What is private generic functions
Private generic functions are a type of generic function specially designed for Rooch. Compared with general generic functions, they have stricter constraints.
Simply put, a private generic function is a generic function annotated with the #[private_generics(T1 [, T2, ... Tn])]
attribute.
Effect
Private generic functions can determine whether the generic type is defined in the module where the caller is located. If not, it cannot be used. For general generic functions, types defined by other modules can still be used normally after being imported into the current module through the use
statement.
This means that private generic functions are only available for custom types and cannot be used for types defined by other modules and built-in types.
Example
Private generic function does not accept built-in types
Let's first look at an example without using private generic functions.
module rooch_examples::module1 {
struct Box<T> has drop {
v: T
}
public fun new_box<T, U>(value: T): Box<T> {
Box { v: value }
}
public fun get_box_value<T>(box: &Box<T>): &T {
&box.v
}
#[test]
fun test1() {
let box = new_box<u32, u64>(123);
assert!(get_box_value(&box) == &123, 1000);
}
}
First define a Box<T>
type, which is a generic structure that contains a field v
of type T
.
Then define two generic functions new_box
and get_box_value
. The function new_box
is used to create a value of type Box<T>
, and the function get_box_value
is used to obtain the field value v:<T>
in type Box<T>
.
Note: The function
new_box
adds an additional typeU
. In fact, the function does not use it, but for the subsequent demonstration of the private generic constraint feature, theU
type constraint is specially added.
We simply write a unit test to verify our code logic. We pass new_box
an integer literal 123
and create a box value of type Box<u32>
that wraps a u32
type. In the assertion expression, the integer literal reference &123
is implicitly inferred as &123u32
, and get_box_value
obtains &123u32
from the box
. The two are equal and can pass the test successfully.
Run unit tests:
$ rooch move test
INCLUDING DEPENDENCY MoveStdlib
INCLUDING DEPENDENCY MoveosStdlib
INCLUDING DEPENDENCY RoochFramework
BUILDING private_generics
Running Move unit tests
2024-06-26T15:35:02.835842Z INFO moveos_common::utils: set max open fds 8192
[ PASS ] 0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module1::test1
Test result: OK. Total tests: 1; passed: 1; failed: 0
Next, we perform private generic constraints on the generic function new_box
, add the #[private_generics(T)]
attribute annotation in the previous line of the function, and leave other places unchanged:
#[private_generics(T)]
public fun new_box<T, U>(value: T): Box<T> {
Box { v: value }
}
With the addition of a private generic constraint, type T
must be defined within the current module when the function is called. Obviously the built-in type u32
is not defined in the current module, so if you run the code at this time, an error will be reported, as follows:
$ rooch move test
error: resource type "U32" in function "0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module1::new_box" not defined in current module or not allowed
┌─ ./sources/module1.move:17:19
│
17 │ let box = new_box<u32, u64>(123);
│ ^^^^^^^^^^^^^^^^^^^^^^
Error: extended checks failed
Private generics do not constrain type U
, so it does not check whether the type U
is declared in the current module.
Private generic functions use custom types defined by the current module
Based on the above code, we slightly modify it:
module rooch_examples::module1 {
struct Data has drop {
v: u64
}
struct Box<T> has drop {
v: T
}
#[private_generics(T)]
public fun new_box<T, U>(value: T): Box<T> {
Box { v: value }
}
public fun get_box_value<T>(box: &Box<T>): &T {
&box.v
}
#[test]
fun test1() {
let data = Data { v: 123 };
let box = new_box<Data, u64>(data);
assert!(get_box_value(&box).v == 123, 1000);
}
}
First, add a new custom type Data
, which is a common structure that contains a u64
type field v
.
Then modify the unit test function test1
, construct a Data
type data data
, and modify the generic type parameter u32
of the private generic function new_box
to Data
. In the assertion, use the member operator .
Get the u64
integer value within data
for comparison.
At this point, run the test again and the test example can pass the test successfully:
$ rooch move test
INCLUDING DEPENDENCY MoveStdlib
INCLUDING DEPENDENCY MoveosStdlib
INCLUDING DEPENDENCY RoochFramework
BUILDING private_generics
Running Move unit tests
2024-06-26T15:38:13.522724Z INFO moveos_common::utils: set max open fds 8192
[ PASS ] 0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module1::test1
Test result: OK. Total tests: 1; passed: 1; failed: 0
The private generic function is called in module1
, and the custom type Data
is also defined in the current module, so Data
can pass the function's private generic constraints.
Next we will demonstrate defining a custom type in another module, importing this custom type into the current module through the use
statement, and passing it to the private generic function. Guess if it can be used normally?
Private generic functions do not accept custom types defined by other modules
We define a new module called module2
:
module rooch_examples::module2 {
struct Data2 has copy, drop {
v: u64
}
public fun new_data(value: u64): Data2 {
Data2 {
v: value
}
}
}
In this module, we define a new type Data2
and a function new_data
that creates this type. Because in Move, all structures can only be constructed in the module in which they are declared, and fields can only be accessed within the module of the structure, so in order to be constructed by an external module, there must be a corresponding function.
Next, we continue to modify module1
:
module rooch_examples::module1 {
#[test_only]
use rooch_examples::module2::{new_data, Data2};
struct Data has drop {
v: u64
}
struct Box<T> has drop {
v: T
}
#[private_generics(T)]
public fun new_box<T, U>(value: T): Box<T> {
Box { v: value }
}
public fun get_box_value<T>(box: &Box<T>): &T {
&box.v
}
#[test]
fun test1() {
let data = Data { v: 123 };
let box = new_box<Data, u64>(data);
assert!(get_box_value(&box).v == 123, 1000);
}
#[test]
fun test2() {
let data2 = new_data(456);
let box2 = new_box<Data2, Data2>(data2);
assert!(get_box_value(&box2) == &new_data(456), 2000)
}
}
We import the types and functions defined by module2
and then create the unit test test2
.
In the test, we call the new_data
function to create a value data2
of module2::Data2
type, and modify the type parameter of the private generic function to Data2
.
Note that the type parameter Data2
passed when calling the private generic function at this time is defined in the external module and obviously cannot pass the private generic constraint!
At this point, run the unit test:
$ rooch move test
error: resource type "Data2" in function "0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module1::new_box" not defined in current module or not allowed
┌─ ./sources/module1.move:32:20
│
32 │ let box2 = new_box<Data2, Data2>(data2);
│ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Error: extended checks failed
Modules can call private generic functions defined by other modules
Next, we do a small test to check whether other modules can call the private generic function.
Let’s create a new module module3
:
module rooch_examples::module3 {
#[test_only]
use rooch_examples::module1::{new_box, get_box_value};
struct Data3 has copy, drop {
v: u64
}
#[test]
fun test3() {
let data3 = Data3 { v: 789 };
let box3 = new_box<Data3, u8>(data3);
assert!(get_box_value(&box3) == &Data3 { v: 789 }, 3000);
}
}
It can be seen that at this time module3
imports the private generic function new_box
defined by module1
and the generic function get_box_value
that obtains the Box<T>
type.
At this time, we comment out the unit test test2
in module1
and rerun the unit test:
$ rooch move test
INCLUDING DEPENDENCY MoveStdlib
INCLUDING DEPENDENCY MoveosStdlib
INCLUDING DEPENDENCY RoochFramework
BUILDING private_generics
Running Move unit tests
2024-06-26T15:59:25.520858Z INFO moveos_common::utils: set max open fds 8192
[ PASS ] 0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module3::test3
[ PASS ] 0xfc3c1fa4f1538deee1048fa066a1b0029f2cf428e21667e5a7d4d570626c112e::module1::test1
Test result: OK. Total tests: 2; passed: 2; failed: 0
Application
Such a function is defined in the MoveOS standard library:
#[private_generics(T)]
/// Borrow a mut resource from the account's storage
/// This function equates to `borrow_global_mut<T>(address)` instruction in Move
public fun borrow_mut_resource<T: key>(account: address): &mut T {
let account_obj = borrow_mut_account_internal(account);
account_borrow_mut_resource_interal<T>(account_obj)
}
The function borrow_mut_resource
is a private generic function, and the type T
constrained by the private generic is a resource type.
For a private generic function like this, the module that calls it must define the type of private generic constraint. Let's take a look at an example used in Rooch Framework:
public fun install_auth_validator<ValidatorType: store>(account_signer: &signer) {
features::ensure_testnet_enabled();
let validator = auth_validator_registry::borrow_validator_by_type<ValidatorType>();
let validator_id = auth_validator::validator_id(validator);
let account_addr = signer::address_of(account_signer);
assert!(
!is_auth_validator_installed(account_addr, validator_id),
ErrorAuthValidatorAlreadyInstalled);
if (!account::exists_resource<InstalledAuthValidator>(account_addr)) {
let installed_auth_validator = InstalledAuthValidator {
validators: vector::empty(),
};
account::move_resource_to<InstalledAuthValidator>(account_signer, installed_auth_validator);
};
let installed_auth_validator = account::borrow_mut_resource<InstalledAuthValidator>(account_addr);
vector::push_back(&mut installed_auth_validator.validators, validator_id);
}
The install_auth_validator
function in account_authentication.move
uses the account::borrow_mut_resource
private generic function, which means InstalledAuthValidator
must also be defined in the current module.
We can find the definition of the InstalledAuthValidator
type at the beginning of the current module:
/// A resource that holds the auth validator ids for this account has installed.
struct InstalledAuthValidator has key {
validators: vector<u64>,
}
Summary
We have used four small examples to demonstrate how to define and use private generic functions, and show you how to use private generic functions in Rooch Framework. After reading this, I believe you have fully mastered it. Understand the concept, function and usage of private generic functions in Rooch.