A more ergonomic and more flexible form of thread local storage. [![Docs Status](https://docs.rs/threadstack/badge.svg)](https://docs.rs/threadstack) [![license](https://img.shields.io/badge/license-MIT-blue.svg)](https://github.com/jgarvin/threadstack/blob/main/LICENCE) [![crates.io badge](https://img.shields.io/crates/v/threadstack.svg)](https://crates.io/crates/threadstack) Inspired by the [parameters feature](https://docs.racket-lang.org/reference/parameters.html) from Racket. The general idea is the following. Many applications have "context" variables that are needed by almost every module in the application. It is extremely tedious to pass down these values through every every function in the program. The obvious temptation is to use a global variable instead, but global variables have a bunch of widely known downsides: * They lack thread safety. * They create a hidden side channel between modules in your application that can create "spooky action at a distance." * Because there is only one instance of a global variable modules in the program can fight over what they want the value of it to be. Threadstacks are a middle ground. Essentially instead of having a global variable, you keep a thread local stack of values. You can only refer to the value at the top of the stack, and the borrow checker will guarantee that your reference goes away before the value is popped. You can push new values on the stack, but they automatically expire when the lexical scope containing your push ends. Values on the threadstack are immutable unless you go out of your way to use a type with interior mutability like `Cell` or `RefCell`, so code that wants to customize the value typically will do so by pushing on onto the stack rather than clobbering the existing value as would normally occur with a global variable. This gives you the effect of a global variable that you can temporarily override. Functions that before would have referenced a global variable instead reference the top of the stack, and by pushing a value on the stack before calling said functions you can affect their behavior. However you are unable to affect the behavior when your caller calls those functions because by the time control returns to your caller the lexical scope containing your push will have ended and the value you pushed will have automatically been popped from the stack. This limits the degree to which different modules can step on each other. Because the provided `let_ref_thread_stack_value!` creates references that have a special lifetime tied to the current stack frame, it is not necessary to wrap all code using thread stack values inside a call to something like `my_local_key.with(|data| {...})` like you would have to with the standard `thread_local!` TLS implementation. Example: ```rust use threadstack::*; declare_thread_stacks!( FOO: String = String::from("hello world"); ); let_ref_thread_stack_value!(my_reference, FOO); assert!(my_reference == "hello world"); { push_thread_stack_value!("hello universe".into(), FOO); let_ref_thread_stack_value!(my_other_reference, FOO); assert!(my_other_reference == "hello universe"); } assert!(my_reference == "hello world"); push_thread_stack_value!("hello galaxy".into(), FOO); assert!(my_reference == "hello world"); // still is reference to old value! let_ref_thread_stack_value!(my_reference, FOO); // shadows the old reference assert!(my_reference == "hello galaxy"); ````