cri-o/vendor/google.golang.org/appengine/search/search.go
Jacek J. Łakis bf51655a7b vendor: Update vendoring for the exec client and server implementations
Signed-off-by: Jacek J. Łakis <jacek.lakis@intel.com>
Signed-off-by: Samuel Ortiz <sameo@linux.intel.com>
2017-04-24 18:38:41 +02:00

1121 lines
32 KiB
Go

// Copyright 2012 Google Inc. All rights reserved.
// Use of this source code is governed by the Apache 2.0
// license that can be found in the LICENSE file.
package search // import "google.golang.org/appengine/search"
// TODO: let Put specify the document language: "en", "fr", etc. Also: order_id?? storage??
// TODO: Index.GetAll (or Iterator.GetAll)?
// TODO: struct <-> protobuf tests.
// TODO: enforce Python's MIN_NUMBER_VALUE and MIN_DATE (which would disallow a zero
// time.Time)? _MAXIMUM_STRING_LENGTH?
import (
"errors"
"fmt"
"math"
"reflect"
"regexp"
"strconv"
"strings"
"time"
"unicode/utf8"
"github.com/golang/protobuf/proto"
"golang.org/x/net/context"
"google.golang.org/appengine"
"google.golang.org/appengine/internal"
pb "google.golang.org/appengine/internal/search"
)
var (
// ErrInvalidDocumentType is returned when methods like Put, Get or Next
// are passed a dst or src argument of invalid type.
ErrInvalidDocumentType = errors.New("search: invalid document type")
// ErrNoSuchDocument is returned when no document was found for a given ID.
ErrNoSuchDocument = errors.New("search: no such document")
)
// Atom is a document field whose contents are indexed as a single indivisible
// string.
type Atom string
// HTML is a document field whose contents are indexed as HTML. Only text nodes
// are indexed: "foo<b>bar" will be treated as "foobar".
type HTML string
// validIndexNameOrDocID is the Go equivalent of Python's
// _ValidateVisiblePrintableAsciiNotReserved.
func validIndexNameOrDocID(s string) bool {
if strings.HasPrefix(s, "!") {
return false
}
for _, c := range s {
if c < 0x21 || 0x7f <= c {
return false
}
}
return true
}
var (
fieldNameRE = regexp.MustCompile(`^[A-Za-z][A-Za-z0-9_]*$`)
languageRE = regexp.MustCompile(`^[a-z]{2}$`)
)
// validFieldName is the Go equivalent of Python's _CheckFieldName. It checks
// the validity of both field and facet names.
func validFieldName(s string) bool {
return len(s) <= 500 && fieldNameRE.MatchString(s)
}
// validDocRank checks that the ranks is in the range [0, 2^31).
func validDocRank(r int) bool {
return 0 <= r && r <= (1<<31-1)
}
// validLanguage checks that a language looks like ISO 639-1.
func validLanguage(s string) bool {
return languageRE.MatchString(s)
}
// validFloat checks that f is in the range [-2147483647, 2147483647].
func validFloat(f float64) bool {
return -(1<<31-1) <= f && f <= (1<<31-1)
}
// Index is an index of documents.
type Index struct {
spec pb.IndexSpec
}
// orderIDEpoch forms the basis for populating OrderId on documents.
var orderIDEpoch = time.Date(2011, 1, 1, 0, 0, 0, 0, time.UTC)
// Open opens the index with the given name. The index is created if it does
// not already exist.
//
// The name is a human-readable ASCII string. It must contain no whitespace
// characters and not start with "!".
func Open(name string) (*Index, error) {
if !validIndexNameOrDocID(name) {
return nil, fmt.Errorf("search: invalid index name %q", name)
}
return &Index{
spec: pb.IndexSpec{
Name: &name,
},
}, nil
}
// Put saves src to the index. If id is empty, a new ID is allocated by the
// service and returned. If id is not empty, any existing index entry for that
// ID is replaced.
//
// The ID is a human-readable ASCII string. It must contain no whitespace
// characters and not start with "!".
//
// src must be a non-nil struct pointer or implement the FieldLoadSaver
// interface.
func (x *Index) Put(c context.Context, id string, src interface{}) (string, error) {
d, err := saveDoc(src)
if err != nil {
return "", err
}
if id != "" {
if !validIndexNameOrDocID(id) {
return "", fmt.Errorf("search: invalid ID %q", id)
}
d.Id = proto.String(id)
}
// spec is modified by Call when applying the current Namespace, so copy it to
// avoid retaining the namespace beyond the scope of the Call.
spec := x.spec
req := &pb.IndexDocumentRequest{
Params: &pb.IndexDocumentParams{
Document: []*pb.Document{d},
IndexSpec: &spec,
},
}
res := &pb.IndexDocumentResponse{}
if err := internal.Call(c, "search", "IndexDocument", req, res); err != nil {
return "", err
}
if len(res.Status) > 0 {
if s := res.Status[0]; s.GetCode() != pb.SearchServiceError_OK {
return "", fmt.Errorf("search: %s: %s", s.GetCode(), s.GetErrorDetail())
}
}
if len(res.Status) != 1 || len(res.DocId) != 1 {
return "", fmt.Errorf("search: internal error: wrong number of results (%d Statuses, %d DocIDs)",
len(res.Status), len(res.DocId))
}
return res.DocId[0], nil
}
// Get loads the document with the given ID into dst.
//
// The ID is a human-readable ASCII string. It must be non-empty, contain no
// whitespace characters and not start with "!".
//
// dst must be a non-nil struct pointer or implement the FieldLoadSaver
// interface.
//
// ErrFieldMismatch is returned when a field is to be loaded into a different
// type than the one it was stored from, or when a field is missing or
// unexported in the destination struct. ErrFieldMismatch is only returned if
// dst is a struct pointer. It is up to the callee to decide whether this error
// is fatal, recoverable, or ignorable.
func (x *Index) Get(c context.Context, id string, dst interface{}) error {
if id == "" || !validIndexNameOrDocID(id) {
return fmt.Errorf("search: invalid ID %q", id)
}
req := &pb.ListDocumentsRequest{
Params: &pb.ListDocumentsParams{
IndexSpec: &x.spec,
StartDocId: proto.String(id),
Limit: proto.Int32(1),
},
}
res := &pb.ListDocumentsResponse{}
if err := internal.Call(c, "search", "ListDocuments", req, res); err != nil {
return err
}
if res.Status == nil || res.Status.GetCode() != pb.SearchServiceError_OK {
return fmt.Errorf("search: %s: %s", res.Status.GetCode(), res.Status.GetErrorDetail())
}
if len(res.Document) != 1 || res.Document[0].GetId() != id {
return ErrNoSuchDocument
}
return loadDoc(dst, res.Document[0], nil)
}
// Delete deletes a document from the index.
func (x *Index) Delete(c context.Context, id string) error {
req := &pb.DeleteDocumentRequest{
Params: &pb.DeleteDocumentParams{
DocId: []string{id},
IndexSpec: &x.spec,
},
}
res := &pb.DeleteDocumentResponse{}
if err := internal.Call(c, "search", "DeleteDocument", req, res); err != nil {
return err
}
if len(res.Status) != 1 {
return fmt.Errorf("search: internal error: wrong number of results (%d)", len(res.Status))
}
if s := res.Status[0]; s.GetCode() != pb.SearchServiceError_OK {
return fmt.Errorf("search: %s: %s", s.GetCode(), s.GetErrorDetail())
}
return nil
}
// List lists all of the documents in an index. The documents are returned in
// increasing ID order.
func (x *Index) List(c context.Context, opts *ListOptions) *Iterator {
t := &Iterator{
c: c,
index: x,
count: -1,
listInclusive: true,
more: moreList,
}
if opts != nil {
t.listStartID = opts.StartID
t.limit = opts.Limit
t.idsOnly = opts.IDsOnly
}
return t
}
func moreList(t *Iterator) error {
req := &pb.ListDocumentsRequest{
Params: &pb.ListDocumentsParams{
IndexSpec: &t.index.spec,
},
}
if t.listStartID != "" {
req.Params.StartDocId = &t.listStartID
req.Params.IncludeStartDoc = &t.listInclusive
}
if t.limit > 0 {
req.Params.Limit = proto.Int32(int32(t.limit))
}
if t.idsOnly {
req.Params.KeysOnly = &t.idsOnly
}
res := &pb.ListDocumentsResponse{}
if err := internal.Call(t.c, "search", "ListDocuments", req, res); err != nil {
return err
}
if res.Status == nil || res.Status.GetCode() != pb.SearchServiceError_OK {
return fmt.Errorf("search: %s: %s", res.Status.GetCode(), res.Status.GetErrorDetail())
}
t.listRes = res.Document
t.listStartID, t.listInclusive, t.more = "", false, nil
if len(res.Document) != 0 && t.limit <= 0 {
if id := res.Document[len(res.Document)-1].GetId(); id != "" {
t.listStartID, t.more = id, moreList
}
}
return nil
}
// ListOptions are the options for listing documents in an index. Passing a nil
// *ListOptions is equivalent to using the default values.
type ListOptions struct {
// StartID is the inclusive lower bound for the ID of the returned
// documents. The zero value means all documents will be returned.
StartID string
// Limit is the maximum number of documents to return. The zero value
// indicates no limit.
Limit int
// IDsOnly indicates that only document IDs should be returned for the list
// operation; no document fields are populated.
IDsOnly bool
}
// Search searches the index for the given query.
func (x *Index) Search(c context.Context, query string, opts *SearchOptions) *Iterator {
t := &Iterator{
c: c,
index: x,
searchQuery: query,
more: moreSearch,
}
if opts != nil {
if opts.Cursor != "" {
if opts.Offset != 0 {
return errIter("at most one of Cursor and Offset may be specified")
}
t.searchCursor = proto.String(string(opts.Cursor))
}
t.limit = opts.Limit
t.fields = opts.Fields
t.idsOnly = opts.IDsOnly
t.sort = opts.Sort
t.exprs = opts.Expressions
t.refinements = opts.Refinements
t.facetOpts = opts.Facets
t.searchOffset = opts.Offset
t.countAccuracy = opts.CountAccuracy
}
return t
}
func moreSearch(t *Iterator) error {
// We use per-result (rather than single/per-page) cursors since this
// lets us return a Cursor for every iterator document. The two cursor
// types are largely interchangeable: a page cursor is the same as the
// last per-result cursor in a given search response.
req := &pb.SearchRequest{
Params: &pb.SearchParams{
IndexSpec: &t.index.spec,
Query: &t.searchQuery,
Cursor: t.searchCursor,
CursorType: pb.SearchParams_PER_RESULT.Enum(),
FieldSpec: &pb.FieldSpec{
Name: t.fields,
},
},
}
if t.limit > 0 {
req.Params.Limit = proto.Int32(int32(t.limit))
}
if t.searchOffset > 0 {
req.Params.Offset = proto.Int32(int32(t.searchOffset))
t.searchOffset = 0
}
if t.countAccuracy > 0 {
req.Params.MatchedCountAccuracy = proto.Int32(int32(t.countAccuracy))
}
if t.idsOnly {
req.Params.KeysOnly = &t.idsOnly
}
if t.sort != nil {
if err := sortToProto(t.sort, req.Params); err != nil {
return err
}
}
if t.refinements != nil {
if err := refinementsToProto(t.refinements, req.Params); err != nil {
return err
}
}
for _, e := range t.exprs {
req.Params.FieldSpec.Expression = append(req.Params.FieldSpec.Expression, &pb.FieldSpec_Expression{
Name: proto.String(e.Name),
Expression: proto.String(e.Expr),
})
}
for _, f := range t.facetOpts {
if err := f.setParams(req.Params); err != nil {
return fmt.Errorf("bad FacetSearchOption: %v", err)
}
}
// Don't repeat facet search.
t.facetOpts = nil
res := &pb.SearchResponse{}
if err := internal.Call(t.c, "search", "Search", req, res); err != nil {
return err
}
if res.Status == nil || res.Status.GetCode() != pb.SearchServiceError_OK {
return fmt.Errorf("search: %s: %s", res.Status.GetCode(), res.Status.GetErrorDetail())
}
t.searchRes = res.Result
if len(res.FacetResult) > 0 {
t.facetRes = res.FacetResult
}
t.count = int(*res.MatchedCount)
if t.limit > 0 {
t.more = nil
} else {
t.more = moreSearch
}
return nil
}
// SearchOptions are the options for searching an index. Passing a nil
// *SearchOptions is equivalent to using the default values.
type SearchOptions struct {
// Limit is the maximum number of documents to return. The zero value
// indicates no limit.
Limit int
// IDsOnly indicates that only document IDs should be returned for the search
// operation; no document fields are populated.
IDsOnly bool
// Sort controls the ordering of search results.
Sort *SortOptions
// Fields specifies which document fields to include in the results. If omitted,
// all document fields are returned. No more than 100 fields may be specified.
Fields []string
// Expressions specifies additional computed fields to add to each returned
// document.
Expressions []FieldExpression
// Facets controls what facet information is returned for these search results.
// If no options are specified, no facet results will be returned.
Facets []FacetSearchOption
// Refinements filters the returned documents by requiring them to contain facets
// with specific values. Refinements are applied in conjunction for facets with
// different names, and in disjunction otherwise.
Refinements []Facet
// Cursor causes the results to commence with the first document after
// the document associated with the cursor.
Cursor Cursor
// Offset specifies the number of documents to skip over before returning results.
// When specified, Cursor must be nil.
Offset int
// CountAccuracy specifies the maximum result count that can be expected to
// be accurate. If zero, the count accuracy defaults to 20.
CountAccuracy int
}
// Cursor represents an iterator's position.
//
// The string value of a cursor is web-safe. It can be saved and restored
// for later use.
type Cursor string
// FieldExpression defines a custom expression to evaluate for each result.
type FieldExpression struct {
// Name is the name to use for the computed field.
Name string
// Expr is evaluated to provide a custom content snippet for each document.
// See https://cloud.google.com/appengine/docs/go/search/options for
// the supported expression syntax.
Expr string
}
// FacetSearchOption controls what facet information is returned in search results.
type FacetSearchOption interface {
setParams(*pb.SearchParams) error
}
// AutoFacetDiscovery returns a FacetSearchOption which enables automatic facet
// discovery for the search. Automatic facet discovery looks for the facets
// which appear the most often in the aggregate in the matched documents.
//
// The maximum number of facets returned is controlled by facetLimit, and the
// maximum number of values per facet by facetLimit. A limit of zero indicates
// a default limit should be used.
func AutoFacetDiscovery(facetLimit, valueLimit int) FacetSearchOption {
return &autoFacetOpt{facetLimit, valueLimit}
}
type autoFacetOpt struct {
facetLimit, valueLimit int
}
const defaultAutoFacetLimit = 10 // As per python runtime search.py.
func (o *autoFacetOpt) setParams(params *pb.SearchParams) error {
lim := int32(o.facetLimit)
if lim == 0 {
lim = defaultAutoFacetLimit
}
params.AutoDiscoverFacetCount = &lim
if o.valueLimit > 0 {
params.FacetAutoDetectParam = &pb.FacetAutoDetectParam{
ValueLimit: proto.Int32(int32(o.valueLimit)),
}
}
return nil
}
// FacetDiscovery returns a FacetSearchOption which selects a facet to be
// returned with the search results. By default, the most frequently
// occurring values for that facet will be returned. However, you can also
// specify a list of particular Atoms or specific Ranges to return.
func FacetDiscovery(name string, value ...interface{}) FacetSearchOption {
return &facetOpt{name, value}
}
type facetOpt struct {
name string
values []interface{}
}
func (o *facetOpt) setParams(params *pb.SearchParams) error {
req := &pb.FacetRequest{Name: &o.name}
params.IncludeFacet = append(params.IncludeFacet, req)
if len(o.values) == 0 {
return nil
}
vtype := reflect.TypeOf(o.values[0])
reqParam := &pb.FacetRequestParam{}
for _, v := range o.values {
if reflect.TypeOf(v) != vtype {
return errors.New("values must all be Atom, or must all be Range")
}
switch v := v.(type) {
case Atom:
reqParam.ValueConstraint = append(reqParam.ValueConstraint, string(v))
case Range:
rng, err := rangeToProto(v)
if err != nil {
return fmt.Errorf("invalid range: %v", err)
}
reqParam.Range = append(reqParam.Range, rng)
default:
return fmt.Errorf("unsupported value type %T", v)
}
}
req.Params = reqParam
return nil
}
// FacetDocumentDepth returns a FacetSearchOption which controls the number of
// documents to be evaluated with preparing facet results.
func FacetDocumentDepth(depth int) FacetSearchOption {
return facetDepthOpt(depth)
}
type facetDepthOpt int
func (o facetDepthOpt) setParams(params *pb.SearchParams) error {
params.FacetDepth = proto.Int32(int32(o))
return nil
}
// FacetResult represents the number of times a particular facet and value
// appeared in the documents matching a search request.
type FacetResult struct {
Facet
// Count is the number of times this specific facet and value appeared in the
// matching documents.
Count int
}
// Range represents a numeric range with inclusive start and exclusive end.
// Start may be specified as math.Inf(-1) to indicate there is no minimum
// value, and End may similarly be specified as math.Inf(1); at least one of
// Start or End must be a finite number.
type Range struct {
Start, End float64
}
var (
negInf = math.Inf(-1)
posInf = math.Inf(1)
)
// AtLeast returns a Range matching any value greater than, or equal to, min.
func AtLeast(min float64) Range {
return Range{Start: min, End: posInf}
}
// LessThan returns a Range matching any value less than max.
func LessThan(max float64) Range {
return Range{Start: negInf, End: max}
}
// SortOptions control the ordering and scoring of search results.
type SortOptions struct {
// Expressions is a slice of expressions representing a multi-dimensional
// sort.
Expressions []SortExpression
// Scorer, when specified, will cause the documents to be scored according to
// search term frequency.
Scorer Scorer
// Limit is the maximum number of objects to score and/or sort. Limit cannot
// be more than 10,000. The zero value indicates a default limit.
Limit int
}
// SortExpression defines a single dimension for sorting a document.
type SortExpression struct {
// Expr is evaluated to provide a sorting value for each document.
// See https://cloud.google.com/appengine/docs/go/search/options for
// the supported expression syntax.
Expr string
// Reverse causes the documents to be sorted in ascending order.
Reverse bool
// The default value to use when no field is present or the expresion
// cannot be calculated for a document. For text sorts, Default must
// be of type string; for numeric sorts, float64.
Default interface{}
}
// A Scorer defines how a document is scored.
type Scorer interface {
toProto(*pb.ScorerSpec)
}
type enumScorer struct {
enum pb.ScorerSpec_Scorer
}
func (e enumScorer) toProto(spec *pb.ScorerSpec) {
spec.Scorer = e.enum.Enum()
}
var (
// MatchScorer assigns a score based on term frequency in a document.
MatchScorer Scorer = enumScorer{pb.ScorerSpec_MATCH_SCORER}
// RescoringMatchScorer assigns a score based on the quality of the query
// match. It is similar to a MatchScorer but uses a more complex scoring
// algorithm based on match term frequency and other factors like field type.
// Please be aware that this algorithm is continually refined and can change
// over time without notice. This means that the ordering of search results
// that use this scorer can also change without notice.
RescoringMatchScorer Scorer = enumScorer{pb.ScorerSpec_RESCORING_MATCH_SCORER}
)
func sortToProto(sort *SortOptions, params *pb.SearchParams) error {
for _, e := range sort.Expressions {
spec := &pb.SortSpec{
SortExpression: proto.String(e.Expr),
}
if e.Reverse {
spec.SortDescending = proto.Bool(false)
}
if e.Default != nil {
switch d := e.Default.(type) {
case float64:
spec.DefaultValueNumeric = &d
case string:
spec.DefaultValueText = &d
default:
return fmt.Errorf("search: invalid Default type %T for expression %q", d, e.Expr)
}
}
params.SortSpec = append(params.SortSpec, spec)
}
spec := &pb.ScorerSpec{}
if sort.Limit > 0 {
spec.Limit = proto.Int32(int32(sort.Limit))
params.ScorerSpec = spec
}
if sort.Scorer != nil {
sort.Scorer.toProto(spec)
params.ScorerSpec = spec
}
return nil
}
func refinementsToProto(refinements []Facet, params *pb.SearchParams) error {
for _, r := range refinements {
ref := &pb.FacetRefinement{
Name: proto.String(r.Name),
}
switch v := r.Value.(type) {
case Atom:
ref.Value = proto.String(string(v))
case Range:
rng, err := rangeToProto(v)
if err != nil {
return fmt.Errorf("search: refinement for facet %q: %v", r.Name, err)
}
// Unfortunately there are two identical messages for identify Facet ranges.
ref.Range = &pb.FacetRefinement_Range{Start: rng.Start, End: rng.End}
default:
return fmt.Errorf("search: unsupported refinement for facet %q of type %T", r.Name, v)
}
params.FacetRefinement = append(params.FacetRefinement, ref)
}
return nil
}
func rangeToProto(r Range) (*pb.FacetRange, error) {
rng := &pb.FacetRange{}
if r.Start != negInf {
if !validFloat(r.Start) {
return nil, errors.New("invalid value for Start")
}
rng.Start = proto.String(strconv.FormatFloat(r.Start, 'e', -1, 64))
} else if r.End == posInf {
return nil, errors.New("either Start or End must be finite")
}
if r.End != posInf {
if !validFloat(r.End) {
return nil, errors.New("invalid value for End")
}
rng.End = proto.String(strconv.FormatFloat(r.End, 'e', -1, 64))
}
return rng, nil
}
func protoToRange(rng *pb.FacetRefinement_Range) Range {
r := Range{Start: negInf, End: posInf}
if x, err := strconv.ParseFloat(rng.GetStart(), 64); err != nil {
r.Start = x
}
if x, err := strconv.ParseFloat(rng.GetEnd(), 64); err != nil {
r.End = x
}
return r
}
// Iterator is the result of searching an index for a query or listing an
// index.
type Iterator struct {
c context.Context
index *Index
err error
listRes []*pb.Document
listStartID string
listInclusive bool
searchRes []*pb.SearchResult
facetRes []*pb.FacetResult
searchQuery string
searchCursor *string
searchOffset int
sort *SortOptions
fields []string
exprs []FieldExpression
refinements []Facet
facetOpts []FacetSearchOption
more func(*Iterator) error
count int
countAccuracy int
limit int // items left to return; 0 for unlimited.
idsOnly bool
}
// errIter returns an iterator that only returns the given error.
func errIter(err string) *Iterator {
return &Iterator{
err: errors.New(err),
}
}
// Done is returned when a query iteration has completed.
var Done = errors.New("search: query has no more results")
// Count returns an approximation of the number of documents matched by the
// query. It is only valid to call for iterators returned by Search.
func (t *Iterator) Count() int { return t.count }
// fetchMore retrieves more results, if there are no errors or pending results.
func (t *Iterator) fetchMore() {
if t.err == nil && len(t.listRes)+len(t.searchRes) == 0 && t.more != nil {
t.err = t.more(t)
}
}
// Next returns the ID of the next result. When there are no more results,
// Done is returned as the error.
//
// dst must be a non-nil struct pointer, implement the FieldLoadSaver
// interface, or be a nil interface value. If a non-nil dst is provided, it
// will be filled with the indexed fields. dst is ignored if this iterator was
// created with an IDsOnly option.
func (t *Iterator) Next(dst interface{}) (string, error) {
t.fetchMore()
if t.err != nil {
return "", t.err
}
var doc *pb.Document
var exprs []*pb.Field
switch {
case len(t.listRes) != 0:
doc = t.listRes[0]
t.listRes = t.listRes[1:]
case len(t.searchRes) != 0:
doc = t.searchRes[0].Document
exprs = t.searchRes[0].Expression
t.searchCursor = t.searchRes[0].Cursor
t.searchRes = t.searchRes[1:]
default:
return "", Done
}
if doc == nil {
return "", errors.New("search: internal error: no document returned")
}
if !t.idsOnly && dst != nil {
if err := loadDoc(dst, doc, exprs); err != nil {
return "", err
}
}
return doc.GetId(), nil
}
// Cursor returns the cursor associated with the current document (that is,
// the document most recently returned by a call to Next).
//
// Passing this cursor in a future call to Search will cause those results
// to commence with the first document after the current document.
func (t *Iterator) Cursor() Cursor {
if t.searchCursor == nil {
return ""
}
return Cursor(*t.searchCursor)
}
// Facets returns the facets found within the search results, if any facets
// were requested in the SearchOptions.
func (t *Iterator) Facets() ([][]FacetResult, error) {
t.fetchMore()
if t.err != nil && t.err != Done {
return nil, t.err
}
var facets [][]FacetResult
for _, f := range t.facetRes {
fres := make([]FacetResult, 0, len(f.Value))
for _, v := range f.Value {
ref := v.Refinement
facet := FacetResult{
Facet: Facet{Name: ref.GetName()},
Count: int(v.GetCount()),
}
if ref.Value != nil {
facet.Value = Atom(*ref.Value)
} else {
facet.Value = protoToRange(ref.Range)
}
fres = append(fres, facet)
}
facets = append(facets, fres)
}
return facets, nil
}
// saveDoc converts from a struct pointer or
// FieldLoadSaver/FieldMetadataLoadSaver to the Document protobuf.
func saveDoc(src interface{}) (*pb.Document, error) {
var err error
var fields []Field
var meta *DocumentMetadata
switch x := src.(type) {
case FieldLoadSaver:
fields, meta, err = x.Save()
default:
fields, meta, err = saveStructWithMeta(src)
}
if err != nil {
return nil, err
}
fieldsProto, err := fieldsToProto(fields)
if err != nil {
return nil, err
}
d := &pb.Document{
Field: fieldsProto,
OrderId: proto.Int32(int32(time.Since(orderIDEpoch).Seconds())),
}
if meta != nil {
if meta.Rank != 0 {
if !validDocRank(meta.Rank) {
return nil, fmt.Errorf("search: invalid rank %d, must be [0, 2^31)", meta.Rank)
}
*d.OrderId = int32(meta.Rank)
}
if len(meta.Facets) > 0 {
facets, err := facetsToProto(meta.Facets)
if err != nil {
return nil, err
}
d.Facet = facets
}
}
return d, nil
}
func fieldsToProto(src []Field) ([]*pb.Field, error) {
// Maps to catch duplicate time or numeric fields.
timeFields, numericFields := make(map[string]bool), make(map[string]bool)
dst := make([]*pb.Field, 0, len(src))
for _, f := range src {
if !validFieldName(f.Name) {
return nil, fmt.Errorf("search: invalid field name %q", f.Name)
}
fieldValue := &pb.FieldValue{}
switch x := f.Value.(type) {
case string:
fieldValue.Type = pb.FieldValue_TEXT.Enum()
fieldValue.StringValue = proto.String(x)
case Atom:
fieldValue.Type = pb.FieldValue_ATOM.Enum()
fieldValue.StringValue = proto.String(string(x))
case HTML:
fieldValue.Type = pb.FieldValue_HTML.Enum()
fieldValue.StringValue = proto.String(string(x))
case time.Time:
if timeFields[f.Name] {
return nil, fmt.Errorf("search: duplicate time field %q", f.Name)
}
timeFields[f.Name] = true
fieldValue.Type = pb.FieldValue_DATE.Enum()
fieldValue.StringValue = proto.String(strconv.FormatInt(x.UnixNano()/1e6, 10))
case float64:
if numericFields[f.Name] {
return nil, fmt.Errorf("search: duplicate numeric field %q", f.Name)
}
if !validFloat(x) {
return nil, fmt.Errorf("search: numeric field %q with invalid value %f", f.Name, x)
}
numericFields[f.Name] = true
fieldValue.Type = pb.FieldValue_NUMBER.Enum()
fieldValue.StringValue = proto.String(strconv.FormatFloat(x, 'e', -1, 64))
case appengine.GeoPoint:
if !x.Valid() {
return nil, fmt.Errorf(
"search: GeoPoint field %q with invalid value %v",
f.Name, x)
}
fieldValue.Type = pb.FieldValue_GEO.Enum()
fieldValue.Geo = &pb.FieldValue_Geo{
Lat: proto.Float64(x.Lat),
Lng: proto.Float64(x.Lng),
}
default:
return nil, fmt.Errorf("search: unsupported field type: %v", reflect.TypeOf(f.Value))
}
if f.Language != "" {
switch f.Value.(type) {
case string, HTML:
if !validLanguage(f.Language) {
return nil, fmt.Errorf("search: invalid language for field %q: %q", f.Name, f.Language)
}
fieldValue.Language = proto.String(f.Language)
default:
return nil, fmt.Errorf("search: setting language not supported for field %q of type %T", f.Name, f.Value)
}
}
if p := fieldValue.StringValue; p != nil && !utf8.ValidString(*p) {
return nil, fmt.Errorf("search: %q field is invalid UTF-8: %q", f.Name, *p)
}
dst = append(dst, &pb.Field{
Name: proto.String(f.Name),
Value: fieldValue,
})
}
return dst, nil
}
func facetsToProto(src []Facet) ([]*pb.Facet, error) {
dst := make([]*pb.Facet, 0, len(src))
for _, f := range src {
if !validFieldName(f.Name) {
return nil, fmt.Errorf("search: invalid facet name %q", f.Name)
}
facetValue := &pb.FacetValue{}
switch x := f.Value.(type) {
case Atom:
if !utf8.ValidString(string(x)) {
return nil, fmt.Errorf("search: %q facet is invalid UTF-8: %q", f.Name, x)
}
facetValue.Type = pb.FacetValue_ATOM.Enum()
facetValue.StringValue = proto.String(string(x))
case float64:
if !validFloat(x) {
return nil, fmt.Errorf("search: numeric facet %q with invalid value %f", f.Name, x)
}
facetValue.Type = pb.FacetValue_NUMBER.Enum()
facetValue.StringValue = proto.String(strconv.FormatFloat(x, 'e', -1, 64))
default:
return nil, fmt.Errorf("search: unsupported facet type: %v", reflect.TypeOf(f.Value))
}
dst = append(dst, &pb.Facet{
Name: proto.String(f.Name),
Value: facetValue,
})
}
return dst, nil
}
// loadDoc converts from protobufs to a struct pointer or
// FieldLoadSaver/FieldMetadataLoadSaver. The src param provides the document's
// stored fields and facets, and any document metadata. An additional slice of
// fields, exprs, may optionally be provided to contain any derived expressions
// requested by the developer.
func loadDoc(dst interface{}, src *pb.Document, exprs []*pb.Field) (err error) {
fields, err := protoToFields(src.Field)
if err != nil {
return err
}
facets, err := protoToFacets(src.Facet)
if err != nil {
return err
}
if len(exprs) > 0 {
exprFields, err := protoToFields(exprs)
if err != nil {
return err
}
// Mark each field as derived.
for i := range exprFields {
exprFields[i].Derived = true
}
fields = append(fields, exprFields...)
}
meta := &DocumentMetadata{
Rank: int(src.GetOrderId()),
Facets: facets,
}
switch x := dst.(type) {
case FieldLoadSaver:
return x.Load(fields, meta)
default:
return loadStructWithMeta(dst, fields, meta)
}
}
func protoToFields(fields []*pb.Field) ([]Field, error) {
dst := make([]Field, 0, len(fields))
for _, field := range fields {
fieldValue := field.GetValue()
f := Field{
Name: field.GetName(),
}
switch fieldValue.GetType() {
case pb.FieldValue_TEXT:
f.Value = fieldValue.GetStringValue()
f.Language = fieldValue.GetLanguage()
case pb.FieldValue_ATOM:
f.Value = Atom(fieldValue.GetStringValue())
case pb.FieldValue_HTML:
f.Value = HTML(fieldValue.GetStringValue())
f.Language = fieldValue.GetLanguage()
case pb.FieldValue_DATE:
sv := fieldValue.GetStringValue()
millis, err := strconv.ParseInt(sv, 10, 64)
if err != nil {
return nil, fmt.Errorf("search: internal error: bad time.Time encoding %q: %v", sv, err)
}
f.Value = time.Unix(0, millis*1e6)
case pb.FieldValue_NUMBER:
sv := fieldValue.GetStringValue()
x, err := strconv.ParseFloat(sv, 64)
if err != nil {
return nil, err
}
f.Value = x
case pb.FieldValue_GEO:
geoValue := fieldValue.GetGeo()
geoPoint := appengine.GeoPoint{geoValue.GetLat(), geoValue.GetLng()}
if !geoPoint.Valid() {
return nil, fmt.Errorf("search: internal error: invalid GeoPoint encoding: %v", geoPoint)
}
f.Value = geoPoint
default:
return nil, fmt.Errorf("search: internal error: unknown data type %s", fieldValue.GetType())
}
dst = append(dst, f)
}
return dst, nil
}
func protoToFacets(facets []*pb.Facet) ([]Facet, error) {
if len(facets) == 0 {
return nil, nil
}
dst := make([]Facet, 0, len(facets))
for _, facet := range facets {
facetValue := facet.GetValue()
f := Facet{
Name: facet.GetName(),
}
switch facetValue.GetType() {
case pb.FacetValue_ATOM:
f.Value = Atom(facetValue.GetStringValue())
case pb.FacetValue_NUMBER:
sv := facetValue.GetStringValue()
x, err := strconv.ParseFloat(sv, 64)
if err != nil {
return nil, err
}
f.Value = x
default:
return nil, fmt.Errorf("search: internal error: unknown data type %s", facetValue.GetType())
}
dst = append(dst, f)
}
return dst, nil
}
func namespaceMod(m proto.Message, namespace string) {
set := func(s **string) {
if *s == nil {
*s = &namespace
}
}
switch m := m.(type) {
case *pb.IndexDocumentRequest:
set(&m.Params.IndexSpec.Namespace)
case *pb.ListDocumentsRequest:
set(&m.Params.IndexSpec.Namespace)
case *pb.DeleteDocumentRequest:
set(&m.Params.IndexSpec.Namespace)
case *pb.SearchRequest:
set(&m.Params.IndexSpec.Namespace)
}
}
func init() {
internal.RegisterErrorCodeMap("search", pb.SearchServiceError_ErrorCode_name)
internal.NamespaceMods["search"] = namespaceMod
}