package validator
import (
"bytes"
"context"
"crypto/sha256"
"encoding/json"
"fmt"
"net"
"net/url"
"os"
"reflect"
"strconv"
"strings"
"sync"
"time"
"unicode/utf8"
urn "github.com/leodido/go-urn"
)
// Func accepts a FieldLevel interface for all validation needs. The return
// value should be true when validation succeeds.
type Func func ( fl FieldLevel ) bool
// FuncCtx accepts a context.Context and FieldLevel interface for all
// validation needs. The return value should be true when validation succeeds.
type FuncCtx func ( ctx context . Context , fl FieldLevel ) bool
// wrapFunc wraps noramal Func makes it compatible with FuncCtx
func wrapFunc ( fn Func ) FuncCtx {
if fn == nil {
return nil // be sure not to wrap a bad function.
}
return func ( ctx context . Context , fl FieldLevel ) bool {
return fn ( fl )
}
}
var (
restrictedTags = map [ string ] struct { } {
diveTag : { } ,
keysTag : { } ,
endKeysTag : { } ,
structOnlyTag : { } ,
omitempty : { } ,
skipValidationTag : { } ,
utf8HexComma : { } ,
utf8Pipe : { } ,
noStructLevelTag : { } ,
requiredTag : { } ,
isdefault : { } ,
}
// BakedInAliasValidators is a default mapping of a single validation tag that
// defines a common or complex set of validation(s) to simplify
// adding validation to structs.
bakedInAliases = map [ string ] string {
"iscolor" : "hexcolor|rgb|rgba|hsl|hsla" ,
}
// BakedInValidators is the default map of ValidationFunc
// you can add, remove or even replace items to suite your needs,
// or even disregard and use your own map if so desired.
bakedInValidators = map [ string ] Func {
"required" : hasValue ,
"required_with" : requiredWith ,
"required_with_all" : requiredWithAll ,
"required_without" : requiredWithout ,
"required_without_all" : requiredWithoutAll ,
"isdefault" : isDefault ,
"len" : hasLengthOf ,
"min" : hasMinOf ,
"max" : hasMaxOf ,
"eq" : isEq ,
"ne" : isNe ,
"lt" : isLt ,
"lte" : isLte ,
"gt" : isGt ,
"gte" : isGte ,
"eqfield" : isEqField ,
"eqcsfield" : isEqCrossStructField ,
"necsfield" : isNeCrossStructField ,
"gtcsfield" : isGtCrossStructField ,
"gtecsfield" : isGteCrossStructField ,
"ltcsfield" : isLtCrossStructField ,
"ltecsfield" : isLteCrossStructField ,
"nefield" : isNeField ,
"gtefield" : isGteField ,
"gtfield" : isGtField ,
"ltefield" : isLteField ,
"ltfield" : isLtField ,
"fieldcontains" : fieldContains ,
"fieldexcludes" : fieldExcludes ,
"alpha" : isAlpha ,
"alphanum" : isAlphanum ,
"alphaunicode" : isAlphaUnicode ,
"alphanumunicode" : isAlphanumUnicode ,
"numeric" : isNumeric ,
"number" : isNumber ,
"hexadecimal" : isHexadecimal ,
"hexcolor" : isHEXColor ,
"rgb" : isRGB ,
"rgba" : isRGBA ,
"hsl" : isHSL ,
"hsla" : isHSLA ,
"e164" : isE164 ,
"email" : isEmail ,
"url" : isURL ,
"uri" : isURI ,
"urn_rfc2141" : isUrnRFC2141 , // RFC 2141
"file" : isFile ,
"base64" : isBase64 ,
"base64url" : isBase64URL ,
"contains" : contains ,
"containsany" : containsAny ,
"containsrune" : containsRune ,
"excludes" : excludes ,
"excludesall" : excludesAll ,
"excludesrune" : excludesRune ,
"startswith" : startsWith ,
"endswith" : endsWith ,
"startsnotwith" : startsNotWith ,
"endsnotwith" : endsNotWith ,
"isbn" : isISBN ,
"isbn10" : isISBN10 ,
"isbn13" : isISBN13 ,
"eth_addr" : isEthereumAddress ,
"btc_addr" : isBitcoinAddress ,
"btc_addr_bech32" : isBitcoinBech32Address ,
"uuid" : isUUID ,
"uuid3" : isUUID3 ,
"uuid4" : isUUID4 ,
"uuid5" : isUUID5 ,
"uuid_rfc4122" : isUUIDRFC4122 ,
"uuid3_rfc4122" : isUUID3RFC4122 ,
"uuid4_rfc4122" : isUUID4RFC4122 ,
"uuid5_rfc4122" : isUUID5RFC4122 ,
"ascii" : isASCII ,
"printascii" : isPrintableASCII ,
"multibyte" : hasMultiByteCharacter ,
"datauri" : isDataURI ,
"latitude" : isLatitude ,
"longitude" : isLongitude ,
"ssn" : isSSN ,
"ipv4" : isIPv4 ,
"ipv6" : isIPv6 ,
"ip" : isIP ,
"cidrv4" : isCIDRv4 ,
"cidrv6" : isCIDRv6 ,
"cidr" : isCIDR ,
"tcp4_addr" : isTCP4AddrResolvable ,
"tcp6_addr" : isTCP6AddrResolvable ,
"tcp_addr" : isTCPAddrResolvable ,
"udp4_addr" : isUDP4AddrResolvable ,
"udp6_addr" : isUDP6AddrResolvable ,
"udp_addr" : isUDPAddrResolvable ,
"ip4_addr" : isIP4AddrResolvable ,
"ip6_addr" : isIP6AddrResolvable ,
"ip_addr" : isIPAddrResolvable ,
"unix_addr" : isUnixAddrResolvable ,
"mac" : isMAC ,
"hostname" : isHostnameRFC952 , // RFC 952
"hostname_rfc1123" : isHostnameRFC1123 , // RFC 1123
"fqdn" : isFQDN ,
"unique" : isUnique ,
"oneof" : isOneOf ,
"html" : isHTML ,
"html_encoded" : isHTMLEncoded ,
"url_encoded" : isURLEncoded ,
"dir" : isDir ,
"json" : isJSON ,
"hostname_port" : isHostnamePort ,
"lowercase" : isLowercase ,
"uppercase" : isUppercase ,
"datetime" : isDatetime ,
}
)
var oneofValsCache = map [ string ] [ ] string { }
var oneofValsCacheRWLock = sync . RWMutex { }
func parseOneOfParam2 ( s string ) [ ] string {
oneofValsCacheRWLock . RLock ( )
vals , ok := oneofValsCache [ s ]
oneofValsCacheRWLock . RUnlock ( )
if ! ok {
oneofValsCacheRWLock . Lock ( )
vals = splitParamsRegex . FindAllString ( s , - 1 )
for i := 0 ; i < len ( vals ) ; i ++ {
vals [ i ] = strings . Replace ( vals [ i ] , "'" , "" , - 1 )
}
oneofValsCache [ s ] = vals
oneofValsCacheRWLock . Unlock ( )
}
return vals
}
func isURLEncoded ( fl FieldLevel ) bool {
return uRLEncodedRegex . MatchString ( fl . Field ( ) . String ( ) )
}
func isHTMLEncoded ( fl FieldLevel ) bool {
return hTMLEncodedRegex . MatchString ( fl . Field ( ) . String ( ) )
}
func isHTML ( fl FieldLevel ) bool {
return hTMLRegex . MatchString ( fl . Field ( ) . String ( ) )
}
func isOneOf ( fl FieldLevel ) bool {
vals := parseOneOfParam2 ( fl . Param ( ) )
field := fl . Field ( )
var v string
switch field . Kind ( ) {
case reflect . String :
v = field . String ( )
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
v = strconv . FormatInt ( field . Int ( ) , 10 )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 :
v = strconv . FormatUint ( field . Uint ( ) , 10 )
default :
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
for i := 0 ; i < len ( vals ) ; i ++ {
if vals [ i ] == v {
return true
}
}
return false
}
// isUnique is the validation function for validating if each array|slice|map value is unique
func isUnique ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
v := reflect . ValueOf ( struct { } { } )
switch field . Kind ( ) {
case reflect . Slice , reflect . Array :
if param == "" {
m := reflect . MakeMap ( reflect . MapOf ( field . Type ( ) . Elem ( ) , v . Type ( ) ) )
for i := 0 ; i < field . Len ( ) ; i ++ {
m . SetMapIndex ( field . Index ( i ) , v )
}
return field . Len ( ) == m . Len ( )
}
sf , ok := field . Type ( ) . Elem ( ) . FieldByName ( param )
if ! ok {
panic ( fmt . Sprintf ( "Bad field name %s" , param ) )
}
m := reflect . MakeMap ( reflect . MapOf ( sf . Type , v . Type ( ) ) )
for i := 0 ; i < field . Len ( ) ; i ++ {
m . SetMapIndex ( field . Index ( i ) . FieldByName ( param ) , v )
}
return field . Len ( ) == m . Len ( )
case reflect . Map :
m := reflect . MakeMap ( reflect . MapOf ( field . Type ( ) . Elem ( ) , v . Type ( ) ) )
for _ , k := range field . MapKeys ( ) {
m . SetMapIndex ( field . MapIndex ( k ) , v )
}
return field . Len ( ) == m . Len ( )
default :
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
}
// IsMAC is the validation function for validating if the field's value is a valid MAC address.
func isMAC ( fl FieldLevel ) bool {
_ , err := net . ParseMAC ( fl . Field ( ) . String ( ) )
return err == nil
}
// IsCIDRv4 is the validation function for validating if the field's value is a valid v4 CIDR address.
func isCIDRv4 ( fl FieldLevel ) bool {
ip , _ , err := net . ParseCIDR ( fl . Field ( ) . String ( ) )
return err == nil && ip . To4 ( ) != nil
}
// IsCIDRv6 is the validation function for validating if the field's value is a valid v6 CIDR address.
func isCIDRv6 ( fl FieldLevel ) bool {
ip , _ , err := net . ParseCIDR ( fl . Field ( ) . String ( ) )
return err == nil && ip . To4 ( ) == nil
}
// IsCIDR is the validation function for validating if the field's value is a valid v4 or v6 CIDR address.
func isCIDR ( fl FieldLevel ) bool {
_ , _ , err := net . ParseCIDR ( fl . Field ( ) . String ( ) )
return err == nil
}
// IsIPv4 is the validation function for validating if a value is a valid v4 IP address.
func isIPv4 ( fl FieldLevel ) bool {
ip := net . ParseIP ( fl . Field ( ) . String ( ) )
return ip != nil && ip . To4 ( ) != nil
}
// IsIPv6 is the validation function for validating if the field's value is a valid v6 IP address.
func isIPv6 ( fl FieldLevel ) bool {
ip := net . ParseIP ( fl . Field ( ) . String ( ) )
return ip != nil && ip . To4 ( ) == nil
}
// IsIP is the validation function for validating if the field's value is a valid v4 or v6 IP address.
func isIP ( fl FieldLevel ) bool {
ip := net . ParseIP ( fl . Field ( ) . String ( ) )
return ip != nil
}
// IsSSN is the validation function for validating if the field's value is a valid SSN.
func isSSN ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Len ( ) != 11 {
return false
}
return sSNRegex . MatchString ( field . String ( ) )
}
// IsLongitude is the validation function for validating if the field's value is a valid longitude coordinate.
func isLongitude ( fl FieldLevel ) bool {
field := fl . Field ( )
var v string
switch field . Kind ( ) {
case reflect . String :
v = field . String ( )
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
v = strconv . FormatInt ( field . Int ( ) , 10 )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 :
v = strconv . FormatUint ( field . Uint ( ) , 10 )
case reflect . Float32 :
v = strconv . FormatFloat ( field . Float ( ) , 'f' , - 1 , 32 )
case reflect . Float64 :
v = strconv . FormatFloat ( field . Float ( ) , 'f' , - 1 , 64 )
default :
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
return longitudeRegex . MatchString ( v )
}
// IsLatitude is the validation function for validating if the field's value is a valid latitude coordinate.
func isLatitude ( fl FieldLevel ) bool {
field := fl . Field ( )
var v string
switch field . Kind ( ) {
case reflect . String :
v = field . String ( )
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
v = strconv . FormatInt ( field . Int ( ) , 10 )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 :
v = strconv . FormatUint ( field . Uint ( ) , 10 )
case reflect . Float32 :
v = strconv . FormatFloat ( field . Float ( ) , 'f' , - 1 , 32 )
case reflect . Float64 :
v = strconv . FormatFloat ( field . Float ( ) , 'f' , - 1 , 64 )
default :
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
return latitudeRegex . MatchString ( v )
}
// IsDataURI is the validation function for validating if the field's value is a valid data URI.
func isDataURI ( fl FieldLevel ) bool {
uri := strings . SplitN ( fl . Field ( ) . String ( ) , "," , 2 )
if len ( uri ) != 2 {
return false
}
if ! dataURIRegex . MatchString ( uri [ 0 ] ) {
return false
}
return base64Regex . MatchString ( uri [ 1 ] )
}
// HasMultiByteCharacter is the validation function for validating if the field's value has a multi byte character.
func hasMultiByteCharacter ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Len ( ) == 0 {
return true
}
return multibyteRegex . MatchString ( field . String ( ) )
}
// IsPrintableASCII is the validation function for validating if the field's value is a valid printable ASCII character.
func isPrintableASCII ( fl FieldLevel ) bool {
return printableASCIIRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsASCII is the validation function for validating if the field's value is a valid ASCII character.
func isASCII ( fl FieldLevel ) bool {
return aSCIIRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID5 is the validation function for validating if the field's value is a valid v5 UUID.
func isUUID5 ( fl FieldLevel ) bool {
return uUID5Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID4 is the validation function for validating if the field's value is a valid v4 UUID.
func isUUID4 ( fl FieldLevel ) bool {
return uUID4Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID3 is the validation function for validating if the field's value is a valid v3 UUID.
func isUUID3 ( fl FieldLevel ) bool {
return uUID3Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID is the validation function for validating if the field's value is a valid UUID of any version.
func isUUID ( fl FieldLevel ) bool {
return uUIDRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID5RFC4122 is the validation function for validating if the field's value is a valid RFC4122 v5 UUID.
func isUUID5RFC4122 ( fl FieldLevel ) bool {
return uUID5RFC4122Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID4RFC4122 is the validation function for validating if the field's value is a valid RFC4122 v4 UUID.
func isUUID4RFC4122 ( fl FieldLevel ) bool {
return uUID4RFC4122Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUID3RFC4122 is the validation function for validating if the field's value is a valid RFC4122 v3 UUID.
func isUUID3RFC4122 ( fl FieldLevel ) bool {
return uUID3RFC4122Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsUUIDRFC4122 is the validation function for validating if the field's value is a valid RFC4122 UUID of any version.
func isUUIDRFC4122 ( fl FieldLevel ) bool {
return uUIDRFC4122Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsISBN is the validation function for validating if the field's value is a valid v10 or v13 ISBN.
func isISBN ( fl FieldLevel ) bool {
return isISBN10 ( fl ) || isISBN13 ( fl )
}
// IsISBN13 is the validation function for validating if the field's value is a valid v13 ISBN.
func isISBN13 ( fl FieldLevel ) bool {
s := strings . Replace ( strings . Replace ( fl . Field ( ) . String ( ) , "-" , "" , 4 ) , " " , "" , 4 )
if ! iSBN13Regex . MatchString ( s ) {
return false
}
var checksum int32
var i int32
factor := [ ] int32 { 1 , 3 }
for i = 0 ; i < 12 ; i ++ {
checksum += factor [ i % 2 ] * int32 ( s [ i ] - '0' )
}
return ( int32 ( s [ 12 ] - '0' ) ) - ( ( 10 - ( checksum % 10 ) ) % 10 ) == 0
}
// IsISBN10 is the validation function for validating if the field's value is a valid v10 ISBN.
func isISBN10 ( fl FieldLevel ) bool {
s := strings . Replace ( strings . Replace ( fl . Field ( ) . String ( ) , "-" , "" , 3 ) , " " , "" , 3 )
if ! iSBN10Regex . MatchString ( s ) {
return false
}
var checksum int32
var i int32
for i = 0 ; i < 9 ; i ++ {
checksum += ( i + 1 ) * int32 ( s [ i ] - '0' )
}
if s [ 9 ] == 'X' {
checksum += 10 * 10
} else {
checksum += 10 * int32 ( s [ 9 ] - '0' )
}
return checksum % 11 == 0
}
// IsEthereumAddress is the validation function for validating if the field's value is a valid ethereum address based currently only on the format
func isEthereumAddress ( fl FieldLevel ) bool {
address := fl . Field ( ) . String ( )
if ! ethAddressRegex . MatchString ( address ) {
return false
}
if ethaddressRegexUpper . MatchString ( address ) || ethAddressRegexLower . MatchString ( address ) {
return true
}
// checksum validation is blocked by https://github.com/golang/crypto/pull/28
return true
}
// IsBitcoinAddress is the validation function for validating if the field's value is a valid btc address
func isBitcoinAddress ( fl FieldLevel ) bool {
address := fl . Field ( ) . String ( )
if ! btcAddressRegex . MatchString ( address ) {
return false
}
alphabet := [ ] byte ( "123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz" )
decode := [ 25 ] byte { }
for _ , n := range [ ] byte ( address ) {
d := bytes . IndexByte ( alphabet , n )
for i := 24 ; i >= 0 ; i -- {
d += 58 * int ( decode [ i ] )
decode [ i ] = byte ( d % 256 )
d /= 256
}
}
h := sha256 . New ( )
_ , _ = h . Write ( decode [ : 21 ] )
d := h . Sum ( [ ] byte { } )
h = sha256 . New ( )
_ , _ = h . Write ( d )
validchecksum := [ 4 ] byte { }
computedchecksum := [ 4 ] byte { }
copy ( computedchecksum [ : ] , h . Sum ( d [ : 0 ] ) )
copy ( validchecksum [ : ] , decode [ 21 : ] )
return validchecksum == computedchecksum
}
// IsBitcoinBech32Address is the validation function for validating if the field's value is a valid bech32 btc address
func isBitcoinBech32Address ( fl FieldLevel ) bool {
address := fl . Field ( ) . String ( )
if ! btcLowerAddressRegexBech32 . MatchString ( address ) && ! btcUpperAddressRegexBech32 . MatchString ( address ) {
return false
}
am := len ( address ) % 8
if am == 0 || am == 3 || am == 5 {
return false
}
address = strings . ToLower ( address )
alphabet := "qpzry9x8gf2tvdw0s3jn54khce6mua7l"
hr := [ ] int { 3 , 3 , 0 , 2 , 3 } // the human readable part will always be bc
addr := address [ 3 : ]
dp := make ( [ ] int , 0 , len ( addr ) )
for _ , c := range addr {
dp = append ( dp , strings . IndexRune ( alphabet , c ) )
}
ver := dp [ 0 ]
if ver < 0 || ver > 16 {
return false
}
if ver == 0 {
if len ( address ) != 42 && len ( address ) != 62 {
return false
}
}
values := append ( hr , dp ... )
GEN := [ ] int { 0x3b6a57b2 , 0x26508e6d , 0x1ea119fa , 0x3d4233dd , 0x2a1462b3 }
p := 1
for _ , v := range values {
b := p >> 25
p = ( p & 0x1ffffff ) << 5 ^ v
for i := 0 ; i < 5 ; i ++ {
if ( b >> uint ( i ) ) & 1 == 1 {
p ^ = GEN [ i ]
}
}
}
if p != 1 {
return false
}
b := uint ( 0 )
acc := 0
mv := ( 1 << 5 ) - 1
var sw [ ] int
for _ , v := range dp [ 1 : len ( dp ) - 6 ] {
acc = ( acc << 5 ) | v
b += 5
for b >= 8 {
b -= 8
sw = append ( sw , ( acc >> b ) & mv )
}
}
if len ( sw ) < 2 || len ( sw ) > 40 {
return false
}
return true
}
// ExcludesRune is the validation function for validating that the field's value does not contain the rune specified within the param.
func excludesRune ( fl FieldLevel ) bool {
return ! containsRune ( fl )
}
// ExcludesAll is the validation function for validating that the field's value does not contain any of the characters specified within the param.
func excludesAll ( fl FieldLevel ) bool {
return ! containsAny ( fl )
}
// Excludes is the validation function for validating that the field's value does not contain the text specified within the param.
func excludes ( fl FieldLevel ) bool {
return ! contains ( fl )
}
// ContainsRune is the validation function for validating that the field's value contains the rune specified within the param.
func containsRune ( fl FieldLevel ) bool {
r , _ := utf8 . DecodeRuneInString ( fl . Param ( ) )
return strings . ContainsRune ( fl . Field ( ) . String ( ) , r )
}
// ContainsAny is the validation function for validating that the field's value contains any of the characters specified within the param.
func containsAny ( fl FieldLevel ) bool {
return strings . ContainsAny ( fl . Field ( ) . String ( ) , fl . Param ( ) )
}
// Contains is the validation function for validating that the field's value contains the text specified within the param.
func contains ( fl FieldLevel ) bool {
return strings . Contains ( fl . Field ( ) . String ( ) , fl . Param ( ) )
}
// StartsWith is the validation function for validating that the field's value starts with the text specified within the param.
func startsWith ( fl FieldLevel ) bool {
return strings . HasPrefix ( fl . Field ( ) . String ( ) , fl . Param ( ) )
}
// EndsWith is the validation function for validating that the field's value ends with the text specified within the param.
func endsWith ( fl FieldLevel ) bool {
return strings . HasSuffix ( fl . Field ( ) . String ( ) , fl . Param ( ) )
}
// StartsNotWith is the validation function for validating that the field's value does not start with the text specified within the param.
func startsNotWith ( fl FieldLevel ) bool {
return ! startsWith ( fl )
}
// EndsNotWith is the validation function for validating that the field's value does not end with the text specified within the param.
func endsNotWith ( fl FieldLevel ) bool {
return ! endsWith ( fl )
}
// FieldContains is the validation function for validating if the current field's value contains the field specified by the param's value.
func fieldContains ( fl FieldLevel ) bool {
field := fl . Field ( )
currentField , _ , ok := fl . GetStructFieldOK ( )
if ! ok {
return false
}
return strings . Contains ( field . String ( ) , currentField . String ( ) )
}
// FieldExcludes is the validation function for validating if the current field's value excludes the field specified by the param's value.
func fieldExcludes ( fl FieldLevel ) bool {
field := fl . Field ( )
currentField , _ , ok := fl . GetStructFieldOK ( )
if ! ok {
return true
}
return ! strings . Contains ( field . String ( ) , currentField . String ( ) )
}
// IsNeField is the validation function for validating if the current field's value is not equal to the field specified by the param's value.
func isNeField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return true
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) != currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) != currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) != currentField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) != int64 ( currentField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return true
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return ! fieldTime . Equal ( t )
}
}
// default reflect.String:
return field . String ( ) != currentField . String ( )
}
// IsNe is the validation function for validating that the field's value does not equal the provided param value.
func isNe ( fl FieldLevel ) bool {
return ! isEq ( fl )
}
// IsLteCrossStructField is the validation function for validating if the current field's value is less than or equal to the field, within a separate struct, specified by the param's value.
func isLteCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , topKind , ok := fl . GetStructFieldOK ( )
if ! ok || topKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) <= topField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) <= topField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) <= topField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) <= int64 ( topField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return false
}
if fieldType == timeType {
fieldTime := field . Interface ( ) . ( time . Time )
topTime := topField . Interface ( ) . ( time . Time )
return fieldTime . Before ( topTime ) || fieldTime . Equal ( topTime )
}
}
// default reflect.String:
return field . String ( ) <= topField . String ( )
}
// IsLtCrossStructField is the validation function for validating if the current field's value is less than the field, within a separate struct, specified by the param's value.
// NOTE: This is exposed for use within your own custom functions and not intended to be called directly.
func isLtCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , topKind , ok := fl . GetStructFieldOK ( )
if ! ok || topKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) < topField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) < topField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) < topField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) < int64 ( topField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return false
}
if fieldType == timeType {
fieldTime := field . Interface ( ) . ( time . Time )
topTime := topField . Interface ( ) . ( time . Time )
return fieldTime . Before ( topTime )
}
}
// default reflect.String:
return field . String ( ) < topField . String ( )
}
// IsGteCrossStructField is the validation function for validating if the current field's value is greater than or equal to the field, within a separate struct, specified by the param's value.
func isGteCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , topKind , ok := fl . GetStructFieldOK ( )
if ! ok || topKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) >= topField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) >= topField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) >= topField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) >= int64 ( topField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return false
}
if fieldType == timeType {
fieldTime := field . Interface ( ) . ( time . Time )
topTime := topField . Interface ( ) . ( time . Time )
return fieldTime . After ( topTime ) || fieldTime . Equal ( topTime )
}
}
// default reflect.String:
return field . String ( ) >= topField . String ( )
}
// IsGtCrossStructField is the validation function for validating if the current field's value is greater than the field, within a separate struct, specified by the param's value.
func isGtCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , topKind , ok := fl . GetStructFieldOK ( )
if ! ok || topKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) > topField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) > topField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) > topField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) > int64 ( topField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return false
}
if fieldType == timeType {
fieldTime := field . Interface ( ) . ( time . Time )
topTime := topField . Interface ( ) . ( time . Time )
return fieldTime . After ( topTime )
}
}
// default reflect.String:
return field . String ( ) > topField . String ( )
}
// IsNeCrossStructField is the validation function for validating that the current field's value is not equal to the field, within a separate struct, specified by the param's value.
func isNeCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return true
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return topField . Int ( ) != field . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return topField . Uint ( ) != field . Uint ( )
case reflect . Float32 , reflect . Float64 :
return topField . Float ( ) != field . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( topField . Len ( ) ) != int64 ( field . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return true
}
if fieldType == timeType {
t := field . Interface ( ) . ( time . Time )
fieldTime := topField . Interface ( ) . ( time . Time )
return ! fieldTime . Equal ( t )
}
}
// default reflect.String:
return topField . String ( ) != field . String ( )
}
// IsEqCrossStructField is the validation function for validating that the current field's value is equal to the field, within a separate struct, specified by the param's value.
func isEqCrossStructField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
topField , topKind , ok := fl . GetStructFieldOK ( )
if ! ok || topKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return topField . Int ( ) == field . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return topField . Uint ( ) == field . Uint ( )
case reflect . Float32 , reflect . Float64 :
return topField . Float ( ) == field . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( topField . Len ( ) ) == int64 ( field . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != topField . Type ( ) {
return false
}
if fieldType == timeType {
t := field . Interface ( ) . ( time . Time )
fieldTime := topField . Interface ( ) . ( time . Time )
return fieldTime . Equal ( t )
}
}
// default reflect.String:
return topField . String ( ) == field . String ( )
}
// IsEqField is the validation function for validating if the current field's value is equal to the field specified by the param's value.
func isEqField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) == currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) == currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) == currentField . Float ( )
case reflect . Slice , reflect . Map , reflect . Array :
return int64 ( field . Len ( ) ) == int64 ( currentField . Len ( ) )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return false
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return fieldTime . Equal ( t )
}
}
// default reflect.String:
return field . String ( ) == currentField . String ( )
}
// IsEq is the validation function for validating if the current field's value is equal to the param's value.
func isEq ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
return field . String ( ) == param
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) == p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) == p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) == p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) == p
case reflect . Bool :
p := asBool ( param )
return field . Bool ( ) == p
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsBase64 is the validation function for validating if the current field's value is a valid base 64.
func isBase64 ( fl FieldLevel ) bool {
return base64Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsBase64URL is the validation function for validating if the current field's value is a valid base64 URL safe string.
func isBase64URL ( fl FieldLevel ) bool {
return base64URLRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsURI is the validation function for validating if the current field's value is a valid URI.
func isURI ( fl FieldLevel ) bool {
field := fl . Field ( )
switch field . Kind ( ) {
case reflect . String :
s := field . String ( )
// checks needed as of Go 1.6 because of change https://github.com/golang/go/commit/617c93ce740c3c3cc28cdd1a0d712be183d0b328#diff-6c2d018290e298803c0c9419d8739885L195
// emulate browser and strip the '#' suffix prior to validation. see issue-#237
if i := strings . Index ( s , "#" ) ; i > - 1 {
s = s [ : i ]
}
if len ( s ) == 0 {
return false
}
_ , err := url . ParseRequestURI ( s )
return err == nil
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsURL is the validation function for validating if the current field's value is a valid URL.
func isURL ( fl FieldLevel ) bool {
field := fl . Field ( )
switch field . Kind ( ) {
case reflect . String :
var i int
s := field . String ( )
// checks needed as of Go 1.6 because of change https://github.com/golang/go/commit/617c93ce740c3c3cc28cdd1a0d712be183d0b328#diff-6c2d018290e298803c0c9419d8739885L195
// emulate browser and strip the '#' suffix prior to validation. see issue-#237
if i = strings . Index ( s , "#" ) ; i > - 1 {
s = s [ : i ]
}
if len ( s ) == 0 {
return false
}
url , err := url . ParseRequestURI ( s )
if err != nil || url . Scheme == "" {
return false
}
return true
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// isUrnRFC2141 is the validation function for validating if the current field's value is a valid URN as per RFC 2141.
func isUrnRFC2141 ( fl FieldLevel ) bool {
field := fl . Field ( )
switch field . Kind ( ) {
case reflect . String :
str := field . String ( )
_ , match := urn . Parse ( [ ] byte ( str ) )
return match
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsFile is the validation function for validating if the current field's value is a valid file path.
func isFile ( fl FieldLevel ) bool {
field := fl . Field ( )
switch field . Kind ( ) {
case reflect . String :
fileInfo , err := os . Stat ( field . String ( ) )
if err != nil {
return false
}
return ! fileInfo . IsDir ( )
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsE164 is the validation function for validating if the current field's value is a valid e.164 formatted phone number.
func isE164 ( fl FieldLevel ) bool {
return e164Regex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsEmail is the validation function for validating if the current field's value is a valid email address.
func isEmail ( fl FieldLevel ) bool {
return emailRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsHSLA is the validation function for validating if the current field's value is a valid HSLA color.
func isHSLA ( fl FieldLevel ) bool {
return hslaRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsHSL is the validation function for validating if the current field's value is a valid HSL color.
func isHSL ( fl FieldLevel ) bool {
return hslRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsRGBA is the validation function for validating if the current field's value is a valid RGBA color.
func isRGBA ( fl FieldLevel ) bool {
return rgbaRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsRGB is the validation function for validating if the current field's value is a valid RGB color.
func isRGB ( fl FieldLevel ) bool {
return rgbRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsHEXColor is the validation function for validating if the current field's value is a valid HEX color.
func isHEXColor ( fl FieldLevel ) bool {
return hexcolorRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsHexadecimal is the validation function for validating if the current field's value is a valid hexadecimal.
func isHexadecimal ( fl FieldLevel ) bool {
return hexadecimalRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsNumber is the validation function for validating if the current field's value is a valid number.
func isNumber ( fl FieldLevel ) bool {
switch fl . Field ( ) . Kind ( ) {
case 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 :
return true
default :
return numberRegex . MatchString ( fl . Field ( ) . String ( ) )
}
}
// IsNumeric is the validation function for validating if the current field's value is a valid numeric value.
func isNumeric ( fl FieldLevel ) bool {
switch fl . Field ( ) . Kind ( ) {
case 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 :
return true
default :
return numericRegex . MatchString ( fl . Field ( ) . String ( ) )
}
}
// IsAlphanum is the validation function for validating if the current field's value is a valid alphanumeric value.
func isAlphanum ( fl FieldLevel ) bool {
return alphaNumericRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsAlpha is the validation function for validating if the current field's value is a valid alpha value.
func isAlpha ( fl FieldLevel ) bool {
return alphaRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsAlphanumUnicode is the validation function for validating if the current field's value is a valid alphanumeric unicode value.
func isAlphanumUnicode ( fl FieldLevel ) bool {
return alphaUnicodeNumericRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// IsAlphaUnicode is the validation function for validating if the current field's value is a valid alpha unicode value.
func isAlphaUnicode ( fl FieldLevel ) bool {
return alphaUnicodeRegex . MatchString ( fl . Field ( ) . String ( ) )
}
// isDefault is the opposite of required aka hasValue
func isDefault ( fl FieldLevel ) bool {
return ! hasValue ( fl )
}
// HasValue is the validation function for validating if the current field's value is not the default static value.
func hasValue ( fl FieldLevel ) bool {
field := fl . Field ( )
switch field . Kind ( ) {
case reflect . Slice , reflect . Map , reflect . Ptr , reflect . Interface , reflect . Chan , reflect . Func :
return ! field . IsNil ( )
default :
if fl . ( * validate ) . fldIsPointer && field . Interface ( ) != nil {
return true
}
return field . IsValid ( ) && field . Interface ( ) != reflect . Zero ( field . Type ( ) ) . Interface ( )
}
}
// requireCheckField is a func for check field kind
func requireCheckFieldKind ( fl FieldLevel , param string , defaultNotFoundValue bool ) bool {
field := fl . Field ( )
kind := field . Kind ( )
var nullable , found bool
if len ( param ) > 0 {
field , kind , nullable , found = fl . GetStructFieldOKAdvanced2 ( fl . Parent ( ) , param )
if ! found {
return defaultNotFoundValue
}
}
switch kind {
case reflect . Invalid :
return defaultNotFoundValue
case reflect . Slice , reflect . Map , reflect . Ptr , reflect . Interface , reflect . Chan , reflect . Func :
return field . IsNil ( )
default :
if nullable && field . Interface ( ) != nil {
return false
}
return field . IsValid ( ) && field . Interface ( ) == reflect . Zero ( field . Type ( ) ) . Interface ( )
}
}
// RequiredWith is the validation function
// The field under validation must be present and not empty only if any of the other specified fields are present.
func requiredWith ( fl FieldLevel ) bool {
params := parseOneOfParam2 ( fl . Param ( ) )
for _ , param := range params {
if ! requireCheckFieldKind ( fl , param , true ) {
return hasValue ( fl )
}
}
return true
}
// RequiredWithAll is the validation function
// The field under validation must be present and not empty only if all of the other specified fields are present.
func requiredWithAll ( fl FieldLevel ) bool {
params := parseOneOfParam2 ( fl . Param ( ) )
for _ , param := range params {
if requireCheckFieldKind ( fl , param , true ) {
return true
}
}
return hasValue ( fl )
}
// RequiredWithout is the validation function
// The field under validation must be present and not empty only when any of the other specified fields are not present.
func requiredWithout ( fl FieldLevel ) bool {
if requireCheckFieldKind ( fl , strings . TrimSpace ( fl . Param ( ) ) , true ) {
return hasValue ( fl )
}
return true
}
// RequiredWithoutAll is the validation function
// The field under validation must be present and not empty only when all of the other specified fields are not present.
func requiredWithoutAll ( fl FieldLevel ) bool {
params := parseOneOfParam2 ( fl . Param ( ) )
for _ , param := range params {
if ! requireCheckFieldKind ( fl , param , true ) {
return true
}
}
return hasValue ( fl )
}
// IsGteField is the validation function for validating if the current field's value is greater than or equal to the field specified by the param's value.
func isGteField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) >= currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) >= currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) >= currentField . Float ( )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return false
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return fieldTime . After ( t ) || fieldTime . Equal ( t )
}
}
// default reflect.String
return len ( field . String ( ) ) >= len ( currentField . String ( ) )
}
// IsGtField is the validation function for validating if the current field's value is greater than the field specified by the param's value.
func isGtField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) > currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) > currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) > currentField . Float ( )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return false
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return fieldTime . After ( t )
}
}
// default reflect.String
return len ( field . String ( ) ) > len ( currentField . String ( ) )
}
// IsGte is the validation function for validating if the current field's value is greater than or equal to the param's value.
func isGte ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
p := asInt ( param )
return int64 ( utf8 . RuneCountInString ( field . String ( ) ) ) >= p
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) >= p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) >= p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) >= p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) >= p
case reflect . Struct :
if field . Type ( ) == timeType {
now := time . Now ( ) . UTC ( )
t := field . Interface ( ) . ( time . Time )
return t . After ( now ) || t . Equal ( now )
}
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsGt is the validation function for validating if the current field's value is greater than the param's value.
func isGt ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
p := asInt ( param )
return int64 ( utf8 . RuneCountInString ( field . String ( ) ) ) > p
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) > p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) > p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) > p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) > p
case reflect . Struct :
if field . Type ( ) == timeType {
return field . Interface ( ) . ( time . Time ) . After ( time . Now ( ) . UTC ( ) )
}
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// HasLengthOf is the validation function for validating if the current field's value is equal to the param's value.
func hasLengthOf ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
p := asInt ( param )
return int64 ( utf8 . RuneCountInString ( field . String ( ) ) ) == p
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) == p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) == p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) == p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) == p
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// HasMinOf is the validation function for validating if the current field's value is greater than or equal to the param's value.
func hasMinOf ( fl FieldLevel ) bool {
return isGte ( fl )
}
// IsLteField is the validation function for validating if the current field's value is less than or equal to the field specified by the param's value.
func isLteField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) <= currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) <= currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) <= currentField . Float ( )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return false
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return fieldTime . Before ( t ) || fieldTime . Equal ( t )
}
}
// default reflect.String
return len ( field . String ( ) ) <= len ( currentField . String ( ) )
}
// IsLtField is the validation function for validating if the current field's value is less than the field specified by the param's value.
func isLtField ( fl FieldLevel ) bool {
field := fl . Field ( )
kind := field . Kind ( )
currentField , currentKind , ok := fl . GetStructFieldOK ( )
if ! ok || currentKind != kind {
return false
}
switch kind {
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
return field . Int ( ) < currentField . Int ( )
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
return field . Uint ( ) < currentField . Uint ( )
case reflect . Float32 , reflect . Float64 :
return field . Float ( ) < currentField . Float ( )
case reflect . Struct :
fieldType := field . Type ( )
// Not Same underlying type i.e. struct and time
if fieldType != currentField . Type ( ) {
return false
}
if fieldType == timeType {
t := currentField . Interface ( ) . ( time . Time )
fieldTime := field . Interface ( ) . ( time . Time )
return fieldTime . Before ( t )
}
}
// default reflect.String
return len ( field . String ( ) ) < len ( currentField . String ( ) )
}
// IsLte is the validation function for validating if the current field's value is less than or equal to the param's value.
func isLte ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
p := asInt ( param )
return int64 ( utf8 . RuneCountInString ( field . String ( ) ) ) <= p
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) <= p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) <= p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) <= p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) <= p
case reflect . Struct :
if field . Type ( ) == timeType {
now := time . Now ( ) . UTC ( )
t := field . Interface ( ) . ( time . Time )
return t . Before ( now ) || t . Equal ( now )
}
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// IsLt is the validation function for validating if the current field's value is less than the param's value.
func isLt ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
switch field . Kind ( ) {
case reflect . String :
p := asInt ( param )
return int64 ( utf8 . RuneCountInString ( field . String ( ) ) ) < p
case reflect . Slice , reflect . Map , reflect . Array :
p := asInt ( param )
return int64 ( field . Len ( ) ) < p
case reflect . Int , reflect . Int8 , reflect . Int16 , reflect . Int32 , reflect . Int64 :
p := asInt ( param )
return field . Int ( ) < p
case reflect . Uint , reflect . Uint8 , reflect . Uint16 , reflect . Uint32 , reflect . Uint64 , reflect . Uintptr :
p := asUint ( param )
return field . Uint ( ) < p
case reflect . Float32 , reflect . Float64 :
p := asFloat ( param )
return field . Float ( ) < p
case reflect . Struct :
if field . Type ( ) == timeType {
return field . Interface ( ) . ( time . Time ) . Before ( time . Now ( ) . UTC ( ) )
}
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// HasMaxOf is the validation function for validating if the current field's value is less than or equal to the param's value.
func hasMaxOf ( fl FieldLevel ) bool {
return isLte ( fl )
}
// IsTCP4AddrResolvable is the validation function for validating if the field's value is a resolvable tcp4 address.
func isTCP4AddrResolvable ( fl FieldLevel ) bool {
if ! isIP4Addr ( fl ) {
return false
}
_ , err := net . ResolveTCPAddr ( "tcp4" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsTCP6AddrResolvable is the validation function for validating if the field's value is a resolvable tcp6 address.
func isTCP6AddrResolvable ( fl FieldLevel ) bool {
if ! isIP6Addr ( fl ) {
return false
}
_ , err := net . ResolveTCPAddr ( "tcp6" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsTCPAddrResolvable is the validation function for validating if the field's value is a resolvable tcp address.
func isTCPAddrResolvable ( fl FieldLevel ) bool {
if ! isIP4Addr ( fl ) && ! isIP6Addr ( fl ) {
return false
}
_ , err := net . ResolveTCPAddr ( "tcp" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsUDP4AddrResolvable is the validation function for validating if the field's value is a resolvable udp4 address.
func isUDP4AddrResolvable ( fl FieldLevel ) bool {
if ! isIP4Addr ( fl ) {
return false
}
_ , err := net . ResolveUDPAddr ( "udp4" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsUDP6AddrResolvable is the validation function for validating if the field's value is a resolvable udp6 address.
func isUDP6AddrResolvable ( fl FieldLevel ) bool {
if ! isIP6Addr ( fl ) {
return false
}
_ , err := net . ResolveUDPAddr ( "udp6" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsUDPAddrResolvable is the validation function for validating if the field's value is a resolvable udp address.
func isUDPAddrResolvable ( fl FieldLevel ) bool {
if ! isIP4Addr ( fl ) && ! isIP6Addr ( fl ) {
return false
}
_ , err := net . ResolveUDPAddr ( "udp" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsIP4AddrResolvable is the validation function for validating if the field's value is a resolvable ip4 address.
func isIP4AddrResolvable ( fl FieldLevel ) bool {
if ! isIPv4 ( fl ) {
return false
}
_ , err := net . ResolveIPAddr ( "ip4" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsIP6AddrResolvable is the validation function for validating if the field's value is a resolvable ip6 address.
func isIP6AddrResolvable ( fl FieldLevel ) bool {
if ! isIPv6 ( fl ) {
return false
}
_ , err := net . ResolveIPAddr ( "ip6" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsIPAddrResolvable is the validation function for validating if the field's value is a resolvable ip address.
func isIPAddrResolvable ( fl FieldLevel ) bool {
if ! isIP ( fl ) {
return false
}
_ , err := net . ResolveIPAddr ( "ip" , fl . Field ( ) . String ( ) )
return err == nil
}
// IsUnixAddrResolvable is the validation function for validating if the field's value is a resolvable unix address.
func isUnixAddrResolvable ( fl FieldLevel ) bool {
_ , err := net . ResolveUnixAddr ( "unix" , fl . Field ( ) . String ( ) )
return err == nil
}
func isIP4Addr ( fl FieldLevel ) bool {
val := fl . Field ( ) . String ( )
if idx := strings . LastIndex ( val , ":" ) ; idx != - 1 {
val = val [ 0 : idx ]
}
ip := net . ParseIP ( val )
return ip != nil && ip . To4 ( ) != nil
}
func isIP6Addr ( fl FieldLevel ) bool {
val := fl . Field ( ) . String ( )
if idx := strings . LastIndex ( val , ":" ) ; idx != - 1 {
if idx != 0 && val [ idx - 1 : idx ] == "]" {
val = val [ 1 : idx - 1 ]
}
}
ip := net . ParseIP ( val )
return ip != nil && ip . To4 ( ) == nil
}
func isHostnameRFC952 ( fl FieldLevel ) bool {
return hostnameRegexRFC952 . MatchString ( fl . Field ( ) . String ( ) )
}
func isHostnameRFC1123 ( fl FieldLevel ) bool {
return hostnameRegexRFC1123 . MatchString ( fl . Field ( ) . String ( ) )
}
func isFQDN ( fl FieldLevel ) bool {
val := fl . Field ( ) . String ( )
if val == "" {
return false
}
return fqdnRegexRFC1123 . MatchString ( val )
}
// IsDir is the validation function for validating if the current field's value is a valid directory.
func isDir ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Kind ( ) == reflect . String {
fileInfo , err := os . Stat ( field . String ( ) )
if err != nil {
return false
}
return fileInfo . IsDir ( )
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// isJSON is the validation function for validating if the current field's value is a valid json string.
func isJSON ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Kind ( ) == reflect . String {
val := field . String ( )
return json . Valid ( [ ] byte ( val ) )
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// isHostnamePort validates a <dns>:<port> combination for fields typically used for socket address.
func isHostnamePort ( fl FieldLevel ) bool {
val := fl . Field ( ) . String ( )
host , port , err := net . SplitHostPort ( val )
if err != nil {
return false
}
// Port must be a iny <= 65535.
if portNum , err := strconv . ParseInt ( port , 10 , 32 ) ; err != nil || portNum > 65535 || portNum < 1 {
return false
}
// If host is specified, it should match a DNS name
if host != "" {
return hostnameRegexRFC1123 . MatchString ( host )
}
return true
}
// isLowercase is the validation function for validating if the current field's value is a lowercase string.
func isLowercase ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Kind ( ) == reflect . String {
if field . String ( ) == "" {
return false
}
return field . String ( ) == strings . ToLower ( field . String ( ) )
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// isUppercase is the validation function for validating if the current field's value is an uppercase string.
func isUppercase ( fl FieldLevel ) bool {
field := fl . Field ( )
if field . Kind ( ) == reflect . String {
if field . String ( ) == "" {
return false
}
return field . String ( ) == strings . ToUpper ( field . String ( ) )
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
// isDatetime is the validation function for validating if the current field's value is a valid datetime string.
func isDatetime ( fl FieldLevel ) bool {
field := fl . Field ( )
param := fl . Param ( )
if field . Kind ( ) == reflect . String {
_ , err := time . Parse ( param , field . String ( ) )
if err != nil {
return false
}
return true
}
panic ( fmt . Sprintf ( "Bad field type %T" , field . Interface ( ) ) )
}
