# Proptest [![Build Status](https://github.com/AltSysrq/proptest/workflows/Rust/badge.svg?branch=master)](https://github.com/AltSysrq/proptest/actions) [![Build status](https://ci.appveyor.com/api/projects/status/ofe98xfthbx1m608/branch/master?svg=true)](https://ci.appveyor.com/project/AltSysrq/proptest/branch/master) [![](http://meritbadge.herokuapp.com/proptest)](https://crates.io/crates/proptest) [![](https://img.shields.io/website/https/altsysrq.github.io/proptest-book.svg)][book] [![](https://docs.rs/proptest/badge.svg)][api-docs] [book]: https://altsysrq.github.io/proptest-book/intro.html [api-docs]: https://altsysrq.github.io/rustdoc/proptest/latest/proptest/ ## Introduction Proptest is a property testing framework (i.e., the QuickCheck family) inspired by the [Hypothesis](http://hypothesis.works/) framework for Python. It allows to test that certain properties of your code hold for arbitrary inputs, and if a failure is found, automatically finds the minimal test case to reproduce the problem. Unlike QuickCheck, generation and shrinking is defined on a per-value basis instead of per-type, which makes it more flexible and simplifies composition. ### Status of this crate The crate is fairly close to being feature-complete and has not seen substantial architectural changes in quite some time. At this point, it mainly sees passive maintenance. See the [changelog](https://github.com/AltSysrq/proptest/blob/master/proptest/CHANGELOG.md) for a full list of substantial historical changes, breaking and otherwise. ### What is property testing? _Property testing_ is a system of testing code by checking that certain properties of its output or behaviour are fulfilled for all inputs. These inputs are generated automatically, and, critically, when a failing input is found, the input is automatically reduced to a _minimal_ test case. Property testing is best used to compliment traditional unit testing (i.e., using specific inputs chosen by hand). Traditional tests can test specific known edge cases, simple inputs, and inputs that were known in the past to reveal bugs, whereas property tests will search for more complicated inputs that cause problems. ## Getting Started Let's say we want to make a function that parses dates of the form `YYYY-MM-DD`. We're not going to worry about _validating_ the date, any triple of integers is fine. So let's bang something out real quick. ```rust,no_run fn parse_date(s: &str) -> Option<(u32, u32, u32)> { if 10 != s.len() { return None; } if "-" != &s[4..5] || "-" != &s[7..8] { return None; } let year = &s[0..4]; let month = &s[6..7]; let day = &s[8..10]; year.parse::().ok().and_then( |y| month.parse::().ok().and_then( |m| day.parse::().ok().map( |d| (y, m, d)))) } ``` It compiles, that means it works, right? Maybe not, let's add some tests. ```rust,ignore #[test] fn test_parse_date() { assert_eq!(None, parse_date("2017-06-1")); assert_eq!(None, parse_date("2017-06-170")); assert_eq!(None, parse_date("2017006-17")); assert_eq!(None, parse_date("2017-06017")); assert_eq!(Some((2017, 06, 17)), parse_date("2017-06-17")); } ``` Tests pass, deploy to production! But now your application starts crashing, and people are upset that you moved Christmas to February. Maybe we need to be a bit more thorough. In `Cargo.toml`, add ```toml [dev-dependencies] proptest = "1.0.0" ``` Now we can add some property tests to our date parser. But how do we test the date parser for arbitrary inputs, without making another date parser in the test to validate it? We won't need to as long as we choose our inputs and properties correctly. But before correctness, there's actually an even simpler property to test: _The function should not crash._ Let's start there. ```rust,ignore // Bring the macros and other important things into scope. use proptest::prelude::*; proptest! { #[test] fn doesnt_crash(s in "\\PC*") { parse_date(&s); } } ``` What this does is take a literally random `&String` (ignore `\\PC*` for the moment, we'll get back to that — if you've already figured it out, contain your excitement for a bit) and give it to `parse_date()` and then throw the output away. When we run this, we get a bunch of scary-looking output, eventually ending with ```text thread 'main' panicked at 'Test failed: byte index 4 is not a char boundary; it is inside 'ௗ' (bytes 2..5) of `aAௗ0㌀0`; minimal failing input: s = "aAௗ0㌀0" successes: 102 local rejects: 0 global rejects: 0 ' ``` If we look at the top directory after the test fails, we'll see a new `proptest-regressions` directory, which contains some files corresponding to source files containing failing test cases. These are [_failure persistence_](https://altsysrq.github.io/proptest-book/proptest/failure-persistence.html) files. The first thing we should do is add these to source control. ```text $ git add proptest-regressions ``` The next thing we should do is copy the failing case to a traditional unit test since it has exposed a bug not similar to what we've tested in the past. ```rust,ignore #[test] fn test_unicode_gibberish() { assert_eq!(None, parse_date("aAௗ0㌀0")); } ``` Now, let's see what happened... we forgot about UTF-8! You can't just blindly slice strings since you could split a character, in this case that Tamil diacritic placed atop other characters in the string. In the interest of making the code changes as small as possible, we'll just check that the string is ASCII and reject anything that isn't. ```rust,no_run fn parse_date(s: &str) -> Option<(u32, u32, u32)> { if 10 != s.len() { return None; } // NEW: Ignore non-ASCII strings so we don't need to deal with Unicode. if !s.is_ascii() { return None; } if "-" != &s[4..5] || "-" != &s[7..8] { return None; } let year = &s[0..4]; let month = &s[6..7]; let day = &s[8..10]; year.parse::().ok().and_then( |y| month.parse::().ok().and_then( |m| day.parse::().ok().map( |d| (y, m, d)))) } ``` The tests pass now! But we know there are still more problems, so let's test more properties. Another property we want from our code is that it parses every valid date. We can add another test to the `proptest!` section: ```rust,ignore proptest! { // snip... #[test] fn parses_all_valid_dates(s in "[0-9]{4}-[0-9]{2}-[0-9]{2}") { parse_date(&s).unwrap(); } } ``` The thing to the right-hand side of `in` is actually a *regular expression*, and `s` is chosen from strings which match it. So in our previous test, `"\\PC*"` was generating arbitrary strings composed of arbitrary non-control characters. Now, we generate things in the YYYY-MM-DD format. The new test passes, so let's move on to something else. The final property we want to check is that the dates are actually parsed _correctly_. Now, we can't do this by generating strings — we'd end up just reimplementing the date parser in the test! Instead, we start from the expected output, generate the string, and check that it gets parsed back. ```rust,ignore proptest! { // snip... #[test] fn parses_date_back_to_original(y in 0u32..10000, m in 1u32..13, d in 1u32..32) { let (y2, m2, d2) = parse_date( &format!("{:04}-{:02}-{:02}", y, m, d)).unwrap(); // prop_assert_eq! is basically the same as assert_eq!, but doesn't // cause a bunch of panic messages to be printed on intermediate // test failures. Which one to use is largely a matter of taste. prop_assert_eq!((y, m, d), (y2, m2, d2)); } } ``` Here, we see that besides regexes, we can use any expression which is a `proptest::strategy::Strategy`, in this case, integer ranges. The test fails when we run it. Though there's not much output this time. ```text thread 'main' panicked at 'Test failed: assertion failed: `(left == right)` (left: `(0, 10, 1)`, right: `(0, 0, 1)`) at examples/dateparser_v2.rs:46; minimal failing input: y = 0, m = 10, d = 1 successes: 2 local rejects: 0 global rejects: 0 ', examples/dateparser_v2.rs:33 note: Run with `RUST_BACKTRACE=1` for a backtrace. ``` The failing input is `(y, m, d) = (0, 10, 1)`, which is a rather specific output. Before thinking about why this breaks the code, let's look at what proptest did to arrive at this value. At the start of our test function, insert ```rust,ignore println!("y = {}, m = {}, d = {}", y, m, d); ``` Running the test again, we get something like this: ```text y = 2497, m = 8, d = 27 y = 9641, m = 8, d = 18 y = 7360, m = 12, d = 20 y = 3680, m = 12, d = 20 y = 1840, m = 12, d = 20 y = 920, m = 12, d = 20 y = 460, m = 12, d = 20 y = 230, m = 12, d = 20 y = 115, m = 12, d = 20 y = 57, m = 12, d = 20 y = 28, m = 12, d = 20 y = 14, m = 12, d = 20 y = 7, m = 12, d = 20 y = 3, m = 12, d = 20 y = 1, m = 12, d = 20 y = 0, m = 12, d = 20 y = 0, m = 6, d = 20 y = 0, m = 9, d = 20 y = 0, m = 11, d = 20 y = 0, m = 10, d = 20 y = 0, m = 10, d = 10 y = 0, m = 10, d = 5 y = 0, m = 10, d = 3 y = 0, m = 10, d = 2 y = 0, m = 10, d = 1 ``` The test failure message said there were two successful cases; we see these at the very top, `2497-08-27` and `9641-08-18`. The next case, `7360-12-20`, failed. There's nothing immediately obviously special about this date. Fortunately, proptest reduced it to a much simpler case. First, it rapidly reduced the `y` input to `0` at the beginning, and similarly reduced the `d` input to the minimum allowable value of `1` at the end. Between those two, though, we see something different: it tried to shrink `12` to `6`, but then ended up raising it back up to `10`. This is because the `0000-06-20` and `0000-09-20` test cases _passed_. In the end, we get the date `0000-10-01`, which apparently gets parsed as `0000-00-01`. Again, this failing case was added to the failure persistence file, and we should add this as its own unit test: ```text $ git add proptest-regressions ``` ```rust,ignore #[test] fn test_october_first() { assert_eq!(Some((0, 10, 1)), parse_date("0000-10-01")); } ``` Now to figure out what's broken in the code. Even without the intermediate input, we can say with reasonable confidence that the year and day parts don't come into the picture since both were reduced to the minimum allowable input. The month input was _not_, but was reduced to `10`. This means we can infer that there's something special about `10` that doesn't hold for `9`. In this case, that "special something" is being two digits wide. In our code: ```rust,ignore let month = &s[6..7]; ``` We were off by one, and need to use the range `5..7`. After fixing this, the test passes. The `proptest!` macro has some additional syntax, including for setting configuration for things like the number of test cases to generate. See its [documentation](https://altsysrq.github.io/rustdoc/proptest/latest/proptest/macro.proptest.html) for more details. ## Differences between QuickCheck and Proptest QuickCheck and Proptest are similar in many ways: both generate random inputs for a function to check certain properties, and automatically shrink inputs to minimal failing cases. The one big difference is that QuickCheck generates and shrinks values based on type alone, whereas Proptest uses explicit `Strategy` objects. The QuickCheck approach has a lot of disadvantages in comparison: - QuickCheck can only define one generator and shrinker per type. If you need a custom generation strategy, you need to wrap it in a newtype and implement traits on that by hand. In Proptest, you can define arbitrarily many different strategies for the same type, and there are plenty built-in. - For the same reason, QuickCheck has a single "size" configuration that tries to define the range of values generated. If you need an integer between 0 and 100 and another between 0 and 1000, you probably need to do another newtype. In Proptest, you can directly just express that you want a `0..100` integer and a `0..1000` integer. - Types in QuickCheck are not easily composable. Defining `Arbitrary` and `Shrink` for a new struct which is simply produced by the composition of its fields requires implementing both by hand, including a bidirectional mapping between the struct and a tuple of its fields. In Proptest, you can make a tuple of the desired components and then `prop_map` it into the desired form. Shrinking happens automatically in terms of the input types. - Because constraints on values cannot be expressed in QuickCheck, generation and shrinking may lead to a lot of input rejections. Strategies in Proptest are aware of simple constraints and do not generate or shrink to values that violate them. The author of Hypothesis also has an [article on this topic](http://hypothesis.works/articles/integrated-shrinking/). Of course, there's also some relative downsides that fall out of what Proptest does differently: - Generating complex values in Proptest can be up to an order of magnitude slower than in QuickCheck. This is because QuickCheck performs stateless shrinking based on the output value, whereas Proptest must hold on to all the intermediate states and relationships in order for its richer shrinking model to work. ## Limitations of Property Testing Given infinite time, property testing will eventually explore the whole input space to a test. However, time is not infinite, so only a randomly sampled portion of the input space can be explored. This means that property testing is extremely unlikely to find single-value edge cases in a large space. For example, the following test will virtually always pass: ```rust use proptest::prelude::*; proptest! { #[test] fn i64_abs_is_never_negative(a: i64) { // This actually fails if a == i64::MIN, but randomly picking one // specific value out of 2⁶⁴ is overwhelmingly unlikely. assert!(a.abs() >= 0); } } ``` Because of this, traditional unit testing with intelligently selected cases is still necessary for many kinds of problems. Similarly, in some cases it can be hard or impossible to define a strategy which actually produces useful inputs. A strategy of `.{1,4096}` may be great to fuzz a C parser, but is highly unlikely to produce anything that makes it to a code generator. # Acknowledgements This crate wouldn't have come into existence had it not been for the [Rust port of QuickCheck](https://github.com/burntsushi/quickcheck) and the [`regex_generate`](https://github.com/CryptArchy/regex_generate) crate which gave wonderful examples of what is possible. ## Contribution Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.