// Copyright 2015 go-swagger maintainers // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package validate import ( "fmt" "reflect" "strings" "unicode/utf8" "github.com/go-openapi/errors" "github.com/go-openapi/strfmt" "github.com/go-openapi/swag" ) // Enum validates if the data is a member of the enum func Enum(path, in string, data interface{}, enum interface{}) *errors.Validation { return EnumCase(path, in, data, enum, true) } // EnumCase validates if the data is a member of the enum and may respect case-sensitivity for strings func EnumCase(path, in string, data interface{}, enum interface{}, caseSensitive bool) *errors.Validation { val := reflect.ValueOf(enum) if val.Kind() != reflect.Slice { return nil } dataString := convertEnumCaseStringKind(data, caseSensitive) var values []interface{} for i := 0; i < val.Len(); i++ { ele := val.Index(i) enumValue := ele.Interface() if data != nil { if reflect.DeepEqual(data, enumValue) { return nil } enumString := convertEnumCaseStringKind(enumValue, caseSensitive) if dataString != nil && enumString != nil && strings.EqualFold(*dataString, *enumString) { return nil } actualType := reflect.TypeOf(enumValue) if actualType == nil { // Safeguard. Frankly, I don't know how we may get a nil continue } expectedValue := reflect.ValueOf(data) if expectedValue.IsValid() && expectedValue.Type().ConvertibleTo(actualType) { // Attempt comparison after type conversion if reflect.DeepEqual(expectedValue.Convert(actualType).Interface(), enumValue) { return nil } } } values = append(values, enumValue) } return errors.EnumFail(path, in, data, values) } // convertEnumCaseStringKind converts interface if it is kind of string and case insensitivity is set func convertEnumCaseStringKind(value interface{}, caseSensitive bool) *string { if caseSensitive { return nil } val := reflect.ValueOf(value) if val.Kind() != reflect.String { return nil } str := fmt.Sprintf("%v", value) return &str } // MinItems validates that there are at least n items in a slice func MinItems(path, in string, size, min int64) *errors.Validation { if size < min { return errors.TooFewItems(path, in, min, size) } return nil } // MaxItems validates that there are at most n items in a slice func MaxItems(path, in string, size, max int64) *errors.Validation { if size > max { return errors.TooManyItems(path, in, max, size) } return nil } // UniqueItems validates that the provided slice has unique elements func UniqueItems(path, in string, data interface{}) *errors.Validation { val := reflect.ValueOf(data) if val.Kind() != reflect.Slice { return nil } var unique []interface{} for i := 0; i < val.Len(); i++ { v := val.Index(i).Interface() for _, u := range unique { if reflect.DeepEqual(v, u) { return errors.DuplicateItems(path, in) } } unique = append(unique, v) } return nil } // MinLength validates a string for minimum length func MinLength(path, in, data string, minLength int64) *errors.Validation { strLen := int64(utf8.RuneCount([]byte(data))) if strLen < minLength { return errors.TooShort(path, in, minLength, data) } return nil } // MaxLength validates a string for maximum length func MaxLength(path, in, data string, maxLength int64) *errors.Validation { strLen := int64(utf8.RuneCount([]byte(data))) if strLen > maxLength { return errors.TooLong(path, in, maxLength, data) } return nil } // Required validates an interface for requiredness func Required(path, in string, data interface{}) *errors.Validation { val := reflect.ValueOf(data) if val.IsValid() { if reflect.DeepEqual(reflect.Zero(val.Type()).Interface(), val.Interface()) { return errors.Required(path, in, data) } return nil } return errors.Required(path, in, data) } // RequiredString validates a string for requiredness func RequiredString(path, in, data string) *errors.Validation { if data == "" { return errors.Required(path, in, data) } return nil } // RequiredNumber validates a number for requiredness func RequiredNumber(path, in string, data float64) *errors.Validation { if data == 0 { return errors.Required(path, in, data) } return nil } // Pattern validates a string against a regular expression func Pattern(path, in, data, pattern string) *errors.Validation { re, err := compileRegexp(pattern) if err != nil { return errors.FailedPattern(path, in, fmt.Sprintf("%s, but pattern is invalid: %s", pattern, err.Error()), data) } if !re.MatchString(data) { return errors.FailedPattern(path, in, pattern, data) } return nil } // MaximumInt validates if a number is smaller than a given maximum func MaximumInt(path, in string, data, max int64, exclusive bool) *errors.Validation { if (!exclusive && data > max) || (exclusive && data >= max) { return errors.ExceedsMaximumInt(path, in, max, exclusive, data) } return nil } // MaximumUint validates if a number is smaller than a given maximum func MaximumUint(path, in string, data, max uint64, exclusive bool) *errors.Validation { if (!exclusive && data > max) || (exclusive && data >= max) { return errors.ExceedsMaximumUint(path, in, max, exclusive, data) } return nil } // Maximum validates if a number is smaller than a given maximum func Maximum(path, in string, data, max float64, exclusive bool) *errors.Validation { if (!exclusive && data > max) || (exclusive && data >= max) { return errors.ExceedsMaximum(path, in, max, exclusive, data) } return nil } // Minimum validates if a number is smaller than a given minimum func Minimum(path, in string, data, min float64, exclusive bool) *errors.Validation { if (!exclusive && data < min) || (exclusive && data <= min) { return errors.ExceedsMinimum(path, in, min, exclusive, data) } return nil } // MinimumInt validates if a number is smaller than a given minimum func MinimumInt(path, in string, data, min int64, exclusive bool) *errors.Validation { if (!exclusive && data < min) || (exclusive && data <= min) { return errors.ExceedsMinimumInt(path, in, min, exclusive, data) } return nil } // MinimumUint validates if a number is smaller than a given minimum func MinimumUint(path, in string, data, min uint64, exclusive bool) *errors.Validation { if (!exclusive && data < min) || (exclusive && data <= min) { return errors.ExceedsMinimumUint(path, in, min, exclusive, data) } return nil } // MultipleOf validates if the provided number is a multiple of the factor func MultipleOf(path, in string, data, factor float64) *errors.Validation { // multipleOf factor must be positive if factor < 0 { return errors.MultipleOfMustBePositive(path, in, factor) } var mult float64 if factor < 1 { mult = 1 / factor * data } else { mult = data / factor } if !swag.IsFloat64AJSONInteger(mult) { return errors.NotMultipleOf(path, in, factor, data) } return nil } // MultipleOfInt validates if the provided integer is a multiple of the factor func MultipleOfInt(path, in string, data int64, factor int64) *errors.Validation { // multipleOf factor must be positive if factor < 0 { return errors.MultipleOfMustBePositive(path, in, factor) } mult := data / factor if mult*factor != data { return errors.NotMultipleOf(path, in, factor, data) } return nil } // MultipleOfUint validates if the provided unsigned integer is a multiple of the factor func MultipleOfUint(path, in string, data, factor uint64) *errors.Validation { mult := data / factor if mult*factor != data { return errors.NotMultipleOf(path, in, factor, data) } return nil } // FormatOf validates if a string matches a format in the format registry func FormatOf(path, in, format, data string, registry strfmt.Registry) *errors.Validation { if registry == nil { registry = strfmt.Default } if ok := registry.ContainsName(format); !ok { return errors.InvalidTypeName(format) } if ok := registry.Validates(format, data); !ok { return errors.InvalidType(path, in, format, data) } return nil } // MaximumNativeType provides native type constraint validation as a facade // to various numeric types versions of Maximum constraint check. // // Assumes that any possible loss conversion during conversion has been // checked beforehand. // // NOTE: currently, the max value is marshalled as a float64, no matter what, // which means there may be a loss during conversions (e.g. for very large integers) // // TODO: Normally, a JSON MAX_SAFE_INTEGER check would ensure conversion remains loss-free func MaximumNativeType(path, in string, val interface{}, max float64, exclusive bool) *errors.Validation { kind := reflect.ValueOf(val).Type().Kind() switch kind { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: value := valueHelp.asInt64(val) return MaximumInt(path, in, value, int64(max), exclusive) case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: value := valueHelp.asUint64(val) if max < 0 { return errors.ExceedsMaximum(path, in, max, exclusive, val) } return MaximumUint(path, in, value, uint64(max), exclusive) case reflect.Float32, reflect.Float64: fallthrough default: value := valueHelp.asFloat64(val) return Maximum(path, in, value, max, exclusive) } } // MinimumNativeType provides native type constraint validation as a facade // to various numeric types versions of Minimum constraint check. // // Assumes that any possible loss conversion during conversion has been // checked beforehand. // // NOTE: currently, the min value is marshalled as a float64, no matter what, // which means there may be a loss during conversions (e.g. for very large integers) // // TODO: Normally, a JSON MAX_SAFE_INTEGER check would ensure conversion remains loss-free func MinimumNativeType(path, in string, val interface{}, min float64, exclusive bool) *errors.Validation { kind := reflect.ValueOf(val).Type().Kind() switch kind { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: value := valueHelp.asInt64(val) return MinimumInt(path, in, value, int64(min), exclusive) case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: value := valueHelp.asUint64(val) if min < 0 { return nil } return MinimumUint(path, in, value, uint64(min), exclusive) case reflect.Float32, reflect.Float64: fallthrough default: value := valueHelp.asFloat64(val) return Minimum(path, in, value, min, exclusive) } } // MultipleOfNativeType provides native type constraint validation as a facade // to various numeric types version of MultipleOf constraint check. // // Assumes that any possible loss conversion during conversion has been // checked beforehand. // // NOTE: currently, the multipleOf factor is marshalled as a float64, no matter what, // which means there may be a loss during conversions (e.g. for very large integers) // // TODO: Normally, a JSON MAX_SAFE_INTEGER check would ensure conversion remains loss-free func MultipleOfNativeType(path, in string, val interface{}, multipleOf float64) *errors.Validation { kind := reflect.ValueOf(val).Type().Kind() switch kind { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: value := valueHelp.asInt64(val) return MultipleOfInt(path, in, value, int64(multipleOf)) case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: value := valueHelp.asUint64(val) return MultipleOfUint(path, in, value, uint64(multipleOf)) case reflect.Float32, reflect.Float64: fallthrough default: value := valueHelp.asFloat64(val) return MultipleOf(path, in, value, multipleOf) } } // IsValueValidAgainstRange checks that a numeric value is compatible with // the range defined by Type and Format, that is, may be converted without loss. // // NOTE: this check is about type capacity and not formal verification such as: 1.0 != 1L func IsValueValidAgainstRange(val interface{}, typeName, format, prefix, path string) error { kind := reflect.ValueOf(val).Type().Kind() // What is the string representation of val stringRep := "" switch kind { case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: stringRep = swag.FormatUint64(valueHelp.asUint64(val)) case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: stringRep = swag.FormatInt64(valueHelp.asInt64(val)) case reflect.Float32, reflect.Float64: stringRep = swag.FormatFloat64(valueHelp.asFloat64(val)) default: return fmt.Errorf("%s value number range checking called with invalid (non numeric) val type in %s", prefix, path) } var errVal error switch typeName { case integerType: switch format { case integerFormatInt32: _, errVal = swag.ConvertInt32(stringRep) case integerFormatUInt32: _, errVal = swag.ConvertUint32(stringRep) case integerFormatUInt64: _, errVal = swag.ConvertUint64(stringRep) case integerFormatInt64: fallthrough default: _, errVal = swag.ConvertInt64(stringRep) } case numberType: fallthrough default: switch format { case numberFormatFloat, numberFormatFloat32: _, errVal = swag.ConvertFloat32(stringRep) case numberFormatDouble, numberFormatFloat64: fallthrough default: // No check can be performed here since // no number beyond float64 is supported } } if errVal != nil { // We don't report the actual errVal from strconv if format != "" { errVal = fmt.Errorf("%s value must be of type %s with format %s in %s", prefix, typeName, format, path) } else { errVal = fmt.Errorf("%s value must be of type %s (default format) in %s", prefix, typeName, path) } } return errVal }