redis/search_commands.go

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package redis
import (
"context"
"fmt"
"strconv"
"github.com/redis/go-redis/v9/internal"
"github.com/redis/go-redis/v9/internal/proto"
)
type SearchCmdable interface {
FT_List(ctx context.Context) *StringSliceCmd
FTAggregate(ctx context.Context, index string, query string) *MapStringInterfaceCmd
FTAggregateWithArgs(ctx context.Context, index string, query string, options *FTAggregateOptions) *AggregateCmd
FTAliasAdd(ctx context.Context, index string, alias string) *StatusCmd
FTAliasDel(ctx context.Context, alias string) *StatusCmd
FTAliasUpdate(ctx context.Context, index string, alias string) *StatusCmd
FTAlter(ctx context.Context, index string, skipInitalScan bool, definition []interface{}) *StatusCmd
FTConfigGet(ctx context.Context, option string) *MapMapStringInterfaceCmd
FTConfigSet(ctx context.Context, option string, value interface{}) *StatusCmd
FTCreate(ctx context.Context, index string, options *FTCreateOptions, schema ...*FieldSchema) *StatusCmd
FTCursorDel(ctx context.Context, index string, cursorId int) *StatusCmd
FTCursorRead(ctx context.Context, index string, cursorId int, count int) *MapStringInterfaceCmd
FTDictAdd(ctx context.Context, dict string, term ...interface{}) *IntCmd
FTDictDel(ctx context.Context, dict string, term ...interface{}) *IntCmd
FTDictDump(ctx context.Context, dict string) *StringSliceCmd
FTDropIndex(ctx context.Context, index string) *StatusCmd
FTDropIndexWithArgs(ctx context.Context, index string, options *FTDropIndexOptions) *StatusCmd
FTExplain(ctx context.Context, index string, query string) *StringCmd
FTExplainWithArgs(ctx context.Context, index string, query string, options *FTExplainOptions) *StringCmd
FTInfo(ctx context.Context, index string) *FTInfoCmd
FTSpellCheck(ctx context.Context, index string, query string) *FTSpellCheckCmd
FTSpellCheckWithArgs(ctx context.Context, index string, query string, options *FTSpellCheckOptions) *FTSpellCheckCmd
FTSearch(ctx context.Context, index string, query string) *FTSearchCmd
FTSearchWithArgs(ctx context.Context, index string, query string, options *FTSearchOptions) *FTSearchCmd
FTSynDump(ctx context.Context, index string) *FTSynDumpCmd
FTSynUpdate(ctx context.Context, index string, synGroupId interface{}, terms []interface{}) *StatusCmd
FTSynUpdateWithArgs(ctx context.Context, index string, synGroupId interface{}, options *FTSynUpdateOptions, terms []interface{}) *StatusCmd
FTTagVals(ctx context.Context, index string, field string) *StringSliceCmd
}
type FTCreateOptions struct {
OnHash bool
OnJSON bool
Prefix []interface{}
Filter string
DefaultLanguage string
LanguageField string
Score float64
ScoreField string
PayloadField string
MaxTextFields int
NoOffsets bool
Temporary int
NoHL bool
NoFields bool
NoFreqs bool
StopWords []interface{}
SkipInitalScan bool
}
type FieldSchema struct {
FieldName string
As string
FieldType SearchFieldType
Sortable bool
UNF bool
NoStem bool
NoIndex bool
PhoneticMatcher string
Weight float64
Seperator string
CaseSensitive bool
WithSuffixtrie bool
VectorArgs *FTVectorArgs
GeoShapeFieldType string
}
type FTVectorArgs struct {
FlatOptions *FTFlatOptions
HNSWOptions *FTHNSWOptions
}
type FTFlatOptions struct {
Type string
Dim int
DistanceMetric string
InitialCapacity int
BlockSize int
}
type FTHNSWOptions struct {
Type string
Dim int
DistanceMetric string
InitialCapacity int
MaxEdgesPerNode int
MaxAllowedEdgesPerNode int
EFRunTime int
Epsilon float64
}
type FTDropIndexOptions struct {
DeleteDocs bool
}
type SpellCheckTerms struct {
Include bool
Exclude bool
Dictionary string
}
type FTExplainOptions struct {
Dialect string
}
type FTSynUpdateOptions struct {
SkipInitialScan bool
}
type SearchAggregator int
const (
SearchInvalid = SearchAggregator(iota)
SearchAvg
SearchSum
SearchMin
SearchMax
SearchCount
SearchCountDistinct
SearchCountDistinctish
SearchStdDev
SearchQuantile
SearchToList
SearchFirstValue
SearchRandomSample
)
func (a SearchAggregator) String() string {
switch a {
case SearchInvalid:
return ""
case SearchAvg:
return "AVG"
case SearchSum:
return "SUM"
case SearchMin:
return "MIN"
case SearchMax:
return "MAX"
case SearchCount:
return "COUNT"
case SearchCountDistinct:
return "COUNT_DISTINCT"
case SearchCountDistinctish:
return "COUNT_DISTINCTISH"
case SearchStdDev:
return "STDDEV"
case SearchQuantile:
return "QUANTILE"
case SearchToList:
return "TOLIST"
case SearchFirstValue:
return "FIRST_VALUE"
case SearchRandomSample:
return "RANDOM_SAMPLE"
default:
return ""
}
}
type SearchFieldType int
const (
SearchFieldTypeInvalid = SearchFieldType(iota)
SearchFieldTypeNumeric
SearchFieldTypeTag
SearchFieldTypeText
SearchFieldTypeGeo
SearchFieldTypeVector
SearchFieldTypeGeoShape
)
func (t SearchFieldType) String() string {
switch t {
case SearchFieldTypeInvalid:
return ""
case SearchFieldTypeNumeric:
return "NUMERIC"
case SearchFieldTypeTag:
return "TAG"
case SearchFieldTypeText:
return "TEXT"
case SearchFieldTypeGeo:
return "GEO"
case SearchFieldTypeVector:
return "VECTOR"
case SearchFieldTypeGeoShape:
return "GEOSHAPE"
default:
return "TEXT"
}
}
// Each AggregateReducer have different args.
// Please follow https://redis.io/docs/interact/search-and-query/search/aggregations/#supported-groupby-reducers for more information.
type FTAggregateReducer struct {
Reducer SearchAggregator
Args []interface{}
As string
}
type FTAggregateGroupBy struct {
Fields []interface{}
Reduce []FTAggregateReducer
}
type FTAggregateSortBy struct {
FieldName string
Asc bool
Desc bool
}
type FTAggregateApply struct {
Field string
As string
}
type FTAggregateLoad struct {
Field string
As string
}
type FTAggregateWithCursor struct {
Count int
MaxIdle int
}
type FTAggregateOptions struct {
Verbatim bool
LoadAll bool
Load []FTAggregateLoad
Timeout int
GroupBy []FTAggregateGroupBy
SortBy []FTAggregateSortBy
SortByMax int
Apply []FTAggregateApply
LimitOffset int
Limit int
Filter string
WithCursor bool
WithCursorOptions *FTAggregateWithCursor
Params map[string]interface{}
DialectVersion int
}
type FTSearchFilter struct {
FieldName interface{}
Min interface{}
Max interface{}
}
type FTSearchGeoFilter struct {
FieldName string
Longitude float64
Latitude float64
Radius float64
Unit string
}
type FTSearchReturn struct {
FieldName string
As string
}
type FTSearchSortBy struct {
FieldName string
Asc bool
Desc bool
}
type FTSearchOptions struct {
NoContent bool
Verbatim bool
NoStopWrods bool
WithScores bool
WithPayloads bool
WithSortKeys bool
Filters []FTSearchFilter
GeoFilter []FTSearchGeoFilter
InKeys []interface{}
InFields []interface{}
Return []FTSearchReturn
Slop int
Timeout int
InOrder bool
Language string
Expander string
Scorer string
ExplainScore bool
Payload string
SortBy []FTSearchSortBy
SortByWithCount bool
LimitOffset int
Limit int
Params map[string]interface{}
DialectVersion int
}
type FTSynDumpResult struct {
Term string
Synonyms []string
}
type FTSynDumpCmd struct {
baseCmd
val []FTSynDumpResult
}
type FTAggregateResult struct {
Total int
Rows []AggregateRow
}
type AggregateRow struct {
Fields map[string]interface{}
}
type AggregateCmd struct {
baseCmd
val *FTAggregateResult
}
type FTInfoResult struct {
IndexErrors IndexErrors
Attributes []FTAttribute
BytesPerRecordAvg string
Cleaning int
CursorStats CursorStats
DialectStats map[string]int
DocTableSizeMB float64
FieldStatistics []FieldStatistic
GCStats GCStats
GeoshapesSzMB float64
HashIndexingFailures int
IndexDefinition IndexDefinition
IndexName string
IndexOptions []string
Indexing int
InvertedSzMB float64
KeyTableSizeMB float64
MaxDocID int
NumDocs int
NumRecords int
NumTerms int
NumberOfUses int
OffsetBitsPerRecordAvg string
OffsetVectorsSzMB float64
OffsetsPerTermAvg string
PercentIndexed float64
RecordsPerDocAvg string
SortableValuesSizeMB float64
TagOverheadSzMB float64
TextOverheadSzMB float64
TotalIndexMemorySzMB float64
TotalIndexingTime int
TotalInvertedIndexBlocks int
VectorIndexSzMB float64
}
type IndexErrors struct {
IndexingFailures int
LastIndexingError string
LastIndexingErrorKey string
}
type FTAttribute struct {
Identifier string
Attribute string
Type string
Weight float64
Sortable bool
NoStem bool
NoIndex bool
UNF bool
PhoneticMatcher string
CaseSensitive bool
WithSuffixtrie bool
}
type CursorStats struct {
GlobalIdle int
GlobalTotal int
IndexCapacity int
IndexTotal int
}
type FieldStatistic struct {
Identifier string
Attribute string
IndexErrors IndexErrors
}
type GCStats struct {
BytesCollected int
TotalMsRun int
TotalCycles int
AverageCycleTimeMs string
LastRunTimeMs int
GCNumericTreesMissed int
GCBlocksDenied int
}
type IndexDefinition struct {
KeyType string
Prefixes []string
DefaultScore float64
}
type FTSpellCheckOptions struct {
Distance int
Terms *FTSpellCheckTerms
Dialect int
}
type FTSpellCheckTerms struct {
Inclusion string // Either "INCLUDE" or "EXCLUDE"
Dictionary string
Terms []interface{}
}
type SpellCheckResult struct {
Term string
Suggestions []SpellCheckSuggestion
}
type SpellCheckSuggestion struct {
Score float64
Suggestion string
}
type FTSearchResult struct {
Total int
Docs []Document
}
type Document struct {
ID string
Score *float64
Payload *string
SortKey *string
Fields map[string]string
}
type AggregateQuery []interface{}
// FT_List - Lists all the existing indexes in the database.
// For more information, please refer to the Redis documentation:
// [FT._LIST]: (https://redis.io/commands/ft._list/)
func (c cmdable) FT_List(ctx context.Context) *StringSliceCmd {
cmd := NewStringSliceCmd(ctx, "FT._LIST")
_ = c(ctx, cmd)
return cmd
}
// FTAggregate - Performs a search query on an index and applies a series of aggregate transformations to the result.
// The 'index' parameter specifies the index to search, and the 'query' parameter specifies the search query.
// For more information, please refer to the Redis documentation:
// [FT.AGGREGATE]: (https://redis.io/commands/ft.aggregate/)
func (c cmdable) FTAggregate(ctx context.Context, index string, query string) *MapStringInterfaceCmd {
args := []interface{}{"FT.AGGREGATE", index, query}
cmd := NewMapStringInterfaceCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
func FTAggregateQuery(query string, options *FTAggregateOptions) AggregateQuery {
queryArgs := []interface{}{query}
if options != nil {
if options.Verbatim {
queryArgs = append(queryArgs, "VERBATIM")
}
if options.LoadAll && options.Load != nil {
panic("FT.AGGREGATE: LOADALL and LOAD are mutually exclusive")
}
if options.LoadAll {
queryArgs = append(queryArgs, "LOAD", "*")
}
if options.Load != nil {
queryArgs = append(queryArgs, "LOAD", len(options.Load))
for _, load := range options.Load {
queryArgs = append(queryArgs, load.Field)
if load.As != "" {
queryArgs = append(queryArgs, "AS", load.As)
}
}
}
if options.Timeout > 0 {
queryArgs = append(queryArgs, "TIMEOUT", options.Timeout)
}
if options.GroupBy != nil {
for _, groupBy := range options.GroupBy {
queryArgs = append(queryArgs, "GROUPBY", len(groupBy.Fields))
queryArgs = append(queryArgs, groupBy.Fields...)
for _, reducer := range groupBy.Reduce {
queryArgs = append(queryArgs, "REDUCE")
queryArgs = append(queryArgs, reducer.Reducer.String())
if reducer.Args != nil {
queryArgs = append(queryArgs, len(reducer.Args))
queryArgs = append(queryArgs, reducer.Args...)
} else {
queryArgs = append(queryArgs, 0)
}
if reducer.As != "" {
queryArgs = append(queryArgs, "AS", reducer.As)
}
}
}
}
if options.SortBy != nil {
queryArgs = append(queryArgs, "SORTBY")
sortByOptions := []interface{}{}
for _, sortBy := range options.SortBy {
sortByOptions = append(sortByOptions, sortBy.FieldName)
if sortBy.Asc && sortBy.Desc {
panic("FT.AGGREGATE: ASC and DESC are mutually exclusive")
}
if sortBy.Asc {
sortByOptions = append(sortByOptions, "ASC")
}
if sortBy.Desc {
sortByOptions = append(sortByOptions, "DESC")
}
}
queryArgs = append(queryArgs, len(sortByOptions))
queryArgs = append(queryArgs, sortByOptions...)
}
if options.SortByMax > 0 {
queryArgs = append(queryArgs, "MAX", options.SortByMax)
}
for _, apply := range options.Apply {
queryArgs = append(queryArgs, "APPLY", apply.Field)
if apply.As != "" {
queryArgs = append(queryArgs, "AS", apply.As)
}
}
if options.LimitOffset > 0 {
queryArgs = append(queryArgs, "LIMIT", options.LimitOffset)
}
if options.Limit > 0 {
queryArgs = append(queryArgs, options.Limit)
}
if options.Filter != "" {
queryArgs = append(queryArgs, "FILTER", options.Filter)
}
if options.WithCursor {
queryArgs = append(queryArgs, "WITHCURSOR")
if options.WithCursorOptions != nil {
if options.WithCursorOptions.Count > 0 {
queryArgs = append(queryArgs, "COUNT", options.WithCursorOptions.Count)
}
if options.WithCursorOptions.MaxIdle > 0 {
queryArgs = append(queryArgs, "MAXIDLE", options.WithCursorOptions.MaxIdle)
}
}
}
if options.Params != nil {
queryArgs = append(queryArgs, "PARAMS", len(options.Params)*2)
for key, value := range options.Params {
queryArgs = append(queryArgs, key, value)
}
}
if options.DialectVersion > 0 {
queryArgs = append(queryArgs, "DIALECT", options.DialectVersion)
}
}
return queryArgs
}
func ProcessAggregateResult(data []interface{}) (*FTAggregateResult, error) {
if len(data) == 0 {
return nil, fmt.Errorf("no data returned")
}
total, ok := data[0].(int64)
if !ok {
return nil, fmt.Errorf("invalid total format")
}
rows := make([]AggregateRow, 0, len(data)-1)
for _, row := range data[1:] {
fields, ok := row.([]interface{})
if !ok {
return nil, fmt.Errorf("invalid row format")
}
rowMap := make(map[string]interface{})
for i := 0; i < len(fields); i += 2 {
key, ok := fields[i].(string)
if !ok {
return nil, fmt.Errorf("invalid field key format")
}
value := fields[i+1]
rowMap[key] = value
}
rows = append(rows, AggregateRow{Fields: rowMap})
}
result := &FTAggregateResult{
Total: int(total),
Rows: rows,
}
return result, nil
}
func NewAggregateCmd(ctx context.Context, args ...interface{}) *AggregateCmd {
return &AggregateCmd{
baseCmd: baseCmd{
ctx: ctx,
args: args,
},
}
}
func (cmd *AggregateCmd) SetVal(val *FTAggregateResult) {
cmd.val = val
}
func (cmd *AggregateCmd) Val() *FTAggregateResult {
return cmd.val
}
func (cmd *AggregateCmd) Result() (*FTAggregateResult, error) {
return cmd.val, cmd.err
}
func (cmd *AggregateCmd) String() string {
return cmdString(cmd, cmd.val)
}
func (cmd *AggregateCmd) readReply(rd *proto.Reader) (err error) {
data, err := rd.ReadSlice()
if err != nil {
cmd.err = err
return nil
}
cmd.val, err = ProcessAggregateResult(data)
if err != nil {
cmd.err = err
}
return nil
}
// FTAggregateWithArgs - Performs a search query on an index and applies a series of aggregate transformations to the result.
// The 'index' parameter specifies the index to search, and the 'query' parameter specifies the search query.
// This function also allows for specifying additional options such as: Verbatim, LoadAll, Load, Timeout, GroupBy, SortBy, SortByMax, Apply, LimitOffset, Limit, Filter, WithCursor, Params, and DialectVersion.
// For more information, please refer to the Redis documentation:
// [FT.AGGREGATE]: (https://redis.io/commands/ft.aggregate/)
func (c cmdable) FTAggregateWithArgs(ctx context.Context, index string, query string, options *FTAggregateOptions) *AggregateCmd {
args := []interface{}{"FT.AGGREGATE", index, query}
if options != nil {
if options.Verbatim {
args = append(args, "VERBATIM")
}
if options.LoadAll && options.Load != nil {
panic("FT.AGGREGATE: LOADALL and LOAD are mutually exclusive")
}
if options.LoadAll {
args = append(args, "LOAD", "*")
}
if options.Load != nil {
args = append(args, "LOAD", len(options.Load))
for _, load := range options.Load {
args = append(args, load.Field)
if load.As != "" {
args = append(args, "AS", load.As)
}
}
}
if options.Timeout > 0 {
args = append(args, "TIMEOUT", options.Timeout)
}
if options.GroupBy != nil {
for _, groupBy := range options.GroupBy {
args = append(args, "GROUPBY", len(groupBy.Fields))
args = append(args, groupBy.Fields...)
for _, reducer := range groupBy.Reduce {
args = append(args, "REDUCE")
args = append(args, reducer.Reducer.String())
if reducer.Args != nil {
args = append(args, len(reducer.Args))
args = append(args, reducer.Args...)
} else {
args = append(args, 0)
}
if reducer.As != "" {
args = append(args, "AS", reducer.As)
}
}
}
}
if options.SortBy != nil {
args = append(args, "SORTBY")
sortByOptions := []interface{}{}
for _, sortBy := range options.SortBy {
sortByOptions = append(sortByOptions, sortBy.FieldName)
if sortBy.Asc && sortBy.Desc {
panic("FT.AGGREGATE: ASC and DESC are mutually exclusive")
}
if sortBy.Asc {
sortByOptions = append(sortByOptions, "ASC")
}
if sortBy.Desc {
sortByOptions = append(sortByOptions, "DESC")
}
}
args = append(args, len(sortByOptions))
args = append(args, sortByOptions...)
}
if options.SortByMax > 0 {
args = append(args, "MAX", options.SortByMax)
}
for _, apply := range options.Apply {
args = append(args, "APPLY", apply.Field)
if apply.As != "" {
args = append(args, "AS", apply.As)
}
}
if options.LimitOffset > 0 {
args = append(args, "LIMIT", options.LimitOffset)
}
if options.Limit > 0 {
args = append(args, options.Limit)
}
if options.Filter != "" {
args = append(args, "FILTER", options.Filter)
}
if options.WithCursor {
args = append(args, "WITHCURSOR")
if options.WithCursorOptions != nil {
if options.WithCursorOptions.Count > 0 {
args = append(args, "COUNT", options.WithCursorOptions.Count)
}
if options.WithCursorOptions.MaxIdle > 0 {
args = append(args, "MAXIDLE", options.WithCursorOptions.MaxIdle)
}
}
}
if options.Params != nil {
args = append(args, "PARAMS", len(options.Params)*2)
for key, value := range options.Params {
args = append(args, key, value)
}
}
if options.DialectVersion > 0 {
args = append(args, "DIALECT", options.DialectVersion)
}
}
cmd := NewAggregateCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTAliasAdd - Adds an alias to an index.
// The 'index' parameter specifies the index to which the alias is added, and the 'alias' parameter specifies the alias.
// For more information, please refer to the Redis documentation:
// [FT.ALIASADD]: (https://redis.io/commands/ft.aliasadd/)
func (c cmdable) FTAliasAdd(ctx context.Context, index string, alias string) *StatusCmd {
args := []interface{}{"FT.ALIASADD", alias, index}
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTAliasDel - Removes an alias from an index.
// The 'alias' parameter specifies the alias to be removed.
// For more information, please refer to the Redis documentation:
// [FT.ALIASDEL]: (https://redis.io/commands/ft.aliasdel/)
func (c cmdable) FTAliasDel(ctx context.Context, alias string) *StatusCmd {
cmd := NewStatusCmd(ctx, "FT.ALIASDEL", alias)
_ = c(ctx, cmd)
return cmd
}
// FTAliasUpdate - Updates an alias to an index.
// The 'index' parameter specifies the index to which the alias is updated, and the 'alias' parameter specifies the alias.
// If the alias already exists for a different index, it updates the alias to point to the specified index instead.
// For more information, please refer to the Redis documentation:
// [FT.ALIASUPDATE]: (https://redis.io/commands/ft.aliasupdate/)
func (c cmdable) FTAliasUpdate(ctx context.Context, index string, alias string) *StatusCmd {
cmd := NewStatusCmd(ctx, "FT.ALIASUPDATE", alias, index)
_ = c(ctx, cmd)
return cmd
}
// FTAlter - Alters the definition of an existing index.
// The 'index' parameter specifies the index to alter, and the 'skipInitalScan' parameter specifies whether to skip the initial scan.
// The 'definition' parameter specifies the new definition for the index.
// For more information, please refer to the Redis documentation:
// [FT.ALTER]: (https://redis.io/commands/ft.alter/)
func (c cmdable) FTAlter(ctx context.Context, index string, skipInitalScan bool, definition []interface{}) *StatusCmd {
args := []interface{}{"FT.ALTER", index}
if skipInitalScan {
args = append(args, "SKIPINITIALSCAN")
}
args = append(args, "SCHEMA", "ADD")
args = append(args, definition...)
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTConfigGet - Retrieves the value of a RediSearch configuration parameter.
// The 'option' parameter specifies the configuration parameter to retrieve.
// For more information, please refer to the Redis documentation:
// [FT.CONFIG GET]: (https://redis.io/commands/ft.config-get/)
func (c cmdable) FTConfigGet(ctx context.Context, option string) *MapMapStringInterfaceCmd {
cmd := NewMapMapStringInterfaceCmd(ctx, "FT.CONFIG", "GET", option)
_ = c(ctx, cmd)
return cmd
}
// FTConfigSet - Sets the value of a RediSearch configuration parameter.
// The 'option' parameter specifies the configuration parameter to set, and the 'value' parameter specifies the new value.
// For more information, please refer to the Redis documentation:
// [FT.CONFIG SET]: (https://redis.io/commands/ft.config-set/)
func (c cmdable) FTConfigSet(ctx context.Context, option string, value interface{}) *StatusCmd {
cmd := NewStatusCmd(ctx, "FT.CONFIG", "SET", option, value)
_ = c(ctx, cmd)
return cmd
}
// FTCreate - Creates a new index with the given options and schema.
// The 'index' parameter specifies the name of the index to create.
// The 'options' parameter specifies various options for the index, such as:
// whether to index hashes or JSONs, prefixes, filters, default language, score, score field, payload field, etc.
// The 'schema' parameter specifies the schema for the index, which includes the field name, field type, etc.
// For more information, please refer to the Redis documentation:
// [FT.CREATE]: (https://redis.io/commands/ft.create/)
func (c cmdable) FTCreate(ctx context.Context, index string, options *FTCreateOptions, schema ...*FieldSchema) *StatusCmd {
args := []interface{}{"FT.CREATE", index}
if options != nil {
if options.OnHash && !options.OnJSON {
args = append(args, "ON", "HASH")
}
if options.OnJSON && !options.OnHash {
args = append(args, "ON", "JSON")
}
if options.OnHash && options.OnJSON {
panic("FT.CREATE: ON HASH and ON JSON are mutually exclusive")
}
if options.Prefix != nil {
args = append(args, "PREFIX", len(options.Prefix))
args = append(args, options.Prefix...)
}
if options.Filter != "" {
args = append(args, "FILTER", options.Filter)
}
if options.DefaultLanguage != "" {
args = append(args, "LANGUAGE", options.DefaultLanguage)
}
if options.LanguageField != "" {
args = append(args, "LANGUAGE_FIELD", options.LanguageField)
}
if options.Score > 0 {
args = append(args, "SCORE", options.Score)
}
if options.ScoreField != "" {
args = append(args, "SCORE_FIELD", options.ScoreField)
}
if options.PayloadField != "" {
args = append(args, "PAYLOAD_FIELD", options.PayloadField)
}
if options.MaxTextFields > 0 {
args = append(args, "MAXTEXTFIELDS", options.MaxTextFields)
}
if options.NoOffsets {
args = append(args, "NOOFFSETS")
}
if options.Temporary > 0 {
args = append(args, "TEMPORARY", options.Temporary)
}
if options.NoHL {
args = append(args, "NOHL")
}
if options.NoFields {
args = append(args, "NOFIELDS")
}
if options.NoFreqs {
args = append(args, "NOFREQS")
}
if options.StopWords != nil {
args = append(args, "STOPWORDS", len(options.StopWords))
args = append(args, options.StopWords...)
}
if options.SkipInitalScan {
args = append(args, "SKIPINITIALSCAN")
}
}
if schema == nil {
panic("FT.CREATE: SCHEMA is required")
}
args = append(args, "SCHEMA")
for _, schema := range schema {
if schema.FieldName == "" || schema.FieldType == SearchFieldTypeInvalid {
panic("FT.CREATE: SCHEMA FieldName and FieldType are required")
}
args = append(args, schema.FieldName)
if schema.As != "" {
args = append(args, "AS", schema.As)
}
args = append(args, schema.FieldType.String())
if schema.VectorArgs != nil {
if schema.FieldType != SearchFieldTypeVector {
panic("FT.CREATE: SCHEMA FieldType VECTOR is required for VectorArgs")
}
if schema.VectorArgs.FlatOptions != nil && schema.VectorArgs.HNSWOptions != nil {
panic("FT.CREATE: SCHEMA VectorArgs FlatOptions and HNSWOptions are mutually exclusive")
}
if schema.VectorArgs.FlatOptions != nil {
args = append(args, "FLAT")
if schema.VectorArgs.FlatOptions.Type == "" || schema.VectorArgs.FlatOptions.Dim == 0 || schema.VectorArgs.FlatOptions.DistanceMetric == "" {
panic("FT.CREATE: Type, Dim and DistanceMetric are required for VECTOR FLAT")
}
flatArgs := []interface{}{
"TYPE", schema.VectorArgs.FlatOptions.Type,
"DIM", schema.VectorArgs.FlatOptions.Dim,
"DISTANCE_METRIC", schema.VectorArgs.FlatOptions.DistanceMetric,
}
if schema.VectorArgs.FlatOptions.InitialCapacity > 0 {
flatArgs = append(flatArgs, "INITIAL_CAP", schema.VectorArgs.FlatOptions.InitialCapacity)
}
if schema.VectorArgs.FlatOptions.BlockSize > 0 {
flatArgs = append(flatArgs, "BLOCK_SIZE", schema.VectorArgs.FlatOptions.BlockSize)
}
args = append(args, len(flatArgs))
args = append(args, flatArgs...)
}
if schema.VectorArgs.HNSWOptions != nil {
args = append(args, "HNSW")
if schema.VectorArgs.HNSWOptions.Type == "" || schema.VectorArgs.HNSWOptions.Dim == 0 || schema.VectorArgs.HNSWOptions.DistanceMetric == "" {
panic("FT.CREATE: Type, Dim and DistanceMetric are required for VECTOR HNSW")
}
hnswArgs := []interface{}{
"TYPE", schema.VectorArgs.HNSWOptions.Type,
"DIM", schema.VectorArgs.HNSWOptions.Dim,
"DISTANCE_METRIC", schema.VectorArgs.HNSWOptions.DistanceMetric,
}
if schema.VectorArgs.HNSWOptions.InitialCapacity > 0 {
hnswArgs = append(hnswArgs, "INITIAL_CAP", schema.VectorArgs.HNSWOptions.InitialCapacity)
}
if schema.VectorArgs.HNSWOptions.MaxEdgesPerNode > 0 {
hnswArgs = append(hnswArgs, "M", schema.VectorArgs.HNSWOptions.MaxEdgesPerNode)
}
if schema.VectorArgs.HNSWOptions.MaxAllowedEdgesPerNode > 0 {
hnswArgs = append(hnswArgs, "EF_CONSTRUCTION", schema.VectorArgs.HNSWOptions.MaxAllowedEdgesPerNode)
}
if schema.VectorArgs.HNSWOptions.EFRunTime > 0 {
hnswArgs = append(hnswArgs, "EF_RUNTIME", schema.VectorArgs.HNSWOptions.EFRunTime)
}
if schema.VectorArgs.HNSWOptions.Epsilon > 0 {
hnswArgs = append(hnswArgs, "EPSILON", schema.VectorArgs.HNSWOptions.Epsilon)
}
args = append(args, len(hnswArgs))
args = append(args, hnswArgs...)
}
}
if schema.GeoShapeFieldType != "" {
if schema.FieldType != SearchFieldTypeGeoShape {
panic("FT.CREATE: SCHEMA FieldType GEOSHAPE is required for GeoShapeFieldType")
}
args = append(args, schema.GeoShapeFieldType)
}
if schema.NoStem {
args = append(args, "NOSTEM")
}
if schema.Sortable {
args = append(args, "SORTABLE")
}
if schema.UNF {
args = append(args, "UNF")
}
if schema.NoIndex {
args = append(args, "NOINDEX")
}
if schema.PhoneticMatcher != "" {
args = append(args, "PHONETIC", schema.PhoneticMatcher)
}
if schema.Weight > 0 {
args = append(args, "WEIGHT", schema.Weight)
}
if schema.Seperator != "" {
args = append(args, "SEPERATOR", schema.Seperator)
}
if schema.CaseSensitive {
args = append(args, "CASESENSITIVE")
}
if schema.WithSuffixtrie {
args = append(args, "WITHSUFFIXTRIE")
}
}
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTCursorDel - Deletes a cursor from an existing index.
// The 'index' parameter specifies the index from which to delete the cursor, and the 'cursorId' parameter specifies the ID of the cursor to delete.
// For more information, please refer to the Redis documentation:
// [FT.CURSOR DEL]: (https://redis.io/commands/ft.cursor-del/)
func (c cmdable) FTCursorDel(ctx context.Context, index string, cursorId int) *StatusCmd {
cmd := NewStatusCmd(ctx, "FT.CURSOR", "DEL", index, cursorId)
_ = c(ctx, cmd)
return cmd
}
// FTCursorRead - Reads the next results from an existing cursor.
// The 'index' parameter specifies the index from which to read the cursor, the 'cursorId' parameter specifies the ID of the cursor to read, and the 'count' parameter specifies the number of results to read.
// For more information, please refer to the Redis documentation:
// [FT.CURSOR READ]: (https://redis.io/commands/ft.cursor-read/)
func (c cmdable) FTCursorRead(ctx context.Context, index string, cursorId int, count int) *MapStringInterfaceCmd {
args := []interface{}{"FT.CURSOR", "READ", index, cursorId}
if count > 0 {
args = append(args, "COUNT", count)
}
cmd := NewMapStringInterfaceCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTDictAdd - Adds terms to a dictionary.
// The 'dict' parameter specifies the dictionary to which to add the terms, and the 'term' parameter specifies the terms to add.
// For more information, please refer to the Redis documentation:
// [FT.DICTADD]: (https://redis.io/commands/ft.dictadd/)
func (c cmdable) FTDictAdd(ctx context.Context, dict string, term ...interface{}) *IntCmd {
args := []interface{}{"FT.DICTADD", dict}
args = append(args, term...)
cmd := NewIntCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTDictDel - Deletes terms from a dictionary.
// The 'dict' parameter specifies the dictionary from which to delete the terms, and the 'term' parameter specifies the terms to delete.
// For more information, please refer to the Redis documentation:
// [FT.DICTDEL]: (https://redis.io/commands/ft.dictdel/)
func (c cmdable) FTDictDel(ctx context.Context, dict string, term ...interface{}) *IntCmd {
args := []interface{}{"FT.DICTDEL", dict}
args = append(args, term...)
cmd := NewIntCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTDictDump - Returns all terms in the specified dictionary.
// The 'dict' parameter specifies the dictionary from which to return the terms.
// For more information, please refer to the Redis documentation:
// [FT.DICTDUMP]: (https://redis.io/commands/ft.dictdump/)
func (c cmdable) FTDictDump(ctx context.Context, dict string) *StringSliceCmd {
cmd := NewStringSliceCmd(ctx, "FT.DICTDUMP", dict)
_ = c(ctx, cmd)
return cmd
}
// FTDropIndex - Deletes an index.
// The 'index' parameter specifies the index to delete.
// For more information, please refer to the Redis documentation:
// [FT.DROPINDEX]: (https://redis.io/commands/ft.dropindex/)
func (c cmdable) FTDropIndex(ctx context.Context, index string) *StatusCmd {
args := []interface{}{"FT.DROPINDEX", index}
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTDropIndexWithArgs - Deletes an index with options.
// The 'index' parameter specifies the index to delete, and the 'options' parameter specifies the DeleteDocs option for docs deletion.
// For more information, please refer to the Redis documentation:
// [FT.DROPINDEX]: (https://redis.io/commands/ft.dropindex/)
func (c cmdable) FTDropIndexWithArgs(ctx context.Context, index string, options *FTDropIndexOptions) *StatusCmd {
args := []interface{}{"FT.DROPINDEX", index}
if options != nil {
if options.DeleteDocs {
args = append(args, "DD")
}
}
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTExplain - Returns the execution plan for a complex query.
// The 'index' parameter specifies the index to query, and the 'query' parameter specifies the query string.
// For more information, please refer to the Redis documentation:
// [FT.EXPLAIN]: (https://redis.io/commands/ft.explain/)
func (c cmdable) FTExplain(ctx context.Context, index string, query string) *StringCmd {
cmd := NewStringCmd(ctx, "FT.EXPLAIN", index, query)
_ = c(ctx, cmd)
return cmd
}
// FTExplainWithArgs - Returns the execution plan for a complex query with options.
// The 'index' parameter specifies the index to query, the 'query' parameter specifies the query string, and the 'options' parameter specifies the Dialect for the query.
// For more information, please refer to the Redis documentation:
// [FT.EXPLAIN]: (https://redis.io/commands/ft.explain/)
func (c cmdable) FTExplainWithArgs(ctx context.Context, index string, query string, options *FTExplainOptions) *StringCmd {
args := []interface{}{"FT.EXPLAIN", index, query}
if options.Dialect != "" {
args = append(args, "DIALECT", options.Dialect)
}
cmd := NewStringCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTExplainCli - Returns the execution plan for a complex query. [Not Implemented]
// For more information, see https://redis.io/commands/ft.explaincli/
func (c cmdable) FTExplainCli(ctx context.Context, key, path string) error {
panic("not implemented")
}
func parseFTInfo(data map[string]interface{}) (FTInfoResult, error) {
var ftInfo FTInfoResult
// Manually parse each field from the map
if indexErrors, ok := data["Index Errors"].([]interface{}); ok {
ftInfo.IndexErrors = IndexErrors{
IndexingFailures: internal.ToInteger(indexErrors[1]),
LastIndexingError: internal.ToString(indexErrors[3]),
LastIndexingErrorKey: internal.ToString(indexErrors[5]),
}
}
if attributes, ok := data["attributes"].([]interface{}); ok {
for _, attr := range attributes {
if attrMap, ok := attr.([]interface{}); ok {
att := FTAttribute{}
for i := 0; i < len(attrMap); i++ {
if internal.ToLower(internal.ToString(attrMap[i])) == "attribute" {
att.Attribute = internal.ToString(attrMap[i+1])
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "identifier" {
att.Identifier = internal.ToString(attrMap[i+1])
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "type" {
att.Type = internal.ToString(attrMap[i+1])
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "weight" {
att.Weight = internal.ToFloat(attrMap[i+1])
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "nostem" {
att.NoStem = true
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "sortable" {
att.Sortable = true
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "noindex" {
att.NoIndex = true
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "unf" {
att.UNF = true
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "phonetic" {
att.PhoneticMatcher = internal.ToString(attrMap[i+1])
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "case_sensitive" {
att.CaseSensitive = true
continue
}
if internal.ToLower(internal.ToString(attrMap[i])) == "withsuffixtrie" {
att.WithSuffixtrie = true
continue
}
}
ftInfo.Attributes = append(ftInfo.Attributes, att)
}
}
}
ftInfo.BytesPerRecordAvg = internal.ToString(data["bytes_per_record_avg"])
ftInfo.Cleaning = internal.ToInteger(data["cleaning"])
if cursorStats, ok := data["cursor_stats"].([]interface{}); ok {
ftInfo.CursorStats = CursorStats{
GlobalIdle: internal.ToInteger(cursorStats[1]),
GlobalTotal: internal.ToInteger(cursorStats[3]),
IndexCapacity: internal.ToInteger(cursorStats[5]),
IndexTotal: internal.ToInteger(cursorStats[7]),
}
}
if dialectStats, ok := data["dialect_stats"].([]interface{}); ok {
ftInfo.DialectStats = make(map[string]int)
for i := 0; i < len(dialectStats); i += 2 {
ftInfo.DialectStats[internal.ToString(dialectStats[i])] = internal.ToInteger(dialectStats[i+1])
}
}
ftInfo.DocTableSizeMB = internal.ToFloat(data["doc_table_size_mb"])
if fieldStats, ok := data["field statistics"].([]interface{}); ok {
for _, stat := range fieldStats {
if statMap, ok := stat.([]interface{}); ok {
ftInfo.FieldStatistics = append(ftInfo.FieldStatistics, FieldStatistic{
Identifier: internal.ToString(statMap[1]),
Attribute: internal.ToString(statMap[3]),
IndexErrors: IndexErrors{
IndexingFailures: internal.ToInteger(statMap[5].([]interface{})[1]),
LastIndexingError: internal.ToString(statMap[5].([]interface{})[3]),
LastIndexingErrorKey: internal.ToString(statMap[5].([]interface{})[5]),
},
})
}
}
}
if gcStats, ok := data["gc_stats"].([]interface{}); ok {
ftInfo.GCStats = GCStats{}
for i := 0; i < len(gcStats); i += 2 {
if internal.ToLower(internal.ToString(gcStats[i])) == "bytes_collected" {
ftInfo.GCStats.BytesCollected = internal.ToInteger(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "total_ms_run" {
ftInfo.GCStats.TotalMsRun = internal.ToInteger(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "total_cycles" {
ftInfo.GCStats.TotalCycles = internal.ToInteger(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "average_cycle_time_ms" {
ftInfo.GCStats.AverageCycleTimeMs = internal.ToString(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "last_run_time_ms" {
ftInfo.GCStats.LastRunTimeMs = internal.ToInteger(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "gc_numeric_trees_missed" {
ftInfo.GCStats.GCNumericTreesMissed = internal.ToInteger(gcStats[i+1])
continue
}
if internal.ToLower(internal.ToString(gcStats[i])) == "gc_blocks_denied" {
ftInfo.GCStats.GCBlocksDenied = internal.ToInteger(gcStats[i+1])
continue
}
}
}
ftInfo.GeoshapesSzMB = internal.ToFloat(data["geoshapes_sz_mb"])
ftInfo.HashIndexingFailures = internal.ToInteger(data["hash_indexing_failures"])
if indexDef, ok := data["index_definition"].([]interface{}); ok {
ftInfo.IndexDefinition = IndexDefinition{
KeyType: internal.ToString(indexDef[1]),
Prefixes: internal.ToStringSlice(indexDef[3]),
DefaultScore: internal.ToFloat(indexDef[5]),
}
}
ftInfo.IndexName = internal.ToString(data["index_name"])
ftInfo.IndexOptions = internal.ToStringSlice(data["index_options"].([]interface{}))
ftInfo.Indexing = internal.ToInteger(data["indexing"])
ftInfo.InvertedSzMB = internal.ToFloat(data["inverted_sz_mb"])
ftInfo.KeyTableSizeMB = internal.ToFloat(data["key_table_size_mb"])
ftInfo.MaxDocID = internal.ToInteger(data["max_doc_id"])
ftInfo.NumDocs = internal.ToInteger(data["num_docs"])
ftInfo.NumRecords = internal.ToInteger(data["num_records"])
ftInfo.NumTerms = internal.ToInteger(data["num_terms"])
ftInfo.NumberOfUses = internal.ToInteger(data["number_of_uses"])
ftInfo.OffsetBitsPerRecordAvg = internal.ToString(data["offset_bits_per_record_avg"])
ftInfo.OffsetVectorsSzMB = internal.ToFloat(data["offset_vectors_sz_mb"])
ftInfo.OffsetsPerTermAvg = internal.ToString(data["offsets_per_term_avg"])
ftInfo.PercentIndexed = internal.ToFloat(data["percent_indexed"])
ftInfo.RecordsPerDocAvg = internal.ToString(data["records_per_doc_avg"])
ftInfo.SortableValuesSizeMB = internal.ToFloat(data["sortable_values_size_mb"])
ftInfo.TagOverheadSzMB = internal.ToFloat(data["tag_overhead_sz_mb"])
ftInfo.TextOverheadSzMB = internal.ToFloat(data["text_overhead_sz_mb"])
ftInfo.TotalIndexMemorySzMB = internal.ToFloat(data["total_index_memory_sz_mb"])
ftInfo.TotalIndexingTime = internal.ToInteger(data["total_indexing_time"])
ftInfo.TotalInvertedIndexBlocks = internal.ToInteger(data["total_inverted_index_blocks"])
ftInfo.VectorIndexSzMB = internal.ToFloat(data["vector_index_sz_mb"])
return ftInfo, nil
}
type FTInfoCmd struct {
baseCmd
val FTInfoResult
}
func newFTInfoCmd(ctx context.Context, args ...interface{}) *FTInfoCmd {
return &FTInfoCmd{
baseCmd: baseCmd{
ctx: ctx,
args: args,
},
}
}
func (cmd *FTInfoCmd) String() string {
return cmdString(cmd, cmd.val)
}
func (cmd *FTInfoCmd) SetVal(val FTInfoResult) {
cmd.val = val
}
func (cmd *FTInfoCmd) Result() (FTInfoResult, error) {
return cmd.val, cmd.err
}
func (cmd *FTInfoCmd) Val() FTInfoResult {
return cmd.val
}
func (cmd *FTInfoCmd) readReply(rd *proto.Reader) (err error) {
n, err := rd.ReadMapLen()
if err != nil {
return err
}
data := make(map[string]interface{}, n)
for i := 0; i < n; i++ {
k, err := rd.ReadString()
if err != nil {
return err
}
v, err := rd.ReadReply()
if err != nil {
if err == Nil {
data[k] = Nil
continue
}
if err, ok := err.(proto.RedisError); ok {
data[k] = err
continue
}
return err
}
data[k] = v
}
cmd.val, err = parseFTInfo(data)
if err != nil {
cmd.err = err
}
return nil
}
// FTInfo - Retrieves information about an index.
// The 'index' parameter specifies the index to retrieve information about.
// For more information, please refer to the Redis documentation:
// [FT.INFO]: (https://redis.io/commands/ft.info/)
func (c cmdable) FTInfo(ctx context.Context, index string) *FTInfoCmd {
cmd := newFTInfoCmd(ctx, "FT.INFO", index)
_ = c(ctx, cmd)
return cmd
}
// FTSpellCheck - Checks a query string for spelling errors.
// For more details about spellcheck query please follow:
// https://redis.io/docs/interact/search-and-query/advanced-concepts/spellcheck/
// For more information, please refer to the Redis documentation:
// [FT.SPELLCHECK]: (https://redis.io/commands/ft.spellcheck/)
func (c cmdable) FTSpellCheck(ctx context.Context, index string, query string) *FTSpellCheckCmd {
args := []interface{}{"FT.SPELLCHECK", index, query}
cmd := newFTSpellCheckCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTSpellCheckWithArgs - Checks a query string for spelling errors with additional options.
// For more details about spellcheck query please follow:
// https://redis.io/docs/interact/search-and-query/advanced-concepts/spellcheck/
// For more information, please refer to the Redis documentation:
// [FT.SPELLCHECK]: (https://redis.io/commands/ft.spellcheck/)
func (c cmdable) FTSpellCheckWithArgs(ctx context.Context, index string, query string, options *FTSpellCheckOptions) *FTSpellCheckCmd {
args := []interface{}{"FT.SPELLCHECK", index, query}
if options != nil {
if options.Distance > 0 {
args = append(args, "DISTANCE", options.Distance)
}
if options.Terms != nil {
args = append(args, "TERMS", options.Terms.Inclusion, options.Terms.Dictionary)
args = append(args, options.Terms.Terms...)
}
if options.Dialect > 0 {
args = append(args, "DIALECT", options.Dialect)
}
}
cmd := newFTSpellCheckCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
type FTSpellCheckCmd struct {
baseCmd
val []SpellCheckResult
}
func newFTSpellCheckCmd(ctx context.Context, args ...interface{}) *FTSpellCheckCmd {
return &FTSpellCheckCmd{
baseCmd: baseCmd{
ctx: ctx,
args: args,
},
}
}
func (cmd *FTSpellCheckCmd) String() string {
return cmdString(cmd, cmd.val)
}
func (cmd *FTSpellCheckCmd) SetVal(val []SpellCheckResult) {
cmd.val = val
}
func (cmd *FTSpellCheckCmd) Result() ([]SpellCheckResult, error) {
return cmd.val, cmd.err
}
func (cmd *FTSpellCheckCmd) Val() []SpellCheckResult {
return cmd.val
}
func (cmd *FTSpellCheckCmd) readReply(rd *proto.Reader) (err error) {
data, err := rd.ReadSlice()
if err != nil {
cmd.err = err
return nil
}
cmd.val, err = parseFTSpellCheck(data)
if err != nil {
cmd.err = err
}
return nil
}
func parseFTSpellCheck(data []interface{}) ([]SpellCheckResult, error) {
results := make([]SpellCheckResult, 0, len(data))
for _, termData := range data {
termInfo, ok := termData.([]interface{})
if !ok || len(termInfo) != 3 {
return nil, fmt.Errorf("invalid term format")
}
term, ok := termInfo[1].(string)
if !ok {
return nil, fmt.Errorf("invalid term format")
}
suggestionsData, ok := termInfo[2].([]interface{})
if !ok {
return nil, fmt.Errorf("invalid suggestions format")
}
suggestions := make([]SpellCheckSuggestion, 0, len(suggestionsData))
for _, suggestionData := range suggestionsData {
suggestionInfo, ok := suggestionData.([]interface{})
if !ok || len(suggestionInfo) != 2 {
return nil, fmt.Errorf("invalid suggestion format")
}
scoreStr, ok := suggestionInfo[0].(string)
if !ok {
return nil, fmt.Errorf("invalid suggestion score format")
}
score, err := strconv.ParseFloat(scoreStr, 64)
if err != nil {
return nil, fmt.Errorf("invalid suggestion score value")
}
suggestion, ok := suggestionInfo[1].(string)
if !ok {
return nil, fmt.Errorf("invalid suggestion format")
}
suggestions = append(suggestions, SpellCheckSuggestion{
Score: score,
Suggestion: suggestion,
})
}
results = append(results, SpellCheckResult{
Term: term,
Suggestions: suggestions,
})
}
return results, nil
}
func parseFTSearch(data []interface{}, noContent, withScores, withPayloads, withSortKeys bool) (FTSearchResult, error) {
if len(data) < 1 {
return FTSearchResult{}, fmt.Errorf("unexpected search result format")
}
total, ok := data[0].(int64)
if !ok {
return FTSearchResult{}, fmt.Errorf("invalid total results format")
}
var results []Document
for i := 1; i < len(data); {
docID, ok := data[i].(string)
if !ok {
return FTSearchResult{}, fmt.Errorf("invalid document ID format")
}
doc := Document{
ID: docID,
Fields: make(map[string]string),
}
i++
if noContent {
results = append(results, doc)
continue
}
if withScores && i < len(data) {
if scoreStr, ok := data[i].(string); ok {
score, err := strconv.ParseFloat(scoreStr, 64)
if err != nil {
return FTSearchResult{}, fmt.Errorf("invalid score format")
}
doc.Score = &score
i++
}
}
if withPayloads && i < len(data) {
if payload, ok := data[i].(string); ok {
doc.Payload = &payload
i++
}
}
if withSortKeys && i < len(data) {
if sortKey, ok := data[i].(string); ok {
doc.SortKey = &sortKey
i++
}
}
if i < len(data) {
fields, ok := data[i].([]interface{})
if !ok {
return FTSearchResult{}, fmt.Errorf("invalid document fields format")
}
for j := 0; j < len(fields); j += 2 {
key, ok := fields[j].(string)
if !ok {
return FTSearchResult{}, fmt.Errorf("invalid field key format")
}
value, ok := fields[j+1].(string)
if !ok {
return FTSearchResult{}, fmt.Errorf("invalid field value format")
}
doc.Fields[key] = value
}
i++
}
results = append(results, doc)
}
return FTSearchResult{
Total: int(total),
Docs: results,
}, nil
}
type FTSearchCmd struct {
baseCmd
val FTSearchResult
options *FTSearchOptions
}
func newFTSearchCmd(ctx context.Context, options *FTSearchOptions, args ...interface{}) *FTSearchCmd {
return &FTSearchCmd{
baseCmd: baseCmd{
ctx: ctx,
args: args,
},
options: options,
}
}
func (cmd *FTSearchCmd) String() string {
return cmdString(cmd, cmd.val)
}
func (cmd *FTSearchCmd) SetVal(val FTSearchResult) {
cmd.val = val
}
func (cmd *FTSearchCmd) Result() (FTSearchResult, error) {
return cmd.val, cmd.err
}
func (cmd *FTSearchCmd) Val() FTSearchResult {
return cmd.val
}
func (cmd *FTSearchCmd) readReply(rd *proto.Reader) (err error) {
data, err := rd.ReadSlice()
if err != nil {
cmd.err = err
return nil
}
cmd.val, err = parseFTSearch(data, cmd.options.NoContent, cmd.options.WithScores, cmd.options.WithPayloads, cmd.options.WithSortKeys)
if err != nil {
cmd.err = err
}
return nil
}
// FTSearch - Executes a search query on an index.
// The 'index' parameter specifies the index to search, and the 'query' parameter specifies the search query.
// For more information, please refer to the Redis documentation:
// [FT.SEARCH]: (https://redis.io/commands/ft.search/)
func (c cmdable) FTSearch(ctx context.Context, index string, query string) *FTSearchCmd {
args := []interface{}{"FT.SEARCH", index, query}
cmd := newFTSearchCmd(ctx, &FTSearchOptions{}, args...)
_ = c(ctx, cmd)
return cmd
}
type SearchQuery []interface{}
func FTSearchQuery(query string, options *FTSearchOptions) SearchQuery {
queryArgs := []interface{}{query}
if options != nil {
if options.NoContent {
queryArgs = append(queryArgs, "NOCONTENT")
}
if options.Verbatim {
queryArgs = append(queryArgs, "VERBATIM")
}
if options.NoStopWrods {
queryArgs = append(queryArgs, "NOSTOPWORDS")
}
if options.WithScores {
queryArgs = append(queryArgs, "WITHSCORES")
}
if options.WithPayloads {
queryArgs = append(queryArgs, "WITHPAYLOADS")
}
if options.WithSortKeys {
queryArgs = append(queryArgs, "WITHSORTKEYS")
}
if options.Filters != nil {
for _, filter := range options.Filters {
queryArgs = append(queryArgs, "FILTER", filter.FieldName, filter.Min, filter.Max)
}
}
if options.GeoFilter != nil {
for _, geoFilter := range options.GeoFilter {
queryArgs = append(queryArgs, "GEOFILTER", geoFilter.FieldName, geoFilter.Longitude, geoFilter.Latitude, geoFilter.Radius, geoFilter.Unit)
}
}
if options.InKeys != nil {
queryArgs = append(queryArgs, "INKEYS", len(options.InKeys))
queryArgs = append(queryArgs, options.InKeys...)
}
if options.InFields != nil {
queryArgs = append(queryArgs, "INFIELDS", len(options.InFields))
queryArgs = append(queryArgs, options.InFields...)
}
if options.Return != nil {
queryArgs = append(queryArgs, "RETURN")
queryArgsReturn := []interface{}{}
for _, ret := range options.Return {
queryArgsReturn = append(queryArgsReturn, ret.FieldName)
if ret.As != "" {
queryArgsReturn = append(queryArgsReturn, "AS", ret.As)
}
}
queryArgs = append(queryArgs, len(queryArgsReturn))
queryArgs = append(queryArgs, queryArgsReturn...)
}
if options.Slop > 0 {
queryArgs = append(queryArgs, "SLOP", options.Slop)
}
if options.Timeout > 0 {
queryArgs = append(queryArgs, "TIMEOUT", options.Timeout)
}
if options.InOrder {
queryArgs = append(queryArgs, "INORDER")
}
if options.Language != "" {
queryArgs = append(queryArgs, "LANGUAGE", options.Language)
}
if options.Expander != "" {
queryArgs = append(queryArgs, "EXPANDER", options.Expander)
}
if options.Scorer != "" {
queryArgs = append(queryArgs, "SCORER", options.Scorer)
}
if options.ExplainScore {
queryArgs = append(queryArgs, "EXPLAINSCORE")
}
if options.Payload != "" {
queryArgs = append(queryArgs, "PAYLOAD", options.Payload)
}
if options.SortBy != nil {
queryArgs = append(queryArgs, "SORTBY")
for _, sortBy := range options.SortBy {
queryArgs = append(queryArgs, sortBy.FieldName)
if sortBy.Asc && sortBy.Desc {
panic("FT.SEARCH: ASC and DESC are mutually exclusive")
}
if sortBy.Asc {
queryArgs = append(queryArgs, "ASC")
}
if sortBy.Desc {
queryArgs = append(queryArgs, "DESC")
}
}
if options.SortByWithCount {
queryArgs = append(queryArgs, "WITHCOUT")
}
}
if options.LimitOffset >= 0 && options.Limit > 0 {
queryArgs = append(queryArgs, "LIMIT", options.LimitOffset, options.Limit)
}
if options.Params != nil {
queryArgs = append(queryArgs, "PARAMS", len(options.Params)*2)
for key, value := range options.Params {
queryArgs = append(queryArgs, key, value)
}
}
if options.DialectVersion > 0 {
queryArgs = append(queryArgs, "DIALECT", options.DialectVersion)
}
}
return queryArgs
}
// FTSearchWithArgs - Executes a search query on an index with additional options.
// The 'index' parameter specifies the index to search, the 'query' parameter specifies the search query,
// and the 'options' parameter specifies additional options for the search.
// For more information, please refer to the Redis documentation:
// [FT.SEARCH]: (https://redis.io/commands/ft.search/)
func (c cmdable) FTSearchWithArgs(ctx context.Context, index string, query string, options *FTSearchOptions) *FTSearchCmd {
args := []interface{}{"FT.SEARCH", index, query}
if options != nil {
if options.NoContent {
args = append(args, "NOCONTENT")
}
if options.Verbatim {
args = append(args, "VERBATIM")
}
if options.NoStopWrods {
args = append(args, "NOSTOPWORDS")
}
if options.WithScores {
args = append(args, "WITHSCORES")
}
if options.WithPayloads {
args = append(args, "WITHPAYLOADS")
}
if options.WithSortKeys {
args = append(args, "WITHSORTKEYS")
}
if options.Filters != nil {
for _, filter := range options.Filters {
args = append(args, "FILTER", filter.FieldName, filter.Min, filter.Max)
}
}
if options.GeoFilter != nil {
for _, geoFilter := range options.GeoFilter {
args = append(args, "GEOFILTER", geoFilter.FieldName, geoFilter.Longitude, geoFilter.Latitude, geoFilter.Radius, geoFilter.Unit)
}
}
if options.InKeys != nil {
args = append(args, "INKEYS", len(options.InKeys))
args = append(args, options.InKeys...)
}
if options.InFields != nil {
args = append(args, "INFIELDS", len(options.InFields))
args = append(args, options.InFields...)
}
if options.Return != nil {
args = append(args, "RETURN")
argsReturn := []interface{}{}
for _, ret := range options.Return {
argsReturn = append(argsReturn, ret.FieldName)
if ret.As != "" {
argsReturn = append(argsReturn, "AS", ret.As)
}
}
args = append(args, len(argsReturn))
args = append(args, argsReturn...)
}
if options.Slop > 0 {
args = append(args, "SLOP", options.Slop)
}
if options.Timeout > 0 {
args = append(args, "TIMEOUT", options.Timeout)
}
if options.InOrder {
args = append(args, "INORDER")
}
if options.Language != "" {
args = append(args, "LANGUAGE", options.Language)
}
if options.Expander != "" {
args = append(args, "EXPANDER", options.Expander)
}
if options.Scorer != "" {
args = append(args, "SCORER", options.Scorer)
}
if options.ExplainScore {
args = append(args, "EXPLAINSCORE")
}
if options.Payload != "" {
args = append(args, "PAYLOAD", options.Payload)
}
if options.SortBy != nil {
args = append(args, "SORTBY")
for _, sortBy := range options.SortBy {
args = append(args, sortBy.FieldName)
if sortBy.Asc && sortBy.Desc {
panic("FT.SEARCH: ASC and DESC are mutually exclusive")
}
if sortBy.Asc {
args = append(args, "ASC")
}
if sortBy.Desc {
args = append(args, "DESC")
}
}
if options.SortByWithCount {
args = append(args, "WITHCOUT")
}
}
if options.LimitOffset >= 0 && options.Limit > 0 {
args = append(args, "LIMIT", options.LimitOffset, options.Limit)
}
if options.Params != nil {
args = append(args, "PARAMS", len(options.Params)*2)
for key, value := range options.Params {
args = append(args, key, value)
}
}
if options.DialectVersion > 0 {
args = append(args, "DIALECT", options.DialectVersion)
}
}
cmd := newFTSearchCmd(ctx, options, args...)
_ = c(ctx, cmd)
return cmd
}
func NewFTSynDumpCmd(ctx context.Context, args ...interface{}) *FTSynDumpCmd {
return &FTSynDumpCmd{
baseCmd: baseCmd{
ctx: ctx,
args: args,
},
}
}
func (cmd *FTSynDumpCmd) String() string {
return cmdString(cmd, cmd.val)
}
func (cmd *FTSynDumpCmd) SetVal(val []FTSynDumpResult) {
cmd.val = val
}
func (cmd *FTSynDumpCmd) Val() []FTSynDumpResult {
return cmd.val
}
func (cmd *FTSynDumpCmd) Result() ([]FTSynDumpResult, error) {
return cmd.val, cmd.err
}
func (cmd *FTSynDumpCmd) readReply(rd *proto.Reader) error {
termSynonymPairs, err := rd.ReadSlice()
if err != nil {
return err
}
var results []FTSynDumpResult
for i := 0; i < len(termSynonymPairs); i += 2 {
term, ok := termSynonymPairs[i].(string)
if !ok {
return fmt.Errorf("invalid term format")
}
synonyms, ok := termSynonymPairs[i+1].([]interface{})
if !ok {
return fmt.Errorf("invalid synonyms format")
}
synonymList := make([]string, len(synonyms))
for j, syn := range synonyms {
synonym, ok := syn.(string)
if !ok {
return fmt.Errorf("invalid synonym format")
}
synonymList[j] = synonym
}
results = append(results, FTSynDumpResult{
Term: term,
Synonyms: synonymList,
})
}
cmd.val = results
return nil
}
// FTSynDump - Dumps the contents of a synonym group.
// The 'index' parameter specifies the index to dump.
// For more information, please refer to the Redis documentation:
// [FT.SYNDUMP]: (https://redis.io/commands/ft.syndump/)
func (c cmdable) FTSynDump(ctx context.Context, index string) *FTSynDumpCmd {
cmd := NewFTSynDumpCmd(ctx, "FT.SYNDUMP", index)
_ = c(ctx, cmd)
return cmd
}
// FTSynUpdate - Creates or updates a synonym group with additional terms.
// The 'index' parameter specifies the index to update, the 'synGroupId' parameter specifies the synonym group id, and the 'terms' parameter specifies the additional terms.
// For more information, please refer to the Redis documentation:
// [FT.SYNUPDATE]: (https://redis.io/commands/ft.synupdate/)
func (c cmdable) FTSynUpdate(ctx context.Context, index string, synGroupId interface{}, terms []interface{}) *StatusCmd {
args := []interface{}{"FT.SYNUPDATE", index, synGroupId}
args = append(args, terms...)
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTSynUpdateWithArgs - Creates or updates a synonym group with additional terms and options.
// The 'index' parameter specifies the index to update, the 'synGroupId' parameter specifies the synonym group id, the 'options' parameter specifies additional options for the update, and the 'terms' parameter specifies the additional terms.
// For more information, please refer to the Redis documentation:
// [FT.SYNUPDATE]: (https://redis.io/commands/ft.synupdate/)
func (c cmdable) FTSynUpdateWithArgs(ctx context.Context, index string, synGroupId interface{}, options *FTSynUpdateOptions, terms []interface{}) *StatusCmd {
args := []interface{}{"FT.SYNUPDATE", index, synGroupId}
if options.SkipInitialScan {
args = append(args, "SKIPINITIALSCAN")
}
args = append(args, terms...)
cmd := NewStatusCmd(ctx, args...)
_ = c(ctx, cmd)
return cmd
}
// FTTagVals - Returns all distinct values indexed in a tag field.
// The 'index' parameter specifies the index to check, and the 'field' parameter specifies the tag field to retrieve values from.
// For more information, please refer to the Redis documentation:
// [FT.TAGVALS]: (https://redis.io/commands/ft.tagvals/)
func (c cmdable) FTTagVals(ctx context.Context, index string, field string) *StringSliceCmd {
cmd := NewStringSliceCmd(ctx, "FT.TAGVALS", index, field)
_ = c(ctx, cmd)
return cmd
}
// type FTProfileResult struct {
// Results []interface{}
// Profile ProfileDetails
// }
// type ProfileDetails struct {
// TotalProfileTime string
// ParsingTime string
// PipelineCreationTime string
// Warning string
// IteratorsProfile []IteratorProfile
// ResultProcessorsProfile []ResultProcessorProfile
// }
// type IteratorProfile struct {
// Type string
// QueryType string
// Time interface{}
// Counter int
// Term string
// Size int
// ChildIterators []IteratorProfile
// }
// type ResultProcessorProfile struct {
// Type string
// Time interface{}
// Counter int
// }
// func parseFTProfileResult(data []interface{}) (FTProfileResult, error) {
// var result FTProfileResult
// if len(data) < 2 {
// return result, fmt.Errorf("unexpected data length")
// }
// // Parse results
// result.Results = data[0].([]interface{})
// // Parse profile details
// profileData := data[1].([]interface{})
// profileDetails := ProfileDetails{}
// for i := 0; i < len(profileData); i += 2 {
// switch profileData[i].(string) {
// case "Total profile time":
// profileDetails.TotalProfileTime = profileData[i+1].(string)
// case "Parsing time":
// profileDetails.ParsingTime = profileData[i+1].(string)
// case "Pipeline creation time":
// profileDetails.PipelineCreationTime = profileData[i+1].(string)
// case "Warning":
// profileDetails.Warning = profileData[i+1].(string)
// case "Iterators profile":
// profileDetails.IteratorsProfile = parseIteratorsProfile(profileData[i+1].([]interface{}))
// case "Result processors profile":
// profileDetails.ResultProcessorsProfile = parseResultProcessorsProfile(profileData[i+1].([]interface{}))
// }
// }
// result.Profile = profileDetails
// return result, nil
// }
// func parseIteratorsProfile(data []interface{}) []IteratorProfile {
// var iterators []IteratorProfile
// for _, item := range data {
// profile := item.([]interface{})
// iterator := IteratorProfile{}
// for i := 0; i < len(profile); i += 2 {
// switch profile[i].(string) {
// case "Type":
// iterator.Type = profile[i+1].(string)
// case "Query type":
// iterator.QueryType = profile[i+1].(string)
// case "Time":
// iterator.Time = profile[i+1]
// case "Counter":
// iterator.Counter = int(profile[i+1].(int64))
// case "Term":
// iterator.Term = profile[i+1].(string)
// case "Size":
// iterator.Size = int(profile[i+1].(int64))
// case "Child iterators":
// iterator.ChildIterators = parseChildIteratorsProfile(profile[i+1].([]interface{}))
// }
// }
// iterators = append(iterators, iterator)
// }
// return iterators
// }
// func parseChildIteratorsProfile(data []interface{}) []IteratorProfile {
// var iterators []IteratorProfile
// for _, item := range data {
// profile := item.([]interface{})
// iterator := IteratorProfile{}
// for i := 0; i < len(profile); i += 2 {
// switch profile[i].(string) {
// case "Type":
// iterator.Type = profile[i+1].(string)
// case "Query type":
// iterator.QueryType = profile[i+1].(string)
// case "Time":
// iterator.Time = profile[i+1]
// case "Counter":
// iterator.Counter = int(profile[i+1].(int64))
// case "Term":
// iterator.Term = profile[i+1].(string)
// case "Size":
// iterator.Size = int(profile[i+1].(int64))
// }
// }
// iterators = append(iterators, iterator)
// }
// return iterators
// }
// func parseResultProcessorsProfile(data []interface{}) []ResultProcessorProfile {
// var processors []ResultProcessorProfile
// for _, item := range data {
// profile := item.([]interface{})
// processor := ResultProcessorProfile{}
// for i := 0; i < len(profile); i += 2 {
// switch profile[i].(string) {
// case "Type":
// processor.Type = profile[i+1].(string)
// case "Time":
// processor.Time = profile[i+1]
// case "Counter":
// processor.Counter = int(profile[i+1].(int64))
// }
// }
// processors = append(processors, processor)
// }
// return processors
// }
// func NewFTProfileCmd(ctx context.Context, args ...interface{}) *FTProfileCmd {
// return &FTProfileCmd{
// baseCmd: baseCmd{
// ctx: ctx,
// args: args,
// },
// }
// }
// type FTProfileCmd struct {
// baseCmd
// val FTProfileResult
// }
// func (cmd *FTProfileCmd) String() string {
// return cmdString(cmd, cmd.val)
// }
// func (cmd *FTProfileCmd) SetVal(val FTProfileResult) {
// cmd.val = val
// }
// func (cmd *FTProfileCmd) Result() (FTProfileResult, error) {
// return cmd.val, cmd.err
// }
// func (cmd *FTProfileCmd) Val() FTProfileResult {
// return cmd.val
// }
// func (cmd *FTProfileCmd) readReply(rd *proto.Reader) (err error) {
// data, err := rd.ReadSlice()
// if err != nil {
// return err
// }
// cmd.val, err = parseFTProfileResult(data)
// if err != nil {
// cmd.err = err
// }
// return nil
// }
// // FTProfile - Executes a search query and returns a profile of how the query was processed.
// // The 'index' parameter specifies the index to search, the 'limited' parameter specifies whether to limit the results,
// // and the 'query' parameter specifies the search / aggreagte query. Please notice that you must either pass a SearchQuery or an AggregateQuery.
// // For more information, please refer to the Redis documentation:
// // [FT.PROFILE]: (https://redis.io/commands/ft.profile/)
// func (c cmdable) FTProfile(ctx context.Context, index string, limited bool, query interface{}) *FTProfileCmd {
// queryType := ""
// var argsQuery []interface{}
// switch v := query.(type) {
// case AggregateQuery:
// queryType = "AGGREGATE"
// argsQuery = v
// case SearchQuery:
// queryType = "SEARCH"
// argsQuery = v
// default:
// panic("FT.PROFILE: query must be either AggregateQuery or SearchQuery")
// }
// args := []interface{}{"FT.PROFILE", index, queryType}
// if limited {
// args = append(args, "LIMITED")
// }
// args = append(args, "QUERY")
// args = append(args, argsQuery...)
// cmd := NewFTProfileCmd(ctx, args...)
// _ = c(ctx, cmd)
// return cmd
// }