The idea of QuickCheck was originally introduced in John's paper QuickCheck: a lightweight tool for random testing of Haskell programs and its Haskell derivation QuickCheck, which aimed at simplifying the writing of tests by generating them. The core is to automatically generate tests based on a the signature of the specification / theorem (i.e. properties which functions should satisfy) and QuickCheck then tests that the properties hold. The idea spread to other languages and is now implemented in MoonBit. Because of the differences in type systems between Haskell and MoonBit, the original idea morphed into something different. There are several differences to this approach:
- We have discarded many ideas in Haskell QuickCheck that have been proven inappropriate by time.
- Some features requires a very fancy type system were removed (Or not considered currently). For instance, the generation of functions requires GADT but MoonBit does not.
- MoonBit QuickCheck brings many modern academic ideas into industrial practice (listed below).
Let's start with something very simple. Suppose that we just wrote a function reverse
which takes an array as argument and returns its reverse. We want to test its functionality by writing unit tests:
test "reverse" {
inspect!(reverse(([] : Array[Int])), content="[]")
inspect!(reverse([1, 2, 3]), content="[3, 2, 1]")
}
Is this enough to prove that this function is correct? No, the bugs may lies in the remaining untested code. But if we want more rigorous verification, we may need to write more test cases. For the complicated program, there would never be time to. How can we reduce the cost of testing? The key to doing so must be to generalize the test functions, so that each function covers not only one test case, but many. This is where QuickCheck comes in. We can write a property that reverse
should hold for any array, and QuickCheck will generate a large number of random array and check that the property holds for all of them.
But what property should we write? We may notice that the reverse of the reverse of an array is the original array. So we can write a property that reverse
should hold for any array:
fn prop_reverse_identity(arr : Array[Int]) {
reverse(reverse(arr)) == arr
}
We may consider the code logically as:
Looks good, now we can use QuickCheck to test this property (Note that we wrap the function in Arrow
to make it a Testable
though implicit conversion not work now):
test {
quick_check_fn!(prop_reverse_identity)
// equivalent to quick_check!(Arrow(prop_reverse_identity))
}
The quick_check
function takes a Testable
and runs tests, reporting the result (The three number in the brackets are the number of passed, discarded and total tests):
+++ [100/0/100] Ok, passed!
Now let's see another example: suppose we wrote a function remove(arr : Array[Int], x : Int) -> Array[Int]
that takes an array and an element and returns a new array with all occurrences of x
removed. The intuitive implementation is to search for x
in the array and remove it if found:
fn remove(arr : Array[Int], x : Int) -> Array[Int] {
match arr.search(x) {
Some(i) => arr.remove(i) |> ignore
None => ()
}
arr
}
We may consider the following properties:
- If an element was removed from the array, the length of the array should be less than or equal to the original array
- If an element was removed from the array, the element should not exist in the array
Now we translate the first property into MoonBit code (Note that the property function should have only one argument, but we can use tuple to pass multiple arguments):
fn prop_length_is_not_greater(iarr : (Int, Array[Int])) -> Bool {
let (x, arr) = iarr
let len = arr.length()
remove(arr, x).length() <= len
}
Run QuickCheck, all tests passed. However, this property is not considered a good property because it is can be fulfilled easily and the test is not very meaningful. Most Bugs may still exist in the function.
test {
quick_check_fn!(prop_length_is_not_greater)
}
// +++ [100/0/100] Ok, passed!
The later property is considered better (The with_max_success
function sets the number of tests that should be performed to 1000
):
fn prop_remove_not_presence(iarr : (Int, Array[Int])) -> Bool {
let (x, arr) = iarr
remove(arr, x).contains(x).not()
}
test {
quick_check_fn!(prop_remove_not_presence) |> with_max_success(1000)
}
The QuickCheck reports a failure with a counterexample in the second line after almost 100 tests:
*** [107/0/1000] Failed! Falsified.
(0, [0, 0])
When x = 0
and arr = [0, 0]
the property does not hold. The remove
function should remove all occurrences of x
in the array, but it only removes the first one. In this example, as in many cases, the randomly generated test case contains junk values that have nothing to do with the test failure itself. When QuickCheck finds a failing test case, it tries to simplify it by applying some shrinking strategies. In fact the failing case is much complex but the shrinking algorithm has simplified it to the minimal case and presented it to us.
Now let's move to the core of QuickCheck. The quickcheck
function has the following signature:
fn quick_check[P : Testable](P) -> Unit!Failure
It takes a value of type that implemented Testable
as argument and runs the test. This is an effectful function that may throw an failure to the MoonBit test driver when a test fails (Or give up). If success, it simply returns Unit
with the sentence Ok, passed!
printed to the console.
type Arrow[A, P] (A) -> P
impl[P : Testable, A : Arbitrary + Shrink + Show] Testable for Arrow[A, P]
The Arrow
type (wrapped single-valued function) does implement the Testable
trait, so we can pass the property function directly to quick_check
. Note that the argument type should have implemented the Arbitrary
, Shrink
and Show
traits. The Show
is necessary for the quick_check
function to print the counterexample when a test fails, without which the testing is considered useless. The other two traits play important roles in QuickCheck. Now we give some brief introduction to them.
Arbitrary
is a trait that generates random values of a type. It has a method arbitrary
that takes a size and a random number generator and then returns a random value of the type.
pub trait Arbitrary {
arbitrary(Int, RandomState) -> Self
}
Shrink
is a trait that shrinks a value to a simpler one. It has a method shrink
that takes a value and returns a iter of simpler values (Lazy).
pub trait Shrink {
shrink(Self) -> Iter[Self]
}
Now we given to a more detailed explanation to the underlying structure of Arbitrary
and its relation to the generators.
Test data is produced by test data generators. QuickCheck defines default generators for some often used types, but you can use your own, and will need to define your own generators for any new types you introduce (Or for simple types we can use the trivial definition by derive(Arbitrary)
).
Generators have types of the form Gen[T]
, which is a generator for values of type T
. It was defined as a struct, it contains single field named gen
, with type (Int, RandomState) -> T
(The first parameter is the size of the generated value, and the second is the random number generator), notice that this is similar to the arbitrary
method in the Arbitrary
trait:
struct Gen[T] {
gen : (Int, RandomState) -> T
}
QuickCheck defines a series of useful methods for Gen[T]
, for the most basic ones, we can use Gen::new(f: (Int, RandomState) -> T)
to create a generator from a function and run it by invoking the run
method:
let g : Gen[Int] = Gen::new(..) // Suppose we have a generator for Int
let x : Int = g.run(100, RandomState::new()) // Generate a random Int at size 100
Gen[T]
was implemented as functor, applicative and monad which means you can compose it in many ways.
fn pure[T](val : T) -> Gen[T]
fn fmap[T, U](self : Gen[T], f : (T) -> U) -> Gen[U]
fn ap[T, U](self : Gen[(T) -> U], v : Gen[T]) -> Gen[U]
fn bind[T, U](self : Gen[T], f : (T) -> Gen[U]) -> Gen[U]
For instance, you can use the fmap
method to transform the generated value:
let g : Gen[Int] = Gen::new(..)
let g2 : Gen[Int] = g.fmap(fn(x) { x + 1 })
let g3 : Gen[String] = g.fmap(fn(x) { x.to_string() })
Or create a dependent generator:
let g : Gen[Int] = Gen::new(..)
let g2 : Gen[Int] = g.bind(fn(x : Int) {
if x == 0 {
Gen::pure(100)
} else {
Gen::pure(200)
}
})
The following documents explains some useful combinators for Gen[T]
.
A generator may take the form one_of
which chooses among the generators in the array with equal probability. For example, this generates a random boolean which is true with probability one half:
let gen_bool : Gen[Bool] = one_of([pure(true), pure(false)])
If you want to control the distribution of results using frequency instead. We have frequency
which chooses a generator from the array randomly, but weighs the probability of choosing each alternative by the factor given. For example, this generates true in the probability of
let gen_freq : Gen[Bool] = frequency([(4, pure(true)), (1, pure(false))])
We have pointed that test data generators have an size parameter. QuickCheck begins by generating small test cases, and gradually increases the size as testing progresses. Different test data generators interpret the size parameter in different ways: some ignore it, some interprets it as an upper bound on the size of containers. Most generators defined in Arbitrary
trait depends on the size parameter but most separated generator combinators does not.
You can obtain the value of the size parameter using sized
combinator.
pub fn sized[T](f : (Int) -> Gen[T]) -> Gen[T]
For example, we can make a trivial generator for a list of integers with a given length:
let gen : Gen[Int] = sized(fn { size => pure(size) })
let arr = Array::makei(20, fn { i => gen.sample(size=i) })
inspect!(arr, content="[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]")
The purpose of size control is to ensure that test cases are large enough to reveal errors, while remaining small enough to test fast. Sometimes the default size control does not achieve this. So we have provided some tool functions like resize
and scale
(check the document for details) for this purpose.
QuickCheck defines default test data generators and shrinkers for some often used types (By trait Arbitrary
and Shrink
). You do not need to define or apply these explicitly for every property because QuickCheck can provide a property with appropriate generators and shrinkers for the property's arguments. But if you are required to do so, you can use the forall
for explicitly universal quantification.
quick_check!(forall(spawn(), fn(x : List[Int]) { x.rev().rev() == x }))
Note that the spawn
function is useful for creating Gen[T]
from its arbitrary instance, in this example the type checker infers the type of the first argument in forall
to be Gen[List[T]]
from the type of the property function.
fn Gen::spawn[T : Arbitrary]() -> Gen[T]
Shrinkers have types of the form (T) -> Iter[T]
. When given a value, a shrinker produces a sequence of values that are (in some way) simpler than the given value. If QuickCheck finds a set of values that fails a given property, it will try to make that value simpler than the original value by getting the shrinks for the value and trying each one in turn to check that the property is still false. If it is, the smaller value becomes the new counterexample and the shrinking process continues with that value.
This section summarizes some common mistakes in using QuickCheck:
- Testing with external effects: If a property requires an external state, for example, the user's input, the global mutable and etc, you should pass the state as an argument to the property function. Otherwise, the property is not a pure function and the test is not repeatable.
- Mutable arguments was unexpectedly modified: You should keep the arguments immutable in the property function. If you need to modify the arguments, you should make a copy of them.
Recall the remove
function we want to test before. The QuickCheck do report an error for us, but the generator is quite random and the tuple element (x, arr): (Int, Array[Int])
is independent. In most cases, the x
is not in the array, so the test is not very meaningful (falls to the branch None => ()
). Now we use the one_of_array
combinator to generate a random element from a generated non-empty array, which makes the test more meaningful.
test {
quick_check!(
forall(
spawn(),
fn(a : Array[Int]) {
forall(one_of_array(a),
fn(y : Int) { remove(a, y).contains(y).not() })
|> filter(a.length() != 0)
},
),
)
}
We admit the following facts:
- The first
spawn
evaluates to a generator ofArray[Int]
. - The
forall
function can be nested. - There is a
filter
function that filters out the test cases that do not satisfy the condition, non-empty array is required in this case. - The
one_of_array
function selects a random element from a non-empty array.
*** [4/33/100] Failed! Falsified.
[0, 0]
0
We find that there are 33 cases that do not satisfy the condition, and the counterexample is [0, 0]
and 0
, which points out the issue clearly. The one_of_array
function selects a random element from the array, so the y
is always 0
in this case. The remove
function only removes the first one, so the property does not hold.
Now let's further verify our hypothesis: The function remove
only removes the first one but not all. So if we instead formulate a conditional property which restricts the input array contains no duplicated elements, then our tests should pass. Use the function filter
can filter out unwanted test cases:
test {
fn no_duplicate(x : Array[Int]) -> Bool {
@sorted_set.from_iter(x.iter()).size() == x.length().to_int64()
}
quick_check!(
forall(
spawn(),
fn(iarr : (Int, Array[Int])) {
let (x, arr) = iarr
filter(remove(arr.copy(), x).contains(x).not(), no_duplicate(arr))
},
),
)
}
- Notice that we use
arr.copy()
to make a copy of the array, because theremove
function may modify the argument array. - The
no_duplicate
function checks whether the input array contains no duplicated elements. - As discussed above, the
filter
combinator filters out the test cases that do not satisfy the condition.
Running this test, we find that all tests passed. Now we have strong evidence that the remove
function only removes the first one but not all.
We may interest in the distribution of the generated data: sometimes the generator may produce trivial data that does not help us to find the bugs. We want to find out what data is generated and how often in order to improve the generator. QuickCheck provides functions like label
, collect
and classify
to achieve this.
test "classes" {
quick_check_fn!(
fn(x : List[Int]) {
Arrow(prop_rev)
|> classify(x.length() > 5, "long list")
|> classify(x.length() <= 5, "short list")
},
)
}
The classify
function takes a boolean and a string, and if the boolean is true, the test case is classified with the string.
+++ [100/0/100] Ok, passed!
22% : short list
78% : long list
The label
function takes a string and classifies the test case with the string.
test "label" {
quick_check_fn!(
fn(x : List[Int]) {
Arrow(prop_rev)
|> label(if x.is_empty() { "trivial" } else { "non-trivial" })
}
)
}
The result is as follows:
+++ [100/0/100] Ok, passed!
8% : trivial
92% : non-trivial
The collect
function is a generalization of label
. The difference is that the collect
takes an argument implementing the Show
trait, and the label
takes a string directly. The collect
function is useful when you want to classify the test case with a complex value.
We have applied MoonBit QuickCheck to test the correctness of the MoonBit core. For now we have found several bugs in the core, including:
- Escaped characters in JSON
- Invalid JSON in inspect function
- BigInt.op_sub edge cases
- Unterminated moon test
- Incorrect BigInt.op_div due to the ill normalization step
- Functional Enumeration
- Random Generation
- Currently use the SplitMix algorithms
- Falsify (with free shrinkers)
- Basic Implementation
- Test driver adaption
- Boolean Property
- Test Invariants
- Operation Invariance
-
Testable
Trait - Existential Quantification
- Linear Shrinking
- Internal Shrinking
- Integrated Shrinking
- OCaml QCheck
- Haskell QuickCheck
- Feat: functional enumeration of algebraic types
- QuickCheck: a lightweight tool for random testing of Haskell programs
- SmallCheck and Lazy SmallCheck automatic exhaustive testing for small values
- Automatic Testing of Operation Invariance
- Fast Splittable Pseudorandom Number Generators
- falsify: Internal Shrinking Reimagined for Haskell
- Selective applicative functors