Today, the internet is such an important tool
in our everyday life.
We use it to consume media, to communicate
with friends and colleagues, to learn, to
handle our finances and much more…
But the web as we know it has a problem: the
information on it is centralized.
It’s all stored on big server farms like
this one and these are usually controlled
by a single company.
I mean have you ever wondered what would happen
if sites like YouTube or Wikipedia would go
How would you watch cat videos or spend hours
reading one Wikipedia page after the other?
This centralization brings another problem
with it and that is censorship.
Because content is hosted on just a few servers
it’s easy for governments to block access
In 2017 Turkey ordered internet provides to
block access to Wikipedia because the administration
called it “a threat to national security”.
So you get the idea: centralization of the
web isn’t a good thing.
But then why do we keep using such a model?
Well that’s because we have high expectations
when it comes to the web.
We want pages, images and videos to load instantly
and we want them in high quality.
Centralizing servers allows companies to have
complete control over how fast it can deliver
all of this content.
Another reason we use this model is that there
just isn’t a good and fast alternative.
But that might be about to change!
Meet IPFS, the Interplanetary file system.
That’s a fancy name and they have ambitious
goals as well.
They want to make the web completely distributed
by running it on a P2P network that works
similarly to how BitTorrent works.
Let’s take a look at how IPFS can accomplish
these goals but first you have to understand
how we access content on the web right now.
Let’s say you want to download a photo from
When you do that, you tell the computer exactly
where to find the photo.
In this case the location of the photo is
the IP address or the domain name.
This is called “location based” addressing.
You tell the computer where to get the information
but if that location isn’t accessible, in
other words the server is down, you won’t
get the photo.
However there is a high chance that someone
else has downloaded that picture before and
still has a copy of it and yet your computer
won’t be able to grab a copy from that person…
To fix this, IPFS moves from “location based”
addressing to “content based” addressing.
Instead of saying /where/ to find a resource,
you just say /what/ it is you want.
But how this does this work?
Well every file has a unique hash, which can
be compared to a fingerprint.
When you want to download a certain file,
you ask the network: “who has the file with
this hash?” and someone on the IPFS network
will provide it to you.
Now you might think: hold on a minute, how
do I know that that person hasn’t tampered
with the file?
Well, because you used a hash to request the
file, you can verify what you have received.
You request the file with a certain hash,
so when you receive the file you check if
the hash matches with what you have received.
Security built in!
Another nice feature of using hashes to address
content is deduplication.
When multiple people publish the same file
on IPFS, it will only be created once and
that makes the network very efficient.
Alright enough with this high level overview.
Let’s take a look at how IPFS stores files
and makes them accessible to others.
Files are stored inside IPFS objects and these
objects can store up to 256kb worth of data
and can contain links to other IPFS objects.
A simple “Hello World” text file, which
is very small, can be stored in a single IPFS
But what about files larger than 256kb?
Like an image or video for instance.
Well those are split up into multiple IPFS
objects that are all 256kb in size and afterwards
the system will create an empty IPFS object
that links to all the other pieces of the
The data architecture of IPFS is very simple
and yet it can be very powerful.
This architecture allows us to really use
it like a filesystem.
Here’s a simple directory structure with
some files in it.
We can translate this into IPFS objects as
well, creating an object for each file and
But that’s not all!
You see because IPFS uses content based addressing,
once something is added, it cannot be changed
It’s an immutable datastore much like a
But then how do you change stuff on it?
Well IPFS supports versioning of your files.
Let’s say you’re working on an important
document that you want to share with everyone
When you do that, IPFS will create a new “Commit
object” for you.
This object is really basic: it just tells
IPFS which commit went before it and it links
to the IPFS object of your file.
Now let’s imagine that after a while you
want to update this file.
Well, you just add your updated file to the
IPFS network and the software will create
a new commit object for your file.
This commit object now links to the previous
This process can be repeated endlessly.
IPFS will make sure that your file, plus it’s
entire history is accessible to the other
nodes on the network.
This all sounds great but it’s not without
it’s limitations or drawbacks.
The biggest problem that IPFS faces is keeping
Every node on the network keeps a cache of
the files that it has downloaded and helps
to share them if other people need them.
But if a specific file is hosted by – let’s
say these 4 nodes – and those nodes go offline
then that file becomes unavailable and no
one can grab a copy of it.
A bit like BitTorrent swarms without seeders.
There are two possible solutions for this
Either we incentivize people to store files
and make them available or we can proactively
distribute files and make sure that there
are always a certain number of copies available
on the network.
That’s exactly what Filecoin intends to
Filecoin is created by the same group of people
that have created IPFS.
It’s basically a blockchain built on top
of IPFS that wants to create a decentralized
market for storage.
If you have some free space, you can rent
it out to others and make money of it in the
Filecoin creates a strong incentive for nodes
to keep the files online for as long as possible
because otherwise they won’t be rewarded.
The system also makes sure that files are
replicated on many nodes so they cannot become
That’s a quick summary of Filecoin and how
it intends to built on top of IPFS to solve
some of it’s issue’s.
Leave a comment below if you want to learn
more about Filecoin in a future video.
Last thing we’re going to take a look at
is how IPFS can be used.
As I mentioned before, in 2017 the Turkish
government decided to block access to Wikipedia.
The people behind IPFS responded by taking
the Turkish Wikipedia and putting a copy of
it on IPFS.
Because IPFS is distributed and there are
no central servers, the government can’t
Another nice application is DTube which is
basically a site like YouTube but entirely
distributes and hosted on IPFS.
Anyone can publish videos and anyone can help
to support the network.
By now you must be wondering: why is IPFS
called the Interplanetary filesystem?
Is is suited to run across multiple planets?
Well let’s assume that we have a base on
Communicating from Mars to Earth is quite
Depending on the position of the two planets,
a signal can take somewhere between 4 and
24 minutes to travel between them.
Let’s take the best case scenario: you’re
on Mars, you open your laptop and request
a copy of the Wikipedia page of planet Earth,
because you’ve forgotten what it’s like
The request to Wikipedia travels 4 minutes
to earth and when it arrives there, it is
send on the internet, to the Wikipedia servers
who respond in just a few a milliseconds.
That response however still has to travel
4 minutes back to Mars.
So on a good day, visiting a single webpage
will take you 8 minutes.
On a bad day, 48 minutes…
With IPFS it’s possible to cache large parts
of the internet on Mars.
So if someone already requested a page that
you want to download, it can come straight
from a node on Mars, making that page load
just as fast as it would on earth.
So, yes, IPFS could be used to distribute
parts of the internet across multiple planets.
So to summarize: IPFS is a very ambitious
project that could lead to a truly decentralized
internet and now you know how it works.
Make sure to hit the subscribe button if you
want more videos like this one and as always:
thank you so much for watching!