package structs import ( "fmt" "strings" "github.com/mitchellh/hashstructure" ) const ( // NodeUniqueNamespace is a prefix that can be appended to node meta or // attribute keys to mark them for exclusion in computed node class. NodeUniqueNamespace = "unique." ) // UniqueNamespace takes a key and returns the key marked under the unique // namespace. func UniqueNamespace(key string) string { return fmt.Sprintf("%s%s", NodeUniqueNamespace, key) } // IsUniqueNamespace returns whether the key is under the unique namespace. func IsUniqueNamespace(key string) bool { return strings.HasPrefix(key, NodeUniqueNamespace) } // ComputeClass computes a derived class for the node based on its attributes. // ComputedClass is a unique id that identifies nodes with a common set of // attributes and capabilities. Thus, when calculating a node's computed class // we avoid including any uniquely identifing fields. func (n *Node) ComputeClass() error { hash, err := hashstructure.Hash(n, nil) if err != nil { return err } n.ComputedClass = fmt.Sprintf("v1:%d", hash) return nil } // HashInclude is used to blacklist uniquely identifying node fields from being // included in the computed node class. func (n Node) HashInclude(field string, v interface{}) (bool, error) { switch field { case "Datacenter", "Attributes", "Meta", "NodeClass": return true, nil default: return false, nil } } // HashIncludeMap is used to blacklist uniquely identifying node map keys from being // included in the computed node class. func (n Node) HashIncludeMap(field string, k, v interface{}) (bool, error) { key, ok := k.(string) if !ok { return false, fmt.Errorf("map key %v not a string", k) } switch field { case "Meta", "Attributes": return !IsUniqueNamespace(key), nil default: return false, fmt.Errorf("unexpected map field: %v", field) } } // EscapedConstraints takes a set of constraints and returns the set that // escapes computed node classes. func EscapedConstraints(constraints []*Constraint) []*Constraint { var escaped []*Constraint for _, c := range constraints { if constraintTargetEscapes(c.LTarget) || constraintTargetEscapes(c.RTarget) { escaped = append(escaped, c) } } return escaped } // constraintTargetEscapes returns whether the target of a constraint escapes // computed node class optimization. func constraintTargetEscapes(target string) bool { switch { case strings.HasPrefix(target, "$node.unique."): return true case strings.HasPrefix(target, "$attr.unique."): return true case strings.HasPrefix(target, "$meta.unique."): return true default: return false } }