One way to do this is to have the threading package in the user code register itself for some sort of timer interrupt from the kernel. Whenever it receives such an interrupt, it can tell the kernel to halt execution of all of the kernel threads that are themselves running multiple different threads. For each of those threads, the timer interrupt code can inspect the stack for those threads, record important information (registers, stack pointer, program counter, etc.) in an auxiliary location, then load in the stored information for another one of the simulated threads running on that actual thread. It can then resume the kernel thread running the simulated thread. In this way, you can simulate context switching between the multiple threads running on a single kernel thread.
To implement something like locking, you could keep track of all the lock information locally in your user space. Whenever a simulated thread tries to acquire a lock, you can check whether the thread can successfully get the lock. If so, you just give it the lock. Otherwise, you simulate a context switch by swapping out what simulated thread is running on that real thread, then marking the simulated thread as blocked until the lock becomes free again.
This is just a start - there's a lot of other details here (what if one of the simulated threads tries to do a blocking I/O operation? You can't just block the kernel thread, since that would halt all the simulated threads!), but this is the gist of the idea.