github.com/iamlotus/docker@v1.8.1/docs/userguide/dockerlinks.md (about) 1 <!--[metadata]> 2 +++ 3 title = "Linking containers together" 4 description = "Learn how to connect Docker containers together." 5 keywords = ["Examples, Usage, user guide, links, linking, docker, documentation, examples, names, name, container naming, port, map, network port, network"] 6 [menu.main] 7 parent = "smn_containers" 8 weight = 4 9 +++ 10 <![end-metadata]--> 11 12 # Linking containers together 13 14 In [the Using Docker section](/userguide/usingdocker), you saw how you can 15 connect to a service running inside a Docker container via a network 16 port. But a port connection is only one way you can interact with services and 17 applications running inside Docker containers. In this section, we'll briefly revisit 18 connecting via a network port and then we'll introduce you to another method of access: 19 container linking. 20 21 ## Connect using network port mapping 22 23 In [the Using Docker section](/userguide/usingdocker), you created a 24 container that ran a Python Flask application: 25 26 $ docker run -d -P training/webapp python app.py 27 28 > **Note:** 29 > Containers have an internal network and an IP address 30 > (as we saw when we used the `docker inspect` command to show the container's 31 > IP address in the [Using Docker](/userguide/usingdocker/) section). 32 > Docker can have a variety of network configurations. You can see more 33 > information on Docker networking [here](/articles/networking/). 34 35 When that container was created, the `-P` flag was used to automatically map 36 any network port inside it to a random high port within an *ephemeral port 37 range* on your Docker host. Next, when `docker ps` was run, you saw that port 38 5000 in the container was bound to port 49155 on the host. 39 40 $ docker ps nostalgic_morse 41 CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES 42 bc533791f3f5 training/webapp:latest python app.py 5 seconds ago Up 2 seconds 0.0.0.0:49155->5000/tcp nostalgic_morse 43 44 You also saw how you can bind a container's ports to a specific port using 45 the `-p` flag. Here port 80 of the host is mapped to port 5000 of the 46 container: 47 48 $ docker run -d -p 80:5000 training/webapp python app.py 49 50 And you saw why this isn't such a great idea because it constrains you to 51 only one container on that specific port. 52 53 There are also a few other ways you can configure the `-p` flag. By 54 default the `-p` flag will bind the specified port to all interfaces on 55 the host machine. But you can also specify a binding to a specific 56 interface, for example only to the `localhost`. 57 58 $ docker run -d -p 127.0.0.1:80:5000 training/webapp python app.py 59 60 This would bind port 5000 inside the container to port 80 on the 61 `localhost` or `127.0.0.1` interface on the host machine. 62 63 Or, to bind port 5000 of the container to a dynamic port but only on the 64 `localhost`, you could use: 65 66 $ docker run -d -p 127.0.0.1::5000 training/webapp python app.py 67 68 You can also bind UDP ports by adding a trailing `/udp`. For example: 69 70 $ docker run -d -p 127.0.0.1:80:5000/udp training/webapp python app.py 71 72 You also learned about the useful `docker port` shortcut which showed us the 73 current port bindings. This is also useful for showing you specific port 74 configurations. For example, if you've bound the container port to the 75 `localhost` on the host machine, then the `docker port` output will reflect that. 76 77 $ docker port nostalgic_morse 5000 78 127.0.0.1:49155 79 80 > **Note:** 81 > The `-p` flag can be used multiple times to configure multiple ports. 82 83 ## Connect with the linking system 84 85 Network port mappings are not the only way Docker containers can connect 86 to one another. Docker also has a linking system that allows you to link 87 multiple containers together and send connection information from one to another. 88 When containers are linked, information about a source container can be sent to a 89 recipient container. This allows the recipient to see selected data describing 90 aspects of the source container. 91 92 ### The importance of naming 93 94 To establish links, Docker relies on the names of your containers. 95 You've already seen that each container you create has an automatically 96 created name; indeed you've become familiar with our old friend 97 `nostalgic_morse` during this guide. You can also name containers 98 yourself. This naming provides two useful functions: 99 100 1. It can be useful to name containers that do specific functions in a way 101 that makes it easier for you to remember them, for example naming a 102 container containing a web application `web`. 103 104 2. It provides Docker with a reference point that allows it to refer to other 105 containers, for example, you can specify to link the container `web` to container `db`. 106 107 You can name your container by using the `--name` flag, for example: 108 109 $ docker run -d -P --name web training/webapp python app.py 110 111 This launches a new container and uses the `--name` flag to 112 name the container `web`. You can see the container's name using the 113 `docker ps` command. 114 115 $ docker ps -l 116 CONTAINER ID IMAGE COMMAND CREATED STATUS PORTS NAMES 117 aed84ee21bde training/webapp:latest python app.py 12 hours ago Up 2 seconds 0.0.0.0:49154->5000/tcp web 118 119 You can also use `docker inspect` to return the container's name. 120 121 122 > **Note:** 123 > Container names have to be unique. That means you can only call 124 > one container `web`. If you want to re-use a container name you must delete 125 > the old container (with `docker rm`) before you can create a new 126 > container with the same name. As an alternative you can use the `--rm` 127 > flag with the `docker run` command. This will delete the container 128 > immediately after it is stopped. 129 130 ## Communication across links 131 132 Links allow containers to discover each other and securely transfer information about one 133 container to another container. When you set up a link, you create a conduit between a 134 source container and a recipient container. The recipient can then access select data 135 about the source. To create a link, you use the `--link` flag. First, create a new 136 container, this time one containing a database. 137 138 $ docker run -d --name db training/postgres 139 140 This creates a new container called `db` from the `training/postgres` 141 image, which contains a PostgreSQL database. 142 143 Now, you need to delete the `web` container you created previously so you can replace it 144 with a linked one: 145 146 $ docker rm -f web 147 148 Now, create a new `web` container and link it with your `db` container. 149 150 $ docker run -d -P --name web --link db:db training/webapp python app.py 151 152 This will link the new `web` container with the `db` container you created 153 earlier. The `--link` flag takes the form: 154 155 --link <name or id>:alias 156 157 Where `name` is the name of the container we're linking to and `alias` is an 158 alias for the link name. You'll see how that alias gets used shortly. 159 The `--link` flag also takes the form: 160 161 --link <name or id> 162 163 In which case the alias will match the name. You could have written the previous 164 example as: 165 166 $ docker run -d -P --name web --link db training/webapp python app.py 167 168 Next, inspect your linked containers with `docker inspect`: 169 170 $ docker inspect -f "{{ .HostConfig.Links }}" web 171 [/db:/web/db] 172 173 You can see that the `web` container is now linked to the `db` container 174 `web/db`. Which allows it to access information about the `db` container. 175 176 So what does linking the containers actually do? You've learned that a link allows a 177 source container to provide information about itself to a recipient container. In 178 our example, the recipient, `web`, can access information about the source `db`. To do 179 this, Docker creates a secure tunnel between the containers that doesn't need to 180 expose any ports externally on the container; you'll note when we started the 181 `db` container we did not use either the `-P` or `-p` flags. That's a big benefit of 182 linking: we don't need to expose the source container, here the PostgreSQL database, to 183 the network. 184 185 Docker exposes connectivity information for the source container to the 186 recipient container in two ways: 187 188 * Environment variables, 189 * Updating the `/etc/hosts` file. 190 191 ### Environment variables 192 193 Docker creates several environment variables when you link containers. Docker 194 automatically creates environment variables in the target container based on 195 the `--link` parameters. It will also expose all environment variables 196 originating from Docker from the source container. These include variables from: 197 198 * the `ENV` commands in the source container's Dockerfile 199 * the `-e`, `--env` and `--env-file` options on the `docker run` 200 command when the source container is started 201 202 These environment variables enable programmatic discovery from within the 203 target container of information related to the source container. 204 205 > **Warning**: 206 > It is important to understand that *all* environment variables originating 207 > from Docker within a container are made available to *any* container 208 > that links to it. This could have serious security implications if sensitive 209 > data is stored in them. 210 211 Docker sets an `<alias>_NAME` environment variable for each target container 212 listed in the `--link` parameter. For example, if a new container called 213 `web` is linked to a database container called `db` via `--link db:webdb`, 214 then Docker creates a `WEBDB_NAME=/web/webdb` variable in the `web` container. 215 216 Docker also defines a set of environment variables for each port exposed by the 217 source container. Each variable has a unique prefix in the form: 218 219 `<name>_PORT_<port>_<protocol>` 220 221 The components in this prefix are: 222 223 * the alias `<name>` specified in the `--link` parameter (for example, `webdb`) 224 * the `<port>` number exposed 225 * a `<protocol>` which is either TCP or UDP 226 227 Docker uses this prefix format to define three distinct environment variables: 228 229 * The `prefix_ADDR` variable contains the IP Address from the URL, for 230 example `WEBDB_PORT_8080_TCP_ADDR=172.17.0.82`. 231 * The `prefix_PORT` variable contains just the port number from the URL for 232 example `WEBDB_PORT_8080_TCP_PORT=8080`. 233 * The `prefix_PROTO` variable contains just the protocol from the URL for 234 example `WEBDB_PORT_8080_TCP_PROTO=tcp`. 235 236 If the container exposes multiple ports, an environment variable set is 237 defined for each one. This means, for example, if a container exposes 4 ports 238 that Docker creates 12 environment variables, 3 for each port. 239 240 Additionally, Docker creates an environment variable called `<alias>_PORT`. 241 This variable contains the URL of the source container's first exposed port. 242 The 'first' port is defined as the exposed port with the lowest number. 243 For example, consider the `WEBDB_PORT=tcp://172.17.0.82:8080` variable. If 244 that port is used for both tcp and udp, then the tcp one is specified. 245 246 Finally, Docker also exposes each Docker originated environment variable 247 from the source container as an environment variable in the target. For each 248 variable Docker creates an `<alias>_ENV_<name>` variable in the target 249 container. The variable's value is set to the value Docker used when it 250 started the source container. 251 252 Returning back to our database example, you can run the `env` 253 command to list the specified container's environment variables. 254 255 ``` 256 $ docker run --rm --name web2 --link db:db training/webapp env 257 . . . 258 DB_NAME=/web2/db 259 DB_PORT=tcp://172.17.0.5:5432 260 DB_PORT_5432_TCP=tcp://172.17.0.5:5432 261 DB_PORT_5432_TCP_PROTO=tcp 262 DB_PORT_5432_TCP_PORT=5432 263 DB_PORT_5432_TCP_ADDR=172.17.0.5 264 . . . 265 ``` 266 267 You can see that Docker has created a series of environment variables with 268 useful information about the source `db` container. Each variable is prefixed 269 with 270 `DB_`, which is populated from the `alias` you specified above. If the `alias` 271 were `db1`, the variables would be prefixed with `DB1_`. You can use these 272 environment variables to configure your applications to connect to the database 273 on the `db` container. The connection will be secure and private; only the 274 linked `web` container will be able to talk to the `db` container. 275 276 ### Important notes on Docker environment variables 277 278 Unlike host entries in the [`/etc/hosts` file](#updating-the-etchosts-file), 279 IP addresses stored in the environment variables are not automatically updated 280 if the source container is restarted. We recommend using the host entries in 281 `/etc/hosts` to resolve the IP address of linked containers. 282 283 These environment variables are only set for the first process in the 284 container. Some daemons, such as `sshd`, will scrub them when spawning shells 285 for connection. 286 287 ### Updating the `/etc/hosts` file 288 289 In addition to the environment variables, Docker adds a host entry for the 290 source container to the `/etc/hosts` file. Here's an entry for the `web` 291 container: 292 293 $ docker run -t -i --rm --link db:webdb training/webapp /bin/bash 294 root@aed84ee21bde:/opt/webapp# cat /etc/hosts 295 172.17.0.7 aed84ee21bde 296 . . . 297 172.17.0.5 webdb 6e5cdeb2d300 db 298 299 You can see two relevant host entries. The first is an entry for the `web` 300 container that uses the Container ID as a host name. The second entry uses the 301 link alias to reference the IP address of the `db` container. In addition to 302 the alias you provide, the linked container's name--if unique from the alias 303 provided to the `--link` parameter--and the linked container's hostname will 304 also be added in `/etc/hosts` for the linked container's IP address. You can ping 305 that host now via any of these entries: 306 307 root@aed84ee21bde:/opt/webapp# apt-get install -yqq inetutils-ping 308 root@aed84ee21bde:/opt/webapp# ping webdb 309 PING webdb (172.17.0.5): 48 data bytes 310 56 bytes from 172.17.0.5: icmp_seq=0 ttl=64 time=0.267 ms 311 56 bytes from 172.17.0.5: icmp_seq=1 ttl=64 time=0.250 ms 312 56 bytes from 172.17.0.5: icmp_seq=2 ttl=64 time=0.256 ms 313 314 > **Note:** 315 > In the example, you'll note you had to install `ping` because it was not included 316 > in the container initially. 317 318 Here, you used the `ping` command to ping the `db` container using its host entry, 319 which resolves to `172.17.0.5`. You can use this host entry to configure an application 320 to make use of your `db` container. 321 322 > **Note:** 323 > You can link multiple recipient containers to a single source. For 324 > example, you could have multiple (differently named) web containers attached to your 325 >`db` container. 326 327 If you restart the source container, the linked containers `/etc/hosts` files 328 will be automatically updated with the source container's new IP address, 329 allowing linked communication to continue. 330 331 $ docker restart db 332 db 333 $ docker run -t -i --rm --link db:db training/webapp /bin/bash 334 root@aed84ee21bde:/opt/webapp# cat /etc/hosts 335 172.17.0.7 aed84ee21bde 336 . . . 337 172.17.0.9 db 338 339 # Next step 340 341 Now that you know how to link Docker containers together, the next step is 342 learning how to manage data, volumes and mounts inside your containers. 343 344 Go to [Managing Data in Containers](/userguide/dockervolumes). 345