[RFC 0/6] Bootloader based hibernation
Vivek Kumar
quic_vivekuma at quicinc.com
Wed May 18 00:48:35 PDT 2022
Kernel Hibernation
Linux Kernel has been already supporting hibernation, a process which
involves freezing of all userspace tasks, followed by quiescing of all
kernel device drivers and then a DDR snapshot is taken which is saved
to disc-swap partition, after the save, the system can either shutdown
or continue further. Generally during the next power cycle when kernel
boots and after probing almost all of the drivers, in the late_init()
part, it checks if a hibernation image is present in the specified swap
slot, if a valid hibernation image is found, it superimposes the currently
executing Kernel with an older kernel from the snapshot, moving further,
it calls the restore of the drivers and unfreezes the userspace tasks.
CONFIG_HIBERNATION and a designated swap partition needs to be present
for to enable Hibernation.
Bootloader Based Hibernation:
Automotive usecases require better boot KPIs, Hence we are proposing a
bootloader based hibernation restore. Purpose of bootloader based
hibernation is to improve the overall boot time till the first display
frame is seen on the screen or a camera application can be launched from
userspace after the power on reset key is pressed. This RFC patchset
implements a slightly tweaked version of hibernation in which the
restoration of an older snapshot into DDR is being carried out from the
bootloader (ABL) itself, by doing this we are saving some time
(1 second measured on msm-4.14 Kernel) by not running a
temporary kernel and figuring out the hibernation image at late_init().
In order to achieve the same bootloader checks for the hibernation
image at a very early stage from swap partition, it parses the image and
loads it in the DDR instead of loading boot image form boot partition.
Since we are not running the temporary kernel,which would have done some
basic ARM related setup like, MMU enablement, EL2 setup, CPU setup etc,
entry point into hibernation snapshot image directly from bootloader is
different, on similar lines, all device drivers are now re-programming
the IO-mapped registers as part of the restore callback (which is
triggered from the hibernation framework) to bring back the HW/SW sync.
Other factors like, read-speed of the secondary storage device and
organization of the hibernation image in the swap partition effects the
total image restore time and the overall boot time. In our current
implementation we have serialized the allocation of swap-partition's slots
in kernel, so when hibernation image is being saved to disc, each page is
not scattered across various swap-slot offsets, rather it in a serial
manner. For example, if a DDR page at Page frame number 0x8005 is
located at a swap-slot offset 50, the next valid DDR page at PFN 0x8005
will be preset at the swap-slot offset 51. With this optimization in
place, bootloader can utilize the max capacity of issuing a disc-read
for reading a bigger chunk (~50 MBs at once) from the swap slot,
and also parsing of the image becomes simpler as it is available
contiguously.
Vivek Kumar (6):
arm64: hibernate: Introduce new entry point to kernel
PM: Hibernate: Add option to disable disk offset randomization
block: gendisk: Add a new genhd capability flag
mm: swap: Add randomization check for swapon/off calls
Hibernate: Add check for pte_valid in saveable page
irqchip/gic-v3: Re-init GIC hardware upon hibernation restore
Documentation/admin-guide/kernel-parameters.txt | 11 ++
arch/arm64/kernel/hibernate.c | 9 ++
drivers/irqchip/irq-gic-v3.c | 138 ++++++++++++++++-
include/linux/blkdev.h | 1 +
kernel/power/snapshot.c | 43 ++++++++
kernel/power/swap.c | 12 +++
mm/swapfile.c | 6 +-
7 files changed, 216 insertions(+), 4 deletions(-)
--
2.7.4
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