package netmap import ( "fmt" "sort" "github.com/nspcc-dev/hrw" "github.com/nspcc-dev/neofs-api-go/v2/netmap" subnetid "github.com/nspcc-dev/neofs-sdk-go/subnet/id" ) // Selector represents v2-compatible netmap selector. type Selector netmap.Selector // processSelectors processes selectors and returns error is any of them is invalid. func (c *Context) processSelectors(p *PlacementPolicy) error { selectors := p.Selectors() for i, s := range selectors { if s.Filter() != MainFilterName { _, ok := c.Filters[s.Filter()] if !ok { return fmt.Errorf("%w: SELECT FROM '%s'", ErrFilterNotFound, s.Filter()) } } c.Selectors[s.Name()] = &selectors[i] result, err := c.getSelection(p, &s) if err != nil { return err } c.Selections[s.Name()] = result } return nil } // GetNodesCount returns amount of buckets and minimum number of nodes in every bucket // for the given selector. func GetNodesCount(_ *PlacementPolicy, s *Selector) (int, int) { switch s.Clause() { case ClauseSame: return 1, int(s.Count()) default: return int(s.Count()), 1 } } // getSelection returns nodes grouped by s.attribute. // Last argument specifies if more buckets can be used to fulfill CBF. func (c *Context) getSelection(p *PlacementPolicy, s *Selector) ([]Nodes, error) { bucketCount, nodesInBucket := GetNodesCount(p, s) buckets := c.getSelectionBase(p.SubnetID(), s) if len(buckets) < bucketCount { return nil, fmt.Errorf("%w: '%s'", ErrNotEnoughNodes, s.Name()) } // We need deterministic output in case there is no pivot. // If pivot is set, buckets are sorted by HRW. // However, because initial order influences HRW order for buckets with equal weights, // we also need to have deterministic input to HRW sorting routine. if len(c.pivot) == 0 { if s.Attribute() == "" { sort.Slice(buckets, func(i, j int) bool { return buckets[i].nodes[0].ID < buckets[j].nodes[0].ID }) } else { sort.Slice(buckets, func(i, j int) bool { return buckets[i].attr < buckets[j].attr }) } } maxNodesInBucket := nodesInBucket * int(c.cbf) nodes := make([]Nodes, 0, len(buckets)) fallback := make([]Nodes, 0, len(buckets)) for i := range buckets { ns := buckets[i].nodes if len(ns) >= maxNodesInBucket { nodes = append(nodes, ns[:maxNodesInBucket]) } else if len(ns) >= nodesInBucket { fallback = append(fallback, ns) } } if len(nodes) < bucketCount { // Fallback to using minimum allowed backup factor (1). nodes = append(nodes, fallback...) if len(nodes) < bucketCount { return nil, fmt.Errorf("%w: '%s'", ErrNotEnoughNodes, s.Name()) } } if len(c.pivot) != 0 { weights := make([]float64, len(nodes)) for i := range nodes { weights[i] = GetBucketWeight(nodes[i], c.aggregator(), c.weightFunc) } hrw.SortSliceByWeightValue(nodes, weights, c.pivotHash) } if s.Attribute() == "" { nodes, fallback = nodes[:bucketCount], nodes[bucketCount:] for i := range fallback { index := i % bucketCount if len(nodes[index]) >= maxNodesInBucket { break } nodes[index] = append(nodes[index], fallback[i]...) } } return nodes[:bucketCount], nil } type nodeAttrPair struct { attr string nodes Nodes } // getSelectionBase returns nodes grouped by selector attribute. // It it guaranteed that each pair will contain at least one node. func (c *Context) getSelectionBase(subnetID *subnetid.ID, s *Selector) []nodeAttrPair { f := c.Filters[s.Filter()] isMain := s.Filter() == MainFilterName result := []nodeAttrPair{} nodeMap := map[string]Nodes{} attr := s.Attribute() for i := range c.Netmap.Nodes { var sid subnetid.ID if subnetID != nil { sid = *subnetID } // TODO(fyrchik): make `BelongsToSubnet` to accept pointer if !BelongsToSubnet(c.Netmap.Nodes[i].NodeInfo, sid) { continue } if isMain || c.match(f, &c.Netmap.Nodes[i]) { if attr == "" { // Default attribute is transparent identifier which is different for every node. result = append(result, nodeAttrPair{attr: "", nodes: Nodes{c.Netmap.Nodes[i]}}) } else { v := c.Netmap.Nodes[i].Attribute(attr) nodeMap[v] = append(nodeMap[v], c.Netmap.Nodes[i]) } } } if attr != "" { for k, ns := range nodeMap { result = append(result, nodeAttrPair{attr: k, nodes: ns}) } } if len(c.pivot) != 0 { for i := range result { hrw.SortSliceByWeightValue(result[i].nodes, result[i].nodes.Weights(c.weightFunc), c.pivotHash) } } return result } // NewSelector creates and returns new Selector instance. // // Defaults: // - name: ""; // - attribute: ""; // - filter: ""; // - clause: ClauseUnspecified; // - count: 0. func NewSelector() *Selector { return NewSelectorFromV2(new(netmap.Selector)) } // NewSelectorFromV2 converts v2 Selector to Selector. // // Nil netmap.Selector converts to nil. func NewSelectorFromV2(f *netmap.Selector) *Selector { return (*Selector)(f) } // ToV2 converts Selector to v2 Selector. // // Nil Selector converts to nil. func (s *Selector) ToV2() *netmap.Selector { return (*netmap.Selector)(s) } // Name returns selector name. func (s *Selector) Name() string { return (*netmap.Selector)(s). GetName() } // SetName sets selector name. func (s *Selector) SetName(name string) { (*netmap.Selector)(s). SetName(name) } // Count returns count of nodes to select from bucket. func (s *Selector) Count() uint32 { return (*netmap.Selector)(s). GetCount() } // SetCount sets count of nodes to select from bucket. func (s *Selector) SetCount(c uint32) { (*netmap.Selector)(s). SetCount(c) } // Clause returns modifier showing how to form a bucket. func (s *Selector) Clause() Clause { return ClauseFromV2( (*netmap.Selector)(s). GetClause(), ) } // SetClause sets modifier showing how to form a bucket. func (s *Selector) SetClause(c Clause) { (*netmap.Selector)(s). SetClause(c.ToV2()) } // Attribute returns attribute bucket to select from. func (s *Selector) Attribute() string { return (*netmap.Selector)(s). GetAttribute() } // SetAttribute sets attribute bucket to select from. func (s *Selector) SetAttribute(a string) { (*netmap.Selector)(s). SetAttribute(a) } // Filter returns filter reference to select from. func (s *Selector) Filter() string { return (*netmap.Selector)(s). GetFilter() } // SetFilter sets filter reference to select from. func (s *Selector) SetFilter(f string) { (*netmap.Selector)(s). SetFilter(f) } // Marshal marshals Selector into a protobuf binary form. func (s *Selector) Marshal() ([]byte, error) { return (*netmap.Selector)(s).StableMarshal(nil), nil } // Unmarshal unmarshals protobuf binary representation of Selector. func (s *Selector) Unmarshal(data []byte) error { return (*netmap.Selector)(s).Unmarshal(data) } // MarshalJSON encodes Selector to protobuf JSON format. func (s *Selector) MarshalJSON() ([]byte, error) { return (*netmap.Selector)(s).MarshalJSON() } // UnmarshalJSON decodes Selector from protobuf JSON format. func (s *Selector) UnmarshalJSON(data []byte) error { return (*netmap.Selector)(s).UnmarshalJSON(data) }