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Enable doctests the the manual
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Switching to julia-repl revealed several code blocks that could
trivially be turned into doctests.
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mortenpi committed May 25, 2017
1 parent 92ec724 commit d7af1aa
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14 changes: 12 additions & 2 deletions doc/src/devdocs/cartesian.md
Original file line number Diff line number Diff line change
Expand Up @@ -53,9 +53,19 @@ is `@nref 3 A i` (as in `A[i_1,i_2,i_3]`, where the array comes first).
If you're developing code with Cartesian, you may find that debugging is easier when you examine
the generated code, using `macroexpand`:

```julia-repl
```@meta
DocTestSetup = quote
import Base.Cartesian: @nref
end
```

```jldoctest
julia> macroexpand(:(@nref 2 A i))
:(A[i_1,i_2])
:(A[i_1, i_2])
```

```@meta
DocTestSetup = nothing
```

### Supplying the number of expressions
Expand Down
20 changes: 10 additions & 10 deletions doc/src/devdocs/reflection.md
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Expand Up @@ -14,7 +14,7 @@ The names of `DataType` fields may be interrogated using [`fieldnames()`](@ref).
given the following type, `fieldnames(Point)` returns an arrays of [`Symbol`](@ref) elements representing
the field names:

```julia-repl
```jldoctest struct_point
julia> struct Point
x::Int
y
Expand All @@ -29,17 +29,17 @@ julia> fieldnames(Point)
The type of each field in a `Point` object is stored in the `types` field of the `Point` variable
itself:

```julia-repl
```jldoctest struct_point
julia> Point.types
svec(Int64,Any)
svec(Int64, Any)
```

While `x` is annotated as an `Int`, `y` was unannotated in the type definition, therefore `y`
defaults to the `Any` type.

Types are themselves represented as a structure called `DataType`:

```julia-repl
```jldoctest struct_point
julia> typeof(Point)
DataType
```
Expand All @@ -52,9 +52,9 @@ of these fields is the `types` field observed in the example above.
The *direct* subtypes of any `DataType` may be listed using [`subtypes()`](@ref). For example,
the abstract `DataType``AbstractFloat` has four (concrete) subtypes:

```julia-repl
```jldoctest
julia> subtypes(AbstractFloat)
4-element Array{DataType,1}:
4-element Array{Union{DataType, UnionAll},1}:
BigFloat
Float16
Float32
Expand Down Expand Up @@ -83,9 +83,9 @@ the unquoted and interpolated expression (`Expr`) form for a given macro. To use
`quote` the expression block itself (otherwise, the macro will be evaluated and the result will
be passed instead!). For example:

```julia-repl
```jldoctest
julia> macroexpand( :(@edit println("")) )
:((Base.edit)(println,(Base.typesof)("")))
:((Base.edit)(println, (Base.typesof)("")))
```

The functions `Base.Meta.show_sexpr()` and [`dump()`](@ref) are used to display S-expr style views
Expand All @@ -95,11 +95,11 @@ Finally, the [`expand()`](@ref) function gives the `lowered` form of any express
particular interest for understanding both macros and top-level statements such as function declarations
and variable assignments:

```julia-repl
```jldoctest
julia> expand( :(f() = 1) )
:(begin
$(Expr(:method, :f))
$(Expr(:method, :f, :((Core.svec)((Core.svec)((Core.Typeof)(f)),(Core.svec)())), CodeInfo(:(begin # none, line 1:
$(Expr(:method, :f, :((Core.svec)((Core.svec)((Core.Typeof)(f)), (Core.svec)())), CodeInfo(:(begin # none, line 1:
return 1
end)), false))
return f
Expand Down
4 changes: 2 additions & 2 deletions doc/src/devdocs/subarrays.md
Original file line number Diff line number Diff line change
Expand Up @@ -152,7 +152,7 @@ we can define dispatch directly on `SubArray{T,N,A,I,true}` without any intermed
Since this computation doesn't depend on runtime values, it can miss some cases in which the stride
happens to be uniform:

```julia-repl
```jldoctest
julia> A = reshape(1:4*2, 4, 2)
4×2 Base.ReshapedArray{Int64,2,UnitRange{Int64},Tuple{}}:
1 5
Expand All @@ -171,7 +171,7 @@ A view constructed as `view(A, 2:2:4, :)` happens to have uniform stride, and th
indexing indeed could be performed efficiently. However, success in this case depends on the
size of the array: if the first dimension instead were odd,

```julia-repl
```jldoctest
julia> A = reshape(1:5*2, 5, 2)
5×2 Base.ReshapedArray{Int64,2,UnitRange{Int64},Tuple{}}:
1 6
Expand Down
8 changes: 4 additions & 4 deletions doc/src/manual/arrays.md
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Expand Up @@ -768,7 +768,7 @@ The [`sparse()`](@ref) function is often a handy way to construct sparse matrice
its input a vector `I` of row indices, a vector `J` of column indices, and a vector `V` of nonzero
values. `sparse(I,J,V)` constructs a sparse matrix such that `S[I[k], J[k]] = V[k]`.

```julia-repl
```jldoctest sparse_function
julia> I = [1, 4, 3, 5]; J = [4, 7, 18, 9]; V = [1, 2, -5, 3];
julia> S = sparse(I,J,V)
Expand All @@ -782,12 +782,12 @@ julia> S = sparse(I,J,V)
The inverse of the [`sparse()`](@ref) function is [`findn()`](@ref), which retrieves the inputs
used to create the sparse matrix.

```julia-repl
```jldoctest sparse_function
julia> findn(S)
([1,4,5,3],[4,7,9,18])
([1, 4, 5, 3], [4, 7, 9, 18])
julia> findnz(S)
([1,4,5,3],[4,7,9,18],[1,2,3,-5])
([1, 4, 5, 3], [4, 7, 9, 18], [1, 2, 3, -5])
```

Another way to create sparse matrices is to convert a dense matrix into a sparse matrix using
Expand Down
29 changes: 14 additions & 15 deletions doc/src/manual/conversion-and-promotion.md
Original file line number Diff line number Diff line change
Expand Up @@ -46,7 +46,7 @@ generally takes two arguments: the first is a type object while the second is a
to that type; the returned value is the value converted to an instance of given type. The simplest
way to understand this function is to see it in action:

```julia-repl
```jldoctest
julia> x = 12
12
Expand All @@ -66,25 +66,24 @@ julia> typeof(ans)
Float64
julia> a = Any[1 2 3; 4 5 6]
2x3 Array{Any,2}:
2×3 Array{Any,2}:
1 2 3
4 5 6
julia> convert(Array{Float64}, a)
2x3 Array{Float64,2}:
2×3 Array{Float64,2}:
1.0 2.0 3.0
4.0 5.0 6.0
```

Conversion isn't always possible, in which case a no method error is thrown indicating that `convert`
doesn't know how to perform the requested conversion:

```julia-repl
```jldoctest
julia> convert(AbstractFloat, "foo")
ERROR: MethodError: Cannot `convert` an object of type String to an object of type AbstractFloat
This may have arisen from a call to the constructor AbstractFloat(...),
since type constructors fall back to convert methods.
...
```

Some languages consider parsing strings as numbers or formatting numbers as strings to be conversions
Expand All @@ -111,7 +110,7 @@ example, since the type is a singleton, there would never be any reason to use i
the body. When invoked, the method determines whether a numeric value is true or false as a boolean,
by comparing it to one and zero:

```julia-repl
```jldoctest
julia> convert(Bool, 1)
true
Expand Down Expand Up @@ -196,24 +195,24 @@ any number of arguments, and returns a tuple of the same number of values, conve
type, or throws an exception if promotion is not possible. The most common use case for promotion
is to convert numeric arguments to a common type:

```julia-repl
```jldoctest
julia> promote(1, 2.5)
(1.0,2.5)
(1.0, 2.5)
julia> promote(1, 2.5, 3)
(1.0,2.5,3.0)
(1.0, 2.5, 3.0)
julia> promote(2, 3//4)
(2//1,3//4)
(2//1, 3//4)
julia> promote(1, 2.5, 3, 3//4)
(1.0,2.5,3.0,0.75)
(1.0, 2.5, 3.0, 0.75)
julia> promote(1.5, im)
(1.5 + 0.0im,0.0 + 1.0im)
(1.5 + 0.0im, 0.0 + 1.0im)
julia> promote(1 + 2im, 3//4)
(1//1 + 2//1*im,3//4 + 0//1*im)
(1//1 + 2//1*im, 3//4 + 0//1*im)
```

Floating-point values are promoted to the largest of the floating-point argument types. Integer
Expand Down Expand Up @@ -253,7 +252,7 @@ Rational(n::Integer, d::Integer) = Rational(promote(n,d)...)

This allows calls like the following to work:

```julia-repl
```jldoctest
julia> Rational(Int8(15),Int32(-5))
-3//1
Expand Down Expand Up @@ -297,7 +296,7 @@ which, given any number of type objects, returns the common type to which those
to `promote` should be promoted. Thus, if one wants to know, in absence of actual values, what
type a collection of values of certain types would promote to, one can use `promote_type`:

```julia-repl
```jldoctest
julia> promote_type(Int8, UInt16)
Int64
```
Expand Down
10 changes: 5 additions & 5 deletions doc/src/manual/integers-and-floating-point-numbers.md
Original file line number Diff line number Diff line change
Expand Up @@ -584,7 +584,7 @@ To make common numeric formulas and expressions clearer, Julia allows variables
preceded by a numeric literal, implying multiplication. This makes writing polynomial expressions
much cleaner:

```jldoctest
```jldoctest numeric-coefficients
julia> x = 3
3
Expand All @@ -597,7 +597,7 @@ julia> 1.5x^2 - .5x + 1

It also makes writing exponential functions more elegant:

```julia-repl
```jldoctest numeric-coefficients
julia> 2^2x
64
```
Expand All @@ -607,23 +607,23 @@ negation. So `2^3x` is parsed as `2^(3x)`, and `2x^3` is parsed as `2*(x^3)`.

Numeric literals also work as coefficients to parenthesized expressions:

```julia-repl
```jldoctest numeric-coefficients
julia> 2(x-1)^2 - 3(x-1) + 1
3
```

Additionally, parenthesized expressions can be used as coefficients to variables, implying multiplication
of the expression by the variable:

```julia-repl
```jldoctest numeric-coefficients
julia> (x-1)x
6
```

Neither juxtaposition of two parenthesized expressions, nor placing a variable before a parenthesized
expression, however, can be used to imply multiplication:

```julia-repl
```jldoctest numeric-coefficients
julia> (x-1)(x+1)
ERROR: MethodError: objects of type Int64 are not callable
Expand Down
2 changes: 1 addition & 1 deletion doc/src/manual/metaprogramming.md
Original file line number Diff line number Diff line change
Expand Up @@ -920,7 +920,7 @@ we returned from the definition, now with the *value* of `x`.

What happens if we evaluate `foo` again with a type that we have already used?

```julia-repl generated
```jldoctest generated
julia> foo(4)
16
```
Expand Down
4 changes: 2 additions & 2 deletions doc/src/manual/performance-tips.md
Original file line number Diff line number Diff line change
Expand Up @@ -257,7 +257,7 @@ like `m` but not for objects like `t`.
Of course, all of this is true only if we construct `m` with a concrete type. We can break this
by explicitly constructing it with an abstract type:

```julia-repl myambig2
```jldoctest myambig2
julia> m = MyType{AbstractFloat}(3.2)
MyType{AbstractFloat}(3.2)
Expand Down Expand Up @@ -429,7 +429,7 @@ the array type `A`.
However, there's one remaining hole: we haven't enforced that `A` has element type `T`, so it's
perfectly possible to construct an object like this:

```julia-repl
```jldoctest containers2
julia> b = MyContainer{Int64, UnitRange{Float64}}(UnitRange(1.3, 5.0));
julia> typeof(b)
Expand Down
2 changes: 1 addition & 1 deletion doc/src/manual/running-external-programs.md
Original file line number Diff line number Diff line change
Expand Up @@ -49,7 +49,7 @@ true

More generally, you can use [`open()`](@ref) to read from or write to an external command.

```julia-repl
```jldoctest
julia> open(`less`, "w", STDOUT) do io
for i = 1:3
println(io, i)
Expand Down
4 changes: 2 additions & 2 deletions doc/src/manual/strings.md
Original file line number Diff line number Diff line change
Expand Up @@ -645,7 +645,7 @@ For when a capture doesn't match, instead of a substring, `m.captures` contains
position, and `m.offsets` has a zero offset (recall that indices in Julia are 1-based, so a zero
offset into a string is invalid). Here is a pair of somewhat contrived examples:

```jldoctest
```jldoctest acdmatch
julia> m = match(r"(a|b)(c)?(d)", "acd")
RegexMatch("acd", 1="a", 2="c", 3="d")
Expand Down Expand Up @@ -692,7 +692,7 @@ julia> m.offsets
It is convenient to have captures returned as an array so that one can use destructuring syntax
to bind them to local variables:

```julia-repl
```jldoctest acdmatch
julia> first, second, third = m.captures; first
"a"
```
Expand Down
6 changes: 3 additions & 3 deletions doc/src/manual/variables-and-scoping.md
Original file line number Diff line number Diff line change
Expand Up @@ -174,7 +174,7 @@ julia> x
Within soft scopes, the *global* keyword is never necessary, although allowed. The only case
when it would change the semantics is (currently) a syntax error:

```julia-repl
```jldoctest
julia> let
local j = 2
let
Expand Down Expand Up @@ -332,7 +332,7 @@ The reason to allow *modifying local* variables of parent scopes in nested funct
constructing [closures](https://en.wikipedia.org/wiki/Closure_%28computer_programming%29) which
have a private state, for instance the `state` variable in the following example:

```julia-repl
```jldoctest
julia> let
state = 0
global counter
Expand Down Expand Up @@ -411,7 +411,7 @@ julia> Fs[2]()
Since the `begin` construct does not introduce a new scope, it can be useful to use a zero-argument
`let` to just introduce a new scope block without creating any new bindings:

```julia-repl
```jldoctest
julia> let
local x = 1
let
Expand Down
6 changes: 3 additions & 3 deletions doc/src/stdlib/sort.md
Original file line number Diff line number Diff line change
Expand Up @@ -3,7 +3,7 @@
Julia has an extensive, flexible API for sorting and interacting with already-sorted arrays of
values. By default, Julia picks reasonable algorithms and sorts in standard ascending order:

```julia-repl
```jldoctest
julia> sort([2,3,1])
3-element Array{Int64,1}:
1
Expand All @@ -13,7 +13,7 @@ julia> sort([2,3,1])

You can easily sort in reverse order as well:

```julia-repl
```jldoctest
julia> sort([2,3,1], rev=true)
3-element Array{Int64,1}:
3
Expand All @@ -23,7 +23,7 @@ julia> sort([2,3,1], rev=true)

To sort an array in-place, use the "bang" version of the sort function:

```julia-repl
```jldoctest
julia> a = [2,3,1];
julia> sort!(a);
Expand Down

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