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Marble is a metamorphic testing library for Zig.

This library tracks Zig master and was last tested on 0.12.0-dev.4472+1c7798a3c

Metamorphic testing is a powerful technique that provides additional test coverage by applying a number of transformations to test input, and then checking if certain relations still hold between the outputs. Marble will automatically run through all possible combinations of these transformations.

Here's a great introduction by Cockroach Labs. I highly recommend reading before using this library.

The repository contains a few test examples

Resources

Building

To build and run test examples:

zig build
zig build test

Importing the library

Add Marble as a Zig package in your build file, or simply import it directly after vendoring/adding a submodule:

const marble = @import("marble/main.zig");

Writing tests

A metamorphic Zig test looks something like this:

const SinusTest = struct {
    const tolerance = std.math.epsilon(f64) * 20;

    /// This test has a single value, but you could also design the test to take an
    /// array as input. The transformations, check and execute functions would then
    /// loop through them all. Alternatively, the test can be run multiple times
    /// with different inputs.
    value: f64,

    /// The mathematical property "sin(x) = sin(π − x)" must hold
    pub fn transformPi(self: *SinusTest) void {
        self.value = std.math.pi - self.value;
    }

    /// Adding half the epsilon must still cause the relation to hold given the tolerance
    pub fn transformEpsilon(self: *SinusTest) void {
        self.value = self.value + std.math.epsilon(f64) / 2.0;
    }

    /// A metamorphic relation is a relation between outputs in different executions.
    /// This relation must hold after every execution of transformation combinations.
    pub fn check(_: *SinusTest, original_output: f64, transformed_output: f64) bool {
        return std.math.approxEqAbs(f64, original_output, transformed_output, tolerance);
    }

    /// Called initially to compute the baseline output, and after every transformation combination
    pub fn execute(self: *SinusTest) f64 {
        return std.math.sin(self.value);
    }
};

test "sinus" {
    var i: f64 = 1;
    while (i < 100) : (i += 1) {
        var t = SinusTest{ .value = i };
        try std.testing.expect(try marble.run(SinusTest, &t, .{}));
    }
}

You will get compile time errors if the requirements for a metamorphic test are not met.

In short, you must provide a value field, a check function, an execute function and one or more transform... functions.

Writing transformations

Add one or more functions starting with transform...

Marble will execute all combinations of the transformation functions. After every combination, execute is called followed by check.

Transformations should change the value property - Marble will remember what it was originally. The transformations must be such that check succeeds. That is, the relations between the inital output and the transformed output must still hold.

Checking if relations still hold

You must provide a check function to see if one or more relations hold, and return true if so. If false is returned, the test fails with a print-out of the current transformation-combination.

Relation checks may be conditional; check out the tests for examples on how this works.

Executing

You must provide an execute function that computes a result based on the current value. The simplest form will simply return the current value, but you can do any arbitrary operation here. This function is called before any transformations to form a baseline. This baseline is passed as the first argument to check

Optional before/after calls

Before and after the test, and every combination, before(...) and after(...) is called if present. This is useful to reset state, initialize test cases, and perform clean-up.

What happens during a test run?

Using the example above, the following pseudocode runs will be performed:

baseline = execute()

// First combination
transformPi()
out = execute()
check(baseline, out)

// Second combination
transformEpsilon()
out = execute()
check(baseline, out)

// Third combination
transformPi()
transformEpsilon()
out = execute()
check(baseline, out)

Configuring runs

The run function takes a RunConfiguration:

/// If set to true, only run each transformation once separately
skip_combinations: bool = false,

/// If true, print detailed information during the run
verbose: bool = false,

Error reporting

If a test fails, the current combination being executed is printed. For instance, the following tells us that the combination of transformAdditionalTerm and transformCase caused the metamorphic relation to fail:

Test [2/2] test "query"... Test case failed with transformation(s):
  >> transformAdditionalTerm
  >> transformCase

Terminology