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AccessMap

This repo contains all of the infrastructure needed to create and run AccessMap except for the data, which can be generated using the opensidewalks-data repo. These are the AccessMap-specific software projects used to deploy AccessMap:

The full pipeline of how AccessMap is deployed can be seen in this diagram:

AccessMap orchestration diagram

Deployment strategy

Important: outside of deploying Rakam, all of the following steps sould be executed in the accessmap/ subdirectory of this repository.

AccessMap is currently deployed using docker-compose, so the documentation will assume some familiarity with the command line and docker. It uses the relatively recent docker-compose config version 3.8 or above, which requires a newer version of the docker-compose CLI (it is developed using version 1.29).

AccessMap uses a 3-stage development-staging-production workflow, wherein new ideas can be tested out in feature branches, merged to develop, tested on a staged copy of the production application, and finally released:

  • New features/branches are developed within each separate repository and tested against a deployment of this repository.

  • Once a given feature or branch is mature, a tagged release is made for that service's repository.

  • This repository may be updated to refer to those releases as part of internal testing and development. This happens on the develop branch of this repository.

  • When we are ready to release a new version of AccessMap to the public, we merge the develop branch into master and tag a new release of this repository. Therefore, the latest tagged release on the master branch always reflects the code running on www.accessmap.io.

If you are running your own deployment of AccessMap, you can, of course, follow any release strategy that you prefer and build from any version of our services, but this is the primary workflow around which we have designed this repository.

Configuration

An AccessMap deployment is configured by (1) environment variables and (2) networkable pedestrian network feature data.

Environment variables

AccessMap uses environment variables to configure its deployments to maximize portability and follow best practices. These environment variables can be set in a number of ways according to the docker-compose documentation, but the easiest is to use an environment file. We provide a template environment file, accessmap.env.sample, that should be copied to accessmap.env and can be edited to your needs. The included sample environment file documents the purpose and meaning of each environment variable.

Pedestrian network data

AccessMap requires two data files in the data/ directory: transportation.geojson and regions.geojson. The data used by AccessMap can be generated from scratch using this repository: https://github.com/opensidewalks/opensidewalks-data.

transportation.geojson

This should be a GeoJSON file formatted according to the OpenSidewalks Schema spec: https://github.com/OpenSidewalks/OpenSidewalks-Schema. Our data pipeline generates GeoJSON data that conforms to this spec.

The data in such a file will be LineString features representing pedestrian pathways as well as metadata that describe them. Where they meet end-to-end, AccessMap's routing engine (Unweaver) will network them together.

regions.geojson

This should be a GeoJSON file containing Polygons of service areas. Each Feature should have these properties defined:

  • key: A unique string by which the region will be tracked within the web application. For example, Seattle's key is wa.seattle.

  • name: A human-readable name for the region. This should be kept short, as the UI does not yet adapt well to long names.

  • bounds: An array of [West, South, East, North] coordinates that describe the bounding box of the region.

  • lon: The preferred longitude of the map view starting location for the region.

  • lat: The preferred latitude of the map view starting location for the region.

  • zoom: The preferred map zoom level of the map view starting at the region.

Our data pipeline generates a combined regions.geojson file that conforms to this spec.

Running a deployment

Configuration

QuickStart

See the section on setting up the accessmap.env file above.

Building assets

Quickstart

Run these three commands: docker-compose run build_webapp docker-compose run build_tiles docker-compose run build_router

Explanation

Several assets must be built before deployment: (1) The web application must be transpiled and optimized, (2) map vector tiles must be built from the input GeoJSON files, and (3) the routable graph must be built from transportation.geojson.

These can be built using docker-compose run <service>, where <service> is the build container name. The build container names are, build_webapp, build_tiles, and build_router, so docker-compose run build_webapp will build the assets for the AccessMap webapp container. As an alternative, it is also possible to start the service and build containers using the build profile: docker-compose --profile build up. Note that the build steps take time, so it may be several minutes before the state of the services reflects the new built assets.

The built assets will be added to the build/ directory.

Database migrations

Quickstart

To create and/or migrate the api database schemas, just run docker-compose run migrate_api-db.

Explanation

The user api (api) service needs to store user and profile information in an SQLAlchemy-compatible database. The sample accessmap.env file defines a (temporary) sqlite3 endpoint, but in production this should be a dedicated server like postgresql.

Once the database has been defined, its schemas must be created by the api service. In addition, if the api codebase is updated to change any schemas, the existing database must be 'migrated' to match it.

Running Accessmap services

Quickstart - During Development

Run docker-compose up. Alternatively, run docker-compose up -d to background the compose process.

Quickstart - In Production

Run docker-compose -f docker-compose.yml -f docker-compose.prod.yml up. Alternatively, run docker-compose -f docker-compose.yml -f docker-compose.prod.yml up -d to background the compose process.

Note that you may need to set or change your accessmap.env file for a production set up. See the file for documentation on what to change.

Analytics

AccessMap tracks website interactions to do research on user interactions and root out bugs. Analytics are disabled from a deployment by default. An AccessMap user can also opt out of client-side analytics.

In order to have full control over data provenance (preserve privacy) and collect fully custom datasets, AccessMap makes use of a self-hosted instance of the Rakam API. Just like with the AccessMap services, this repository provides a docker-compose-based deployment workflow for Rakam, under the rakam/ subdirectory.

Running rakam

During development

In development mode, rakam requires no configuration, just run:

docker-compose up -d

This will create a docker-based postgresql database and a self-configuring instance of Rakam.

In production

For production, two environment variables must be configured: one to set the URI for a persistent postgresql database, ideally defined outside of this repository, and a unique secret key that will be used to create and access client-side analytics data. These are easiest to configure using a rakam.env file, for which we have provided a template, rakam.env.sample. To use it, copy it (cp rakam.env.sample rakam.env) and edit with a plain text editor. The meaning of each environment variale is described in the sample environment file.

To run the software in production mode, we need to skip the override file. This can be done by running docker-compose -f docker-compose.yml up.

Getting an analytics project key

rakam operates on the basis of "projects", which are isolated namespaces in the analytics database. It is a good idea to create a new project for every new study you do, e.g. for A/B testing.

rakam uses a web API to manage the creation of projects. To create a new one, you need to have the RAKAM_CONFIG_LOCK__KEY credential mentioned above and create a request to the endpoint. An example in development mode:

curl --request POST --url http://localhost:9999/analytics/project/create -d '{"name": "project1", "lock_key": "mylockKey"}'

Save the response data! At a minimum, you will need to save the write key for use by AccessMap. If necessary, you can retrieve these data at a later time directly in the database in the api_key table.

In the POSTed data, "name" is the unique namespace for your new project and "lock_key" is the secret key (essentially a password) you've defined in your config. Make sure to run rakam in production mode if it is internet-facing.

When AccessMap is also deployed, it proxies requests to /analytics to this rakam instance (if correctly configured), so you can also create new projects at the http(s)://$hostname/analytics/project/create endpoint.

Save these credentials! The write_key is needed for any project that wants to send analytics to this rakam project. If you lose these credentials for any reason, they can be accessed at the database backing rakam in the api_key table.

Logs

Logging solutions are many, varied, annoying, particularly with docker-based workflows. We just deploy on Ubuntu systems and edit /etc/logrotate.d/rsyslog and add the following settings under the /var/log/syslog section:

rotate 2000
daily
create
missingok
notifempty
delaycompress
compress
dateext
postrotate
    invoke-rc.d rsyslog rotate > /dev/null
endscript

Most of these are the default settings as of writing. The import parts are:

  1. rotate 2000 indicates how long to keep logs. Because rotations are daily, this is 2000 days.

  2. daily indicates a daily log rotation - a new archived log file will be created every day.

  3. dateext adds the date to the end of the compressed, archived log.

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