ref: d6ed17c60fd13c933347110c720afa09e04df1c8
dir: /tpl/collections/where.go/
// Copyright 2017 The Hugo Authors. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package collections import ( "errors" "fmt" "reflect" "strings" "github.com/gohugoio/hugo/common/maps" ) // Where returns a filtered subset of a given data type. func (ns *Namespace) Where(seq, key interface{}, args ...interface{}) (interface{}, error) { seqv, isNil := indirect(reflect.ValueOf(seq)) if isNil { return nil, errors.New("can't iterate over a nil value of type " + reflect.ValueOf(seq).Type().String()) } mv, op, err := parseWhereArgs(args...) if err != nil { return nil, err } var path []string kv := reflect.ValueOf(key) if kv.Kind() == reflect.String { path = strings.Split(strings.Trim(kv.String(), "."), ".") } switch seqv.Kind() { case reflect.Array, reflect.Slice: return ns.checkWhereArray(seqv, kv, mv, path, op) case reflect.Map: return ns.checkWhereMap(seqv, kv, mv, path, op) default: return nil, fmt.Errorf("can't iterate over %v", seq) } } func (ns *Namespace) checkCondition(v, mv reflect.Value, op string) (bool, error) { v, vIsNil := indirect(v) if !v.IsValid() { vIsNil = true } mv, mvIsNil := indirect(mv) if !mv.IsValid() { mvIsNil = true } if vIsNil || mvIsNil { switch op { case "", "=", "==", "eq": return vIsNil == mvIsNil, nil case "!=", "<>", "ne": return vIsNil != mvIsNil, nil } return false, nil } if v.Kind() == reflect.Bool && mv.Kind() == reflect.Bool { switch op { case "", "=", "==", "eq": return v.Bool() == mv.Bool(), nil case "!=", "<>", "ne": return v.Bool() != mv.Bool(), nil } return false, nil } var ivp, imvp *int64 var fvp, fmvp *float64 var svp, smvp *string var slv, slmv interface{} var ima []int64 var fma []float64 var sma []string if mv.Type() == v.Type() { switch v.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: iv := v.Int() ivp = &iv imv := mv.Int() imvp = &imv case reflect.String: sv := v.String() svp = &sv smv := mv.String() smvp = &smv case reflect.Float64: fv := v.Float() fvp = &fv fmv := mv.Float() fmvp = &fmv case reflect.Struct: switch v.Type() { case timeType: iv := toTimeUnix(v) ivp = &iv imv := toTimeUnix(mv) imvp = &imv } case reflect.Array, reflect.Slice: slv = v.Interface() slmv = mv.Interface() } } else if isNumber(v.Kind()) && isNumber(mv.Kind()) { fv, err := toFloat(v) if err != nil { return false, err } fvp = &fv fmv, err := toFloat(mv) if err != nil { return false, err } fmvp = &fmv } else { if mv.Kind() != reflect.Array && mv.Kind() != reflect.Slice { return false, nil } if mv.Len() == 0 { return false, nil } if v.Kind() != reflect.Interface && mv.Type().Elem().Kind() != reflect.Interface && mv.Type().Elem() != v.Type() && v.Kind() != reflect.Array && v.Kind() != reflect.Slice { return false, nil } switch v.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: iv := v.Int() ivp = &iv for i := 0; i < mv.Len(); i++ { if anInt, err := toInt(mv.Index(i)); err == nil { ima = append(ima, anInt) } } case reflect.String: sv := v.String() svp = &sv for i := 0; i < mv.Len(); i++ { if aString, err := toString(mv.Index(i)); err == nil { sma = append(sma, aString) } } case reflect.Float64: fv := v.Float() fvp = &fv for i := 0; i < mv.Len(); i++ { if aFloat, err := toFloat(mv.Index(i)); err == nil { fma = append(fma, aFloat) } } case reflect.Struct: switch v.Type() { case timeType: iv := toTimeUnix(v) ivp = &iv for i := 0; i < mv.Len(); i++ { ima = append(ima, toTimeUnix(mv.Index(i))) } } case reflect.Array, reflect.Slice: slv = v.Interface() slmv = mv.Interface() } } switch op { case "", "=", "==", "eq": switch { case ivp != nil && imvp != nil: return *ivp == *imvp, nil case svp != nil && smvp != nil: return *svp == *smvp, nil case fvp != nil && fmvp != nil: return *fvp == *fmvp, nil } case "!=", "<>", "ne": switch { case ivp != nil && imvp != nil: return *ivp != *imvp, nil case svp != nil && smvp != nil: return *svp != *smvp, nil case fvp != nil && fmvp != nil: return *fvp != *fmvp, nil } case ">=", "ge": switch { case ivp != nil && imvp != nil: return *ivp >= *imvp, nil case svp != nil && smvp != nil: return *svp >= *smvp, nil case fvp != nil && fmvp != nil: return *fvp >= *fmvp, nil } case ">", "gt": switch { case ivp != nil && imvp != nil: return *ivp > *imvp, nil case svp != nil && smvp != nil: return *svp > *smvp, nil case fvp != nil && fmvp != nil: return *fvp > *fmvp, nil } case "<=", "le": switch { case ivp != nil && imvp != nil: return *ivp <= *imvp, nil case svp != nil && smvp != nil: return *svp <= *smvp, nil case fvp != nil && fmvp != nil: return *fvp <= *fmvp, nil } case "<", "lt": switch { case ivp != nil && imvp != nil: return *ivp < *imvp, nil case svp != nil && smvp != nil: return *svp < *smvp, nil case fvp != nil && fmvp != nil: return *fvp < *fmvp, nil } case "in", "not in": var r bool switch { case ivp != nil && len(ima) > 0: r, _ = ns.In(ima, *ivp) case fvp != nil && len(fma) > 0: r, _ = ns.In(fma, *fvp) case svp != nil: if len(sma) > 0 { r, _ = ns.In(sma, *svp) } else if smvp != nil { r, _ = ns.In(*smvp, *svp) } default: return false, nil } if op == "not in" { return !r, nil } return r, nil case "intersect": r, err := ns.Intersect(slv, slmv) if err != nil { return false, err } if reflect.TypeOf(r).Kind() == reflect.Slice { s := reflect.ValueOf(r) if s.Len() > 0 { return true, nil } return false, nil } return false, errors.New("invalid intersect values") default: return false, errors.New("no such operator") } return false, nil } func evaluateSubElem(obj reflect.Value, elemName string) (reflect.Value, error) { if !obj.IsValid() { return zero, errors.New("can't evaluate an invalid value") } typ := obj.Type() obj, isNil := indirect(obj) if obj.Kind() == reflect.Interface { // If obj is an interface, we need to inspect the value it contains // to see the full set of methods and fields. // Indirect returns the value that it points to, which is what's needed // below to be able to reflect on its fields. obj = reflect.Indirect(obj.Elem()) } // first, check whether obj has a method. In this case, obj is // a struct or its pointer. If obj is a struct, // to check all T and *T method, use obj pointer type Value objPtr := obj if objPtr.Kind() != reflect.Interface && objPtr.CanAddr() { objPtr = objPtr.Addr() } mt, ok := objPtr.Type().MethodByName(elemName) if ok { switch { case mt.PkgPath != "": return zero, fmt.Errorf("%s is an unexported method of type %s", elemName, typ) case mt.Type.NumIn() > 1: return zero, fmt.Errorf("%s is a method of type %s but requires more than 1 parameter", elemName, typ) case mt.Type.NumOut() == 0: return zero, fmt.Errorf("%s is a method of type %s but returns no output", elemName, typ) case mt.Type.NumOut() > 2: return zero, fmt.Errorf("%s is a method of type %s but returns more than 2 outputs", elemName, typ) case mt.Type.NumOut() == 1 && mt.Type.Out(0).Implements(errorType): return zero, fmt.Errorf("%s is a method of type %s but only returns an error type", elemName, typ) case mt.Type.NumOut() == 2 && !mt.Type.Out(1).Implements(errorType): return zero, fmt.Errorf("%s is a method of type %s returning two values but the second value is not an error type", elemName, typ) } res := objPtr.Method(mt.Index).Call([]reflect.Value{}) if len(res) == 2 && !res[1].IsNil() { return zero, fmt.Errorf("error at calling a method %s of type %s: %s", elemName, typ, res[1].Interface().(error)) } return res[0], nil } // elemName isn't a method so next start to check whether it is // a struct field or a map value. In both cases, it mustn't be // a nil value if isNil { return zero, fmt.Errorf("can't evaluate a nil pointer of type %s by a struct field or map key name %s", typ, elemName) } switch obj.Kind() { case reflect.Struct: ft, ok := obj.Type().FieldByName(elemName) if ok { if ft.PkgPath != "" && !ft.Anonymous { return zero, fmt.Errorf("%s is an unexported field of struct type %s", elemName, typ) } return obj.FieldByIndex(ft.Index), nil } return zero, fmt.Errorf("%s isn't a field of struct type %s", elemName, typ) case reflect.Map: kv := reflect.ValueOf(elemName) if kv.Type().AssignableTo(obj.Type().Key()) { return obj.MapIndex(kv), nil } return zero, fmt.Errorf("%s isn't a key of map type %s", elemName, typ) } return zero, fmt.Errorf("%s is neither a struct field, a method nor a map element of type %s", elemName, typ) } // parseWhereArgs parses the end arguments to the where function. Return a // match value and an operator, if one is defined. func parseWhereArgs(args ...interface{}) (mv reflect.Value, op string, err error) { switch len(args) { case 1: mv = reflect.ValueOf(args[0]) case 2: var ok bool if op, ok = args[0].(string); !ok { err = errors.New("operator argument must be string type") return } op = strings.TrimSpace(strings.ToLower(op)) mv = reflect.ValueOf(args[1]) default: err = errors.New("can't evaluate the array by no match argument or more than or equal to two arguments") } return } // checkWhereArray handles the where-matching logic when the seqv value is an // Array or Slice. func (ns *Namespace) checkWhereArray(seqv, kv, mv reflect.Value, path []string, op string) (interface{}, error) { rv := reflect.MakeSlice(seqv.Type(), 0, 0) for i := 0; i < seqv.Len(); i++ { var vvv reflect.Value rvv := seqv.Index(i) if kv.Kind() == reflect.String { if params, ok := rvv.Interface().(maps.Params); ok { vvv = reflect.ValueOf(params.Get(path...)) } else { vvv = rvv for _, elemName := range path { var err error vvv, err = evaluateSubElem(vvv, elemName) if err != nil { continue } } } } else { vv, _ := indirect(rvv) if vv.Kind() == reflect.Map && kv.Type().AssignableTo(vv.Type().Key()) { vvv = vv.MapIndex(kv) } } if ok, err := ns.checkCondition(vvv, mv, op); ok { rv = reflect.Append(rv, rvv) } else if err != nil { return nil, err } } return rv.Interface(), nil } // checkWhereMap handles the where-matching logic when the seqv value is a Map. func (ns *Namespace) checkWhereMap(seqv, kv, mv reflect.Value, path []string, op string) (interface{}, error) { rv := reflect.MakeMap(seqv.Type()) keys := seqv.MapKeys() for _, k := range keys { elemv := seqv.MapIndex(k) switch elemv.Kind() { case reflect.Array, reflect.Slice: r, err := ns.checkWhereArray(elemv, kv, mv, path, op) if err != nil { return nil, err } switch rr := reflect.ValueOf(r); rr.Kind() { case reflect.Slice: if rr.Len() > 0 { rv.SetMapIndex(k, elemv) } } case reflect.Interface: elemvv, isNil := indirect(elemv) if isNil { continue } switch elemvv.Kind() { case reflect.Array, reflect.Slice: r, err := ns.checkWhereArray(elemvv, kv, mv, path, op) if err != nil { return nil, err } switch rr := reflect.ValueOf(r); rr.Kind() { case reflect.Slice: if rr.Len() > 0 { rv.SetMapIndex(k, elemv) } } } } } return rv.Interface(), nil } // toFloat returns the float value if possible. func toFloat(v reflect.Value) (float64, error) { switch v.Kind() { case reflect.Float32, reflect.Float64: return v.Float(), nil case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: return v.Convert(reflect.TypeOf(float64(0))).Float(), nil case reflect.Interface: return toFloat(v.Elem()) } return -1, errors.New("unable to convert value to float") } // toInt returns the int value if possible, -1 if not. // TODO(bep) consolidate all these reflect funcs. func toInt(v reflect.Value) (int64, error) { switch v.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: return v.Int(), nil case reflect.Interface: return toInt(v.Elem()) } return -1, errors.New("unable to convert value to int") } func toUint(v reflect.Value) (uint64, error) { switch v.Kind() { case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: return v.Uint(), nil case reflect.Interface: return toUint(v.Elem()) } return 0, errors.New("unable to convert value to uint") } // toString returns the string value if possible, "" if not. func toString(v reflect.Value) (string, error) { switch v.Kind() { case reflect.String: return v.String(), nil case reflect.Interface: return toString(v.Elem()) } return "", errors.New("unable to convert value to string") } func toTimeUnix(v reflect.Value) int64 { if v.Kind() == reflect.Interface { return toTimeUnix(v.Elem()) } if v.Type() != timeType { panic("coding error: argument must be time.Time type reflect Value") } return v.MethodByName("Unix").Call([]reflect.Value{})[0].Int() }