consul/agent/structs/service_definition.go

418 lines
14 KiB
Go

package structs
import (
"encoding/json"
"fmt"
"reflect"
"github.com/hashicorp/go-multierror"
"github.com/mitchellh/copystructure"
"github.com/mitchellh/mapstructure"
"github.com/mitchellh/reflectwalk"
)
// ServiceDefinition is used to JSON decode the Service definitions. For
// documentation on specific fields see NodeService which is better documented.
type ServiceDefinition struct {
Kind ServiceKind `json:",omitempty"`
ID string
Name string
Tags []string
Address string
Meta map[string]string
Port int
Check CheckType
Checks CheckTypes
Weights *Weights
Token string
EnableTagOverride bool
// DEPRECATED (ProxyDestination) - remove this when removing ProxyDestination
// ProxyDestination is deprecated in favour of Proxy.DestinationServiceName
ProxyDestination string `json:",omitempty"`
// Proxy is the configuration set for Kind = connect-proxy. It is mandatory in
// that case and an error to be set for any other kind. This config is part of
// a proxy service definition and is distinct from but shares some fields with
// the Connect.Proxy which configures a managed proxy as part of the actual
// service's definition. This duplication is ugly but seemed better than the
// alternative which was to re-use the same struct fields for both cases even
// though the semantics are different and the non-shared fields make no sense
// in the other case. ProxyConfig may be a more natural name here, but it's
// confusing for the UX because one of the fields in ConnectProxyConfig is
// also called just "Config"
Proxy *ConnectProxyConfig
Connect *ServiceConnect
}
func (s *ServiceDefinition) NodeService() *NodeService {
ns := &NodeService{
Kind: s.Kind,
ID: s.ID,
Service: s.Name,
Tags: s.Tags,
Address: s.Address,
Meta: s.Meta,
Port: s.Port,
Weights: s.Weights,
EnableTagOverride: s.EnableTagOverride,
}
if s.Connect != nil {
ns.Connect = *s.Connect
}
if s.Proxy != nil {
ns.Proxy = *s.Proxy
// Ensure the Upstream type is defaulted
for i := range ns.Proxy.Upstreams {
if ns.Proxy.Upstreams[i].DestinationType == "" {
ns.Proxy.Upstreams[i].DestinationType = UpstreamDestTypeService
}
}
} else {
// DEPRECATED (ProxyDestination) - remove this when removing ProxyDestination
// Legacy convert ProxyDestination into a Proxy config
ns.Proxy.DestinationServiceName = s.ProxyDestination
}
if ns.ID == "" && ns.Service != "" {
ns.ID = ns.Service
}
return ns
}
// ConnectManagedProxy returns a ConnectManagedProxy from the ServiceDefinition
// if one is configured validly. Note that is may return nil if no proxy is
// configured and will also return nil error in this case too as it's an
// expected case. The error returned indicates that there was an attempt to
// configure a proxy made but that it was invalid input, e.g. invalid
// "exec_mode".
func (s *ServiceDefinition) ConnectManagedProxy() (*ConnectManagedProxy, error) {
if s.Connect == nil || s.Connect.Proxy == nil {
return nil, nil
}
// NodeService performs some simple normalization like copying ID from Name
// which we shouldn't hard code ourselves here...
ns := s.NodeService()
execMode, err := NewProxyExecMode(s.Connect.Proxy.ExecMode)
if err != nil {
return nil, err
}
// If upstreams were set in the config and NOT in the actual Upstreams field,
// extract them out to the new explicit Upstreams and unset in config to make
// transition smooth.
if deprecatedUpstreams, ok := s.Connect.Proxy.Config["upstreams"]; ok {
if len(s.Connect.Proxy.Upstreams) == 0 {
if slice, ok := deprecatedUpstreams.([]interface{}); ok {
for _, raw := range slice {
var oldU deprecatedBuiltInProxyUpstreamConfig
var decMeta mapstructure.Metadata
decCfg := &mapstructure.DecoderConfig{
Metadata: &decMeta,
Result: &oldU,
}
dec, err := mapstructure.NewDecoder(decCfg)
if err != nil {
// Just skip it - we never used to parse this so never failed
// invalid stuff till it hit the proxy. This is a best-effort
// attempt to not break existing service definitions so it's not the
// end of the world if we don't have exactly the same failure mode
// for invalid input.
continue
}
err = dec.Decode(raw)
if err != nil {
// same logic as above
continue
}
newT := UpstreamDestTypeService
if oldU.DestinationType == "prepared_query" {
newT = UpstreamDestTypePreparedQuery
}
u := Upstream{
DestinationType: newT,
DestinationName: oldU.DestinationName,
DestinationNamespace: oldU.DestinationNamespace,
Datacenter: oldU.DestinationDatacenter,
LocalBindAddress: oldU.LocalBindAddress,
LocalBindPort: oldU.LocalBindPort,
}
// Any unrecognized keys should be copied into the config map
if len(decMeta.Unused) > 0 {
u.Config = make(map[string]interface{})
// Paranoid type assertion - mapstructure would have errored if this
// wasn't safe but panics are bad...
if rawMap, ok := raw.(map[string]interface{}); ok {
for _, k := range decMeta.Unused {
u.Config[k] = rawMap[k]
}
}
}
s.Connect.Proxy.Upstreams = append(s.Connect.Proxy.Upstreams, u)
}
}
}
// Remove upstreams even if we didn't add them for consistency.
delete(s.Connect.Proxy.Config, "upstreams")
}
p := &ConnectManagedProxy{
ExecMode: execMode,
Command: s.Connect.Proxy.Command,
Config: s.Connect.Proxy.Config,
Upstreams: s.Connect.Proxy.Upstreams,
// ProxyService will be setup when the agent registers the configured
// proxies and starts them etc.
TargetServiceID: ns.ID,
}
// Ensure the Upstream type is defaulted
for i := range p.Upstreams {
if p.Upstreams[i].DestinationType == "" {
p.Upstreams[i].DestinationType = UpstreamDestTypeService
}
}
return p, nil
}
// deprecatedBuiltInProxyUpstreamConfig is a struct for extracting old
// connect/proxy.UpstreamConfiguration syntax upstreams from existing managed
// proxy configs to convert them to new first-class Upstreams.
type deprecatedBuiltInProxyUpstreamConfig struct {
LocalBindAddress string `json:"local_bind_address" hcl:"local_bind_address,attr" mapstructure:"local_bind_address"`
LocalBindPort int `json:"local_bind_port" hcl:"local_bind_port,attr" mapstructure:"local_bind_port"`
DestinationName string `json:"destination_name" hcl:"destination_name,attr" mapstructure:"destination_name"`
DestinationNamespace string `json:"destination_namespace" hcl:"destination_namespace,attr" mapstructure:"destination_namespace"`
DestinationType string `json:"destination_type" hcl:"destination_type,attr" mapstructure:"destination_type"`
DestinationDatacenter string `json:"destination_datacenter" hcl:"destination_datacenter,attr" mapstructure:"destination_datacenter"`
// ConnectTimeoutMs is removed explicitly because any additional config we
// find including this field should be put into the opaque Config map in
// Upstream.
}
// Validate validates the service definition. This also calls the underlying
// Validate method on the NodeService.
//
// NOTE(mitchellh): This currently only validates fields related to Connect
// and is incomplete with regards to other fields.
func (s *ServiceDefinition) Validate() error {
var result error
if s.Kind == ServiceKindTypical {
if s.Connect != nil {
if s.Connect.Proxy != nil {
if s.Connect.Native {
result = multierror.Append(result, fmt.Errorf(
"Services that are Connect native may not have a proxy configuration"))
}
if s.Port == 0 {
result = multierror.Append(result, fmt.Errorf(
"Services with a Connect managed proxy must have a port set"))
}
}
}
}
// Validate the NodeService which covers a lot
if err := s.NodeService().Validate(); err != nil {
result = multierror.Append(result, err)
}
return result
}
func (s *ServiceDefinition) CheckTypes() (checks CheckTypes, err error) {
if !s.Check.Empty() {
err := s.Check.Validate()
if err != nil {
return nil, err
}
checks = append(checks, &s.Check)
}
for _, check := range s.Checks {
if err := check.Validate(); err != nil {
return nil, err
}
checks = append(checks, check)
}
return checks, nil
}
// ServiceDefinitionConnectProxy is the connect proxy config within a service
// registration. Note this is duplicated in config.ServiceConnectProxy and needs
// to be kept in sync.
type ServiceDefinitionConnectProxy struct {
Command []string `json:",omitempty"`
ExecMode string `json:",omitempty"`
Config map[string]interface{} `json:",omitempty"`
Upstreams []Upstream `json:",omitempty"`
}
func (p *ServiceDefinitionConnectProxy) MarshalJSON() ([]byte, error) {
type typeCopy ServiceDefinitionConnectProxy
copy := typeCopy(*p)
// If we have config, then we want to run it through our proxyConfigWalker
// which is a reflectwalk implementation that attempts to turn arbitrary
// interface{} values into JSON-safe equivalents (more or less). This
// should always work because the config input is either HCL or JSON and
// both are JSON compatible.
if copy.Config != nil {
configCopyRaw, err := copystructure.Copy(copy.Config)
if err != nil {
return nil, err
}
configCopy, ok := configCopyRaw.(map[string]interface{})
if !ok {
// This should never fail because we KNOW the input type,
// but we don't ever want to risk the panic.
return nil, fmt.Errorf("internal error: config copy is not right type")
}
if err := reflectwalk.Walk(configCopy, &proxyConfigWalker{}); err != nil {
return nil, err
}
copy.Config = configCopy
}
return json.Marshal(&copy)
}
var typMapIfaceIface = reflect.TypeOf(map[interface{}]interface{}{})
// proxyConfigWalker implements interfaces for the reflectwalk package
// (github.com/mitchellh/reflectwalk) that can be used to automatically
// make the proxy configuration safe for JSON usage.
//
// Most of the implementation here is just keeping track of where we are
// in the reflectwalk process, so that we can replace values. The key logic
// is in Slice() and SliceElem().
//
// In particular we're looking to replace two cases the msgpack codec causes:
//
// 1.) String values get turned into byte slices. JSON will base64-encode
// this and we don't want that, so we convert them back to strings.
//
// 2.) Nested maps turn into map[interface{}]interface{}. JSON cannot
// encode this, so we need to turn it back into map[string]interface{}.
//
// This is tested via the TestServiceDefinitionConnectProxy_json test.
type proxyConfigWalker struct {
lastValue reflect.Value // lastValue of map, required for replacement
loc, lastLoc reflectwalk.Location // locations
cs []reflect.Value // container stack
csKey []reflect.Value // container keys (maps) stack
csData interface{} // current container data
sliceIndex []int // slice index stack (one for each slice in cs)
}
func (w *proxyConfigWalker) Enter(loc reflectwalk.Location) error {
w.lastLoc = w.loc
w.loc = loc
return nil
}
func (w *proxyConfigWalker) Exit(loc reflectwalk.Location) error {
w.loc = reflectwalk.None
w.lastLoc = reflectwalk.None
switch loc {
case reflectwalk.Map:
w.cs = w.cs[:len(w.cs)-1]
case reflectwalk.MapValue:
w.csKey = w.csKey[:len(w.csKey)-1]
case reflectwalk.Slice:
// Split any values that need to be split
w.cs = w.cs[:len(w.cs)-1]
case reflectwalk.SliceElem:
w.csKey = w.csKey[:len(w.csKey)-1]
w.sliceIndex = w.sliceIndex[:len(w.sliceIndex)-1]
}
return nil
}
func (w *proxyConfigWalker) Map(m reflect.Value) error {
w.cs = append(w.cs, m)
return nil
}
func (w *proxyConfigWalker) MapElem(m, k, v reflect.Value) error {
w.csData = k
w.csKey = append(w.csKey, k)
w.lastValue = v
return nil
}
func (w *proxyConfigWalker) Slice(v reflect.Value) error {
// If we find a []byte slice, it is an HCL-string converted to []byte.
// Convert it back to a Go string and replace the value so that JSON
// doesn't base64-encode it.
if v.Type() == reflect.TypeOf([]byte{}) {
resultVal := reflect.ValueOf(string(v.Interface().([]byte)))
switch w.lastLoc {
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)
case reflectwalk.Slice:
s := w.cs[len(w.cs)-1]
s.Index(w.sliceIndex[len(w.sliceIndex)-1]).Set(resultVal)
default:
return fmt.Errorf("cannot convert []byte")
}
}
w.cs = append(w.cs, v)
return nil
}
func (w *proxyConfigWalker) SliceElem(i int, elem reflect.Value) error {
w.csKey = append(w.csKey, reflect.ValueOf(i))
w.sliceIndex = append(w.sliceIndex, i)
// We're looking specifically for map[interface{}]interface{}, but the
// values in a slice are wrapped up in interface{} so we need to unwrap
// that first. Therefore, we do three checks: 1.) is it valid? so we
// don't panic, 2.) is it an interface{}? so we can unwrap it and 3.)
// after unwrapping the interface do we have the map we expect?
if !elem.IsValid() {
return nil
}
if elem.Kind() != reflect.Interface {
return nil
}
if inner := elem.Elem(); inner.Type() == typMapIfaceIface {
// map[interface{}]interface{}, attempt to weakly decode into string keys
var target map[string]interface{}
if err := mapstructure.WeakDecode(inner.Interface(), &target); err != nil {
return err
}
elem.Set(reflect.ValueOf(target))
}
return nil
}