在本篇文章中，我们继续来说Kubernetes。

经过一段时间的探索，我们先后完成了Kubernetes集群搭建，DNS、Dashboard、Heapster等插件安装，集群安全配置，搭建作为Persistent Volume的CephRBD，以及服务更新等探索和实现工作。现在Kubernetes集群层面的Logging需求逐渐浮上水面了。

随着一些小应用在我们的Kubernetes集群上的部署上线，集群的运行迈上了正轨。但问题随之而来，那就是如何查找和诊断集群自身的问题以及运行于Pod中应用的问题。日志，没错！我们也只能依赖Kubernetes组件以及Pod中应用输出的日志。不过目前我们仅能通过kubectl logs命令或Kubernetes Dashboard来查看Log。在没有cluster level logging的情况下，我们需要分别查看各个Pod的日志，操作繁琐，过程低效。我们迫切地需要为Kubernetes集群搭建一套集群级别的集中日志收集和分析设施。

对于任何基础设施或后端服务系统，日志都是极其重要的。对于受Google内部容器管理系统Borg启发而催生出的Kubernetes项目来说，自然少不了对Logging的支持。在“Logging Overview“中，官方概要介绍了Kubernetes上的几个层次的Logging方案，并给出Cluster-level logging的参考架构：

Kubernetes还给出了参考实现：
– Logging Backend：Elastic Search stack(包括：Kibana)
– Logging-agent：fluentd

ElasticSearch stack实现的cluster level logging的一个优势在于其对Kubernetes集群中的Pod没有侵入性，Pod无需做任何配合性改动。同时EFK/ELK方案在业内也是相对成熟稳定的。

在本文中，我将为我们的Kubernetes 1.3.7集群安装ElasticSearch、Fluentd和Kibana。由于1.3.7版本略有些old，EFK能否在其上面run起来，我也是心中未知。能否像《生化危机：终章》那样有一个完美的结局，我们还需要一步一步“打怪升级”慢慢看。

一、Kubernetes 1.3.7集群的 “漏网之鱼”

Kubernetes 1.3.7集群是通过kube-up.sh搭建并初始化的。按照K8s官方文档有关elasticsearch logging的介绍，在kubernetes/cluster/ubuntu/config-default.sh中，我也发现了下面几个配置项：

// kubernetes/cluster/ubuntu/config-default.sh
# Optional: Enable node logging.
ENABLE_NODE_LOGGING=false
LOGGING_DESTINATION=${LOGGING_DESTINATION:-elasticsearch}

# Optional: When set to true, Elasticsearch and Kibana will be setup as part of the cluster bring up.
ENABLE_CLUSTER_LOGGING=false
ELASTICSEARCH_LOGGING_REPLICAS=${ELASTICSEARCH_LOGGING_REPLICAS:-1}

显然，当初如果搭建集群伊始时要是知道这些配置的意义，可能那个时候就会将elastic logging集成到集群中了。现在为时已晚，集群上已经跑了很多应用，无法重新通过kube-up.sh中断集群运行并安装elastic logging了。我只能手工进行安装了！

二、镜像准备

1.3.7源码中kubernetes/cluster/addons/fluentd-elasticsearch下的manifest已经比较old了，我们直接使用kubernetes最新源码中的manifest文件：

k8s.io/kubernetes/cluster/addons/fluentd-elasticsearch$ ls *.yaml
es-controller.yaml  es-service.yaml  fluentd-es-ds.yaml  kibana-controller.yaml  kibana-service.yaml

分析这些yaml，我们需要三个镜像：

 gcr.io/google_containers/fluentd-elasticsearch:1.22
 gcr.io/google_containers/elasticsearch:v2.4.1-1
 gcr.io/google_containers/kibana:v4.6.1-1

显然镜像都在墙外。由于生产环境下的Docker引擎并没有配置加速器代理，因此我们需要手工下载一下这三个镜像。我采用的方法是通过另外一台配置了加速器的机器上的Docker引擎将三个image下载，并重新打tag，上传到我在hub.docker.com上的账号下，以elasticsearch:v2.4.1-1为例：

# docker pull  gcr.io/google_containers/elasticsearch:v2.4.1-1
# docker tag gcr.io/google_containers/elasticsearch:v2.4.1-1 bigwhite/elasticsearch:v2.4.1-1
# docker push bigwhite/elasticsearch:v2.4.1-1

下面是我们在后续安装过程中真正要使用到的镜像：

bigwhite/fluentd-elasticsearch:1.22
bigwhite/elasticsearch:v2.4.1-1
bigwhite/kibana:v4.6.1-1

三、启动fluentd

fluentd是以DaemonSet的形式跑在K8s集群上的，这样k8s可以保证每个k8s cluster node上都会启动一个fluentd(注意：将image改为上述镜像地址，如果你配置了加速器，那自然就不必了)。

# kubectl create -f fluentd-es-ds.yaml --record
daemonset "fluentd-es-v1.22" created

查看daemonset中的Pod的启动情况，我们发现：

kube-system                  fluentd-es-v1.22-as3s5                  0/1       CrashLoopBackOff   2          43s       172.16.99.6    10.47.136.60
kube-system                  fluentd-es-v1.22-qz193                  0/1       CrashLoopBackOff   2          43s       172.16.57.7    10.46.181.146

fluentd Pod启动失败，fluentd的日志可以通过/var/log/fluentd.log查看：

# tail -100f /var/log/fluentd.log

2017-03-02 02:27:01 +0000 [info]: reading config file path="/etc/td-agent/td-agent.conf"
2017-03-02 02:27:01 +0000 [info]: starting fluentd-0.12.31
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-mixin-config-placeholders' version '0.4.0'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-mixin-plaintextformatter' version '0.2.6'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-docker_metadata_filter' version '0.1.3'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-elasticsearch' version '1.5.0'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-kafka' version '0.4.1'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-kubernetes_metadata_filter' version '0.24.0'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-mongo' version '0.7.16'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-rewrite-tag-filter' version '1.5.5'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-s3' version '0.8.0'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-scribe' version '0.10.14'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-td' version '0.10.29'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-td-monitoring' version '0.2.2'
2017-03-02 02:27:01 +0000 [info]: gem 'fluent-plugin-webhdfs' version '0.4.2'
2017-03-02 02:27:01 +0000 [info]: gem 'fluentd' version '0.12.31'
2017-03-02 02:27:01 +0000 [info]: adding match pattern="fluent.**" type="null"
2017-03-02 02:27:01 +0000 [info]: adding filter pattern="kubernetes.**" type="kubernetes_metadata"
2017-03-02 02:27:02 +0000 [error]: config error file="/etc/td-agent/td-agent.conf" error="Invalid Kubernetes API v1 endpoint https://192.168.3.1:443/api: 401 Unauthorized"
2017-03-02 02:27:02 +0000 [info]: process finished code=256
2017-03-02 02:27:02 +0000 [warn]: process died within 1 second. exit.

从上述日志中的error来看：fluentd访问apiserver secure port(443)出错了：Unauthorized! 通过分析 cluster/addons/fluentd-elasticsearch/fluentd-es-image/build.sh和td-agent.conf，我们发现是fluentd image中的fluent-plugin-kubernetes_metadata_filter要去访问API Server以获取一些kubernetes的metadata信息。不过未做任何特殊配置的fluent-plugin-kubernetes_metadata_filter，我猜测它使用的是kubernetes为Pod传入的环境变量：KUBERNETES_SERVICE_HOST和KUBERNETES_SERVICE_PORT来得到API Server的访问信息的。但API Server在secure port上是开启了安全身份验证机制的，fluentd直接访问必然是失败的。

我们找到了fluent-plugin-kubernetes_metadata_filter项目在github.com上的主页，在这个页面上我们看到了fluent-plugin-kubernetes_metadata_filter支持的其他配置，包括：ca_file、client_cert、client_key等，显然这些字眼非常眼熟。我们需要修改一下fluentd image中td-agent.conf的配置，为fluent-plugin-kubernetes_metadata_filter增加一些配置项，比如：

// td-agent.conf
... ...
<filter kubernetes.**>
  type kubernetes_metadata
  ca_file /srv/kubernetes/ca.crt
  client_cert /srv/kubernetes/kubecfg.crt
  client_key /srv/kubernetes/kubecfg.key
</filter>
... ...

这里我不想重新制作image，那么怎么办呢？Kubernetes提供了ConfigMap这一强大的武器，我们可以将新版td-agent.conf制作成kubernetes的configmap资源，并挂载到fluentd pod的相应位置以替换image中默认的td-agent.conf。

需要注意两点：
* 在基于td-agent.conf创建configmap资源之前，需要将td-agent.conf中的注释行都删掉，否则生成的configmap的内容可能不正确；
* fluentd pod将创建在kube-system下，因此configmap资源也需要创建在kube-system namespace下面，否则kubectl create无法找到对应的configmap。

# kubectl create configmap td-agent-config --from-file=./td-agent.conf -n kube-system
configmap "td-agent-config" created

# kubectl get configmaps -n kube-system
NAME              DATA      AGE
td-agent-config   1         9s

# kubectl get configmaps td-agent-config -o yaml
apiVersion: v1
data:
  td-agent.conf: |
    <match fluent.**>
      type null
    </match>

    <source>
      type tail
      path /var/log/containers/*.log
      pos_file /var/log/es-containers.log.pos
      time_format %Y-%m-%dT%H:%M:%S.%NZ
      tag kubernetes.*
      format json
      read_from_head true
    </source>
... ...

fluentd-es-ds.yaml也要随之做一些改动，主要是增加两个mount: 一个是mount 上面的configmap td-agent-config，另外一个就是mount hostpath：/srv/kubernetes以获取到相关client端的数字证书：

  spec:
      containers:
      - name: fluentd-es
        image: bigwhite/fluentd-elasticsearch:1.22
        command:
          - '/bin/sh'
          - '-c'
          - '/usr/sbin/td-agent 2>&1 >> /var/log/fluentd.log'
        resources:
          limits:
            memory: 200Mi
          #requests:
            #cpu: 100m
            #memory: 200Mi
        volumeMounts:
        - name: varlog
          mountPath: /var/log
        - name: varlibdockercontainers
          mountPath: /var/lib/docker/containers
          readOnly: true
        - name: td-agent-config
          mountPath: /etc/td-agent
        - name: tls-files
          mountPath: /srv/kubernetes
      terminationGracePeriodSeconds: 30
      volumes:
      - name: varlog
        hostPath:
          path: /var/log
      - name: varlibdockercontainers
        hostPath:
          path: /var/lib/docker/containers
      - name: td-agent-config
        configMap:
          name: td-agent-config
      - name: tls-files
        hostPath:
          path: /srv/kubernetes

接下来，我们重新创建fluentd ds，步骤不赘述。这回我们的创建成功了：

kube-system                  fluentd-es-v1.22-adsrx                  1/1       Running    0          1s        172.16.99.6    10.47.136.60
kube-system                  fluentd-es-v1.22-rpme3                  1/1       Running    0          1s        172.16.57.7    10.46.181.146

但通过查看/var/log/fluentd.log，我们依然能看到“问题”：

2017-03-02 03:57:58 +0000 [warn]: temporarily failed to flush the buffer. next_retry=2017-03-02 03:57:59 +0000 error_class="Fluent::ElasticsearchOutput::ConnectionFailure" error="Can not reach Elasticsearch cluster ({:host=>\"elasticsearch-logging\", :port=>9200, :scheme=>\"http\"})!" plugin_id="object:3fd99fa857d8"
  2017-03-02 03:57:58 +0000 [warn]: suppressed same stacktrace
2017-03-02 03:58:00 +0000 [warn]: temporarily failed to flush the buffer. next_retry=2017-03-02 03:58:03 +0000 error_class="Fluent::ElasticsearchOutput::ConnectionFailure" error="Can not reach Elasticsearch cluster ({:host=>\"elasticsearch-logging\", :port=>9200, :scheme=>\"http\"})!" plugin_id="object:3fd99fa857d8"
2017-03-02 03:58:00 +0000 [info]: process finished code=9
2017-03-02 03:58:00 +0000 [error]: fluentd main process died unexpectedly. restarting.

由于ElasticSearch logging还未创建，这是连不上elasticsearch所致。

四、启动elasticsearch

启动elasticsearch：

# kubectl create -f es-controller.yaml
replicationcontroller "elasticsearch-logging-v1" created

# kubectl create -f es-service.yaml
service "elasticsearch-logging" created

get pods：

kube-system                  elasticsearch-logging-v1-3bzt6          1/1       Running    0          7s        172.16.57.8    10.46.181.146
kube-system                  elasticsearch-logging-v1-nvbe1          1/1       Running    0          7s        172.16.99.10   10.47.136.60

elastic search logging启动成功后，上述fluentd的fail日志就没有了！

不过elastic search真的运行ok了么？我们查看一下elasticsearch相关Pod日志：

# kubectl logs -f elasticsearch-logging-v1-3bzt6 -n kube-system
F0302 03:59:41.036697       8 elasticsearch_logging_discovery.go:60] kube-system namespace doesn't exist: the server has asked for the client to provide credentials (get namespaces kube-system)
goroutine 1 [running]:
k8s.io/kubernetes/vendor/github.com/golang/glog.stacks(0x19a8100, 0xc400000000, 0xc2, 0x186)
... ...
main.main()
    elasticsearch_logging_discovery.go:60 +0xb53

[2017-03-02 03:59:42,587][INFO ][node                     ] [elasticsearch-logging-v1-3bzt6] version[2.4.1], pid[16], build[c67dc32/2016-09-27T18:57:55Z]
[2017-03-02 03:59:42,588][INFO ][node                     ] [elasticsearch-logging-v1-3bzt6] initializing ...
[2017-03-02 03:59:44,396][INFO ][plugins                  ] [elasticsearch-logging-v1-3bzt6] modules [reindex, lang-expression, lang-groovy], plugins [], sites []
... ...
[2017-03-02 03:59:44,441][INFO ][env                      ] [elasticsearch-logging-v1-3bzt6] heap size [1007.3mb], compressed ordinary object pointers [true]
[2017-03-02 03:59:48,355][INFO ][node                     ] [elasticsearch-logging-v1-3bzt6] initialized
[2017-03-02 03:59:48,355][INFO ][node                     ] [elasticsearch-logging-v1-3bzt6] starting ...
[2017-03-02 03:59:48,507][INFO ][transport                ] [elasticsearch-logging-v1-3bzt6] publish_address {172.16.57.8:9300}, bound_addresses {[::]:9300}
[2017-03-02 03:59:48,547][INFO ][discovery                ] [elasticsearch-logging-v1-3bzt6] kubernetes-logging/7_f_M2TKRZWOw4NhBc4EqA
[2017-03-02 04:00:18,552][WARN ][discovery                ] [elasticsearch-logging-v1-3bzt6] waited for 30s and no initial state was set by the discovery
[2017-03-02 04:00:18,562][INFO ][http                     ] [elasticsearch-logging-v1-3bzt6] publish_address {172.16.57.8:9200}, bound_addresses {[::]:9200}
[2017-03-02 04:00:18,562][INFO ][node                     ] [elasticsearch-logging-v1-3bzt6] started
[2017-03-02 04:01:15,754][WARN ][discovery.zen.ping.unicast] [elasticsearch-logging-v1-3bzt6] failed to send ping to [{#zen_unicast_1#}{127.0.0.1}{127.0.0.1:9300}]
SendRequestTransportException[[][127.0.0.1:9300][internal:discovery/zen/unicast]]; nested: NodeNotConnectedException[[][127.0.0.1:9300] Node not connected];
... ...
Caused by: NodeNotConnectedException[[][127.0.0.1:9300] Node not connected]
    at org.elasticsearch.transport.netty.NettyTransport.nodeChannel(NettyTransport.java:1141)
    at org.elasticsearch.transport.netty.NettyTransport.sendRequest(NettyTransport.java:830)
    at org.elasticsearch.transport.TransportService.sendRequest(TransportService.java:329)
    ... 12 more

总结了一下，日志中有两个错误：
- 无法访问到API Server，这个似乎和fluentd最初的问题一样；
- elasticsearch两个节点间互ping失败。

要想找到这两个问题的原因，还得回到源头，去分析elastic search image的组成。

通过cluster/addons/fluentd-elasticsearch/es-image/run.sh文件内容：

/elasticsearch_logging_discovery >> /elasticsearch/config/elasticsearch.yml

chown -R elasticsearch:elasticsearch /data

/bin/su -c /elasticsearch/bin/elasticsearch elasticsearch

我们了解到image中，其实包含了两个程序，一个为/elasticsearch_logging_discovery，该程序执行后生成一个配置文件： /elasticsearch/config/elasticsearch.yml。该配置文件后续被另外一个程序：/elasticsearch/bin/elasticsearch使用。

我们查看一下已经运行的docker中的elasticsearch.yml文件内容：

# docker exec 3cad31f6eb08 cat /elasticsearch/config/elasticsearch.yml
cluster.name: kubernetes-logging

node.name: ${NODE_NAME}
node.master: ${NODE_MASTER}
node.data: ${NODE_DATA}

transport.tcp.port: ${TRANSPORT_PORT}
http.port: ${HTTP_PORT}

path.data: /data

network.host: 0.0.0.0

discovery.zen.minimum_master_nodes: ${MINIMUM_MASTER_NODES}
discovery.zen.ping.multicast.enabled: false

这个结果中缺少了一项：

discovery.zen.ping.unicast.hosts: ["172.30.0.11", "172.30.192.15"]

这也是导致第二个问题的原因。综上，elasticsearch logging的错误其实都是由于/elasticsearch_logging_discovery无法访问API Server导致 /elasticsearch/config/elasticsearch.yml没有被正确生成造成的，我们就来解决这个问题。

我查看了一下/elasticsearch_logging_discovery的源码，elasticsearch_logging_discovery是一个典型通过client-go通过service account访问API Server的程序，很显然这就是我在《在Kubernetes Pod中使用Service Account访问API Server》一文中提到的那个问题：默认的service account不好用。

解决方法：在kube-system namespace下创建一个新的service account资源，并在es-controller.yaml中显式使用该新创建的service account。

创建一个新的serviceaccount在kube-system namespace下：

//serviceaccount.yaml
apiVersion: v1
kind: ServiceAccount
metadata:
  name: k8s-efk

# kubectl create -f serviceaccount.yaml -n kube-system
serviceaccount "k8s-efk" created

# kubectl get serviceaccount -n kube-system
NAME      SECRETS   AGE
default   1         139d
k8s-efk   1         17s

在es-controller.yaml中，使用service account “k8s-efk”：

//es-controller.yaml
... ...
spec:
  replicas: 2
  selector:
    k8s-app: elasticsearch-logging
    version: v1
  template:
    metadata:
      labels:
        k8s-app: elasticsearch-logging
        version: v1
        kubernetes.io/cluster-service: "true"
    spec:
      serviceAccount: k8s-efk
      containers:
... ...

重新创建elasticsearch logging service后，我们再来查看elasticsearch-logging pod的日志：

# kubectl logs -f elasticsearch-logging-v1-dklui -n kube-system
[2017-03-02 08:26:46,500][INFO ][node                     ] [elasticsearch-logging-v1-dklui] version[2.4.1], pid[14], build[c67dc32/2016-09-27T18:57:55Z]
[2017-03-02 08:26:46,504][INFO ][node                     ] [elasticsearch-logging-v1-dklui] initializing ...
[2017-03-02 08:26:47,984][INFO ][plugins                  ] [elasticsearch-logging-v1-dklui] modules [reindex, lang-expression, lang-groovy], plugins [], sites []
[2017-03-02 08:26:48,073][INFO ][env                      ] [elasticsearch-logging-v1-dklui] using [1] data paths, mounts [[/data (/dev/vda1)]], net usable_space [16.9gb], net total_space [39.2gb], spins? [possibly], types [ext4]
[2017-03-02 08:26:48,073][INFO ][env                      ] [elasticsearch-logging-v1-dklui] heap size [1007.3mb], compressed ordinary object pointers [true]
[2017-03-02 08:26:53,241][INFO ][node                     ] [elasticsearch-logging-v1-dklui] initialized
[2017-03-02 08:26:53,241][INFO ][node                     ] [elasticsearch-logging-v1-dklui] starting ...
[2017-03-02 08:26:53,593][INFO ][transport                ] [elasticsearch-logging-v1-dklui] publish_address {172.16.57.8:9300}, bound_addresses {[::]:9300}
[2017-03-02 08:26:53,651][INFO ][discovery                ] [elasticsearch-logging-v1-dklui] kubernetes-logging/Ky_OuYqMRkm_918aHRtuLg
[2017-03-02 08:26:56,736][INFO ][cluster.service          ] [elasticsearch-logging-v1-dklui] new_master {elasticsearch-logging-v1-dklui}{Ky_OuYqMRkm_918aHRtuLg}{172.16.57.8}{172.16.57.8:9300}{master=true}, added {{elasticsearch-logging-v1-vjxm3}{cbzgrfZATyWkHfQYHZhs7Q}{172.16.99.10}{172.16.99.10:9300}{master=true},}, reason: zen-disco-join(elected_as_master, [1] joins received)
[2017-03-02 08:26:56,955][INFO ][http                     ] [elasticsearch-logging-v1-dklui] publish_address {172.16.57.8:9200}, bound_addresses {[::]:9200}
[2017-03-02 08:26:56,956][INFO ][node                     ] [elasticsearch-logging-v1-dklui] started
[2017-03-02 08:26:57,157][INFO ][gateway                  ] [elasticsearch-logging-v1-dklui] recovered [0] indices into cluster_state
[2017-03-02 08:27:05,378][INFO ][cluster.metadata         ] [elasticsearch-logging-v1-dklui] [logstash-2017.03.02] creating index, cause [auto(bulk api)], templates [], shards [5]/[1], mappings []
[2017-03-02 08:27:06,360][INFO ][cluster.metadata         ] [elasticsearch-logging-v1-dklui] [logstash-2017.03.01] creating index, cause [auto(bulk api)], templates [], shards [5]/[1], mappings []
[2017-03-02 08:27:07,163][INFO ][cluster.routing.allocation] [elasticsearch-logging-v1-dklui] Cluster health status changed from [RED] to [YELLOW] (reason: [shards started [[logstash-2017.03.01][3], [logstash-2017.03.01][3]] ...]).
[2017-03-02 08:27:07,354][INFO ][cluster.metadata         ] [elasticsearch-logging-v1-dklui] [logstash-2017.03.02] create_mapping [fluentd]
[2017-03-02 08:27:07,988][INFO ][cluster.metadata         ] [elasticsearch-logging-v1-dklui] [logstash-2017.03.01] create_mapping [fluentd]
[2017-03-02 08:27:09,578][INFO ][cluster.routing.allocation] [elasticsearch-logging-v1-dklui] Cluster health status changed from [YELLOW] to [GREEN] (reason: [shards started [[logstash-2017.03.02][4]] ...]).

elasticsearch logging启动运行ok！

五、启动kibana

有了elasticsearch logging的“前车之鉴”，这次我们也把上面新创建的serviceaccount：k8s-efk显式赋值给kibana-controller.yaml:

//kibana-controller.yaml
... ...
spec:
      serviceAccount: k8s-efk
      containers:
      - name: kibana-logging
        image: bigwhite/kibana:v4.6.1-1
        resources:
          # keep request = limit to keep this container in guaranteed class
          limits:
            cpu: 100m
          #requests:
          #  cpu: 100m
        env:
          - name: "ELASTICSEARCH_URL"
            value: "http://elasticsearch-logging:9200"
          - name: "KIBANA_BASE_URL"
            value: "/api/v1/proxy/namespaces/kube-system/services/kibana-logging"
        ports:
        - containerPort: 5601
          name: ui
          protocol: TCP
... ...

启动kibana，并观察pod日志：

# kubectl create -f kibana-controller.yaml
# kubectl create -f kibana-service.yaml
# kubectl logs -f kibana-logging-3604961973-jby53 -n kube-system
ELASTICSEARCH_URL=http://elasticsearch-logging:9200
server.basePath: /api/v1/proxy/namespaces/kube-system/services/kibana-logging
{"type":"log","@timestamp":"2017-03-02T08:30:15Z","tags":["info","optimize"],"pid":6,"message":"Optimizing and caching bundles for kibana and statusPage. This may take a few minutes"}

kibana缓存着实需要一段时间，请耐心等待！可能是几分钟。之后你将会看到如下日志：

# kubectl logs -f kibana-logging-3604961973-jby53 -n kube-system
ELASTICSEARCH_URL=http://elasticsearch-logging:9200
server.basePath: /api/v1/proxy/namespaces/kube-system/services/kibana-logging
{"type":"log","@timestamp":"2017-03-02T08:30:15Z","tags":["info","optimize"],"pid":6,"message":"Optimizing and caching bundles for kibana and statusPage. This may take a few minutes"}
{"type":"log","@timestamp":"2017-03-02T08:40:04Z","tags":["info","optimize"],"pid":6,"message":"Optimization of bundles for kibana and statusPage complete in 588.60 seconds"}
{"type":"log","@timestamp":"2017-03-02T08:40:04Z","tags":["status","plugin:kibana@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:05Z","tags":["status","plugin:elasticsearch@1.0.0","info"],"pid":6,"state":"yellow","message":"Status changed from uninitialized to yellow - Waiting for Elasticsearch","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:05Z","tags":["status","plugin:kbn_vislib_vis_types@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:05Z","tags":["status","plugin:markdown_vis@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:05Z","tags":["status","plugin:metric_vis@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:06Z","tags":["status","plugin:spyModes@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:06Z","tags":["status","plugin:statusPage@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:06Z","tags":["status","plugin:table_vis@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from uninitialized to green - Ready","prevState":"uninitialized","prevMsg":"uninitialized"}
{"type":"log","@timestamp":"2017-03-02T08:40:06Z","tags":["listening","info"],"pid":6,"message":"Server running at http://0.0.0.0:5601"}
{"type":"log","@timestamp":"2017-03-02T08:40:11Z","tags":["status","plugin:elasticsearch@1.0.0","info"],"pid":6,"state":"yellow","message":"Status changed from yellow to yellow - No existing Kibana index found","prevState":"yellow","prevMsg":"Waiting for Elasticsearch"}
{"type":"log","@timestamp":"2017-03-02T08:40:14Z","tags":["status","plugin:elasticsearch@1.0.0","info"],"pid":6,"state":"green","message":"Status changed from yellow to green - Kibana index ready","prevState":"yellow","prevMsg":"No existing Kibana index found"}

接下来，通过浏览器访问下面地址就可以访问kibana的web页面了，注意：Kinaba的web页面加载也需要一段时间。

https://{API Server external IP}:{API Server secure port}/api/v1/proxy/namespaces/kube-system/services/kibana-logging/app/kibana#/settings/indices/

下面是创建一个index（相当于mysql中的一个database）页面：

取消“Index contains time-based events”，然后点击“Create”即可创建一个Index。

点击页面上的”Setting” -> “Status”，可以查看当前elasticsearch logging的整体状态，如果一切ok，你将会看到下图这样的页面：

创建Index后，可以在Discover下看到ElasticSearch logging中汇聚的日志：

六、小结

以上就是在Kubernetes 1.3.7集群上安装Fluentd和ElasticSearch stack，实现kubernetes cluster level logging的过程。在使用kubeadm安装的Kubernetes 1.5.1环境下安装这些，则基本不会遇到上述这些问题。

另外ElasticSearch logging默认挂载的volume是emptyDir，实验用可以。但要部署在生产环境，必须换成Persistent Volume，比如：CephRBD。

当前手上有两个Kubernetes cluster，一个是采用kube-up.sh安装的k8s 1.3.7版本，另外一个则是采用kubeadm安装的k8s 1.5.1版本。由于1.3.7版本安装在前，并且目前它也是承载了我们PaaS平台的环境，因此对于这个版本的Kubernetes安装环境、配置操作、日志查看、集群操作等相对较为熟悉。而Kubeadm安装的1.5.1版本K8s集群在组件部署、配置、日志等诸多方面与1.3.7版本有了较大差异。刚上手的时候，你会发现你原来所熟知的1.3.7的东西都不在原先的位置上了。估计很多和我一样，采用kubeadm将集群升级到1.5.1版本的朋友们都会遇到这类问题，于是这里打算对Kubeadm方式安装的Kubernetes集群进行一些小小的探索，把一些变动较大的点列出来，供大家参考。

一、环境

这里使用的依然是文章《使用Kubeadm安装Kubernetes》中安装完毕的Kubernetes 1.5.1集群环境，底层是阿里云ECS，操作系统是Ubuntu 16.04.1。网络用的是weave network。

试验集群只有两个Node：一个master node和一个minion node。但Master node由于被taint了，因此它与minion node一样参与集群调度和承担负载。

二、核心组件的Pod化

Kubeadm安装的k8s集群与kube-up.sh安装集群相比，最大的不同应该算是kubernetes核心组件的Pod化，即：kube-apiserver、kube-controller-manager、kube-scheduler、kube-proxy、kube-discovery以及etcd等核心组件都运行在集群中的Pod里的，这颇有些CoreOS的风格。只有一个组件是例外的，那就是负责在node上与本地容器引擎交互的Kubelet。

K8s的核心组件Pod均放在kube-system namespace中，通过kubectl(on master node)可以查看到：

# kubectl get pods -n kube-system
NAME                                    READY     STATUS    RESTARTS   AGE
etcd-iz25beglnhtz                       1/1       Running   2          26d
kube-apiserver-iz25beglnhtz             1/1       Running   3          26d
kube-controller-manager-iz25beglnhtz    1/1       Running   2          26d
kube-scheduler-iz25beglnhtz             1/1       Running   4          26d
... ...

另外细心的朋友可能会发现，这些核心组建的Pod名字均以所在Node的主机名为结尾，比如：kube-apiserver-iz25beglnhtz中的”iz25beglnhtz”就是其所在Node的主机名。

不过，即便这些核心组件是一个容器的形式运行在集群中，组件所使用网络依然是所在Node的主机网络，而不是Pod Network：

# docker ps|grep apiserver
98ea64bbf6c8        gcr.io/google_containers/kube-apiserver-amd64:v1.5.1            "kube-apiserver --ins"   10 days ago         Up 10 days                              k8s_kube-apiserver.6c2e367b_kube-apiserver-iz25beglnhtz_kube-system_033de1afc0844729cff5e100eb700a81_557d1fb2
4f87d22b8334        gcr.io/google_containers/pause-amd64:3.0                        "/pause"                 10 days ago         Up 10 days                              k8s_POD.d8dbe16c_kube-apiserver-iz25beglnhtz_kube-system_033de1afc0844729cff5e100eb700a81_5931e490

# docker inspect 98ea64bbf6c8
... ...
"HostConfig": {
"NetworkMode": "container:4f87d22b833425082be55851d72268023d41b50649e46c738430d9dfd3abea11",
}
... ...

# docker inspect 4f87d22b833425082be55851d72268023d41b50649e46c738430d9dfd3abea11
... ...
"HostConfig": {
"NetworkMode": "host",
}
... ...

从上面docker inspect的输出可以看出kube-apiserver pod里面的pause容器采用的网络模式是host网络，而以pause容器网络为基础的kube-apiserver 容器显然就继承了这一network namespace。因此从外面看，访问Kube-apiserver这样的组件和以前没什么两样：在Master node上可以通过localhost:8080访问；在Node外，可以通过master_node_ip:6443端口访问。

三、核心组件启动配置调整

在kube-apiserver等核心组件还是以本地程序运行在物理机上的时代，修改kube-apiserver的启动参数，比如修改一下–service-node-port-range的范围、添加一个–basic-auth-file等，我们都可以通过直接修改/etc/default/kube-apiserver(以Ubuntu 14.04为例)文件的内容并重启kube-apiserver service(service restart kube-apiserver)的方式实现。其他核心组件：诸如：kube-controller-manager、kube-proxy和kube-scheduler均是如此。

但在kubeadm时代，这些配置文件不再存在，取而代之的是和用户Pod描述文件类似的manifest文件(都放置在/etc/kubernetes/manifests下面)：

/etc/kubernetes/manifests# ls
etcd.json  kube-apiserver.json  kube-controller-manager.json  kube-scheduler.json

我们以为kube-apiserver增加一个启动参数：”–service-node-port-range=80-32767″ 为例：

打开并编辑/etc/kubernetes/manifests/kube-apiserver.json，在“command字段对应的值中添加”–service-node-port-range=80-32767″：

"containers": [
      {
        "name": "kube-apiserver",
        "image": "gcr.io/google_containers/kube-apiserver-amd64:v1.5.1",
        "command": [
          "kube-apiserver",
          "--insecure-bind-address=127.0.0.1",
          "--admission-control=NamespaceLifecycle,LimitRanger,ServiceAccount,PersistentVolumeLabel,DefaultStorageClass,ResourceQuota",
          "--service-cluster-ip-range=10.96.0.0/12",
          "--service-account-key-file=/etc/kubernetes/pki/apiserver-key.pem",
          "--client-ca-file=/etc/kubernetes/pki/ca.pem",
          "--tls-cert-file=/etc/kubernetes/pki/apiserver.pem",
          "--tls-private-key-file=/etc/kubernetes/pki/apiserver-key.pem",
          "--token-auth-file=/etc/kubernetes/pki/tokens.csv",
          "--secure-port=6443",
          "--allow-privileged",
          "--advertise-address=10.47.217.91",
          "--kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname",
          "--anonymous-auth=false",
          "--etcd-servers=http://127.0.0.1:2379",
          "--service-node-port-range=80-32767"
        ],

注意：不要忘记在–etcd-servers这一行后面添加一个逗号，否则kube-apiserver会退出。

修改后，你会发现kube-apiserver会被自动重启。这是kubelet的功劳。kubelet在启动时监听/etc/kubernetes/manifests目录下的文件变化并做适当处理：

# ps -ef|grep kubelet
root      1633     1  5  2016 ?        1-09:24:47 /usr/bin/kubelet --kubeconfig=/etc/kubernetes/kubelet.conf --require-kubeconfig=true --pod-manifest-path=/etc/kubernetes/manifests --allow-privileged=true --network-plugin=cni --cni-conf-dir=/etc/cni/net.d --cni-bin-dir=/opt/cni/bin --cluster-dns=10.96.0.10 --cluster-domain=cluster.local

kubelet自身是一个systemd的service，它的启动配置可以通过下面文件修改：

# cat /etc/systemd/system/kubelet.service.d/10-kubeadm.conf
[Service]
Environment="KUBELET_KUBECONFIG_ARGS=--kubeconfig=/etc/kubernetes/kubelet.conf --require-kubeconfig=true"
Environment="KUBELET_SYSTEM_PODS_ARGS=--pod-manifest-path=/etc/kubernetes/manifests --allow-privileged=true"
Environment="KUBELET_NETWORK_ARGS=--network-plugin=cni --cni-conf-dir=/etc/cni/net.d --cni-bin-dir=/opt/cni/bin"
Environment="KUBELET_DNS_ARGS=--cluster-dns=10.96.0.10 --cluster-domain=cluster.local"
ExecStart=
ExecStart=/usr/bin/kubelet $KUBELET_KUBECONFIG_ARGS $KUBELET_SYSTEM_PODS_ARGS $KUBELET_NETWORK_ARGS $KUBELET_DNS_ARGS $KUBELET_EXTRA_ARGS

四、kubectl的配置

kube-up.sh安装的k8s集群会在每个Node上的~/.kube/下创建config文件，用于kubectl访问apiserver和操作集群使用。但在kubeadm模式下，~/.kube/下面的内容变成了：

~/.kube# ls
cache/  schema/

于是有了问题1：config哪里去了？

之所以在master node上我们的kubectl依旧可以工作，那是因为默认kubectl会访问localhost:8080来与kube-apiserver交互。如果kube-apiserver没有关闭–insecure-port，那么kubectl便可以正常与kube-apiserver交互，因为–insecure-port是没有任何校验机制的。

于是又了问题2：如果是其他node上的kubectl与kube-apiserver通信或者master node上的kubectl通过secure port与kube-apiserver通信，应该如何配置？

接下来，我们一并来回答上面两个问题。kubeadm在创建集群时，在master node的/etc/kubernetes下面创建了两个文件：

/etc/kubernetes# ls -l
total 32
-rw------- 1 root root 9188 Dec 28 17:32 admin.conf
-rw------- 1 root root 9188 Dec 28 17:32 kubelet.conf
... ...

这两个文件的内容是完全一样的，仅从文件名可以看出是谁在使用。比如kubelet.conf这个文件，我们就在kubelet程序的启动参数中看到过：–kubeconfig=/etc/kubernetes/kubelet.conf

# ps -ef|grep kubelet
root      1633     1  5  2016 ?        1-09:26:41 /usr/bin/kubelet --kubeconfig=/etc/kubernetes/kubelet.conf --require-kubeconfig=true --pod-manifest-path=/etc/kubernetes/manifests --allow-privileged=true --network-plugin=cni --cni-conf-dir=/etc/cni/net.d --cni-bin-dir=/opt/cni/bin --cluster-dns=10.96.0.10 --cluster-domain=cluster.local

打开这个文件，你会发现这就是一个kubeconfig文件，文件内容较长，我们通过kubectl config view来查看一下这个文件的结构：

# kubectl --kubeconfig /etc/kubernetes/kubelet.conf config view
apiVersion: v1
clusters:
- cluster:
    certificate-authority-data: REDACTED
    server: https://{master node local ip}:6443
  name: kubernetes
contexts:
- context:
    cluster: kubernetes
    user: admin
  name: admin@kubernetes
- context:
    cluster: kubernetes
    user: kubelet
  name: kubelet@kubernetes
current-context: admin@kubernetes
kind: Config
preferences: {}
users:
- name: admin
  user:
    client-certificate-data: REDACTED
    client-key-data: REDACTED
- name: kubelet
  user:
    client-certificate-data: REDACTED
    client-key-data: REDACTED

这和我们在《Kubernetes集群Dashboard插件安装》一文中介绍的kubeconfig文件内容并不二致。不同之处就是“REDACTED”这个字样的值，我们对应到kubelet.conf中，发现每个REDACTED字样对应的都是一段数据，这段数据是由对应的数字证书内容或密钥内容转换(base64)而来的，在访问apiserver时会用到。

我们在minion node上测试一下：

minion node：

# kubectl get pods
The connection to the server localhost:8080 was refused - did you specify the right host or port?

# kubectl --kubeconfig /etc/kubernetes/kubelet.conf get pods
NAME                         READY     STATUS    RESTARTS   AGE
my-nginx-1948696469-359d6    1/1       Running   2          26d
my-nginx-1948696469-3g0n7    1/1       Running   3          26d
my-nginx-1948696469-xkzsh    1/1       Running   2          26d
my-ubuntu-2560993602-5q7q5   1/1       Running   2          26d
my-ubuntu-2560993602-lrrh0   1/1       Running   2          26d

kubeadm创建k8s集群时，会在master node上创建一些用于组件间访问的证书、密钥和token文件，上面的kubeconfig中的“REDACTED”所代表的内容就是从这些文件转化而来的：

/etc/kubernetes/pki# ls
apiserver-key.pem  apiserver.pem  apiserver-pub.pem  ca-key.pem  ca.pem  ca-pub.pem  sa-key.pem  sa-pub.pem  tokens.csv

• apiserver-key.pem：kube-apiserver的私钥文件
• apiserver.pem：kube-apiserver的公钥证书
• apiserver-pub.pem kube-apiserver的公钥文件
• ca-key.pem：CA的私钥文件
• ca.pem：CA的公钥证书
• ca-pub.pem ：CA的公钥文件
• sa-key.pem ：serviceaccount私钥文件
• sa-pub.pem ：serviceaccount的公钥文件
• tokens.csv：kube-apiserver用于校验的token文件

在k8s各核心组件的启动参数中会看到上面文件的身影，比如：

 kube-apiserver --insecure-bind-address=127.0.0.1 --admission-control=NamespaceLifecycle,LimitRanger,ServiceAccount,PersistentVolumeLabel,DefaultStorageClass,ResourceQuota --service-cluster-ip-range=10.96.0.0/12 --service-account-key-file=/etc/kubernetes/pki/apiserver-key.pem --client-ca-file=/etc/kubernetes/pki/ca.pem --tls-cert-file=/etc/kubernetes/pki/apiserver.pem --tls-private-key-file=/etc/kubernetes/pki/apiserver-key.pem --token-auth-file=/etc/kubernetes/pki/tokens.csv --secure-port=6443 --allow-privileged --advertise-address={master node local ip} --kubelet-preferred-address-types=InternalIP,ExternalIP,Hostname --anonymous-auth=false --etcd-servers=http://127.0.0.1:2379 --service-node-port-range=80-32767

我们还可以在minion node上通过curl还手工测试一下通过安全通道访问master node上的kube-apiserver。在《Kubernetes集群的安全配置》一文中，我们提到过k8s的authentication（包括：客户端证书认证、basic auth、static token等）只要通过其中一个即可。当前kube-apiserver开启了客户端证书认证（–client-ca-file）和static token验证(–token-auth-file)，我们只要通过其中一个，就可以通过authentication，于是我们使用static token方式。static token file的内容格式：

token,user,uid,"group1,group2,group3"

对应到master node上的tokens.csv

# cat /etc/kubernetes/pki/tokens.csv
{token},{user},812ffe41-cce0-11e6-9bd3-00163e1001d7,system:kubelet-bootstrap

我们用这个token通过curl与apiserver交互：

# curl --cacert /etc/kubernetes/pki/ca.pem -H "Authorization: Bearer {token}"  https://{master node local ip}:6443
{
  "paths": [
    "/api",
    "/api/v1",
    "/apis",
    "/apis/apps",
    "/apis/apps/v1beta1",
    "/apis/authentication.k8s.io",
    "/apis/authentication.k8s.io/v1beta1",
    "/apis/authorization.k8s.io",
    "/apis/authorization.k8s.io/v1beta1",
    "/apis/autoscaling",
    "/apis/autoscaling/v1",
    "/apis/batch",
    "/apis/batch/v1",
    "/apis/batch/v2alpha1",
    "/apis/certificates.k8s.io",
    "/apis/certificates.k8s.io/v1alpha1",
    "/apis/extensions",
    "/apis/extensions/v1beta1",
    "/apis/policy",
    "/apis/policy/v1beta1",
    "/apis/rbac.authorization.k8s.io",
    "/apis/rbac.authorization.k8s.io/v1alpha1",
    "/apis/storage.k8s.io",
    "/apis/storage.k8s.io/v1beta1",
    "/healthz",
    "/healthz/poststarthook/bootstrap-controller",
    "/healthz/poststarthook/extensions/third-party-resources",
    "/healthz/poststarthook/rbac/bootstrap-roles",
    "/logs",
    "/metrics",
    "/swaggerapi/",
    "/ui/",
    "/version"
  ]
}

交互成功！