libfit

FIT is a lean library of portable C++ abstractions for control flow and memory management beyond what is offered by the C++ 14 standard library.

FIT is intended to facilitate the implementation of Fuchsia SDK libraries and their clients. Some of its features are intended to simplify asynchronous event-driven programs as the C++ 14 standard library has some limitations in that regard. Such programs are very common on Fuchsia due to the prevalence of asynchronous inter-process communication throughout the operating system.

FIT only depends on the C++ language and standard library. It offers essential enhancements to the C++ standard library rather than attempting to replace it or become a framework for writing applications. FIT can be thought of as an “annex” that expresses a few ideas we wish the C++ standard library might itself implement someday.

FIT is lean.

What Belongs in FIT

Several Fuchsia SDK libraries, such as libfidl, depend on FIT and on the C++ standard library. As these libraries are broadly used, we must take care in deciding what features to include in FIT to avoid burdening developers with unnecessary code or dependencies.

In general, the goal is to identify specific abstractions that make sense to generalize across the entire ecosystem of Fuchsia C++ applications. These will necessarily be somewhat low-level but high impact. We don‘t want to add code to FIT simply because we think it’s cool. We need evidence that it is a common idiom and that a broad audience of developers will significantly benefit from its promotion.

Here are a few criteria to consider:

  • Is the feature lightweight, general-purpose, and platform-independent?
  • Is the feature not well served by other means, particularly by the C++ standard library?
  • Is the feature needed by a Fuchsia SDK library?
  • Does the feature embody a beneficial idiom that clients of the Fuchsia SDK commonly use?
  • Has the feature been re-implemented many times already leading to code fragmentation that we would like to eliminate?

If in doubt, leave it out. See [Justifications] below.

What Doesn't Belong in FIT

FIT is not intended to become a catch-all class library.

Specifically prohibited features:

  • Features that introduce dependencies on libraries other than the C and C++ standard library.
  • Features that only work on certain operating systems.
  • Collection classes where the C++ 14 standard library already offers an adequate (if not perfect) alternative.
  • Classes that impose an implementation burden on clients such as event loops, dispatchers, frameworks, and other glue code.

Implementation Considerations

FIT is not exception safe (but could be made to be in the future).

Style Conventions

FIT's API style follows C++ standard library conventions.

In brief:

  • Class, method, field, and variable identifiers are snake_case.
  • Template parameters are CamelCase.
  • Preprocessor macros are UPPER_SNAKE_CASE.
  • Whenever a FIT API mimics a C++ standard library API, it should have a similar structure. For example, fit::function offers the same methods as std::function except where necessary to diverge due to its move-only semantics.

Rule of thumb: Using FIT should feel like using the C++ standard library.

Justifications

These sections explain why certain features are in FIT.

fit::function

  • libfidl‘s API needs a callable function wrapper with move semantics but C++ 14’s std::function only supports copyable function objects which forces FIDL to allocate callback state on the heap making programs less efficient and harder to write.
  • Lots of other C++ code uses callbacks extensively and would benefit from move semantics for similar reasons.
  • So we should create a move-only function wrapper to use everywhere.

fit::defer

  • When writing asynchronous event-driven programs, it can become challenging to ensure that resources remain in scope for the duration of an operation in progress and are subsequently released.
  • The C++ 14 standard library offers several classes with RAII semantics, such as std::unique_ptr, which are helpful in these situations. Unfortunately the C++ 14 standard library does not offer affordances for easily invoking a function when a block or object goes out of scope short of implementing a new class from scratch.
  • We have observed several re-implementations of the same idea throughout the system.
  • So we should create a simple way to invoke a function on scope exit.

fit::optional

  • std::optional is very useful but it requires C++ 17.
  • We have observed several re-implementations of the same idea throughout the system and it's also a building block for other features such as fit::nullable.
  • So we should create a poly-fill for std::optional on C++ 14.
  • TODO(fxbug.dev/28041): The initial implementation only covers a minimal subset of the std::optional API. Flesh this out more fully.

fit::nullable

  • Case study: fit::defer has a need to store a closure that may be nullable. We were able to replace its hand-rolled lifetime management code with fit::nullable thereby vastly simplifying its implementation.
  • Case study: fit::future has a need to track its own validity along with a continuation that may or not be present.
  • Case study: We have previously observed bugs where developers were surprised when assigning a null closure to wrappers such as fit::function fit::defer, or fit::future left these objects in a supposedly “valid” but uninvocable state. These objects therefore take care to detect null closures and enter an “invalid” state. Using fit::is_null and fit::nullable makes it easier to eliminate this redundant state and simplifies the API for clients of these wrappers.
  • std::optional can be effective here but it doesn‘t directly handle nullity so it takes more care to coalesce the null and “not present” states. std::optional also increases the size of the object to carry an extra bool and passing, whereas fit::nullable eliminates this overhead by taking advantage of the underlying value’s null state (if there is one).
  • So we introduce fit::nullable to handle both cases systematically while still hewing close to the semantics of std::optional.

fit::promise, fit::future, fit::executor, etc.

  • When writing asynchronous event-driven programs, it's convenient to be able to stage a sequence of asynchronous tasks. This tends to be challenging to implement in a callback-driven manner due to object lifetime issues, so we would like an alternative pattern that is easier to apply correctly, such as by expressing asynchronous logic as a compositions of futures.
  • The C++ 14 standard library offers std::future but it is tied to a thread-based execution model. Awaiting a future requires blocking, which is bad for event loops.
  • So libfit offers a family of APIs that work better with event loops.