esp-idf/components/driver/gptimer/README.md

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# GPTimer Driver Design
## State Transition
> State transition is achieved by using the primitives provided by `<stdatomic.h>`.
```mermaid
stateDiagram-v2
[*] --> init: gptimer_new_timer
init --> enable: gptimer_enable
enable --> init: gptimer_disable
enable --> run: gptimer_start*
run --> enable: gptimer_stop*
init --> [*]: gptimer_del_timer
```
Other functions won't change the driver state. The functions above labeled with `*` are allowed to be used in the interrupt context.
## Concurrency
There might be race conditions when the user calls the APIs from a thread and interrupt at the same time. e.g. a Task is just running the `gptimer_start`, and suddenly an interrupt occurs, where the user calls `gptimer_stop` for the same timer handle. Which is possible to make a "stopped" timer continue to run if the interrupt is returned before the Task.
```mermaid
stateDiagram-v2
state Race-Condition {
Thread --> gptimer_start
state gptimer_start {
state is_enabled <<choice>>
[*] --> is_enabled: Enabled?
is_enabled --> run_wait: yes
is_enabled --> [*] : no
run_wait --> run: call HAL/LL functions to start timer
}
--
Interrupt --> gptimer_stop
state gptimer_stop {
state is_running <<choice>>
[*] --> is_running: Running?
is_running --> enable_wait: yes
is_running --> [*] : no
enable_wait --> enable: call HAL/LL functions to stop timer
}
}
```
By introducing a "middle" state like `run_wait` and `enable_wait`, we make sure that the timer is in a safe state before we start/stop it. And if the state is invalid, it can return an error code to the user.