First off, when you get to the breakpoint you hit in
first has already executed and is no longer on the stack.
When we go into
first, we instantly hit an
Well, first of all, it does call
asyncFunction(). This returns a promise, and will have started some asynchronous process that will later resolve it. Now we can't continue with the next line of
first (ie, the
console.log('first completed')) because our
await means we can't carry on until the promise was fulfilled, so we need to suspend execution here and go find something else to do with our free time.
So, we look up the stack. We're still in the
first() call from main, and now we can just return a promise from that call, which we will resolve when the asynchronous execution completes.
main ignores that promise return value, so we continue right with
second(). Once we've executed
second, we look back to whatever called that, and carry on with synchronous execution in the way everyone would expect.
Then, at some point in the future, our promise fulfills. Maybe it was waiting on an API call to return. Maybe it was waiting on the database to reply back to it. In our example, it was waiting for a 2s timeout. Whatever it was waiting for, it now is ready to be dealt with, and we can un-suspend the
first call and continue executing there. It's not "called" from
main - internally the function is picked back up, just like a callback, but crucially is called with a completely new stack, which will be destroyed once we're done calling the remainder of the function.
Given that we're in a new stack, and have long since left the 'main' stack frame, how do
first end up on the stack again when we hit the breakpoint inside it?
For a long time, if you ran your code inside debuggers, the simple answer was that they wouldn't. You'd just get the function you were in, and the debugger would tell you it had been called from "asynchronous code", or something similar.
However, nowadays some debuggers can follow awaited code back to the promise that it is resolving (remember,
async are mostly just syntactic sugar on top of promises). In other words, when your awaited code finishes, and the "promise" under the hood resolves, your debugger helpfully figures out what the stack "should" look like. What it shows doesn't actually bear much resemblance to how the engine ended up calling the function - after all, it was called out of the event loop. However, I think it's a helpful addition, enabling us all to keep the mental model of our code much simpler than what's actually going on!
Some further reading on how this works, which covers much more detail than I can here:
asynchronousfunctions together. I am not very sure tough, but I can imagine,
main()starts, and pushes
async. Immediately after
second()is called and pushed to a different callstack, cuz
sync. I usually imagine
asyncfuncions to myself as some sort of threads.
nodeshas a single
eventloop. But the
eventloopis just the final executioner. I think there'll still be different
callstacksor something like queues. In the end, the eventloop takes all these queues and just executes them in some order. I have not enough knowledge to answer this question correctly , so I just put this as comment.
callstack. I think it's just the stacktrace. I guess this is handled more low-level.`