
are performed over every element of an array when called with a single argument, as insum(A)
, even ifA
has more than one dimension. - In Julia, parentheses must be used to call a function with zero arguments, like in
rand()
. - Julia discourages the use of semicolons to end statements. The results of statements are not automatically printed (except at the interactive prompt), and lines of code do not need to end with semicolons.
println
or@printf
can be used to print specific output. - In Julia, if
A
andB
are arrays, logical comparison operations likeA == B
do not return an array of booleans. Instead, useA .== B
, and similarly for the other boolean operators like<
,>
. - In Julia, the operators
&
,|
, and⊻
(xor
) perform the bitwise operations equivalent toand
,or
, andxor
respectively in MATLAB, and have precedence similar to Python's bitwise operators (unlike C). They can operate on scalars or element-wise across arrays and can be used to combine logical arrays, but note the difference in order of operations: parentheses may be required (e.g., to select elements ofA
equal to 1 or 2 use(A .== 1) .| (A .== 2)
). - In Julia, the elements of a collection can be passed as arguments to a function using the splat operator
...
, as inxs=[1,2]; f(xs...)
. - Julia's
svd
returns singular values as a vector instead of as a dense diagonal matrix. - In Julia,
...
is not used to continue lines of code. Instead, incomplete expressions automatically continue onto the next line. - In both Julia and MATLAB, the variable
ans
is set to the value of the last expression issued in an interactive session. In Julia, unlike MATLAB,ans
is not set when Julia code is run in non-interactive mode. - Julia's
struct
s do not support dynamically adding fields at runtime, unlike MATLAB'sclass
es. Instead, use aDict
. - In Julia each module has its own global scope/namespace, whereas in MATLAB there is just one global scope.
- In MATLAB, an idiomatic way to remove unwanted values is to use logical indexing, like in the expression
x(x>3)
or in the statementx(x>3) = []
to modifyx
in-place. In contrast, Julia provides the higher order functionsfilter
andfilter!
, allowing users to writefilter(z->z>3, x)
andfilter!(z->z>3, x)
as alternatives to the corresponding transliterationsx[x.>3]
andx = x[x.>3]
. Usingfilter!
reduces the use of temporary arrays. - The analogue of extracting (or "dereferencing") all elements of a cell array, e.g. in
vertcat(A{:})
in MATLAB, is written using the splat operator in Julia, e.g. asvcat(A...)
.
Noteworthy differences from R
One of Julia's goals is to provide an effective language for data analysis and statistical programming. For users coming to Julia from R, these are some noteworthy differences:
Julia's single quotes enclose characters, not strings.
Julia can create substrings by indexing into strings. In R, strings must be converted into character vectors before creating substrings.
In Julia, like Python but unlike R, strings can be created with triple quotes
""" ... """
. This syntax is convenient for constructing strings that contain line breaks.In Julia, varargs are specified using the splat operator
...
, which always follows the name of a specific variable, unlike R, for which...
can occur in isolation.In Julia, modulus is
mod(a, b)
, nota %% b
.%
in Julia is the remainder operator.-
In Julia, not all data structures support logical indexing. Furthermore, logical indexing in Julia is supported only with vectors of length equal to the object being indexed. For example:
- In R,
c(1, 2, 3, 4)[c(TRUE, FALSE)]
is equivalent toc(1, 3)
. - In R,
c(1, 2, 3, 4)[c(TRUE, FALSE, TRUE, FALSE)]
is equivalent toc(1, 3)
. - In Julia,
[1, 2, 3, 4][[true, false]]
throws aBoundsError
. - In Julia,
[1, 2, 3, 4][[true, false, true, false]]
produces[1, 3]
.
- In R,
Like many languages, Julia does not always allow operations on vectors of different lengths, unlike R where the vectors only need to share a common index range. For example,
c(1, 2, 3, 4) + c(1, 2)
is valid R but the equivalent[1, 2, 3, 4] + [1, 2]
will throw an error in Julia.Julia allows an optional trailing comma when that comma does not change the meaning of code. This can cause confusion among R users when indexing into arrays. For example,
x[1,]
in R would return the first row of a matrix; in Julia, however, the comma is ignored, sox[1,] == x[1]
, and will return the first element. To extract a row, be sure to use:
, as inx[1,:]
.Julia's
map
takes the function first, then its arguments, unlikelapply(<structure>, function, ...)
in R. Similarly Julia's equivalent ofapply(X, MARGIN, FUN, ...)
in R ismapslices
where the function is the first argument.Multivariate apply in R, e.g.
mapply(choose, 11:13, 1:3)
, can be written asbroadcast(binomial, 11:13, 1:3)
in Julia. Equivalently Julia offers a shorter dot syntax for vectorizing functionsbinomial.(11:13, 1:3)
.Julia uses
end
to denote the end of conditional blocks, likeif
, loop blocks, likewhile
/for
, and functions. In lieu of the one-lineif ( cond ) statement
, Julia allows statements of the formif cond; statement; end
,cond && statement
and!cond || statement
. Assignment statements in the latter two syntaxes must be explicitly wrapped in parentheses, e.g.cond && (x = value)
.In Julia,
<-
,<<-
and->
are not assignment operators.Julia's
->
creates an anonymous function.Julia constructs vectors using brackets. Julia's
[1, 2, 3]
is the equivalent of R'sc(1, 2, 3)
.Julia's
*
operator can perform matrix multiplication, unlike in R. IfA
andB
are matrices, thenA * B
denotes a matrix multiplication in Julia, equivalent to R'sA %*% B
. In R, this same notation would perform an element-wise (Hadamard) product. To get the element-wise multiplication operation, you need to writeA .* B
in Julia.Julia performs matrix transposition using the
transpose
function and conjugated transposition using the'
operator or theadjoint
function. Julia'stranspose(A)
is therefore equivalent to R'st(A)
. Additionally a non-recursive transpose in Julia is provided by thepermutedims
function.Julia does not require parentheses when writing
if
statements orfor
/while
loops: usefor i in [1, 2, 3]
instead offor (i in c(1, 2, 3))
andif i == 1
instead ofif (i == 1)
.Julia does not treat the numbers
0
and1
as Booleans. You cannot writeif (1)
in Julia, becauseif
statements accept only booleans. Instead, you can writeif true
,if Bool(1)
, orif 1==1
.Julia does not provide
nrow
andncol
. Instead, usesize(M, 1)
fornrow(M)
andsize(M, 2)
forncol(M)
.Julia is careful to distinguish scalars, vectors and matrices. In R,
1
andc(1)
are the same. In Julia, they cannot be used interchangeably.Julia cannot assign to the results of function calls on the left hand side of an assignment operation: you cannot write
diag(M) = fill(1, n)
.-
Julia discourages populating the main namespace with functions. Most statistical functionality for Julia is found in packages under the JuliaStats organization. For example:
- Functions pertaining to probability distributions are provided by the Distributions package.
- The DataFrames package provides data frames.
- Generalized linear models are provided by the GLM package.
Julia provides tuples and real hash tables, but not R-style lists. When returning multiple items, you should typically use a tuple or a named tuple: instead of
list(a = 1, b = 2)
, use(1, 2)
or(a=1, b=2)
.Julia encourages users to write their own types, which are easier to use than S3 or S4 objects in R. Julia's multiple dispatch system means that
table(x::TypeA)
andtable(x::TypeB)
act like R'stable.TypeA(x)
andtable.TypeB(x)
.In Julia, values are not copied when assigned or passed to a function. If a function modifies an array, the changes will be visible in the caller. This is very different from R and allows new functions to operate on large data structures much more efficiently.
In Julia, vectors and matrices are concatenated using
hcat
,vcat
andhvcat
, notc
,rbind
andcbind
like in R.In Julia, a range like
a:b
is not shorthand for a vector like in R, but is a specializedAbstractRange
object that is used for iteration without high memory overhead. To convert a range into a vector, usecollect(a:b)
.Julia's
max
andmin
are the equivalent ofpmax
andpmin
respectively in R, but both arguments need to have the same dimensions. Whilemaximum
andminimum
replacemax
andmin
in R, there are important differences.Julia's
sum
,prod
,maximum
, andminimum
are different from their counterparts in R. They all accept an optional keyword argumentdims
, which indicates the dimensions, over which the operation is carried out. For instance, letA = [1 2; 3 4]
in Julia andB <- rbind(c(1,2),c(3,4))
be the same matrix in R. Thensum(A)
gives the same result assum(B)
, butsum(A, dims=1)
is a row vector containing the sum over each column andsum(A, dims=2)
is a column vector containing the sum over each row. This contrasts to the behavior of R, where separatecolSums(B)
androwSums(B)
functions provide these functionalities. If thedims
keyword argument is a vector, then it specifies all the dimensions over which the sum is performed, while retaining the dimensions of the summed array, e.g.sum(A, dims=(1,2)) == hcat(10)
. It should be noted that there is no error checking regarding the second argument.Julia has several functions that can mutate their arguments. For example, it has both
sort
andsort!
.In R, performance requires vectorization. In Julia, almost the opposite is true: the best performing code is often achieved by using devectorized loops.
Julia is eagerly evaluated and does not support R-style lazy evaluation. For most users, this means that there are very few unquoted expressions or column names.
Julia does not support the
NULL
type. The closest equivalent isnothing
, but it behaves like a scalar value rather than like a list. Usex === nothing
instead ofis.null(x)
.In Julia, missing values are represented by the
missing
object rather than byNA
. Useismissing(x)
(orismissing.(x)
for element-wise operation on vectors) instead ofis.na(x)
. Theskipmissing
function is generally used instead ofna.rm=TRUE
(though in some particular cases functions take askipmissing
argument).Julia lacks the equivalent of R's
assign
orget
.In Julia,
return
does not require parentheses.In R, an idiomatic way to remove unwanted values is to use logical indexing, like in the expression
x[x>3]
or in the statementx = x[x>3]
to modifyx
in-place. In contrast, Julia provides the higher order functionsfilter
andfilter!
, allowing users to writefilter(z->z>3, x)
andfilter!(z->z>3, x)
as alternatives to the corresponding transliterationsx[x.>3]
andx = x[x.>3]
. Usingfilter!
reduces the use of temporary arrays.
Noteworthy differences from Python
- Julia requires
end
to end a block. Unlike Python, Julia has nopass
keyword. - In Julia, indexing of arrays, strings, etc. is 1-based not 0-based.
- Julia's slice indexing includes the last element, unlike in Python.
a[2:3]
in Julia isa[1:3]
in Python. - Julia does not support negative indices. In particular, the last element of a list or array is indexed with
end
in Julia, not-1
as in Python. - Julia's
for
,if
,while
, etc. blocks are terminated by theend
keyword. Indentation level is not significant as it is in Python. - Julia has no line continuation syntax: if, at the end of a line, the input so far is a complete expression, it is considered done; otherwise the input continues. One way to force an expression to continue is to wrap it in parentheses.
- Julia arrays are column major (Fortran ordered) whereas NumPy arrays are row major (C-ordered) by default. To get optimal performance when looping over arrays, the order of the loops should be reversed in Julia relative to NumPy (see relevant section of Performance Tips).
- Julia's updating operators (e.g.
+=
,-=
, ...) are not in-place whereas NumPy's are. This meansA = [1, 1]; B = A; B += [3, 3]
doesn't change values inA
, it rather rebinds the nameB
to the result of the right-hand sideB = B + 3
, which is a new array. For in-place operation, useB .+= 3
(see also dot operators), explicit loops, orInplaceOps.jl
. - Julia evaluates default values of function arguments every time the method is invoked, unlike in Python where the default values are evaluated only once when the function is defined. For example, the function
f(x=rand()) = x
returns a new random number every time it is invoked without argument. On the other hand, the functiong(x=[1,2]) = push!(x,3)
returns[1,2,3]
every time it is called asg()
. - In Julia
%
is the remainder operator, whereas in Python it is the modulus. - The commonly used
Int
type corresponds to the machine integer type (Int32
orInt64
). This means it will overflow, such that2^64 == 0
. If you need larger values use another appropriate type, such asInt128
,BigInt
or a floating point type likeFloat64
.
Noteworthy differences from C/C++
- Julia arrays are indexed with square brackets, and can have more than one dimension
A[i,j]
. This syntax is not just syntactic sugar for a reference to a pointer or address as in C/C++. See the Julia documentation for the syntax for array construction (it has changed between versions). - In Julia, indexing of arrays, strings, etc. is 1-based not 0-based.
- Julia arrays are not copied when assigned to another variable. After
A = B
, changing elements ofB
will modifyA
as well. Updating operators like+=
do not operate in-place, they are equivalent toA = A + B
which rebinds the left-hand side to the result of the right-hand side expression. - Julia arrays are column major (Fortran ordered) whereas C/C++ arrays are row major ordered by default. To get optimal performance when looping over arrays, the order of the loops should be reversed in Julia relative to C/C++ (see relevant section of Performance Tips).
- Julia values are not copied when assigned or passed to a function. If a function modifies an array, the changes will be visible in the caller.
- In Julia, whitespace is significant, unlike C/C++, so care must be taken when adding/removing whitespace from a Julia program.
- In Julia, literal numbers without a decimal point (such as
42
) create signed integers, of typeInt
, but literals too large to fit in the machine word size will automatically be promoted to a larger size type, such asInt64
(ifInt
isInt32
),Int128
, or the arbitrarily largeBigInt
type. There are no numeric literal suffixes, such asL
,LL
,U
,UL
,ULL
to indicate unsigned and/or signed vs. unsigned. Decimal literals are always signed, and hexadecimal literals (which start with0x
like C/C++), are unsigned. Hexadecimal literals also, unlike C/C++/Java and unlike decimal literals in Julia, have a type based on the length of the literal, including leading 0s. For example,0x0
and0x00
have typeUInt8
,0x000
and0x0000
have typeUInt16
, then literals with 5 to 8 hex digits have typeUInt32
, 9 to 16 hex digits typeUInt64
and 17 to 32 hex digits typeUInt128
. This needs to be taken into account when defining hexadecimal masks, for example~0xf == 0xf0
is very different from~0x000f == 0xfff0
. 64 bitFloat64
and 32 bitFloat32
bit literals are expressed as1.0
and1.0f0
respectively. Floating point literals are rounded (and not promoted to theBigFloat
type) if they can not be exactly represented. Floating point literals are closer in behavior to C/C++. Octal (prefixed with0o
) and binary (prefixed with0b
) literals are also treated as unsigned. - String literals can be delimited with either
"
or"""
,"""
delimited literals can contain"
characters without quoting it like"\""
. String literals can have values of other variables or expressions interpolated into them, indicated by$variablename
or$(expression)
, which evaluates the variable name or the expression in the context of the function. -
//
indicates aRational
number, and not a single-line comment (which is#
in Julia) -
#=
indicates the start of a multiline comment, and=#
ends it. - Functions in Julia return values from their last expression(s) or the
return
keyword. Multiple values can be returned from functions and assigned as tuples, e.g.(a, b) = myfunction()
ora, b = myfunction()
, instead of having to pass pointers to values as one would have to do in C/C++ (i.e.a = myfunction(&b)
. - Julia does not require the use of semicolons to end statements. The results of expressions are not automatically printed (except at the interactive prompt, i.e. the REPL), and lines of code do not need to end with semicolons.
println
or@printf
can be used to print specific output. In the REPL,;
can be used to suppress output.;
also has a different meaning within[ ]
, something to watch out for.;
can be used to separate expressions on a single line, but are not strictly necessary in many cases, and are more an aid to readability. - In Julia, the operator
⊻
(xor
) performs the bitwise XOR operation, i.e.^
in C/C++. Also, the bitwise operators do not have the same precedence as C/++, so parenthesis may be required. - Julia's
^
is exponentiation (pow), not bitwise XOR as in C/C++ (use⊻
, orxor
, in Julia) - Julia has two right-shift operators,
>>
and>>>
.>>>
performs an arithmetic shift,>>
always performs a logical shift, unlike C/C++, where the meaning of>>
depends on the type of the value being shifted. - Julia's
->
creates an anonymous function, it does not access a member via a pointer. - Julia does not require parentheses when writing
if
statements orfor
/while
loops: usefor i in [1, 2, 3]
instead offor (int i=1; i <= 3; i++)
andif i == 1
instead ofif (i == 1)
. - Julia does not treat the numbers
0
and1
as Booleans. You cannot writeif (1)
in Julia, becauseif
statements accept only booleans. Instead, you can writeif true
,if Bool(1)
, orif 1==1
. - Julia uses
end
to denote the end of conditional blocks, likeif
, loop blocks, likewhile
/for
, and functions. In lieu of the one-lineif ( cond ) statement
, Julia allows statements of the formif cond; statement; end
,cond && statement
and!cond || statement
. Assignment statements in the latter two syntaxes must be explicitly wrapped in parentheses, e.g.cond && (x = value)
, because of the operator precedence. - Julia has no line continuation syntax: if, at the end of a line, the input so far is a complete expression, it is considered done; otherwise the input continues. One way to force an expression to continue is to wrap it in parentheses.
- Julia macros operate on parsed expressions, rather than the text of the program, which allows them to perform sophisticated transformations of Julia code. Macro names start with the
@
character, and have both a function-like syntax,@mymacro(arg1, arg2, arg3)
, and a statement-like syntax,@mymacro arg1 arg2 arg3
. The forms are interchangeable; the function-like form is particularly useful if the macro appears within another expression, and is often clearest. The statement-like form is often used to annotate blocks, as in the distributedfor
construct:@distributed for i in 1:n; #= body =#; end
. Where the end of the macro construct may be unclear, use the function-like form. - Julia has an enumeration type, expressed using the macro
@enum(name, value1, value2, ...)
For example:@enum(Fruit, banana=1, apple, pear)
- By convention, functions that modify their arguments have a
!
at the end of the name, for examplepush!
. - In C++, by default, you have static dispatch, i.e. you need to annotate a function as virtual, in order to have dynamic dispatch. On the other hand, in Julia every method is "virtual" (although it's more general than that since methods are dispatched on every argument type, not only
this
, using the most-specific-declaration rule).
Noteworthy differences from Common Lisp
Julia uses 1-based indexing for arrays by default, and it can also handle arbitrary index offsets.
Functions and variables share the same namespace (“Lisp-1”).
There is a
Pair
type, but it is not meant to be used as aCOMMON-LISP:CONS
. Various iterable collections can be used interchangeably in most parts of the language (eg splatting, tuples, etc).Tuple
s are the closest to Common Lisp lists for short collections of heterogeneous elements. UseNamedTuple
s in place of alists. For larger collections of homogeneous types,Array
s andDict
s should be used.The typical Julia workflow for prototyping also uses continuous manipulation of the image, implemented with the Revise.jl package.
Bignums are supported, but conversion is not automatic; ordinary integers overflow.
Modules (namespaces) can be hierarchical.
import
andusing
have a dual role: they load the code and make it available in the namespace.import
for only the module name is possible (roughly equivalent toASDF:LOAD-OP
). Slot names don't need to be exported separately. Global variables can't be assigned to from outside the module (except witheval(mod, :(var = val))
as an escape hatch).Macros start with
@
, and are not as seamlessly integrated into the language as Common Lisp; consequently, macro usage is not as widespread as in the latter. A form of hygiene for macros is supported by the language. Because of the different surface syntax, there is no equivalent toCOMMON-LISP:&BODY
.All functions are generic and use multiple dispatch. Argument lists don't have to follow the same template, which leads to a powerful idiom (see
do
). Optional and keyword arguments are handled differently. Method ambiguities are not resolved like in the Common Lisp Object System, necessitating the definition of a more specific method for the intersection.Symbols do not belong to any package, and do not contain any values per se.
M.var
evaluates the symbolvar
in the moduleM
.A functional programming style is fully supported by the language, including closures, but isn't always the idiomatic solution for Julia. Some workarounds may be necessary for performance when modifying captured variables.
© 2009–2020 Jeff Bezanson, Stefan Karpinski, Viral B. Shah, and other contributors
Licensed under the MIT License.
https://docs.julialang.org/en/v1.3.1/manual/noteworthy-differences/