2015-03-29 16:47:30 +00:00
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Building An Image
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=================
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Now that you have diskimage-builder properly :doc:`installed <installation>`
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you can get started by building your first disk image.
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VM Image
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--------
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Our first image is going to be a bootable vm image using one of the standard
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supported distribution :doc:`elements <../elements>` (Ubuntu or Fedora).
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The following command will start our image build (distro must be either
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'ubuntu' or 'fedora'):
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::
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disk-image-create <distro> vm
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This will create a qcow2 file 'image.qcow2' which can then be booted.
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Elements
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--------
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It is important to note that we are passing in a list of
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:doc:`elements <../elements>` to disk-image-create in our above command. Elements
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are how we decide what goes into our image and what modifications will be
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performed.
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Some elements provide a root filesystem, such as the ubuntu or fedora element
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in our example above, which other elements modify to create our image. At least
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one of these 'distro elements' must be specified when performing an image
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build. It's worth pointing out that there are many distro elements (you can even
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create your own), and even multiples for some of the distros. This is because
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there are often multiple ways to install a distro which are very different.
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For example: One distro element might use a cloud image while another uses
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a package installation tool to build a root filesystem for the same distro.
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Other elements modify our image in some way. The 'vm' element in our example
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above ensures that our image has a bootloader properly installed. This is only
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needed for certain use cases and certain output formats and therefore it is
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not performed by default.
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2015-08-03 06:18:30 +00:00
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Output Formats
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--------------
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By default a qcow2 image is created by the disk-image-create command. Other
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output formats may be specified using the `-t <format>` argument. Multiple
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output formats can also be specified by comma separation. The supported output
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formats are:
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* qcow2
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* tar
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2016-12-17 21:41:14 +00:00
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* tgz
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2016-12-18 01:59:07 +00:00
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* squashfs
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2015-08-03 06:18:30 +00:00
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* vhd
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* docker
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* raw
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2015-12-15 23:45:36 +00:00
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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Disk Image Layout
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-----------------
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2017-02-03 20:09:58 +00:00
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When generating a vm block image (e.g. qcow2 or raw), by default one
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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image with one partition holding all files is created.
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The configuration is done by means of the environment variable
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2016-07-16 20:16:13 +00:00
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`DIB_BLOCK_DEVICE_CONFIG`. This variable must hold YAML structured
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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configuration data.
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The default is:
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::
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2016-07-16 20:16:13 +00:00
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DIB_BLOCK_DEVICE_CONFIG='
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2017-02-03 20:09:58 +00:00
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- local_loop:
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name: image0
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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2017-02-03 20:09:58 +00:00
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- partitioning:
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base: image0
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label: mbr
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partitions:
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- name: root
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flags: [ boot, primary ]
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size: 100%'
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2016-07-16 20:16:13 +00:00
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In general each module that depends on another module has a `base`
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element that points to the depending base.
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Limitations
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+++++++++++
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The appropriate functionality to use multiple partitions and even LVMs
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is currently under development; therefore the possible configuration
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is currently limited, but will get more flexible as soon as all the
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functionality is implemented.
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In future this will be a list of some elements, each describing one
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part of block device setup - but because currently only `local_loop`
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and `partitioning` are implemented, it contains only the configuration
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of these steps.
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Currently it is possible to create multiple local loop devices, but
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all but the `image0` will be not useable (are deleted during the
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build process).
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Currently only one partitions is used for the image. The name of this
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2017-02-03 20:09:58 +00:00
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partition must be `root`. Other partitions are created but not
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2016-07-16 20:16:13 +00:00
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used.
|
Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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Level 0
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+++++++
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Module: Local Loop
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..................
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This module generates a local image file and uses the loop device to
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create a block device from it. The symbolic name for this module is
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`local_loop`.
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Configuration options:
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name
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(mandatory) The name of the image. This is used as the name for the
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image in the file system and also as a symbolic name to be able to
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reference this image (e.g. to create a partition table on this
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disk).
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size
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(optional) The size of the disk. The size can be expressed using
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unit names like TiB (1024^4 bytes) or GB (1000^3 bytes).
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Examples: 2.5GiB, 12KB.
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If the size is not specified here, the size as given to
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disk-image-create (--image-size) or the automatically computed size
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is used.
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directory
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(optional) The directory where the image is created.
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Example:
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::
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2016-07-16 20:16:13 +00:00
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local_loop:
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name: image0
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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2016-07-16 20:16:13 +00:00
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local_loop:
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name: data_image
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size: 7.5GiB
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directory: /var/tmp
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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This creates two image files and uses the loop device to use them as
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2016-07-16 20:16:13 +00:00
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block devices. One image file called `image0` is created with
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Refactor: block-device handling (local loop)
Block device handling can be somewhat complex - especially
when taking things like md, lvm or encryption into account.
This patch factors out the creation and deletion of the local
loop image device handling into a python library.
The main propose of this patch is to implement the needed
infrastructure. Based on this, more advanced functions can be added.
Example: (advanced) partitioning, LVM, handling different boot
scenarios (BIOS, UEFI, ...), possibility of handling multiple images
(local loop image, iSCSI, physical hard disk, ...), handling of
different filesystems for different partitions / LVs.
Change-Id: Ib626b36a00f8a5dc3dbde8df3e2619a2438eaaf1
Signed-off-by: Andreas Florath <andreas@florath.net>
2016-05-21 19:32:35 +00:00
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default size in the default temp directory. The second image has the
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size of 7.5GiB and is created in the `/var/tmp` folder.
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Please note that due to current implementation restrictions it is only
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allowed to specify one local loop image.
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2016-07-16 20:16:13 +00:00
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Level 1
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+++++++
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Module: Partitioning
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....................
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This module generates partitions into existing block devices. This
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means that it is possible to take any kind of block device (e.g. LVM,
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encrypted, ...) and create partition information in it.
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The symbolic name for this module is `partitioning`.
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Currently the only partitioning layout is Master Boot Record `MBR`.
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It is possible to create primary or logical partitions or a mix of
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them. The numbering of the logical partitions will typically start
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with `5`, e.g. `/dev/vda5` for the first partition, `/dev/vda6` for
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the second and so on.
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The number of partitions created by this module is theoretical
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unlimited and it was tested with more than 1000 partitions inside one
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block device. Nevertheless the Linux kernel and different tools (like
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`parted`, `sfdisk`, `fdisk`) have some default maximum number of
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partitions that they can handle. Please consult the documentation of
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the appropriate software you plan to use and adapt the number of
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partitions.
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Partitions are created in the order they are configured. Primary
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partitions - if needed - must be first in the list.
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There are the following key / value pairs to define one disk:
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base
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(mandatory) The base device where to create the partitions in.
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label
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(mandatory) Possible values: 'mbr'
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This uses the Master Boot Record (MBR) layout for the disk.
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(There are currently plans to add GPT later on.)
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align
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(optional - default value '1MiB')
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Set the alignment of the partition. This must be a multiple of the
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block size (i.e. 512 bytes). The default of 1MiB (~ 2048 * 512
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bytes blocks) is the default for modern systems and known to
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perform well on a wide range of targets [6]. For each partition
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there might be some space that is not used - which is `align` - 512
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bytes. For the default of 1MiB exactly 1048064 bytes (= 1 MiB -
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512 byte) are not used in the partition itself. Please note that
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if a boot loader should be written to the disk or partition,
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there is a need for some space. E.g. grub needs 63 * 512 byte
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blocks between the MBR and the start of the partition data; this
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means when grub will be installed, the `align` must be set at least
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to 64 * 512 byte = 32 KiB.
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partitions
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(mandatory) A list of dictionaries. Each dictionary describes one
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partition.
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The following key / value pairs can be given for each partition:
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name
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(mandatory) The name of the partition. With the help of this name,
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the partition can later be referenced, e.g. while creating a
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file system.
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flags
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(optional) List of flags for the partition. Default: empty.
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Possible values:
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boot
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Sets the boot flag for the partition
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primary
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Partition should be a primary partition. If not set a logical
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partition will be created.
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size
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(mandatory) The size of the partition. The size can either be an
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absolute number using units like `10GiB` or `1.75TB` or relative
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(percentage) numbers: in the later case the size is calculated
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based on the remaining free space.
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Example:
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::
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2017-02-03 20:09:58 +00:00
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- partitioning:
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base: image0
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label: mbr
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partitions:
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- name: part-01
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flags: [ boot ]
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size: 1GiB
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- name: part-02
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size: 100%
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- partitioning:
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base: data_image
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label: mbr
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partitions:
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- name: data0
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size: 33%
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- name: data1
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size: 50%
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- name: data2
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size: 100%
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2016-07-16 20:16:13 +00:00
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On the `image0` two partitions are created. The size of the first is
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1GiB, the second uses the remaining free space. On the `data_image`
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three partitions are created: all are about 1/3 of the disk size.
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2015-12-15 23:45:36 +00:00
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Filesystem Caveat
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-----------------
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2016-12-08 04:59:15 +00:00
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By default, disk-image-create uses a 4k byte-to-inode ratio when
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creating the filesystem in the image. This allows large 'whole-system'
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images to utilize several TB disks without exhausting inodes. In
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contrast, when creating images intended for tenant instances, this
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ratio consumes more disk space than an end-user would expect (e.g. a
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50GB root disk has 47GB avail.). If the image is intended to run
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within a tens to hundrededs of gigabyte disk, setting the
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byte-to-inode ratio to the ext4 default of 16k will allow for more
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usable space on the instance. The default can be overridden by passing
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``--mkfs-options`` like this::
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2015-12-15 23:45:36 +00:00
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disk-image-create --mkfs-options '-i 16384' <distro> vm
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2016-12-08 04:59:15 +00:00
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You can also select a different filesystem by setting the ``FS_TYPE``
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environment variable.
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Note ``--mkfs-options`` are options passed to the mfks *driver*,
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rather than ``mkfs`` itself (i.e. after the initial `-t` argument).
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2016-01-17 11:38:59 +00:00
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Speedups
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--------
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If you have 4GB of available physical RAM (as reported by /proc/meminfo
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MemTotal), or more, diskimage-builder will create a tmpfs mount to build the
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image in. This will improve image build time by building it in RAM.
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By default, the tmpfs file system uses 50% of the available RAM.
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Therefore, the RAM should be at least the double of the minimum tmpfs
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size required.
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For larger images, when no sufficient amount of RAM is available, tmpfs
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can be disabled completely by passing --no-tmpfs to disk-image-create.
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ramdisk-image-create builds a regular image and then within that image
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creates ramdisk.
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If tmpfs is not used, you will need enough room in /tmp to store two
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uncompressed cloud images. If tmpfs is used, you would still need /tmp space
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for one uncompressed cloud image and about 20% of that image for working files.
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