src | ||
.gitignore | ||
Cargo.lock | ||
Cargo.toml | ||
README.md | ||
simple_import.leo | ||
simple.leo |
The Leo Language
- All code examples can be copied and pasted into simple.program directly and executed with cargo run
- Programs should be formatted:
- Import definitions
- Stuct definitions
- Function definitions
Integers:
Currently, all integers are parsed as u32. You can choose to explicitly add the type or let the compiler interpret implicitly.
function main() -> (u32) {
a = 1u32 + 1u32
b = 1 - 1
c = 2 * 2
d = 4 / 2
e = 2 ** 3
return a
}
Field Elements:
Field elements must have the type added explicitly.
function main() -> (fe) {
f = 21888242871839275222246405745257275088548364400416034343698204186575808495617fe
a = 1fe + 1fe
b = 1fe - 1fe
c = 2fe * 2fe
d = 4fe / 2fe
return a
}
Booleans:
function main() -> (bool) {
a = true || false
b = false && false
c = 1 == 1
return a
}
Arrays:
Leo supports static arrays with fixed length. Array type must be explicitly stated
function main() -> (u32[2]) {
// initialize an integer array with integer values
u32[3] a = [1, 2, 3]
// set a member to a value
a[2] = 4
// initialize an array of 4 values all equal to 42
u32[4] b = [42; 4]
// initialize an array of 5 values copying all elements of b using a spread
u32[5] c = [1, ...b]
// initialize an array copying a slice from `c`
d = c[1..3]
// initialize a field array
fe[2] e = [5fe; 2]
// initialize a boolean array
bool[3] f = [true, false || true, true]
// return an array
return d
}
Structs:
struct Point {
u32 x
u32 y
}
function main() -> (u32) {
Point p = Point {x: 1, y: 0}
return p.x
}
struct Foo {
bool x
}
function main() -> (Foo) {
Foo f = Foo {x: true}
f.x = false
return f
}
Conditionals:
function main() -> (u32) {
y = if 3==3 then 1 else 5 fi
return y
}
function main() -> (fe) {
a = 1fe
for i in 0..4 do
a = a + 1fe
endfor
return a
}
Functions:
function test1(a : u32) -> (u32) {
return a + 1
}
function test2(b: fe) -> (fe) {
return b * 2fe
}
function test3(c: bool) -> (bool) {
return c && true
}
function main() -> (u32) {
return test1(5)
}
Function Scope:
function foo() -> (field) {
// return myGlobal <- not allowed
return 42fe
}
function main() -> (field) {
myGlobal = 42fe
return foo()
}
Parameters:
Main function arguments are allocated as public or private variables in the program's constaint system.
function main(a: private fe) -> (fe) {
return a
}
function main(a: public fe) -> (fe) {
return a
}
Imports:
Note that there can only be one main function across all imported files. /simple_import.leo
struct Point {
u32 x
u32 y
}
/simple.leo
from "./simple_import" import Point
function main() -> (Point) {
Point p = Point { x: 1, y: 2}
return p
}
Default exports are not currently supported. There should only be one main function across all files.
Leo CLI
Develop
To compile your program and verify that it builds properly, run:
leo build
To execute unit tests on your program, run:
leo test
Run
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
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.
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
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 the blockchain, run:
leo deploy
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
.