1814 lines
68 KiB
Python
1814 lines
68 KiB
Python
#!/usr/bin/env python3
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# cluster.py - PVC client function library, cluster management
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# Part of the Parallel Virtual Cluster (PVC) system
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#
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# Copyright (C) 2018-2024 Joshua M. Boniface <joshua@boniface.me>
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#
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# This program is free software: you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# the Free Software Foundation, version 3.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program. If not, see <https://www.gnu.org/licenses/>.
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#
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###############################################################################
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from distutils.util import strtobool
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from json import loads
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import daemon_lib.common as common
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import daemon_lib.faults as faults
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import daemon_lib.node as pvc_node
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import daemon_lib.vm as pvc_vm
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import daemon_lib.ceph as pvc_ceph
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# import daemon_lib.osd as pvc_osd
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def set_maintenance(zkhandler, maint_state):
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current_maint_state = zkhandler.read("base.config.maintenance")
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if maint_state == current_maint_state:
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if maint_state == "true":
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return True, "Cluster is already in maintenance mode"
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else:
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return True, "Cluster is already in normal mode"
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if maint_state == "true":
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zkhandler.write([("base.config.maintenance", "true")])
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return True, "Successfully set cluster in maintenance mode"
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else:
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zkhandler.write([("base.config.maintenance", "false")])
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return True, "Successfully set cluster in normal mode"
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def getClusterHealthFromFaults(zkhandler, faults_list):
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unacknowledged_faults = [fault for fault in faults_list if fault["status"] != "ack"]
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# Generate total cluster health numbers
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cluster_health_value = 100
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cluster_health_messages = list()
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for fault in sorted(
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unacknowledged_faults,
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key=lambda x: (x["health_delta"], x["last_reported"]),
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reverse=True,
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):
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cluster_health_value -= fault["health_delta"]
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message = {
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"id": fault["id"],
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"health_delta": fault["health_delta"],
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"text": fault["message"],
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}
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cluster_health_messages.append(message)
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if cluster_health_value < 0:
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cluster_health_value = 0
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cluster_health = {
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"health": cluster_health_value,
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"messages": cluster_health_messages,
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}
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return cluster_health
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def getClusterHealth(zkhandler, node_list, vm_list, ceph_osd_list):
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health_delta_map = {
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"node_stopped": 50,
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"node_flushed": 10,
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"vm_stopped": 10,
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"osd_out": 50,
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"osd_down": 10,
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"osd_full": 50,
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"osd_nearfull": 10,
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"memory_overprovisioned": 50,
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"ceph_err": 50,
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"ceph_warn": 10,
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}
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# Generate total cluster health numbers
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cluster_health_value = 100
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cluster_health_messages = list()
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for index, node in enumerate(node_list):
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# Apply node health values to total health number
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try:
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node_health_int = int(node["health"])
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except Exception:
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node_health_int = 100
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cluster_health_value -= 100 - node_health_int
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for entry in node["health_details"]:
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if entry["health_delta"] > 0:
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cluster_health_messages.append(
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f"{node['name']}: plugin '{entry['name']}': {entry['message']}"
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)
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# Handle unhealthy node states
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if node["daemon_state"] not in ["run"]:
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cluster_health_value -= health_delta_map["node_stopped"]
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cluster_health_messages.append(
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f"cluster: Node {node['name']} in {node['daemon_state'].upper()} daemon state"
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)
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elif node["domain_state"] not in ["ready"]:
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cluster_health_value -= health_delta_map["node_flushed"]
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cluster_health_messages.append(
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f"cluster: Node {node['name']} in {node['domain_state'].upper()} domain state"
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)
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for index, vm in enumerate(vm_list):
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# Handle unhealthy VM states
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if vm["state"] in ["stop", "fail"]:
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cluster_health_value -= health_delta_map["vm_stopped"]
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cluster_health_messages.append(
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f"cluster: VM {vm['name']} in {vm['state'].upper()} state"
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)
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for index, ceph_osd in enumerate(ceph_osd_list):
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in_texts = {1: "in", 0: "out"}
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up_texts = {1: "up", 0: "down"}
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# Handle unhealthy OSD states
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if in_texts[ceph_osd["stats"]["in"]] not in ["in"]:
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cluster_health_value -= health_delta_map["osd_out"]
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cluster_health_messages.append(
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f"cluster: Ceph OSD {ceph_osd['id']} in {in_texts[ceph_osd['stats']['in']].upper()} state"
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)
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elif up_texts[ceph_osd["stats"]["up"]] not in ["up"]:
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cluster_health_value -= health_delta_map["osd_down"]
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cluster_health_messages.append(
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f"cluster: Ceph OSD {ceph_osd['id']} in {up_texts[ceph_osd['stats']['up']].upper()} state"
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)
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# Handle full or nearfull OSDs (>85%)
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if ceph_osd["stats"]["utilization"] >= 90:
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cluster_health_value -= health_delta_map["osd_full"]
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cluster_health_messages.append(
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f"cluster: Ceph OSD {ceph_osd['id']} is FULL ({ceph_osd['stats']['utilization']:.1f}% > 90%)"
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)
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elif ceph_osd["stats"]["utilization"] >= 85:
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cluster_health_value -= health_delta_map["osd_nearfull"]
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cluster_health_messages.append(
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f"cluster: Ceph OSD {ceph_osd['id']} is NEARFULL ({ceph_osd['stats']['utilization']:.1f}% > 85%)"
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)
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# Check for (n-1) overprovisioning
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# Assume X nodes. If the total VM memory allocation (counting only running VMss) is greater than
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# the total memory of the (n-1) smallest nodes, trigger this warning.
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n_minus_1_total = 0
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alloc_total = 0
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node_largest_index = None
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node_largest_count = 0
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for index, node in enumerate(node_list):
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node_mem_total = node["memory"]["total"]
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node_mem_alloc = node["memory"]["allocated"]
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alloc_total += node_mem_alloc
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# Determine if this node is the largest seen so far
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if node_mem_total > node_largest_count:
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node_largest_index = index
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node_largest_count = node_mem_total
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n_minus_1_node_list = list()
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for index, node in enumerate(node_list):
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if index == node_largest_index:
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continue
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n_minus_1_node_list.append(node)
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for index, node in enumerate(n_minus_1_node_list):
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n_minus_1_total += node["memory"]["total"]
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if alloc_total > n_minus_1_total:
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cluster_health_value -= health_delta_map["memory_overprovisioned"]
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cluster_health_messages.append(
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f"cluster: Total memory is OVERPROVISIONED ({alloc_total} > {n_minus_1_total} @ N-1)"
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)
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# Check Ceph cluster health
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ceph_health = loads(zkhandler.read("base.storage.health"))
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ceph_health_status = ceph_health["status"]
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ceph_health_entries = ceph_health["checks"].keys()
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ceph_health_status_map = {
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"HEALTH_ERR": "ERROR",
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"HEALTH_WARN": "WARNING",
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}
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for entry in ceph_health_entries:
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cluster_health_messages.append(
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f"cluster: Ceph {ceph_health_status_map[ceph_health['checks'][entry]['severity']]} {entry}: {ceph_health['checks'][entry]['summary']['message']}"
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)
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if ceph_health_status == "HEALTH_ERR":
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cluster_health_value -= health_delta_map["ceph_err"]
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elif ceph_health_status == "HEALTH_WARN":
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cluster_health_value -= health_delta_map["ceph_warn"]
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if cluster_health_value < 0:
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cluster_health_value = 0
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cluster_health = {
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"health": cluster_health_value,
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"messages": cluster_health_messages,
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}
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return cluster_health
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def getNodeHealth(zkhandler, node_list):
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# Get the health state of all nodes
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node_health_reads = list()
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for node in node_list:
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node_health_reads += [
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("node.monitoring.health", node),
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("node.monitoring.plugins", node),
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]
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all_node_health_details = zkhandler.read_many(node_health_reads)
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# Parse out the Node health details
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node_health = dict()
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for nidx, node in enumerate(node_list):
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# Split the large list of return values by the IDX of this node
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# Each node result is 2 fields long
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pos_start = nidx * 2
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pos_end = nidx * 2 + 2
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node_health_value, node_health_plugins = tuple(
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all_node_health_details[pos_start:pos_end]
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)
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node_health_details = pvc_node.getNodeHealthDetails(
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zkhandler, node, node_health_plugins.split()
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)
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node_health_messages = list()
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for entry in node_health_details:
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if entry["health_delta"] > 0:
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node_health_messages.append(f"'{entry['name']}': {entry['message']}")
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try:
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node_health_value = int(node_health_value)
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except Exception:
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pass
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node_health_entry = {
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"health": node_health_value,
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"messages": node_health_messages,
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}
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node_health[node] = node_health_entry
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return node_health
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def getClusterInformation(zkhandler):
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# Get cluster maintenance state
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maintenance_state = zkhandler.read("base.config.maintenance")
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# Get primary node
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maintenance_state, primary_node = zkhandler.read_many(
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[
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("base.config.maintenance"),
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("base.config.primary_node"),
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]
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)
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# Get PVC version of primary node
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pvc_version = zkhandler.read(("node.data.pvc_version", primary_node))
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# Get the list of Nodes
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node_list = zkhandler.children("base.node")
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node_count = len(node_list)
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# Get the daemon and domain states of all Nodes
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node_state_reads = list()
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for node in node_list:
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node_state_reads += [
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("node.state.daemon", node),
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("node.state.domain", node),
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]
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all_node_states = zkhandler.read_many(node_state_reads)
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# Parse out the Node states
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node_data = list()
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formatted_node_states = {"total": node_count}
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for nidx, node in enumerate(node_list):
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# Split the large list of return values by the IDX of this node
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# Each node result is 2 fields long
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pos_start = nidx * 2
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pos_end = nidx * 2 + 2
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node_daemon_state, node_domain_state = tuple(all_node_states[pos_start:pos_end])
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node_data.append(
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{
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"name": node,
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"daemon_state": node_daemon_state,
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"domain_state": node_domain_state,
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}
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)
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node_state = f"{node_daemon_state},{node_domain_state}"
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# Add to the count for this node's state
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if node_state in common.node_state_combinations:
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if formatted_node_states.get(node_state) is not None:
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formatted_node_states[node_state] += 1
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else:
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formatted_node_states[node_state] = 1
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# Get the list of VMs
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vm_list = zkhandler.children("base.domain")
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vm_count = len(vm_list)
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# Get the states of all VMs
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vm_state_reads = list()
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for vm in vm_list:
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vm_state_reads += [
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("domain", vm),
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("domain.state", vm),
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]
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all_vm_states = zkhandler.read_many(vm_state_reads)
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# Parse out the VM states
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vm_data = list()
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formatted_vm_states = {"total": vm_count}
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for vidx, vm in enumerate(vm_list):
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# Split the large list of return values by the IDX of this VM
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# Each VM result is 2 field long
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pos_start = vidx * 2
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pos_end = vidx * 2 + 2
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vm_name, vm_state = tuple(all_vm_states[pos_start:pos_end])
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vm_data.append(
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{
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"uuid": vm,
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"name": vm_name,
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"state": vm_state,
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}
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)
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# Add to the count for this VM's state
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if vm_state in common.vm_state_combinations:
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if formatted_vm_states.get(vm_state) is not None:
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formatted_vm_states[vm_state] += 1
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else:
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formatted_vm_states[vm_state] = 1
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# Get the list of Ceph OSDs
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ceph_osd_list = zkhandler.children("base.osd")
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ceph_osd_count = len(ceph_osd_list)
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# Get the states of all OSDs ("stat" is not a typo since we're reading stats; states are in
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# the stats JSON object)
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osd_stat_reads = list()
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for osd in ceph_osd_list:
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osd_stat_reads += [("osd.stats", osd)]
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all_osd_stats = zkhandler.read_many(osd_stat_reads)
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# Parse out the OSD states
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osd_data = list()
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formatted_osd_states = {"total": ceph_osd_count}
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up_texts = {1: "up", 0: "down"}
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in_texts = {1: "in", 0: "out"}
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for oidx, osd in enumerate(ceph_osd_list):
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# Split the large list of return values by the IDX of this OSD
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# Each OSD result is 1 field long, so just use the IDX
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_osd_stats = all_osd_stats[oidx]
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# We have to load this JSON object and get our up/in states from it
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osd_stats = loads(_osd_stats)
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# Get our states
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osd_up = up_texts[osd_stats["up"]]
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osd_in = in_texts[osd_stats["in"]]
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osd_data.append(
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{
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"id": osd,
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"up": osd_up,
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"in": osd_in,
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}
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)
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osd_state = f"{osd_up},{osd_in}"
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# Add to the count for this OSD's state
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if osd_state in common.ceph_osd_state_combinations:
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if formatted_osd_states.get(osd_state) is not None:
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formatted_osd_states[osd_state] += 1
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else:
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formatted_osd_states[osd_state] = 1
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# Get the list of Networks
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network_list = zkhandler.children("base.network")
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network_count = len(network_list)
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# Get the list of Ceph pools
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ceph_pool_list = zkhandler.children("base.pool")
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ceph_pool_count = len(ceph_pool_list)
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# Get the list of Ceph volumes
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ceph_volume_list = list()
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for pool in ceph_pool_list:
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ceph_volume_list_pool = zkhandler.children(("volume", pool))
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if ceph_volume_list_pool is not None:
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ceph_volume_list += [f"{pool}/{volume}" for volume in ceph_volume_list_pool]
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ceph_volume_count = len(ceph_volume_list)
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# Get the list of Ceph snapshots
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ceph_snapshot_list = list()
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for volume in ceph_volume_list:
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ceph_snapshot_list_volume = zkhandler.children(("snapshot", volume))
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if ceph_snapshot_list_volume is not None:
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ceph_snapshot_list += [
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f"{volume}@{snapshot}" for snapshot in ceph_snapshot_list_volume
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]
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ceph_snapshot_count = len(ceph_snapshot_list)
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# Get the list of faults
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faults_data = faults.getAllFaults(zkhandler)
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# Format the status data
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cluster_information = {
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"cluster_health": getClusterHealthFromFaults(zkhandler, faults_data),
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"node_health": getNodeHealth(zkhandler, node_list),
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"maintenance": maintenance_state,
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"primary_node": primary_node,
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"pvc_version": pvc_version,
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"upstream_ip": zkhandler.read("base.config.upstream_ip"),
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"nodes": formatted_node_states,
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"vms": formatted_vm_states,
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"networks": network_count,
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"osds": formatted_osd_states,
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"pools": ceph_pool_count,
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"volumes": ceph_volume_count,
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"snapshots": ceph_snapshot_count,
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"detail": {
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"node": node_data,
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"vm": vm_data,
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"osd": osd_data,
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"faults": faults_data,
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},
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}
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return cluster_information
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def get_info(zkhandler):
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# This is a thin wrapper function for naming purposes
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cluster_information = getClusterInformation(zkhandler)
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if cluster_information:
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return True, cluster_information
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else:
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return False, "ERROR: Failed to obtain cluster information!"
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def get_health_metrics(zkhandler):
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"""
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Get health-related metrics from the PVC cluster
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"""
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status_retflag, status_data = get_info(zkhandler)
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if not status_retflag:
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return False, "Error: Status data threw error"
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faults_data = status_data["detail"]["faults"]
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node_data = status_data["detail"]["node"]
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vm_data = status_data["detail"]["vm"]
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osd_data = status_data["detail"]["osd"]
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output_lines = list()
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output_lines.append("# HELP pvc_info PVC cluster information")
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output_lines.append("# TYPE pvc_info gauge")
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output_lines.append(
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f"pvc_info{{primary_node=\"{status_data['primary_node']}\", version=\"{status_data['pvc_version']}\", upstream_ip=\"{status_data['upstream_ip']}\"}} 1"
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)
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output_lines.append("# HELP pvc_cluster_maintenance PVC cluster maintenance state")
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output_lines.append("# TYPE pvc_cluster_maintenance gauge")
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output_lines.append(
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f"pvc_cluster_maintenance {1 if bool(strtobool(status_data['maintenance'])) else 0}"
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)
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output_lines.append("# HELP pvc_cluster_health PVC cluster health status")
|
|
output_lines.append("# TYPE pvc_cluster_health gauge")
|
|
output_lines.append(f"pvc_cluster_health {status_data['cluster_health']['health']}")
|
|
|
|
output_lines.append("# HELP pvc_cluster_faults PVC cluster new faults")
|
|
output_lines.append("# TYPE pvc_cluster_faults gauge")
|
|
fault_map = dict()
|
|
for fault_type in common.fault_state_combinations:
|
|
fault_map[fault_type] = 0
|
|
for fault in faults_data:
|
|
fault_map[fault["status"]] += 1
|
|
for fault_type in fault_map:
|
|
output_lines.append(
|
|
f'pvc_cluster_faults{{status="{fault_type}"}} {fault_map[fault_type]}'
|
|
)
|
|
|
|
# output_lines.append("# HELP pvc_cluster_faults PVC cluster health faults")
|
|
# output_lines.append("# TYPE pvc_cluster_faults gauge")
|
|
# for fault_msg in status_data["cluster_health"]["messages"]:
|
|
# output_lines.append(
|
|
# f"pvc_cluster_faults{{id=\"{fault_msg['id']}\", message=\"{fault_msg['text']}\"}} {fault_msg['health_delta']}"
|
|
# )
|
|
|
|
output_lines.append("# HELP pvc_node_health PVC cluster node health status")
|
|
output_lines.append("# TYPE pvc_node_health gauge")
|
|
for node in status_data["node_health"]:
|
|
node_health = status_data["node_health"][node]["health"]
|
|
if isinstance(node_health, (int, float)):
|
|
output_lines.append(f'pvc_node_health{{node="{node}"}} {node_health}')
|
|
|
|
output_lines.append("# HELP pvc_node_daemon_states PVC Node daemon state counts")
|
|
output_lines.append("# TYPE pvc_node_daemon_states gauge")
|
|
node_daemon_state_map = dict()
|
|
for state in set([s.split(",")[0] for s in common.node_state_combinations]):
|
|
node_daemon_state_map[state] = 0
|
|
for node in node_data:
|
|
node_daemon_state_map[node["daemon_state"]] += 1
|
|
for state in node_daemon_state_map:
|
|
output_lines.append(
|
|
f'pvc_node_daemon_states{{state="{state}"}} {node_daemon_state_map[state]}'
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_domain_states PVC Node domain state counts")
|
|
output_lines.append("# TYPE pvc_node_domain_states gauge")
|
|
node_domain_state_map = dict()
|
|
for state in set([s.split(",")[1] for s in common.node_state_combinations]):
|
|
node_domain_state_map[state] = 0
|
|
for node in node_data:
|
|
node_domain_state_map[node["domain_state"]] += 1
|
|
for state in node_domain_state_map:
|
|
output_lines.append(
|
|
f'pvc_node_domain_states{{state="{state}"}} {node_domain_state_map[state]}'
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_states PVC VM state counts")
|
|
output_lines.append("# TYPE pvc_vm_states gauge")
|
|
vm_state_map = dict()
|
|
for state in set(common.vm_state_combinations):
|
|
vm_state_map[state] = 0
|
|
for vm in vm_data:
|
|
vm_state_map[vm["state"]] += 1
|
|
for state in vm_state_map:
|
|
output_lines.append(f'pvc_vm_states{{state="{state}"}} {vm_state_map[state]}')
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_up_states PVC OSD up state counts")
|
|
output_lines.append("# TYPE pvc_ceph_osd_up_states gauge")
|
|
osd_up_state_map = dict()
|
|
for state in set([s.split(",")[0] for s in common.ceph_osd_state_combinations]):
|
|
osd_up_state_map[state] = 0
|
|
for osd in osd_data:
|
|
if osd["up"] == "up":
|
|
osd_up_state_map["up"] += 1
|
|
else:
|
|
osd_up_state_map["down"] += 1
|
|
for state in osd_up_state_map:
|
|
output_lines.append(
|
|
f'pvc_ceph_osd_up_states{{state="{state}"}} {osd_up_state_map[state]}'
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_in_states PVC OSD in state counts")
|
|
output_lines.append("# TYPE pvc_ceph_osd_in_states gauge")
|
|
osd_in_state_map = dict()
|
|
for state in set([s.split(",")[1] for s in common.ceph_osd_state_combinations]):
|
|
osd_in_state_map[state] = 0
|
|
for osd in osd_data:
|
|
if osd["in"] == "in":
|
|
osd_in_state_map["in"] += 1
|
|
else:
|
|
osd_in_state_map["out"] += 1
|
|
for state in osd_in_state_map:
|
|
output_lines.append(
|
|
f'pvc_ceph_osd_in_states{{state="{state}"}} {osd_in_state_map[state]}'
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_nodes PVC Node count")
|
|
output_lines.append("# TYPE pvc_nodes gauge")
|
|
output_lines.append(f"pvc_nodes {status_data['nodes']['total']}")
|
|
|
|
output_lines.append("# HELP pvc_vms PVC VM count")
|
|
output_lines.append("# TYPE pvc_vms gauge")
|
|
output_lines.append(f"pvc_vms {status_data['vms']['total']}")
|
|
|
|
output_lines.append("# HELP pvc_osds PVC OSD count")
|
|
output_lines.append("# TYPE pvc_osds gauge")
|
|
output_lines.append(f"pvc_osds {status_data['osds']['total']}")
|
|
|
|
output_lines.append("# HELP pvc_networks PVC Network count")
|
|
output_lines.append("# TYPE pvc_networks gauge")
|
|
output_lines.append(f"pvc_networks {status_data['networks']}")
|
|
|
|
output_lines.append("# HELP pvc_pools PVC Storage Pool count")
|
|
output_lines.append("# TYPE pvc_pools gauge")
|
|
output_lines.append(f"pvc_pools {status_data['pools']}")
|
|
|
|
output_lines.append("# HELP pvc_volumes PVC Storage Volume count")
|
|
output_lines.append("# TYPE pvc_volumes gauge")
|
|
output_lines.append(f"pvc_volumes {status_data['volumes']}")
|
|
|
|
output_lines.append("# HELP pvc_snapshots PVC Storage Snapshot count")
|
|
output_lines.append("# TYPE pvc_snapshots gauge")
|
|
output_lines.append(f"pvc_snapshots {status_data['snapshots']}")
|
|
|
|
return True, "\n".join(output_lines) + "\n"
|
|
|
|
|
|
def get_resource_metrics(zkhandler):
|
|
"""
|
|
Get resource-related metrics from the PVC cluster (except Ceph metrics)
|
|
"""
|
|
node_retflag, node_data = pvc_node.get_list(zkhandler)
|
|
if not node_retflag:
|
|
return False, "Error: Node data threw error"
|
|
|
|
vm_retflag, vm_data = pvc_vm.get_list(zkhandler)
|
|
if not vm_retflag:
|
|
return False, "Error: VM data threw error"
|
|
|
|
osd_retflag, osd_data = pvc_ceph.get_list_osd(zkhandler)
|
|
if not osd_retflag:
|
|
return False, "Error: OSD data threw error"
|
|
|
|
pool_retflag, pool_data = pvc_ceph.get_list_pool(zkhandler)
|
|
if not pool_retflag:
|
|
return False, "Error: Pool data threw error"
|
|
|
|
output_lines = list()
|
|
|
|
#
|
|
# Network Utilization stats
|
|
#
|
|
# This is a bit of a doozie. First, for each node, we have to determine the % utilization
|
|
# of all the (active) network interface on that node, averaged together. Then we average
|
|
# the values of all the nodes together.
|
|
# This is very rough, but should give some idea as to the total network bandwidth used
|
|
# and available.
|
|
all_total_speed = 0
|
|
all_total_util = 0
|
|
all_total_count = 0
|
|
per_node_network_utilization = dict()
|
|
for node in node_data:
|
|
if node["daemon_state"] != "run":
|
|
continue
|
|
|
|
total_speed = 0
|
|
total_util = 0
|
|
total_count = 0
|
|
for iface in node["interfaces"].keys():
|
|
link_state = node["interfaces"][iface]["state"]
|
|
if link_state != "up":
|
|
continue
|
|
|
|
link_speed = node["interfaces"][iface]["link_speed"] * 2 # full-duplex
|
|
total_speed += link_speed
|
|
|
|
total_bps = node["interfaces"][iface]["total_bps"]
|
|
total_util += total_bps
|
|
|
|
total_count += 1
|
|
|
|
if total_count > 0:
|
|
# Average the speed and util by the count
|
|
avg_speed = float(total_speed / total_count)
|
|
all_total_speed += avg_speed
|
|
avg_util = float(total_util / total_count)
|
|
all_total_util += avg_util
|
|
|
|
all_total_count += 1
|
|
|
|
per_node_network_utilization[node["name"]] = avg_util / avg_speed * 100
|
|
else:
|
|
per_node_network_utilization[node["name"]] = 0.0
|
|
|
|
if all_total_count > 0:
|
|
all_avg_speed = all_total_speed / all_total_count
|
|
all_avg_util = all_total_util / all_total_count
|
|
|
|
used_network_percentage = all_avg_util / all_avg_speed * 100
|
|
else:
|
|
used_network_percentage = 0
|
|
|
|
#
|
|
# Cluster stats
|
|
#
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_cpu_utilization PVC cluster CPU utilization percentage (n-1)"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_cpu_utilization gauge")
|
|
node_sorted_cpu = [
|
|
n["cpu_count"]
|
|
for n in sorted(node_data, key=lambda n: n["cpu_count"], reverse=False)
|
|
]
|
|
total_cpu = sum(node_sorted_cpu[:-1])
|
|
used_cpu = sum([n["load"] for n in node_data])
|
|
used_cpu_percentage = used_cpu / total_cpu * 100
|
|
output_lines.append(f"pvc_cluster_cpu_utilization {used_cpu_percentage:2.2f}")
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_network_utilization PVC cluster network utilization percentage"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_network_utilization gauge")
|
|
output_lines.append(
|
|
f"pvc_cluster_network_utilization {used_network_percentage:2.2f}"
|
|
)
|
|
|
|
node_sorted_memory = [
|
|
n["memory"]["total"]
|
|
for n in sorted(node_data, key=lambda n: n["memory"]["total"], reverse=False)
|
|
]
|
|
total_memory = sum(node_sorted_memory[:-1])
|
|
|
|
used_memory = sum([n["memory"]["used"] for n in node_data])
|
|
used_memory_percentage = used_memory / total_memory * 100
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_memory_real_utilization PVC cluster real memory utilization percentage (n-1)"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_memory_real_utilization gauge")
|
|
output_lines.append(
|
|
f"pvc_cluster_memory_real_utilization {used_memory_percentage:2.2f}"
|
|
)
|
|
|
|
allocated_memory = sum([n["memory"]["allocated"] for n in node_data])
|
|
allocated_memory_percentage = allocated_memory / total_memory * 100
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_memory_allocated_utilization PVC cluster allocated memory utilization percentage (n-1)"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_memory_allocated_utilization gauge")
|
|
output_lines.append(
|
|
f"pvc_cluster_memory_allocated_utilization {allocated_memory_percentage:2.2f}"
|
|
)
|
|
|
|
provisioned_memory = sum([n["memory"]["provisioned"] for n in node_data])
|
|
provisioned_memory_percentage = provisioned_memory / total_memory * 100
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_memory_provisioned_utilization PVC cluster provisioned memory utilization percentage (n-1)"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_memory_provisioned_utilization gauge")
|
|
output_lines.append(
|
|
f"pvc_cluster_memory_provisioned_utilization {provisioned_memory_percentage:2.2f}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_cluster_disk_utilization PVC cluster disk utilization percentage (n-2)"
|
|
)
|
|
output_lines.append("# TYPE pvc_cluster_disk_utilization gauge")
|
|
# Do it manually rather than a sum() in case one OSD is not fully up yet
|
|
total_disk = 0
|
|
used_disk = 0
|
|
for osd in osd_data:
|
|
try:
|
|
total_disk += osd["stats"]["kb"]
|
|
used_disk += osd["stats"]["kb_used"]
|
|
except Exception:
|
|
continue
|
|
used_disk_percentage = used_disk / total_disk * 100
|
|
output_lines.append(f"pvc_cluster_disk_utilization {used_disk_percentage:2.2f}")
|
|
|
|
#
|
|
# Node stats
|
|
#
|
|
output_lines.append("# HELP pvc_node_host_cpus PVC node host CPU count")
|
|
output_lines.append("# TYPE pvc_node_host_cpus gauge")
|
|
for node in node_data:
|
|
total_cpus = (
|
|
node["vcpu"]["total"]
|
|
if isinstance(node["vcpu"]["total"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_host_cpus{{node=\"{node['name']}\"}} {total_cpus}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_allocated_vcpus PVC node allocated vCPU count")
|
|
output_lines.append("# TYPE pvc_node_allocated_vcpus gauge")
|
|
for node in node_data:
|
|
allocated_cpus = (
|
|
node["vcpu"]["allocated"]
|
|
if isinstance(node["vcpu"]["allocated"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_allocated_vcpus{{node=\"{node['name']}\"}} {allocated_cpus}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_load PVC node 1 minute load average")
|
|
output_lines.append("# TYPE pvc_node_load gauge")
|
|
for node in node_data:
|
|
load_average = node["load"] if isinstance(node["load"], (int, float)) else 0.0
|
|
output_lines.append(
|
|
f"pvc_node_load_average{{node=\"{node['name']}\"}} {load_average}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_cpu_utilization PVC node CPU utilization")
|
|
output_lines.append("# TYPE pvc_node_cpu_utilization gauge")
|
|
for node in node_data:
|
|
load_average = node["load"] if isinstance(node["load"], (int, float)) else 0.0
|
|
cpu_count = (
|
|
node["cpu_count"] if isinstance(node["cpu_count"], (int, float)) else 0
|
|
)
|
|
if cpu_count > 0:
|
|
used_cpu_percentage = load_average / cpu_count * 100
|
|
else:
|
|
used_cpu_percentage = 0.0
|
|
output_lines.append(
|
|
f"pvc_node_cpu_utilization{{node=\"{node['name']}\"}} {used_cpu_percentage:2.2f}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_domains_count PVC node running domain count")
|
|
output_lines.append("# TYPE pvc_node_domains_count gauge")
|
|
for node in node_data:
|
|
running_domains_count = (
|
|
node["domains_count"]
|
|
if isinstance(node["domains_count"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_domains_count{{node=\"{node['name']}\"}} {running_domains_count}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_architecture PVC node system architecture")
|
|
output_lines.append("# TYPE pvc_node_architecture gauge")
|
|
for node in node_data:
|
|
architecture = node["arch"]
|
|
output_lines.append(
|
|
f"pvc_node_architecture{{node=\"{node['name']}\",architecture=\"{architecture}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_kernel PVC node active kernel version")
|
|
output_lines.append("# TYPE pvc_node_kernel gauge")
|
|
for node in node_data:
|
|
kernel = node["kernel"]
|
|
output_lines.append(
|
|
f"pvc_node_kernel{{node=\"{node['name']}\",kernel=\"{kernel}\"}} 1"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_network_traffic_rx PVC node received network traffic"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_network_traffic_rx gauge")
|
|
for node in node_data:
|
|
rx_bps = 0
|
|
for interface in node["interfaces"].keys():
|
|
rx_bps += node["interfaces"][interface]["rx_bps"]
|
|
output_lines.append(
|
|
f"pvc_node_network_traffic_rx{{node=\"{node['name']}\"}} {rx_bps:2.2f}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_network_traffic_tx PVC node transmitted network traffic"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_network_traffic_tx gauge")
|
|
for node in node_data:
|
|
tx_bps = 0
|
|
for interface in node["interfaces"].keys():
|
|
tx_bps += node["interfaces"][interface]["tx_bps"]
|
|
output_lines.append(
|
|
f"pvc_node_network_traffic_tx{{node=\"{node['name']}\"}} {tx_bps:2.2f}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_network_packets_rx PVC node received network packets"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_network_packets_rx gauge")
|
|
for node in node_data:
|
|
rx_pps = 0
|
|
for interface in node["interfaces"].keys():
|
|
rx_pps += node["interfaces"][interface]["rx_pps"]
|
|
output_lines.append(
|
|
f"pvc_node_network_packets_rx{{node=\"{node['name']}\"}} {rx_pps:2.2f}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_network_packets_tx PVC node transmitted network packets"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_network_packets_tx gauge")
|
|
for node in node_data:
|
|
tx_pps = 0
|
|
for interface in node["interfaces"].keys():
|
|
tx_pps += node["interfaces"][interface]["tx_pps"]
|
|
output_lines.append(
|
|
f"pvc_node_network_packets_tx{{node=\"{node['name']}\"}} {tx_pps:2.2f}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_network_utilization PVC node network utilization percentage"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_network_utilization gauge")
|
|
for node in node_data:
|
|
used_network_percentage = per_node_network_utilization.get(node["name"], 0)
|
|
output_lines.append(
|
|
f"pvc_node_network_utilization{{node=\"{node['name']}\"}} {used_network_percentage:2.2f}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_total_memory PVC node total memory in MB")
|
|
output_lines.append("# TYPE pvc_node_total_memory gauge")
|
|
for node in node_data:
|
|
total_memory = (
|
|
node["memory"]["total"]
|
|
if isinstance(node["memory"]["total"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_total_memory{{node=\"{node['name']}\"}} {total_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_allocated_memory PVC node allocated memory in MB"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_allocated_memory gauge")
|
|
for node in node_data:
|
|
allocated_memory = (
|
|
node["memory"]["allocated"]
|
|
if isinstance(node["memory"]["allocated"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_allocated_memory{{node=\"{node['name']}\"}} {allocated_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_allocated_memory_utilization PVC node allocated memory utilization"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_allocated_memory_utilization gauge")
|
|
for node in node_data:
|
|
allocated_memory = (
|
|
node["memory"]["allocated"]
|
|
if isinstance(node["memory"]["allocated"], (int, float))
|
|
else 0
|
|
)
|
|
total_memory = (
|
|
node["memory"]["total"]
|
|
if isinstance(node["memory"]["total"], (int, float))
|
|
else 0
|
|
)
|
|
allocated_memory_utilization = (
|
|
(allocated_memory / total_memory * 100) if total_memory > 0 else 0.0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_allocated_memory_utilization{{node=\"{node['name']}\"}} {allocated_memory_utilization}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_provisioned_memory PVC node provisioned memory in MB"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_provisioned_memory gauge")
|
|
for node in node_data:
|
|
provisioned_memory = (
|
|
node["memory"]["provisioned"]
|
|
if isinstance(node["memory"]["provisioned"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_provisioned_memory{{node=\"{node['name']}\"}} {provisioned_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_provisioned_memory_utilization PVC node provisioned memory utilization"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_provisioned_memory_utilization gauge")
|
|
for node in node_data:
|
|
provisioned_memory = (
|
|
node["memory"]["provisioned"]
|
|
if isinstance(node["memory"]["provisioned"], (int, float))
|
|
else 0
|
|
)
|
|
total_memory = (
|
|
node["memory"]["total"]
|
|
if isinstance(node["memory"]["total"], (int, float))
|
|
else 0
|
|
)
|
|
provisioned_memory_utilization = (
|
|
(provisioned_memory / total_memory * 100) if total_memory > 0 else 0.0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_provisioned_memory_utilization{{node=\"{node['name']}\"}} {provisioned_memory_utilization}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_used_memory PVC node used memory in MB")
|
|
output_lines.append("# TYPE pvc_node_used_memory gauge")
|
|
for node in node_data:
|
|
used_memory = (
|
|
node["memory"]["used"]
|
|
if isinstance(node["memory"]["used"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_used_memory{{node=\"{node['name']}\"}} {used_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_node_used_memory_utilization PVC node used memory utilization"
|
|
)
|
|
output_lines.append("# TYPE pvc_node_used_memory_utilization gauge")
|
|
for node in node_data:
|
|
used_memory = (
|
|
node["memory"]["used"]
|
|
if isinstance(node["memory"]["used"], (int, float))
|
|
else 0
|
|
)
|
|
total_memory = (
|
|
node["memory"]["total"]
|
|
if isinstance(node["memory"]["total"], (int, float))
|
|
else 0
|
|
)
|
|
used_memory_utilization = (
|
|
(used_memory / total_memory * 100) if total_memory > 0 else 0.0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_used_memory_utilization{{node=\"{node['name']}\"}} {used_memory_utilization}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_node_free_memory PVC node free memory in MB")
|
|
output_lines.append("# TYPE pvc_node_free_memory gauge")
|
|
for node in node_data:
|
|
free_memory = (
|
|
node["memory"]["free"]
|
|
if isinstance(node["memory"]["free"], (int, float))
|
|
else 0
|
|
)
|
|
output_lines.append(
|
|
f"pvc_node_free_memory{{node=\"{node['name']}\"}} {free_memory}"
|
|
)
|
|
|
|
#
|
|
# VM stats
|
|
#
|
|
output_lines.append("# HELP pvc_vm_active_node PVC VM active node")
|
|
output_lines.append("# TYPE pvc_vm_active_node gauge")
|
|
for vm in vm_data:
|
|
active_node = vm["node"]
|
|
output_lines.append(
|
|
f"pvc_vm_active_node{{vm=\"{vm['name']}\", node=\"{active_node}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_machine_type PVC VM machine type")
|
|
output_lines.append("# TYPE pvc_vm_machine_type gauge")
|
|
for vm in vm_data:
|
|
machine_type = vm["machine"]
|
|
output_lines.append(
|
|
f"pvc_vm_machine_type{{vm=\"{vm['name']}\", node=\"{machine_type}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_serial_console PVC VM serial console")
|
|
output_lines.append("# TYPE pvc_vm_serial_console gauge")
|
|
for vm in vm_data:
|
|
output_lines.append(
|
|
f"pvc_vm_serial_console{{vm=\"{vm['name']}\"}} {1 if vm.get('console', '') == 'pty' else 0}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_vnc_console PVC VM VNC console")
|
|
output_lines.append("# TYPE pvc_vm_vnc_console gauge")
|
|
for vm in vm_data:
|
|
output_lines.append(
|
|
f"pvc_vm_vnc_console{{vm=\"{vm['name']}\"}} {1 if vm['vnc'].get('listen', '') == 'pty' else 0}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_vnc_listen_address PVC VM VNC listen address")
|
|
output_lines.append("# TYPE pvc_vm_vnc_listen_address gauge")
|
|
for vm in vm_data:
|
|
vnc_listen_address = vm["vnc"]["listen"]
|
|
output_lines.append(
|
|
f"pvc_vm_vnc_listen_address{{vm=\"{vm['name']}\", address=\"{vnc_listen_address}\"}} {1 if vnc_listen_address is not None else 0}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_vnc_listen_port PVC VM VNC listen port")
|
|
output_lines.append("# TYPE pvc_vm_vnc_listen_port gauge")
|
|
for vm in vm_data:
|
|
vnc_listen_port = vm["vnc"]["port"]
|
|
output_lines.append(
|
|
f"pvc_vm_vnc_listen_port{{vm=\"{vm['name']}\", port=\"{vnc_listen_port}\"}} {1 if vnc_listen_port is not None else 0}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_vcpus PVC VM provisioned vCPUs")
|
|
output_lines.append("# TYPE pvc_vm_vcpus gauge")
|
|
for vm in vm_data:
|
|
vcpus = vm["vcpu"]
|
|
output_lines.append(f"pvc_vm_vcpus{{vm=\"{vm['name']}\"}} {vcpus}")
|
|
|
|
output_lines.append("# HELP pvc_vm_vcpus_cpu_time PVC VM vCPU CPU time")
|
|
output_lines.append("# TYPE pvc_vm_vcpus_cpu_time gauge")
|
|
for vm in vm_data:
|
|
cpu_time = vm["vcpu_stats"]["cpu_time"]
|
|
output_lines.append(f"pvc_vm_vcpus_cpu_time{{vm=\"{vm['name']}\"}} {cpu_time}")
|
|
|
|
output_lines.append("# HELP pvc_vm_vcpus_user_time PVC VM vCPU User time")
|
|
output_lines.append("# TYPE pvc_vm_vcpus_user_time gauge")
|
|
for vm in vm_data:
|
|
user_time = vm["vcpu_stats"]["user_time"]
|
|
output_lines.append(
|
|
f"pvc_vm_vcpus_user_time{{vm=\"{vm['name']}\"}} {user_time}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_vcpus_system_time PVC VM vCPU System time")
|
|
output_lines.append("# TYPE pvc_vm_vcpus_system_time gauge")
|
|
for vm in vm_data:
|
|
system_time = vm["vcpu_stats"]["system_time"]
|
|
output_lines.append(
|
|
f"pvc_vm_vcpus_system_time{{vm=\"{vm['name']}\"}} {system_time}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory PVC VM provisioned memory MB")
|
|
output_lines.append("# TYPE pvc_vm_memory gauge")
|
|
for vm in vm_data:
|
|
memory = vm["memory"]
|
|
output_lines.append(f"pvc_vm_memory{{vm=\"{vm['name']}\"}} {memory}")
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_vm_memory_stats_actual PVC VM actual memory allocation"
|
|
)
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_actual gauge")
|
|
for vm in vm_data:
|
|
actual_memory = vm["memory_stats"]["actual"]
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_actual{{vm=\"{vm['name']}\"}} {actual_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_stats_rss PVC VM RSS memory")
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_rss gauge")
|
|
for vm in vm_data:
|
|
rss_memory = vm["memory_stats"]["rss"]
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_rss{{vm=\"{vm['name']}\"}} {rss_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_stats_unused PVC VM unused memory")
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_unused gauge")
|
|
for vm in vm_data:
|
|
unused_memory = vm["memory_stats"].get("unused", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_unused{{vm=\"{vm['name']}\"}} {unused_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_stats_available PVC VM available memory")
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_available gauge")
|
|
for vm in vm_data:
|
|
available_memory = vm["memory_stats"].get("available", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_available{{vm=\"{vm['name']}\"}} {available_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_stats_usable PVC VM usable memory")
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_usable gauge")
|
|
for vm in vm_data:
|
|
usable_memory = vm["memory_stats"].get("usable", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_usable{{vm=\"{vm['name']}\"}} {usable_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_vm_memory_stats_disk_caches PVC VM disk cache memory"
|
|
)
|
|
output_lines.append("# TYPE pvc_vm_memory_stats_disk_caches gauge")
|
|
for vm in vm_data:
|
|
disk_caches_memory = vm["memory_stats"].get("disk_caches", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_disk_caches{{vm=\"{vm['name']}\"}} {disk_caches_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_swap_in PVC VM memory swap in")
|
|
output_lines.append("# TYPE pvc_vm_memory_swap_in gauge")
|
|
for vm in vm_data:
|
|
swap_in_memory = vm["memory_stats"].get("swap_in", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_swap_in{{vm=\"{vm['name']}\"}} {swap_in_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_swap_out PVC VM memory swap out")
|
|
output_lines.append("# TYPE pvc_vm_memory_swap_out gauge")
|
|
for vm in vm_data:
|
|
swap_out_memory = vm["memory_stats"].get("swap_out", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_swap_out{{vm=\"{vm['name']}\"}} {swap_out_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_major_fault PVC VM memory major faults")
|
|
output_lines.append("# TYPE pvc_vm_memory_major_fault gauge")
|
|
for vm in vm_data:
|
|
major_fault_memory = vm["memory_stats"].get("major_fault", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_major_fault{{vm=\"{vm['name']}\"}} {major_fault_memory}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_memory_minor_fault PVC VM memory minor faults")
|
|
output_lines.append("# TYPE pvc_vm_memory_minor_fault gauge")
|
|
for vm in vm_data:
|
|
minor_fault_memory = vm["memory_stats"].get("minor_fault", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_minor_fault{{vm=\"{vm['name']}\"}} {minor_fault_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_vm_memory_hugetlb_pgalloc PVC VM memory huge table allocations"
|
|
)
|
|
output_lines.append("# TYPE pvc_vm_memory_hugetlb_pgalloc gauge")
|
|
for vm in vm_data:
|
|
hugetlb_pgalloc_memory = vm["memory_stats"].get("hugetlb_pgalloc", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_hugetlb_pgalloc{{vm=\"{vm['name']}\"}} {hugetlb_pgalloc_memory}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_vm_memory_hugetlb_pgfail PVC VM memory huge table failures"
|
|
)
|
|
output_lines.append("# TYPE pvc_vm_memory_hugetlb_pgfail gauge")
|
|
for vm in vm_data:
|
|
hugetlb_pgfail_memory = vm["memory_stats"].get("hugetlb_pgfail", 0)
|
|
output_lines.append(
|
|
f"pvc_vm_memory_stats_hugetlb_pgfail{{vm=\"{vm['name']}\"}} {hugetlb_pgfail_memory}"
|
|
)
|
|
|
|
#
|
|
# VM Network stats
|
|
#
|
|
output_lines.append("# HELP pvc_vm_network_macaddr PVC VM network MAC address")
|
|
output_lines.append("# TYPE pvc_vm_network_macaddr gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
mac_address = network["mac"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_macaddr{{vm=\"{vm['name']}\",vni=\"{vni}\",macaddr=\"{mac_address}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_model PVC VM network device model")
|
|
output_lines.append("# TYPE pvc_vm_network_model gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
model = network["model"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_model{{vm=\"{vm['name']}\",vni=\"{vni}\",model=\"{model}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_rd_packets PVC VM network packets read")
|
|
output_lines.append("# TYPE pvc_vm_network_rd_packets gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
rd_packets = network["rd_packets"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_rd_packets{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {rd_packets}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_rd_bytes PVC VM network bytes read")
|
|
output_lines.append("# TYPE pvc_vm_network_rd_bytes gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
rd_bytes = network["rd_bytes"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_rd_bytes{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {rd_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_rd_errors PVC VM network read errors")
|
|
output_lines.append("# TYPE pvc_vm_network_rd_errors gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
rd_errors = network["rd_errors"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_rd_errors{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {rd_errors}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_rd_drops PVC VM network read drops")
|
|
output_lines.append("# TYPE pvc_vm_network_rd_drops gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
rd_drops = network["rd_drops"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_rd_drops{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {rd_drops}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_wr_packets PVC VM network packets write")
|
|
output_lines.append("# TYPE pvc_vm_network_wr_packets gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
wr_packets = network["wr_packets"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_wr_packets{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {wr_packets}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_wr_bytes PVC VM network bytes write")
|
|
output_lines.append("# TYPE pvc_vm_network_wr_bytes gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
wr_bytes = network["wr_bytes"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_wr_bytes{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {wr_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_wr_errors PVC VM network write errors")
|
|
output_lines.append("# TYPE pvc_vm_network_wr_errors gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
wr_errors = network["wr_errors"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_wr_errors{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {wr_errors}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_network_wr_drops PVC VM network write drops")
|
|
output_lines.append("# TYPE pvc_vm_network_wr_drops gauge")
|
|
for vm in vm_data:
|
|
for network in vm["networks"]:
|
|
vni = network["vni"]
|
|
wr_drops = network["wr_drops"]
|
|
output_lines.append(
|
|
f"pvc_vm_network_wr_drops{{vm=\"{vm['name']}\",vni=\"{vni}\"}} {wr_drops}"
|
|
)
|
|
|
|
#
|
|
# VM Disk stats
|
|
#
|
|
output_lines.append("# HELP pvc_vm_disk_rd_req PVC VM disk read requests")
|
|
output_lines.append("# TYPE pvc_vm_disk_rd_req gauge")
|
|
for vm in vm_data:
|
|
for disk in vm["disks"]:
|
|
dev = disk["dev"]
|
|
rd_req = disk["rd_req"]
|
|
output_lines.append(
|
|
f"pvc_vm_disk_rd_req{{vm=\"{vm['name']}\",disk=\"{dev}\"}} {rd_req}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_disk_rd_bytes PVC VM disk bytes read")
|
|
output_lines.append("# TYPE pvc_vm_disk_rd_bytes gauge")
|
|
for vm in vm_data:
|
|
for disk in vm["disks"]:
|
|
dev = disk["dev"]
|
|
rd_bytes = disk["rd_bytes"]
|
|
output_lines.append(
|
|
f"pvc_vm_disk_rd_bytes{{vm=\"{vm['name']}\",disk=\"{dev}\"}} {rd_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_disk_wr_req PVC VM disk write requests")
|
|
output_lines.append("# TYPE pvc_vm_disk_wr_req gauge")
|
|
for vm in vm_data:
|
|
for disk in vm["disks"]:
|
|
dev = disk["dev"]
|
|
wr_req = disk["wr_req"]
|
|
output_lines.append(
|
|
f"pvc_vm_disk_wr_req{{vm=\"{vm['name']}\",disk=\"{dev}\"}} {wr_req}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_vm_disk_wr_bytes PVC VM disk bytes write")
|
|
output_lines.append("# TYPE pvc_vm_disk_wr_bytes gauge")
|
|
for vm in vm_data:
|
|
for disk in vm["disks"]:
|
|
dev = disk["dev"]
|
|
wr_bytes = disk["wr_bytes"]
|
|
output_lines.append(
|
|
f"pvc_vm_disk_wr_bytes{{vm=\"{vm['name']}\",disk=\"{dev}\"}} {wr_bytes}"
|
|
)
|
|
|
|
#
|
|
# Ceph OSD stats
|
|
#
|
|
output_lines.append("# HELP pvc_ceph_osd_device PVC OSD device (host + blockdev)")
|
|
output_lines.append("# TYPE pvc_ceph_osd_device gauge")
|
|
for osd in osd_data:
|
|
osd_node = osd["node"]
|
|
osd_blockdev = osd["device"]
|
|
osd_device = f"{osd_node}:{osd_blockdev}"
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_device{{osd=\"{osd['id']}\",device=\"{osd_device}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_db_device PVC OSD database device")
|
|
output_lines.append("# TYPE pvc_ceph_osd_db_device gauge")
|
|
for osd in osd_data:
|
|
osd_db_device = osd["db_device"]
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_db_device{{osd=\"{osd['id']}\",db_device=\"{osd_db_device}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_device_class PVC OSD device class")
|
|
output_lines.append("# TYPE pvc_ceph_osd_device_class gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_device_class = osd["stats"]["class"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_device_class{{osd=\"{osd['id']}\",device_class=\"{osd_device_class}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_util PVC OSD utilization percentage")
|
|
output_lines.append("# TYPE pvc_ceph_osd_util gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_util = osd["stats"]["utilization"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_util{{osd=\"{osd['id']}\"}} {osd_util}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_var PVC OSD utilization variability")
|
|
output_lines.append("# TYPE pvc_ceph_osd_var gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_var = osd["stats"]["var"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_var{{osd=\"{osd['id']}\"}} {osd_var}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_pgs PVC OSD placement groups")
|
|
output_lines.append("# TYPE pvc_ceph_osd_pgs gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_pgs = osd["stats"]["pgs"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_pgs{{osd=\"{osd['id']}\"}} {osd_pgs}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_size PVC OSD size KB")
|
|
output_lines.append("# TYPE pvc_ceph_osd_size gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_size = osd["stats"]["kb"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_size{{osd=\"{osd['id']}\"}} {osd_size}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_used PVC OSD used bytes")
|
|
output_lines.append("# TYPE pvc_ceph_osd_used gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_used = osd["stats"]["kb_used"] * 1024
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_used{{osd=\"{osd['id']}\"}} {osd_used}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_used_data PVC OSD used (data) bytes")
|
|
output_lines.append("# TYPE pvc_ceph_osd_used_data gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_used_data = osd["stats"]["kb_used_data"] * 1024
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_used_data{{osd=\"{osd['id']}\"}} {osd_used_data}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_used_omap PVC OSD used (omap) bytes")
|
|
output_lines.append("# TYPE pvc_ceph_osd_used_omap gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_used_omap = osd["stats"]["kb_used_omap"] * 1024
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_used_omap{{osd=\"{osd['id']}\"}} {osd_used_omap}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_used_meta PVC OSD used (meta) bytes")
|
|
output_lines.append("# TYPE pvc_ceph_osd_used_meta gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_used_meta = osd["stats"]["kb_used_meta"] * 1024
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_used_meta{{osd=\"{osd['id']}\"}} {osd_used_meta}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_avail PVC OSD available bytes")
|
|
output_lines.append("# TYPE pvc_ceph_osd_avail gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_avail = osd["stats"]["kb_avail"] * 1024
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_avail{{osd=\"{osd['id']}\"}} {osd_avail}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_weight PVC OSD weight")
|
|
output_lines.append("# TYPE pvc_ceph_osd_weight gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_weight = osd["stats"]["weight"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_weight{{osd=\"{osd['id']}\"}} {osd_weight}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_reweight PVC OSD reweight")
|
|
output_lines.append("# TYPE pvc_ceph_osd_reweight gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_reweight = osd["stats"]["reweight"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_reweight{{osd=\"{osd['id']}\"}} {osd_reweight}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_osd_wr_ops PVC OSD write operations per second"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_osd_wr_ops gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_wr_ops = osd["stats"]["wr_ops"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_wr_ops{{osd=\"{osd['id']}\"}} {osd_wr_ops}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_wr_data PVC OSD write bytes per second")
|
|
output_lines.append("# TYPE pvc_ceph_osd_wr_data gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_wr_data = pvc_ceph.format_bytes_fromhuman(osd["stats"]["wr_data"])
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_wr_data{{osd=\"{osd['id']}\"}} {osd_wr_data}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_rd_ops PVC OSD read operations per second")
|
|
output_lines.append("# TYPE pvc_ceph_osd_rd_ops gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_rd_ops = osd["stats"]["rd_ops"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(f"pvc_ceph_osd_rd_ops{{osd=\"{osd['id']}\"}} {osd_rd_ops}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_osd_rd_data PVC OSD read bytes per second")
|
|
output_lines.append("# TYPE pvc_ceph_osd_rd_data gauge")
|
|
for osd in osd_data:
|
|
try:
|
|
osd_rd_data = pvc_ceph.format_bytes_fromhuman(osd["stats"]["rd_data"])
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_osd_rd_data{{osd=\"{osd['id']}\"}} {osd_rd_data}"
|
|
)
|
|
|
|
#
|
|
# Ceph Pool stats
|
|
#
|
|
output_lines.append("# HELP pvc_ceph_pool_tier PVC Pool tier")
|
|
output_lines.append("# TYPE pvc_ceph_pool_tier gauge")
|
|
for pool in pool_data:
|
|
pool_tier = pool["tier"]
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_tier{{pool=\"{pool['name']}\",tier=\"{pool_tier}\"}} 1"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_pgs PVC Pool placement groups")
|
|
output_lines.append("# TYPE pvc_ceph_pool_pgs gauge")
|
|
for pool in pool_data:
|
|
pool_pgs = pool["pgs"]
|
|
output_lines.append(f"pvc_ceph_pool_pgs{{pool=\"{pool['name']}\"}} {pool_pgs}")
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_volumes PVC Pool volumes count")
|
|
output_lines.append("# TYPE pvc_ceph_pool_volumes gauge")
|
|
for pool in pool_data:
|
|
pool_volumes = pool["volume_count"]
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_volumes{{pool=\"{pool['name']}\"}} {pool_volumes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_stored_bytes PVC Pool stored bytes")
|
|
output_lines.append("# TYPE pvc_ceph_pool_stored_bytes gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_stored_bytes = pool["stats"]["stored_bytes"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_stored_bytes{{pool=\"{pool['name']}\"}} {pool_stored_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_free_bytes PVC Pool free bytes")
|
|
output_lines.append("# TYPE pvc_ceph_pool_free_bytes gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_free_bytes = pool["stats"]["free_bytes"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_free_bytes{{pool=\"{pool['name']}\"}} {pool_free_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_used_bytes PVC Pool used bytes")
|
|
output_lines.append("# TYPE pvc_ceph_pool_used_bytes gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_used_bytes = pool["stats"]["used_bytes"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_used_bytes{{pool=\"{pool['name']}\"}} {pool_used_bytes}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_used_percent PVC Pool used percent")
|
|
output_lines.append("# TYPE pvc_ceph_pool_used_percent gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_used_percent = pool["stats"]["used_percent"] * 100
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_used_percent{{pool=\"{pool['name']}\"}} {pool_used_percent:2.2f}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_num_objects PVC Pool total objects")
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects = pool["stats"]["num_objects"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects{{pool=\"{pool['name']}\"}} {pool_num_objects}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_num_objects_clones PVC Pool clone objects"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects_clones gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects_clones = pool["stats"]["num_object_clones"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects_clones{{pool=\"{pool['name']}\"}} {pool_num_objects_clones}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_num_objects_copies PVC Pool object copies"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects_copies gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects_copies = pool["stats"]["num_object_copies"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects_copies{{pool=\"{pool['name']}\"}} {pool_num_objects_copies}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_num_objects_missing_on_primary PVC Pool objects missing on primary"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects_missing_on_primary gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects_missing_on_primary = pool["stats"][
|
|
"num_objects_missing_on_primary"
|
|
]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects_missing_on_primary{{pool=\"{pool['name']}\"}} {pool_num_objects_missing_on_primary}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_num_objects_unfound PVC Pool objects unfound"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects_unfound gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects_unfound = pool["stats"]["num_objects_unfound"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects_unfound{{pool=\"{pool['name']}\"}} {pool_num_objects_unfound}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_num_objects_degraded PVC Pool objects degraded"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_num_objects_degraded gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_num_objects_degraded = pool["stats"]["num_objects_degraded"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_num_objects_degraded{{pool=\"{pool['name']}\"}} {pool_num_objects_degraded}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_read_ops PVC Pool read operations lifetime"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_read_ops gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_read_ops = pool["stats"]["read_ops"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_read_ops{{pool=\"{pool['name']}\"}} {pool_read_ops}"
|
|
)
|
|
|
|
output_lines.append("# HELP pvc_ceph_pool_read_bytes PVC Pool read bytes lifetime")
|
|
output_lines.append("# TYPE pvc_ceph_pool_read_bytes gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_read_bytes = pool["stats"]["read_bytes"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_read_bytes{{pool=\"{pool['name']}\"}} {pool_read_bytes}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_write_ops PVC Pool write operations lifetime"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_write_ops gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_write_ops = pool["stats"]["write_ops"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_write_ops{{pool=\"{pool['name']}\"}} {pool_write_ops}"
|
|
)
|
|
|
|
output_lines.append(
|
|
"# HELP pvc_ceph_pool_write_bytes PVC Pool write bytes lifetime"
|
|
)
|
|
output_lines.append("# TYPE pvc_ceph_pool_write_bytes gauge")
|
|
for pool in pool_data:
|
|
try:
|
|
pool_write_bytes = pool["stats"]["write_bytes"]
|
|
except Exception:
|
|
continue
|
|
output_lines.append(
|
|
f"pvc_ceph_pool_write_bytes{{pool=\"{pool['name']}\"}} {pool_write_bytes}"
|
|
)
|
|
|
|
return True, "\n".join(output_lines) + "\n"
|
|
|
|
|
|
def cluster_initialize(zkhandler, overwrite=False):
|
|
# Abort if we've initialized the cluster before
|
|
if zkhandler.exists("base.config.primary_node") and not overwrite:
|
|
return False, "ERROR: Cluster contains data and overwrite not set."
|
|
|
|
if overwrite:
|
|
# Delete the existing keys
|
|
for key in zkhandler.schema.keys("base"):
|
|
if key == "root":
|
|
# Don't delete the root key
|
|
continue
|
|
|
|
status = zkhandler.delete("base.{}".format(key), recursive=True)
|
|
if not status:
|
|
return (
|
|
False,
|
|
"ERROR: Failed to delete data in cluster; running nodes perhaps?",
|
|
)
|
|
|
|
# Create the root keys
|
|
zkhandler.schema.apply(zkhandler)
|
|
|
|
return True, "Successfully initialized cluster"
|
|
|
|
|
|
def cluster_backup(zkhandler):
|
|
# Dictionary of values to come
|
|
cluster_data = dict()
|
|
|
|
def get_data(path):
|
|
data = zkhandler.read(path)
|
|
children = zkhandler.children(path)
|
|
|
|
cluster_data[path] = data
|
|
|
|
if children:
|
|
if path == "/":
|
|
child_prefix = "/"
|
|
else:
|
|
child_prefix = path + "/"
|
|
|
|
for child in children:
|
|
if child_prefix + child == "/zookeeper":
|
|
# We must skip the built-in /zookeeper tree
|
|
continue
|
|
if child_prefix + child == "/patroni":
|
|
# We must skip the /patroni tree
|
|
continue
|
|
|
|
get_data(child_prefix + child)
|
|
|
|
try:
|
|
get_data("/")
|
|
except Exception as e:
|
|
return False, "ERROR: Failed to obtain backup: {}".format(e)
|
|
|
|
return True, cluster_data
|
|
|
|
|
|
def cluster_restore(zkhandler, cluster_data):
|
|
# Build a key+value list
|
|
kv = []
|
|
schema_version = None
|
|
for key in cluster_data:
|
|
if key == zkhandler.schema.path("base.schema.version"):
|
|
schema_version = cluster_data[key]
|
|
data = cluster_data[key]
|
|
kv.append((key, data))
|
|
|
|
if int(schema_version) != int(zkhandler.schema.version):
|
|
return (
|
|
False,
|
|
"ERROR: Schema version of backup ({}) does not match cluster schema version ({}).".format(
|
|
schema_version, zkhandler.schema.version
|
|
),
|
|
)
|
|
|
|
# Close the Zookeeper connection
|
|
result = zkhandler.write(kv)
|
|
|
|
if result:
|
|
return True, "Restore completed successfully."
|
|
else:
|
|
return False, "Restore failed."
|