I think a real world example will clear the confusion, so let’s see how things are done in Linux.
First of all Linux doesn’t differentiate between process and thread, entity that can be scheduled is called task in Linux and represented by
task_struct. So whenever you execute a
fork() system call, a new
task_struct is created which holds data (or pointer) associated with new task.
So in Linux world a kernel thread means a
Because scheduler only knows about these entities which can be assigned to different CPU’s (logical or physical). In other words if you want Linux scheduler to schedule your process you must create a
User thread is something that is supported and managed outside of kernel by some execution environment (EE from now on) such as JVM. These EE’s will provide you with some functions to create new threads.
But why a user thread must always be mapped to a specific kernel thread.
Let’s say you created some threads using your EE. eventually they must be executed by the CPU and from above explanation we know that the thread must have a
task_struct in order to be assigned to some CPU. That is why the mapping must exist. It’s the duty of your EE to create
If your EE uses many to one model then it will create only one
task_struct for all the threads and it will schedule all these threads onto that
task_struct. Think of it as there is one CPU (
task_struct) and many processes (threads created in EE), your operating system (the EE) will multiplex these processes on that single CPU.
If it uses one to one model than there will be one
task_struct for every thread created in EE. So when you create a new thread in your EE, corresponding
task_struct gets created in the kernel.
Windows does things differentlly ( process and thread is different ) but general idea stays the same that is kernel thread is the entity that CPU scheduler considers for assignment hence user threads must be mapped to corresponding kernel threads (if you want CPU to execute them).