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base: github:3.1.2
Branches Tags
github:main github:topic/tests-expand-autogenerated-policy github:dependabot/cargo/src/agent/tracing-667a7af472 github:dependabot/cargo/src/agent/clap-f572f62cb7 github:dependabot/cargo/src/tools/kata-ctl/toml-0.9.8 github:remove-install_go github:dependabot/cargo/src/tools/kata-ctl/strum-0.27.1 github:dependabot/cargo/src/tools/genpolicy/const_format-0.2.35 github:dependabot/cargo/src/tools/agent-ctl/toml-0.9.11spec-1.1.0 github:dependabot/cargo/src/libs/toml-1.0.3 github:dependabot/cargo/src/agent/strum-0.27.1 github:dependabot/cargo/src/agent/toml-0.9.6 github:dependabot/cargo/src/agent/const_format-0.2.35 github:dependabot/go_modules/src/runtime/k8s.io/cri-api-0.35.2 github:dependabot/github_actions/docker/build-push-action-6.19.2 github:dependabot/go_modules/src/runtime/github.com/go-openapi/errors-0.22.6 github:dependabot/cargo/src/agent/tokio-c49fc46c2e github:dependabot/cargo/src/tools/genpolicy/openssl-6888b711b6 github:dependabot/cargo/src/agent/tracing-9421c2f3ac github:topic/tests-try-crio github:osv-scanner-bump-2.3.3 github:topic/tests-lower-the-load-on-aks github:sprt/disable-pmem github:topic/ci-lower-secrets-required github:disable-guest-empty-dir github:topic/oras-cache-still-not-working github:bump-to-go-1.25 github:dependabot/go_modules/src/runtime/github.com/go-openapi/runtime-0.29.2 github:topic/re-enable-sandboxapi-tests github:topic/main-no-cache github:topic/kata-deploy-upgrade github:copilot/replace-gperf-url-with-urls github:zizmor-update-to-1.20 github:dependabot/github_actions/actions/attest-build-provenance-3.2.0 github:dependabot/github_actions/docker/login-action-3.7.0 github:stale-issues-by-date github:dependabot/github_actions/tim-actions/wip-check-1.1.0 github:dependabot/go_modules/src/runtime/github.com/containerd/containerd/api-1.9.0 github:dependabot/github_actions/actions/download-artifact-7.0.0 github:topic/arm64-increase-runner-timeout github:decouple-kernel-rootfs github:dependabot/go_modules/src/runtime/github.com/containerd/containerd/api-1.10.0 github:topic/ovmf-tdx github:dependabot/cargo/kvm-ioctls-0.24.0 github:ci-test github:topic/move-builder-images-to-quay.io github:runtime-rs-stability-test github:runtime-rs-policy-debug github:numa-topology github:topic/stability-rs github:dependabot/cargo/vmm-sys-util-0.15.0 github:dependabot/cargo/vm-memory-0.16.2 github:fupan_test github:topic/tests-experimental-force-guest-pull-test-authenticated-registries github:fupan_tests github:dependabot/cargo/src/agent/tracing-subscriber-0.3.20 github:fupan_nontee_test github:sprt-patch-2 github:sprt/test-pr-up github:sprt/cleanup-policy-settings github:fix-create-container-timeout github:zvonkok-patch-1 github:amd64-nvidia-gpu-cicd-part2 github:burgerdev/codegen-test github:kata-tests-gh-cli-trigger github:topic/wainersm-ci_setup_kubectl github:topic/wainersm/fix_coco_stability_tests github:sprt/remove-ci-env github:revert-11466-blockfile github:saul/updateimg github:sprt/fix-validate-ok-to-test github:sprt-patch-1
github:3.27.0 github:3.26.0 github:3.25.0 github:3.24.0 github:3.23.0 github:3.22.0 github:3.21.0 github:3.20.0 github:3.19.1 github:3.19.0 github:3.18.0 github:3.17.0 github:3.16.0 github:3.15.0 github:3.14.0 github:3.13.0 github:3.12.0 github:3.11.0 github:3.10.1 github:3.10.0 github:3.9.0 github:3.8.0 github:3.7.0 github:3.6.0 github:3.5.0 github:3.4.0 github:release-3.4.0 github:3.3.0-test github:3.3.0 github:CC-0.8.1 github:CC-0.8.0 github:3.2.0 github:3.3.0-alpha0 github:3.2.0-rc0 github:3.2.0-alpha4 github:CC-0.7.0 github:3.1.3 github:CC-0.6.0 github:3.2.0-alpha3 github:3.2.0-alpha2 github:3.1.2 github:3.2.0-alpha1 github:3.1.1 github:CC-0.5.0 github:3.2.0-alpha0 github:3.1.0 github:CC-0.4.0 github:3.0.2 github:3.1.0-rc0 github:CC-0.3.0 github:3.0.1 github:3.1.0-alpha1 github:CC-0.2.0 github:3.0.0 github:3.1.0-alpha0 github:2.5.2 github:3.0.0-rc1 github:3.0.0-rc0 github:3.0.0-alpha1 github:untagged-b5b6198308b02e3a2666 github:2.5.1 github:3.0.0-alpha0 github:2.5.0 github:2.4.3 github:2.5.0-rc0 github:2.4.2 github:2.5.0-alpha2 github:2.5.0-alpha1 github:2.4.1 github:2.4.0 github:2.5.0-alpha0 github:2.4.0-rc0 github:2.3.3 github:2.3.2 github:2.4.0-alpha2 github:2.3.1 github:2.4.0-alpha1 github:2.3.0 github:2.4.0-alpha0 github:2.3.0-rc1 github:2.2.3 github:2.3.0-rc0 github:2.2.2 github:2.3.0-alpha2 github:2.2.1 github:2.3.0-alpha1 github:2.3.0-alpha0 github:2.2.0 github:2.2.0-rc0 github:2.2.0-alpha1 github:2.1.1 github:2.2.0-alpha0 github:2.1.0 github:2.0.4 github:2.1.0-rc0 github:2.0.3 github:2.1.0-alpha2 github:2.1.0-alpha0 github:2.1.0-alpha1 github:2.1-alpha1 github:2.0.2 github:1.13.0-alpha0 github:2.0.1 github:1.12.1 github:2.1-alpha0 github:1.11.5 github:1.12.0 github:1.12.0-rc0 github:1.11.4 github:1.10.8 github:2.0.0 github:2.0.0-rc1 github:untagged-c2a61792b39392572d0f github:2.0.0-rc0 github:1.11.3 github:1.10.7 github:1.12.0-alpha1 github:2.0.0-alpha3 github:1.10.6 github:1.11.2 github:1.12.0-alpha0 github:2.0.0-alpha2 github:1.10.5 github:1.11.1 github:2.0.0-alpha1 github:1.11.0 github:1.10.4 github:1.9.7 github:1.10.3 github:1.11.0-rc0 github:1.9.6 github:1.11.0-alpha1 github:1.10.1 github:1.9.5 github:1.11.0-alpha0 github:1.9.4 github:1.10.0 github:1.9.3 github:1.10.0-rc0 github:1.9.0-rc0 github:1.9.0-alpha2 github:1.9.0-alpha0 github:stable-1.8.2 github:stable-1.8-test.0
..
compare: github:2.4.0
Branches Tags
github:main github:topic/tests-expand-autogenerated-policy github:dependabot/cargo/src/agent/tracing-667a7af472 github:dependabot/cargo/src/agent/clap-f572f62cb7 github:dependabot/cargo/src/tools/kata-ctl/toml-0.9.8 github:remove-install_go github:dependabot/cargo/src/tools/kata-ctl/strum-0.27.1 github:dependabot/cargo/src/tools/genpolicy/const_format-0.2.35 github:dependabot/cargo/src/tools/agent-ctl/toml-0.9.11spec-1.1.0 github:dependabot/cargo/src/libs/toml-1.0.3 github:dependabot/cargo/src/agent/strum-0.27.1 github:dependabot/cargo/src/agent/toml-0.9.6 github:dependabot/cargo/src/agent/const_format-0.2.35 github:dependabot/go_modules/src/runtime/k8s.io/cri-api-0.35.2 github:dependabot/github_actions/docker/build-push-action-6.19.2 github:dependabot/go_modules/src/runtime/github.com/go-openapi/errors-0.22.6 github:dependabot/cargo/src/agent/tokio-c49fc46c2e github:dependabot/cargo/src/tools/genpolicy/openssl-6888b711b6 github:dependabot/cargo/src/agent/tracing-9421c2f3ac github:topic/tests-try-crio github:osv-scanner-bump-2.3.3 github:topic/tests-lower-the-load-on-aks github:sprt/disable-pmem github:topic/ci-lower-secrets-required github:disable-guest-empty-dir github:topic/oras-cache-still-not-working github:bump-to-go-1.25 github:dependabot/go_modules/src/runtime/github.com/go-openapi/runtime-0.29.2 github:topic/re-enable-sandboxapi-tests github:topic/main-no-cache github:topic/kata-deploy-upgrade github:copilot/replace-gperf-url-with-urls github:zizmor-update-to-1.20 github:dependabot/github_actions/actions/attest-build-provenance-3.2.0 github:dependabot/github_actions/docker/login-action-3.7.0 github:stale-issues-by-date github:dependabot/github_actions/tim-actions/wip-check-1.1.0 github:dependabot/go_modules/src/runtime/github.com/containerd/containerd/api-1.9.0 github:dependabot/github_actions/actions/download-artifact-7.0.0 github:topic/arm64-increase-runner-timeout github:decouple-kernel-rootfs github:dependabot/go_modules/src/runtime/github.com/containerd/containerd/api-1.10.0 github:topic/ovmf-tdx github:dependabot/cargo/kvm-ioctls-0.24.0 github:ci-test github:topic/move-builder-images-to-quay.io github:runtime-rs-stability-test github:runtime-rs-policy-debug github:numa-topology github:topic/stability-rs github:dependabot/cargo/vmm-sys-util-0.15.0 github:dependabot/cargo/vm-memory-0.16.2 github:fupan_test github:topic/tests-experimental-force-guest-pull-test-authenticated-registries github:fupan_tests github:dependabot/cargo/src/agent/tracing-subscriber-0.3.20 github:fupan_nontee_test github:sprt-patch-2 github:sprt/test-pr-up github:sprt/cleanup-policy-settings github:fix-create-container-timeout github:zvonkok-patch-1 github:amd64-nvidia-gpu-cicd-part2 github:burgerdev/codegen-test github:kata-tests-gh-cli-trigger github:topic/wainersm-ci_setup_kubectl github:topic/wainersm/fix_coco_stability_tests github:sprt/remove-ci-env github:revert-11466-blockfile github:saul/updateimg github:sprt/fix-validate-ok-to-test github:sprt-patch-1
github:3.27.0 github:3.26.0 github:3.25.0 github:3.24.0 github:3.23.0 github:3.22.0 github:3.21.0 github:3.20.0 github:3.19.1 github:3.19.0 github:3.18.0 github:3.17.0 github:3.16.0 github:3.15.0 github:3.14.0 github:3.13.0 github:3.12.0 github:3.11.0 github:3.10.1 github:3.10.0 github:3.9.0 github:3.8.0 github:3.7.0 github:3.6.0 github:3.5.0 github:3.4.0 github:release-3.4.0 github:3.3.0-test github:3.3.0 github:CC-0.8.1 github:CC-0.8.0 github:3.2.0 github:3.3.0-alpha0 github:3.2.0-rc0 github:3.2.0-alpha4 github:CC-0.7.0 github:3.1.3 github:CC-0.6.0 github:3.2.0-alpha3 github:3.2.0-alpha2 github:3.1.2 github:3.2.0-alpha1 github:3.1.1 github:CC-0.5.0 github:3.2.0-alpha0 github:3.1.0 github:CC-0.4.0 github:3.0.2 github:3.1.0-rc0 github:CC-0.3.0 github:3.0.1 github:3.1.0-alpha1 github:CC-0.2.0 github:3.0.0 github:3.1.0-alpha0 github:2.5.2 github:3.0.0-rc1 github:3.0.0-rc0 github:3.0.0-alpha1 github:untagged-b5b6198308b02e3a2666 github:2.5.1 github:3.0.0-alpha0 github:2.5.0 github:2.4.3 github:2.5.0-rc0 github:2.4.2 github:2.5.0-alpha2 github:2.5.0-alpha1 github:2.4.1 github:2.4.0 github:2.5.0-alpha0 github:2.4.0-rc0 github:2.3.3 github:2.3.2 github:2.4.0-alpha2 github:2.3.1 github:2.4.0-alpha1 github:2.3.0 github:2.4.0-alpha0 github:2.3.0-rc1 github:2.2.3 github:2.3.0-rc0 github:2.2.2 github:2.3.0-alpha2 github:2.2.1 github:2.3.0-alpha1 github:2.3.0-alpha0 github:2.2.0 github:2.2.0-rc0 github:2.2.0-alpha1 github:2.1.1 github:2.2.0-alpha0 github:2.1.0 github:2.0.4 github:2.1.0-rc0 github:2.0.3 github:2.1.0-alpha2 github:2.1.0-alpha0 github:2.1.0-alpha1 github:2.1-alpha1 github:2.0.2 github:1.13.0-alpha0 github:2.0.1 github:1.12.1 github:2.1-alpha0 github:1.11.5 github:1.12.0 github:1.12.0-rc0 github:1.11.4 github:1.10.8 github:2.0.0 github:2.0.0-rc1 github:untagged-c2a61792b39392572d0f github:2.0.0-rc0 github:1.11.3 github:1.10.7 github:1.12.0-alpha1 github:2.0.0-alpha3 github:1.10.6 github:1.11.2 github:1.12.0-alpha0 github:2.0.0-alpha2 github:1.10.5 github:1.11.1 github:2.0.0-alpha1 github:1.11.0 github:1.10.4 github:1.9.7 github:1.10.3 github:1.11.0-rc0 github:1.9.6 github:1.11.0-alpha1 github:1.10.1 github:1.9.5 github:1.11.0-alpha0 github:1.9.4 github:1.10.0 github:1.9.3 github:1.10.0-rc0 github:1.9.0-rc0 github:1.9.0-alpha2 github:1.9.0-alpha0 github:stable-1.8.2 github:stable-1.8-test.0

36 Commits
3.1.2 ... 2.4.0

Author SHA1 Message Date
Fabiano Fidêncio
0ad6f05dee Merge pull request #4024 from bergwolf/2.4.0-branch-bump 
# Kata Containers 2.4.0
 2022-04-01 13:46:35 +02:00
Peng Tao
4c9c01a124 release: Kata Containers 2.4.0 
- stable-2.4 | agent: fix container stop error with signal SIGRTMIN+3
- stable-2.4 | kata-monitor: fix duplicated output when printing usage
- stable-2.4 | runtime: Stop getting OOM events from agent for "ttrpc closed" error
- kata-deploy: fix version bump from -rc to stable
- stable-2.4: release: Include all the rust vendored code into the vendored tarball
- stable-2.4 | tools: release: Do not consider release candidates as stable releases
- agent: Signal the whole process group
- stable-2.4 | docs: Update k8s documentation
- backport main commits to stable 2.4
- stable-2.4: Bump QEMU to 6.2 (bringing then SGX support in)
- runtime: Properly handle ESRCH error when signaling container
- stable-2.4 | versions: Upgrade to Cloud Hypervisor v22.1

f2319d69 release: Adapt kata-deploy for 2.4.0
cae48e9c agent: fix container stop error with signal SIGRTMIN+3
342aa95c kata-monitor: fix duplicated output when printing usage
9f75e226 runtime: add logs around sandbox monitor
363fbed8 runtime: stop getting OOM events when ttrpc: closed error
f840de5a workflows,release: Ship *all* the rust vendored code
952cea5f tools: Add a generate_vendor.sh script
cc965fa0 kata-deploy: fix version bump from -rc to stable
f41cc184 tools: release: Do not consider release candidates as stable releases
e059b50f runtime: Add more debug logs for container io stream copy
71ce6f53 agent: Kill the all the container processes of the same cgroup
30fc2c86 docs: Update k8s documentation
24028969 virtcontainers: Run mock hook from build tree rather than system bin dir
4e54aa5a doc: fix filename typo
d815393c manager: Add options to change self test behaviour
4111e1a3 manager: Add option to enable component debug
2918be18 manager: Create containerd link
6b31b068 kernel: fix cve-2022-0847
5589b246 doc: update Intel SGX use cases document
1da88dca tools: update QEMU to 6.2
3e2f9223 runtime: Properly handle ESRCH error when signaling container
4c21cb3e versions: Upgrade to Cloud Hypervisor v22.1

Signed-off-by: Peng Tao <bergwolf@hyper.sh>
 2022-04-01 06:20:20 +00:00
Peng Tao
f2319d693d release: Adapt kata-deploy for 2.4.0 
kata-deploy files must be adapted to a new release.  The cases where it
happens are when the release goes from -> to:
* main -> stable:
  * kata-deploy-stable / kata-cleanup-stable: are removed

* stable -> stable:
  * kata-deploy / kata-cleanup: bump the release to the new one.

There are no changes when doing an alpha release, as the files on the
"main" branch always point to the "latest" and "stable" tags.

Signed-off-by: Peng Tao <bergwolf@hyper.sh>
 2022-04-01 06:20:20 +00:00
Bin Liu
98ccf8f6a1 Merge pull request #4008 from wxx213/stable-2.4 
stable-2.4 | agent: fix container stop error with signal SIGRTMIN+3
 2022-04-01 11:29:18 +08:00
Wang Xingxing
cae48e9c9b agent: fix container stop error with signal SIGRTMIN+3 
The nix::sys::signal::Signal package api cannot deal with SIGRTMIN+3,
directly use libc function to send the signal.

Fixes: #3990

Signed-off-by: Wang Xingxing <stellarwxx@163.com>
(cherry picked from commit 0d765bd082)
Signed-off-by: Wang Xingxing <stellarwxx@163.com>
 2022-03-31 16:49:06 +08:00
snir911
a36103c759 Merge pull request #4003 from fgiudici/kata-monitor_fix_help_backport 
stable-2.4 | kata-monitor: fix duplicated output when printing usage
 2022-03-30 18:57:17 +03:00
Fabiano Fidêncio
6abbcc551c Merge pull request #3997 from liubin/backport-2.4 
stable-2.4 | runtime: Stop getting OOM events from agent for "ttrpc closed" error
 2022-03-30 14:08:55 +02:00
Francesco Giudici
342aa95cc8 kata-monitor: fix duplicated output when printing usage 
(default: "/run/containerd/containerd.sock") is duplicated when
printing kata-monitor usage:

[root@kubernetes ~]# kata-monitor --help
Usage of kata-monitor:
  -listen-address string
        The address to listen on for HTTP requests. (default ":8090")
  -log-level string
        Log level of logrus(trace/debug/info/warn/error/fatal/panic). (default "info")
  -runtime-endpoint string
        Endpoint of CRI container runtime service. (default: "/run/containerd/containerd.sock") (default "/run/containerd/containerd.sock")

the golang flag package takes care of adding the defaults when printing
usage. Remove the explicit print of the value so that it would not be
printed on screen twice.

Fixes: #3998

Signed-off-by: Francesco Giudici <fgiudici@redhat.com>
(cherry picked from commit a63bbf9793)
 2022-03-30 14:02:54 +02:00
bin
9f75e226f1 runtime: add logs around sandbox monitor 
For debugging purposes, add some logs.

Fixes: #3815

Signed-off-by: bin <bin@hyper.sh>
 2022-03-30 17:11:40 +08:00
bin
363fbed804 runtime: stop getting OOM events when ttrpc: closed error 
getOOMEvents is a long-waiting call, it will retry when failed.
For cases of agent shutdown, the retry should stop.

When the agent hasn't detected agent has died, we can also check
whether the error is "ttrpc: closed".

Fixes: #3815

Signed-off-by: bin <bin@hyper.sh>
 2022-03-30 17:11:35 +08:00
Fabiano Fidêncio
54a638317a Merge pull request #3988 from bergwolf/github/kata-deploy 
kata-deploy: fix version bump from -rc to stable
 2022-03-30 11:01:45 +02:00
Peng Tao
8ce6b12b41 Merge pull request #3993 from fidencio/wip/stable-2.4-release-include-all-rust-vendored-code-to-the-vendored-tarball 
stable-2.4: release: Include all the rust vendored code into the vendored tarball
 2022-03-30 16:10:47 +08:00
Fabiano Fidêncio
f840de5acb workflows,release: Ship *all* the rust vendored code 
Instead of only vendoring the code needed by the agent, let's ensure we
vendor all the needed rust code, and let's do it using the newly
introduced enerate_vendor.sh script.

Fixes: #3973

Signed-off-by: Fabiano Fidêncio <fabiano.fidencio@intel.com>
(cherry picked from commit 3606923ac8)
 2022-03-29 23:27:43 +02:00
Fabiano Fidêncio
952cea5f5d tools: Add a generate_vendor.sh script 
This script is responsible for generating a tarball with all the rust
vendored code that is needed for fully building kata-containers on a
disconnected environment.

Signed-off-by: Fabiano Fidêncio <fabiano.fidencio@intel.com>
(cherry picked from commit 2eb07455d0)
 2022-03-29 23:27:29 +02:00
Peng Tao
cc965fa0cb kata-deploy: fix version bump from -rc to stable 
In such case, we should bump from "latest" tag rather than from
current_version.

Fixes: #3986
Signed-off-by: Peng Tao <bergwolf@hyper.sh>
 2022-03-29 03:45:27 +00:00
GabyCT
44b1473d0c Merge pull request #3977 from fidencio/wip/backport-fix-for-3847 
stable-2.4 | tools: release: Do not consider release candidates as stable releases
 2022-03-28 10:38:47 -06:00
Fupan Li
565efd1bf2 Merge pull request #3975 from bergwolf/github/backport-stable-2.4 
agent: Signal the whole process group
 2022-03-28 18:26:12 +08:00
Fabiano Fidêncio
f41cc18427 tools: release: Do not consider release candidates as stable releases 
During the release of 2.4.0-rc0 @egernst noticed an incositency in the
way we handle release tags, as release candidates are being taken as
"stable" releases, while both the kata-deploy tests and the release
action consider this as "latest".

Ideally we should have our own tag for "release candidate", but that's
something that could and should be discussed more extensively outside of
the scope of this quick fix.

For now, let's align the code generating the PR for bumping the release
with what we already do as part of the release action and kata-deploy
test, and tag "-rc"  as latest, regardless of which branch it's coming
from.

Fixes: #3847

Signed-off-by: Fabiano Fidêncio <fabiano.fidencio@intel.com>
(cherry picked from commit 4adf93ef2c)
 2022-03-28 11:01:58 +02:00
Feng Wang
e059b50f5c runtime: Add more debug logs for container io stream copy 
This can help debugging container lifecycle issues

Fixes: #3913

Signed-off-by: Feng Wang <feng.wang@databricks.com>
 2022-03-28 16:22:22 +08:00
Feng Wang
71ce6f537f agent: Kill the all the container processes of the same cgroup 
Otherwise the container process might leak and cause an unclean exit

Fixes: #3913

Signed-off-by: Feng Wang <feng.wang@databricks.com>
 2022-03-28 16:21:51 +08:00
Bin Liu
a2b73b60bd Merge pull request #3960 from cmaf/update-k8s-docs-1-stable-2.4 
stable-2.4 | docs: Update k8s documentation
 2022-03-25 15:25:25 +08:00
Bin Liu
2ce9ce7b8f Merge pull request #3954 from bergwolf/github/backport-stable-2.4 
backport main commits to stable 2.4
 2022-03-25 14:45:17 +08:00
Chelsea Mafrica
30fc2c863d docs: Update k8s documentation 
Update documentation with missing step to untaint node to enable
scheduling and update the example to run a pod using the kata runtime
class instead of untrusted workloads, which applies to versions of CRI-O
prior to v1.12.

Fixes #3863

Signed-off-by: Chelsea Mafrica <chelsea.e.mafrica@intel.com>
(cherry picked from commit 5c434270d1)
 2022-03-24 11:22:18 -07:00
David Gibson
24028969c2 virtcontainers: Run mock hook from build tree rather than system bin dir 
Running unit tests should generally have minimal dependencies on
things outside the build tree.  It *definitely* shouldn't modify
system wide things outside the build tree.  Currently the runtime
"make test" target does so, though.

Several of the tests in src/runtime/pkg/katautils/hook_test.go require a
sample hook binary.  They expect this hook in
/usr/bin/virtcontainers/bin/test/hook, so the makefile, as root, installs
the test binary to that location.

Go tests automatically run within the package's directory though, so
there's no need to use a system wide path.  We can use a relative path to
the binary build within the tree just as easily.

fixes #3941

Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
 2022-03-24 12:02:00 +08:00
Garrett Mahin
4e54aa5a7b doc: fix filename typo 
Corrects a filename typo in cleanup cluster part
of kata-deploy README.md

Fixes: #3869
Signed-off-by: Garrett Mahin <garrett.mahin@gmail.com>
 2022-03-24 12:00:17 +08:00
James O. D. Hunt
d815393c3e manager: Add options to change self test behaviour 
Added new `kata-manager` options to control the self-test behaviour. By
default, after installation the manager will run a test to ensure a Kata
Containers container can be created. New options allow:

- The self test to be disabled.
- Only the self test to be run (no installation).

These features allow changes to be made to the installed system before
the self test is run.

Fixes: #3851.

Signed-off-by: James O. D. Hunt <james.o.hunt@intel.com>
 2022-03-24 11:59:48 +08:00
James O. D. Hunt
4111e1a3de manager: Add option to enable component debug 
Added a `-d` option to `kata-manager` to enable Kata Containers
and containerd debug.

Signed-off-by: James O. D. Hunt <james.o.hunt@intel.com>
 2022-03-24 11:59:33 +08:00
James O. D. Hunt
2918be180f manager: Create containerd link 
Make the `kata-manager` create a `containerd` link to ensure the
downloaded containerd systemd service file can find the daemon when
using the GitHub packaged version of containerd.

Signed-off-by: James O. D. Hunt <james.o.hunt@intel.com>
 2022-03-24 11:59:26 +08:00
Julio Montes
6b31b06832 kernel: fix cve-2022-0847 
bump guest kernel version to fix cve-2022-0847 "Dirty Pipe"

fixes #3852

Signed-off-by: Julio Montes <julio.montes@intel.com>
 2022-03-24 11:58:43 +08:00
Fabiano Fidêncio
53a9cf7dc4 Merge pull request #3927 from fidencio/stable-2.4/qemu-bump 
stable-2.4: Bump QEMU to 6.2 (bringing then SGX support in)
 2022-03-23 07:20:35 +01:00
Julio Montes
5589b246d7 doc: update Intel SGX use cases document 
Installation section is not longer needed because of the latest
default kata kernel supports Intel SGX.
Include QEMU to the list of supported hypervisors.

fixes #3911

Signed-off-by: Julio Montes <julio.montes@intel.com>
(cherry picked from commit 24b29310b2)
 2022-03-22 08:36:04 +01:00
Julio Montes
1da88dca4b tools: update QEMU to 6.2 
bring Intel SGX support

Changes tha may impact in Kata Containers
Arm:
The 'virt' machine now supports an emulated ITS
The 'virt' machine now supports more than 123 CPUs in TCG emulation mode
The pl031 real-time clock device now supports sending RTC_CHANGE QMP events

PowerPC:
Improved POWER10 support for the 'powernv' machine
Initial support for POWER10 DD2.0 CPU added
Added support for FORM2 PAPR NUMA descriptions in the "pseries" machine
 type

s390x:
Improved storage key emulation (e.g. fixed address handling, lazy
 storage key enablement for TCG, ...)
New gen16 CPU features are now enabled automatically in the latest
 machine type

KVM:
Support for SGX in the virtual machine, using the /dev/sgx_vepc device
 on the host and the "memory-backend-epc" backend in QEMU.
New "hv-apicv" CPU property (aliased to "hv-avic") sets the
 HV_DEPRECATING_AEOI_RECOMMENDED bit in CPUID[0x40000004].EAX.

virtio-mem:
QEMU now fully supports guest memory dumps with virtio-mem.
QEMU now cleanly supports precopy migration, postcopy migration and
 background snapshots with virtio-mem.

fixes #3902

Signed-off-by: Julio Montes <julio.montes@intel.com>
(cherry picked from commit 18d4d7fb1d)
 2022-03-22 08:35:45 +01:00
Peng Tao
8cc2231818 Merge pull request #3892 from fengwang666/my_2.4_pr_backport 
runtime: Properly handle ESRCH error when signaling container
 2022-03-15 10:11:25 +08:00
GabyCT
63c1498f05 Merge pull request #3891 from likebreath/stable-2.4 
stable-2.4 | versions: Upgrade to Cloud Hypervisor v22.1
 2022-03-14 17:44:09 -06:00
Feng Wang
3e2f9223b0 runtime: Properly handle ESRCH error when signaling container 
Currently kata shim v2 doesn't translate ESRCH signal, causing container
fail to stop and shim leak.

Fixes: #3874

Signed-off-by: Feng Wang <feng.wang@databricks.com>
(cherry picked from commit aa5ae6b17c)
 2022-03-14 13:15:54 -07:00
Bo Chen
4c21cb3eb1 versions: Upgrade to Cloud Hypervisor v22.1 
This is a bug fix release. The following issues have been addressed:
1) VFIO ioctl reordering to fix MSI on AMD platforms; 2) Fix virtio-net
control queue.

Details can be found: https://github.com/cloud-hypervisor/cloud-hypervisor/releases/tag/v22.1

Fixes: #3872

Signed-off-by: Bo Chen <chen.bo@intel.com>
(cherry picked from commit 7a18e32fa7)
 2022-03-14 12:34:31 -07:00
2444 changed files with 38488 additions and 464037 deletions
Expand all files Collapse all files

40
.github/cargo-deny-composite-action/cargo-deny-generator.sh vendored
View File

@@ -1,40 +0,0 @@
#!/bin/bash
#
# Copyright (c) 2022 Red Hat
#
# SPDX-License-Identifier: Apache-2.0
#
script_dir=$(dirname "$(readlink -f "$0")")
parent_dir=$(realpath "${script_dir}/../..")
cidir="${parent_dir}/ci"
source "${cidir}/lib.sh"
cargo_deny_file="${script_dir}/action.yaml"
cat cargo-deny-skeleton.yaml.in > "${cargo_deny_file}"
changed_files_status=$(run_get_pr_changed_file_details)
changed_files_status=$(echo "$changed_files_status" | grep "Cargo\.toml$" || true)
changed_files=$(echo "$changed_files_status" | awk '{print $NF}' || true)
if [ -z "$changed_files" ]; then
cat >> "${cargo_deny_file}" << EOF
- run: echo "No Cargo.toml files to check"
shell: bash
EOF
fi
for path in $changed_files
do
cat >> "${cargo_deny_file}" << EOF
- name: ${path}
continue-on-error: true
shell: bash
run: |
pushd $(dirname ${path})
cargo deny check
popd
EOF
done

30
.github/cargo-deny-composite-action/cargo-deny-skeleton.yaml.in vendored
View File

@@ -1,30 +0,0 @@
#
# Copyright (c) 2022 Red Hat
#
# SPDX-License-Identifier: Apache-2.0
#
name: 'Cargo Crates Check'
description: 'Checks every Cargo.toml file using cargo-deny'
env:
CARGO_TERM_COLOR: always
runs:
using: "composite"
steps:
- name: Install Rust
uses: actions-rs/toolchain@v1
with:
profile: minimal
toolchain: nightly
override: true
- name: Cache
uses: Swatinem/rust-cache@v2
- name: Install Cargo deny
shell: bash
run: |
which cargo
cargo install --locked cargo-deny || true

100
.github/workflows/add-backport-label.yaml vendored
View File

@@ -1,100 +0,0 @@
name: Add backport label
on:
pull_request:
types:
- opened
- synchronize
- reopened
- edited
- labeled
- unlabeled
jobs:
check-issues:
if: ${{ github.event.label.name != 'auto-backport' }}
runs-on: ubuntu-latest
steps:
- name: Checkout code to allow hub to communicate with the project
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
uses: actions/checkout@v3
- name: Install hub extension script
run: |
pushd $(mktemp -d) &>/dev/null
git clone --single-branch --depth 1 "https://github.com/kata-containers/.github" && cd .github/scripts
sudo install hub-util.sh /usr/local/bin
popd &>/dev/null
- name: Determine whether to add label
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
env:
GITHUB_TOKEN: ${{ secrets.GITHUB_TOKEN }}
CONTAINS_AUTO_BACKPORT: ${{ contains(github.event.pull_request.labels.*.name, 'auto-backport') }}
id: add_label
run: |
pr=${{ github.event.pull_request.number }}
linked_issue_urls=$(hub-util.sh \
list-issues-for-pr "$pr" |\
grep -v "^\#" |\
cut -d';' -f3 || true)
[ -z "$linked_issue_urls" ] && {
echo "::error::No linked issues for PR $pr"
exit 1
}
has_bug=false
for issue_url in $(echo "$linked_issue_urls")
do
issue=$(echo "$issue_url"| awk -F\/ '{print $NF}' || true)
[ -z "$issue" ] && {
echo "::error::Cannot determine issue number from $issue_url for PR $pr"
exit 1
}
labels=$(hub-util.sh list-labels-for-issue "$issue")
label_names=$(echo $labels | jq -r '.[].name' || true)
if [[ "$label_names" =~ "bug" ]]; then
has_bug=true
break
fi
done
has_backport_needed_label=${{ contains(github.event.pull_request.labels.*.name, 'needs-backport') }}
has_no_backport_needed_label=${{ contains(github.event.pull_request.labels.*.name, 'no-backport-needed') }}
echo "::set-output name=add_backport_label::false"
if [ $has_backport_needed_label = true ] || [ $has_bug = true ]; then
if [[ $has_no_backport_needed_label = false ]]; then
echo "::set-output name=add_backport_label::true"
fi
fi
# Do not spam comment, only if auto-backport label is going to be newly added.
echo "::set-output name=auto_backport_added::$CONTAINS_AUTO_BACKPORT"
- name: Add comment
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') && steps.add_label.outputs.add_backport_label == 'true' && steps.add_label.outputs.auto_backport_added == 'false' }}
uses: actions/github-script@v6
with:
script: |
github.rest.issues.createComment({
issue_number: context.issue.number,
owner: context.repo.owner,
repo: context.repo.repo,
body: 'This issue has been marked for auto-backporting. Add label(s) backport-to-BRANCHNAME to backport to them'
})
# Allow label to be removed by adding no-backport-needed label
- name: Remove auto-backport label
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') && steps.add_label.outputs.add_backport_label == 'false' }}
uses: andymckay/labeler@e6c4322d0397f3240f0e7e30a33b5c5df2d39e90
with:
remove-labels: "auto-backport"
repo-token: ${{ secrets.GITHUB_TOKEN }}
- name: Add auto-backport label
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') && steps.add_label.outputs.add_backport_label == 'true' }}
uses: andymckay/labeler@e6c4322d0397f3240f0e7e30a33b5c5df2d39e90
with:
add-labels: "auto-backport"
repo-token: ${{ secrets.GITHUB_TOKEN }}

40
.github/workflows/add-pr-sizing-label.yaml vendored
View File

@@ -1,40 +0,0 @@
# Copyright (c) 2022 Intel Corporation
#
# SPDX-License-Identifier: Apache-2.0
#
name: Add PR sizing label
on:
pull_request_target:
types:
- opened
- reopened
- synchronize
jobs:
add-pr-size-label:
runs-on: ubuntu-latest
steps:
- name: Checkout code
uses: actions/checkout@v1
- name: Install PR sizing label script
run: |
# Clone into a temporary directory to avoid overwriting
# any existing github directory.
pushd $(mktemp -d) &>/dev/null
git clone --single-branch --depth 1 "https://github.com/kata-containers/.github" && cd .github/scripts
sudo install pr-add-size-label.sh /usr/local/bin
popd &>/dev/null
- name: Add PR sizing label
env:
GITHUB_TOKEN: ${{ secrets.KATA_GITHUB_ACTIONS_PR_SIZE_TOKEN }}
run: |
pr=${{ github.event.number }}
# Removing man-db, workflow kept failing, fixes: #4480
sudo apt -y remove --purge man-db
sudo apt -y install diffstat patchutils
pr-add-size-label.sh -p "$pr"

29
.github/workflows/auto-backport.yaml vendored
View File

@@ -1,29 +0,0 @@
on:
pull_request_target:
types: ["labeled", "closed"]
jobs:
backport:
name: Backport PR
runs-on: ubuntu-latest
if: |
github.event.pull_request.merged == true
&& contains(github.event.pull_request.labels.*.name, 'auto-backport')
&& (
(github.event.action == 'labeled' && github.event.label.name == 'auto-backport')
|| (github.event.action == 'closed')
)
steps:
- name: Backport Action
uses: sqren/backport-github-action@v8.9.2
with:
github_token: ${{ secrets.GITHUB_TOKEN }}
auto_backport_label_prefix: backport-to-
- name: Info log
if: ${{ success() }}
run: cat /home/runner/.backport/backport.info.log
- name: Debug log
if: ${{ failure() }}
run: cat /home/runner/.backport/backport.debug.log

26
.github/workflows/cargo-deny-runner.yaml vendored
View File

@@ -1,26 +0,0 @@
name: Cargo Crates Check Runner
on:
pull_request:
types:
- opened
- edited
- reopened
- synchronize
paths-ignore: [ '**.md', '**.png', '**.jpg', '**.jpeg', '**.svg', '/docs/**' ]
jobs:
cargo-deny-runner:
runs-on: ubuntu-latest
steps:
- name: Checkout Code
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
uses: actions/checkout@v3
- name: Generate Action
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: bash cargo-deny-generator.sh
working-directory: ./.github/cargo-deny-composite-action/
env:
GOPATH: ${{ runner.workspace }}/kata-containers
- name: Run Action
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
uses: ./.github/cargo-deny-composite-action

9
.github/workflows/commit-message-check.yaml vendored
View File

@@ -10,7 +10,7 @@ env:
error_msg: |+
See the document below for help on formatting commits for the project.
https://github.com/kata-containers/community/blob/main/CONTRIBUTING.md#patch-format
https://github.com/kata-containers/community/blob/master/CONTRIBUTING.md#patch-format
jobs:
commit-message-check:
@@ -63,8 +63,7 @@ jobs:
# the entire commit message.
#
# - Body lines *can* be longer than the maximum if they start
# with a non-alphabetic character or if there is no whitespace in
# the line.
# with a non-alphabetic character.
#
# This allows stack traces, log files snippets, emails, long URLs,
# etc to be specified. Some of these naturally "work" as they start
@@ -75,8 +74,8 @@ jobs:
#
# - A SoB comment can be any length (as it is unreasonable to penalise
# people with long names/email addresses :)
pattern: '^.+(\n([a-zA-Z].{0,150}|[^a-zA-Z\n].*|[^\s\n]*|Signed-off-by:.*|))+$'
error: 'Body line too long (max 150)'
pattern: '^.+(\n([a-zA-Z].{0,149}|[^a-zA-Z\n].*|Signed-off-by:.*|))+$'
error: 'Body line too long (max 72)'
post_error: ${{ env.error_msg }}
- name: Check Fixes

10
.github/workflows/darwin-tests.yaml vendored
View File

@@ -5,16 +5,20 @@ on:
- edited
- reopened
- synchronize
paths-ignore: [ '**.md', '**.png', '**.jpg', '**.jpeg', '**.svg', '/docs/**' ]
name: Darwin tests
jobs:
test:
runs-on: macos-latest
strategy:
matrix:
go-version: [1.16.x, 1.17.x]
os: [macos-latest]
runs-on: ${{ matrix.os }}
steps:
- name: Install Go
uses: actions/setup-go@v2
with:
go-version: 1.19.3
go-version: ${{ matrix.go-version }}
- name: Checkout code
uses: actions/checkout@v2
- name: Build utils

37
.github/workflows/docs-url-alive-check.yaml vendored
View File

@@ -1,37 +0,0 @@
on:
schedule:
- cron: '0 23 * * 0'
name: Docs URL Alive Check
jobs:
test:
runs-on: ubuntu-20.04
# don't run this action on forks
if: github.repository_owner == 'kata-containers'
env:
target_branch: ${{ github.base_ref }}
steps:
- name: Install Go
uses: actions/setup-go@v2
with:
go-version: 1.19.3
env:
GOPATH: ${{ runner.workspace }}/kata-containers
- name: Set env
run: |
echo "GOPATH=${{ github.workspace }}" >> $GITHUB_ENV
echo "${{ github.workspace }}/bin" >> $GITHUB_PATH
- name: Checkout code
uses: actions/checkout@v2
with:
fetch-depth: 0
path: ./src/github.com/${{ github.repository }}
- name: Setup
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && ./ci/setup.sh
env:
GOPATH: ${{ runner.workspace }}/kata-containers
# docs url alive check
- name: Docs URL Alive Check
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && make docs-url-alive-check

9
.github/workflows/kata-deploy-push.yaml vendored
View File

@@ -18,17 +18,20 @@ jobs:
matrix:
asset:
- kernel
- kernel-dragonball-experimental
- shim-v2
- qemu
- cloud-hypervisor
- firecracker
- rootfs-image
- rootfs-initrd
- virtiofsd
- nydus
steps:
- uses: actions/checkout@v2
- name: Install docker
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
curl -fsSL https://test.docker.com -o test-docker.sh
sh test-docker.sh
- name: Build ${{ matrix.asset }}
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |

45
.github/workflows/kata-deploy-test.yaml vendored
View File

@@ -1,10 +1,4 @@
on:
workflow_dispatch: # this is used to trigger the workflow on non-main branches
inputs:
pr:
description: 'PR number from the selected branch to test'
type: string
required: true
issue_comment:
types: [created, edited]
@@ -18,20 +12,19 @@ jobs:
&& github.event_name == 'issue_comment'
&& github.event.action == 'created'
&& startsWith(github.event.comment.body, '/test_kata_deploy')
|| github.event_name == 'workflow_dispatch'
steps:
- name: Check membership on comment or dispatch
- name: Check membership
uses: kata-containers/is-organization-member@1.0.1
id: is_organization_member
with:
organization: kata-containers
username: ${{ github.event.comment.user.login || github.event.sender.login }}
username: ${{ github.event.comment.user.login }}
token: ${{ secrets.GITHUB_TOKEN }}
- name: Fail if not member
run: |
result=${{ steps.is_organization_member.outputs.result }}
if [ $result == false ]; then
user=${{ github.event.comment.user.login || github.event.sender.login }}
user=${{ github.event.comment.user.login }}
echo Either ${user} is not part of the kata-containers organization
echo or ${user} has its Organization Visibility set to Private at
echo https://github.com/orgs/kata-containers/people?query=${user}
@@ -50,28 +43,26 @@ jobs:
- cloud-hypervisor
- firecracker
- kernel
- kernel-dragonball-experimental
- nydus
- qemu
- rootfs-image
- rootfs-initrd
- shim-v2
- virtiofsd
steps:
- name: get-PR-ref
id: get-PR-ref
run: |
if [ ${{ github.event_name }} == 'issue_comment' ]; then
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
else # workflow_dispatch
ref="refs/pull/${{ github.event.inputs.pr }}/merge"
fi
echo "reference for PR: " ${ref} "event:" ${{ github.event_name }}
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
echo "reference for PR: " ${ref}
echo "##[set-output name=pr-ref;]${ref}"
- uses: actions/checkout@v2
with:
ref: ${{ steps.get-PR-ref.outputs.pr-ref }}
- name: Install docker
run: |
curl -fsSL https://test.docker.com -o test-docker.sh
sh test-docker.sh
- name: Build ${{ matrix.asset }}
run: |
make "${KATA_ASSET}-tarball"
@@ -96,12 +87,8 @@ jobs:
- name: get-PR-ref
id: get-PR-ref
run: |
if [ ${{ github.event_name }} == 'issue_comment' ]; then
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
else # workflow_dispatch
ref="refs/pull/${{ github.event.inputs.pr }}/merge"
fi
echo "reference for PR: " ${ref} "event:" ${{ github.event_name }}
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
echo "reference for PR: " ${ref}
echo "##[set-output name=pr-ref;]${ref}"
- uses: actions/checkout@v2
with:
@@ -127,12 +114,8 @@ jobs:
- name: get-PR-ref
id: get-PR-ref
run: |
if [ ${{ github.event_name }} == 'issue_comment' ]; then
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
else # workflow_dispatch
ref="refs/pull/${{ github.event.inputs.pr }}/merge"
fi
echo "reference for PR: " ${ref} "event:" ${{ github.event_name }}
ref=$(cat $GITHUB_EVENT_PATH | jq -r '.issue.pull_request.url' | sed 's#^.*\/pulls#refs\/pull#' | sed 's#$#\/merge#')
echo "reference for PR: " ${ref}
echo "##[set-output name=pr-ref;]${ref}"
- uses: actions/checkout@v2
with:

13
.github/workflows/release.yaml vendored
View File

@@ -1,8 +1,8 @@
name: Publish Kata release artifacts
name: Publish Kata 2.x release artifacts
on:
push:
tags:
- '[0-9]+.[0-9]+.[0-9]+*'
- '2.*'
jobs:
build-asset:
@@ -13,18 +13,19 @@ jobs:
- cloud-hypervisor
- firecracker
- kernel
- kernel-dragonball-experimental
- nydus
- qemu
- rootfs-image
- rootfs-initrd
- shim-v2
- virtiofsd
steps:
- uses: actions/checkout@v2
- name: Install docker
run: |
curl -fsSL https://test.docker.com -o test-docker.sh
sh test-docker.sh
- name: Build ${{ matrix.asset }}
run: |
./tools/packaging/kata-deploy/local-build/kata-deploy-copy-yq-installer.sh
./tools/packaging/kata-deploy/local-build/kata-deploy-binaries-in-docker.sh --build="${KATA_ASSET}"
build_dir=$(readlink -f build)
# store-artifact does not work with symlink

25
.github/workflows/snap-release.yaml vendored
View File

@@ -1,12 +1,8 @@
name: Release Kata in snapcraft store
name: Release Kata 2.x in snapcraft store
on:
push:
tags:
- '[0-9]+.[0-9]+.[0-9]+*'
env:
SNAPCRAFT_STORE_CREDENTIALS: ${{ secrets.snapcraft_token }}
- '2.*'
jobs:
release-snap:
runs-on: ubuntu-20.04
@@ -17,21 +13,12 @@ jobs:
fetch-depth: 0
- name: Install Snapcraft
run: |
# Required to avoid snapcraft install failure
sudo chown root:root /
# "--classic" is needed for the GitHub action runner
# environment.
sudo snap install snapcraft --classic
# Allow other parts to access snap binaries
echo /snap/bin >> "$GITHUB_PATH"
uses: samuelmeuli/action-snapcraft@v1
with:
snapcraft_token: ${{ secrets.snapcraft_token }}
- name: Build snap
run: |
# Removing man-db, workflow kept failing, fixes: #4480
sudo apt -y remove --purge man-db
sudo apt-get install -y git git-extras
kata_url="https://github.com/kata-containers/kata-containers"
latest_version=$(git ls-remote --tags ${kata_url} | egrep -o "refs.*" | egrep -v "\-alpha|\-rc|{}" | egrep -o "[[:digit:]]+\.[[:digit:]]+\.[[:digit:]]+" | sort -V -r | head -1)
@@ -39,7 +26,7 @@ jobs:
# Check semantic versioning format (x.y.z) and if the current tag is the latest tag
if echo "${current_version}" | grep -q "^[[:digit:]]\+\.[[:digit:]]\+\.[[:digit:]]\+$" && echo -e "$latest_version\n$current_version" | sort -C -V; then
# Current version is the latest version, build it
snapcraft snap --debug --destructive-mode
snapcraft -d snap --destructive-mode
fi
- name: Upload snap

14
.github/workflows/snap.yaml vendored
View File

@@ -6,7 +6,6 @@ on:
- synchronize
- reopened
- edited
paths-ignore: [ '**.md', '**.png', '**.jpg', '**.jpeg', '**.svg', '/docs/**' ]
jobs:
test:
@@ -20,18 +19,9 @@ jobs:
- name: Install Snapcraft
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
# Required to avoid snapcraft install failure
sudo chown root:root /
# "--classic" is needed for the GitHub action runner
# environment.
sudo snap install snapcraft --classic
# Allow other parts to access snap binaries
echo /snap/bin >> "$GITHUB_PATH"
uses: samuelmeuli/action-snapcraft@v1
- name: Build snap
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
snapcraft snap --debug --destructive-mode
snapcraft -d snap --destructive-mode

33
.github/workflows/static-checks-dragonball.yaml vendored
View File

@@ -1,33 +0,0 @@
on:
pull_request:
types:
- opened
- edited
- reopened
- synchronize
paths-ignore: [ '**.md', '**.png', '**.jpg', '**.jpeg', '**.svg', '/docs/**' ]
name: Static checks dragonball
jobs:
test-dragonball:
runs-on: self-hosted
env:
RUST_BACKTRACE: "1"
steps:
- uses: actions/checkout@v3
- name: Set env
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
echo "GOPATH=${{ github.workspace }}" >> $GITHUB_ENV
- name: Install Rust
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
./ci/install_rust.sh
PATH=$PATH:"$HOME/.cargo/bin"
- name: Run Unit Test
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd src/dragonball
cargo version
rustc --version
sudo -E env PATH=$PATH LIBC=gnu SUPPORT_VIRTUALIZATION=true make test

66
.github/workflows/static-checks.yaml vendored
View File

@@ -8,16 +8,12 @@ on:
name: Static checks
jobs:
static-checks:
runs-on: ubuntu-20.04
test:
strategy:
matrix:
cmd:
- "make vendor"
- "make static-checks"
- "make check"
- "make test"
- "sudo -E PATH=\"$PATH\" make test"
go-version: [1.16.x, 1.17.x]
os: [ubuntu-20.04]
runs-on: ${{ matrix.os }}
env:
TRAVIS: "true"
TRAVIS_BRANCH: ${{ github.base_ref }}
@@ -26,33 +22,13 @@ jobs:
RUST_BACKTRACE: "1"
target_branch: ${{ github.base_ref }}
steps:
- name: Checkout code
uses: actions/checkout@v3
with:
fetch-depth: 0
path: ./src/github.com/${{ github.repository }}
- name: Install Go
uses: actions/setup-go@v3
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
uses: actions/setup-go@v2
with:
go-version: 1.19.3
go-version: ${{ matrix.go-version }}
env:
GOPATH: ${{ runner.workspace }}/kata-containers
- name: Check kernel config version
run: |
cd "${{ github.workspace }}/src/github.com/${{ github.repository }}"
kernel_dir="tools/packaging/kernel/"
kernel_version_file="${kernel_dir}kata_config_version"
modified_files=$(git diff --name-only origin/main..HEAD)
result=$(git whatchanged origin/main..HEAD "${kernel_dir}" >>"/dev/null")
if git whatchanged origin/main..HEAD "${kernel_dir}" >>"/dev/null"; then
echo "Kernel directory has changed, checking if $kernel_version_file has been updated"
if echo "$modified_files" | grep -v "README.md" | grep "${kernel_dir}" >>"/dev/null"; then
echo "$modified_files" | grep "$kernel_version_file" >>/dev/null || ( echo "Please bump version in $kernel_version_file" && exit 1)
else
echo "Readme file changed, no need for kernel config version update."
fi
echo "Check passed"
fi
- name: Setup GOPATH
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
@@ -65,6 +41,12 @@ jobs:
run: |
echo "GOPATH=${{ github.workspace }}" >> $GITHUB_ENV
echo "${{ github.workspace }}/bin" >> $GITHUB_PATH
- name: Checkout code
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
uses: actions/checkout@v2
with:
fetch-depth: 0
path: ./src/github.com/${{ github.repository }}
- name: Setup travis references
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
@@ -84,7 +66,6 @@ jobs:
rustup target add x86_64-unknown-linux-musl
rustup component add rustfmt clippy
- name: Setup seccomp
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
libseccomp_install_dir=$(mktemp -d -t libseccomp.XXXXXXXXXX)
gperf_install_dir=$(mktemp -d -t gperf.XXXXXXXXXX)
@@ -92,7 +73,24 @@ jobs:
echo "Set environment variables for the libseccomp crate to link the libseccomp library statically"
echo "LIBSECCOMP_LINK_TYPE=static" >> $GITHUB_ENV
echo "LIBSECCOMP_LIB_PATH=${libseccomp_install_dir}/lib" >> $GITHUB_ENV
- name: Run check
# Check whether the vendored code is up-to-date & working as the first thing
- name: Check vendored code
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && ${{ matrix.cmd }}
cd ${GOPATH}/src/github.com/${{ github.repository }} && make vendor
- name: Static Checks
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && make static-checks
- name: Run Compiler Checks
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && make check
- name: Run Unit Tests
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && make test
- name: Run Unit Tests As Root User
if: ${{ !contains(github.event.pull_request.labels.*.name, 'force-skip-ci') }}
run: |
cd ${GOPATH}/src/github.com/${{ github.repository }} && sudo -E PATH="$PATH" make test

5
.gitignore vendored
View File

@@ -4,12 +4,9 @@
**/*.rej
**/target
**/.vscode
**/.idea
**/.fleet
pkg/logging/Cargo.lock
src/agent/src/version.rs
src/agent/kata-agent.service
src/agent/protocols/src/*.rs
!src/agent/protocols/src/lib.rs
build
src/tools/log-parser/kata-log-parser

26
Makefile
View File

@@ -6,25 +6,24 @@
# List of available components
COMPONENTS =
COMPONENTS += libs
COMPONENTS += agent
COMPONENTS += dragonball
COMPONENTS += runtime
COMPONENTS += runtime-rs
# List of available tools
TOOLS =
TOOLS += agent-ctl
TOOLS += kata-ctl
TOOLS += log-parser
TOOLS += runk
TOOLS += trace-forwarder
STANDARD_TARGETS = build check clean install static-checks-build test vendor
STANDARD_TARGETS = build check clean install test vendor
default: all
all: logging-crate-tests build
logging-crate-tests:
make -C src/libs/logging
include utils.mk
include ./tools/packaging/kata-deploy/local-build/Makefile
@@ -37,16 +36,13 @@ generate-protocols:
make -C src/agent generate-protocols
# Some static checks rely on generated source files of components.
static-checks: static-checks-build
static-checks: build
bash ci/static-checks.sh
docs-url-alive-check:
bash ci/docs-url-alive-check.sh
.PHONY: \
all \
kata-tarball \
install-tarball \
binary-tarball \
default \
static-checks \
docs-url-alive-check
install-binary-tarball \
logging-crate-tests \
static-checks

7
README.md
View File

@@ -71,7 +71,6 @@ See the [official documentation](docs) including:
- [Developer guide](docs/Developer-Guide.md)
- [Design documents](docs/design)
- [Architecture overview](docs/design/architecture)
- [Architecture 3.0 overview](docs/design/architecture_3.0/)
## Configuration
@@ -117,9 +116,7 @@ The table below lists the core parts of the project:
| Component | Type | Description |
|-|-|-|
| [runtime](src/runtime) | core | Main component run by a container manager and providing a containerd shimv2 runtime implementation. |
| [runtime-rs](src/runtime-rs) | core | The Rust version runtime. |
| [agent](src/agent) | core | Management process running inside the virtual machine / POD that sets up the container environment. |
| [`dragonball`](src/dragonball) | core | An optional built-in VMM brings out-of-the-box Kata Containers experience with optimizations on container workloads |
| [documentation](docs) | documentation | Documentation common to all components (such as design and install documentation). |
| [tests](https://github.com/kata-containers/tests) | tests | Excludes unit tests which live with the main code. |
@@ -133,9 +130,7 @@ The table below lists the remaining parts of the project:
| [kernel](https://www.kernel.org) | kernel | Linux kernel used by the hypervisor to boot the guest image. Patches are stored [here](tools/packaging/kernel). |
| [osbuilder](tools/osbuilder) | infrastructure | Tool to create "mini O/S" rootfs and initrd images and kernel for the hypervisor. |
| [`agent-ctl`](src/tools/agent-ctl) | utility | Tool that provides low-level access for testing the agent. |
| [`kata-ctl`](src/tools/kata-ctl) | utility | Tool that provides advanced commands and debug facilities. |
| [`trace-forwarder`](src/tools/trace-forwarder) | utility | Agent tracing helper. |
| [`runk`](src/tools/runk) | utility | Standard OCI container runtime based on the agent. |
| [`ci`](https://github.com/kata-containers/ci) | CI | Continuous Integration configuration files and scripts. |
| [`katacontainers.io`](https://github.com/kata-containers/www.katacontainers.io) | Source for the [`katacontainers.io`](https://www.katacontainers.io) site. |
@@ -143,7 +138,7 @@ The table below lists the remaining parts of the project:
Kata Containers is now
[available natively for most distributions](docs/install/README.md#packaged-installation-methods).
However, packaging scripts and metadata are still used to generate [snap](snap/local) and GitHub releases. See
However, packaging scripts and metadata are still used to generate snap and GitHub releases. See
the [components](#components) section for further details.
## Glossary of Terms

2
VERSION
View File

@@ -1 +1 @@
3.1.2
2.4.0

8
ci/darwin-test.sh
View File

@@ -11,10 +11,10 @@ runtimedir=$cidir/../src/runtime
build_working_packages() {
# working packages:
device_api=$runtimedir/pkg/device/api
device_config=$runtimedir/pkg/device/config
device_drivers=$runtimedir/pkg/device/drivers
device_manager=$runtimedir/pkg/device/manager
device_api=$runtimedir/virtcontainers/device/api
device_config=$runtimedir/virtcontainers/device/config
device_drivers=$runtimedir/virtcontainers/device/drivers
device_manager=$runtimedir/virtcontainers/device/manager
rc_pkg_dir=$runtimedir/pkg/resourcecontrol/
utils_pkg_dir=$runtimedir/virtcontainers/utils

6
ci/docs-url-alive-check.sh → ci/go-test.sh
View File

@@ -1,6 +1,6 @@
#!/bin/bash
#!/usr/bin/env bash
#
# Copyright (c) 2021 Easystack Inc.
# Copyright (c) 2020 Intel Corporation
#
# SPDX-License-Identifier: Apache-2.0
@@ -9,4 +9,4 @@ set -e
cidir=$(dirname "$0")
source "${cidir}/lib.sh"
run_docs_url_alive_check
run_go_test

37
ci/install_libseccomp.sh
View File

@@ -19,31 +19,29 @@ source "${tests_repo_dir}/.ci/lib.sh"
# fail. So let's ensure they are unset here.
unset PREFIX DESTDIR
arch=${ARCH:-$(uname -m)}
arch=$(uname -m)
workdir="$(mktemp -d --tmpdir build-libseccomp.XXXXX)"
# Variables for libseccomp
libseccomp_version="${LIBSECCOMP_VERSION:-""}"
if [ -z "${libseccomp_version}" ]; then
libseccomp_version=$(get_version "externals.libseccomp.version")
fi
libseccomp_url="${LIBSECCOMP_URL:-""}"
if [ -z "${libseccomp_url}" ]; then
libseccomp_url=$(get_version "externals.libseccomp.url")
fi
# Currently, specify the libseccomp version directly without using `versions.yaml`
# because the current Snap workflow is incomplete.
# After solving the issue, replace this code by using the `versions.yaml`.
# libseccomp_version=$(get_version "externals.libseccomp.version")
# libseccomp_url=$(get_version "externals.libseccomp.url")
libseccomp_version="2.5.1"
libseccomp_url="https://github.com/seccomp/libseccomp"
libseccomp_tarball="libseccomp-${libseccomp_version}.tar.gz"
libseccomp_tarball_url="${libseccomp_url}/releases/download/v${libseccomp_version}/${libseccomp_tarball}"
cflags="-O2"
# Variables for gperf
gperf_version="${GPERF_VERSION:-""}"
if [ -z "${gperf_version}" ]; then
gperf_version=$(get_version "externals.gperf.version")
fi
gperf_url="${GPERF_URL:-""}"
if [ -z "${gperf_url}" ]; then
gperf_url=$(get_version "externals.gperf.url")
fi
# Currently, specify the gperf version directly without using `versions.yaml`
# because the current Snap workflow is incomplete.
# After solving the issue, replace this code by using the `versions.yaml`.
# gperf_version=$(get_version "externals.gperf.version")
# gperf_url=$(get_version "externals.gperf.url")
gperf_version="3.1"
gperf_url="https://ftp.gnu.org/gnu/gperf"
gperf_tarball="gperf-${gperf_version}.tar.gz"
gperf_tarball_url="${gperf_url}/${gperf_tarball}"
@@ -72,8 +70,7 @@ build_and_install_gperf() {
curl -sLO "${gperf_tarball_url}"
tar -xf "${gperf_tarball}"
pushd "gperf-${gperf_version}"
# Unset $CC for configure, we will always use native for gperf
CC= ./configure --prefix="${gperf_install_dir}"
./configure --prefix="${gperf_install_dir}"
make
make install
export PATH=$PATH:"${gperf_install_dir}"/bin
@@ -87,7 +84,7 @@ build_and_install_libseccomp() {
curl -sLO "${libseccomp_tarball_url}"
tar -xf "${libseccomp_tarball}"
pushd "libseccomp-${libseccomp_version}"
./configure --prefix="${libseccomp_install_dir}" CFLAGS="${cflags}" --enable-static --host="${arch}"
./configure --prefix="${libseccomp_install_dir}" CFLAGS="${cflags}" --enable-static
make
make install
popd

24
ci/install_musl.sh Executable file
View File

@@ -0,0 +1,24 @@
#!/usr/bin/env bash
# Copyright (c) 2020 Ant Group
#
# SPDX-License-Identifier: Apache-2.0
#
set -e
install_aarch64_musl() {
local arch=$(uname -m)
if [ "${arch}" == "aarch64" ]; then
local musl_tar="${arch}-linux-musl-native.tgz"
local musl_dir="${arch}-linux-musl-native"
pushd /tmp
if curl -sLO --fail https://musl.cc/${musl_tar}; then
tar -zxf ${musl_tar}
mkdir -p /usr/local/musl/
cp -r ${musl_dir}/* /usr/local/musl/
fi
popd
fi
}
install_aarch64_musl

12
ci/install_yq.sh
View File

@@ -43,16 +43,6 @@ function install_yq() {
"aarch64")
goarch=arm64
;;
"arm64")
# If we're on an apple silicon machine, just assign amd64.
# The version of yq we use doesn't have a darwin arm build,
# but Rosetta can come to the rescue here.
if [ $goos == "Darwin" ]; then
goarch=amd64
else
goarch=arm64
fi
;;
"ppc64le")
goarch=ppc64le
;;
@@ -74,7 +64,7 @@ function install_yq() {
fi
## NOTE: ${var,,} => gives lowercase value of var
local yq_url="https://${yq_pkg}/releases/download/${yq_version}/yq_${goos}_${goarch}"
local yq_url="https://${yq_pkg}/releases/download/${yq_version}/yq_${goos,,}_${goarch}"
curl -o "${yq_path}" -LSsf "${yq_url}"
[ $? -ne 0 ] && die "Download ${yq_url} failed"
chmod +x "${yq_path}"

24
ci/lib.sh
View File

@@ -18,13 +18,6 @@ clone_tests_repo()
{
if [ -d "$tests_repo_dir" ]; then
[ -n "${CI:-}" ] && return
# git config --global --add safe.directory will always append
# the target to .gitconfig without checking the existence of
# the target, so it's better to check it before adding the target repo.
local sd="$(git config --global --get safe.directory ${tests_repo_dir} || true)"
if [ -z "${sd}" ]; then
git config --global --add safe.directory ${tests_repo_dir}
fi
pushd "${tests_repo_dir}"
git checkout "${branch}"
git pull
@@ -46,21 +39,8 @@ run_static_checks()
bash "$tests_repo_dir/.ci/static-checks.sh" "$@"
}
run_docs_url_alive_check()
run_go_test()
{
clone_tests_repo
# Make sure we have the targeting branch
git remote set-branches --add origin "${branch}"
git fetch -a
bash "$tests_repo_dir/.ci/static-checks.sh" --docs --all "github.com/kata-containers/kata-containers"
}
run_get_pr_changed_file_details()
{
clone_tests_repo
# Make sure we have the targeting branch
git remote set-branches --add origin "${branch}"
git fetch -a
source "$tests_repo_dir/.ci/lib.sh"
get_pr_changed_file_details
bash "$tests_repo_dir/.ci/go-test.sh"
}

33
deny.toml
View File

@@ -1,33 +0,0 @@
targets = [
{ triple = "x86_64-apple-darwin" },
{ triple = "x86_64-unknown-linux-gnu" },
{ triple = "x86_64-unknown-linux-musl" },
]
[advisories]
vulnerability = "deny"
unsound = "deny"
unmaintained = "deny"
ignore = ["RUSTSEC-2020-0071"]
[bans]
multiple-versions = "allow"
deny = [
{ name = "cmake" },
{ name = "openssl-sys" },
]
[licenses]
unlicensed = "deny"
allow-osi-fsf-free = "neither"
copyleft = "allow"
# We want really high confidence when inferring licenses from text
confidence-threshold = 0.93
allow = ["0BSD", "Apache-2.0", "BSD-2-Clause", "BSD-3-Clause", "CC0-1.0", "ISC", "MIT", "MPL-2.0"]
private = { ignore = true}
exceptions = []
[sources]
unknown-registry = "allow"
unknown-git = "allow"

339
docs/Developer-Guide.md
View File

@@ -33,41 +33,51 @@ You need to install the following to build Kata Containers components:
- `make`.
- `gcc` (required for building the shim and runtime).
# Build and install Kata Containers
## Build and install the Kata Containers runtime
# Build and install the Kata Containers runtime
```bash
$ git clone https://github.com/kata-containers/kata-containers.git
$ pushd kata-containers/src/runtime
$ make && sudo -E "PATH=$PATH" make install
$ sudo mkdir -p /etc/kata-containers/
$ sudo install -o root -g root -m 0640 /usr/share/defaults/kata-containers/configuration.toml /etc/kata-containers
$ popd
```
$ go get -d -u github.com/kata-containers/kata-containers
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/src/runtime
$ make && sudo -E PATH=$PATH make install
```
The build will create the following:
- runtime binary: `/usr/local/bin/kata-runtime` and `/usr/local/bin/containerd-shim-kata-v2`
- configuration file: `/usr/share/defaults/kata-containers/configuration.toml` and `/etc/kata-containers/configuration.toml`
- configuration file: `/usr/share/defaults/kata-containers/configuration.toml`
# Check hardware requirements
You can check if your system is capable of creating a Kata Container by running the following:
```
$ sudo kata-runtime check
```
If your system is *not* able to run Kata Containers, the previous command will error out and explain why.
## Configure to use initrd or rootfs image
Kata containers can run with either an initrd image or a rootfs image.
If you want to test with `initrd`, make sure you have uncommented `initrd = /usr/share/kata-containers/kata-containers-initrd.img`
in your configuration file, commenting out the `image` line in
`/etc/kata-containers/configuration.toml`. For example:
If you want to test with `initrd`, make sure you have `initrd = /usr/share/kata-containers/kata-containers-initrd.img`
in your configuration file, commenting out the `image` line:
```bash
`/usr/share/defaults/kata-containers/configuration.toml` and comment out the `image` line with the following. For example:
```
$ sudo mkdir -p /etc/kata-containers/
$ sudo install -o root -g root -m 0640 /usr/share/defaults/kata-containers/configuration.toml /etc/kata-containers
$ sudo sed -i 's/^\(image =.*\)/# \1/g' /etc/kata-containers/configuration.toml
$ sudo sed -i 's/^# \(initrd =.*\)/\1/g' /etc/kata-containers/configuration.toml
```
You can create the initrd image as shown in the [create an initrd image](#create-an-initrd-image---optional) section.
If you want to test with a rootfs `image`, make sure you have uncommented `image = /usr/share/kata-containers/kata-containers.img`
If you want to test with a rootfs `image`, make sure you have `image = /usr/share/kata-containers/kata-containers.img`
in your configuration file, commenting out the `initrd` line. For example:
```bash
```
$ sudo mkdir -p /etc/kata-containers/
$ sudo install -o root -g root -m 0640 /usr/share/defaults/kata-containers/configuration.toml /etc/kata-containers
$ sudo sed -i 's/^\(initrd =.*\)/# \1/g' /etc/kata-containers/configuration.toml
```
The rootfs image is created as shown in the [create a rootfs image](#create-a-rootfs-image) section.
@@ -80,38 +90,19 @@ rootfs `image`(100MB+).
Enable seccomp as follows:
```bash
```
$ sudo sed -i '/^disable_guest_seccomp/ s/true/false/' /etc/kata-containers/configuration.toml
```
This will pass container seccomp profiles to the kata agent.
## Enable SELinux on the guest
> **Note:**
>
> - To enable SELinux on the guest, SELinux MUST be also enabled on the host.
> - You MUST create and build a rootfs image for SELinux in advance.
> See [Create a rootfs image](#create-a-rootfs-image) and [Build a rootfs image](#build-a-rootfs-image).
> - SELinux on the guest is supported in only a rootfs image currently, so
> you cannot enable SELinux with the agent init (`AGENT_INIT=yes`) yet.
Enable guest SELinux in Enforcing mode as follows:
```
$ sudo sed -i '/^disable_guest_selinux/ s/true/false/g' /etc/kata-containers/configuration.toml
```
The runtime automatically will set `selinux=1` to the kernel parameters and `xattr` option to
`virtiofsd` when `disable_guest_selinux` is set to `false`.
If you want to enable SELinux in Permissive mode, add `enforcing=0` to the kernel parameters.
## Enable full debug
Enable full debug as follows:
```bash
```
$ sudo mkdir -p /etc/kata-containers/
$ sudo install -o root -g root -m 0640 /usr/share/defaults/kata-containers/configuration.toml /etc/kata-containers
$ sudo sed -i -e 's/^# *\(enable_debug\).*=.*$/\1 = true/g' /etc/kata-containers/configuration.toml
$ sudo sed -i -e 's/^kernel_params = "\(.*\)"/kernel_params = "\1 agent.log=debug initcall_debug"/g' /etc/kata-containers/configuration.toml
```
@@ -125,7 +116,7 @@ detailed below.
The Kata logs appear in the `containerd` log files, along with logs from `containerd` itself.
For more information about `containerd` debug, please see the
[`containerd` documentation](https://github.com/containerd/containerd/blob/main/docs/getting-started.md).
[`containerd` documentation](https://github.com/containerd/containerd/blob/master/docs/getting-started.md).
#### Enabling full `containerd` debug
@@ -184,7 +175,7 @@ and offers possible workarounds and fixes.
it stores. When messages are suppressed, it is noted in the logs. This can be checked
for by looking for those notifications, such as:
```bash
```sh
$ sudo journalctl --since today | fgrep Suppressed
Jun 29 14:51:17 mymachine systemd-journald[346]: Suppressed 4150 messages from /system.slice/docker.service
```
@@ -209,7 +200,7 @@ RateLimitBurst=0
Restart `systemd-journald` for the changes to take effect:
```bash
```sh
$ sudo systemctl restart systemd-journald
```
@@ -223,52 +214,39 @@ $ sudo systemctl restart systemd-journald
The agent is built with a statically linked `musl.` The default `libc` used is `musl`, but on `ppc64le` and `s390x`, `gnu` should be used. To configure this:
```bash
$ export ARCH="$(uname -m)"
```
$ export ARCH=$(uname -m)
$ if [ "$ARCH" = "ppc64le" -o "$ARCH" = "s390x" ]; then export LIBC=gnu; else export LIBC=musl; fi
$ [ "${ARCH}" == "ppc64le" ] && export ARCH=powerpc64le
$ rustup target add "${ARCH}-unknown-linux-${LIBC}"
$ [ ${ARCH} == "ppc64le" ] && export ARCH=powerpc64le
$ rustup target add ${ARCH}-unknown-linux-${LIBC}
```
To build the agent:
```
$ go get -d -u github.com/kata-containers/kata-containers
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/src/agent && make
```
The agent is built with seccomp capability by default.
If you want to build the agent without the seccomp capability, you need to run `make` with `SECCOMP=no` as follows.
```bash
$ make -C kata-containers/src/agent SECCOMP=no
```
For building the agent with seccomp support using `musl`, set the environment
variables for the [`libseccomp` crate](https://github.com/libseccomp-rs/libseccomp-rs).
```bash
$ export LIBSECCOMP_LINK_TYPE=static
$ export LIBSECCOMP_LIB_PATH="the path of the directory containing libseccomp.a"
$ make -C kata-containers/src/agent
$ make -C $GOPATH/src/github.com/kata-containers/kata-containers/src/agent SECCOMP=no
```
If the compilation fails when the agent tries to link the `libseccomp` library statically
against `musl`, you will need to build `libseccomp` manually with `-U_FORTIFY_SOURCE`.
You can use [our script](https://github.com/kata-containers/kata-containers/blob/main/ci/install_libseccomp.sh)
to install `libseccomp` for the agent.
```bash
$ mkdir -p ${seccomp_install_path} ${gperf_install_path}
$ kata-containers/ci/install_libseccomp.sh ${seccomp_install_path} ${gperf_install_path}
$ export LIBSECCOMP_LIB_PATH="${seccomp_install_path}/lib"
```
On `ppc64le` and `s390x`, `glibc` is used. You will need to install the `libseccomp` library
provided by your distribution.
> e.g. `libseccomp-dev` for Ubuntu, or `libseccomp-devel` for CentOS
> **Note:**
>
> - If you enable seccomp in the main configuration file but build the agent without seccomp capability,
> the runtime exits conservatively with an error message.
## Get the osbuilder
```
$ go get -d -u github.com/kata-containers/kata-containers
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder
```
## Create a rootfs image
### Create a local rootfs
@@ -276,32 +254,24 @@ As a prerequisite, you need to install Docker. Otherwise, you will not be
able to run the `rootfs.sh` script with `USE_DOCKER=true` as expected in
the following example.
```bash
$ export distro="ubuntu" # example
$ export ROOTFS_DIR="$(realpath kata-containers/tools/osbuilder/rootfs-builder/rootfs)"
$ sudo rm -rf "${ROOTFS_DIR}"
$ pushd kata-containers/tools/osbuilder/rootfs-builder
$ script -fec 'sudo -E USE_DOCKER=true ./rootfs.sh "${distro}"'
$ popd
```
$ export ROOTFS_DIR=${GOPATH}/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder/rootfs
$ sudo rm -rf ${ROOTFS_DIR}
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder
$ script -fec 'sudo -E GOPATH=$GOPATH USE_DOCKER=true ./rootfs.sh ${distro}'
```
You MUST choose a distribution (e.g., `ubuntu`) for `${distro}`.
You can get a supported distributions list in the Kata Containers by running the following.
```bash
$ ./kata-containers/tools/osbuilder/rootfs-builder/rootfs.sh -l
```
$ ./rootfs.sh -l
```
If you want to build the agent without seccomp capability, you need to run the `rootfs.sh` script with `SECCOMP=no` as follows.
```bash
$ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true SECCOMP=no ./rootfs.sh "${distro}"'
```
If you want to enable SELinux on the guest, you MUST choose `centos` and run the `rootfs.sh` script with `SELINUX=yes` as follows.
```
$ script -fec 'sudo -E GOPATH=$GOPATH USE_DOCKER=true SELINUX=yes ./rootfs.sh centos'
$ script -fec 'sudo -E GOPATH=$GOPATH AGENT_INIT=yes USE_DOCKER=true SECCOMP=no ./rootfs.sh ${distro}'
```
> **Note:**
@@ -317,32 +287,18 @@ $ script -fec 'sudo -E GOPATH=$GOPATH USE_DOCKER=true SELINUX=yes ./rootfs.sh ce
>
> - You should only do this step if you are testing with the latest version of the agent.
```bash
$ sudo install -o root -g root -m 0550 -t "${ROOTFS_DIR}/usr/bin" "${ROOTFS_DIR}/../../../../src/agent/target/x86_64-unknown-linux-musl/release/kata-agent"
$ sudo install -o root -g root -m 0440 "${ROOTFS_DIR}/../../../../src/agent/kata-agent.service" "${ROOTFS_DIR}/usr/lib/systemd/system/"
$ sudo install -o root -g root -m 0440 "${ROOTFS_DIR}/../../../../src/agent/kata-containers.target" "${ROOTFS_DIR}/usr/lib/systemd/system/"
```
$ sudo install -o root -g root -m 0550 -t ${ROOTFS_DIR}/usr/bin ../../../src/agent/target/x86_64-unknown-linux-musl/release/kata-agent
$ sudo install -o root -g root -m 0440 ../../../src/agent/kata-agent.service ${ROOTFS_DIR}/usr/lib/systemd/system/
$ sudo install -o root -g root -m 0440 ../../../src/agent/kata-containers.target ${ROOTFS_DIR}/usr/lib/systemd/system/
```
### Build a rootfs image
```bash
$ pushd kata-containers/tools/osbuilder/image-builder
$ script -fec 'sudo -E USE_DOCKER=true ./image_builder.sh "${ROOTFS_DIR}"'
$ popd
```
If you want to enable SELinux on the guest, you MUST run the `image_builder.sh` script with `SELINUX=yes`
to label the guest image as follows.
To label the image on the host, you need to make sure that SELinux is enabled (`selinuxfs` is mounted) on the host
and the rootfs MUST be created by running the `rootfs.sh` with `SELINUX=yes`.
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder/image-builder
$ script -fec 'sudo -E USE_DOCKER=true ./image_builder.sh ${ROOTFS_DIR}'
```
$ script -fec 'sudo -E USE_DOCKER=true SELINUX=yes ./image_builder.sh ${ROOTFS_DIR}'
```
Currently, the `image_builder.sh` uses `chcon` as an interim solution in order to apply `container_runtime_exec_t`
to the `kata-agent`. Hence, if you run `restorecon` to the guest image after running the `image_builder.sh`,
the `kata-agent` needs to be labeled `container_runtime_exec_t` again by yourself.
> **Notes:**
>
@@ -353,31 +309,25 @@ the `kata-agent` needs to be labeled `container_runtime_exec_t` again by yoursel
> variable in the previous command and ensure the `qemu-img` command is
> available on your system.
> - If `qemu-img` is not installed, you will likely see errors such as `ERROR: File /dev/loop19p1 is not a block device` and `losetup: /tmp/tmp.bHz11oY851: Warning: file is smaller than 512 bytes; the loop device may be useless or invisible for system tools`. These can be mitigated by installing the `qemu-img` command (available in the `qemu-img` package on Fedora or the `qemu-utils` package on Debian).
> - If `loop` module is not probed, you will likely see errors such as `losetup: cannot find an unused loop device`. Execute `modprobe loop` could resolve it.
### Install the rootfs image
```bash
$ pushd kata-containers/tools/osbuilder/image-builder
$ commit="$(git log --format=%h -1 HEAD)"
$ date="$(date +%Y-%m-%d-%T.%N%z)"
```
$ commit=$(git log --format=%h -1 HEAD)
$ date=$(date +%Y-%m-%d-%T.%N%z)
$ image="kata-containers-${date}-${commit}"
$ sudo install -o root -g root -m 0640 -D kata-containers.img "/usr/share/kata-containers/${image}"
$ (cd /usr/share/kata-containers && sudo ln -sf "$image" kata-containers.img)
$ popd
```
## Create an initrd image - OPTIONAL
### Create a local rootfs for initrd image
```bash
$ export distro="ubuntu" # example
$ export ROOTFS_DIR="$(realpath kata-containers/tools/osbuilder/rootfs-builder/rootfs)"
$ sudo rm -rf "${ROOTFS_DIR}"
$ pushd kata-containers/tools/osbuilder/rootfs-builder/
$ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true ./rootfs.sh "${distro}"'
$ popd
```
$ export ROOTFS_DIR="${GOPATH}/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder/rootfs"
$ sudo rm -rf ${ROOTFS_DIR}
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder
$ script -fec 'sudo -E GOPATH=$GOPATH AGENT_INIT=yes USE_DOCKER=true ./rootfs.sh ${distro}'
```
`AGENT_INIT` controls if the guest image uses the Kata agent as the guest `init` process. When you create an initrd image,
always set `AGENT_INIT` to `yes`.
@@ -385,14 +335,14 @@ always set `AGENT_INIT` to `yes`.
You MUST choose a distribution (e.g., `ubuntu`) for `${distro}`.
You can get a supported distributions list in the Kata Containers by running the following.
```bash
$ ./kata-containers/tools/osbuilder/rootfs-builder/rootfs.sh -l
```
$ ./rootfs.sh -l
```
If you want to build the agent without seccomp capability, you need to run the `rootfs.sh` script with `SECCOMP=no` as follows.
```bash
$ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true SECCOMP=no ./rootfs.sh "${distro}"'
```
$ script -fec 'sudo -E GOPATH=$GOPATH AGENT_INIT=yes USE_DOCKER=true SECCOMP=no ./rootfs.sh ${distro}'
```
> **Note:**
@@ -401,31 +351,28 @@ $ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true SECCOMP=no ./rootfs.sh "${
Optionally, add your custom agent binary to the rootfs with the following commands. The default `$LIBC` used
is `musl`, but on ppc64le and s390x, `gnu` should be used. Also, Rust refers to ppc64le as `powerpc64le`:
```bash
$ export ARCH="$(uname -m)"
$ [ "${ARCH}" == "ppc64le" ] || [ "${ARCH}" == "s390x" ] && export LIBC=gnu || export LIBC=musl
$ [ "${ARCH}" == "ppc64le" ] && export ARCH=powerpc64le
$ sudo install -o root -g root -m 0550 -T "${ROOTFS_DIR}/../../../../src/agent/target/${ARCH}-unknown-linux-${LIBC}/release/kata-agent" "${ROOTFS_DIR}/sbin/init"
```
$ export ARCH=$(uname -m)
$ [ ${ARCH} == "ppc64le" ] || [ ${ARCH} == "s390x" ] && export LIBC=gnu || export LIBC=musl
$ [ ${ARCH} == "ppc64le" ] && export ARCH=powerpc64le
$ sudo install -o root -g root -m 0550 -T ../../../src/agent/target/${ARCH}-unknown-linux-${LIBC}/release/kata-agent ${ROOTFS_DIR}/sbin/init
```
### Build an initrd image
```bash
$ pushd kata-containers/tools/osbuilder/initrd-builder
$ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true ./initrd_builder.sh "${ROOTFS_DIR}"'
$ popd
```
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder/initrd-builder
$ script -fec 'sudo -E AGENT_INIT=yes USE_DOCKER=true ./initrd_builder.sh ${ROOTFS_DIR}'
```
### Install the initrd image
```bash
$ pushd kata-containers/tools/osbuilder/initrd-builder
$ commit="$(git log --format=%h -1 HEAD)"
$ date="$(date +%Y-%m-%d-%T.%N%z)"
```
$ commit=$(git log --format=%h -1 HEAD)
$ date=$(date +%Y-%m-%d-%T.%N%z)
$ image="kata-containers-initrd-${date}-${commit}"
$ sudo install -o root -g root -m 0640 -D kata-containers-initrd.img "/usr/share/kata-containers/${image}"
$ (cd /usr/share/kata-containers && sudo ln -sf "$image" kata-containers-initrd.img)
$ popd
```
# Install guest kernel images
@@ -444,43 +391,43 @@ Kata Containers makes use of upstream QEMU branch. The exact version
and repository utilized can be found by looking at the [versions file](../versions.yaml).
Find the correct version of QEMU from the versions file:
```bash
$ source kata-containers/tools/packaging/scripts/lib.sh
$ qemu_version="$(get_from_kata_deps "assets.hypervisor.qemu.version")"
$ echo "${qemu_version}"
```
$ source ${GOPATH}/src/github.com/kata-containers/kata-containers/tools/packaging/scripts/lib.sh
$ qemu_version=$(get_from_kata_deps "assets.hypervisor.qemu.version")
$ echo ${qemu_version}
```
Get source from the matching branch of QEMU:
```bash
$ git clone -b "${qemu_version}" https://github.com/qemu/qemu.git
$ your_qemu_directory="$(realpath qemu)"
```
$ go get -d github.com/qemu/qemu
$ cd ${GOPATH}/src/github.com/qemu/qemu
$ git checkout ${qemu_version}
$ your_qemu_directory=${GOPATH}/src/github.com/qemu/qemu
```
There are scripts to manage the build and packaging of QEMU. For the examples below, set your
environment as:
```bash
$ packaging_dir="$(realpath kata-containers/tools/packaging)"
```
$ go get -d github.com/kata-containers/kata-containers
$ packaging_dir="${GOPATH}/src/github.com/kata-containers/kata-containers/tools/packaging"
```
Kata often utilizes patches for not-yet-upstream and/or backported fixes for components,
including QEMU. These can be found in the [packaging/QEMU directory](../tools/packaging/qemu/patches),
and it's *recommended* that you apply them. For example, suppose that you are going to build QEMU
version 5.2.0, do:
```bash
$ "$packaging_dir/scripts/apply_patches.sh" "$packaging_dir/qemu/patches/5.2.x/"
```
$ cd $your_qemu_directory
$ $packaging_dir/scripts/apply_patches.sh $packaging_dir/qemu/patches/5.2.x/
```
To build utilizing the same options as Kata, you should make use of the `configure-hypervisor.sh` script. For example:
```bash
$ pushd "$your_qemu_directory"
$ "$packaging_dir/scripts/configure-hypervisor.sh" kata-qemu > kata.cfg
$ eval ./configure "$(cat kata.cfg)"
$ make -j $(nproc --ignore=1)
# Optional
$ sudo -E make install
$ popd
```
If you do not want to install the respective QEMU version, the configuration file can be modified to point to the correct binary. In `/etc/kata-containers/configuration.toml`, change `path = "/path/to/qemu/build/qemu-system-x86_64"` to point to the correct QEMU binary.
$ cd $your_qemu_directory
$ $packaging_dir/scripts/configure-hypervisor.sh kata-qemu > kata.cfg
$ eval ./configure "$(cat kata.cfg)"
$ make -j $(nproc)
$ sudo -E make install
```
See the [static-build script for QEMU](../tools/packaging/static-build/qemu/build-static-qemu.sh) for a reference on how to get, setup, configure and build QEMU for Kata.
@@ -492,33 +439,11 @@ See the [static-build script for QEMU](../tools/packaging/static-build/qemu/buil
> under upstream review for supporting NVDIMM on aarch64.
>
You could build the custom `qemu-system-aarch64` as required with the following command:
```bash
$ git clone https://github.com/kata-containers/tests.git
$ script -fec 'sudo -E tests/.ci/install_qemu.sh'
```
## Build `virtiofsd`
When using the file system type virtio-fs (default), `virtiofsd` is required
```bash
$ pushd kata-containers/tools/packaging/static-build/virtiofsd
$ ./build.sh
$ popd
$ go get -d github.com/kata-containers/tests
$ script -fec 'sudo -E ${GOPATH}/src/github.com/kata-containers/tests/.ci/install_qemu.sh'
```
Modify `/etc/kata-containers/configuration.toml` and update value `virtio_fs_daemon = "/path/to/kata-containers/tools/packaging/static-build/virtiofsd/virtiofsd/virtiofsd"` to point to the binary.
# Check hardware requirements
You can check if your system is capable of creating a Kata Container by running the following:
```bash
$ sudo kata-runtime check
```
If your system is *not* able to run Kata Containers, the previous command will error out and explain why.
# Run Kata Containers with Containerd
Refer to the [How to use Kata Containers and Containerd](how-to/containerd-kata.md) how-to guide.
@@ -540,7 +465,7 @@ script and paste its output directly into a
> [runtime](../src/runtime) repository.
To perform analysis on Kata logs, use the
[`kata-log-parser`](../src/tools/log-parser)
[`kata-log-parser`](https://github.com/kata-containers/tests/tree/main/cmd/log-parser)
tool, which can convert the logs into formats (e.g. JSON, TOML, XML, and YAML).
See [Set up a debug console](#set-up-a-debug-console).
@@ -549,7 +474,7 @@ See [Set up a debug console](#set-up-a-debug-console).
## Checking Docker default runtime
```bash
```
$ sudo docker info 2>/dev/null | grep -i "default runtime" | cut -d: -f2- | grep -q runc && echo "SUCCESS" || echo "ERROR: Incorrect default Docker runtime"
```
## Set up a debug console
@@ -566,7 +491,7 @@ contain either `/bin/sh` or `/bin/bash`.
Enable debug_console_enabled in the `configuration.toml` configuration file:
```toml
```
[agent.kata]
debug_console_enabled = true
```
@@ -577,7 +502,7 @@ This will pass `agent.debug_console agent.debug_console_vport=1026` to agent as
For Kata Containers `2.0.x` releases, the `kata-runtime exec` command depends on the`kata-monitor` running, in order to get the sandbox's `vsock` address to connect to. Thus, first start the `kata-monitor` process.
```bash
```
$ sudo kata-monitor
```
@@ -597,7 +522,7 @@ bash-4.2# exit
exit
```
`kata-runtime exec` has a command-line option `runtime-namespace`, which is used to specify under which [runtime namespace](https://github.com/containerd/containerd/blob/main/docs/namespaces.md) the particular pod was created. By default, it is set to `k8s.io` and works for containerd when configured
`kata-runtime exec` has a command-line option `runtime-namespace`, which is used to specify under which [runtime namespace](https://github.com/containerd/containerd/blob/master/docs/namespaces.md) the particular pod was created. By default, it is set to `k8s.io` and works for containerd when configured
with Kubernetes. For CRI-O, the namespace should set to `default` explicitly. This should not be confused with [Kubernetes namespaces](https://kubernetes.io/docs/concepts/overview/working-with-objects/namespaces/).
For other CRI-runtimes and configurations, you may need to set the namespace utilizing the `runtime-namespace` option.
@@ -639,10 +564,10 @@ an additional `coreutils` package.
For example using CentOS:
```bash
$ pushd kata-containers/tools/osbuilder/rootfs-builder
$ export ROOTFS_DIR="$(realpath ./rootfs)"
$ script -fec 'sudo -E USE_DOCKER=true EXTRA_PKGS="bash coreutils" ./rootfs.sh centos'
```
$ cd $GOPATH/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder
$ export ROOTFS_DIR=${GOPATH}/src/github.com/kata-containers/kata-containers/tools/osbuilder/rootfs-builder/rootfs
$ script -fec 'sudo -E GOPATH=$GOPATH USE_DOCKER=true EXTRA_PKGS="bash coreutils" ./rootfs.sh centos'
```
#### Build the debug image
@@ -657,10 +582,9 @@ Install the image:
>**Note**: When using an initrd image, replace the below rootfs image name `kata-containers.img`
>with the initrd image name `kata-containers-initrd.img`.
```bash
```
$ name="kata-containers-centos-with-debug-console.img"
$ sudo install -o root -g root -m 0640 kata-containers.img "/usr/share/kata-containers/${name}"
$ popd
```
Next, modify the `image=` values in the `[hypervisor.qemu]` section of the
@@ -669,7 +593,7 @@ to specify the full path to the image name specified in the previous code
section. Alternatively, recreate the symbolic link so it points to
the new debug image:
```bash
```
$ (cd /usr/share/kata-containers && sudo ln -sf "$name" kata-containers.img)
```
@@ -680,7 +604,7 @@ to avoid all subsequently created containers from using the debug image.
Create a container as normal. For example using `crictl`:
```bash
```
$ sudo crictl run -r kata container.yaml pod.yaml
```
@@ -693,7 +617,7 @@ those for firecracker / cloud-hypervisor.
Add `agent.debug_console` to the guest kernel command line to allow the agent process to start a debug console.
```bash
```
$ sudo sed -i -e 's/^kernel_params = "\(.*\)"/kernel_params = "\1 agent.debug_console"/g' "${kata_configuration_file}"
```
@@ -714,7 +638,7 @@ between the host and the guest. The kernel command line option `agent.debug_cons
Add the parameter `agent.debug_console_vport=1026` to the kernel command line
as shown below:
```bash
```
sudo sed -i -e 's/^kernel_params = "\(.*\)"/kernel_params = "\1 agent.debug_console_vport=1026"/g' "${kata_configuration_file}"
```
@@ -727,7 +651,7 @@ Next, connect to the debug console. The VSOCKS paths vary slightly between each
VMM solution.
In case of cloud-hypervisor, connect to the `vsock` as shown:
```bash
```
$ sudo su -c 'cd /var/run/vc/vm/${sandbox_id}/root/ && socat stdin unix-connect:clh.sock'
CONNECT 1026
```
@@ -735,7 +659,7 @@ CONNECT 1026
**Note**: You need to type `CONNECT 1026` and press `RETURN` key after entering the `socat` command.
For firecracker, connect to the `hvsock` as shown:
```bash
```
$ sudo su -c 'cd /var/run/vc/firecracker/${sandbox_id}/root/ && socat stdin unix-connect:kata.hvsock'
CONNECT 1026
```
@@ -744,7 +668,7 @@ CONNECT 1026
For QEMU, connect to the `vsock` as shown:
```bash
```
$ sudo su -c 'cd /var/run/vc/vm/${sandbox_id} && socat "stdin,raw,echo=0,escape=0x11" "unix-connect:console.sock"'
```
@@ -757,7 +681,7 @@ If the image is created using
[osbuilder](../tools/osbuilder), the following YAML
file exists and contains details of the image and how it was created:
```bash
```
$ cat /var/lib/osbuilder/osbuilder.yaml
```
@@ -776,11 +700,11 @@ options to have the kernel boot messages logged into the system journal.
For generic information on enabling debug in the configuration file, see the
[Enable full debug](#enable-full-debug) section.
The kernel boot messages will appear in the `kata` logs (and in the `containerd` or `CRI-O` log appropriately).
The kernel boot messages will appear in the `containerd` or `CRI-O` log appropriately,
such as:
```bash
$ sudo journalctl -t kata
$ sudo journalctl -t containerd
-- Logs begin at Thu 2020-02-13 16:20:40 UTC, end at Thu 2020-02-13 16:30:23 UTC. --
...
time="2020-09-15T14:56:23.095113803+08:00" level=debug msg="reading guest console" console-protocol=unix console-url=/run/vc/vm/ab9f633385d4987828d342e47554fc6442445b32039023eeddaa971c1bb56791/console.sock pid=107642 sandbox=ab9f633385d4987828d342e47554fc6442445b32039023eeddaa971c1bb56791 source=virtcontainers subsystem=sandbox vmconsole="[ 0.395399] brd: module loaded"
@@ -790,4 +714,3 @@ time="2020-09-15T14:56:23.105268162+08:00" level=debug msg="reading guest consol
time="2020-09-15T14:56:23.121121598+08:00" level=debug msg="reading guest console" console-protocol=unix console-url=/run/vc/vm/ab9f633385d4987828d342e47554fc6442445b32039023eeddaa971c1bb56791/console.sock pid=107642 sandbox=ab9f633385d4987828d342e47554fc6442445b32039023eeddaa971c1bb56791 source=virtcontainers subsystem=sandbox vmconsole="[ 0.421324] memmap_init_zone_device initialised 32768 pages in 12ms"
...
```
Refer to the [kata-log-parser documentation](../src/tools/log-parser/README.md) which is useful to fetch these.

51
docs/Limitations.md
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@@ -46,7 +46,7 @@ The following link shows the latest list of limitations:
# Contributing
If you would like to work on resolving a limitation, please refer to the
[contributors guide](https://github.com/kata-containers/community/blob/main/CONTRIBUTING.md).
[contributors guide](https://github.com/kata-containers/community/blob/master/CONTRIBUTING.md).
If you wish to raise an issue for a new limitation, either
[raise an issue directly on the runtime](https://github.com/kata-containers/kata-containers/issues/new)
or see the
@@ -60,26 +60,17 @@ This section lists items that might be possible to fix.
## OCI CLI commands
### Docker and Podman support
Currently Kata Containers does not support Podman.
Currently Kata Containers does not support Docker or Podman.
See issue https://github.com/kata-containers/kata-containers/issues/722 for more information.
Docker supports Kata Containers since 22.06:
```bash
$ sudo docker run --runtime io.containerd.kata.v2
```
Kata Containers works perfectly with containerd, we recommend to use
containerd's Docker-style command line tool [`nerdctl`](https://github.com/containerd/nerdctl).
## Runtime commands
### checkpoint and restore
The runtime does not provide `checkpoint` and `restore` commands. There
are discussions about using VM save and restore to give us a
[`criu`](https://github.com/checkpoint-restore/criu)-like functionality,
`[criu](https://github.com/checkpoint-restore/criu)`-like functionality,
which might provide a solution.
Note that the OCI standard does not specify `checkpoint` and `restore`
@@ -102,42 +93,6 @@ All other configurations are supported and are working properly.
## Networking
### Host network
Host network (`nerdctl/docker run --net=host`or [Kubernetes `HostNetwork`](https://kubernetes.io/docs/reference/kubernetes-api/workload-resources/pod-v1/#hosts-namespaces)) is not supported.
It is not possible to directly access the host networking configuration
from within the VM.
The `--net=host` option can still be used with `runc` containers and
inter-mixed with running Kata Containers, thus enabling use of `--net=host`
when necessary.
It should be noted, currently passing the `--net=host` option into a
Kata Container may result in the Kata Container networking setup
modifying, re-configuring and therefore possibly breaking the host
networking setup. Do not use `--net=host` with Kata Containers.
### Support for joining an existing VM network
Docker supports the ability for containers to join another containers
namespace with the `docker run --net=containers` syntax. This allows
multiple containers to share a common network namespace and the network
interfaces placed in the network namespace. Kata Containers does not
support network namespace sharing. If a Kata Container is setup to
share the network namespace of a `runc` container, the runtime
effectively takes over all the network interfaces assigned to the
namespace and binds them to the VM. Consequently, the `runc` container loses
its network connectivity.
### docker run --link
The runtime does not support the `docker run --link` command. This
command is now deprecated by docker and we have no intention of adding support.
Equivalent functionality can be achieved with the newer docker networking commands.
See more documentation at
[docs.docker.com](https://docs.docker.com/network/links/).
## Resource management
Due to the way VMs differ in their CPU and memory allocation, and sharing

1
docs/README.md
View File

@@ -30,6 +30,7 @@ See the [how-to documentation](how-to).
* [GPU Passthrough with Kata](./use-cases/GPU-passthrough-and-Kata.md)
* [SR-IOV with Kata](./use-cases/using-SRIOV-and-kata.md)
* [Intel QAT with Kata](./use-cases/using-Intel-QAT-and-kata.md)
* [VPP with Kata](./use-cases/using-vpp-and-kata.md)
* [SPDK vhost-user with Kata](./use-cases/using-SPDK-vhostuser-and-kata.md)
* [Intel SGX with Kata](./use-cases/using-Intel-SGX-and-kata.md)

6
docs/Release-Process.md
View File

@@ -4,11 +4,11 @@
## Requirements
- [hub](https://github.com/github/hub)
* Using an [application token](https://github.com/settings/tokens) is required for hub (set to a GITHUB_TOKEN environment variable).
* Using an [application token](https://github.com/settings/tokens) is required for hub.
- GitHub permissions to push tags and create releases in Kata repositories.
- GPG configured to sign git tags. https://docs.github.com/en/authentication/managing-commit-signature-verification/generating-a-new-gpg-key
- GPG configured to sign git tags. https://help.github.com/articles/generating-a-new-gpg-key/
- You should configure your GitHub to use your ssh keys (to push to branches). See https://help.github.com/articles/adding-a-new-ssh-key-to-your-github-account/.
* As an alternative, configure hub to push and fork with HTTPS, `git config --global hub.protocol https` (Not tested yet) *
@@ -48,7 +48,7 @@
### Merge all bump version Pull requests
- The above step will create a GitHub pull request in the Kata projects. Trigger the CI using `/test` command on each bump Pull request.
- Trigger the `test-kata-deploy` workflow which is under the `Actions` tab on the repository GitHub page (make sure to select the correct branch and validate it passes).
- Trigger the test-kata-deploy workflow on the kata-containers repository bump Pull request using `/test_kata_deploy` (monitor under the "action" tab).
- Check any failures and fix if needed.
- Work with the Kata approvers to verify that the CI works and the pull requests are merged.

14
docs/Unit-Test-Advice.md
View File

@@ -277,9 +277,7 @@ mod tests {
## Temporary files
Use `t.TempDir()` to create temporary directory. The directory created by
`t.TempDir()` is automatically removed when the test and all its subtests
complete.
Always delete temporary files on success.
### Golang temporary files
@@ -288,7 +286,11 @@ func TestSomething(t *testing.T) {
assert := assert.New(t)
// Create a temporary directory
tmpdir := t.TempDir()
tmpdir, err := os.MkdirTemp("", "")
assert.NoError(err)
// Delete it at the end of the test
defer os.RemoveAll(tmpdir)
// Add test logic that will use the tmpdir here...
}
@@ -320,7 +322,7 @@ mod tests {
## Test user
[Unit tests are run *twice*](../src/runtime/go-test.sh):
[Unit tests are run *twice*](https://github.com/kata-containers/tests/blob/main/.ci/go-test.sh):
- as the current user
- as the `root` user (if different to the current user)
@@ -341,7 +343,7 @@ The main repository has the most comprehensive set of skip abilities. See:
One method is to use the `nix` crate along with some custom macros:
```rust
```
#[cfg(test)]
mod tests {
#[allow(unused_macros)]

2
docs/code-pr-advice.md
View File

@@ -79,7 +79,7 @@ a "`BUG: feature X not implemented see {bug-url}`" type error.
- Don't use multiple log calls when a single log call could be used.
- Use structured logging where possible to allow
[standard tooling](../src/tools/log-parser)
[standard tooling](https://github.com/kata-containers/tests/tree/main/cmd/log-parser)
be able to extract the log fields.
### Names

5
docs/design/README.md
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@@ -7,14 +7,11 @@ Kata Containers design documents:
- [Design requirements for Kata Containers](kata-design-requirements.md)
- [VSocks](VSocks.md)
- [VCPU handling](vcpu-handling.md)
- [VCPU threads pinning](vcpu-threads-pinning.md)
- [Host cgroups](host-cgroups.md)
- [Agent systemd cgroup](agent-systemd-cgroup.md)
- [`Inotify` support](inotify.md)
- [Metrics(Kata 2.0)](kata-2-0-metrics.md)
- [Design for Kata Containers `Lazyload` ability with `nydus`](kata-nydus-design.md)
- [Design for direct-assigned volume](direct-blk-device-assignment.md)
- [Design for core-scheduling](core-scheduling.md)
---
- [Design proposals](proposals)

9
docs/design/VSocks.md
View File

@@ -67,15 +67,22 @@ Using a proxy for multiplexing the connections between the VM and the host uses
4.5MB per [POD][2]. In a high density deployment this could add up to GBs of
memory that could have been used to host more PODs. When we talk about density
each kilobyte matters and it might be the decisive factor between run another
POD or not. Before making the decision not to use VSOCKs, you should ask
POD or not. For example if you have 500 PODs running in a server, the same
amount of [`kata-proxy`][3] processes will be running and consuming for around
2250MB of RAM. Before making the decision not to use VSOCKs, you should ask
yourself, how many more containers can run with the memory RAM consumed by the
Kata proxies?
### Reliability
[`kata-proxy`][3] is in charge of multiplexing the connections between virtual
machine and host processes, if it dies all connections get broken. For example
if you have a [POD][2] with 10 containers running, if `kata-proxy` dies it would
be impossible to contact your containers, though they would still be running.
Since communication via VSOCKs is direct, the only way to lose communication
with the containers is if the VM itself or the `containerd-shim-kata-v2` dies, if this happens
the containers are removed automatically.
[1]: https://wiki.qemu.org/Features/VirtioVsock
[2]: ./vcpu-handling.md#virtual-cpus-and-kubernetes-pods
[3]: https://github.com/kata-containers/proxy

84
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@@ -1,84 +0,0 @@
# Systemd Cgroup for Agent
As we know, we can interact with cgroups in two ways, **`cgroupfs`** and **`systemd`**. The former is achieved by reading and writing cgroup `tmpfs` files under `/sys/fs/cgroup` while the latter is done by configuring a transient unit by requesting systemd. Kata agent uses **`cgroupfs`** by default, unless you pass the parameter `--systemd-cgroup`.
## usage
For systemd, kata agent configures cgroups according to the following `linux.cgroupsPath` format standard provided by `runc` (`[slice]:[prefix]:[name]`). If you don't provide a valid `linux.cgroupsPath`, kata agent will treat it as `"system.slice:kata_agent:<container-id>"`.
> Here slice is a systemd slice under which the container is placed. If empty, it defaults to system.slice, except when cgroup v2 is used and rootless container is created, in which case it defaults to user.slice.
>
> Note that slice can contain dashes to denote a sub-slice (e.g. user-1000.slice is a correct notation, meaning a `subslice` of user.slice), but it must not contain slashes (e.g. user.slice/user-1000.slice is invalid).
>
> A slice of `-` represents a root slice.
>
> Next, prefix and name are used to compose the unit name, which is `<prefix>-<name>.scope`, unless name has `.slice` suffix, in which case prefix is ignored and the name is used as is.
## supported properties
The kata agent will translate the parameters in the `linux.resources` of `config.json` into systemd unit properties, and send it to systemd for configuration. Since systemd supports limited properties, only the following parameters in `linux.resources` will be applied. We will simply treat hybrid mode as legacy mode by the way.
- CPU
- v1
| runtime spec resource | systemd property name |
| --------------------- | --------------------- |
| `cpu.shares` | `CPUShares` |
- v2
| runtime spec resource | systemd property name |
| -------------------------- | -------------------------- |
| `cpu.shares` | `CPUShares` |
| `cpu.period` | `CPUQuotaPeriodUSec`(v242) |
| `cpu.period` & `cpu.quota` | `CPUQuotaPerSecUSec` |
- MEMORY
- v1
| runtime spec resource | systemd property name |
| --------------------- | --------------------- |
| `memory.limit` | `MemoryLimit` |
- v2
| runtime spec resource | systemd property name |
| ------------------------------ | --------------------- |
| `memory.low` | `MemoryLow` |
| `memory.max` | `MemoryMax` |
| `memory.swap` & `memory.limit` | `MemorySwapMax` |
- PIDS
| runtime spec resource | systemd property name |
| --------------------- | --------------------- |
| `pids.limit ` | `TasksMax` |
- CPUSET
| runtime spec resource | systemd property name |
| --------------------- | -------------------------- |
| `cpuset.cpus` | `AllowedCPUs`(v244) |
| `cpuset.mems` | `AllowedMemoryNodes`(v244) |
## Systemd Interface
`session.rs` and `system.rs` in `src/agent/rustjail/src/cgroups/systemd/interface` are automatically generated by `zbus-xmlgen`, which is is an accompanying tool provided by `zbus` to generate Rust code from `D-Bus XML interface descriptions`. The specific commands to generate these two files are as follows:
```shell
// system.rs
zbus-xmlgen --system org.freedesktop.systemd1 /org/freedesktop/systemd1
// session.rs
zbus-xmlgen --session org.freedesktop.systemd1 /org/freedesktop/systemd1
```
The current implementation of `cgroups/systemd` uses `system.rs` while `session.rs` could be used to build rootless containers in the future.
## references
- [runc - systemd cgroup driver](https://github.com/opencontainers/runc/blob/main/docs/systemd.md)
- [systemd.resource-control — Resource control unit settings](https://www.freedesktop.org/software/systemd/man/systemd.resource-control.html)

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@@ -17,7 +17,7 @@ Kubelet instance is responsible for managing the lifecycle of pods
within the nodes and eventually relies on a container runtime to
handle execution. The Kubelet architecture decouples lifecycle
management from container execution through a dedicated gRPC based
[Container Runtime Interface (CRI)](https://github.com/kubernetes/design-proposals-archive/blob/main/node/container-runtime-interface-v1.md).
[Container Runtime Interface (CRI)](https://github.com/kubernetes/community/blob/master/contributors/design-proposals/node/container-runtime-interface-v1.md).
In other words, a Kubelet is a CRI client and expects a CRI
implementation to handle the server side of the interface.

14
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@@ -1,17 +1,5 @@
# Storage
## Limits
Kata Containers is [compatible](README.md#compatibility) with existing
standards and runtime. From the perspective of storage, this means no
limits are placed on the amount of storage a container
[workload](README.md#workload) may use.
Since cgroups are not able to set limits on storage allocation, if you
wish to constrain the amount of storage a container uses, consider
using an existing facility such as `quota(1)` limits or
[device mapper](#devicemapper) limits.
## virtio SCSI
If a block-based graph driver is [configured](README.md#configuration),
@@ -32,7 +20,7 @@ For virtio-fs, the [runtime](README.md#runtime) starts one `virtiofsd` daemon
## Devicemapper
The
[devicemapper `snapshotter`](https://github.com/containerd/containerd/tree/main/snapshots/devmapper)
[devicemapper `snapshotter`](https://github.com/containerd/containerd/tree/master/snapshots/devmapper)
is a special case. The `snapshotter` uses dedicated block devices
rather than formatted filesystems, and operates at the block level
rather than the file level. This knowledge is used to directly use the

169
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@@ -1,169 +0,0 @@
# Kata 3.0 Architecture
## Overview
In cloud-native scenarios, there is an increased demand for container startup speed, resource consumption, stability, and security, areas where the present Kata Containers runtime is challenged relative to other runtimes. To achieve this, we propose a solid, field-tested and secure Rust version of the kata-runtime.
Also, we provide the following designs:
- Turn key solution with builtin `Dragonball` Sandbox
- Async I/O to reduce resource consumption
- Extensible framework for multiple services, runtimes and hypervisors
- Lifecycle management for sandbox and container associated resources
### Rationale for choosing Rust
We chose Rust because it is designed as a system language with a focus on efficiency.
In contrast to Go, Rust makes a variety of design trade-offs in order to obtain
good execution performance, with innovative techniques that, in contrast to C or
C++, provide reasonable protection against common memory errors (buffer
overflow, invalid pointers, range errors), error checking (ensuring errors are
dealt with), thread safety, ownership of resources, and more.
These benefits were verified in our project when the Kata Containers guest agent
was rewritten in Rust. We notably saw a significant reduction in memory usage
with the Rust-based implementation.
## Design
### Architecture
![architecture](./images/architecture.png)
### Built-in VMM
#### Current Kata 2.x architecture
![not_builtin_vmm](./images/not_built_in_vmm.png)
As shown in the figure, runtime and VMM are separate processes. The runtime process forks the VMM process and interacts through the inter-process RPC. Typically, process interaction consumes more resources than peers within the process, and it will result in relatively low efficiency. At the same time, the cost of resource operation and maintenance should be considered. For example, when performing resource recovery under abnormal conditions, the exception of any process must be detected by others and activate the appropriate resource recovery process. If there are additional processes, the recovery becomes even more difficult.
#### How To Support Built-in VMM
We provide `Dragonball` Sandbox to enable built-in VMM by integrating VMM's function into the Rust library. We could perform VMM-related functionalities by using the library. Because runtime and VMM are in the same process, there is a benefit in terms of message processing speed and API synchronization. It can also guarantee the consistency of the runtime and the VMM life cycle, reducing resource recovery and exception handling maintenance, as shown in the figure:
![builtin_vmm](./images/built_in_vmm.png)
### Async Support
#### Why Need Async
**Async is already in stable Rust and allows us to write async code**
- Async provides significantly reduced CPU and memory overhead, especially for workloads with a large amount of IO-bound tasks
- Async is zero-cost in Rust, which means that you only pay for what you use. Specifically, you can use async without heap allocations and dynamic dispatch, which greatly improves efficiency
- For more (see [Why Async?](https://rust-lang.github.io/async-book/01_getting_started/02_why_async.html) and [The State of Asynchronous Rust](https://rust-lang.github.io/async-book/01_getting_started/03_state_of_async_rust.html)).
**There may be several problems if implementing kata-runtime with Sync Rust**
- Too many threads with a new TTRPC connection
- TTRPC threads: reaper thread(1) + listener thread(1) + client handler(2)
- Add 3 I/O threads with a new container
- In Sync mode, implementing a timeout mechanism is challenging. For example, in TTRPC API interaction, the timeout mechanism is difficult to align with Golang
#### How To Support Async
The kata-runtime is controlled by TOKIO_RUNTIME_WORKER_THREADS to run the OS thread, which is 2 threads by default. For TTRPC and container-related threads run in the `tokio` thread in a unified manner, and related dependencies need to be switched to Async, such as Timer, File, Netlink, etc. With the help of Async, we can easily support no-block I/O and timer. Currently, we only utilize Async for kata-runtime. The built-in VMM keeps the OS thread because it can ensure that the threads are controllable.
**For N tokio worker threads and M containers**
- Sync runtime(both OS thread and `tokio` task are OS thread but without `tokio` worker thread) OS thread number: 4 + 12*M
- Async runtime(only OS thread is OS thread) OS thread number: 2 + N
```shell
├─ main(OS thread)
├─ async-logger(OS thread)
└─ tokio worker(N * OS thread)
├─ agent log forwarder(1 * tokio task)
├─ health check thread(1 * tokio task)
├─ TTRPC reaper thread(M * tokio task)
├─ TTRPC listener thread(M * tokio task)
├─ TTRPC client handler thread(7 * M * tokio task)
├─ container stdin io thread(M * tokio task)
├─ container stdout io thread(M * tokio task)
└─ container stderr io thread(M * tokio task)
```
### Extensible Framework
The Kata 3.x runtime is designed with the extension of service, runtime, and hypervisor, combined with configuration to meet the needs of different scenarios. At present, the service provides a register mechanism to support multiple services. Services could interact with runtime through messages. In addition, the runtime handler handles messages from services. To meet the needs of a binary that supports multiple runtimes and hypervisors, the startup must obtain the runtime handler type and hypervisor type through configuration.
![framework](./images/framework.png)
### Resource Manager
In our case, there will be a variety of resources, and every resource has several subtypes. Especially for `Virt-Container`, every subtype of resource has different operations. And there may be dependencies, such as the share-fs rootfs and the share-fs volume will use share-fs resources to share files to the VM. Currently, network and share-fs are regarded as sandbox resources, while rootfs, volume, and cgroup are regarded as container resources. Also, we abstract a common interface for each resource and use subclass operations to evaluate the differences between different subtypes.
![resource manager](./images/resourceManager.png)
## Roadmap
- Stage 1 (June): provide basic features (current delivered)
- Stage 2 (September): support common features
- Stage 3: support full features
| **Class** | **Sub-Class** | **Development Stage** | **Status** |
| -------------------------- | ------------------- | --------------------- |------------|
| Service | task service | Stage 1 | ✅ |
| | extend service | Stage 3 | 🚫 |
| | image service | Stage 3 | 🚫 |
| Runtime handler | `Virt-Container` | Stage 1 | ✅ |
| Endpoint | VETH Endpoint | Stage 1 | ✅ |
| | Physical Endpoint | Stage 2 | ✅ |
| | Tap Endpoint | Stage 2 | ✅ |
| | `Tuntap` Endpoint | Stage 2 | ✅ |
| | `IPVlan` Endpoint | Stage 2 | ✅ |
| | `MacVlan` Endpoint | Stage 2 | ✅ |
| | MACVTAP Endpoint | Stage 3 | 🚫 |
| | `VhostUserEndpoint` | Stage 3 | 🚫 |
| Network Interworking Model | Tc filter | Stage 1 | ✅ |
| | `MacVtap` | Stage 3 | 🚧 |
| Storage | Virtio-fs | Stage 1 | ✅ |
| | `nydus` | Stage 2 | 🚧 |
| | `device mapper` | Stage 2 | 🚫 |
| `Cgroup V2` | | Stage 2 | 🚧 |
| Hypervisor | `Dragonball` | Stage 1 | 🚧 |
| | QEMU | Stage 2 | 🚫 |
| | ACRN | Stage 3 | 🚫 |
| | Cloud Hypervisor | Stage 3 | 🚫 |
| | Firecracker | Stage 3 | 🚫 |
## FAQ
- Are the "service", "message dispatcher" and "runtime handler" all part of the single Kata 3.x runtime binary?
Yes. They are components in Kata 3.x runtime. And they will be packed into one binary.
1. Service is an interface, which is responsible for handling multiple services like task service, image service and etc.
2. Message dispatcher, it is used to match multiple requests from the service module.
3. Runtime handler is used to deal with the operation for sandbox and container.
- What is the name of the Kata 3.x runtime binary?
Apparently we can't use `containerd-shim-v2-kata` because it's already used. We are facing the hardest issue of "naming" again. Any suggestions are welcomed.
Internally we use `containerd-shim-v2-rund`.
- Is the Kata 3.x design compatible with the containerd shimv2 architecture?
Yes. It is designed to follow the functionality of go version kata. And it implements the `containerd shim v2` interface/protocol.
- How will users migrate to the Kata 3.x architecture?
The migration plan will be provided before the Kata 3.x is merging into the main branch.
- Is `Dragonball` limited to its own built-in VMM? Can the `Dragonball` system be configured to work using an external `Dragonball` VMM/hypervisor?
The `Dragonball` could work as an external hypervisor. However, stability and performance is challenging in this case. Built in VMM could optimise the container overhead, and it's easy to maintain stability.
`runD` is the `containerd-shim-v2` counterpart of `runC` and can run a pod/containers. `Dragonball` is a `microvm`/VMM that is designed to run container workloads. Instead of `microvm`/VMM, we sometimes refer to it as secure sandbox.
- QEMU, Cloud Hypervisor and Firecracker support are planned, but how that would work. Are they working in separate process?
Yes. They are unable to work as built in VMM.
- What is `upcall`?
The `upcall` is used to hotplug CPU/memory/MMIO devices, and it solves two issues.
1. avoid dependency on PCI/ACPI
2. avoid dependency on `udevd` within guest and get deterministic results for hotplug operations. So `upcall` is an alternative to ACPI based CPU/memory/device hotplug. And we may cooperate with the community to add support for ACPI based CPU/memory/device hotplug if needed.
`Dbs-upcall` is a `vsock-based` direct communication tool between VMM and guests. The server side of the `upcall` is a driver in guest kernel (kernel patches are needed for this feature) and it'll start to serve the requests once the kernel has started. And the client side is in VMM , it'll be a thread that communicates with VSOCK through `uds`. We have accomplished device hotplug / hot-unplug directly through `upcall` in order to avoid virtualization of ACPI to minimize virtual machine's overhead. And there could be many other usage through this direct communication channel. It's already open source.
https://github.com/openanolis/dragonball-sandbox/tree/main/crates/dbs-upcall
- The URL below says the kernel patches work with 4.19, but do they also work with 5.15+ ?
Forward compatibility should be achievable, we have ported it to 5.10 based kernel.
- Are these patches platform-specific or would they work for any architecture that supports VSOCK?
It's almost platform independent, but some message related to CPU hotplug are platform dependent.
- Could the kernel driver be replaced with a userland daemon in the guest using loopback VSOCK?
We need to create device nodes for hot-added CPU/memory/devices, so it's not easy for userspace daemon to do these tasks.
- The fact that `upcall` allows communication between the VMM and the guest suggests that this architecture might be incompatible with https://github.com/confidential-containers where the VMM should have no knowledge of what happens inside the VM.
1. `TDX` doesn't support CPU/memory hotplug yet.
2. For ACPI based device hotplug, it depends on ACPI `DSDT` table, and the guest kernel will execute `ASL` code to handle during handling those hotplug event. And it should be easier to audit VSOCK based communication than ACPI `ASL` methods.
- What is the security boundary for the monolithic / "Built-in VMM" case?
It has the security boundary of virtualization. More details will be provided in next stage.

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@@ -1,12 +0,0 @@
# Core scheduling
Core scheduling is a Linux kernel feature that allows only trusted tasks to run concurrently on
CPUs sharing compute resources (for example, hyper-threads on a core).
Containerd versions >= 1.6.4 leverage this to treat all of the processes associated with a
given pod or container to be a single group of trusted tasks. To indicate this should be carried
out, containerd sets the `SCHED_CORE` environment variable for each shim it spawns. When this is
set, the Kata Containers shim implementation uses the `prctl` syscall to create a new core scheduling
domain for the shim process itself as well as future VMM processes it will start.
For more details on the core scheduling feature, see the [Linux documentation](https://www.kernel.org/doc/html/latest/admin-guide/hw-vuln/core-scheduling.html).

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@@ -1,253 +0,0 @@
# Motivation
Today, there exist a few gaps between Container Storage Interface (CSI) and virtual machine (VM) based runtimes such as Kata Containers
that prevent them from working together smoothly.
First, its cumbersome to use a persistent volume (PV) with Kata Containers. Today, for a PV with Filesystem volume mode, Virtio-fs
is the only way to surface it inside a Kata Container guest VM. But often mounting the filesystem (FS) within the guest operating system (OS) is
desired due to performance benefits, availability of native FS features and security benefits over the Virtio-fs mechanism.
Second, its difficult if not impossible to resize a PV online with Kata Containers. While a PV can be expanded on the host OS,
the updated metadata needs to be propagated to the guest OS in order for the application container to use the expanded volume.
Currently, there is not a way to propagate the PV metadata from the host OS to the guest OS without restarting the Pod sandbox.
# Proposed Solution
Because of the OS boundary, these features cannot be implemented in the CSI node driver plugin running on the host OS
as is normally done in the runc container. Instead, they can be done by the Kata Containers agent inside the guest OS,
but it requires the CSI driver to pass the relevant information to the Kata Containers runtime.
An ideal long term solution would be to have the `kubelet` coordinating the communication between the CSI driver and
the container runtime, as described in [KEP-2857](https://github.com/kubernetes/enhancements/pull/2893/files).
However, as the KEP is still under review, we would like to propose a short/medium term solution to unblock our use case.
The proposed solution is built on top of a previous [proposal](https://github.com/egernst/kata-containers/blob/da-proposal/docs/design/direct-assign-volume.md)
described by Eric Ernst. The previous proposal has two gaps:
1. Writing a `csiPlugin.json` file to the volume root path introduced a security risk. A malicious user can gain unauthorized
access to a block device by writing their own `csiPlugin.json` to the above location through an ephemeral CSI plugin.
2. The proposal didn't describe how to establish a mapping between a volume and a kata sandbox, which is needed for
implementing CSI volume resize and volume stat collection APIs.
This document particularly focuses on how to address these two gaps.
## Assumptions and Limitations
1. The proposal assumes that a block device volume will only be used by one Pod on a node at a time, which we believe
is the most common pattern in Kata Containers use cases. Its also unsafe to have the same block device attached to more than
one Kata pod. In the context of Kubernetes, the `PersistentVolumeClaim` (PVC) needs to have the `accessMode` as `ReadWriteOncePod`.
2. More advanced Kubernetes volume features such as, `fsGroup`, `fsGroupChangePolicy`, and `subPath` are not supported.
## End User Interface
1. The user specifies a PV as a direct-assigned volume. How a PV is specified as a direct-assigned volume is left for each CSI implementation to decide.
There are a few options for reference:
1. A storage class parameter specifies whether it's a direct-assigned volume. This avoids any lookups of PVC
or Pod information from the CSI plugin (as external provisioner takes care of these). However, all PVs in the storage class with the parameter set
will have host mounts skipped.
2. Use a PVC annotation. This approach requires the CSI plugins have `--extra-create-metadata` [set](https://kubernetes-csi.github.io/docs/external-provisioner.html#persistentvolumeclaim-and-persistentvolume-parameters)
to be able to perform a lookup of the PVC annotations from the API server. Pro: API server lookup of annotations only required during creation of PV.
Con: The CSI plugin will always skip host mounting of the PV.
3. The CSI plugin can also lookup pod `runtimeclass` during `NodePublish`. This approach can be found in the [ALIBABA CSI plugin](https://github.com/kubernetes-sigs/alibaba-cloud-csi-driver/blob/master/pkg/disk/nodeserver.go#L248).
2. The CSI node driver delegates the direct assigned volume to the Kata Containers runtime. The CSI node driver APIs need to
be modified to pass the volume mount information and collect volume information to/from the Kata Containers runtime by invoking `kata-runtime` command line commands.
* **NodePublishVolume** -- It invokes `kata-runtime direct-volume add --volume-path [volumePath] --mount-info [mountInfo]`
to propagate the volume mount information to the Kata Containers runtime for it to carry out the filesystem mount operation.
The `volumePath` is the [target_path](https://github.com/container-storage-interface/spec/blob/master/csi.proto#L1364) in the CSI `NodePublishVolumeRequest`.
The `mountInfo` is a serialized JSON string.
* **NodeGetVolumeStats** -- It invokes `kata-runtime direct-volume stats --volume-path [volumePath]` to retrieve the filesystem stats of direct-assigned volume.
* **NodeExpandVolume** -- It invokes `kata-runtime direct-volume resize --volume-path [volumePath] --size [size]` to send a resize request to the Kata Containers runtime to
resize the direct-assigned volume.
* **NodeStageVolume/NodeUnStageVolume** -- It invokes `kata-runtime direct-volume remove --volume-path [volumePath]` to remove the persisted metadata of a direct-assigned volume.
The `mountInfo` object is defined as follows:
```Golang
type MountInfo struct {
// The type of the volume (ie. block)
VolumeType string `json:"volume-type"`
// The device backing the volume.
Device string `json:"device"`
// The filesystem type to be mounted on the volume.
FsType string `json:"fstype"`
// Additional metadata to pass to the agent regarding this volume.
Metadata map[string]string `json:"metadata,omitempty"`
// Additional mount options.
Options []string `json:"options,omitempty"`
}
```
Notes: given that the `mountInfo` is persisted to the disk by the Kata runtime, it shouldn't container any secrets (such as SMB mount password).
## Implementation Details
### Kata runtime
Instead of the CSI node driver writing the mount info into a `csiPlugin.json` file under the volume root,
as described in the original proposal, here we propose that the CSI node driver passes the mount information to
the Kata Containers runtime through a new `kata-runtime` commandline command. The `kata-runtime` then writes the mount
information to a `mountInfo.json` file in a predefined location (`/run/kata-containers/shared/direct-volumes/[volume_path]/`).
When the Kata Containers runtime starts a container, it verifies whether a volume mount is a direct-assigned volume by checking
whether there is a `mountInfo` file under the computed Kata `direct-volumes` directory. If it is, the runtime parses the `mountInfo` file,
updates the mount spec with the data in `mountInfo`. The updated mount spec is then passed to the Kata agent in the guest VM together
with other mounts. The Kata Containers runtime also creates a file named by the sandbox id under the `direct-volumes/[volume_path]/`
directory. The reason for adding a sandbox id file is to establish a mapping between the volume and the sandbox using it.
Later, when the Kata Containers runtime handles the `get-stats` and `resize` commands, it uses the sandbox id to identify
the endpoint of the corresponding `containerd-shim-kata-v2`.
### containerd-shim-kata-v2 changes
`containerd-shim-kata-v2` provides an API for sandbox management through a Unix domain socket. Two new handlers are proposed: `/direct-volume/stats` and `/direct-volume/resize`:
Example:
```bash
$ curl --unix-socket "$shim_socket_path" -I -X GET 'http://localhost/direct-volume/stats/[urlSafeVolumePath]'
$ curl --unix-socket "$shim_socket_path" -I -X POST 'http://localhost/direct-volume/resize' -d '{ "volumePath"": [volumePath], "Size": "123123" }'
```
The shim then forwards the corresponding request to the `kata-agent` to carry out the operations inside the guest VM. For `resize` operation,
the Kata runtime also needs to notify the hypervisor to resize the block device (e.g. call `block_resize` in QEMU).
### Kata agent changes
The mount spec of a direct-assigned volume is passed to `kata-agent` through the existing `Storage` GRPC object.
Two new APIs and three new GRPC objects are added to GRPC protocol between the shim and agent for resizing and getting volume stats:
```protobuf
rpc GetVolumeStats(VolumeStatsRequest) returns (VolumeStatsResponse);
rpc ResizeVolume(ResizeVolumeRequest) returns (google.protobuf.Empty);
message VolumeStatsRequest {
// The volume path on the guest outside the container
string volume_guest_path = 1;
}
message ResizeVolumeRequest {
// Full VM guest path of the volume (outside the container)
string volume_guest_path = 1;
uint64 size = 2;
}
// This should be kept in sync with CSI NodeGetVolumeStatsResponse (https://github.com/container-storage-interface/spec/blob/v1.5.0/csi.proto)
message VolumeStatsResponse {
// This field is OPTIONAL.
repeated VolumeUsage usage = 1;
// Information about the current condition of the volume.
// This field is OPTIONAL.
// This field MUST be specified if the VOLUME_CONDITION node
// capability is supported.
VolumeCondition volume_condition = 2;
}
message VolumeUsage {
enum Unit {
UNKNOWN = 0;
BYTES = 1;
INODES = 2;
}
// The available capacity in specified Unit. This field is OPTIONAL.
// The value of this field MUST NOT be negative.
uint64 available = 1;
// The total capacity in specified Unit. This field is REQUIRED.
// The value of this field MUST NOT be negative.
uint64 total = 2;
// The used capacity in specified Unit. This field is OPTIONAL.
// The value of this field MUST NOT be negative.
uint64 used = 3;
// Units by which values are measured. This field is REQUIRED.
Unit unit = 4;
}
// VolumeCondition represents the current condition of a volume.
message VolumeCondition {
// Normal volumes are available for use and operating optimally.
// An abnormal volume does not meet these criteria.
// This field is REQUIRED.
bool abnormal = 1;
// The message describing the condition of the volume.
// This field is REQUIRED.
string message = 2;
}
```
### Step by step walk-through
Given the following definition:
```YAML
---
apiVersion: v1
kind: Pod
metadata:
name: app
spec:
runtime-class: kata-qemu
containers:
- name: app
image: centos
command: ["/bin/sh"]
args: ["-c", "while true; do echo $(date -u) >> /data/out.txt; sleep 5; done"]
volumeMounts:
- name: persistent-storage
mountPath: /data
volumes:
- name: persistent-storage
persistentVolumeClaim:
claimName: ebs-claim
---
apiVersion: v1
kind: PersistentVolumeClaim
metadata:
annotations:
skip-hostmount: "true"
name: ebs-claim
spec:
accessModes:
- ReadWriteOncePod
volumeMode: Filesystem
storageClassName: ebs-sc
resources:
requests:
storage: 4Gi
---
kind: StorageClass
apiVersion: storage.k8s.io/v1
metadata:
name: ebs-sc
provisioner: ebs.csi.aws.com
volumeBindingMode: WaitForFirstConsumer
parameters:
csi.storage.k8s.io/fstype: ext4
```
Lets assume that changes have been made in the `aws-ebs-csi-driver` node driver.
**Node publish volume**
1. In the node CSI driver, the `NodePublishVolume` API invokes: `kata-runtime direct-volume add --volume-path "/kubelet/a/b/c/d/sdf" --mount-info "{\"Device\": \"/dev/sdf\", \"fstype\": \"ext4\"}"`.
2. The `Kata-runtime` writes the mount-info JSON to a file called `mountInfo.json` under `/run/kata-containers/shared/direct-volumes/kubelet/a/b/c/d/sdf`.
**Node unstage volume**
1. In the node CSI driver, the `NodeUnstageVolume` API invokes: `kata-runtime direct-volume remove --volume-path "/kubelet/a/b/c/d/sdf"`.
2. Kata-runtime deletes the directory `/run/kata-containers/shared/direct-volumes/kubelet/a/b/c/d/sdf`.
**Use the volume in sandbox**
1. Upon the request to start a container, the `containerd-shim-kata-v2` examines the container spec,
and iterates through the mounts. For each mount, if there is a `mountInfo.json` file under `/run/kata-containers/shared/direct-volumes/[mount source path]`,
it generates a `storage` GRPC object after overwriting the mount spec with the information in `mountInfo.json`.
2. The shim sends the storage objects to kata-agent through TTRPC.
3. The shim writes a file with the sandbox id as the name under `/run/kata-containers/shared/direct-volumes/[mount source path]`.
4. The kata-agent mounts the storage objects for the container.
**Node expand volume**
1. In the node CSI driver, the `NodeExpandVolume` API invokes: `kata-runtime direct-volume resize -volume-path "/kubelet/a/b/c/d/sdf" -size 8Gi`.
2. The Kata runtime checks whether there is a sandbox id file under the directory `/run/kata-containers/shared/direct-volumes/kubelet/a/b/c/d/sdf`.
3. The Kata runtime identifies the shim instance through the sandbox id, and sends a GRPC request to resize the volume.
4. The shim handles the request, asks the hypervisor to resize the block device and sends a GRPC request to Kata agent to resize the filesystem.
5. Kata agent receives the request and resizes the filesystem.
**Node get volume stats**
1. In the node CSI driver, the `NodeGetVolumeStats` API invokes: `kata-runtime direct-volume stats -volume-path "/kubelet/a/b/c/d/sdf"`.
2. The Kata runtime checks whether there is a sandbox id file under the directory `/run/kata-containers/shared/direct-volumes/kubelet/a/b/c/d/sdf`.
3. The Kata runtime identifies the shim instance through the sandbox id, and sends a GRPC request to get the volume stats.
4. The shim handles the request and forwards it to the Kata agent.
5. Kata agent receives the request and returns the filesystem stats.

19
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@@ -12,7 +12,7 @@ The OCI [runtime specification][linux-config] provides guidance on where the con
> [`cgroupsPath`][cgroupspath]: (string, OPTIONAL) path to the cgroups. It can be used to either control the cgroups
> hierarchy for containers or to run a new process in an existing container
The cgroups are hierarchical, and this can be seen with the following pod example:
Cgroups are hierarchical, and this can be seen with the following pod example:
- Pod 1: `cgroupsPath=/kubepods/pod1`
- Container 1: `cgroupsPath=/kubepods/pod1/container1`
@@ -247,14 +247,14 @@ cgroup size and constraints accordingly.
# Supported cgroups
Kata Containers currently supports cgroups `v1` and `v2`.
Kata Containers currently only supports cgroups `v1`.
In the following sections each cgroup is described briefly.
## cgroups v1
## Cgroups V1
`cgroups v1` are under a [`tmpfs`][1] filesystem mounted at `/sys/fs/cgroup`, where each cgroup is
mounted under a separate cgroup filesystem. A `cgroups v1` hierarchy may look like the following
`Cgroups V1` are under a [`tmpfs`][1] filesystem mounted at `/sys/fs/cgroup`, where each cgroup is
mounted under a separate cgroup filesystem. A `Cgroups v1` hierarchy may look like the following
diagram:
```
@@ -301,12 +301,13 @@ diagram:
A process can join a cgroup by writing its process id (`pid`) to `cgroup.procs` file,
or join a cgroup partially by writing the task (thread) id (`tid`) to the `tasks` file.
Kata Containers only supports `v1`.
To know more about `cgroups v1`, see [cgroupsv1(7)][2].
## cgroups v2
## Cgroups V2
`cgroups v2` are also known as unified cgroups, unlike `cgroups v1`, the cgroups are
mounted under the same cgroup filesystem. A `cgroups v2` hierarchy may look like the following
`Cgroups v2` are also known as unified cgroups, unlike `cgroups v1`, the cgroups are
mounted under the same cgroup filesystem. A `Cgroups v2` hierarchy may look like the following
diagram:
```
@@ -353,6 +354,8 @@ Same as `cgroups v1`, a process can join the cgroup by writing its process id (`
`cgroup.procs` file, or join a cgroup partially by writing the task (thread) id (`tid`) to
`cgroup.threads` file.
Kata Containers does not support cgroups `v2` on the host.
### Distro Support
Many Linux distributions do not yet support `cgroups v2`, as it is quite a recent addition.

1
docs/design/kata-2-0-metrics.md
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@@ -51,7 +51,6 @@ The `kata-monitor` management agent should be started on each node where the Kat
> **Note**: a *node* running Kata containers will be either a single host system or a worker node belonging to a K8s cluster capable of running Kata pods.
- Aggregate sandbox metrics running on the node, adding the `sandbox_id` label to them.
- Attach the additional `cri_uid`, `cri_name` and `cri_namespace` labels to the sandbox metrics, tracking the `uid`, `name` and `namespace` Kubernetes pod metadata.
- Expose a new Prometheus target, allowing all node metrics coming from the Kata shim to be collected by Prometheus indirectly. This simplifies the targets count in Prometheus and avoids exposing shim's metrics by `ip:port`.
Only one `kata-monitor` process runs in each node.

64
docs/design/vcpu-handling.md
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@@ -2,15 +2,24 @@
## Default number of virtual CPUs
Before starting a container, the [runtime][4] reads the `default_vcpus` option
from the [configuration file][5] to determine the number of virtual CPUs
Before starting a container, the [runtime][6] reads the `default_vcpus` option
from the [configuration file][7] to determine the number of virtual CPUs
(vCPUs) needed to start the virtual machine. By default, `default_vcpus` is
equal to 1 for fast boot time and a small memory footprint per virtual machine.
Be aware that increasing this value negatively impacts the virtual machine's
boot time and memory footprint.
In general, we recommend that you do not edit this variable, unless you know
what are you doing. If your container needs more than one vCPU, use
[Kubernetes `cpu` limits][1] to assign more resources.
[docker `--cpus`][1], [docker update][4], or [Kubernetes `cpu` limits][2] to
assign more resources.
*Docker*
```sh
$ docker run --name foo -ti --cpus 2 debian bash
$ docker update --cpus 4 foo
```
*Kubernetes*
@@ -40,7 +49,7 @@ $ sudo -E kubectl create -f ~/cpu-demo.yaml
## Virtual CPUs and Kubernetes pods
A Kubernetes pod is a group of one or more containers, with shared storage and
network, and a specification for how to run the containers [[specification][2]].
network, and a specification for how to run the containers [[specification][3]].
In Kata Containers this group of containers, which is called a sandbox, runs inside
the same virtual machine. If you do not specify a CPU constraint, the runtime does
not add more vCPUs and the container is not placed inside a CPU cgroup.
@@ -64,7 +73,13 @@ constraints with each container trying to consume 100% of vCPU, the resources
divide in two parts, 50% of vCPU for each container because your virtual
machine does not have enough resources to satisfy containers needs. If you want
to give access to a greater or lesser portion of vCPUs to a specific container,
use [Kubernetes `cpu` requests][1].
use [`docker --cpu-shares`][1] or [Kubernetes `cpu` requests][2].
*Docker*
```sh
$ docker run -ti --cpus-shares=512 debian bash
```
*Kubernetes*
@@ -94,9 +109,10 @@ $ sudo -E kubectl create -f ~/cpu-demo.yaml
Before running containers without CPU constraint, consider that your containers
are not running alone. Since your containers run inside a virtual machine other
processes use the vCPUs as well (e.g. `systemd` and the Kata Containers
[agent][3]). In general, we recommend setting `default_vcpus` equal to 1 to
[agent][5]). In general, we recommend setting `default_vcpus` equal to 1 to
allow non-container processes to run on this vCPU and to specify a CPU
constraint for each container.
constraint for each container. If your container is already running and needs
more vCPUs, you can add more using [docker update][4].
## Container with CPU constraint
@@ -105,7 +121,7 @@ constraints using the following formula: `vCPUs = ceiling( quota / period )`, wh
`quota` specifies the number of microseconds per CPU Period that the container is
guaranteed CPU access and `period` specifies the CPU CFS scheduler period of time
in microseconds. The result determines the number of vCPU to hot plug into the
virtual machine. Once the vCPUs have been added, the [agent][3] places the
virtual machine. Once the vCPUs have been added, the [agent][5] places the
container inside a CPU cgroup. This placement allows the container to use only
its assigned resources.
@@ -122,6 +138,25 @@ the virtual machine starts with 8 vCPUs and 1 vCPUs is added and assigned
to the container. Non-container processes might be able to use 8 vCPUs but they
use a maximum 1 vCPU, hence 7 vCPUs might not be used.
*Container without CPU constraint*
```sh
$ docker run -ti debian bash -c "nproc; cat /sys/fs/cgroup/cpu,cpuacct/cpu.cfs_*"
1 # number of vCPUs
100000 # cfs period
-1 # cfs quota
```
*Container with CPU constraint*
```sh
docker run --cpus 4 -ti debian bash -c "nproc; cat /sys/fs/cgroup/cpu,cpuacct/cpu.cfs_*"
5 # number of vCPUs
100000 # cfs period
400000 # cfs quota
```
## Virtual CPU handling without hotplug
In some cases, the hardware and/or software architecture being utilized does not support
@@ -148,8 +183,11 @@ the container's `spec` will provide the sizing information directly. If these ar
calculate the number of CPUs required for the workload and augment this by `default_vcpus`
configuration option, and use this for the virtual machine size.
[1]: https://kubernetes.io/docs/tasks/configure-pod-container/assign-cpu-resource
[2]: https://kubernetes.io/docs/concepts/workloads/pods/pod/
[3]: ../../src/agent
[4]: ../../src/runtime
[5]: ../../src/runtime/README.md#configuration
[1]: https://docs.docker.com/config/containers/resource_constraints/#cpu
[2]: https://kubernetes.io/docs/tasks/configure-pod-container/assign-cpu-resource
[3]: https://kubernetes.io/docs/concepts/workloads/pods/pod/
[4]: https://docs.docker.com/engine/reference/commandline/update/
[5]: ../../src/agent
[6]: ../../src/runtime
[7]: ../../src/runtime/README.md#configuration

37
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@@ -1,37 +0,0 @@
# Design Doc for Kata Containers' VCPUs Pinning Feature
## Background
By now, vCPU threads of Kata Containers are scheduled randomly to CPUs. And each pod would request a specific set of CPUs which we call it CPU set (just the CPU set meaning in Linux cgroups).
If the number of vCPU threads are equal to that of CPUs claimed in CPU set, we can then pin each vCPU thread to one specified CPU, to reduce the cost of random scheduling.
## Detailed Design
### Passing Config Parameters
Two ways are provided to use this vCPU thread pinning feature: through `QEMU` configuration file and through annotations. Finally the pinning parameter is passed to `HypervisorConfig`.
### Related Linux Thread Scheduling API
| API Info | Value |
|-------------------|-----------------------------------------------------------|
| Package | `golang.org/x/sys/unix` |
| Method | `unix.SchedSetaffinity(thread_id, &unixCPUSet)` |
| Official Doc Page | https://pkg.go.dev/golang.org/x/sys/unix#SchedSetaffinity |
### When is VCPUs Pinning Checked?
As shown in Section 1, when `num(vCPU threads) == num(CPUs in CPU set)`, we shall pin each vCPU thread to a specified CPU. And when this condition is broken, we should restore to the original random scheduling pattern.
So when may `num(CPUs in CPU set)` change? There are 5 possible scenes:
| Possible scenes | Related Code |
|-----------------------------------|--------------------------------------------|
| when creating a container | File Sandbox.go, in method `CreateContainer` |
| when starting a container | File Sandbox.go, in method `StartContainer` |
| when deleting a container | File Sandbox.go, in method `DeleteContainer` |
| when updating a container | File Sandbox.go, in method `UpdateContainer` |
| when creating multiple containers | File Sandbox.go, in method `createContainers` |
### Core Pinning Logics
We can split the whole process into the following steps. Related methods are `checkVCPUsPinning` and `resetVCPUsPinning`, in file Sandbox.go.
![](arch-images/vcpus-pinning-process.png)

9
docs/design/virtualization.md
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@@ -39,7 +39,7 @@ Details of each solution and a summary are provided below.
Kata Containers with QEMU has complete compatibility with Kubernetes.
Depending on the host architecture, Kata Containers supports various machine types,
for example `q35` on x86 systems, `virt` on ARM systems and `pseries` on IBM Power systems. The default Kata Containers
for example `pc` and `q35` on x86 systems, `virt` on ARM systems and `pseries` on IBM Power systems. The default Kata Containers
machine type is `q35`. The machine type and its [`Machine accelerators`](#machine-accelerators) can
be changed by editing the runtime [`configuration`](architecture/README.md#configuration) file.
@@ -60,8 +60,9 @@ Machine accelerators are architecture specific and can be used to improve the pe
and enable specific features of the machine types. The following machine accelerators
are used in Kata Containers:
- NVDIMM: This machine accelerator is x86 specific and only supported by `q35` machine types.
`nvdimm` is used to provide the root filesystem as a persistent memory device to the Virtual Machine.
- NVDIMM: This machine accelerator is x86 specific and only supported by `pc` and
`q35` machine types. `nvdimm` is used to provide the root filesystem as a persistent
memory device to the Virtual Machine.
#### Hotplug devices
@@ -110,7 +111,7 @@ Devices and features used:
- VFIO
- hotplug
- seccomp filters
- [HTTP OpenAPI](https://github.com/cloud-hypervisor/cloud-hypervisor/blob/main/vmm/src/api/openapi/cloud-hypervisor.yaml)
- [HTTP OpenAPI](https://github.com/cloud-hypervisor/cloud-hypervisor/blob/master/vmm/src/api/openapi/cloud-hypervisor.yaml)
### Summary

11
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View File

@@ -5,7 +5,7 @@
- [Run Kata containers with `crictl`](run-kata-with-crictl.md)
- [Run Kata Containers with Kubernetes](run-kata-with-k8s.md)
- [How to use Kata Containers and Containerd](containerd-kata.md)
- [How to use Kata Containers and containerd with Kubernetes](how-to-use-k8s-with-containerd-and-kata.md)
- [How to use Kata Containers and CRI (containerd) with Kubernetes](how-to-use-k8s-with-cri-containerd-and-kata.md)
- [Kata Containers and service mesh for Kubernetes](service-mesh.md)
- [How to import Kata Containers logs into Fluentd](how-to-import-kata-logs-with-fluentd.md)
@@ -15,11 +15,6 @@
- `qemu`
- `cloud-hypervisor`
- `firecracker`
In the case of `firecracker` the use of a block device `snapshotter` is needed
for the VM rootfs. Refer to the following guide for additional configuration
steps:
- [Setup Kata containers with `firecracker`](how-to-use-kata-containers-with-firecracker.md)
- `ACRN`
While `qemu` , `cloud-hypervisor` and `firecracker` work out of the box with installation of Kata,
@@ -42,6 +37,4 @@
- [How to setup swap devices in guest kernel](how-to-setup-swap-devices-in-guest-kernel.md)
- [How to run rootless vmm](how-to-run-rootless-vmm.md)
- [How to run Docker with Kata Containers](how-to-run-docker-with-kata.md)
- [How to run Kata Containers with `nydus`](how-to-use-virtio-fs-nydus-with-kata.md)
- [How to run Kata Containers with AMD SEV-SNP](how-to-run-kata-containers-with-SNP-VMs.md)
- [How to use EROFS to build rootfs in Kata Containers](how-to-use-erofs-build-rootfs.md)
- [How to run Kata Containers with `nydus`](how-to-use-virtio-fs-nydus-with-kata.md)

160
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View File

@@ -40,7 +40,7 @@ use `RuntimeClass` instead of the deprecated annotations.
### Containerd Runtime V2 API: Shim V2 API
The [`containerd-shim-kata-v2` (short as `shimv2` in this documentation)](../../src/runtime/cmd/containerd-shim-kata-v2/)
implements the [Containerd Runtime V2 (Shim API)](https://github.com/containerd/containerd/tree/main/runtime/v2) for Kata.
implements the [Containerd Runtime V2 (Shim API)](https://github.com/containerd/containerd/tree/master/runtime/v2) for Kata.
With `shimv2`, Kubernetes can launch Pod and OCI-compatible containers with one shim per Pod. Prior to `shimv2`, `2N+1`
shims (i.e. a `containerd-shim` and a `kata-shim` for each container and the Pod sandbox itself) and no standalone `kata-proxy`
process were used, even with VSOCK not available.
@@ -72,13 +72,14 @@ $ command -v containerd
### Install CNI plugins
> **Note:** You do not need to install CNI plugins if you do not want to use containerd with Kubernetes.
> If you have installed Kubernetes with `kubeadm`, you might have already installed the CNI plugins.
You can manually install CNI plugins as follows:
```bash
$ git clone https://github.com/containernetworking/plugins.git
$ pushd plugins
$ go get github.com/containernetworking/plugins
$ pushd $GOPATH/src/github.com/containernetworking/plugins
$ ./build_linux.sh
$ sudo mkdir /opt/cni
$ sudo cp -r bin /opt/cni/
@@ -93,8 +94,8 @@ $ popd
You can install the `cri-tools` from source code:
```bash
$ git clone https://github.com/kubernetes-sigs/cri-tools.git
$ pushd cri-tools
$ go get github.com/kubernetes-incubator/cri-tools
$ pushd $GOPATH/src/github.com/kubernetes-incubator/cri-tools
$ make
$ sudo -E make install
$ popd
@@ -130,42 +131,74 @@ For
The `RuntimeClass` is suggested.
The following configuration includes two runtime classes:
The following configuration includes three runtime classes:
- `plugins.cri.containerd.runtimes.runc`: the runc, and it is the default runtime.
- `plugins.cri.containerd.runtimes.kata`: The function in containerd (reference [the document here](https://github.com/containerd/containerd/tree/main/runtime/v2#binary-naming))
- `plugins.cri.containerd.runtimes.kata`: The function in containerd (reference [the document here](https://github.com/containerd/containerd/tree/master/runtime/v2#binary-naming))
where the dot-connected string `io.containerd.kata.v2` is translated to `containerd-shim-kata-v2` (i.e. the
binary name of the Kata implementation of [Containerd Runtime V2 (Shim API)](https://github.com/containerd/containerd/tree/main/runtime/v2)).
binary name of the Kata implementation of [Containerd Runtime V2 (Shim API)](https://github.com/containerd/containerd/tree/master/runtime/v2)).
- `plugins.cri.containerd.runtimes.katacli`: the `containerd-shim-runc-v1` calls `kata-runtime`, which is the legacy process.
```toml
[plugins.cri.containerd]
no_pivot = false
[plugins.cri.containerd.runtimes]
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.runc]
privileged_without_host_devices = false
runtime_type = "io.containerd.runc.v2"
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.runc.options]
BinaryName = ""
CriuImagePath = ""
CriuPath = ""
CriuWorkPath = ""
IoGid = 0
[plugins.cri.containerd.runtimes.runc]
runtime_type = "io.containerd.runc.v1"
[plugins.cri.containerd.runtimes.runc.options]
NoPivotRoot = false
NoNewKeyring = false
ShimCgroup = ""
IoUid = 0
IoGid = 0
BinaryName = "runc"
Root = ""
CriuPath = ""
SystemdCgroup = false
[plugins.cri.containerd.runtimes.kata]
runtime_type = "io.containerd.kata.v2"
privileged_without_host_devices = true
pod_annotations = ["io.katacontainers.*"]
container_annotations = ["io.katacontainers.*"]
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.kata.options]
ConfigPath = "/opt/kata/share/defaults/kata-containers/configuration.toml"
[plugins.cri.containerd.runtimes.katacli]
runtime_type = "io.containerd.runc.v1"
[plugins.cri.containerd.runtimes.katacli.options]
NoPivotRoot = false
NoNewKeyring = false
ShimCgroup = ""
IoUid = 0
IoGid = 0
BinaryName = "/usr/bin/kata-runtime"
Root = ""
CriuPath = ""
SystemdCgroup = false
```
From Containerd v1.2.4 and Kata v1.6.0, there is a new runtime option supported, which allows you to specify a specific Kata configuration file as follows:
```toml
[plugins.cri.containerd.runtimes.kata]
runtime_type = "io.containerd.kata.v2"
privileged_without_host_devices = true
[plugins.cri.containerd.runtimes.kata.options]
ConfigPath = "/etc/kata-containers/config.toml"
```
`privileged_without_host_devices` tells containerd that a privileged Kata container should not have direct access to all host devices. If unset, containerd will pass all host devices to Kata container, which may cause security issues.
`pod_annotations` is the list of pod annotations passed to both the pod sandbox as well as container through the OCI config.
`container_annotations` is the list of container annotations passed through to the OCI config of the containers.
This `ConfigPath` option is optional. If you do not specify it, shimv2 first tries to get the configuration file from the environment variable `KATA_CONF_FILE`. If neither are set, shimv2 will use the default Kata configuration file paths (`/etc/kata-containers/configuration.toml` and `/usr/share/defaults/kata-containers/configuration.toml`).
If you use Containerd older than v1.2.4 or a version of Kata older than v1.6.0 and also want to specify a configuration file, you can use the following workaround, since the shimv2 accepts an environment variable, `KATA_CONF_FILE` for the configuration file path. Then, you can create a
shell script with the following:
```bash
#!/usr/bin/env bash
KATA_CONF_FILE=/etc/kata-containers/firecracker.toml containerd-shim-kata-v2 $@
```
Name it as `/usr/local/bin/containerd-shim-katafc-v2` and reference it in the configuration of containerd:
```toml
[plugins.cri.containerd.runtimes.kata-firecracker]
runtime_type = "io.containerd.katafc.v2"
```
#### Kata Containers as the runtime for untrusted workload
For cases without `RuntimeClass` support, we can use the legacy annotation method to support using Kata Containers
@@ -185,8 +218,28 @@ and then, run an untrusted workload with Kata Containers:
runtime_type = "io.containerd.kata.v2"
```
For the earlier versions of Kata Containers and containerd that do not support Runtime V2 (Shim API), you can use the following alternative configuration:
```toml
[plugins.cri.containerd]
# "plugins.cri.containerd.default_runtime" is the runtime to use in containerd.
[plugins.cri.containerd.default_runtime]
# runtime_type is the runtime type to use in containerd e.g. io.containerd.runtime.v1.linux
runtime_type = "io.containerd.runtime.v1.linux"
# "plugins.cri.containerd.untrusted_workload_runtime" is a runtime to run untrusted workloads on it.
[plugins.cri.containerd.untrusted_workload_runtime]
# runtime_type is the runtime type to use in containerd e.g. io.containerd.runtime.v1.linux
runtime_type = "io.containerd.runtime.v1.linux"
# runtime_engine is the name of the runtime engine used by containerd.
runtime_engine = "/usr/bin/kata-runtime"
```
You can find more information on the [Containerd config documentation](https://github.com/containerd/cri/blob/master/docs/config.md)
#### Kata Containers as the default runtime
If you want to set Kata Containers as the only runtime in the deployment, you can simply configure as follows:
@@ -197,6 +250,15 @@ If you want to set Kata Containers as the only runtime in the deployment, you ca
runtime_type = "io.containerd.kata.v2"
```
Alternatively, for the earlier versions of Kata Containers and containerd that do not support Runtime V2 (Shim API), you can use the following alternative configuration:
```toml
[plugins.cri.containerd]
[plugins.cri.containerd.default_runtime]
runtime_type = "io.containerd.runtime.v1.linux"
runtime_engine = "/usr/bin/kata-runtime"
```
### Configuration for `cri-tools`
> **Note:** If you skipped the [Install `cri-tools`](#install-cri-tools) section, you can skip this section too.
@@ -250,55 +312,11 @@ To run a container with Kata Containers through the containerd command line, you
```bash
$ sudo ctr image pull docker.io/library/busybox:latest
$ sudo ctr run --cni --runtime io.containerd.run.kata.v2 -t --rm docker.io/library/busybox:latest hello sh
$ sudo ctr run --runtime io.containerd.run.kata.v2 -t --rm docker.io/library/busybox:latest hello sh
```
This launches a BusyBox container named `hello`, and it will be removed by `--rm` after it quits.
The `--cni` flag enables CNI networking for the container. Without this flag, a container with just a
loopback interface is created.
### Launch containers using `ctr` command line with rootfs bundle
#### Get rootfs
Use the script to create rootfs
```bash
ctr i pull quay.io/prometheus/busybox:latest
ctr i export rootfs.tar quay.io/prometheus/busybox:latest
rootfs_tar=rootfs.tar
bundle_dir="./bundle"
mkdir -p "${bundle_dir}"
# extract busybox rootfs
rootfs_dir="${bundle_dir}/rootfs"
mkdir -p "${rootfs_dir}"
layers_dir="$(mktemp -d)"
tar -C "${layers_dir}" -pxf "${rootfs_tar}"
for ((i=0;i<$(cat ${layers_dir}/manifest.json | jq -r ".[].Layers | length");i++)); do
tar -C ${rootfs_dir} -xf ${layers_dir}/$(cat ${layers_dir}/manifest.json | jq -r ".[].Layers[${i}]")
done
```
#### Get `config.json`
Use runc spec to generate `config.json`
```bash
cd ./bundle/rootfs
runc spec
mv config.json ../
```
Change the root `path` in `config.json` to the absolute path of rootfs
```JSON
"root":{
"path":"/root/test/bundle/rootfs",
"readonly": false
},
```
#### Run container
```bash
sudo ctr run -d --runtime io.containerd.run.kata.v2 --config bundle/config.json hello
sudo ctr t exec --exec-id ${ID} -t hello sh
```
### Launch Pods with `crictl` command line
With the `crictl` command line of `cri-tools`, you can specify runtime class with `-r` or `--runtime` flag.

6
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View File

@@ -45,9 +45,6 @@ spec:
- name: containerdsocket
mountPath: /run/containerd/containerd.sock
readOnly: true
- name: sbs
mountPath: /run/vc/sbs/
readOnly: true
terminationGracePeriodSeconds: 30
volumes:
- name: containerdtask
@@ -56,6 +53,3 @@ spec:
- name: containerdsocket
hostPath:
path: /run/containerd/containerd.sock
- name: sbs
hostPath:
path: /run/vc/sbs/

12
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View File

@@ -15,18 +15,6 @@ $ sudo .ci/aarch64/install_rom_aarch64.sh
$ popd
```
## Config KATA QEMU
After executing the above script, two files will be generated under the directory `/usr/share/kata-containers/` by default, namely `kata-flash0.img` and `kata-flash1.img`. Next we need to change the configuration file of `kata qemu`, which is in `/opt/kata/share/defaults/kata-containers/configuration-qemu.toml` by default, specify in the configuration file to use the UEFI ROM installed above. The above is an example of `kata deploy` installation. For package management installation, please use `kata-runtime env` to find the location of the configuration file. Please refer to the following configuration.
```
[hypervisor.qemu]
# -pflash can add image file to VM. The arguments of it should be in format
# of ["/path/to/flash0.img", "/path/to/flash1.img"]
pflashes = ["/usr/share/kata-containers/kata-flash0.img", "/usr/share/kata-containers/kata-flash1.img"]
```
## Run for test
Let's test if the memory hotplug is ready for Kata after install the UEFI ROM. Make sure containerd is ready to run Kata before test.

4
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View File

@@ -68,7 +68,7 @@ the Kata logs import to the EFK stack.
> stack they are able to utilise in order to modify and test as necessary.
Minikube by default
[configures](https://github.com/kubernetes/minikube/blob/master/deploy/iso/minikube-iso/board/minikube/x86_64/rootfs-overlay/etc/systemd/journald.conf)
[configures](https://github.com/kubernetes/minikube/blob/master/deploy/iso/minikube-iso/board/coreos/minikube/rootfs-overlay/etc/systemd/journald.conf)
the `systemd-journald` with the
[`Storage=volatile`](https://www.freedesktop.org/software/systemd/man/journald.conf.html) option,
which results in the journal being stored in `/run/log/journal`. Unfortunately, the Minikube EFK
@@ -163,7 +163,7 @@ sub-filter on, for instance, the `SYSLOG_IDENTIFIER` to differentiate the Kata c
on the `PRIORITY` to filter out critical issues etc.
Kata generates a significant amount of Kata specific information, which can be seen as
[`logfmt`](../../src/tools/log-parser/README.md#logfile-requirements).
[`logfmt`](https://github.com/kata-containers/tests/tree/main/cmd/log-parser#logfile-requirements).
data contained in the `MESSAGE` field. Imported as-is, there is no easy way to filter on that data
in Kibana:

6
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View File

@@ -48,9 +48,9 @@ Running Docker containers Kata Containers requires care because `VOLUME`s specif
kataShared on / type virtiofs (rw,relatime,dax)
```
`kataShared` mount types are powered by [`virtio-fs`](https://virtio-fs.gitlab.io/), a marked improvement over `virtio-9p`, thanks to [PR #1016](https://github.com/kata-containers/runtime/pull/1016). While `virtio-fs` is normally an excellent choice, in the case of DinD workloads `virtio-fs` causes an issue -- [it *cannot* be used as a "upper layer" of `overlayfs` without a custom patch](http://lists.katacontainers.io/pipermail/kata-dev/2020-January/001216.html).
`kataShared` mount types are powered by [`virtio-fs`][virtio-fs], a marked improvement over `virtio-9p`, thanks to [PR #1016](https://github.com/kata-containers/runtime/pull/1016). While `virtio-fs` is normally an excellent choice, in the case of DinD workloads `virtio-fs` causes an issue -- [it *cannot* be used as a "upper layer" of `overlayfs` without a custom patch](http://lists.katacontainers.io/pipermail/kata-dev/2020-January/001216.html).
As `/var/lib/docker` is a `VOLUME` specified by DinD (i.e. the `docker` images tagged `*-dind`/`*-dind-rootless`), `docker` will fail to start (or even worse, silently pick a worse storage driver like `vfs`) when started in a Kata Container. Special measures must be taken when running DinD-powered workloads in Kata Containers.
As `/var/lib/docker` is a `VOLUME` specified by DinD (i.e. the `docker` images tagged `*-dind`/`*-dind-rootless`), `docker` fill fail to start (or even worse, silently pick a worse storage driver like `vfs`) when started in a Kata Container. Special measures must be taken when running DinD-powered workloads in Kata Containers.
## Workarounds/Solutions
@@ -58,7 +58,7 @@ Thanks to various community contributions (see [issue references below](#referen
### Use a memory backed volume
For small workloads (small container images, without much generated filesystem load), a memory-backed volume is sufficient. Kubernetes supports a variant of [the `EmptyDir` volume](https://kubernetes.io/docs/concepts/storage/volumes/#emptydir), which allows for memdisk-backed storage -- the the `medium: Memory`. An example of a `Pod` using such a setup [was contributed](https://github.com/kata-containers/runtime/issues/1429#issuecomment-477385283), and is reproduced below:
For small workloads (small container images, without much generated filesystem load), a memory-backed volume is sufficient. Kubernetes supports a variant of [the `EmptyDir` volume][k8s-emptydir], which allows for memdisk-backed storage -- the [the `medium: Memory` ][k8s-memory-volume-type]. An example of a `Pod` using such a setup [was contributed](https://github.com/kata-containers/runtime/issues/1429#issuecomment-477385283), and is reproduced below:
```yaml
apiVersion: v1

159
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View File

@@ -1,159 +0,0 @@
# Kata Containers with AMD SEV-SNP VMs
## Disclaimer
This guide is designed for developers and is - same as the Developer Guide - not intended for production systems or end users. It is advisable to only follow this guide on non-critical development systems.
## Prerequisites
To run Kata Containers in SNP-VMs, the following software stack is used.
![Kubernetes integration with shimv2](./images/SNP-stack.svg)
The host BIOS and kernel must be capable of supporting AMD SEV-SNP and configured accordingly. For Kata Containers, the host kernel with branch [`sev-snp-iommu-avic_5.19-rc6_v3`](https://github.com/AMDESE/linux/tree/sev-snp-iommu-avic_5.19-rc6_v3) and commit [`3a88547`](https://github.com/AMDESE/linux/commit/3a885471cf89156ea555341f3b737ad2a8d9d3d0) is known to work in conjunction with SEV Firmware version 1.51.3 (0xh\_1.33.03) available on AMD's [SEV developer website](https://developer.amd.com/sev/). See [AMD's guide](https://github.com/AMDESE/AMDSEV/tree/sev-snp-devel) to configure the host accordingly. Verify that you are able to run SEV-SNP encrypted VMs first. The guest components required for Kata Containers are built as described below.
**Tip**: It is easiest to first have Kata Containers running on your system and then modify it to run containers in SNP-VMs. Follow the [Developer guide](../Developer-Guide.md#warning) and then follow the below steps. Nonetheless, you can just follow this guide from the start.
## How to build
Follow all of the below steps to install Kata Containers with SNP-support from scratch. These steps mostly follow the developer guide with modifications to support SNP
__Steps from the Developer Guide:__
- Get all the [required components](../Developer-Guide.md#requirements-to-build-individual-components) for building the kata-runtime
- [Build the and install kata-runtime](../Developer-Guide.md#build-and-install-the-kata-containers-runtime)
- [Build a custom agent](../Developer-Guide.md#build-a-custom-kata-agent---optional)
- [Create an initrd image](../Developer-Guide.md#create-an-initrd-image---optional) by first building a rootfs, then building the initrd based on the rootfs, use a custom agent and install. `ubuntu` works as the distribution of choice.
- Get the [required components](../../tools/packaging/kernel/README.md#requirements) to build a custom kernel
__SNP-specific steps:__
- Build the SNP-specific kernel as shown below (see this [guide](../../tools/packaging/kernel/README.md#build-kata-containers-kernel) for more information)
```bash
$ pushd kata-containers/tools/packaging/kernel/
$ ./build-kernel.sh -a x86_64 -x snp setup
$ ./build-kernel.sh -a x86_64 -x snp build
$ sudo -E PATH="${PATH}" ./build-kernel.sh -x snp install
$ popd
```
- Build a current OVMF capable of SEV-SNP:
```bash
$ pushd kata-containers/tools/packaging/static-build/ovmf
$ ./build.sh
$ tar -xvf edk2-x86_64.tar.gz
$ popd
```
- Build a custom QEMU
```bash
$ source kata-containers/tools/packaging/scripts/lib.sh
$ qemu_url="$(get_from_kata_deps "assets.hypervisor.qemu.snp.url")"
$ qemu_branch="$(get_from_kata_deps "assets.hypervisor.qemu.snp.branch")"
$ qemu_commit="$(get_from_kata_deps "assets.hypervisor.qemu.snp.commit")"
$ git clone -b "${qemu_branch}" "${qemu_url}"
$ pushd qemu
$ git checkout "${qemu_commit}"
$ ./configure --enable-virtfs --target-list=x86_64-softmmu --enable-debug
$ make -j "$(nproc)"
$ popd
```
### Kata Containers Configuration for SNP
The configuration file located at `/etc/kata-containers/configuration.toml` must be adapted as follows to support SNP-VMs:
- Use the SNP-specific kernel for the guest VM (change path)
```toml
kernel = "/usr/share/kata-containers/vmlinuz-snp.container"
```
- Enable the use of an initrd (uncomment)
```toml
initrd = "/usr/share/kata-containers/kata-containers-initrd.img"
```
- Disable the use of a rootfs (comment out)
```toml
# image = "/usr/share/kata-containers/kata-containers.img"
```
- Use the custom QEMU capable of SNP (change path)
```toml
path = "/path/to/qemu/build/qemu-system-x86_64"
```
- Use `virtio-9p` device since `virtio-fs` is unsupported due to bugs / shortcomings in QEMU version [`snp-v3`](https://github.com/AMDESE/qemu/tree/snp-v3) for SEV and SEV-SNP (change value)
```toml
shared_fs = "virtio-9p"
```
- Disable `virtiofsd` since it is no longer required (comment out)
```toml
# virtio_fs_daemon = "/usr/libexec/virtiofsd"
```
- Disable NVDIMM (uncomment)
```toml
disable_image_nvdimm = true
```
- Disable shared memory (uncomment)
```toml
file_mem_backend = ""
```
- Enable confidential guests (uncomment)
```toml
confidential_guest = true
```
- Enable SNP-VMs (uncomment)
```toml
sev_snp_guest = true
```
- Configure an OVMF (add path)
```toml
firmware = "/path/to/kata-containers/tools/packaging/static-build/ovmf/opt/kata/share/ovmf/OVMF.fd"
```
## Test Kata Containers with Containerd
With Kata Containers configured to support SNP-VMs, we use containerd to test and deploy containers in these VMs.
### Install Containerd
If not already present, follow [this guide](./containerd-kata.md#install) to install containerd and its related components including `CNI` and the `cri-tools` (skip Kata Containers since we already installed it)
### Containerd Configuration
Follow [this guide](./containerd-kata.md#configuration) to configure containerd to use Kata Containers
## Run Kata Containers in SNP-VMs
Run the below commands to start a container. See [this guide](./containerd-kata.md#run) for more information
```bash
$ sudo ctr image pull docker.io/library/busybox:latest
$ sudo ctr run --cni --runtime io.containerd.run.kata.v2 -t --rm docker.io/library/busybox:latest hello sh
```
### Check for active SNP:
Inside the running container, run the following commands to check if SNP is active. It should look something like this:
```
/ # dmesg | grep -i sev
[ 0.299242] Memory Encryption Features active: AMD SEV SEV-ES SEV-SNP
[ 0.472286] SEV: Using SNP CPUID table, 31 entries present.
[ 0.514574] SEV: SNP guest platform device initialized.
[ 0.885425] sev-guest sev-guest: Initialized SEV guest driver (using vmpck_id 0)
```
### Obtain an SNP Attestation Report
To obtain an attestation report inside the container, the `/dev/sev-guest` must first be configured. As of now, the VM does not perform this step, however it can be performed inside the container, either in the terminal or in code.
Example for shell:
```
/ # SNP_MAJOR=$(cat /sys/devices/virtual/misc/sev-guest/dev | awk -F: '{print $1}')
/ # SNP_MINOR=$(cat /sys/devices/virtual/misc/sev-guest/dev | awk -F: '{print $2}')
/ # mknod -m 600 /dev/sev-guest c "${SNP_MAJOR}" "${SNP_MINOR}"
```
## Known Issues
- Support for cgroups v2 is still [work in progress](https://github.com/kata-containers/kata-containers/issues/927). If issues occur due to cgroups v2 becoming the default in newer systems, one possible solution is to downgrade cgroups to v1:
```bash
sudo sed -i 's/^\(GRUB_CMDLINE_LINUX=".*\)"/\1 systemd.unified_cgroup_hierarchy=0"/' /etc/default/grub
sudo update-grub
sudo reboot
```
- If both SEV and SEV-SNP are supported by the host, Kata Containers uses SEV-SNP by default. You can verify what features are enabled by checking `/sys/module/kvm_amd/parameters/sev` and `sev_snp`. This means that Kata Containers can not run both SEV-SNP-VMs and SEV-VMs at the same time. If SEV is to be used by Kata Containers instead, reload the `kvm_amd` kernel module without SNP-support, this will disable SNP-support for the entire platform.
```bash
sudo rmmod kvm_amd && sudo modprobe kvm_amd sev_snp=0
```

2
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@@ -19,7 +19,7 @@ Also you should ensure that `kubectl` working correctly.
> **Note**: More information about Kubernetes integrations:
> - [Run Kata Containers with Kubernetes](run-kata-with-k8s.md)
> - [How to use Kata Containers and Containerd](containerd-kata.md)
> - [How to use Kata Containers and containerd with Kubernetes](how-to-use-k8s-with-containerd-and-kata.md)
> - [How to use Kata Containers and CRI (containerd plugin) with Kubernetes](how-to-use-k8s-with-cri-containerd-and-kata.md)
## Configure Prometheus

6
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View File

@@ -57,7 +57,6 @@ There are several kinds of Kata configurations and they are listed below.
| `io.katacontainers.config.hypervisor.enable_iothreads` | `boolean`| enable IO to be processed in a separate thread. Supported currently for virtio-`scsi` driver |
| `io.katacontainers.config.hypervisor.enable_mem_prealloc` | `boolean` | the memory space used for `nvdimm` device by the hypervisor |
| `io.katacontainers.config.hypervisor.enable_vhost_user_store` | `boolean` | enable vhost-user storage device (QEMU) |
| `io.katacontainers.config.hypervisor.vhost_user_reconnect_timeout_sec` | `string`| the timeout for reconnecting vhost user socket (QEMU)
| `io.katacontainers.config.hypervisor.enable_virtio_mem` | `boolean` | enable virtio-mem (QEMU) |
| `io.katacontainers.config.hypervisor.entropy_source` (R) | string| the path to a host source of entropy (`/dev/random`, `/dev/urandom` or real hardware RNG device) |
| `io.katacontainers.config.hypervisor.file_mem_backend` (R) | string | file based memory backend root directory |
@@ -88,11 +87,10 @@ There are several kinds of Kata configurations and they are listed below.
| `io.katacontainers.config.hypervisor.use_vsock` | `boolean` | specify use of `vsock` for agent communication |
| `io.katacontainers.config.hypervisor.vhost_user_store_path` (R) | `string` | specify the directory path where vhost-user devices related folders, sockets and device nodes should be (QEMU) |
| `io.katacontainers.config.hypervisor.virtio_fs_cache_size` | uint32 | virtio-fs DAX cache size in `MiB` |
| `io.katacontainers.config.hypervisor.virtio_fs_cache` | string | the cache mode for virtio-fs, valid values are `always`, `auto` and `never` |
| `io.katacontainers.config.hypervisor.virtio_fs_cache` | string | the cache mode for virtio-fs, valid values are `always`, `auto` and `none` |
| `io.katacontainers.config.hypervisor.virtio_fs_daemon` | string | virtio-fs `vhost-user` daemon path |
| `io.katacontainers.config.hypervisor.virtio_fs_extra_args` | string | extra options passed to `virtiofs` daemon |
| `io.katacontainers.config.hypervisor.enable_guest_swap` | `boolean` | enable swap in the guest |
| `io.katacontainers.config.hypervisor.use_legacy_serial` | `boolean` | uses legacy serial device for guest's console (QEMU) |
## Container Options
| Key | Value Type | Comments |
@@ -174,7 +172,7 @@ kind: Pod
metadata:
name: pod2
annotations:
io.katacontainers.config.runtime.disable_guest_seccomp: "false"
io.katacontainers.config.runtime.disable_guest_seccomp: false
spec:
runtimeClassName: kata
containers:

8
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View File

@@ -17,9 +17,9 @@ Enable setup swap device in guest kernel as follows:
$ sudo sed -i -e 's/^#enable_guest_swap.*$/enable_guest_swap = true/g' /etc/kata-containers/configuration.toml
```
## Run a Kata Containers utilizing swap device
## Run a Kata Container utilizing swap device
Use following command to start a Kata Containers with swappiness 60 and 1GB swap device (swap_in_bytes - memory_limit_in_bytes).
Use following command to start a Kata Container with swappiness 60 and 1GB swap device (swap_in_bytes - memory_limit_in_bytes).
```
$ pod_yaml=pod.yaml
$ container_yaml=container.yaml
@@ -43,12 +43,12 @@ command:
- top
EOF
$ sudo crictl pull $image
$ podid=$(sudo crictl runp --runtime kata $pod_yaml)
$ podid=$(sudo crictl runp $pod_yaml)
$ cid=$(sudo crictl create $podid $container_yaml $pod_yaml)
$ sudo crictl start $cid
```
Kata Containers setups swap device for this container only when `io.katacontainers.container.resource.swappiness` is set.
Kata Container setups swap device for this container only when `io.katacontainers.container.resource.swappiness` is set.
The following table shows the swap size how to decide if `io.katacontainers.container.resource.swappiness` is set.
|`io.katacontainers.container.resource.swap_in_bytes`|`memory_limit_in_bytes`|swap size|

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@@ -1,90 +0,0 @@
# Configure Kata Containers to use EROFS build rootfs
## Introduction
For kata containers, rootfs is used in the read-only way. EROFS can noticeably decrease metadata overhead.
`mkfs.erofs` can generate compressed and uncompressed EROFS images.
For uncompressed images, no files are compressed. However, it is optional to inline the data blocks at the end of the file with the metadata.
For compressed images, each file will be compressed using the lz4 or lz4hc algorithm, and it will be confirmed whether it can save space. Use No compression of the file if compression does not save space.
## Performance comparison
| | EROFS | EXT4 | XFS |
|-----------------|-------| --- | --- |
| Image Size [MB] | 106(uncompressed) | 256 | 126 |
## Guidance
### Install the `erofs-utils`
#### `apt/dnf` install
On newer `Ubuntu/Debian` systems, it can be installed directly using the `apt` command, and on `Fedora` it can be installed directly using the `dnf` command.
```shell
# Debian/Ubuntu
$ apt install erofs-utils
# Fedora
$ dnf install erofs-utils
```
#### Source install
[https://git.kernel.org/pub/scm/linux/kernel/git/xiang/erofs-utils.git](https://git.kernel.org/pub/scm/linux/kernel/git/xiang/erofs-utils.git)
##### Compile dependencies
If you need to enable the `Lz4` compression feature, `Lz4 1.8.0+` is required, and `Lz4 1.9.3+` is strongly recommended.
##### Compilation process
For some old lz4 versions (lz4-1.8.0~1.8.3), if lz4-static is not installed, the lz4hc algorithm will not be supported. lz4-static can be installed with apt install lz4-static.x86_64. However, these versions have some bugs in compression, and it is not recommended to use these versions directly.
If you use `lz4 1.9.0+`, you can directly use the following command to compile.
```shell
$ ./autogen.sh
$ ./configure
$ make
```
The compiled `mkfs.erofs` program will be saved in the `mkfs` directory. Afterwards, the generated tools can be installed to a system directory using make install (requires root privileges).
### Create a local rootfs
```shell
$ export distro="ubuntu"
$ export FS_TYPE="erofs"
$ export ROOTFS_DIR="realpath kata-containers/tools/osbuilder/rootfs-builder/rootfs"
$ sudo rm -rf "${ROOTFS_DIR}"
$ pushd kata-containers/tools/osbuilder/rootfs-builder
$ script -fec 'sudo -E SECCOMP=no ./rootfs.sh "${distro}"'
$ popd
```
### Add a custom agent to the image - OPTIONAL
> Note:
> - You should only do this step if you are testing with the latest version of the agent.
```shell
$ sudo install -o root -g root -m 0550 -t "${ROOTFS_DIR}/usr/bin" "${ROOTFS_DIR}/../../../../src/agent/target/x86_64-unknown-linux-musl/release/kata-agent"
$ sudo install -o root -g root -m 0440 "${ROOTFS_DIR}/../../../../src/agent/kata-agent.service" "${ROOTFS_DIR}/usr/lib/systemd/system/"
$ sudo install -o root -g root -m 0440 "${ROOTFS_DIR}/../../../../src/agent/kata-containers.target" "${ROOTFS_DIR}/usr/lib/systemd/system/"
```
### Build a root image
```shell
$ pushd kata-containers/tools/osbuilder/image-builder
$ script -fec 'sudo -E ./image_builder.sh "${ROOTFS_DIR}"'
$ popd
```
### Install the rootfs image
```shell
$ pushd kata-containers/tools/osbuilder/image-builder
$ commit="$(git log --format=%h -1 HEAD)"
$ date="$(date +%Y-%m-%d-%T.%N%z)"
$ rootfs="erofs"
$ image="kata-containers-${rootfs}-${date}-${commit}"
$ sudo install -o root -g root -m 0640 -D kata-containers.img "/usr/share/kata-containers/${image}"
$ (cd /usr/share/kata-containers && sudo ln -sf "$image" kata-containers.img)
$ popd
```
### Use `EROFS` in the runtime
```shell
$ sudo sed -i -e 's/^# *\(rootfs_type\).*=.*$/\1 = erofs/g' /etc/kata-containers/configuration.toml
```

12
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@@ -1,15 +1,15 @@
# How to use Kata Containers and containerd with Kubernetes
# How to use Kata Containers and CRI (containerd plugin) with Kubernetes
This document describes how to set up a single-machine Kubernetes (k8s) cluster.
The Kubernetes cluster will use the
[containerd](https://github.com/containerd/containerd/) and
[Kata Containers](https://katacontainers.io) to launch workloads.
[CRI containerd](https://github.com/containerd/containerd/) and
[Kata Containers](https://katacontainers.io) to launch untrusted workloads.
## Requirements
- Kubernetes, Kubelet, `kubeadm`
- containerd
- containerd with `cri` plug-in
- Kata Containers
> **Note:** For information about the supported versions of these components,
@@ -149,7 +149,7 @@ $ sudo -E kubectl taint nodes --all node-role.kubernetes.io/master-
## Create runtime class for Kata Containers
By default, all pods are created with the default runtime configured in containerd.
By default, all pods are created with the default runtime configured in CRI containerd plugin.
From Kubernetes v1.12, users can use [`RuntimeClass`](https://kubernetes.io/docs/concepts/containers/runtime-class/#runtime-class) to specify a different runtime for Pods.
```bash
@@ -166,7 +166,7 @@ $ sudo -E kubectl apply -f runtime.yaml
## Run pod in Kata Containers
If a pod has the `runtimeClassName` set to `kata`, the CRI runs the pod with the
If a pod has the `runtimeClassName` set to `kata`, the CRI plugin runs the pod with the
[Kata Containers runtime](../../src/runtime/README.md).
- Create an pod configuration that using Kata Containers runtime

2
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View File

@@ -101,7 +101,7 @@ Start an ACRN based Kata Container,
$ sudo docker run -ti --runtime=kata-runtime busybox sh
```
You will see ACRN(`acrn-dm`) is now running on your system, as well as a `kata-shim`. You should obtain an interactive shell prompt. Verify that all the Kata processes terminate once you exit the container.
You will see ACRN(`acrn-dm`) is now running on your system, as well as a `kata-shim`, `kata-proxy`. You should obtain an interactive shell prompt. Verify that all the Kata processes terminate once you exit the container.
```bash
$ ps -ef | grep -E "kata|acrn"

254
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View File

@@ -1,254 +0,0 @@
# Configure Kata Containers to use Firecracker
This document provides an overview on how to run Kata Containers with the AWS Firecracker hypervisor.
## Introduction
AWS Firecracker is an open source virtualization technology that is purpose-built for creating and managing secure, multi-tenant container and function-based services that provide serverless operational models. AWS Firecracker runs workloads in lightweight virtual machines, called `microVMs`, which combine the security and isolation properties provided by hardware virtualization technology with the speed and flexibility of Containers.
Please refer to AWS Firecracker [documentation](https://github.com/firecracker-microvm/firecracker/blob/main/docs/getting-started.md) for more details.
## Pre-requisites
This document requires the presence of Kata Containers on your system. Install using the instructions available through the following links:
- Kata Containers [automated installation](../install/README.md)
- Kata Containers manual installation: Automated installation does not seem to be supported for Clear Linux, so please use [manual installation](../Developer-Guide.md) steps.
> **Note:** Create rootfs image and not initrd image.
## Install AWS Firecracker
Kata Containers only support AWS Firecracker v0.23.4 ([yet](https://github.com/kata-containers/kata-containers/pull/1519)).
To install Firecracker we need to get the `firecracker` and `jailer` binaries:
```bash
$ release_url="https://github.com/firecracker-microvm/firecracker/releases"
$ version="v0.23.1"
$ arch=`uname -m`
$ curl ${release_url}/download/${version}/firecracker-${version}-${arch} -o firecracker
$ curl ${release_url}/download/${version}/jailer-${version}-${arch} -o jailer
$ chmod +x jailer firecracker
```
To make the binaries available from the default system `PATH` it is recommended to move them to `/usr/local/bin` or add a symbolic link:
```bash
$ sudo ln -s $(pwd)/firecracker /usr/local/bin
$ sudo ln -s $(pwd)/jailer /usr/local/bin
```
More details can be found in [AWS Firecracker docs](https://github.com/firecracker-microvm/firecracker/blob/main/docs/getting-started.md)
In order to run Kata with AWS Firecracker a block device as the backing store for a VM is required. To interact with `containerd` and Kata we use the `devmapper` `snapshotter`.
## Configure `devmapper`
To check support for your `containerd` installation, you can run:
```
$ ctr plugins ls |grep devmapper
```
if the output of the above command is:
```
io.containerd.snapshotter.v1 devmapper linux/amd64 ok
```
then you can skip this section and move on to `Configure Kata Containers with AWS Firecracker`
If the output of the above command is:
```
io.containerd.snapshotter.v1 devmapper linux/amd64 error
```
then we need to setup `devmapper` `snapshotter`. Based on a [very useful
guide](https://docs.docker.com/storage/storagedriver/device-mapper-driver/)
from docker, we can set it up using the following scripts:
> **Note:** The following scripts assume a 100G sparse file for storing container images, a 10G sparse file for the thin-provisioning pool and 10G base image files for any sandboxed container created. This means that we will need at least 10GB free space.
```
#!/bin/bash
set -ex
DATA_DIR=/var/lib/containerd/devmapper
POOL_NAME=devpool
mkdir -p ${DATA_DIR}
# Create data file
sudo touch "${DATA_DIR}/data"
sudo truncate -s 100G "${DATA_DIR}/data"
# Create metadata file
sudo touch "${DATA_DIR}/meta"
sudo truncate -s 10G "${DATA_DIR}/meta"
# Allocate loop devices
DATA_DEV=$(sudo losetup --find --show "${DATA_DIR}/data")
META_DEV=$(sudo losetup --find --show "${DATA_DIR}/meta")
# Define thin-pool parameters.
# See https://www.kernel.org/doc/Documentation/device-mapper/thin-provisioning.txt for details.
SECTOR_SIZE=512
DATA_SIZE="$(sudo blockdev --getsize64 -q ${DATA_DEV})"
LENGTH_IN_SECTORS=$(bc <<< "${DATA_SIZE}/${SECTOR_SIZE}")
DATA_BLOCK_SIZE=128
LOW_WATER_MARK=32768
# Create a thin-pool device
sudo dmsetup create "${POOL_NAME}" \
--table "0 ${LENGTH_IN_SECTORS} thin-pool ${META_DEV} ${DATA_DEV} ${DATA_BLOCK_SIZE} ${LOW_WATER_MARK}"
cat << EOF
#
# Add this to your config.toml configuration file and restart containerd daemon
#
[plugins]
[plugins.devmapper]
pool_name = "${POOL_NAME}"
root_path = "${DATA_DIR}"
base_image_size = "10GB"
discard_blocks = true
EOF
```
Make it executable and run it:
```bash
$ sudo chmod +x ~/scripts/devmapper/create.sh
$ cd ~/scripts/devmapper/
$ sudo ./create.sh
```
Now, we can add the `devmapper` configuration provided from the script to `/etc/containerd/config.toml`.
> **Note:** If you are using the default `containerd` configuration (`containerd config default >> /etc/containerd/config.toml`), you may need to edit the existing `[plugins."io.containerd.snapshotter.v1.devmapper"]`configuration.
Save and restart `containerd`:
```bash
$ sudo systemctl restart containerd
```
We can use `dmsetup` to verify that the thin-pool was created successfully.
```bash
$ sudo dmsetup ls
```
We should also check that `devmapper` is registered and running:
```bash
$ sudo ctr plugins ls | grep devmapper
```
This script needs to be run only once, while setting up the `devmapper` `snapshotter` for `containerd`. Afterwards, make sure that on each reboot, the thin-pool is initialized from the same data directory. Otherwise, all the fetched containers (or the ones that you have created) will be re-initialized. A simple script that re-creates the thin-pool from the same data directory is shown below:
```
#!/bin/bash
set -ex
DATA_DIR=/var/lib/containerd/devmapper
POOL_NAME=devpool
# Allocate loop devices
DATA_DEV=$(sudo losetup --find --show "${DATA_DIR}/data")
META_DEV=$(sudo losetup --find --show "${DATA_DIR}/meta")
# Define thin-pool parameters.
# See https://www.kernel.org/doc/Documentation/device-mapper/thin-provisioning.txt for details.
SECTOR_SIZE=512
DATA_SIZE="$(sudo blockdev --getsize64 -q ${DATA_DEV})"
LENGTH_IN_SECTORS=$(bc <<< "${DATA_SIZE}/${SECTOR_SIZE}")
DATA_BLOCK_SIZE=128
LOW_WATER_MARK=32768
# Create a thin-pool device
sudo dmsetup create "${POOL_NAME}" \
--table "0 ${LENGTH_IN_SECTORS} thin-pool ${META_DEV} ${DATA_DEV} ${DATA_BLOCK_SIZE} ${LOW_WATER_MARK}"
```
We can create a systemd service to run the above script on each reboot:
```bash
$ sudo nano /lib/systemd/system/devmapper_reload.service
```
The service file:
```
[Unit]
Description=Devmapper reload script
[Service]
ExecStart=/path/to/script/reload.sh
[Install]
WantedBy=multi-user.target
```
Enable the newly created service:
```bash
$ sudo systemctl daemon-reload
$ sudo systemctl enable devmapper_reload.service
$ sudo systemctl start devmapper_reload.service
```
## Configure Kata Containers with AWS Firecracker
To configure Kata Containers with AWS Firecracker, copy the generated `configuration-fc.toml` file when building the `kata-runtime` to either `/etc/kata-containers/configuration-fc.toml` or `/usr/share/defaults/kata-containers/configuration-fc.toml`.
The following command shows full paths to the `configuration.toml` files that the runtime loads. It will use the first path that exists. (Please make sure the kernel and image paths are set correctly in the `configuration.toml` file)
```bash
$ sudo kata-runtime --show-default-config-paths
```
## Configure `containerd`
Next, we need to configure containerd. Add a file in your path (e.g. `/usr/local/bin/containerd-shim-kata-fc-v2`) with the following contents:
```
#!/bin/bash
KATA_CONF_FILE=/etc/kata-containers/configuration-fc.toml /usr/local/bin/containerd-shim-kata-v2 $@
```
> **Note:** You may need to edit the paths of the configuration file and the `containerd-shim-kata-v2` to correspond to your setup.
Make it executable:
```bash
$ sudo chmod +x /usr/local/bin/containerd-shim-kata-fc-v2
```
Add the relevant section in `containerd`s `config.toml` file (`/etc/containerd/config.toml`):
```
[plugins.cri.containerd.runtimes]
[plugins.cri.containerd.runtimes.kata-fc]
runtime_type = "io.containerd.kata-fc.v2"
```
> **Note:** If you are using the default `containerd` configuration (`containerd config default >> /etc/containerd/config.toml`),
> the configuration should change to :
```
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes]
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.kata-fc]
runtime_type = "io.containerd.kata-fc.v2"
```
Restart `containerd`:
```bash
$ sudo systemctl restart containerd
```
## Verify the installation
We are now ready to launch a container using Kata with Firecracker to verify that everything worked:
```bash
$ sudo ctr images pull --snapshotter devmapper docker.io/library/ubuntu:latest
$ sudo ctr run --snapshotter devmapper --runtime io.containerd.run.kata-fc.v2 -t --rm docker.io/library/ubuntu
```

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@@ -31,7 +31,7 @@ See below example config:
[plugins.cri]
[plugins.cri.containerd]
[plugins.cri.containerd.runtimes.runc]
runtime_type = "io.containerd.runc.v2"
runtime_type = "io.containerd.runc.v1"
privileged_without_host_devices = false
[plugins.cri.containerd.runtimes.kata]
runtime_type = "io.containerd.kata.v2"
@@ -40,7 +40,7 @@ See below example config:
ConfigPath = "/opt/kata/share/defaults/kata-containers/configuration.toml"
```
- [How to use Kata Containers and containerd with Kubernetes](how-to-use-k8s-with-containerd-and-kata.md)
- [Kata Containers with Containerd and CRI documentation](how-to-use-k8s-with-cri-containerd-and-kata.md)
- [Containerd CRI config documentation](https://github.com/containerd/containerd/blob/main/docs/cri/config.md)
#### CRI-O

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@@ -15,7 +15,7 @@ After choosing one CRI implementation, you must make the appropriate configurati
to ensure it integrates with Kata Containers.
Kata Containers 1.5 introduced the `shimv2` for containerd 1.2.0, reducing the components
required to spawn pods and containers, and this is the preferred way to run Kata Containers with Kubernetes ([as documented here](../how-to/how-to-use-k8s-with-containerd-and-kata.md#configure-containerd-to-use-kata-containers)).
required to spawn pods and containers, and this is the preferred way to run Kata Containers with Kubernetes ([as documented here](../how-to/how-to-use-k8s-with-cri-containerd-and-kata.md#configure-containerd-to-use-kata-containers)).
An equivalent shim implementation for CRI-O is planned.
@@ -57,7 +57,7 @@ content shown below:
To customize containerd to select Kata Containers runtime, follow our
"Configure containerd to use Kata Containers" internal documentation
[here](../how-to/how-to-use-k8s-with-containerd-and-kata.md#configure-containerd-to-use-kata-containers).
[here](../how-to/how-to-use-k8s-with-cri-containerd-and-kata.md#configure-containerd-to-use-kata-containers).
## Install Kubernetes
@@ -85,7 +85,7 @@ Environment="KUBELET_EXTRA_ARGS=--container-runtime=remote --runtime-request-tim
Environment="KUBELET_EXTRA_ARGS=--container-runtime=remote --runtime-request-timeout=15m --container-runtime-endpoint=unix:///run/containerd/containerd.sock"
```
For more information about containerd see the "Configure Kubelet to use containerd"
documentation [here](../how-to/how-to-use-k8s-with-containerd-and-kata.md#configure-kubelet-to-use-containerd).
documentation [here](../how-to/how-to-use-k8s-with-cri-containerd-and-kata.md#configure-kubelet-to-use-containerd).
## Run a Kubernetes pod with Kata Containers
@@ -99,18 +99,7 @@ $ sudo systemctl restart kubelet
$ sudo kubeadm init --ignore-preflight-errors=all --cri-socket /var/run/crio/crio.sock --pod-network-cidr=10.244.0.0/16
# If using containerd
$ cat <<EOF | tee kubeadm-config.yaml
apiVersion: kubeadm.k8s.io/v1beta3
kind: InitConfiguration
nodeRegistration:
criSocket: "/run/containerd/containerd.sock"
---
kind: KubeletConfiguration
apiVersion: kubelet.config.k8s.io/v1beta1
cgroupDriver: cgroupfs
podCIDR: "10.244.0.0/16"
EOF
$ sudo kubeadm init --ignore-preflight-errors=all --config kubeadm-config.yaml
$ sudo kubeadm init --ignore-preflight-errors=all --cri-socket /run/containerd/containerd.sock --pod-network-cidr=10.244.0.0/16
$ export KUBECONFIG=/etc/kubernetes/admin.conf
```

3
docs/hypervisors.md
View File

@@ -33,7 +33,6 @@ are available, their default values and how each setting can be used.
[Cloud Hypervisor] | rust | `aarch64`, `x86_64` | Type 2 ([KVM]) | `configuration-clh.toml` |
[Firecracker] | rust | `aarch64`, `x86_64` | Type 2 ([KVM]) | `configuration-fc.toml` |
[QEMU] | C | all | Type 2 ([KVM]) | `configuration-qemu.toml` |
[`Dragonball`] | rust | `aarch64`, `x86_64` | Type 2 ([KVM]) | `configuration-dragonball.toml` |
## Determine currently configured hypervisor
@@ -53,7 +52,6 @@ the hypervisors:
[Cloud Hypervisor] | Low latency, small memory footprint, small attack surface | Minimal | | excellent | excellent | High performance modern cloud workloads | |
[Firecracker] | Very slimline | Extremely minimal | Doesn't support all device types | excellent | excellent | Serverless / FaaS | |
[QEMU] | Lots of features | Lots | | good | good | Good option for most users | | All users |
[`Dragonball`] | Built-in VMM, low CPU and memory overhead| Minimal | | excellent | excellent | Optimized for most container workloads | `out-of-the-box` Kata Containers experience |
For further details, see the [Virtualization in Kata Containers](design/virtualization.md) document and the official documentation for each hypervisor.
@@ -62,4 +60,3 @@ For further details, see the [Virtualization in Kata Containers](design/virtuali
[Firecracker]: https://github.com/firecracker-microvm/firecracker
[KVM]: https://en.wikipedia.org/wiki/Kernel-based_Virtual_Machine
[QEMU]: http://www.qemu-project.org
[`Dragonball`]: https://github.com/openanolis/dragonball-sandbox

3
docs/install/README.md
View File

@@ -79,6 +79,3 @@ versions. This is not recommended for normal users.
* [upgrading document](../Upgrading.md)
* [developer guide](../Developer-Guide.md)
* [runtime documentation](../../src/runtime/README.md)
## Kata Containers 3.0 rust runtime installation
* [installation guide](../install/kata-containers-3.0-rust-runtime-installation-guide.md)

8
docs/install/container-manager/containerd/containerd-install.md
View File

@@ -19,6 +19,12 @@
> - If you decide to proceed and install a Kata Containers release, you can
> still check for the latest version of Kata Containers by running
> `kata-runtime check --only-list-releases`.
>
> - These instructions will not work for Fedora 31 and higher since those
> distribution versions only support cgroups version 2 by default. However,
> Kata Containers currently requires cgroups version 1 (on the host side). See
> https://github.com/kata-containers/kata-containers/issues/927 for further
> details.
## Install Kata Containers
@@ -75,7 +81,7 @@
- Download the standard `systemd(1)` service file and install to
`/etc/systemd/system/`:
- https://raw.githubusercontent.com/containerd/containerd/main/containerd.service
- https://raw.githubusercontent.com/containerd/containerd/master/containerd.service
> **Notes:**
>

102
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View File

@@ -1,102 +0,0 @@
# Kata Containers 3.0 rust runtime installation
The following is an overview of the different installation methods available.
## Prerequisites
Kata Containers 3.0 rust runtime requires nested virtualization or bare metal. Check
[hardware requirements](/src/runtime/README.md#hardware-requirements) to see if your system is capable of running Kata
Containers.
### Platform support
Kata Containers 3.0 rust runtime currently runs on 64-bit systems supporting the following
architectures:
> **Notes:**
> For other architectures, see https://github.com/kata-containers/kata-containers/issues/4320
| Architecture | Virtualization technology |
|-|-|
| `x86_64`| [Intel](https://www.intel.com) VT-x |
| `aarch64` ("`arm64`")| [ARM](https://www.arm.com) Hyp |
## Packaged installation methods
| Installation method | Description | Automatic updates | Use case | Availability
|------------------------------------------------------|----------------------------------------------------------------------------------------------|-------------------|-----------------------------------------------------------------------------------------------|----------- |
| [Using kata-deploy](#kata-deploy-installation) | The preferred way to deploy the Kata Containers distributed binaries on a Kubernetes cluster | **No!** | Best way to give it a try on kata-containers on an already up and running Kubernetes cluster. | Yes |
| [Using official distro packages](#official-packages) | Kata packages provided by Linux distributions official repositories | yes | Recommended for most users. | No |
| [Using snap](#snap-installation) | Easy to install | yes | Good alternative to official distro packages. | No |
| [Automatic](#automatic-installation) | Run a single command to install a full system | **No!** | For those wanting the latest release quickly. | No |
| [Manual](#manual-installation) | Follow a guide step-by-step to install a working system | **No!** | For those who want the latest release with more control. | No |
| [Build from source](#build-from-source-installation) | Build the software components manually | **No!** | Power users and developers only. | Yes |
### Kata Deploy Installation
Follow the [`kata-deploy`](../../tools/packaging/kata-deploy/README.md).
### Official packages
`ToDo`
### Snap Installation
`ToDo`
### Automatic Installation
`ToDo`
### Manual Installation
`ToDo`
## Build from source installation
### Rust Environment Set Up
* Download `Rustup` and install `Rust`
> **Notes:**
> Rust version 1.62.0 is needed
Example for `x86_64`
```
$ curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh
$ source $HOME/.cargo/env
$ rustup install 1.62.0
$ rustup default 1.62.0-x86_64-unknown-linux-gnu
```
* Musl support for fully static binary
Example for `x86_64`
```
$ rustup target add x86_64-unknown-linux-musl
```
* [Musl `libc`](http://musl.libc.org/) install
Example for musl 1.2.3
```
$ curl -O https://git.musl-libc.org/cgit/musl/snapshot/musl-1.2.3.tar.gz
$ tar vxf musl-1.2.3.tar.gz
$ cd musl-1.2.3/
$ ./configure --prefix=/usr/local/
$ make && sudo make install
```
### Install Kata 3.0 Rust Runtime Shim
```
$ git clone https://github.com/kata-containers/kata-containers.git
$ cd kata-containers/src/runtime-rs
$ make && sudo make install
```
After running the command above, the default config file `configuration.toml` will be installed under `/usr/share/defaults/kata-containers/`, the binary file `containerd-shim-kata-v2` will be installed under `/usr/local/bin/` .
### Build Kata Containers Kernel
Follow the [Kernel installation guide](/tools/packaging/kernel/README.md).
### Build Kata Rootfs
Follow the [Rootfs installation guide](../../tools/osbuilder/rootfs-builder/README.md).
### Build Kata Image
Follow the [Image installation guide](../../tools/osbuilder/image-builder/README.md).
### Install Containerd
Follow the [Containerd installation guide](container-manager/containerd/containerd-install.md).

20
docs/install/minikube-installation-guide.md
View File

@@ -55,11 +55,11 @@ Here are the features to set up a CRI-O based Minikube, and why you need them:
| what | why |
| ---- | --- |
| `--bootstrapper=kubeadm` | As recommended for [minikube CRI-O](https://minikube.sigs.k8s.io/docs/handbook/config/#runtime-configuration) |
| `--bootstrapper=kubeadm` | As recommended for [minikube CRI-o](https://kubernetes.io/docs/setup/minikube/#cri-o) |
| `--container-runtime=cri-o` | Using CRI-O for Kata |
| `--enable-default-cni` | As recommended for [minikube CRI-O](https://minikube.sigs.k8s.io/docs/handbook/config/#runtime-configuration) |
| `--enable-default-cni` | As recommended for [minikube CRI-o](https://kubernetes.io/docs/setup/minikube/#cri-o) |
| `--memory 6144` | Allocate sufficient memory, as Kata Containers default to 1 or 2Gb |
| `--network-plugin=cni` | As recommended for [minikube CRI-O](https://minikube.sigs.k8s.io/docs/handbook/config/#runtime-configuration) |
| `--network-plugin=cni` | As recommended for [minikube CRI-o](https://kubernetes.io/docs/setup/minikube/#cri-o) |
| `--vm-driver kvm2` | The host VM driver |
To use containerd, modify the `--container-runtime` argument:
@@ -71,6 +71,12 @@ To use containerd, modify the `--container-runtime` argument:
> **Notes:**
> - Adjust the `--memory 6144` line to suit your environment and requirements. Kata Containers default to
> requesting 2048MB per container. We recommended you supply more than that to the Minikube node.
> - Prior to Minikube/Kubernetes v1.14, the beta `RuntimeClass` feature also needed enabling with
> the following.
>
> | what | why |
> | ---- | --- |
> | `--feature-gates=RuntimeClass=true` | Kata needs to use the `RuntimeClass` Kubernetes feature |
The full command is therefore:
@@ -132,9 +138,17 @@ $ kubectl -n kube-system exec ${podname} -- ps -ef | fgrep infinity
## Enabling Kata Containers
> **Note:** Only Minikube/Kubernetes versions <= 1.13 require this step. Since version
> v1.14, the `RuntimeClass` is enabled by default. Performing this step on Kubernetes > v1.14 is
> however benign.
Now you have installed the Kata Containers components in the Minikube node. Next, you need to configure
Kubernetes `RuntimeClass` to know when to use Kata Containers to run a pod.
```sh
$ kubectl apply -f https://raw.githubusercontent.com/kubernetes/node-api/master/manifests/runtimeclass_crd.yaml > runtimeclass_crd.yaml
```
### Register the runtime
Now register the `kata qemu` runtime with that class. This should result in no errors:

2
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View File

@@ -3,4 +3,4 @@
Kata Containers supports passing certain GPUs from the host into the container. Select the GPU vendor for detailed information:
- [Intel](Intel-GPU-passthrough-and-Kata.md)
- [NVIDIA](NVIDIA-GPU-passthrough-and-Kata.md)
- [Nvidia](Nvidia-GPU-passthrough-and-Kata.md)

598
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View File

@@ -1,598 +0,0 @@
# Using NVIDIA GPU device with Kata Containers
An NVIDIA GPU device can be passed to a Kata Containers container using GPU
passthrough (NVIDIA GPU pass-through mode) as well as GPU mediated passthrough
(NVIDIA `vGPU` mode).
NVIDIA GPU pass-through mode, an entire physical GPU is directly assigned to one
VM, bypassing the NVIDIA Virtual GPU Manager. In this mode of operation, the GPU
is accessed exclusively by the NVIDIA driver running in the VM to which it is
assigned. The GPU is not shared among VMs.
NVIDIA Virtual GPU (`vGPU`) enables multiple virtual machines (VMs) to have
simultaneous, direct access to a single physical GPU, using the same NVIDIA
graphics drivers that are deployed on non-virtualized operating systems. By
doing this, NVIDIA `vGPU` provides VMs with unparalleled graphics performance,
compute performance, and application compatibility, together with the
cost-effectiveness and scalability brought about by sharing a GPU among multiple
workloads. A `vGPU` can be either time-sliced or Multi-Instance GPU (MIG)-backed
with [MIG-slices](https://docs.nvidia.com/datacenter/tesla/mig-user-guide/).
| Technology | Description | Behavior | Detail |
| --- | --- | --- | --- |
| NVIDIA GPU pass-through mode | GPU passthrough | Physical GPU assigned to a single VM | Direct GPU assignment to VM without limitation |
| NVIDIA vGPU time-sliced | GPU time-sliced | Physical GPU time-sliced for multiple VMs | Mediated passthrough |
| NVIDIA vGPU MIG-backed | GPU with MIG-slices | Physical GPU MIG-sliced for multiple VMs | Mediated passthrough |
## Hardware Requirements
NVIDIA GPUs Recommended for Virtualization:
- NVIDIA Tesla (T4, M10, P6, V100 or newer)
- NVIDIA Quadro RTX 6000/8000
## Host BIOS Requirements
Some hardware requires a larger PCI BARs window, for example, NVIDIA Tesla P100,
K40m
```sh
$ lspci -s d0:00.0 -vv | grep Region
Region 0: Memory at e7000000 (32-bit, non-prefetchable) [size=16M]
Region 1: Memory at 222800000000 (64-bit, prefetchable) [size=32G] # Above 4G
Region 3: Memory at 223810000000 (64-bit, prefetchable) [size=32M]
```
For large BARs devices, MMIO mapping above 4G address space should be `enabled`
in the PCI configuration of the BIOS.
Some hardware vendors use a different name in BIOS, such as:
- Above 4G Decoding
- Memory Hole for PCI MMIO
- Memory Mapped I/O above 4GB
If one is using a GPU based on the Ampere architecture and later additionally
SR-IOV needs to be enabled for the `vGPU` use-case.
The following steps outline the workflow for using an NVIDIA GPU with Kata.
## Host Kernel Requirements
The following configurations need to be enabled on your host kernel:
- `CONFIG_VFIO`
- `CONFIG_VFIO_IOMMU_TYPE1`
- `CONFIG_VFIO_MDEV`
- `CONFIG_VFIO_MDEV_DEVICE`
- `CONFIG_VFIO_PCI`
Your host kernel needs to be booted with `intel_iommu=on` on the kernel command
line.
## Install and configure Kata Containers
To use non-large BARs devices (for example, NVIDIA Tesla T4), you need Kata
version 1.3.0 or above. Follow the [Kata Containers setup
instructions](../install/README.md) to install the latest version of Kata.
To use large BARs devices (for example, NVIDIA Tesla P100), you need Kata
version 1.11.0 or above.
The following configuration in the Kata `configuration.toml` file as shown below
can work:
Hotplug for PCI devices with small BARs by `acpi_pcihp` (Linux's ACPI PCI
Hotplug driver):
```sh
machine_type = "q35"
hotplug_vfio_on_root_bus = false
```
Hotplug for PCIe devices with large BARs by `pciehp` (Linux's PCIe Hotplug
driver):
```sh
machine_type = "q35"
hotplug_vfio_on_root_bus = true
pcie_root_port = 1
```
## Build Kata Containers kernel with GPU support
The default guest kernel installed with Kata Containers does not provide GPU
support. To use an NVIDIA GPU with Kata Containers, you need to build a kernel
with the necessary GPU support.
The following kernel config options need to be enabled:
```sh
# Support PCI/PCIe device hotplug (Required for large BARs device)
CONFIG_HOTPLUG_PCI_PCIE=y
# Support for loading modules (Required for load NVIDIA drivers)
CONFIG_MODULES=y
CONFIG_MODULE_UNLOAD=y
# Enable the MMIO access method for PCIe devices (Required for large BARs device)
CONFIG_PCI_MMCONFIG=y
```
The following kernel config options need to be disabled:
```sh
# Disable Open Source NVIDIA driver nouveau
# It conflicts with NVIDIA official driver
CONFIG_DRM_NOUVEAU=n
```
> **Note**: `CONFIG_DRM_NOUVEAU` is normally disabled by default.
It is worth checking that it is not enabled in your kernel configuration to
prevent any conflicts.
Build the Kata Containers kernel with the previous config options, using the
instructions described in [Building Kata Containers
kernel](../../tools/packaging/kernel). For further details on building and
installing guest kernels, see [the developer
guide](../Developer-Guide.md#install-guest-kernel-images).
There is an easy way to build a guest kernel that supports NVIDIA GPU:
```sh
## Build guest kernel with ../../tools/packaging/kernel
# Prepare (download guest kernel source, generate .config)
$ ./build-kernel.sh -v 5.15.23 -g nvidia -f setup
# Build guest kernel
$ ./build-kernel.sh -v 5.15.23 -g nvidia build
# Install guest kernel
$ sudo -E ./build-kernel.sh -v 5.15.23 -g nvidia install
```
To build NVIDIA Driver in Kata container, `linux-headers` are required.
This is a way to generate deb packages for `linux-headers`:
> **Note**:
> Run `make rpm-pkg` to build the rpm package.
> Run `make deb-pkg` to build the deb package.
>
```sh
$ cd kata-linux-5.15.23-89
$ make deb-pkg
```
Before using the new guest kernel, please update the `kernel` parameters in
`configuration.toml`.
```sh
kernel = "/usr/share/kata-containers/vmlinuz-nvidia-gpu.container"
```
## NVIDIA GPU pass-through mode with Kata Containers
Use the following steps to pass an NVIDIA GPU device in pass-through mode with Kata:
1. Find the Bus-Device-Function (BDF) for the GPU device on the host:
```sh
$ sudo lspci -nn -D | grep -i nvidia
0000:d0:00.0 3D controller [0302]: NVIDIA Corporation Device [10de:20b9] (rev a1)
```
> PCI address `0000:d0:00.0` is assigned to the hardware GPU device.
> `10de:20b9` is the device ID of the hardware GPU device.
2. Find the IOMMU group for the GPU device:
```sh
$ BDF="0000:d0:00.0"
$ readlink -e /sys/bus/pci/devices/$BDF/iommu_group
```
The previous output shows that the GPU belongs to IOMMU group 192. The next
step is to bind the GPU to the VFIO-PCI driver.
```sh
$ BDF="0000:d0:00.0"
$ DEV="/sys/bus/pci/devices/$BDF"
$ echo "vfio-pci" > $DEV/driver_override
$ echo $BDF > $DEV/driver/unbind
$ echo $BDF > /sys/bus/pci/drivers_probe
# To return the device to the standard driver, we simply clear the
# driver_override and reprobe the device, ex:
$ echo > $DEV/preferred_driver
$ echo $BDF > $DEV/driver/unbind
$ echo $BDF > /sys/bus/pci/drivers_probe
```
3. Check the IOMMU group number under `/dev/vfio`:
```sh
$ ls -l /dev/vfio
total 0
crw------- 1 zvonkok zvonkok 243, 0 Mar 18 03:06 192
crw-rw-rw- 1 root root 10, 196 Mar 18 02:27 vfio
```
4. Start a Kata container with the GPU device:
```sh
# You may need to `modprobe vhost-vsock` if you get
# host system doesn't support vsock: stat /dev/vhost-vsock
$ sudo ctr --debug run --runtime "io.containerd.kata.v2" --device /dev/vfio/192 --rm -t "docker.io/library/archlinux:latest" arch uname -r
```
5. Run `lspci` within the container to verify the GPU device is seen in the list
of the PCI devices. Note the vendor-device id of the GPU (`10de:20b9`) in the `lspci` output.
```sh
$ sudo ctr --debug run --runtime "io.containerd.kata.v2" --device /dev/vfio/192 --rm -t "docker.io/library/archlinux:latest" arch sh -c "lspci -nn | grep '10de:20b9'"
```
6. Additionally, you can check the PCI BARs space of the NVIDIA GPU device in the container:
```sh
$ sudo ctr --debug run --runtime "io.containerd.kata.v2" --device /dev/vfio/192 --rm -t "docker.io/library/archlinux:latest" arch sh -c "lspci -s 02:00.0 -vv | grep Region"
```
> **Note**: If you see a message similar to the above, the BAR space of the NVIDIA
> GPU has been successfully allocated.
## NVIDIA vGPU mode with Kata Containers
NVIDIA vGPU is a licensed product on all supported GPU boards. A software license
is required to enable all vGPU features within the guest VM. NVIDIA vGPU manager
needs to be installed on the host to configure GPUs in vGPU mode. See [NVIDIA Virtual GPU Software Documentation v14.0 through 14.1](https://docs.nvidia.com/grid/14.0/) for more details.
### NVIDIA vGPU time-sliced
In the time-sliced mode, the GPU is not partitioned and the workload uses the
whole GPU and shares access to the GPU engines. Processes are scheduled in
series. The best effort scheduler is the default one and can be exchanged by
other scheduling policies see the documentation above how to do that.
Beware if you had `MIG` enabled before to disable `MIG` on the GPU if you want
to use `time-sliced` `vGPU`.
```sh
$ sudo nvidia-smi -mig 0
```
Enable the virtual functions for the physical GPU in the `sysfs` file system.
```sh
$ sudo /usr/lib/nvidia/sriov-manage -e 0000:41:00.0
```
Get the `BDF` of the available virtual function on the GPU, and choose one for the
following steps.
```sh
$ cd /sys/bus/pci/devices/0000:41:00.0/
$ ls -l | grep virtfn
```
#### List all available vGPU instances
The following shell snippet will walk the `sysfs` and only print instances
that are available, that can be created.
```sh
# The 00.0 is often the PF of the device the VFs will have the funciont in the
# BDF incremented by some values so e.g. the very first VF is 0000:41:00.4
cd /sys/bus/pci/devices/0000:41:00.0/
for vf in $(ls -d virtfn*)
do
BDF=$(basename $(readlink -f $vf))
for md in $(ls -d $vf/mdev_supported_types/*)
do
AVAIL=$(cat $md/available_instances)
NAME=$(cat $md/name)
DIR=$(basename $md)
if [ $AVAIL -gt 0 ]; then
echo "| BDF | INSTANCES | NAME | DIR |"
echo "+--------------+-----------+----------------+------------+"
printf "| %12s |%10d |%15s | %10s |\n\n" "$BDF" "$AVAIL" "$NAME" "$DIR"
fi
done
done
```
If there are available instances you get something like this (for the first VF),
beware that the output is highly dependent on the GPU you have, if there is no
output check again if `MIG` is really disabled.
```sh
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-4C | nvidia-692 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-8C | nvidia-693 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-10C | nvidia-694 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-16C | nvidia-695 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-20C | nvidia-696 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-40C | nvidia-697 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 | GRID A100D-80C | nvidia-698 |
```
Change to the `mdev_supported_types` directory for the virtual function on which
you want to create the `vGPU`. Taking the first output as an example:
```sh
$ cd virtfn0/mdev_supported_types/nvidia-692
$ UUIDGEN=$(uuidgen)
$ sudo bash -c "echo $UUIDGEN > create"
```
Confirm that the `vGPU` was created. You should see the `UUID` pointing to a
subdirectory of the `sysfs` space.
```sh
$ ls -l /sys/bus/mdev/devices/
```
Get the `IOMMU` group number and verify there is a `VFIO` device created to use
with Kata.
```sh
$ ls -l /sys/bus/mdev/devices/*/
$ ls -l /dev/vfio
```
Use the `VFIO` device created in the same way as in the pass-through use-case.
Beware that the guest needs the NVIDIA guest drivers, so one would need to build
a new guest `OS` image.
### NVIDIA vGPU MIG-backed
We're not going into detail what `MIG` is but briefly it is a technology to
partition the hardware into independent instances with guaranteed quality of
service. For more details see [NVIDIA Multi-Instance GPU User Guide](https://docs.nvidia.com/datacenter/tesla/mig-user-guide/).
First enable `MIG` mode for a GPU, depending on the platform you're running
a reboot would be necessary. Some platforms support GPU reset.
```sh
$ sudo nvidia-smi -mig 1
```
If the platform supports a GPU reset one can run, otherwise you will get a
warning to reboot the server.
```sh
$ sudo nvidia-smi --gpu-reset
```
The driver per default provides a number of profiles that users can opt-in when
configuring the MIG feature.
```sh
$ sudo nvidia-smi mig -lgip
+-----------------------------------------------------------------------------+
| GPU instance profiles: |
| GPU Name ID Instances Memory P2P SM DEC ENC |
| Free/Total GiB CE JPEG OFA |
|=============================================================================|
| 0 MIG 1g.10gb 19 7/7 9.50 No 14 0 0 |
| 1 0 0 |
+-----------------------------------------------------------------------------+
| 0 MIG 1g.10gb+me 20 1/1 9.50 No 14 1 0 |
| 1 1 1 |
+-----------------------------------------------------------------------------+
| 0 MIG 2g.20gb 14 3/3 19.50 No 28 1 0 |
| 2 0 0 |
+-----------------------------------------------------------------------------+
...
```
Create the GPU instances that correspond to the `vGPU` types of the `MIG-backed`
`vGPUs` that you will create [NVIDIA A100 PCIe 80GB Virtual GPU Types](https://docs.nvidia.com/grid/13.0/grid-vgpu-user-guide/index.html#vgpu-types-nvidia-a100-pcie-80gb).
```sh
# MIG 1g.10gb --> vGPU A100D-1-10C
$ sudo nvidia-smi mig -cgi 19
```
List the GPU instances and get the GPU instance id to create the compute
instance.
```sh
$ sudo nvidia-smi mig -lgi # list the created GPU instances
$ sudo nvidia-smi mig -cci -gi 9 # each GPU instance can have several compute
# instances. Instance -> Workload
```
Verify that the compute instances were created within the GPU instance
```sh
$ nvidia-smi
... snip ...
+-----------------------------------------------------------------------------+
| MIG devices: |
+------------------+----------------------+-----------+-----------------------+
| GPU GI CI MIG | Memory-Usage | Vol| Shared |
| ID ID Dev | BAR1-Usage | SM Unc| CE ENC DEC OFA JPG|
| | | ECC| |
|==================+======================+===========+=======================|
| 0 9 0 0 | 0MiB / 9728MiB | 14 0 | 1 0 0 0 0 |
| | 0MiB / 4095MiB | | |
+------------------+----------------------+-----------+-----------------------+
... snip ...
```
We can use the [snippet](#list-all-available-vgpu-instances) from before to list
the available `vGPU` instances, this time `MIG-backed`.
```sh
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.4 | 1 |GRID A100D-1-10C | nvidia-699 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:00.5 | 1 |GRID A100D-1-10C | nvidia-699 |
| BDF | INSTANCES | NAME | DIR |
+--------------+-----------+----------------+------------+
| 0000:41:01.6 | 1 |GRID A100D-1-10C | nvidia-699 |
... snip ...
```
Repeat the steps after the [snippet](#list-all-available-vgpu-instances) listing
to create the corresponding `mdev` device and use the guest `OS` created in the
previous section with `time-sliced` `vGPUs`.
## Install NVIDIA Driver + Toolkit in Kata Containers Guest OS
Consult the [Developer-Guide](https://github.com/kata-containers/kata-containers/blob/main/docs/Developer-Guide.md#create-a-rootfs-image) on how to create a
rootfs base image for a distribution of your choice. This is going to be used as
a base for a NVIDIA enabled guest OS. Use the `EXTRA_PKGS` variable to install
all the needed packages to compile the drivers. Also copy the kernel development
packages from the previous `make deb-pkg` into `$ROOTFS_DIR`.
```sh
export EXTRA_PKGS="gcc make curl gnupg"
```
Having the `$ROOTFS_DIR` exported in the previous step we can now install all the
needed parts in the guest OS. In this case, we have an Ubuntu based rootfs.
First off all mount the special filesystems into the rootfs
```sh
$ sudo mount -t sysfs -o ro none ${ROOTFS_DIR}/sys
$ sudo mount -t proc -o ro none ${ROOTFS_DIR}/proc
$ sudo mount -t tmpfs none ${ROOTFS_DIR}/tmp
$ sudo mount -o bind,ro /dev ${ROOTFS_DIR}/dev
$ sudo mount -t devpts none ${ROOTFS_DIR}/dev/pts
```
Now we can enter `chroot`
```sh
$ sudo chroot ${ROOTFS_DIR}
```
Inside the rootfs one is going to install the drivers and toolkit to enable the
easy creation of GPU containers with Kata. We can also use this rootfs for any
other container not specifically only for GPUs.
As a prerequisite install the copied kernel development packages
```sh
$ sudo dpkg -i *.deb
```
Get the driver run file, since we need to build the driver against a kernel that
is not running on the host we need the ability to specify the exact version we
want the driver to build against. Take the kernel version one used for building
the NVIDIA kernel (`5.15.23-nvidia-gpu`).
```sh
$ wget https://us.download.nvidia.com/XFree86/Linux-x86_64/510.54/NVIDIA-Linux-x86_64-510.54.run
$ chmod +x NVIDIA-Linux-x86_64-510.54.run
# Extract the source files so we can run the installer with arguments
$ ./NVIDIA-Linux-x86_64-510.54.run -x
$ cd NVIDIA-Linux-x86_64-510.54
$ ./nvidia-installer -k 5.15.23-nvidia-gpu
```
Having the drivers installed we need to install the toolkit which will take care
of providing the right bits into the container.
```sh
$ distribution=$(. /etc/os-release;echo $ID$VERSION_ID)
$ curl -fsSL https://nvidia.github.io/libnvidia-container/gpgkey | sudo gpg --dearmor -o /usr/share/keyrings/nvidia-container-toolkit-keyring.gpg
$ curl -s -L https://nvidia.github.io/libnvidia-container/$distribution/libnvidia-container.list | sed 's#deb https://#deb [signed-by=/usr/share/keyrings/nvidia-container-toolkit-keyring.gpg] https://#g' | sudo tee /etc/apt/sources.list.d/nvidia-container-toolkit.list
$ apt update
$ apt install nvidia-container-toolkit
```
Create the hook execution file for Kata:
```
# Content of $ROOTFS_DIR/usr/share/oci/hooks/prestart/nvidia-container-toolkit.sh
#!/bin/bash -x
/usr/bin/nvidia-container-toolkit -debug $@
```
Make sure the hook shell is executable:
```sh
chmod +x $ROOTFS_DIR/usr/share/oci/hooks/prestart/nvidia-container-toolkit.sh
```
As the last step one can do some cleanup of files or package caches. Build the
rootfs and configure it for use with Kata according to the development guide.
Enable the `guest_hook_path` in Kata's `configuration.toml`
```sh
guest_hook_path = "/usr/share/oci/hooks"
```
One has built a NVIDIA rootfs, kernel and now we can run any GPU container
without installing the drivers into the container. Check NVIDIA device status
with `nvidia-smi`
```sh
$ sudo ctr --debug run --runtime "io.containerd.kata.v2" --device /dev/vfio/192 --rm -t "docker.io/nvidia/cuda:11.6.0-base-ubuntu20.04" cuda nvidia-smi
Fri Mar 18 10:36:59 2022
+-----------------------------------------------------------------------------+
| NVIDIA-SMI 510.54 Driver Version: 510.54 CUDA Version: 11.6 |
|-------------------------------+----------------------+----------------------+
| GPU Name Persistence-M| Bus-Id Disp.A | Volatile Uncorr. ECC |
| Fan Temp Perf Pwr:Usage/Cap| Memory-Usage | GPU-Util Compute M. |
| | | MIG M. |
|===============================+======================+======================|
| 0 NVIDIA A30X Off | 00000000:02:00.0 Off | 0 |
| N/A 38C P0 67W / 230W | 0MiB / 24576MiB | 0% Default |
| | | Disabled |
+-------------------------------+----------------------+----------------------+
+-----------------------------------------------------------------------------+
| Processes: |
| GPU GI CI PID Type Process name GPU Memory |
| ID ID Usage |
|=============================================================================|
| No running processes found |
+-----------------------------------------------------------------------------+
```
As the last step one can remove the additional packages and files that were added
to the `$ROOTFS_DIR` to keep it as small as possible.
## References
- [Configuring a VM for GPU Pass-Through by Using the QEMU Command Line](https://docs.nvidia.com/grid/latest/grid-vgpu-user-guide/index.html#using-gpu-pass-through-red-hat-el-qemu-cli)
- https://gitlab.com/nvidia/container-images/driver/-/tree/master
- https://github.com/NVIDIA/nvidia-docker/wiki/Driver-containers

293
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View File

@@ -0,0 +1,293 @@
# Using Nvidia GPU device with Kata Containers
An Nvidia GPU device can be passed to a Kata Containers container using GPU passthrough
(Nvidia GPU pass-through mode) as well as GPU mediated passthrough (Nvidia vGPU mode). 
Nvidia GPU pass-through mode, an entire physical GPU is directly assigned to one VM,
bypassing the Nvidia Virtual GPU Manager. In this mode of operation, the GPU is accessed
exclusively by the Nvidia driver running in the VM to which it is assigned.
The GPU is not shared among VMs.
Nvidia Virtual GPU (vGPU) enables multiple virtual machines (VMs) to have simultaneous,
direct access to a single physical GPU, using the same Nvidia graphics drivers that are
deployed on non-virtualized operating systems. By doing this, Nvidia vGPU provides VMs
with unparalleled graphics performance, compute performance, and application compatibility,
together with the cost-effectiveness and scalability brought about by sharing a GPU
among multiple workloads.
| Technology | Description | Behaviour | Detail |
| --- | --- | --- | --- |
| Nvidia GPU pass-through mode | GPU passthrough | Physical GPU assigned to a single VM | Direct GPU assignment to VM without limitation |
| Nvidia vGPU mode | GPU sharing | Physical GPU shared by multiple VMs | Mediated passthrough |
## Hardware Requirements
Nvidia GPUs Recommended for Virtualization:
- Nvidia Tesla (T4, M10, P6, V100 or newer)
- Nvidia Quadro RTX 6000/8000
## Host BIOS Requirements
Some hardware requires a larger PCI BARs window, for example, Nvidia Tesla P100, K40m
```
$ lspci -s 04:00.0 -vv | grep Region
Region 0: Memory at c6000000 (32-bit, non-prefetchable) [size=16M]
Region 1: Memory at 383800000000 (64-bit, prefetchable) [size=16G] #above 4G
Region 3: Memory at 383c00000000 (64-bit, prefetchable) [size=32M]
```
For large BARs devices, MMIO mapping above 4G address space should be `enabled`
in the PCI configuration of the BIOS.
Some hardware vendors use different name in BIOS, such as:
- Above 4G Decoding
- Memory Hole for PCI MMIO
- Memory Mapped I/O above 4GB
The following steps outline the workflow for using an Nvidia GPU with Kata.
## Host Kernel Requirements
The following configurations need to be enabled on your host kernel:
- `CONFIG_VFIO`
- `CONFIG_VFIO_IOMMU_TYPE1`
- `CONFIG_VFIO_MDEV`
- `CONFIG_VFIO_MDEV_DEVICE`
- `CONFIG_VFIO_PCI`
Your host kernel needs to be booted with `intel_iommu=on` on the kernel command line.
## Install and configure Kata Containers
To use non-large BARs devices (for example, Nvidia Tesla T4), you need Kata version 1.3.0 or above.
Follow the [Kata Containers setup instructions](../install/README.md)
to install the latest version of Kata.
To use large BARs devices (for example, Nvidia Tesla P100), you need Kata version 1.11.0 or above.
The following configuration in the Kata `configuration.toml` file as shown below can work:
Hotplug for PCI devices by `acpi_pcihp` (Linux's ACPI PCI Hotplug driver):
```
machine_type = "q35"
hotplug_vfio_on_root_bus = false
```
Hotplug for PCIe devices by `pciehp` (Linux's PCIe Hotplug driver):
```
machine_type = "q35"
hotplug_vfio_on_root_bus = true
pcie_root_port = 1
```
## Build Kata Containers kernel with GPU support
The default guest kernel installed with Kata Containers does not provide GPU support.
To use an Nvidia GPU with Kata Containers, you need to build a kernel with the
necessary GPU support.
The following kernel config options need to be enabled:
```
# Support PCI/PCIe device hotplug (Required for large BARs device)
CONFIG_HOTPLUG_PCI_PCIE=y
# Support for loading modules (Required for load Nvidia drivers)
CONFIG_MODULES=y
CONFIG_MODULE_UNLOAD=y
# Enable the MMIO access method for PCIe devices (Required for large BARs device)
CONFIG_PCI_MMCONFIG=y
```
The following kernel config options need to be disabled:
```
# Disable Open Source Nvidia driver nouveau
# It conflicts with Nvidia official driver
CONFIG_DRM_NOUVEAU=n
```
> **Note**: `CONFIG_DRM_NOUVEAU` is normally disabled by default.
It is worth checking that it is not enabled in your kernel configuration to prevent any conflicts.
Build the Kata Containers kernel with the previous config options,
using the instructions described in [Building Kata Containers kernel](../../tools/packaging/kernel).
For further details on building and installing guest kernels,
see [the developer guide](../Developer-Guide.md#install-guest-kernel-images).
There is an easy way to build a guest kernel that supports Nvidia GPU:
```
## Build guest kernel with ../../tools/packaging/kernel
# Prepare (download guest kernel source, generate .config)
$ ./build-kernel.sh -v 4.19.86 -g nvidia -f setup
# Build guest kernel
$ ./build-kernel.sh -v 4.19.86 -g nvidia build
# Install guest kernel
$ sudo -E ./build-kernel.sh -v 4.19.86 -g nvidia install
/usr/share/kata-containers/vmlinux-nvidia-gpu.container -> vmlinux-4.19.86-70-nvidia-gpu
/usr/share/kata-containers/vmlinuz-nvidia-gpu.container -> vmlinuz-4.19.86-70-nvidia-gpu
```
To build Nvidia Driver in Kata container, `kernel-devel` is required.
This is a way to generate rpm packages for `kernel-devel`:
```
$ cd kata-linux-4.19.86-68
$ make rpm-pkg
Output RPMs:
~/rpmbuild/RPMS/x86_64/kernel-devel-4.19.86_nvidia_gpu-1.x86_64.rpm
```
> **Note**:
> - `kernel-devel` should be installed in Kata container before run Nvidia driver installer.
> - Run `make deb-pkg` to build the deb package.
Before using the new guest kernel, please update the `kernel` parameters in `configuration.toml`.
```
kernel = "/usr/share/kata-containers/vmlinuz-nvidia-gpu.container"
```
## Nvidia GPU pass-through mode with Kata Containers
Use the following steps to pass an Nvidia GPU device in pass-through mode with Kata:
1. Find the Bus-Device-Function (BDF) for GPU device on host:
```
$ sudo lspci -nn -D | grep -i nvidia
0000:04:00.0 3D controller [0302]: NVIDIA Corporation Device [10de:15f8] (rev a1)
0000:84:00.0 3D controller [0302]: NVIDIA Corporation Device [10de:15f8] (rev a1)
```
> PCI address `0000:04:00.0` is assigned to the hardware GPU device.
> `10de:15f8` is the device ID of the hardware GPU device.
2. Find the IOMMU group for the GPU device:
```
$ BDF="0000:04:00.0"
$ readlink -e /sys/bus/pci/devices/$BDF/iommu_group
/sys/kernel/iommu_groups/45
```
The previous output shows that the GPU belongs to IOMMU group 45.
3. Check the IOMMU group number under `/dev/vfio`:
```
$ ls -l /dev/vfio
total 0
crw------- 1 root root 248, 0 Feb 28 09:57 45
crw------- 1 root root 248, 1 Feb 28 09:57 54
crw-rw-rw- 1 root root 10, 196 Feb 28 09:57 vfio
```
4. Start a Kata container with GPU device:
```
$ sudo docker run -it --runtime=kata-runtime --cap-add=ALL --device /dev/vfio/45 centos /bin/bash
```
5. Run `lspci` within the container to verify the GPU device is seen in the list
of the PCI devices. Note the vendor-device id of the GPU (`10de:15f8`) in the `lspci` output.
```
$ lspci -nn -D | grep '10de:15f8'
0000:01:01.0 3D controller [0302]: NVIDIA Corporation GP100GL [Tesla P100 PCIe 16GB] [10de:15f8] (rev a1)
```
6. Additionally, you can check the PCI BARs space of the Nvidia GPU device in the container:
```
$ lspci -s 01:01.0 -vv | grep Region
Region 0: Memory at c0000000 (32-bit, non-prefetchable) [disabled] [size=16M]
Region 1: Memory at 4400000000 (64-bit, prefetchable) [disabled] [size=16G]
Region 3: Memory at 4800000000 (64-bit, prefetchable) [disabled] [size=32M]
```
> **Note**: If you see a message similar to the above, the BAR space of the Nvidia
> GPU has been successfully allocated.
## Nvidia vGPU mode with Kata Containers
Nvidia vGPU is a licensed product on all supported GPU boards. A software license
is required to enable all vGPU features within the guest VM.
> **Note**: There is no suitable test environment, so it is not written here.
## Install Nvidia Driver in Kata Containers
Download the official Nvidia driver from
[https://www.nvidia.com/Download/index.aspx](https://www.nvidia.com/Download/index.aspx),
for example `NVIDIA-Linux-x86_64-418.87.01.run`.
Install the `kernel-devel`(generated in the previous steps) for guest kernel:
```
$ sudo rpm -ivh kernel-devel-4.19.86_gpu-1.x86_64.rpm
```
Here is an example to extract, compile and install Nvidia driver:
```
## Extract
$ sh ./NVIDIA-Linux-x86_64-418.87.01.run -x
## Compile and install (It will take some time)
$ cd NVIDIA-Linux-x86_64-418.87.01
$ sudo ./nvidia-installer -a -q --ui=none \
--no-cc-version-check \
--no-opengl-files --no-install-libglvnd \
--kernel-source-path=/usr/src/kernels/`uname -r`
```
Or just run one command line:
```
$ sudo sh ./NVIDIA-Linux-x86_64-418.87.01.run -a -q --ui=none \
--no-cc-version-check \
--no-opengl-files --no-install-libglvnd \
--kernel-source-path=/usr/src/kernels/`uname -r`
```
To view detailed logs of the installer:
```
$ tail -f /var/log/nvidia-installer.log
```
Load Nvidia driver module manually
```
# Optionalgenerate modules.dep and map files for Nvidia driver
$ sudo depmod
# Load module
$ sudo modprobe nvidia-drm
# Check module
$ lsmod | grep nvidia
nvidia_drm 45056 0
nvidia_modeset 1093632 1 nvidia_drm
nvidia 18202624 1 nvidia_modeset
drm_kms_helper 159744 1 nvidia_drm
drm 364544 3 nvidia_drm,drm_kms_helper
i2c_core 65536 3 nvidia,drm_kms_helper,drm
ipmi_msghandler 49152 1 nvidia
```
Check Nvidia device status with `nvidia-smi`
```
$ nvidia-smi
Tue Mar 3 00:03:49 2020
+-----------------------------------------------------------------------------+
| NVIDIA-SMI 418.87.01 Driver Version: 418.87.01 CUDA Version: 10.1 |
|-------------------------------+----------------------+----------------------+
| GPU Name Persistence-M| Bus-Id Disp.A | Volatile Uncorr. ECC |
| Fan Temp Perf Pwr:Usage/Cap| Memory-Usage | GPU-Util Compute M. |
|===============================+======================+======================|
| 0 Tesla P100-PCIE... Off | 00000000:01:01.0 Off | 0 |
| N/A 27C P0 25W / 250W | 0MiB / 16280MiB | 0% Default |
+-------------------------------+----------------------+----------------------+
+-----------------------------------------------------------------------------+
| Processes: GPU Memory |
| GPU PID Type Process name Usage |
|=============================================================================|
| No running processes found |
+-----------------------------------------------------------------------------+
```
## References
- [Configuring a VM for GPU Pass-Through by Using the QEMU Command Line](https://docs.nvidia.com/grid/latest/grid-vgpu-user-guide/index.html#using-gpu-pass-through-red-hat-el-qemu-cli)
- https://gitlab.com/nvidia/container-images/driver/-/tree/master
- https://github.com/NVIDIA/nvidia-docker/wiki/Driver-containers

10
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View File

@@ -49,7 +49,7 @@ the latest driver.
$ export QAT_DRIVER_VER=qat1.7.l.4.14.0-00031.tar.gz
$ export QAT_DRIVER_URL=https://downloadmirror.intel.com/30178/eng/${QAT_DRIVER_VER}
$ export QAT_CONF_LOCATION=~/QAT_conf
$ export QAT_DOCKERFILE=https://raw.githubusercontent.com/intel/intel-device-plugins-for-kubernetes/main/demo/openssl-qat-engine/Dockerfile
$ export QAT_DOCKERFILE=https://raw.githubusercontent.com/intel/intel-device-plugins-for-kubernetes/master/demo/openssl-qat-engine/Dockerfile
$ export QAT_SRC=~/src/QAT
$ export GOPATH=~/src/go
$ export KATA_KERNEL_LOCATION=~/kata
@@ -279,8 +279,8 @@ $ export KERNEL_EXTRAVERSION=$(awk '/^EXTRAVERSION =/{print $NF}' $GOPATH/$LINUX
$ export KERNEL_ROOTFS_DIR=${KERNEL_MAJOR_VERSION}.${KERNEL_PATHLEVEL}.${KERNEL_SUBLEVEL}${KERNEL_EXTRAVERSION}
$ cd $QAT_SRC
$ KERNEL_SOURCE_ROOT=$GOPATH/$LINUX_VER ./configure --enable-icp-sriov=guest
$ sudo -E make all -j $($(nproc ${CI:+--ignore 1}))
$ sudo -E make INSTALL_MOD_PATH=$ROOTFS_DIR qat-driver-install -j $($(nproc ${CI:+--ignore 1}))
$ sudo -E make all -j$(nproc)
$ sudo -E make INSTALL_MOD_PATH=$ROOTFS_DIR qat-driver-install -j$(nproc)
```
The `usdm_drv` module also needs to be copied into the rootfs modules path and
@@ -312,7 +312,7 @@ working properly with the Kata Containers VM.
### Build OpenSSL Intel® QAT engine container
Use the OpenSSL Intel® QAT [Dockerfile](https://github.com/intel/intel-device-plugins-for-kubernetes/tree/main/demo/openssl-qat-engine)
Use the OpenSSL Intel® QAT [Dockerfile](https://github.com/intel/intel-device-plugins-for-kubernetes/tree/master/demo/openssl-qat-engine)
to build a container image with an optimized OpenSSL engine for
Intel® QAT. Using `docker build` with the Kata Containers runtime can sometimes
have issues. Therefore, make sure that `runc` is the default Docker container
@@ -444,7 +444,7 @@ $ sudo docker save -o openssl-qat-engine.tar openssl-qat-engine:latest
$ sudo ctr -n=k8s.io images import openssl-qat-engine.tar
```
The [Intel® QAT Plugin](https://github.com/intel/intel-device-plugins-for-kubernetes/blob/main/cmd/qat_plugin/README.md)
The [Intel® QAT Plugin](https://github.com/intel/intel-device-plugins-for-kubernetes/blob/master/cmd/qat_plugin/README.md)
needs to be started so that the virtual functions can be discovered and
used by Kubernetes.

10
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View File

@@ -18,13 +18,16 @@ CONFIG_X86_SGX_KVM=y
* Kubernetes cluster configured with:
* [`kata-deploy`](../../tools/packaging/kata-deploy) based Kata Containers installation
* [Intel SGX Kubernetes device plugin](https://github.com/intel/intel-device-plugins-for-kubernetes/tree/main/cmd/sgx_plugin#deploying-with-pre-built-images) and associated components including [operator](https://github.com/intel/intel-device-plugins-for-kubernetes/blob/main/cmd/operator/README.md) and dependencies
* [Intel SGX Kubernetes device plugin](https://github.com/intel/intel-device-plugins-for-kubernetes/tree/main/cmd/sgx_plugin#deploying-with-pre-built-images)
> Note: Kata Containers supports creating VM sandboxes with Intel® SGX enabled
> using [cloud-hypervisor](https://github.com/cloud-hypervisor/cloud-hypervisor/) and [QEMU](https://www.qemu.org/) VMMs only.
### Kata Containers Configuration
Before running a Kata Container make sure that your version of `crio` or `containerd`
supports annotations.
For `containerd` check in `/etc/containerd/config.toml` that the list of `pod_annotations` passed
to the `sandbox` are: `["io.katacontainers.*", "sgx.intel.com/epc"]`.
@@ -61,9 +64,6 @@ spec:
name: eosgx-demo-job-1
image: oeciteam/oe-helloworld:latest
imagePullPolicy: IfNotPresent
volumeMounts:
- mountPath: /dev
name: dev-mount
securityContext:
readOnlyRootFilesystem: true
capabilities:
@@ -99,4 +99,4 @@ because socket passthrough is not supported. An alternative is to deploy the `ae
container.
* Projects like [Gramine Shielded Containers (GSC)](https://gramine-gsc.readthedocs.io/en/latest/) are
also known to work. For GSC specifically, the Kata guest kernel needs to have the `CONFIG_NUMA=y`
enabled and at least one CPU online when running the GSC container. The Kata Containers guest kernel currently has `CONFIG_NUMA=y` enabled by default.
enabled and at least one CPU online when running the GSC container.

5
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View File

@@ -197,6 +197,11 @@ vhost_user_store_path = "<Path of the base directory for vhost-user device>"
> under `[hypervisor.qemu]` section.
For the subdirectories of `vhost_user_store_path`: `block` is used for block
device; `block/sockets` is where we expect UNIX domain sockets for vhost-user
block devices to live; `block/devices` is where simulated block device nodes
for vhost-user block devices are created.
For the subdirectories of `vhost_user_store_path`:
- `block` is used for block device;
- `block/sockets` is where we expect UNIX domain sockets for vhost-user

76
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View File

@@ -0,0 +1,76 @@
# Setup to run VPP
The Data Plane Development Kit (DPDK) is a set of libraries and drivers for
fast packet processing. Vector Packet Processing (VPP) is a platform
extensible framework that provides out-of-the-box production quality
switch and router functionality. VPP is a high performance packet-processing
stack that can run on commodity CPUs. Enabling VPP with DPDK support can
yield significant performance improvements over a Linux\* bridge providing a
switch with DPDK VHOST-USER ports.
For more information about VPP visit their [wiki](https://wiki.fd.io/view/VPP).
## Install and configure Kata Containers
Follow the [Kata Containers setup instructions](../Developer-Guide.md).
In order to make use of VHOST-USER based interfaces, the container needs to be backed
by huge pages. `HugePages` support is required for the large memory pool allocation used for
DPDK packet buffers. This is a feature which must be configured within the Linux Kernel. See
[the DPDK documentation](https://doc.dpdk.org/guides/linux_gsg/sys_reqs.html#use-of-hugepages-in-the-linux-environment)
for details on how to enable for the host. After enabling huge pages support on the host system,
update the Kata configuration to enable huge page support in the guest kernel:
```
$ sudo sed -i -e 's/^# *\(enable_hugepages\).*=.*$/\1 = true/g' /usr/share/defaults/kata-containers/configuration.toml
```
## Install VPP
Follow the [VPP installation instructions](https://wiki.fd.io/view/VPP/Installing_VPP_binaries_from_packages).
After a successful installation, your host system is ready to start
connecting Kata Containers with VPP bridges.
### Install the VPP Docker\* plugin
To create a Docker network and connect Kata Containers easily to that network through
Docker, install a VPP Docker plugin.
To install the plugin, follow the [plugin installation instructions](https://github.com/clearcontainers/vpp).
This VPP plugin allows the creation of a VPP network. Every container added
to this network is connected through an L2 bridge-domain provided by VPP.
## Example: Launch two Kata Containers using VPP
To use VPP, use Docker to create a network that makes use of VPP.
For example:
```
$ sudo docker network create -d=vpp --ipam-driver=vpp --subnet=192.168.1.0/24 --gateway=192.168.1.1 vpp_net
```
Test connectivity by launching two containers:
```
$ sudo docker run --runtime=kata-runtime --net=vpp_net --ip=192.168.1.2 --mac-address=CA:FE:CA:FE:01:02 -it busybox bash -c "ip a; ip route; sleep 300"
$ sudo docker run --runtime=kata-runtime --net=vpp_net --ip=192.168.1.3 --mac-address=CA:FE:CA:FE:01:03 -it busybox bash -c "ip a; ip route; ping 192.168.1.2"
```
These commands setup two Kata Containers connected via a VPP L2 bridge
domain. The first of the two VMs displays the networking details and then
sleeps providing a period of time for it to be pinged. The second
VM displays its networking details and then pings the first VM, verifying
connectivity between them.
After verifying connectivity, cleanup with the following commands:
```
$ sudo docker kill $(sudo docker ps --no-trunc -aq)
$ sudo docker rm $(sudo docker ps --no-trunc -aq)
$ sudo docker network rm vpp_net
$ sudo service vpp stop
```

38
snap/local/README.md → snap/README.md
View File

@@ -22,35 +22,21 @@ $ sudo snap install kata-containers --classic
## Build and install snap image
Run the command below which will use the packaging Makefile to build the snap image:
Run next command at the root directory of the packaging repository.
```sh
$ make -C tools/packaging snap
$ make snap
```
> **Warning:**
>
> By default, `snapcraft` will create a clean virtual machine
> environment to build the snap in using the `multipass` tool.
>
> However, `multipass` is silently disabled when `--destructive-mode` is
> used.
>
> Since building the Kata Containers package currently requires
> `--destructive-mode`, the snap will be built using the host
> environment. To avoid parts of the build auto-detecting additional
> features to enable (for example for QEMU), we recommend that you
> only run the snap build in a minimal host environment.
To install the resulting snap image, snap must be put in [classic mode][3] and the
security confinement must be disabled (`--classic`). Also since the resulting snap
has not been signed the verification of signature must be omitted (`--dangerous`).
security confinement must be disabled (*--classic*). Also since the resulting snap
has not been signed the verification of signature must be omitted (*--dangerous*).
```sh
$ sudo snap install --classic --dangerous "kata-containers_${version}_${arch}.snap"
$ sudo snap install --classic --dangerous kata-containers_[VERSION]_[ARCH].snap
```
Replace `${version}` with the current version of Kata Containers and `${arch}` with
Replace `VERSION` with the current version of Kata Containers and `ARCH` with
the system architecture.
## Configure Kata Containers
@@ -90,12 +76,12 @@ then a new configuration file can be [created](#configure-kata-containers)
and [configured][7].
[1]: https://docs.snapcraft.io/snaps/intro
[2]: ../../docs/design/architecture/README.md#root-filesystem-image
[2]: ../docs/design/architecture/README.md#root-filesystem-image
[3]: https://docs.snapcraft.io/reference/confinement#classic
[4]: https://github.com/kata-containers/kata-containers/tree/main/src/runtime#configuration
[4]: https://github.com/kata-containers/runtime#configuration
[5]: https://docs.docker.com/engine/reference/commandline/dockerd
[6]: ../../docs/install/docker/ubuntu-docker-install.md
[7]: ../../docs/Developer-Guide.md#configure-to-use-initrd-or-rootfs-image
[6]: ../docs/install/docker/ubuntu-docker-install.md
[7]: ../docs/Developer-Guide.md#configure-to-use-initrd-or-rootfs-image
[8]: https://snapcraft.io/kata-containers
[9]: ../../docs/Developer-Guide.md#run-kata-containers-with-docker
[10]: ../../docs/Developer-Guide.md#run-kata-containers-with-kubernetes
[9]: ../docs/Developer-Guide.md#run-kata-containers-with-docker
[10]: ../docs/Developer-Guide.md#run-kata-containers-with-kubernetes

114
snap/local/snap-common.sh
View File

@@ -1,114 +0,0 @@
#!/usr/bin/env bash
#
# Copyright (c) 2022 Intel Corporation
#
# SPDX-License-Identifier: Apache-2.0
# Description: Idempotent script to be sourced by all parts in a
# snapcraft config file.
set -o errexit
set -o nounset
set -o pipefail
# XXX: Bash-specific code. zsh doesn't support this option and that *does*
# matter if this script is run sourced... since it'll be using zsh! ;)
[ -n "$BASH_VERSION" ] && set -o errtrace
[ -n "${DEBUG:-}" ] && set -o xtrace
die()
{
echo >&2 "ERROR: $0: $*"
}
[ -n "${SNAPCRAFT_STAGE:-}" ] ||\
die "must be sourced from a snapcraft config file"
snap_yq_version=3.4.1
snap_common_install_yq()
{
export yq="${SNAPCRAFT_STAGE}/bin/yq"
local yq_pkg
yq_pkg="github.com/mikefarah/yq"
local yq_url
yq_url="https://${yq_pkg}/releases/download/${snap_yq_version}/yq_${goos}_${goarch}"
curl -o "${yq}" -L "${yq_url}"
chmod +x "${yq}"
}
# Function that should be called for each snap "part" in
# snapcraft.yaml.
snap_common_main()
{
# Architecture
arch="$(uname -m)"
case "${arch}" in
aarch64)
goarch="arm64"
qemu_arch="${arch}"
;;
ppc64le)
goarch="ppc64le"
qemu_arch="ppc64"
;;
s390x)
goarch="${arch}"
qemu_arch="${arch}"
;;
x86_64)
goarch="amd64"
qemu_arch="${arch}"
;;
*) die "unsupported architecture: ${arch}" ;;
esac
dpkg_arch=$(dpkg --print-architecture)
# golang
#
# We need the O/S name in golang format, but since we don't
# know if the godeps part has run, we don't know if golang is
# available yet, hence fall back to a standard system command.
goos="$(go env GOOS &>/dev/null || true)"
[ -z "$goos" ] && goos=$(uname -s|tr '[A-Z]' '[a-z]')
export GOROOT="${SNAPCRAFT_STAGE}"
export GOPATH="${GOROOT}/gopath"
export GO111MODULE="auto"
mkdir -p "${GOPATH}/bin"
export PATH="${GOPATH}/bin:${PATH}"
# Proxy
export http_proxy="${http_proxy:-}"
export https_proxy="${https_proxy:-}"
# Binaries
mkdir -p "${SNAPCRAFT_STAGE}/bin"
export PATH="$PATH:${SNAPCRAFT_STAGE}/bin"
# YAML query tool
export yq="${SNAPCRAFT_STAGE}/bin/yq"
# Kata paths
export kata_dir=$(printf "%s/src/github.com/%s/%s" \
"${GOPATH}" \
"${SNAPCRAFT_PROJECT_NAME}" \
"${SNAPCRAFT_PROJECT_NAME}")
export versions_file="${kata_dir}/versions.yaml"
[ -n "${yq:-}" ] && [ -x "${yq:-}" ] || snap_common_install_yq
}
snap_common_main

280
snap/snapcraft.yaml
View File

@@ -1,5 +1,4 @@
name: kata-containers
website: https://github.com/kata-containers/kata-containers
summary: Build lightweight VMs that seamlessly plug into the containers ecosystem
description: |
Kata Containers is an open source project and community working to build a
@@ -19,18 +18,20 @@ parts:
- git
- git-extras
override-pull: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
version="9999"
kata_url="https://github.com/kata-containers/kata-containers"
if echo "${GITHUB_REF:-}" | grep -q -E "^refs/tags"; then
version=$(echo ${GITHUB_REF:-} | cut -d/ -f3)
if echo "${GITHUB_REF}" | grep -q -E "^refs/tags"; then
version=$(echo ${GITHUB_REF} | cut -d/ -f3)
git checkout ${version}
fi
snapcraftctl set-grade "stable"
snapcraftctl set-version "${version}"
# setup GOPATH - this repo dir should be there
export GOPATH=${SNAPCRAFT_STAGE}/gopath
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
mkdir -p $(dirname ${kata_dir})
ln -sf $(realpath "${SNAPCRAFT_STAGE}/..") ${kata_dir}
@@ -42,79 +43,33 @@ parts:
build-packages:
- curl
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
# put everything in stage
cd "${SNAPCRAFT_STAGE}"
cd ${SNAPCRAFT_STAGE}
version="$(${yq} r ${kata_dir}/versions.yaml languages.golang.meta.newest-version)"
yq_path="./yq"
yq_pkg="github.com/mikefarah/yq"
goos="linux"
case "$(uname -m)" in
aarch64) goarch="arm64";;
ppc64le) goarch="ppc64le";;
x86_64) goarch="amd64";;
s390x) goarch="s390x";;
*) echo "unsupported architecture: $(uname -m)"; exit 1;;
esac
yq_version=3.4.1
yq_url="https://${yq_pkg}/releases/download/${yq_version}/yq_${goos}_${goarch}"
curl -o "${yq_path}" -L "${yq_url}"
chmod +x "${yq_path}"
kata_dir=gopath/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
version="$(${yq_path} r ${kata_dir}/versions.yaml languages.golang.meta.newest-version)"
tarfile="go${version}.${goos}-${goarch}.tar.gz"
curl -LO https://golang.org/dl/${tarfile}
tar -xf ${tarfile} --strip-components=1
rustdeps:
after: [metadata]
plugin: nil
prime:
- -*
build-packages:
- curl
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
# put everything in stage
cd "${SNAPCRAFT_STAGE}"
version="$(${yq} r ${kata_dir}/versions.yaml languages.rust.meta.newest-version)"
if ! command -v rustup > /dev/null; then
curl https://sh.rustup.rs -sSf | sh -s -- -y --default-toolchain ${version}
fi
export PATH=${PATH}:${HOME}/.cargo/bin
rustup toolchain install ${version}
rustup default ${version}
if [ "${arch}" == "ppc64le" ] || [ "${arch}" == "s390x" ] ; then
[ "${arch}" == "ppc64le" ] && arch="powerpc64le"
rustup target add ${arch}-unknown-linux-gnu
else
rustup target add ${arch}-unknown-linux-musl
$([ "$(whoami)" != "root" ] && echo sudo) ln -sf /usr/bin/g++ /bin/musl-g++
fi
rustup component add rustfmt
docker:
after: [metadata]
plugin: nil
prime:
- -*
build-packages:
- ca-certificates
- containerd
- curl
- gnupg
- lsb-release
- runc
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
curl -fsSL https://download.docker.com/linux/ubuntu/gpg |\
sudo gpg --batch --yes --dearmor -o /usr/share/keyrings/docker-archive-keyring.gpg
distro_codename=$(lsb_release -cs)
echo "deb [arch=${dpkg_arch} signed-by=/usr/share/keyrings/docker-archive-keyring.gpg] https://download.docker.com/linux/ubuntu ${distro_codename} stable" |\
sudo tee /etc/apt/sources.list.d/docker.list > /dev/null
sudo apt-get -y update
sudo apt-get -y install docker-ce docker-ce-cli containerd.io
echo "Unmasking docker service"
sudo -E systemctl unmask docker.service || true
sudo -E systemctl unmask docker.socket || true
echo "Adding $USER into docker group"
sudo -E gpasswd -a $USER docker
echo "Starting docker"
sudo -E systemctl start docker || true
image:
after: [godeps, docker, qemu, kernel]
after: [godeps, qemu, kernel]
plugin: nil
build-packages:
- docker.io
@@ -125,67 +80,95 @@ parts:
- uidmap
- gnupg2
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
[ "$(uname -m)" = "ppc64le" ] || [ "$(uname -m)" = "s390x" ] && sudo apt-get --no-install-recommends install -y protobuf-compiler
[ "${arch}" = "ppc64le" ] || [ "${arch}" = "s390x" ] && sudo apt-get --no-install-recommends install -y protobuf-compiler
yq=${SNAPCRAFT_STAGE}/yq
# set GOPATH
export GOPATH=${SNAPCRAFT_STAGE}/gopath
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
export GOROOT=${SNAPCRAFT_STAGE}
export PATH="${GOROOT}/bin:${PATH}"
export GO111MODULE="auto"
http_proxy=${http_proxy:-""}
https_proxy=${https_proxy:-""}
if [ -n "$http_proxy" ]; then
echo "Setting proxy $http_proxy"
sudo -E systemctl set-environment http_proxy="$http_proxy" || true
sudo -E systemctl set-environment https_proxy="$https_proxy" || true
sudo -E systemctl set-environment http_proxy=$http_proxy || true
sudo -E systemctl set-environment https_proxy=$https_proxy || true
fi
# Copy yq binary. It's used in the container
mkdir -p "${GOPATH}/bin/"
cp -a "${yq}" "${GOPATH}/bin/"
cd "${kata_dir}/tools/osbuilder"
echo "Unmasking docker service"
sudo -E systemctl unmask docker.service || true
sudo -E systemctl unmask docker.socket || true
echo "Adding $USER into docker group"
sudo -E gpasswd -a $USER docker
echo "Starting docker"
sudo -E systemctl start docker || true
cd ${kata_dir}/tools/osbuilder
# build image
export AGENT_INIT=yes
export USE_DOCKER=1
export DEBUG=1
arch="$(uname -m)"
initrd_distro=$(${yq} r -X ${kata_dir}/versions.yaml assets.initrd.architecture.${arch}.name)
image_distro=$(${yq} r -X ${kata_dir}/versions.yaml assets.image.architecture.${arch}.name)
case "$arch" in
x86_64)
# In some build systems it's impossible to build a rootfs image, try with the initrd image
sudo -E PATH=$PATH make image DISTRO="${image_distro}" || sudo -E PATH="$PATH" make initrd DISTRO="${initrd_distro}"
sudo -E PATH=$PATH make image DISTRO=${image_distro} || sudo -E PATH=$PATH make initrd DISTRO=${initrd_distro}
;;
aarch64|ppc64le|s390x)
sudo -E PATH="$PATH" make initrd DISTRO="${initrd_distro}"
sudo -E PATH=$PATH make initrd DISTRO=${initrd_distro}
;;
*) die "unsupported architecture: ${arch}" ;;
*) echo "unsupported architecture: $(uname -m)"; exit 1;;
esac
# Install image
kata_image_dir="${SNAPCRAFT_PART_INSTALL}/usr/share/kata-containers"
mkdir -p "${kata_image_dir}"
cp kata-containers*.img "${kata_image_dir}"
kata_image_dir=${SNAPCRAFT_PART_INSTALL}/usr/share/kata-containers
mkdir -p ${kata_image_dir}
cp kata-containers*.img ${kata_image_dir}
runtime:
after: [godeps, image, cloud-hypervisor]
plugin: nil
build-attributes: [no-patchelf]
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
# set GOPATH
export GOPATH=${SNAPCRAFT_STAGE}/gopath
export GOROOT=${SNAPCRAFT_STAGE}
export PATH="${GOROOT}/bin:${PATH}"
export GO111MODULE="auto"
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
cd "${kata_dir}/src/runtime"
cd ${kata_dir}/src/runtime
qemu_cmd="qemu-system-${qemu_arch}"
# setup arch
arch=$(uname -m)
if [ ${arch} = "ppc64le" ]; then
arch="ppc64"
fi
# build and install runtime
make \
PREFIX="/snap/${SNAPCRAFT_PROJECT_NAME}/current/usr" \
PREFIX=/snap/${SNAPCRAFT_PROJECT_NAME}/current/usr \
SKIP_GO_VERSION_CHECK=1 \
QEMUCMD="${qemu_cmd}"
QEMUCMD=qemu-system-$arch
make install \
PREFIX=/usr \
DESTDIR="${SNAPCRAFT_PART_INSTALL}" \
DESTDIR=${SNAPCRAFT_PART_INSTALL} \
SKIP_GO_VERSION_CHECK=1 \
QEMUCMD="${qemu_cmd}"
QEMUCMD=qemu-system-$arch
if [ ! -f ${SNAPCRAFT_PART_INSTALL}/../../image/install/usr/share/kata-containers/kata-containers.img ]; then
sed -i -e "s|^image =.*|initrd = \"/snap/${SNAPCRAFT_PROJECT_NAME}/current/usr/share/kata-containers/kata-containers-initrd.img\"|" \
@@ -202,37 +185,44 @@ parts:
- bison
- flex
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
yq=${SNAPCRAFT_STAGE}/yq
export PATH="${PATH}:${SNAPCRAFT_STAGE}"
export GOPATH=${SNAPCRAFT_STAGE}/gopath
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
versions_file="${kata_dir}/versions.yaml"
kernel_version="$(${yq} r $versions_file assets.kernel.version)"
#Remove extra 'v'
kernel_version="${kernel_version#v}"
kernel_version=${kernel_version#v}
[ "${arch}" = "s390x" ] && sudo apt-get --no-install-recommends install -y libssl-dev
[ "$(uname -m)" = "s390x" ] && sudo apt-get --no-install-recommends install -y libssl-dev
cd "${kata_dir}/tools/packaging/kernel"
export GOPATH=${SNAPCRAFT_STAGE}/gopath
export GO111MODULE="auto"
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
cd ${kata_dir}/tools/packaging/kernel
kernel_dir_prefix="kata-linux-"
# Setup and build kernel
./build-kernel.sh -v "${kernel_version}" -d setup
./build-kernel.sh -v ${kernel_version} -d setup
cd ${kernel_dir_prefix}*
make -j $(nproc ${CI:+--ignore 1}) EXTRAVERSION=".container"
make -j $(($(nproc)-1)) EXTRAVERSION=".container"
kernel_suffix="${kernel_version}.container"
kata_kernel_dir="${SNAPCRAFT_PART_INSTALL}/usr/share/kata-containers"
mkdir -p "${kata_kernel_dir}"
kernel_suffix=${kernel_version}.container
kata_kernel_dir=${SNAPCRAFT_PART_INSTALL}/usr/share/kata-containers
mkdir -p ${kata_kernel_dir}
# Install bz kernel
make install INSTALL_PATH="${kata_kernel_dir}" EXTRAVERSION=".container" || true
vmlinuz_name="vmlinuz-${kernel_suffix}"
ln -sf "${vmlinuz_name}" "${kata_kernel_dir}/vmlinuz.container"
make install INSTALL_PATH=${kata_kernel_dir} EXTRAVERSION=".container" || true
vmlinuz_name=vmlinuz-${kernel_suffix}
ln -sf ${vmlinuz_name} ${kata_kernel_dir}/vmlinuz.container
# Install raw kernel
vmlinux_path="vmlinux"
[ "${arch}" = "s390x" ] && vmlinux_path="arch/s390/boot/vmlinux"
vmlinux_name="vmlinux-${kernel_suffix}"
cp "${vmlinux_path}" "${kata_kernel_dir}/${vmlinux_name}"
ln -sf "${vmlinux_name}" "${kata_kernel_dir}/vmlinux.container"
vmlinux_path=vmlinux
[ "$(uname -m)" = "s390x" ] && vmlinux_path=arch/s390/boot/compressed/vmlinux
vmlinux_name=vmlinux-${kernel_suffix}
cp ${vmlinux_path} ${kata_kernel_dir}/${vmlinux_name}
ln -sf ${vmlinux_name} ${kata_kernel_dir}/vmlinux.container
qemu:
plugin: make
@@ -259,8 +249,12 @@ parts:
- libselinux1-dev
- ninja-build
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
yq=${SNAPCRAFT_STAGE}/yq
export GOPATH=${SNAPCRAFT_STAGE}/gopath
export GO111MODULE="auto"
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
versions_file="${kata_dir}/versions.yaml"
branch="$(${yq} r ${versions_file} assets.hypervisor.qemu.version)"
url="$(${yq} r ${versions_file} assets.hypervisor.qemu.url)"
commit=""
@@ -268,11 +262,11 @@ parts:
patches_version_dir="${kata_dir}/tools/packaging/qemu/patches/tag_patches/${branch}"
# download source
qemu_dir="${SNAPCRAFT_STAGE}/qemu"
qemu_dir=${SNAPCRAFT_STAGE}/qemu
rm -rf "${qemu_dir}"
git clone --depth 1 --branch ${branch} --single-branch ${url} "${qemu_dir}"
cd "${qemu_dir}"
[ -z "${commit}" ] || git checkout "${commit}"
cd ${qemu_dir}
[ -z "${commit}" ] || git checkout ${commit}
[ -n "$(ls -A ui/keycodemapdb)" ] || git clone --depth 1 https://github.com/qemu/keycodemapdb ui/keycodemapdb/
[ -n "$(ls -A capstone)" ] || git clone --depth 1 https://github.com/qemu/capstone capstone
@@ -283,10 +277,10 @@ parts:
${kata_dir}/tools/packaging/scripts/apply_patches.sh "${patches_version_dir}"
# Only x86_64 supports libpmem
[ "${arch}" = "x86_64" ] && sudo apt-get --no-install-recommends install -y apt-utils ca-certificates libpmem-dev
[ "$(uname -m)" = "x86_64" ] && sudo apt-get --no-install-recommends install -y apt-utils ca-certificates libpmem-dev
configure_hypervisor="${kata_dir}/tools/packaging/scripts/configure-hypervisor.sh"
chmod +x "${configure_hypervisor}"
configure_hypervisor=${kata_dir}/tools/packaging/scripts/configure-hypervisor.sh
chmod +x ${configure_hypervisor}
# static build. The --prefix, --libdir, --libexecdir, --datadir arguments are
# based on PREFIX and set by configure-hypervisor.sh
echo "$(PREFIX=/snap/${SNAPCRAFT_PROJECT_NAME}/current/usr ${configure_hypervisor} -s kata-qemu) \
@@ -296,17 +290,17 @@ parts:
# Copy QEMU configurations (Kconfigs)
case "${branch}" in
"v5.1.0")
cp -a "${kata_dir}"/tools/packaging/qemu/default-configs/* default-configs
cp -a ${kata_dir}/tools/packaging/qemu/default-configs/* default-configs
;;
*)
cp -a "${kata_dir}"/tools/packaging/qemu/default-configs/* configs/devices/
cp -a ${kata_dir}/tools/packaging/qemu/default-configs/* configs/devices/
;;
esac
# build and install
make -j $(nproc ${CI:+--ignore 1})
make install DESTDIR="${SNAPCRAFT_PART_INSTALL}"
make -j $(($(nproc)-1))
make install DESTDIR=${SNAPCRAFT_PART_INSTALL}
prime:
- -snap/
- -usr/bin/qemu-ga
@@ -322,44 +316,26 @@ parts:
# Hack: move qemu to /
"snap/kata-containers/current/": "./"
virtiofsd:
plugin: nil
after: [godeps, rustdeps, docker]
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
echo "INFO: Building rust version of virtiofsd"
cd "${SNAPCRAFT_PROJECT_DIR}"
# Clean-up build dir in case it already exists
sudo -E NO_TTY=true make virtiofsd-tarball
sudo install \
--owner='root' \
--group='root' \
--mode=0755 \
-D \
--target-directory="${SNAPCRAFT_PART_INSTALL}/usr/libexec/" \
build/virtiofsd/builddir/virtiofsd/virtiofsd
cloud-hypervisor:
plugin: nil
after: [godeps, docker]
after: [godeps]
override-build: |
source "${SNAPCRAFT_PROJECT_DIR}/snap/local/snap-common.sh"
arch=$(uname -m)
if [ "{$arch}" == "aarch64" ] || [ "${arch}" == "x64_64" ]; then
sudo apt-get -y update
sudo apt-get -y install ca-certificates curl gnupg lsb-release
curl -fsSL https://download.docker.com/linux/ubuntu/gpg | sudo gpg --batch --yes --dearmor -o /usr/share/keyrings/docker-archive-keyring.gpg
echo "deb [arch=$(dpkg --print-architecture) signed-by=/usr/share/keyrings/docker-archive-keyring.gpg] https://download.docker.com/linux/ubuntu $(lsb_release -cs) stable" | sudo tee /etc/apt/sources.list.d/docker.list > /dev/null
sudo apt-get -y update
sudo apt-get -y install docker-ce docker-ce-cli containerd.io
sudo systemctl start docker.socket
if [ "${arch}" == "aarch64" ] || [ "${arch}" == "x86_64" ]; then
cd "${SNAPCRAFT_PROJECT_DIR}"
export GOPATH=${SNAPCRAFT_STAGE}/gopath
kata_dir=${GOPATH}/src/github.com/${SNAPCRAFT_PROJECT_NAME}/${SNAPCRAFT_PROJECT_NAME}
cd ${kata_dir}
sudo -E NO_TTY=true make cloud-hypervisor-tarball
tarfile="${SNAPCRAFT_PROJECT_DIR}/tools/packaging/kata-deploy/local-build/build/kata-static-cloud-hypervisor.tar.xz"
tmpdir=$(mktemp -d)
tar -xvJpf "${tarfile}" -C "${tmpdir}"
install -D "${tmpdir}/opt/kata/bin/cloud-hypervisor" "${SNAPCRAFT_PART_INSTALL}/usr/bin/cloud-hypervisor"
rm -rf "${tmpdir}"
tar xvJpf build/kata-static-cloud-hypervisor.tar.xz -C /tmp/
install -D /tmp/opt/kata/bin/cloud-hypervisor ${SNAPCRAFT_PART_INSTALL}/usr/bin/cloud-hypervisor
fi
apps:

1425
src/agent/Cargo.lock generated
View File

File diff suppressed because it is too large Load Diff

25
src/agent/Cargo.toml
View File

@@ -3,26 +3,24 @@ name = "kata-agent"
version = "0.1.0"
authors = ["The Kata Containers community <kata-dev@lists.katacontainers.io>"]
edition = "2018"
license = "Apache-2.0"
[dependencies]
oci = { path = "../libs/oci" }
rustjail = { path = "rustjail" }
protocols = { path = "../libs/protocols", features = ["async"] }
protocols = { path = "../libs/protocols" }
lazy_static = "1.3.0"
ttrpc = { version = "0.6.0", features = ["async"], default-features = false }
protobuf = "2.27.0"
ttrpc = { version = "0.5.0", features = ["async", "protobuf-codec"], default-features = false }
protobuf = "=2.14.0"
libc = "0.2.58"
nix = "0.24.2"
nix = "0.23.0"
capctl = "0.2.0"
serde_json = "1.0.39"
scan_fmt = "0.2.3"
scopeguard = "1.0.0"
thiserror = "1.0.26"
regex = "1.5.6"
regex = "1.5.4"
serial_test = "0.5.1"
kata-sys-util = { path = "../libs/kata-sys-util" }
kata-types = { path = "../libs/kata-types" }
sysinfo = "0.23.0"
# Async helpers
async-trait = "0.1.42"
@@ -30,7 +28,7 @@ async-recursion = "0.3.2"
futures = "0.3.17"
# Async runtime
tokio = { version = "1.28.1", features = ["full"] }
tokio = { version = "1.14.0", features = ["full"] }
tokio-vsock = "0.3.1"
netlink-sys = { version = "0.7.0", features = ["tokio_socket",]}
@@ -51,7 +49,7 @@ log = "0.4.11"
prometheus = { version = "0.13.0", features = ["process"] }
procfs = "0.12.0"
anyhow = "1.0.32"
cgroups = { package = "cgroups-rs", version = "0.3.2" }
cgroups = { package = "cgroups-rs", version = "0.2.8" }
# Tracing
tracing = "0.1.26"
@@ -67,8 +65,6 @@ clap = { version = "3.0.1", features = ["derive"] }
[dev-dependencies]
tempfile = "3.1.0"
test-utils = { path = "../libs/test-utils" }
which = "4.3.0"
[workspace]
members = [
@@ -80,8 +76,3 @@ lto = true
[features]
seccomp = ["rustjail/seccomp"]
standard-oci-runtime = ["rustjail/standard-oci-runtime"]
[[bin]]
name = "kata-agent"
path = "src/main.rs"

28
src/agent/Makefile
View File

@@ -14,6 +14,10 @@ PROJECT_COMPONENT = kata-agent
TARGET = $(PROJECT_COMPONENT)
SOURCES := \
$(shell find . 2>&1 | grep -E '.*\.rs$$') \
Cargo.toml
VERSION_FILE := ./VERSION
VERSION := $(shell grep -v ^\# $(VERSION_FILE))
COMMIT_NO := $(shell git rev-parse HEAD 2>/dev/null || true)
@@ -33,16 +37,8 @@ ifeq ($(SECCOMP),yes)
override EXTRA_RUSTFEATURES += seccomp
endif
##VAR STANDARD_OCI_RUNTIME=yes|no define if agent enables standard oci runtime feature
STANDARD_OCI_RUNTIME := no
# Enable standard oci runtime feature of rust build
ifeq ($(STANDARD_OCI_RUNTIME),yes)
override EXTRA_RUSTFEATURES += standard-oci-runtime
endif
ifneq ($(EXTRA_RUSTFEATURES),)
override EXTRA_RUSTFEATURES := --features "$(EXTRA_RUSTFEATURES)"
override EXTRA_RUSTFEATURES := --features $(EXTRA_RUSTFEATURES)
endif
include ../../utils.mk
@@ -107,19 +103,20 @@ endef
##TARGET default: build code
default: $(TARGET) show-header
static-checks-build: $(GENERATED_CODE)
$(TARGET): $(GENERATED_CODE) logging-crate-tests $(TARGET_PATH)
$(TARGET): $(GENERATED_CODE) $(TARGET_PATH)
logging-crate-tests:
make -C $(CWD)/../libs/logging
$(TARGET_PATH): show-summary
@RUSTFLAGS="$(EXTRA_RUSTFLAGS) --deny warnings" cargo build --target $(TRIPLE) $(if $(findstring release,$(BUILD_TYPE)),--release) $(EXTRA_RUSTFEATURES)
$(TARGET_PATH): $(SOURCES) | show-summary
@RUSTFLAGS="$(EXTRA_RUSTFLAGS) --deny warnings" cargo build --target $(TRIPLE) --$(BUILD_TYPE) $(EXTRA_RUSTFEATURES)
$(GENERATED_FILES): %: %.in
@sed $(foreach r,$(GENERATED_REPLACEMENTS),-e 's|@$r@|$($r)|g') "$<" > "$@"
##TARGET optimize: optimized build
optimize: show-summary show-header
@RUSTFLAGS="-C link-arg=-s $(EXTRA_RUSTFLAGS) --deny warnings" cargo build --target $(TRIPLE) $(if $(findstring release,$(BUILD_TYPE)),--release) $(EXTRA_RUSTFEATURES)
optimize: $(SOURCES) | show-summary show-header
@RUSTFLAGS="-C link-arg=-s $(EXTRA_RUSTFLAGS) --deny warnings" cargo build --target $(TRIPLE) --$(BUILD_TYPE) $(EXTRA_RUSTFEATURES)
##TARGET install: install agent
install: install-services
@@ -202,6 +199,7 @@ codecov-html: check_tarpaulin
.PHONY: \
help \
logging-crate-tests \
optimize \
show-header \
show-summary \

20
src/agent/rustjail/Cargo.toml
View File

@@ -3,7 +3,6 @@ name = "rustjail"
version = "0.1.0"
authors = ["The Kata Containers community <kata-dev@lists.katacontainers.io>"]
edition = "2018"
license = "Apache-2.0"
[dependencies]
serde = "1.0.91"
@@ -11,38 +10,31 @@ serde_json = "1.0.39"
serde_derive = "1.0.91"
oci = { path = "../../libs/oci" }
protocols = { path ="../../libs/protocols" }
kata-sys-util = { path = "../../libs/kata-sys-util" }
caps = "0.5.0"
nix = "0.24.2"
nix = "0.23.0"
scopeguard = "1.0.0"
capctl = "0.2.0"
lazy_static = "1.3.0"
libc = "0.2.58"
protobuf = "2.27.0"
protobuf = "=2.14.0"
slog = "2.5.2"
slog-scope = "4.1.2"
scan_fmt = "0.2.6"
regex = "1.5.6"
regex = "1.5.4"
path-absolutize = "1.2.0"
anyhow = "1.0.32"
cgroups = { package = "cgroups-rs", version = "0.3.2" }
cgroups = { package = "cgroups-rs", version = "0.2.8" }
rlimit = "0.5.3"
cfg-if = "0.1.0"
tokio = { version = "1.28.1", features = ["sync", "io-util", "process", "time", "macros", "rt"] }
tokio = { version = "1.2.0", features = ["sync", "io-util", "process", "time", "macros"] }
futures = "0.3.17"
async-trait = "0.1.31"
inotify = "0.9.2"
libseccomp = { version = "0.3.0", optional = true }
zbus = "2.3.0"
bit-vec= "0.6.3"
xattr = "0.2.3"
libseccomp = { version = "0.1.3", optional = true }
[dev-dependencies]
serial_test = "0.5.0"
tempfile = "3.1.0"
test-utils = { path = "../../libs/test-utils" }
[features]
seccomp = ["libseccomp"]
standard-oci-runtime = []

210
src/agent/rustjail/src/cgroups/fs/mod.rs
View File

@@ -32,7 +32,6 @@ use protocols::agent::{
BlkioStats, BlkioStatsEntry, CgroupStats, CpuStats, CpuUsage, HugetlbStats, MemoryData,
MemoryStats, PidsStats, ThrottlingData,
};
use std::any::Any;
use std::collections::HashMap;
use std::fs;
use std::path::Path;
@@ -76,7 +75,7 @@ macro_rules! set_resource {
impl CgroupManager for Manager {
fn apply(&self, pid: pid_t) -> Result<()> {
self.cgroup.add_task_by_tgid(CgroupPid::from(pid as u64))?;
self.cgroup.add_task(CgroupPid::from(pid as u64))?;
Ok(())
}
@@ -175,7 +174,7 @@ impl CgroupManager for Manager {
freezer_controller.freeze()?;
}
_ => {
return Err(anyhow!("Invalid FreezerState"));
return Err(anyhow!(nix::Error::EINVAL));
}
}
@@ -194,83 +193,6 @@ impl CgroupManager for Manager {
Ok(result)
}
fn update_cpuset_path(&self, guest_cpuset: &str, container_cpuset: &str) -> Result<()> {
if guest_cpuset.is_empty() {
return Ok(());
}
info!(sl!(), "update_cpuset_path to: {}", guest_cpuset);
let h = cgroups::hierarchies::auto();
let root_cg = h.root_control_group();
let root_cpuset_controller: &CpuSetController = root_cg.controller_of().unwrap();
let path = root_cpuset_controller.path();
let root_path = Path::new(path);
info!(sl!(), "root cpuset path: {:?}", &path);
let container_cpuset_controller: &CpuSetController = self.cgroup.controller_of().unwrap();
let path = container_cpuset_controller.path();
let container_path = Path::new(path);
info!(sl!(), "container cpuset path: {:?}", &path);
let mut paths = vec![];
for ancestor in container_path.ancestors() {
if ancestor == root_path {
break;
}
paths.push(ancestor);
}
info!(sl!(), "parent paths to update cpuset: {:?}", &paths);
let mut i = paths.len();
loop {
if i == 0 {
break;
}
i -= 1;
// remove cgroup root from path
let r_path = &paths[i]
.to_str()
.unwrap()
.trim_start_matches(root_path.to_str().unwrap());
info!(sl!(), "updating cpuset for parent path {:?}", &r_path);
let cg = new_cgroup(cgroups::hierarchies::auto(), r_path)?;
let cpuset_controller: &CpuSetController = cg.controller_of().unwrap();
cpuset_controller.set_cpus(guest_cpuset)?;
}
if !container_cpuset.is_empty() {
info!(
sl!(),
"updating cpuset for container path: {:?} cpuset: {}",
&container_path,
container_cpuset
);
container_cpuset_controller.set_cpus(container_cpuset)?;
}
Ok(())
}
fn get_cgroup_path(&self, cg: &str) -> Result<String> {
if cgroups::hierarchies::is_cgroup2_unified_mode() {
let cg_path = format!("/sys/fs/cgroup/{}", self.cpath);
return Ok(cg_path);
}
// for cgroup v1
Ok(self.paths.get(cg).map(|s| s.to_string()).unwrap())
}
fn as_any(&self) -> Result<&dyn Any> {
Ok(self)
}
fn name(&self) -> &str {
"cgroupfs"
}
}
fn set_network_resources(
@@ -330,28 +252,19 @@ fn set_devices_resources(
}
fn set_hugepages_resources(
cg: &cgroups::Cgroup,
_cg: &cgroups::Cgroup,
hugepage_limits: &[LinuxHugepageLimit],
res: &mut cgroups::Resources,
) {
info!(sl!(), "cgroup manager set hugepage");
let mut limits = vec![];
let hugetlb_controller = cg.controller_of::<HugeTlbController>();
for l in hugepage_limits.iter() {
if hugetlb_controller.is_some() && hugetlb_controller.unwrap().size_supported(&l.page_size)
{
let hr = HugePageResource {
size: l.page_size.clone(),
limit: l.limit,
};
limits.push(hr);
} else {
warn!(
sl!(),
"{} page size support cannot be verified, dropping requested limit", l.page_size
);
}
let hr = HugePageResource {
size: l.page_size.clone(),
limit: l.limit,
};
limits.push(hr);
}
res.hugepages.limits = limits;
}
@@ -478,7 +391,7 @@ fn set_memory_resources(cg: &cgroups::Cgroup, memory: &LinuxMemory, update: bool
if let Some(swappiness) = memory.swappiness {
if (0..=100).contains(&swappiness) {
mem_controller.set_swappiness(swappiness)?;
mem_controller.set_swappiness(swappiness as u64)?;
} else {
return Err(anyhow!(
"invalid value:{}. valid memory swappiness range is 0-100",
@@ -677,9 +590,9 @@ fn get_cpuacct_stats(cg: &cgroups::Cgroup) -> SingularPtrField<CpuUsage> {
let h = lines_to_map(&cpuacct.stat);
let usage_in_usermode =
(((*h.get("user").unwrap_or(&0) * NANO_PER_SECOND) as f64) / *CLOCK_TICKS) as u64;
(((*h.get("user").unwrap() * NANO_PER_SECOND) as f64) / *CLOCK_TICKS) as u64;
let usage_in_kernelmode =
(((*h.get("system").unwrap_or(&0) * NANO_PER_SECOND) as f64) / *CLOCK_TICKS) as u64;
(((*h.get("system").unwrap() * NANO_PER_SECOND) as f64) / *CLOCK_TICKS) as u64;
let total_usage = cpuacct.usage;
@@ -695,13 +608,24 @@ fn get_cpuacct_stats(cg: &cgroups::Cgroup) -> SingularPtrField<CpuUsage> {
});
}
if cg.v2() {
return SingularPtrField::some(CpuUsage {
total_usage: 0,
percpu_usage: vec![],
usage_in_kernelmode: 0,
usage_in_usermode: 0,
unknown_fields: UnknownFields::default(),
cached_size: CachedSize::default(),
});
}
// try to get from cpu controller
let cpu_controller: &CpuController = get_controller_or_return_singular_none!(cg);
let stat = cpu_controller.cpu().stat;
let h = lines_to_map(&stat);
let usage_in_usermode = *h.get("user_usec").unwrap_or(&0);
let usage_in_kernelmode = *h.get("system_usec").unwrap_or(&0);
let total_usage = *h.get("usage_usec").unwrap_or(&0);
let usage_in_usermode = *h.get("user_usec").unwrap();
let usage_in_kernelmode = *h.get("system_usec").unwrap();
let total_usage = *h.get("usage_usec").unwrap();
let percpu_usage = vec![];
SingularPtrField::some(CpuUsage {
@@ -725,7 +649,7 @@ fn get_memory_stats(cg: &cgroups::Cgroup) -> SingularPtrField<MemoryStats> {
let value = memory.use_hierarchy;
let use_hierarchy = value == 1;
// get memory data
// gte memory datas
let usage = SingularPtrField::some(MemoryData {
usage: memory.usage_in_bytes,
max_usage: memory.max_usage_in_bytes,
@@ -987,8 +911,9 @@ pub fn get_paths() -> Result<HashMap<String, String>> {
Ok(m)
}
pub fn get_mounts(paths: &HashMap<String, String>) -> Result<HashMap<String, String>> {
pub fn get_mounts() -> Result<HashMap<String, String>> {
let mut m = HashMap::new();
let paths = get_paths()?;
for l in fs::read_to_string(MOUNTS)?.lines() {
let p: Vec<&str> = l.splitn(2, " - ").collect();
@@ -1016,9 +941,9 @@ pub fn get_mounts(paths: &HashMap<String, String>) -> Result<HashMap<String, Str
Ok(m)
}
fn new_cgroup(h: Box<dyn cgroups::Hierarchy>, path: &str) -> Result<Cgroup> {
fn new_cgroup(h: Box<dyn cgroups::Hierarchy>, path: &str) -> Cgroup {
let valid_path = path.trim_start_matches('/').to_string();
cgroups::Cgroup::new(h, valid_path.as_str()).map_err(anyhow::Error::from)
cgroups::Cgroup::new(h, valid_path.as_str())
}
impl Manager {
@@ -1026,7 +951,7 @@ impl Manager {
let mut m = HashMap::new();
let paths = get_paths()?;
let mounts = get_mounts(&paths)?;
let mounts = get_mounts()?;
for key in paths.keys() {
let mnt = mounts.get(key);
@@ -1040,16 +965,83 @@ impl Manager {
m.insert(key.to_string(), p);
}
let cg = new_cgroup(cgroups::hierarchies::auto(), cpath)?;
Ok(Self {
paths: m,
mounts,
// rels: paths,
cpath: cpath.to_string(),
cgroup: cg,
cgroup: new_cgroup(cgroups::hierarchies::auto(), cpath),
})
}
pub fn update_cpuset_path(&self, guest_cpuset: &str, container_cpuset: &str) -> Result<()> {
if guest_cpuset.is_empty() {
return Ok(());
}
info!(sl!(), "update_cpuset_path to: {}", guest_cpuset);
let h = cgroups::hierarchies::auto();
let root_cg = h.root_control_group();
let root_cpuset_controller: &CpuSetController = root_cg.controller_of().unwrap();
let path = root_cpuset_controller.path();
let root_path = Path::new(path);
info!(sl!(), "root cpuset path: {:?}", &path);
let container_cpuset_controller: &CpuSetController = self.cgroup.controller_of().unwrap();
let path = container_cpuset_controller.path();
let container_path = Path::new(path);
info!(sl!(), "container cpuset path: {:?}", &path);
let mut paths = vec![];
for ancestor in container_path.ancestors() {
if ancestor == root_path {
break;
}
paths.push(ancestor);
}
info!(sl!(), "parent paths to update cpuset: {:?}", &paths);
let mut i = paths.len();
loop {
if i == 0 {
break;
}
i -= 1;
// remove cgroup root from path
let r_path = &paths[i]
.to_str()
.unwrap()
.trim_start_matches(root_path.to_str().unwrap());
info!(sl!(), "updating cpuset for parent path {:?}", &r_path);
let cg = new_cgroup(cgroups::hierarchies::auto(), r_path);
let cpuset_controller: &CpuSetController = cg.controller_of().unwrap();
cpuset_controller.set_cpus(guest_cpuset)?;
}
if !container_cpuset.is_empty() {
info!(
sl!(),
"updating cpuset for container path: {:?} cpuset: {}",
&container_path,
container_cpuset
);
container_cpuset_controller.set_cpus(container_cpuset)?;
}
Ok(())
}
pub fn get_cg_path(&self, cg: &str) -> Option<String> {
if cgroups::hierarchies::is_cgroup2_unified_mode() {
let cg_path = format!("/sys/fs/cgroup/{}", self.cpath);
return Some(cg_path);
}
// for cgroup v1
self.paths.get(cg).map(|s| s.to_string())
}
}
// get the guest's online cpus.

25
src/agent/rustjail/src/cgroups/mock.rs
View File

@@ -11,7 +11,6 @@ use anyhow::Result;
use cgroups::freezer::FreezerState;
use libc::{self, pid_t};
use oci::LinuxResources;
use std::any::Any;
use std::collections::HashMap;
use std::string::String;
@@ -54,22 +53,6 @@ impl CgroupManager for Manager {
fn get_pids(&self) -> Result<Vec<pid_t>> {
Ok(Vec::new())
}
fn update_cpuset_path(&self, _: &str, _: &str) -> Result<()> {
Ok(())
}
fn get_cgroup_path(&self, _: &str) -> Result<String> {
Ok("".to_string())
}
fn as_any(&self) -> Result<&dyn Any> {
Ok(self)
}
fn name(&self) -> &str {
"mock"
}
}
impl Manager {
@@ -80,4 +63,12 @@ impl Manager {
cpath: cpath.to_string(),
})
}
pub fn update_cpuset_path(&self, _: &str, _: &str) -> Result<()> {
Ok(())
}
pub fn get_cg_path(&self, _: &str) -> Option<String> {
Some("".to_string())
}
}

22
src/agent/rustjail/src/cgroups/mod.rs
View File

@@ -4,10 +4,8 @@
//
use anyhow::{anyhow, Result};
use core::fmt::Debug;
use oci::LinuxResources;
use protocols::agent::CgroupStats;
use std::any::Any;
use cgroups::freezer::FreezerState;
@@ -40,24 +38,4 @@ pub trait Manager {
fn set(&self, _container: &LinuxResources, _update: bool) -> Result<()> {
Err(anyhow!("not supported!"))
}
fn update_cpuset_path(&self, _: &str, _: &str) -> Result<()> {
Err(anyhow!("not supported!"))
}
fn get_cgroup_path(&self, _: &str) -> Result<String> {
Err(anyhow!("not supported!"))
}
fn as_any(&self) -> Result<&dyn Any> {
Err(anyhow!("not supported!"))
}
fn name(&self) -> &str;
}
impl Debug for dyn Manager + Send + Sync {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
write!(f, "{}", self.name())
}
}

10
src/agent/rustjail/src/cgroups/notifier.rs
View File

@@ -151,12 +151,12 @@ async fn register_memory_event(
let eventfd = eventfd(0, EfdFlags::EFD_CLOEXEC)?;
let event_control_path = Path::new(&cg_dir).join("cgroup.event_control");
let data = if arg.is_empty() {
format!("{} {}", eventfd, event_file.as_raw_fd())
let data;
if arg.is_empty() {
data = format!("{} {}", eventfd, event_file.as_raw_fd());
} else {
format!("{} {} {}", eventfd, event_file.as_raw_fd(), arg)
};
data = format!("{} {} {}", eventfd, event_file.as_raw_fd(), arg);
}
fs::write(&event_control_path, data)?;

10
src/agent/rustjail/src/cgroups/systemd.rs Normal file
View File

@@ -0,0 +1,10 @@
// Copyright (c) 2019 Ant Financial
//
// SPDX-License-Identifier: Apache-2.0
//
use crate::cgroups::Manager as CgroupManager;
pub struct Manager {}
impl CgroupManager for Manager {}

95
src/agent/rustjail/src/cgroups/systemd/cgroups_path.rs
View File

@@ -1,95 +0,0 @@
// Copyright 2021-2022 Kata Contributors
//
// SPDX-License-Identifier: Apache-2.0
//
use anyhow::{anyhow, Result};
use super::common::{DEFAULT_SLICE, SCOPE_SUFFIX, SLICE_SUFFIX};
use std::string::String;
#[derive(Serialize, Deserialize, Debug, Clone)]
pub struct CgroupsPath {
pub slice: String,
pub prefix: String,
pub name: String,
}
impl CgroupsPath {
pub fn new(cgroups_path_str: &str) -> Result<Self> {
let path_vec: Vec<&str> = cgroups_path_str.split(':').collect();
if path_vec.len() != 3 {
return Err(anyhow!("invalid cpath: {:?}", cgroups_path_str));
}
Ok(CgroupsPath {
slice: if path_vec[0].is_empty() {
DEFAULT_SLICE.to_string()
} else {
path_vec[0].to_owned()
},
prefix: path_vec[1].to_owned(),
name: path_vec[2].to_owned(),
})
}
// ref: https://github.com/opencontainers/runc/blob/main/docs/systemd.md
// return: (parent_slice, unit_name)
pub fn parse(&self) -> Result<(String, String)> {
Ok((
parse_parent(self.slice.to_owned())?,
get_unit_name(self.prefix.to_owned(), self.name.to_owned()),
))
}
}
fn parse_parent(slice: String) -> Result<String> {
if !slice.ends_with(SLICE_SUFFIX) || slice.contains('/') {
return Err(anyhow!("invalid slice name: {}", slice));
} else if slice == "-.slice" {
return Ok(String::new());
}
let mut slice_path = String::new();
let mut prefix = String::new();
for subslice in slice.trim_end_matches(SLICE_SUFFIX).split('-') {
if subslice.is_empty() {
return Err(anyhow!("invalid slice name: {}", slice));
}
slice_path = format!("{}/{}{}{}", slice_path, prefix, subslice, SLICE_SUFFIX);
prefix = format!("{}{}-", prefix, subslice);
}
slice_path.remove(0);
Ok(slice_path)
}
fn get_unit_name(prefix: String, name: String) -> String {
if name.ends_with(SLICE_SUFFIX) {
name
} else if prefix.is_empty() {
format!("{}{}", name, SCOPE_SUFFIX)
} else {
format!("{}-{}{}", prefix, name, SCOPE_SUFFIX)
}
}
#[cfg(test)]
mod tests {
use super::CgroupsPath;
#[test]
fn test_cgroup_path_parse() {
let slice = "system.slice";
let prefix = "kata_agent";
let name = "123";
let cgroups_path =
CgroupsPath::new(format!("{}:{}:{}", slice, prefix, name).as_str()).unwrap();
assert_eq!(slice, cgroups_path.slice.as_str());
assert_eq!(prefix, cgroups_path.prefix.as_str());
assert_eq!(name, cgroups_path.name.as_str());
let (parent_slice, unit_name) = cgroups_path.parse().unwrap();
assert_eq!(format!("{}", slice), parent_slice);
assert_eq!(format!("{}-{}.scope", prefix, name), unit_name);
}
}

17
src/agent/rustjail/src/cgroups/systemd/common.rs
View File

@@ -1,17 +0,0 @@
// Copyright 2021-2022 Kata Contributors
//
// SPDX-License-Identifier: Apache-2.0
//
pub const DEFAULT_SLICE: &str = "system.slice";
pub const SLICE_SUFFIX: &str = ".slice";
pub const SCOPE_SUFFIX: &str = ".scope";
pub const UNIT_MODE: &str = "replace";
pub type Properties<'a> = Vec<(&'a str, zbus::zvariant::Value<'a>)>;
#[derive(Serialize, Deserialize, Debug, Clone)]
pub enum CgroupHierarchy {
Legacy,
Unified,
}

129
src/agent/rustjail/src/cgroups/systemd/dbus_client.rs
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@@ -1,129 +0,0 @@
// Copyright 2021-2022 Kata Contributors
//
// SPDX-License-Identifier: Apache-2.0
//
use std::vec;
use super::common::CgroupHierarchy;
use super::common::{Properties, SLICE_SUFFIX, UNIT_MODE};
use super::interface::system::ManagerProxyBlocking as SystemManager;
use anyhow::{Context, Result};
use zbus::zvariant::Value;
pub trait SystemdInterface {
fn start_unit(
&self,
pid: i32,
parent: &str,
unit_name: &str,
cg_hierarchy: &CgroupHierarchy,
) -> Result<()>;
fn set_properties(&self, unit_name: &str, properties: &Properties) -> Result<()>;
fn stop_unit(&self, unit_name: &str) -> Result<()>;
fn get_version(&self) -> Result<String>;
fn unit_exists(&self, unit_name: &str) -> Result<bool>;
fn add_process(&self, pid: i32, unit_name: &str) -> Result<()>;
}
#[derive(Serialize, Deserialize, Debug, Clone)]
pub struct DBusClient {}
impl DBusClient {
fn build_proxy(&self) -> Result<SystemManager<'static>> {
let connection =
zbus::blocking::Connection::system().context("Establishing a D-Bus connection")?;
let proxy = SystemManager::new(&connection).context("Building a D-Bus proxy manager")?;
Ok(proxy)
}
}
impl SystemdInterface for DBusClient {
fn start_unit(
&self,
pid: i32,
parent: &str,
unit_name: &str,
cg_hierarchy: &CgroupHierarchy,
) -> Result<()> {
let proxy = self.build_proxy()?;
// enable CPUAccounting & MemoryAccounting & (Block)IOAccounting by default
let mut properties: Properties = vec![
("CPUAccounting", Value::Bool(true)),
("DefaultDependencies", Value::Bool(false)),
("MemoryAccounting", Value::Bool(true)),
("TasksAccounting", Value::Bool(true)),
("Description", Value::Str("kata-agent container".into())),
("PIDs", Value::Array(vec![pid as u32].into())),
];
match *cg_hierarchy {
CgroupHierarchy::Legacy => properties.push(("IOAccounting", Value::Bool(true))),
CgroupHierarchy::Unified => properties.push(("BlockIOAccounting", Value::Bool(true))),
}
if unit_name.ends_with(SLICE_SUFFIX) {
properties.push(("Wants", Value::Str(parent.into())));
} else {
properties.push(("Slice", Value::Str(parent.into())));
properties.push(("Delegate", Value::Bool(true)));
}
proxy
.start_transient_unit(unit_name, UNIT_MODE, &properties, &[])
.with_context(|| format!("failed to start transient unit {}", unit_name))?;
Ok(())
}
fn set_properties(&self, unit_name: &str, properties: &Properties) -> Result<()> {
let proxy = self.build_proxy()?;
proxy
.set_unit_properties(unit_name, true, properties)
.with_context(|| format!("failed to set unit properties {}", unit_name))?;
Ok(())
}
fn stop_unit(&self, unit_name: &str) -> Result<()> {
let proxy = self.build_proxy()?;
proxy
.stop_unit(unit_name, UNIT_MODE)
.with_context(|| format!("failed to stop unit {}", unit_name))?;
Ok(())
}
fn get_version(&self) -> Result<String> {
let proxy = self.build_proxy()?;
let systemd_version = proxy
.version()
.with_context(|| "failed to get systemd version".to_string())?;
Ok(systemd_version)
}
fn unit_exists(&self, unit_name: &str) -> Result<bool> {
let proxy = self
.build_proxy()
.with_context(|| format!("Checking if systemd unit {} exists", unit_name))?;
Ok(proxy.get_unit(unit_name).is_ok())
}
fn add_process(&self, pid: i32, unit_name: &str) -> Result<()> {
let proxy = self.build_proxy()?;
proxy
.attach_processes_to_unit(unit_name, "/", &[pid as u32])
.with_context(|| format!("failed to add process {}", unit_name))?;
Ok(())
}
}

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src/agent/rustjail/src/cgroups/systemd/interface/mod.rs
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@@ -1,7 +0,0 @@
// Copyright 2021-2022 Kata Contributors
//
// SPDX-License-Identifier: Apache-2.0
//
pub(crate) mod session;
pub(crate) mod system;

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src/agent/rustjail/src/cgroups/systemd/interface/session.rs
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src/agent/rustjail/src/cgroups/systemd/interface/system.rs
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