Update the LDAP troubleshooting steps so that they are consistent with the rest of the documentaiton, which nowadays expects us to be running netbox via systemd instead of supervisord. Fixes#4504.
* Add tests for rack elevation filtering
* Add q variable to serializers for RackElevationDetailFilterSerializer
* Add code to allow filtering of position on the rack elevation
* Add email testing example
Includes an example provided by Jeremy
* Updated with suggestions
Co-authored-by: Jeremy Stretch <jeremy.stretch@networktocode.com>
There was no documentation to move back into the netbox folder after installing/configuring nginx. You would move into nginx on line 42 then try and figure out why you couldn't copy gunicorn on line 113.
Closes#822: CSV import for device components
* Implement CSV import for netbox-community#822
* Comment out default_return_url until there is a proper target
* Fix the default value of `enabled` when not included in the import
* rear_port is definitely required here
* Power Ports don't have a type (yet)
* Add import for console-ports and console-server-ports
* Add import for device-bays
* Fixes#3341 - Added in-line vlan editing
* Fixes#2160 - Added bulk vlan editing
Inconsequential behaviour changes:
* APISelect can now take "full=True" to return a non-brief set
* Select2 will no group by "group & site, group, site, global" if full=True is set in APISelect
* Closes#2902 - Migrate to systemd from supervisord
* Closes#2902 - Migrate to systemd from supervisord
* Update systemd unit and environment file
* Add gunicorn.conf
* Update documentation and CHANGELOG. Moved parameters around on service file
* Update Gitignore
* Add filter for has local context data
* Broke out filter and form for re-use
* Fix missing StaticSelect2 import
* Fix missing BOOLEAN_WITH_BLANK_CHOICES import
* Fix class resolution
* Fix field ordering
* Fix PEP8 errors
As per the [`README.rst`][1] of `django-cacheops`, if a password is
added to the connection string, it must be in the form
`redis://:password@host:port/db`. Notice the colon, which was missing
from the implementation in [`settings.py`][2].
[1]: 8ad970d55a/README.rst
[2]: 86d5b48007/netbox/netbox/settings.py (L349)
Include the full path for the ?next= variable in login links if we are not on the logon page.
Additionally include next for post requests that have the next variable set (will only come from the login page itself generally)
* Hide URLs
* Hide elements with "noprint" class
* Added noprint to:
* Header Panel
* Search Panel, Tags Panel
* Buttons
* Various list elements
* Related elements
Paths with trailing slashes do not work on windows, they cause errors such as `django.core.exceptions.SuspiciousFileOperation: The joined path (C:\Projects\netbox\netbox\static\clipboard-2.0.4.min.js) is located outside of the base path component (C:\Projects\netbox\netbox\static\)`.
After some feedback, that `netbox-community/docker` is not an ideal name, I've renamed the repo back to `netbox-docker`. Hence one more PR to update that link.
This means that problems give a more specific reason. In the event
that dot is not found, the error is now:
There was an error generating the requested graph: failed to execute ['dot',
'-Tpng'], make sure the Graphviz executables are on your systems' PATH
Sometimes it is desirable to associate arbitrary data with a group of devices to aid in their configuration. For example, you might want to associate a set of syslog servers for all devices at a particular site. Context data enables the association of arbitrary data to devices and virtual machines grouped by region, site, role, platform, and/or tenant. Context data is arranged hierarchically, so that data with a higher weight can be entered to override more general lower-weight data. Multiple instances of data are automatically merged by NetBox to present a single dictionary for each object.
Devices and Virtual Machines may also have a local config context defined. This local context will always overwrite the rendered config context objects for the Device/VM. This is useful in situations were the device requires a one-off value different from the rest of the environment.
Custom links allow users to place arbitrary hyperlinks within NetBox views. These are helpful for cross-referencing related records in external systems. For example, you might create a custom link on the device view which links to the current device in a network monitoring system.
Custom links are created under the admin UI. Each link is associated with a particular NetBox object type (site, device, prefix, etc.) and will be displayed on relevant views. Each link is assigned text and a URL, both of which support Jinja2 templating. The text and URL are rendered with the context variable `obj` representing the current object.
Custom links appear as buttons at the top right corner of the page. Numeric weighting can be used to influence the ordering of links.
## Conditional Rendering
Only links which render with non-empty text are included on the page. You can employ conditional Jinja2 logic to control the conditions under which a link gets rendered.
For example, if you only want to display a link for active devices, you could set the link text to
```
{% if obj.status == 1 %}View NMS{% endif %}
```
The link will not appear when viewing a device with any status other than "active."
Another example, if you want to only show an object of a certain manufacturer, you could set the link text to:
```
{% if obj.device_type.manufacturer.name == 'Cisco' %}View NMS {% endif %}
```
The link will only appear when viewing a device with a manufacturer name of "Cisco."
## Link Groups
You can specify a group name to organize links into related sets. Grouped links will render as a dropdown menu beneath a
Custom scripting was introduced to provide a way for users to execute custom logic from within the NetBox UI. Custom scripts enable the user to directly and conveniently manipulate NetBox data in a prescribed fashion. They can be used to accomplish myriad tasks, such as:
* Automatically populate new devices and cables in preparation for a new site deployment
* Create a range of new reserved prefixes or IP addresses
* Fetch data from an external source and import it to NetBox
Custom scripts are Python code and exist outside of the official NetBox code base, so they can be updated and changed without interfering with the core NetBox installation. And because they're written from scratch, a custom script can be used to accomplish just about anything.
## Writing Custom Scripts
All custom scripts must inherit from the `extras.scripts.Script` base class. This class provides the functionality necessary to generate forms and log activity.
```
from extras.scripts import Script
class MyScript(Script):
..
```
Scripts comprise two core components: variables and a `run()` method. Variables allow your script to accept user input via the NetBox UI. The `run()` method is where your script's execution logic lives. (Note that your script can have as many methods as needed: this is merely the point of invocation for NetBox.)
```
class MyScript(Script):
var1 = StringVar(...)
var2 = IntegerVar(...)
var3 = ObjectVar(...)
def run(self, data, commit):
...
```
The `run()` method should accept two arguments:
*`data` - A dictionary containing all of the variable data passed via the web form.
*`commit` - A boolean indicating whether database changes will be committed.
!!! note
The `commit` argument was introduced in NetBox v2.7.8. Backward compatibility is maintained for scripts which accept only the `data` argument, however moving forward scripts should accept both arguments.
Defining variables is optional: You may create a script with only a `run()` method if no user input is needed.
Returning output from your script is optional. Any raw output generated by the script will be displayed under the "output" tab in the UI.
## Module Attributes
### `name`
You can define `name` within a script module (the Python file which contains one or more scripts) to set the module name. If `name` is not defined, the filename will be used.
## Script Attributes
Script attributes are defined under a class named `Meta` within the script. These are optional, but encouraged.
### `name`
This is the human-friendly names of your script. If omitted, the class name will be used.
### `description`
A human-friendly description of what your script does.
### `field_order`
A list of field names indicating the order in which the form fields should appear. This is optional, and should not be required on Python 3.6 and above. For example:
```
field_order = ['var1', 'var2', 'var3']
```
### `commit_default`
The checkbox to commit database changes when executing a script is checked by default. Set `commit_default` to False under the script's Meta class to leave this option unchecked by default.
```
commit_default = False
```
## Accessing Request Data
Details of the current HTTP request (the one being made to execute the script) are available as the instance attribute `self.request`. This can be used to infer, for example, the user executing the script and the client IP address:
self.log_info("Running as user {} (IP: {})...".format(username,ip_address))
```
For a complete list of available request parameters, please see the [Django documentation](https://docs.djangoproject.com/en/stable/ref/request-response/).
## Reading Data from Files
The Script class provides two convenience methods for reading data from files:
*`load_yaml`
*`load_json`
These two methods will load data in YAML or JSON format, respectively, from files within the local path (i.e. `SCRIPTS_ROOT`).
## Logging
The Script object provides a set of convenient functions for recording messages at different severity levels:
*`log_debug`
*`log_success`
*`log_info`
*`log_warning`
*`log_failure`
Log messages are returned to the user upon execution of the script. Markdown rendering is supported for log messages.
## Variable Reference
### StringVar
Stores a string of characters (i.e. a line of text). Options include:
*`min_length` - Minimum number of characters
*`max_length` - Maximum number of characters
*`regex` - A regular expression against which the provided value must match
Note: `min_length` and `max_length` can be set to the same number to effect a fixed-length field.
### TextVar
Arbitrary text of any length. Renders as multi-line text input field.
### IntegerVar
Stored a numeric integer. Options include:
*`min_value` - Minimum value
*`max_value` - Maximum value
### BooleanVar
A true/false flag. This field has no options beyond the defaults.
### ChoiceVar
A set of choices from which the user can select one.
*`choices` - A list of `(value, label)` tuples representing the available choices. For example:
```python
CHOICES=(
('n','North'),
('s','South'),
('e','East'),
('w','West')
)
direction=ChoiceVar(choices=CHOICES)
```
### ObjectVar
A NetBox object. The list of available objects is defined by the queryset parameter. Each instance of this variable is limited to a single object type.
*`queryset` - A [Django queryset](https://docs.djangoproject.com/en/stable/topics/db/queries/)
### FileVar
An uploaded file. Note that uploaded files are present in memory only for the duration of the script's execution: They will not be save for future use.
### IPAddressVar
An IPv4 or IPv6 address, without a mask. Returns a `netaddr.IPAddress` object.
### IPAddressWithMaskVar
An IPv4 or IPv6 address with a mask. Returns a `netaddr.IPNetwork` object which includes the mask.
### IPNetworkVar
An IPv4 or IPv6 network with a mask. Returns a `netaddr.IPNetwork` object. Two attributes are available to validate the provided mask:
*`min_prefix_length` - Minimum length of the mask (default: none)
*`max_prefix_length` - Maximum length of the mask (default: none)
### Default Options
All variables support the following default options:
*`default` - The field's default value
*`description` - A brief description of the field
*`label` - The name of the form field
*`required` - Indicates whether the field is mandatory (default: true)
*`widget` - The class of form widget to use (see the [Django documentation](https://docs.djangoproject.com/en/stable/ref/forms/widgets/))
## Example
Below is an example script that creates new objects for a planned site. The user is prompted for three variables:
* The name of the new site
* The device model (a filtered list of defined device types)
* The number of access switches to create
These variables are presented as a web form to be completed by the user. Once submitted, the script's `run()` method is called to create the appropriate objects.
```
from django.utils.text import slugify
from dcim.choices import DeviceStatusChoices, SiteStatusChoices
from dcim.models import Device, DeviceRole, DeviceType, Site
@@ -4,7 +4,7 @@ NetBox allows users to define custom templates that can be used when exporting o
Each export template is associated with a certain type of object. For instance, if you create an export template for VLANs, your custom template will appear under the "Export" button on the VLANs list.
Export templates are written in [Django's template language](https://docs.djangoproject.com/en/1.9/ref/templates/language/), which is very similar to Jinja2. The list of objects returned from the database is stored in the `queryset` variable, which you'll typically want to iterate through using a `for` loop. Object properties can be access by name. For example:
Export templates are written in [Django's template language](https://docs.djangoproject.com/en/stable/ref/templates/language/), which is very similar to Jinja2. The list of objects returned from the database is stored in the `queryset` variable, which you'll typically want to iterate through using a `for` loop. Object properties can be access by name. For example:
NetBox does not have the ability to generate graphs natively, but this feature allows you to embed contextual graphs from an external resources (such as a monitoring system) inside the site, provider, and interface views. Each embedded graph must be defined with the following parameters:
* **Type:** Site, provider, or interface. This determines in which view the graph will be displayed.
* **Type:** Site, device, provider, or interface. This determines in which view the graph will be displayed.
* **Weight:** Determines the order in which graphs are displayed (lower weights are displayed first). Graphs with equal weights will be ordered alphabetically by name.
* **Name:** The title to display above the graph.
* **Source URL:** The source of the image to be embedded. The associated object will be available as a template variable named `obj`.
* **Link URL (optional):** A URL to which the graph will be linked. The associated object will be available as a template variable named `obj`.
Graph names and links can be rendered using the Django or Jinja2 template languages.
!!! warning
Support for the Django templating language will be removed in NetBox v2.8. Jinja2 is recommended.
## Examples
You only need to define one graph object for each graph you want to include when viewing an object. For example, if you want to include a graph of traffic through an interface over the past five minutes, your graph source might looks like this:
NetBox supports integration with the [NAPALM automation](https://napalm-automation.net/) library. NAPALM allows NetBox to fetch live data from devices and return it to a requester via its REST API.
!!! info
To enable the integration, the NAPALM library must be installed. See [installation steps](../../installation/3-netbox/#napalm-automation-optional) for more information.
```
GET /api/dcim/devices/1/napalm/?method=get_environment
{
"get_environment": {
...
}
}
```
## Authentication
By default, the [`NAPALM_USERNAME`](../../configuration/optional-settings/#napalm_username) and [`NAPALM_PASSWORD`](../../configuration/optional-settings/#napalm_password) are used for NAPALM authentication. They can be overridden for an individual API call through the `X-NAPALM-Username` and `X-NAPALM-Password` headers.
The list of supported NAPALM methods depends on the [NAPALM driver](https://napalm.readthedocs.io/en/latest/support/index.html#general-support-matrix) configured for the platform of a device. NetBox only supports [get](https://napalm.readthedocs.io/en/latest/support/index.html#getters-support-matrix) methods.
## Multiple Methods
More than one method in an API call can be invoked by adding multiple `method` parameters. For example:
```
GET /api/dcim/devices/1/napalm/?method=get_ntp_servers&method=get_ntp_peers
{
"get_ntp_servers": {
...
},
"get_ntp_peers": {
...
}
}
```
## Optional Arguments
The behavior of NAPALM drivers can be adjusted according to the [optional arguments](https://napalm.readthedocs.io/en/latest/support/index.html#optional-arguments). NetBox exposes those arguments using headers prefixed with `X-NAPALM-`.
For instance, the SSH port is changed to 2222 in this API call:
NetBox supports optionally exposing native Prometheus metrics from the application. [Prometheus](https://prometheus.io/) is a popular time series metric platform used for monitoring.
NetBox exposes metrics at the `/metrics` HTTP endpoint, e.g. `https://netbox.local/metrics`. Metric exposition can be toggled with the `METRICS_ENABLED` configuration setting. Metrics are not exposed by default.
## Metric Types
NetBox makes use of the [django-prometheus](https://github.com/korfuri/django-prometheus) library to export a number of different types of metrics, including:
- Per model insert, update, and delete counters
- Per view request counters
- Per view request latency histograms
- Request body size histograms
- Response body size histograms
- Response code counters
- Database connection, execution, and error counters
- Cache hit, miss, and invalidation counters
- Django middleware latency histograms
- Other Django related metadata metrics
For the exhaustive list of exposed metrics, visit the `/metrics` endpoint on your NetBox instance.
## Multi Processing Notes
When deploying NetBox in a multiprocess mannor--such as using Gunicorn as recomented in the installation docs--the Prometheus client library requires the use of a shared directory
to collect metrics from all the worker processes. This can be any arbitrary directory to which the processes have read/write access. This directory is then made available by use of the
`prometheus_multiproc_dir` environment variable.
This can be setup by first creating a shared directory and then adding this line (with the appropriate directory) to the `[program:netbox]` section of the supervisor config file.
@@ -12,7 +12,7 @@ A NetBox report is a mechanism for validating the integrity of data within NetBo
## Writing Reports
Reports must be saved as files in the [`REPORTS_ROOT`](../configuration/optional-settings/#reports_root) path (which defaults to `netbox/reports/`). Each file created within this path is considered a separate module. Each module holds one or more reports (Python classes), each of which performs a certain function. The logic of each report is broken into discrete test methods, each of which applies a small portion of the logic comprising the overall test.
Reports must be saved as files in the [`REPORTS_ROOT`](../../configuration/optional-settings/#reports_root) path (which defaults to `netbox/reports/`). Each file created within this path is considered a separate module. Each module holds one or more reports (Python classes), each of which performs a certain function. The logic of each report is broken into discrete test methods, each of which applies a small portion of the logic comprising the overall test.
!!! warning
The reports path includes a file named `__init__.py`, which registers the path as a Python module. Do not delete this file.
@@ -32,7 +32,8 @@ class DeviceIPsReport(Report):
Within each report class, we'll create a number of test methods to execute our report's logic. In DeviceConnectionsReport, for instance, we want to ensure that every live device has a console connection, an out-of-band management connection, and two power connections.
```
from dcim.constants import CONNECTION_STATUS_PLANNED, DEVICE_STATUS_ACTIVE
from dcim.choices import DeviceStatusChoices
from dcim.constants import CONNECTION_STATUS_PLANNED
from dcim.models import ConsolePort, Device, PowerPort
from extras.reports import Report
@@ -43,8 +44,9 @@ class DeviceConnectionsReport(Report):
def test_console_connection(self):
# Check that every console port for every active device has a connection defined.
for console_port in ConsolePort.objects.select_related('device').filter(device__status=DEVICE_STATUS_ACTIVE):
if console_port.cs_port is None:
active = DeviceStatusChoices.STATUS_ACTIVE
for console_port in ConsolePort.objects.prefetch_related('device').filter(device__status=active):
if console_port.connected_endpoint is None:
self.log_failure(
console_port.device,
"No console connection defined for {}".format(console_port.name)
@@ -60,10 +62,10 @@ class DeviceConnectionsReport(Report):
def test_power_connections(self):
# Check that every active device has at least two connected power supplies.
for device in Device.objects.filter(status=DEVICE_STATUS_ACTIVE):
for device in Device.objects.filter(status=DeviceStatusChoices.STATUS_ACTIVE):
connected_ports = 0
for power_port in PowerPort.objects.filter(device=device):
if power_port.power_outlet is not None:
if power_port.connected_endpoint is not None:
connected_ports += 1
if power_port.connection_status == CONNECTION_STATUS_PLANNED:
self.log_warning(
@@ -128,4 +130,4 @@ Reports can be run on the CLI by invoking the management command:
python3 manage.py runreport <module>
```
One or more report modules may be specified.
where ``<module>`` is the name of the python file in the ``reports`` directory without the ``.py`` extension. One or more report modules may be specified.
Tags are free-form text labels which can be applied to a variety of objects within NetBox. Tags are created on-demand as they are assigned to objects. Use commas to separate tags when adding multiple tags to an object 9for example: `Inventoried, Monitored`). Use double quotes around a multi-word tag when adding only one tag, e.g. `"Core Switch"`.
Each tag has a label and a URL-friendly slug. For example, the slug for a tag named "Dunder Mifflin, Inc." would be `dunder-mifflin-inc`. The slug is generated automatically and makes tags easier to work with as URL parameters.
Objects can be filtered by the tags they have applied. For example, the following API request will retrieve all devices tagged as "monitored":
```
GET /api/dcim/devices/?tag=monitored
```
Tags are included in the API representation of an object as a list of plain strings:
NetBox can generate simple topology maps from the physical network connections recorded in its database. First, you'll need to create a topology map definition under the admin UI at Extras > Topology Maps.
Each topology map is associated with a site. A site can have multiple topology maps, which might each illustrate a different aspect of its infrastructure (for example, production versus backend infrastructure).
To define the scope of a topology map, decide which devices you want to include. The map will only include interface connections with both points terminated on an included device. Specify the devices to include in the **device patterns** field by entering a list of [regular expressions](https://en.wikipedia.org/wiki/Regular_expression) matching device names. For example, if you wanted to include "mgmt-switch1" through "mgmt-switch99", you might use the regex `mgmt-switch\d+`.
Each line of the **device patterns** field represents a hierarchical layer within the topology map. For example, you might map a traditional network with core, distribution, and access tiers like this:
```
core-switch-[abcd]
dist-switch\d
access-switch\d+;oob-switch\d+
```
Note that you can combine multiple regexes onto one line using semicolons. The order in which regexes are listed on a line is significant: devices matching the first regex will be rendered first, and subsequent groups will be rendered to the right of those.
A webhook defines an HTTP request that is sent to an external application when certain types of objects are created, updated, and/or deleted in NetBox. When a webhook is triggered, a POST request is sent to its configured URL. This request will include a full representation of the object being modified for consumption by the receiver. Webhooks are configured via the admin UI under Extras > Webhooks.
A webhook is a mechanism for conveying to some external system a change that took place in NetBox. For example, you may want to notify a monitoring system whenever a device status is changed in NetBox. This can be done by creating a webhook for the device model in NetBox. When NetBox detects a change to a device, an HTTP request containing the details of the change and who made it be sent to the specified receiver. Webhooks are configured in the admin UI under Extras > Webhooks.
An optional secret key can be configured for each webhook. This will append a `X-Hook-Signature` header to the request, consisting of a HMAC (SHA-512) hex digest of the request body using the secret as the key. This digest can be used by the receiver to authenticate the request's content.
## Configuration
## Installation
* **Name** - A unique name for the webhook. The name is not included with outbound messages.
* **Object type(s)** - The type or types of NetBox object that will trigger the webhook.
* **Enabled** - If unchecked, the webhook will be inactive.
* **Events** - A webhook may trigger on any combination of create, update, and delete events. At least one event type must be selected.
* **HTTP method** - The type of HTTP request to send. Options include GET, POST, PUT, PATCH, and DELETE.
* **URL** - The fuly-qualified URL of the request to be sent. This may specify a destination port number if needed.
* **HTTP content type** - The value of the request's `Content-Type` header. (Defaults to `application/json`)
* **Additional headers** - Any additional headers to include with the request (optional). Add one header per line in the format `Name: Value`. Jinja2 templating is supported for this field (see below).
* **Body template** - The content of the request being sent (optional). Jinja2 templating is supported for this field (see below). If blank, NetBox will populate the request body with a raw dump of the webhook context. (If the HTTP cotent type is set to `application/json`, this will be formatted as a JSON object.)
* **Secret** - A secret string used to prove authenticity of the request (optional). This will append a `X-Hook-Signature` header to the request, consisting of a HMAC (SHA-512) hex digest of the request body using the secret as the key.
* **SSL verification** - Uncheck this option to disable validation of the receiver's SSL certificate. (Disable with caution!)
* **CA file path** - The file path to a particular certificate authority (CA) file to use when validating the receiver's SSL certificate (optional).
If you are upgrading from a previous version of Netbox and want to enable the webhook feature, please follow the directions listed in the sections below.
## Jinja2 Template Support
* [Install Redis server and djano-rq package](../installation/2-netbox/#install-python-packages)
* [Modify configuration to enable webhooks](../installation/2-netbox/#webhooks-configuration)
* [Create supervisord program to run the rqworker process](../installation/3-http-daemon/#supervisord-installation)
[Jinja2 templating](https://jinja.palletsprojects.com/) is supported for the `additional_headers` and `body_template` fields. This enables the user to convey change data in the request headers as well as to craft a customized request body. Request content can be crafted to enable the direct interaction with external systems by ensuring the outgoing message is in a format the receiver expects and understands.
## Requests
For example, you might create a NetBox webhook to [trigger a Slack message](https://api.slack.com/messaging/webhooks) any time an IP address is created. You can accomplish this using the following configuration:
The webhook POST request is structured as so (assuming `application/json` as the Content-Type):
* Object type: IPAM > IP address
* HTTP method: POST
* URL: <Slack incoming webhook URL>
* HTTP content type: `application/json`
* Body template: `{"text": "IP address {{ data['address'] }} was created by {{ username }}!"}`
### Available Context
The following data is available as context for Jinja2 templates:
*`event` - The type of event which triggered the webhook: created, updated, or deleted.
*`model` - The NetBox model which triggered the change.
*`timestamp` - The time at which the event occurred (in [ISO 8601](https://en.wikipedia.org/wiki/ISO_8601) format).
*`username` - The name of the user account associated with the change.
*`request_id` - The unique request ID. This may be used to correlate multiple changes associated with a single request.
*`data` - A serialized representation of the object _after_ the change was made. This is typically equivalent to the model's representation in NetBox's REST API.
### Default Request Body
If no body template is specified, the request body will be populated with a JSON object containing the context data. For example, a newly created site might appear as follows:
`data` is the serialized representation of the model instance(s) from the event. The same serializers from the NetBox API are used. So an example of the payload for a Site delete event would be:
## Webhook Processing
When a change is detected, any resulting webhooks are placed into a Redis queue for processing. This allows the user's request to complete without needing to wait for the outgoing webhook(s) to be processed. The webhooks are then extracted from the queue by the `rqworker` process and HTTP requests are sent to their respective destinations. The current webhook queue and any failed webhooks can be inspected in the admin UI under Django RQ > Queues.
A request is considered successful if the response has a 2XX status code; otherwise, the request is marked as having failed. Failed requests may be retried manually via the admin UI.
## Troubleshooting
To assist with verifying that the content of outgoing webhooks is rendered correctly, NetBox provides a simple HTTP listener that can be run locally to receive and display webhook requests. First, modify the target URL of the desired webhook to `http://localhost:9000/`. This will instruct NetBox to send the request to the local server on TCP port 9000. Then, start the webhook receiver service from the NetBox root directory:
```no-highlight
{
"event": "deleted",
"signal_received_timestamp": 1508781858.544069,
"model": "Site",
"data": {
"asn": None,
"comments": "",
"contact_email": "",
"contact_name": "",
"contact_phone": "",
"count_circuits": 0,
"count_devices": 0,
"count_prefixes": 0,
"count_racks": 0,
"count_vlans": 0,
"custom_fields": {},
"facility": "",
"id": 54,
"name": "test",
"physical_address": "",
"region": None,
"shipping_address": "",
"slug": "test",
"tenant": None
}
}
$ python netbox/manage.py webhook_receiver
Listening on port http://localhost:9000. Stop with CONTROL-C.
```
A request is considered successful if the response status code is any one of a list of "good" statuses defined in the [requests library](https://github.com/requests/requests/blob/205755834d34a8a6ecf2b0b5b2e9c3e6a7f4e4b6/requests/models.py#L688), otherwise the request is marked as having failed. The user may manually retry a failed request.
You can test the receiver itself by sending any HTTP request to it. For example:
## Backend Status
```no-highlight
$ curl -X POST http://localhost:9000 --data '{"foo": "bar"}'
```
Django-rq includes a status page in the admin site which can be used to view the result of processed webhooks and manually retry any failed webhooks. Access it from http://netbox.local/admin/webhook-backend-status/.
The server will print output similar to the following:
Note that `webhook_receiver` does not actually _do_ anything with the information received: It merely prints the request headers and body for inspection.
Now, when the NetBox webhook is triggered and processed, you should see its headers and content appear in the terminal where the webhook receiver is listening. If you don't, check that the `rqworker` process is running and that webhook events are being placed into the queue (visible under the NetBox admin UI).
NetBox includes a Python shell within which objects can be directly queried, created, modified, and deleted. To enter the shell, run the following command:
```
./manage.py nbshell
```
This will launch a customized version of [the built-in Django shell](https://docs.djangoproject.com/en/dev/ref/django-admin/#shell) with all relevant NetBox models pre-loaded. (If desired, the stock Django shell is also available by executing `./manage.py shell`.)
This will launch a customized version of [the built-in Django shell](https://docs.djangoproject.com/en/stable/ref/django-admin/#shell) with all relevant NetBox models pre-loaded. (If desired, the stock Django shell is also available by executing `./manage.py shell`.)
### lsmodels() will show available models. Use help(<model>) for more info.
```
@@ -28,7 +30,7 @@ DCIM:
## Querying Objects
Objects are retrieved by forming a [Django queryset](https://docs.djangoproject.com/en/dev/topics/db/queries/#retrieving-objects). The base queryset for an object takes the form `<model>.objects.all()`, which will return a (truncated) list of all objects of that type.
Objects are retrieved by forming a [Django queryset](https://docs.djangoproject.com/en/stable/topics/db/queries/#retrieving-objects). The base queryset for an object takes the form `<model>.objects.all()`, which will return a (truncated) list of all objects of that type.
```
>>> Device.objects.all()
@@ -99,7 +101,7 @@ This approach can span multiple levels of relations. For example, the following
```
!!! note
While the above query is functional, it is very inefficient. There are ways to optimize such requests, however they are out of the scope of this document. For more information, see the [Django queryset method reference](https://docs.djangoproject.com/en/dev/ref/models/querysets/) documentation.
While the above query is functional, it is very inefficient. There are ways to optimize such requests, however they are out of the scope of this document. For more information, see the [Django queryset method reference](https://docs.djangoproject.com/en/stable/ref/models/querysets/) documentation.
Reverse relationships can be traversed as well. For example, the following will find all devices with an interface named "em0":
@@ -137,7 +139,7 @@ To return the inverse of a filtered queryset, use `exclude()` instead of `filter
```
!!! info
The examples above are intended only to provide a cursory introduction to queryset filtering. For an exhaustive list of the available filters, please consult the [Django queryset API docs](https://docs.djangoproject.com/en/dev/ref/models/querysets/).
The examples above are intended only to provide a cursory introduction to queryset filtering. For an exhaustive list of the available filters, please consult the [Django queryset API docs](https://docs.djangoproject.com/en/stable/ref/models/querysets/).
NetBox uses [PostgreSQL](https://www.postgresql.org/) for its database, so general PostgreSQL best practices will apply to NetBox. You can dump and restore the database using the `pg_dump` and `psql` utilities, respectively.
!!! note
The examples below assume that your database is named `netbox`.
## Export the Database
### Export the Database
Use the `pg_dump` utility to export the entire database to a file:
@@ -19,7 +21,7 @@ When replicating a production database for development purposes, you may find it
Keep in mind that PostgreSQL user accounts and permissions are not included with the dump: You will need to create those manually if you want to fully replicate the original database (see the [installation docs](installation/1-postgresql.md)). When setting up a development instance of NetBox, it's strongly recommended to use different credentials anyway.
Keep in mind that PostgreSQL user accounts and permissions are not included with the dump: You will need to create those manually if you want to fully replicate the original database (see the [installation docs](../installation/1-postgresql.md)). When setting up a development instance of NetBox, it's strongly recommended to use different credentials anyway.
## Export the Database Schema
### Export the Database Schema
If you want to export only the database schema, and not the data itself (e.g. for development reference), do the following:
```no-highlight
pg_dump -s netbox > netbox_schema.sql
```
If you are migrating your instance of NetBox to a different machine, please make sure you invalidate the cache by performing this command:
```no-highlight
python3 manage.py invalidate all
```
---
# Replicating Media
## Replicating Media
NetBox stored uploaded files (such as image attachments) in its media directory. To fully replicate an instance of NetBox, you'll need to copy both the database and the media files.
## Archive the Media Directory
### Archive the Media Directory
Execute the following command from the root of the NetBox installation path (typically `/opt/netbox`):
@@ -54,7 +61,7 @@ Execute the following command from the root of the NetBox installation path (typ
tar -czf netbox_media.tar.gz netbox/media/
```
## Restore the Media Directory
### Restore the Media Directory
To extract the saved archive into a new installation, run the following from the installation root:
The NetBox API employs token-based authentication. For convenience, cookie authentication can also be used when navigating the browsable API.
# Tokens
## Tokens
A token is a unique identifier that identifies a user to the API. Each user in NetBox may have one or more tokens which he or she can use to authenticate to the API. To create a token, navigate to the API tokens page at `/user/api-tokens/`.
@@ -13,7 +15,7 @@ By default, a token can be used for all operations available via the API. Desele
Additionally, a token can be set to expire at a specific time. This can be useful if an external client needs to be granted temporary access to NetBox.
# Authenticating to the API
## Authenticating to the API
By default, read operations will be available without authentication. In this case, a token may be included in the request, but is not necessary.
However, if the [`LOGIN_REQUIRED`](../configuration/optional-settings/#login_required) configuration setting has been set to `True`, all requests must be authenticated.
However, if the [`LOGIN_REQUIRED`](../../configuration/optional-settings/#login_required) configuration setting has been set to `True`, all requests must be authenticated.
Send a `POST` request to the site list endpoint with token authentication and JSON-formatted data. Only mandatory fields are required. This example includes one non required field, "region."
Note that in this example we are creating a site bound to a region with the ID of 5. For write API actions (`POST`, `PUT`, and `PATCH`) the integer ID value is used for `ForeignKey` (related model) relationships, instead of the nested representation that is used in the `GET` (list) action.
### Modify an existing site
## Modify an existing site
Make an authenticated `PUT` request to the site detail endpoint. As with a create (`POST`) request, all mandatory fields must be included.
@@ -112,14 +112,14 @@ Make an authenticated `PUT` request to the site detail endpoint. As with a creat
Make an authenticated `PATCH` request to the device endpoint. With `PATCH`, unlike `POST` and `PUT`, we only specify the field that is being changed. In this example, we add a serial number to a device.
NetBox v2.0 and later includes a full-featured REST API that allows its data model to be read and manipulated externally.
# The NetBox REST API
# What is a REST API?
## What is a REST API?
REST stands for [representational state transfer](https://en.wikipedia.org/wiki/Representational_state_transfer). It's a particular type of API which employs HTTP to create, retrieve, update, and delete objects from a database. (This set of operations is commonly referred to as CRUD.) Each type of operation is associated with a particular HTTP verb:
Each attribute of the NetBox object is expressed as a field in the dictionary. Fields may include their own nested objects, as in the case of the `status` field above. Every object includes a primary key named `id` which uniquely identifies it in the database.
# URL Hierarchy
## Interactive Documentation
Comprehensive, interactive documentation of all API endpoints is available on a running NetBox instance at `/api/docs/`. This interface provides a convenient sandbox for researching and experimenting with NetBox's various API endpoints and different request types.
## URL Hierarchy
NetBox's entire API is housed under the API root at `https://<hostname>/api/`. The URL structure is divided at the root level by application: circuits, DCIM, extras, IPAM, secrets, and tenancy. Within each application, each model has its own path. For example, the provider and circuit objects are located under the "circuits" application:
@@ -60,7 +64,9 @@ Lists of objects can be filtered using a set of query parameters. For example, t
GET /api/dcim/interfaces/?device_id=123
```
# Serialization
See [filtering](filtering.md) for more details.
## Serialization
The NetBox API employs three types of serializers to represent model data:
@@ -104,56 +110,84 @@ The base serializer is used to represent the default view of a model. This inclu
}
```
Related objects (e.g. `ForeignKey` fields) are represented using a nested serializer. A nested serializer provides a minimal representation of an object, including only its URL and enough information to construct its name. When performing write api actions (`POST`, `PUT`, and `PATCH`), any `ForeignKey` relationships do not use the nested serializer, instead you will pass just the integer ID of the related model.
### Related Objects
When a base serializer includes one or more nested serializers, the hierarchical structure precludes it from being used for write operations. Thus, a flat representation of an object may be provided using a writable serializer. This serializer includes only raw database values and is not typically used for retrieval, except as part of the response to the creation or updating of an object.
Related objects (e.g. `ForeignKey` fields) are represented using a nested serializer. A nested serializer provides a minimal representation of an object, including only its URL and enough information to display the object to a user. When performing write API actions (`POST`, `PUT`, and `PATCH`), related objects may be specified by either numeric ID (primary key), or by a set of attributes sufficiently unique to return the desired object.
For example, when creating a new device, its rack can be specified by NetBox ID (PK):
```
{
"id": 1201,
"site": 7,
"group": 4,
"vid": 102,
"name": "Users-Floor2",
"tenant": null,
"status": 1,
"role": 9,
"description": ""
"name": "MyNewDevice",
"rack": 123,
...
}
```
## Static Choice Fields
Some model fields, such as the `status` field in the above example, utilize static integers corresponding to static choices. The available choices can be retrieved from the read-only `_choices` endpoint within each app. A specific `model:field` tuple may optionally be specified in the URL.
Each choice includes a human-friendly label and its corresponding numeric value. For example, `GET /api/ipam/_choices/prefix:status/` will return:
Or by a set of nested attributes used to identify the rack:
```
[
{
"value": 0,
"label": "Container"
{
"name": "MyNewDevice",
"rack": {
"site": {
"name": "Equinix DC6"
},
"name": "R204"
},
{
...
}
```
Note that if the provided parameters do not return exactly one object, a validation error is raised.
### Brief Format
Most API endpoints support an optional "brief" format, which returns only a minimal representation of each object in the response. This is useful when you need only a list of the objects themselves without any related data, such as when populating a drop-down list in a form.
For example, the default (complete) format of an IP address looks like this:
Thus, to set a prefix's status to "Reserved," it would be assigned the integer `2`.
The brief format is much more terse, but includes a link to the object's full representation:
A request for `GET /api/ipam/_choices/` will return choices for _all_ fields belonging to models within the IPAM app.
```
GET /api/ipam/prefixes/13980/?brief=1
# Pagination
{
"id": 13980,
"url": "https://netbox/api/ipam/prefixes/13980/",
"family": 4,
"prefix": "192.0.2.0/24"
}
```
The brief format is supported for both lists and individual objects.
## Pagination
API responses which contain a list of objects (for example, a request to `/api/dcim/devices/`) will be paginated to avoid unnecessary overhead. The root JSON object will contain the following attributes:
@@ -185,7 +219,7 @@ Vary: Accept
}
```
The default page size derives from the [`PAGINATE_COUNT`](../configuration/optional-settings/#paginate_count) configuration setting, which defaults to 50. However, this can be overridden per request by specifying the desired `offset` and `limit` query parameters. For example, if you wish to retrieve a hundred devices at a time, you would make a request for:
The default page size derives from the [`PAGINATE_COUNT`](../../configuration/optional-settings/#paginate_count) configuration setting, which defaults to 50. However, this can be overridden per request by specifying the desired `offset` and `limit` query parameters. For example, if you wish to retrieve a hundred devices at a time, you would make a request for:
```
http://localhost:8000/api/dcim/devices/?limit=100
@@ -202,26 +236,50 @@ The response will return devices 1 through 100. The URL provided in the `next` a
}
```
The maximum number of objects that can be returned is limited by the [`MAX_PAGE_SIZE`](../configuration/optional-settings/#max_page_size) setting, which is 1000 by default. Setting this to `0` or `None` will remove the maximum limit. An API consumer can then pass `?limit=0` to retrieve _all_ matching objects with a single request.
The maximum number of objects that can be returned is limited by the [`MAX_PAGE_SIZE`](../../configuration/optional-settings/#max_page_size) setting, which is 1000 by default. Setting this to `0` or `None` will remove the maximum limit. An API consumer can then pass `?limit=0` to retrieve _all_ matching objects with a single request.
!!! warning
Disabling the page size limit introduces a potential for very resource-intensive requests, since one API request can effectively retrieve an entire table from the database.
# Filtering
## Filtering
A list of objects retrieved via the API can be filtered by passing one or more query parameters. The same parameters used by the web UI work for the API as well. For example, to return only prefixes with a status of "Active" (`1`):
A list of objects retrieved via the API can be filtered by passing one or more query parameters. The same parameters used by the web UI work for the API as well. For example, to return only prefixes with a status of "Active" (identified by the slug `active`):
```
GET /api/ipam/prefixes/?status=1
GET /api/ipam/prefixes/?status=active
```
The same filter can be incldued multiple times. These will effect a logical OR and return objects matching any of the given values. For example, the following will return all active and reserved prefixes:
The choices available for fixed choice fields such as `status` can be retrieved by sending an `OPTIONS` API request for the desired endpoint:
For most fields, when a filter is passed multiple times, objects matching _any_ of the provided values will be returned. For example, `GET /api/dcim/sites/?name=Foo&name=Bar` will return all sites named "Foo" _or_ "Bar". The exception to this rule is ManyToManyFields which may have multiple values assigned. Tags are the most common example of a ManyToManyField. For example, `GET /api/dcim/sites/?tag=foo&tag=bar` will return only sites tagged with both "foo" _and_ "bar".
### Custom Fields
To filter on a custom field, prepend `cf_` to the field name. For example, the following query will return only sites where a custom field named `foo` is equal to 123:
As with most other objects, the NetBox API can be used to create, modify, and delete secrets. However, additional steps are needed to encrypt or decrypt secret data.
# Generating a Session Key
## Generating a Session Key
In order to encrypt or decrypt secret data, a session key must be attached to the API request. To generate a session key, send an authenticated request to the `/api/secrets/get-session-key/` endpoint with the private RSA key which matches your [UserKey](../data-model/secrets/#user-keys). The private key must be POSTed with the name `private_key`.
In order to encrypt or decrypt secret data, a session key must be attached to the API request. To generate a session key, send an authenticated request to the `/api/secrets/get-session-key/` endpoint with the private RSA key which matches your [UserKey](../../core-functionality/secrets/#user-keys). The private key must be POSTed with the name `private_key`.
```
$ curl -X POST http://localhost:8000/api/secrets/get-session-key/ \
@@ -19,7 +21,7 @@ $ curl -X POST http://localhost:8000/api/secrets/get-session-key/ \
The request uses your private key to unlock your stored copy of the master key and generate a session key which can be attached in the `X-Session-Key` header of future API requests.
# Retrieving Secrets
## Retrieving Secrets
A session key is not needed to retrieve unencrypted secrets: The secret is returned like any normal object with its `plaintext` field set to null.
The number of seconds to retain cache entries before automatically invalidating them.
---
## CHANGELOG_RETENTION
Default: 90
@@ -64,7 +72,13 @@ If True, cross-origin resource sharing (CORS) requests will be accepted from all
## CORS_ORIGIN_REGEX_WHITELIST
These settings specify a list of origins that are authorized to make cross-site API requests. Use `CORS_ORIGIN_WHITELIST` to define a list of exact hostnames, or `CORS_ORIGIN_REGEX_WHITELIST` to define a set of regular expressions. (These settings have no effect if `CORS_ORIGIN_ALLOW_ALL` is True.)
These settings specify a list of origins that are authorized to make cross-site API requests. Use `CORS_ORIGIN_WHITELIST` to define a list of exact hostnames, or `CORS_ORIGIN_REGEX_WHITELIST` to define a set of regular expressions. (These settings have no effect if `CORS_ORIGIN_ALLOW_ALL` is True.) For example:
```
CORS_ORIGIN_WHITELIST = [
'https://example.com',
]
```
---
@@ -76,6 +90,22 @@ This setting enables debugging. This should be done only during development or t
---
## DEVELOPER
Default: False
This parameter serves as a safeguard to prevent some potentially dangerous behavior, such as generating new database schema migrations. Set this to `True`**only** if you are actively developing the NetBox code base.
---
## DOCS_ROOT
Default: `$INSTALL_DIR/docs/`
The file path to NetBox's documentation. This is used when presenting context-sensitive documentation in the web UI. by default, this will be the `docs/` directory within the root NetBox installation path. (Set this to `None` to disable the embedded documentation.)
---
## EMAIL
In order to send email, NetBox needs an email server configured. The following items can be defined within the `EMAIL` setting:
@@ -87,9 +117,47 @@ In order to send email, NetBox needs an email server configured. The following i
* TIMEOUT - Amount of time to wait for a connection (seconds)
* FROM_EMAIL - Sender address for emails sent by NetBox
Email is sent from NetBox only for critical events. If you would like to test the email server configuration please use the django function [send_mail()](https://docs.djangoproject.com/en/stable/topics/email/#send-mail):
```
# python ./manage.py nbshell
>>> from django.core.mail import send_mail
>>> send_mail(
'Test Email Subject',
'Test Email Body',
'noreply-netbox@example.com',
['users@example.com'],
fail_silently=False
)
```
---
# ENFORCE_GLOBAL_UNIQUE
## EXEMPT_VIEW_PERMISSIONS
Default: Empty list
A list of models to exempt from the enforcement of view permissions. Models listed here will be viewable by all users and by anonymous users.
List models in the form `<app>.<model>`. For example:
```
EXEMPT_VIEW_PERMISSIONS = [
'dcim.site',
'dcim.region',
'ipam.prefix',
]
```
To exempt _all_ models from view permission enforcement, set the following. (Note that `EXEMPT_VIEW_PERMISSIONS` must be an iterable.)
```
EXEMPT_VIEW_PERMISSIONS = ['*']
```
---
## ENFORCE_GLOBAL_UNIQUE
Default: False
@@ -97,11 +165,26 @@ Enforcement of unique IP space can be toggled on a per-VRF basis. To enforce uni
---
## HTTP_PROXIES
Default: None
A dictionary of HTTP proxies to use for outbound requests originating from NetBox (e.g. when sending webhooks). Proxies should be specified by schema as per the [Python requests library documentation](https://2.python-requests.org/en/master/user/advanced/). For example:
```python
HTTP_PROXIES={
'http':'http://10.10.1.10:3128',
'https':'http://10.10.1.10:1080',
}
```
---
## LOGGING
By default, all messages of INFO severity or higher will be logged to the console. Additionally, if `DEBUG` is False and email access has been configured, ERROR and CRITICAL messages will be emailed to the users defined in `ADMINS`.
The Django framework on which NetBox runs allows for the customization of logging, e.g. to write logs to file. Please consult the [Django logging documentation](https://docs.djangoproject.com/en/1.11/topics/logging/) for more information on configuring this setting. Below is an example which will write all INFO and higher messages to a file:
The Django framework on which NetBox runs allows for the customization of logging, e.g. to write logs to file. Please consult the [Django logging documentation](https://docs.djangoproject.com/en/stable/topics/logging/) for more information on configuring this setting. Below is an example which will write all INFO and higher messages to a file:
```
LOGGING = {
@@ -123,6 +206,14 @@ LOGGING = {
}
```
### Available Loggers
*`netbox.auth.*` - Authentication events
*`netbox.api.views.*` - Views which handle business logic for the REST API
*`netbox.views.*` - Views which handle business logic for the web UI
---
## LOGIN_REQUIRED
@@ -133,6 +224,14 @@ Setting this to True will permit only authenticated users to access any part of
---
## LOGIN_TIMEOUT
Default: 1209600 seconds (14 days)
The liftetime (in seconds) of the authentication cookie issued to a NetBox user upon login.
---
## MAINTENANCE_MODE
Default: False
@@ -157,6 +256,14 @@ The file path to the location where media files (such as image attachments) are
---
## METRICS_ENABLED
Default: False
Toggle exposing Prometheus metrics at `/metrics`. See the [Prometheus Metrics](../../additional-features/prometheus-metrics/) documentation for more details.
---
## NAPALM_USERNAME
## NAPALM_PASSWORD
@@ -207,6 +314,39 @@ Determine how many objects to display per page within each list of objects.
---
## PLUGINS
Default: Empty
A list of installed [NetBox plugins](../../plugins/) to enable. Plugins will not take effect unless they are listed here.
!!! warning
Plugins extend NetBox by allowing external code to run with the same access and privileges as NetBox itself. Only install plugins from trusted sources. The NetBox maintainers make absolutely no guarantees about the integrity or security of your installation with plugins enabled.
---
## PLUGINS_CONFIG
Default: Empty
This parameter holds configuration settings for individual NetBox plugins. It is defined as a dictionary, with each key using the name of an installed plugin. The specific parameters supported are unique to each plugin: Reference the plugin's documentation to determine the supported parameters. An example configuration is shown below:
```python
PLUGINS_CONFIG={
'plugin1':{
'foo':123,
'bar':True
},
'plugin2':{
'foo':456,
},
}
```
Note that a plugin must be listed in `PLUGINS` for its configuration to take effect.
---
## PREFER_IPV4
Default: False
@@ -215,6 +355,72 @@ When determining the primary IP address for a device, IPv6 is preferred over IPv
---
## REMOTE_AUTH_ENABLED
Default: `False`
NetBox can be configured to support remote user authentication by inferring user authentication from an HTTP header set by the HTTP reverse proxy (e.g. nginx or Apache). Set this to `True` to enable this functionality. (Local authentication will still take effect as a fallback.)
Python path to the custom [Django authentication backend](https://docs.djangoproject.com/en/stable/topics/auth/customizing/) to use for external user authentication, if not using NetBox's built-in backend. (Requires `REMOTE_AUTH_ENABLED`.)
---
## REMOTE_AUTH_HEADER
Default: `'HTTP_REMOTE_USER'`
When remote user authentication is in use, this is the name of the HTTP header which informs NetBox of the currently authenticated user. (Requires `REMOTE_AUTH_ENABLED`.)
---
## REMOTE_AUTH_AUTO_CREATE_USER
Default: `True`
If true, NetBox will automatically create local accounts for users authenticated via a remote service. (Requires `REMOTE_AUTH_ENABLED`.)
---
## REMOTE_AUTH_DEFAULT_GROUPS
Default: `[]` (Empty list)
The list of groups to assign a new user account when created using remote authentication. (Requires `REMOTE_AUTH_ENABLED`.)
---
## REMOTE_AUTH_DEFAULT_PERMISSIONS
Default: `[]` (Empty list)
The list of permissions to assign a new user account when created using remote authentication. (Requires `REMOTE_AUTH_ENABLED`.)
---
## RELEASE_CHECK_TIMEOUT
Default: 86,400 (24 hours)
The number of seconds to retain the latest version that is fetched from the GitHub API before automatically invalidating it and fetching it from the API again. This must be set to at least one hour (3600 seconds).
---
## RELEASE_CHECK_URL
Default: None
The releases of this repository are checked to detect new releases, which are shown on the home page of the web interface. You can change this to your own fork of the NetBox repository, or set it to `None` to disable the check. The URL provided **must** be compatible with the GitHub API.
Use `'https://api.github.com/repos/netbox-community/netbox/releases'` to check for release in the official NetBox repository.
---
## REPORTS_ROOT
Default: $BASE_DIR/netbox/reports/
@@ -223,6 +429,42 @@ The file path to the location where custom reports will be kept. By default, thi
---
## SCRIPTS_ROOT
Default: $BASE_DIR/netbox/scripts/
The file path to the location where custom scripts will be kept. By default, this is the `netbox/scripts/` directory within the base NetBox installation path.
---
## SESSION_FILE_PATH
Default: None
Session data is used to track authenticated users when they access NetBox. By default, NetBox stores session data in the PostgreSQL database. However, this inhibits authentication to a standby instance of NetBox without write access to the database. Alternatively, a local file path may be specified here and NetBox will store session data as files instead of using the database. Note that the user as which NetBox runs must have read and write permissions to this path.
---
## STORAGE_BACKEND
Default: None (local storage)
The backend storage engine for handling uploaded files (e.g. image attachments). NetBox supports integration with the [`django-storages`](https://django-storages.readthedocs.io/en/stable/) package, which provides backends for several popular file storage services. If not configured, local filesystem storage will be used.
The configuration parameters for the specified storage backend are defined under the `STORAGE_CONFIG` setting.
---
## STORAGE_CONFIG
Default: Empty
A dictionary of configuration parameters for the storage backend configured as `STORAGE_BACKEND`. The specific parameters to be used here are specific to each backend; see the [`django-storages` documentation](https://django-storages.readthedocs.io/en/stable/) for more detail.
If `STORAGE_BACKEND` is not defined, this setting will be ignored.
---
## TIME_ZONE
Default: UTC
@@ -231,17 +473,9 @@ The time zone NetBox will use when dealing with dates and times. It is recommend
---
## WEBHOOKS_ENABLED
Default: False
Enable this option to run the webhook backend. See the docs section on the webhook backend [here](../miscellaneous/webhooks/) for more information on setup and use.
---
## Date and Time Formatting
You may define custom formatting for date and times. For detailed instructions on writing format strings, please see [the Django documentation](https://docs.djangoproject.com/en/dev/ref/templates/builtins/#date).
You may define custom formatting for date and times. For detailed instructions on writing format strings, please see [the Django documentation](https://docs.djangoproject.com/en/stable/ref/templates/builtins/#date).
[Redis](https://redis.io/) is a key-value store which functions as a very lightweight database. It is required when enabling NetBox [webhooks](../miscellaneous/webhooks/). A Redis connection is configured using a dictionary similar to the following:
```
REDIS = {
'HOST': 'localhost',
'PORT': 6379,
'PASSWORD': '',
'DATABASE': 0,
'DEFAULT_TIMEOUT': 300,
}
```
### DATABASE
Default: 0
The Redis database ID.
### DEFAULT_TIMEOUT
Default: 300
The timeout value to use when connecting to the Redis server (in seconds).
### HOST
Default: localhost
The hostname or IP address of the Redis server.
### PORT
Default: 6379
The TCP port to use when connecting to the Redis server.
### PASSWORD
Default: None
The password to use when authenticating to the Redis server (optional).
This is a list of valid fully-qualified domain names (FQDNs) that is used to reach the NetBox service. Usually this is the same as the hostname for the NetBox server, but can also be different (e.g. when using a reverse proxy serving the NetBox website under a different FQDN than the hostname of the NetBox server). NetBox will not permit access to the server via any other hostnames (or IPs). The value of this option is also used to set `CSRF_TRUSTED_ORIGINS`, which restricts `HTTP POST` to the same set of hosts (more about this [here](https://docs.djangoproject.com/en/1.9/ref/settings/#std:setting-CSRF_TRUSTED_ORIGINS)). Keep in mind that NetBox, by default, has `USE_X_FORWARDED_HOST = True` (in `netbox/netbox/settings.py`) which means that if you're using a reverse proxy, it's the FQDN used to reach that reverse proxy which needs to be in this list (more about this [here](https://docs.djangoproject.com/en/1.9/ref/settings/#allowed-hosts)).
This is a list of valid fully-qualified domain names (FQDNs) that is used to reach the NetBox service. Usually this is the same as the hostname for the NetBox server, but can also be different (e.g. when using a reverse proxy serving the NetBox website under a different FQDN than the hostname of the NetBox server). NetBox will not permit access to the server via any other hostnames (or IPs). The value of this option is also used to set `CSRF_TRUSTED_ORIGINS`, which restricts `HTTP POST` to the same set of hosts (more about this [here](https://docs.djangoproject.com/en/stable/ref/settings/#std:setting-CSRF_TRUSTED_ORIGINS)). Keep in mind that NetBox, by default, has `USE_X_FORWARDED_HOST = True` (in `netbox/netbox/settings.py`) which means that if you're using a reverse proxy, it's the FQDN used to reach that reverse proxy which needs to be in this list (more about this [here](https://docs.djangoproject.com/en/stable/ref/settings/#allowed-hosts)).
NetBox requires access to a PostgreSQL database service to store data. This service can run locally or on a remote system. The following parameters must be defined within the `DATABASE` dictionary:
* NAME - Database name
* USER - PostgreSQL username
* PASSWORD - PostgreSQL password
* HOST - Name or IP address of the database server (use `localhost` if running locally)
* PORT - TCP port of the PostgreSQL service; leave blank for default port (5432)
*`NAME` - Database name
*`USER` - PostgreSQL username
*`PASSWORD` - PostgreSQL password
*`HOST` - Name or IP address of the database server (use `localhost` if running locally)
*`PORT` - TCP port of the PostgreSQL service; leave blank for default port (5432)
*`CONN_MAX_AGE` - Lifetime of a [persistent database connection](https://docs.djangoproject.com/en/stable/ref/databases/#persistent-connections), in seconds (150-300 is recommended)
'PORT':'',# Database port (leave blank for default)
'CONN_MAX_AGE':300,# Max database connection age
}
```
!!! note
NetBox supports all PostgreSQL database options supported by the underlying Django framework. For a complete list of available parameters, please see [the Django documentation](https://docs.djangoproject.com/en/stable/ref/settings/#databases).
---
## REDIS
[Redis](https://redis.io/) is an in-memory data store similar to memcached. While Redis has been an optional component of
NetBox since the introduction of webhooks in version 2.4, it is required starting in 2.6 to support NetBox's caching
functionality (as well as other planned features). In 2.7, the connection settings were broken down into two sections for
task queuing and caching, allowing the user to connect to different Redis instances/databases per feature.
Redis is configured using a configuration setting similar to `DATABASE` and these settings are the same for both of the `tasks` and `caching` subsections:
*`HOST` - Name or IP address of the Redis server (use `localhost` if running locally)
*`PORT` - TCP port of the Redis service; leave blank for default port (6379)
*`PASSWORD` - Redis password (if set)
*`DATABASE` - Numeric database ID
*`DEFAULT_TIMEOUT` - Connection timeout in seconds
*`SSL` - Use SSL connection to Redis
Example:
```python
REDIS={
'tasks':{
'HOST':'redis.example.com',
'PORT':1234,
'PASSWORD':'foobar',
'DATABASE':0,
'DEFAULT_TIMEOUT':300,
'SSL':False,
},
'caching':{
'HOST':'localhost',
'PORT':6379,
'PASSWORD':'',
'DATABASE':1,
'DEFAULT_TIMEOUT':300,
'SSL':False,
}
}
```
!!! note
If you are upgrading from a version prior to v2.7, please note that the Redis connection configuration settings have
changed. Manual modification to bring the `REDIS` section inline with the above specification is necessary
!!! warning
It is highly recommended to keep the task and cache databases separate. Using the same database number on the
same Redis instance for both may result in queued background tasks being lost during cache flushing events.
### Using Redis Sentinel
If you are using [Redis Sentinel](https://redis.io/topics/sentinel) for high-availability purposes, there is minimal
configuration necessary to convert NetBox to recognize it. It requires the removal of the `HOST` and `PORT` keys from
above and the addition of two new keys.
*`SENTINELS`: List of tuples or tuple of tuples with each inner tuple containing the name or IP address
of the Redis server and port for each sentinel instance to connect to
*`SENTINEL_SERVICE`: Name of the master / service to connect to
A provider is any entity which provides some form of connectivity. While this obviously includes carriers which offer Internet and private transit service, it might also include Internet exchange (IX) points and even organizations with whom you peer directly.
Each provider may be assigned an autonomous system number (ASN), an account number, and relevant contact information.
{!docs/models/circuits/provider.md!}
---
# Circuits
A circuit represents a single _physical_ link connecting exactly two endpoints. (A circuit with more than two endpoints is a virtual circuit, which is not currently supported by NetBox.) Each circuit belongs to a provider and must be assigned a circuit ID which is unique to that provider.
## Circuit Types
Circuits are classified by type. For example, you might define circuit types for:
* Internet transit
* Out-of-band connectivity
* Peering
* Private backhaul
Circuit types are fully customizable.
## Circuit Terminations
A circuit may have one or two terminations, annotated as the "A" and "Z" sides of the circuit. A single-termination circuit can be used when you don't know (or care) about the far end of a circuit (for example, an Internet access circuit which connects to a transit provider). A dual-termination circuit is useful for tracking circuits which connect two sites.
Each circuit termination is tied to a site, and optionally to a specific device and interface within that site. Each termination can be assigned a separate downstream and upstream speed independent from one another. Fields are also available to track cross-connect and patch panel details.
!!! note
A circuit represents a physical link, and cannot have more than two endpoints. When modeling a multi-point topology, each leg of the topology must be defined as a discrete circuit.
!!! note
A circuit may terminate only to a physical interface. Circuits may not terminate to LAG interfaces, which are virtual interfaces: You must define each physical circuit within a service bundle separately and terminate it to its actual physical interface.
Each device type is assigned a number of component templates which define the physical components within a device. These are:
* Console ports
* Console server ports
* Power ports
* Power outlets
* Network interfaces
* Front ports
* Rear ports
* Device bays (which house child devices)
Whenever a new device is created, its components are automatically created per the templates assigned to its device type. For example, a Juniper EX4300-48T device type might have the following component templates defined:
* One template for a console port ("Console")
* Two templates for power ports ("PSU0" and "PSU1")
* 48 templates for 1GE interfaces ("ge-0/0/0" through "ge-0/0/47")
* Four templates for 10GE interfaces ("xe-0/2/0" through "xe-0/2/3")
Once component templates have been created, every new device that you create as an instance of this type will automatically be assigned each of the components listed above.
!!! note
Assignment of components from templates occurs only at the time of device creation. If you modify the templates of a device type, it will not affect devices which have already been created. However, you always have the option of adding, modifying, or deleting components on existing devices.
A device type represents a particular make and model of hardware that exists in the real world. Device types define the physical attributes of a device (rack height and depth) and its individual components (console, power, and network interfaces).
Device types are instantiated as devices installed within racks. For example, you might define a device type to represent a Juniper EX4300-48T network switch with 48 Ethernet interfaces. You can then create multiple devices of this type named "switch1," "switch2," and so on. Each device will inherit the components (such as interfaces) of its device type at the time of creation. (However, changes made to a device type will **not** apply to instances of that device type retroactively.)
The device type model includes three flags which inform what type of components may be added to it:
*`is_console_server`: This device type has console server ports
*`is_pdu`: This device type has power outlets
*`is_network_device`: This device type has network interfaces
Some devices house child devices which share physical resources, like space and power, but which functional independently from one another. A common example of this is blade server chassis. Each device type is designated as one of the following:
* A parent device (which has device bays)
* A child device (which must be installed in a device bay)
* Neither
!!! note
This parent/child relationship is **not** suitable for modeling chassis-based devices, wherein child members share a common control plane.
## Manufacturers
Each device type must be assigned to a manufacturer. The model number of a device type must be unique to its manufacturer.
## Component Templates
Each device type is assigned a number of component templates which define the physical components within a device. These are:
* Console ports
* Console server ports
* Power ports
* Power outlets
* Network interfaces
* Device bays (which house child devices)
Whenever a new device is created, its components are automatically created per the templates assigned to its device type. For example, a Juniper EX4300-48T device type might have the following component templates defined:
* One template for a console port ("Console")
* Two templates for power ports ("PSU0" and "PSU1")
* 48 templates for 1GE interfaces ("ge-0/0/0" through "ge-0/0/47")
* Four templates for 10GE interfaces ("xe-0/2/0" through "xe-0/2/3")
Once component templates have been created, every new device that you create as an instance of this type will automatically be assigned each of the components listed above.
!!! note
Assignment of components from templates occurs only at the time of device creation. If you modify the templates of a device type, it will not affect devices which have already been created. However, you always have the option of adding, modifying, or deleting components on existing devices.
{!docs/models/dcim/device.md!}
{!docs/models/dcim/devicerole.md!}
{!docs/models/dcim/platform.md!}
---
# Devices
## Device Components
Every piece of hardware which is installed within a rack exists in NetBox as a device. Devices are measured in rack units (U) and can be half depth or full depth. A device may have a height of 0U: These devices do not consume vertical rack space and cannot be assigned to a particular rack unit. A common example of a 0U device is a vertically-mounted PDU.
When assigning a multi-U device to a rack, it is considered to be mounted in the lowest-numbered rack unit which it occupies. For example, a 3U device which occupies U8 through U10 is said to be mounted in U8. This logic applies to racks with both ascending and descending unit numbering.
A device is said to be full depth if its installation on one rack face prevents the installation of any other device on the opposite face within the same rack unit(s). This could be either because the device is physically too deep to allow a device behind it, or because the installation of an opposing device would impede airflow.
## Device Roles
Devices can be organized by functional roles. These roles are fully customizable. For example, you might create roles for core switches, distribution switches, and access switches.
{!docs/models/dcim/consoleport.md!}
{!docs/models/dcim/consoleserverport.md!}
{!docs/models/dcim/powerport.md!}
{!docs/models/dcim/poweroutlet.md!}
{!docs/models/dcim/interface.md!}
{!docs/models/dcim/frontport.md!}
{!docs/models/dcim/rearport.md!}
{!docs/models/dcim/devicebay.md!}
{!docs/models/dcim/inventoryitem.md!}
---
# Device Components
There are six types of device components which comprise all of the interconnection logic with NetBox:
* Console ports
* Console server ports
* Power ports
* Power outlets
* Network interfaces
* Device bays
## Console
Console ports connect only to console server ports. Console connections can be marked as either *planned* or *connected*.
## Power
Power ports connect only to power outlets. Power connections can be marked as either *planned* or *connected*.
## Interfaces
Interfaces connect to one another in a symmetric manner: If interface A connects to interface B, interface B therefore connects to interface A. Each type of connection can be classified as either *planned* or *connected*.
Each interface is a assigned a form factor denoting its physical properties. Two special form factors exist: the "virtual" form factor can be used to designate logical interfaces (such as SVIs), and the "LAG" form factor can be used to desinate link aggregation groups to which physical interfaces can be assigned.
Each interface can also be enabled or disabled, and optionally designated as management-only (for out-of-band management). Fields are also provided to store an interface's MTU and MAC address.
VLANs can be assigned to each interface as either tagged or untagged. (An interface may have only one untagged VLAN.)
## Device Bays
Device bays represent the ability of a device to house child devices. For example, you might install four blade servers into a 2U chassis. The chassis would appear in the rack elevation as a 2U device with four device bays. Each server within it would be defined as a 0U device installed in one of the device bays. Child devices do not appear within rack elevations, but they are included in the "Non-Racked Devices" list within the rack view.
{!docs/models/dcim/virtualchassis.md!}
---
# Platforms
A platform defines the type of software running on a device or virtual machine. This can be helpful when it is necessary to distinguish between, for instance, different feature sets. Note that two devices of the same type may be assigned different platforms: for example, one Juniper MX240 running Junos 14 and another running Junos 15.
The platform model is also used to indicate which [NAPALM](https://napalm-automation.net/) driver NetBox should use when connecting to a remote device. The name of the driver along with optional parameters are stored with the platform.
The assignment of platforms to devices is an optional feature, and may be disregarded if not desired.
---
# Inventory Items
Inventory items represent hardware components installed within a device, such as a power supply or CPU. Currently, these are used merely for inventory tracking, although future development might see their functionality expand. Like device types, each item can optionally be assigned a manufacturer.
---
# Virtual Chassis
A virtual chassis represents a set of devices which share a single control plane: a stack of switches which are managed as a single device, for example. Each device in the virtual chassis is assigned a position and (optionally) a priority. Exactly one device is designated the virtual chassis master: This device will typically be assigned a name, secrets, services, and other attributes related to its management.
It's important to recognize the distinction between a virtual chassis and a chassis-based device. For instance, a virtual chassis is not used to model a chassis switch with removable line cards such as the Juniper EX9208, as its line cards are _not_ physically separate devices capable of operating independently.
The first step to documenting your IP space is to define its scope by creating aggregates. Aggregates establish the root of your IP address hierarchy by defining the top-level allocations that you're interested in managing. Most organizations will want to track some commonly-used private IP spaces, such as:
* 10.0.0.0/8 (RFC 1918)
* 100.64.0.0/10 (RFC 6598)
* 172.16.0.0/12 (RFC 1918)
* 192.168.0.0/16 (RFC 1918)
* One or more /48s within fd00::/8 (IPv6 unique local addressing)
In addition to one or more of these, you'll want to create an aggregate for each globally-routable space your organization has been allocated. These aggregates should match the allocations recorded in public WHOIS databases.
Each IP prefix will be automatically arranged under its parent aggregate if one exists. Note that it's advised to create aggregates only for IP ranges actually allocated to your organization (or marked for private use): There is no need to define aggregates for provider-assigned space which is only used on Internet circuits, for example.
Aggregates cannot overlap with one another: They can only exist side-by-side. For instance, you cannot define both 10.0.0.0/8 and 10.16.0.0/16 as aggregates, because they overlap. 10.16.0.0/16 in this example would be created as a prefix and automatically grouped under 10.0.0.0/8. Remember, the purpose of aggregates is to establish the root of your IP addressing hierarchy.
## Regional Internet Registries (RIRs)
[Regional Internet registries](https://en.wikipedia.org/wiki/Regional_Internet_registry) are responsible for the allocation of globally-routable address space. The five RIRs are ARIN, RIPE, APNIC, LACNIC, and AFRINIC. However, some address space has been set aside for internal use, such as defined in RFCs 1918 and 6598. NetBox considers these RFCs as a sort of RIR as well; that is, an authority which "owns" certain address space. There also exist lower-tier registries which serve a particular geographic area.
Each aggregate must be assigned to one RIR. You are free to define whichever RIRs you choose (or create your own). The RIR model includes a boolean flag which indicates whether the RIR allocates only private IP space.
For example, suppose your organization has been allocated 104.131.0.0/16 by ARIN. It also makes use of RFC 1918 addressing internally. You would first create RIRs named ARIN and RFC 1918, then create an aggregate for each of these top-level prefixes, assigning it to its respective RIR.
{!docs/models/ipam/aggregate.md!}
{!docs/models/ipam/rir.md!}
---
# Prefixes
A prefix is an IPv4 or IPv6 network and mask expressed in CIDR notation (e.g. 192.0.2.0/24). A prefix entails only the "network portion" of an IP address: All bits in the address not covered by the mask must be zero. (In other words, a prefix cannot be a specific IP address.)
Prefixes are automatically arranged by their parent aggregates. Additionally, each prefix can be assigned to a particular site and VRF (routing table). All prefixes not assigned to a VRF will appear in the "global" table.
Each prefix can be assigned a status and a role. These terms are often used interchangeably so it's important to recognize the difference between them. The **status** defines a prefix's operational state. Statuses are hard-coded in NetBox and can be one of the following:
* Container - A summary of child prefixes
* Active - Provisioned and in use
* Reserved - Designated for future use
* Deprecated - No longer in use
On the other hand, a prefix's **role** defines its function. Role assignment is optional and roles are fully customizable. For example, you might create roles to differentiate between production and development infrastructure.
A prefix may also be assigned to a VLAN. This association is helpful for identifying which prefixes are included when reviewing a list of VLANs.
The prefix model include a "pool" flag. If enabled, NetBox will treat this prefix as a range (such as a NAT pool) wherein every IP address is valid and assignable. This logic is used for identifying available IP addresses within a prefix. If this flag is disabled, NetBox will assume that the first and last (broadcast) address within the prefix are unusable.
{!docs/models/ipam/prefix.md!}
---
# IP Addresses
An IP address comprises a single host address (either IPv4 or IPv6) and its subnet mask. Its mask should match exactly how the IP address is configured on an interface in the real world.
Like prefixes, an IP address can optionally be assigned to a VRF (otherwise, it will appear in the "global" table). IP addresses are automatically organized under parent prefixes within their respective VRFs.
Also like prefixes, each IP address can be assigned a status and a role. Statuses are hard-coded in NetBox and include the following:
* Active
* Reserved
* Deprecated
* DHCP
Each IP address can optionally be assigned a special role. Roles are used to indicate some special attribute of an IP address: for example, it is used as a loopback, or is a virtual IP maintained using VRRP. (Note that this differs in purpose from a _functional_ role, and thus cannot be customized.) Available roles include:
* Loopback
* Secondary
* Anycast
* VIP
* VRRP
* HSRP
* GLBP
An IP address can be assigned to a device or virtual machine interface, and an interface may have multiple IP addresses assigned to it. Further, each device and virtual machine may have one of its interface IPs designated as its primary IP address (one for IPv4 and one for IPv6).
## Network Address Translation (NAT)
An IP address can be designated as the network address translation (NAT) inside IP address for exactly one other IP address. This is useful primarily to denote a translation between public and private IP addresses. This relationship is followed in both directions: For example, if 10.0.0.1 is assigned as the inside IP for 192.0.2.1, 192.0.2.1 will be displayed as the outside IP for 10.0.0.1.
!!! note
NetBox does not support tracking one-to-many NAT relationships (also called port address translation). This type of policy requires additional logic to model and cannot be fully represented by IP address alone.
{!docs/models/ipam/ipaddress.md!}
---
# Virtual Routing and Forwarding (VRF)
A VRF object in NetBox represents a virtual routing and forwarding (VRF) domain. Each VRF is essentially a separate routing table. VRFs are commonly used to isolate customers or organizations from one another within a network, or to route overlapping address space (e.g. multiple instances of the 10.0.0.0/8 space).
Each VRF is assigned a unique name and route distinguisher (RD). The RD is expected to take one of the forms prescribed in [RFC 4364](https://tools.ietf.org/html/rfc4364#section-4.2), however its formatting is not strictly enforced.
Each prefix and IP address may be assigned to one (and only one) VRF. If you have a prefix or IP address which exists in multiple VRFs, you will need to create a separate instance of it in NetBox for each VRF. Any IP prefix or address not assigned to a VRF is said to belong to the "global" table.
By default, NetBox will allow duplicate prefixes to be assigned to a VRF. This behavior can be disabled by setting the "enforce unique" flag on the VRF model.
!!! note
Enforcement of unique IP space can be toggled for global table (non-VRF prefixes) using the `ENFORCE_GLOBAL_UNIQUE` configuration setting.
Below is a simple diagram demonstrating how power is modeled in NetBox.
!!! note
The power feeds are connected to the same power panel for illustrative purposes; usually, you would have such feeds diversely connected to panels to avoid the single point of failure.
A secret represents a single credential or other sensitive string of characters which must be stored securely. Each secret is assigned to a device within NetBox. The plaintext value of a secret is encrypted to a ciphertext immediately prior to storage within the database using a 256-bit AES master key. A SHA256 hash of the plaintext is also stored along with each ciphertext to validate the decrypted plaintext.
Each secret can also store an optional name parameter, which is not encrypted. This may be useful for storing user names.
## Roles
Each secret is assigned a functional role which indicates what it is used for. Secret roles are customizable. Typical roles might include:
* Login credentials
* SNMP community strings
* RADIUS/TACACS+ keys
* IKE key strings
* Routing protocol shared secrets
Roles are also used to control access to secrets. Each role is assigned an arbitrary number of groups and/or users. Only the users associated with a role have permission to decrypt the secrets assigned to that role. (A superuser has permission to decrypt all secrets, provided they have an active user key.)
{!docs/models/secrets/secret.md!}
{!docs/models/secrets/secretrole.md!}
---
# User Keys
Each user within NetBox can associate his or her account with an RSA public key. If activated by an administrator, this user key will contain a unique, encrypted copy of the AES master key needed to retrieve secret data.
User keys may be created by users individually, however they are of no use until they have been activated by a user who already possesses an active user key.
## Creating the First User Key
When NetBox is first installed, it contains no encryption keys. Before it can store secrets, a user (typically the superuser) must create a user key. This can be done by navigating to Profile > User Key.
To create a user key, you can either generate a new RSA key pair, or upload the public key belonging to a pair you already have. If generating a new key pair, **you must save the private key** locally before saving your new user key. Once your user key has been created, its public key will be displayed under your profile.
When the first user key is created in NetBox, a random master encryption key is generated automatically. This key is then encrypted using the public key provided and stored as part of your user key. **The master key cannot be recovered** without your private key.
Once a user key has been assigned an encrypted copy of the master key, it is considered activated and can now be used to encrypt and decrypt secrets.
## Creating Additional User Keys
Any user can create his or her user key by generating or uploading a public RSA key. However, a user key cannot be used to encrypt or decrypt secrets until it has been activated with an encrypted copy of the master key.
Only an administrator with an active user key can activate other user keys. To do so, access the NetBox admin UI and navigate to Secrets > User Keys. Select the user key(s) to be activated, and select "activate selected user keys" from the actions dropdown. You will need to provide your private key in order to decrypt the master key. A copy of the master key is then encrypted using the public key associated with the user key being activated.
A service represents a layer four TCP or UDP service available on a device or virtual machine. For example, you might want to document that an HTTP service is running on a device. Each service includes a name, protocol, and port number; for example, "SSH (TCP/22)" or "DNS (UDP/53)."
A service may optionally be bound to one or more specific IP addresses belonging to its parent device or VM. (If no IP addresses are bound, the service is assumed to be reachable via any assigned IP address.)
How you choose to use sites will depend on the nature of your organization, but typically a site will equate to a building or campus. For example, a chain of banks might create a site to represent each of its branches, a site for its corporate headquarters, and two additional sites for its presence in two colocation facilities.
Each site must be assigned one of the following operational statuses:
* Active
* Planned
* Retired
The site model provides a facility ID field which can be used to annotate a facility ID (such as a datacenter name) associated with the site. Each site may also have an autonomous system (AS) number and time zone associated with it. (Time zones are provided by the [pytz](https://pypi.org/project/pytz/) package.)
The site model also includes several fields for storing contact and address information.
## Regions
Sites can be arranged geographically using regions. A region might represent a continent, country, city, campus, or other area depending on your use case. Regions can be nested recursively to construct a hierarchy. For example, you might define several country regions, and within each of those several state or city regions to which sites are assigned.
{!docs/models/dcim/site.md!}
{!docs/models/dcim/region.md!}
---
# Racks
The rack model represents a physical two- or four-post equipment rack in which equipment is mounted. Each rack must be assigned to a site. Rack height is measured in *rack units* (U); racks are commonly between 42U and 48U tall, but NetBox allows you to define racks of arbitrary height. A toggle is provided to indicate whether rack units are in ascending or descending order.
Each rack is assigned a name and (optionally) a separate facility ID. This is helpful when leasing space in a data center your organization does not own: The facility will often assign a seemingly arbitrary ID to a rack (for example, "M204.313") whereas internally you refer to is simply as "R113." A unique serial number may also be associated with each rack.
A rack must be designated as one of the following types:
* 2-post frame
* 4-post frame
* 4-post cabinet
* Wall-mounted frame
* Wall-mounted cabinet
Each rack has two faces (front and rear) on which devices can be mounted. Rail-to-rail width may be 19 or 23 inches.
## Rack Groups
Racks can be arranged into groups. As with sites, how you choose to designate rack groups will depend on the nature of your organization. For example, if each site represents a campus, each group might represent a building within a campus. If each site represents a building, each rack group might equate to a floor or room.
Each rack group must be assigned to a parent site. Hierarchical recursion of rack groups is not currently supported.
## Rack Roles
Each rack can optionally be assigned a functional role. For example, you might designate a rack for compute or storage resources, or to house colocated customer devices. Rack roles are fully customizable.
## Rack Space Reservations
Users can reserve units within a rack for future use. Multiple non-contiguous rack units can be associated with a single reservation (but reservations cannot span multiple racks). A rack reservation may optionally designate a specific tenant.
A tenant represents a discrete entity for administrative purposes. Typically, tenants are used to represent individual customers or internal departments within an organization. The following objects can be assigned to tenants:
* Sites
* Racks
* Rack reservations
* Devices
* VRFs
* Prefixes
* IP addresses
* VLANs
* Circuits
* Virtual machines
Tenant assignment is used to signify ownership of an object in NetBox. As such, each object may only be owned by a single tenant. For example, if you have a firewall dedicated to a particular customer, you would assign it to the tenant which represents that customer. However, if the firewall serves multiple customers, it doesn't *belong* to any particular customer, so tenant assignment would not be appropriate.
### Tenant Groups
Tenants can be organized by custom groups. For instance, you might create one group called "Customers" and one called "Acquisitions." The assignment of tenants to groups is optional.
A cluster is a logical grouping of physical resources within which virtual machines run. A cluster must be assigned a type, and may optionally be assigned to a group and/or site.
Physical devices may be associated with clusters as hosts. This allows users to track on which host(s) a particular VM may reside. However, NetBox does not support pinning a specific VM within a cluster to a particular host device.
## Cluster Types
A cluster type represents a technology or mechanism by which a cluster is formed. For example, you might create a cluster type named "VMware vSphere" for a locally hosted cluster or "DigitalOcean NYC3" for one hosted by a cloud provider.
## Cluster Groups
Cluster groups may be created for the purpose of organizing clusters. The assignment of clusters to groups is optional.
---
# Virtual Machines
A virtual machine represents a virtual compute instance hosted within a cluster. Each VM must be associated with exactly one cluster.
Like devices, each VM can be assigned a platform and have interfaces created on it. VM interfaces behave similarly to device interfaces, and can be assigned IP addresses, VLANs, and services. However, given their virtual nature, they cannot be connected to other interfaces. Unlike physical devices, VMs cannot be assigned console or power ports, device bays, or inventory items.
The following resources can be defined for each VM:
A VLAN represents an isolated layer two domain, identified by a name and a numeric ID (1-4094) as defined in [IEEE 802.1Q](https://en.wikipedia.org/wiki/IEEE_802.1Q). Each VLAN may be assigned to a site and/or VLAN group.
Each VLAN must be assigned one of the following operational statuses:
* Active
* Reserved
* Deprecated
Each VLAN may also be assigned a functional role. Prefixes and VLANs share the same set of customizable roles.
## VLAN Groups
VLAN groups can be used to organize VLANs within NetBox. Groups can also be used to enforce uniqueness: Each VLAN within a group must have a unique ID and name. VLANs which are not assigned to a group may have overlapping names and IDs (including VLANs which belong to a common site). For example, you can create two VLANs with ID 123, but they cannot both be assigned to the same group.
The registry is an in-memory data structure which houses various miscellaneous application-wide parameters, such as installed plugins. It is not exposed to the user and is not intended to be modified by any code outside of NetBox core.
The registry behaves essentially like a Python dictionary, with the notable exception that once a store (key) has been declared, it cannot be deleted or overwritten. The value of a store can, however, me modified; e.g. by appending a value to a list. Store values generally do not change once the application has been initialized.
## Stores
### `model_features`
A dictionary of particular features (e.g. custom fields) mapped to the NetBox models which support them, arranged by app. For example:
```python
{
'custom_fields':{
'circuits':['provider','circuit'],
'dcim':['site','rack','devicetype',...],
...
},
'webhooks':{
...
},
...
}
```
### `plugin_menu_items`
Navigation menu items provided by NetBox plugins. Each plugin is registered as a key with the list of menu items it provides. An example:
```python
{
'Plugin A':(
<MenuItem>,<MenuItem>,<MenuItem>,
),
'Plugin B':(
<MenuItem>,<MenuItem>,<MenuItem>,
),
}
```
### `plugin_template_extensions`
Plugin content that gets embedded into core NetBox templates. The store comprises NetBox models registered as dictionary keys, each pointing to a list of applicable template extension classes that exist. An example:
Below is a list of items to consider when adding a new field to a model:
### 1. Generate and run database migration
## 1. Generate and run database migration
Django migrations are used to express changes to the database schema. In most cases, Django can generate these automatically, however very complex changes may require manual intervention. Always remember to specify a short but descriptive name when generating a new migration.
@@ -16,7 +16,7 @@ Where possible, try to merge related changes into a single migration. For exampl
!!! note
Migrations can only be merged within a release. Once a new release has been published, its migrations cannot be altered.
### 2. Add validation logic to `clean()`
## 2. Add validation logic to `clean()`
If the new field introduces additional validation requirements (beyond what's included with the field itself), implement them in the model's `clean()` method. Remember to call the model's original method using `super()` before or agter your custom validation as appropriate:
@@ -32,23 +32,23 @@ class Foo(models.Model):
raise ValidationError()
```
### 3. Add CSV helpers
## 3. Add CSV helpers
Add the name of the new field to `csv_headers` and included a CSV-friendly representation of its data in the model's `to_csv()` method. These will be used when exporting objects in CSV format.
### 4. Update relevant querysets
## 4. Update relevant querysets
If you're adding a relational field (e.g. `ForeignKey`) and intend to include the data when retreiving a list of objects, be sure to include the field using `select_related()` or `prefetch_related()` as appropriate. This will optimize the view and avoid excessive database lookups.
If you're adding a relational field (e.g. `ForeignKey`) and intend to include the data when retreiving a list of objects, be sure to include the field using `prefetch_related()` as appropriate. This will optimize the view and avoid excessive database lookups.
### 5. Update API serializer
## 5. Update API serializer
Extend the model's API serializer in `<app>.api.serializers` to include the new field. In most cases, it will not be necessary to also extend the nested serializer, which produces a minimal represenation of the model.
### 6. Add choices to API view
## 6. Add choices to API view
If the new field has static choices, add it to the `FieldChoicesViewSet` for the app.
### 7. Add field to forms
## 7. Add field to forms
Extend any forms to include the new field as appropriate. Common forms include:
@@ -57,18 +57,26 @@ Extend any forms to include the new field as appropriate. Common forms include:
* **CSV import** - The form used when bulk importing objects in CSV format
* **Filter** - Displays the options available for filtering a list of objects (both UI and API)
### 8. Extend object filter set
## 8. Extend object filter set
If the new field should be filterable, add it to the `FilterSet` for the model. If the field should be searchable, remember to reference it in the FilterSet's `search()` method.
### 9. Add column to object table
## 9. Add column to object table
If the new field will be included in the object list view, add a column to the model's table. For simple fields, adding the field name to `Meta.fields` will be sufficient. More complex fields may require explicitly declaring a new column.
### 10. Update the UI templates
## 10. Update the UI templates
Edit the object's view template to display the new field. There may also be a custom add/edit form template that needs to be updated.
### 11. Adjust API and model tests
## 11. Create/extend test cases
Extend the model and/or API tests to verify that the new field and any accompanying validation logic perform as expected. This is especially important for relational fields.
Create or extend the relevant test cases to verify that the new field and any accompanying validation logic perform as expected. This is especially important for relational fields. NetBox incorporates various test suites, including:
* API serializer/view tests
* Filter tests
* Form tests
* Model tests
* View tests
Be diligent to ensure all of the relevant test suites are adapted or extended as necessary to test any new functionality.
NetBox is maintained as a [GitHub project](https://github.com/digitalocean/netbox) under the Apache 2 license. Users are encouraged to submit GitHub issues for feature requests and bug reports, however we are very selective about pull requests. Please see the `CONTRIBUTING` guide for more direction on contributing to NetBox.
NetBox is maintained as a [GitHub project](https://github.com/netbox-community/netbox) under the Apache 2 license. Users are encouraged to submit GitHub issues for feature requests and bug reports, however we are very selective about pull requests. Please see the `CONTRIBUTING` guide for more direction on contributing to NetBox.
## Communication
Communication among developers should always occur via public channels:
* [GitHub issues](https://github.com/digitalocean/netbox/issues) - All feature requests, bug reports, and other substantial changes to the code base **must** be documented in an issue.
* [GitHub issues](https://github.com/netbox-community/netbox/issues) - All feature requests, bug reports, and other substantial changes to the code base **must** be documented in an issue.
* [The mailing list](https://groups.google.com/forum/#!forum/netbox-discuss) - The preferred forum for general discussion and support issues. Ideal for shaping a feature request prior to submitting an issue.
* [#netbox on NetworkToCode](http://slack.networktocode.com/) - Good for quick chats. Avoid any discussion that might need to be referenced later on, as the chat history is not retained long.
Required Python packages are maintained in two files. `base_requirements.txt` contains a list of all the packages required by NetBox. Some of them may be pinned to a specific version of the package due to a known issue. For example:
3. Run all tests and check that the UI and API function as expected.
4. Update the package versions in `requirements.txt` as appropriate.
## Update Static Libraries
### Update Static Libraries
Update the following static libraries to their most recent stable release:
* Bootstrap 3
* Font Awesome 4
* Select2
* jQuery
* jQuery UI
## Manually Perform a New Install
### Create a new Release Notes Page
Create a file at `/docs/release-notes/X.Y.md` to establish the release notes for the new release. Add the file to the table of contents within `mkdocs.yml`, and point `index.md` to the new file.
### Manually Perform a New Install
Create a new installation of NetBox by following [the current documentation](http://netbox.readthedocs.io/en/latest/). This should be a manual process, so that issues with the documentation can be identified and corrected.
## Close the Release Milestone
### Close the Release Milestone
Close the release milestone on GitHub. Ensure that there are no remaining open issues associated with it.
---
# All Releases
## All Releases
## Verify CI Build Status
### Verify CI Build Status
Ensure that continuous integration testing on the `develop` branch is completing successfully.
## Update Version and Changelog
### Update Version and Changelog
Update the `VERSION` constant in `settings.py` to the new release version and add the current date to the release notes in `CHANGELOG.md`.
Update the `VERSION` constant in `settings.py` to the new release version and annotate the current data in the release notes for the new version.
## Submit a Pull Request
### Submit a Pull Request
Submit a pull request title **"Release vX.Y.X"** to merge the `develop` branch into `master`. Include a brief change log listing the features, improvements, and/or bugs addressed in the release.
Submit a pull request title **"Release vX.Y.Z"** to merge the `develop` branch into `master`. Include a brief change log listing the features, improvements, and/or bugs addressed in the release.
Once CI has completed on the PR, merge it.
## Create a New Release
### Create a New Release
Draft a [new release](https://github.com/digitalocean/netbox/releases/new) with the following parameters.
Draft a [new release](https://github.com/netbox-community/netbox/releases/new) with the following parameters.
* **Tag:** Current version (e.g. `v2.3.4`)
* **Target:** `master`
@@ -68,7 +75,7 @@ Draft a [new release](https://github.com/digitalocean/netbox/releases/new) with
Copy the description from the pull request into the release notes.
## Update the Development Version
### Update the Development Version
On the `develop` branch, update `VERSION` in `settings.py` to point to the next release. For example, if you just released v2.3.4, set:
@@ -76,6 +83,6 @@ On the `develop` branch, update `VERSION` in `settings.py` to point to the next
VERSION = 'v2.3.5-dev'
```
## Announce the Release
### Announce the Release
Announce the release on the [mailing list](https://groups.google.com/forum/#!forum/netbox-discuss). Include a link to the release and the (HTML-formatted) release notes.
NetBox generally follows the [Django style guide](https://docs.djangoproject.com/en/dev/internals/contributing/writing-code/coding-style/), which is itself based on [PEP 8](https://www.python.org/dev/peps/pep-0008/). [Pycodestyle](https://github.com/pycqa/pycodestyle) is used to validate code formatting, ignoring certain violations. See `scripts/cibuild.sh`.
NetBox generally follows the [Django style guide](https://docs.djangoproject.com/en/stable/internals/contributing/writing-code/coding-style/), which is itself based on [PEP 8](https://www.python.org/dev/peps/pep-0008/). [Pycodestyle](https://github.com/pycqa/pycodestyle) is used to validate code formatting, ignoring certain violations. See `scripts/cibuild.sh`.
The introduction of a new dependency is best avoided unless it is absolutely necessary. For small features, it's generally preferable to replicate functionality within the NetBox code base rather than to introduce reliance on an external project. This reduces both the burden of tracking new releases and our exposure to outside bugs and attacks.
If there's a strong case for introducing a new depdency, it must meet the following criteria:
If there's a strong case for introducing a new dependency, it must meet the following criteria:
* Its complete source code must be published and freely accessible without registration.
* Its license must be conducive to inclusion in an open source project.
@@ -45,10 +45,18 @@ When adding a new dependency, a short description of the package and the URL of
* When in doubt, remain consistent: It is better to be consistently incorrect than inconsistently correct. If you notice in the course of unrelated work a pattern that should be corrected, continue to follow the pattern for now and open a bug so that the entire code base can be evaluated at a later point.
* Prioritize readability over concision. Python is a very flexible language that typically gives us several options for expressing a given piece of logic, but some may be more friendly to the reader than others. (List comprehensions are particularly vulnerable to over-optimization.) Always remain considerate of the future reader who may need to interpret your code without the benefit of the context within which you are writing it.
* No easter eggs. While they can be fun, NetBox must be considered as a business-critical tool. The potential, however minor, for introducing a bug caused by unnecessary logic is best avoided entirely.
* Constants (variables which generally do not change) should be declared in `constants.py` within each app. Wildcard imports from the file are acceptable.
* Every model should have a docstring. Every custom method should include an expalantion of its function.
* Every model should have a docstring. Every custom method should include an explanation of its function.
* Nested API serializers generate minimal representations of an object. These are stored separately from the primary serializers to avoid circular dependencies. Always import nested serializers from other apps directly. For example, from within the DCIM app you would write `from ipam.api.nested_serializers import NestedIPAddressSerializer`.
## Branding
* When referring to NetBox in writing, use the proper form "NetBox," with the letters N and B capitalized. The lowercase form "netbox" should be used in code, filenames, etc. But never "Netbox" or any other deviation.
* There is an SVG form of the NetBox logo at [docs/netbox_logo.svg](../netbox_logo.svg). It is preferred to use this logo for all purposes as it scales to arbitrary sizes without loss of resolution. If a raster image is required, the SVG logo should be converted to a PNG image of the prescribed size.
The `users.UserConfig` model holds individual preferences for each user in the form of JSON data. This page serves as a manifest of all recognized user preferences in NetBox.
## Available Preferences
| Name | Description |
| ---- | ----------- |
| extras.configcontext.format | Preferred format when rendering config context data (JSON or YAML) |
| pagination.per_page | The number of items to display per page of a paginated table |
| tables.${table_name}.columns | The ordered list of columns to display when viewing the table |
@@ -12,7 +12,7 @@ NetBox is an open source web application designed to help manage and document co
* **Data circuits** - Long-haul communications circuits and providers
* **Secrets** - Encrypted storage of sensitive credentials
# What NetBox Is Not
## What NetBox Is Not
While NetBox strives to cover many areas of network management, the scope of its feature set is necessarily limited. This ensures that development focuses on core functionality and that scope creep is reasonably contained. To that end, it might help to provide some examples of functionality that NetBox **does not** provide:
@@ -24,23 +24,23 @@ While NetBox strives to cover many areas of network management, the scope of its
That said, NetBox _can_ be used to great effect in populating external tools with the data they need to perform these functions.
# Design Philosophy
## Design Philosophy
NetBox was designed with the following tenets foremost in mind.
## Replicate the Real World
### Replicate the Real World
Careful consideration has been given to the data model to ensure that it can accurately reflect a real-world network. For instance, IP addresses are assigned not to devices, but to specific interfaces attached to a device, and an interface may have multiple IP addresses assigned to it.
## Serve as a "Source of Truth"
### Serve as a "Source of Truth"
NetBox intends to represent the _desired_ state of a network versus its _operational_ state. As such, automated import of live network state is strongly discouraged. All data created in NetBox should first be vetted by a human to ensure its integrity. NetBox can then be used to populate monitoring and provisioning systems with a high degree of confidence.
## Keep it Simple
### Keep it Simple
When given a choice between a relatively simple [80% solution](https://en.wikipedia.org/wiki/Pareto_principle) and a much more complex complete solution, the former will typically be favored. This ensures a lean codebase with a low learning curve.
# Application Stack
## Application Stack
NetBox is built on the [Django](https://djangoproject.com/) Python framework and utilizes a [PostgreSQL](https://www.postgresql.org/) database. It runs as a WSGI service behind your choice of HTTP server.
@@ -53,6 +53,10 @@ NetBox is built on the [Django](https://djangoproject.com/) Python framework and
| Task queuing | Redis/django-rq |
| Live device access | NAPALM |
# Getting Started
## Supported Python Versions
NetBox supports Python 3.6 and 3.7 environments currently. (Support for Python 3.5 was removed in NetBox v2.8.)
## Getting Started
See the [installation guide](installation/index.md) for help getting NetBox up and running quickly.
NetBox requires a PostgreSQL database to store data. This can be hosted locally or on a remote server. (Please note that MySQL is not supported, as NetBox leverages PostgreSQL's built-in [network address types](https://www.postgresql.org/docs/current/static/datatype-net-types.html).)
# PostgreSQL Database Installation
!!! note
The installation instructions provided here have been tested to work on Ubuntu 16.04 and CentOS 7.4. The particular commands needed to install dependencies on other distributions may vary significantly. Unfortunately, this is outside the control of the NetBox maintainers. Please consult your distribution's documentation for assistance with any errors.
This section entails the installation and configuration of a local PostgreSQL database. If you already have a PostgreSQL database service in place, skip to [the next section](2-redis.md).
!!! warning
NetBox v2.2 and later requires PostgreSQL 9.4 or higher.
NetBox requires PostgreSQL 9.4 or higher. Please note that MySQL and other relational databases are **not** supported.
# Installation
The installation instructions provided here have been tested to work on Ubuntu 18.04 and CentOS 7.5. The particular commands needed to install dependencies on other distributions may vary significantly. Unfortunately, this is outside the control of the NetBox maintainers. Please consult your distribution's documentation for assistance with any errors.
**Ubuntu**
## Installation
#### Ubuntu
If a recent enough version of PostgreSQL is not available through your distribution's package manager, you'll need to install it from an official [PostgreSQL repository](https://wiki.postgresql.org/wiki/Apt).
@@ -17,13 +18,13 @@ If a recent enough version of PostgreSQL is not available through your distribut
# apt-get install -y postgresql libpq-dev
```
**CentOS**
#### CentOS
CentOS 7.4 does not ship with a recent enough version of PostgreSQL, so it will need to be installed from an external repository. The instructions below show the installation of PostgreSQL 9.6.
CentOS 7.5 does not ship with a recent enough version of PostgreSQL, so it will need to be installed from an external repository. The instructions below show the installation of PostgreSQL 9.6, however you may opt to install a more recent version.
@@ -41,7 +42,7 @@ Then, start the service and enable it to run at boot:
# systemctl enable postgresql-9.6
```
# Database Creation
## Database Creation
At a minimum, we need to create a database for NetBox and assign it a username and password for authentication. This is done with the following commands.
@@ -62,6 +63,8 @@ GRANT
postgres=# \q
```
## Verify Service Status
You can verify that authentication works issuing the following command and providing the configured password. (Replace `localhost` with your database server if using a remote database.)
You may opt to install NetBox either from a numbered release or by cloning the master branch of its repository on GitHub.
## Option A: Download a Release
Download the [latest stable release](https://github.com/digitalocean/netbox/releases) from GitHub as a tarball or ZIP archive and extract it to your desired path. In this example, we'll use `/opt/netbox`.
Ensure that the media directory (`/opt/netbox/netbox/media/` in this example) and all its subdirectories are writable by the user account as which NetBox runs. If the NetBox process does not have permission to write to this directory, attempts to upload files (e.g. image attachments) will fail. (The appropriate user account will vary by platform.)
Install the required Python packages using pip. (If you encounter any compilation errors during this step, ensure that you've installed all of the system dependencies listed above.)
```no-highlight
# pip3 install -r requirements.txt
```
!!! note
If you encounter errors while installing the required packages, check that you're running a recent version of pip (v9.0.1 or higher) with the command `pip3 -V`.
## NAPALM Automation (Optional)
NetBox supports integration with the [NAPALM automation](https://napalm-automation.net/) library. NAPALM allows NetBox to fetch live data from devices and return it to a requester via its REST API. Installation of NAPALM is optional. To enable it, install the `napalm` package using pip or pip3:
```no-highlight
# pip3 install napalm
```
## Webhooks (Optional)
[Webhooks](../data-model/extras/#webhooks) allow NetBox to integrate with external services by pushing out a notification each time a relevant object is created, updated, or deleted. Enabling the webhooks feature requires [Redis](https://redis.io/), a lightweight in-memory database. You may opt to install a Redis sevice locally (see below) or connect to an external one.
**Ubuntu**
```no-highlight
# apt-get install -y redis-server
```
**CentOS**
```no-highlight
# yum install -y redis
```
Enabling webhooks also requires installing the [`django-rq`](https://github.com/ui/django-rq) package. This allows NetBox to use the Redis database as a queue for outgoing webhooks.
```no-highlight
# pip3 install django-rq
```
# Configuration
Move into the NetBox configuration directory and make a copy of `configuration.example.py` named `configuration.py`.
```no-highlight
# cd netbox/netbox/
# cp configuration.example.py configuration.py
```
Open `configuration.py` with your preferred editor and set the following variables:
* ALLOWED_HOSTS
* DATABASE
* SECRET_KEY
## ALLOWED_HOSTS
This is a list of the valid hostnames by which this server can be reached. You must specify at least one name or IP address.
This parameter holds the database configuration details. You must define the username and password used when you configured PostgreSQL. If the service is running on a remote host, replace `localhost` with its address.
'PORT': '', # Database port (leave blank for default)
}
```
## SECRET_KEY
Generate a random secret key of at least 50 alphanumeric characters. This key must be unique to this installation and must not be shared outside the local system.
You may use the script located at `netbox/generate_secret_key.py` to generate a suitable key.
!!! note
In the case of a highly available installation with multiple web servers, `SECRET_KEY` must be identical among all servers in order to maintain a persistent user session state.
## Webhooks Configuration
If you have opted to enable the webhooks, set `WEBHOOKS_ENABLED = True` and define the relevant `REDIS` database parameters. Below is an example:
```python
WEBHOOKS_ENABLED = True
REDIS = {
'HOST': 'localhost',
'PORT': 6379,
'PASSWORD': '',
'DATABASE': 0,
'DEFAULT_TIMEOUT': 300,
}
```
# Run Database Migrations
Before NetBox can run, we need to install the database schema. This is done by running `python3 manage.py migrate` from the `netbox` directory (`/opt/netbox/netbox/` in our example):
If this step results in a PostgreSQL authentication error, ensure that the username and password created in the database match what has been specified in `configuration.py`
# Create a Super User
NetBox does not come with any predefined user accounts. You'll need to create a super user to be able to log into NetBox:
```no-highlight
# python3 manage.py createsuperuser
Username: admin
Email address: admin@example.com
Password:
Password (again):
Superuser created successfully.
```
# Collect Static Files
```no-highlight
# python3 manage.py collectstatic --no-input
You have requested to collect static files at the destination
location as specified in your settings:
/opt/netbox/netbox/static
This will overwrite existing files!
Are you sure you want to do this?
Type 'yes' to continue, or 'no' to cancel: yes
```
# Load Initial Data (Optional)
NetBox ships with some initial data to help you get started: RIR definitions, common devices roles, etc. You can delete any seed data that you don't want to keep.
!!! note
This step is optional. It's perfectly fine to start using NetBox without using this initial data if you'd rather create everything from scratch.
```no-highlight
# python3 manage.py loaddata initial_data
Installed 43 object(s) from 4 fixture(s)
```
# Test the Application
At this point, NetBox should be able to run. We can verify this by starting a development instance:
Django version 2.0.9, using settings 'netbox.settings'
Starting development server at http://0.0.0.0:8000/
Quit the server with CONTROL-C.
```
Next, connect to the name or IP of the server (as defined in `ALLOWED_HOSTS`) on port 8000; for example, <http://127.0.0.1:8000/>. You should be greeted with the NetBox home page. Note that this built-in web service is for development and testing purposes only. **It is not suited for production use.**
!!! warning
If the test service does not run, or you cannot reach the NetBox home page, something has gone wrong. Do not proceed with the rest of this guide until the installation has been corrected.
[Redis](https://redis.io/) is an in-memory key-value store which NetBox employs for caching and queuing. This section entails the installation and configuration of a local Redis instance. If you already have a Redis service in place, skip to [the next section](3-netbox.md).
### Ubuntu
```no-highlight
# apt-get install -y redis-server
```
### CentOS
```no-highlight
# yum install -y epel-release
# yum install -y redis
# systemctl start redis
# systemctl enable redis
```
You may wish to modify the Redis configuration at `/etc/redis.conf` or `/etc/redis/redis.conf`, however in most cases the default configuration is sufficient.
## Verify Service Status
Use the `redis-cli` utility to ensure the Redis service is functional:
We'll set up a simple WSGI front end using [gunicorn](http://gunicorn.org/) for the purposes of this guide. For web servers, we provide example configurations for both [nginx](https://www.nginx.com/resources/wiki/) and [Apache](http://httpd.apache.org/docs/2.4). (You are of course free to use whichever combination of HTTP and WSGI services you'd like.) We'll also use [supervisord](http://supervisord.org/) to enable service persistence.
!!! info
For the sake of brevity, only Ubuntu 16.04 instructions are provided here, but this sort of web server and WSGI configuration is not unique to NetBox. Please consult your distribution's documentation for assistance if needed.
# Web Server Installation
## Option A: nginx
The following will serve as a minimal nginx configuration. Be sure to modify your server name and installation path appropriately.
```no-highlight
# apt-get install -y nginx
```
Once nginx is installed, save the following configuration to `/etc/nginx/sites-available/netbox`. Be sure to replace `netbox.example.com` with the domain name or IP address of your installation. (This should match the value configured for `ALLOWED_HOSTS` in `configuration.py`.)
```nginx
server {
listen 80;
server_name netbox.example.com;
client_max_body_size 25m;
location /static/ {
alias /opt/netbox/netbox/static/;
}
location / {
proxy_pass http://127.0.0.1:8001;
proxy_set_header X-Forwarded-Host $server_name;
proxy_set_header X-Real-IP $remote_addr;
proxy_set_header X-Forwarded-Proto $scheme;
add_header P3P 'CP="ALL DSP COR PSAa PSDa OUR NOR ONL UNI COM NAV"';
}
}
```
Then, delete `/etc/nginx/sites-enabled/default` and create a symlink in the `sites-enabled` directory to the configuration file you just created.
```no-highlight
# cd /etc/nginx/sites-enabled/
# rm default
# ln -s /etc/nginx/sites-available/netbox
```
Restart the nginx service to use the new configuration.
```no-highlight
# service nginx restart
```
To enable SSL, consider this guide on [securing nginx with Let's Encrypt](https://www.digitalocean.com/community/tutorials/how-to-secure-nginx-with-let-s-encrypt-on-ubuntu-16-04).
Once Apache is installed, proceed with the following configuration (Be sure to modify the `ServerName` appropriately):
```apache
<VirtualHost *:80>
ProxyPreserveHost On
ServerName netbox.example.com
Alias /static /opt/netbox/netbox/static
# Needed to allow token-based API authentication
WSGIPassAuthorization on
<Directory /opt/netbox/netbox/static>
Options Indexes FollowSymLinks MultiViews
AllowOverride None
Require all granted
</Directory>
<Location /static>
ProxyPass !
</Location>
RequestHeader set "X-Forwarded-Proto" expr=%{REQUEST_SCHEME}
ProxyPass / http://127.0.0.1:8001/
ProxyPassReverse / http://127.0.0.1:8001/
</VirtualHost>
```
Save the contents of the above example in `/etc/apache2/sites-available/netbox.conf`, enable the `proxy` and `proxy_http` modules, and reload Apache:
```no-highlight
# a2enmod proxy
# a2enmod proxy_http
# a2enmod headers
# a2ensite netbox
# service apache2 restart
```
To enable SSL, consider this guide on [securing Apache with Let's Encrypt](https://www.digitalocean.com/community/tutorials/how-to-secure-apache-with-let-s-encrypt-on-ubuntu-16-04).
# gunicorn Installation
Install gunicorn:
```no-highlight
# pip3 install gunicorn
```
Save the following configuration in the root netbox installation path as `gunicorn_config.py` (e.g. `/opt/netbox/gunicorn_config.py` per our example installation). Be sure to verify the location of the gunicorn executable on your server (e.g. `which gunicorn`) and to update the `pythonpath` variable if needed. If using CentOS/RHEL, change the username from `www-data` to `nginx` or `apache`.
```no-highlight
command = '/usr/bin/gunicorn'
pythonpath = '/opt/netbox/netbox'
bind = '127.0.0.1:8001'
workers = 3
user = 'www-data'
```
# supervisord Installation
Install supervisor:
```no-highlight
# apt-get install -y supervisor
```
Save the following as `/etc/supervisor/conf.d/netbox.conf`. Update the `command` and `directory` paths as needed. If using CentOS/RHEL, change the username from `www-data` to `nginx` or `apache`.
Then, restart the supervisor service to detect and run the gunicorn service:
```no-highlight
# service supervisor restart
```
At this point, you should be able to connect to the nginx HTTP service at the server name or IP address you provided. If you are unable to connect, check that the nginx service is running and properly configured. If you receive a 502 (bad gateway) error, this indicates that gunicorn is misconfigured or not running.
!!! info
Please keep in mind that the configurations provided here are bare minimums required to get NetBox up and running. You will almost certainly want to make some changes to better suit your production environment.
This section of the documentation discusses installing and configuring the NetBox application itself.
## Install System Packages
Begin by installing all system packages required by NetBox and its dependencies. Note that beginning with NetBox v2.8, Python 3.6 or later is required.
You may opt to install NetBox either from a numbered release or by cloning the master branch of its repository on GitHub.
### Option A: Download a Release
Download the [latest stable release](https://github.com/netbox-community/netbox/releases) from GitHub as a tarball or ZIP archive and extract it to your desired path. In this example, we'll use `/opt/netbox`.
Create a system user account named `netbox`. We'll configure the WSGI and HTTP services to run under this account. We'll also assign this user ownership of the media directory. This ensures that NetBox will be able to save local files.
!!! note
CentOS users may need to create the `netbox` group first.
We'll use a Python [virtual environment](https://docs.python.org/3.6/tutorial/venv.html) to ensure NetBox's required packages don't conflict with anything in the base system. This will create a directory named `venv` in our NetBox root.
```no-highlight
# python3 -m venv /opt/netbox/venv
```
Next, activate the virtual environment and install the required Python packages. You should see your console prompt change to indicate the active environment. (Activating the virtual environment updates your command shell to use the local copy of Python that we just installed for NetBox instead of the system's Python interpreter.)
```no-highlight
# source venv/bin/activate
(venv) # pip3 install -r requirements.txt
```
### NAPALM Automation (Optional)
NetBox supports integration with the [NAPALM automation](https://napalm-automation.net/) library. NAPALM allows NetBox to fetch live data from devices and return it to a requester via its REST API. Installation of NAPALM is optional. To enable it, install the `napalm` package:
```no-highlight
(venv) # pip3 install napalm
```
To ensure NAPALM is automatically re-installed during future upgrades, create a file named `local_requirements.txt` in the NetBox root directory (alongside `requirements.txt`) and list the `napalm` package:
```no-highlight
# echo napalm >> local_requirements.txt
```
### Remote File Storage (Optional)
By default, NetBox will use the local filesystem to storage uploaded files. To use a remote filesystem, install the [`django-storages`](https://django-storages.readthedocs.io/en/stable/) library and configure your [desired backend](../../configuration/optional-settings/#storage_backend) in `configuration.py`.
```no-highlight
(venv) # pip3 install django-storages
```
Don't forget to add the `django-storages` package to `local_requirements.txt` to ensure it gets re-installed during future upgrades:
```no-highlight
# echo django-storages >> local_requirements.txt
```
## Configuration
Move into the NetBox configuration directory and make a copy of `configuration.example.py` named `configuration.py`.
This parameter holds the database configuration details. You must define the username and password used when you configured PostgreSQL. If the service is running on a remote host, replace `localhost` with its address. See the [configuration documentation](../../configuration/required-settings/#database) for more detail on individual parameters.
'PORT': '', # Database port (leave blank for default)
'CONN_MAX_AGE': 300, # Max database connection age
}
```
### REDIS
Redis is a in-memory key-value store required as part of the NetBox installation. It is used for features such as webhooks and caching. Redis typically requires minimal configuration; the values below should suffice for most installations. See the [configuration documentation](../../configuration/required-settings/#redis) for more detail on individual parameters.
```python
REDIS = {
'tasks': {
'HOST': 'redis.example.com',
'PORT': 1234,
'PASSWORD': 'foobar',
'DATABASE': 0,
'DEFAULT_TIMEOUT': 300,
'SSL': False,
},
'caching': {
'HOST': 'localhost',
'PORT': 6379,
'PASSWORD': '',
'DATABASE': 1,
'DEFAULT_TIMEOUT': 300,
'SSL': False,
}
}
```
### SECRET_KEY
Generate a random secret key of at least 50 alphanumeric characters. This key must be unique to this installation and must not be shared outside the local system.
You may use the script located at `netbox/generate_secret_key.py` to generate a suitable key.
!!! note
In the case of a highly available installation with multiple web servers, `SECRET_KEY` must be identical among all servers in order to maintain a persistent user session state.
## Run Database Migrations
Before NetBox can run, we need to install the database schema. This is done by running `python3 manage.py migrate` from the `netbox` directory (`/opt/netbox/netbox/` in our example):
If this step results in a PostgreSQL authentication error, ensure that the username and password created in the database match what has been specified in `configuration.py`
## Create a Super User
NetBox does not come with any predefined user accounts. You'll need to create a super user to be able to log into NetBox:
Django version 2.0.9, using settings 'netbox.settings'
Starting development server at http://0.0.0.0:8000/
Quit the server with CONTROL-C.
```
Next, connect to the name or IP of the server (as defined in `ALLOWED_HOSTS`) on port 8000; for example, <http://127.0.0.1:8000/>. You should be greeted with the NetBox home page. Note that this built-in web service is for development and testing purposes only. **It is not suited for production use.**
!!! warning
If the test service does not run, or you cannot reach the NetBox home page, something has gone wrong. Do not proceed with the rest of this guide until the installation has been corrected.
Note that the initial UI will be locked down for non-authenticated users.
After logging in as the superuser you created earlier, all areas of the UI will be available.
We'll set up a simple WSGI front end using [gunicorn](http://gunicorn.org/) for the purposes of this guide. For web servers, we provide example configurations for both [nginx](https://www.nginx.com/resources/wiki/) and [Apache](http://httpd.apache.org/docs/2.4). (You are of course free to use whichever combination of HTTP and WSGI services you'd like.) We'll use systemd to enable service persistence.
!!! info
For the sake of brevity, only Ubuntu 18.04 instructions are provided here, but this sort of web server and WSGI configuration is not unique to NetBox. Please consult your distribution's documentation for assistance if needed.
## Obtain an SSL Certificate
To enable HTTPS access to NetBox, you'll need a valid SSL certificate. You can purchase one from a trusted commercial provider, obtain one for free from [Let's Encrypt](https://letsencrypt.org/getting-started/), or generate your own (although self-signed certificates are generally untrusted). Both the public certificate and private key files need to be installed on your NetBox server in a location that is readable by the `netbox` user.
The command below can be used to generate a self-signed certificate for testing purposes, however it is strongly recommended to use a certificate from a trusted authority in production. Two files will be created: the public certificate (`netbox.crt`) and the private key (`netbox.key`). The certificate is published to the world, whereas the private key must be kept secret at all times.
The following will serve as a minimal nginx configuration. Be sure to modify your server name and installation path appropriately.
```no-highlight
# apt-get install -y nginx
```
Once nginx is installed, copy the default nginx configuration file to `/etc/nginx/sites-available/netbox`. Be sure to replace `netbox.example.com` with the domain name or IP address of your installation. (This should match the value configured for `ALLOWED_HOSTS` in `configuration.py`.)
Finally, ensure that the required Apache modules are enabled, enable the `netbox` site, and reload Apache:
```no-highlight
# a2enmod ssl proxy proxy_http headers
# a2ensite netbox
# service apache2 restart
```
!!! note
Certain components of NetBox (such as the display of rack elevation diagrams) rely on the use of embedded objects. Ensure that your HTTP server configuration does not override the `X-Frame-Options` response header set by NetBox.
## Gunicorn Configuration
Copy `/opt/netbox/contrib/gunicorn.py` to `/opt/netbox/gunicorn.py`. (We make a copy of this file to ensure that any changes to it do not get overwritten by a future upgrade.)
```no-highlight
# cd /opt/netbox
# cp contrib/gunicorn.py /opt/netbox/gunicorn.py
```
You may wish to edit this file to change the bound IP address or port number, or to make performance-related adjustments. See [the Gunicorn documentation](https://docs.gunicorn.org/en/stable/configure.html) for the available configuration parameters.
## systemd Configuration
We'll use systemd to control the daemonization of NetBox services. First, copy `contrib/netbox.service` and `contrib/netbox-rq.service` to the `/etc/systemd/system/` directory:
```no-highlight
# cp contrib/*.service /etc/systemd/system/
```
Then, start the `netbox` and `netbox-rq` services and enable them to initiate at boot time:
```no-highlight
# systemctl daemon-reload
# systemctl start netbox netbox-rq
# systemctl enable netbox netbox-rq
```
You can use the command `systemctl status netbox` to verify that the WSGI service is running:
At this point, you should be able to connect to the HTTP service at the server name or IP address you provided.
!!! info
Please keep in mind that the configurations provided here are bare minimums required to get NetBox up and running. You may want to make adjustments to better suit your production environment.
## Troubleshooting
If you are unable to connect to the HTTP server, check that:
* Nginx/Apache is running and configured to listen on the correct port.
* Access is not being blocked by a firewall. (Try connecting locally from the server itself.)
If you are able to connect but receive a 502 (bad gateway) error, check the following:
* The NetBox system process (gunicorn) is running: `systemctl status netbox`
* nginx/Apache is configured to connect to the port on which gunicorn is listening (default is 8001).
* SELinux is not preventing the reverse proxy connection. You may need to allow HTTP network connections with the command `setsebool -P httpd_can_network_connect 1`
This guide explains how to implement LDAP authentication using an external server. User authentication will fall back to built-in Django users in the event of a failure.
Create a file in the same directory as `configuration.py` (typically `netbox/netbox/`) named `ldap_config.py`. Define all of the parameters required below in `ldap_config.py`. Complete documentation of all `django-auth-ldap` configuration options is included in the project's [official documentation](http://django-auth-ldap.readthedocs.io/).
## General Server Configuration
### General Server Configuration
!!! info
When using Windows Server 2012 you may need to specify a port on `AUTH_LDAP_SERVER_URI`. Use `3269` for secure, or `3268` for non-secure.
@@ -54,7 +66,7 @@ LDAP_IGNORE_CERT_ERRORS = True
STARTTLS can be configured by setting `AUTH_LDAP_START_TLS = True` and using the `ldap://` URI scheme.
## User Authentication
### User Authentication
!!! info
When using Windows Server 2012, `AUTH_LDAP_USER_DN_TEMPLATE` should be set to None.
@@ -79,7 +91,8 @@ AUTH_LDAP_USER_ATTR_MAP = {
}
```
# User Groups for Permissions
### User Groups for Permissions
!!! info
When using Microsoft Active Directory, support for nested groups can be activated by using `NestedGroupOfNamesType()` instead of `GroupOfNamesType()` for `AUTH_LDAP_GROUP_TYPE`. You will also need to modify the import line to use `NestedGroupOfNamesType` instead of `GroupOfNamesType` .
# Cache groups for one hour to reduce LDAP traffic
AUTH_LDAP_CACHE_GROUPS = True
AUTH_LDAP_GROUP_CACHE_TIMEOUT = 3600
AUTH_LDAP_CACHE_TIMEOUT = 3600
```
* `is_active` - All users must be mapped to at least this group to enable authentication. Without this, users cannot log in.
* `is_staff` - Users mapped to this group are enabled for access to the administration tools; this is the equivalent of checking the "staff status" box on a manually created user. This doesn't grant any specific permissions.
* `is_superuser` - Users mapped to this group will be granted superuser status. Superusers are implicitly granted all permissions.
!!! warning
Authentication will fail if the groups (the distinguished names) do not exist in the LDAP directory.
## Troubleshooting LDAP
`systemctl restart netbox` restarts the Netbox service, and initiates any changes made to `ldap_config.py`. If there are syntax errors present, the NetBox process will not spawn an instance, and errors should be logged to `/var/log/messages`.
For troubleshooting LDAP user/group queries, add the following lines to the start of `ldap_config.py` after `import ldap`.
Ensure the file and path specified in logfile exist and are writable and executable by the application service account. Restart the netbox service and attempt to log into the site to trigger log entries to this file.
The following sections detail how to set up a new instance of NetBox:
1. [PostgreSQL database](1-postgresql.md)
2. [NetBox components](2-netbox.md)
3. [HTTP dameon](3-http-daemon.md)
4. [LDAP authentication](4-ldap.md) (optional)
1. [Redis](2-redis.md)
3. [NetBox components](3-netbox.md)
4. [HTTP daemon](4-http-daemon.md)
5. [LDAP authentication](5-ldap.md) (optional)
# Upgrading
Below is a simplified overview of the NetBox application stack for reference:
## Upgrading
If you are upgrading from an existing installation, please consult the [upgrading guide](upgrading.md).
NetBox v2.5 and later requires Python 3. Please see the instruction for [migrating to Python 3](migrating-to-python3.md) if you are still using Python 2.
Netbox v2.5.9 and later moved to using systemd instead of supervisord. Please see the instructions for [migrating to systemd](migrating-to-systemd.md) if you are still using supervisord.
This document contains instructions for migrating from a legacy NetBox deployment using [supervisor](http://supervisord.org/) to a systemd-based approach.
## Ubuntu
### Uninstall supervisord
```no-highlight
# apt-get remove -y supervisor
```
### Configure systemd
!!! note
These instructions assume the presence of a Python virtual environment at `/opt/netbox/venv`. If you have not created this environment, please refer to the [installation instructions](3-netbox.md#set-up-python-environment) for direction.
We'll use systemd to control the daemonization of NetBox services. First, copy `contrib/netbox.service` and `contrib/netbox-rq.service` to the `/etc/systemd/system/` directory:
```no-highlight
# cp contrib/*.service /etc/systemd/system/
```
!!! note
You may need to modify the user that the systemd service runs as. Please verify the user for httpd on your specific release and edit both files to match your httpd service under user and group. The username could be "nobody", "nginx", "apache", "www-data", or something else.
Then, start the `netbox` and `netbox-rq` services and enable them to initiate at boot time:
```no-highlight
# systemctl daemon-reload
# systemctl start netbox netbox-rq
# systemctl enable netbox netbox-rq
```
You can use the command `systemctl status netbox` to verify that the WSGI service is running:
At this point, you should be able to connect to the HTTP service at the server name or IP address you provided. If you are unable to connect, check that the nginx service is running and properly configured. If you receive a 502 (bad gateway) error, this indicates that gunicorn is misconfigured or not running. Issue the command `journalctl -xe` to see why the services were unable to start.
!!! info
Please keep in mind that the configurations provided here are bare minimums required to get NetBox up and running. You may want to make adjustments to better suit your production environment.
Prior to upgrading your NetBox instance, be sure to carefully review all [release notes](../../release-notes/) that have been published since your current version was released. Although the upgrade process typically does not involve additional work, certain releases may introduce breaking or backward-incompatible changes. These are called out in the release notes under the version in which the change went into effect.
!!! note
Beginning with version 2.8, NetBox requires Python 3.6 or later.
## Install the Latest Code
As with the initial installation, you can upgrade NetBox by either downloading the latest release package or by cloning the `master` branch of the git repository.
## Option A: Download a Release
### Option A: Download a Release
Download the [latest stable release](https://github.com/digitalocean/netbox/releases) from GitHub as a tarball or ZIP archive. Extract it to your desired path. In this example, we'll use `/opt/netbox`.
Download the [latest stable release](https://github.com/netbox-community/netbox/releases) from GitHub as a tarball or ZIP archive. Extract it to your desired path. In this example, we'll use `/opt/netbox`.
Be sure to replicate your uploaded media as well. (The exact action necessary will depend on where you choose to store your media, but in general moving or copying the media directory will suffice.)
Also make sure to copy over any reports that you've made. Note that if you made them in a separate directory (`/opt/netbox-reports` for example), then you will not need to copy them - the config file that you copied earlier will point to the correct location.
Also make sure to copy over any custom scripts and reports that you've made. Note that if theseare stored outside the project root, you will not need to copy them. (Check the `SCRIPTS_ROOT` and `REPORTS_ROOT` parameters in the configuration file above if you're unsure.)
## Option B: Clone the Git Repository (latest master release)
### Option B: Clone the Git Repository
This guide assumes that NetBox is installed at `/opt/netbox`. Pull down the most recent iteration of the master branch:
@@ -56,26 +66,24 @@ This guide assumes that NetBox is installed at `/opt/netbox`. Pull down the most
# git status
```
# Run the Upgrade Script
## Run the Upgrade Script
Once the new code is in place, run the upgrade script (which may need to be run as root depending on how your environment is configured).
Once the new code is in place, verify that any optional Python packages required by your deployment (e.g. `napalm` or `django-auth-ldap`) are listed in `local_requirements.txt`. Then, run the upgrade script:
```no-highlight
# ./upgrade.sh
```
!!! warning
The upgrade script will prefer Python3 and pip3 if both executables are available. To force it to use Python2 and pip, use the `-2` argument as below. Note that Python 2 will no longer be supported in NetBox v2.5.
```no-highlight
# ./upgrade.sh -2
```
This script:
* Installs or upgrades any new required Python packages
* Destroys and rebuilds the Python virtual environment
* Installs all required Python packages (listed in `requirements.txt`)
* Installs any additional packages from `local_requirements.txt`
* Applies any database migrations that were included in the release
* Collects all static files to be served by the HTTP service
* Deletes stale content types from the database
* Deletes all expired user sessions from the database
* Clears all cached data to prevent conflicts with the new release
!!! note
It's possible that the upgrade script will display a notice warning of unreflected database migrations:
@@ -85,16 +93,16 @@ This script:
This may occur due to semantic differences in environment, and can be safely ignored. Never attempt to create new migrations unless you are intentionally modifying the database schema.
# Restart the WSGI Service
## Restart the NetBox Services
Finally, restart the WSGI service to run the new code. If you followed this guide for the initial installation, this is done using `supervisorctl`:
!!! warning
If you are upgrading from an installation that does not use a Python virtual environment, you'll need to update the systemd service files to reference the new Python and gunicorn executables before restarting the services. These are located in `/opt/netbox/venv/bin/`. See the example service files in `/opt/netbox/contrib/` for reference.
Finally, restart the gunicorn and RQ services:
```no-highlight
# sudo supervisorctl restart netbox
# sudo systemctl restart netbox netbox-rq
```
If using webhooks, also restart the Redis worker:
```no-highlight
# sudo supervisorctl restart netbox-rqworker
```
!!! note
It's possible you are still using supervisord instead of systemd. If so, please see the instructions for [migrating to systemd](migrating-to-systemd.md).
A circuit represents a single _physical_ link connecting exactly two endpoints. (A circuit with more than two endpoints is a virtual circuit, which is not currently supported by NetBox.) Each circuit belongs to a provider and must be assigned a circuit ID which is unique to that provider.
A circuit may have one or two terminations, annotated as the "A" and "Z" sides of the circuit. A single-termination circuit can be used when you don't know (or care) about the far end of a circuit (for example, an Internet access circuit which connects to a transit provider). A dual-termination circuit is useful for tracking circuits which connect two sites.
Each circuit termination is tied to a site, and may optionally be connected via a cable to a specific device interface or pass-through port. Each termination can be assigned a separate downstream and upstream speed independent from one another. Fields are also available to track cross-connect and patch panel details.
!!! note
A circuit represents a physical link, and cannot have more than two endpoints. When modeling a multi-point topology, each leg of the topology must be defined as a discrete circuit.
!!! note
A circuit may terminate only to a physical interface. Circuits may not terminate to LAG interfaces, which are virtual interfaces: You must define each physical circuit within a service bundle separately and terminate it to its actual physical interface.
A provider is any entity which provides some form of connectivity. While this obviously includes carriers which offer Internet and private transit service, it might also include Internet exchange (IX) points and even organizations with whom you peer directly.
Each provider may be assigned an autonomous system number (ASN), an account number, and relevant contact information.
A cable represents a physical connection between two termination points, such as between a console port and a patch panel port, or between two network interfaces. Cables can be traced through pass-through ports to form a complete path between two endpoints. In the example below, three individual cables comprise a path between the two connected endpoints.
All connections between device components in NetBox are represented using cables. However, defining the actual cable plant is optional: Components can be be directly connected using cables with no type or other attributes assigned.
Cables are also used to associated ports and interfaces with circuit terminations. To do this, first create the circuit termination, then navigate the desired component and connect a cable between the two.
A console port provides connectivity to the physical console of a device. Console ports are typically used for temporary access by someone who is physically near the device, or for remote out-of-band access via a console server.
Console ports can be connected to console server ports.
A console server is a device which provides remote access to the local consoles of connected devices. This is typically done to provide remote out-of-band access to network devices.
Console server ports can be connected to console ports.
Every piece of hardware which is installed within a rack exists in NetBox as a device. Devices are measured in rack units (U) and can be half depth or full depth. A device may have a height of 0U: These devices do not consume vertical rack space and cannot be assigned to a particular rack unit. A common example of a 0U device is a vertically-mounted PDU.
When assigning a multi-U device to a rack, it is considered to be mounted in the lowest-numbered rack unit which it occupies. For example, a 3U device which occupies U8 through U10 is said to be mounted in U8. This logic applies to racks with both ascending and descending unit numbering.
A device is said to be full depth if its installation on one rack face prevents the installation of any other device on the opposite face within the same rack unit(s). This could be either because the device is physically too deep to allow a device behind it, or because the installation of an opposing device would impede airflow.
Device bays represent the ability of a device to house child devices. For example, you might install four blade servers into a 2U chassis. The chassis would appear in the rack elevation as a 2U device with four device bays. Each server within it would be defined as a 0U device installed in one of the device bays. Child devices do not appear within rack elevations or the "Non-Racked Devices" list within the rack view.
Child devices are first-class Devices in their own right: that is, fully independent managed entities which don't share any control plane with the parent. Just like normal devices, child devices have their own platform (OS), role, tags, and interfaces. You cannot create a LAG between interfaces in different child devices.
Therefore, Device bays are **not** suitable for modeling chassis-based switches and routers. These should instead be modeled as a single Device, with the line cards as Inventory Items.
Devices can be organized by functional roles. These roles are fully customizable. For example, you might create roles for core switches, distribution switches, and access switches.
A device type represents a particular make and model of hardware that exists in the real world. Device types define the physical attributes of a device (rack height and depth) and its individual components (console, power, and network interfaces).
Device types are instantiated as devices installed within racks. For example, you might define a device type to represent a Juniper EX4300-48T network switch with 48 Ethernet interfaces. You can then create multiple devices of this type named "switch1," "switch2," and so on. Each device will inherit the components (such as interfaces) of its device type at the time of creation. (However, changes made to a device type will **not** apply to instances of that device type retroactively.)
Some devices house child devices which share physical resources, like space and power, but which functional independently from one another. A common example of this is blade server chassis. Each device type is designated as one of the following:
* A parent device (which has device bays)
* A child device (which must be installed in a device bay)
* Neither
!!! note
This parent/child relationship is **not** suitable for modeling chassis-based devices, wherein child members share a common control plane.
For that application you should create a single Device for the chassis, and add Interfaces directly to it. Interfaces can be created in bulk using range patterns, e.g. "Gi1/[1-24]".
Add Inventory Items if you want to record the line cards themselves as separate entities. There is no explicit relationship between each interface and its line card, but it may be implied by the naming (e.g. interfaces "Gi1/x" are on line card 1)
Front ports are pass-through ports used to represent physical cable connections that comprise part of a longer path. For example, the ports on the front face of a UTP patch panel would be modeled in NetBox as front ports.
Each front port is mapped to a specific rear port on the same device. A single rear port may be mapped to multiple rear ports.
Interfaces connect to one another in a symmetric manner: If interface A connects to interface B, interface B therefore connects to interface A. Each type of connection can be classified as either *planned* or *connected*.
Each interface is a assigned a type denoting its physical properties. Two special types exist: the "virtual" type can be used to designate logical interfaces (such as SVIs), and the "LAG" type can be used to desinate link aggregation groups to which physical interfaces can be assigned.
Each interface can also be enabled or disabled, and optionally designated as management-only (for out-of-band management). Fields are also provided to store an interface's MTU and MAC address.
VLANs can be assigned to each interface as either tagged or untagged. (An interface may have only one untagged VLAN.)
Inventory items represent hardware components installed within a device, such as a power supply or CPU or line card. Currently, these are used merely for inventory tracking, although future development might see their functionality expand. Like device types, each item can optionally be assigned a manufacturer.
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