open-nomad/plugins/drivers/proto/driver.proto

641 lines
18 KiB
Protocol Buffer

syntax = "proto3";
package hashicorp.nomad.plugins.drivers.proto;
option go_package = "proto";
import "google/protobuf/duration.proto";
import "google/protobuf/timestamp.proto";
import "github.com/hashicorp/nomad/plugins/shared/hclspec/hcl_spec.proto";
import "github.com/hashicorp/nomad/plugins/shared/structs/proto/attribute.proto";
// Driver service defines RPCs used to communicate with a nomad runtime driver.
// Some rpcs may not be implemented by the driver based on it's capabilities.
service Driver {
// TaskConfigSchema returns the schema for parsing the driver
// configuration of a task.
rpc TaskConfigSchema(TaskConfigSchemaRequest) returns (TaskConfigSchemaResponse) {}
// Capabilities returns a set of features which the driver implements. Some
// RPCs are not possible to implement on some runtimes, this allows the
// driver to indicate if it doesn't support these RPCs and features.
rpc Capabilities(CapabilitiesRequest) returns (CapabilitiesResponse) {}
// Fingerprint starts a stream which emits information about the driver
// including whether the driver healthy and able to function in the
// existing environment.
//
// The driver should immediately stream a FingerprintResponse when the RPC
// is initially called, then send any additional responses if there is a
// change in the driver's state.
rpc Fingerprint(FingerprintRequest) returns (stream FingerprintResponse) {}
// RecoverTask is used when a task has been started but the driver may not
// know about it. Such is the case if the driver restarts or is upgraded.
rpc RecoverTask(RecoverTaskRequest) returns (RecoverTaskResponse) {}
// StartTask starts and tracks the task on the implemented runtime
rpc StartTask(StartTaskRequest) returns (StartTaskResponse) {}
// WaitTask blocks until the given task exits, returning the result of the
// task. It may be called after the task has exited, but before the task is
// destroyed.
rpc WaitTask(WaitTaskRequest) returns (WaitTaskResponse) {}
// StopTask stops a given task by sending the desired signal to the process.
// If the task does not exit on its own within the given timeout, it will be
// forcefully killed.
rpc StopTask(StopTaskRequest) returns (StopTaskResponse) {}
// DestroyTask removes the task from the driver's internal state and cleans
// up any additional resources created by the driver. It cannot be called
// on a running task, unless force is set to true.
rpc DestroyTask(DestroyTaskRequest) returns (DestroyTaskResponse) {}
// InspectTask returns detailed information for the given task
rpc InspectTask(InspectTaskRequest) returns (InspectTaskResponse) {}
// TaskStats collects and returns runtime metrics for the given task
rpc TaskStats(TaskStatsRequest) returns (stream TaskStatsResponse) {}
// TaskEvents starts a streaming RPC where all task events emitted by the
// driver are streamed to the caller.
rpc TaskEvents(TaskEventsRequest) returns (stream DriverTaskEvent) {}
// The following RPCs are only implemented if the driver sets the
// corresponding capability.
// SignalTask sends a signal to the task
rpc SignalTask(SignalTaskRequest) returns (SignalTaskResponse) {}
// ExecTask executes a command inside the tasks execution context
rpc ExecTask(ExecTaskRequest) returns (ExecTaskResponse) {}
// ExecTaskStreaming executes a command inside the tasks execution context
// and streams back results
rpc ExecTaskStreaming(stream ExecTaskStreamingRequest) returns (stream ExecTaskStreamingResponse) {}
}
message TaskConfigSchemaRequest {}
message TaskConfigSchemaResponse {
// Spec is the configuration schema for the job driver config stanza
hashicorp.nomad.plugins.shared.hclspec.Spec spec = 1;
}
message CapabilitiesRequest {}
message CapabilitiesResponse {
// Capabilities provides a way for the driver to denote if it implements
// non-core RPCs. Some Driver service RPCs expose additional information
// or functionality outside of the core task management functions. These
// RPCs are only implemented if the driver sets the corresponding capability.
DriverCapabilities capabilities = 1;
}
message FingerprintRequest {}
message FingerprintResponse {
// Attributes are key/value pairs that annotate the nomad client and can be
// used in scheduling contraints and affinities.
map<string, hashicorp.nomad.plugins.shared.structs.Attribute> attributes = 1;
enum HealthState {
UNDETECTED = 0;
UNHEALTHY = 1;
HEALTHY = 2;
}
// Health is used to determine the state of the health the driver is in.
// Health can be one of the following states:
// * UNDETECTED: driver dependencies are not met and the driver can not start
// * UNHEALTHY: driver dependencies are met but the driver is unable to
// perform operations due to some other problem
// * HEALTHY: driver is able to perform all operations
HealthState health = 2;
// HealthDescription is a human readable message describing the current
// state of driver health
string health_description = 3;
}
message RecoverTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
// Handle is the TaskHandle returned from StartTask
TaskHandle handle = 2;
}
message RecoverTaskResponse {}
message StartTaskRequest {
// Task configuration to launch
TaskConfig task = 1;
}
message StartTaskResponse {
enum Result {
SUCCESS = 0;
RETRY = 1;
FATAL = 2;
}
// Result is set depending on the type of error that occurred while starting
// a task:
//
// * SUCCESS: No error occurred, handle is set
// * RETRY: An error occurred, but is recoverable and the RPC should be retried
// * FATAL: A fatal error occurred and is not likely to succeed if retried
//
// If Result is not successful, the DriverErrorMsg will be set.
Result result = 1;
// DriverErrorMsg is set if an error occurred
string driver_error_msg = 2;
// Handle is opaque to the client, but must be stored in order to recover
// the task.
TaskHandle handle = 3;
// NetworkOverride is set if the driver sets network settings and the service ip/port
// needs to be set differently.
NetworkOverride network_override = 4;
}
message WaitTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
}
message WaitTaskResponse {
// Result is the exit status of the task
ExitResult result = 1;
// Err is set if any driver error occurred while waiting for the task
string err = 2;
}
message StopTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
// Timeout defines the amount of time to wait before forcefully killing
// the task. For example, on Unix clients, this means sending a SIGKILL to
// the process.
google.protobuf.Duration timeout = 2;
// Signal can be set to override the Task's configured shutdown signal
string signal = 3;
}
message StopTaskResponse {}
message DestroyTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
// Force destroys the task even if it is still in a running state
bool force = 2;
}
message DestroyTaskResponse {}
message InspectTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
}
message InspectTaskResponse {
// Task details
TaskStatus task = 1;
// Driver details for task
TaskDriverStatus driver = 2;
// NetworkOverride info if set
NetworkOverride network_override = 3;
}
message TaskStatsRequest {
// TaskId is the ID of the target task
string task_id = 1;
// CollectionInterval is the interval at which to stream stats to the caller
google.protobuf.Duration collection_interval = 2;
}
message TaskStatsResponse {
// Stats for the task
TaskStats stats = 1;
}
message TaskEventsRequest {}
message SignalTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
// Signal is the operating system signal to send to the task. Ex: SIGHUP
string signal = 2;
}
message SignalTaskResponse {}
message ExecTaskRequest {
// TaskId is the ID of the target task
string task_id = 1;
// Command is the command to execute in the task environment
repeated string command = 2;
// Timeout is the amount of time to wait for the command to stop.
// Defaults to 0 (run forever)
google.protobuf.Duration timeout = 3;
}
message ExecTaskResponse {
// Stdout from the exec
bytes stdout = 1;
// Stderr from the exec
bytes stderr = 2;
// Result from the exec
ExitResult result = 3;
}
message ExecTaskStreamingIOOperation {
bytes data = 1;
bool close = 2;
}
message ExecTaskStreamingRequest {
message Setup {
string task_id = 1;
repeated string command = 2;
bool tty = 3;
}
message TerminalSize {
int32 height = 1;
int32 width = 2;
}
Setup setup = 1;
TerminalSize tty_size = 2;
ExecTaskStreamingIOOperation stdin = 3;
}
message ExecTaskStreamingResponse {
ExecTaskStreamingIOOperation stdout = 1;
ExecTaskStreamingIOOperation stderr = 2;
bool exited = 3;
ExitResult result = 4;
}
message DriverCapabilities {
// SendSignals indicates that the driver can send process signals (ex. SIGUSR1)
// to the task.
bool send_signals = 1;
// Exec indicates that the driver supports executing arbitrary commands
// in the task's execution environment.
bool exec = 2;
enum FSIsolation {
NONE = 0;
CHROOT = 1;
IMAGE = 2;
}
// FsIsolation indicates what kind of filesystem isolation a driver supports.
FSIsolation fs_isolation = 3;
}
message TaskConfig {
// Id of the task, recommended to the globally unique, must be unique to the driver.
string id = 1;
// Name of the task
string name = 2;
// MsgpackDriverConfig is the encoded driver configuation of the task
bytes msgpack_driver_config = 3;
// Env is the a set of key/value pairs to be set as environment variables
map<string, string> env = 4;
// DeviceEnv is the set of environment variables that are defined by device
// plugins. This allows the driver to differentiate environment variables
// set by the device plugins and those by the user. When populating the
// task's environment env should be used.
map<string, string> device_env = 5;
// Resources defines the resources to isolate
Resources resources = 6;
// Mounts is a list of targets to bind mount into the task directory
repeated Mount mounts = 7;
// Devices is a list of system devices to mount into the task's execution
// environment.
repeated Device devices = 8;
// User defines the operating system user the tasks should run as
string user = 9;
// AllocDir is the directory on the host where the allocation directory
// exists.
string alloc_dir = 10;
// StdoutPath is the path to the file to open and write task stdout to
string stdout_path = 11;
// StderrPath is the path to the file to open and write task stderr to
string stderr_path = 12;
// TaskGroupName is the name of the task group which this task is a member of
string task_group_name = 13;
// JobName is the name of the job of which this task is part of
string job_name = 14;
// AllocId is the ID of the associated allocation
string alloc_id = 15;
}
message Resources {
// AllocatedResources are the resources set for the task
AllocatedTaskResources allocated_resources = 1;
// LinuxResources are the computed values to set for specific Linux features
LinuxResources linux_resources = 2;
}
message AllocatedTaskResources {
AllocatedCpuResources cpu = 1;
AllocatedMemoryResources memory = 2;
repeated NetworkResource networks = 5;
}
message AllocatedCpuResources {
int64 cpu_shares = 1;
}
message AllocatedMemoryResources {
int64 memory_mb = 2;
}
message NetworkResource {
string device = 1;
string cidr = 2;
string ip = 3;
int32 mbits = 4;
repeated NetworkPort reserved_ports = 5;
repeated NetworkPort dynamic_ports = 6;
}
message NetworkPort {
string label = 1;
int32 value = 2;
}
message LinuxResources {
// CPU CFS (Completely Fair Scheduler) period. Default: 0 (not specified)
int64 cpu_period = 1;
// CPU CFS (Completely Fair Scheduler) quota. Default: 0 (not specified)
int64 cpu_quota = 2;
// CPU shares (relative weight vs. other containers). Default: 0 (not specified)
int64 cpu_shares = 3;
// Memory limit in bytes. Default: 0 (not specified)
int64 memory_limit_bytes = 4;
// OOMScoreAdj adjusts the oom-killer score. Default: 0 (not specified)
int64 oom_score_adj = 5;
// CpusetCpus constrains the allowed set of logical CPUs. Default: "" (not specified)
string cpuset_cpus = 6;
// CpusetMems constrains the allowed set of memory nodes. Default: "" (not specified)
string cpuset_mems = 7;
// PercentTicks is a compatibility option for docker and should not be used
double PercentTicks = 8;
}
message Mount {
// TaskPath is the file path within the task directory to mount to
string task_path = 1;
// HostPath is the file path on the host to mount from
string host_path = 2;
// Readonly if set true, mounts the path in readonly mode
bool readonly = 3;
}
message Device {
// TaskPath is the file path within the task to mount the device to
string task_path = 1;
// HostPath is the path on the host to the source device
string host_path = 2;
// CgroupPermissions defines the Cgroup permissions of the device.
// One or more of the following options can be set:
// * r - allows the task to read from the specified device.
// * w - allows the task to write to the specified device.
// * m - allows the task to create device files that do not yet exist.
//
// Example: "rw"
string cgroup_permissions = 3;
}
enum TaskState {
UNKNOWN = 0;
RUNNING = 1;
EXITED = 2;
}
// TaskHandle is created when starting a task and is used to recover task
message TaskHandle {
// Version is used by the driver to version the DriverState schema.
// Version 0 is reserved by Nomad and should not be used.
int32 version = 1;
// Config is the TaskConfig for the task
TaskConfig config = 2;
// State is the state of the task's execution
TaskState state = 3;
// DriverState is the encoded state for the specific driver
bytes driver_state = 4;
}
// NetworkOverride contains network settings which the driver may override
// for the task, such as when the driver is setting up the task's network.
message NetworkOverride {
// PortMap can be set to replace ports with driver-specific mappings
map<string,int32> port_map = 1;
// Addr is the IP address for the task created by the driver
string addr = 2;
// AutoAdvertise indicates whether the driver thinks services that choose
// to auto_advertise_addresses should use this IP instead of the host's.
bool auto_advertise = 3;
}
// ExitResult contains information about the exit status of a task
message ExitResult {
// ExitCode returned from the task on exit
int32 exit_code = 1;
// Signal is set if a signal was sent to the task
int32 signal = 2;
// OomKilled is true if the task exited as a result of the OOM Killer
bool oom_killed = 3;
}
// TaskStatus includes information of a specific task
message TaskStatus {
string id = 1;
string name = 2;
// State is the state of the task's execution
TaskState state = 3;
// StartedAt is the timestamp when the task was started
google.protobuf.Timestamp started_at = 4;
// CompletedAt is the timestamp when the task exited.
// If the task is still running, CompletedAt will not be set
google.protobuf.Timestamp completed_at = 5;
// Result is set when CompletedAt is set.
ExitResult result = 6;
}
message TaskDriverStatus {
// Attributes is a set of string/string key value pairs specific to the
// implementing driver
map<string, string> attributes = 1;
}
message TaskStats {
// Id of the task
string id = 1;
// Timestamp for which the stats were collected
google.protobuf.Timestamp timestamp = 2;
// AggResourceUsage is the aggreate usage of all processes
TaskResourceUsage agg_resource_usage = 3;
// ResourceUsageByPid breaks the usage stats by process
map<string, TaskResourceUsage> resource_usage_by_pid = 4;
}
message TaskResourceUsage {
// CPU usage stats
CPUUsage cpu = 1;
// Memory usage stats
MemoryUsage memory = 2;
}
message CPUUsage {
double system_mode = 1;
double user_mode = 2;
double total_ticks = 3;
uint64 throttled_periods = 4;
uint64 throttled_time = 5;
double percent = 6;
enum Fields {
SYSTEM_MODE = 0;
USER_MODE = 1;
TOTAL_TICKS = 2;
THROTTLED_PERIODS = 3;
THROTTLED_TIME = 4;
PERCENT = 5;
}
// MeasuredFields indicates which fields were actually sampled
repeated Fields measured_fields = 7;
}
message MemoryUsage {
uint64 rss = 1;
uint64 cache = 2;
uint64 max_usage = 3;
uint64 kernel_usage = 4;
uint64 kernel_max_usage = 5;
uint64 usage = 7;
uint64 swap = 8;
enum Fields {
RSS = 0;
CACHE = 1;
MAX_USAGE = 2;
KERNEL_USAGE = 3;
KERNEL_MAX_USAGE = 4;
USAGE = 5;
SWAP = 6;
}
// MeasuredFields indicates which fields were actually sampled
repeated Fields measured_fields = 6;
}
message DriverTaskEvent {
// TaskId is the id of the task for the event
string task_id = 1;
// AllocId of the task for the event
string alloc_id = 2;
// TaskName is the name of the task for the event
string task_name = 3;
// Timestamp when the event occurred
google.protobuf.Timestamp timestamp = 4;
// Message is the body of the event
string message = 5;
// Annotations allows for additional key/value data to be sent along with the event
map<string,string> annotations = 6;
}