terraform/helper/schema/schema.go

1074 lines
25 KiB
Go

// schema is a high-level framework for easily writing new providers
// for Terraform. Usage of schema is recommended over attempting to write
// to the low-level plugin interfaces manually.
//
// schema breaks down provider creation into simple CRUD operations for
// resources. The logic of diffing, destroying before creating, updating
// or creating, etc. is all handled by the framework. The plugin author
// only needs to implement a configuration schema and the CRUD operations and
// everything else is meant to just work.
//
// A good starting point is to view the Provider structure.
package schema
//go:generate stringer -type=ValueType
import (
"fmt"
"reflect"
"sort"
"strconv"
"strings"
"github.com/hashicorp/terraform/terraform"
"github.com/mitchellh/mapstructure"
)
// ValueType is an enum of the type that can be represented by a schema.
type ValueType int
const (
TypeInvalid ValueType = iota
TypeBool
TypeInt
TypeFloat
TypeString
TypeList
TypeMap
TypeSet
typeObject
)
// Zero returns the zero value for a type.
func (t ValueType) Zero() interface{} {
switch t {
case TypeInvalid:
return nil
case TypeBool:
return false
case TypeInt:
return 0
case TypeFloat:
return 0.0
case TypeString:
return ""
case TypeList:
return []interface{}{}
case TypeMap:
return map[string]interface{}{}
case TypeSet:
return nil
case typeObject:
return map[string]interface{}{}
default:
panic(fmt.Sprintf("unknown type %s", t))
}
}
// Schema is used to describe the structure of a value.
//
// Read the documentation of the struct elements for important details.
type Schema struct {
// Type is the type of the value and must be one of the ValueType values.
//
// This type not only determines what type is expected/valid in configuring
// this value, but also what type is returned when ResourceData.Get is
// called. The types returned by Get are:
//
// TypeBool - bool
// TypeInt - int
// TypeString - string
// TypeList - []interface{}
// TypeMap - map[string]interface{}
// TypeSet - *schema.Set
//
Type ValueType
// If one of these is set, then this item can come from the configuration.
// Both cannot be set. If Optional is set, the value is optional. If
// Required is set, the value is required.
//
// One of these must be set if the value is not computed. That is:
// value either comes from the config, is computed, or is both.
Optional bool
Required bool
// If this is non-nil, then this will be a default value that is used
// when this item is not set in the configuration/state.
//
// DefaultFunc can be specified if you want a dynamic default value.
// Only one of Default or DefaultFunc can be set.
//
// If Required is true above, then Default cannot be set. DefaultFunc
// can be set with Required. If the DefaultFunc returns nil, then there
// will no default and the user will be asked to fill it in.
//
// If either of these is set, then the user won't be asked for input
// for this key if the default is not nil.
Default interface{}
DefaultFunc SchemaDefaultFunc
// Description is used as the description for docs or asking for user
// input. It should be relatively short (a few sentences max) and should
// be formatted to fit a CLI.
Description string
// InputDefault is the default value to use for when inputs are requested.
// This differs from Default in that if Default is set, no input is
// asked for. If Input is asked, this will be the default value offered.
InputDefault string
// The fields below relate to diffs.
//
// If Computed is true, then the result of this value is computed
// (unless specified by config) on creation.
//
// If ForceNew is true, then a change in this resource necessitates
// the creation of a new resource.
//
// StateFunc is a function called to change the value of this before
// storing it in the state (and likewise before comparing for diffs).
// The use for this is for example with large strings, you may want
// to simply store the hash of it.
Computed bool
ForceNew bool
StateFunc SchemaStateFunc
// The following fields are only set for a TypeList or TypeSet Type.
//
// Elem must be either a *Schema or a *Resource only if the Type is
// TypeList, and represents what the element type is. If it is *Schema,
// the element type is just a simple value. If it is *Resource, the
// element type is a complex structure, potentially with its own lifecycle.
Elem interface{}
// The follow fields are only valid for a TypeSet type.
//
// Set defines a function to determine the unique ID of an item so that
// a proper set can be built.
Set SchemaSetFunc
// ComputedWhen is a set of queries on the configuration. Whenever any
// of these things is changed, it will require a recompute (this requires
// that Computed is set to true).
//
// NOTE: This currently does not work.
ComputedWhen []string
}
// SchemaDefaultFunc is a function called to return a default value for
// a field.
type SchemaDefaultFunc func() (interface{}, error)
// SchemaSetFunc is a function that must return a unique ID for the given
// element. This unique ID is used to store the element in a hash.
type SchemaSetFunc func(interface{}) int
// SchemaStateFunc is a function used to convert some type to a string
// to be stored in the state.
type SchemaStateFunc func(interface{}) string
func (s *Schema) GoString() string {
return fmt.Sprintf("*%#v", *s)
}
func (s *Schema) finalizeDiff(
d *terraform.ResourceAttrDiff) *terraform.ResourceAttrDiff {
if d == nil {
return d
}
if d.NewRemoved {
return d
}
if s.Computed {
if d.Old != "" && d.New == "" {
// This is a computed value with an old value set already,
// just let it go.
return nil
}
if d.New == "" {
// Computed attribute without a new value set
d.NewComputed = true
}
}
if s.ForceNew {
// Force new, set it to true in the diff
d.RequiresNew = true
}
return d
}
// schemaMap is a wrapper that adds nice functions on top of schemas.
type schemaMap map[string]*Schema
// Data returns a ResourceData for the given schema, state, and diff.
//
// The diff is optional.
func (m schemaMap) Data(
s *terraform.InstanceState,
d *terraform.InstanceDiff) (*ResourceData, error) {
return &ResourceData{
schema: m,
state: s,
diff: d,
}, nil
}
// Diff returns the diff for a resource given the schema map,
// state, and configuration.
func (m schemaMap) Diff(
s *terraform.InstanceState,
c *terraform.ResourceConfig) (*terraform.InstanceDiff, error) {
result := new(terraform.InstanceDiff)
result.Attributes = make(map[string]*terraform.ResourceAttrDiff)
d := &ResourceData{
schema: m,
state: s,
config: c,
}
for k, schema := range m {
err := m.diff(k, schema, result, d, false)
if err != nil {
return nil, err
}
}
// If the diff requires a new resource, then we recompute the diff
// so we have the complete new resource diff, and preserve the
// RequiresNew fields where necessary so the user knows exactly what
// caused that.
if result.RequiresNew() {
// Create the new diff
result2 := new(terraform.InstanceDiff)
result2.Attributes = make(map[string]*terraform.ResourceAttrDiff)
// Reset the data to not contain state. We have to call init()
// again in order to reset the FieldReaders.
d.state = nil
d.init()
// Perform the diff again
for k, schema := range m {
err := m.diff(k, schema, result2, d, false)
if err != nil {
return nil, err
}
}
// Force all the fields to not force a new since we know what we
// want to force new.
for k, attr := range result2.Attributes {
if attr == nil {
continue
}
if attr.RequiresNew {
attr.RequiresNew = false
}
if s != nil {
attr.Old = s.Attributes[k]
}
}
// Now copy in all the requires new diffs...
for k, attr := range result.Attributes {
if attr == nil {
continue
}
newAttr, ok := result2.Attributes[k]
if !ok {
newAttr = attr
}
if attr.RequiresNew {
newAttr.RequiresNew = true
}
result2.Attributes[k] = newAttr
}
// And set the diff!
result = result2
}
// Remove any nil diffs just to keep things clean
for k, v := range result.Attributes {
if v == nil {
delete(result.Attributes, k)
}
}
// Go through and detect all of the ComputedWhens now that we've
// finished the diff.
// TODO
if result.Empty() {
// If we don't have any diff elements, just return nil
return nil, nil
}
return result, nil
}
// Input implements the terraform.ResourceProvider method by asking
// for input for required configuration keys that don't have a value.
func (m schemaMap) Input(
input terraform.UIInput,
c *terraform.ResourceConfig) (*terraform.ResourceConfig, error) {
keys := make([]string, 0, len(m))
for k, _ := range m {
keys = append(keys, k)
}
sort.Strings(keys)
for _, k := range keys {
v := m[k]
// Skip things that don't require config, if that is even valid
// for a provider schema.
if !v.Required && !v.Optional {
continue
}
// Skip things that have a value of some sort already
if _, ok := c.Raw[k]; ok {
continue
}
// Skip if it has a default
if v.Default != nil {
continue
}
if f := v.DefaultFunc; f != nil {
value, err := f()
if err != nil {
return nil, fmt.Errorf(
"%s: error loading default: %s", k, err)
}
if value != nil {
continue
}
}
var value interface{}
var err error
switch v.Type {
case TypeBool:
fallthrough
case TypeInt:
fallthrough
case TypeString:
value, err = m.inputString(input, k, v)
default:
panic(fmt.Sprintf("Unknown type for input: %#v", v.Type))
}
if err != nil {
return nil, fmt.Errorf(
"%s: %s", k, err)
}
c.Config[k] = value
}
return c, nil
}
// Validate validates the configuration against this schema mapping.
func (m schemaMap) Validate(c *terraform.ResourceConfig) ([]string, []error) {
return m.validateObject("", m, c)
}
// InternalValidate validates the format of this schema. This should be called
// from a unit test (and not in user-path code) to verify that a schema
// is properly built.
func (m schemaMap) InternalValidate() error {
for k, v := range m {
if v.Type == TypeInvalid {
return fmt.Errorf("%s: Type must be specified", k)
}
if v.Optional && v.Required {
return fmt.Errorf("%s: Optional or Required must be set, not both", k)
}
if v.Required && v.Computed {
return fmt.Errorf("%s: Cannot be both Required and Computed", k)
}
if !v.Required && !v.Optional && !v.Computed {
return fmt.Errorf("%s: One of optional, required, or computed must be set", k)
}
if v.Computed && v.Default != nil {
return fmt.Errorf("%s: Default must be nil if computed", k)
}
if v.Required && v.Default != nil {
return fmt.Errorf("%s: Default cannot be set with Required", k)
}
if len(v.ComputedWhen) > 0 && !v.Computed {
return fmt.Errorf("%s: ComputedWhen can only be set with Computed", k)
}
if v.Type == TypeList || v.Type == TypeSet {
if v.Elem == nil {
return fmt.Errorf("%s: Elem must be set for lists", k)
}
if v.Default != nil {
return fmt.Errorf("%s: Default is not valid for lists or sets", k)
}
if v.Type == TypeList && v.Set != nil {
return fmt.Errorf("%s: Set can only be set for TypeSet", k)
} else if v.Type == TypeSet && v.Set == nil {
return fmt.Errorf("%s: Set must be set", k)
}
switch t := v.Elem.(type) {
case *Resource:
if err := t.InternalValidate(); err != nil {
return err
}
case *Schema:
bad := t.Computed || t.Optional || t.Required
if bad {
return fmt.Errorf(
"%s: Elem must have only Type set", k)
}
}
}
}
return nil
}
func (m schemaMap) diff(
k string,
schema *Schema,
diff *terraform.InstanceDiff,
d *ResourceData,
all bool) error {
var err error
switch schema.Type {
case TypeBool:
fallthrough
case TypeInt:
fallthrough
case TypeString:
err = m.diffString(k, schema, diff, d, all)
case TypeList:
err = m.diffList(k, schema, diff, d, all)
case TypeMap:
err = m.diffMap(k, schema, diff, d, all)
case TypeSet:
err = m.diffSet(k, schema, diff, d, all)
default:
err = fmt.Errorf("%s: unknown type %#v", k, schema.Type)
}
return err
}
func (m schemaMap) diffList(
k string,
schema *Schema,
diff *terraform.InstanceDiff,
d *ResourceData,
all bool) error {
o, n, _, computedList := d.diffChange(k)
if computedList {
n = nil
}
nSet := n != nil
// If we have an old value and no new value is set or will be
// computed once all variables can be interpolated and we're
// computed, then nothing has changed.
if o != nil && n == nil && !computedList && schema.Computed {
return nil
}
if o == nil {
o = []interface{}{}
}
if n == nil {
n = []interface{}{}
}
if s, ok := o.(*Set); ok {
o = s.List()
}
if s, ok := n.(*Set); ok {
n = s.List()
}
os := o.([]interface{})
vs := n.([]interface{})
// If the new value was set, and the two are equal, then we're done.
// We have to do this check here because sets might be NOT
// reflect.DeepEqual so we need to wait until we get the []interface{}
if !all && nSet && reflect.DeepEqual(os, vs) {
return nil
}
// Get the counts
oldLen := len(os)
newLen := len(vs)
oldStr := strconv.FormatInt(int64(oldLen), 10)
// If the whole list is computed, then say that the # is computed
if computedList {
diff.Attributes[k+".#"] = &terraform.ResourceAttrDiff{
Old: oldStr,
NewComputed: true,
}
return nil
}
// If the counts are not the same, then record that diff
changed := oldLen != newLen
computed := oldLen == 0 && newLen == 0 && schema.Computed
if changed || computed || all {
countSchema := &Schema{
Type: TypeInt,
Computed: schema.Computed,
ForceNew: schema.ForceNew,
}
newStr := ""
if !computed {
newStr = strconv.FormatInt(int64(newLen), 10)
} else {
oldStr = ""
}
diff.Attributes[k+".#"] = countSchema.finalizeDiff(&terraform.ResourceAttrDiff{
Old: oldStr,
New: newStr,
})
}
// Figure out the maximum
maxLen := oldLen
if newLen > maxLen {
maxLen = newLen
}
switch t := schema.Elem.(type) {
case *Resource:
// This is a complex resource
for i := 0; i < maxLen; i++ {
for k2, schema := range t.Schema {
subK := fmt.Sprintf("%s.%d.%s", k, i, k2)
err := m.diff(subK, schema, diff, d, all)
if err != nil {
return err
}
}
}
case *Schema:
// Copy the schema so that we can set Computed/ForceNew from
// the parent schema (the TypeList).
t2 := *t
t2.ForceNew = schema.ForceNew
// This is just a primitive element, so go through each and
// just diff each.
for i := 0; i < maxLen; i++ {
subK := fmt.Sprintf("%s.%d", k, i)
err := m.diff(subK, &t2, diff, d, all)
if err != nil {
return err
}
}
default:
return fmt.Errorf("%s: unknown element type (internal)", k)
}
return nil
}
func (m schemaMap) diffMap(
k string,
schema *Schema,
diff *terraform.InstanceDiff,
d *ResourceData,
all bool) error {
prefix := k + "."
// First get all the values from the state
var stateMap, configMap map[string]string
o, n, _, _ := d.diffChange(k)
if err := mapstructure.WeakDecode(o, &stateMap); err != nil {
return fmt.Errorf("%s: %s", k, err)
}
if err := mapstructure.WeakDecode(n, &configMap); err != nil {
return fmt.Errorf("%s: %s", k, err)
}
// Delete any count values, since we don't use those
delete(configMap, "#")
delete(stateMap, "#")
// Check if the number of elements has changed. If we're computing
// a list and there isn't a config, then it hasn't changed.
oldLen, newLen := len(stateMap), len(configMap)
changed := oldLen != newLen
if oldLen != 0 && newLen == 0 && schema.Computed {
changed = false
}
computed := oldLen == 0 && newLen == 0 && schema.Computed
if changed || computed {
countSchema := &Schema{
Type: TypeInt,
Computed: schema.Computed,
ForceNew: schema.ForceNew,
}
oldStr := strconv.FormatInt(int64(oldLen), 10)
newStr := ""
if !computed {
newStr = strconv.FormatInt(int64(newLen), 10)
} else {
oldStr = ""
}
diff.Attributes[k+".#"] = countSchema.finalizeDiff(
&terraform.ResourceAttrDiff{
Old: oldStr,
New: newStr,
},
)
}
// If the new map is nil and we're computed, then ignore it.
if n == nil && schema.Computed {
return nil
}
// Now we compare, preferring values from the config map
for k, v := range configMap {
old := stateMap[k]
delete(stateMap, k)
if old == v && !all {
continue
}
diff.Attributes[prefix+k] = schema.finalizeDiff(&terraform.ResourceAttrDiff{
Old: old,
New: v,
})
}
for k, v := range stateMap {
diff.Attributes[prefix+k] = schema.finalizeDiff(&terraform.ResourceAttrDiff{
Old: v,
NewRemoved: true,
})
}
return nil
}
func (m schemaMap) diffSet(
k string,
schema *Schema,
diff *terraform.InstanceDiff,
d *ResourceData,
all bool) error {
o, n, _, computedSet := d.diffChange(k)
if computedSet {
n = nil
}
nSet := n != nil
// If we have an old value and no new value is set or will be
// computed once all variables can be interpolated and we're
// computed, then nothing has changed.
if o != nil && n == nil && !computedSet && schema.Computed {
return nil
}
if o == nil {
o = &Set{F: schema.Set}
}
if n == nil {
n = &Set{F: schema.Set}
}
os := o.(*Set)
ns := n.(*Set)
// If the new value was set, compare the listCode's to determine if
// the two are equal. Comparing listCode's instead of the actuall values
// is needed because there could be computed values in the set which
// would result in false positives while comparing.
if !all && nSet && reflect.DeepEqual(os.listCode(), ns.listCode()) {
return nil
}
// Get the counts
oldLen := os.Len()
newLen := ns.Len()
oldStr := strconv.Itoa(oldLen)
newStr := strconv.Itoa(newLen)
// If the set computed then say that the # is computed
if computedSet || (schema.Computed && !nSet) {
// If # already exists, equals 0 and no new set is supplied, there
// is nothing to record in the diff
count, ok := d.GetOk(k + ".#")
if ok && count.(int) == 0 && !nSet && !computedSet {
return nil
}
// Set the count but make sure that if # does not exist, we don't
// use the zeroed value
countStr := strconv.Itoa(count.(int))
if !ok {
countStr = ""
}
diff.Attributes[k+".#"] = &terraform.ResourceAttrDiff{
Old: countStr,
NewComputed: true,
}
return nil
}
// If the counts are not the same, then record that diff
changed := oldLen != newLen
if changed || all {
countSchema := &Schema{
Type: TypeInt,
Computed: schema.Computed,
ForceNew: schema.ForceNew,
}
diff.Attributes[k+".#"] = countSchema.finalizeDiff(&terraform.ResourceAttrDiff{
Old: oldStr,
New: newStr,
})
}
for _, code := range ns.listCode() {
switch t := schema.Elem.(type) {
case *Resource:
// This is a complex resource
for k2, schema := range t.Schema {
subK := fmt.Sprintf("%s.%d.%s", k, code, k2)
subK = strings.Replace(subK, "-", "~", -1)
err := m.diff(subK, schema, diff, d, true)
if err != nil {
return err
}
}
case *Schema:
// Copy the schema so that we can set Computed/ForceNew from
// the parent schema (the TypeSet).
t2 := *t
t2.ForceNew = schema.ForceNew
// This is just a primitive element, so go through each and
// just diff each.
subK := fmt.Sprintf("%s.%d", k, code)
subK = strings.Replace(subK, "-", "~", -1)
err := m.diff(subK, &t2, diff, d, true)
if err != nil {
return err
}
default:
return fmt.Errorf("%s: unknown element type (internal)", k)
}
}
return nil
}
func (m schemaMap) diffString(
k string,
schema *Schema,
diff *terraform.InstanceDiff,
d *ResourceData,
all bool) error {
var originalN interface{}
var os, ns string
o, n, _, _ := d.diffChange(k)
if n == nil {
n = schema.Default
if schema.DefaultFunc != nil {
var err error
n, err = schema.DefaultFunc()
if err != nil {
return fmt.Errorf("%s, error loading default: %s", k, err)
}
}
}
if schema.StateFunc != nil {
originalN = n
n = schema.StateFunc(n)
}
if err := mapstructure.WeakDecode(o, &os); err != nil {
return fmt.Errorf("%s: %s", k, err)
}
if err := mapstructure.WeakDecode(n, &ns); err != nil {
return fmt.Errorf("%s: %s", k, err)
}
if os == ns && !all {
// They're the same value. If there old value is not blank or we
// have an ID, then return right away since we're already setup.
if os != "" || d.Id() != "" {
return nil
}
// Otherwise, only continue if we're computed
if !schema.Computed {
return nil
}
}
removed := false
if o != nil && n == nil {
removed = true
}
if removed && schema.Computed {
return nil
}
diff.Attributes[k] = schema.finalizeDiff(&terraform.ResourceAttrDiff{
Old: os,
New: ns,
NewExtra: originalN,
NewRemoved: removed,
})
return nil
}
func (m schemaMap) inputString(
input terraform.UIInput,
k string,
schema *Schema) (interface{}, error) {
result, err := input.Input(&terraform.InputOpts{
Id: k,
Query: k,
Description: schema.Description,
Default: schema.InputDefault,
})
return result, err
}
func (m schemaMap) validate(
k string,
schema *Schema,
c *terraform.ResourceConfig) ([]string, []error) {
raw, ok := c.Get(k)
if !ok && schema.DefaultFunc != nil {
// We have a dynamic default. Check if we have a value.
var err error
raw, err = schema.DefaultFunc()
if err != nil {
return nil, []error{fmt.Errorf(
"%s, error loading default: %s", k, err)}
}
// We're okay as long as we had a value set
ok = raw != nil
}
if !ok {
if schema.Required {
return nil, []error{fmt.Errorf(
"%s: required field is not set", k)}
}
return nil, nil
}
if !schema.Required && !schema.Optional {
// This is a computed-only field
return nil, []error{fmt.Errorf(
"%s: this field cannot be set", k)}
}
return m.validatePrimitive(k, raw, schema, c)
}
func (m schemaMap) validateList(
k string,
raw interface{},
schema *Schema,
c *terraform.ResourceConfig) ([]string, []error) {
// We use reflection to verify the slice because you can't
// case to []interface{} unless the slice is exactly that type.
rawV := reflect.ValueOf(raw)
if rawV.Kind() != reflect.Slice {
return nil, []error{fmt.Errorf(
"%s: should be a list", k)}
}
// Now build the []interface{}
raws := make([]interface{}, rawV.Len())
for i, _ := range raws {
raws[i] = rawV.Index(i).Interface()
}
var ws []string
var es []error
for i, raw := range raws {
key := fmt.Sprintf("%s.%d", k, i)
var ws2 []string
var es2 []error
switch t := schema.Elem.(type) {
case *Resource:
// This is a sub-resource
ws2, es2 = m.validateObject(key, t.Schema, c)
case *Schema:
// This is some sort of primitive
ws2, es2 = m.validatePrimitive(key, raw, t, c)
}
if len(ws2) > 0 {
ws = append(ws, ws2...)
}
if len(es2) > 0 {
es = append(es, es2...)
}
}
return ws, es
}
func (m schemaMap) validateMap(
k string,
raw interface{},
schema *Schema,
c *terraform.ResourceConfig) ([]string, []error) {
// We use reflection to verify the slice because you can't
// case to []interface{} unless the slice is exactly that type.
rawV := reflect.ValueOf(raw)
switch rawV.Kind() {
case reflect.Map:
case reflect.Slice:
default:
return nil, []error{fmt.Errorf(
"%s: should be a map", k)}
}
// If it is not a slice, it is valid
if rawV.Kind() != reflect.Slice {
return nil, nil
}
// It is a slice, verify that all the elements are maps
raws := make([]interface{}, rawV.Len())
for i, _ := range raws {
raws[i] = rawV.Index(i).Interface()
}
for _, raw := range raws {
v := reflect.ValueOf(raw)
if v.Kind() != reflect.Map {
return nil, []error{fmt.Errorf(
"%s: should be a map", k)}
}
}
return nil, nil
}
func (m schemaMap) validateObject(
k string,
schema map[string]*Schema,
c *terraform.ResourceConfig) ([]string, []error) {
var ws []string
var es []error
for subK, s := range schema {
key := subK
if k != "" {
key = fmt.Sprintf("%s.%s", k, subK)
}
ws2, es2 := m.validate(key, s, c)
if len(ws2) > 0 {
ws = append(ws, ws2...)
}
if len(es2) > 0 {
es = append(es, es2...)
}
}
// Detect any extra/unknown keys and report those as errors.
prefix := k + "."
for configK, _ := range c.Raw {
if k != "" {
if !strings.HasPrefix(configK, prefix) {
continue
}
configK = configK[len(prefix):]
}
if _, ok := schema[configK]; !ok {
es = append(es, fmt.Errorf(
"%s: invalid or unknown key: %s", k, configK))
}
}
return ws, es
}
func (m schemaMap) validatePrimitive(
k string,
raw interface{},
schema *Schema,
c *terraform.ResourceConfig) ([]string, []error) {
if c.IsComputed(k) {
// If the key is being computed, then it is not an error
return nil, nil
}
switch schema.Type {
case TypeSet:
fallthrough
case TypeList:
return m.validateList(k, raw, schema, c)
case TypeMap:
return m.validateMap(k, raw, schema, c)
case TypeBool:
// Verify that we can parse this as the correct type
var n bool
if err := mapstructure.WeakDecode(raw, &n); err != nil {
return nil, []error{err}
}
case TypeInt:
// Verify that we can parse this as an int
var n int
if err := mapstructure.WeakDecode(raw, &n); err != nil {
return nil, []error{err}
}
case TypeString:
// Verify that we can parse this as a string
var n string
if err := mapstructure.WeakDecode(raw, &n); err != nil {
return nil, []error{err}
}
default:
panic(fmt.Sprintf("Unknown validation type: %#v", schema.Type))
}
return nil, nil
}