open-nomad/command/node_status.go

925 lines
25 KiB
Go

package command
import (
"fmt"
"math"
"sort"
"strconv"
"strings"
"time"
humanize "github.com/dustin/go-humanize"
"github.com/hashicorp/nomad/api"
"github.com/hashicorp/nomad/api/contexts"
"github.com/hashicorp/nomad/helper"
"github.com/posener/complete"
)
const (
// floatFormat is a format string for formatting floats.
floatFormat = "#,###.##"
// bytesPerMegabyte is the number of bytes per MB
bytesPerMegabyte = 1024 * 1024
)
type NodeStatusCommand struct {
Meta
length int
short bool
verbose bool
list_allocs bool
self bool
stats bool
json bool
tmpl string
}
func (c *NodeStatusCommand) Help() string {
helpText := `
Usage: nomad node status [options] <node>
Display status information about a given node. The list of nodes
returned includes only nodes which jobs may be scheduled to, and
includes status and other high-level information.
If a node ID is passed, information for that specific node will be displayed,
including resource usage statistics. If no node ID's are passed, then a
short-hand list of all nodes will be displayed. The -self flag is useful to
quickly access the status of the local node.
General Options:
` + generalOptionsUsage() + `
Node Status Options:
-self
Query the status of the local node.
-stats
Display detailed resource usage statistics.
-allocs
Display a count of running allocations for each node.
-short
Display short output. Used only when a single node is being
queried, and drops verbose output about node allocations.
-verbose
Display full information.
-json
Output the node in its JSON format.
-t
Format and display node using a Go template.
`
return strings.TrimSpace(helpText)
}
func (c *NodeStatusCommand) Synopsis() string {
return "Display status information about nodes"
}
func (c *NodeStatusCommand) AutocompleteFlags() complete.Flags {
return mergeAutocompleteFlags(c.Meta.AutocompleteFlags(FlagSetClient),
complete.Flags{
"-allocs": complete.PredictNothing,
"-json": complete.PredictNothing,
"-self": complete.PredictNothing,
"-short": complete.PredictNothing,
"-stats": complete.PredictNothing,
"-t": complete.PredictAnything,
"-verbose": complete.PredictNothing,
})
}
func (c *NodeStatusCommand) AutocompleteArgs() complete.Predictor {
return complete.PredictFunc(func(a complete.Args) []string {
client, err := c.Meta.Client()
if err != nil {
return nil
}
resp, _, err := client.Search().PrefixSearch(a.Last, contexts.Nodes, nil)
if err != nil {
return []string{}
}
return resp.Matches[contexts.Nodes]
})
}
func (c *NodeStatusCommand) Name() string { return "node-status" }
func (c *NodeStatusCommand) Run(args []string) int {
flags := c.Meta.FlagSet(c.Name(), FlagSetClient)
flags.Usage = func() { c.Ui.Output(c.Help()) }
flags.BoolVar(&c.short, "short", false, "")
flags.BoolVar(&c.verbose, "verbose", false, "")
flags.BoolVar(&c.list_allocs, "allocs", false, "")
flags.BoolVar(&c.self, "self", false, "")
flags.BoolVar(&c.stats, "stats", false, "")
flags.BoolVar(&c.json, "json", false, "")
flags.StringVar(&c.tmpl, "t", "", "")
if err := flags.Parse(args); err != nil {
return 1
}
// Check that we got either a single node or none
args = flags.Args()
if len(args) > 1 {
c.Ui.Error("This command takes either one or no arguments")
c.Ui.Error(commandErrorText(c))
return 1
}
// Truncate the id unless full length is requested
c.length = shortId
if c.verbose {
c.length = fullId
}
// Get the HTTP client
client, err := c.Meta.Client()
if err != nil {
c.Ui.Error(fmt.Sprintf("Error initializing client: %s", err))
return 1
}
// Use list mode if no node name was provided
if len(args) == 0 && !c.self {
// Query the node info
nodes, _, err := client.Nodes().List(nil)
if err != nil {
c.Ui.Error(fmt.Sprintf("Error querying node status: %s", err))
return 1
}
// If output format is specified, format and output the node data list
if c.json || len(c.tmpl) > 0 {
out, err := Format(c.json, c.tmpl, nodes)
if err != nil {
c.Ui.Error(err.Error())
return 1
}
c.Ui.Output(out)
return 0
}
// Return nothing if no nodes found
if len(nodes) == 0 {
return 0
}
// Format the nodes list
out := make([]string, len(nodes)+1)
out[0] = "ID|DC|Name|Class|"
if c.verbose {
out[0] += "Address|Version|"
}
out[0] += "Drain|Eligibility|Status"
if c.list_allocs {
out[0] += "|Running Allocs"
}
for i, node := range nodes {
out[i+1] = fmt.Sprintf("%s|%s|%s|%s",
limit(node.ID, c.length),
node.Datacenter,
node.Name,
node.NodeClass)
if c.verbose {
out[i+1] += fmt.Sprintf("|%s|%s",
node.Address, node.Version)
}
out[i+1] += fmt.Sprintf("|%v|%s|%s",
node.Drain,
node.SchedulingEligibility,
node.Status)
if c.list_allocs {
numAllocs, err := getRunningAllocs(client, node.ID)
if err != nil {
c.Ui.Error(fmt.Sprintf("Error querying node allocations: %s", err))
return 1
}
out[i+1] += fmt.Sprintf("|%v",
len(numAllocs))
}
}
// Dump the output
c.Ui.Output(formatList(out))
return 0
}
// Query the specific node
var nodeID string
if !c.self {
nodeID = args[0]
} else {
var err error
if nodeID, err = getLocalNodeID(client); err != nil {
c.Ui.Error(err.Error())
return 1
}
}
if len(nodeID) == 1 {
c.Ui.Error(fmt.Sprintf("Identifier must contain at least two characters."))
return 1
}
nodeID = sanitizeUUIDPrefix(nodeID)
nodes, _, err := client.Nodes().PrefixList(nodeID)
if err != nil {
c.Ui.Error(fmt.Sprintf("Error querying node info: %s", err))
return 1
}
// Return error if no nodes are found
if len(nodes) == 0 {
c.Ui.Error(fmt.Sprintf("No node(s) with prefix %q found", nodeID))
return 1
}
if len(nodes) > 1 {
// Dump the output
c.Ui.Error(fmt.Sprintf("Prefix matched multiple nodes\n\n%s",
formatNodeStubList(nodes, c.verbose)))
return 1
}
// Prefix lookup matched a single node
node, _, err := client.Nodes().Info(nodes[0].ID, nil)
if err != nil {
c.Ui.Error(fmt.Sprintf("Error querying node info: %s", err))
return 1
}
// If output format is specified, format and output the data
if c.json || len(c.tmpl) > 0 {
out, err := Format(c.json, c.tmpl, node)
if err != nil {
c.Ui.Error(err.Error())
return 1
}
c.Ui.Output(out)
return 0
}
return c.formatNode(client, node)
}
func nodeDrivers(n *api.Node) []string {
var drivers []string
for k, v := range n.Attributes {
// driver.docker = 1
parts := strings.Split(k, ".")
if len(parts) != 2 {
continue
} else if parts[0] != "driver" {
continue
} else if v != "1" {
continue
}
drivers = append(drivers, parts[1])
}
sort.Strings(drivers)
return drivers
}
func nodeCSIControllerNames(n *api.Node) []string {
var names []string
for name := range n.CSIControllerPlugins {
names = append(names, name)
}
sort.Strings(names)
return names
}
func nodeCSINodeNames(n *api.Node) []string {
var names []string
for name := range n.CSINodePlugins {
names = append(names, name)
}
sort.Strings(names)
return names
}
func nodeCSIVolumeNames(n *api.Node, allocs []*api.Allocation) []string {
var names []string
for _, alloc := range allocs {
tg := alloc.GetTaskGroup()
if tg == nil || len(tg.Volumes) == 0 {
continue
}
for _, v := range tg.Volumes {
names = append(names, v.Name)
}
}
sort.Strings(names)
return names
}
func nodeVolumeNames(n *api.Node) []string {
var volumes []string
for name := range n.HostVolumes {
volumes = append(volumes, name)
}
sort.Strings(volumes)
return volumes
}
func formatDrain(n *api.Node) string {
if n.DrainStrategy != nil {
b := new(strings.Builder)
b.WriteString("true")
if n.DrainStrategy.DrainSpec.Deadline.Nanoseconds() < 0 {
b.WriteString("; force drain")
} else if n.DrainStrategy.ForceDeadline.IsZero() {
b.WriteString("; no deadline")
} else {
fmt.Fprintf(b, "; %s deadline", formatTime(n.DrainStrategy.ForceDeadline))
}
if n.DrainStrategy.IgnoreSystemJobs {
b.WriteString("; ignoring system jobs")
}
return b.String()
}
return strconv.FormatBool(n.Drain)
}
func (c *NodeStatusCommand) formatNode(client *api.Client, node *api.Node) int {
// Make one API call for allocations
nodeAllocs, _, err := client.Nodes().Allocations(node.ID, nil)
if err != nil {
c.Ui.Error(fmt.Sprintf("Error querying node allocations: %s", err))
return 1
}
var runningAllocs []*api.Allocation
for _, alloc := range nodeAllocs {
if alloc.ClientStatus == "running" {
runningAllocs = append(runningAllocs, alloc)
}
}
// Format the header output
basic := []string{
fmt.Sprintf("ID|%s", node.ID),
fmt.Sprintf("Name|%s", node.Name),
fmt.Sprintf("Class|%s", node.NodeClass),
fmt.Sprintf("DC|%s", node.Datacenter),
fmt.Sprintf("Drain|%v", formatDrain(node)),
fmt.Sprintf("Eligibility|%s", node.SchedulingEligibility),
fmt.Sprintf("Status|%s", node.Status),
fmt.Sprintf("CSI Controllers|%s", strings.Join(nodeCSIControllerNames(node), ",")),
fmt.Sprintf("CSI Drivers|%s", strings.Join(nodeCSINodeNames(node), ",")),
}
if c.short {
basic = append(basic, fmt.Sprintf("Host Volumes|%s", strings.Join(nodeVolumeNames(node), ",")))
basic = append(basic, fmt.Sprintf("CSI Volumes|%s", strings.Join(nodeCSIVolumeNames(node, runningAllocs), ",")))
basic = append(basic, fmt.Sprintf("Drivers|%s", strings.Join(nodeDrivers(node), ",")))
c.Ui.Output(c.Colorize().Color(formatKV(basic)))
// Output alloc info
if err := c.outputAllocInfo(node, nodeAllocs); err != nil {
c.Ui.Error(fmt.Sprintf("%s", err))
return 1
}
return 0
}
// Get the host stats
hostStats, nodeStatsErr := client.Nodes().Stats(node.ID, nil)
if nodeStatsErr != nil {
c.Ui.Output("")
c.Ui.Error(fmt.Sprintf("error fetching node stats: %v", nodeStatsErr))
}
if hostStats != nil {
uptime := time.Duration(hostStats.Uptime * uint64(time.Second))
basic = append(basic, fmt.Sprintf("Uptime|%s", uptime.String()))
}
// When we're not running in verbose mode, then also include host volumes and
// driver info in the basic output
if !c.verbose {
basic = append(basic, fmt.Sprintf("Host Volumes|%s", strings.Join(nodeVolumeNames(node), ",")))
basic = append(basic, fmt.Sprintf("CSI Volumes|%s", strings.Join(nodeCSIVolumeNames(node, runningAllocs), ",")))
driverStatus := fmt.Sprintf("Driver Status| %s", c.outputTruncatedNodeDriverInfo(node))
basic = append(basic, driverStatus)
}
// Output the basic info
c.Ui.Output(c.Colorize().Color(formatKV(basic)))
// If we're running in verbose mode, include full host volume and driver info
if c.verbose {
c.outputNodeVolumeInfo(node)
c.outputNodeCSIVolumeInfo(client, node, runningAllocs)
c.outputNodeDriverInfo(node)
}
// Emit node events
c.outputNodeStatusEvents(node)
// Get list of running allocations on the node
allocatedResources := getAllocatedResources(client, runningAllocs, node)
c.Ui.Output(c.Colorize().Color("\n[bold]Allocated Resources[reset]"))
c.Ui.Output(formatList(allocatedResources))
actualResources, err := getActualResources(client, runningAllocs, node)
if err == nil {
c.Ui.Output(c.Colorize().Color("\n[bold]Allocation Resource Utilization[reset]"))
c.Ui.Output(formatList(actualResources))
}
hostResources, err := getHostResources(hostStats, node)
if err != nil {
c.Ui.Output("")
c.Ui.Error(fmt.Sprintf("error fetching node stats: %v", err))
}
if err == nil {
c.Ui.Output(c.Colorize().Color("\n[bold]Host Resource Utilization[reset]"))
c.Ui.Output(formatList(hostResources))
}
if err == nil && node.NodeResources != nil && len(node.NodeResources.Devices) > 0 {
c.Ui.Output(c.Colorize().Color("\n[bold]Device Resource Utilization[reset]"))
c.Ui.Output(formatList(getDeviceResourcesForNode(hostStats.DeviceStats, node)))
}
if hostStats != nil && c.stats {
c.Ui.Output(c.Colorize().Color("\n[bold]CPU Stats[reset]"))
c.printCpuStats(hostStats)
c.Ui.Output(c.Colorize().Color("\n[bold]Memory Stats[reset]"))
c.printMemoryStats(hostStats)
c.Ui.Output(c.Colorize().Color("\n[bold]Disk Stats[reset]"))
c.printDiskStats(hostStats)
if len(hostStats.DeviceStats) > 0 {
c.Ui.Output(c.Colorize().Color("\n[bold]Device Stats[reset]"))
printDeviceStats(c.Ui, hostStats.DeviceStats)
}
}
if err := c.outputAllocInfo(node, nodeAllocs); err != nil {
c.Ui.Error(fmt.Sprintf("%s", err))
return 1
}
return 0
}
func (c *NodeStatusCommand) outputAllocInfo(node *api.Node, nodeAllocs []*api.Allocation) error {
c.Ui.Output(c.Colorize().Color("\n[bold]Allocations[reset]"))
c.Ui.Output(formatAllocList(nodeAllocs, c.verbose, c.length))
if c.verbose {
c.formatAttributes(node)
c.formatDeviceAttributes(node)
c.formatMeta(node)
}
return nil
}
func (c *NodeStatusCommand) outputTruncatedNodeDriverInfo(node *api.Node) string {
drivers := make([]string, 0, len(node.Drivers))
for driverName, driverInfo := range node.Drivers {
if !driverInfo.Detected {
continue
}
if !driverInfo.Healthy {
drivers = append(drivers, fmt.Sprintf("%s (unhealthy)", driverName))
} else {
drivers = append(drivers, driverName)
}
}
sort.Strings(drivers)
return strings.Trim(strings.Join(drivers, ","), ", ")
}
func (c *NodeStatusCommand) outputNodeVolumeInfo(node *api.Node) {
c.Ui.Output(c.Colorize().Color("\n[bold]Host Volumes"))
names := make([]string, 0, len(node.HostVolumes))
for name := range node.HostVolumes {
names = append(names, name)
}
sort.Strings(names)
output := make([]string, 0, len(names)+1)
output = append(output, "Name|ReadOnly|Source")
for _, volName := range names {
info := node.HostVolumes[volName]
output = append(output, fmt.Sprintf("%s|%v|%s", volName, info.ReadOnly, info.Path))
}
c.Ui.Output(formatList(output))
}
func (c *NodeStatusCommand) outputNodeCSIVolumeInfo(client *api.Client, node *api.Node, runningAllocs []*api.Allocation) {
c.Ui.Output(c.Colorize().Color("\n[bold]CSI Volumes"))
// Duplicate nodeCSIVolumeNames to sort by name but also index volume names to ids
var names []string
requests := map[string]*api.VolumeRequest{}
for _, alloc := range runningAllocs {
tg := alloc.GetTaskGroup()
if tg == nil || len(tg.Volumes) == 0 {
continue
}
for _, v := range tg.Volumes {
names = append(names, v.Name)
requests[v.Source] = v
}
}
if len(names) == 0 {
return
}
sort.Strings(names)
// Fetch the volume objects with current status
// Ignore an error, all we're going to do is omit the volumes
volumes := map[string]*api.CSIVolumeListStub{}
vs, _ := client.Nodes().CSIVolumes(node.ID, nil)
for _, v := range vs {
n := requests[v.ID].Name
volumes[n] = v
}
// Output the volumes in name order
output := make([]string, 0, len(names)+1)
output = append(output, "ID|Name|Plugin ID|Schedulable|Provider|Access Mode")
for _, name := range names {
v := volumes[name]
output = append(output, fmt.Sprintf(
"%s|%s|%s|%t|%s|%s",
v.ID,
name,
v.PluginID,
v.Schedulable,
v.Provider,
v.AccessMode,
))
}
c.Ui.Output(formatList(output))
}
func (c *NodeStatusCommand) outputNodeDriverInfo(node *api.Node) {
c.Ui.Output(c.Colorize().Color("\n[bold]Drivers"))
size := len(node.Drivers)
nodeDrivers := make([]string, 0, size+1)
nodeDrivers = append(nodeDrivers, "Driver|Detected|Healthy|Message|Time")
drivers := make([]string, 0, len(node.Drivers))
for driver := range node.Drivers {
drivers = append(drivers, driver)
}
sort.Strings(drivers)
for _, driver := range drivers {
info := node.Drivers[driver]
timestamp := formatTime(info.UpdateTime)
nodeDrivers = append(nodeDrivers, fmt.Sprintf("%s|%v|%v|%s|%s", driver, info.Detected, info.Healthy, info.HealthDescription, timestamp))
}
c.Ui.Output(formatList(nodeDrivers))
}
func (c *NodeStatusCommand) outputNodeStatusEvents(node *api.Node) {
c.Ui.Output(c.Colorize().Color("\n[bold]Node Events"))
c.outputNodeEvent(node.Events)
}
func (c *NodeStatusCommand) outputNodeEvent(events []*api.NodeEvent) {
size := len(events)
nodeEvents := make([]string, size+1)
if c.verbose {
nodeEvents[0] = "Time|Subsystem|Message|Details"
} else {
nodeEvents[0] = "Time|Subsystem|Message"
}
for i, event := range events {
timestamp := formatTime(event.Timestamp)
subsystem := formatEventSubsystem(event.Subsystem, event.Details["driver"])
msg := event.Message
if c.verbose {
details := formatEventDetails(event.Details)
nodeEvents[size-i] = fmt.Sprintf("%s|%s|%s|%s", timestamp, subsystem, msg, details)
} else {
nodeEvents[size-i] = fmt.Sprintf("%s|%s|%s", timestamp, subsystem, msg)
}
}
c.Ui.Output(formatList(nodeEvents))
}
func formatEventSubsystem(subsystem, driverName string) string {
if driverName == "" {
return subsystem
}
// If this event is for a driver, append the driver name to make the message
// clearer
return fmt.Sprintf("Driver: %s", driverName)
}
func formatEventDetails(details map[string]string) string {
output := make([]string, 0, len(details))
for k, v := range details {
output = append(output, fmt.Sprintf("%s: %s", k, v))
}
return strings.Join(output, ", ")
}
func (c *NodeStatusCommand) formatAttributes(node *api.Node) {
// Print the attributes
keys := make([]string, len(node.Attributes))
for k := range node.Attributes {
keys = append(keys, k)
}
sort.Strings(keys)
var attributes []string
for _, k := range keys {
if k != "" {
attributes = append(attributes, fmt.Sprintf("%s|%s", k, node.Attributes[k]))
}
}
c.Ui.Output(c.Colorize().Color("\n[bold]Attributes[reset]"))
c.Ui.Output(formatKV(attributes))
}
func (c *NodeStatusCommand) formatDeviceAttributes(node *api.Node) {
if node.NodeResources == nil {
return
}
devices := node.NodeResources.Devices
if len(devices) == 0 {
return
}
sort.Slice(devices, func(i, j int) bool {
return devices[i].ID() < devices[j].ID()
})
first := true
for _, d := range devices {
if len(d.Attributes) == 0 {
continue
}
if first {
c.Ui.Output("\nDevice Group Attributes")
first = false
} else {
c.Ui.Output("")
}
c.Ui.Output(formatKV(getDeviceAttributes(d)))
}
}
func (c *NodeStatusCommand) formatMeta(node *api.Node) {
// Print the meta
keys := make([]string, 0, len(node.Meta))
for k := range node.Meta {
keys = append(keys, k)
}
sort.Strings(keys)
var meta []string
for _, k := range keys {
if k != "" {
meta = append(meta, fmt.Sprintf("%s|%s", k, node.Meta[k]))
}
}
c.Ui.Output(c.Colorize().Color("\n[bold]Meta[reset]"))
c.Ui.Output(formatKV(meta))
}
func (c *NodeStatusCommand) printCpuStats(hostStats *api.HostStats) {
l := len(hostStats.CPU)
for i, cpuStat := range hostStats.CPU {
cpuStatsAttr := make([]string, 4)
cpuStatsAttr[0] = fmt.Sprintf("CPU|%v", cpuStat.CPU)
cpuStatsAttr[1] = fmt.Sprintf("User|%v%%", humanize.FormatFloat(floatFormat, cpuStat.User))
cpuStatsAttr[2] = fmt.Sprintf("System|%v%%", humanize.FormatFloat(floatFormat, cpuStat.System))
cpuStatsAttr[3] = fmt.Sprintf("Idle|%v%%", humanize.FormatFloat(floatFormat, cpuStat.Idle))
c.Ui.Output(formatKV(cpuStatsAttr))
if i+1 < l {
c.Ui.Output("")
}
}
}
func (c *NodeStatusCommand) printMemoryStats(hostStats *api.HostStats) {
memoryStat := hostStats.Memory
memStatsAttr := make([]string, 4)
memStatsAttr[0] = fmt.Sprintf("Total|%v", humanize.IBytes(memoryStat.Total))
memStatsAttr[1] = fmt.Sprintf("Available|%v", humanize.IBytes(memoryStat.Available))
memStatsAttr[2] = fmt.Sprintf("Used|%v", humanize.IBytes(memoryStat.Used))
memStatsAttr[3] = fmt.Sprintf("Free|%v", humanize.IBytes(memoryStat.Free))
c.Ui.Output(formatKV(memStatsAttr))
}
func (c *NodeStatusCommand) printDiskStats(hostStats *api.HostStats) {
l := len(hostStats.DiskStats)
for i, diskStat := range hostStats.DiskStats {
diskStatsAttr := make([]string, 7)
diskStatsAttr[0] = fmt.Sprintf("Device|%s", diskStat.Device)
diskStatsAttr[1] = fmt.Sprintf("MountPoint|%s", diskStat.Mountpoint)
diskStatsAttr[2] = fmt.Sprintf("Size|%s", humanize.IBytes(diskStat.Size))
diskStatsAttr[3] = fmt.Sprintf("Used|%s", humanize.IBytes(diskStat.Used))
diskStatsAttr[4] = fmt.Sprintf("Available|%s", humanize.IBytes(diskStat.Available))
diskStatsAttr[5] = fmt.Sprintf("Used Percent|%v%%", humanize.FormatFloat(floatFormat, diskStat.UsedPercent))
diskStatsAttr[6] = fmt.Sprintf("Inodes Percent|%v%%", humanize.FormatFloat(floatFormat, diskStat.InodesUsedPercent))
c.Ui.Output(formatKV(diskStatsAttr))
if i+1 < l {
c.Ui.Output("")
}
}
}
// getRunningAllocs returns a slice of allocation id's running on the node
func getRunningAllocs(client *api.Client, nodeID string) ([]*api.Allocation, error) {
var allocs []*api.Allocation
// Query the node allocations
nodeAllocs, _, err := client.Nodes().Allocations(nodeID, nil)
// Filter list to only running allocations
for _, alloc := range nodeAllocs {
if alloc.ClientStatus == "running" {
allocs = append(allocs, alloc)
}
}
return allocs, err
}
// getAllocatedResources returns the resource usage of the node.
func getAllocatedResources(client *api.Client, runningAllocs []*api.Allocation, node *api.Node) []string {
// Compute the total
total := computeNodeTotalResources(node)
// Get Resources
var cpu, mem, disk int
for _, alloc := range runningAllocs {
cpu += *alloc.Resources.CPU
mem += *alloc.Resources.MemoryMB
disk += *alloc.Resources.DiskMB
}
resources := make([]string, 2)
resources[0] = "CPU|Memory|Disk"
resources[1] = fmt.Sprintf("%d/%d MHz|%s/%s|%s/%s",
cpu,
*total.CPU,
humanize.IBytes(uint64(mem*bytesPerMegabyte)),
humanize.IBytes(uint64(*total.MemoryMB*bytesPerMegabyte)),
humanize.IBytes(uint64(disk*bytesPerMegabyte)),
humanize.IBytes(uint64(*total.DiskMB*bytesPerMegabyte)))
return resources
}
// computeNodeTotalResources returns the total allocatable resources (resources
// minus reserved)
func computeNodeTotalResources(node *api.Node) api.Resources {
total := api.Resources{}
r := node.Resources
res := node.Reserved
if res == nil {
res = &api.Resources{}
}
total.CPU = helper.IntToPtr(*r.CPU - *res.CPU)
total.MemoryMB = helper.IntToPtr(*r.MemoryMB - *res.MemoryMB)
total.DiskMB = helper.IntToPtr(*r.DiskMB - *res.DiskMB)
return total
}
// getActualResources returns the actual resource usage of the allocations.
func getActualResources(client *api.Client, runningAllocs []*api.Allocation, node *api.Node) ([]string, error) {
// Compute the total
total := computeNodeTotalResources(node)
// Get Resources
var cpu float64
var mem uint64
for _, alloc := range runningAllocs {
// Make the call to the client to get the actual usage.
stats, err := client.Allocations().Stats(alloc, nil)
if err != nil {
return nil, err
}
cpu += stats.ResourceUsage.CpuStats.TotalTicks
mem += stats.ResourceUsage.MemoryStats.RSS
}
resources := make([]string, 2)
resources[0] = "CPU|Memory"
resources[1] = fmt.Sprintf("%v/%d MHz|%v/%v",
math.Floor(cpu),
*total.CPU,
humanize.IBytes(mem),
humanize.IBytes(uint64(*total.MemoryMB*bytesPerMegabyte)))
return resources, nil
}
// getHostResources returns the actual resource usage of the node.
func getHostResources(hostStats *api.HostStats, node *api.Node) ([]string, error) {
if hostStats == nil {
return nil, fmt.Errorf("actual resource usage not present")
}
var resources []string
// calculate disk usage
storageDevice := node.Attributes["unique.storage.volume"]
var diskUsed, diskSize uint64
var physical bool
for _, disk := range hostStats.DiskStats {
if disk.Device == storageDevice {
diskUsed = disk.Used
diskSize = disk.Size
physical = true
}
}
resources = make([]string, 2)
resources[0] = "CPU|Memory|Disk"
if physical {
resources[1] = fmt.Sprintf("%v/%d MHz|%s/%s|%s/%s",
math.Floor(hostStats.CPUTicksConsumed),
*node.Resources.CPU,
humanize.IBytes(hostStats.Memory.Used),
humanize.IBytes(hostStats.Memory.Total),
humanize.IBytes(diskUsed),
humanize.IBytes(diskSize),
)
} else {
// If non-physical device are used, output device name only,
// since nomad doesn't collect the stats data.
resources[1] = fmt.Sprintf("%v/%d MHz|%s/%s|(%s)",
math.Floor(hostStats.CPUTicksConsumed),
*node.Resources.CPU,
humanize.IBytes(hostStats.Memory.Used),
humanize.IBytes(hostStats.Memory.Total),
storageDevice,
)
}
return resources, nil
}
// formatNodeStubList is used to return a table format of a list of node stubs.
func formatNodeStubList(nodes []*api.NodeListStub, verbose bool) string {
// Return error if no nodes are found
if len(nodes) == 0 {
return ""
}
// Truncate the id unless full length is requested
length := shortId
if verbose {
length = fullId
}
// Format the nodes list that matches the prefix so that the user
// can create a more specific request
out := make([]string, len(nodes)+1)
out[0] = "ID|DC|Name|Class|Drain|Eligibility|Status"
for i, node := range nodes {
out[i+1] = fmt.Sprintf("%s|%s|%s|%s|%v|%s|%s",
limit(node.ID, length),
node.Datacenter,
node.Name,
node.NodeClass,
node.Drain,
node.SchedulingEligibility,
node.Status)
}
return formatList(out)
}