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Version: v1.0.0-beta.0

Assert Function

Noir includes a special assert function which will explicitly constrain the predicate/comparison expression that follows to be true. If this expression is false at runtime, the program will fail to be proven. Example:

fn main(x : Field, y : Field) {
assert(x == y);
}

Assertions only work for predicate operations, such as ==. If there's any ambiguity on the operation, the program will fail to compile. For example, it is unclear if assert(x + y) would check for x + y == 0 or simply would return true.

You can optionally provide a message to be logged when the assertion fails:

assert(x == y, "x and y are not equal");

Aside string literals, the optional message can be a format string or any other type supported as input for Noir's print functions. This feature lets you incorporate runtime variables into your failed assertion logs:

assert(x == y, f"Expected x == y, but got {x} == {y}");

Using a variable as an assertion message directly:

struct myStruct {
myField: Field
}

let s = myStruct { myField: y };
assert(s.myField == x, s);

There is also a special static_assert function that behaves like assert, but that runs at compile-time.

fn main(xs: [Field; 3]) {
let x = 2 + 2;
let y = 4;
static_assert(x == y, "expected 2 + 2 to equal 4");

// This passes since the length of `xs` is known at compile-time
static_assert(xs.len() == 3, "expected the input to have 3 elements");
}

This function fails when passed a dynamic (run-time) argument:

fn main(x : Field, y : Field) {
// this fails because `x` is not known at compile-time
static_assert(x == 2, "expected x to be known at compile-time and equal to 2");

let mut example_slice = &[];
if y == 4 {
example_slice = example_slice.push_back(0);
}

// This fails because the length of `example_slice` is not known at
// compile-time
let error_message = "expected an empty slice, known at compile-time";
static_assert(example_slice.len() == 0, error_message);
}