package scheduler import ( "fmt" "reflect" "regexp" "strconv" "strings" "github.com/hashicorp/go-version" "github.com/hashicorp/nomad/nomad/structs" ) // FeasibleIterator is used to iteratively yield nodes that // match feasibility constraints. The iterators may manage // some state for performance optimizations. type FeasibleIterator interface { // Next yields a feasible node or nil if exhausted Next() *structs.Node // Reset is invoked when an allocation has been placed // to reset any stale state. Reset() } // StaticIterator is a FeasibleIterator which returns nodes // in a static order. This is used at the base of the iterator // chain only for testing due to deterministic behavior. type StaticIterator struct { ctx Context nodes []*structs.Node offset int seen int } // NewStaticIterator constructs a random iterator from a list of nodes func NewStaticIterator(ctx Context, nodes []*structs.Node) *StaticIterator { iter := &StaticIterator{ ctx: ctx, nodes: nodes, } return iter } func (iter *StaticIterator) Next() *structs.Node { // Check if exhausted n := len(iter.nodes) if iter.offset == n || iter.seen == n { if iter.seen != n { iter.offset = 0 } else { return nil } } // Return the next offset offset := iter.offset iter.offset += 1 iter.seen += 1 iter.ctx.Metrics().EvaluateNode() return iter.nodes[offset] } func (iter *StaticIterator) Reset() { iter.seen = 0 } func (iter *StaticIterator) SetNodes(nodes []*structs.Node) { iter.nodes = nodes iter.offset = 0 iter.seen = 0 } // NewRandomIterator constructs a static iterator from a list of nodes // after applying the Fisher-Yates algorithm for a random shuffle. This // is applied in-place func NewRandomIterator(ctx Context, nodes []*structs.Node) *StaticIterator { // shuffle with the Fisher-Yates algorithm shuffleNodes(nodes) // Create a static iterator return NewStaticIterator(ctx, nodes) } // DriverIterator is a FeasibleIterator which returns nodes that // have the drivers necessary to scheduler a task group. type DriverIterator struct { ctx Context source FeasibleIterator drivers map[string]struct{} } // NewDriverIterator creates a DriverIterator from a source and set of drivers func NewDriverIterator(ctx Context, source FeasibleIterator, drivers map[string]struct{}) *DriverIterator { iter := &DriverIterator{ ctx: ctx, source: source, drivers: drivers, } return iter } func (iter *DriverIterator) SetDrivers(d map[string]struct{}) { iter.drivers = d } func (iter *DriverIterator) Next() *structs.Node { for { // Get the next option from the source option := iter.source.Next() if option == nil { return nil } // Use this node if possible if iter.hasDrivers(option) { return option } iter.ctx.Metrics().FilterNode(option, "missing drivers") } } func (iter *DriverIterator) Reset() { iter.source.Reset() } // hasDrivers is used to check if the node has all the appropriate // drivers for this task group. Drivers are registered as node attribute // like "driver.docker=1" with their corresponding version. func (iter *DriverIterator) hasDrivers(option *structs.Node) bool { for driver := range iter.drivers { driverStr := fmt.Sprintf("driver.%s", driver) value, ok := option.Attributes[driverStr] if !ok { return false } enabled, err := strconv.ParseBool(value) if err != nil { iter.ctx.Logger(). Printf("[WARN] scheduler.DriverIterator: node %v has invalid driver setting %v: %v", option.ID, driverStr, value) return false } if !enabled { return false } } return true } // ConstraintIterator is a FeasibleIterator which returns nodes // that match a given set of constraints. This is used to filter // on job, task group, and task constraints. type ConstraintIterator struct { ctx Context source FeasibleIterator constraints []*structs.Constraint } // NewConstraintIterator creates a ConstraintIterator from a source and set of constraints func NewConstraintIterator(ctx Context, source FeasibleIterator, constraints []*structs.Constraint) *ConstraintIterator { iter := &ConstraintIterator{ ctx: ctx, source: source, constraints: constraints, } return iter } func (iter *ConstraintIterator) SetConstraints(c []*structs.Constraint) { iter.constraints = c } func (iter *ConstraintIterator) Next() *structs.Node { for { // Get the next option from the source option := iter.source.Next() if option == nil { return nil } // Use this node if possible if iter.meetsConstraints(option) { return option } } } func (iter *ConstraintIterator) Reset() { iter.source.Reset() } func (iter *ConstraintIterator) meetsConstraints(option *structs.Node) bool { for _, constraint := range iter.constraints { if !iter.meetsConstraint(constraint, option) { iter.ctx.Metrics().FilterNode(option, constraint.String()) return false } } return true } func (iter *ConstraintIterator) meetsConstraint(constraint *structs.Constraint, option *structs.Node) bool { // Only enforce hard constraints, soft constraints are used for ranking if !constraint.Hard { return true } // Resolve the targets lVal, ok := resolveConstraintTarget(constraint.LTarget, option) if !ok { return false } rVal, ok := resolveConstraintTarget(constraint.RTarget, option) if !ok { return false } // Check if satisfied return checkConstraint(iter.ctx, constraint.Operand, lVal, rVal) } // resolveConstraintTarget is used to resolve the LTarget and RTarget of a Constraint func resolveConstraintTarget(target string, node *structs.Node) (interface{}, bool) { // If no prefix, this must be a literal value if !strings.HasPrefix(target, "$") { return target, true } // Handle the interpolations switch { case "$node.id" == target: return node.ID, true case "$node.datacenter" == target: return node.Datacenter, true case "$node.name" == target: return node.Name, true case strings.HasPrefix(target, "$attr."): attr := strings.TrimPrefix(target, "$attr.") val, ok := node.Attributes[attr] return val, ok case strings.HasPrefix(target, "$meta."): meta := strings.TrimPrefix(target, "$meta.") val, ok := node.Meta[meta] return val, ok default: return nil, false } } // checkConstraint checks if a constraint is satisfied func checkConstraint(ctx Context, operand string, lVal, rVal interface{}) bool { switch operand { case "=", "==", "is": return reflect.DeepEqual(lVal, rVal) case "!=", "not": return !reflect.DeepEqual(lVal, rVal) case "<", "<=", ">", ">=": return checkLexicalOrder(operand, lVal, rVal) case "version": return checkVersionConstraint(ctx, lVal, rVal) case "regexp": return checkRegexpConstraint(ctx, lVal, rVal) default: return false } } // checkLexicalOrder is used to check for lexical ordering func checkLexicalOrder(op string, lVal, rVal interface{}) bool { // Ensure the values are strings lStr, ok := lVal.(string) if !ok { return false } rStr, ok := rVal.(string) if !ok { return false } switch op { case "<": return lStr < rStr case "<=": return lStr <= rStr case ">": return lStr > rStr case ">=": return lStr >= rStr default: return false } } // checkVersionConstraint is used to compare a version on the // left hand side with a set of constraints on the right hand side func checkVersionConstraint(ctx Context, lVal, rVal interface{}) bool { // Parse the version var versionStr string switch v := lVal.(type) { case string: versionStr = v case int: versionStr = fmt.Sprintf("%d", v) default: return false } // Parse the verison vers, err := version.NewVersion(versionStr) if err != nil { return false } // Constraint must be a string constraintStr, ok := rVal.(string) if !ok { return false } // Check the cache for a match cache := ctx.ConstraintCache() constraints := cache[constraintStr] // Parse the constraints if constraints == nil { constraints, err = version.NewConstraint(constraintStr) if err != nil { return false } cache[constraintStr] = constraints } // Check the constraints against the version return constraints.Check(vers) } // checkRegexpConstraint is used to compare a value on the // left hand side with a regexp on the right hand side func checkRegexpConstraint(ctx Context, lVal, rVal interface{}) bool { // Ensure left-hand is string lStr, ok := lVal.(string) if !ok { return false } // Regexp must be a string regexpStr, ok := rVal.(string) if !ok { return false } // Check the cache cache := ctx.RegexpCache() re := cache[regexpStr] // Parse the regexp if re == nil { var err error re, err = regexp.Compile(regexpStr) if err != nil { return false } cache[regexpStr] = re } // Look for a match return re.MatchString(lStr) }