/ * *
* Package validator
*
* MISC :
* - anonymous structs - they don ' t have names so expect the Struct name within StructErrors to be blank
*
* /
package validator
import (
"bytes"
"errors"
"fmt"
"reflect"
"strings"
"sync"
"time"
"unicode"
)
const (
utf8HexComma = "0x2C"
tagSeparator = ","
orSeparator = "|"
noValidationTag = "-"
tagKeySeparator = "="
structOnlyTag = "structonly"
omitempty = "omitempty"
required = "required"
fieldErrMsg = "Field validation for \"%s\" failed on the \"%s\" tag"
sliceErrMsg = "Field validation for \"%s\" index \"%d\" failed on the \"%s\" tag"
mapErrMsg = "Field validation for \"%s\" key \"%s\" failed on the \"%s\" tag"
structErrMsg = "Struct:%s\n"
diveTag = "dive"
diveSplit = "," + diveTag
)
var structPool * pool
// Pool holds a channelStructErrors.
type pool struct {
pool chan * StructErrors
}
// NewPool creates a new pool of Clients.
func newPool ( max int ) * pool {
return & pool {
pool : make ( chan * StructErrors , max ) ,
}
}
// Borrow a StructErrors from the pool.
func ( p * pool ) Borrow ( ) * StructErrors {
var c * StructErrors
select {
case c = <- p . pool :
default :
c = & StructErrors {
Errors : map [ string ] * FieldError { } ,
StructErrors : map [ string ] * StructErrors { } ,
}
}
return c
}
// Return returns a StructErrors to the pool.
func ( p * pool ) Return ( c * StructErrors ) {
select {
case p . pool <- c :
default :
// let it go, let it go...
}
}
type cachedTags struct {
keyVals [ ] [ ] string
isOrVal bool
}
type cachedField struct {
index int
name string
tags [ ] * cachedTags
tag string
kind reflect . Kind
typ reflect . Type
isTime bool
isSliceOrArray bool
isMap bool
isTimeSubtype bool
sliceSubtype reflect . Type
mapSubtype reflect . Type
sliceSubKind reflect . Kind
mapSubKind reflect . Kind
// DiveMaxDepth uint64 // zero means no depth
// DiveTags map[uint64]string // map of dive depth and associated tag as string]
diveTag string
}
type cachedStruct struct {
children int
name string
kind reflect . Kind
fields [ ] * cachedField
}
type structsCacheMap struct {
lock sync . RWMutex
m map [ reflect . Type ] * cachedStruct
}
func ( s * structsCacheMap ) Get ( key reflect . Type ) ( * cachedStruct , bool ) {
s . lock . RLock ( )
defer s . lock . RUnlock ( )
value , ok := s . m [ key ]
return value , ok
}
func ( s * structsCacheMap ) Set ( key reflect . Type , value * cachedStruct ) {
s . lock . Lock ( )
defer s . lock . Unlock ( )
s . m [ key ] = value
}
var structCache = & structsCacheMap { m : map [ reflect . Type ] * cachedStruct { } }
type fieldsCacheMap struct {
lock sync . RWMutex
m map [ string ] [ ] * cachedTags
}
func ( s * fieldsCacheMap ) Get ( key string ) ( [ ] * cachedTags , bool ) {
s . lock . RLock ( )
defer s . lock . RUnlock ( )
value , ok := s . m [ key ]
return value , ok
}
func ( s * fieldsCacheMap ) Set ( key string , value [ ] * cachedTags ) {
s . lock . Lock ( )
defer s . lock . Unlock ( )
s . m [ key ] = value
}
var fieldsCache = & fieldsCacheMap { m : map [ string ] [ ] * cachedTags { } }
// // SliceError contains a fields error for a single index within an array or slice
// // NOTE: library only checks the first dimension of the array so if you have a multidimensional
// // array [][]string that validations after the "dive" tag are applied to []string not each
// // string within it. It is not a dificulty with traversing the chain, but how to add validations
// // to what dimension of an array and even how to report on them in any meaningful fashion.
// type SliceError struct {
// Index uint64
// Field string
// Tag string
// Kind reflect.Kind
// Type reflect.Type
// Param string
// Value interface{}
// }
// // This is intended for use in development + debugging and not intended to be a production error message.
// // it also allows SliceError to be used as an Error interface
// func (e *SliceError) Error() string {
// return fmt.Sprintf(sliceErrMsg, e.Field, e.Index, e.Tag)
// }
// // MapError contains a fields error for a single key within a map
// // NOTE: library only checks the first dimension of the array so if you have a multidimensional
// // array [][]string that validations after the "dive" tag are applied to []string not each
// // string within it. It is not a dificulty with traversing the chain, but how to add validations
// // to what dimension of an array and even how to report on them in any meaningful fashion.
// type MapError struct {
// Key interface{}
// Field string
// Tag string
// Kind reflect.Kind
// Type reflect.Type
// Param string
// Value interface{}
// }
// // This is intended for use in development + debugging and not intended to be a production error message.
// // it also allows MapError to be used as an Error interface
// func (e *MapError) Error() string {
// return fmt.Sprintf(mapErrMsg, e.Field, e.Key, e.Tag)
// }
// FieldError contains a single field's validation error along
// with other properties that may be needed for error message creation
type FieldError struct {
Field string
Tag string
Kind reflect . Kind
Type reflect . Type
Param string
Value interface { }
isPlaceholderErr bool
IsSliceOrArray bool
IsMap bool
// Key interface{}
// Index int
SliceOrArrayErrs [ ] error // counld be FieldError, StructErrors
MapErrs map [ interface { } ] error // counld be FieldError, StructErrors
}
// This is intended for use in development + debugging and not intended to be a production error message.
// it also allows FieldError to be used as an Error interface
func ( e * FieldError ) Error ( ) string {
return fmt . Sprintf ( fieldErrMsg , e . Field , e . Tag )
}
// StructErrors is hierarchical list of field and struct validation errors
// for a non hierarchical representation please see the Flatten method for StructErrors
type StructErrors struct {
// Name of the Struct
Struct string
// Struct Field Errors
Errors map [ string ] * FieldError
// Struct Fields of type struct and their errors
// key = Field Name of current struct, but internally Struct will be the actual struct name unless anonymous struct, it will be blank
StructErrors map [ string ] * StructErrors
// Index int
// Key interface{}
// IsSliceOrArrayError bool
// IsMapError bool
// Key interface{}
// Index uint64
}
// This is intended for use in development + debugging and not intended to be a production error message.
// it also allows StructErrors to be used as an Error interface
func ( e * StructErrors ) Error ( ) string {
buff := bytes . NewBufferString ( fmt . Sprintf ( structErrMsg , e . Struct ) )
for _ , err := range e . Errors {
buff . WriteString ( err . Error ( ) )
buff . WriteString ( "\n" )
}
for _ , err := range e . StructErrors {
buff . WriteString ( err . Error ( ) )
}
return buff . String ( )
}
// Flatten flattens the StructErrors hierarchical structure into a flat namespace style field name
// for those that want/need it
func ( e * StructErrors ) Flatten ( ) map [ string ] * FieldError {
if e == nil {
return nil
}
errs := map [ string ] * FieldError { }
for _ , f := range e . Errors {
errs [ f . Field ] = f
}
for key , val := range e . StructErrors {
otherErrs := val . Flatten ( )
for _ , f2 := range otherErrs {
f2 . Field = fmt . Sprintf ( "%s.%s" , key , f2 . Field )
errs [ f2 . Field ] = f2
}
}
return errs
}
// Func accepts all values needed for file and cross field validation
// top = top level struct when validating by struct otherwise nil
// current = current level struct when validating by struct otherwise optional comparison value
// f = field value for validation
// param = parameter used in validation i.e. gt=0 param would be 0
type Func func ( top interface { } , current interface { } , f interface { } , param string ) bool
// Validate implements the Validate Struct
// NOTE: Fields within are not thread safe and that is on purpose
// Functions and Tags should all be predifined before use, so subscribe to the philosiphy
// or make it thread safe on your end
type Validate struct {
// tagName being used.
tagName string
// validateFuncs is a map of validation functions and the tag keys
validationFuncs map [ string ] Func
}
// New creates a new Validate instance for use.
func New ( tagName string , funcs map [ string ] Func ) * Validate {
structPool = newPool ( 10 )
return & Validate {
tagName : tagName ,
validationFuncs : funcs ,
}
}
// SetTag sets tagName of the Validator to one of your choosing after creation
// perhaps to dodge a tag name conflict in a specific section of code
// NOTE: this method is not thread-safe
func ( v * Validate ) SetTag ( tagName string ) {
v . tagName = tagName
}
// SetMaxStructPoolSize sets the struct pools max size. this may be usefull for fine grained
// performance tuning towards your application, however, the default should be fine for
// nearly all cases. only increase if you have a deeply nested struct structure.
// NOTE: this method is not thread-safe
// NOTE: this is only here to keep compatibility with v5, in v6 the method will be removed
// and the max pool size will be passed into the New function
func ( v * Validate ) SetMaxStructPoolSize ( max int ) {
structPool = newPool ( max )
}
// AddFunction adds a validation Func to a Validate's map of validators denoted by the key
// NOTE: if the key already exists, it will get replaced.
// NOTE: this method is not thread-safe
func ( v * Validate ) AddFunction ( key string , f Func ) error {
if len ( key ) == 0 {
return errors . New ( "Function Key cannot be empty" )
}
if f == nil {
return errors . New ( "Function cannot be empty" )
}
v . validationFuncs [ key ] = f
return nil
}
// Struct validates a struct, even it's nested structs, and returns a struct containing the errors
// NOTE: Nested Arrays, or Maps of structs do not get validated only the Array or Map itself; the reason is that there is no good
// way to represent or report which struct within the array has the error, besides can validate the struct prior to adding it to
// the Array or Map.
func ( v * Validate ) Struct ( s interface { } ) * StructErrors {
return v . structRecursive ( s , s , s )
}
// structRecursive validates a struct recursivly and passes the top level and current struct around for use in validator functions and returns a struct containing the errors
func ( v * Validate ) structRecursive ( top interface { } , current interface { } , s interface { } ) * StructErrors {
structValue := reflect . ValueOf ( s )
if structValue . Kind ( ) == reflect . Ptr && ! structValue . IsNil ( ) {
return v . structRecursive ( top , current , structValue . Elem ( ) . Interface ( ) )
}
if structValue . Kind ( ) != reflect . Struct && structValue . Kind ( ) != reflect . Interface {
panic ( "interface passed for validation is not a struct" )
}
structType := reflect . TypeOf ( s )
var structName string
var numFields int
var cs * cachedStruct
var isCached bool
cs , isCached = structCache . Get ( structType )
if isCached {
structName = cs . name
numFields = cs . children
} else {
structName = structType . Name ( )
numFields = structValue . NumField ( )
cs = & cachedStruct { name : structName , children : numFields }
structCache . Set ( structType , cs )
}
validationErrors := structPool . Borrow ( )
validationErrors . Struct = structName
for i := 0 ; i < numFields ; i ++ {
var valueField reflect . Value
var cField * cachedField
var typeField reflect . StructField
if isCached {
cField = cs . fields [ i ]
valueField = structValue . Field ( cField . index )
if valueField . Kind ( ) == reflect . Ptr && ! valueField . IsNil ( ) {
valueField = valueField . Elem ( )
}
} else {
valueField = structValue . Field ( i )
if valueField . Kind ( ) == reflect . Ptr && ! valueField . IsNil ( ) {
valueField = valueField . Elem ( )
}
typeField = structType . Field ( i )
cField = & cachedField { index : i , tag : typeField . Tag . Get ( v . tagName ) , isTime : valueField . Type ( ) == reflect . TypeOf ( time . Time { } ) }
if cField . tag == noValidationTag {
cs . children --
continue
}
// if no validation and not a struct (which may containt fields for validation)
if cField . tag == "" && ( ( valueField . Kind ( ) != reflect . Struct && valueField . Kind ( ) != reflect . Interface ) || valueField . Type ( ) == reflect . TypeOf ( time . Time { } ) ) {
cs . children --
continue
}
cField . name = typeField . Name
cField . kind = valueField . Kind ( )
cField . typ = valueField . Type ( )
}
// this can happen if the first cache value was nil
// but the second actually has a value
if cField . kind == reflect . Ptr {
cField . kind = valueField . Kind ( )
}
switch cField . kind {
case reflect . Struct , reflect . Interface :
if ! unicode . IsUpper ( rune ( cField . name [ 0 ] ) ) {
cs . children --
continue
}
if cField . isTime {
// cField.isTime = true
if fieldError := v . fieldWithNameAndValue ( top , current , valueField . Interface ( ) , cField . tag , cField . name , false , cField ) ; fieldError != nil {
validationErrors . Errors [ fieldError . Field ] = fieldError
// free up memory reference
fieldError = nil
}
} else {
if strings . Contains ( cField . tag , structOnlyTag ) {
cs . children --
continue
}
if valueField . Kind ( ) == reflect . Ptr && valueField . IsNil ( ) {
if strings . Contains ( cField . tag , omitempty ) {
continue
}
if strings . Contains ( cField . tag , required ) {
validationErrors . Errors [ cField . name ] = & FieldError {
Field : cField . name ,
Tag : required ,
Value : valueField . Interface ( ) ,
}
continue
}
}
if structErrors := v . structRecursive ( top , valueField . Interface ( ) , valueField . Interface ( ) ) ; structErrors != nil {
validationErrors . StructErrors [ cField . name ] = structErrors
// free up memory map no longer needed
structErrors = nil
}
}
case reflect . Slice , reflect . Array :
cField . isSliceOrArray = true
cField . sliceSubtype = cField . typ . Elem ( )
cField . isTimeSubtype = cField . sliceSubtype == reflect . TypeOf ( time . Time { } )
cField . sliceSubKind = cField . sliceSubtype . Kind ( )
if fieldError := v . fieldWithNameAndValue ( top , current , valueField . Interface ( ) , cField . tag , cField . name , false , cField ) ; fieldError != nil {
validationErrors . Errors [ fieldError . Field ] = fieldError
// free up memory reference
fieldError = nil
}
case reflect . Map :
cField . isMap = true
cField . mapSubtype = cField . typ . Elem ( )
cField . isTimeSubtype = cField . mapSubtype == reflect . TypeOf ( time . Time { } )
cField . mapSubKind = cField . mapSubtype . Kind ( )
if fieldError := v . fieldWithNameAndValue ( top , current , valueField . Interface ( ) , cField . tag , cField . name , false , cField ) ; fieldError != nil {
validationErrors . Errors [ fieldError . Field ] = fieldError
// free up memory reference
fieldError = nil
}
default :
if fieldError := v . fieldWithNameAndValue ( top , current , valueField . Interface ( ) , cField . tag , cField . name , false , cField ) ; fieldError != nil {
validationErrors . Errors [ fieldError . Field ] = fieldError
// free up memory reference
fieldError = nil
}
}
if ! isCached {
cs . fields = append ( cs . fields , cField )
}
}
if len ( validationErrors . Errors ) == 0 && len ( validationErrors . StructErrors ) == 0 {
structPool . Return ( validationErrors )
return nil
}
return validationErrors
}
// Field allows validation of a single field, still using tag style validation to check multiple errors
func ( v * Validate ) Field ( f interface { } , tag string ) * FieldError {
return v . FieldWithValue ( nil , f , tag )
}
// FieldWithValue allows validation of a single field, possibly even against another fields value, still using tag style validation to check multiple errors
func ( v * Validate ) FieldWithValue ( val interface { } , f interface { } , tag string ) * FieldError {
return v . fieldWithNameAndValue ( nil , val , f , tag , "" , true , nil )
}
func ( v * Validate ) fieldWithNameAndValue ( val interface { } , current interface { } , f interface { } , tag string , name string , isSingleField bool , cacheField * cachedField ) * FieldError {
var cField * cachedField
var isCached bool
// var isInDive bool
var valueField reflect . Value
// This is a double check if coming from validate.Struct but need to be here in case function is called directly
if tag == noValidationTag {
return nil
}
if strings . Contains ( tag , omitempty ) && ! hasValue ( val , current , f , "" ) {
return nil
}
valueField = reflect . ValueOf ( f )
if cacheField == nil {
// valueField = reflect.ValueOf(f)
if valueField . Kind ( ) == reflect . Ptr && ! valueField . IsNil ( ) {
valueField = valueField . Elem ( )
f = valueField . Interface ( )
}
cField = & cachedField { name : name , kind : valueField . Kind ( ) , tag : tag , typ : valueField . Type ( ) }
switch cField . kind {
case reflect . Slice , reflect . Array :
cField . isSliceOrArray = true
cField . sliceSubtype = cField . typ . Elem ( )
cField . isTimeSubtype = cField . sliceSubtype == reflect . TypeOf ( time . Time { } )
cField . sliceSubKind = cField . sliceSubtype . Kind ( )
case reflect . Map :
cField . isMap = true
cField . mapSubtype = cField . typ . Elem ( )
cField . isTimeSubtype = cField . mapSubtype == reflect . TypeOf ( time . Time { } )
cField . mapSubKind = cField . mapSubtype . Kind ( )
}
} else {
cField = cacheField
}
switch cField . kind {
case reflect . Struct , reflect . Interface , reflect . Invalid :
if cField . typ != reflect . TypeOf ( time . Time { } ) {
panic ( "Invalid field passed to ValidateFieldWithTag" )
}
}
if len ( cField . tags ) == 0 {
if isSingleField {
cField . tags , isCached = fieldsCache . Get ( tag )
}
if ! isCached {
for k , t := range strings . Split ( tag , tagSeparator ) {
if t == diveTag {
if k == 0 {
cField . diveTag = tag [ 4 : ]
} else {
cField . diveTag = strings . SplitN ( tag , diveSplit , 2 ) [ 1 ] [ 1 : ]
}
break
}
orVals := strings . Split ( t , orSeparator )
cTag := & cachedTags { isOrVal : len ( orVals ) > 1 , keyVals : make ( [ ] [ ] string , len ( orVals ) ) }
// if isInDive {
// s, ok := cField.DiveTags[cField.DiveMaxDepth]
// if ok {
// cField.DiveTags[cField.DiveMaxDepth] = cField.DiveTags[cField.DiveMaxDepth] + tagSeparator + tag
// } else {
// cField.DiveTags[cField.DiveMaxDepth] = tag
// }
// continue
// } else {
cField . tags = append ( cField . tags , cTag )
// }
for i , val := range orVals {
vals := strings . SplitN ( val , tagKeySeparator , 2 )
key := strings . TrimSpace ( vals [ 0 ] )
if len ( key ) == 0 {
panic ( fmt . Sprintf ( "Invalid validation tag on field %s" , name ) )
}
param := ""
if len ( vals ) > 1 {
param = strings . Replace ( vals [ 1 ] , utf8HexComma , "," , - 1 )
}
cTag . keyVals [ i ] = [ ] string { key , param }
}
}
if isSingleField {
fieldsCache . Set ( cField . tag , cField . tags )
}
}
}
var fieldErr * FieldError
var err error
for _ , cTag := range cField . tags {
if cTag . isOrVal {
errTag := ""
for _ , val := range cTag . keyVals {
fieldErr , err = v . fieldWithNameAndSingleTag ( val , current , f , val [ 0 ] , val [ 1 ] , name )
if err == nil {
return nil
}
errTag += orSeparator + fieldErr . Tag
}
errTag = strings . TrimLeft ( errTag , orSeparator )
fieldErr . Tag = errTag
fieldErr . Kind = cField . kind
fieldErr . Type = cField . typ
return fieldErr
}
if fieldErr , err = v . fieldWithNameAndSingleTag ( val , current , f , cTag . keyVals [ 0 ] [ 0 ] , cTag . keyVals [ 0 ] [ 1 ] , name ) ; err != nil {
fieldErr . Kind = cField . kind
fieldErr . Type = cField . typ
return fieldErr
}
}
if len ( cField . diveTag ) > 0 {
if cField . isSliceOrArray {
if errs := v . traverseSliceOrArray ( val , current , valueField , cField ) ; errs != nil && len ( errs ) > 0 {
return & FieldError {
Field : cField . name ,
Kind : cField . kind ,
Type : cField . typ ,
Value : f ,
isPlaceholderErr : true ,
IsSliceOrArray : true ,
// Index: i,
SliceOrArrayErrs : errs ,
}
}
// return if error here
} else if cField . isMap {
// return if error here
} else {
// throw error, if not a slice or map then should not have gotten here
}
// dive tags need to be passed to traverse
// traverse needs to call a SliceOrArray recursive function to meet depth requirements
// for depth, diveTag := range cField.DiveTags {
// // error returned should be added to SliceOrArrayErrs
// if errs := v.traverseSliceOrArrayField(val, current, depth, currentDepth+1, diveTag, cField, valueField); len(errs) > 0 {
// // result := &FieldError{
// // Field: cField.name,
// // Kind: cField.kind,
// // Type: cField.typ,
// // Value: valueField.Index(i).Interface(),
// // isPlaceholderErr: true,
// // IsSliceOrArray:true,
// // Index:i,
// // SliceOrArrayErrs:
// // }
// }
// for _, tag := range diveTag {
// fmt.Println("Depth:", depth, " Tag:", tag, " SliceType:", cField.SliceSubtype, " MapType:", cField.MapSubtype, " Kind:", cField.kind)
// }
// }
}
return nil
}
func ( v * Validate ) traverseSliceOrArray ( val interface { } , current interface { } , valueField reflect . Value , cField * cachedField ) [ ] error {
errs := make ( [ ] error , 0 )
for i := 0 ; i < valueField . Len ( ) ; i ++ {
idxField := valueField . Index ( i )
switch cField . sliceSubKind {
case reflect . Struct , reflect . Interface :
if cField . isTimeSubtype || idxField . Type ( ) == reflect . TypeOf ( time . Time { } ) {
if fieldError := v . fieldWithNameAndValue ( val , current , idxField . Interface ( ) , cField . diveTag , cField . name , true , nil ) ; fieldError != nil {
errs = append ( errs , fieldError )
}
continue
}
if idxField . Kind ( ) == reflect . Ptr && idxField . IsNil ( ) {
if strings . Contains ( cField . tag , omitempty ) {
continue
}
if strings . Contains ( cField . tag , required ) {
errs = append ( errs , & FieldError {
Field : cField . name ,
Tag : required ,
Value : idxField . Interface ( ) ,
Kind : reflect . Ptr ,
Type : cField . sliceSubtype ,
} )
continue
}
}
if structErrors := v . structRecursive ( val , current , idxField . Interface ( ) ) ; structErrors != nil {
errs = append ( errs , structErrors )
}
default :
if fieldError := v . fieldWithNameAndValue ( val , current , idxField . Interface ( ) , cField . diveTag , cField . name , true , nil ) ; fieldError != nil {
errs = append ( errs , fieldError )
}
}
}
return errs
}
// func (v *Validate) traverseSliceOrArrayField(val interface{}, current interface{}, depth uint64, currentDepth uint64, diveTags []*cachedTags, cField *cachedField, valueField reflect.Value) []error {
// for i := 0; i < valueField.Len(); i++ {
// if depth != currentDepth {
// switch cField.SliceSubKind {
// case reflect.Slice, reflect.Array:
// return v.fieldWithNameAndValue(val, current, valueField.Index(i).Interface(), cField.tag, cField.name, false, cField, currentDepth)
// // type FieldError struct {
// // Field string
// // Tag string
// // Kind reflect.Kind
// // Type reflect.Type
// // Param string
// // Value interface{}
// // HasErr bool
// // IsSliceOrArray bool
// // IsMap bool
// // Key interface{}
// // Index uint64
// // SliceOrArrayErrs []*error // counld be FieldError, StructErrors
// // MapErrs map[interface{}]*error // counld be FieldError, StructErrors
// // }
// // result := &FieldError{
// // Field: cField.name,
// // Kind: cField.kind,
// // Type: cField.typ,
// // Value: valueField.Index(i).Interface(),
// // isPlaceholderErr: true,
// // IsSliceOrArray:true,
// // Index:i,
// // SliceOrArrayErrs:
// // }
// // validationErrors.Errors[fieldError.Field] = fieldError
// // // free up memory reference
// // fieldError = nil
// // }
// default:
// panic("attempting to dive deeper, but Kind is not a Slice nor Array")
// }
// }
// // switch cField.SliceSubKind {
// // case reflect.Struct, reflect.Interface:
// // // need to check if required tag and or omitempty just like in struct recirsive
// // if cField.isTimeSubtype || valueField.Type() == reflect.TypeOf(time.Time{}) {
// // if fieldError := v.fieldWithNameAndValue(top, current, valueField.Index(i).Interface(), cField.tag, cField.name, false, cField); fieldError != nil {
// // validationErrors.Errors[fieldError.Field] = fieldError
// // // free up memory reference
// // fieldError = nil
// // }
// // }
// // }
// fmt.Println(valueField.Index(i))
// }
// // fmt.Println(v)
// // for _, item := range arr {
// // }
// return nil
// }
func ( v * Validate ) fieldWithNameAndSingleTag ( val interface { } , current interface { } , f interface { } , key string , param string , name string ) ( * FieldError , error ) {
// OK to continue because we checked it's existance before getting into this loop
if key == omitempty {
return nil , nil
}
valFunc , ok := v . validationFuncs [ key ]
if ! ok {
panic ( fmt . Sprintf ( "Undefined validation function on field %s" , name ) )
}
if err := valFunc ( val , current , f , param ) ; err {
return nil , nil
}
return & FieldError {
Field : name ,
Tag : key ,
Value : f ,
Param : param ,
} , errors . New ( key )
}