# The Leo Programming Language ```mermaid gantt title Test Diagram section Section A task :a1, 2014-01-01, 30d Another task :after a1 , 20d ``` * Programs should be formatted: 1. Import definitions 2. Circuit definitions 3. Function definitions ## Mutability * All defined variables in Leo are immutable by default. * Variables can be made mutable with the `mut` keyword. ```rust function main() { let a = 0u32; //a = 1 <- Will fail let mut b = 0u32; b = 1; // <- Ok } ``` ## Booleans Explicit types are optional. ```rust function main() -> bool { let a: bool = true || false; let b = false && false; let c = 1u32 == 1u32; return a } ``` ## Numbers * The definition of a number must include an explict type. * After assignment, you can choose to explicitly add the type or let the compiler interpret implicitly. * Type casting is not supported. * Comparators are not supported. ### Integers Supported integer types: `u8`, `u16`, `u32`, `u64`, `u128` ```rust function main() -> u32 { let a = 2u32; // explicit type let a: u32 = 1 + 1; // explicit type let b = a - 1; // implicit type let c = b * 4; let d = c / 2; let e = d ** 3; return e } ``` ### Field Elements ```rust function main() -> field { let a = 1000field; // explicit type let a: field = 21888242871839275222246405745257275088548364400416034343698204186575808495617; // explicit type let b = a + 1; // implicit type let c = b - 1; let d = c * 4; let e = d / 2; return e } ``` ### Affine Points The set of affine points on the elliptic curve passed into the leo compiler forms a group. Leo supports this set as a primitive data type. ```rust function main() -> group { let a = 1000group; // explicit type let a = (21888242871839275222246405745257275088548364400416034343698204186575808495617, 21888242871839275222246405745257275088548364400416034343698204186575808495617)group; // explicit type let b = a + 0; // implicit type let c = b - 0; return c } ``` ### Operator Assignment Statements ```rust function main() -> u32 { let mut a = 10; a += 5; a -= 10; a *= 5; a /= 5; a **= 2; return a } ``` ## Arrays Leo supports static arrays with fixed length. ```rust function main() -> u32[2] { // initialize an integer array with integer values let mut a: u32[3] = [1, 2, 3]; // set a mutable member to a value a[2] = 4; // initialize an array of 4 values all equal to 42 let b = [42u8; 4]; // initialize an array of 5 values copying all elements of b using a spread let c = [1, ...b]; // initialize an array copying a slice from `c` let d = c[1..3]; // initialize a field array let e = [5field; 2]; // initialize a boolean array let f = [true, false || true, true]; return d } ``` ### Multidimensional Arrays ```rust function main() -> u32[3][2] { let m = [[0u32, 0u32], [0u32, 0u32]]; let m: u32[3][2] = [[0; 3]; 2]; return m } ``` ## Conditionals ### If Else Ternary Expression ```rust function main() -> u32 { let y = if 3==3 ? 1 : 5; return y } ``` ### If Else Conditional Statement ** **Experimental** ** The current constraint system is not optimized for statement branching. Please use the ternary expression above until this feature is stable. ```rust function main(a: private bool, b: private bool) -> u32 { let mut res = 0u32; if (a) { res = 1; } else if (b) { res = 2; } else { res = 3; } return res } ``` ### For loop ```rust function main() -> fe { let mut a = 1field; for i in 0..4 { a = a + 1; } return a } ``` ## Functions ```rust function test1(a : u32) -> u32 { return a + 1 } function test2(b: fe) -> field { return b * 2field } function test3(c: bool) -> bool { return c && true } function main() -> u32 { return test1(5) } ``` ### Function Scope ```rust function foo() -> field { // return myGlobal <- not allowed return 42field } function main() -> field { let myGlobal = 42field; return foo() } ``` ### Multiple returns Functions can return tuples whose types are specified in the function signature. ```rust function test() -> (u32, u32[2]) { return 1, [2, 3] } function main() -> u32[3] { let (a, b) = test(); // (a, u32[2] b) = test() <- explicit type also works return [a, ...b] } ``` ### Main function inputs Main function inputs are allocated as public or private variables in the program's constaint system. ```rust function main(a: private field) -> field { return a } ``` ```rust function main(a: public field) -> field { return a } ``` Private by default. Below `a` is implicitly private. ```rust function main(a: field) -> field { return a } ``` Function inputs are passed by value. ```rust function test(mut a: u32) { a = 0; } function main() -> u32 { let a = 1; test(a); return a // <- returns 1 } ``` ## Circuits Circuits in Leo are similar to classes in object oriented langauges. Circuits are defined above functions in a Leo program. Circuits can have one or more members. Members can be defined as fields which hold primitive values ```rust circuit Point { x: u32 y: u32 } function main() -> u32 { let p = Point {x: 1, y: 0}; return p.x } ``` Members can also be defined as functions. ```rust circuit Circ { function echo(x: u32) -> u32 { return x } } function main() -> u32 { let c = Circ { }; return c.echo(1u32) } ``` Circuit functions can be made static, enabling them to be called without instantiation. ```rust circuit Circ { static function echo(x: u32) -> u32 { return x } } function main() -> u32 { return Circ::echo(1u32) } ``` The `Self` keyword is supported in circuit functions. ```rust circuit Circ { b: bool static function new() -> Self { return Self { b: true } } } function main() -> Circ { let c = Circ::new(); return c.b } ``` ## Imports Both struct and function imports are supported. import all: `*` import alias: `symbol as alias` `src/simple_import.leo` ```rust circuit Point { x: u32 y: u32 } function test() -> (u32, u32[2]) { return 1, [2, 3] } ``` `src/simple.leo` ```rust from "./simple_import" import { Point as Foo, test }; // from "./simple_import" import * function main() -> (u32[3]) { let p = Foo { x: 1, y: 2}; let (a, b) = test(); return [a, ...b] } ``` ## Constraints ### Assert Equals This will enforce that the two values are equal in the constraint system. ```rust function main() { assert_eq(45, 45); assert_eq(2fe, 2fe); assert_eq(true, true); } ``` ## Testing Use the `test` keyword to add tests to a leo program. Tests must have 0 function inputs and 0 function returns. ```rust function main(a: u32) -> u32 { return a } test function expect_pass() { let a = 1u32; let res = main(a); assert_eq!(res, 1u32); } test function expect_fail() { assert_eq!(1u8, 0u8); } ``` # Leo Inputs Public and private inputs for a Leo program are specified in the `inputs/` directory. The syntax for an input file is a limited subset of the Leo program syntax. The default inputs file is `inputs/inputs.leo`. ## Sections A Leo input file is made up of sections. Sections are defined by a section header in brackets followed by one or more input definitions. Section headers specify the target file which must have a main function with matching input names and types. `inputs/inputs.leo` ```rust [main] // <- section header a: private u32 = 1; // <- private input b: public u32 = 2; // <- public input ``` `src/main.leo` ```rust function main(a: private u32, b: public u32) -> u32 { let c: u32 = a + b; return c } ``` ## Input Definitions ### Supported types ```rust [main] a: bool = true; // <- booleans b: u8 = 2; // <- integers c: field = 0; // <- fields d: group = (0, 1)group // <- group tuples ``` ### Arrays ```rust [main] a: private u8[4] = [0u8; 4]; // <- single b: private u8[2][3] = [[0u8; 2]; 3]; // <- multi-dimensional ``` # Leo CLI ## Develop ### `leo new` To setup a new package, run: ``` leo new {$NAME} ``` This will create a new directory with a given package name. The new package will have a directory structure as follows: ``` - inputs # Your program inputs - inputs.leo # Your program inputs for main.leo - outputs # Your program outputs - src - lib.leo # Your program library - main.leo # Your program - tests - test.leo # Your program tests - Leo.toml # Your program manifest ``` ### `leo init` To initialize an existing directory, run: ``` leo init ``` This will initialize the current directory with the same package directory setup. ### `leo build` To compile your program and verify that it builds properly, run: ``` leo build ``` ### `leo test` To execute unit tests on your program, run: ``` leo test ``` The results of test compilation and the constraint system will be printed: ``` INFO leo Running 2 tests INFO leo test language::expect_pass compiled. Constraint system satisfied: true ERROR leo test language::expect_fail errored: Assertion 1u8 == 0u8 failed ``` ## Run ### `leo setup` To perform the program setup, producing a proving key and verification key, run: ``` leo setup ``` Leo uses cryptographic randomness from your machine to perform the setup. The proving key and verification key are stored in the `target` directory as `.leo.pk` and `.leo.vk`: ``` {$LIBRARY}/target/{$PROGRAM}.leo.pk {$LIBRARY}/target/{$PROGRAM}.leo.vk ``` ### `leo prove` To execute the program and produce an execution proof, run: ``` leo prove ``` Leo starts by checking the `target` directory for an existing `.leo.pk` file. If it doesn't exist, it will proceed to run `leo setup` and then continue. Next any input files in the `inputs` directory are parsed and all input values are passed to the program. Once again, Leo uses cryptographic randomness from your machine to produce the proof. The proof is stored in the `target` directory as `.leo.proof`: ``` {$LIBRARY}/target/{$PROGRAM}.leo.proof ``` ### `leo verify` To verify the program proof, run: ``` leo verify ``` Leo starts by checking the `target` directory for an existing `.leo.proof` file. If it doesn't exist, it will proceed to run `leo prove` and then continue. After the verifier is run, Leo will output either `true` or `false` based on the verification. ## Remote To use remote compilation features, start by authentication with: ``` leo login ``` You will proceed to authenticate using your username and password. Next, Leo will parse your `Leo.toml` file for `remote = True` to confirm whether remote compilation is enabled. If remote compilation is enabled, Leo syncs your workspace so when you run `leo build`, `leo test`, `leo setup` and `leo prove`, your program will run the program setup and execution performantly on remote machines. This speeds up the testing cycle and helps the developer to iterate significantly faster. ## Publish To package your program as a gadget and publish it online, run: ``` leo publish ``` Leo will proceed to snapshot your directory and upload your directory to the circuit manager. Leo will verify that `leo build` succeeds and that `leo test` passes without error. If your gadget name has already been taken, `leo publish` will fail. ## Deploy To deploy your program to Aleo, run: ``` leo deploy ``` # Install To install Leo from source, in the root directory of the repository, run: ``` cargo install --path . ``` ## TODO - Change `target` directory to some other directory to avoid collision. - Figure out how `leo prove` should take in assignments. - Come up with a serialization format for `.leo.pk`, `.leo.vk`, and `.leo.proof`.