tests/qemu-iotests/302 - qemu - Git at Google

 #!/usr/bin/env python3
 # group: quick
 #
 # Tests converting qcow2 compressed to NBD
 #
 # Copyright (c) 2020 Nir Soffer <nirsof@gmail.com>
 #
 # This program is free software; you can redistribute it and/or modify
 # it under the terms of the GNU General Public License as published by
 # the Free Software Foundation; either version 2 of the License, or
 # (at your option) any later version.
 #
 # This program is distributed in the hope that it will be useful,
 # but WITHOUT ANY WARRANTY; without even the implied warranty of
 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 # GNU General Public License for more details.
 #
 # You should have received a copy of the GNU General Public License
 # along with this program.  If not, see <http://www.gnu.org/licenses/>.
 #
 # owner=nirsof@gmail.com

 import io
 import tarfile

 import iotests

 from iotests import (
     file_path,
     qemu_img,
     qemu_img_check,
     qemu_img_create,
     qemu_img_log,
     qemu_img_measure,
     qemu_io,
     qemu_nbd_popen,
     img_info_log,
 )

 iotests.script_initialize(supported_fmts=["qcow2"])

 # Create source disk. Using qcow2 to enable strict comparing later, and
 # avoid issues with random filesystem on CI environment.
 src_disk = file_path("disk.qcow2")
 qemu_img_create("-f", iotests.imgfmt, src_disk, "1g")
 qemu_io("-f", iotests.imgfmt, "-c", "write 1m 64k", src_disk)

 # The use case is writing qcow2 image directly into an ova file, which
 # is a tar file with specific layout. This is tricky since we don't know the
 # size of the image before compressing, so we have to do:
 # 1. Add an ovf file.
 # 2. Find the offset of the next member data.
 # 3. Make room for image data, allocating for the worst case.
 # 4. Write compressed image data into the tar.
 # 5. Add a tar entry with the actual image size.
 # 6. Shrink the tar to the actual size, aligned to 512 bytes.

 tar_file = file_path("test.ova")

 with tarfile.open(tar_file, "w") as tar:

     # 1. Add an ovf file.

     ovf_data = b"<xml/>"
     ovf = tarfile.TarInfo("vm.ovf")
     ovf.size = len(ovf_data)
     tar.addfile(ovf, io.BytesIO(ovf_data))

     # 2. Find the offset of the next member data.

     offset = tar.fileobj.tell() + 512

     # 3. Make room for image data, allocating for the worst case.

     measure = qemu_img_measure("-O", "qcow2", src_disk)
     tar.fileobj.truncate(offset + measure["required"])

     # 4. Write compressed image data into the tar.

     nbd_sock = file_path("nbd-sock", base_dir=iotests.sock_dir)
     nbd_uri = "nbd+unix:///exp?socket=" + nbd_sock

     # Use raw format to allow creating qcow2 directly into tar file.
     with qemu_nbd_popen(
             "--socket", nbd_sock,
             "--export-name", "exp",
             "--format", "raw",
             "--offset", str(offset),
             tar_file):

         iotests.log("=== Target image info ===")
         # Not img_info_log as it enforces imgfmt, but now we print info on raw
         qemu_img_log("info", nbd_uri)

         qemu_img(
             "convert",
             "-f", iotests.imgfmt,
             "-O", "qcow2",
             "-c",
             src_disk,
             nbd_uri)

         iotests.log("=== Converted image info ===")
         img_info_log(nbd_uri)

         iotests.log("=== Converted image check ===")
         qemu_img_log("check", nbd_uri)

         iotests.log("=== Comparing to source disk ===")
         qemu_img_log("compare", src_disk, nbd_uri)

         actual_size = qemu_img_check(nbd_uri)["image-end-offset"]

     # 5. Add a tar entry with the actual image size.

     disk = tarfile.TarInfo("disk")
     disk.size = actual_size
     tar.addfile(disk)

     # 6. Shrink the tar to the actual size, aligned to 512 bytes.

     tar_size = offset + (disk.size + 511) & ~511
     tar.fileobj.seek(tar_size)
     tar.fileobj.truncate(tar_size)

 with tarfile.open(tar_file) as tar:
     members = [{"name": m.name, "size": m.size, "offset": m.offset_data}
                for m in tar]
     iotests.log("=== OVA file contents ===")
     iotests.log(members)
	#!/usr/bin/env python3
	# group: quick
	#
	# Tests converting qcow2 compressed to NBD
	#
	# Copyright (c) 2020 Nir Soffer <nirsof@gmail.com>
	#
	# This program is free software; you can redistribute it and/or modify
	# it under the terms of the GNU General Public License as published by
	# the Free Software Foundation; either version 2 of the License, or
	# (at your option) any later version.
	#
	# This program is distributed in the hope that it will be useful,
	# but WITHOUT ANY WARRANTY; without even the implied warranty of
	# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	# GNU General Public License for more details.
	#
	# You should have received a copy of the GNU General Public License
	# along with this program. If not, see <http://www.gnu.org/licenses/>.
	#
	# owner=nirsof@gmail.com

	import io
	import tarfile

	import iotests

	from iotests import (
	file_path,
	qemu_img,
	qemu_img_check,
	qemu_img_create,
	qemu_img_log,
	qemu_img_measure,
	qemu_io,
	qemu_nbd_popen,
	img_info_log,
	)

	iotests.script_initialize(supported_fmts=["qcow2"])

	# Create source disk. Using qcow2 to enable strict comparing later, and
	# avoid issues with random filesystem on CI environment.
	src_disk = file_path("disk.qcow2")
	qemu_img_create("-f", iotests.imgfmt, src_disk, "1g")
	qemu_io("-f", iotests.imgfmt, "-c", "write 1m 64k", src_disk)

	# The use case is writing qcow2 image directly into an ova file, which
	# is a tar file with specific layout. This is tricky since we don't know the
	# size of the image before compressing, so we have to do:
	# 1. Add an ovf file.
	# 2. Find the offset of the next member data.
	# 3. Make room for image data, allocating for the worst case.
	# 4. Write compressed image data into the tar.
	# 5. Add a tar entry with the actual image size.
	# 6. Shrink the tar to the actual size, aligned to 512 bytes.

	tar_file = file_path("test.ova")

	with tarfile.open(tar_file, "w") as tar:

	# 1. Add an ovf file.

	ovf_data = b"<xml/>"
	ovf = tarfile.TarInfo("vm.ovf")
	ovf.size = len(ovf_data)
	tar.addfile(ovf, io.BytesIO(ovf_data))

	# 2. Find the offset of the next member data.

	offset = tar.fileobj.tell() + 512

	# 3. Make room for image data, allocating for the worst case.

	measure = qemu_img_measure("-O", "qcow2", src_disk)
	tar.fileobj.truncate(offset + measure["required"])

	# 4. Write compressed image data into the tar.

	nbd_sock = file_path("nbd-sock", base_dir=iotests.sock_dir)
	nbd_uri = "nbd+unix:///exp?socket=" + nbd_sock

	# Use raw format to allow creating qcow2 directly into tar file.
	with qemu_nbd_popen(
	"--socket", nbd_sock,
	"--export-name", "exp",
	"--format", "raw",
	"--offset", str(offset),
	tar_file):

	iotests.log("=== Target image info ===")
	# Not img_info_log as it enforces imgfmt, but now we print info on raw
	qemu_img_log("info", nbd_uri)

	qemu_img(
	"convert",
	"-f", iotests.imgfmt,
	"-O", "qcow2",
	"-c",
	src_disk,
	nbd_uri)

	iotests.log("=== Converted image info ===")
	img_info_log(nbd_uri)

	iotests.log("=== Converted image check ===")
	qemu_img_log("check", nbd_uri)

	iotests.log("=== Comparing to source disk ===")
	qemu_img_log("compare", src_disk, nbd_uri)

	actual_size = qemu_img_check(nbd_uri)["image-end-offset"]

	# 5. Add a tar entry with the actual image size.

	disk = tarfile.TarInfo("disk")
	disk.size = actual_size
	tar.addfile(disk)

	# 6. Shrink the tar to the actual size, aligned to 512 bytes.

	tar_size = offset + (disk.size + 511) & ~511
	tar.fileobj.seek(tar_size)
	tar.fileobj.truncate(tar_size)

	with tarfile.open(tar_file) as tar:
	members = [{"name": m.name, "size": m.size, "offset": m.offset_data}
	for m in tar]
	iotests.log("=== OVA file contents ===")
	iotests.log(members)