constellation/internal/validation/constraints.go
Otto Bittner b1b8571877 validation: use regex instead of dns lookup
Doing a DNS lookup may fail for domain names that are valid
but currently not assigned.
The old test also breaks inside the bazel sandbox.
2023-11-08 14:43:05 +01:00

318 lines
8.6 KiB
Go

/*
Copyright (c) Edgeless Systems GmbH
SPDX-License-Identifier: AGPL-3.0-only
*/
package validation
import (
"fmt"
"net"
"reflect"
"regexp"
)
// Used to validate DNS names.
var domainRegex = regexp.MustCompile(`^(?i)[a-z0-9-]+(\.[a-z0-9-]+)+\.?$`)
// Constraint is a constraint on a document or a field of a document.
type Constraint struct {
// Satisfied returns no error if the constraint is satisfied.
// Otherwise, it returns the reason why the constraint is not satisfied,
// possibly including its child errors, i.e., errors returned by constraints
// that are embedded in this constraint.
Satisfied func() *TreeError
}
/*
WithFieldTrace adds a well-formatted trace to the field to the error message
shown when the constraint is not satisfied. Both "doc" and "field" must be pointers:
- "doc" must be a pointer to the top level document
- "field" must be a pointer to the field to be validated
Example for a non-pointer field:
Equal(d.IntField, 42).WithFieldTrace(d, &d.IntField)
Example for a pointer field:
NotEmpty(d.StrPtrField).WithFieldTrace(d, d.StrPtrField)
Due to Go's addressability limititations regarding maps, if a map field is
to be validated, WithMapFieldTrace must be used instead of WithFieldTrace.
*/
func (c *Constraint) WithFieldTrace(doc any, field any) *Constraint {
// we only want to dereference the needle once to dereference the pointer
// used to pass it to the function without losing reference to it, as the
// needle could be an arbitrarily long chain of pointers. The same
// applies to the haystack.
derefedField := pointerDeref(reflect.ValueOf(field))
fieldRef := referenceableValue{
value: derefedField,
addr: derefedField.UnsafeAddr(),
_type: derefedField.Type(),
}
derefedDoc := pointerDeref(reflect.ValueOf(doc))
docRef := referenceableValue{
value: derefedDoc,
addr: derefedDoc.UnsafeAddr(),
_type: derefedDoc.Type(),
}
return c.withTrace(docRef, fieldRef)
}
/*
WithMapFieldTrace adds a well-formatted trace to the map field to the error message
shown when the constraint is not satisfied. Both "doc" and "field" must be pointers:
- "doc" must be a pointer to the top level document
- "field" must be a pointer to the map containing the field to be validated
- "mapKey" must be the key of the field to be validated in the map pointed to by "field"
Example:
Equal(d.IntField, 42).WithMapFieldTrace(d, &d.MapField, mapKey)
For non-map fields, WithFieldTrace should be used instead of WithMapFieldTrace.
*/
func (c *Constraint) WithMapFieldTrace(doc any, field any, mapKey string) *Constraint {
// we only want to dereference the needle once to dereference the pointer
// used to pass it to the function without losing reference to it, as the
// needle could be an arbitrarily long chain of pointers. The same
// applies to the haystack.
derefedField := pointerDeref(reflect.ValueOf(field))
fieldRef := referenceableValue{
value: derefedField,
addr: derefedField.UnsafeAddr(),
_type: derefedField.Type(),
mapKey: mapKey,
}
derefedDoc := pointerDeref(reflect.ValueOf(doc))
docRef := referenceableValue{
value: derefedDoc,
addr: derefedDoc.UnsafeAddr(),
_type: derefedDoc.Type(),
}
return c.withTrace(docRef, fieldRef)
}
// withTrace wraps the constraint's error message with a well-formatted trace.
func (c *Constraint) withTrace(docRef, fieldRef referenceableValue) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if err := c.Satisfied(); err != nil {
return newTraceError(docRef, fieldRef, err)
}
return nil
},
}
}
// MatchRegex is a constraint that if s matches regex.
func MatchRegex(s string, regex string) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if !regexp.MustCompile(regex).MatchString(s) {
return NewErrorTree(fmt.Errorf("%s must match the pattern %s", s, regex))
}
return nil
},
}
}
// Equal is a constraint that checks if s is equal to t.
func Equal[T comparable](s T, t T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if s != t {
return NewErrorTree(fmt.Errorf("%v must be equal to %v", s, t))
}
return nil
},
}
}
// NotEqual is a constraint that checks if s is not equal to t.
func NotEqual[T comparable](s T, t T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if Equal(s, t).Satisfied() == nil {
return NewErrorTree(fmt.Errorf("%v must not be equal to %v", s, t))
}
return nil
},
}
}
// Empty is a constraint that checks if s is empty.
func Empty[T comparable](s T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
var zero T
if s != zero {
return NewErrorTree(fmt.Errorf("%v must be empty", s))
}
return nil
},
}
}
// NotEmpty is a constraint that checks if s is not empty.
func NotEmpty[T comparable](s T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if Empty(s).Satisfied() == nil {
return NewErrorTree(fmt.Errorf("must not be empty"))
}
return nil
},
}
}
// OneOf is a constraint that s is in the set of values p.
func OneOf[T comparable](s T, p []T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
for _, v := range p {
if s == v {
return nil
}
}
return NewErrorTree(fmt.Errorf("%v must be one of %v", s, p))
},
}
}
// IPAddress is a constraint that checks if s is a valid IP address.
func IPAddress(s string) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if net.ParseIP(s) == nil {
return NewErrorTree(fmt.Errorf("%s must be a valid IP address", s))
}
return nil
},
}
}
// CIDR is a constraint that checks if s is a valid CIDR.
func CIDR(s string) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if _, _, err := net.ParseCIDR(s); err != nil {
return NewErrorTree(fmt.Errorf("%s must be a valid CIDR", s))
}
return nil
},
}
}
// DNSName is a constraint that checks if s is a valid DNS name.
func DNSName(s string) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if !domainRegex.MatchString(s) {
return NewErrorTree(fmt.Errorf("%s must be a valid DNS name", s))
}
return nil
},
}
}
// EmptySlice is a constraint that checks if s is an empty slice.
func EmptySlice[T comparable](s []T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if len(s) != 0 {
return NewErrorTree(fmt.Errorf("%v must be empty", s))
}
return nil
},
}
}
// NotEmptySlice is a constraint that checks if slice s is not empty.
func NotEmptySlice[T comparable](s []T) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if EmptySlice(s).Satisfied() == nil {
return NewErrorTree(fmt.Errorf("must not be empty"))
}
return nil
},
}
}
// All is a constraint that checks if all elements of s satisfy the constraint c.
// The constraint should be parametric in regards to the index of the element in s,
// as well as the element itself.
func All[T comparable](s []T, c func(i int, v T) *Constraint) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
retErr := NewErrorTree(fmt.Errorf("all of the constraints must be satisfied: "))
for i, v := range s {
if err := c(i, v).Satisfied(); err != nil {
retErr.appendChild(err)
}
}
if len(retErr.children) == 0 {
return nil
}
return retErr
},
}
}
// And groups multiple constraints in an "and" relation and fails according to the given strategy.
func And(errStrat ErrStrategy, constraints ...*Constraint) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
retErr := NewErrorTree(fmt.Errorf("all of the constraints must be satisfied: "))
for _, constraint := range constraints {
if err := constraint.Satisfied(); err != nil {
if errStrat == FailFast {
return err
}
retErr.appendChild(err)
}
}
if len(retErr.children) == 0 {
return nil
}
return retErr
},
}
}
// Or groups multiple constraints in an "or" relation.
func Or(constraints ...*Constraint) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
retErr := NewErrorTree(fmt.Errorf("at least one of the constraints must be satisfied: "))
for _, constraint := range constraints {
err := constraint.Satisfied()
if err == nil {
return nil
}
retErr.appendChild(err)
}
if len(retErr.children) == 0 {
return nil
}
return retErr
},
}
}
// IfNotNil evaluates a constraint if and only if s is not nil.
func IfNotNil[T comparable](s *T, c func() *Constraint) *Constraint {
return &Constraint{
Satisfied: func() *TreeError {
if s == nil {
return nil
}
return c().Satisfied()
},
}
}