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386 lines
7.4 KiB
Markdown
386 lines
7.4 KiB
Markdown
# The Leo Language
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* All code examples can be copied and pasted into `main.leo` directly and executed with cargo run
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* Programs should be formatted:
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1. Import definitions
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2. Struct definitions
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3. Function definitions
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### Integers:
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Currently, all integers are parsed as u32.
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You can choose to explicitly add the type or let the compiler interpret implicitly.
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```rust
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function main() -> u32 {
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let a: u32 = 1u32 + 1u32; // explicit type
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let b = 1 - 1; // implicit type
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let c = 2 * 2;
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let d = 4 / 2;
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let e = 2 ** 3;
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return a
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}
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```
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### Field Elements:
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Field elements must have the type added explicitly.
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```rust
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function main() -> fe {
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let f: fe = 21888242871839275222246405745257275088548364400416034343698204186575808495617fe;
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let a = 1fe + 1fe;
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let b = 1fe - 1fe;
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let c = 2fe * 2fe;
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let d = 4fe / 2fe;
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return a
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}
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```
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### Operator Assignment Statements:
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```rust
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function main() -> u32 {
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let a = 10;
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a += 5;
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a -= 10;
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a *= 5;
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a /= 5;
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a **= 2;
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return a
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}
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```
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### Booleans:
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```rust
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function main() -> bool {
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let a: bool = true || false;
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let b = false && false;
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let c = 1 == 1;
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return a
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}
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```
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### Arrays:
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Leo supports static arrays with fixed length.
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Array type must be explicitly stated
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```rust
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function main() -> u32[2] {
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// initialize an integer array with integer values
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let a: u32[3] = [1, 2, 3];
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// set a member to a value
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a[2] = 4;
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// initialize an array of 4 values all equal to 42
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let b = [42; 4];
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// initialize an array of 5 values copying all elements of b using a spread
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let c = [1, ...b];
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// initialize an array copying a slice from `c`
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let d = c[1..3];
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// initialize a field array
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let e = [5fe; 2];
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// initialize a boolean array
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let f = [true, false || true, true];
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// return an array
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return d
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}
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```
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### Structs:
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```rust
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struct Point {
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x: u32
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y: u32
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}
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function main() -> u32 {
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Point p = Point {x: 1, y: 0}
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return p.x
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}
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```
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```rust
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struct Foo {
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x: bool
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}
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function main() -> Foo {
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let f = Foo {x: true};
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f.x = false;
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return f
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}
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```
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### Assert Equals:
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This will enforce that the two values are equal in the constraint system.
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```rust
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function main() {
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assert_eq(45, 45);
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assert_eq(2fe, 2fe);
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assert_eq(true, true);
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}
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```
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### Conditionals:
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#### If Else Ternary Expression
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```rust
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function main() -> u32 {
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let y = if 3==3 ? 1 : 5;
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return y
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}
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```
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#### If Else Conditional Statement
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```rust
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function main(a: private bool, b: private bool) -> u32 {
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let res = 0;
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if (a) {
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res = 1;
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} else if (b) {
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res = 2;
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} else {
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res = 3;
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}
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return res
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}
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```
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#### For loop
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```rust
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function main() -> fe {
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let a = 1fe;
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for i in 0..4 {
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a = a + 1fe;
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}
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return a
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}
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```
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### Functions:
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```rust
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function test1(a : u32) -> u32 {
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return a + 1
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}
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function test2(b: fe) -> fe {
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return b * 2fe
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}
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function test3(c: bool) -> bool {
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return c && true
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}
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function main() -> u32 {
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return test1(5)
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}
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```
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#### Function Scope:
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```rust
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function foo() -> field {
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// return myGlobal <- not allowed
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return 42fe
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}
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function main() -> field {
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let myGlobal = 42fe;
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return foo()
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}
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```
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#### Multiple returns:
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Functions can return tuples whose types are specified in the function signature.
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```rust
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function test() -> (u32, u32[2]) {
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return 1, [2, 3]
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}
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function main() -> u32[3] {
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let (a, b) = test();
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// (a, u32[2] b) = test() <- explicit type also works
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return [a, ...b]
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}
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```
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#### Main function inputs:
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Main function inputs are allocated as public or private variables in the program's constaint system.
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```rust
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function main(a: private fe) -> fe {
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return a
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}
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```
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```rust
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function main(a: public fe) -> fe {
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return a
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}
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```
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Function inputs are passed by value.
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```rust
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function test(a: u32) {
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a = 0;
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}
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function main() -> u32 {
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let a = 1;
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test(a);
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return a // <- returns 1
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}
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```
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### Imports:
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Both struct and function imports are supported.
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import all: `*`
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import alias: `symbol as alias`
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/simple_import.leo
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```rust
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struct Point {
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x: u32
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y: u32
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}
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function test() -> (u32, u32[2]) {
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return 1, [2, 3]
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}
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```
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/simple.leo
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```rust
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from "./simple_import" import {
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Point as Foo,
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test
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};
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// from "./simple_import" import *
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function main() -> (u32[3]) {
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let p = Foo { x: 1, y: 2};
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let (a, b) = test();
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return [a, ...b]
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}
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```
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# Leo CLI
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## Develop
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### `leo new`
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To setup a new package, run:
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```
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leo new {$NAME}
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```
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This will create a new directory with a given package name. The new package will have a directory structure as follows:
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```
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- inputs # Your program inputs
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- outputs # Your program outputs
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- src
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- lib.leo # Your program library
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- main.leo # Your program
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- tests
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- tests.leo # Your program tests
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- Leo.toml # Your program manifest
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```
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### `leo init`
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To initialize an existing directory, run:
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```
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leo init
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```
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This will initialize the current directory with the same package directory setup.
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### `leo build`
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To compile your program and verify that it builds properly, run:
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```
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leo build
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```
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### `leo test`
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To execute unit tests on your program, run:
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```
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leo test
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```
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## Run
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### `leo setup`
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To perform the program setup, producing a proving key and verification key, run:
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```
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leo setup
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```
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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`:
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```
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{$LIBRARY}/target/{$PROGRAM}.leo.pk
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{$LIBRARY}/target/{$PROGRAM}.leo.vk
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```
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### `leo prove`
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To execute the program and produce an execution proof, run:
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```
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leo prove
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```
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Leo starts by checking the `target` directory for an existing `.leo.pk` file. If it doesn't exist, it will proceed to run `leo setup` and then continue.
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Once again, Leo uses cryptographic randomness from your machine to produce the proof. The proof is stored in the `target` directory as `.leo.proof`:
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```
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{$LIBRARY}/target/{$PROGRAM}.leo.proof
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```
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### `leo verify`
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To verify the program proof, run:
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```
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leo verify
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```
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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.
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After the verifier is run, Leo will output either `true` or `false` based on the verification.
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## Remote
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To use remote compilation features, start by authentication with:
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```
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leo login
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```
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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.
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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.
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This speeds up the testing cycle and helps the developer to iterate significantly faster.
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## Publish
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To package your program as a gadget and publish it online, run:
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```
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leo publish
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```
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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.
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If your gadget name has already been taken, `leo publish` will fail.
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## Deploy
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To deploy your program to Aleo, run:
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```
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leo deploy
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```
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## TODO
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- Change `target` directory to some other directory to avoid collision.
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- Figure out how `leo prove` should take in assignments.
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- Come up with a serialization format for `.leo.pk`, `.leo.vk`, and `.leo.proof`. |