open-consul/agent/configentry/resolve.go

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package configentry
import (
"fmt"
"github.com/hashicorp/go-hclog"
"github.com/mitchellh/copystructure"
"github.com/hashicorp/consul/agent/structs"
)
func ComputeResolvedServiceConfig(
args *structs.ServiceConfigRequest,
upstreamIDs []structs.ServiceID,
legacyUpstreams bool,
entries *ResolvedServiceConfigSet,
logger hclog.Logger,
) (*structs.ServiceConfigResponse, error) {
var thisReply structs.ServiceConfigResponse
thisReply.MeshGateway.Mode = structs.MeshGatewayModeDefault
// TODO(freddy) Refactor this into smaller set of state store functions
// Pass the WatchSet to both the service and proxy config lookups. If either is updated during the
// blocking query, this function will be rerun and these state store lookups will both be current.
// We use the default enterprise meta to look up the global proxy defaults because they are not namespaced.
var proxyConfGlobalProtocol string
proxyConf := entries.GetProxyDefaults(args.PartitionOrDefault())
if proxyConf != nil {
// Apply the proxy defaults to the sidecar's proxy config
mapCopy, err := copystructure.Copy(proxyConf.Config)
if err != nil {
return nil, fmt.Errorf("failed to copy global proxy-defaults: %v", err)
}
thisReply.ProxyConfig = mapCopy.(map[string]interface{})
thisReply.Mode = proxyConf.Mode
thisReply.TransparentProxy = proxyConf.TransparentProxy
thisReply.MeshGateway = proxyConf.MeshGateway
thisReply.Expose = proxyConf.Expose
// Extract the global protocol from proxyConf for upstream configs.
rawProtocol := proxyConf.Config["protocol"]
if rawProtocol != nil {
var ok bool
proxyConfGlobalProtocol, ok = rawProtocol.(string)
if !ok {
return nil, fmt.Errorf("invalid protocol type %T", rawProtocol)
}
}
}
serviceConf := entries.GetServiceDefaults(
structs.NewServiceID(args.Name, &args.EnterpriseMeta),
)
if serviceConf != nil {
if serviceConf.Expose.Checks {
thisReply.Expose.Checks = true
}
if len(serviceConf.Expose.Paths) >= 1 {
thisReply.Expose.Paths = serviceConf.Expose.Paths
}
if serviceConf.MeshGateway.Mode != structs.MeshGatewayModeDefault {
thisReply.MeshGateway.Mode = serviceConf.MeshGateway.Mode
}
if serviceConf.Protocol != "" {
if thisReply.ProxyConfig == nil {
thisReply.ProxyConfig = make(map[string]interface{})
}
thisReply.ProxyConfig["protocol"] = serviceConf.Protocol
}
if serviceConf.TransparentProxy.OutboundListenerPort != 0 {
thisReply.TransparentProxy.OutboundListenerPort = serviceConf.TransparentProxy.OutboundListenerPort
}
if serviceConf.TransparentProxy.DialedDirectly {
thisReply.TransparentProxy.DialedDirectly = serviceConf.TransparentProxy.DialedDirectly
}
if serviceConf.Mode != structs.ProxyModeDefault {
thisReply.Mode = serviceConf.Mode
}
if serviceConf.Destination != nil {
thisReply.Destination = *serviceConf.Destination
}
if serviceConf.MaxInboundConnections > 0 {
if thisReply.ProxyConfig == nil {
thisReply.ProxyConfig = map[string]interface{}{}
}
thisReply.ProxyConfig["max_inbound_connections"] = serviceConf.MaxInboundConnections
}
thisReply.Meta = serviceConf.Meta
}
// First collect all upstreams into a set of seen upstreams.
// Upstreams can come from:
// - Explicitly from proxy registrations, and therefore as an argument to this RPC endpoint
// - Implicitly from centralized upstream config in service-defaults
seenUpstreams := map[structs.ServiceID]struct{}{}
var (
noUpstreamArgs = len(upstreamIDs) == 0 && len(args.Upstreams) == 0
// Check the args and the resolved value. If it was exclusively set via a config entry, then args.Mode
// will never be transparent because the service config request does not use the resolved value.
tproxy = args.Mode == structs.ProxyModeTransparent || thisReply.Mode == structs.ProxyModeTransparent
)
// The upstreams passed as arguments to this endpoint are the upstreams explicitly defined in a proxy registration.
// If no upstreams were passed, then we should only return the resolved config if the proxy is in transparent mode.
// Otherwise we would return a resolved upstream config to a proxy with no configured upstreams.
if noUpstreamArgs && !tproxy {
return &thisReply, nil
}
// First store all upstreams that were provided in the request
for _, sid := range upstreamIDs {
if _, ok := seenUpstreams[sid]; !ok {
seenUpstreams[sid] = struct{}{}
}
}
// Then store upstreams inferred from service-defaults and mapify the overrides.
var (
upstreamConfigs = make(map[structs.ServiceID]*structs.UpstreamConfig)
upstreamDefaults *structs.UpstreamConfig
// usConfigs stores the opaque config map for each upstream and is keyed on the upstream's ID.
usConfigs = make(map[structs.ServiceID]map[string]interface{})
)
if serviceConf != nil && serviceConf.UpstreamConfig != nil {
for i, override := range serviceConf.UpstreamConfig.Overrides {
if override.Name == "" {
logger.Warn(
"Skipping UpstreamConfig.Overrides entry without a required name field",
"entryIndex", i,
"kind", serviceConf.GetKind(),
"name", serviceConf.GetName(),
"namespace", serviceConf.GetEnterpriseMeta().NamespaceOrEmpty(),
)
continue // skip this impossible condition
}
seenUpstreams[override.ServiceID()] = struct{}{}
upstreamConfigs[override.ServiceID()] = override
}
if serviceConf.UpstreamConfig.Defaults != nil {
upstreamDefaults = serviceConf.UpstreamConfig.Defaults
// Store the upstream defaults under a wildcard key so that they can be applied to
// upstreams that are inferred from intentions and do not have explicit upstream configuration.
cfgMap := make(map[string]interface{})
upstreamDefaults.MergeInto(cfgMap)
wildcard := structs.NewServiceID(structs.WildcardSpecifier, args.WithWildcardNamespace())
usConfigs[wildcard] = cfgMap
}
}
for upstream := range seenUpstreams {
resolvedCfg := make(map[string]interface{})
// The protocol of an upstream is resolved in this order:
// 1. Default protocol from proxy-defaults (how all services should be addressed)
// 2. Protocol for upstream service defined in its service-defaults (how the upstream wants to be addressed)
// 3. Protocol defined for the upstream in the service-defaults.(upstream_config.defaults|upstream_config.overrides) of the downstream
// (how the downstream wants to address it)
protocol := proxyConfGlobalProtocol
upstreamSvcDefaults := entries.GetServiceDefaults(
structs.NewServiceID(upstream.ID, &upstream.EnterpriseMeta),
)
if upstreamSvcDefaults != nil {
if upstreamSvcDefaults.Protocol != "" {
protocol = upstreamSvcDefaults.Protocol
}
}
if protocol != "" {
resolvedCfg["protocol"] = protocol
}
// Merge centralized defaults for all upstreams before configuration for specific upstreams
if upstreamDefaults != nil {
upstreamDefaults.MergeInto(resolvedCfg)
}
// The MeshGateway value from the proxy registration overrides the one from upstream_defaults
// because it is specific to the proxy instance.
//
// The goal is to flatten the mesh gateway mode in this order:
// 0. Value from centralized upstream_defaults
// 1. Value from local proxy registration
// 2. Value from centralized upstream_config
// 3. Value from local upstream definition. This last step is done in the client's service manager.
if !args.MeshGateway.IsZero() {
resolvedCfg["mesh_gateway"] = args.MeshGateway
}
if upstreamConfigs[upstream] != nil {
upstreamConfigs[upstream].MergeInto(resolvedCfg)
}
if len(resolvedCfg) > 0 {
usConfigs[upstream] = resolvedCfg
}
}
// don't allocate the slices just to not fill them
if len(usConfigs) == 0 {
return &thisReply, nil
}
if legacyUpstreams {
// For legacy upstreams we return a map that is only keyed on the string ID, since they precede namespaces
thisReply.UpstreamConfigs = make(map[string]map[string]interface{})
for us, conf := range usConfigs {
thisReply.UpstreamConfigs[us.ID] = conf
}
} else {
thisReply.UpstreamIDConfigs = make(structs.OpaqueUpstreamConfigs, 0, len(usConfigs))
for us, conf := range usConfigs {
thisReply.UpstreamIDConfigs = append(thisReply.UpstreamIDConfigs,
structs.OpaqueUpstreamConfig{Upstream: us, Config: conf})
}
}
return &thisReply, nil
}