示例#1
0
文件: kdbg.c 项目: Seinern/electra
void sys_write_breakpoint_handler(arm_context_t* state) {
  // we will have to skip it one instruction ahead because single step won't work...
  state->ss.ss_64.pc += 4;
  
  // this means emulating what that instruction did:
  // LDR             X8, [X8,#0x388]
  uint64_t val = rk64(state->ss.ss_64.x[8] + 0x388);
  state->ss.ss_64.x[8] = val;
  
  uint64_t uap = state->ss.ss_64.x[1];
  char* replacer_string = strdup("a different string!\n");
  wk64(uap+8, (uint64_t)replacer_string);
  wk64(uap+0x10, strlen(replacer_string));
}
示例#2
0
// build a fake host priv port
mach_port_t fake_host_priv() {
    if (fake_host_priv_port != MACH_PORT_NULL) {
        return fake_host_priv_port;
    }
    // get the address of realhost:
    uint64_t hostport_addr = find_port(mach_host_self());
    uint64_t realhost = rk64(hostport_addr + koffset(KSTRUCT_OFFSET_IPC_PORT_IP_KOBJECT));
    
    // allocate a port
    mach_port_t port = MACH_PORT_NULL;
    kern_return_t err;
    err = mach_port_allocate(mach_task_self(), MACH_PORT_RIGHT_RECEIVE, &port);
    if (err != KERN_SUCCESS) {
        printf("failed to allocate port\n");
        return MACH_PORT_NULL;
    }
    
    // get a send right
    mach_port_insert_right(mach_task_self(), port, port, MACH_MSG_TYPE_MAKE_SEND);
    
    // locate the port
    uint64_t port_addr = find_port(port);
    
    // change the type of the port
#define IKOT_HOST_PRIV 4
#define IO_ACTIVE   0x80000000
    wk32(port_addr + koffset(KSTRUCT_OFFSET_IPC_PORT_IO_BITS), IO_ACTIVE|IKOT_HOST_PRIV);
    
    // change the space of the port
    wk64(port_addr + koffset(KSTRUCT_OFFSET_IPC_PORT_IP_RECEIVER), ipc_space_kernel());
    
    // set the kobject
    wk64(port_addr + koffset(KSTRUCT_OFFSET_IPC_PORT_IP_KOBJECT), realhost);
    
    fake_host_priv_port = port;
    
    return port;
}
示例#3
0
文件: kdbg.c 项目: Seinern/electra
void handle_kernel_bp_hits(mach_port_t target_thread_port, uint64_t looper_pc, uint64_t breakpoint, breakpoint_callback callback) {
  // get the target thread's thread_t
  uint64_t thread_port_addr = find_port_address(target_thread_port, MACH_MSG_TYPE_COPY_SEND);
  uint64_t thread_t_addr = rk64(thread_port_addr + koffset(KSTRUCT_OFFSET_IPC_PORT_IP_KOBJECT));
  
  while (1) {
    uint64_t looper_saved_state = 0;
    int found_it = 0;
    while (!found_it) {
      if (syscall_complete) {
        return;
      }
      // we've pinned ourself to the same core, so if we're running, it isn't...
      // in some ways this code is very racy, but when we actually have detected that the target
      // thread has hit the breakpoint it should be safe until we restart it
      // and up until then we don't do anything too dangerous...
      
      
      // get the kstack pointer
      uint64_t kstackptr = rk64(thread_t_addr + koffset(KSTRUCT_OFFSET_THREAD_KSTACKPTR));
      
      printf("kstackptr: %llx\n", kstackptr);
      
      // get the thread_kernel_state
      // the stack lives below kstackptr, and kstackptr itself points to a struct thread_kernel_state:
      // the first bit of that is just an arm_context_t:
      // this is the scheduled-off state
      arm_context_t saved_ksched_state = {0};
      kmemcpy((uint64_t)&saved_ksched_state, kstackptr, sizeof(arm_context_t));
      
      // get the saved stack pointer
      uint64_t sp = saved_ksched_state.ss.ss_64.sp;
      printf("sp: %llx\n", sp);
      
      if (sp == 0) {
        continue;
      }
      
      uint64_t stack[128] = {0};
      
      // walk up from there and look for the saved state dumped by the fiq:
      // note that it won't be right at the bottom of the stack
      // instead there are the frames for:
      //   ast_taken_kernel       <-- above this is the saved state which will get restored when the hw bp spinner gets rescheduled
      //     thread_block_reason
      //       thread_invoke
      //         machine_switch_context
      //           Switch_context <-- the frame actually at the bottom of the stack
      
      // should probably walk those stack frame properly, but this will do...
      
      // grab the stack
      kmemcpy((uint64_t)&stack[0], sp, sizeof(stack));
      //for (int i = 0; i < 128; i++) {
      //  printf("%016llx\n", stack[i]);
      //}
      
      for (int i = 0; i < 128; i++) {
        uint64_t flavor_and_count = stack[i];
        if (flavor_and_count != (ARM_SAVED_STATE64 | (((uint64_t)ARM_SAVED_STATE64_COUNT) << 32))) {
          continue;
        }
        
        arm_context_t* saved_state = (arm_context_t*)&stack[i];
        
        if (saved_state->ss.ss_64.pc != looper_pc) {
          continue;
        }
        
        found_it = 1;
        looper_saved_state = sp + (i*sizeof(uint64_t));
        printf("found the saved state probably at %llx\n", looper_saved_state); // should walk the stack properly..
        break;
      }
      
      if (!found_it) {
        printf("unable to find the saved scheduler tick state on the stack, waiting a bit then trying again...\n");
        sleep(1);
        return;
      }
      
    }
    
    
    
    // now keep walking up and find the saved state for the code which hit the BP:
    uint64_t bp_hitting_state = looper_saved_state + sizeof(arm_context_t);
    found_it = 0;
    for (int i = 0; i < 1000; i++) {
      uint64_t flavor_and_count = rk64(bp_hitting_state);
      if (flavor_and_count != (ARM_SAVED_STATE64 | (((uint64_t)ARM_SAVED_STATE64_COUNT) << 32))) {
        bp_hitting_state += 8;
        continue;
      }
      
      arm_context_t bp_context;
      kmemcpy((uint64_t)&bp_context, bp_hitting_state, sizeof(arm_context_t));
      
      for (int i = 0; i < 40; i++) {
        uint64_t* buf = (uint64_t*)&bp_context;
        printf("%016llx\n", buf[i]);
      }
      
      if (bp_context.ss.ss_64.pc != breakpoint) {
        printf("hummm, found an unexpected breakpoint: %llx\n", bp_context.ss.ss_64.pc);
      }
      
      found_it = 1;
      break;
    }
    
    if (!found_it) {
      printf("unable to find bp hitting state\n");
    }
    
    // fix up the bp hitting state so it will continue (with whatever modifications we want:)
    // get a copy of the state:
    arm_context_t bp_context;
    kmemcpy((uint64_t)&bp_context, bp_hitting_state, sizeof(arm_context_t));
    
    callback(&bp_context);
    
    // write that new state back:
    kmemcpy(bp_hitting_state, (uint64_t)&bp_context, sizeof(arm_context_t));
    
    // unblock the looper:
    wk64(looper_saved_state + offsetof(arm_context_t, ss.ss_64.pc), ksym(KSYMBOL_SLEH_SYNC_EPILOG));
    
    // when it runs again it should break out of the loop and continue the syscall
    // forces us off the core and hopefully it on:
    thread_switch(target_thread_port, 0, 0);
    swtch_pri(0);
    
  }
}
示例#4
0
文件: kdbg.c 项目: Seinern/electra
// pin the current thread to a processor, returns a pointer to the processor we're pinned to
uint64_t pin_current_thread() {
  // get the current thread_t:
  uint64_t th = current_thread();

#if 0
  // get the processor_t this thread last ran on
  uint64_t processor = rk64(th + koffset(KSTRUCT_OFFSET_THREAD_LAST_PROCESSOR));
  printf("thread %llx last ran on %llx, pinning it to that core\n", th, processor);
  
  // this is probably fine...
  wk64(th + koffset(KSTRUCT_OFFSET_THREAD_BOUND_PROCESSOR), processor);
#endif
  
  // need the struct cpu_data for that processor which is stored in the CpuDataEntries array, declared in data.s
  // it's 6*4k in to the data segment
  uint64_t cpu_data_entries = ksym(KSYMBOL_CPU_DATA_ENTRIES);
  
  int cpu_id = 0;
  
  // it's an array of cpu_data_entry_t which contains just the 64-bit physical and virtual addresses of struct cpu_data
  uint64_t cpu_data = rk64(cpu_data_entries + ((cpu_id * 0x10) + 8));
  
  uint64_t processor = rk64(cpu_data + koffset(KSTRUCT_OFFSET_CPU_DATA_CPU_PROCESSOR));
  printf("trying to pin to cpu0: %llx\n", processor);
  // pin to that cpu
  // this is probably fine...
  wk64(th + koffset(KSTRUCT_OFFSET_THREAD_BOUND_PROCESSOR), processor);
  
  // that binding will only take account once we get scheduled off and back on again so yield the cpu:
  printf("pin_current_thread yielding cpu\n");
  swtch_pri(0);
  printf("pin_current_thread back on cpu\n");
  uint64_t chosen = rk64(th + koffset(KSTRUCT_OFFSET_THREAD_CHOSEN_PROCESSOR));
  printf("running on %llx\n", chosen);

#if 0
  // should now be running on the chosen processor, and should only get scheduled on there:
  printf("we're running again!\n");

  
  int got_switched = 0;
  for (int i = 0; i < 1000; i++) {
    swtch_pri(0);
    uint64_t p = rk64(th + koffset(KSTRUCT_OFFSET_THREAD_CHOSEN_PROCESSOR));
    if (p != processor) {
      printf("got moved off target processor\n");
      got_switched = 1;
      break;
    }
    usleep(15000);
    p = rk64(th + koffset(KSTRUCT_OFFSET_THREAD_CHOSEN_PROCESSOR));
    if (p != processor) {
      printf("got moved off target processor\n");
      got_switched = 1;
      break;
    }
  }
  if (!got_switched) {
    printf("looks like pinning works!\n");
  }
#endif
  return processor;
}