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Applies to SUSE Linux Enterprise Desktop 15 SP6

18 Kexec and Kdump

Kexec is a tool to boot to another kernel from the currently running one. You can perform faster system reboots without any hardware initialization. You can also prepare the system to boot to another kernel if the system crashes.

18.1 Introduction

With Kexec, you can replace the running kernel with another one without a hard reboot. The tool is useful for several reasons:

  • Faster system rebooting

    If you need to reboot the system frequently, Kexec can save you significant time.

  • Avoiding unreliable firmware and hardware

    Computer hardware is complex and serious problems may occur during the system start-up. You cannot always replace unreliable hardware immediately. Kexec boots the kernel to a controlled environment with the hardware already initialized. The risk of unsuccessful system start is then minimized.

  • Saving the dump of a crashed kernel

    Kexec preserves the contents of the physical memory. After the production kernel fails, the capture kernel (an additional kernel running in a reserved memory range) saves the state of the failed kernel. The saved image can help you with the subsequent analysis.

  • Booting without GRUB 2 configuration

    When the system boots a kernel with Kexec, it skips the boot loader stage. The normal booting procedure can fail because of an error in the boot loader configuration. With Kexec, you do not depend on a working boot loader configuration.

18.2 Required packages

To use Kexec on SUSE® Linux Enterprise Desktop to speed up reboots or avoid potential hardware problems, make sure that the package kexec-tools is installed. It contains a script called kexec-bootloader, which reads the boot loader configuration and runs Kexec using the same kernel options as the normal boot loader.

To set up an environment that helps you obtain debug information in case of a kernel crash, make sure that the package makedumpfile is installed.

The preferred method of using Kdump in SUSE Linux Enterprise Desktop is through the YaST Kdump module. To use the YaST module, make sure that the package yast2-kdump is installed.

18.3 Kexec internals

The most important component of Kexec is the /sbin/kexec command. You can load a kernel with Kexec in two different ways:

  • Load the kernel to the address space of a production kernel for a regular reboot:

    # kexec -l KERNEL_IMAGE

    You can later boot to this kernel with kexec -e.

  • Load the kernel to a reserved area of memory:

    # kexec -p KERNEL_IMAGE

    This kernel is booted automatically when the system crashes.

To boot another kernel and preserve the data of the production kernel when the system crashes, you need to reserve a dedicated area of the system memory. The production kernel never loads to this area because it must be always available. It is used for the capture kernel so that the memory pages of the production kernel can be preserved.

To reserve the area, append the option crashkernel to the boot command line of the production kernel. To determine the necessary values for crashkernel, follow the instructions in Section 18.4, “Calculating crashkernel allocation size”.

This is not a parameter of the capture kernel. The capture kernel does not use Kexec.

The capture kernel is loaded to the reserved area and waits for the kernel to crash. Then, Kdump tries to invoke the capture kernel because the production kernel is no longer reliable at this stage. This means that even Kdump can fail.

To load the capture kernel, you need to include the kernel boot parameters. In most cases, the initial RAM file system is used for booting. You can specify it with --initrd=FILENAME. With --append=CMDLINE, you append options to the command line of the kernel to boot.

It is required to include the command line of the production kernel. You can simply copy the command line with --append="$(cat /proc/cmdline)" or add more options with --append="$(cat /proc/cmdline) more_options".

For example, to load the /boot/vmlinuz-6.4.0-150600.9-default kernel image with the command line of the currently running production kernel and the /boot/initrd file, run the following command:

#  kexec -l /boot/vmlinuz-6.4.0-150600.9-default \
 --append="$(cat /proc/cmdline)" --initrd=/boot/initrd

You can always unload the previously loaded kernel. To unload a kernel that was loaded with the -l option, use the kexec -u command. To unload a crash kernel loaded with the -p option, use kexec -p -u command.

18.4 Calculating crashkernel allocation size

To use Kexec with a capture kernel and to use Kdump in any way, RAM needs to be allocated for the capture kernel. The allocation size depends on the expected hardware configuration of the computer, therefore you need to specify it.

The allocation size also depends on the hardware architecture of your computer. Make sure to follow the procedure intended for your system architecture.

Procedure 18.1: Allocation size on AMD64/Intel 64
  1. To find out the base value for the computer, run the following command:

    # kdumptool calibrate
    Total: 49074
    Low: 72
    High: 180
    MinLow: 72
    MaxLow: 3085
    MinHigh: 0
    MaxHigh: 45824

    All values are given in megabytes.

  2. Take note of the values of Low and High.

    Note
    Note: Significance of Low and High values

    On AMD64/Intel 64 computers, the High value stands for the memory reservation for all available memory. The Low value stands for the memory reservation in the DMA32 zone, that is, all the memory up to the 4 GB mark.

    SIZE_LOW is the amount of memory required by 32-bit-only devices. The kernel allocates 64M for DMA32 bounce buffers. If your server does not have any 32-bit-only devices, everything should work with the default allocation of 72M for SIZE_LOW. A possible exception to this is on NUMA machines, which may make it appear that more Low memory is needed. The Kdump kernel may be booted with numa=off to make sure normal kernel allocations do not use Low memory.

  3. Adapt the High value from the previous step for the number of LUN kernel paths (paths to storage devices) attached to the computer. A sensible value in megabytes can be calculated using this formula:

    SIZE_HIGH = RECOMMENDATION + (LUNs / 2)

    The following parameters are used in this formula:

    • SIZE_HIGH.  The resulting value for High.

    • RECOMMENDATION.  The value recommended by kdumptool calibrate for High.

    • LUNs.  The maximum number of LUN kernel paths that you expect to ever create on the computer. Exclude multipath devices from this number, as these are ignored. To get the current number of LUNs available on your system, run the following command:

      >  cat /proc/scsi/scsi | grep Lun | wc -l
  4. If the drivers for your device make many reservations in the DMA32 zone, the Low value also needs to be adjusted. However, there is no simple formula to calculate these. Finding the right size can therefore be a process of trial and error.

    For the beginning, use the Low value recommended by kdumptool calibrate.

  5. The values now need to be set in the correct location.

    If you are changing the kernel command line directly

    Append the following kernel option to your boot loader configuration:

    crashkernel=SIZE_HIGH,high crashkernel=SIZE_LOW,low

    Replace the placeholders SIZE_HIGH and SIZE_LOW with the appropriate value from the previous steps and append the letter M (for megabytes).

    As an example, the following is valid:

    crashkernel=36M,high crashkernel=72M,low
    If you are using the YaST GUI:

    Set Kdump Low Memory to the determined Low value.

    Set Kdump High Memory to the determined High value.

    If you are using the YaST command line interface:

    Use the following command:

    # yast kdump startup enable alloc_mem=LOW,HIGH

    Replace LOW with the determined Low value. Replace HIGH with the determined HIGH value.

Tip
Tip: Excluding unused and inactive CCW devices on IBM Z

Depending on the number of available devices the calculated amount of memory specified by the crashkernel kernel parameter may not be sufficient. Instead of increasing the value, you may alternatively limit the amount of devices visible to the kernel. This lowers the required amount of memory for the crashkernel setting.

  1. To ignore devices you can run the cio_ignore tool to generate an appropriate stanza to ignore all devices, except the ones currently active or in use.

    > sudo cio_ignore -u -k
    cio_ignore=all,!da5d,!f500-f502

    When you run cio_ignore -u -k, the blocklist becomes active and replaces any existing blocklist immediately. Unused devices are not being purged, so they still appear in the channel subsystem. But adding new channel devices (via CP ATTACH under z/VM or dynamic I/O configuration change in LPAR) treats them as blocked. To prevent this, preserve the original setting by running sudo cio_ignore -l first and reverting to that state after running cio_ignore -u -k. As an alternative, add the generated stanza to the regular kernel boot parameters.

  2. Now add the cio_ignore kernel parameter with the stanza from above to KDUMP_CMDLINE_APPEND in /etc/sysconfig/kdump, for example:

    KDUMP_COMMANDLINE_APPEND="cio_ignore=all,!da5d,!f500-f502"
  3. Activate the setting by restarting kdump:

    systemctl restart kdump.service

18.5 Basic Kexec usage

To use Kexec, ensure the respective service is enabled and running:

  • Make sure the Kexec service is loaded at system start:

    > sudo systemctl enable kexec-load.service
  • Make sure the Kexec service is running:

    > sudo systemctl start kexec-load.service

To verify if your Kexec environment works properly, try rebooting into a new Kernel with Kexec. Make sure no users are currently logged in and no important services are running on the system. Then run the following command:

systemctl kexec

The new kernel previously loaded to the address space of the older kernel rewrites it and takes control immediately. It displays the usual start-up messages. When the new kernel boots, it skips all hardware and firmware checks. Make sure no warning messages appear.

Tip
Tip: Using Kexec with the reboot command

To make reboot use Kexec rather than performing a regular reboot, run the following command:

ln -s /usr/lib/systemd/system/kexec.target /etc/systemd/system/reboot.target

You can revert this at any time by deleting etc/systemd/system/reboot.target.

18.6 How to configure Kexec for routine reboots

Kexec is often used for frequent reboots. For example, if it takes a long time to run through the hardware detection routines or if the start-up is not reliable.

The firmware and the boot loader are not used when the system reboots with Kexec. Any changes you make to the boot loader configuration are ignored until the computer performs a hard reboot.

18.7 Basic Kdump configuration

You can use Kdump to save kernel dumps. If the kernel crashes, it is useful to copy the memory image of the crashed environment to the file system. You can then debug the dump file to find the cause of the kernel crash. This is called core dump.

Kdump works similarly to Kexec (see Chapter 18, Kexec and Kdump). The capture kernel is executed after the running production kernel crashes. The difference is that Kexec replaces the production kernel with the capture kernel. With Kdump, you still have access to the memory space of the crashed production kernel. You can save the memory snapshot of the crashed kernel in the environment of the Kdump kernel.

Tip
Tip: Dumps over network

In environments with limited local storage, you need to set up kernel dumps over the network. Kdump supports configuring the specified network interface and bringing it up via initrd. Both LAN and VLAN interfaces are supported. Specify the network interface and the mode (DHCP or static) either with YaST, or using the KDUMP_NETCONFIG option in the /etc/sysconfig/kdump file.

Important
Important: Target file system for Kdump must be mounted during configuration

When configuring Kdump, you can specify a location to which the dumped images are saved (default: /var/crash). This location must be mounted when configuring Kdump, otherwise the configuration fails.

18.7.1 Manual Kdump configuration

Kdump reads its configuration from the /etc/sysconfig/kdump file. To make sure that Kdump works on your system, its default configuration is sufficient. To use Kdump with the default settings, follow these steps:

  1. Determine the amount of memory needed for Kdump by following the instructions in Section 18.4, “Calculating crashkernel allocation size”. Make sure to set the kernel parameter crashkernel.

  2. Reboot the computer.

  3. Enable the Kdump service:

    # systemctl enable kdump
  4. You can edit the options in /etc/sysconfig/kdump. Reading the comments helps you understand the meaning of individual options.

  5. Execute the init script once with sudo systemctl start kdump, or reboot the system.

After configuring Kdump with the default values, check if it works as expected. Make sure that no users are currently logged in and no important services are running on your system. Then follow these steps:

  1. Switch to the rescue target with systemctl isolate rescue.target

  2. Restart the Kdump service:

    # systemctl start kdump
  3. Unmount all the disk file systems except the root file system with:

    # umount -a
  4. Remount the root file system in read-only mode:

    # mount -o remount,ro /
  5. Invoke a kernel panic with the procfs interface to Magic SysRq keys:

    # echo c > /proc/sysrq-trigger
Important
Important: Size of kernel dumps

The KDUMP_KEEP_OLD_DUMPS option controls the number of preserved kernel dumps (default is 5). Without compression, the size of the dump can take up to the size of the physical memory or RAM. Make sure you have sufficient space on the /var partition.

The capture kernel boots and the crashed kernel memory snapshot is saved to the file system. The save path is given by the KDUMP_SAVEDIR option and it defaults to /var/crash. If KDUMP_IMMEDIATE_REBOOT is set to yes , the system automatically reboots the production kernel. Log in and check that the dump has been created under /var/crash.

18.7.2 YaST configuration

To configure Kdump with YaST, you need to install the yast2-kdump package. Then either start the Kernel Kdump module in the System category of YaST Control Center, or enter yast2 kdump in the command line as root.

Screenshot of the YaST Kdump Module
Figure 18.1: YaST Kdump module: start-up page

In the Start-Up window, select Enable Kdump.

The values for Kdump Memory are automatically generated the first time you open the window. However, that does not mean that they are always sufficient. To set the right values, follow the instructions in Section 18.4, “Calculating crashkernel allocation size”.

Important
Important: After hardware changes, set Kdump memory values again

If you have set up Kdump on a computer and later decide to change the amount of RAM or hard disks available to it, YaST continues to display and use outdated memory values.

To work around this, determine the necessary memory again, as described in Section 18.4, “Calculating crashkernel allocation size”. Then set it manually in YaST.

Click Dump Filtering in the left pane, and check what pages to include in the dump. You do not need to include the following memory content to be able to debug kernel problems:

  • Pages filled with zero

  • Cache pages

  • User data pages

  • Free pages

In the Dump Target window, select the type of the dump target and the URL where you want to save the dump. If you selected a network protocol, such as FTP or SSH, you need to enter relevant access information as well.

Tip
Tip: Sharing the dump directory with other applications

It is possible to specify a path for saving Kdump dumps where other applications also save their dumps. When cleaning its old dump files, Kdump safely ignores other applications' dump files.

Fill the Email Notification window information if you want Kdump to inform you about its events via e-mail and confirm your changes with OK after fine tuning Kdump in the Expert Settings window. Kdump is now configured.

18.7.3 Kdump over SSH

Dump files usually contain sensitive data which should be protected from unauthorized disclosure. To allow transmission of such data over an insecure network, Kdump can save dump files to a remote machine using the SSH protocol.

  1. The target host identity must be known to Kdump. This is needed to ensure that sensitive data is never sent to an imposter. When Kdump generates a new initrd, it runs ssh-keygen -F TARGET_HOST to query the target host's identity. This works only if TARGET_HOST public key is already known. An easy way to achieve that is to make an SSH connection to TARGET_HOST as root on the Kdump host.

  2. Kdump must be able to authenticate to the target machine. Only public key authentication is currently available. By default, Kdump uses root's private key, but it is advisable to make a separate key for Kdump. This can be done with ssh-keygen:

    1. # ssh-keygen -f ~/.ssh/kdump_key
    2. Press Enter when prompted for passphrase (that is, do not use any passphrase).

    3. Open /etc/sysconfig/kdump and set KDUMP_SSH_IDENTITY to kdump_key. You can use full path to the file if it is not placed under ~/.ssh.

  3. Set up the Kdump SSH key to authorize logins to the remote host.

    # ssh-copy-id -i ~/.ssh/kdump_key TARGET_HOST
  4. Set up KDUMP_SAVEDIR. There are two options:

    Secure File Transfer Protocol (SFTP)

    SFTP is the preferred method for transmitting files over SSH. The target host must enable the SFTP subsystem (SUSE Linux Enterprise Desktop default). Example:

    KDUMP_SAVEDIR=sftp://TARGET_HOST/path/to/dumps
    Secure Shell protocol (SSH)

    Some other distributions use SSH to run certain commands on the target host. SUSE Linux Enterprise Desktop can also use this method. The Kdump user on the target host must have a login shell that can execute these commands: mkdir, dd and mv. Example:

    KDUMP_SAVEDIR=ssh://TARGET_HOST/path/to/dumps
  5. Restart the Kdump service to use the new configuration.

18.8 Analyzing the crash dump

After you obtain the dump, it is time to analyze it. There are several options.

The original tool to analyze the dumps is GDB. You can even use it in the latest environments, although it has several disadvantages and limitations:

  • GDB was not specifically designed to debug kernel dumps.

  • GDB does not support ELF64 binaries on 32-bit platforms.

  • GDB does not understand other formats than ELF dumps (it cannot debug compressed dumps).

That is why the crash utility was implemented. It analyzes crash dumps and debugs the running system as well. It provides functionality specific to debugging the Linux kernel and is much more suitable for advanced debugging.

To debug the Linux kernel, install its debugging information package, too. Check if the package is installed on your system with:

> zypper se kernel | grep debug
Important
Important: Repository for packages with debugging information

If you subscribed your system for online updates, you can find debuginfo packages in the *-Debuginfo-Updates online installation repository relevant for SUSE Linux Enterprise Desktop 15 SP6. Use YaST to enable the repository.

To open the captured dump in crash on the machine that produced the dump, use a command like this:

crash /boot/vmlinux-6.4.0-150600.9-default.gz \
/var/crash/2024-04-23-11\:17/vmcore

The first parameter represents the kernel image. The second parameter is the dump file captured by Kdump. You can find this file under /var/crash by default.

Tip
Tip: Getting basic information from a kernel crash dump

SUSE Linux Enterprise Desktop ships with the utility kdumpid (included in a package with the same name) for identifying unknown kernel dumps. It can be used to extract basic information such as architecture and kernel release. It supports lkcd, diskdump, Kdump files and ELF dumps. When called with the -v switch it tries to extract additional information such as machine type, kernel banner string and kernel configuration flavor.

18.8.1 Kernel binary formats

The Linux kernel comes in Executable and Linkable Format (ELF). This file is called vmlinux and is directly generated in the compilation process. Not all boot loaders support ELF binaries, especially on the AMD64/Intel 64 architecture. The following solutions exist on different architectures supported by SUSE® Linux Enterprise Desktop.

18.8.1.1 AMD64/Intel 64

Kernel packages for AMD64/Intel 64 from SUSE contain two kernel files: vmlinuz and vmlinux.gz.

  • vmlinuz This is the file executed by the boot loader.

    The Linux kernel consists of two parts: the kernel itself (vmlinux) and the setup code run by the boot loader. These two parts are linked together to create vmlinuz (note the distinction: z compared to x).

    In the kernel source tree, the file is called bzImage.

  • vmlinux.gz This is a compressed ELF image that can be used by crash and GDB. The ELF image is never used by the boot loader itself on AMD64/Intel 64. Therefore, only a compressed version is shipped.

18.8.1.2 POWER

The yaboot boot loader on POWER also supports loading ELF images, but not compressed ones. In the POWER kernel package, there is an ELF Linux kernel file vmlinux. Considering crash, this is the easiest architecture.

If you decide to analyze the dump on another machine, you must check both the architecture of the computer and the files necessary for debugging.

You can analyze the dump on another computer only if it runs a Linux system of the same architecture. To check the compatibility, use the command uname -i on both computers and compare the outputs.

If you are going to analyze the dump on another computer, you also need the appropriate files from the kernel and kernel debug packages.

  1. Put the kernel dump, the kernel image from /boot, and its associated debugging info file from /usr/lib/debug/boot into a single empty directory.

  2. Additionally, copy the kernel modules from /lib/modules/$(uname -r)/kernel/ and the associated debug info files from /usr/lib/debug/lib/modules/$(uname -r)/kernel/ into a subdirectory named modules.

  3. In the directory with the dump, the kernel image, its debug info file, and the modules subdirectory, start the crash utility:

    > crash VMLINUX-VERSION vmcore

Regardless of the computer on which you analyze the dump, the crash utility produces output similar to this:

> crash /boot/vmlinux-6.4.0-150600.9-default.gz \
/var/crash/2024-04-23-11\:17/vmcore
crash 7.2.1
Copyright (C) 2002-2017  Red Hat, Inc.
Copyright (C) 2004, 2005, 2006, 2010  IBM Corporation
Copyright (C) 1999-2006  Hewlett-Packard Co
Copyright (C) 2005, 2006, 2011, 2012  Fujitsu Limited
Copyright (C) 2006, 2007  VA Linux Systems Japan K.K.
Copyright (C) 2005, 2011  NEC Corporation
Copyright (C) 1999, 2002, 2007  Silicon Graphics, Inc.
Copyright (C) 1999, 2000, 2001, 2002  Mission Critical Linux, Inc.
This program is free software, covered by the GNU General Public License,
and you are welcome to change it and/or distribute copies of it under
certain conditions.  Enter "help copying" to see the conditions.
This program has absolutely no warranty.  Enter "help warranty" for details.

GNU gdb (GDB) 7.6
Copyright (C) 2013 Free Software Foundation, Inc.
License GPLv3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html>
This is free software: you are free to change and redistribute it.
There is NO WARRANTY, to the extent permitted by law.  Type "show copying"
and "show warranty" for details.
This GDB was configured as "x86_64-unknown-linux-gnu".

      KERNEL: /boot/vmlinux-6.4.0-150600.9-default.gz
   DEBUGINFO: /usr/lib/debug/boot/vmlinux-6.4.0-150600.9-default.debug
    DUMPFILE: /var/crash/2024-04-23-11:17/vmcore
        CPUS: 2
        DATE: Thu Apr 23 13:17:01 2024
      UPTIME: 00:10:41
LOAD AVERAGE: 0.01, 0.09, 0.09
       TASKS: 42
    NODENAME: eros
     RELEASE: 6.4.0-150600.9-default
     VERSION: #1 SMP 2024-03-31 14:50:44 +0200
     MACHINE: x86_64  (2999 Mhz)
      MEMORY: 16 GB
       PANIC: "SysRq : Trigger a crashdump"
         PID: 9446
     COMMAND: "bash"
        TASK: ffff88003a57c3c0  [THREAD_INFO: ffff880037168000]
         CPU: 1
       STATE: TASK_RUNNING (SYSRQ)
crash> 

The command output prints first useful data: There were 42 tasks running at the moment of the kernel crash. The cause of the crash was a SysRq trigger invoked by the task with PID 9446. It was a Bash process because the echo that has been used is an internal command of the Bash shell.

The crash utility builds upon GDB and provides many additional commands. If you enter bt without any parameters, the backtrace of the task running at the moment of the crash is printed:

crash> bt
PID: 9446   TASK: ffff88003a57c3c0  CPU: 1   COMMAND: "bash"
 #0 [ffff880037169db0] crash_kexec at ffffffff80268fd6
 #1 [ffff880037169e80] __handle_sysrq at ffffffff803d50ed
 #2 [ffff880037169ec0] write_sysrq_trigger at ffffffff802f6fc5
 #3 [ffff880037169ed0] proc_reg_write at ffffffff802f068b
 #4 [ffff880037169f10] vfs_write at ffffffff802b1aba
 #5 [ffff880037169f40] sys_write at ffffffff802b1c1f
 #6 [ffff880037169f80] system_call_fastpath at ffffffff8020bfbb
    RIP: 00007fa958991f60  RSP: 00007fff61330390  RFLAGS: 00010246
    RAX: 0000000000000001  RBX: ffffffff8020bfbb  RCX: 0000000000000001
    RDX: 0000000000000002  RSI: 00007fa959284000  RDI: 0000000000000001
    RBP: 0000000000000002   R8: 00007fa9592516f0   R9: 00007fa958c209c0
    R10: 00007fa958c209c0  R11: 0000000000000246  R12: 00007fa958c1f780
    R13: 00007fa959284000  R14: 0000000000000002  R15: 00000000595569d0
    ORIG_RAX: 0000000000000001  CS: 0033  SS: 002b
crash> 

Now it is clear what happened: The internal echo command of Bash shell sent a character to /proc/sysrq-trigger. After the corresponding handler recognized this character, it invoked the crash_kexec() function. This function called panic() and Kdump saved a dump.

In addition to the basic GDB commands and the extended version of bt, the crash utility defines other commands related to the structure of the Linux kernel. These commands understand the internal data structures of the Linux kernel and present their contents in a human readable format. For example, you can list the tasks running at the moment of the crash with ps. With sym, you can list all the kernel symbols with the corresponding addresses, or inquire an individual symbol for its value. With files, you can display all the open file descriptors of a process. With kmem, you can display details about the kernel memory usage. With vm, you can inspect the virtual memory of a process, even at the level of individual page mappings. The list of useful commands is long, and many of these accept a wide range of options.

The commands that we mentioned reflect the functionality of the common Linux commands, such as ps and lsof. To find out the exact sequence of events with the debugger, you need to know how to use GDB and to have strong debugging skills. Both of these are out of the scope of this document. Additionally, you need to understand the Linux kernel. Several useful reference information sources are given at the end of this document.

18.9 Advanced Kdump configuration

The configuration for Kdump is stored in /etc/sysconfig/kdump. You can also use YaST to configure it. Kdump configuration options are available under System › Kernel Kdump in YaST Control Center. The following Kdump options may be useful for you.

You can change the directory for the kernel dumps with the KDUMP_SAVEDIR option. Keep in mind that the size of kernel dumps can be large. Kdump refuses to save the dump if the free disk space, subtracted by the estimated dump size, drops below the value specified by the KDUMP_FREE_DISK_SIZE option. KDUMP_SAVEDIR understands the URL format PROTOCOL://SPECIFICATION, where PROTOCOL is one of file, ftp, sftp, nfs or cifs, and specification varies for each protocol. For example, to save kernel dump on an FTP server, use the following URL as a template: ftp://username:password@ftp.example.com:123/var/crash.

Kernel dumps are large and contain many pages that are not necessary for analysis. With KDUMP_DUMPLEVEL option, you can omit such pages. The option understands numeric value between 0 and 31. If you specify 0, the dump size is the largest. If you specify 31, it produces the smallest dump. For a complete table of possible values, see the manual page of kdump (man 7 kdump).

Sometimes it is useful to make the size of the kernel dump smaller. For example, you can do so to transfer the dump over the network or to save disk space in the dump directory. This can be done with KDUMP_DUMPFORMAT set to compressed. The crash utility supports dynamic decompression of the compressed dumps.

Important
Important: Changes to the Kdump configuration file

After making changes to the /etc/sysconfig/kdump file, you need to run systemctl restart kdump.service. Otherwise, the changes only take effect next time you reboot the system.

18.10 More information

There is no single comprehensive reference to Kexec and Kdump usage. However, there are helpful resources that deal with certain aspects:

For more details on crash dump analysis and debugging tools, use the following resources:

  • In addition to the info page of GDB (info gdb), there are printable guides at https://sourceware.org/gdb/documentation/ .

  • The crash utility features a comprehensive online help. Use help COMMAND to display the online help for command.

  • If you have the necessary Perl skills, you can use Alicia to make the debugging easier. This Perl-based front-end to the crash utility can be found at https://alicia.sourceforge.net/ .

  • If you prefer to use Python instead, you should install Pykdump. This package helps you control GDB through Python scripts.

  • A comprehensive overview of the Linux kernel internals is given in Understanding the Linux Kernel by Daniel P. Bovet and Marco Cesati (ISBN 978-0-596-00565-8).