k3s/vendor/github.com/google/cadvisor/info/v1/container.go

682 lines
20 KiB
Go

// Copyright 2014 Google Inc. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package v1
import (
"reflect"
"time"
)
type CpuSpec struct {
Limit uint64 `json:"limit"`
MaxLimit uint64 `json:"max_limit"`
Mask string `json:"mask,omitempty"`
Quota uint64 `json:"quota,omitempty"`
Period uint64 `json:"period,omitempty"`
}
type MemorySpec struct {
// The amount of memory requested. Default is unlimited (-1).
// Units: bytes.
Limit uint64 `json:"limit,omitempty"`
// The amount of guaranteed memory. Default is 0.
// Units: bytes.
Reservation uint64 `json:"reservation,omitempty"`
// The amount of swap space requested. Default is unlimited (-1).
// Units: bytes.
SwapLimit uint64 `json:"swap_limit,omitempty"`
}
type ContainerSpec struct {
// Time at which the container was created.
CreationTime time.Time `json:"creation_time,omitempty"`
// Metadata labels associated with this container.
Labels map[string]string `json:"labels,omitempty"`
// Metadata envs associated with this container. Only whitelisted envs are added.
Envs map[string]string `json:"envs,omitempty"`
HasCpu bool `json:"has_cpu"`
Cpu CpuSpec `json:"cpu,omitempty"`
HasMemory bool `json:"has_memory"`
Memory MemorySpec `json:"memory,omitempty"`
HasNetwork bool `json:"has_network"`
HasFilesystem bool `json:"has_filesystem"`
// HasDiskIo when true, indicates that DiskIo stats will be available.
HasDiskIo bool `json:"has_diskio"`
HasCustomMetrics bool `json:"has_custom_metrics"`
CustomMetrics []MetricSpec `json:"custom_metrics,omitempty"`
// Image name used for this container.
Image string `json:"image,omitempty"`
}
// Container reference contains enough information to uniquely identify a container
type ContainerReference struct {
// The container id
Id string `json:"id,omitempty"`
// The absolute name of the container. This is unique on the machine.
Name string `json:"name"`
// Other names by which the container is known within a certain namespace.
// This is unique within that namespace.
Aliases []string `json:"aliases,omitempty"`
// Namespace under which the aliases of a container are unique.
// An example of a namespace is "docker" for Docker containers.
Namespace string `json:"namespace,omitempty"`
}
// Sorts by container name.
type ContainerReferenceSlice []ContainerReference
func (self ContainerReferenceSlice) Len() int { return len(self) }
func (self ContainerReferenceSlice) Swap(i, j int) { self[i], self[j] = self[j], self[i] }
func (self ContainerReferenceSlice) Less(i, j int) bool { return self[i].Name < self[j].Name }
// ContainerInfoRequest is used when users check a container info from the REST API.
// It specifies how much data users want to get about a container
type ContainerInfoRequest struct {
// Max number of stats to return. Specify -1 for all stats currently available.
// Default: 60
NumStats int `json:"num_stats,omitempty"`
// Start time for which to query information.
// If omitted, the beginning of time is assumed.
Start time.Time `json:"start,omitempty"`
// End time for which to query information.
// If omitted, current time is assumed.
End time.Time `json:"end,omitempty"`
}
// Returns a ContainerInfoRequest with all default values specified.
func DefaultContainerInfoRequest() ContainerInfoRequest {
return ContainerInfoRequest{
NumStats: 60,
}
}
func (self *ContainerInfoRequest) Equals(other ContainerInfoRequest) bool {
return self.NumStats == other.NumStats &&
self.Start.Equal(other.Start) &&
self.End.Equal(other.End)
}
type ContainerInfo struct {
ContainerReference
// The direct subcontainers of the current container.
Subcontainers []ContainerReference `json:"subcontainers,omitempty"`
// The isolation used in the container.
Spec ContainerSpec `json:"spec,omitempty"`
// Historical statistics gathered from the container.
Stats []*ContainerStats `json:"stats,omitempty"`
}
// TODO(vmarmol): Refactor to not need this equality comparison.
// ContainerInfo may be (un)marshaled by json or other en/decoder. In that
// case, the Timestamp field in each stats/sample may not be precisely
// en/decoded. This will lead to small but acceptable differences between a
// ContainerInfo and its encode-then-decode version. Eq() is used to compare
// two ContainerInfo accepting small difference (<10ms) of Time fields.
func (self *ContainerInfo) Eq(b *ContainerInfo) bool {
// If both self and b are nil, then Eq() returns true
if self == nil {
return b == nil
}
if b == nil {
return self == nil
}
// For fields other than time.Time, we will compare them precisely.
// This would require that any slice should have same order.
if !reflect.DeepEqual(self.ContainerReference, b.ContainerReference) {
return false
}
if !reflect.DeepEqual(self.Subcontainers, b.Subcontainers) {
return false
}
if !self.Spec.Eq(&b.Spec) {
return false
}
for i, expectedStats := range b.Stats {
selfStats := self.Stats[i]
if !expectedStats.Eq(selfStats) {
return false
}
}
return true
}
func (self *ContainerSpec) Eq(b *ContainerSpec) bool {
// Creation within 1s of each other.
diff := self.CreationTime.Sub(b.CreationTime)
if (diff > time.Second) || (diff < -time.Second) {
return false
}
if self.HasCpu != b.HasCpu {
return false
}
if !reflect.DeepEqual(self.Cpu, b.Cpu) {
return false
}
if self.HasMemory != b.HasMemory {
return false
}
if !reflect.DeepEqual(self.Memory, b.Memory) {
return false
}
if self.HasNetwork != b.HasNetwork {
return false
}
if self.HasFilesystem != b.HasFilesystem {
return false
}
if self.HasDiskIo != b.HasDiskIo {
return false
}
if self.HasCustomMetrics != b.HasCustomMetrics {
return false
}
return true
}
func (self *ContainerInfo) StatsAfter(ref time.Time) []*ContainerStats {
n := len(self.Stats) + 1
for i, s := range self.Stats {
if s.Timestamp.After(ref) {
n = i
break
}
}
if n > len(self.Stats) {
return nil
}
return self.Stats[n:]
}
func (self *ContainerInfo) StatsStartTime() time.Time {
var ret time.Time
for _, s := range self.Stats {
if s.Timestamp.Before(ret) || ret.IsZero() {
ret = s.Timestamp
}
}
return ret
}
func (self *ContainerInfo) StatsEndTime() time.Time {
var ret time.Time
for i := len(self.Stats) - 1; i >= 0; i-- {
s := self.Stats[i]
if s.Timestamp.After(ret) {
ret = s.Timestamp
}
}
return ret
}
// This mirrors kernel internal structure.
type LoadStats struct {
// Number of sleeping tasks.
NrSleeping uint64 `json:"nr_sleeping"`
// Number of running tasks.
NrRunning uint64 `json:"nr_running"`
// Number of tasks in stopped state
NrStopped uint64 `json:"nr_stopped"`
// Number of tasks in uninterruptible state
NrUninterruptible uint64 `json:"nr_uninterruptible"`
// Number of tasks waiting on IO
NrIoWait uint64 `json:"nr_io_wait"`
}
// CPU usage time statistics.
type CpuUsage struct {
// Total CPU usage.
// Unit: nanoseconds.
Total uint64 `json:"total"`
// Per CPU/core usage of the container.
// Unit: nanoseconds.
PerCpu []uint64 `json:"per_cpu_usage,omitempty"`
// Time spent in user space.
// Unit: nanoseconds.
User uint64 `json:"user"`
// Time spent in kernel space.
// Unit: nanoseconds.
System uint64 `json:"system"`
}
// Cpu Completely Fair Scheduler statistics.
type CpuCFS struct {
// Total number of elapsed enforcement intervals.
Periods uint64 `json:"periods"`
// Total number of times tasks in the cgroup have been throttled.
ThrottledPeriods uint64 `json:"throttled_periods"`
// Total time duration for which tasks in the cgroup have been throttled.
// Unit: nanoseconds.
ThrottledTime uint64 `json:"throttled_time"`
}
// Cpu Aggregated scheduler statistics
type CpuSchedstat struct {
// https://www.kernel.org/doc/Documentation/scheduler/sched-stats.txt
// time spent on the cpu
RunTime uint64 `json:"run_time"`
// time spent waiting on a runqueue
RunqueueTime uint64 `json:"runqueue_time"`
// # of timeslices run on this cpu
RunPeriods uint64 `json:"run_periods"`
}
// All CPU usage metrics are cumulative from the creation of the container
type CpuStats struct {
Usage CpuUsage `json:"usage"`
CFS CpuCFS `json:"cfs"`
Schedstat CpuSchedstat `json:"schedstat"`
// Smoothed average of number of runnable threads x 1000.
// We multiply by thousand to avoid using floats, but preserving precision.
// Load is smoothed over the last 10 seconds. Instantaneous value can be read
// from LoadStats.NrRunning.
LoadAverage int32 `json:"load_average"`
}
type PerDiskStats struct {
Device string `json:"device"`
Major uint64 `json:"major"`
Minor uint64 `json:"minor"`
Stats map[string]uint64 `json:"stats"`
}
type DiskIoStats struct {
IoServiceBytes []PerDiskStats `json:"io_service_bytes,omitempty"`
IoServiced []PerDiskStats `json:"io_serviced,omitempty"`
IoQueued []PerDiskStats `json:"io_queued,omitempty"`
Sectors []PerDiskStats `json:"sectors,omitempty"`
IoServiceTime []PerDiskStats `json:"io_service_time,omitempty"`
IoWaitTime []PerDiskStats `json:"io_wait_time,omitempty"`
IoMerged []PerDiskStats `json:"io_merged,omitempty"`
IoTime []PerDiskStats `json:"io_time,omitempty"`
}
type MemoryStats struct {
// Current memory usage, this includes all memory regardless of when it was
// accessed.
// Units: Bytes.
Usage uint64 `json:"usage"`
// Maximum memory usage recorded.
// Units: Bytes.
MaxUsage uint64 `json:"max_usage"`
// Number of bytes of page cache memory.
// Units: Bytes.
Cache uint64 `json:"cache"`
// The amount of anonymous and swap cache memory (includes transparent
// hugepages).
// Units: Bytes.
RSS uint64 `json:"rss"`
// The amount of swap currently used by the processes in this cgroup
// Units: Bytes.
Swap uint64 `json:"swap"`
// The amount of memory used for mapped files (includes tmpfs/shmem)
MappedFile uint64 `json:"mapped_file"`
// The amount of working set memory, this includes recently accessed memory,
// dirty memory, and kernel memory. Working set is <= "usage".
// Units: Bytes.
WorkingSet uint64 `json:"working_set"`
Failcnt uint64 `json:"failcnt"`
ContainerData MemoryStatsMemoryData `json:"container_data,omitempty"`
HierarchicalData MemoryStatsMemoryData `json:"hierarchical_data,omitempty"`
}
type MemoryStatsMemoryData struct {
Pgfault uint64 `json:"pgfault"`
Pgmajfault uint64 `json:"pgmajfault"`
}
type InterfaceStats struct {
// The name of the interface.
Name string `json:"name"`
// Cumulative count of bytes received.
RxBytes uint64 `json:"rx_bytes"`
// Cumulative count of packets received.
RxPackets uint64 `json:"rx_packets"`
// Cumulative count of receive errors encountered.
RxErrors uint64 `json:"rx_errors"`
// Cumulative count of packets dropped while receiving.
RxDropped uint64 `json:"rx_dropped"`
// Cumulative count of bytes transmitted.
TxBytes uint64 `json:"tx_bytes"`
// Cumulative count of packets transmitted.
TxPackets uint64 `json:"tx_packets"`
// Cumulative count of transmit errors encountered.
TxErrors uint64 `json:"tx_errors"`
// Cumulative count of packets dropped while transmitting.
TxDropped uint64 `json:"tx_dropped"`
}
type NetworkStats struct {
InterfaceStats `json:",inline"`
Interfaces []InterfaceStats `json:"interfaces,omitempty"`
// TCP connection stats (Established, Listen...)
Tcp TcpStat `json:"tcp"`
// TCP6 connection stats (Established, Listen...)
Tcp6 TcpStat `json:"tcp6"`
// UDP connection stats
Udp UdpStat `json:"udp"`
// UDP6 connection stats
Udp6 UdpStat `json:"udp6"`
}
type TcpStat struct {
// Count of TCP connections in state "Established"
Established uint64
// Count of TCP connections in state "Syn_Sent"
SynSent uint64
// Count of TCP connections in state "Syn_Recv"
SynRecv uint64
// Count of TCP connections in state "Fin_Wait1"
FinWait1 uint64
// Count of TCP connections in state "Fin_Wait2"
FinWait2 uint64
// Count of TCP connections in state "Time_Wait
TimeWait uint64
// Count of TCP connections in state "Close"
Close uint64
// Count of TCP connections in state "Close_Wait"
CloseWait uint64
// Count of TCP connections in state "Listen_Ack"
LastAck uint64
// Count of TCP connections in state "Listen"
Listen uint64
// Count of TCP connections in state "Closing"
Closing uint64
}
type UdpStat struct {
// Count of UDP sockets in state "Listen"
Listen uint64
// Count of UDP packets dropped by the IP stack
Dropped uint64
// Count of packets Queued for Receieve
RxQueued uint64
// Count of packets Queued for Transmit
TxQueued uint64
}
type FsStats struct {
// The block device name associated with the filesystem.
Device string `json:"device,omitempty"`
// Type of the filesytem.
Type string `json:"type"`
// Number of bytes that can be consumed by the container on this filesystem.
Limit uint64 `json:"capacity"`
// Number of bytes that is consumed by the container on this filesystem.
Usage uint64 `json:"usage"`
// Base Usage that is consumed by the container's writable layer.
// This field is only applicable for docker container's as of now.
BaseUsage uint64 `json:"base_usage"`
// Number of bytes available for non-root user.
Available uint64 `json:"available"`
// HasInodes when true, indicates that Inodes info will be available.
HasInodes bool `json:"has_inodes"`
// Number of Inodes
Inodes uint64 `json:"inodes"`
// Number of available Inodes
InodesFree uint64 `json:"inodes_free"`
// Number of reads completed
// This is the total number of reads completed successfully.
ReadsCompleted uint64 `json:"reads_completed"`
// Number of reads merged
// Reads and writes which are adjacent to each other may be merged for
// efficiency. Thus two 4K reads may become one 8K read before it is
// ultimately handed to the disk, and so it will be counted (and queued)
// as only one I/O. This field lets you know how often this was done.
ReadsMerged uint64 `json:"reads_merged"`
// Number of sectors read
// This is the total number of sectors read successfully.
SectorsRead uint64 `json:"sectors_read"`
// Number of milliseconds spent reading
// This is the total number of milliseconds spent by all reads (as
// measured from __make_request() to end_that_request_last()).
ReadTime uint64 `json:"read_time"`
// Number of writes completed
// This is the total number of writes completed successfully.
WritesCompleted uint64 `json:"writes_completed"`
// Number of writes merged
// See the description of reads merged.
WritesMerged uint64 `json:"writes_merged"`
// Number of sectors written
// This is the total number of sectors written successfully.
SectorsWritten uint64 `json:"sectors_written"`
// Number of milliseconds spent writing
// This is the total number of milliseconds spent by all writes (as
// measured from __make_request() to end_that_request_last()).
WriteTime uint64 `json:"write_time"`
// Number of I/Os currently in progress
// The only field that should go to zero. Incremented as requests are
// given to appropriate struct request_queue and decremented as they finish.
IoInProgress uint64 `json:"io_in_progress"`
// Number of milliseconds spent doing I/Os
// This field increases so long as field 9 is nonzero.
IoTime uint64 `json:"io_time"`
// weighted number of milliseconds spent doing I/Os
// This field is incremented at each I/O start, I/O completion, I/O
// merge, or read of these stats by the number of I/Os in progress
// (field 9) times the number of milliseconds spent doing I/O since the
// last update of this field. This can provide an easy measure of both
// I/O completion time and the backlog that may be accumulating.
WeightedIoTime uint64 `json:"weighted_io_time"`
}
type AcceleratorStats struct {
// Make of the accelerator (nvidia, amd, google etc.)
Make string `json:"make"`
// Model of the accelerator (tesla-p100, tesla-k80 etc.)
Model string `json:"model"`
// ID of the accelerator.
ID string `json:"id"`
// Total accelerator memory.
// unit: bytes
MemoryTotal uint64 `json:"memory_total"`
// Total accelerator memory allocated.
// unit: bytes
MemoryUsed uint64 `json:"memory_used"`
// Percent of time over the past sample period during which
// the accelerator was actively processing.
DutyCycle uint64 `json:"duty_cycle"`
}
type ProcessStats struct {
// Number of processes
ProcessCount uint64 `json:"process_count"`
// Number of open file descriptors
FdCount uint64 `json:"fd_count"`
}
type ContainerStats struct {
// The time of this stat point.
Timestamp time.Time `json:"timestamp"`
Cpu CpuStats `json:"cpu,omitempty"`
DiskIo DiskIoStats `json:"diskio,omitempty"`
Memory MemoryStats `json:"memory,omitempty"`
Network NetworkStats `json:"network,omitempty"`
// Filesystem statistics
Filesystem []FsStats `json:"filesystem,omitempty"`
// Task load stats
TaskStats LoadStats `json:"task_stats,omitempty"`
// Metrics for Accelerators. Each Accelerator corresponds to one element in the array.
Accelerators []AcceleratorStats `json:"accelerators,omitempty"`
// ProcessStats for Containers
Processes ProcessStats `json:"processes,omitempty"`
// Custom metrics from all collectors
CustomMetrics map[string][]MetricVal `json:"custom_metrics,omitempty"`
}
func timeEq(t1, t2 time.Time, tolerance time.Duration) bool {
// t1 should not be later than t2
if t1.After(t2) {
t1, t2 = t2, t1
}
diff := t2.Sub(t1)
if diff <= tolerance {
return true
}
return false
}
const (
// 10ms, i.e. 0.01s
timePrecision time.Duration = 10 * time.Millisecond
)
// This function is useful because we do not require precise time
// representation.
func (a *ContainerStats) Eq(b *ContainerStats) bool {
if !timeEq(a.Timestamp, b.Timestamp, timePrecision) {
return false
}
return a.StatsEq(b)
}
// Checks equality of the stats values.
func (a *ContainerStats) StatsEq(b *ContainerStats) bool {
// TODO(vmarmol): Consider using this through reflection.
if !reflect.DeepEqual(a.Cpu, b.Cpu) {
return false
}
if !reflect.DeepEqual(a.Memory, b.Memory) {
return false
}
if !reflect.DeepEqual(a.DiskIo, b.DiskIo) {
return false
}
if !reflect.DeepEqual(a.Network, b.Network) {
return false
}
if !reflect.DeepEqual(a.Filesystem, b.Filesystem) {
return false
}
return true
}
// Event contains information general to events such as the time at which they
// occurred, their specific type, and the actual event. Event types are
// differentiated by the EventType field of Event.
type Event struct {
// the absolute container name for which the event occurred
ContainerName string `json:"container_name"`
// the time at which the event occurred
Timestamp time.Time `json:"timestamp"`
// the type of event. EventType is an enumerated type
EventType EventType `json:"event_type"`
// the original event object and all of its extraneous data, ex. an
// OomInstance
EventData EventData `json:"event_data,omitempty"`
}
// EventType is an enumerated type which lists the categories under which
// events may fall. The Event field EventType is populated by this enum.
type EventType string
const (
EventOom EventType = "oom"
EventOomKill = "oomKill"
EventContainerCreation = "containerCreation"
EventContainerDeletion = "containerDeletion"
)
// Extra information about an event. Only one type will be set.
type EventData struct {
// Information about an OOM kill event.
OomKill *OomKillEventData `json:"oom,omitempty"`
}
// Information related to an OOM kill instance
type OomKillEventData struct {
// process id of the killed process
Pid int `json:"pid"`
// The name of the killed process
ProcessName string `json:"process_name"`
}