__private_extern__ kern_return_t
chudxnu_thread_get_state(
thread_t thread,
thread_flavor_t flavor,
thread_state_t tstate,
mach_msg_type_number_t *count,
boolean_t user_only)
{
if (user_only) {
/* We can't get user state for kernel threads */
if (thread->task == kernel_task)
return KERN_FAILURE;
/* this properly handles deciding whether or not the thread is 64 bit or not */
return machine_thread_get_state(thread, flavor, tstate, count);
} else {
// i386 machine_thread_get_kern_state() is different from the PPC version which returns
// the previous save area - user or kernel - rather than kernel or NULL if no kernel
// interrupt state available
// the real purpose of this branch is the following:
// the user doesn't care if the thread states are user or kernel, he
// just wants the thread state, so we need to determine the proper one
// to return, kernel or user, for the given thread.
if(thread == current_thread() && current_cpu_datap()->cpu_int_state) {
// the above are conditions where we possibly can read the kernel
// state. we still need to determine if this interrupt happened in
// kernel or user context
if(USER_STATE(thread) == current_cpu_datap()->cpu_int_state &&
current_cpu_datap()->cpu_interrupt_level == 1) {
// interrupt happened in user land
return machine_thread_get_state(thread, flavor, tstate, count);
} else {
// kernel interrupt.
return machine_thread_get_kern_state(thread, flavor, tstate, count);
}
} else {
// get the user-mode thread state
return machine_thread_get_state(thread, flavor, tstate, count);
}
}
}
static void
kern_collectth_state(thread_t thread, tir_t *t)
{
vm_offset_t header;
int hoffset, i ;
mythread_state_flavor_t *flavors;
struct thread_command *tc;
/*
* Fill in thread command structure.
*/
header = t->header;
hoffset = t->hoffset;
flavors = t->flavors;
tc = (struct thread_command *) (header + hoffset);
tc->cmd = LC_THREAD;
tc->cmdsize = (uint32_t)sizeof(struct thread_command) + t->tstate_size;
hoffset += (uint32_t)sizeof(struct thread_command);
/*
* Follow with a struct thread_state_flavor and
* the appropriate thread state struct for each
* thread state flavor.
*/
for (i = 0; i < kdp_mynum_flavors; i++) {
*(mythread_state_flavor_t *)(header+hoffset) =
flavors[i];
hoffset += (uint32_t)sizeof(mythread_state_flavor_t);
/* Locate and obtain the non-volatile register context
* for this kernel thread. This should ideally be
* encapsulated in machine_thread_get_kern_state()
* but that routine appears to have been co-opted
* by CHUD to obtain pre-interrupt state.
*/
if (flavors[i].flavor == x86_THREAD_STATE64) {
x86_thread_state64_t *tstate = (x86_thread_state64_t *) (header + hoffset);
vm_offset_t kstack;
x86_saved_state64_t *cpstate = current_cpu_datap()->cpu_fatal_trap_state;
bzero(tstate, x86_THREAD_STATE64_COUNT * sizeof(int));
if ((current_thread() == thread) && (cpstate != NULL)) {
tstate->rax = cpstate->rax;
tstate->rbx = cpstate->rbx;
tstate->rcx = cpstate->rcx;
tstate->rdx = cpstate->rdx;
tstate->rdi = cpstate->rdi;
tstate->rsi = cpstate->rsi;
tstate->rbp = cpstate->rbp;
tstate->r8 = cpstate->r8;
tstate->r9 = cpstate->r9;
tstate->r10 = cpstate->r10;
tstate->r11 = cpstate->r11;
tstate->r12 = cpstate->r12;
tstate->r13 = cpstate->r13;
tstate->r14 = cpstate->r14;
tstate->r15 = cpstate->r15;
tstate->rip = cpstate->isf.rip;
tstate->rsp = cpstate->isf.rsp;
tstate->rflags = cpstate->isf.rflags;
tstate->cs = cpstate->isf.cs;
tstate->fs = cpstate->fs;
tstate->gs = cpstate->gs;
} else if ((kstack = thread->kernel_stack) != 0){
struct x86_kernel_state *iks = STACK_IKS(kstack);
tstate->rbx = iks->k_rbx;
tstate->rsp = iks->k_rsp;
tstate->rbp = iks->k_rbp;
tstate->r12 = iks->k_r12;
tstate->r13 = iks->k_r13;
tstate->r14 = iks->k_r14;
tstate->r15 = iks->k_r15;
tstate->rip = iks->k_rip;
}
}
else if (machine_thread_get_kern_state(thread,
flavors[i].flavor, (thread_state_t) (header+hoffset),
&flavors[i].count) != KERN_SUCCESS)
printf ("Failure in machine_thread_get_kern_state()\n");
hoffset += (uint32_t)(flavors[i].count*sizeof(int));
}
t->hoffset = hoffset;
}
