This is the fifth part of the Kernel booting process
series. We saw transition to the 64-bit mode in the previous part and we will continue from this point in this part. We will see the last steps before we jump to the kernel code as preparation for kernel decompression, relocation and directly kernel decompression. So... let's start to dive in the kernel code again.
We stoped right before jump on 64-bit entry point - startup_64
which located in the arch/x86/boot/compressed/head_64.S source code file. We already saw the jump to the startup_64
in the startup_32
:
pushl $__KERNEL_CS
leal startup_64(%ebp), %eax
...
...
...
pushl %eax
...
...
...
lret
in the previous part, startup_64
starts to work. Since we loaded the new Global Descriptor Table and there was CPU transition in other mode (64-bit mode in our case), we can see setup of the data segments:
.code64
.org 0x200
ENTRY(startup_64)
xorl %eax, %eax
movl %eax, %ds
movl %eax, %es
movl %eax, %ss
movl %eax, %fs
movl %eax, %gs
in the beginning of the startup_64
. All segment registers besides cs
points now to the ds
which is 0x18
(if you don't understand why it is 0x18
, read the previous part).
The next step is computation of difference between where kernel was compiled and where it was loaded:
#ifdef CONFIG_RELOCATABLE
leaq startup_32(%rip), %rbp
movl BP_kernel_alignment(%rsi), %eax
decl %eax
addq %rax, %rbp
notq %rax
andq %rax, %rbp
cmpq $LOAD_PHYSICAL_ADDR, %rbp
jge 1f
#endif
movq $LOAD_PHYSICAL_ADDR, %rbp
1:
leaq z_extract_offset(%rbp), %rbx
rbp
contains decompressed kernel start address and after this code executed rbx
register will contain address where to relocate the kernel code for decompression. We already saw code like this in the startup_32
( you can read about it in the previous part - Calculate relocation address), but we need to do this calculation again because bootloader can use 64-bit boot protocol and startup_32
just will not be executed in this case.
In the next step we can see setup of the stack and reset of flags register:
leaq boot_stack_end(%rbx), %rsp
pushq $0
popfq
As you can see above rbx
register contains the start address of the decompressing kernel code and we just put this address with boot_stack_end
offset to the rsp
register. After this stack will be correct. You can find definition of the boot_stack_end
in the end of compressed/head_64.S
file:
.bss
.balign 4
boot_heap:
.fill BOOT_HEAP_SIZE, 1, 0
boot_stack:
.fill BOOT_STACK_SIZE, 1, 0
boot_stack_end:
It located in the .bss
section right before .pgtable
. You can look at arch/x86/boot/compressed/vmlinux.lds.S to find it.
As we set the stack, now we can copy the compressed kernel to the address that we got above, when we calculated the relocation address of the decompressed kernel. Let's look on this code:
pushq %rsi
leaq (_bss-8)(%rip), %rsi
leaq (_bss-8)(%rbx), %rdi
movq $_bss, %rcx
shrq $3, %rcx
std
rep movsq
cld
popq %rsi
First of all we push rsi
to the stack. We need save value of rsi
, because this register now stores pointer to the boot_params
real mode structure (you must remember this structure, we filled it in the start of kernel setup). In the end of this code we'll restore pointer to the boot_params
into rsi
again.
The next two leaq
instructions calculates effective address of the rip
and rbx
with _bss - 8
offset and put it to the rsi
and rdi
. Why we calculate this addresses? Actually compressed kernel image located between this copying code (from startup_32
to the current code) and the decompression code. You can verify this by looking on the linker script - arch/x86/boot/compressed/vmlinux.lds.S:
. = 0;
.head.text : {
_head = . ;
HEAD_TEXT
_ehead = . ;
}
.rodata..compressed : {
*(.rodata..compressed)
}
.text : {
_text = .; /* Text */
*(.text)
*(.text.*)
_etext = . ;
}
Note that .head.text
section contains startup_32
. You can remember it from the previous part:
__HEAD
.code32
ENTRY(startup_32)
...
...
...
.text
section contains decompression code:
assembly
.text
relocated:
...
...
...
/*
* Do the decompression, and jump to the new kernel..
*/
...
And .rodata..compressed
contains compressed kernel image.
So rsi
will contain rip
relative address of the _bss - 8
and rdi
will contain relocation relative address of the ``_bss - 8. As we store these addresses in register, we put the address of
_bss` to the `rcx` register. As you can see in the `vmlinux.lds.S`, it located in the end of all sections with the setup/kernel code. Now we can start to copy data from `rsi` to `rdi` by 8 bytes with `movsq` instruction.
Note that there is std
instruction before data copying, it sets DF
flag and it means that rsi
and rdi
will be decremeted or in other words, we will crbxopy bytes in backwards.
In the end we clear DF
flag with cld
instruction and restore boot_params
structure to the rsi
.
After it we get .text
section address address and jump to it:
leaq relocated(%rbx), %rax
jmp *%rax
.text
sections starts with the relocated
label. For the start there is clearing of the bss
section with:
xorl %eax, %eax
leaq _bss(%rip), %rdi
leaq _ebss(%rip), %rcx
subq %rdi, %rcx
shrq $3, %rcx
rep stosq
Here we just clear eax
, put RIP relative address of the _bss
to the rdi
and _ebss
to rcx
and fill it with zeros with rep stosq
instructions.
In the end we can see the call of the decompress_kernel
routine:
pushq %rsi
movq $z_run_size, %r9
pushq %r9
movq %rsi, %rdi
leaq boot_heap(%rip), %rsi
leaq input_data(%rip), %rdx
movl $z_input_len, %ecx
movq %rbp, %r8
movq $z_output_len, %r9
call decompress_kernel
popq %r9
popq %rsi
Again we save rsi
with pointer to boot_params
structure and call decompress_kernel
from the arch/x86/boot/compressed/misc.c with seven arguments. All arguments will be passed through the registers. We finished all preparation and now can look on the kernel decompression.
As i wrote above, decompress_kernel
function is in the arch/x86/boot/compressed/misc.c source code file. This function starts with the video/console initialization that we saw in the previous parts. This calls need if bootloaded used 32 or 64-bit protocols. After this we store pointers to the start of the free memory and to the end of it:
free_mem_ptr = heap;
free_mem_end_ptr = heap + BOOT_HEAP_SIZE;
where heap
is the second parameter of the decompress_kernel
function which we got with:
leaq boot_heap(%rip), %rsi
As you saw about boot_heap
defined as:
boot_heap:
.fill BOOT_HEAP_SIZE, 1, 0
where BOOT_HEAP_SIZE
is 0x400000
if the kernel compressed with bzip2
or 0x8000
if not.
In the next step we call choose_kernel_location
function from the arch/x86/boot/compressed/aslr.c. As we can understand from the function name it chooses memory location where to decompress the kernel image. Let's look on this function.
At the start choose_kernel_location
tries to find kaslr
option in the command line if CONFIG_HIBERNATION
is set and nokaslr
option if this configuration option CONFIG_HIBERNATION
is not set:
#ifdef CONFIG_HIBERNATION
if (!cmdline_find_option_bool("kaslr")) {
debug_putstr("KASLR disabled by default...\n");
goto out;
}
#else
if (cmdline_find_option_bool("nokaslr")) {
debug_putstr("KASLR disabled by cmdline...\n");
goto out;
}
#endif
If there is no kaslr
or nokaslr
in the command line it jumps to out
label:
out:
return (unsigned char *)choice;
which just returns the output
parameter which we passed to the choose_kernel_location
without any changes. Let's try to understand what is it kaslr
. We can find information about it in the documentation:
kaslr/nokaslr [X86]
Enable/disable kernel and module base offset ASLR
(Address Space Layout Randomization) if built into
the kernel. When CONFIG_HIBERNATION is selected,
kASLR is disabled by default. When kASLR is enabled,
hibernation will be disabled.
It means that we can pass kaslr
option to the kernel's command line and get random address for the decompressed kernel (more about aslr you can read here).
Let's consider the case when kernel's command line contains kaslr
option.
There is the call of the mem_avoid_init
function from the same aslr.c
source code file. This function gets the unsafe memory regions (initrd, kernel command line and etc...). We need to know about this memory regions to not overlap them with the kernel after decompression. For example:
initrd_start = (u64)real_mode->ext_ramdisk_image << 32;
initrd_start |= real_mode->hdr.ramdisk_image;
initrd_size = (u64)real_mode->ext_ramdisk_size << 32;
initrd_size |= real_mode->hdr.ramdisk_size;
mem_avoid[1].start = initrd_start;
mem_avoid[1].size = initrd_size;
Here we can see calculation of the initrd start address and size. ext_ramdisk_image
is high 32-bits of the ramdisk_image
field from boot header and ext_ramdisk_size
is high 32-bits of the ramdisk_size
field from boot protocol:
Offset Proto Name Meaning
/Size
...
...
...
0218/4 2.00+ ramdisk_image initrd load address (set by boot loader)
021C/4 2.00+ ramdisk_size initrd size (set by boot loader)
...
And ext_ramdisk_image
and ext_ramdisk_size
you can find in the Documentation/x86/zero-page.txt:
Offset Proto Name Meaning
/Size
...
...
...
0C0/004 ALL ext_ramdisk_image ramdisk_image high 32bits
0C4/004 ALL ext_ramdisk_size ramdisk_size high 32bits
...
So we're taking ext_ramdisk_image
and ext_ramdisk_size
, shifting they left on 32 (now they will contain low 32-bits in the high 32-bit bits) and getting start address of the initrd
and size of it. After this we store these values in the mem_avoid
array which defined as:
#define MEM_AVOID_MAX 5
static struct mem_vector mem_avoid[MEM_AVOID_MAX];
where mem_vector
structure is:
struct mem_vector {
unsigned long start;
unsigned long size;
};
The next step after we collected all unsafe memory regions in the mem_avoid
array will be search of the random address which does not overlap with the unsafe regions with the find_random_addr
function.
First of all we can see align of the output address in the find_random_addr
function:
minimum = ALIGN(minimum, CONFIG_PHYSICAL_ALIGN);
you can remember CONFIG_PHYSICAL_ALIGN
configuration option from the previous part. This option provides the value to which kernel should be aligned and it is 0x200000
by default. After that we got aligned output address, we go through the memory and collect regions which are good for decompressed kernel image:
for (i = 0; i < real_mode->e820_entries; i++) {
process_e820_entry(&real_mode->e820_map[i], minimum, size);
}
You can remember that we collected e820_entries
in the second part of the Kernel booting process part 2.
First of all process_e820_entry
function does some checks that e820 memory region is not non-RAM, that the start address of the memory region is not bigger than Maximum allowed aslr
offset and that memory region is not less than value of kernel alignment:
struct mem_vector region, img;
if (entry->type != E820_RAM)
return;
if (entry->addr >= CONFIG_RANDOMIZE_BASE_MAX_OFFSET)
return;
if (entry->addr + entry->size < minimum)
return;
After this, we store e820 memory region start address and the size in the mem_vector
structure (we saw definition of this structure above):
region.start = entry->addr;
region.size = entry->size;
As we store these values, we align the region.start
as we did it in the find_random_addr
function and check that we didn't get address that bigger than original memory region:
region.start = ALIGN(region.start, CONFIG_PHYSICAL_ALIGN);
if (region.start > entry->addr + entry->size)
return;
Next we get difference between the original address and aligned and check that if the last address in the memory region is bigger than CONFIG_RANDOMIZE_BASE_MAX_OFFSET
, we reduce the memory region size that end of kernel image will be less than maximum aslr
offset:
region.size -= region.start - entry->addr;
if (region.start + region.size > CONFIG_RANDOMIZE_BASE_MAX_OFFSET)
region.size = CONFIG_RANDOMIZE_BASE_MAX_OFFSET - region.start;
In the end we go through the all unsafe memory regions and check that this region does not overlap unsafe ares with kernel command line, initrd and etc...:
for (img.start = region.start, img.size = image_size ;
mem_contains(®ion, &img) ;
img.start += CONFIG_PHYSICAL_ALIGN) {
if (mem_avoid_overlap(&img))
continue;
slots_append(img.start);
}
If memory region does not overlap unsafe regions we call slots_append
function with the start address of the region. slots_append
function just collects start addresses of memory regions to the slots
array:
slots[slot_max++] = addr;
which defined as:
static unsigned long slots[CONFIG_RANDOMIZE_BASE_MAX_OFFSET /
CONFIG_PHYSICAL_ALIGN];
static unsigned long slot_max;
After process_e820_entry
will be executed, we will have array of the addresses which are safe for the decompressed kernel. Next we call slots_fetch_random
function for getting random item from this array:
if (slot_max == 0)
return 0;
return slots[get_random_long() % slot_max];
where get_random_long
function checks different CPU flags as X86_FEATURE_RDRAND
or X86_FEATURE_TSC
and chooses method for getting random number (it can be obtain with RDRAND instruction, Time stamp counter, programmable interval timer and etc...). After that we got random address execution of the choose_kernel_location
is finished.
Now let's back to the misc.c. After we got address for the kernel image, there need to do some checks to be sure that gotten random address is correctly aligned and address is not wrong.
After all these checks will see the familiar message:
Decompressing Linux...
and call decompress
function which will decompress the kernel. decompress
function depends on what decompression algorithm was chosen during kernel compilartion:
#ifdef CONFIG_KERNEL_GZIP
#include "../../../../lib/decompress_inflate.c"
#endif
#ifdef CONFIG_KERNEL_BZIP2
#include "../../../../lib/decompress_bunzip2.c"
#endif
#ifdef CONFIG_KERNEL_LZMA
#include "../../../../lib/decompress_unlzma.c"
#endif
#ifdef CONFIG_KERNEL_XZ
#include "../../../../lib/decompress_unxz.c"
#endif
#ifdef CONFIG_KERNEL_LZO
#include "../../../../lib/decompress_unlzo.c"
#endif
#ifdef CONFIG_KERNEL_LZ4
#include "../../../../lib/decompress_unlz4.c"
#endif
After kernel will be decompressed, the last function handle_relocations
will relocate the kernel to the address that we got from choose_kernel_location
. After that kernel relocated we return from the decompress_kernel
to the head_64.S
. The address of the kernel will be in the rax
register and we jump on it:
jmp *%rax
That's all. Now we are in the kernel!
This is the end of the fifth and the last part about linux kernel booting process. We will not see posts about kernel booting anymore (maybe only updates in this and previous posts), but there will be many posts about other kernel internals.
Next chapter will be about kernel initialization and we will see the first steps in the linux kernel initialization code.
If you will have any questions or suggestions write me a comment or ping me in 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.