package jobspec import ( "bytes" "fmt" "io" "os" "path/filepath" "regexp" "strconv" "strings" "time" "github.com/hashicorp/hcl" hclobj "github.com/hashicorp/hcl/hcl" "github.com/hashicorp/nomad/nomad/structs" "github.com/mitchellh/mapstructure" ) // Parse parses the job spec from the given io.Reader. // // Due to current internal limitations, the entire contents of the // io.Reader will be copied into memory first before parsing. func Parse(r io.Reader) (*structs.Job, error) { // Copy the reader into an in-memory buffer first since HCL requires it. var buf bytes.Buffer if _, err := io.Copy(&buf, r); err != nil { return nil, err } // Parse the buffer obj, err := hcl.Parse(buf.String()) if err != nil { return nil, fmt.Errorf("error parsing: %s", err) } buf.Reset() var job structs.Job // Parse the job out jobO := obj.Get("job", false) if jobO == nil { return nil, fmt.Errorf("'job' stanza not found") } if err := parseJob(&job, jobO); err != nil { return nil, fmt.Errorf("error parsing 'job': %s", err) } return &job, nil } // ParseFile parses the given path as a job spec. func ParseFile(path string) (*structs.Job, error) { path, err := filepath.Abs(path) if err != nil { return nil, err } f, err := os.Open(path) if err != nil { return nil, err } defer f.Close() return Parse(f) } func parseJob(result *structs.Job, obj *hclobj.Object) error { if obj.Len() > 1 { return fmt.Errorf("only one 'job' block allowed") } // Get our job object obj = obj.Elem(true)[0] // Decode the full thing into a map[string]interface for ease var m map[string]interface{} if err := hcl.DecodeObject(&m, obj); err != nil { return err } delete(m, "constraint") delete(m, "meta") delete(m, "update") // Set the ID and name to the object key result.ID = obj.Key result.Name = obj.Key // Defaults result.Priority = 50 result.Region = "global" result.Type = "service" // Decode the rest if err := mapstructure.WeakDecode(m, result); err != nil { return err } // Parse constraints if o := obj.Get("constraint", false); o != nil { if err := parseConstraints(&result.Constraints, o); err != nil { return err } } // If we have an update strategy, then parse that if o := obj.Get("update", false); o != nil { if err := parseUpdate(&result.Update, o); err != nil { return err } } // Parse out meta fields. These are in HCL as a list so we need // to iterate over them and merge them. if metaO := obj.Get("meta", false); metaO != nil { for _, o := range metaO.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &result.Meta); err != nil { return err } } } // If we have tasks outside, do those if o := obj.Get("task", false); o != nil { var tasks []*structs.Task if err := parseTasks(&tasks, o); err != nil { return err } result.TaskGroups = make([]*structs.TaskGroup, len(tasks), len(tasks)*2) for i, t := range tasks { result.TaskGroups[i] = &structs.TaskGroup{ Name: t.Name, Count: 1, Tasks: []*structs.Task{t}, } } } // Parse the task groups if o := obj.Get("group", false); o != nil { if err := parseGroups(result, o); err != nil { return fmt.Errorf("error parsing 'group': %s", err) } } return nil } func parseGroups(result *structs.Job, obj *hclobj.Object) error { // Get all the maps of keys to the actual object objects := make(map[string]*hclobj.Object) for _, o1 := range obj.Elem(false) { for _, o2 := range o1.Elem(true) { if _, ok := objects[o2.Key]; ok { return fmt.Errorf( "group '%s' defined more than once", o2.Key) } objects[o2.Key] = o2 } } if len(objects) == 0 { return nil } // Go through each object and turn it into an actual result. collection := make([]*structs.TaskGroup, 0, len(objects)) for n, o := range objects { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } delete(m, "constraint") delete(m, "meta") delete(m, "task") // Default count to 1 if not specified if _, ok := m["count"]; !ok { m["count"] = 1 } // Build the group with the basic decode var g structs.TaskGroup g.Name = n if err := mapstructure.WeakDecode(m, &g); err != nil { return err } // Parse constraints if o := o.Get("constraint", false); o != nil { if err := parseConstraints(&g.Constraints, o); err != nil { return err } } // Parse out meta fields. These are in HCL as a list so we need // to iterate over them and merge them. if metaO := o.Get("meta", false); metaO != nil { for _, o := range metaO.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &g.Meta); err != nil { return err } } } // Parse tasks if o := o.Get("task", false); o != nil { if err := parseTasks(&g.Tasks, o); err != nil { return err } } collection = append(collection, &g) } result.TaskGroups = append(result.TaskGroups, collection...) return nil } func parseConstraints(result *[]*structs.Constraint, obj *hclobj.Object) error { for _, o := range obj.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } m["LTarget"] = m["attribute"] m["RTarget"] = m["value"] m["Operand"] = m["operator"] // If "version" is provided, set the operand // to "version" and the value to the "RTarget" if constraint, ok := m[structs.ConstraintVersion]; ok { m["Operand"] = structs.ConstraintVersion m["RTarget"] = constraint } // If "regexp" is provided, set the operand // to "regexp" and the value to the "RTarget" if constraint, ok := m[structs.ConstraintRegex]; ok { m["Operand"] = structs.ConstraintRegex m["RTarget"] = constraint } if value, ok := m[structs.ConstraintDistinctHosts]; ok { enabled, err := strconv.ParseBool(value.(string)) if err != nil { return err } // If it is not enabled, skip the constraint. if !enabled { continue } m["Operand"] = structs.ConstraintDistinctHosts } // Build the constraint var c structs.Constraint if err := mapstructure.WeakDecode(m, &c); err != nil { return err } if c.Operand == "" { c.Operand = "=" } *result = append(*result, &c) } return nil } func parseTasks(result *[]*structs.Task, obj *hclobj.Object) error { // Get all the maps of keys to the actual object objects := make([]*hclobj.Object, 0, 5) set := make(map[string]struct{}) for _, o1 := range obj.Elem(false) { for _, o2 := range o1.Elem(true) { if _, ok := set[o2.Key]; ok { return fmt.Errorf( "group '%s' defined more than once", o2.Key) } objects = append(objects, o2) set[o2.Key] = struct{}{} } } if len(objects) == 0 { return nil } for _, o := range objects { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } delete(m, "config") delete(m, "env") delete(m, "constraint") delete(m, "meta") delete(m, "resources") // Build the task var t structs.Task t.Name = o.Key if err := mapstructure.WeakDecode(m, &t); err != nil { return err } // If we have env, then parse them if o := o.Get("env", false); o != nil { for _, o := range o.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &t.Env); err != nil { return err } } } // If we have config, then parse that if o := o.Get("config", false); o != nil { for _, o := range o.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &t.Config); err != nil { return err } } } // Parse constraints if o := o.Get("constraint", false); o != nil { if err := parseConstraints(&t.Constraints, o); err != nil { return err } } // Parse out meta fields. These are in HCL as a list so we need // to iterate over them and merge them. if metaO := o.Get("meta", false); metaO != nil { for _, o := range metaO.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &t.Meta); err != nil { return err } } } // If we have resources, then parse that if o := o.Get("resources", false); o != nil { var r structs.Resources if err := parseResources(&r, o); err != nil { return fmt.Errorf("task '%s': %s", t.Name, err) } t.Resources = &r } *result = append(*result, &t) } return nil } var reDynamicPorts *regexp.Regexp = regexp.MustCompile("^[a-zA-Z0-9_]+$") var errDynamicPorts = fmt.Errorf("DynamicPort label does not conform to naming requirements %s", reDynamicPorts.String()) func parseResources(result *structs.Resources, obj *hclobj.Object) error { if obj.Len() > 1 { return fmt.Errorf("only one 'resource' block allowed per task") } for _, o := range obj.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } delete(m, "network") if err := mapstructure.WeakDecode(m, result); err != nil { return err } // Parse the network resources if o := o.Get("network", false); o != nil { if o.Len() > 1 { return fmt.Errorf("only one 'network' resource allowed") } var r structs.NetworkResource var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } if err := mapstructure.WeakDecode(m, &r); err != nil { return err } // Keep track of labels we've already seen so we can ensure there // are no collisions when we turn them into environment variables. // lowercase:NomalCase so we can get the first for the error message seenLabel := map[string]string{} for _, label := range r.DynamicPorts { if !reDynamicPorts.MatchString(label) { return errDynamicPorts } first, seen := seenLabel[strings.ToLower(label)] if seen { return fmt.Errorf("Found a port label collision: `%s` overlaps with previous `%s`", label, first) } else { seenLabel[strings.ToLower(label)] = label } } result.Networks = []*structs.NetworkResource{&r} } } return nil } func parseUpdate(result *structs.UpdateStrategy, obj *hclobj.Object) error { if obj.Len() > 1 { return fmt.Errorf("only one 'update' block allowed per job") } for _, o := range obj.Elem(false) { var m map[string]interface{} if err := hcl.DecodeObject(&m, o); err != nil { return err } for _, key := range []string{"stagger", "Stagger"} { if raw, ok := m[key]; ok { switch v := raw.(type) { case string: dur, err := time.ParseDuration(v) if err != nil { return fmt.Errorf("invalid stagger time '%s'", raw) } m[key] = dur case int: m[key] = time.Duration(v) * time.Second default: return fmt.Errorf("invalid type for stagger time '%s'", raw) } } } if err := mapstructure.WeakDecode(m, result); err != nil { return err } } return nil }