@nprindle/augustus
v3.1.0
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A library to construct combinators for serializing, deserializing, and validating data
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augustus
A work-in-progress library to construct combinators for serializing,
deserializing, and validating data in TypeScript, agnostic of your serialization
target. augustus
uses a combinator-based approach, making it simple to compose
schemas that can marshal between domain and representation types, as well as
safely validate the structure of deserialized data. It also provides utilities
for safe JSON serialization/deserialization.
Motivation
This library is designed to help on two fronts:
Validation
In TypeScript, it's often very difficult to validate the structure of data after
it has been deserialized. For example, JSON.parse
returns an any
, and to use
this data, you have one of two choices:
- Use the
any
directly, or do an unsafe type assertion into your expected type. This will fail (sometimes silently) at runtime if the data does not match the expected structure. - Write a type predicate to assert that your data is of the expected type:
(x: unknown) => x is S
. However, this is a tedious and unsafe process. Since type predicates unsafely turn boolean return values into type assertions, their correctness cannot be checked by the compiler by design; if the structure of your data changes, it will silently break your type predicate.
Instead, using a combinator-based approach allows for more flexible, modular, and reusable data validation, making it simple to build up complex and nested validation structures from simple building blocks. This makes it much easier and safer to change the types or structure of represented data.
Encoding and Serialization
Unlike most serialization libraries, augustus
is largely agnostic to your
serialization target, be it JSON, BSON, etc. It does this by first encoding your
domain types to a representation type. When serializing, it's common to first
marshal your domain model into JSON-representable types before using
JSON.stringify
to serialize, and marshal the representation back to your
domain after using JSON.parse
to deserialize. Building schemas using
combinators removes most of the manual labor of marshalling.
A common alternative approach is to annotate fields that should be serialized
using decorators. While syntactically clean, this approach isn't very composable
or extensible for nontrivial encodings, such as with dependency injection, and
usually only provides one serialization target. augustus
's combinators let you
model complex serialization demands without sacrificing simplicity or
flexibility.
This library uses the following terms:
serialize/deserialize: to convert to and from some serialized representation; e.g., a JSON string.
encode/decode: to convert a domain type to and from a serializable representation; e.g., encoding a class instance into a plain object before serializing it into JSON.
- The encoded representation should be a type that's serializable into your target. For example, if targeting JSON, your representation should be strings, numbers, booleans, nulls, arrays, or objects.
Here's a diagram of this process:
encode serialize
-------> ----------->
domain repr serialization target
<------- <-----------
decode deserialize
For example, to serialize a class instance into JSON:
encode serialize
-------> ----------->
class object JSON string
<------- <-----------
decode deserialize
Usage
Schemas
augustus
uses combinators to build up Schema
s. A Schema
consists of three
things:
interface Schema<Domain, Repr> {
encode(val: Domain): Repr;
decode(data: Repr): Domain;
validate(data: unknown): data is Repr;
}
For example:
import { Schema, Schemas } from "@nprindle/augustus";
// Trivial schema; numbers should be represented as numbers
const schema: Schema<number, number> = Schemas.aNumber;
schema.encode(4); // 4
schema.decode(4); // 4
// A Schema can validate that unknown data is the correct type
const x: unknown = 4;
schema.validate(x); // true
// The validation can be used as a type predicate:
if (schema.validate(x)) {
// Now, 'x' is a number
console.log(x * 2);
}
Primitive schemas
The following schemas for TypeScript's/JavaScript's primitive types are exposed:
string
:aString
number
:aNumber
boolean
:aBoolean
null
:aNull
undefined
:anUndefined
- WARNING: if targeting JSON,
undefined
isn't representable. Be aware that serializing a top-levelundefined
will fail, and serializing an array with an elementundefined
will convert it intonull
. It's safe to use as a value of an object, however; see theoptional
combinator for details.
- WARNING: if targeting JSON,
Basic combinators
Besides primitive schemas, there are many other useful basic schemas and combinators for aggregate schemas:
import { Schemas as S, DomainOf } from "@nprindle/augustus";
type ARecord = {
a: string;
b: number;
c: string | undefined;
d: (boolean | null)[];
e: [Map<string, string>, Set<number>];
f: "foo";
};
// Records
const aRecordSchema = S.recordOf({
// Basic primitive types
a: S.aString,
b: S.aNumber,
// Optional keys
c: S.optional(S.aString),
// Unions and arrays
d: S.arrayOf(S.union(S.aNull, S.aBoolean)),
// Tuples, maps, sets
e: S.tupleOf(S.map(S.aString, S.aString), S.set(S.aNumber)),
// Literal types ('as const' is required for the literal type inference)
f: S.literal("foo" as const),
});
// You can even recover the domain or representation type of a schema!
type AlsoARecord = DomainOf<typeof aRecordSchema>; // same as ARecord
We can also serialize instances of classes:
import { Schemas as S, DomainOf } from "@nprindle/augustus";
class C {
constructor(readonly n: number) {}
}
// Provide a record of fields to serialize and a way to reconstruct a class
// instance from the fields
const schema = S.classOf({ n: S.aNumber }, ({ n }) => new C(n));
It's often nice to define class schemas as static variables on the classes they encode.
There are many more combinators for constructing schemas. Many of the important ones are described in subsections below.
contra
and co
These are used take a base schema and transform its domain type or representation type, respectively.
contra
takes a base schema, as well as ways to transform between the new and
old domain types, and composes them with your base schema to get a new schema
that can convert between your new domain type and your representation type:
encode encode
-------> ------->
new domain old domain repr
<------- <-------
decode decode
| | |
| |----base schema-----|
| |
|------new schema after 'contra'-------|
co
is similar, but chains to the right of the repr
to make a new
representation type. However, this also requires you to provide a new validating
function, so this is much less useful than contra
.
Additionally, if you already have two schemas Schema<A, B>
and Schema<B, C>
and want to compose them into a Schema<A, C>
, you can use compose
. Note that
this is more information than is required to make this composition; the
validation function of the Schema<A, B>
will be discarded. If you don't
already have the two schemas to compose, prefer contra
.
constrain
and asserting
constrain
doesn't change the type of a schema, but it narrows the schema's
validation to only accept values that also match an additional predicate:
import { Schemas as S } from "@nprindle/augustus";
const positive = S.constrain(S.aNumber, x => x > 0);
positive.validate(15); // true
positive.validate(-1); // false
The matching
combinator is just constrain
, but the predicate is to match a
regex:
import { Schemas as S } from "@nprindle/augustus";
const alnumStr = S.matching(/[a-zA-Z0-9]*/);
alnumStr.validate("abc123"); // true
alnumStr.validate("!@#$%^"); // false
asserting
is similar to constrain
, but instead of taking a regular
predicate, it takes a type predicate. This lets you narrow the representation
type of a schema:
import { Schemas as S } from "@nprindle/augustus";
const obj = { foo: 1, bar: 2 };
const objKeySchema = S.asserting(
S.aString,
(x: string): x is keyof typeof obj => x in obj,
);
indexing
and mapping
indexing
encodes elements of an array using their index. This is a somewhat
dangerous combinator; changes to the order of elements will break your
validation. Also, attempting to encode something that's not a value in the array
will simply fail at runtime.
import { Schemas as S } from "@nprindle/augustus";
const arr = [ "foo", "bar", "baz" ];
const schema = S.indexing(arr);
schema.encode("foo"); // 0
schema.decode(2); // "baz"
mapping
encodes elements of an object using their key. This is useful for
serializing multiton patterns, which often depend on instance equality. However,
this is also somewhat dangerous; the same caveats apply as in indexing
import { Schemas as S } from "@nprindle/augustus";
const obj = { foo: 1, bar: 2, baz: 3 };
const schema = S.mapping(arr);
schema.encode(1); // "foo"
schema.decode("bar"); // 2
injecting
injecting
is a little more complicated than other combinators. injecting
handles situations where reconstructing the domain type requires additional
context, such as in dependency injection. To do this, we can take a base domain
type that doesn't have the context, and augment it with injecting
to get a
special InjectSchema
type. An InjectSchema
is able to project from the true
domain type into the base domain type, and inject a base domain type with
context to reconstruct the true domain type. Here's an example:
import { Schemas as S } from "@nprindle/augustus";
class Sub {
// The 'context' is dependency injected, and should not be serialized
constructor(readonly context: Super, readonly n: number) {}
}
// Our 'true' domain type is 'Sub', but if we're decoding from a { n: number },
// then we still need a 'Super' to reconstruct a 'Sub' instance
const incorrectSubSchema = S.classOf(
{ n: S.aNumber },
({ n }) => new Sub(???, n) // we need a 'Super' here!
);
// Our 'base' domain type is { n: number }, the fields we want to serialize
// without the 'Super' context
const baseSchema = S.recordOf({ n: S.aNumber });
// We use 'injecting' to get a special 'InjectSchema':
const subSchema: InjectSchema<
Sub, // the true domain type
Super, // the type of the required context
{ n: number; }, // the base domain type
{ n: number; } // the representation type
> = S.injecting(
baseSchema,
// 'project' from the true domain type to the base domain type
(sub: Sub): { n: number; } => ({ n: sub.n }),
// 'inject' the base domain type with context to get the true domain type
(context: Super) => (base: { n: number; }) => new Sub(context, base.n),
);
Without all the explanatory comments:
import { Schemas as S } from "@nprindle/augustus";
class Sub {
constructor(readonly context: Super, readonly n: number) {}
static schema = S.injecting(
S.aRecordOf({ n: S.aNumber }),
sub => ({ n: sub.n }),
context => base => new Sub(context, base.n)
);
}
Later, if we're serializing something that contains a Sub
, we can extend our
normal base schema using contra
to manage the injection and projection for us:
class Foo {
// Assume that we want to serialize both of these fields, and that we've
// already written Super.schema and Sub.schema
private constructor(readonly sup: Super, readonly sub: Sub) {}
static newFoo(): Foo {
const sup = new Super();
// 'sup' is injected during creation
const sub = new Sub(sup, 5);
return new Foo(sup, sub)
}
static schema = S.contra(
S.recordOf({ sup: Super.schema, sub: Sub.schema }),
(f: Foo) => {
const sup = f.sup;
// Project the context out of the sub
const sub = Sub.schema.project(f.sub);
return { sub, sup };
},
({ subBase, sup }) => {
// Recover a 'Sub' by injecting the 'sup' context
const sub = Sub.schema.inject(sup)(subBase);
return new Foo(sup, sub);
}
);
}
lazy
and lazy aggregates
Sometimes, you may need to serialize recursive (or even mutually recursive!) types:
interface ListNode {
data: number;
next: ListNode | null;
}
But if you try to write a schema, you'll find that you need the ListNode
schema in order to serialize one of the fields of a ListNode
; that is, you
need the schema to define the schema. In this case, you might try to write
something like this:
import { Schemas as S } from "@nprindle/augustus";
const listNodeSchema = S.recordOf({
data: S.aNumber,
next: S.union(S.aNull, listNodeSchema),
});
But this doesn't work, since you're using the variable before it's been defined.
One solution to this is to use lazy
, which accepts a no-args function () =>
Schema<T, S>
and turns it into a schema, pushing the function call inwards.
This way, we can defer evaluation of the constant with minimal overhead:
import { Schemas as S } from "@nprindle/augustus";
const listNodeSchema = S.recordOf({
data: S.aNumber,
next: S.union(S.aNull, S.lazy(() => listNodeSchema)),
});
In general, it is usually good practice to narrow the scope of lazy
as much as
possible. For example, here we put it only around listNodeSchema
, rather than
S.lazy(() => S.union(S.aNull, listNodeSchema))
or around the entire schema.
However, for schemas that encode aggregates, such as arrayOf
, we don't want to
re-evaluate the no-args function for every element of the array during
evaluation; we really only need to evaluate it once. For situations like these,
there is a separate LazySchemas
namespace containing alternate lazy versions
of the aggregate combinators:
import { Schemas as S, LazySchemas as LS } from "@nprindle/augustus";
interface TreeNode {
data: number;
children: TreeNode[];
}
const treeNodeSchema = S.recordOf({
data: S.aNumber,
// more efficient than S.arrayOf(S.lazy(() => treeNodeSchema))
children: LS.arrayOf(() => treeNodeSchema),
});
Serialization
If you have a schema, you can encode your domain types and serialize them to
a JSON string using jsonEncodeWith
:
import { Schemas as S, jsonEncodeWith } from "@nprindle/augustus";
const schema = S.arrayOf(S.aNumber);
jsonEncodeWith([1, 2, 3], schema); // "[1,2,3]"
Similarly, if you have a JSON string, and you want to attempt to deserialize and
decode it, you can use jsonDecodeWith
. This returns a DecodeResult
, which is
one of the following:
- A success, meaning that
JSON.parse
andaugustus
's validation succeeded - A syntax error, meaning that
JSON.parse
failed- Runtime exceptions thrown by
JSON.parse
are caught and returned as part of the return value instead
- Runtime exceptions thrown by
- An invalid structure error, meaning that the value deserialized but didn't match the expected structure
import { Schemas as S, jsonDecodeWith } from "@nprindle/augustus";
const schema = S.arrayOf(S.aNumber);
jsonDecodeWith("[1,2,3]", schema);
// { resultType: "success", result: [1, 2, 3] }
jsonDecodeWith("[1,2,3", schema);
// { resultType: "syntaxError", error: ... }
jsonDecodeWith("true", schema);
// { resultType: "invalidStructure" }