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Aleo SDK

The Aleo SDK is a developer framework to make it simple to create a new account, craft a transaction, and broadcast it to the network.

Table of Contents

1. Overview

For more information on Aleo, visit Welcome to Aleo to get started.

2. Build Guide

2.1 Install Rust

We recommend installing Rust using rustup. You can install rustup as follows:

2.2 Build from Source Code

We recommend installing aleo this way. In your terminal, run:

# Download the source code
git clone https://github.com/AleoHQ/aleo.git

# Enter the 'aleo' directory
cd aleo

# Install 'aleo'
cargo install --path .

Now to use aleo, in your terminal, run:

aleo

3. Usage Guide

3.1 Generate a new Aleo account

To generate a new Aleo account, run:

aleo account new [FLAGS] [OPTIONS]

The command can be run with the following optional parameters:

FLAGS:
    -h, --help       Prints help information
    -V, --version    Prints version information

OPTIONS:
    -s, --seed <seed>

3.2 Create and build a new project

To create a new project, we'll use the new command. Our project:

aleo new foo

This will create foo directory and the files with the basic structure of the project:

  • README.md having the skeleton of a README with instructions on how to compile.
  • main.aleo the main file of the source code.
  • program.json containing the identification of the project in JSON format. Particularly, a dev address and its private key for the program.

The main.aleo file should have contents like this:

// The 'foo.aleo' program.
program foo.aleo;

function hello:
    input r0 as u32.public;
    input r1 as u32.private;
    add r0 r1 into r2;
    output r2 as u32.private;

To compile the project, run in the main directory:

aleo build

You will see output like this:

⏳ Compiling 'foo.aleo'...
 • Loaded universal setup (in 1478 ms)
 • Built 'hello' (in 3250 ms)
✅ Built 'foo.aleo' (in "~/foo")

First, a "universal setup" is loaded into your environment. You can read more about this here or in the Marlin paper.

Once the universal setup is ready, every function in your main.aleo file is built, generating this in the output folder:

  • hello.prover the prover for the hello function.
  • hello.verifier the verifier for the hello function.
  • main.avm the bytecode of your aleo program to be run by the VM.

As you can already guess, we have only one .avm file for the whole program, but a prover and verifier for every function.

3.3 Running a program

You can run a program with the aleo run command, followed by the function name you want to execute and its input parameters

aleo run hello 2u32 3u32

When the execution is finished, you should see the following output:

🚀 Executing 'foo.aleo/hello'...
 • Calling 'foo.aleo/hello'...
 • Executed 'hello' (in 1170 ms)
➡️  Output
 • 5u32
✅ Executed 'foo.aleo/hello' (in "[...]/foo")

As you can see, the output register was assigned with the 5u32 value, representing the sum of the inputs.

3.4 Overview of a program

Let's examine the foo program inside the main.aleo file:

// The 'foo.aleo' program.
program foo.aleo;

function hello:
    input r0 as u32.public;
    input r1 as u32.private;
    add r0 r1 into r2;
    output r2 as u32.private;

First, we need to declare the program as the following:

program foo.aleo;

Afterwards, we can start writing its functions (or other Aleo structures such as interfaces, records, closures, as we will see later).

In the case of functions we have it very easy:

function [function_name]:

The functions are composed of three main parts:

  • The input section

    Here we declare its input parameters:

        input r0 as u32.public;
        input r1 as u32.private;
    

    Everything in Aleo instructions is declared/stored inside a register with a type (i8,field,bool, etc.) and a visibility option (public or private), registers are named r0, r1, ..., rn.

    In this case we use r0 and r1 to store the inputs passed in sequential order to a program as u32 values, where we can store 32-bit unsigned integers to perform our sum operation.

  • The instructions section

    The next section consists in the core of our function, here we call the amount of Aleo Instructions we need to make our program do what we want. For example, performing an addition operation:

        add r0 r1 into r2;
    

    Every Aleo instruction is followed by its input parameters with its specific types, and the result is stored in the into register.

    You can find all the available aleo instructions here.

  • The output section

    Similar to the input section, the output section does the same for the output of the program. It's the return of the function.

        output r2 as u32.private;
    

3.5 Types

Aleo uses a strongly-typed syntax. The language supports 16 primitive types, and allows users to define custom types.

The Aleo primitive types include:

address
boolean
field
group
i8
i16
i32
i64
i128
u8
u16
u32
u64
u128
scalar
string

Users can define custom types using the interface or record keywords. We will explore these in the next few sections.

3.5.1 Registers

Registers are the places where you store data to then be able to modify it.

3.5.2 Interfaces

Interfaces are user-defined data structures. They are very much like traditional structs in conventional programming languages. You can store interfaces into registers, like with any other Aleo data types.

For example, let's build an interface representing a fixed-size array of 3 elements. Add this at the bottom of the main.aleo file:

interface array3:
    a0 as u32;
    a1 as u32;
    a2 as u32;

Now, just for example purposes, let's code a function that adds one to each element of a register with an array3 data type stored in it.

function sum_one_to_array3:
    input r0 as array3.private;
    add r0.a0 1u32 into r1;
    add r0.a1 1u32 into r2;
    add r0.a2 1u32 into r3;
    cast r1 r2 r3 into r4 as array3;
    output r4 as array3.private;

As you can see, we can input an interface into register r0 and access interface elements with the . syntax. We perform the add instruction on every element, storing the results in registers r1, r2 and r3 and, finally, we make use of the cast command to create a new array3 interface into r4.

Now, let's run it. In this case, the only new thing you need to know is that interfaces are passed to the CLI in the following format:

"{a0: 1u32, a1: 2u32, a2: 3u32}"

Now we can execute the aleo run command. We will clean the project to pick up the new code:

aleo clean && aleo run sum_one_to_array3 "{a0: 0u32, a1: 1u32, a2: 2u32}"

And we get the new array3 element as output:

🚀 Executing 'foo.aleo/sum_one_to_array3'...
 • Calling 'foo.aleo/sum_one_to_array3'...
 • Executed 'sum_one_to_array3' (in 1331 ms)
➡️  Output
 • {
  a0: 1u32,
  a1: 2u32,
  a2: 3u32
}
✅ Executed 'foo.aleo/sum_one_to_array3' (in "[...]/foo")

3.5.3 Records

A record is a fundamental data structure for encoding user assets and application state. They are very similar to interfaces, but they have two non-optional parameters:

record token:
    owner as address.private
    gates as u64.private

the owner refers to the Aleo address that owns the record and gates is the amount of credits that the record has to spend.

Records are important because they represent the basic Aleo structure to handle state in your application.

When running an Aleo function, only records that belong to the application address can be passed as input registers. Otherwise, an error would be raised and the application wouldn't run.

You can find your development application address inside the program.json file:

{
    "program": "foo.aleo",
    "version": "0.0.0",
    "description": "",
    "development": {
        "private_key": "APrivateKey1zkpFsQNXJwdvjKs9bRsM91KcwJW1gW4CDtF3FJbgVBAvPds",
        "address": "aleo1x5nz5u4j50w482t5xtqc3jdwly9s8saaxlgjz0wvmuzmxv2l5q9qmypx09"
    },
    "license": "MIT"
}

3.5.4 Aleo State

In Aleo, the state of an application is managed through records. An Aleo account can create a transaction to consume a record and produce a new record in its place. Records in Aleo are encrypted to the record owner address, ensuring that all records in Aleo are fully private.

3.6 Your first Aleo Program: Making a transfer

Consider this program:

// The 'foo.aleo' program.
program foo.aleo;
record token:
    owner as address.private;
    gates as u64.private;
    amount as u64.private;
function transfer_amount:
    //  sender token record
    input r0 as token.record;
    // receiver address
    input r1 as address.private;
    // amount to transfer
    input r2 as u64.private;
    // final balance of sender
    sub r0.amount r2 into r3;
    // final balance of receiver
    add 0u64 r2 into r4;
    // sender token record after the transfer
    cast r0.owner r0.gates r3 into r5 as token.record;
    // receiver token record after the transfer
    cast r1 0u64 r4 into r6 as token.record;
    // sender new token record
    output r5 as token.record;
    // receiver new token record
    output r6 as token.record;

First, we define our own record data type called token, that has the two non-optional parameters, owner and gates, and a user-defined parameter called amount, representing the amount of tokens we have.

This transfer_amount function receives 3 input parameters (sender record, receiver record and amount) and stores them in 3 registers (r0, r1 and r2). After that, it computes the final balance for both of them and stores it in r3 and r4 (using sub and add instructions to compute the subtraction and addition respectively). With those final amounts, it creates the output records for sender and receiver, storing them in r5 and r6 . Finally, both records are sent out of the function with the output instruction.

To run this function, the first parameter is the input record of the program. The format of this parameter is the same as for interface types:

{
  owner: aleo1x5nz5u4j50w482t5xtqc3jdwly9s8saaxlgjz0wvmuzmxv2l5q9qmypx09.private,
  gates: 0u64.private,
  amount: 50u64.private
}

Where:

  • owner: the public address of the program, as found in the development.address of the build/program.json file.
  • gates: the gates that the record has.
  • other parameters: depending on the program itself (in this example, we used the parameter amount with the value 50).

Let's run the transfer_amount function (if you are following along, remember to use the address found in the program.json for the owner field):

aleo clean && aleo run transfer_amount "{
owner: aleo1x5nz5u4j50w482t5xtqc3jdwly9s8saaxlgjz0wvmuzmxv2l5q9qmypx09.private,
gates: 0u64.private,
amount: 50u64.private
}" aleo1h3gu7fky36y8r7v2x9phc434fgf20g8qd7c7u45v269jfw6vmugqjegcvp 10u64

We get the following output records:

🚀 Executing 'foo.aleo/transfer_amount'...
 • Calling 'foo.aleo/transfer_amount'...
 • Executed 'transfer_amount' (in 3520 ms)
➡️  Outputs
 • {
  owner: aleo1x5nz5u4j50w482t5xtqc3jdwly9s8saaxlgjz0wvmuzmxv2l5q9qmypx09.private,
  gates: 0u64.private,
  amount: 40u64.private
  _nonce: 2293253577170800572742339369209137467208538700597121244293392265726446806023group.public
}
 • {
  owner: aleo1h3gu7fky36y8r7v2x9phc434fgf20g8qd7c7u45v269jfw6vmugqjegcvp.private,
  gates: 0u64.private,
  amount: 10u64.private
  _nonce: 2323253577170856894742339369235137467208538700597121244293392765726742543235group.public
}
✅ Executed 'foo.aleo/transfer_amount' (in "[...]/foo")

And that's it. You have transferred your first own-defined tokens in Aleo!

Note: the _nonce is not written in Aleo instructions. The compiler outputs the _nonce in record outputs. The user needs to provide it as input when using a record.