visit
Remember that a blockchain is an immutable, sequential chain of records called Blocks. They can contain transactions, files or any data you like, really. But the important thing is that they’re chained together using hashes.
If you aren’t sure what a hash is, .Who is this guide aimed at? You should be comfy reading and writing some basic Python, as well as have some understanding of how HTTP requests work, since we’ll be talking to our Blockchain over HTTP.
What do I need? Make sure that + (along with pip) is installed. You’ll also need to install Flask and the wonderful Requests library:
pip install Flask==0.12.2 requests==2.18.4
Where’s the final code? The source code is .
Open up your favourite text editor or IDE, personally I ❤️ . Create a new file, called
blockchain.py
. We’ll only use a single file, but if you get lost, you can always refer to the .Representing a Blockchain
We’ll create a
Blockchain
class whose constructor creates an initial empty list (to store our blockchain), and another to store transactions. Here’s the blueprint for our class:class Blockchain(object):
def __init__(self):
self.chain = []
self.current_transactions = []
def new_block(self):
# Creates a new Block and adds it to the chain
pass
def new_transaction(self):
# Adds a new transaction to the list of transactions
pass
@staticmethod
def hash(block):
# Hashes a Block
pass
@property
def last_block(self):
# Returns the last Block in the chain
pass
(Blueprint of our Blockchain Class)
Our
Blockchain
class is responsible for managing the chain. It will store transactions and have some helper methods for adding new blocks to the chain. Let’s start fleshing out some methods.What does a Block look like?
Each Block has an index, a timestamp (in Unix time), a list of transactions, a proof (more on that later), and the hash of the previous Block.
Here’s an example of what a single Block looks like:block = {
'index': 1,
'timestamp': 1506057125.900785,
'transactions': [
{
'sender': "8527147fe1f5426f9dd545de4b27ee00",
'recipient': "a77f5cdfa2934df3954a5c7c7da5df1f",
'amount': 5,
}
],
'proof': 324984774000,
'previous_hash': "2cf24dba5fb0a30e26e83b2ac5b9e29e1b161e5c1fa7425e73043362938b9824"
}
(Example of a Block in our Blockchain)
At this point, the idea of a chain should be apparent—each new block contains within itself, the hash of the previous Block. This is crucial because it’s what gives blockchains immutability: If an attacker corrupted an earlier Block in the chain then all subsequent blocks will contain incorrect hashes.
Does this make sense? If it doesn’t, take some time to let it sink in—it’s the core idea behind blockchains.
Adding Transactions to a Block
We’ll need a way of adding transactions to a Block. Our
new_transaction()
method is responsible for this, and it’s pretty straight-forward:class Blockchain(object):
...
def new_transaction(self, sender, recipient, amount):
"""
Creates a new transaction to go into the next mined Block
:param sender: <str> Address of the Sender
:param recipient: <str> Address of the Recipient
:param amount: <int> Amount
:return: <int> The index of the Block that will hold this transaction
"""
self.current_transactions.append({
'sender': sender,
'recipient': recipient,
'amount': amount,
})
return self.last_block['index'] + 1
After
new_transaction()
adds a transaction to the list, it returns the index of the block which the transaction will be added to—the next one to be mined. This will be useful later on, to the user submitting the transaction.Creating new Blocks
When our
Blockchain
is instantiated we’ll need to seed it with a genesis block—a block with no predecessors. We’ll also need to add a “proof” to our genesis block which is the result of mining (or proof of work). We’ll talk more about mining later.In addition to creating the genesis block in our constructor, we’ll also flesh out the methods for
new_block()
, new_transaction()
and hash()
:import hashlib
import json
from time import time
class Blockchain(object):
def __init__(self):
self.current_transactions = []
self.chain = []
# Create the genesis block
self.new_block(previous_hash=1, proof=100)
def new_block(self, proof, previous_hash=None):
"""
Create a new Block in the Blockchain
:param proof: <int> The proof given by the Proof of Work algorithm
:param previous_hash: (Optional) <str> Hash of previous Block
:return: <dict> New Block
"""
block = {
'index': len(self.chain) + 1,
'timestamp': time(),
'transactions': self.current_transactions,
'proof': proof,
'previous_hash': previous_hash or self.hash(self.chain[-1]),
}
# Reset the current list of transactions
self.current_transactions = []
self.chain.append(block)
return block
def new_transaction(self, sender, recipient, amount):
"""
Creates a new transaction to go into the next mined Block
:param sender: <str> Address of the Sender
:param recipient: <str> Address of the Recipient
:param amount: <int> Amount
:return: <int> The index of the Block that will hold this transaction
"""
self.current_transactions.append({
'sender': sender,
'recipient': recipient,
'amount': amount,
})
return self.last_block['index'] + 1
@property
def last_block(self):
return self.chain[-1]
@staticmethod
def hash(block):
"""
Creates a SHA-256 hash of a Block
:param block: <dict> Block
:return: <str>
"""
# We must make sure that the Dictionary is Ordered, or we'll have inconsistent hashes
block_string = json.dumps(block, sort_keys=True).encode()
return hashlib.sha256(block_string).hexdigest()
The above should be straight-forward—I’ve added some comments and docstrings to help keep it clear. We’re almost done with representing our blockchain. But at this point, you must be wondering how new blocks are created, forged or mined.
Understanding Proof of Work
A Proof of Work algorithm (PoW) is how new Blocks are created or mined on the blockchain. The goal of PoW is to discover a number which solves a problem. The number must be difficult to find but easy to verify—computationally speaking—by anyone on the network. This is the core idea behind Proof of Work.
We’ll look at a very simple example to help this sink in.Let’s decide that the hash of some integer x multiplied by another y must end in 0. So,
hash(x * y) = ac23dc...0
. And for this simplified example, let’s fix x = 5
. Implementing this in Python:from hashlib import sha256
x = 5
y = 0 # We don't know what y should be yet...
while sha256(f'{x*y}'.encode()).hexdigest()[-1] != "0":
y += 1
print(f'The solution is y = {y}')
The solution here is
y = 21
. Since, the produced hash ends in 0:hash(5 * 21) = 1253e9373e...5e3600155e860
The network is able to easily verify their solution.
Implementing basic Proof of Work
Let’s implement a similar algorithm for our blockchain. Our rule will be similar to the example above:Find a number p that when hashed with the previous block’s solution a hash with 4 leadingis produced.0s
import hashlib
import json
from time import time
from uuid import uuid4
class Blockchain(object):
...
def proof_of_work(self, last_proof):
"""
Simple Proof of Work Algorithm:
- Find a number p' such that hash(pp') contains leading 4 zeroes, where p is the previous p'
- p is the previous proof, and p' is the new proof
:param last_proof: <int>
:return: <int>
"""
proof = 0
while self.valid_proof(last_proof, proof) is False:
proof += 1
return proof
@staticmethod
def valid_proof(last_proof, proof):
"""
Validates the Proof: Does hash(last_proof, proof) contain 4 leading zeroes?
:param last_proof: <int> Previous Proof
:param proof: <int> Current Proof
:return: <bool> True if correct, False if not.
"""
guess = f'{last_proof}{proof}'.encode()
guess_hash = hashlib.sha256(guess).hexdigest()
return guess_hash[:4] == "0000"
/transactions/new
to create a new transaction to a block/mine
to tell our server to mine a new block./chain
to return the full BlockchainSetting up Flask
Our “server” will form a single node in our blockchain network. Let’s create some boilerplate code:import hashlib
import json
from textwrap import dedent
from time import time
from uuid import uuid4
from flask import Flask
class Blockchain(object):
...
# Instantiate our Node
app = Flask(__name__)
# Generate a globally unique address for this node
node_identifier = str(uuid4()).replace('-', '')
# Instantiate the Blockchain
blockchain = Blockchain()
@app.route('/mine', methods=['GET'])
def mine():
return "We'll mine a new Block"
@app.route('/transactions/new', methods=['POST'])
def new_transaction():
return "We'll add a new transaction"
@app.route('/chain', methods=['GET'])
def full_chain():
response = {
'chain': blockchain.chain,
'length': len(blockchain.chain),
}
return jsonify(response), 200
if __name__ == '__main__':
app.run(host='0.0.0.0', port=5000)
Blockchain
class./mine
endpoint, which is a GET
request./transactions/new
endpoint, which is a POST
request, since we’ll be sending data to it./chain
endpoint, which returns the full Blockchain.The Transactions Endpoint
This is what the request for a transaction will look like. It’s what the user sends to the server:{
"sender": "my address",
"recipient": "someone else's address",
"amount": 5
}
import hashlib
import json
from textwrap import dedent
from time import time
from uuid import uuid4
from flask import Flask, jsonify, request
...
@app.route('/transactions/new', methods=['POST'])
def new_transaction():
values = request.get_json()
# Check that the required fields are in the POST'ed data
required = ['sender', 'recipient', 'amount']
if not all(k in values for k in required):
return 'Missing values', 400
# Create a new Transaction
index = blockchain.new_transaction(values['sender'], values['recipient'], values['amount'])
response = {'message': f'Transaction will be added to Block {index}'}
return jsonify(response), 201
(A method for creating Transactions)
The Mining Endpoint
Our mining endpoint is where the magic happens, and it’s easy. It has to do three things:import hashlib
import json
from time import time
from uuid import uuid4
from flask import Flask, jsonify, request
...
@app.route('/mine', methods=['GET'])
def mine():
# We run the proof of work algorithm to get the next proof...
last_block = blockchain.last_block
last_proof = last_block['proof']
proof = blockchain.proof_of_work(last_proof)
# We must receive a reward for finding the proof.
# The sender is "0" to signify that this node has mined a new coin.
blockchain.new_transaction(
sender="0",
recipient=node_identifier,
amount=1,
)
# Forge the new Block by adding it to the chain
previous_hash = blockchain.hash(last_block)
block = blockchain.new_block(proof, previous_hash)
response = {
'message': "New Block Forged",
'index': block['index'],
'transactions': block['transactions'],
'proof': block['proof'],
'previous_hash': block['previous_hash'],
}
return jsonify(response), 200
$ python blockchain.py
* Running on //127.0.0.1:5000/ (Press CTRL+C to quit)
Let’s try mining a block by making a
GET
request to //localhost:5000/mine
:(Using Postman to make a GET request)
Let’s create a new transaction by making a
POST
request to //localhost:5000/transactions/new
with a body containing our transaction structure:(Using Postman to make a POST request)
If you aren’t using Postman, then you can make the equivalent request using cURL:$ curl -X POST -H "Content-Type: application/json" -d '{
"sender": "d4ee26eee15148ee92c6cd394edd974e",
"recipient": "someone-other-address",
"amount": 5
}' "//localhost:5000/transactions/new"
{
"chain": [
{
"index": 1,
"previous_hash": 1,
"proof": 100,
"timestamp": 1506280650.770839,
"transactions": []
},
{
"index": 2,
"previous_hash": "c099bc...bfb7",
"proof": 35293,
"timestamp": 1506280664.717925,
"transactions": [
{
"amount": 1,
"recipient": "8bbcb347e0634905b0cac7955bae152b",
"sender": "0"
}
]
},
{
"index": 3,
"previous_hash": "eff91a...10f2",
"proof": 35089,
"timestamp": 1506280666.1086972,
"transactions": [
{
"amount": 1,
"recipient": "8bbcb347e0634905b0cac7955bae152b",
"sender": "0"
}
]
}
],
"length": 3
}
This is very cool. We’ve got a basic Blockchain that accepts transactions and allows us to mine new Blocks. But the whole point of Blockchains is that they should be decentralized. And if they’re decentralized, how on earth do we ensure that they all reflect the same chain? This is called the problem of Consensus, and we’ll have to implement a Consensus Algorithm if we want more than one node in our network.
Registering new Nodes
Before we can implement a Consensus Algorithm, we need a way to let a node know about neighbouring nodes on the network. Each node on our network should keep a registry of other nodes on the network. Thus, we’ll need some more endpoints:/nodes/register
to accept a list of new nodes in the form of URLs./nodes/resolve
to implement our Consensus Algorithm, which resolves any conflicts—to ensure a node has the correct chain....
from urllib.parse import urlparse
...
class Blockchain(object):
def __init__(self):
...
self.nodes = set()
...
def register_node(self, address):
"""
Add a new node to the list of nodes
:param address: <str> Address of node. Eg. '//192.168.0.5:5000'
:return: None
"""
parsed_url = urlparse(address)
self.nodes.add(parsed_url.netloc)
(A method for adding neighbouring nodes to our Network)
Note that we’ve used a
set()
to hold the list of nodes. This is a cheap way of ensuring that the addition of new nodes is idempotent—meaning that no matter how many times we add a specific node, it appears exactly once.Implementing the Consensus Algorithm
As mentioned, a conflict is when one node has a different chain to another node. To resolve this, we’ll make the rule that the longest valid chain is authoritative. In other words, the longest chain on the network is the de-facto one. Using this algorithm, we reach Consensus amongst the nodes in our network.
...
import requests
class Blockchain(object)
...
def valid_chain(self, chain):
"""
Determine if a given blockchain is valid
:param chain: <list> A blockchain
:return: <bool> True if valid, False if not
"""
last_block = chain[0]
current_index = 1
while current_index < len(chain):
block = chain[current_index]
print(f'{last_block}')
print(f'{block}')
print("\n-----------\n")
# Check that the hash of the block is correct
if block['previous_hash'] != self.hash(last_block):
return False
# Check that the Proof of Work is correct
if not self.valid_proof(last_block['proof'], block['proof']):
return False
last_block = block
current_index += 1
return True
def resolve_conflicts(self):
"""
This is our Consensus Algorithm, it resolves conflicts
by replacing our chain with the longest one in the network.
:return: <bool> True if our chain was replaced, False if not
"""
neighbours = self.nodes
new_chain = None
# We're only looking for chains longer than ours
max_length = len(self.chain)
# Grab and verify the chains from all the nodes in our network
for node in neighbours:
response = requests.get(f'//{node}/chain')
if response.status_code == 200:
length = response.json()['length']
chain = response.json()['chain']
# Check if the length is longer and the chain is valid
if length > max_length and self.valid_chain(chain):
max_length = length
new_chain = chain
# Replace our chain if we discovered a new, valid chain longer than ours
if new_chain:
self.chain = new_chain
return True
return False
The first method
valid_chain()
is responsible for checking if a chain is valid by looping through each block and verifying both the hash and the proof.resolve_conflicts()
is a method which loops through all our neighbouring nodes, downloads their chains and verifies them using the above method. If a valid chain is found, whose length is greater than ours, we replace ours.Let’s register the two endpoints to our API, one for adding neighbouring nodes and the another for resolving conflicts:@app.route('/nodes/register', methods=['POST'])
def register_nodes():
values = request.get_json()
nodes = values.get('nodes')
if nodes is None:
return "Error: Please supply a valid list of nodes", 400
for node in nodes:
blockchain.register_node(node)
response = {
'message': 'New nodes have been added',
'total_nodes': list(blockchain.nodes),
}
return jsonify(response), 201
@app.route('/nodes/resolve', methods=['GET'])
def consensus():
replaced = blockchain.resolve_conflicts()
if replaced:
response = {
'message': 'Our chain was replaced',
'new_chain': blockchain.chain
}
else:
response = {
'message': 'Our chain is authoritative',
'chain': blockchain.chain
}
return jsonify(response), 200
At this point you can grab a different machine if you like, and spin up different nodes on your network. Or spin up processes using different ports on the same machine. I spun up another node on my machine, on a different port, and registered it with my current node. Thus, I have two nodes: and
//localhost:5001
.(Registering a new Node)
I then mined some new Blocks on node 2, to ensure the chain was longer. Afterward, I called
GET /nodes/resolve
on node 1, where the chain was replaced by the Consensus Algorithm:(Consensus Algorithm at Work)
And that’s a wrap... Go get some friends together to help test out your Blockchain.Update: I’m planning on following up with a Part 2, where we’ll extend our Blockchain to have a Transaction Validation Mechanism as well as discuss some ways in which you can productionize your Blockchain.
If you enjoyed this guide, or have any suggestions or questions, let me know in the comments. And if you’ve spotted any errors, feel free to contribute to the code !
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