1. Create a Smart Contract
This is the first chapter of the tutorial on building an end-to-end dapp on Aptos. If you haven’t done it, review that introduction, and ensure your environment meets the prerequisites listed there.
Now that you are all set up and at your terminal:
-
cd
into themy-first-dapp
root directory, and create a newmove
directory. -
cd
into the newmove
directory and run:aptos move init --name my_todo_list
That command creates asources/
directory andMove.toml
file inside themove
directory. -
Your new
move
directory should now resemble:
What is a Move.toml
file?
A Move.toml
file is a manifest file that contains metadata such as name, version, and dependencies for the package.
Take a look at the new Move.toml
file. You should see your package information and an AptosFramework
dependency. Note that the name
property is the same --name
attribute we passed to the aptos move init
command before. The AptosFramework
dependency points to the aptos-core/aptos-move/framework/aptos-framework
GitHub repo main branch.
Why sources
directory?
The sources
directory holds a collection of .move
modules files. And later when we want to compile the package using the CLI, the compiler will look for that sources
directory and its Move.toml
file.
Create a Move module
An account is needed to publish a Move module. So first we need to create an account. Once we have the account’s private key, we can create a module under its account address and publish the module using that account.
-
In our
move
directory, runaptos init --network devnet
. Press enter when prompted.This creates for us a
.aptos
directory with aconfig.yaml
file that holds our profile information. In theconfig.yaml
file, we now have our profiles list that holds adefault
profile. If you open that file, you will see content resembling:config.yamlprofiles: default: private_key: "0xee8f387ef0b4bb0018c4b91d1c0f71776a9b85935b4c6ec2823d6c0022fbf5cb" public_key: "0xc6c07218d79a806380ca67761905063ec7a78d41f79619f4562462a0f8b6be11" account: cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018 rest_url: "https://api.devnet.aptoslabs.com" faucet_url: "https://faucet.devnet.aptoslabs.com"
From now on, whenever we run a CLI command in this
move
directory, it will run with that default profile. We use thedevnet
network flag so eventually when we publish our package it will get published to thedevnet
network.You just created a new account on the Aptos (dev) network! Yay! You can see it by going to the Aptos Explorer Devnet network view, pasting the
account
address value from your configuration file into the search field, and clicking on the dropdown option!
As mentioned, our sources
directory holds our .move
module files; so let’s add our first Move file.
- Open the
Move.toml
file. - Add the following code to that Move file, substituting your actual default profile account address from
.aptos/config.yaml
:
[addresses]
todolist_addr='<default-profile-account-address>'
If the default profile account address is cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018
, your Move.toml
file should look like:
[addresses]
todolist_addr='cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018'
- Create a new
todolist.move
file within thesources
directory and add the following to that file:
module todolist_addr::todolist {
}
A Move module is stored under an address (so when it published anyone can access it using that address); the syntax for a Move module is
module <account-address>::<module-name> {
}
In our module, the account-address
is todolist_addr
(a variable we just declared on the Move.toml
file in the previous step that holds an address
), and the module-name
is todolist
(a random name we selected).
Our contract logic
Before jumping into writing code, let’s first understand what we want our smart contract program to do. For ease of understanding, we will keep the logic pretty simple:
- An account creates a new list.
- An account creates a new task on their list.
- Whenever someone creates a new task, emit a
task_created
event.
- Whenever someone creates a new task, emit a
- Let an account mark their task as completed.
Creating an event is not mandatory yet useful if dapps/users want to monitor data, such as how many people create a new task, using the Aptos Indexer.
We can start with defining a TodoList
struct, that holds the:
- tasks array
- new task event
- a task counter that counts the number of created tasks (we can use that to differentiate between the tasks)
And also create a Task
struct that holds:
- the task ID - derived from the TodoList task counter.
- address - the account address who created that task.
- content - the task content.
- completed - a boolean that marks whether that task is completed or not.
On the todolist.move
file, update the content in the module with:
...
struct TodoList has key {
tasks: Table<u64, Task>,
set_task_event: event::EventHandle<Task>,
task_counter: u64
}
struct Task has store, drop, copy {
task_id: u64,
address:address,
content: String,
completed: bool,
}
...
What did we just add?
TodoList
A struct that has the key
and store
abilities:
Key
ability allows struct to be used as a storage identifier. In other words,key
is an ability to be stored at the top-level and act as a storage. We need it here to haveTodoList
be a resource stored in our user account.
When a struct has the key
ability, it turns this struct into a resource
:
Resource
is stored under the account - therefore it exists only when assigned to an account and can be accessed through this account only.
Task
A struct that has the store
, drop
and copy
abilities.
• Store
- Task needs Store
as it’s stored inside another struct (TodoList)
• Copy
- value can be copied (or cloned by value).
• Drop
- value can be dropped by the end of scope.
Let’s try to compile what we have now:
cd
into themove
directory.- Run:
aptos move compile
Seeing errors?! Let’s understand them.
We have some errors on Unbound type
- this is happening because we used some types but never imported them, and the compiler doesn’t know where to get them from.
- On the top of the module, import those types by adding:
...
use aptos_framework::event;
use std::string::String;
use aptos_std::table::Table;
...
That will tell the compiler where it can get those types from.
- Run the
aptos move compile
command again; If all goes well, we should see a response resembling (where the resulting account address is your default profile account address):
INCLUDING DEPENDENCY AptosFramework
INCLUDING DEPENDENCY AptosStdlib
INCLUDING DEPENDENCY MoveStdlib
BUILDING myTodolist
{
"Result": [
"cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018::todolist"
]
}
At this point, we have successfully compiled our Move module. Yay!
We also have a new move/build
directory (created by the compiler) that holds our compiled modules, build information and sources
directory.
Create list function
The first thing an account can and should do with our contract is to create a new list.
Creating a list is essentially submitting a transaction, and so we need to know the signer
who signed and submitted the transaction:
- Add a
create_list
function that accepts asigner
public entry fun create_list(account: &signer){
}
Let’s understand the components of this function
-
entry
- an entry function is a function that can be called via transactions. Simply put, whenever you want to submit a transaction to the chain, you should call an entry function. -
&signer
- The signer argument is injected by the Move VM as the address who signed that transaction.
Our code has a TodoList
resource. Resource is stored under the account; therefore, it exists only when assigned to an account and can be accessed only through this account.
That means to create the TodoList
resource, we need to assign it to an account that only this account can have access to.
The create_list
function can handle that TodoList
resource creation.
- Add the following to the
create_list
function
public entry fun create_list(account: &signer){
let tasks_holder = TodoList {
tasks: table::new(),
set_task_event: account::new_event_handle<Task>(account),
task_counter: 0
};
// move the TodoList resource under the signer account
move_to(account, tasks_holder);
}
This function takes in a signer
, creates a new TodoList
resource, and uses move_to
to have the resource stored in the provided signer account.
Create task function
As mentioned before, our contract has a create task function that lets an account create a new task. Creating a task is also essentially submitting a transaction, and so we need to know the signer
who signed and submitted the transaction. Another element we want to accept in our function is the task content
.
- Add a
create_task
function that accepts asigner
and taskcontent
and the function logic.
public entry fun create_task(account: &signer, content: String) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
// gets the TodoList resource
let todo_list = borrow_global_mut<TodoList>(signer_address);
// increment task counter
let counter = todo_list.task_counter + 1;
// creates a new Task
let new_task = Task {
task_id: counter,
address: signer_address,
content,
completed: false
};
// adds the new task into the tasks table
table::upsert(&mut todo_list.tasks, counter, new_task);
// sets the task counter to be the incremented counter
todo_list.task_counter = counter;
// fires a new task created event
event::emit_event<Task>(
&mut borrow_global_mut<TodoList>(signer_address).set_task_event,
new_task,
);
}
- Since we now use two new modules - signer and table (you can see it being used in
signer::
andtable::
) - we need to import these modules. At the top of the file, add those two use statements:
use std::signer;
use aptos_std::table::{Self, Table}; // This one we already have, need to modify it
Back to the code; what is happening here?
- First, we want to get the signer address, so we can get this account’s
TodoList
resource. - Then, we retrieve the
TodoList
resource with thesigner_address
; with that we have access to theTodoList
properties. - We can now increment the
task_counter
property, and create a newTask
with thesigner_address
,counter
and the providedcontent
. - We push it to the
todo_list.tasks
table that holds all of our tasks along with the newcounter
(which is the table key) and the newly created Task. - Then we assign the global
task_counter
to be the new incremented counter. - Finally, we emit the
task_created
event that holds the new Task data.emit_event
is anaptos-framework
function that accepts a reference to the event handle and a message. In our case, we are passing the function a reference (using the sign &) to the account’sTodoListresource
set_task_event
property as the first argument and a second message argument which is the new Task we just created. Remember, we have aset_task_event
property in ourTodoList
struct.
Complete task function
Another function we want our contract to hold is the option to mark a task as completed.
- Add a
complete_task
function that accepts asigner
and atask_id
:
public entry fun complete_task(account: &signer, task_id: u64) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
// gets the TodoList resource
let todo_list = borrow_global_mut<TodoList>(signer_address);
// gets the task matches the task_id
let task_record = table::borrow_mut(&mut todo_list.tasks, task_id);
// update task as completed
task_record.completed = true;
}
Let’s understand the code.
- As before in our create list function, we retrieve the
TodoList
struct by the signer address, so we can have access to the tasks table that holds all the account tasks. - Then, we look for the task with the provided
task_id
on thetodo_list.tasks
table. - Finally, we update that task completed property to be true.
Now try to compile the code:
- Run:
aptos move compile
- Another
Unbound
error? To fix this, add ause
statement to use theaccount
module.
use aptos_framework::account;
- run
aptos move compile
again.
Add validations
As this code now compiles, we want to have some validations and checks before creating a new task or updating the task as completed, so we can be sure our functions work as expected.
- Add a check to the
create_task
function to make sure the signer account has a list:
public entry fun create_task(account: &signer, content: String) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
// assert signer has created a list
assert!(exists<TodoList>(signer_address), 1);
...
}
- Add a check to the
complete_task
function to make sure the:- signer has created a list.
- task exists.
- task is not completed.
With:
public entry fun complete_task(account: &signer, task_id: u64) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
// assert signer has created a list
assert!(exists<TodoList>(signer_address), 1);
// gets the TodoList resource
let todo_list = borrow_global_mut<TodoList>(signer_address);
// assert task exists
assert!(table::contains(&todo_list.tasks, task_id), 2);
// gets the task matched the task_id
let task_record = table::borrow_mut(&mut todo_list.tasks, task_id);
// assert task is not completed
assert!(task_record.completed == false, 3);
// update task as completed
task_record.completed = true;
}
We just added our first assert
statements!
If you noticed, assert
accepts two arguments: the first is what to check for, and the second is an error code. Instead of passing in an arbitrary number, a convention is to declare errors
on the top of the module file and use these instead.
On the top of the module file (under the use
statements), add those error declarations:
// Errors
const E_NOT_INITIALIZED: u64 = 1;
const ETASK_DOESNT_EXIST: u64 = 2;
const ETASK_IS_COMPLETED: u64 = 3;
Now we can update our asserts with these constants:
public entry fun create_task(account: &signer, content: String) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
// assert signer has created a list
assert!(exists<TodoList>(signer_address), E_NOT_INITIALIZED);
...
}
public entry fun complete_task(account: &signer, task_id: u64) acquires TodoList {
// gets the signer address
let signer_address = signer::address_of(account);
assert!(exists<TodoList>(signer_address), E_NOT_INITIALIZED);
// gets the TodoList resource
let todo_list = borrow_global_mut<TodoList>(signer_address);
// assert task exists
assert!(table::contains(&todo_list.tasks, task_id), ETASK_DOESNT_EXIST);
// gets the task matched the task_id
let task_record = table::borrow_mut(&mut todo_list.tasks, task_id);
// assert task is not completed
assert!(task_record.completed == false, ETASK_IS_COMPLETED);
// update task as completed
task_record.completed = true;
}
WONDERFUL!!
Let’s stop for one moment and make sure our code compiles by running the aptos move compile
command. If all goes well, we should output resembling:
INCLUDING DEPENDENCY AptosFramework
INCLUDING DEPENDENCY AptosStdlib
INCLUDING DEPENDENCY MoveStdlib
BUILDING myTodolist
{
"Result": [
"cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018::todolist"
]
}
If you encounter errors, make sure you followed the steps above correctly and try to determine the cause of the issues.
Write tests
Now that we have our smart contract logic ready, we need to add some tests for it.
Test functions use the #[test]
annotation.
- Add the following code to the bottom of the file:
#[test]
public entry fun test_flow() {
}
we need to use entry
here because we are testing an entry
function.
- For simplicity, and because we don’t have much code to test, we use one function to test the whole flow of the app. The test steps are:
// create a list
// create a task
// update task as completed
Update the test function to be:
#[test(admin = @0x123)]
public entry fun test_flow(admin: signer) acquires TodoList {
// creates an admin @todolist_addr account for test
account::create_account_for_test(signer::address_of(&admin));
// initialize contract with admin account
create_list(&admin);
// creates a task by the admin account
create_task(&admin, string::utf8(b"New Task"));
let task_count = event::counter(&borrow_global<TodoList>(signer::address_of(&admin)).set_task_event);
assert!(task_count == 1, 4);
let todo_list = borrow_global<TodoList>(signer::address_of(&admin));
assert!(todo_list.task_counter == 1, 5);
let task_record = table::borrow(&todo_list.tasks, todo_list.task_counter);
assert!(task_record.task_id == 1, 6);
assert!(task_record.completed == false, 7);
assert!(task_record.content == string::utf8(b"New Task"), 8);
assert!(task_record.address == signer::address_of(&admin), 9);
// updates task as completed
complete_task(&admin, 1);
let todo_list = borrow_global<TodoList>(signer::address_of(&admin));
let task_record = table::borrow(&todo_list.tasks, 1);
assert!(task_record.task_id == 1, 10);
assert!(task_record.completed == true, 11);
assert!(task_record.content == string::utf8(b"New Task"), 12);
assert!(task_record.address == signer::address_of(&admin), 13);
}
Our #[test]
annotation has changed and declares an account variable.
Additionally, the function itself now accepts a signer argument.
Let’s understand our tests.
Since our tests run outside an account scope, we need to create accounts to use in our tests. The #[test]
annotation gives us the option to declare those accounts. We use an admin
account and set it to a random account address (@0x123
). The function accepts this signer (account) and creates it by using a built-in function to create an account for test.
Then we simply go through the flow by:
- creating a list
- creating a task
- updating a task as completed
And assert the expected data/behavior at each step.
Before running the tests again, we need to import (use
) some new modules we are now employing in our code:
- At the top of the file, add this
use
statement:
use std::string::{Self, String}; // already have it, need to modify
- Run the
aptos move test
command. If all goes right, we should see a success message like:
Running Move unit tests
[ PASS ] 0xcbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018::todolist::test_flow
Test result: OK. Total tests: 1; passed: 1; failed: 0
{
"Result": "Success"
}
- Let’s add one more test to make sure our
complete_task
function works as expected. Add another test function with:
#[test(admin = @0x123)]
#[expected_failure(abort_code = E_NOT_INITIALIZED)]
public entry fun account_can_not_update_task(admin: signer) acquires TodoList {
// creates an admin @todolist_addr account for test
account::create_account_for_test(signer::address_of(&admin));
// account can not toggle task as no list was created
complete_task(&admin, 2);
}
This test confirms that an account can’t use that function if they haven’t created a list before.
The test also uses a special annotation #[expected_failure]
that, as the name suggests, expects to fail with an E_NOT_INITIALIZED
error code.
- Run the
aptos move test
command. If all goes right, we should see a success message like:
Running Move unit tests
[ PASS ] 0xcbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018::todolist::account_can_not_update_task
[ PASS ] 0xcbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018::todolist::test_flow
Test result: OK. Total tests: 2; passed: 2; failed: 0
{
"Result": "Success"
}
Now that everything works, we can compile the Move modules and publish the Move package to chain so our React app (and everyone else) can interact with our smart contract!
Publish todolist module to chain
For now, the easiest way to publish a Move package to chain is using the CLI:
cd
into ourmove
directory, and run:aptos move compile
We are getting some Unused alias errors. This is because we added the string
alias before since we use it in our tests. But we don’t use this alias in our smart contract code.
This is why we are getting this error when we want to compile the module but not are getting it when we only run tests.
To fix it, we can add a use
statement that would be used only in tests.
Add the following use
statement where we have all of our import statements.
use std::string::String; // change to this
...
#[test_only]
use std::string; // add this
- Run:
aptos move test
andaptos move compile
- all should work without errors. - Run:
aptos move publish
- Enter
yes
in the prompt. - That will compile, simulate and finally publish your module into devnet. You should see a success message:
{
"Result": {
"transaction_hash": "0x96b84689a53a28db7be6346627a99967f719946bc22766811a674e69da7783fa",
"gas_used": 7368,
"gas_unit_price": 100,
"sender": "cbddf398841353776903dbab2fdaefc54f181d07e114ae818b1a67af28d1b018",
"sequence_number": 2,
"success": true,
"timestamp_us": 1674246585276143,
"version": 651327,
"vm_status": "Executed successfully"
}
}
- You can now head to the Aptos Explorer, change the dropdown on the top right to the Devnet network and look for that
transaction_hash
value - this will show you the transaction details.
Now let’s set up a React app in chapter 2.