A have a type-check error in recursive types.

I am trying to write types for react-jss styles object.

type StylesFn<P extends object> = (
  props: P
) => CSS.Properties<JssValue<P>> | number | string;

type JssValue<P extends object> =
  | string
  | number
  | Array<string | number>
  | StylesFn<P>;

// @ts-ignore
interface StylesObject<K extends string = any, P extends object = {}>
  extends Styles {
  [x: string]: CSS.Properties<JssValue<P>> | Styles<K, P>;
export type Styles<K extends string = any, P extends object = {}> = {
  [x in K]: CSS.Properties<JssValue<P>> | StylesObject<any, P> | StylesFn<P>

It works fine, but typescript writes an error. I use @ts-ignore, but this is not fancy

ERROR 24:11  typecheck  Interface 'StylesObject<K, P>' incorrectly extends interface 'Styles<any, {}>'.
  Index signatures are incompatible.
    Type 'Properties<JssValue<P>> | Styles<K, P>' is not assignable to type 'StylesFn<{}> | Properties<JssValue<{}>> | StylesObject<any, {}>'.
      Type 'Properties<JssValue<P>>' is not assignable to type 'StylesFn<{}> | Properties<JssValue<{}>> | StylesObject<any, {}>'.
        Type 'Properties<JssValue<P>>' is not assignable to type 'Properties<JssValue<{}>>'.
          Type 'JssValue<P>' is not assignable to type 'JssValue<{}>'.
            Type 'StylesFn<P>' is not assignable to type 'JssValue<{}>'.
              Type 'StylesFn<P>' is not assignable to type 'StylesFn<{}>'.
                Type '{}' is not assignable to type 'P'.
                  '{}' is assignable to the constraint of type 'P', but 'P' could be instantiated with a different subtype of constraint 'object'.

What does this error mean?

  • It's the same error message as in this question which might be partially answered by comments.
    – ChrisW
    Jun 20 '19 at 21:10

Complementing @fetzz great answer.


TLDR; There are two common causes for this kind of error message. You are doing the first one (see below). Along with the text, I explain in rich detail what this error message wants to convey.

CAUSE 1: In typescript, a concrete instance is not allowed to be assigned to a type parameter. Following you can see an example of the 'problem' and the 'problem solved', so you can compare the difference and see what changes:


const func1 = <A extends string>(a: A = 'foo') => `hello!` // Error!

const func2 = <A extends string>(a: A) => {
    a = `foo`  // Error!


const func1 = <A extends string>(a: A) => `hello!` // ok

const func2 = <A extends string>(a: A) => { //ok

See in: TS Playground

CAUSE 2: Although you are not doing the below error in your code. It is also a normal circumstance where this kind of error message pops up. You should avoid doing this:

Repeat (by mistaken) the Type Parameter in a class, type, or interface.

Don't let the complexity of the below code confuse you, the only thing I want you to concentrate on is how the removing of the letter 'A' solves the problem:


type Foo<A> = {
    //look the above 'A' is conflicting with the below 'A'
    map: <A,B>(f: (_: A) => B) => Foo<B>

const makeFoo = <A>(a: A): Foo<A> => ({
   map: f => makeFoo(f(a)) //error!


type Foo<A> = {
    // conflict removed
    map: <B>(f: (_: A) => B) => Foo<B>

const makeFoo = <A>(a: A): Foo<A> => ({
   map: f => makeFoo(f(a)) //ok

See in: TS Playground



Following I'll decompose each element of the error message below:

Type '{}' is not assignable to type 'P'.
  '{}' is assignable to the constraint of type 'P', but 'P' could be
 instantiated with a different subtype of constraint'object'


It's a type that you can assign anything except null or undefined. For example:

type A = {}
const a0: A = undefined // error
const a1: A = null // error
const a2: A = 2 // ok
const a3: A = 'hello world' //ok
const a4: A = { foo: 'bar' } //ok
// and so on...

See in: TS Playground

WHAT IS is not assignable

To assign is to make a variable of a particular type correspond to a particular instance. If you mismatch the type of the instance you get an error. For example:

// type string is not assignable to type number 
const a: number = 'hello world' //error

// type number is assinable to type number
const b: number = 2 // ok

WHAT IS A different subtype

Two types are equals: if they do not add or remove details in relation to each other.

Two types are different: if they are not equal.

Type A is a subtype of type S: if A adds detail without removing already existent detail from S.

type A and type B are different subtypes of type S: If A and B are subtypes of S, but A and B are different types. Said in other words: A and B adds detail to the type S, but they do not add the same detail.

Example: In the code below, all the following statements are true:

  1. A and D are equal types
  2. B is subtype of A
  3. E is not subtype of A
  4. B and C are different subtype of A
type A = { readonly 0: '0'}
type B = { readonly 0: '0', readonly foo: 'foo'}
type C = { readonly 0: '0', readonly bar: 'bar'}
type D = { readonly 0: '0'}
type E = { readonly 1: '1', readonly bar: 'bar'}
type A = number
type B = 2
type C = 7
type D = number
type E = `hello world`
type A = boolean
type B = true
type C = false
type D = boolean
type E = number

NOTE: Structural Type

When you see in TS the use of type keyword, for instance in type A = { foo: 'Bar' } you should read: Type alias A is pointing to type structure { foo: 'Bar' }.

The general syntax is: type [type_alias_name] = [type_structure].

Typescript type system just checks against [type_structure] and not against the [type_alias_name]. That means that in TS there's no difference in terms of type checking between following: type A = { foo: 'bar } and type B = { foo: 'bar' }. For more see: Official Doc.

WHAT IS constraint of type 'X'

The Type Constraint is simply what you put on the right side of the 'extends' keyword. In the below example, the Type Constraint is 'B'.

const func = <A extends B>(a: A) => `hello!`

Reads: Type Constraint 'B' is the constraint of type 'A'


To illustrate I'll show you three cases. The only thing that will vary in each case is the Type Constraint, nothing else will change.

What I want you to notice is that the restriction that Type Constraint imposes to Type Parameter does not include different subtypes. Let's see it:


type Foo         =  { readonly 0: '0'}
type SubType     =  { readonly 0: '0', readonly a: 'a'}
type DiffSubType =  { readonly 0: '0', readonly b: 'b'}

const foo:             Foo         = { 0: '0'}
const foo_SubType:     SubType     = { 0: '0', a: 'a' }
const foo_DiffSubType: DiffSubType = { 0: '0', b: 'b' }


const func = <A>(a: A) => `hello!`

// call examples
const c0 = func(undefined) // ok
const c1 = func(null) // ok
const c2 = func(() => undefined) // ok
const c3 = func(10) // ok
const c4 = func(`hi`) // ok
const c5 = func({}) //ok
const c6 = func(foo) // ok
const c7 = func(foo_SubType) //ok
const c8 = func(foo_DiffSubType) //ok


Note below that restriction does not affect subtypes.

VERY IMPORTANT: In Typescript the Type Constraint does not restrict different subtypes

const func = <A extends Foo>(a: A) => `hello!`

// call examples
const c0 = func(undefined) // error
const c1 = func(null) // error
const c2 = func(() => undefined) // error
const c3 = func(10) // error
const c4 = func(`hi`) // error
const c5 = func({}) // error
const c6 = func(foo) // ok
const c7 = func(foo_SubType) // ok  <-- Allowed
const c8 = func(foo_DiffSubType) // ok <-- Allowed


const func = <A extends SubType>(a: A) => `hello!`

// call examples
const c0 = func(undefined) // error
const c1 = func(null) // error
const c2 = func(() => undefined) // error
const c3 = func(10) // error
const c4 = func(`hi`) // error
const c5 = func({}) // error
const c6 = func(foo) // error <-- Restricted now
const c7 = func(foo_SubType) // ok  <-- Still allowed
const c8 = func(foo_DiffSubType) // error <-- NO MORE ALLOWED !

See in TS playground


The function below:

const func = <A extends Foo>(a: A = foo_SubType) => `hello!` //error!

Yields this error message:

Type 'SubType' is not assignable to type 'A'.
  'SubType' is assignable to the constraint of type 'A', but 'A'
could be instantiated with a different subtype of constraint 

Because Typescript infers A from the function call, but there's no restriction in the language limiting you to call the function with different subtypes of 'Foo'. For instance, all function's call below are considered valid:

const c0 = func(foo)  // ok! type 'Foo' will be infered and assigned to 'A'
const c1 = func(foo_SubType) // ok! type 'SubType' will be infered
const c2 = func(foo_DiffSubType) // ok! type 'DiffSubType' will be infered

Therefore assigning a concrete type to a generic Type Parameter is incorrect because in TS the Type Parameter can always be instantiated to some arbitrary different subtype.


Never assign a concrete type to a generic type parameter, consider it as read-only! Instead, do this:

const func = <A extends Foo>(a: A) => `hello!` //ok!

See in TS Playground

  • 1
    Is "<A extends Foo>(a: A) => hello!" not equivalent to "(a: Foo) => hello!"? Jan 15 '20 at 21:28
  • 1
    @Max Thank you. you asked: Why? SubFoo and DiffSubType both implement same prop1 and both add one additional prop, shouldn't they be both be just subtypes of Foo? They're just subtypes of Foo, you're not wrong. The question is: Given they ARE subtypes, are they equal or different subtype? Answer: Different because they add different properties/methods in relation to each other. See this example here (maybe you are more familiar with interface keyword). Jan 27 '20 at 15:48
  • 1
    @ford04 thank you. I made the updates to the answer to reflect your comments. Apr 27 '20 at 17:40
  • 1
    @MrWolfZ In expression const f = <T extends X>(a: T) => //..., the term extends express a requirement that T MUST obey any of following two requeriments: or (1) T is equal to X, or; (2) T is equal to any arbitrary sub-type of X. People erroneusly assume that the term extends only express (1) and not express (2). But because (2) is also possible, TS inhibits you to assign a particular instance of type X to type T and expect you to choose a different approuch if you want to remain type-safe. (So in your case it's not a limitation on Pick, it's a limitation on T itself). Aug 11 '20 at 0:59
  • 1
    the way typescript interprets this syntax is just nonsense, when someone writes ` <A extends string>(a: A = 'foo')` he (most likely) means that a should have a default value of "foo" which of type string and this is perfectly fine Sep 13 at 20:08

That error is warning you, that your Generic Type P can't be assigned to {}, since the Generic Type P can be a more defined, or restricted, to a particular type that can conflict with the default value.

That means that the value {} can't satisfy all the possible Types that can be used by the Generic Type P.

Let's create another example with only booleans that should be easier to understand:

interface OnlyBoolIdentityInterface<T> {
  (arg: T): T;

function onlyBoolGeneric<T extends boolean>(arg: T = false): T {
  return arg;

if you define a Type that is more specific than a boolean for example:

type TrueType = true;

and if you specialised the function OnlyBoolIdentityInterface to only support true values like this:

const onlyTrueIdentity: OnlyBoolIdentityInterface<TrueType> = onlyBoolGeneric;

even if TrueType respects the constraint set by T extends boolean the default value arg: T = false is not a TrueType.

This is the situation is what the error is trying to convey to you.

So how can you fix this type of errors?

  1. Or you remove the default value
  2. Or T needs to extend the specialised type of the default param that on my example is false
  3. Or T can interfere directly with params that receive default params

For more context about this error message see the issue that suggested this error message https://github.com/Microsoft/TypeScript/issues/29049.

  • I'v replaced P extends object = {} with P extends object = any in type Styles and this resolves my issue. Thx
    – teux
    Jun 22 '19 at 15:03
  • 1
    I don't understand either of the answers. I think I get the mechanics that makes it impossible, but I don't get why this would be an intended warning. Using fn from your answer, both fn(true) and fn(false) are correct, right? Isn't the = false part in the function definition giving it a default value, so fn() would be equivalent to fn(false)? Why would obj possibly being true affect my intention that the default parameter shall be false?
    – T Tse
    Mar 20 '20 at 15:08
  • 3
    @ShioT when you create a Generic function you allow someone using the function to make a new version of it more specialised. So if a make a newer version that only accepts true values your default value will break that possible specialised version maybe this other example code that I created will help
    – Fetz
    May 6 '20 at 11:33
  • @Fetz This makes sense now.
    – T Tse
    May 7 '20 at 2:54
  • Reading thread for the third time, what I figured so far: To fix this you probably need to simplify code or remove default params. Agree this is probably better intended as an error message.
    – Thom
    Jun 9 '20 at 16:24

A bit shorter explanation.

Example that throws error:

type ObjectWithPropType<T> = {prop: T};

// Mind return type - T
const createCustomObject = <T extends ObjectWithPropType<any>>(prop: any): T => ({ prop });

type CustomObj = ObjectWithProp<string> & { id: string };

const customObj = createCustomObj<CustomObj>('value'); // Invalid
// function will only ever return {prop: T} type.

The problem here is that the return object will only ever match the attribute prop and not any other attribute. Extending the ObjectWithPropType gives a false sense of type constraint. This example is all in all a wrong approach it was used just for illustration to show actual conflict in object attributes.

How to constrain subtype in create function:

type StringPropObject = ObjectWithPropType<string>

const createCustomObject = <T>(prop: T extends ObjectWithPropType<infer U> ? U : T): ObjectWithPropType<T> => ({ prop });

const stringObj = createCustomObject<StringPropObject>('test');

In this case, the function requires the argument to be a string. The object only has prop attribute and function do return required shape.

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