Assign all values starting at 1 and use `Nullable{T}` to represent no value, unless you can't
I appreciate Microsoft's framework guidelines, but I disagree with them on enum practices. I think there is a lot of subtlety in the various use cases of enums that aren't really addressed there, or in other answers here.
However, flag enums really do need a None = 0
value to work. The rest of this answer does not apply to flag enums.
Also, before going on, it might be good to state the golden rule of C# enums:
Enums are a semi-type-safe minefield
For this answer, I will use this hypothetical enum:
enum UserType {
Basic,
Admin
}
There are different ways we might use this enum type.
Case 1: Part of a data structure queried from the DB
class UserQueryResult {
// Name of the saved user
public string Name { get; set; }
// Type of the saved user
public UserType Type { get; set; }
// Lucky number of the user, if they have one
public int? LuckyNumber { get; set; }
}
Case 2: Part of a search query
class UserSearchQuery {
// If set, only return users with this name
public string Name { get; set; }
// If set, only return users with this type
public UserType Type { get; set; }
// If set, only return users with this lucky number
public int? LuckyNumber { get; set; }
}
Case 3: Part of a POST request
class CreateUserRequest {
// Name of user to save
public string Name { get; set; }
// Type of user to save
public UserType Type { get; set; }
// Lucky number of user, if they have one
public int? LuckyNumber { get; set; }
}
These three classes all look the same, but the data comes from different places and is validated and processed differently.
Case 1: Part of a data structure queried from the DB
We can make some assumptions about the validity of this data, because it should have been validated before saving.
Name
should be a valid non-empty string.
Type
should be either Basic
or Admin
, never null
or some other invalid value. (For now, ignore how this property is persisted, whether as INT
/VARCHAR
/etc.)
- Nulls are never valid for
Name
or Type
. If using newer C# language features, the Name
property might be declared as non-nullable (string! Name
), although this might not be directly supported by all ORMs, and so you may need to validate against nulls after querying data.
Case 2: Part of a search query
This is a client request, so there may be invalid input. Additionally, these properties should be optional, so clients can search using only the filters they care about.
You might want to model this type using Nullable<T>
for value types and explicit nullable reference types.
public class UserSearchQuery {
// Only return users with this name
public string? Name { get; set; }
// Only return users with this type
public UserType? Type { get; set; }
// If set, only return users with this lucky number
public int? LuckyNumber { get; set; }
}
Things you may want to validate:
Name
is either null
or a non-empty string. Alternately, you may just treat empty or whitespace as null
. (You probably don't want to validate the value is a real user name. If its not valid, the search will return 0 results.)
Type
is a valid enum value, or some representation of "no filter". For example, if a client sends Type = "Superuser"
this may indicate a client bug and a 400 response would be helpful.
Case 3: Part of a POST request
This is also client input, but these properties should not allow null
/blank values, and there will be different validation rules.
Things you may want to validate:
Name
is a non-null
, non-empty string
Name
is at least X characters long
Name
does not contain punctuation or whitespace
Type
is a valid value
Like case 1, you may want to use string! Name
to more accurately represent your data. However, if this is being parsed from HTTP requests, you may need to explicitly validate against nulls still, depending on the framework you are using.
So, what is the best way to represent "no type"?
The framework guidelines say that we should add an element to our enum to represent this:
enum UserType {
None,
Basic,
Admin
}
So how does this affect our 3 use cases? It affects all of them, because they are all using UserType
.
Case 1: Part of a data structure queried from the DB
Instances of UserQueryResult
can now be created with Type = UserType.None
.
Of course, this isn't the first invalid state our typing allows. UserQueryResult
already allowed Name = ""
, but we are adding a possible invalid state.
In places where we access UserQueryResult.Type
, we should already have a defensive way to handle invalid UserType
values, since the type system allows things like (UserType)999
.
Case 2: Part of a search query
If we stick with using Nullable<T>
for value types on our optional properties, we now have two ways to represent "do not filter on UserType
".
Type = UserType.None
Type = null
This means anywhere we use this type we need some &&
or ||
logic to deal with both cases.
If we get rid of Nullable<T>
on enum types but leave it on other value types, then we reduce the number of options, but have a more complicated API contract with multiple conventions for us and clients to remember.
Case 3: Part of a POST request
The types now allow Type = UserType.None
on this request. We'll need to add a special validation rule to check against this.
What we can see from the effects of this change on these 3 cases is that we have coupled the list of valid values to the representation of "no value". "No value" is only valid for Case 2, but we have forced the code for Case 1 and Case 3 to handle extra "no value" complexity.
Additionally, we can see in Case 2 that we already have a generic way to represent "no value" for value types, which is Nullable<T>
. In many ways this resembles the null
handling for reference types, bringing us close to a single unified way to represent "no value" across all types, reducing developer mental load.
Conclusion 1
Use Nullable<T>
for "no value", for consistency, and so that you have a distinct type to represent "a value that is never 'no value'".
So that is why you shouldn't add a None
value. But why should you explicitly assign enum int
values?
Reason 1: Unassigned properties have the value default(T)
For reference types, default(T) == null
.
For value types, default(T) == (T)0
.
Let's say a client wants to POST a request to create a new user. A good JSON payload would look like this:
{
"Name": "James",
"Type": "Admin",
"LuckyNumber": 12
}
(For readability, our JSON parser is configured to accept strings for enums. Whether using strings or ints for enums in JSON is not really relevant here.)
As expected, this payload will be parsed to a C# object like this:
{
Name = "James",
Type = UserType.Admin,
LuckyNumber = 12
}
What happens if our client sends incomplete JSON?
{
"Name": "James",
// Client forgot to add Type property
"LuckyNumber": 12
}
This will be parsed as
{
Name = "James",
Type = default(UserType),
LuckyNumber = 12
}
Again, default(UserType) == (UserType)0
.
Our enum could be declared in one of three ways:
- Start with
None
(None = 0
, or just None
implicitly assigned to 0
)
- Start with
Admin
implicitly assigned to 0
- Start with
Admin = 1
In case 1, Type
gets parsed as None
. Since None
is part of our enum, we already need to validate against this case to prevent saving None
to the DB. However, I already covered the reasons why you shouldn't have a None
value.
In case 2, Type
gets parsed as Admin
. After that happens, there isn't a way to differentiate between an Admin
value that came from "Type": "Admin"
in the payload, vs Type
missing in the payload. This is obviously not good.
In case 3, Type
gets parsed as (UserType)0
, which doesn't have a name. This looks odd at first, but is actually the best possible scenario. Because enums allow invalid values (like (UserType)999
), we should be validating against invalid values from clients anyway. This just makes "unassigned" an invalid value instead of a valid one.
To me, case 3 also seems well aligned with the recent additions to C# that make it harder to represent invalid values: non-nullable reference types and required properties. Conversely, case 1 feels like a legacy pattern from C# 1, before generics and Nullable<T>
.
Reason 2: Avoid accidental contract changes
If your enum's integer values are part of the external-facing contract of your service, changing the integers can break clients.
There are two main places enums are external-facing:
- Saving/loading from a database
- HTTP requests/responses
Here is the easiest way to accidentally create a breaking change with enums. Start with this enum:
enum UserType {
Admin, // = 0
Superuser, // = 1
Basic // = 2
}
Clients are using hardcoded values 0
, 1
, and 2
for user types. Then the business wants to deprecate the Superuser
type. A dev removes that enum element.
enum UserType {
Admin, // = 0
Basic // = 1
}
How many behaviors are now broken?
- A client might POST
2
for a Basic user, but it will get a validation error for an invalid Type value
- A client might POST
1
for a Superuser, but it will save a Basic user
- A client might GET
1
for a Basic user and think it has a Superuser
- A client will never GET
2
and will never show Basic user functionality
What if we had assigned explicit values to the enum fields at the beginning, and then removed Superuser
?
enum UserType {
Admin = 1
// No more Superuser = 2
Basic = 3
}
No accidental breakage:
- POSTing and GETing
3
for Basic users still works
- POSTing
2
for a Superuser will get a validation error for an invalid value
- A client will never GET
2
and will never show Superuser functionality
The HTTP case can also be mitigated by serializing enums as strings instead of numbers. However, that isn't ideal if you really need to minimize payload sizes. String enum serialization is less common on the DB side, I think because the same team often owns the DB and the service using it, whereas API clients can be more distributed and communication can be more challenging.
Conclusion 2:
Always explicitly assign values to each enum field, to prevent accidental breaking changes. But never assign `0` (except for flag enums), so that you can differentiate between unassigned properties and valid values.