package reflect import ( "errors" "fmt" "net/url" "reflect" "regexp" "strconv" "strings" "unicode" ) var ( // ErrInvalidStruct specifies invalid struct error ErrInvalidStruct = errors.New("invalid struct specified") // ErrInvalidParam specifies invalid url query params ErrInvalidParam = errors.New("invalid url query param provided") ) var ( bracketSplitter = regexp.MustCompile(`\[|\]`) ) func fieldName(name string) string { newstr := make([]rune, 0) upper := false for idx, chr := range name { if idx == 0 { upper = true } else if chr == '_' { upper = true continue } if upper { newstr = append(newstr, unicode.ToUpper(chr)) } else { newstr = append(newstr, chr) } upper = false } return string(newstr) } // IsEmpty returns true if value empty func IsEmpty(v reflect.Value) bool { switch getKind(v) { case reflect.Array, reflect.Map, reflect.Slice, reflect.String: return v.Len() == 0 case reflect.Bool: return !v.Bool() case reflect.Int: return v.Int() == 0 case reflect.Uint: return v.Uint() == 0 case reflect.Float32: return v.Float() == 0 case reflect.Interface, reflect.Ptr: if v.IsNil() { return true } return IsEmpty(v.Elem()) case reflect.Func: return v.IsNil() case reflect.Invalid: return true } return false } // Zero creates new zero interface func Zero(src interface{}) (interface{}, error) { sv := reflect.ValueOf(src) if sv.Kind() == reflect.Ptr { sv = sv.Elem() } if sv.Kind() == reflect.Invalid { return nil, ErrInvalidStruct } dst := reflect.New(sv.Type()) return dst.Interface(), nil } // StructFields returns slice of struct fields func StructFields(src interface{}) ([]reflect.StructField, error) { var fields []reflect.StructField sv := reflect.ValueOf(src) if sv.Kind() == reflect.Ptr { sv = sv.Elem() } if sv.Kind() != reflect.Struct { return nil, ErrInvalidStruct } typ := sv.Type() for idx := 0; idx < typ.NumField(); idx++ { fld := typ.Field(idx) val := sv.Field(idx) if !val.CanSet() || len(fld.PkgPath) != 0 { continue } if val.Kind() == reflect.Struct { infields, err := StructFields(val.Interface()) if err != nil { return nil, err } fields = append(fields, infields...) } else { fields = append(fields, fld) } } return fields, nil } // CopyDefaults for a from b // a and b should be pointers to the same kind of struct func CopyDefaults(a, b interface{}) { pt := reflect.TypeOf(a) t := pt.Elem() va := reflect.ValueOf(a).Elem() vb := reflect.ValueOf(b).Elem() for i := 0; i < t.NumField(); i++ { aField := va.Field(i) if aField.CanSet() { bField := vb.Field(i) aField.Set(bField) } } } // CopyFrom sets the public members of a from b // a and b should be pointers to structs // a can be a different type from b // Only the Fields which have the same name and assignable type on a // and b will be set. func CopyFrom(a, b interface{}) { ta := reflect.TypeOf(a).Elem() tb := reflect.TypeOf(b).Elem() va := reflect.ValueOf(a).Elem() vb := reflect.ValueOf(b).Elem() for i := 0; i < tb.NumField(); i++ { bField := vb.Field(i) tbField := tb.Field(i) name := tbField.Name aField := va.FieldByName(name) taField, found := ta.FieldByName(name) if found && aField.IsValid() && bField.IsValid() && aField.CanSet() && tbField.Type.AssignableTo(taField.Type) { aField.Set(bField) } } } // URLMap returns map of url query params func URLMap(query string) (map[string]interface{}, error) { var ( mp interface{} = make(map[string]interface{}) ) params := strings.Split(query, "&") for _, part := range params { tm, err := queryToMap(part) if err != nil { return nil, err } mp = merge(mp, tm) } return mp.(map[string]interface{}), nil } // FlattenMap expand key.subkey to nested map func FlattenMap(a map[string]interface{}) map[string]interface{} { // preprocess map nb := make(map[string]interface{}, len(a)) for k, v := range a { ps := strings.Split(k, ".") if len(ps) == 1 { nb[k] = v continue } em := make(map[string]interface{}) em[ps[len(ps)-1]] = v for i := len(ps) - 2; i > 0; i-- { nm := make(map[string]interface{}) nm[ps[i]] = em em = nm } if vm, ok := nb[ps[0]]; ok { // nested map nm := vm.(map[string]interface{}) for vk, vv := range em { nm[vk] = vv } nb[ps[0]] = nm } else { nb[ps[0]] = em } } return nb } // MergeMap merges maps func MergeMap(a interface{}, b map[string]interface{}) error { var err error ta := reflect.TypeOf(a) if ta.Kind() == reflect.Ptr { ta = ta.Elem() } va := reflect.ValueOf(a) if va.Kind() == reflect.Ptr { va = va.Elem() } for mk, mv := range b { vmv := reflect.ValueOf(mv) name := fieldName(mk) fva := va.FieldByName(name) fta, found := ta.FieldByName(name) if !found || !fva.IsValid() || !fva.CanSet() || fta.PkgPath != "" { continue } // fast path via direct assign if vmv.Type().AssignableTo(fta.Type) && !IsEmpty(vmv) { fva.Set(vmv) continue } switch getKind(fva) { case reflect.Bool: err = mergeBool(fva, vmv) case reflect.String: err = mergeString(fva, vmv) case reflect.Int: err = mergeInt(fva, vmv) case reflect.Uint: err = mergeUint(fva, vmv) case reflect.Float32: err = mergeFloat(fva, vmv) case reflect.Array: //fmt.Printf("Array %#+v %#+v\n", fva, vmv) case reflect.Slice: err = mergeSlice(fva, vmv) case reflect.Ptr: if fva.IsNil() { fva.Set(reflect.New(fva.Type().Elem())) if fva.Elem().Type().Kind() == reflect.Struct { for i := 0; i < fva.Elem().NumField(); i++ { field := fva.Elem().Field(i) if field.Type().Kind() == reflect.Ptr && field.IsNil() && fva.Elem().Type().Field(i).Anonymous { field.Set(reflect.New(field.Type().Elem())) } } } } if nmp, ok := vmv.Interface().(map[string]interface{}); ok { err = MergeMap(fva.Interface(), nmp) } else { err = fmt.Errorf("cant fill") } case reflect.Struct: if nmp, ok := vmv.Interface().(map[string]interface{}); ok { err = MergeMap(fva.Interface(), nmp) } else { err = fmt.Errorf("cant fill") } case reflect.Map: //fmt.Printf("Map %#+v %#+v\n", fva, vmv) } if err != nil { return err } } return nil } func mergeSlice(va, vb reflect.Value) error { switch getKind(vb) { /* case reflect.Int: if vb.Int() == 1 { va.SetBool(true) } case reflect.Uint: if vb.Uint() == 1 { va.SetBool(true) } case reflect.Float64: if vb.Float() == 1 { va.SetBool(true) } */ case reflect.String: var err error fn := func(c rune) bool { return c == ',' || c == ';' || c == ' ' } slice := strings.FieldsFunc(vb.String(), fn) va.Set(reflect.MakeSlice(va.Type(), len(slice), len(slice))) for idx, sl := range slice { vl := reflect.ValueOf(sl) switch va.Type().Elem().Kind() { case reflect.Bool: err = mergeBool(va.Index(idx), vl) case reflect.String: err = mergeString(va.Index(idx), vl) case reflect.Ptr: if va.Index(idx).IsNil() { va.Index(idx).Set(reflect.New(va.Index(idx).Type().Elem())) } switch va.Type().Elem().String() { case "*wrapperspb.BoolValue": if eva := reflect.Indirect(va.Index(idx)).FieldByName("Value"); eva.IsValid() { err = mergeBool(eva, vl) } case "*wrapperspb.BytesValue": if eva := va.Index(idx).FieldByName("Value"); eva.IsValid() { err = mergeUint(eva, vl) } case "*wrapperspb.DoubleValue", "*wrapperspb.FloatValue": if eva := reflect.Indirect(va.Index(idx)).FieldByName("Value"); eva.IsValid() { err = mergeFloat(eva, vl) } case "*wrapperspb.Int32Value", "*wrapperspb.Int64Value": if eva := reflect.Indirect(va.Index(idx)).FieldByName("Value"); eva.IsValid() { err = mergeInt(eva, vl) } case "*wrapperspb.StringValue": if eva := reflect.Indirect(va.Index(idx)).FieldByName("Value"); eva.IsValid() { err = mergeString(eva, vl) } case "*wrapperspb.UInt32Value", "*wrapperspb.UInt64Value": if eva := reflect.Indirect(va.Index(idx)).FieldByName("Value"); eva.IsValid() { err = mergeUint(eva, vl) } } } if err != nil { return err } } default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func mergeBool(va, vb reflect.Value) error { switch getKind(vb) { case reflect.Int: if vb.Int() == 1 { va.SetBool(true) } case reflect.Uint: if vb.Uint() == 1 { va.SetBool(true) } case reflect.Float32: if vb.Float() == 1 { va.SetBool(true) } case reflect.String: b, err := strconv.ParseBool(vb.String()) if err != nil { return err } va.SetBool(b) default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func mergeString(va, vb reflect.Value) error { switch getKind(vb) { case reflect.Int: va.SetString(fmt.Sprintf("%d", vb.Int())) case reflect.Uint: va.SetString(fmt.Sprintf("%d", vb.Uint())) case reflect.Float32: va.SetString(fmt.Sprintf("%f", vb.Float())) case reflect.String: va.Set(vb) default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func mergeInt(va, vb reflect.Value) error { switch getKind(vb) { case reflect.Int: va.Set(vb) case reflect.Uint: va.SetInt(int64(vb.Uint())) case reflect.Float32: va.SetInt(int64(vb.Float())) case reflect.String: f, err := strconv.ParseInt(vb.String(), 10, va.Type().Bits()) if err != nil { return err } va.SetInt(f) default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func mergeUint(va, vb reflect.Value) error { switch getKind(vb) { case reflect.Int: va.SetUint(uint64(vb.Int())) case reflect.Uint: va.Set(vb) case reflect.Float32: va.SetUint(uint64(vb.Float())) case reflect.String: f, err := strconv.ParseUint(vb.String(), 10, va.Type().Bits()) if err != nil { return err } va.SetUint(f) default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func mergeFloat(va, vb reflect.Value) error { switch getKind(vb) { case reflect.Int: va.SetFloat(float64(vb.Int())) case reflect.Uint: va.SetFloat(float64(vb.Uint())) case reflect.Float32: va.Set(vb) case reflect.String: f, err := strconv.ParseFloat(vb.String(), va.Type().Bits()) if err != nil { return err } va.SetFloat(f) default: return fmt.Errorf("cant merge %v %s with %v %s", va, va.Kind(), vb, vb.Kind()) } return nil } func getKind(val reflect.Value) reflect.Kind { kind := val.Kind() switch { case kind >= reflect.Int && kind <= reflect.Int64: return reflect.Int case kind >= reflect.Uint && kind <= reflect.Uint64: return reflect.Uint case kind >= reflect.Float32 && kind <= reflect.Float64: return reflect.Float32 } return kind } func btSplitter(str string) []string { r := bracketSplitter.Split(str, -1) for idx, s := range r { if len(s) == 0 { if len(r) > idx+1 { copy(r[idx:], r[idx+1:]) r = r[:len(r)-1] } } } return r } // queryToMap turns something like a[b][c]=4 into // map[string]interface{}{ // "a": map[string]interface{}{ // "b": map[string]interface{}{ // "c": 4, // }, // }, // } func queryToMap(param string) (map[string]interface{}, error) { rawKey, rawValue, err := splitKeyAndValue(param) if err != nil { return nil, err } rawValue, err = url.QueryUnescape(rawValue) if err != nil { return nil, err } rawKey, err = url.QueryUnescape(rawKey) if err != nil { return nil, err } pieces := btSplitter(rawKey) key := pieces[0] // If len==1 then rawKey has no [] chars and we can just // decode this as key=value into {key: value} if len(pieces) == 1 { return map[string]interface{}{ key: rawValue, }, nil } // If len > 1 then we have something like a[b][c]=2 // so we need to turn this into {"a": {"b": {"c": 2}}} // To do this we break our key into two pieces: // a and b[c] // and then we set {"a": queryToMap("b[c]", value)} ret := make(map[string]interface{}) ret[key], err = queryToMap(buildNewKey(rawKey) + "=" + rawValue) if err != nil { return nil, err } // When URL params have a set of empty brackets (eg a[]=1) // it is assumed to be an array. This will get us the // correct value for the array item and return it as an // []interface{} so that it can be merged properly. if pieces[1] == "" { temp := ret[key].(map[string]interface{}) ret[key] = []interface{}{temp[""]} } return ret, nil } // buildNewKey will take something like: // origKey = "bar[one][two]" // pieces = [bar one two ] // and return "one[two]" func buildNewKey(origKey string) string { pieces := btSplitter(origKey) ret := origKey[len(pieces[0])+1:] ret = ret[:len(pieces[1])] + ret[len(pieces[1])+1:] return ret } // splitKeyAndValue splits a URL param at the last equal // sign and returns the two strings. If no equal sign is // found, the ErrInvalidParam error is returned. func splitKeyAndValue(param string) (string, string, error) { li := strings.LastIndex(param, "=") if li == -1 { return "", "", ErrInvalidParam } return param[:li], param[li+1:], nil } // merge merges a with b if they are either both slices // or map[string]interface{} types. Otherwise it returns b. func merge(a interface{}, b interface{}) interface{} { if av, aok := a.(map[string]interface{}); aok { if bv, bok := b.(map[string]interface{}); bok { return mergeMapIface(av, bv) } } if av, aok := a.([]interface{}); aok { if bv, bok := b.([]interface{}); bok { return mergeSliceIface(av, bv) } } va := reflect.ValueOf(a) vb := reflect.ValueOf(b) if (va.Type().Kind() == reflect.Slice) && (va.Type().Elem().Kind() == vb.Type().Kind() || vb.Type().ConvertibleTo(va.Type().Elem())) { va = reflect.Append(va, vb.Convert(va.Type().Elem())) return va.Interface() } return b } // mergeMap merges a with b, attempting to merge any nested // values in nested maps but eventually overwriting anything // in a that can't be merged with whatever is in b. func mergeMapIface(a map[string]interface{}, b map[string]interface{}) map[string]interface{} { for bK, bV := range b { if aV, ok := a[bK]; ok { if (reflect.ValueOf(aV).Type().Kind() == reflect.ValueOf(bV).Type().Kind()) || ((reflect.ValueOf(aV).Type().Kind() == reflect.Slice) && reflect.ValueOf(aV).Type().Elem().Kind() == reflect.ValueOf(bV).Type().Kind()) { nV := []interface{}{aV, bV} a[bK] = nV } else { a[bK] = merge(a[bK], bV) } } else { a[bK] = bV } } return a } // mergeSlice merges a with b and returns the result. func mergeSliceIface(a []interface{}, b []interface{}) []interface{} { a = append(a, b...) return a }