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Interrupts and Interrupt Handling. Part 3.
Interrupt handlers
This is the third part of the chapter about an interrupts and an exceptions handling and in the previous part we stoped in the setup_arch
function from the arch/x86/kernel/setup.c on the setting of the two exceptions handlers for the two following exceptions:
#DB
- debug exception, transfers control from the interrupted process to the debug handler;#BP
- breakpoint exception, caused by theint 3
instruction.
These exceptions allow the x86_64
architecture to have early exception processing for the purpose of debugging via the kgdb.
As you can remember we set these exceptions handlers in the early_trap_init
function:
void __init early_trap_init(void)
{
set_intr_gate_ist(X86_TRAP_DB, &debug, DEBUG_STACK);
set_system_intr_gate_ist(X86_TRAP_BP, &int3, DEBUG_STACK);
load_idt(&idt_descr);
}
from the arch/x86/kernel/traps.c. We already saw implementation of the set_intr_gate_ist
and set_system_intr_gate_ist
functions in the previous part and now we will look on the implementation of these early exceptions handlers.
Debug and Breakpoint exceptions
Ok, we set the interrupts gates in the early_trap_init
function for the #DB
and #BP
exceptions and now time is to look on their handlers. But first of all let's look on these exceptions. The first exceptions - #DB
or debug exception occurs when a debug event occurs, for example attempt to change the contents of a debug register. Debug registers are special registers which present in processors starting from the Intel 80386 and as you can understand from its name they are used for debugging. These registers allow to set breakpoints on the code and read or write data to trace, thus tracking the place of errors. The debug registers are privileged resources available and the program in either real-address or protected mode at CPL
is 0
, that's why we have used set_intr_gate_ist
for the #DB
, but not the set_system_intr_gate_ist
. The verctor number of the #DB
exceptions is 1
(we pass it as X86_TRAP_DB
) and has no error code:
----------------------------------------------------------------------------------------------
|Vector|Mnemonic|Description |Type |Error Code|Source |
----------------------------------------------------------------------------------------------
|1 | #DB |Reserved |F/T |NO | |
----------------------------------------------------------------------------------------------
The second is #BP
or breakpoint exception occurs when processor executes the INT 3 instruction. We can add it anywhere in our code, for example let's look on the simple program:
// breakpoint.c
#include <stdio.h>
int main() {
int i;
while (i < 6){
printf("i equal to: %d\n", i);
__asm__("int3");
++i;
}
}
If we will compile and run this program, we will see following output:
$ gcc breakpoint.c -o breakpoint
i equal to: 0
Trace/breakpoint trap
But if will run it with gdb, we will see our breakpoint and can continue execution of our program:
$ gdb breakpoint
...
...
...
(gdb) run
Starting program: /home/alex/breakpoints
i equal to: 0
Program received signal SIGTRAP, Trace/breakpoint trap.
0x0000000000400585 in main ()
=> 0x0000000000400585 <main+31>: 83 45 fc 01 add DWORD PTR [rbp-0x4],0x1
(gdb) c
Continuing.
i equal to: 1
Program received signal SIGTRAP, Trace/breakpoint trap.
0x0000000000400585 in main ()
=> 0x0000000000400585 <main+31>: 83 45 fc 01 add DWORD PTR [rbp-0x4],0x1
(gdb) c
Continuing.
i equal to: 2
Program received signal SIGTRAP, Trace/breakpoint trap.
0x0000000000400585 in main ()
=> 0x0000000000400585 <main+31>: 83 45 fc 01 add DWORD PTR [rbp-0x4],0x1
...
...
...
Now we know a little about these two exceptions and we can move on to consideration of their handlers.
Preparation before an interrupt handler
As you can note, the set_intr_gate_ist
and set_system_intr_gate_ist
functions takes an addresses of the exceptions handlers in the second parameter:
&debug
;&int3
.
You will not find these functions in the C code. All that can be found in in the *.c/*.h
files only definition of this functions in the arch/x86/include/asm/traps.h:
asmlinkage void debug(void);
asmlinkage void int3(void);
But we can see asmlinkage
descriptor here. The asmlinkage
is the special specificator of the gcc. Actually for a C
functions which are will be called from assembly, we need in explicit declaration of the function calling convention. In our case, if function maked with asmlinkage
descriptor, then gcc
will compile the function to retrieve parameters from stack. So, both handlers are defined in the arch/x86/kernel/entry_64.S assembly source code file with the idtentry
macro:
idtentry debug do_debug has_error_code=0 paranoid=1 shift_ist=DEBUG_STACK
idtentry int3 do_int3 has_error_code=0 paranoid=1 shift_ist=DEBUG_STACK
Actually debug
and int3
are not interrupts handlers. Remember that before we can execute an interrupt/exception handler, we need to do some preparations as:
- When an interrupt or exception occured, the processor uses an exception or interrupt vector as an index to a descriptor in the
IDT
; - In legacy mode
ss:esp
registers are pushed on the stack only if privilege level changed. In 64-bit modess:rsp
pushed on the stack everytime; - During stack switching with
IST
the newss
selector is forced to null. Oldss
andrsp
are pushed on the new stack. - The
rflags
,cs
,rip
and error code pushed on the stack; - Control transfered to an interrupt handler;
- After an interrupt handler will finish its work and finishes with the
iret
instruction, oldss
will be poped from the stack and loaded to thess
register. ss:rsp
will be popped from the stack unconditionally in the 64-bit mode and will be popped only if there is a privilege level change in legacy mode.iret
instruction will restorerip
,cs
andrflags
;- Interrupted program will continue its execution.
+--------------------+
+40 | ss |
+32 | rsp |
+24 | rflags |
+16 | cs |
+8 | rip |
0 | error code |
+--------------------+
Now we can see on the preparations before a process will transfer control to an interrupt/exception handler from practical side. As I already wrote above the first thirteen exceptions handlers defined in the arch/x86/kernel/entry_64.S assembly file with the idtentry macro:
.macro idtentry sym do_sym has_error_code:req paranoid=0 shift_ist=-1
ENTRY(\sym)
...
...
...
END(\sym)
.endm
This macro defines an exception entry point and as we can see it takes five
arguments:
sym
- defines global symbol with the.globl name
.do_sym
- an interrupt handler.has_error_code:req
- information about error code, The:req
qualifier tells the assembler that the argument is required;paranoid
- shows us how we need to check current mode;shift_ist
- shows us what's stack to use;
As we can see our exceptions handlers are almost the same:
idtentry debug do_debug has_error_code=0 paranoid=1 shift_ist=DEBUG_STACK
idtentry int3 do_int3 has_error_code=0 paranoid=1 shift_ist=DEBUG_STACK
The differences are only in the global name and name of exceptions handlers. Now let's look how idtentry
macro implemented. It starts from the two checks:
.if \shift_ist != -1 && \paranoid == 0
.error "using shift_ist requires paranoid=1"
.endif
.if \has_error_code
XCPT_FRAME
.else
INTR_FRAME
.endif
First check makes the check that an exceptions uses Interrupt stack table
and paranoid
is set, in other way it emits the erorr with the .error directive. The second if
clause checks existence of an error code and calls XCPT_FRAME
or INTR_FRAME
macros depends on it. These macros just expand to the set of CFI directives which are used by GNU AS
to manage call frames. The CFI
directives are used only to generate dwarf2 unwind information for better backtraces and they don't change any code, so we will not go into detail about it and from this point I will skip all code which is related to these directives. In the next step we check error code again and push it on the stack if an exception has it with the:
.ifeq \has_error_code
pushq_cfi $-1
.endif
The pushq_cfi
macro defined in the arch/x86/include/asm/dwarf2.h and expands to the pushq
instruction which pushes given error code:
.macro pushq_cfi reg
pushq \reg
CFI_ADJUST_CFA_OFFSET 8
.endm
Pay attention on the $-1
. We already know that when an exception occrus, the processor pushes ss
, rsp
, rflags
, cs
and rip
on the stack:
#define RIP 16*8
#define CS 17*8
#define EFLAGS 18*8
#define RSP 19*8
#define SS 20*8
With the pushq \reg
we denote that place before the RIP
will contain error code of an exception:
#define ORIG_RAX 15*8
The ORIG_RAX
will contain error code of an exception, IRQ number on a hardware interrupt and system call number on system call entry. In the next step we can see thr ALLOC_PT_GPREGS_ON_STACK
macro which allocates space for the 15 general purpose registers on the stack:
.macro ALLOC_PT_GPREGS_ON_STACK addskip=0
subq $15*8+\addskip, %rsp
CFI_ADJUST_CFA_OFFSET 15*8+\addskip
.endm
After this we check paranoid
and if it is set we check first three CPL
bits. We compare it with the 3
and it allows us to know did we come from userspace or not:
.if \paranoid
.if \paranoid == 1
CFI_REMEMBER_STATE
testl $3, CS(%rsp)
jnz 1f
.endif
call paranoid_entry
.else
call error_entry
.endif
If we came from userspace we jump on the label 1
which starts from the call error_entry
instruction. The error_entry
saves all registers in the pt_regs
structure which presetens an interrupt/exception stack frame and defined in the arch/x86/include/uapi/asm/ptrace.h. It saves common and extra registers on the stack with the:
SAVE_C_REGS 8
SAVE_EXTRA_REGS 8
from rdi
to r15
and executes swapgs instruction. This instruction provides a method to for the Linux kernel to obtain a pointer to the kernel data structures and save the user's gsbase
. After this we will exit from the error_entry
with the ret
instruction. After the error_entry
finished to execute, since we came from userspace we need to switch on kernel interrupt stack:
movq %rsp,%rdi
call sync_regs
We just save all registers to the error_entry
in the error_entry
, we put address of the pt_regs
to the rdi
and call sync_regs
function from the arch/x86/kernel/traps.c:
asmlinkage __visible notrace struct pt_regs *sync_regs(struct pt_regs *eregs)
{
struct pt_regs *regs = task_pt_regs(current);
*regs = *eregs;
return regs;
}
This function switchs off the IST
stack if we came from usermode. After this we switch on the stack which we got from the sync_regs
:
movq %rax,%rsp
movq %rsp,%rdi
and put pointer of the pt_regs
again in the rdi
, and in the last step we call an exception handler:
call \do_sym
So, realy exceptions handlers are do_debug
and do_int3
functions. We will see these function in this part, but little later. First of all let's look on the preparations before a processor will transfer control to an interrupt handler. In another way if paranoid
is set, but it is not 1, we call paranoid_entry
which makes almost the same that error_entry
, but it checks current mode with more slow but accurate way:
ENTRY(paranoid_entry)
SAVE_C_REGS 8
SAVE_EXTRA_REGS 8
...
...
movl $MSR_GS_BASE,%ecx
rdmsr
testl %edx,%edx
js 1f /* negative -> in kernel */
SWAPGS
...
...
ret
END(paranoid_entry)
If edx
wll be negative, we are in the kernel mode. As we store all registers on the stack, check that we are in the kernel mode, we need to setup IST
stack if it is set for a given exception, call an exception handler and restore the exception stack:
.if \shift_ist != -1
subq $EXCEPTION_STKSZ, CPU_TSS_IST(\shift_ist)
.endif
call \do_sym
.if \shift_ist != -1
addq $EXCEPTION_STKSZ, CPU_TSS_IST(\shift_ist)
.endif
The last step when an exception handler will finish it's work all registers will be restored from the stack with the RESTORE_C_REGS
and RESTORE_EXTRA_REGS
macros and control will be returned an interrupted task. That's all. Now we know about preparation before an interrupt/exception handler will start to execute and we can go directly to the implementation of the handlers.
Implementation of ainterrupts and exceptions handlers
Both handlers do_debug
and do_int3
defined in the arch/x86/kernel/traps.c source code file and have two similar things: All interrupts/exceptions handlers marked with the dotraplinkage
prefix that expands to the:
#define dotraplinkage __visible
#define __visible __attribute__((externally_visible))
which tells to compiler that something else uses this function (in our case these functions are called from the assembly interrupt preparation code). And also they takes two parameters:
- pointer to the
pt_regs
structure which contains registers of the interrupted task; - error code.
First of all let's consider do_debug
handler. This function starts from the getting previous state with the ist_enter
function from the arch/x86/kernel/traps.c. We call it because we need to know, did we come to the interrupt handler from the kernel mode or user mode.
prev_state = ist_enter(regs);
The ist_enter
function returns previous state context state and executes a couple preprartions before we continue to handle an exception. It starts from the check of the previous mode with the user_mode_vm
macro. It takes pt_regs
structure which contains a set of registers of the interrupted task and returns 1
if we came from userspace and 0
if we came from kernel space. According to the previous mode we execute exception_enter
if we are from the userspace or inform RCU if we are from krenel space:
...
if (user_mode_vm(regs)) {
prev_state = exception_enter();
} else {
rcu_nmi_enter();
prev_state = IN_KERNEL;
}
...
...
...
return prev_state;
After this we load the DR6
debug registers to the dr6
variable with the call of the get_debugreg
macro from the arch/x86/include/asm/debugreg.h:
get_debugreg(dr6, 6);
dr6 &= ~DR6_RESERVED;
The DR6
debug register is debug status register contains information about the reason for stopping the #DB
or debug exception handler. After we loaded its value to the dr6
variable we filter out all reserved bits (4:12
bits). In the next step we check dr6
register and previous state with the following if
condition expression:
if (!dr6 && user_mode_vm(regs))
user_icebp = 1;
If dr6
does not show any reasons why we caught this trap we set user_icebp
to one which means that user-code wants to get SIGTRAP signal. In the next step we check was it kmemcheck trap and if yes we go to exit:
if ((dr6 & DR_STEP) && kmemcheck_trap(regs))
goto exit;
After we did all these checks, we clear the dr6
register, clear the DEBUGCTLMSR_BTF
flag which provides single-step on branches debugging, set dr6
register for the current thread and increase debug_stack_usage
[per-cpu](Per-CPU variables) variable with the:
set_debugreg(0, 6);
clear_tsk_thread_flag(tsk, TIF_BLOCKSTEP);
tsk->thread.debugreg6 = dr6;
debug_stack_usage_inc();
As we saved dr6
, we can allow irqs:
static inline void preempt_conditional_sti(struct pt_regs *regs)
{
preempt_count_inc();
if (regs->flags & X86_EFLAGS_IF)
local_irq_enable();
}
more about local_irq_enabled
and related stuff you can read in the second part about interrupts handling in the Linux kernel. In the next step we check the previous mode was virtual 8086 and handle the trap:
if (regs->flags & X86_VM_MASK) {
handle_vm86_trap((struct kernel_vm86_regs *) regs, error_code, X86_TRAP_DB);
preempt_conditional_cli(regs);
debug_stack_usage_dec();
goto exit;
}
...
...
...
exit:
ist_exit(regs, prev_state);
If we came not from the virtual 8086 mode, we need to check dr6
register and previous mode as we did it above. Here we check if step mode debugging is
enabled and we are not from the user mode, we enabled step mode debugging in the dr6
copy in the current thread, set TIF_SINGLE_STEP
falg and re-enable Trap flag for the user mode:
if ((dr6 & DR_STEP) && !user_mode(regs)) {
tsk->thread.debugreg6 &= ~DR_STEP;
set_tsk_thread_flag(tsk, TIF_SINGLESTEP);
regs->flags &= ~X86_EFLAGS_TF;
}
Then we get SIGTRAP
signal code:
si_code = get_si_code(tsk->thread.debugreg6);
and send it for user icebp traps:
if (tsk->thread.debugreg6 & (DR_STEP | DR_TRAP_BITS) || user_icebp)
send_sigtrap(tsk, regs, error_code, si_code);
preempt_conditional_cli(regs);
debug_stack_usage_dec();
exit:
ist_exit(regs, prev_state);
In the end we disabled irqs
, decrement value of the debug_stack_usage
and exit from the exception handler with the ist_exit
function.
The second exception handler is do_int3
defined in the same source code file - arch/x86/kernel/traps.c. In the do_int3
we makes almost the same that in the do_debug
handler. We get the previous state with the ist_enter
, increment and decrement the debug_stack_usage
per-cpu variable, enabled and disable local interrupts. But of course there is one difference between these two handlers. We need to lock and than sync processor cores during breakpoint patching.
That's all.
Conclusion
It is the end of the third part about interrupts and interrupt handling in the Linux kernel. We saw the initialization of the Interrupt descriptor table in the previous part with the #DB
and #BP
gates and started to dive into preparation before control will be transfered to an exception handler and implementation of some interrupt handlers in this part. In the next part we will continue to dive into this theme and will go next by the setup_arch
function and will try to understand interrupts handling related stuff.
If you will have any questions or suggestions write me a comment or ping me at twitter.
Please note that English is not my first language, And I am really sorry for any inconvenience. If you will find any mistakes please send me PR to linux-internals.