open-consul/vendor/github.com/hashicorp/hil/walk.go
James Phillips ee43212da4 Updates vendored dependencies.
This removes some unused dependencies that I know we plan to re-add later,
but this makes for a clean `godep save` for now.
2016-03-07 10:45:39 -08:00

267 lines
6.5 KiB
Go

package hil
import (
"fmt"
"reflect"
"strings"
"github.com/hashicorp/hil/ast"
"github.com/mitchellh/reflectwalk"
)
// WalkFn is the type of function to pass to Walk. Modify fields within
// WalkData to control whether replacement happens.
type WalkFn func(*WalkData) error
// WalkData is the structure passed to the callback of the Walk function.
//
// This structure contains data passed in as well as fields that are expected
// to be written by the caller as a result. Please see the documentation for
// each field for more information.
type WalkData struct {
// Root is the parsed root of this HIL program
Root ast.Node
// Location is the location within the structure where this
// value was found. This can be used to modify behavior within
// slices and so on.
Location reflectwalk.Location
// The below two values must be set by the callback to have any effect.
//
// Replace, if true, will replace the value in the structure with
// ReplaceValue. It is up to the caller to make sure this is a string.
Replace bool
ReplaceValue string
}
// Walk will walk an arbitrary Go structure and parse any string as an
// HIL program and call the callback cb to determine what to replace it
// with.
//
// This function is very useful for arbitrary HIL program interpolation
// across a complex configuration structure. Due to the heavy use of
// reflection in this function, it is recommend to write many unit tests
// with your typical configuration structures to hilp mitigate the risk
// of panics.
func Walk(v interface{}, cb WalkFn) error {
walker := &interpolationWalker{F: cb}
return reflectwalk.Walk(v, walker)
}
// interpolationWalker implements interfaces for the reflectwalk package
// (github.com/mitchellh/reflectwalk) that can be used to automatically
// execute a callback for an interpolation.
type interpolationWalker struct {
F WalkFn
key []string
lastValue reflect.Value
loc reflectwalk.Location
cs []reflect.Value
csKey []reflect.Value
csData interface{}
sliceIndex int
unknownKeys []string
}
func (w *interpolationWalker) Enter(loc reflectwalk.Location) error {
w.loc = loc
return nil
}
func (w *interpolationWalker) Exit(loc reflectwalk.Location) error {
w.loc = reflectwalk.None
switch loc {
case reflectwalk.Map:
w.cs = w.cs[:len(w.cs)-1]
case reflectwalk.MapValue:
w.key = w.key[:len(w.key)-1]
w.csKey = w.csKey[:len(w.csKey)-1]
case reflectwalk.Slice:
// Split any values that need to be split
w.splitSlice()
w.cs = w.cs[:len(w.cs)-1]
case reflectwalk.SliceElem:
w.csKey = w.csKey[:len(w.csKey)-1]
}
return nil
}
func (w *interpolationWalker) Map(m reflect.Value) error {
w.cs = append(w.cs, m)
return nil
}
func (w *interpolationWalker) MapElem(m, k, v reflect.Value) error {
w.csData = k
w.csKey = append(w.csKey, k)
w.key = append(w.key, k.String())
w.lastValue = v
return nil
}
func (w *interpolationWalker) Slice(s reflect.Value) error {
w.cs = append(w.cs, s)
return nil
}
func (w *interpolationWalker) SliceElem(i int, elem reflect.Value) error {
w.csKey = append(w.csKey, reflect.ValueOf(i))
w.sliceIndex = i
return nil
}
func (w *interpolationWalker) Primitive(v reflect.Value) error {
setV := v
// We only care about strings
if v.Kind() == reflect.Interface {
setV = v
v = v.Elem()
}
if v.Kind() != reflect.String {
return nil
}
astRoot, err := Parse(v.String())
if err != nil {
return err
}
// If the AST we got is just a literal string value with the same
// value then we ignore it. We have to check if its the same value
// because it is possible to input a string, get out a string, and
// have it be different. For example: "foo-$${bar}" turns into
// "foo-${bar}"
if n, ok := astRoot.(*ast.LiteralNode); ok {
if s, ok := n.Value.(string); ok && s == v.String() {
return nil
}
}
if w.F == nil {
return nil
}
data := WalkData{Root: astRoot, Location: w.loc}
if err := w.F(&data); err != nil {
return fmt.Errorf(
"%s in:\n\n%s",
err, v.String())
}
if data.Replace {
/*
if remove {
w.removeCurrent()
return nil
}
*/
resultVal := reflect.ValueOf(data.ReplaceValue)
switch w.loc {
case reflectwalk.MapKey:
m := w.cs[len(w.cs)-1]
// Delete the old value
var zero reflect.Value
m.SetMapIndex(w.csData.(reflect.Value), zero)
// Set the new key with the existing value
m.SetMapIndex(resultVal, w.lastValue)
// Set the key to be the new key
w.csData = resultVal
case reflectwalk.MapValue:
// If we're in a map, then the only way to set a map value is
// to set it directly.
m := w.cs[len(w.cs)-1]
mk := w.csData.(reflect.Value)
m.SetMapIndex(mk, resultVal)
default:
// Otherwise, we should be addressable
setV.Set(resultVal)
}
}
return nil
}
func (w *interpolationWalker) removeCurrent() {
// Append the key to the unknown keys
w.unknownKeys = append(w.unknownKeys, strings.Join(w.key, "."))
for i := 1; i <= len(w.cs); i++ {
c := w.cs[len(w.cs)-i]
switch c.Kind() {
case reflect.Map:
// Zero value so that we delete the map key
var val reflect.Value
// Get the key and delete it
k := w.csData.(reflect.Value)
c.SetMapIndex(k, val)
return
}
}
panic("No container found for removeCurrent")
}
func (w *interpolationWalker) replaceCurrent(v reflect.Value) {
c := w.cs[len(w.cs)-2]
switch c.Kind() {
case reflect.Map:
// Get the key and delete it
k := w.csKey[len(w.csKey)-1]
c.SetMapIndex(k, v)
}
}
func (w *interpolationWalker) splitSlice() {
// Get the []interface{} slice so we can do some operations on
// it without dealing with reflection. We'll document each step
// here to be clear.
var s []interface{}
raw := w.cs[len(w.cs)-1]
switch v := raw.Interface().(type) {
case []interface{}:
s = v
case []map[string]interface{}:
return
default:
panic("Unknown kind: " + raw.Kind().String())
}
// Check if we have any elements that we need to split. If not, then
// just return since we're done.
split := false
if !split {
return
}
// Make a new result slice that is twice the capacity to fit our growth.
result := make([]interface{}, 0, len(s)*2)
// Go over each element of the original slice and start building up
// the resulting slice by splitting where we have to.
for _, v := range s {
sv, ok := v.(string)
if !ok {
// Not a string, so just set it
result = append(result, v)
continue
}
// Not a string list, so just set it
result = append(result, sv)
}
// Our slice is now done, we have to replace the slice now
// with this new one that we have.
w.replaceCurrent(reflect.ValueOf(result))
}