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System calls in the Linux kernel. Part 3.
vsyscalls and vDSO
This is the third part of the chapter that describes system calls in the Linux kernel and we saw preparations after a system call caused by a userspace application and process of handling of a system call in the previous part. In this part we will look at two concepts that are very close to the system call concept, they are called vsyscall
and vdso
.
We already know what system call
s are. They are special routines in the Linux kernel which userspace applications ask to do privileged tasks, like to read or to write to a file, to open a socket, etc. As you may know, invoking a system call is an expensive operation in the Linux kernel, because the processor must interrupt the currently executing task and switch context to kernel mode, subsequently jumping again into userspace after the system call handler finishes its work. These two mechanisms - vsyscall
and vdso
are designed to speed up this process for certain system calls and in this part we will try to understand how these mechanisms work.
Introduction to vsyscalls
The vsyscall
or virtual system call
is the first and oldest mechanism in the Linux kernel that is designed to accelerate execution of certain system calls. The principle of work of the vsyscall
concept is simple. The Linux kernel maps into user space a page that contains some variables and the implementation of some system calls. We can find information about this memory space in the Linux kernel documentation for the x86_64:
ffffffffff600000 - ffffffffffdfffff (=8 MB) vsyscalls
or:
~$ sudo cat /proc/1/maps | grep vsyscall
ffffffffff600000-ffffffffff601000 r-xp 00000000 00:00 0 [vsyscall]
After this, these system calls will be executed in userspace and this means that there will not be context switching. Mapping of the vsyscall
page occurs in the map_vsyscall
function that is defined in the arch/x86/entry/vsyscall/vsyscall_64.c source code file. This function is called during the Linux kernel initialization in the setup_arch
function that is defined in the arch/x86/kernel/setup.c source code file (we saw this function in the fifth part of the Linux kernel initialization process chapter).
Note that implementation of the map_vsyscall
function depends on the CONFIG_X86_VSYSCALL_EMULATION
kernel configuration option:
#ifdef CONFIG_X86_VSYSCALL_EMULATION
extern void map_vsyscall(void);
#else
static inline void map_vsyscall(void) {}
#endif
As we can read in the help text, the CONFIG_X86_VSYSCALL_EMULATION
configuration option: Enable vsyscall emulation
. Why emulate vsyscall
? Actually, the vsyscall
is a legacy ABI due to security reasons. Virtual system calls have fixed addresses, meaning that vsyscall
page is still at the same location every time and the location of this page is determined in the map_vsyscall
function. Let's look on the implementation of this function:
void __init map_vsyscall(void)
{
extern char __vsyscall_page;
unsigned long physaddr_vsyscall = __pa_symbol(&__vsyscall_page);
...
...
...
}
As we can see, at the beginning of the map_vsyscall
function we get the physical address of the vsyscall
page with the __pa_symbol
macro (we already saw implementation if this macro in the fourth path of the Linux kernel initialization process). The __vsyscall_page
symbol defined in the arch/x86/entry/vsyscall/vsyscall_emu_64.S assembly source code file and have the following virtual address:
ffffffff81881000 D __vsyscall_page
in the .data..page_aligned, aw
section and contains call of the three following system calls:
gettimeofday
;time
;getcpu
.
Or:
__vsyscall_page:
mov $__NR_gettimeofday, %rax
syscall
ret
.balign 1024, 0xcc
mov $__NR_time, %rax
syscall
ret
.balign 1024, 0xcc
mov $__NR_getcpu, %rax
syscall
ret
Let's go back to the implementation of the map_vsyscall
function and return to the implementation of the __vsyscall_page
later. After we received the physical address of the __vsyscall_page
, we check the value of the vsyscall_mode
variable and set the fix-mapped address for the vsyscall
page with the __set_fixmap
macro:
if (vsyscall_mode != NONE)
__set_fixmap(VSYSCALL_PAGE, physaddr_vsyscall,
vsyscall_mode == NATIVE
? PAGE_KERNEL_VSYSCALL
: PAGE_KERNEL_VVAR);
The __set_fixmap
takes three arguments: The first is index of the fixed_addresses
enum. In our case VSYSCALL_PAGE
is the first element of the fixed_addresses
enum for the x86_64
architecture:
enum fixed_addresses {
...
...
...
#ifdef CONFIG_X86_VSYSCALL_EMULATION
VSYSCALL_PAGE = (FIXADDR_TOP - VSYSCALL_ADDR) >> PAGE_SHIFT,
#endif
...
...
...
It equal to the 511
. The second argument is the physical address of the page that has to be mapped and the third argument is the flags of the page. Note that the flags of the VSYSCALL_PAGE
depend on the vsyscall_mode
variable. It will be PAGE_KERNEL_VSYSCALL
if the vsyscall_mode
variable is NATIVE
and the PAGE_KERNEL_VVAR
otherwise. Both macros (the PAGE_KERNEL_VSYSCALL
and the PAGE_KERNEL_VVAR
) will be expanded to the following flags:
#define __PAGE_KERNEL_VSYSCALL (__PAGE_KERNEL_RX | _PAGE_USER)
#define __PAGE_KERNEL_VVAR (__PAGE_KERNEL_RO | _PAGE_USER)
that represent access rights to the vsyscall
page. Both flags have the same _PAGE_USER
flags that means that the page can be accessed by a user-mode process running at lower privilege levels. The second flag depends on the value of the vsyscall_mode
variable. The first flag (__PAGE_KERNEL_VSYSCALL
) will be set in the case where vsyscall_mode
is NATIVE
. This means virtual system calls will be native syscall
instructions. In other way the vsyscall will have PAGE_KERNEL_VVAR
if the vsyscall_mode
variable will be emulate
. In this case virtual system calls will be turned into traps and are emulated reasonably. The vsyscall_mode
variable gets its value in the vsyscall_setup
function:
static int __init vsyscall_setup(char *str)
{
if (str) {
if (!strcmp("emulate", str))
vsyscall_mode = EMULATE;
else if (!strcmp("native", str))
vsyscall_mode = NATIVE;
else if (!strcmp("none", str))
vsyscall_mode = NONE;
else
return -EINVAL;
return 0;
}
return -EINVAL;
}
That will be called during early kernel parameters parsing:
early_param("vsyscall", vsyscall_setup);
More about early_param
macro you can read in the sixth part of the chapter that describes process of the initialization of the Linux kernel.
In the end of the vsyscall_map
function we just check that virtual address of the vsyscall
page is equal to the value of the VSYSCALL_ADDR
with the BUILD_BUG_ON macro:
BUILD_BUG_ON((unsigned long)__fix_to_virt(VSYSCALL_PAGE) !=
(unsigned long)VSYSCALL_ADDR);
That's all. vsyscall
page is set up. The result of the all the above is the following: If we pass vsyscall=native
parameter to the kernel command line, virtual system calls will be handled as native syscall
instructions in the arch/x86/entry/vsyscall/vsyscall_emu_64.S. The glibc knows addresses of the virtual system call handlers. Note that virtual system call handlers are aligned by 1024
(or 0x400
) bytes:
__vsyscall_page:
mov $__NR_gettimeofday, %rax
syscall
ret
.balign 1024, 0xcc
mov $__NR_time, %rax
syscall
ret
.balign 1024, 0xcc
mov $__NR_getcpu, %rax
syscall
ret
And the start address of the vsyscall
page is the ffffffffff600000
every time. So, the glibc knows the addresses of the all virtual system call handlers. You can find definition of these addresses in the glibc
source code:
#define VSYSCALL_ADDR_vgettimeofday 0xffffffffff600000
#define VSYSCALL_ADDR_vtime 0xffffffffff600400
#define VSYSCALL_ADDR_vgetcpu 0xffffffffff600800
All virtual system call requests will fall into the __vsyscall_page
+ VSYSCALL_ADDR_vsyscall_name
offset, put the number of a virtual system call to the rax
general purpose register and the native for the x86_64 syscall
instruction will be executed.
In the second case, if we pass vsyscall=emulate
parameter to the kernel command line, an attempt to perform virtual system call handler will cause a page fault exception. Of course, remember, the vsyscall
page has __PAGE_KERNEL_VVAR
access rights that forbid execution. The do_page_fault
function is the #PF
or page fault handler. It tries to understand the reason of the last page fault. And one of the reason can be situation when virtual system call called and vsyscall
mode is emulate
. In this case vsyscall
will be handled by the emulate_vsyscall
function that defined in the arch/x86/entry/vsyscall/vsyscall_64.c source code file.
The emulate_vsyscall
function gets the number of a virtual system call, checks it, prints error and sends segmentation fault simply:
...
...
...
vsyscall_nr = addr_to_vsyscall_nr(address);
if (vsyscall_nr < 0) {
warn_bad_vsyscall(KERN_WARNING, regs, "misaligned vsyscall...);
goto sigsegv;
}
...
...
...
sigsegv:
force_sig(SIGSEGV, current);
reutrn true;
As it checked number of a virtual system call, it does some yet another checks like access_ok
violations and execute system call function depends on the number of a virtual system call:
switch (vsyscall_nr) {
case 0:
ret = sys_gettimeofday(
(struct timeval __user *)regs->di,
(struct timezone __user *)regs->si);
break;
...
...
...
}
In the end we put the result of the sys_gettimeofday
or another virtual system call handler to the ax
general purpose register, as we did it with the normal system calls and restore the instruction pointer register and add 8
bytes to the stack pointer register. This operation emulates ret
instruction.
regs->ax = ret;
do_ret:
regs->ip = caller;
regs->sp += 8;
return true;
That's all. Now let's look on the modern concept - vDSO
.
Introduction to vDSO
As I already wrote above, vsyscall
is an obsolete concept and replaced by the vDSO
or virtual dynamic shared object
. The main difference between the vsyscall
and vDSO
mechanisms is that vDSO
maps memory pages into each process in a shared object form, but vsyscall
is static in memory and has the same address every time. For the x86_64
architecture it is called -linux-vdso.so.1
. All userspace applications that dynamically link to glibc
will use the vDSO
automatically. For example:
~$ ldd /bin/uname
linux-vdso.so.1 (0x00007ffe014b7000)
libc.so.6 => /lib64/libc.so.6 (0x00007fbfee2fe000)
/lib64/ld-linux-x86-64.so.2 (0x00005559aab7c000)
Or:
~$ sudo cat /proc/1/maps | grep vdso
7fff39f73000-7fff39f75000 r-xp 00000000 00:00 0 [vdso]
Here we can see that uname util was linked with the three libraries:
linux-vdso.so.1
;libc.so.6
;ld-linux-x86-64.so.2
.
The first provides vDSO
functionality, the second is C
standard library and the third is the program interpreter (more about this you can read in the part that describes linkers). So, the vDSO
solves limitations of the vsyscall
. Implementation of the vDSO
is similar to vsyscall
.
Initialization of the vDSO
occurs in the init_vdso
function that defined in the arch/x86/entry/vdso/vma.c source code file. This function starts from the initialization of the vDSO
images for 32-bits and 64-bits depends on the CONFIG_X86_X32_ABI
kernel configuration option:
static int __init init_vdso(void)
{
init_vdso_image(&vdso_image_64);
#ifdef CONFIG_X86_X32_ABI
init_vdso_image(&vdso_image_x32);
#endif
Both functions initialize the vdso_image
structure. This structure is defined in the two generated source code files: the arch/x86/entry/vdso/vdso-image-64.c and the arch/x86/entry/vdso/vdso-image-32.c. These source code files generated by the vdso2c program from the different source code files, represent different approaches to call a system call like int 0x80
, sysenter
and etc. The full set of the images depends on the kernel configuration.
For example for the x86_64
Linux kernel it will contain vdso_image_64
:
#ifdef CONFIG_X86_64
extern const struct vdso_image vdso_image_64;
#endif
But for the x86
- vdso_image_32
:
#ifdef CONFIG_X86_X32
extern const struct vdso_image vdso_image_x32;
#endif
If our kernel is configured for the x86
architecture or for the x86_64
and compatibility mode, we will have ability to call a system call with the int 0x80
interrupt, if compatibility mode is enabled, we will be able to call a system call with the native syscall instruction
or sysenter
instruction in other way:
#if defined CONFIG_X86_32 || defined CONFIG_COMPAT
extern const struct vdso_image vdso_image_32_int80;
#ifdef CONFIG_COMPAT
extern const struct vdso_image vdso_image_32_syscall;
#endif
extern const struct vdso_image vdso_image_32_sysenter;
#endif
As we can understand from the name of the vdso_image
structure, it represents image of the vDSO
for the certain mode of the system call entry. This structure contains information about size in bytes of the vDSO
area that always a multiple of PAGE_SIZE
(4096
bytes), pointer to the text mapping, start and end address of the alternatives
(set of instructions with better alternatives for the certain type of the processor) and etc. For example vdso_image_64
looks like this:
const struct vdso_image vdso_image_64 = {
.data = raw_data,
.size = 8192,
.text_mapping = {
.name = "[vdso]",
.pages = pages,
},
.alt = 3145,
.alt_len = 26,
.sym_vvar_start = -8192,
.sym_vvar_page = -8192,
.sym_hpet_page = -4096,
};
Where the raw_data
contains raw binary code of the 64-bit vDSO
system calls which are 2
page size:
static struct page *pages[2];
or 8 Kilobytes.
The init_vdso_image
function is defined in the same source code file and just initializes the vdso_image.text_mapping.pages
. First of all this function calculates the number of pages and initializes each vdso_image.text_mapping.pages[number_of_page]
with the virt_to_page
macro that converts given address to the page
structure:
void __init init_vdso_image(const struct vdso_image *image)
{
int i;
int npages = (image->size) / PAGE_SIZE;
for (i = 0; i < npages; i++)
image->text_mapping.pages[i] =
virt_to_page(image->data + i*PAGE_SIZE);
...
...
...
}
The init_vdso
function passed to the subsys_initcall
macro adds the given function to the initcalls
list. All functions from this list will be called in the do_initcalls
function from the init/main.c source code file:
subsys_initcall(init_vdso);
Ok, we just saw initialization of the vDSO
and initialization of page
structures that are related to the memory pages that contain vDSO
system calls. But to where do their pages map? Actually they are mapped by the kernel, when it loads binary to the memory. The Linux kernel calls the arch_setup_additional_pages
function from the arch/x86/entry/vdso/vma.c source code file that checks that vDSO
enabled for the x86_64
and calls the map_vdso
function:
int arch_setup_additional_pages(struct linux_binprm *bprm, int uses_interp)
{
if (!vdso64_enabled)
return 0;
return map_vdso(&vdso_image_64, true);
}
The map_vdso
function is defined in the same source code file and maps pages for the vDSO
and for the shared vDSO
variables. That's all. The main differences between the vsyscall
and the vDSO
concepts is that vsyscall
has a static address of ffffffffff600000
and implements three system calls, whereas the vDSO
loads dynamically and implements five system calls, as defined in arch/x86/entry/vdso/vma.c:
__vdso_clock_gettime
;__vdso_getcpu
;__vdso_gettimeofday
;__vdso_time
;__vdso_clock_getres
.
That's all.
Conclusion
This is the end of the third part about the system calls concept in the Linux kernel. In the previous part we discussed the implementation of the preparation from the Linux kernel side, before a system call will be handled and implementation of the exit
process from a system call handler. In this part we continued to dive into the stuff which is related to the system call concept and learned two new concepts that are very similar to the system call - the vsyscall
and the vDSO
.
After all of these three parts, we know almost all things that are related to system calls, we know what system call is and why user applications need them. We also know what occurs when a user application calls a system call and how the kernel handles system calls.
The next part will be the last part in this chapter and we will see what occurs when a user runs the program.
If you have questions or suggestions, feel free to ping me in twitter 0xAX, drop me email or just create issue.
Please note that English is not my first language and I am really sorry for any inconvenience. If you found any mistakes please send me PR to linux-insides.