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package structs
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import (
"bytes"
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"crypto/md5"
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"crypto/sha1"
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"crypto/sha256"
"crypto/sha512"
"encoding/hex"
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"errors"
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"fmt"
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"io"
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"path/filepath"
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"reflect"
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"regexp"
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"strconv"
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"strings"
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"time"
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"github.com/gorhill/cronexpr"
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"github.com/hashicorp/go-multierror"
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"github.com/hashicorp/go-version"
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"github.com/hashicorp/nomad/helper/args"
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"github.com/mitchellh/copystructure"
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"github.com/ugorji/go/codec"
hcodec "github.com/hashicorp/go-msgpack/codec"
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)
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var (
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ErrNoLeader = fmt . Errorf ( "No cluster leader" )
ErrNoRegionPath = fmt . Errorf ( "No path to region" )
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)
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type MessageType uint8
const (
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NodeRegisterRequestType MessageType = iota
NodeDeregisterRequestType
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NodeUpdateStatusRequestType
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NodeUpdateDrainRequestType
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JobRegisterRequestType
JobDeregisterRequestType
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EvalUpdateRequestType
EvalDeleteRequestType
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AllocUpdateRequestType
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AllocClientUpdateRequestType
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)
const (
// IgnoreUnknownTypeFlag is set along with a MessageType
// to indicate that the message type can be safely ignored
// if it is not recognized. This is for future proofing, so
// that new commands can be added in a way that won't cause
// old servers to crash when the FSM attempts to process them.
IgnoreUnknownTypeFlag MessageType = 128
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// ApiMajorVersion is returned as part of the Status.Version request.
// It should be incremented anytime the APIs are changed in a way
// that would break clients for sane client versioning.
ApiMajorVersion = 1
// ApiMinorVersion is returned as part of the Status.Version request.
// It should be incremented anytime the APIs are changed to allow
// for sane client versioning. Minor changes should be compatible
// within the major version.
ApiMinorVersion = 1
ProtocolVersion = "protocol"
APIMajorVersion = "api.major"
APIMinorVersion = "api.minor"
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)
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// RPCInfo is used to describe common information about query
type RPCInfo interface {
RequestRegion ( ) string
IsRead ( ) bool
AllowStaleRead ( ) bool
}
// QueryOptions is used to specify various flags for read queries
type QueryOptions struct {
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// The target region for this query
Region string
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// If set, wait until query exceeds given index. Must be provided
// with MaxQueryTime.
MinQueryIndex uint64
// Provided with MinQueryIndex to wait for change.
MaxQueryTime time . Duration
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// If set, any follower can service the request. Results
// may be arbitrarily stale.
AllowStale bool
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// If set, used as prefix for resource list searches
Prefix string
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}
func ( q QueryOptions ) RequestRegion ( ) string {
return q . Region
}
// QueryOption only applies to reads, so always true
func ( q QueryOptions ) IsRead ( ) bool {
return true
}
func ( q QueryOptions ) AllowStaleRead ( ) bool {
return q . AllowStale
}
type WriteRequest struct {
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// The target region for this write
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Region string
}
func ( w WriteRequest ) RequestRegion ( ) string {
// The target region for this request
return w . Region
}
// WriteRequest only applies to writes, always false
func ( w WriteRequest ) IsRead ( ) bool {
return false
}
func ( w WriteRequest ) AllowStaleRead ( ) bool {
return false
}
// QueryMeta allows a query response to include potentially
// useful metadata about a query
type QueryMeta struct {
// This is the index associated with the read
Index uint64
// If AllowStale is used, this is time elapsed since
// last contact between the follower and leader. This
// can be used to gauge staleness.
LastContact time . Duration
// Used to indicate if there is a known leader node
KnownLeader bool
}
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// WriteMeta allows a write response to include potentially
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// useful metadata about the write
type WriteMeta struct {
// This is the index associated with the write
Index uint64
}
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// NodeRegisterRequest is used for Node.Register endpoint
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// to register a node as being a schedulable entity.
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type NodeRegisterRequest struct {
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Node * Node
WriteRequest
}
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// NodeDeregisterRequest is used for Node.Deregister endpoint
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// to deregister a node as being a schedulable entity.
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type NodeDeregisterRequest struct {
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NodeID string
WriteRequest
}
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// NodeServerInfo is used to in NodeUpdateResponse to return Nomad server
// information used in RPC server lists.
type NodeServerInfo struct {
// RPCAdvertiseAddr is the IP endpoint that a Nomad Server wishes to
// be contacted at for RPCs.
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RPCAdvertiseAddr string
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// RpcMajorVersion is the major version number the Nomad Server
// supports
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RPCMajorVersion int32
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// RpcMinorVersion is the minor version number the Nomad Server
// supports
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RPCMinorVersion int32
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// Datacenter is the datacenter that a Nomad server belongs to
Datacenter string
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}
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// NodeUpdateStatusRequest is used for Node.UpdateStatus endpoint
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// to update the status of a node.
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type NodeUpdateStatusRequest struct {
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NodeID string
Status string
WriteRequest
}
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// NodeUpdateDrainRequest is used for updatin the drain status
type NodeUpdateDrainRequest struct {
NodeID string
Drain bool
WriteRequest
}
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// NodeEvaluateRequest is used to re-evaluate the ndoe
type NodeEvaluateRequest struct {
NodeID string
WriteRequest
}
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// NodeSpecificRequest is used when we just need to specify a target node
type NodeSpecificRequest struct {
NodeID string
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QueryOptions
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}
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// JobRegisterRequest is used for Job.Register endpoint
// to register a job as being a schedulable entity.
type JobRegisterRequest struct {
Job * Job
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// If EnforceIndex is set then the job will only be registered if the passed
// JobModifyIndex matches the current Jobs index. If the index is zero, the
// register only occurs if the job is new.
EnforceIndex bool
JobModifyIndex uint64
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WriteRequest
}
// JobDeregisterRequest is used for Job.Deregister endpoint
// to deregister a job as being a schedulable entity.
type JobDeregisterRequest struct {
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JobID string
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WriteRequest
}
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// JobEvaluateRequest is used when we just need to re-evaluate a target job
type JobEvaluateRequest struct {
JobID string
WriteRequest
}
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// JobSpecificRequest is used when we just need to specify a target job
type JobSpecificRequest struct {
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JobID string
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QueryOptions
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}
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// JobListRequest is used to parameterize a list request
type JobListRequest struct {
QueryOptions
}
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// JobPlanRequest is used for the Job.Plan endpoint to trigger a dry-run
// evaluation of the Job.
type JobPlanRequest struct {
Job * Job
Diff bool // Toggles an annotated diff
WriteRequest
}
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// NodeListRequest is used to parameterize a list request
type NodeListRequest struct {
QueryOptions
}
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// EvalUpdateRequest is used for upserting evaluations.
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type EvalUpdateRequest struct {
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Evals [ ] * Evaluation
EvalToken string
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WriteRequest
}
// EvalDeleteRequest is used for deleting an evaluation.
type EvalDeleteRequest struct {
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Evals [ ] string
Allocs [ ] string
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WriteRequest
}
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// EvalSpecificRequest is used when we just need to specify a target evaluation
type EvalSpecificRequest struct {
EvalID string
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QueryOptions
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}
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// EvalAckRequest is used to Ack/Nack a specific evaluation
type EvalAckRequest struct {
EvalID string
Token string
WriteRequest
}
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// EvalDequeueRequest is used when we want to dequeue an evaluation
type EvalDequeueRequest struct {
Schedulers [ ] string
Timeout time . Duration
WriteRequest
}
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// EvalListRequest is used to list the evaluations
type EvalListRequest struct {
QueryOptions
}
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// PlanRequest is used to submit an allocation plan to the leader
type PlanRequest struct {
Plan * Plan
WriteRequest
}
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// AllocUpdateRequest is used to submit changes to allocations, either
// to cause evictions or to assign new allocaitons. Both can be done
// within a single transaction
type AllocUpdateRequest struct {
// Alloc is the list of new allocations to assign
Alloc [ ] * Allocation
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// Job is the shared parent job of the allocations.
// It is pulled out since it is common to reduce payload size.
Job * Job
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WriteRequest
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}
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// AllocListRequest is used to request a list of allocations
type AllocListRequest struct {
QueryOptions
}
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// AllocSpecificRequest is used to query a specific allocation
type AllocSpecificRequest struct {
AllocID string
QueryOptions
}
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// AllocsGetRequest is used to query a set of allocations
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type AllocsGetRequest struct {
AllocIDs [ ] string
QueryOptions
}
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// PeriodicForceReqeuest is used to force a specific periodic job.
type PeriodicForceRequest struct {
JobID string
WriteRequest
}
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// GenericRequest is used to request where no
// specific information is needed.
type GenericRequest struct {
QueryOptions
}
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// GenericResponse is used to respond to a request where no
// specific response information is needed.
type GenericResponse struct {
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WriteMeta
}
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// VersionResponse is used for the Status.Version reseponse
type VersionResponse struct {
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Build string
Versions map [ string ] int
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QueryMeta
}
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// JobRegisterResponse is used to respond to a job registration
type JobRegisterResponse struct {
EvalID string
EvalCreateIndex uint64
JobModifyIndex uint64
QueryMeta
}
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// JobDeregisterResponse is used to respond to a job deregistration
type JobDeregisterResponse struct {
EvalID string
EvalCreateIndex uint64
JobModifyIndex uint64
QueryMeta
}
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// NodeUpdateResponse is used to respond to a node update
type NodeUpdateResponse struct {
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HeartbeatTTL time . Duration
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EvalIDs [ ] string
EvalCreateIndex uint64
NodeModifyIndex uint64
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// LeaderRPCAddr is the RPC address of the current Raft Leader. If
// empty, the current Nomad Server is in the minority of a partition.
LeaderRPCAddr string
// NumNodes is the number of Nomad nodes attached to this quorum of
// Nomad Servers at the time of the response. This value can
// fluctuate based on the health of the cluster between heartbeats.
NumNodes int32
// Servers is the full list of known Nomad servers in the local
// region.
Servers [ ] * NodeServerInfo
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QueryMeta
}
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// NodeDrainUpdateResponse is used to respond to a node drain update
type NodeDrainUpdateResponse struct {
EvalIDs [ ] string
EvalCreateIndex uint64
NodeModifyIndex uint64
QueryMeta
}
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// NodeAllocsResponse is used to return allocs for a single node
type NodeAllocsResponse struct {
Allocs [ ] * Allocation
QueryMeta
}
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// NodeClientAllocsResponse is used to return allocs meta data for a single node
type NodeClientAllocsResponse struct {
Allocs map [ string ] uint64
QueryMeta
}
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// SingleNodeResponse is used to return a single node
type SingleNodeResponse struct {
Node * Node
QueryMeta
}
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// JobListResponse is used for a list request
type NodeListResponse struct {
Nodes [ ] * NodeListStub
QueryMeta
}
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// SingleJobResponse is used to return a single job
type SingleJobResponse struct {
Job * Job
QueryMeta
}
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// JobListResponse is used for a list request
type JobListResponse struct {
Jobs [ ] * JobListStub
QueryMeta
}
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// JobPlanResponse is used to respond to a job plan request
type JobPlanResponse struct {
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// Annotations stores annotations explaining decisions the scheduler made.
Annotations * PlanAnnotations
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// FailedTGAllocs is the placement failures per task group.
FailedTGAllocs map [ string ] * AllocMetric
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// JobModifyIndex is the modification index of the job. The value can be
// used when running `nomad run` to ensure that the Job wasn’ t modified
// since the last plan. If the job is being created, the value is zero.
JobModifyIndex uint64
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// CreatedEvals is the set of evaluations created by the scheduler. The
// reasons for this can be rolling-updates or blocked evals.
CreatedEvals [ ] * Evaluation
// Diff contains the diff of the job and annotations on whether the change
// causes an in-place update or create/destroy
Diff * JobDiff
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// NextPeriodicLaunch is the time duration till the job would be launched if
// submitted.
NextPeriodicLaunch time . Time
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WriteMeta
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}
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// SingleAllocResponse is used to return a single allocation
type SingleAllocResponse struct {
Alloc * Allocation
QueryMeta
}
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// AllocsGetResponse is used to return a set of allocations
type AllocsGetResponse struct {
Allocs [ ] * Allocation
QueryMeta
}
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// JobAllocationsResponse is used to return the allocations for a job
type JobAllocationsResponse struct {
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Allocations [ ] * AllocListStub
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QueryMeta
}
// JobEvaluationsResponse is used to return the evaluations for a job
type JobEvaluationsResponse struct {
Evaluations [ ] * Evaluation
QueryMeta
}
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// SingleEvalResponse is used to return a single evaluation
type SingleEvalResponse struct {
Eval * Evaluation
QueryMeta
}
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// EvalDequeueResponse is used to return from a dequeue
type EvalDequeueResponse struct {
Eval * Evaluation
Token string
QueryMeta
}
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// PlanResponse is used to return from a PlanRequest
type PlanResponse struct {
Result * PlanResult
WriteMeta
}
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// AllocListResponse is used for a list request
type AllocListResponse struct {
Allocations [ ] * AllocListStub
QueryMeta
}
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// EvalListResponse is used for a list request
type EvalListResponse struct {
Evaluations [ ] * Evaluation
QueryMeta
}
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// EvalAllocationsResponse is used to return the allocations for an evaluation
type EvalAllocationsResponse struct {
Allocations [ ] * AllocListStub
QueryMeta
}
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// PeriodicForceResponse is used to respond to a periodic job force launch
type PeriodicForceResponse struct {
EvalID string
EvalCreateIndex uint64
WriteMeta
}
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const (
NodeStatusInit = "initializing"
NodeStatusReady = "ready"
NodeStatusDown = "down"
)
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// ShouldDrainNode checks if a given node status should trigger an
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// evaluation. Some states don't require any further action.
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func ShouldDrainNode ( status string ) bool {
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switch status {
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case NodeStatusInit , NodeStatusReady :
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return false
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case NodeStatusDown :
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return true
default :
panic ( fmt . Sprintf ( "unhandled node status %s" , status ) )
}
}
// ValidNodeStatus is used to check if a node status is valid
func ValidNodeStatus ( status string ) bool {
switch status {
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case NodeStatusInit , NodeStatusReady , NodeStatusDown :
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return true
default :
return false
}
}
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// Node is a representation of a schedulable client node
type Node struct {
// ID is a unique identifier for the node. It can be constructed
// by doing a concatenation of the Name and Datacenter as a simple
// approach. Alternatively a UUID may be used.
ID string
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// Datacenter for this node
Datacenter string
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// Node name
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Name string
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// HTTPAddr is the address on which the Nomad client is listening for http
// requests
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HTTPAddr string
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// Attributes is an arbitrary set of key/value
// data that can be used for constraints. Examples
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// include "kernel.name=linux", "arch=386", "driver.docker=1",
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// "docker.runtime=1.8.3"
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Attributes map [ string ] string
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// Resources is the available resources on the client.
// For example 'cpu=2' 'memory=2048'
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Resources * Resources
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// Reserved is the set of resources that are reserved,
// and should be subtracted from the total resources for
// the purposes of scheduling. This may be provide certain
// high-watermark tolerances or because of external schedulers
// consuming resources.
Reserved * Resources
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// Links are used to 'link' this client to external
// systems. For example 'consul=foo.dc1' 'aws=i-83212'
// 'ami=ami-123'
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Links map [ string ] string
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// Meta is used to associate arbitrary metadata with this
// client. This is opaque to Nomad.
Meta map [ string ] string
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// NodeClass is an opaque identifier used to group nodes
// together for the purpose of determining scheduling pressure.
NodeClass string
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// ComputedClass is a unique id that identifies nodes with a common set of
// attributes and capabilities.
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ComputedClass string
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// Drain is controlled by the servers, and not the client.
// If true, no jobs will be scheduled to this node, and existing
// allocations will be drained.
Drain bool
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// Status of this node
Status string
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// StatusDescription is meant to provide more human useful information
StatusDescription string
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// StatusUpdatedAt is the time stamp at which the state of the node was
// updated
StatusUpdatedAt int64
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// Raft Indexes
CreateIndex uint64
ModifyIndex uint64
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}
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func ( n * Node ) Copy ( ) * Node {
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if n == nil {
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return nil
}
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nn := new ( Node )
* nn = * n
nn . Attributes = CopyMapStringString ( nn . Attributes )
nn . Resources = nn . Resources . Copy ( )
nn . Reserved = nn . Reserved . Copy ( )
nn . Links = CopyMapStringString ( nn . Links )
nn . Meta = CopyMapStringString ( nn . Meta )
return nn
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}
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// TerminalStatus returns if the current status is terminal and
// will no longer transition.
func ( n * Node ) TerminalStatus ( ) bool {
switch n . Status {
case NodeStatusDown :
return true
default :
return false
}
}
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// Stub returns a summarized version of the node
func ( n * Node ) Stub ( ) * NodeListStub {
return & NodeListStub {
ID : n . ID ,
Datacenter : n . Datacenter ,
Name : n . Name ,
NodeClass : n . NodeClass ,
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Drain : n . Drain ,
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Status : n . Status ,
StatusDescription : n . StatusDescription ,
CreateIndex : n . CreateIndex ,
ModifyIndex : n . ModifyIndex ,
}
}
// NodeListStub is used to return a subset of job information
// for the job list
type NodeListStub struct {
ID string
Datacenter string
Name string
NodeClass string
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Drain bool
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Status string
StatusDescription string
CreateIndex uint64
ModifyIndex uint64
}
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// Resources is used to define the resources available
// on a client
type Resources struct {
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CPU int
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MemoryMB int ` mapstructure:"memory" `
DiskMB int ` mapstructure:"disk" `
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IOPS int
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Networks [ ] * NetworkResource
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}
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// DefaultResources returns the minimum resources a task can use and be valid.
func DefaultResources ( ) * Resources {
return & Resources {
CPU : 100 ,
MemoryMB : 10 ,
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DiskMB : 300 ,
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IOPS : 0 ,
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}
}
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// Merge merges this resource with another resource.
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func ( r * Resources ) Merge ( other * Resources ) {
if other . CPU != 0 {
r . CPU = other . CPU
}
if other . MemoryMB != 0 {
r . MemoryMB = other . MemoryMB
}
if other . DiskMB != 0 {
r . DiskMB = other . DiskMB
}
if other . IOPS != 0 {
r . IOPS = other . IOPS
}
if len ( other . Networks ) != 0 {
r . Networks = other . Networks
}
}
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// MeetsMinResources returns an error if the resources specified are less than
// the minimum allowed.
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func ( r * Resources ) MeetsMinResources ( ) error {
var mErr multierror . Error
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if r . CPU < 20 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum CPU value is 20; got %d" , r . CPU ) )
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}
if r . MemoryMB < 10 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum MemoryMB value is 10; got %d" , r . MemoryMB ) )
}
if r . DiskMB < 10 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum DiskMB value is 10; got %d" , r . DiskMB ) )
}
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if r . IOPS < 0 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum IOPS value is 0; got %d" , r . IOPS ) )
2016-02-02 20:00:26 +00:00
}
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for i , n := range r . Networks {
if err := n . MeetsMinResources ( ) ; err != nil {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "network resource at index %d failed: %v" , i , err ) )
}
}
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return mErr . ErrorOrNil ( )
}
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// Copy returns a deep copy of the resources
func ( r * Resources ) Copy ( ) * Resources {
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if r == nil {
return nil
}
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newR := new ( Resources )
* newR = * r
2016-03-21 23:29:21 +00:00
if r . Networks != nil {
n := len ( r . Networks )
newR . Networks = make ( [ ] * NetworkResource , n )
for i := 0 ; i < n ; i ++ {
newR . Networks [ i ] = r . Networks [ i ] . Copy ( )
}
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}
return newR
}
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// NetIndex finds the matching net index using device name
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func ( r * Resources ) NetIndex ( n * NetworkResource ) int {
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for idx , net := range r . Networks {
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if net . Device == n . Device {
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return idx
}
}
return - 1
}
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// Superset checks if one set of resources is a superset
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// of another. This ignores network resources, and the NetworkIndex
// should be used for that.
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func ( r * Resources ) Superset ( other * Resources ) ( bool , string ) {
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if r . CPU < other . CPU {
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return false , "cpu exhausted"
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}
if r . MemoryMB < other . MemoryMB {
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return false , "memory exhausted"
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}
if r . DiskMB < other . DiskMB {
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return false , "disk exhausted"
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}
if r . IOPS < other . IOPS {
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return false , "iops exhausted"
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}
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return true , ""
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}
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// Add adds the resources of the delta to this, potentially
// returning an error if not possible.
func ( r * Resources ) Add ( delta * Resources ) error {
if delta == nil {
return nil
}
r . CPU += delta . CPU
r . MemoryMB += delta . MemoryMB
r . DiskMB += delta . DiskMB
r . IOPS += delta . IOPS
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for _ , n := range delta . Networks {
// Find the matching interface by IP or CIDR
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idx := r . NetIndex ( n )
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if idx == - 1 {
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r . Networks = append ( r . Networks , n . Copy ( ) )
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} else {
r . Networks [ idx ] . Add ( n )
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}
}
return nil
}
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func ( r * Resources ) GoString ( ) string {
return fmt . Sprintf ( "*%#v" , * r )
}
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type Port struct {
Label string
Value int ` mapstructure:"static" `
}
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// NetworkResource is used to represent available network
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// resources
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type NetworkResource struct {
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Device string // Name of the device
CIDR string // CIDR block of addresses
IP string // IP address
MBits int // Throughput
ReservedPorts [ ] Port // Reserved ports
DynamicPorts [ ] Port // Dynamically assigned ports
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}
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// MeetsMinResources returns an error if the resources specified are less than
// the minimum allowed.
func ( n * NetworkResource ) MeetsMinResources ( ) error {
var mErr multierror . Error
if n . MBits < 1 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum MBits value is 1; got %d" , n . MBits ) )
}
return mErr . ErrorOrNil ( )
}
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// Copy returns a deep copy of the network resource
func ( n * NetworkResource ) Copy ( ) * NetworkResource {
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if n == nil {
return nil
}
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newR := new ( NetworkResource )
* newR = * n
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if n . ReservedPorts != nil {
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newR . ReservedPorts = make ( [ ] Port , len ( n . ReservedPorts ) )
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copy ( newR . ReservedPorts , n . ReservedPorts )
}
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if n . DynamicPorts != nil {
newR . DynamicPorts = make ( [ ] Port , len ( n . DynamicPorts ) )
copy ( newR . DynamicPorts , n . DynamicPorts )
}
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return newR
}
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// Add adds the resources of the delta to this, potentially
// returning an error if not possible.
func ( n * NetworkResource ) Add ( delta * NetworkResource ) {
if len ( delta . ReservedPorts ) > 0 {
n . ReservedPorts = append ( n . ReservedPorts , delta . ReservedPorts ... )
}
n . MBits += delta . MBits
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n . DynamicPorts = append ( n . DynamicPorts , delta . DynamicPorts ... )
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}
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func ( n * NetworkResource ) GoString ( ) string {
return fmt . Sprintf ( "*%#v" , * n )
}
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func ( n * NetworkResource ) MapLabelToValues ( port_map map [ string ] int ) map [ string ] int {
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labelValues := make ( map [ string ] int )
ports := append ( n . ReservedPorts , n . DynamicPorts ... )
for _ , port := range ports {
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if mapping , ok := port_map [ port . Label ] ; ok {
labelValues [ port . Label ] = mapping
} else {
labelValues [ port . Label ] = port . Value
}
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}
return labelValues
}
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const (
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// JobTypeNomad is reserved for internal system tasks and is
// always handled by the CoreScheduler.
JobTypeCore = "_core"
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JobTypeService = "service"
JobTypeBatch = "batch"
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JobTypeSystem = "system"
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)
const (
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JobStatusPending = "pending" // Pending means the job is waiting on scheduling
JobStatusRunning = "running" // Running means the job has non-terminal allocations
JobStatusDead = "dead" // Dead means all evaluation's and allocations are terminal
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)
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const (
// JobMinPriority is the minimum allowed priority
JobMinPriority = 1
// JobDefaultPriority is the default priority if not
// not specified.
JobDefaultPriority = 50
// JobMaxPriority is the maximum allowed priority
JobMaxPriority = 100
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// Ensure CoreJobPriority is higher than any user
// specified job so that it gets priority. This is important
// for the system to remain healthy.
CoreJobPriority = JobMaxPriority * 2
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)
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// JobSummary summarizes the state of the allocations of a job
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type JobSummary struct {
JobID string
Summary map [ string ] TaskGroupSummary
}
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// TaskGroup summarizes the state of all the allocations of a particular
// TaskGroup
2016-06-30 19:04:22 +00:00
type TaskGroupSummary struct {
Complete int
Failed int
Running int
Starting int
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Lost int
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}
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// Job is the scope of a scheduling request to Nomad. It is the largest
// scoped object, and is a named collection of task groups. Each task group
// is further composed of tasks. A task group (TG) is the unit of scheduling
// however.
type Job struct {
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// Region is the Nomad region that handles scheduling this job
Region string
// ID is a unique identifier for the job per region. It can be
// specified hierarchically like LineOfBiz/OrgName/Team/Project
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ID string
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// ParentID is the unique identifier of the job that spawned this job.
ParentID string
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// Name is the logical name of the job used to refer to it. This is unique
// per region, but not unique globally.
Name string
// Type is used to control various behaviors about the job. Most jobs
// are service jobs, meaning they are expected to be long lived.
// Some jobs are batch oriented meaning they run and then terminate.
// This can be extended in the future to support custom schedulers.
Type string
// Priority is used to control scheduling importance and if this job
// can preempt other jobs.
Priority int
// AllAtOnce is used to control if incremental scheduling of task groups
// is allowed or if we must do a gang scheduling of the entire job. This
// can slow down larger jobs if resources are not available.
2015-09-15 00:43:42 +00:00
AllAtOnce bool ` mapstructure:"all_at_once" `
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2015-08-13 21:02:39 +00:00
// Datacenters contains all the datacenters this job is allowed to span
Datacenters [ ] string
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// Constraints can be specified at a job level and apply to
// all the task groups and tasks.
Constraints [ ] * Constraint
// TaskGroups are the collections of task groups that this job needs
// to run. Each task group is an atomic unit of scheduling and placement.
TaskGroups [ ] * TaskGroup
2015-09-07 22:08:50 +00:00
// Update is used to control the update strategy
Update UpdateStrategy
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// Periodic is used to define the interval the job is run at.
2015-12-01 16:40:32 +00:00
Periodic * PeriodicConfig
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2015-07-03 23:57:48 +00:00
// Meta is used to associate arbitrary metadata with this
// job. This is opaque to Nomad.
Meta map [ string ] string
// Job status
Status string
2015-07-04 00:50:54 +00:00
2015-08-15 20:08:06 +00:00
// StatusDescription is meant to provide more human useful information
StatusDescription string
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// Raft Indexes
2016-01-12 17:50:33 +00:00
CreateIndex uint64
ModifyIndex uint64
JobModifyIndex uint64
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}
2015-12-15 03:20:57 +00:00
// InitFields is used to initialize fields in the Job. This should be called
// when registering a Job.
func ( j * Job ) InitFields ( ) {
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for _ , tg := range j . TaskGroups {
tg . InitFields ( j )
}
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}
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// Copy returns a deep copy of the Job. It is expected that callers use recover.
// This job can panic if the deep copy failed as it uses reflection.
func ( j * Job ) Copy ( ) * Job {
2016-02-11 01:54:43 +00:00
if j == nil {
return nil
}
nj := new ( Job )
* nj = * j
nj . Datacenters = CopySliceString ( nj . Datacenters )
2016-02-11 17:08:20 +00:00
nj . Constraints = CopySliceConstraints ( nj . Constraints )
2015-12-18 20:26:28 +00:00
2016-03-21 23:29:21 +00:00
if j . TaskGroups != nil {
tgs := make ( [ ] * TaskGroup , len ( nj . TaskGroups ) )
for i , tg := range nj . TaskGroups {
tgs [ i ] = tg . Copy ( )
}
nj . TaskGroups = tgs
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}
nj . Periodic = nj . Periodic . Copy ( )
nj . Meta = CopyMapStringString ( nj . Meta )
return nj
2015-12-18 20:26:28 +00:00
}
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// Validate is used to sanity check a job input
func ( j * Job ) Validate ( ) error {
var mErr multierror . Error
if j . Region == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job region" ) )
}
if j . ID == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job ID" ) )
2015-09-16 00:38:23 +00:00
} else if strings . Contains ( j . ID , " " ) {
mErr . Errors = append ( mErr . Errors , errors . New ( "Job ID contains a space" ) )
2015-09-15 17:46:10 +00:00
}
if j . Name == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job name" ) )
}
if j . Type == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job type" ) )
}
if j . Priority < JobMinPriority || j . Priority > JobMaxPriority {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Job priority must be between [%d, %d]" , JobMinPriority , JobMaxPriority ) )
}
if len ( j . Datacenters ) == 0 {
2015-09-25 19:27:31 +00:00
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job datacenters" ) )
2015-09-15 17:46:10 +00:00
}
if len ( j . TaskGroups ) == 0 {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing job task groups" ) )
}
2015-10-11 19:50:16 +00:00
for idx , constr := range j . Constraints {
if err := constr . Validate ( ) ; err != nil {
outer := fmt . Errorf ( "Constraint %d validation failed: %s" , idx + 1 , err )
mErr . Errors = append ( mErr . Errors , outer )
}
}
2015-09-15 17:46:10 +00:00
// Check for duplicate task groups
taskGroups := make ( map [ string ] int )
for idx , tg := range j . TaskGroups {
if tg . Name == "" {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Job task group %d missing name" , idx + 1 ) )
} else if existing , ok := taskGroups [ tg . Name ] ; ok {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Job task group %d redefines '%s' from group %d" , idx + 1 , tg . Name , existing + 1 ) )
} else {
taskGroups [ tg . Name ] = idx
}
2015-10-16 21:15:01 +00:00
2016-07-13 19:50:08 +00:00
if j . Type == "system" && tg . Count > 1 {
2015-10-16 21:15:01 +00:00
mErr . Errors = append ( mErr . Errors ,
2016-07-20 13:23:35 +00:00
fmt . Errorf ( "Job task group %s has count %d. Count cannot exceed 1 with system scheduler" ,
tg . Name , tg . Count ) )
2015-10-16 21:15:01 +00:00
}
2015-09-15 18:23:03 +00:00
}
2015-09-15 17:46:10 +00:00
2015-09-15 18:23:03 +00:00
// Validate the task group
2016-07-20 13:23:35 +00:00
for _ , tg := range j . TaskGroups {
2015-09-15 17:46:10 +00:00
if err := tg . Validate ( ) ; err != nil {
2016-07-20 13:23:35 +00:00
outer := fmt . Errorf ( "Task group %s validation failed: %s" , tg . Name , err )
2015-09-21 00:08:57 +00:00
mErr . Errors = append ( mErr . Errors , outer )
2015-09-15 17:46:10 +00:00
}
}
2015-12-01 00:51:56 +00:00
// Validate periodic is only used with batch jobs.
2016-07-13 19:50:08 +00:00
if j . IsPeriodic ( ) && j . Periodic . Enabled {
2015-12-04 23:10:08 +00:00
if j . Type != JobTypeBatch {
mErr . Errors = append ( mErr . Errors ,
fmt . Errorf ( "Periodic can only be used with %q scheduler" , JobTypeBatch ) )
}
if err := j . Periodic . Validate ( ) ; err != nil {
mErr . Errors = append ( mErr . Errors , err )
}
2015-12-01 00:51:56 +00:00
}
2015-09-15 17:46:10 +00:00
return mErr . ErrorOrNil ( )
}
2015-08-23 23:49:48 +00:00
// LookupTaskGroup finds a task group by name
2015-08-30 02:14:47 +00:00
func ( j * Job ) LookupTaskGroup ( name string ) * TaskGroup {
2015-08-23 23:49:48 +00:00
for _ , tg := range j . TaskGroups {
if tg . Name == name {
return tg
}
}
return nil
}
2015-09-06 22:34:28 +00:00
// Stub is used to return a summary of the job
func ( j * Job ) Stub ( ) * JobListStub {
return & JobListStub {
ID : j . ID ,
2016-01-07 22:43:55 +00:00
ParentID : j . ParentID ,
2015-09-06 22:34:28 +00:00
Name : j . Name ,
Type : j . Type ,
Priority : j . Priority ,
Status : j . Status ,
StatusDescription : j . StatusDescription ,
CreateIndex : j . CreateIndex ,
ModifyIndex : j . ModifyIndex ,
2016-06-08 23:48:02 +00:00
JobModifyIndex : j . JobModifyIndex ,
2015-09-06 22:34:28 +00:00
}
}
2015-12-01 16:40:32 +00:00
// IsPeriodic returns whether a job is periodic.
func ( j * Job ) IsPeriodic ( ) bool {
return j . Periodic != nil
}
2015-09-06 22:34:28 +00:00
// JobListStub is used to return a subset of job information
// for the job list
type JobListStub struct {
ID string
2016-01-07 22:43:55 +00:00
ParentID string
2015-09-06 22:34:28 +00:00
Name string
Type string
Priority int
Status string
StatusDescription string
CreateIndex uint64
ModifyIndex uint64
2016-06-08 23:48:02 +00:00
JobModifyIndex uint64
2015-09-06 22:34:28 +00:00
}
2015-09-07 22:08:50 +00:00
// UpdateStrategy is used to modify how updates are done
type UpdateStrategy struct {
// Stagger is the amount of time between the updates
Stagger time . Duration
// MaxParallel is how many updates can be done in parallel
2015-09-20 21:18:21 +00:00
MaxParallel int ` mapstructure:"max_parallel" `
2015-09-07 22:08:50 +00:00
}
// Rolling returns if a rolling strategy should be used
func ( u * UpdateStrategy ) Rolling ( ) bool {
return u . Stagger > 0 && u . MaxParallel > 0
}
2015-12-01 00:51:56 +00:00
const (
// PeriodicSpecCron is used for a cron spec.
PeriodicSpecCron = "cron"
2015-12-18 20:26:28 +00:00
// PeriodicSpecTest is only used by unit tests. It is a sorted, comma
2016-05-15 16:41:34 +00:00
// separated list of unix timestamps at which to launch.
2015-12-16 21:46:09 +00:00
PeriodicSpecTest = "_internal_test"
2015-12-01 00:51:56 +00:00
)
// Periodic defines the interval a job should be run at.
type PeriodicConfig struct {
// Enabled determines if the job should be run periodically.
Enabled bool
// Spec specifies the interval the job should be run as. It is parsed based
// on the SpecType.
Spec string
// SpecType defines the format of the spec.
SpecType string
2016-01-07 19:19:46 +00:00
// ProhibitOverlap enforces that spawned jobs do not run in parallel.
ProhibitOverlap bool ` mapstructure:"prohibit_overlap" `
2015-12-01 00:51:56 +00:00
}
2016-02-11 01:54:43 +00:00
func ( p * PeriodicConfig ) Copy ( ) * PeriodicConfig {
if p == nil {
return nil
}
np := new ( PeriodicConfig )
* np = * p
return np
}
2015-12-01 00:51:56 +00:00
func ( p * PeriodicConfig ) Validate ( ) error {
if ! p . Enabled {
return nil
}
2015-12-01 00:56:44 +00:00
if p . Spec == "" {
return fmt . Errorf ( "Must specify a spec" )
2015-12-01 00:51:56 +00:00
}
switch p . SpecType {
case PeriodicSpecCron :
// Validate the cron spec
if _ , err := cronexpr . Parse ( p . Spec ) ; err != nil {
return fmt . Errorf ( "Invalid cron spec %q: %v" , p . Spec , err )
}
2015-12-18 20:26:28 +00:00
case PeriodicSpecTest :
// No-op
2015-12-01 00:51:56 +00:00
default :
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return fmt . Errorf ( "Unknown periodic specification type %q" , p . SpecType )
2015-12-01 00:51:56 +00:00
}
return nil
}
// Next returns the closest time instant matching the spec that is after the
// passed time. If no matching instance exists, the zero value of time.Time is
// returned. The `time.Location` of the returned value matches that of the
// passed time.
func ( p * PeriodicConfig ) Next ( fromTime time . Time ) time . Time {
switch p . SpecType {
case PeriodicSpecCron :
if e , err := cronexpr . Parse ( p . Spec ) ; err == nil {
return e . Next ( fromTime )
}
2015-12-18 20:26:28 +00:00
case PeriodicSpecTest :
split := strings . Split ( p . Spec , "," )
if len ( split ) == 1 && split [ 0 ] == "" {
return time . Time { }
}
// Parse the times
times := make ( [ ] time . Time , len ( split ) )
for i , s := range split {
unix , err := strconv . Atoi ( s )
if err != nil {
return time . Time { }
}
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times [ i ] = time . Unix ( int64 ( unix ) , 0 )
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}
// Find the next match
for _ , next := range times {
if fromTime . Before ( next ) {
return next
}
}
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}
return time . Time { }
}
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const (
// PeriodicLaunchSuffix is the string appended to the periodic jobs ID
// when launching derived instances of it.
PeriodicLaunchSuffix = "/periodic-"
)
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// PeriodicLaunch tracks the last launch time of a periodic job.
type PeriodicLaunch struct {
ID string // ID of the periodic job.
Launch time . Time // The last launch time.
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// Raft Indexes
CreateIndex uint64
ModifyIndex uint64
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}
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var (
defaultServiceJobRestartPolicy = RestartPolicy {
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Delay : 15 * time . Second ,
Attempts : 2 ,
Interval : 1 * time . Minute ,
Mode : RestartPolicyModeDelay ,
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}
defaultBatchJobRestartPolicy = RestartPolicy {
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Delay : 15 * time . Second ,
Attempts : 15 ,
Interval : 7 * 24 * time . Hour ,
Mode : RestartPolicyModeDelay ,
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}
)
const (
// RestartPolicyModeDelay causes an artificial delay till the next interval is
// reached when the specified attempts have been reached in the interval.
RestartPolicyModeDelay = "delay"
// RestartPolicyModeFail causes a job to fail if the specified number of
// attempts are reached within an interval.
RestartPolicyModeFail = "fail"
)
// RestartPolicy configures how Tasks are restarted when they crash or fail.
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type RestartPolicy struct {
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// Attempts is the number of restart that will occur in an interval.
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Attempts int
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// Interval is a duration in which we can limit the number of restarts
// within.
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Interval time . Duration
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// Delay is the time between a failure and a restart.
Delay time . Duration
// Mode controls what happens when the task restarts more than attempt times
// in an interval.
Mode string
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}
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func ( r * RestartPolicy ) Copy ( ) * RestartPolicy {
if r == nil {
return nil
}
nrp := new ( RestartPolicy )
* nrp = * r
return nrp
}
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func ( r * RestartPolicy ) Validate ( ) error {
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switch r . Mode {
case RestartPolicyModeDelay , RestartPolicyModeFail :
default :
return fmt . Errorf ( "Unsupported restart mode: %q" , r . Mode )
}
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// Check for ambiguous/confusing settings
if r . Attempts == 0 && r . Mode != RestartPolicyModeFail {
return fmt . Errorf ( "Restart policy %q with %d attempts is ambiguous" , r . Mode , r . Attempts )
}
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if r . Interval == 0 {
return nil
}
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if time . Duration ( r . Attempts ) * r . Delay > r . Interval {
return fmt . Errorf ( "Nomad can't restart the TaskGroup %v times in an interval of %v with a delay of %v" , r . Attempts , r . Interval , r . Delay )
}
return nil
}
func NewRestartPolicy ( jobType string ) * RestartPolicy {
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switch jobType {
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case JobTypeService , JobTypeSystem :
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rp := defaultServiceJobRestartPolicy
return & rp
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case JobTypeBatch :
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rp := defaultBatchJobRestartPolicy
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return & rp
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}
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return nil
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}
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// TaskGroup is an atomic unit of placement. Each task group belongs to
// a job and may contain any number of tasks. A task group support running
// in many replicas using the same configuration..
type TaskGroup struct {
// Name of the task group
Name string
// Count is the number of replicas of this task group that should
// be scheduled.
Count int
// Constraints can be specified at a task group level and apply to
// all the tasks contained.
Constraints [ ] * Constraint
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//RestartPolicy of a TaskGroup
RestartPolicy * RestartPolicy
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// Tasks are the collection of tasks that this task group needs to run
Tasks [ ] * Task
// Meta is used to associate arbitrary metadata with this
// task group. This is opaque to Nomad.
Meta map [ string ] string
}
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func ( tg * TaskGroup ) Copy ( ) * TaskGroup {
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if tg == nil {
return nil
}
ntg := new ( TaskGroup )
* ntg = * tg
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ntg . Constraints = CopySliceConstraints ( ntg . Constraints )
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ntg . RestartPolicy = ntg . RestartPolicy . Copy ( )
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if tg . Tasks != nil {
tasks := make ( [ ] * Task , len ( ntg . Tasks ) )
for i , t := range ntg . Tasks {
tasks [ i ] = t . Copy ( )
}
ntg . Tasks = tasks
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}
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ntg . Meta = CopyMapStringString ( ntg . Meta )
return ntg
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}
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// InitFields is used to initialize fields in the TaskGroup.
func ( tg * TaskGroup ) InitFields ( job * Job ) {
// Set the default restart policy.
if tg . RestartPolicy == nil {
tg . RestartPolicy = NewRestartPolicy ( job . Type )
}
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for _ , task := range tg . Tasks {
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task . InitFields ( job , tg )
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}
}
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// Validate is used to sanity check a task group
func ( tg * TaskGroup ) Validate ( ) error {
var mErr multierror . Error
if tg . Name == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing task group name" ) )
}
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if tg . Count < 0 {
mErr . Errors = append ( mErr . Errors , errors . New ( "Task group count can't be negative" ) )
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}
if len ( tg . Tasks ) == 0 {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing tasks for task group" ) )
}
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for idx , constr := range tg . Constraints {
if err := constr . Validate ( ) ; err != nil {
outer := fmt . Errorf ( "Constraint %d validation failed: %s" , idx + 1 , err )
mErr . Errors = append ( mErr . Errors , outer )
}
}
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if tg . RestartPolicy != nil {
if err := tg . RestartPolicy . Validate ( ) ; err != nil {
mErr . Errors = append ( mErr . Errors , err )
}
} else {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Task Group %v should have a restart policy" , tg . Name ) )
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}
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// Check for duplicate tasks
tasks := make ( map [ string ] int )
for idx , task := range tg . Tasks {
if task . Name == "" {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Task %d missing name" , idx + 1 ) )
} else if existing , ok := tasks [ task . Name ] ; ok {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Task %d redefines '%s' from task %d" , idx + 1 , task . Name , existing + 1 ) )
} else {
tasks [ task . Name ] = idx
}
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}
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2015-09-15 18:23:03 +00:00
// Validate the tasks
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for _ , task := range tg . Tasks {
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if err := task . Validate ( ) ; err != nil {
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outer := fmt . Errorf ( "Task %s validation failed: %s" , task . Name , err )
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mErr . Errors = append ( mErr . Errors , outer )
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}
}
return mErr . ErrorOrNil ( )
}
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// LookupTask finds a task by name
func ( tg * TaskGroup ) LookupTask ( name string ) * Task {
for _ , t := range tg . Tasks {
if t . Name == name {
return t
}
}
return nil
}
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func ( tg * TaskGroup ) GoString ( ) string {
return fmt . Sprintf ( "*%#v" , * tg )
}
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const (
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// TODO add Consul TTL check
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ServiceCheckHTTP = "http"
ServiceCheckTCP = "tcp"
ServiceCheckScript = "script"
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// minCheckInterval is the minimum check interval permitted. Consul
// currently has its MinInterval set to 1s. Mirror that here for
// consistency.
minCheckInterval = 1 * time . Second
// minCheckTimeout is the minimum check timeout permitted for Consul
// script TTL checks.
minCheckTimeout = 1 * time . Second
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)
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// The ServiceCheck data model represents the consul health check that
// Nomad registers for a Task
type ServiceCheck struct {
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Name string // Name of the check, defaults to id
Type string // Type of the check - tcp, http, docker and script
Command string // Command is the command to run for script checks
Args [ ] string // Args is a list of argumes for script checks
Path string // path of the health check url for http type check
Protocol string // Protocol to use if check is http, defaults to http
PortLabel string ` mapstructure:"port" ` // The port to use for tcp/http checks
Interval time . Duration // Interval of the check
Timeout time . Duration // Timeout of the response from the check before consul fails the check
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}
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func ( sc * ServiceCheck ) Copy ( ) * ServiceCheck {
if sc == nil {
return nil
}
nsc := new ( ServiceCheck )
* nsc = * sc
return nsc
}
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// validate a Service's ServiceCheck
func ( sc * ServiceCheck ) validate ( ) error {
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switch strings . ToLower ( sc . Type ) {
case ServiceCheckTCP :
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if sc . Timeout < minCheckTimeout {
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return fmt . Errorf ( "timeout (%v) is lower than required minimum timeout %v" , sc . Timeout , minCheckInterval )
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}
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case ServiceCheckHTTP :
if sc . Path == "" {
return fmt . Errorf ( "http type must have a valid http path" )
}
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2016-07-09 05:25:04 +00:00
if sc . Timeout < minCheckTimeout {
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return fmt . Errorf ( "timeout (%v) is lower than required minimum timeout %v" , sc . Timeout , minCheckInterval )
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}
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case ServiceCheckScript :
if sc . Command == "" {
return fmt . Errorf ( "script type must have a valid script path" )
}
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// TODO: enforce timeout on the Client side and reenable
// validation.
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default :
return fmt . Errorf ( ` invalid type (%+q), must be one of "http", "tcp", or "script" type ` , sc . Type )
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}
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if sc . Interval < minCheckInterval {
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return fmt . Errorf ( "interval (%v) can not be lower than %v" , sc . Interval , minCheckInterval )
2015-11-17 22:25:23 +00:00
}
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2015-11-17 21:36:59 +00:00
return nil
}
2016-04-19 02:38:47 +00:00
// RequiresPort returns whether the service check requires the task has a port.
func ( sc * ServiceCheck ) RequiresPort ( ) bool {
switch sc . Type {
case ServiceCheckHTTP , ServiceCheckTCP :
return true
default :
return false
}
}
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func ( sc * ServiceCheck ) Hash ( serviceID string ) string {
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h := sha1 . New ( )
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io . WriteString ( h , serviceID )
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io . WriteString ( h , sc . Name )
io . WriteString ( h , sc . Type )
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io . WriteString ( h , sc . Command )
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io . WriteString ( h , strings . Join ( sc . Args , "" ) )
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io . WriteString ( h , sc . Path )
io . WriteString ( h , sc . Protocol )
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io . WriteString ( h , sc . PortLabel )
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io . WriteString ( h , sc . Interval . String ( ) )
io . WriteString ( h , sc . Timeout . String ( ) )
return fmt . Sprintf ( "%x" , h . Sum ( nil ) )
}
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// Service represents a Consul service definition in Nomad
type Service struct {
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// Name of the service registered with Consul. Consul defaults the
// Name to ServiceID if not specified. The Name if specified is used
// as one of the seed values when generating a Consul ServiceID.
Name string
// PortLabel is either the numeric port number or the `host:port`.
// To specify the port number using the host's Consul Advertise
// address, specify an empty host in the PortLabel (e.g. `:port`).
PortLabel string ` mapstructure:"port" `
Tags [ ] string // List of tags for the service
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Checks [ ] * ServiceCheck // List of checks associated with the service
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}
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func ( s * Service ) Copy ( ) * Service {
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if s == nil {
return nil
}
2016-06-12 23:36:49 +00:00
ns := new ( Service )
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* ns = * s
ns . Tags = CopySliceString ( ns . Tags )
2016-03-21 23:29:21 +00:00
if s . Checks != nil {
checks := make ( [ ] * ServiceCheck , len ( ns . Checks ) )
2016-02-11 17:08:20 +00:00
for i , c := range ns . Checks {
checks [ i ] = c . Copy ( )
}
2016-03-21 23:29:21 +00:00
ns . Checks = checks
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}
2016-03-21 23:29:21 +00:00
2016-02-11 01:54:43 +00:00
return ns
}
2015-12-11 00:04:04 +00:00
// InitFields interpolates values of Job, Task Group and Task in the Service
// Name. This also generates check names, service id and check ids.
2016-06-12 23:36:49 +00:00
func ( s * Service ) InitFields ( job string , taskGroup string , task string ) {
2015-12-11 00:04:04 +00:00
s . Name = args . ReplaceEnv ( s . Name , map [ string ] string {
"JOB" : job ,
"TASKGROUP" : taskGroup ,
"TASK" : task ,
"BASE" : fmt . Sprintf ( "%s-%s-%s" , job , taskGroup , task ) ,
} ,
)
for _ , check := range s . Checks {
if check . Name == "" {
2015-12-11 00:47:43 +00:00
check . Name = fmt . Sprintf ( "service: %q check" , s . Name )
2015-12-11 00:04:04 +00:00
}
}
}
// Validate checks if the Check definition is valid
2016-06-12 23:36:49 +00:00
func ( s * Service ) Validate ( ) error {
2015-11-17 21:36:59 +00:00
var mErr multierror . Error
2016-02-05 22:42:35 +00:00
2016-03-15 00:44:59 +00:00
// Ensure the service name is valid per RFC-952 §1
// (https://tools.ietf.org/html/rfc952), RFC-1123 §2.1
// (https://tools.ietf.org/html/rfc1123), and RFC-2782
// (https://tools.ietf.org/html/rfc2782).
re := regexp . MustCompile ( ` ^(?i:[a-z0-9]|[a-z0-9][a-z0-9\-] { 0,61}[a-z0-9])$ ` )
if ! re . MatchString ( s . Name ) {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "service name must be valid per RFC 1123 and can contain only alphanumeric characters or dashes and must be less than 63 characters long: %q" , s . Name ) )
2016-02-05 22:42:35 +00:00
}
2015-11-17 21:36:59 +00:00
for _ , c := range s . Checks {
2016-04-19 02:38:47 +00:00
if s . PortLabel == "" && c . RequiresPort ( ) {
2016-07-20 11:41:24 +00:00
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "check %s invalid: check requires a port but the service %+q has no port" , c . Name , s . Name ) )
2016-04-15 08:50:55 +00:00
continue
}
2016-06-14 01:19:40 +00:00
2016-06-14 01:17:43 +00:00
if err := c . validate ( ) ; err != nil {
2016-06-14 01:19:40 +00:00
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "check %s invalid: %v" , c . Name , err ) )
2015-11-17 21:36:59 +00:00
}
}
return mErr . ErrorOrNil ( )
}
2015-12-11 00:04:04 +00:00
// Hash calculates the hash of the check based on it's content and the service
// which owns it
2016-06-12 23:36:49 +00:00
func ( s * Service ) Hash ( ) string {
2015-11-23 07:27:59 +00:00
h := sha1 . New ( )
io . WriteString ( h , s . Name )
io . WriteString ( h , strings . Join ( s . Tags , "" ) )
io . WriteString ( h , s . PortLabel )
return fmt . Sprintf ( "%x" , h . Sum ( nil ) )
}
2015-12-23 00:10:30 +00:00
const (
// DefaultKillTimeout is the default timeout between signaling a task it
// will be killed and killing it.
DefaultKillTimeout = 5 * time . Second
)
2016-02-05 07:28:01 +00:00
// LogConfig provides configuration for log rotation
type LogConfig struct {
MaxFiles int ` mapstructure:"max_files" `
MaxFileSizeMB int ` mapstructure:"max_file_size" `
}
2016-02-11 00:44:31 +00:00
func DefaultLogConfig ( ) * LogConfig {
return & LogConfig {
MaxFiles : 10 ,
MaxFileSizeMB : 10 ,
}
}
2016-02-11 22:44:35 +00:00
// Validate returns an error if the log config specified are less than
2016-02-05 07:28:01 +00:00
// the minimum allowed.
2016-02-11 22:44:35 +00:00
func ( l * LogConfig ) Validate ( ) error {
2016-02-05 07:28:01 +00:00
var mErr multierror . Error
2016-02-11 22:44:35 +00:00
if l . MaxFiles < 1 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum number of files is 1; got %d" , l . MaxFiles ) )
2016-02-05 07:28:01 +00:00
}
2016-02-11 22:44:35 +00:00
if l . MaxFileSizeMB < 1 {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "minimum file size is 1MB; got %d" , l . MaxFileSizeMB ) )
2016-02-05 07:28:01 +00:00
}
return mErr . ErrorOrNil ( )
}
2015-07-03 23:57:48 +00:00
// Task is a single process typically that is executed as part of a task group.
type Task struct {
// Name of the task
Name string
// Driver is used to control which driver is used
Driver string
2016-03-23 11:57:31 +00:00
// User is used to determine which user will run the task. It defaults to
// the same user the Nomad client is being run as.
User string
2015-07-03 23:57:48 +00:00
// Config is provided to the driver to initialize
2015-11-14 02:09:42 +00:00
Config map [ string ] interface { }
2015-07-03 23:57:48 +00:00
2015-09-30 16:18:43 +00:00
// Map of environment variables to be used by the driver
Env map [ string ] string
2015-11-17 07:20:35 +00:00
// List of service definitions exposed by the Task
2016-06-12 23:36:49 +00:00
Services [ ] * Service
2015-11-17 06:37:09 +00:00
2015-07-03 23:57:48 +00:00
// Constraints can be specified at a task level and apply only to
// the particular task.
Constraints [ ] * Constraint
// Resources is the resources needed by this task
Resources * Resources
// Meta is used to associate arbitrary metadata with this
// task. This is opaque to Nomad.
Meta map [ string ] string
2015-12-23 00:10:30 +00:00
// KillTimeout is the time between signaling a task that it will be
// killed and killing it.
KillTimeout time . Duration ` mapstructure:"kill_timeout" `
2016-02-05 07:28:01 +00:00
// LogConfig provides configuration for log rotation
LogConfig * LogConfig ` mapstructure:"logs" `
2016-03-14 05:29:07 +00:00
// Artifacts is a list of artifacts to download and extract before running
// the task.
2016-03-14 18:13:43 +00:00
Artifacts [ ] * TaskArtifact
}
2016-02-10 21:44:53 +00:00
func ( t * Task ) Copy ( ) * Task {
2016-02-11 01:54:43 +00:00
if t == nil {
2016-02-10 21:44:53 +00:00
return nil
}
2016-02-11 01:54:43 +00:00
nt := new ( Task )
* nt = * t
nt . Env = CopyMapStringString ( nt . Env )
2016-06-12 23:36:49 +00:00
if t . Services != nil {
services := make ( [ ] * Service , len ( nt . Services ) )
for i , s := range nt . Services {
2016-03-21 23:29:21 +00:00
services [ i ] = s . Copy ( )
}
2016-06-12 23:36:49 +00:00
nt . Services = services
2016-02-11 01:54:43 +00:00
}
2016-03-21 23:29:21 +00:00
2016-02-11 17:08:20 +00:00
nt . Constraints = CopySliceConstraints ( nt . Constraints )
2016-02-11 01:54:43 +00:00
nt . Resources = nt . Resources . Copy ( )
nt . Meta = CopyMapStringString ( nt . Meta )
2016-03-21 23:29:21 +00:00
if t . Artifacts != nil {
2016-03-22 00:23:04 +00:00
artifacts := make ( [ ] * TaskArtifact , 0 , len ( t . Artifacts ) )
2016-03-21 23:29:21 +00:00
for _ , a := range nt . Artifacts {
artifacts = append ( artifacts , a . Copy ( ) )
}
nt . Artifacts = artifacts
2016-03-14 22:46:06 +00:00
}
2016-02-11 01:54:43 +00:00
if i , err := copystructure . Copy ( nt . Config ) ; err != nil {
nt . Config = i . ( map [ string ] interface { } )
}
return nt
2016-02-10 21:44:53 +00:00
}
2015-12-18 20:17:13 +00:00
// InitFields initializes fields in the task.
func ( t * Task ) InitFields ( job * Job , tg * TaskGroup ) {
t . InitServiceFields ( job . Name , tg . Name )
2015-12-23 00:10:30 +00:00
// Set the default timeout if it is not specified.
if t . KillTimeout == 0 {
t . KillTimeout = DefaultKillTimeout
}
2015-12-18 20:17:13 +00:00
}
// InitServiceFields interpolates values of Job, Task Group
2015-12-11 00:04:04 +00:00
// and Tasks in all the service Names of a Task. This also generates the service
// id, check id and check names.
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func ( t * Task ) InitServiceFields ( job string , taskGroup string ) {
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for _ , service := range t . Services {
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service . InitFields ( job , taskGroup , t . Name )
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}
}
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func ( t * Task ) GoString ( ) string {
return fmt . Sprintf ( "*%#v" , * t )
}
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func ( t * Task ) FindHostAndPortFor ( portLabel string ) ( string , int ) {
for _ , network := range t . Resources . Networks {
if p , ok := network . MapLabelToValues ( nil ) [ portLabel ] ; ok {
return network . IP , p
}
}
return "" , 0
}
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// Validate is used to sanity check a task
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func ( t * Task ) Validate ( ) error {
var mErr multierror . Error
if t . Name == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing task name" ) )
}
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if strings . ContainsAny ( t . Name , ` /\ ` ) {
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// We enforce this so that when creating the directory on disk it will
// not have any slashes.
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mErr . Errors = append ( mErr . Errors , errors . New ( "Task name can not include slashes" ) )
}
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if t . Driver == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing task driver" ) )
}
if t . KillTimeout . Nanoseconds ( ) < 0 {
mErr . Errors = append ( mErr . Errors , errors . New ( "KillTimeout must be a positive value" ) )
}
// Validate the resources.
if t . Resources == nil {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing task resources" ) )
} else if err := t . Resources . MeetsMinResources ( ) ; err != nil {
mErr . Errors = append ( mErr . Errors , err )
}
// Validate the log config
if t . LogConfig == nil {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing Log Config" ) )
} else if err := t . LogConfig . Validate ( ) ; err != nil {
mErr . Errors = append ( mErr . Errors , err )
}
for idx , constr := range t . Constraints {
if err := constr . Validate ( ) ; err != nil {
outer := fmt . Errorf ( "Constraint %d validation failed: %s" , idx + 1 , err )
mErr . Errors = append ( mErr . Errors , outer )
}
}
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// Validate Services
if err := validateServices ( t ) ; err != nil {
mErr . Errors = append ( mErr . Errors , err )
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}
if t . LogConfig != nil && t . Resources != nil {
logUsage := ( t . LogConfig . MaxFiles * t . LogConfig . MaxFileSizeMB )
if t . Resources . DiskMB <= logUsage {
mErr . Errors = append ( mErr . Errors ,
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fmt . Errorf ( "log storage (%d MB) must be less than requested disk capacity (%d MB)" ,
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logUsage , t . Resources . DiskMB ) )
}
}
for idx , artifact := range t . Artifacts {
if err := artifact . Validate ( ) ; err != nil {
outer := fmt . Errorf ( "Artifact %d validation failed: %v" , idx + 1 , err )
mErr . Errors = append ( mErr . Errors , outer )
}
}
return mErr . ErrorOrNil ( )
}
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// validateServices takes a task and validates the services within it are valid
// and reference ports that exist.
func validateServices ( t * Task ) error {
var mErr multierror . Error
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// Ensure that services don't ask for non-existent ports and their names are
// unique.
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servicePorts := make ( map [ string ] [ ] string )
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knownServices := make ( map [ string ] struct { } )
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for i , service := range t . Services {
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if err := service . Validate ( ) ; err != nil {
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outer := fmt . Errorf ( "service[%d] %+q validation failed: %s" , i , service . Name , err )
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mErr . Errors = append ( mErr . Errors , outer )
}
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if _ , ok := knownServices [ service . Name ] ; ok {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "service %q is duplicate" , service . Name ) )
}
knownServices [ service . Name ] = struct { } { }
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if service . PortLabel != "" {
servicePorts [ service . PortLabel ] = append ( servicePorts [ service . PortLabel ] , service . Name )
}
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// Ensure that check names are unique.
knownChecks := make ( map [ string ] struct { } )
for _ , check := range service . Checks {
if _ , ok := knownChecks [ check . Name ] ; ok {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "check %q is duplicate" , check . Name ) )
}
knownChecks [ check . Name ] = struct { } { }
}
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}
// Get the set of port labels.
portLabels := make ( map [ string ] struct { } )
if t . Resources != nil {
for _ , network := range t . Resources . Networks {
ports := network . MapLabelToValues ( nil )
for portLabel , _ := range ports {
portLabels [ portLabel ] = struct { } { }
}
}
}
// Ensure all ports referenced in services exist.
for servicePort , services := range servicePorts {
_ , ok := portLabels [ servicePort ]
if ! ok {
joined := strings . Join ( services , ", " )
err := fmt . Errorf ( "port label %q referenced by services %v does not exist" , servicePort , joined )
mErr . Errors = append ( mErr . Errors , err )
}
}
return mErr . ErrorOrNil ( )
}
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// Set of possible states for a task.
const (
TaskStatePending = "pending" // The task is waiting to be run.
TaskStateRunning = "running" // The task is currently running.
TaskStateDead = "dead" // Terminal state of task.
)
// TaskState tracks the current state of a task and events that caused state
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// transitions.
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type TaskState struct {
// The current state of the task.
State string
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// Series of task events that transition the state of the task.
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Events [ ] * TaskEvent
}
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func ( ts * TaskState ) Copy ( ) * TaskState {
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if ts == nil {
return nil
}
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copy := new ( TaskState )
copy . State = ts . State
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if ts . Events != nil {
copy . Events = make ( [ ] * TaskEvent , len ( ts . Events ) )
for i , e := range ts . Events {
copy . Events [ i ] = e . Copy ( )
}
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}
return copy
}
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// Failed returns if the task has has failed.
func ( ts * TaskState ) Failed ( ) bool {
l := len ( ts . Events )
if ts . State != TaskStateDead || l == 0 {
return false
}
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switch ts . Events [ l - 1 ] . Type {
case TaskNotRestarting , TaskArtifactDownloadFailed , TaskFailedValidation :
return true
default :
return false
}
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}
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// Successful returns whether a task finished successfully.
func ( ts * TaskState ) Successful ( ) bool {
l := len ( ts . Events )
if ts . State != TaskStateDead || l == 0 {
return false
}
e := ts . Events [ l - 1 ]
if e . Type != TaskTerminated {
return false
}
return e . ExitCode == 0
}
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const (
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// TaskDriveFailure indicates that the task could not be started due to a
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// failure in the driver.
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TaskDriverFailure = "Driver Failure"
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// TaskReceived signals that the task has been pulled by the client at the
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// given timestamp.
TaskReceived = "Received"
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// TaskFailedValidation indicates the task was invalid and as such was not
// run.
TaskFailedValidation = "Failed Validation"
// TaskStarted signals that the task was started and its timestamp can be
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// used to determine the running length of the task.
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TaskStarted = "Started"
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// TaskTerminated indicates that the task was started and exited.
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TaskTerminated = "Terminated"
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// TaskKilled indicates a user has killed the task.
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TaskKilled = "Killed"
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// TaskRestarting indicates that task terminated and is being restarted.
TaskRestarting = "Restarting"
// TaskNotRestarting indicates that the task has failed and is not being
// restarted because it has exceeded its restart policy.
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TaskNotRestarting = "Not Restarting"
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// TaskDownloadingArtifacts means the task is downloading the artifacts
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// specified in the task.
TaskDownloadingArtifacts = "Downloading Artifacts"
// TaskArtifactDownloadFailed indicates that downloading the artifacts
// failed.
TaskArtifactDownloadFailed = "Failed Artifact Download"
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)
// TaskEvent is an event that effects the state of a task and contains meta-data
// appropriate to the events type.
type TaskEvent struct {
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Type string
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Time int64 // Unix Nanosecond timestamp
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// Restart fields.
RestartReason string
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// Driver Failure fields.
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DriverError string // A driver error occurred while starting the task.
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// Task Terminated Fields.
ExitCode int // The exit code of the task.
Signal int // The signal that terminated the task.
Message string // A possible message explaining the termination of the task.
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// Task Killed Fields.
KillError string // Error killing the task.
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// TaskRestarting fields.
StartDelay int64 // The sleep period before restarting the task in unix nanoseconds.
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// Artifact Download fields
DownloadError string // Error downloading artifacts
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// Validation fields
ValidationError string // Validation error
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}
func ( te * TaskEvent ) GoString ( ) string {
return fmt . Sprintf ( "%v at %v" , te . Type , te . Time )
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}
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func ( te * TaskEvent ) Copy ( ) * TaskEvent {
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if te == nil {
return nil
}
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copy := new ( TaskEvent )
* copy = * te
return copy
}
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func NewTaskEvent ( event string ) * TaskEvent {
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return & TaskEvent {
Type : event ,
Time : time . Now ( ) . UnixNano ( ) ,
}
}
func ( e * TaskEvent ) SetDriverError ( err error ) * TaskEvent {
if err != nil {
e . DriverError = err . Error ( )
}
return e
}
func ( e * TaskEvent ) SetExitCode ( c int ) * TaskEvent {
e . ExitCode = c
return e
}
func ( e * TaskEvent ) SetSignal ( s int ) * TaskEvent {
e . Signal = s
return e
}
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func ( e * TaskEvent ) SetExitMessage ( err error ) * TaskEvent {
if err != nil {
e . Message = err . Error ( )
}
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return e
}
func ( e * TaskEvent ) SetKillError ( err error ) * TaskEvent {
if err != nil {
e . KillError = err . Error ( )
}
return e
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}
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func ( e * TaskEvent ) SetRestartDelay ( delay time . Duration ) * TaskEvent {
e . StartDelay = int64 ( delay )
return e
}
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func ( e * TaskEvent ) SetRestartReason ( reason string ) * TaskEvent {
e . RestartReason = reason
return e
}
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func ( e * TaskEvent ) SetDownloadError ( err error ) * TaskEvent {
if err != nil {
e . DownloadError = err . Error ( )
}
return e
}
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func ( e * TaskEvent ) SetValidationError ( err error ) * TaskEvent {
if err != nil {
e . ValidationError = err . Error ( )
}
return e
}
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// TaskArtifact is an artifact to download before running the task.
type TaskArtifact struct {
// GetterSource is the source to download an artifact using go-getter
GetterSource string ` mapstructure:"source" `
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// GetterOptions are options to use when downloading the artifact using
// go-getter.
GetterOptions map [ string ] string ` mapstructure:"options" `
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// RelativeDest is the download destination given relative to the task's
// directory.
RelativeDest string ` mapstructure:"destination" `
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}
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func ( ta * TaskArtifact ) Copy ( ) * TaskArtifact {
if ta == nil {
return nil
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}
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nta := new ( TaskArtifact )
* nta = * ta
nta . GetterOptions = CopyMapStringString ( ta . GetterOptions )
return nta
}
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func ( ta * TaskArtifact ) GoString ( ) string {
return fmt . Sprintf ( "%+v" , ta )
}
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func ( ta * TaskArtifact ) Validate ( ) error {
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// Verify the source
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var mErr multierror . Error
if ta . GetterSource == "" {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "source must be specified" ) )
}
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// Verify the destination doesn't escape the tasks directory
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alloc , err := filepath . Abs ( filepath . Join ( "/" , "foo/" , "bar/" ) )
if err != nil {
mErr . Errors = append ( mErr . Errors , err )
return mErr . ErrorOrNil ( )
}
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abs , err := filepath . Abs ( filepath . Join ( alloc , ta . RelativeDest ) )
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if err != nil {
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mErr . Errors = append ( mErr . Errors , err )
return mErr . ErrorOrNil ( )
}
rel , err := filepath . Rel ( alloc , abs )
if err != nil {
mErr . Errors = append ( mErr . Errors , err )
return mErr . ErrorOrNil ( )
}
if strings . HasPrefix ( rel , ".." ) {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "destination escapes task's directory" ) )
2016-03-15 02:55:30 +00:00
}
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// Verify the checksum
if check , ok := ta . GetterOptions [ "checksum" ] ; ok {
check = strings . TrimSpace ( check )
if check == "" {
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mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "checksum value can not be empty" ) )
return mErr . ErrorOrNil ( )
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}
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2016-03-14 22:46:06 +00:00
parts := strings . Split ( check , ":" )
if l := len ( parts ) ; l != 2 {
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mErr . Errors = append ( mErr . Errors , fmt . Errorf ( ` checksum must be given as "type:value"; got %q ` , check ) )
return mErr . ErrorOrNil ( )
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}
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checksumVal := parts [ 1 ]
checksumBytes , err := hex . DecodeString ( checksumVal )
if err != nil {
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mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "invalid checksum: %v" , err ) )
return mErr . ErrorOrNil ( )
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}
checksumType := parts [ 0 ]
expectedLength := 0
switch checksumType {
case "md5" :
expectedLength = md5 . Size
case "sha1" :
expectedLength = sha1 . Size
case "sha256" :
expectedLength = sha256 . Size
case "sha512" :
expectedLength = sha512 . Size
default :
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mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "unsupported checksum type: %s" , checksumType ) )
return mErr . ErrorOrNil ( )
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}
if len ( checksumBytes ) != expectedLength {
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mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "invalid %s checksum: %v" , checksumType , checksumVal ) )
return mErr . ErrorOrNil ( )
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}
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}
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2016-03-15 22:05:36 +00:00
return mErr . ErrorOrNil ( )
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}
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const (
ConstraintDistinctHosts = "distinct_hosts"
ConstraintRegex = "regexp"
ConstraintVersion = "version"
)
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// Constraints are used to restrict placement options.
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type Constraint struct {
LTarget string // Left-hand target
RTarget string // Right-hand target
Operand string // Constraint operand (<=, <, =, !=, >, >=), contains, near
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str string // Memoized string
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}
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func ( c * Constraint ) Copy ( ) * Constraint {
if c == nil {
return nil
}
nc := new ( Constraint )
* nc = * c
return nc
}
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func ( c * Constraint ) String ( ) string {
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if c . str != "" {
return c . str
}
c . str = fmt . Sprintf ( "%s %s %s" , c . LTarget , c . Operand , c . RTarget )
return c . str
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}
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func ( c * Constraint ) Validate ( ) error {
var mErr multierror . Error
if c . Operand == "" {
mErr . Errors = append ( mErr . Errors , errors . New ( "Missing constraint operand" ) )
}
// Perform additional validation based on operand
switch c . Operand {
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case ConstraintRegex :
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if _ , err := regexp . Compile ( c . RTarget ) ; err != nil {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Regular expression failed to compile: %v" , err ) )
}
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case ConstraintVersion :
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if _ , err := version . NewConstraint ( c . RTarget ) ; err != nil {
mErr . Errors = append ( mErr . Errors , fmt . Errorf ( "Version constraint is invalid: %v" , err ) )
}
}
return mErr . ErrorOrNil ( )
}
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const (
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AllocDesiredStatusRun = "run" // Allocation should run
AllocDesiredStatusStop = "stop" // Allocation should stop
AllocDesiredStatusEvict = "evict" // Allocation should stop, and was evicted
2015-08-25 23:18:37 +00:00
)
const (
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AllocClientStatusPending = "pending"
AllocClientStatusRunning = "running"
AllocClientStatusComplete = "complete"
AllocClientStatusFailed = "failed"
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AllocClientStatusLost = "lost"
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)
// Allocation is used to allocate the placement of a task group to a node.
type Allocation struct {
// ID of the allocation (UUID)
ID string
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// ID of the evaluation that generated this allocation
EvalID string
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// Name is a logical name of the allocation.
Name string
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// NodeID is the node this is being placed on
NodeID string
// Job is the parent job of the task group being allocated.
// This is copied at allocation time to avoid issues if the job
// definition is updated.
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JobID string
Job * Job
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// TaskGroup is the name of the task group that should be run
TaskGroup string
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// Resources is the total set of resources allocated as part
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// of this allocation of the task group.
Resources * Resources
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// TaskResources is the set of resources allocated to each
// task. These should sum to the total Resources.
TaskResources map [ string ] * Resources
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// Metrics associated with this allocation
Metrics * AllocMetric
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// Desired Status of the allocation on the client
DesiredStatus string
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// DesiredStatusDescription is meant to provide more human useful information
DesiredDescription string
// Status of the allocation on the client
ClientStatus string
// ClientStatusDescription is meant to provide more human useful information
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ClientDescription string
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2015-11-12 23:28:22 +00:00
// TaskStates stores the state of each task,
TaskStates map [ string ] * TaskState
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// Raft Indexes
CreateIndex uint64
ModifyIndex uint64
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// AllocModifyIndex is not updated when the client updates allocations. This
// lets the client pull only the allocs updated by the server.
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AllocModifyIndex uint64
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// CreateTime is the time the allocation has finished scheduling and been
// verified by the plan applier.
CreateTime int64
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}
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func ( a * Allocation ) Copy ( ) * Allocation {
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if a == nil {
return nil
}
na := new ( Allocation )
* na = * a
na . Job = na . Job . Copy ( )
na . Resources = na . Resources . Copy ( )
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if a . TaskResources != nil {
tr := make ( map [ string ] * Resources , len ( na . TaskResources ) )
for task , resource := range na . TaskResources {
tr [ task ] = resource . Copy ( )
}
na . TaskResources = tr
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}
na . Metrics = na . Metrics . Copy ( )
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if a . TaskStates != nil {
ts := make ( map [ string ] * TaskState , len ( na . TaskStates ) )
for task , state := range na . TaskStates {
ts [ task ] = state . Copy ( )
}
na . TaskStates = ts
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}
return na
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}
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// TerminalStatus returns if the desired or actual status is terminal and
// will no longer transition.
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func ( a * Allocation ) TerminalStatus ( ) bool {
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// First check the desired state and if that isn't terminal, check client
// state.
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switch a . DesiredStatus {
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case AllocDesiredStatusStop , AllocDesiredStatusEvict :
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return true
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default :
}
switch a . ClientStatus {
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case AllocClientStatusComplete , AllocClientStatusFailed , AllocClientStatusLost :
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return true
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default :
return false
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}
}
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// RanSuccessfully returns whether the client has ran the allocation and all
// tasks finished successfully
func ( a * Allocation ) RanSuccessfully ( ) bool {
// Handle the case the client hasn't started the allocation.
if len ( a . TaskStates ) == 0 {
return false
}
// Check to see if all the tasks finised successfully in the allocation
allSuccess := true
for _ , state := range a . TaskStates {
allSuccess = allSuccess && state . Successful ( )
}
return allSuccess
}
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// Stub returns a list stub for the allocation
func ( a * Allocation ) Stub ( ) * AllocListStub {
return & AllocListStub {
ID : a . ID ,
EvalID : a . EvalID ,
Name : a . Name ,
NodeID : a . NodeID ,
JobID : a . JobID ,
TaskGroup : a . TaskGroup ,
DesiredStatus : a . DesiredStatus ,
DesiredDescription : a . DesiredDescription ,
ClientStatus : a . ClientStatus ,
ClientDescription : a . ClientDescription ,
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TaskStates : a . TaskStates ,
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CreateIndex : a . CreateIndex ,
ModifyIndex : a . ModifyIndex ,
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CreateTime : a . CreateTime ,
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}
}
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var (
// AllocationIndexRegex is a regular expression to find the allocation index.
AllocationIndexRegex = regexp . MustCompile ( ".+\\[(\\d+)\\]$" )
)
// Index returns the index of the allocation. If the allocation is from a task
// group with count greater than 1, there will be multiple allocations for it.
func ( a * Allocation ) Index ( ) int {
matches := AllocationIndexRegex . FindStringSubmatch ( a . Name )
if len ( matches ) != 2 {
return - 1
}
index , err := strconv . Atoi ( matches [ 1 ] )
if err != nil {
return - 1
}
return index
}
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// AllocListStub is used to return a subset of alloc information
type AllocListStub struct {
ID string
EvalID string
Name string
NodeID string
JobID string
TaskGroup string
DesiredStatus string
DesiredDescription string
ClientStatus string
ClientDescription string
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TaskStates map [ string ] * TaskState
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CreateIndex uint64
ModifyIndex uint64
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CreateTime int64
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}
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// AllocMetric is used to track various metrics while attempting
// to make an allocation. These are used to debug a job, or to better
// understand the pressure within the system.
type AllocMetric struct {
// NodesEvaluated is the number of nodes that were evaluated
NodesEvaluated int
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// NodesFiltered is the number of nodes filtered due to a constraint
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NodesFiltered int
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// NodesAvailable is the number of nodes available for evaluation per DC.
NodesAvailable map [ string ] int
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// ClassFiltered is the number of nodes filtered by class
ClassFiltered map [ string ] int
// ConstraintFiltered is the number of failures caused by constraint
ConstraintFiltered map [ string ] int
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// NodesExhausted is the number of nodes skipped due to being
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// exhausted of at least one resource
NodesExhausted int
// ClassExhausted is the number of nodes exhausted by class
ClassExhausted map [ string ] int
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// DimensionExhausted provides the count by dimension or reason
DimensionExhausted map [ string ] int
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2015-07-04 00:37:01 +00:00
// Scores is the scores of the final few nodes remaining
// for placement. The top score is typically selected.
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Scores map [ string ] float64
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// AllocationTime is a measure of how long the allocation
// attempt took. This can affect performance and SLAs.
AllocationTime time . Duration
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// CoalescedFailures indicates the number of other
// allocations that were coalesced into this failed allocation.
// This is to prevent creating many failed allocations for a
// single task group.
CoalescedFailures int
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}
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func ( a * AllocMetric ) Copy ( ) * AllocMetric {
if a == nil {
return nil
}
na := new ( AllocMetric )
* na = * a
na . NodesAvailable = CopyMapStringInt ( na . NodesAvailable )
na . ClassFiltered = CopyMapStringInt ( na . ClassFiltered )
na . ConstraintFiltered = CopyMapStringInt ( na . ConstraintFiltered )
na . ClassExhausted = CopyMapStringInt ( na . ClassExhausted )
na . DimensionExhausted = CopyMapStringInt ( na . DimensionExhausted )
na . Scores = CopyMapStringFloat64 ( na . Scores )
return na
}
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func ( a * AllocMetric ) EvaluateNode ( ) {
a . NodesEvaluated += 1
}
func ( a * AllocMetric ) FilterNode ( node * Node , constraint string ) {
a . NodesFiltered += 1
if node != nil && node . NodeClass != "" {
if a . ClassFiltered == nil {
a . ClassFiltered = make ( map [ string ] int )
}
a . ClassFiltered [ node . NodeClass ] += 1
}
if constraint != "" {
if a . ConstraintFiltered == nil {
a . ConstraintFiltered = make ( map [ string ] int )
}
a . ConstraintFiltered [ constraint ] += 1
}
}
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func ( a * AllocMetric ) ExhaustedNode ( node * Node , dimension string ) {
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a . NodesExhausted += 1
if node != nil && node . NodeClass != "" {
if a . ClassExhausted == nil {
a . ClassExhausted = make ( map [ string ] int )
}
a . ClassExhausted [ node . NodeClass ] += 1
}
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if dimension != "" {
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if a . DimensionExhausted == nil {
a . DimensionExhausted = make ( map [ string ] int )
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}
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a . DimensionExhausted [ dimension ] += 1
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}
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}
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func ( a * AllocMetric ) ScoreNode ( node * Node , name string , score float64 ) {
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if a . Scores == nil {
a . Scores = make ( map [ string ] float64 )
}
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key := fmt . Sprintf ( "%s.%s" , node . ID , name )
a . Scores [ key ] = score
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}
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const (
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EvalStatusBlocked = "blocked"
EvalStatusPending = "pending"
EvalStatusComplete = "complete"
EvalStatusFailed = "failed"
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EvalStatusCancelled = "canceled"
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)
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const (
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EvalTriggerJobRegister = "job-register"
EvalTriggerJobDeregister = "job-deregister"
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EvalTriggerPeriodicJob = "periodic-job"
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EvalTriggerNodeUpdate = "node-update"
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EvalTriggerScheduled = "scheduled"
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EvalTriggerRollingUpdate = "rolling-update"
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EvalTriggerMaxPlans = "max-plan-attempts"
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)
const (
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// CoreJobEvalGC is used for the garbage collection of evaluations
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// and allocations. We periodically scan evaluations in a terminal state,
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// in which all the corresponding allocations are also terminal. We
// delete these out of the system to bound the state.
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CoreJobEvalGC = "eval-gc"
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// CoreJobNodeGC is used for the garbage collection of failed nodes.
// We periodically scan nodes in a terminal state, and if they have no
// corresponding allocations we delete these out of the system.
CoreJobNodeGC = "node-gc"
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// CoreJobJobGC is used for the garbage collection of eligible jobs. We
// periodically scan garbage collectible jobs and check if both their
// evaluations and allocations are terminal. If so, we delete these out of
// the system.
CoreJobJobGC = "job-gc"
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// CoreJobForceGC is used to force garbage collection of all GCable objects.
CoreJobForceGC = "force-gc"
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)
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// Evaluation is used anytime we need to apply business logic as a result
// of a change to our desired state (job specification) or the emergent state
// (registered nodes). When the inputs change, we need to "evaluate" them,
// potentially taking action (allocation of work) or doing nothing if the state
// of the world does not require it.
type Evaluation struct {
// ID is a randonly generated UUID used for this evaluation. This
// is assigned upon the creation of the evaluation.
ID string
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// Priority is used to control scheduling importance and if this job
// can preempt other jobs.
Priority int
// Type is used to control which schedulers are available to handle
// this evaluation.
Type string
2015-07-24 05:30:08 +00:00
// TriggeredBy is used to give some insight into why this Eval
// was created. (Job change, node failure, alloc failure, etc).
TriggeredBy string
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// JobID is the job this evaluation is scoped to. Evaluations cannot
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// be run in parallel for a given JobID, so we serialize on this.
JobID string
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// JobModifyIndex is the modify index of the job at the time
// the evaluation was created
JobModifyIndex uint64
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// NodeID is the node that was affected triggering the evaluation.
NodeID string
// NodeModifyIndex is the modify index of the node at the time
// the evaluation was created
NodeModifyIndex uint64
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// Status of the evaluation
Status string
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// StatusDescription is meant to provide more human useful information
StatusDescription string
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// Wait is a minimum wait time for running the eval. This is used to
// support a rolling upgrade.
Wait time . Duration
// NextEval is the evaluation ID for the eval created to do a followup.
// This is used to support rolling upgrades, where we need a chain of evaluations.
NextEval string
// PreviousEval is the evaluation ID for the eval creating this one to do a followup.
// This is used to support rolling upgrades, where we need a chain of evaluations.
PreviousEval string
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// BlockedEval is the evaluation ID for a created blocked eval. A
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// blocked eval will be created if all allocations could not be placed due
// to constraints or lacking resources.
2016-05-25 01:12:59 +00:00
BlockedEval string
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2016-05-19 01:11:40 +00:00
// FailedTGAllocs are task groups which have allocations that could not be
// made, but the metrics are persisted so that the user can use the feedback
// to determine the cause.
FailedTGAllocs map [ string ] * AllocMetric
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// ClassEligibility tracks computed node classes that have been explicitly
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// marked as eligible or ineligible.
ClassEligibility map [ string ] bool
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// EscapedComputedClass marks whether the job has constraints that are not
// captured by computed node classes.
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EscapedComputedClass bool
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2016-05-05 18:21:58 +00:00
// AnnotatePlan triggers the scheduler to provide additional annotations
// during the evaluation. This should not be set during normal operations.
AnnotatePlan bool
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// SnapshotIndex is the Raft index of the snapshot used to process the
// evaluation. As such it will only be set once it has gone through the
// scheduler.
SnapshotIndex uint64
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// Raft Indexes
CreateIndex uint64
ModifyIndex uint64
}
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// TerminalStatus returns if the current status is terminal and
// will no longer transition.
func ( e * Evaluation ) TerminalStatus ( ) bool {
switch e . Status {
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case EvalStatusComplete , EvalStatusFailed , EvalStatusCancelled :
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return true
default :
return false
}
}
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func ( e * Evaluation ) GoString ( ) string {
return fmt . Sprintf ( "<Eval '%s' JobID: '%s'>" , e . ID , e . JobID )
}
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func ( e * Evaluation ) Copy ( ) * Evaluation {
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if e == nil {
return nil
}
2015-08-15 21:16:40 +00:00
ne := new ( Evaluation )
* ne = * e
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// Copy ClassEligibility
if e . ClassEligibility != nil {
classes := make ( map [ string ] bool , len ( e . ClassEligibility ) )
for class , elig := range e . ClassEligibility {
classes [ class ] = elig
}
ne . ClassEligibility = classes
}
// Copy FailedTGAllocs
if e . FailedTGAllocs != nil {
failedTGs := make ( map [ string ] * AllocMetric , len ( e . FailedTGAllocs ) )
for tg , metric := range e . FailedTGAllocs {
failedTGs [ tg ] = metric . Copy ( )
}
ne . FailedTGAllocs = failedTGs
}
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return ne
}
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// ShouldEnqueue checks if a given evaluation should be enqueued into the
// eval_broker
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func ( e * Evaluation ) ShouldEnqueue ( ) bool {
switch e . Status {
case EvalStatusPending :
return true
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case EvalStatusComplete , EvalStatusFailed , EvalStatusBlocked , EvalStatusCancelled :
2016-01-29 23:31:32 +00:00
return false
default :
panic ( fmt . Sprintf ( "unhandled evaluation (%s) status %s" , e . ID , e . Status ) )
}
}
// ShouldBlock checks if a given evaluation should be entered into the blocked
// eval tracker.
func ( e * Evaluation ) ShouldBlock ( ) bool {
switch e . Status {
case EvalStatusBlocked :
return true
2016-01-31 00:16:13 +00:00
case EvalStatusComplete , EvalStatusFailed , EvalStatusPending , EvalStatusCancelled :
2015-08-06 18:28:55 +00:00
return false
default :
panic ( fmt . Sprintf ( "unhandled evaluation (%s) status %s" , e . ID , e . Status ) )
}
}
2015-08-11 23:34:06 +00:00
// MakePlan is used to make a plan from the given evaluation
// for a given Job
func ( e * Evaluation ) MakePlan ( j * Job ) * Plan {
p := & Plan {
EvalID : e . ID ,
2015-08-13 23:29:28 +00:00
Priority : e . Priority ,
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Job : j ,
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NodeUpdate : make ( map [ string ] [ ] * Allocation ) ,
2015-08-11 23:34:06 +00:00
NodeAllocation : make ( map [ string ] [ ] * Allocation ) ,
}
2015-08-13 23:29:28 +00:00
if j != nil {
p . AllAtOnce = j . AllAtOnce
}
2015-08-11 23:34:06 +00:00
return p
}
2015-09-07 22:08:50 +00:00
// NextRollingEval creates an evaluation to followup this eval for rolling updates
func ( e * Evaluation ) NextRollingEval ( wait time . Duration ) * Evaluation {
return & Evaluation {
ID : GenerateUUID ( ) ,
Priority : e . Priority ,
Type : e . Type ,
TriggeredBy : EvalTriggerRollingUpdate ,
JobID : e . JobID ,
JobModifyIndex : e . JobModifyIndex ,
Status : EvalStatusPending ,
Wait : wait ,
PreviousEval : e . ID ,
}
}
2016-05-25 01:12:59 +00:00
// CreateBlockedEval creates a blocked evaluation to followup this eval to place any
2016-05-15 16:41:34 +00:00
// failed allocations. It takes the classes marked explicitly eligible or
2016-01-28 21:43:48 +00:00
// ineligible and whether the job has escaped computed node classes.
2016-05-25 01:12:59 +00:00
func ( e * Evaluation ) CreateBlockedEval ( classEligibility map [ string ] bool , escaped bool ) * Evaluation {
2016-01-28 21:43:48 +00:00
return & Evaluation {
ID : GenerateUUID ( ) ,
Priority : e . Priority ,
Type : e . Type ,
TriggeredBy : e . TriggeredBy ,
JobID : e . JobID ,
JobModifyIndex : e . JobModifyIndex ,
Status : EvalStatusBlocked ,
PreviousEval : e . ID ,
2016-01-30 01:46:44 +00:00
ClassEligibility : classEligibility ,
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EscapedComputedClass : escaped ,
}
}
2015-07-27 21:59:16 +00:00
// Plan is used to submit a commit plan for task allocations. These
// are submitted to the leader which verifies that resources have
// not been overcommitted before admiting the plan.
type Plan struct {
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// EvalID is the evaluation ID this plan is associated with
EvalID string
2015-08-12 22:44:36 +00:00
// EvalToken is used to prevent a split-brain processing of
// an evaluation. There should only be a single scheduler running
// an Eval at a time, but this could be violated after a leadership
// transition. This unique token is used to reject plans that are
// being submitted from a different leader.
EvalToken string
2015-07-27 21:59:16 +00:00
// Priority is the priority of the upstream job
Priority int
2015-07-29 00:49:45 +00:00
// AllAtOnce is used to control if incremental scheduling of task groups
// is allowed or if we must do a gang scheduling of the entire job.
// If this is false, a plan may be partially applied. Otherwise, the
// entire plan must be able to make progress.
AllAtOnce bool
2016-02-21 19:31:27 +00:00
// Job is the parent job of all the allocations in the Plan.
// Since a Plan only involves a single Job, we can reduce the size
// of the plan by only including it once.
Job * Job
2015-08-25 23:52:56 +00:00
// NodeUpdate contains all the allocations for each node. For each node,
// this is a list of the allocations to update to either stop or evict.
NodeUpdate map [ string ] [ ] * Allocation
2015-07-29 00:49:45 +00:00
// NodeAllocation contains all the allocations for each node.
// The evicts must be considered prior to the allocations.
2015-08-04 23:32:46 +00:00
NodeAllocation map [ string ] [ ] * Allocation
2015-08-15 20:27:42 +00:00
2016-05-05 18:21:58 +00:00
// Annotations contains annotations by the scheduler to be used by operators
// to understand the decisions made by the scheduler.
Annotations * PlanAnnotations
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}
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func ( p * Plan ) AppendUpdate ( alloc * Allocation , status , desc string ) {
newAlloc := new ( Allocation )
* newAlloc = * alloc
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// If the job is not set in the plan we are deregistering a job so we
// extract the job from the allocation.
if p . Job == nil && newAlloc . Job != nil {
p . Job = newAlloc . Job
}
// Normalize the job
newAlloc . Job = nil
2016-03-01 22:09:25 +00:00
// Strip the resources as it can be rebuilt.
newAlloc . Resources = nil
2015-08-26 00:06:06 +00:00
newAlloc . DesiredStatus = status
newAlloc . DesiredDescription = desc
2015-08-13 21:02:39 +00:00
node := alloc . NodeID
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existing := p . NodeUpdate [ node ]
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p . NodeUpdate [ node ] = append ( existing , newAlloc )
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}
2015-09-07 19:00:34 +00:00
func ( p * Plan ) PopUpdate ( alloc * Allocation ) {
existing := p . NodeUpdate [ alloc . NodeID ]
n := len ( existing )
if n > 0 && existing [ n - 1 ] . ID == alloc . ID {
existing = existing [ : n - 1 ]
2015-09-07 19:05:18 +00:00
if len ( existing ) > 0 {
p . NodeUpdate [ alloc . NodeID ] = existing
} else {
delete ( p . NodeUpdate , alloc . NodeID )
}
2015-09-07 19:00:34 +00:00
}
}
2015-08-13 21:02:39 +00:00
func ( p * Plan ) AppendAlloc ( alloc * Allocation ) {
node := alloc . NodeID
existing := p . NodeAllocation [ node ]
p . NodeAllocation [ node ] = append ( existing , alloc )
}
2015-08-14 01:16:32 +00:00
// IsNoOp checks if this plan would do nothing
func ( p * Plan ) IsNoOp ( ) bool {
2016-05-19 01:11:40 +00:00
return len ( p . NodeUpdate ) == 0 && len ( p . NodeAllocation ) == 0
2015-08-14 01:16:32 +00:00
}
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// PlanResult is the result of a plan submitted to the leader.
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type PlanResult struct {
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// NodeUpdate contains all the updates that were committed.
NodeUpdate map [ string ] [ ] * Allocation
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// NodeAllocation contains all the allocations that were committed.
2015-08-04 23:32:46 +00:00
NodeAllocation map [ string ] [ ] * Allocation
2015-07-29 00:49:45 +00:00
// RefreshIndex is the index the worker should refresh state up to.
// This allows all evictions and allocations to be materialized.
// If any allocations were rejected due to stale data (node state,
// over committed) this can be used to force a worker refresh.
2015-07-28 23:36:15 +00:00
RefreshIndex uint64
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// AllocIndex is the Raft index in which the evictions and
// allocations took place. This is used for the write index.
2015-07-27 22:31:49 +00:00
AllocIndex uint64
2015-07-27 21:59:16 +00:00
}
2015-08-26 00:36:52 +00:00
// IsNoOp checks if this plan result would do nothing
func ( p * PlanResult ) IsNoOp ( ) bool {
2016-05-19 01:11:40 +00:00
return len ( p . NodeUpdate ) == 0 && len ( p . NodeAllocation ) == 0
2015-08-26 00:36:52 +00:00
}
2015-08-13 22:17:24 +00:00
// FullCommit is used to check if all the allocations in a plan
// were committed as part of the result. Returns if there was
// a match, and the number of expected and actual allocations.
func ( p * PlanResult ) FullCommit ( plan * Plan ) ( bool , int , int ) {
expected := 0
actual := 0
for name , allocList := range plan . NodeAllocation {
didAlloc , _ := p . NodeAllocation [ name ]
expected += len ( allocList )
actual += len ( didAlloc )
}
return actual == expected , expected , actual
}
2016-05-05 18:21:58 +00:00
// PlanAnnotations holds annotations made by the scheduler to give further debug
// information to operators.
type PlanAnnotations struct {
// DesiredTGUpdates is the set of desired updates per task group.
DesiredTGUpdates map [ string ] * DesiredUpdates
}
// DesiredUpdates is the set of changes the scheduler would like to make given
// sufficient resources and cluster capacity.
type DesiredUpdates struct {
Ignore uint64
Place uint64
Migrate uint64
Stop uint64
InPlaceUpdate uint64
DestructiveUpdate uint64
}
2015-06-05 22:21:17 +00:00
// msgpackHandle is a shared handle for encoding/decoding of structs
2015-11-18 23:16:42 +00:00
var MsgpackHandle = func ( ) * codec . MsgpackHandle {
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h := & codec . MsgpackHandle { RawToString : true }
// Sets the default type for decoding a map into a nil interface{}.
// This is necessary in particular because we store the driver configs as a
// nil interface{}.
h . MapType = reflect . TypeOf ( map [ string ] interface { } ( nil ) )
return h
} ( )
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var HashiMsgpackHandle = func ( ) * hcodec . MsgpackHandle {
h := & hcodec . MsgpackHandle { RawToString : true }
// Sets the default type for decoding a map into a nil interface{}.
// This is necessary in particular because we store the driver configs as a
// nil interface{}.
h . MapType = reflect . TypeOf ( map [ string ] interface { } ( nil ) )
return h
} ( )
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// Decode is used to decode a MsgPack encoded object
func Decode ( buf [ ] byte , out interface { } ) error {
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return codec . NewDecoder ( bytes . NewReader ( buf ) , MsgpackHandle ) . Decode ( out )
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}
// Encode is used to encode a MsgPack object with type prefix
func Encode ( t MessageType , msg interface { } ) ( [ ] byte , error ) {
var buf bytes . Buffer
buf . WriteByte ( uint8 ( t ) )
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err := codec . NewEncoder ( & buf , MsgpackHandle ) . Encode ( msg )
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return buf . Bytes ( ) , err
}