Unit Testing

Testing Base Julia

Julia is under rapid development and has an extensive test suite to verify functionality across multiple platforms. If you build Julia from source, you can run this test suite with make test. In a binary install, you can run the test suite using Base.runtests().

Base.runtestsFunction
Base.runtests(tests=["all"]; ncores=ceil(Int, Sys.CPU_THREADS / 2),
              exit_on_error=false, revise=false, [seed])

Run the Julia unit tests listed in tests, which can be either a string or an array of strings, using ncores processors. If exit_on_error is false, when one test fails, all remaining tests in other files will still be run; they are otherwise discarded, when exit_on_error == true. If revise is true, the Revise package is used to load any modifications to Base or to the standard libraries before running the tests. If a seed is provided via the keyword argument, it is used to seed the global RNG in the context where the tests are run; otherwise the seed is chosen randomly.

source

Basic Unit Tests

The Test module provides simple unit testing functionality. Unit testing is a way to see if your code is correct by checking that the results are what you expect. It can be helpful to ensure your code still works after you make changes, and can be used when developing as a way of specifying the behaviors your code should have when complete. You may also want to look at the documentation for adding tests to your Julia Package.

Simple unit testing can be performed with the @test and @test_throws macros:

Test.@testMacro
@test ex
@test f(args...) key=val ...
@test ex broken=true
@test ex skip=true

Test that the expression ex evaluates to true. If executed inside a @testset, return a Pass Result if it does, a Fail Result if it is false, and an Error Result if it could not be evaluated. If executed outside a @testset, throw an exception instead of returning Fail or Error.

Examples

julia> @test true
Test Passed

julia> @test [1, 2] + [2, 1] == [3, 3]
Test Passed

The @test f(args...) key=val... form is equivalent to writing @test f(args..., key=val...) which can be useful when the expression is a call using infix syntax such as approximate comparisons:

julia> @test π ≈ 3.14 atol=0.01
Test Passed

This is equivalent to the uglier test @test ≈(π, 3.14, atol=0.01). It is an error to supply more than one expression unless the first is a call expression and the rest are assignments (k=v).

You can use any key for the key=val arguments, except for broken and skip, which have special meanings in the context of @test:

  • broken=cond indicates a test that should pass but currently consistently fails when cond==true. Tests that the expression ex evaluates to false or causes an exception. Returns a Broken Result if it does, or an Error Result if the expression evaluates to true. Regular @test ex is evaluated when cond==false.
  • skip=cond marks a test that should not be executed but should be included in test summary reporting as Broken, when cond==true. This can be useful for tests that intermittently fail, or tests of not-yet-implemented functionality. Regular @test ex is evaluated when cond==false.

Examples

julia> @test 2 + 2 ≈ 6 atol=1 broken=true
Test Broken
  Expression: ≈(2 + 2, 6, atol = 1)

julia> @test 2 + 2 ≈ 5 atol=1 broken=false
Test Passed

julia> @test 2 + 2 == 5 skip=true
Test Broken
  Skipped: 2 + 2 == 5

julia> @test 2 + 2 == 4 skip=false
Test Passed
Julia 1.7

The broken and skip keyword arguments require at least Julia 1.7.

Test.@test_throwsMacro
@test_throws exception expr

Tests that the expression expr throws exception. The exception may specify either a type, a string, regular expression, or list of strings occurring in the displayed error message, a matching function, or a value (which will be tested for equality by comparing fields). Note that @test_throws does not support a trailing keyword form.

Julia 1.8

The ability to specify anything other than a type or a value as exception requires Julia v1.8 or later.

Examples

julia> @test_throws BoundsError [1, 2, 3][4]
Test Passed
      Thrown: BoundsError

julia> @test_throws DimensionMismatch [1, 2, 3] + [1, 2]
Test Passed
      Thrown: DimensionMismatch

julia> @test_throws "Try sqrt(Complex" sqrt(-1)
Test Passed
     Message: "DomainError with -1.0:\nsqrt will only return a complex result if called with a complex argument. Try sqrt(Complex(x))."

In the final example, instead of matching a single string it could alternatively have been performed with:

  • ["Try", "Complex"] (a list of strings)
  • r"Try sqrt\([Cc]omplex" (a regular expression)
  • str -> occursin("complex", str) (a matching function)

For example, suppose we want to check our new function foo(x) works as expected:

julia> using Test

julia> foo(x) = length(x)^2
foo (generic function with 1 method)

If the condition is true, a Pass is returned:

julia> @test foo("bar") == 9
Test Passed

julia> @test foo("fizz") >= 10
Test Passed

If the condition is false, then a Fail is returned and an exception is thrown:

julia> @test foo("f") == 20
Test Failed at none:1
  Expression: foo("f") == 20
   Evaluated: 1 == 20

ERROR: There was an error during testing

If the condition could not be evaluated because an exception was thrown, which occurs in this case because length is not defined for symbols, an Error object is returned and an exception is thrown:

julia> @test foo(:cat) == 1
Error During Test
  Test threw an exception of type MethodError
  Expression: foo(:cat) == 1
  MethodError: no method matching length(::Symbol)
  Closest candidates are:
    length(::SimpleVector) at essentials.jl:256
    length(::Base.MethodList) at reflection.jl:521
    length(::MethodTable) at reflection.jl:597
    ...
  Stacktrace:
  [...]
ERROR: There was an error during testing

If we expect that evaluating an expression should throw an exception, then we can use @test_throws to check that this occurs:

julia> @test_throws MethodError foo(:cat)
Test Passed
      Thrown: MethodError

Working with Test Sets

Typically a large number of tests are used to make sure functions work correctly over a range of inputs. In the event a test fails, the default behavior is to throw an exception immediately. However, it is normally preferable to run the rest of the tests first to get a better picture of how many errors there are in the code being tested.

Note

The @testset will create a local scope of its own when running the tests in it.

The @testset macro can be used to group tests into sets. All the tests in a test set will be run, and at the end of the test set a summary will be printed. If any of the tests failed, or could not be evaluated due to an error, the test set will then throw a TestSetException.

Test.@testsetMacro
@testset [CustomTestSet] [option=val  ...] ["description"] begin ... end
@testset [CustomTestSet] [option=val  ...] ["description $v"] for v in (...) ... end
@testset [CustomTestSet] [option=val  ...] ["description $v, $w"] for v in (...), w in (...) ... end
@testset [CustomTestSet] [option=val  ...] ["description"] foo()
@testset let v = (...) ... end

With begin/end or function call

When @testset is used, with begin/end or a single function call, the macro starts a new test set in which to evaluate the given expression.

If no custom testset type is given it defaults to creating a DefaultTestSet. DefaultTestSet records all the results and, if there are any Fails or Errors, throws an exception at the end of the top-level (non-nested) test set, along with a summary of the test results.

Any custom testset type (subtype of AbstractTestSet) can be given and it will also be used for any nested @testset invocations. The given options are only applied to the test set where they are given. The default test set type accepts three boolean options:

  • verbose: if true, the result summary of the nested testsets is shown even

when they all pass (the default is false).

  • showtiming: if true, the duration of each displayed testset is shown

(the default is true).

  • failfast: if true, any test failure or error will cause the testset and any

child testsets to return immediately (the default is false). This can also be set globally via the env var JULIA_TEST_FAILFAST.

Julia 1.8

@testset foo() requires at least Julia 1.8.

Julia 1.9

failfast requires at least Julia 1.9.

The description string accepts interpolation from the loop indices. If no description is provided, one is constructed based on the variables. If a function call is provided, its name will be used. Explicit description strings override this behavior.

By default the @testset macro will return the testset object itself, though this behavior can be customized in other testset types. If a for loop is used then the macro collects and returns a list of the return values of the finish method, which by default will return a list of the testset objects used in each iteration.

Before the execution of the body of a @testset, there is an implicit call to Random.seed!(seed) where seed is the current seed of the global RNG. Moreover, after the execution of the body, the state of the global RNG is restored to what it was before the @testset. This is meant to ease reproducibility in case of failure, and to allow seamless re-arrangements of @testsets regardless of their side-effect on the global RNG state.

Examples

julia> @testset "trigonometric identities" begin
           θ = 2/3*π
           @test sin(-θ) ≈ -sin(θ)
           @test cos(-θ) ≈ cos(θ)
           @test sin(2θ) ≈ 2*sin(θ)*cos(θ)
           @test cos(2θ) ≈ cos(θ)^2 - sin(θ)^2
       end;
Test Summary:            | Pass  Total  Time
trigonometric identities |    4      4  0.2s

@testset for

When @testset for is used, the macro starts a new test for each iteration of the provided loop. The semantics of each test set are otherwise identical to that of that begin/end case (as if used for each loop iteration).

@testset let

When @testset let is used, the macro starts a transparent test set with the given object added as a context object to any failing test contained therein. This is useful when performing a set of related tests on one larger object and it is desirable to print this larger object when any of the individual tests fail. Transparent test sets do not introduce additional levels of nesting in the test set hierarchy and are passed through directly to the parent test set (with the context object appended to any failing tests.)

Julia 1.9

@testset let requires at least Julia 1.9.

Examples

julia> @testset let logi = log(im)
           @test imag(logi) == π/2
           @test !iszero(real(logi))
       end
Test Failed at none:3
  Expression: !(iszero(real(logi)))
     Context: logi = 0.0 + 1.5707963267948966im

ERROR: There was an error during testing

We can put our tests for the foo(x) function in a test set:

julia> @testset "Foo Tests" begin
           @test foo("a")   == 1
           @test foo("ab")  == 4
           @test foo("abc") == 9
       end;
Test Summary: | Pass  Total  Time
Foo Tests     |    3      3  0.0s

Test sets can also be nested:

julia> @testset "Foo Tests" begin
           @testset "Animals" begin
               @test foo("cat") == 9
               @test foo("dog") == foo("cat")
           end
           @testset "Arrays $i" for i in 1:3
               @test foo(zeros(i)) == i^2
               @test foo(fill(1.0, i)) == i^2
           end
       end;
Test Summary: | Pass  Total  Time
Foo Tests     |    8      8  0.0s

As well as call functions:

julia> f(x) = @test isone(x)
f (generic function with 1 method)

julia> @testset f(1);
Test Summary: | Pass  Total  Time
f             |    1      1  0.0s

This can be used to allow for factorization of test sets, making it easier to run individual test sets by running the associated functions instead. Note that in the case of functions, the test set will be given the name of the called function. In the event that a nested test set has no failures, as happened here, it will be hidden in the summary, unless the verbose=true option is passed:

julia> @testset verbose = true "Foo Tests" begin
           @testset "Animals" begin
               @test foo("cat") == 9
               @test foo("dog") == foo("cat")
           end
           @testset "Arrays $i" for i in 1:3
               @test foo(zeros(i)) == i^2
               @test foo(fill(1.0, i)) == i^2
           end
       end;
Test Summary: | Pass  Total  Time
Foo Tests     |    8      8  0.0s
  Animals     |    2      2  0.0s
  Arrays 1    |    2      2  0.0s
  Arrays 2    |    2      2  0.0s
  Arrays 3    |    2      2  0.0s

If we do have a test failure, only the details for the failed test sets will be shown:

julia> @testset "Foo Tests" begin
           @testset "Animals" begin
               @testset "Felines" begin
                   @test foo("cat") == 9
               end
               @testset "Canines" begin
                   @test foo("dog") == 9
               end
           end
           @testset "Arrays" begin
               @test foo(zeros(2)) == 4
               @test foo(fill(1.0, 4)) == 15
           end
       end

Arrays: Test Failed
  Expression: foo(fill(1.0, 4)) == 15
   Evaluated: 16 == 15
[...]
Test Summary: | Pass  Fail  Total  Time
Foo Tests     |    3     1      4  0.0s
  Animals     |    2            2  0.0s
  Arrays      |    1     1      2  0.0s
ERROR: Some tests did not pass: 3 passed, 1 failed, 0 errored, 0 broken.

Testing Log Statements

One can use the @test_logs macro to test log statements, or use a TestLogger.

Test.@test_logsMacro
@test_logs [log_patterns...] [keywords] expression

Collect a list of log records generated by expression using collect_test_logs, check that they match the sequence log_patterns, and return the value of expression. The keywords provide some simple filtering of log records: the min_level keyword controls the minimum log level which will be collected for the test, the match_mode keyword defines how matching will be performed (the default :all checks that all logs and patterns match pairwise; use :any to check that the pattern matches at least once somewhere in the sequence.)

The most useful log pattern is a simple tuple of the form (level,message). A different number of tuple elements may be used to match other log metadata, corresponding to the arguments to passed to AbstractLogger via the handle_message function: (level,message,module,group,id,file,line). Elements which are present will be matched pairwise with the log record fields using == by default, with the special cases that Symbols may be used for the standard log levels, and Regexs in the pattern will match string or Symbol fields using occursin.

Examples

Consider a function which logs a warning, and several debug messages:

function foo(n)
    @info "Doing foo with n=$n"
    for i=1:n
        @debug "Iteration $i"
    end
    42
end

We can test the info message using

@test_logs (:info,"Doing foo with n=2") foo(2)

If we also wanted to test the debug messages, these need to be enabled with the min_level keyword:

using Logging
@test_logs (:info,"Doing foo with n=2") (:debug,"Iteration 1") (:debug,"Iteration 2") min_level=Logging.Debug foo(2)

If you want to test that some particular messages are generated while ignoring the rest, you can set the keyword match_mode=:any:

using Logging
@test_logs (:info,) (:debug,"Iteration 42") min_level=Logging.Debug match_mode=:any foo(100)

The macro may be chained with @test to also test the returned value:

@test (@test_logs (:info,"Doing foo with n=2") foo(2)) == 42

If you want to test for the absence of warnings, you can omit specifying log patterns and set the min_level accordingly:

# test that the expression logs no messages when the logger level is warn:
@test_logs min_level=Logging.Warn @info("Some information") # passes
@test_logs min_level=Logging.Warn @warn("Some information") # fails

If you want to test the absence of warnings (or error messages) in stderr which are not generated by @warn, see @test_nowarn.

Test.TestLoggerType
TestLogger(; min_level=Info, catch_exceptions=false)

Create a TestLogger which captures logged messages in its logs::Vector{LogRecord} field.

Set min_level to control the LogLevel, catch_exceptions for whether or not exceptions thrown as part of log event generation should be caught, and respect_maxlog for whether or not to follow the convention of logging messages with maxlog=n for some integer n at most n times.

See also: LogRecord.

Example

julia> using Test, Logging

julia> f() = @info "Hi" number=5;

julia> test_logger = TestLogger();

julia> with_logger(test_logger) do
           f()
           @info "Bye!"
       end

julia> @test test_logger.logs[1].message == "Hi"
Test Passed

julia> @test test_logger.logs[1].kwargs[:number] == 5
Test Passed

julia> @test test_logger.logs[2].message == "Bye!"
Test Passed
Test.LogRecordType
LogRecord

Stores the results of a single log event. Fields:

  • level: the LogLevel of the log message
  • message: the textual content of the log message
  • _module: the module of the log event
  • group: the logging group (by default, the name of the file containing the log event)
  • id: the ID of the log event
  • file: the file containing the log event
  • line: the line within the file of the log event
  • kwargs: any keyword arguments passed to the log event

Other Test Macros

As calculations on floating-point values can be imprecise, you can perform approximate equality checks using either @test a ≈ b (where , typed via tab completion of \approx, is the isapprox function) or use isapprox directly.

julia> @test 1 ≈ 0.999999999
Test Passed

julia> @test 1 ≈ 0.999999
Test Failed at none:1
  Expression: 1 ≈ 0.999999
   Evaluated: 1 ≈ 0.999999

ERROR: There was an error during testing

You can specify relative and absolute tolerances by setting the rtol and atol keyword arguments of isapprox, respectively, after the comparison:

julia> @test 1 ≈ 0.999999  rtol=1e-5
Test Passed

Note that this is not a specific feature of the but rather a general feature of the @test macro: @test a <op> b key=val is transformed by the macro into @test op(a, b, key=val). It is, however, particularly useful for tests.

Test.@inferredMacro
@inferred [AllowedType] f(x)

Tests that the call expression f(x) returns a value of the same type inferred by the compiler. It is useful to check for type stability.

f(x) can be any call expression. Returns the result of f(x) if the types match, and an Error Result if it finds different types.

Optionally, AllowedType relaxes the test, by making it pass when either the type of f(x) matches the inferred type modulo AllowedType, or when the return type is a subtype of AllowedType. This is useful when testing type stability of functions returning a small union such as Union{Nothing, T} or Union{Missing, T}.

julia> f(a) = a > 1 ? 1 : 1.0
f (generic function with 1 method)

julia> typeof(f(2))
Int64

julia> @code_warntype f(2)
MethodInstance for f(::Int64)
  from f(a) @ Main none:1
Arguments
  #self#::Core.Const(f)
  a::Int64
Body::UNION{FLOAT64, INT64}
1 ─ %1 = (a > 1)::Bool
└──      goto #3 if not %1
2 ─      return 1
3 ─      return 1.0

julia> @inferred f(2)
ERROR: return type Int64 does not match inferred return type Union{Float64, Int64}
[...]

julia> @inferred max(1, 2)
2

julia> g(a) = a < 10 ? missing : 1.0
g (generic function with 1 method)

julia> @inferred g(20)
ERROR: return type Float64 does not match inferred return type Union{Missing, Float64}
[...]

julia> @inferred Missing g(20)
1.0

julia> h(a) = a < 10 ? missing : f(a)
h (generic function with 1 method)

julia> @inferred Missing h(20)
ERROR: return type Int64 does not match inferred return type Union{Missing, Float64, Int64}
[...]
Test.@test_deprecatedMacro
@test_deprecated [pattern] expression

When --depwarn=yes, test that expression emits a deprecation warning and return the value of expression. The log message string will be matched against pattern which defaults to r"deprecated"i.

When --depwarn=no, simply return the result of executing expression. When --depwarn=error, check that an ErrorException is thrown.

Examples

# Deprecated in julia 0.7
@test_deprecated num2hex(1)

# The returned value can be tested by chaining with @test:
@test (@test_deprecated num2hex(1)) == "0000000000000001"
Test.@test_warnMacro
@test_warn msg expr

Test whether evaluating expr results in stderr output that contains the msg string or matches the msg regular expression. If msg is a boolean function, tests whether msg(output) returns true. If msg is a tuple or array, checks that the error output contains/matches each item in msg. Returns the result of evaluating expr.

See also @test_nowarn to check for the absence of error output.

Note: Warnings generated by @warn cannot be tested with this macro. Use @test_logs instead.

Test.@test_nowarnMacro
@test_nowarn expr

Test whether evaluating expr results in empty stderr output (no warnings or other messages). Returns the result of evaluating expr.

Note: The absence of warnings generated by @warn cannot be tested with this macro. Use @test_logs instead.

Broken Tests

If a test fails consistently it can be changed to use the @test_broken macro. This will denote the test as Broken if the test continues to fail and alerts the user via an Error if the test succeeds.

Test.@test_brokenMacro
@test_broken ex
@test_broken f(args...) key=val ...

Indicates a test that should pass but currently consistently fails. Tests that the expression ex evaluates to false or causes an exception. Returns a Broken Result if it does, or an Error Result if the expression evaluates to true. This is equivalent to @test ex broken=true.

The @test_broken f(args...) key=val... form works as for the @test macro.

Examples

julia> @test_broken 1 == 2
Test Broken
  Expression: 1 == 2

julia> @test_broken 1 == 2 atol=0.1
Test Broken
  Expression: ==(1, 2, atol = 0.1)

@test_skip is also available to skip a test without evaluation, but counting the skipped test in the test set reporting. The test will not run but gives a Broken Result.

Test.@test_skipMacro
@test_skip ex
@test_skip f(args...) key=val ...

Marks a test that should not be executed but should be included in test summary reporting as Broken. This can be useful for tests that intermittently fail, or tests of not-yet-implemented functionality. This is equivalent to @test ex skip=true.

The @test_skip f(args...) key=val... form works as for the @test macro.

Examples

julia> @test_skip 1 == 2
Test Broken
  Skipped: 1 == 2

julia> @test_skip 1 == 2 atol=0.1
Test Broken
  Skipped: ==(1, 2, atol = 0.1)

Creating Custom AbstractTestSet Types

Packages can create their own AbstractTestSet subtypes by implementing the record and finish methods. The subtype should have a one-argument constructor taking a description string, with any options passed in as keyword arguments.

Test.recordFunction
record(ts::AbstractTestSet, res::Result)

Record a result to a testset. This function is called by the @testset infrastructure each time a contained @test macro completes, and is given the test result (which could be an Error). This will also be called with an Error if an exception is thrown inside the test block but outside of a @test context.

Test.finishFunction
finish(ts::AbstractTestSet)

Do any final processing necessary for the given testset. This is called by the @testset infrastructure after a test block executes.

Custom AbstractTestSet subtypes should call record on their parent (if there is one) to add themselves to the tree of test results. This might be implemented as:

if get_testset_depth() != 0
    # Attach this test set to the parent test set
    parent_ts = get_testset()
    record(parent_ts, self)
    return self
end

Test takes responsibility for maintaining a stack of nested testsets as they are executed, but any result accumulation is the responsibility of the AbstractTestSet subtype. You can access this stack with the get_testset and get_testset_depth methods. Note that these functions are not exported.

Test.get_testsetFunction
get_testset()

Retrieve the active test set from the task's local storage. If no test set is active, use the fallback default test set.

Test.get_testset_depthFunction
get_testset_depth()

Return the number of active test sets, not including the default test set

Test also makes sure that nested @testset invocations use the same AbstractTestSet subtype as their parent unless it is set explicitly. It does not propagate any properties of the testset. Option inheritance behavior can be implemented by packages using the stack infrastructure that Test provides.

Defining a basic AbstractTestSet subtype might look like:

import Test: Test, record, finish
using Test: AbstractTestSet, Result, Pass, Fail, Error
using Test: get_testset_depth, get_testset
struct CustomTestSet <: Test.AbstractTestSet
    description::AbstractString
    foo::Int
    results::Vector
    # constructor takes a description string and options keyword arguments
    CustomTestSet(desc; foo=1) = new(desc, foo, [])
end

record(ts::CustomTestSet, child::AbstractTestSet) = push!(ts.results, child)
record(ts::CustomTestSet, res::Result) = push!(ts.results, res)
function finish(ts::CustomTestSet)
    # just record if we're not the top-level parent
    if get_testset_depth() > 0
        record(get_testset(), ts)
    end
    ts
end

And using that testset looks like:

@testset CustomTestSet foo=4 "custom testset inner 2" begin
    # this testset should inherit the type, but not the argument.
    @testset "custom testset inner" begin
        @test true
    end
end

Test utilities

Test.GenericArrayType

The GenericArray can be used to test generic array APIs that program to the AbstractArray interface, in order to ensure that functions can work with array types besides the standard Array type.

Test.GenericDictType

The GenericDict can be used to test generic dict APIs that program to the AbstractDict interface, in order to ensure that functions can work with associative types besides the standard Dict type.

Test.GenericOrderType

The GenericOrder can be used to test APIs for their support of generic ordered types.

Test.GenericSetType

The GenericSet can be used to test generic set APIs that program to the AbstractSet interface, in order to ensure that functions can work with set types besides the standard Set and BitSet types.

Test.GenericStringType

The GenericString can be used to test generic string APIs that program to the AbstractString interface, in order to ensure that functions can work with string types besides the standard String type.

Test.detect_ambiguitiesFunction
detect_ambiguities(mod1, mod2...; recursive=false,
                                  ambiguous_bottom=false,
                                  allowed_undefineds=nothing)

Return a vector of (Method,Method) pairs of ambiguous methods defined in the specified modules. Use recursive=true to test in all submodules.

ambiguous_bottom controls whether ambiguities triggered only by Union{} type parameters are included; in most cases you probably want to set this to false. See Base.isambiguous.

See Test.detect_unbound_args for an explanation of allowed_undefineds.

Julia 1.8

allowed_undefineds requires at least Julia 1.8.

Test.detect_unbound_argsFunction
detect_unbound_args(mod1, mod2...; recursive=false, allowed_undefineds=nothing)

Return a vector of Methods which may have unbound type parameters. Use recursive=true to test in all submodules.

By default, any undefined symbols trigger a warning. This warning can be suppressed by supplying a collection of GlobalRefs for which the warning can be skipped. For example, setting

allow_undefineds = Set([GlobalRef(Base, :active_repl),
                        GlobalRef(Base, :active_repl_backend)])

would suppress warnings about Base.active_repl and Base.active_repl_backend.

Julia 1.8

allowed_undefineds requires at least Julia 1.8.

Workflow for Testing Packages

Using the tools available to us in the previous sections, here is a potential workflow of creating a package and adding tests to it.

Generating an Example Package

For this workflow, we will create a package called Example:

pkg> generate Example
shell> cd Example
shell> mkdir test
pkg> activate .

Creating Sample Functions

The number one requirement for testing a package is to have functionality to test. For that, we will add some simple functions to Example that we can test. Add the following to src/Example.jl:

module Example

function greet()
    "Hello world!"
end

function simple_add(a, b)
    a + b
end

function type_multiply(a::Float64, b::Float64)
    a * b
end

end

Creating a Test Environment

From within the root of the Example package, navigate to the test directory, activate a new environment there, and add the Test package to the environment:

shell> cd test
pkg> activate .
(test) pkg> add Test

Testing Our Package

Now, we are ready to add tests to Example. It is standard practice to create a file within the test directory called runtests.jl which contains the test sets we want to run. Go ahead and create that file within the test directory and add the following code to it:

using Example
using Test

@testset "Example tests" begin

	@testset "Math tests" begin
		include("math_tests.jl")
	end

	@testset "Greeting tests" begin
		include("greeting_tests.jl")
	end
end

We will need to create those two included files, math_tests.jl and greeting_tests.jl, and add some tests to them.

Note: Notice how we did not have to specify add Example into the test environment's Project.toml. This is a benefit of Julia's testing system that you could read about more here.

Writing Tests for math_tests.jl

Using our knowledge of Test.jl, here are some example tests we could add to math_tests.jl:

@testset "Testset 1" begin
	@test 2 == simple_add(1, 1)
	@test 3.5 == simple_add(1, 2.5)
        @test_throws MethodError simple_add(1, "A")
        @test_throws MethodError simple_add(1, 2, 3)
end

@testset "Testset 2" begin
	@test 1.0 == type_multiply(1.0, 1.0)
        @test isa(type_multiply(2.0, 2.0), Float64)
	@test_throws MethodError type_multiply(1, 2.5)
end

Writing Tests for greeting_tests.jl

Using our knowledge of Test.jl, here are some example tests we could add to math_tests.jl:

@testset "Testset 3" begin
    @test "Hello world!" == greet()
    @test_throws MethodError greet("Antonia")
end

Testing Our Package

Now that we have added our tests and our runtests.jl script in test, we can test our Example package by going back to the root of the Example package environment and reactivating the Example environment:

shell> cd ..
pkg> activate .

From there, we can finally run our test suite as follows:

(Example) pkg> test
     Testing Example
      Status `/tmp/jl_Yngpvy/Project.toml`
  [fa318bd2] Example v0.1.0 `/home/src/Projects/tmp/errata/Example`
  [8dfed614] Test `@stdlib/Test`
      Status `/tmp/jl_Yngpvy/Manifest.toml`
  [fa318bd2] Example v0.1.0 `/home/src/Projects/tmp/errata/Example`
  [2a0f44e3] Base64 `@stdlib/Base64`
  [b77e0a4c] InteractiveUtils `@stdlib/InteractiveUtils`
  [56ddb016] Logging `@stdlib/Logging`
  [d6f4376e] Markdown `@stdlib/Markdown`
  [9a3f8284] Random `@stdlib/Random`
  [ea8e919c] SHA `@stdlib/SHA`
  [9e88b42a] Serialization `@stdlib/Serialization`
  [8dfed614] Test `@stdlib/Test`
     Testing Running tests...
Test Summary: | Pass  Total
Example tests |    9      9
     Testing Example tests passed

And if all went correctly, you should see a similar output as above. Using Test.jl, more complicated tests can be added for packages but this should ideally point developers in the direction of how to get started with testing their own created packages.