Merge pull request #2265 from JuliDi/docs-best-practices
[Docs] Add best practices page
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** xref:basic_application.adoc[Basic application]
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** xref:project_structure.adoc[Project Structure]
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** xref:new_project.adoc[Starting a new Embassy project]
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** xref:best_practices.adoc[Best Practices]
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* xref:layer_by_layer.adoc[Bare metal to async]
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* xref:runtime.adoc[Executor]
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* xref:delaying_a_task.adoc[Delaying a Task]
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* xref:bootloader.adoc[Bootloader]
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* xref:examples.adoc[Examples]
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* xref:developer.adoc[Developer]
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** xref:developer_stm32.adoc[Developer: STM32]
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* xref:developer.adoc[Developer Docs]
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** xref:developer_stm32.adoc[Developer Docs: STM32]
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* xref:embassy_in_the_wild.adoc[Embassy in the wild]
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* xref:faq.adoc[Frequently Asked Questions]
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docs/modules/ROOT/pages/best_practices.adoc
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docs/modules/ROOT/pages/best_practices.adoc
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= Best Practices
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Over time, a couple of best practices have emerged. The following list should serve as a guideline for developers writing embedded software in _Rust_, especially in the context of the _Embassy_ framework.
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== Passing Buffers by Reference
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It may be tempting to pass arrays or wrappers, like link:https://docs.rs/heapless/latest/heapless/[`heapless::Vec`], to a function or return one just like you would with a `std::Vec`. However, in most embedded applications you don't want to spend ressources on an allocator and end up placing buffers on the stack.
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This, however, can easily blow up your stack if you are not careful.
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Consider the following example:
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[,rust]
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----
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fn process_buffer(mut buf: [u8; 1024]) -> [u8; 1024] {
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// do stuff and return new buffer
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for elem in buf.iter_mut() {
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*elem = 0;
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}
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buf
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}
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pub fn main() -> () {
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let buf = [1u8; 1024];
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let buf_new = process_buffer(buf);
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// do stuff with buf_new
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()
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}
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----
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When calling `process_buffer` in your program, a copy of the buffer you pass to the function will be created,
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consuming another 1024 bytes.
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After the processing, another 1024 byte buffer will be placed on the stack to be returned to the caller.
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(You can check the assembly, there will be two memcopy operations, e.g., `bl __aeabi_memcpy` when compiling for a Cortex-M processor.)
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*Possible Solution:*
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Pass the data by reference and not by value on both, the way in and the way out.
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For example, you could return a slice of the input buffer as the output.
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Requiring the lifetime of the input slice and the output slice to be the same, the memory safetly of this procedure will be enforced by the compiler.
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[,rust]
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----
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fn process_buffer<'a>(buf: &'a mut [u8]) -> &'a mut[u8] {
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for elem in buf.iter_mut() {
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*elem = 0;
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}
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buf
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}
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pub fn main() -> () {
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let mut buf = [1u8; 1024];
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let buf_new = process_buffer(&mut buf);
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// do stuff with buf_new
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()
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}
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----
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