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I have wrote a simple LKM in linux kernel 2.6 which traverses linked list of task_struct and manipulates pointer. like this.

printk("original p->tasks.prev->next : %p\n", p->tasks.prev->next);
p->tasks.prev->next = p->tasks.next;
printk("manipulated p->tasks.prev->next : %p\n", p->tasks.prev->next);

printk("original p->tasks.next->prev : %p\n", p->tasks.next->prev);
p->tasks.next->prev = p->tasks.prev;
printk("manipulated p->tasks.next->prev : %p\n", p->tasks.next->prev);

but this has no effect on system. I know that process listing(ps) uses /proc filesystem. so I know this has nothing to do with actual task_struct linked list inside kernel. but I thought linux scheduler would use this list. but it seems wrong.

why is there no effect even if I change task_struct inside kernel?? when is this linked list referenced by system??

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1  
Which test/s did you ran, that does/do not show any difference in behaviour? –  alk Aug 16 '12 at 12:34

1 Answer 1

up vote 3 down vote accepted

The kernel stores the list of processes in a circular doubly linked list called the task list3. Each element in the task list is a process descriptor of the type struct task_struct, which is defined in .The process descriptor contains all the information about a specific process.

The task_struct is a relatively large data structure, at around 1.7 kilobytes on a 32- bit machine.This size, however, is quite small considering that the structure contains all the information that the kernel has and needs about a process.

The task_struct structure is allocated via the slab allocator to provide object reuse and cache coloring.

Prior to the 2.6 kernel series, struct task_struct was stored at the end of the kernel stack of each process.This allowed architectures with few registers, such as x86, to calculate the location of the process descriptor via the stack pointer without using an extra register to store the location.With the process descriptor now dynamically created via the slab allocator, a new structure, struct thread_info, was created that again lives at the bottom of the stack (for stacks that grow down) and at the top of the stack (for stacks that grow up)

The new structure also makes it rather easy to calculate offsets of its values for use in assembly code. The thread_info structure is defined on x86 in

struct thread_info {
 struct task_struct *task;
 struct exec_domain *exec_domain;
 unsigned long flags;
 unsigned long status;
 __u32 cpu;
 __s32 preempt_count;
 mm_segment_t addr_limit;
 struct restart_block restart_block;
 unsigned long previous_esp;
 __u8 supervisor_stack[0];
};

The task element of the structure is a pointer to the task’s actual task_struct.

Inside the kernel, tasks are typically referenced directly by a pointer to their task_struct structure. In fact, most kernel code that deals with processes works directly with struct task_struct. Consequently, it is very useful to be able to quickly look up the process descriptor of the currently executing task, which is done via the current macro.This macro must be separately implemented by each architecture. Some architectures save a pointer to the task_struct structure of the currently running process in a register, allowing for efficient access. Other architectures, such as x86 (which has few registers to waste), make use of the fact that struct thread_info is stored on the kernel stack to calculate the location of thread_info and subsequently the task_struct.

The kernel starts init in the last step of the boot process.The init process, in turn, reads the system initscripts and executes more programs, eventually completing the boot process. Every process on the system has exactly one parent. Likewise, every process has zero or more children. Processes that are all direct children of the same parent are called siblings. The relationship between processes is stored in the process descriptor. Each task_struct has a pointer to the parent’s task_struct, named parent, and a list of children, named children.

it is possible to iterate over a process’s children with:

struct task_struct *task;
struct list_head *list;
list_for_each(list, &current->children) {
task = list_entry(list, struct task_struct, sibling);
/* task now points to one of current's children */
}
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thank you, but this was not what I was really asking though. I have figured out that even if I manipulate the pointers from task_struct, this will have no effect from scheduling because the scheduler has it's own struct list_head from runqueue and waitqueue structure. the fundamental reason is that there are numbers of pointer traversal paths to reach task_struct data. –  daehee Aug 24 '12 at 18:13

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