@nprindle/leibniz
v0.1.0
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A small TypeScript framework for unit testing types using Leibniz equality
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leibniz
A small TypeScript framework for unit testing types using Leibniz equality.
Motivation
Types are a very useful tool to ensure safety, especially for library designers.
However, if you're designing a library that works with complicated types, it's
possible that you can accidentally change your types in a way that makes your
types too broad, too narrow, or changes type inference. leibniz
gives you a
framework to write tests to make sure that the code you expect to compile still
compiles, and the code that shouldn't compile still doesn't.
Usage
Leibniz equality
Eq
The most important type in leibniz
is Eq<A, B>
. A value of type Eq<A, B>
is a proof witnessing that two types A
and B
are equal; if you have a value
of type Eq<A, B>
, then you know that A
and B
are the same type. Whenever
the compiler can figure out that two types are equal, you can simply use refl
(for "reflexive") to make an instance of Eq
for those two types:
type A = number;
type B = { foo: number; }["foo"];
const proof: Eq<A, B> = refl;
Like other kinds of equality, Leibniz equality is reflexive, transitive, and symmetric:
refl
proves reflexivity by making anEq<A, A>
for any typeA
sym
can be used to turn anEq<A, B>
into anEq<B, A>
, though the compiler should normally figure this out for youtrans
can compose anEq<A, B>
and anEq<B, C>
into anEq<A, C>
- The
sub1
andsub2
functions can be used to substitute the first or second type using another equality
Interacting with these proofs is almost never necessary, but if the compiler has
trouble figuring out proofs, you can use the proofs from previous tests to help
it out. Usually, you will only have to write refl
, and the compiler will do
most of the heavy lifting for you.
Other relations
There are many types derived from Eq
representing other type relationship
proofs:
NotEq<A, B>
:A
is not the same type asB
Sub<A, B>
:A
is a subtype ofB
NotSub<A, B>
:A
is not a subtype ofB
StrictSub<A, B>
:A
is a strict subtype ofB
(A
is a subtype, and is not the same type asB
)NotStrictSub<A, B>
:A
is not a strict subtype ofB
Super<A, B>
:A
is a supertype ofB
NotSuper<A, B>
:A
is not a supertype ofB
StrictSuper<A, B>
:A
is a strict supertype ofB
NotStrictSuper<A, B>
:A
is not a strict supertype ofB
Related<A, B>
:A
is related toB
(one is assignable to the other)Disjoint<A, B>
:A
andB
are disjoint (neither is assignable to the other)
Most of these are derived types that can be composed from more basic relationships. For example:
type StrictSub<A, B> = Sub<A, B> & NotEq<A, B>;
All of these should still be able to be instantiated with only a single refl
.
Writing tests
leibniz
tests are written using the test
family of functions. If your tests
compile, then all leibniz
tests passed. If your tests do not compile, then one
of your tests has failed.
If you wish, you can plug a no-op success into your preferred testing framework
so it logs that your leibniz
tests passed:
import "mocha";
import { testEq, refl } from "@nprindle/leibniz";
testEq<number, number, "sanity check">(refl);
describe("types", () => {
it("should compile", () => {});
});
Basic tests
This simplest function in leibniz
is test
, which simply makes sure that an
expression or block of code compiles. It is used like so:
test(() => ...);
// optionally, add a description of the test
test<"...">(() => ...);
For example:
// compiles and passes
test<"strings can be appended">(() => {
const x = "foo";
const y = "bar";
return x + y;
});
// fails to compile
test<"strings can be multiplied">(() => {
const x = "foo";
const y = "bar";
return x * y;
});
To group together multiple expressions, you can simply provide an array literal or object literal:
// combining cases in an array
test<"these function calls all compile">(() => [
foo(3),
bar("test"),
baz(foo),
]);
// use an object to name the cases
test<"these function calls compile too">(() => {
check1: foo(7),
check2: bar("quux"),
check3: baz(bar),
});
The test
function is actually very boring; since it only needs to check that
your code compiles, it's just a no-op; the code in the block is never actually
run.
Relation tests
leibniz
provides many functions to test the relationship between types. It
provides a function for every provided relation proof type (see Other
relations). Each function expects a single proof that the
relation holds, though just passing refl
almost always works.
Here's an example of the most basic relationship test function, testEq
:
testEq<
number,
number,
"sanity check that 'number' is equal to 'number'"
>(refl);
Each test function takes two type parameters, the types to compare. They may additionally take an optional third parameter, usually a literal string type that can serve as a description of what the test is checking. If no description is provided, it will default to an empty description.
The provided relation tests are:
testEq
testNotEq
testSub
testNotSub
testStrictSub
testNotStrictSub
testSuper
testNotSuper
testStrictSuper
testRelated
testDisjoint
Custom relation tests
If you need a relation test that is not provided by default, you can test a
custom relation using the testRel
function. Since the relation proof types can
compose using &
and |
, we can create more complicated relationships out of
them.
For example, let's say that we want to test that two types are related (one is a
subtype of the other), but not equal. That is, we need a Related<A, B>
proof,
but also a NotEq<A, B>
proof. We could write this as follows:
testRel<
Related<A, B> & NotEq<A, B>,
"check that A and B are related but not the same"
>(refl);
The testRel
function is powerful; you can use it to define all of the other
provided testing functions. For example:
testRel<
Sub<A, B> | Super<A, B>,
"same as testRelated<A, B>"
>(refl);
testRel<
Sub<A, B> & NotEq<A, B>
"same as testStrictSub<A, B>"
>(refl);
Examples
Basic examples
Let's write some basic sanity checks to show how leibniz
tests work:
testEq<
string,
string,
"a type should be equal to itself"
>(refl);
testSub<
number,
number,
"a type should be a subtype of itself"
>(refl);
// This will fail to compile
testSub<
number,
3,
"number is not a subtype of a literal type"
>(refl);
testEq<
number[],
{ foo: number }["foo"][],
"equality of derived compound types"
>(refl);
One useful application of type testing is to check that your type inference behaves the way you expect it to. For example:
let x = 3;
testEq<typeof x, number>(refl);
// passes (compiles without error)
const y = 3;
testEq<typeof y, number>(refl);
// fails! const actually infers the narrower literal type '3'
const z = 3;
testEq<typeof z, 3>(refl);
// passes
If you're writing an API with complicated inferred types, it's essential to make sure that types are inferred the way you expect them to be.
Testing for properties
As a more practical example, let's say that we have a component C
, which is an
object with certain properties. Let's say that the shape of C
changes
frequently, but the users of our API know that it should always be an object
with a url: string
property. We want to test that no matter what changes we
make to C
, we always have that property. To check that the type has this
property, we can test that intersecting the keys of C
with { url: string; }
gives us back { url: string; }
:
test<"C tests">(() => {
testSub<
C,
object,
"C should always be an object"
>(refl);
testEq<
C | { url: string; }, // '|' intersects the keys of two types
{ url: string; },
"C should always have a 'url: string' property"
>(refl);
});
We can even abstract this into a separate helper test function:
// Takes a proof of the above form and simply returns it
function testHasProps<
T extends object,
P extends object,
_doc = ""
>(proof: Eq<T | P, P>): Eq<T | P, P> {
return proof;
}
testHasProps<
C,
{ url: string; },
"C should always have a 'url: string' property"
>(refl);
Now, if we make a mistake (like change the shape of C
to have a URL: string
instead), our tests will catch it!
Safe JSON encoding
Let's say we define a function jsonEncode
which wraps JSON.stringify
. Since
JSON.stringify
takes an any
, it has unxpected behavior when called on data
that can't be represented in JSON. For example, JSON.stringify([undefined])
is
"[null]"
!
The input type of our jsonEncode
will be safe; it can only stringify data
which can be represented in JSON:
// Implementing this type is left as an exercise for the reader
type JsonValue = ...;
function jsonEncode(data: JsonValue): string {
return JSON.stringify(data);
}
We want to write some tests to make sure that it would compile if given valid JSON inputs, but wouldn't compile if given an invalid JSON input. A JSON value may be a string, a boolean, a number, null, an array of JSON values, or an object with string keys and JSON values (that may also be undefined; the keys will simply be excluded when stringifying).
One approach is to write a basic test
block to make sure that it accepts some
valid inputs:
test<"jsonEncode should accept valid JSON inputs">(() => [
jsonEncode("foo"),
jsonEncode(true),
jsonEncode(3.14),
jsonEncode(null),
jsonEncode([]),
jsonEncode({}),
jsonEncode({ foo: undefined }),
]);
We could also directly verify that the types can be passed, by checking that the
types are valid subtypes of the function's parameter. We can find the type of
the argument to jsonEncode
with Parameters<typeof jsonEncode>[0]
:
test<"jsonEncode should accept valid JSON inputs">(() => {
type JsonEncodeParam = Parameters<typeof jsonEncode>[0];
testSub<string, JsonEncodeParam>(refl);
testSub<boolean, JsonEncodeParam>(refl);
testSub<number, JsonEncodeParam>(refl);
testSub<null, JsonEncodeParam>(refl);
testSub<JsonValue[], JsonEncodeParam>(refl);
testSub<Record<string, JsonValue | undefined>, JsonEncodeParam>(refl);
});
Now, we also want to make sure that jsonEncode
does NOT accept invalid inputs
like undefined
or undefined[]
. To do this, we can check that these types are
not subtypes of the parameter type:
test<"jsonEncode should not accept invalid inputs">(() => {
type JsonEncodeParam = Parameters<typeof jsonEncode>[0];
testNotSub<
undefined,
JsonEncodeParam,
"jsonEncode should not accept undefined"
>(refl);
testNotSub<
undefined[],
JsonEncodeParam,
"jsonEncode should not accept undefined[]"
>(refl);
});
Now, if we later incorrectly change the type of JsonValue
to accept
undefined
, our tests will fail to compile, and we can catch the error before
release! Note that in addition to making sure that certain code will compile,
leibniz
can also be used to make sure that certain code won't compile.