This article explores the relationship between CRI-compliant runtimes (containerd and CRI-O), the filesystem tools that manipulate container storage, and how the humble link (both symbolic and hard) functions as the architectural glue holding container layers together. Before diving into tools and links, we must establish a baseline. The CRI is a Kubernetes API that kubelet uses to communicate with container runtimes. It abstracts the runtime implementation, allowing Kubernetes to work with Docker (via dockershim, now deprecated), containerd, CRI-O, and others.
Also, the new feature (v1.25+) uses hard links to preserve container state before migration. Conclusion: The Link is the Lost Art of Container Storage The CRI file system tools — crictl , ctr , crio-status —give you x-ray vision into how Kubernetes manages storage. But without understanding the link (whether symbolic, hard, or the conceptual parent pointer between layers), you are blind to half of the system. cri file system tools link
ctr namespace ls # List namespaces (e.g., k8s.io) ctr -n k8s.io snapshot ls # Show all snapshots (image layers) ctr -n k8s.io snapshot mount <key> /mnt # Mount a snapshot to inspect Snapshots are immutable directories linked together via overlayfs. Each snapshot has a "parent" link to the previous layer. 3. crio-status – CRI-O’s Inspection Tool For CRI-O users, crio-status dumps storage and runtime information. But without understanding the link (whether symbolic, hard,
Master these tools. Respect the link. Debug with confidence. Have a specific CRI filesystem issue related to links? Use the commands above to inspect your environment, and always test link operations in a non-production cluster first. It abstracts the runtime implementation