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database.go
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database.go
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package influxdb
import (
"encoding/binary"
"encoding/json"
"fmt"
"math"
"regexp"
"sort"
"strings"
"time"
"github.com/influxdb/influxdb/influxql"
)
const (
maxStringLength = 64 * 1024
)
// database is a collection of retention policies and shards. It also has methods
// for keeping an in memory index of all the measurements, series, and tags in the database.
// Methods on this struct aren't goroutine safe. They assume that the server is handling
// any locking to make things safe.
type database struct {
name string
policies map[string]*RetentionPolicy // retention policies by name
continuousQueries []*ContinuousQuery // continuous queries
defaultRetentionPolicy string
// in memory indexing structures
measurements map[string]*Measurement // measurement name to object and index
series map[uint64]*Series // map series id to the Series object
names []string // sorted list of the measurement names
}
// newDatabase returns an instance of database.
func newDatabase() *database {
return &database{
policies: make(map[string]*RetentionPolicy),
continuousQueries: make([]*ContinuousQuery, 0),
measurements: make(map[string]*Measurement),
series: make(map[uint64]*Series),
names: make([]string, 0),
}
}
// shardGroupByTimestamp returns a shard group that owns a given timestamp.
func (db *database) shardGroupByTimestamp(policy string, timestamp time.Time) (*ShardGroup, error) {
p := db.policies[policy]
if p == nil {
return nil, ErrRetentionPolicyNotFound
}
return p.shardGroupByTimestamp(timestamp), nil
}
// Series takes a series ID and returns a series.
func (db *database) Series(id uint64) *Series {
return db.series[id]
}
// MarshalJSON encodes a database into a JSON-encoded byte slice.
func (db *database) MarshalJSON() ([]byte, error) {
// Copy over properties to intermediate type.
var o databaseJSON
o.Name = db.name
o.DefaultRetentionPolicy = db.defaultRetentionPolicy
for _, rp := range db.policies {
o.Policies = append(o.Policies, rp)
}
o.ContinuousQueries = db.continuousQueries
return json.Marshal(&o)
}
// UnmarshalJSON decodes a JSON-encoded byte slice to a database.
func (db *database) UnmarshalJSON(data []byte) error {
// Decode into intermediate type.
var o databaseJSON
if err := json.Unmarshal(data, &o); err != nil {
return err
}
// Copy over properties from intermediate type.
db.name = o.Name
db.defaultRetentionPolicy = o.DefaultRetentionPolicy
// Copy shard policies.
db.policies = make(map[string]*RetentionPolicy)
for _, rp := range o.Policies {
db.policies[rp.Name] = rp
}
// we need the parsed continuous queries to be in the in memory index
db.continuousQueries = make([]*ContinuousQuery, 0, len(o.ContinuousQueries))
for _, cq := range o.ContinuousQueries {
c, _ := NewContinuousQuery(cq.Query)
db.continuousQueries = append(db.continuousQueries, c)
}
return nil
}
// databaseJSON represents the JSON-serialization format for a database.
type databaseJSON struct {
Name string `json:"name,omitempty"`
DefaultRetentionPolicy string `json:"defaultRetentionPolicy,omitempty"`
Policies []*RetentionPolicy `json:"policies,omitempty"`
ContinuousQueries []*ContinuousQuery `json:"continuousQueries,omitempty"`
}
// Measurement represents a collection of time series in a database. It also contains in memory
// structures for indexing tags. These structures are accessed through private methods on the Measurement
// object. Generally these methods are only accessed from Index, which is responsible for ensuring
// go routine safe access.
type Measurement struct {
Name string `json:"name,omitempty"`
Fields []*Field `json:"fields,omitempty"`
// in-memory index fields
series map[string]*Series // sorted tagset string to the series object
seriesByID map[uint64]*Series // lookup table for series by their id
measurement *Measurement
seriesByTagKeyValue map[string]map[string]seriesIDs // map from tag key to value to sorted set of series ids
seriesIDs seriesIDs // sorted list of series IDs in this measurement
}
// NewMeasurement allocates and initializes a new Measurement.
func NewMeasurement(name string) *Measurement {
return &Measurement{
Name: name,
Fields: make([]*Field, 0),
series: make(map[string]*Series),
seriesByID: make(map[uint64]*Series),
seriesByTagKeyValue: make(map[string]map[string]seriesIDs),
seriesIDs: make(seriesIDs, 0),
}
}
// HasTagKey returns true if at least one eries in this measurement has written a value for the passed in tag key
func (m *Measurement) HasTagKey(k string) bool {
return m.seriesByTagKeyValue[k] != nil
}
// createFieldIfNotExists creates a new field with an autoincrementing ID.
// Returns an error if 255 fields have already been created on the measurement or
// the fields already exists with a different type.
func (m *Measurement) createFieldIfNotExists(name string, typ influxql.DataType) error {
// Ignore if the field already exists.
if f := m.FieldByName(name); f != nil {
if f.Type != typ {
return ErrFieldTypeConflict
}
return nil
}
// Only 255 fields are allowed. If we go over that then return an error.
if len(m.Fields)+1 > math.MaxUint8 {
return ErrFieldOverflow
}
// Create and append a new field.
f := &Field{
ID: uint8(len(m.Fields) + 1),
Name: name,
Type: typ,
}
m.Fields = append(m.Fields, f)
return nil
}
// Field returns a field by id.
func (m *Measurement) Field(id uint8) *Field {
if int(id) > len(m.Fields) {
return nil
}
return m.Fields[id-1]
}
// FieldByName returns a field by name.
func (m *Measurement) FieldByName(name string) *Field {
for _, f := range m.Fields {
if f.Name == name {
return f
}
}
return nil
}
// addSeries will add a series to the measurementIndex. Returns false if already present
func (m *Measurement) addSeries(s *Series) bool {
if _, ok := m.seriesByID[s.ID]; ok {
return false
}
m.seriesByID[s.ID] = s
tagset := string(marshalTags(s.Tags))
m.series[tagset] = s
m.seriesIDs = append(m.seriesIDs, s.ID)
// the series ID should always be higher than all others because it's a new
// series. So don't do the sort if we don't have to.
if len(m.seriesIDs) > 1 && m.seriesIDs[len(m.seriesIDs)-1] < m.seriesIDs[len(m.seriesIDs)-2] {
sort.Sort(m.seriesIDs)
}
// add this series id to the tag index on the measurement
for k, v := range s.Tags {
valueMap := m.seriesByTagKeyValue[k]
if valueMap == nil {
valueMap = make(map[string]seriesIDs)
m.seriesByTagKeyValue[k] = valueMap
}
ids := valueMap[v]
ids = append(ids, s.ID)
// most of the time the series ID will be higher than all others because it's a new
// series. So don't do the sort if we don't have to.
if len(ids) > 1 && ids[len(ids)-1] < ids[len(ids)-2] {
sort.Sort(ids)
}
valueMap[v] = ids
}
return true
}
// dropSeries will remove a series from the measurementIndex. Returns true if already removed
func (m *Measurement) dropSeries(seriesID uint64) bool {
if _, ok := m.seriesByID[seriesID]; !ok {
return true
}
s := m.seriesByID[seriesID]
tagset := string(marshalTags(s.Tags))
delete(m.series, tagset)
delete(m.seriesByID, seriesID)
var ids []uint64
for _, id := range m.seriesIDs {
if id != seriesID {
ids = append(ids, id)
}
}
m.seriesIDs = ids
// remove this series id to the tag index on the measurement
// s.seriesByTagKeyValue is defined as map[string]map[string]seriesIDs
for k, v := range m.seriesByTagKeyValue {
values := v
for kk, vv := range values {
var ids []uint64
for _, id := range vv {
if id != seriesID {
ids = append(ids, id)
}
}
// Check to see if we have any ids, if not, remove the key
if len(ids) == 0 {
delete(values, kk)
} else {
values[kk] = ids
}
}
// If we have no values, then we delete the key
if len(values) == 0 {
delete(m.seriesByTagKeyValue, k)
} else {
m.seriesByTagKeyValue[k] = values
}
}
return true
}
// seriesByTags returns the Series that matches the given tagset.
func (m *Measurement) seriesByTags(tags map[string]string) *Series {
return m.series[string(marshalTags(tags))]
}
// filters walks the where clause of a select statement and returns a map with all series ids
// matching the where clause and any filter expression that should be applied to each
func (m *Measurement) filters(stmt *influxql.SelectStatement) (map[uint64]influxql.Expr, error) {
seriesIdsToExpr := make(map[uint64]influxql.Expr)
if stmt.Condition == nil || stmt.OnlyTimeDimensions() {
for _, id := range m.seriesIDs {
seriesIdsToExpr[id] = nil
}
return seriesIdsToExpr, nil
}
ids, _, _, err := m.walkWhereForSeriesIds(stmt.Condition, seriesIdsToExpr)
if err != nil {
return nil, err
}
// ensure every id is in the map
for _, id := range ids {
if _, ok := seriesIdsToExpr[id]; !ok {
seriesIdsToExpr[id] = nil
}
}
return seriesIdsToExpr, nil
}
// tagSets returns the unique tag sets that exist for the given tag keys. This is used to determine
// what composite series will be created by a group by. i.e. "group by region" should return:
// {"region":"uswest"}, {"region":"useast"}
// or region, service returns
// {"region": "uswest", "service": "redis"}, {"region": "uswest", "service": "mysql"}, etc...
// This will also populate the TagSet objects with the series IDs that match each tagset and any
// influx filter expression that goes with the series
func (m *Measurement) tagSets(stmt *influxql.SelectStatement, dimensions []string) ([]*influxql.TagSet, error) {
// get the unique set of series ids and the filters that should be applied to each
filters, err := m.filters(stmt)
if err != nil {
return nil, err
}
// build the tag sets
var tagStrings []string
tagSets := make(map[string]*influxql.TagSet)
for id, filter := range filters {
// get the series and set the tag values for the dimensions we care about
s := m.seriesByID[id]
tags := make([]string, len(dimensions))
for i, dim := range dimensions {
tags[i] = s.Tags[dim]
}
// marshal it into a string and put this series and its expr into the tagSets map
t := strings.Join(tags, "")
set, ok := tagSets[t]
if !ok {
tagStrings = append(tagStrings, t)
set = &influxql.TagSet{}
// set the tags for this set
tagsForSet := make(map[string]string)
for i, dim := range dimensions {
tagsForSet[dim] = tags[i]
}
set.Tags = tagsForSet
set.Key = marshalTags(tagsForSet)
}
set.AddFilter(id, filter)
tagSets[t] = set
}
// return the tag sets in sorted order
a := make([]*influxql.TagSet, 0, len(tagSets))
sort.Strings(tagStrings)
for _, s := range tagStrings {
a = append(a, tagSets[s])
}
return a, nil
}
// idsForExpr will return a collection of series ids, a bool indicating if the result should be
// used (it'll be false if it's a time expr) and a field expression if the passed in expression is against a field.
func (m *Measurement) idsForExpr(n *influxql.BinaryExpr) (seriesIDs, bool, influxql.Expr, error) {
name, ok := n.LHS.(*influxql.VarRef)
value := n.RHS
if !ok {
name, ok = n.RHS.(*influxql.VarRef)
if !ok {
return nil, false, nil, fmt.Errorf("invalid expression: %s", n.String())
}
value = n.LHS
}
// ignore time literals
if _, ok := value.(*influxql.TimeLiteral); ok || name.Val == "time" {
return nil, false, nil, nil
}
// if it's a field we can't collapse it so we have to look at all series ids for this
if m.FieldByName(name.Val) != nil {
return m.seriesIDs, true, n, nil
}
tagVals, ok := m.seriesByTagKeyValue[name.Val]
if !ok {
return nil, true, nil, nil
}
// if we're looking for series with specific tag values
if str, ok := value.(*influxql.StringLiteral); ok {
var ids seriesIDs
if n.Op == influxql.EQ {
// return series that have a tag of specific value.
ids = tagVals[str.Val]
} else if n.Op == influxql.NEQ {
ids = m.seriesIDs.reject(tagVals[str.Val])
}
return ids, true, nil, nil
}
// if we're looking for series with tag values that match a regex
if re, ok := value.(*influxql.RegexLiteral); ok {
var ids seriesIDs
// The operation is a NEQREGEX, code must start by assuming all match, even
// series without any tags.
if n.Op == influxql.NEQREGEX {
ids = m.seriesIDs
}
for k := range tagVals {
match := re.Val.MatchString(k)
if match && n.Op == influxql.EQREGEX {
ids = ids.union(tagVals[k])
} else if match && n.Op == influxql.NEQREGEX {
ids = ids.reject(tagVals[k])
}
}
return ids, true, nil, nil
}
return nil, true, nil, nil
}
// walkWhereForSeriesIds will recursively walk the where clause and return a collection of series ids, a boolean indicating if this return
// value should be included in the resulting set, and an expression if the return is a field expression.
// The map that it takes maps each series id to the field expression that should be used to evaluate it when iterating over its cursor.
// Series that have no field expressions won't be in the map
func (m *Measurement) walkWhereForSeriesIds(expr influxql.Expr, filters map[uint64]influxql.Expr) (seriesIDs, bool, influxql.Expr, error) {
switch n := expr.(type) {
case *influxql.BinaryExpr:
switch n.Op {
case influxql.EQ, influxql.NEQ, influxql.LT, influxql.LTE, influxql.GT, influxql.GTE, influxql.EQREGEX, influxql.NEQREGEX:
// if it's a compare, then it's either a field expression or against a tag. we can return this
ids, shouldInclude, expr, err := m.idsForExpr(n)
if err != nil {
return nil, false, nil, err
}
for _, id := range ids {
filters[id] = expr
}
return ids, shouldInclude, expr, nil
case influxql.AND, influxql.OR:
// if it's an AND or OR we need to union or intersect the results
var ids seriesIDs
l, il, lexpr, err := m.walkWhereForSeriesIds(n.LHS, filters)
if err != nil {
return nil, false, nil, err
}
r, ir, rexpr, err := m.walkWhereForSeriesIds(n.RHS, filters)
if err != nil {
return nil, false, nil, err
}
if il && ir { // we should include both the LHS and RHS of the BinaryExpr in the return
if n.Op == influxql.AND {
ids = l.intersect(r)
} else if n.Op == influxql.OR {
ids = l.union(r)
}
} else if !il && !ir { // we don't need to include either so return nothing
return nil, false, nil, nil
} else if il { // just include the left side
ids = l
} else { // just include the right side
ids = r
}
if n.Op == influxql.OR && il && ir && (lexpr == nil || rexpr == nil) {
// if it's an OR and we're going to include both sides and one of those expression is nil,
// we need to clear out restrictive filters on series that don't need them anymore
idsToClear := l.intersect(r)
for _, id := range idsToClear {
delete(filters, id)
}
} else {
// put the LHS field expression into the filters
if lexpr != nil {
for _, id := range ids {
f := filters[id]
if f == nil {
filters[id] = lexpr
} else {
filters[id] = &influxql.BinaryExpr{LHS: f, RHS: lexpr, Op: n.Op}
}
}
}
// put the RHS field expression into the filters
if rexpr != nil {
for _, id := range ids {
f := filters[id]
if f == nil {
filters[id] = rexpr
} else {
filters[id] = &influxql.BinaryExpr{LHS: f, RHS: rexpr, Op: n.Op}
}
}
}
// if the op is AND and we include both, clear out any of the non-intersecting ids.
// that is, filters that are no longer part of the end result set
if n.Op == influxql.AND && il && ir {
filtersToClear := l.union(r).reject(ids)
for _, id := range filtersToClear {
delete(filters, id)
}
}
}
// finally return the ids and say that we should include them
return ids, true, nil, nil
}
return m.idsForExpr(n)
case *influxql.ParenExpr:
// walk down the tree
return m.walkWhereForSeriesIds(n.Expr, filters)
default:
return nil, false, nil, nil
}
}
// expandExpr returns a list of expressions expanded by all possible tag combinations.
func (m *Measurement) expandExpr(expr influxql.Expr) []tagSetExpr {
// Retrieve list of unique values for each tag.
valuesByTagKey := m.uniqueTagValues(expr)
// Convert keys to slices.
keys := make([]string, 0, len(valuesByTagKey))
for key := range valuesByTagKey {
keys = append(keys, key)
}
sort.Strings(keys)
// Order uniques by key.
uniques := make([][]string, len(keys))
for i, key := range keys {
uniques[i] = valuesByTagKey[key]
}
// Reduce a condition for each combination of tag values.
return expandExprWithValues(expr, keys, []tagExpr{}, uniques, 0)
}
func expandExprWithValues(expr influxql.Expr, keys []string, tagExprs []tagExpr, uniques [][]string, index int) []tagSetExpr {
// If we have no more keys left then execute the reduction and return.
if index == len(keys) {
// Create a map of tag key/values.
m := make(map[string]*string, len(keys))
for i, key := range keys {
if tagExprs[i].op == influxql.EQ {
m[key] = &tagExprs[i].values[0]
} else {
m[key] = nil
}
}
// TODO: Rewrite full expressions instead of VarRef replacement.
// Reduce using the current tag key/value set.
// Ignore it if reduces down to "false".
e := influxql.Reduce(expr, &tagValuer{tags: m})
if e, ok := e.(*influxql.BooleanLiteral); ok && e.Val == false {
return nil
}
return []tagSetExpr{{values: copyTagExprs(tagExprs), expr: e}}
}
// Otherwise expand for each possible equality value of the key.
var exprs []tagSetExpr
for _, v := range uniques[index] {
exprs = append(exprs, expandExprWithValues(expr, keys, append(tagExprs, tagExpr{keys[index], []string{v}, influxql.EQ}), uniques, index+1)...)
}
exprs = append(exprs, expandExprWithValues(expr, keys, append(tagExprs, tagExpr{keys[index], uniques[index], influxql.NEQ}), uniques, index+1)...)
return exprs
}
// seriesIDsAllOrByExpr walks an expressions for matching series IDs
// or, if no expressions is given, returns all series IDs for the measurement.
func (m *Measurement) seriesIDsAllOrByExpr(expr influxql.Expr) (seriesIDs, error) {
// If no expression given or the measurement has no series,
// we can take just return the ids or nil accordingly.
if expr == nil {
return m.seriesIDs, nil
} else if len(m.seriesIDs) == 0 {
return nil, nil
}
// Get series IDs that match the WHERE clause.
filters := map[uint64]influxql.Expr{}
ids, _, _, err := m.walkWhereForSeriesIds(expr, filters)
if err != nil {
return nil, err
}
return ids, nil
}
// tagValuer is used during expression expansion to evaluate all sets of tag values.
type tagValuer struct {
tags map[string]*string
}
// Value returns the string value of a tag and true if it's listed in the tagset.
func (v *tagValuer) Value(name string) (interface{}, bool) {
if value, ok := v.tags[name]; ok {
if value == nil {
return nil, true
}
return *value, true
}
return nil, false
}
// tagSetExpr represents a set of tag keys/values and associated expression.
type tagSetExpr struct {
values []tagExpr
expr influxql.Expr
}
// tagExpr represents one or more values assigned to a given tag.
type tagExpr struct {
key string
values []string
op influxql.Token // EQ or NEQ
}
func copyTagExprs(a []tagExpr) []tagExpr {
other := make([]tagExpr, len(a))
copy(other, a)
return other
}
// uniqueTagValues returns a list of unique tag values used in an expression.
func (m *Measurement) uniqueTagValues(expr influxql.Expr) map[string][]string {
// Track unique value per tag.
tags := make(map[string]map[string]struct{})
// Find all tag values referenced in the expression.
influxql.WalkFunc(expr, func(n influxql.Node) {
switch n := n.(type) {
case *influxql.BinaryExpr:
// Ignore operators that are not equality.
if n.Op != influxql.EQ {
return
}
// Extract ref and string literal.
var key, value string
switch lhs := n.LHS.(type) {
case *influxql.VarRef:
if rhs, ok := n.RHS.(*influxql.StringLiteral); ok {
key, value = lhs.Val, rhs.Val
}
case *influxql.StringLiteral:
if rhs, ok := n.RHS.(*influxql.VarRef); ok {
key, value = rhs.Val, lhs.Val
}
}
if key == "" {
return
}
// Add value to set.
if tags[key] == nil {
tags[key] = make(map[string]struct{})
}
tags[key][value] = struct{}{}
}
})
// Convert to map of slices.
out := make(map[string][]string)
for k, values := range tags {
out[k] = make([]string, 0, len(values))
for v := range values {
out[k] = append(out[k], v)
}
sort.Strings(out[k])
}
return out
}
// Measurements represents a list of *Measurement.
type Measurements []*Measurement
func (a Measurements) Len() int { return len(a) }
func (a Measurements) Less(i, j int) bool { return a[i].Name < a[j].Name }
func (a Measurements) Swap(i, j int) { a[i], a[j] = a[j], a[i] }
func (a Measurements) intersect(other Measurements) Measurements {
l := a
r := other
// we want to iterate through the shortest one and stop
if len(other) < len(a) {
l = other
r = a
}
// they're in sorted order so advance the counter as needed.
// That is, don't run comparisons against lower values that we've already passed
var i, j int
result := make(Measurements, 0, len(l))
for i < len(l) && j < len(r) {
if l[i].Name == r[j].Name {
result = append(result, l[i])
i++
j++
} else if l[i].Name < r[j].Name {
i++
} else {
j++
}
}
return result
}
func (a Measurements) union(other Measurements) Measurements {
result := make(Measurements, 0, len(a)+len(other))
var i, j int
for i < len(a) && j < len(other) {
if a[i].Name == other[j].Name {
result = append(result, a[i])
i++
j++
} else if a[i].Name < other[j].Name {
result = append(result, a[i])
i++
} else {
result = append(result, other[j])
j++
}
}
// now append the remainder
if i < len(a) {
result = append(result, a[i:]...)
} else if j < len(other) {
result = append(result, other[j:]...)
}
return result
}
// Field represents a series field.
type Field struct {
ID uint8 `json:"id,omitempty"`
Name string `json:"name,omitempty"`
Type influxql.DataType `json:"type,omitempty"`
}
// Fields represents a list of fields.
type Fields []*Field
// FieldCodec providecs encoding and decoding functionality for the fields of a given
// Measurement. It is a distinct type to avoid locking writes on this node while
// potentially long-running queries are executing.
//
// It is not affected by changes to the Measurement object after codec creation.
type FieldCodec struct {
fieldsByID map[uint8]*Field
fieldsByName map[string]*Field
}
// NewFieldCodec returns a FieldCodec for the given Measurement. Must be called with
// a RLock that protects the Measurement.
func NewFieldCodec(m *Measurement) *FieldCodec {
fieldsByID := make(map[uint8]*Field, len(m.Fields))
fieldsByName := make(map[string]*Field, len(m.Fields))
for _, f := range m.Fields {
fieldsByID[f.ID] = f
fieldsByName[f.Name] = f
}
return &FieldCodec{fieldsByID: fieldsByID, fieldsByName: fieldsByName}
}
// EncodeFields converts a map of values with string keys to a byte slice of field
// IDs and values.
//
// If a field exists in the codec, but its type is different, an error is returned. If
// a field is not present in the codec, the system panics.
func (f *FieldCodec) EncodeFields(values map[string]interface{}) ([]byte, error) {
// Allocate byte slice
b := make([]byte, 0, 10)
for k, v := range values {
field := f.fieldsByName[k]
if field == nil {
panic(fmt.Sprintf("field does not exist for %s", k))
} else if influxql.InspectDataType(v) != field.Type {
return nil, fmt.Errorf("field \"%s\" is type %T, mapped as type %s", k, k, field.Type)
}
var buf []byte
switch field.Type {
case influxql.Float:
value := v.(float64)
buf = make([]byte, 9)
binary.BigEndian.PutUint64(buf[1:9], math.Float64bits(value))
case influxql.Integer:
var value uint64
switch v.(type) {
case int:
value = uint64(v.(int))
case int32:
value = uint64(v.(int32))
case int64:
value = uint64(v.(int64))
default:
panic(fmt.Sprintf("invalid integer type: %T", v))
}
buf = make([]byte, 9)
binary.BigEndian.PutUint64(buf[1:9], value)
case influxql.Boolean:
value := v.(bool)
// Only 1 byte need for a boolean.
buf = make([]byte, 2)
if value {
buf[1] = byte(1)
}
case influxql.String:
value := v.(string)
if len(value) > maxStringLength {
value = value[:maxStringLength]
}
// Make a buffer for field ID (1 bytes), the string length (2 bytes), and the string.
buf = make([]byte, len(value)+3)
// Set the string length, then copy the string itself.
binary.BigEndian.PutUint16(buf[1:3], uint16(len(value)))
for i, c := range []byte(value) {
buf[i+3] = byte(c)
}
default:
panic(fmt.Sprintf("unsupported value type during encode fields: %T", v))
}
// Always set the field ID as the leading byte.
buf[0] = field.ID
// Append temp buffer to the end.
b = append(b, buf...)
}
return b, nil
}
// DecodeByID scans a byte slice for a field with the given ID, converts it to its
// expected type, and return that value.
func (f *FieldCodec) DecodeByID(targetID uint8, b []byte) (interface{}, error) {
if len(b) == 0 {
return 0, ErrFieldNotFound
}
for {
if len(b) < 1 {
// No more bytes.
break
}
field, ok := f.fieldsByID[b[0]]
if !ok {
// This can happen, though is very unlikely. If this node receives encoded data, to be written
// to disk, and is queried for that data before its metastore is updated, there will be no field
// mapping for the data during decode. All this can happen because data is encoded by the node
// that first received the write request, not the node that actually writes the data to disk.
// So if this happens, the read must be aborted.
return 0, ErrFieldUnmappedID
}
var value interface{}
switch field.Type {
case influxql.Float:
// Move bytes forward.
value = math.Float64frombits(binary.BigEndian.Uint64(b[1:9]))
b = b[9:]
case influxql.Integer:
value = int64(binary.BigEndian.Uint64(b[1:9]))
b = b[9:]
case influxql.Boolean:
if b[1] == 1 {
value = true
} else {
value = false
}
// Move bytes forward.
b = b[2:]
case influxql.String:
size := binary.BigEndian.Uint16(b[1:3])
value = string(b[3 : 3+size])
// Move bytes forward.
b = b[size+3:]
default:
panic(fmt.Sprintf("unsupported value type during decode by id: %T", field.Type))
}
if field.ID == targetID {
return value, nil
}
}
return 0, ErrFieldNotFound
}
// DecodeFields decodes a byte slice into a set of field ids and values.
func (f *FieldCodec) DecodeFields(b []byte) (map[uint8]interface{}, error) {
if len(b) == 0 {
return nil, nil
}
// Create a map to hold the decoded data.
values := make(map[uint8]interface{}, 0)
for {
if len(b) < 1 {
// No more bytes.
break
}
// First byte is the field identifier.
fieldID := b[0]
field := f.fieldsByID[fieldID]
if field == nil {
// See note in DecodeByID() regarding field-mapping failures.
return nil, ErrFieldUnmappedID
}
var value interface{}
switch field.Type {
case influxql.Float:
value = math.Float64frombits(binary.BigEndian.Uint64(b[1:9]))
// Move bytes forward.
b = b[9:]
case influxql.Integer:
value = int64(binary.BigEndian.Uint64(b[1:9]))
// Move bytes forward.
b = b[9:]
case influxql.Boolean:
if b[1] == 1 {
value = true
} else {
value = false
}
// Move bytes forward.
b = b[2:]
case influxql.String:
size := binary.BigEndian.Uint16(b[1:3])
value = string(b[3 : size+3])
// Move bytes forward.
b = b[size+3:]
default:
panic(fmt.Sprintf("unsupported value type during decode fields: %T", f.fieldsByID[fieldID]))
}
values[fieldID] = value
}
return values, nil
}
// DecodeFieldsWithNames decodes a byte slice into a set of field names and values
func (f *FieldCodec) DecodeFieldsWithNames(b []byte) (map[string]interface{}, error) {
fields, err := f.DecodeFields(b)
if err != nil {
return nil, err
}
m := make(map[string]interface{})
for id, v := range fields {
field := f.fieldsByID[id]
if field != nil {
m[field.Name] = v
}
}
return m, nil
}
// FieldByName returns the field by its name. It will return a nil if not found
func (f *FieldCodec) FieldByName(name string) *Field {
return f.fieldsByName[name]
}
// Series belong to a Measurement and represent unique time series in a database
type Series struct {
ID uint64
Tags map[string]string