Beginner Tutorial

Welcome to the beginner tutorial for Pachyderm. If you’ve already got Pachyderm installed, this guide should take about 15 minutes and you’ll be introduced to the basic concepts of Pachyderm.

Image processing with OpenCV

In this guide we’re going to create a Pachyderm pipeline to do some simple edge detection on a few images. Thanks to Pachyderm’s processing system, we’ll be able to run the pipeline in a distributed, streaming fashion. As new data is added, the pipeline will automatically process it and output the results.

If you hit any errors not covered in this guide, check our Troubleshooting docs for common errors, submit an issue on GitHub, join our users channel on Slack, or email us at and we can help you right away.


This guide assumes that you already have Pachyderm running locally. Check out our Local Installation instructions if haven’t done that yet and then come back here to continue.

Create a Repo

A repo is the highest level data primitive in Pachyderm. Like many things in Pachyderm, it shares it’s name with primitives in Git and is designed to behave analogously. Generally, repos should be dedicated to a single source of data such as log messages from a particular service, a users table, or training data for an ML model. Repos are dirt cheap so don’t be shy about making tons of them.

For this demo, we’ll simply create a repo called “images” to hold the data we want to process:

$ pachctl create-repo images

# See the repo we just created
$ pachctl list-repo
NAME                CREATED             SIZE
images              2 minutes ago       0 B

Adding Data to Pachyderm

Now that we’ve created a repo it’s time to add some data. In Pachyderm, you write data to an explicit commit (again, similar to Git). Commits are immutable snapshots of your data which give Pachyderm its version control properties. Files can be added, removed, or updated in a given commit.

Let’s start by just adding a file, in this case an image, to a new commit. We’ve provided some sample images for you that we host on Imgur.

We’ll use the put-file command along with two flags, -c and -f. -f can take either a local file or a URL which it’ll automatically scrape. In our case, we’ll simply pass the URL.

Unlike Git though, commits in Pachyderm must be explicitly started and finished as they can contain huge amounts of data and we don’t want that much “dirty” data hanging around in an unpersisted state. The -c flag specifies that we want to start a new commit, add data, and finish the commit in a convenient one-liner.

We also specify the repo name “images”, the branch name “master”, and what we want to name the file, “liberty.png”.

$ pachctl put-file images master liberty.png -c -f

Finally, we check to make sure the data we just added is in Pachyderm.

# If we list the repos, we can see that there is now data
$ pachctl list-repo
NAME                CREATED             SIZE
images              5 minutes ago   57.27 KiB

# We can view the commit we just created
$ pachctl list-commit images
REPO                ID                                 PARENT              STARTED            DURATION            SIZE
images              7162f5301e494ec8820012576476326c   <none>              2 minutes ago      38 seconds          57.27 KiB

# And view the file in that commit
$ pachctl list-file images master
NAME                TYPE                SIZE
liberty.png         file                57.27 KiB

We can view the file we just added to Pachyderm. Since this is an image, we can’t just print it out in the terminal, but the following commands will let you view it easily.

# on OSX
$ pachctl get-file images master liberty.png | open -f -a /Applications/

# on Linux
$ pachctl get-file images master liberty.png | display

Create a Pipeline

Now that we’ve got some data in our repo, it’s time to do something with it. Pipelines are the core processing primitive in Pachyderm and they’re specified with a JSON encoding. For this example, we’ve already created the pipeline for you and you can find the code on Github.

When you want to create your own pipelines later, you can refer to the full Pipeline Specification to use more advanced options. This includes building your own code into a container instead of the pre-built Docker image we’ll be using here.

For now, we’re going to create a single pipeline that takes in images and does some simple edge detection.


Below is the pipeline spec and python code we’re using. Let’s walk through the details.

# edges.json
  "pipeline": {
    "name": "edges"
  "transform": {
    "cmd": [ "python3", "/" ],
    "image": "pachyderm/opencv"
  "input": {
    "atom": {
      "repo": "images",
      "glob": "/*"

Our pipeline spec contains a few simple sections. First is the pipeline name, edges. Then we have the transform which specifies the docker image we want to use, pachyderm/opencv (defaults to Dockerhub as the registry), and the entry point Lastly, we specify the input. Here we only have one “atom” input, our images repo with a particular glob pattern.

The glob pattern defines how the input data can be broken up if we wanted to distribute our computation. /* means that each file can be processed individually, which makes sense for images. Glob patterns are one of the most powerful features of Pachyderm so when you start creating your own pipelines, check out the Pipeline Specification.

import cv2
import numpy as np
from matplotlib import pyplot as plt
import os

# make_edges reads an image from /pfs/images and outputs the result of running
# edge detection on that image to /pfs/out. Note that /pfs/images and
# /pfs/out are special directories that Pachyderm injects into the container.
def make_edges(image):
   img = cv2.imread(image)
   tail = os.path.split(image)[1]
   edges = cv2.Canny(img,100,200)
   plt.imsave(os.path.join("/pfs/out", os.path.splitext(tail)[0]+'.png'), edges, cmap = 'gray')

# walk /pfs/images and call make_edges on every file found
for dirpath, dirs, files in os.walk("/pfs/images"):
   for file in files:
       make_edges(os.path.join(dirpath, file))

Our python code is really straight forward. We’re simply walking over all the images in /pfs/images, do our edge detection and write to /pfs/out.

/pfs/images and /pfs/out are special local directories that Pachyderm creates within the container for you. All the input data for a pipeline will be found in /pfs/[input_repo_name] and your code should always write to /pfs/out.

Now let’s create the pipeline in Pachyderm:

$ pachctl create-pipeline -f

What Happens When You Create a Pipeline

Creating a pipeline tells Pachyderm to run your code on every finished commit in a repo as well as all future commits that happen after the pipeline is created. Our repo already had a commit, so Pachyderm automatically launched a job to process that data.

This first time it runs a pipeline it needs to download the image from DockerHub so this might take a minute. Every subsequent run will be much faster.

You can view the job with:

$ pachctl list-job
ID                                     OUTPUT COMMIT                            STARTED             DURATION            STATE
a6c70aa5-9f0c-4e36-b30a-4387fac54eac   edges/1a9c76a2cd154e6e90f200fb80c46d2f   2 minutes ago      About a minute      success

Every pipeline creates a corresponding repo with the same name where it stores its output results. In our example, the “edges” pipeline created a repo called “edges” to store the results.

$ pachctl list-repo
NAME                CREATED            SIZE
edges               2 minutes ago      22.22 KiB
images              10 minutes ago     57.27 KiB

Reading the Output

We can view the output data from the “edges” repo in the same fashion that we viewed the input data.

# on OSX
$ pachctl get-file edges master liberty.png | open -f -a /Applications/

# on Linux
$ pachctl get-file edges master liberty.png | display

Processing More Data

Pipelines will also automatically process the data from new commits as they are created. Think of pipelines as being subscribed to any new commits on their input repo(s). Also similar to Git, commits have a parental structure that tracks which files have changed. In this case we’re going to be adding more images.

Let’s create two new commits in a parental structure. To do this we will simply do two more put-file commands with -c and by specifying master as the branch, it’ll automatically parent our commits onto each other. Branch names are just references to a particular HEAD commit.

$ pachctl put-file images master AT-AT.png -c -f

$ pachctl put-file images master kitten.png -c -f

Adding a new commit of data will automatically trigger the pipeline to run on the new data we’ve added. We’ll see corresponding jobs get started and commits to the output “edges” repo. Let’s also view our new outputs.

# view the jobs that were kicked off
$ pachctl list-job
ID                                     OUTPUT COMMIT                            STARTED             DURATION             STATE
7395c7c9-df0e-4ea8-8202-ec846970b982   edges/8848e11056c04518a8d128b6939d9985   2 minutes ago      Less than a second   success
b90afeb1-c12b-4ca5-a4f4-50c50efb20bb   edges/da51395708cb4812bc8695bb151b69e3   2 minutes ago      1 seconds            success
9182d65e-ea36-4b98-bb07-ebf40fefcce5   edges/4dd2459531414d80936814b13b1a3442   5 minutes ago      3 seconds            success
# View the output data

# on OSX
$ pachctl get-file edges master AT-AT.png | open -f -a /Applications/

$ pachctl get-file edges master kitten.png | open -f -a /Applications/

# on Linux
$ pachctl get-file edges master AT-AT.png | display

$ pachctl get-file edges master kitten.png | display

Exploring the File System (optional)

Another nifty feature of Pachyderm is that you can mount the file system locally to poke around and explore your data using FUSE. FUSE comes pre-installed on most Linux distributions. For OS X, you’ll need to install OSX FUSE. This is just an optional step if you want another view of your data and system and can be useful for local development.

The first thing we need to do is mount Pachyderm’s filesystem (pfs).

First create the mount point:

$ mkdir ~/pfs

And then mount it:

# We background this process because it blocks.
$ pachctl mount ~/pfs &


If you get any errors on OSX, those are most likely benign as it’s just SpotLight trying to index the Fuse volume and not having access.

This will mount pfs on ~/pfs you can inspect the filesystem like you would any other local filesystem such as using ls or pointing your browser at it.


Use pachctl unmount ~/pfs to unmount the filesystem. You can also use the -a flag to remove all Pachyderm FUSE mounts.

Next Steps

We’ve now got Pachyderm running locally with data and a pipeline! If you want to keep playing with Pachyderm locally, you can use what you’ve learned to build on or change this pipeline. You can also start learning some of the more advanced topics to develop analysis in Pachyderm:

We’d love to help and see what you come up with so submit any issues/questions you come across on GitHub , Slack or email at if you want to show off anything nifty you’ve created!