// Package govalidator is package of validators and sanitizers for strings, structs and collections. package govalidator import ( "encoding/json" "fmt" "net" "net/url" "reflect" "regexp" "sort" "strconv" "strings" "time" "unicode" "unicode/utf8" ) var ( fieldsRequiredByDefault bool notNumberRegexp = regexp.MustCompile("[^0-9]+") whiteSpacesAndMinus = regexp.MustCompile("[\\s-]+") paramsRegexp = regexp.MustCompile("\\(.*\\)$") ) const maxURLRuneCount = 2083 const minURLRuneCount = 3 // SetFieldsRequiredByDefault causes validation to fail when struct fields // do not include validations or are not explicitly marked as exempt (using `valid:"-"` or `valid:"email,optional"`). // This struct definition will fail govalidator.ValidateStruct() (and the field values do not matter): // type exampleStruct struct { // Name string `` // Email string `valid:"email"` // This, however, will only fail when Email is empty or an invalid email address: // type exampleStruct2 struct { // Name string `valid:"-"` // Email string `valid:"email"` // Lastly, this will only fail when Email is an invalid email address but not when it's empty: // type exampleStruct2 struct { // Name string `valid:"-"` // Email string `valid:"email,optional"` func SetFieldsRequiredByDefault(value bool) { fieldsRequiredByDefault = value } // IsEmail check if the string is an email. func IsEmail(str string) bool { // TODO uppercase letters are not supported return rxEmail.MatchString(str) } // IsURL check if the string is an URL. func IsURL(str string) bool { if str == "" || utf8.RuneCountInString(str) >= maxURLRuneCount || len(str) <= minURLRuneCount || strings.HasPrefix(str, ".") { return false } u, err := url.Parse(str) if err != nil { return false } if strings.HasPrefix(u.Host, ".") { return false } if u.Host == "" && (u.Path != "" && !strings.Contains(u.Path, ".")) { return false } return rxURL.MatchString(str) } // IsRequestURL check if the string rawurl, assuming // it was received in an HTTP request, is a valid // URL confirm to RFC 3986 func IsRequestURL(rawurl string) bool { url, err := url.ParseRequestURI(rawurl) if err != nil { return false //Couldn't even parse the rawurl } if len(url.Scheme) == 0 { return false //No Scheme found } return true } // IsRequestURI check if the string rawurl, assuming // it was received in an HTTP request, is an // absolute URI or an absolute path. func IsRequestURI(rawurl string) bool { _, err := url.ParseRequestURI(rawurl) return err == nil } // IsAlpha check if the string contains only letters (a-zA-Z). Empty string is valid. func IsAlpha(str string) bool { if IsNull(str) { return true } return rxAlpha.MatchString(str) } //IsUTFLetter check if the string contains only unicode letter characters. //Similar to IsAlpha but for all languages. Empty string is valid. func IsUTFLetter(str string) bool { if IsNull(str) { return true } for _, c := range str { if !unicode.IsLetter(c) { return false } } return true } // IsAlphanumeric check if the string contains only letters and numbers. Empty string is valid. func IsAlphanumeric(str string) bool { if IsNull(str) { return true } return rxAlphanumeric.MatchString(str) } // IsUTFLetterNumeric check if the string contains only unicode letters and numbers. Empty string is valid. func IsUTFLetterNumeric(str string) bool { if IsNull(str) { return true } for _, c := range str { if !unicode.IsLetter(c) && !unicode.IsNumber(c) { //letters && numbers are ok return false } } return true } // IsNumeric check if the string contains only numbers. Empty string is valid. func IsNumeric(str string) bool { if IsNull(str) { return true } return rxNumeric.MatchString(str) } // IsUTFNumeric check if the string contains only unicode numbers of any kind. // Numbers can be 0-9 but also Fractions ¾,Roman Ⅸ and Hangzhou 〩. Empty string is valid. func IsUTFNumeric(str string) bool { if IsNull(str) { return true } if strings.IndexAny(str, "+-") > 0 { return false } if len(str) > 1 { str = strings.TrimPrefix(str, "-") str = strings.TrimPrefix(str, "+") } for _, c := range str { if unicode.IsNumber(c) == false { //numbers && minus sign are ok return false } } return true } // IsUTFDigit check if the string contains only unicode radix-10 decimal digits. Empty string is valid. func IsUTFDigit(str string) bool { if IsNull(str) { return true } if strings.IndexAny(str, "+-") > 0 { return false } if len(str) > 1 { str = strings.TrimPrefix(str, "-") str = strings.TrimPrefix(str, "+") } for _, c := range str { if !unicode.IsDigit(c) { //digits && minus sign are ok return false } } return true } // IsHexadecimal check if the string is a hexadecimal number. func IsHexadecimal(str string) bool { return rxHexadecimal.MatchString(str) } // IsHexcolor check if the string is a hexadecimal color. func IsHexcolor(str string) bool { return rxHexcolor.MatchString(str) } // IsRGBcolor check if the string is a valid RGB color in form rgb(RRR, GGG, BBB). func IsRGBcolor(str string) bool { return rxRGBcolor.MatchString(str) } // IsLowerCase check if the string is lowercase. Empty string is valid. func IsLowerCase(str string) bool { if IsNull(str) { return true } return str == strings.ToLower(str) } // IsUpperCase check if the string is uppercase. Empty string is valid. func IsUpperCase(str string) bool { if IsNull(str) { return true } return str == strings.ToUpper(str) } // IsInt check if the string is an integer. Empty string is valid. func IsInt(str string) bool { if IsNull(str) { return true } return rxInt.MatchString(str) } // IsFloat check if the string is a float. func IsFloat(str string) bool { return str != "" && rxFloat.MatchString(str) } // IsDivisibleBy check if the string is a number that's divisible by another. // If second argument is not valid integer or zero, it's return false. // Otherwise, if first argument is not valid integer or zero, it's return true (Invalid string converts to zero). func IsDivisibleBy(str, num string) bool { f, _ := ToFloat(str) p := int64(f) q, _ := ToInt(num) if q == 0 { return false } return (p == 0) || (p%q == 0) } // IsNull check if the string is null. func IsNull(str string) bool { return len(str) == 0 } // IsByteLength check if the string's length (in bytes) falls in a range. func IsByteLength(str string, min, max int) bool { return len(str) >= min && len(str) <= max } // IsUUIDv3 check if the string is a UUID version 3. func IsUUIDv3(str string) bool { return rxUUID3.MatchString(str) } // IsUUIDv4 check if the string is a UUID version 4. func IsUUIDv4(str string) bool { return rxUUID4.MatchString(str) } // IsUUIDv5 check if the string is a UUID version 5. func IsUUIDv5(str string) bool { return rxUUID5.MatchString(str) } // IsUUID check if the string is a UUID (version 3, 4 or 5). func IsUUID(str string) bool { return rxUUID.MatchString(str) } // IsCreditCard check if the string is a credit card. func IsCreditCard(str string) bool { sanitized := notNumberRegexp.ReplaceAllString(str, "") if !rxCreditCard.MatchString(sanitized) { return false } var sum int64 var digit string var tmpNum int64 var shouldDouble bool for i := len(sanitized) - 1; i >= 0; i-- { digit = sanitized[i:(i + 1)] tmpNum, _ = ToInt(digit) if shouldDouble { tmpNum *= 2 if tmpNum >= 10 { sum += ((tmpNum % 10) + 1) } else { sum += tmpNum } } else { sum += tmpNum } shouldDouble = !shouldDouble } if sum%10 == 0 { return true } return false } // IsISBN10 check if the string is an ISBN version 10. func IsISBN10(str string) bool { return IsISBN(str, 10) } // IsISBN13 check if the string is an ISBN version 13. func IsISBN13(str string) bool { return IsISBN(str, 13) } // IsISBN check if the string is an ISBN (version 10 or 13). // If version value is not equal to 10 or 13, it will be check both variants. func IsISBN(str string, version int) bool { sanitized := whiteSpacesAndMinus.ReplaceAllString(str, "") var checksum int32 var i int32 if version == 10 { if !rxISBN10.MatchString(sanitized) { return false } for i = 0; i < 9; i++ { checksum += (i + 1) * int32(sanitized[i]-'0') } if sanitized[9] == 'X' { checksum += 10 * 10 } else { checksum += 10 * int32(sanitized[9]-'0') } if checksum%11 == 0 { return true } return false } else if version == 13 { if !rxISBN13.MatchString(sanitized) { return false } factor := []int32{1, 3} for i = 0; i < 12; i++ { checksum += factor[i%2] * int32(sanitized[i]-'0') } if (int32(sanitized[12]-'0'))-((10-(checksum%10))%10) == 0 { return true } return false } return IsISBN(str, 10) || IsISBN(str, 13) } // IsJSON check if the string is valid JSON (note: uses json.Unmarshal). func IsJSON(str string) bool { var js json.RawMessage return json.Unmarshal([]byte(str), &js) == nil } // IsMultibyte check if the string contains one or more multibyte chars. Empty string is valid. func IsMultibyte(str string) bool { if IsNull(str) { return true } return rxMultibyte.MatchString(str) } // IsASCII check if the string contains ASCII chars only. Empty string is valid. func IsASCII(str string) bool { if IsNull(str) { return true } return rxASCII.MatchString(str) } // IsPrintableASCII check if the string contains printable ASCII chars only. Empty string is valid. func IsPrintableASCII(str string) bool { if IsNull(str) { return true } return rxPrintableASCII.MatchString(str) } // IsFullWidth check if the string contains any full-width chars. Empty string is valid. func IsFullWidth(str string) bool { if IsNull(str) { return true } return rxFullWidth.MatchString(str) } // IsHalfWidth check if the string contains any half-width chars. Empty string is valid. func IsHalfWidth(str string) bool { if IsNull(str) { return true } return rxHalfWidth.MatchString(str) } // IsVariableWidth check if the string contains a mixture of full and half-width chars. Empty string is valid. func IsVariableWidth(str string) bool { if IsNull(str) { return true } return rxHalfWidth.MatchString(str) && rxFullWidth.MatchString(str) } // IsBase64 check if a string is base64 encoded. func IsBase64(str string) bool { return rxBase64.MatchString(str) } // IsFilePath check is a string is Win or Unix file path and returns it's type. func IsFilePath(str string) (bool, int) { if rxWinPath.MatchString(str) { //check windows path limit see: // http://msdn.microsoft.com/en-us/library/aa365247(VS.85).aspx#maxpath if len(str[3:]) > 32767 { return false, Win } return true, Win } else if rxUnixPath.MatchString(str) { return true, Unix } return false, Unknown } // IsDataURI checks if a string is base64 encoded data URI such as an image func IsDataURI(str string) bool { dataURI := strings.Split(str, ",") if !rxDataURI.MatchString(dataURI[0]) { return false } return IsBase64(dataURI[1]) } // IsISO3166Alpha2 checks if a string is valid two-letter country code func IsISO3166Alpha2(str string) bool { for _, entry := range ISO3166List { if str == entry.Alpha2Code { return true } } return false } // IsISO3166Alpha3 checks if a string is valid three-letter country code func IsISO3166Alpha3(str string) bool { for _, entry := range ISO3166List { if str == entry.Alpha3Code { return true } } return false } // IsISO693Alpha2 checks if a string is valid two-letter language code func IsISO693Alpha2(str string) bool { for _, entry := range ISO693List { if str == entry.Alpha2Code { return true } } return false } // IsISO693Alpha3b checks if a string is valid three-letter language code func IsISO693Alpha3b(str string) bool { for _, entry := range ISO693List { if str == entry.Alpha3bCode { return true } } return false } // IsDNSName will validate the given string as a DNS name func IsDNSName(str string) bool { if str == "" || len(strings.Replace(str, ".", "", -1)) > 255 { // constraints already violated return false } return !IsIP(str) && rxDNSName.MatchString(str) } // IsDialString validates the given string for usage with the various Dial() functions func IsDialString(str string) bool { if h, p, err := net.SplitHostPort(str); err == nil && h != "" && p != "" && (IsDNSName(h) || IsIP(h)) && IsPort(p) { return true } return false } // IsIP checks if a string is either IP version 4 or 6. func IsIP(str string) bool { return net.ParseIP(str) != nil } // IsPort checks if a string represents a valid port func IsPort(str string) bool { if i, err := strconv.Atoi(str); err == nil && i > 0 && i < 65536 { return true } return false } // IsIPv4 check if the string is an IP version 4. func IsIPv4(str string) bool { ip := net.ParseIP(str) return ip != nil && strings.Contains(str, ".") } // IsIPv6 check if the string is an IP version 6. func IsIPv6(str string) bool { ip := net.ParseIP(str) return ip != nil && strings.Contains(str, ":") } // IsCIDR check if the string is an valid CIDR notiation (IPV4 & IPV6) func IsCIDR(str string) bool { _, _, err := net.ParseCIDR(str) return err == nil } // IsMAC check if a string is valid MAC address. // Possible MAC formats: // 01:23:45:67:89:ab // 01:23:45:67:89:ab:cd:ef // 01-23-45-67-89-ab // 01-23-45-67-89-ab-cd-ef // 0123.4567.89ab // 0123.4567.89ab.cdef func IsMAC(str string) bool { _, err := net.ParseMAC(str) return err == nil } // IsHost checks if the string is a valid IP (both v4 and v6) or a valid DNS name func IsHost(str string) bool { return IsIP(str) || IsDNSName(str) } // IsMongoID check if the string is a valid hex-encoded representation of a MongoDB ObjectId. func IsMongoID(str string) bool { return rxHexadecimal.MatchString(str) && (len(str) == 24) } // IsLatitude check if a string is valid latitude. func IsLatitude(str string) bool { return rxLatitude.MatchString(str) } // IsLongitude check if a string is valid longitude. func IsLongitude(str string) bool { return rxLongitude.MatchString(str) } func toJSONName(tag string) string { if tag == "" { return "" } // JSON name always comes first. If there's no options then split[0] is // JSON name, if JSON name is not set, then split[0] is an empty string. split := strings.SplitN(tag, ",", 2) return split[0] } // ValidateStruct use tags for fields. // result will be equal to `false` if there are any errors. func ValidateStruct(s interface{}) (bool, error) { if s == nil { return true, nil } result := true var err error val := reflect.ValueOf(s) if val.Kind() == reflect.Interface || val.Kind() == reflect.Ptr { val = val.Elem() } // we only accept structs if val.Kind() != reflect.Struct { return false, fmt.Errorf("function only accepts structs; got %s", val.Kind()) } var errs Errors for i := 0; i < val.NumField(); i++ { valueField := val.Field(i) typeField := val.Type().Field(i) if typeField.PkgPath != "" { continue // Private field } structResult := true if valueField.Kind() == reflect.Struct && typeField.Tag.Get(tagName) != "-" { var err error structResult, err = ValidateStruct(valueField.Interface()) if err != nil { errs = append(errs, err) } } resultField, err2 := typeCheck(valueField, typeField, val, nil) if err2 != nil { // Replace structure name with JSON name if there is a tag on the variable jsonTag := toJSONName(typeField.Tag.Get("json")) if jsonTag != "" { switch jsonError := err2.(type) { case Error: jsonError.Name = jsonTag err2 = jsonError case Errors: err2 = jsonError } } errs = append(errs, err2) } result = result && resultField && structResult } if len(errs) > 0 { err = errs } return result, err } // parseTagIntoMap parses a struct tag `valid:required~Some error message,length(2|3)` into map[string]string{"required": "Some error message", "length(2|3)": ""} func parseTagIntoMap(tag string) tagOptionsMap { optionsMap := make(tagOptionsMap) options := strings.Split(tag, ",") for _, option := range options { option = strings.TrimSpace(option) validationOptions := strings.Split(option, "~") if !isValidTag(validationOptions[0]) { continue } if len(validationOptions) == 2 { optionsMap[validationOptions[0]] = validationOptions[1] } else { optionsMap[validationOptions[0]] = "" } } return optionsMap } func isValidTag(s string) bool { if s == "" { return false } for _, c := range s { switch { case strings.ContainsRune("\\'\"!#$%&()*+-./:<=>?@[]^_{|}~ ", c): // Backslash and quote chars are reserved, but // otherwise any punctuation chars are allowed // in a tag name. default: if !unicode.IsLetter(c) && !unicode.IsDigit(c) { return false } } } return true } // IsSSN will validate the given string as a U.S. Social Security Number func IsSSN(str string) bool { if str == "" || len(str) != 11 { return false } return rxSSN.MatchString(str) } // IsSemver check if string is valid semantic version func IsSemver(str string) bool { return rxSemver.MatchString(str) } // IsTime check if string is valid according to given format func IsTime(str string, format string) bool { _, err := time.Parse(format, str) return err == nil } // IsRFC3339 check if string is valid timestamp value according to RFC3339 func IsRFC3339(str string) bool { return IsTime(str, time.RFC3339) } // IsISO4217 check if string is valid ISO currency code func IsISO4217(str string) bool { for _, currency := range ISO4217List { if str == currency { return true } } return false } // ByteLength check string's length func ByteLength(str string, params ...string) bool { if len(params) == 2 { min, _ := ToInt(params[0]) max, _ := ToInt(params[1]) return len(str) >= int(min) && len(str) <= int(max) } return false } // RuneLength check string's length // Alias for StringLength func RuneLength(str string, params ...string) bool { return StringLength(str, params...) } // StringMatches checks if a string matches a given pattern. func StringMatches(s string, params ...string) bool { if len(params) == 1 { pattern := params[0] return Matches(s, pattern) } return false } // StringLength check string's length (including multi byte strings) func StringLength(str string, params ...string) bool { if len(params) == 2 { strLength := utf8.RuneCountInString(str) min, _ := ToInt(params[0]) max, _ := ToInt(params[1]) return strLength >= int(min) && strLength <= int(max) } return false } // Range check string's length func Range(str string, params ...string) bool { if len(params) == 2 { value, _ := ToFloat(str) min, _ := ToFloat(params[0]) max, _ := ToFloat(params[1]) return InRange(value, min, max) } return false } func isInRaw(str string, params ...string) bool { if len(params) == 1 { rawParams := params[0] parsedParams := strings.Split(rawParams, "|") return IsIn(str, parsedParams...) } return false } // IsIn check if string str is a member of the set of strings params func IsIn(str string, params ...string) bool { for _, param := range params { if str == param { return true } } return false } func checkRequired(v reflect.Value, t reflect.StructField, options tagOptionsMap) (bool, error) { if requiredOption, isRequired := options["required"]; isRequired { if len(requiredOption) > 0 { return false, Error{t.Name, fmt.Errorf(requiredOption), true, "required"} } return false, Error{t.Name, fmt.Errorf("non zero value required"), false, "required"} } else if _, isOptional := options["optional"]; fieldsRequiredByDefault && !isOptional { return false, Error{t.Name, fmt.Errorf("All fields are required to at least have one validation defined"), false, "required"} } // not required and empty is valid return true, nil } func typeCheck(v reflect.Value, t reflect.StructField, o reflect.Value, options tagOptionsMap) (isValid bool, resultErr error) { if !v.IsValid() { return false, nil } tag := t.Tag.Get(tagName) // Check if the field should be ignored switch tag { case "": if !fieldsRequiredByDefault { return true, nil } return false, Error{t.Name, fmt.Errorf("All fields are required to at least have one validation defined"), false, "required"} case "-": return true, nil } isRootType := false if options == nil { isRootType = true options = parseTagIntoMap(tag) } if isEmptyValue(v) { // an empty value is not validated, check only required return checkRequired(v, t, options) } var customTypeErrors Errors for validatorName, customErrorMessage := range options { if validatefunc, ok := CustomTypeTagMap.Get(validatorName); ok { delete(options, validatorName) if result := validatefunc(v.Interface(), o.Interface()); !result { if len(customErrorMessage) > 0 { customTypeErrors = append(customTypeErrors, Error{Name: t.Name, Err: fmt.Errorf(customErrorMessage), CustomErrorMessageExists: true, Validator: stripParams(validatorName)}) continue } customTypeErrors = append(customTypeErrors, Error{Name: t.Name, Err: fmt.Errorf("%s does not validate as %s", fmt.Sprint(v), validatorName), CustomErrorMessageExists: false, Validator: stripParams(validatorName)}) } } } if len(customTypeErrors.Errors()) > 0 { return false, customTypeErrors } if isRootType { // Ensure that we've checked the value by all specified validators before report that the value is valid defer func() { delete(options, "optional") delete(options, "required") if isValid && resultErr == nil && len(options) != 0 { for validator := range options { isValid = false resultErr = Error{t.Name, fmt.Errorf( "The following validator is invalid or can't be applied to the field: %q", validator), false, stripParams(validator)} return } } }() } switch v.Kind() { case reflect.Bool, reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64, reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr, reflect.Float32, reflect.Float64, reflect.String: // for each tag option check the map of validator functions for validatorSpec, customErrorMessage := range options { var negate bool validator := validatorSpec customMsgExists := len(customErrorMessage) > 0 // Check whether the tag looks like '!something' or 'something' if validator[0] == '!' { validator = validator[1:] negate = true } // Check for param validators for key, value := range ParamTagRegexMap { ps := value.FindStringSubmatch(validator) if len(ps) == 0 { continue } validatefunc, ok := ParamTagMap[key] if !ok { continue } delete(options, validatorSpec) switch v.Kind() { case reflect.String: field := fmt.Sprint(v) // make value into string, then validate with regex if result := validatefunc(field, ps[1:]...); (!result && !negate) || (result && negate) { if customMsgExists { return false, Error{t.Name, fmt.Errorf(customErrorMessage), customMsgExists, stripParams(validatorSpec)} } if negate { return false, Error{t.Name, fmt.Errorf("%s does validate as %s", field, validator), customMsgExists, stripParams(validatorSpec)} } return false, Error{t.Name, fmt.Errorf("%s does not validate as %s", field, validator), customMsgExists, stripParams(validatorSpec)} } default: // type not yet supported, fail return false, Error{t.Name, fmt.Errorf("Validator %s doesn't support kind %s", validator, v.Kind()), false, stripParams(validatorSpec)} } } if validatefunc, ok := TagMap[validator]; ok { delete(options, validatorSpec) switch v.Kind() { case reflect.String: field := fmt.Sprint(v) // make value into string, then validate with regex if result := validatefunc(field); !result && !negate || result && negate { if customMsgExists { return false, Error{t.Name, fmt.Errorf(customErrorMessage), customMsgExists, stripParams(validatorSpec)} } if negate { return false, Error{t.Name, fmt.Errorf("%s does validate as %s", field, validator), customMsgExists, stripParams(validatorSpec)} } return false, Error{t.Name, fmt.Errorf("%s does not validate as %s", field, validator), customMsgExists, stripParams(validatorSpec)} } default: //Not Yet Supported Types (Fail here!) err := fmt.Errorf("Validator %s doesn't support kind %s for value %v", validator, v.Kind(), v) return false, Error{t.Name, err, false, stripParams(validatorSpec)} } } } return true, nil case reflect.Map: if v.Type().Key().Kind() != reflect.String { return false, &UnsupportedTypeError{v.Type()} } var sv stringValues sv = v.MapKeys() sort.Sort(sv) result := true for _, k := range sv { var resultItem bool var err error if v.MapIndex(k).Kind() != reflect.Struct { resultItem, err = typeCheck(v.MapIndex(k), t, o, options) if err != nil { return false, err } } else { resultItem, err = ValidateStruct(v.MapIndex(k).Interface()) if err != nil { return false, err } } result = result && resultItem } return result, nil case reflect.Slice, reflect.Array: result := true for i := 0; i < v.Len(); i++ { var resultItem bool var err error if v.Index(i).Kind() != reflect.Struct { resultItem, err = typeCheck(v.Index(i), t, o, options) if err != nil { return false, err } } else { resultItem, err = ValidateStruct(v.Index(i).Interface()) if err != nil { return false, err } } result = result && resultItem } return result, nil case reflect.Interface: // If the value is an interface then encode its element if v.IsNil() { return true, nil } return ValidateStruct(v.Interface()) case reflect.Ptr: // If the value is a pointer then check its element if v.IsNil() { return true, nil } return typeCheck(v.Elem(), t, o, options) case reflect.Struct: return ValidateStruct(v.Interface()) default: return false, &UnsupportedTypeError{v.Type()} } } func stripParams(validatorString string) string { return paramsRegexp.ReplaceAllString(validatorString, "") } func isEmptyValue(v reflect.Value) bool { switch v.Kind() { case reflect.String, reflect.Array: return v.Len() == 0 case reflect.Map, reflect.Slice: return v.Len() == 0 || v.IsNil() case reflect.Bool: return !v.Bool() case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: return v.Int() == 0 case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr: return v.Uint() == 0 case reflect.Float32, reflect.Float64: return v.Float() == 0 case reflect.Interface, reflect.Ptr: return v.IsNil() } return reflect.DeepEqual(v.Interface(), reflect.Zero(v.Type()).Interface()) } // ErrorByField returns error for specified field of the struct // validated by ValidateStruct or empty string if there are no errors // or this field doesn't exists or doesn't have any errors. func ErrorByField(e error, field string) string { if e == nil { return "" } return ErrorsByField(e)[field] } // ErrorsByField returns map of errors of the struct validated // by ValidateStruct or empty map if there are no errors. func ErrorsByField(e error) map[string]string { m := make(map[string]string) if e == nil { return m } // prototype for ValidateStruct switch e.(type) { case Error: m[e.(Error).Name] = e.(Error).Err.Error() case Errors: for _, item := range e.(Errors).Errors() { n := ErrorsByField(item) for k, v := range n { m[k] = v } } } return m } // Error returns string equivalent for reflect.Type func (e *UnsupportedTypeError) Error() string { return "validator: unsupported type: " + e.Type.String() } func (sv stringValues) Len() int { return len(sv) } func (sv stringValues) Swap(i, j int) { sv[i], sv[j] = sv[j], sv[i] } func (sv stringValues) Less(i, j int) bool { return sv.get(i) < sv.get(j) } func (sv stringValues) get(i int) string { return sv[i].String() }