This repo is based on the homework for the Algorand class of "Building with Blockchain for Web 3.0" (Spring 2021). It can be used as an independent tutorial to learn step by step basic features of the Algorand blockchain.

In this homework, you will learn:

1. how to create your first Algorand accounts.
2. how to create and distribute your first asset or token on the Algorand blockchain.
3. how to trade your token "atomically" without any third party.
4. how to get the official "buildweb3" asset for just 4.2 Algos, by using your first smart signature (aka stateless smart contract).

The first two goals require no programming knowledge and can be done 100% online without installing anything on your computer! If you are interested, just skip Step 0 and do Steps 1, 2, and 3.

Sections "Background" and "Going Further" are not mandatory to complete the homework but provide information that can be useful to build your project on Algorand.

Warning: All the homework is meant to be done on TestNet, where coins (called the Algos) are fake. When switching to MainNet, accounts store real cryptocurrency and proper security of key storage and management needs to be taken into consideration.

Note: To actually do the homework (which can be helpful to check you understand everything), download the file form.md and fill it out. Instructions on how to fill it out are provided in the paragraphs Tasks below. See form.example.md for a filled-out form example.

Note: The answers in form.example.md would be valid answers of (a slightly earlier version of) the homework and you can search for the various accounts and transaction IDs on the block explorer of your choice: AlgoExplorer or GoalSeeker. Note that this homework was recently changed and the answers in form.example.md use slightly higher amounts for each transaction.

If you are only interested in creating your token and not do the full homework, you can skip this section.

Algorand officially supports 4 Software Development Kits (SDK) for developing applications: Python, Javascript, Java, and Go. Additionally, Algorand has community SDKs for Rust and C#. Algorand also provides many command line tools that are very convenient for larger projects but that are not necessary to install for this homework. See the developer documentation for details.

To access a blockchain, you also need access to an Algorand node and optionally to an Algorand indexer that allows to easily read the blockchain. You can either run those on your computer or use an external API service. See the developer documentation.

This homework will use the Algorand TestNet network. TestNet has the same protocol as the main Algorand network MainNet, but uses fake Algos. (The Algo is the native cryptocurrency of the Algorand blockchain.)

In what follows, we give examples with the Python SDK and the free PureStake API Service. However, you may use the SDK of your choice or the command line tools. You may also use another API service or setup a personal node and use it.

For more information about options to set up the development environment, see Set up your development environment . This tutorial is meant to be done on TestNet and not on a private network. Since it requires the use of an indexer, sandbox may not be used.

For more advanced development scenario, we highly recommend setting up sandbox on a private network and installing the Algorand software tools (goal, tealdbg, ...) by doing the following:

1. Installing a node,
2. Switching to TestNet
3. And performing a fast cathup.

tealdbg in particular is very useful to debug smart contracts. On Windows, the best solution is to use Ubuntu 20.04 on WSL 2.

Other API services exist apart from the PureStake API service: https://developer.algorand.org/ecosystem-projects/?tags=api-services Note that the RandLabs/algoexplorer API service can also be used but it does not provide all the same endpoints. In particular, when using the new RandLabs node, confirming the transaction requires using the indexer rather than the "pending transactions" endpoint as used in the documentation.

Warning: Python 2 will not work.

Python 3.8.0 (or later) with Pip must be installed on your computer.

• On Windows 7/8/10: (warning: Windows XP is not supported)
  1. Download the Python installer on https://www.python.org/downloads/windows/
  2. In the first screen of the installer, make sure to select the checkboxes "Install launcher for all users" and "Add Python 3.8 to PATH".
• On macOS:
  • If you do not have HomeBrew installed, open a terminal and run:

  curl https://bootstrap.pypa.io/get-pip.py -o get-pip.py
  python3 get-pip.py

  • If you do use HomeBrew, open a terminal and run:

  brew install python3

• On Ubuntu 18.04 or later, open a terminal and run:

  sudo apt update
  sudo apt install python3-pip
  

Open a terminal and run:

python3 -m pip install py-algorand-sdk --upgrade

Troubleshooting:

• If you are using Windows and get an error, replace python3 by python everywhere.
• If you still get an error, check that you added python in the PATH when installing it (see above). If not, uninstall and re-install Python.

Visit https://developer.purestake.io/ to sign up for free and get a PureStake API Key to access the PureStake API service.

Note: Do not publish anywhere your PureStake API. Anytime you post publicly your code, remove your API key from the code. You may consider using environment variables to store it.

You will also need a code editor, such as Visual Studio Code or PyCharm.

(Optional) If you plan to develop more advanced projects after this homework, we recommend using PyCharm with the AlgoDEA extension. After installing the AlgoDEA extension in PyCharm:

1. Open PyCharm
2. Create a new Algorand project (instead of "Pure Python" project which is the default)
3. Set up the node by clicking on the "Algorand Explorer" on the top right and then fill in the information as shown below:
4. Click on the button "Fetch Network Info". "Genesis Hash" and "Genesis ID" should be automatically populated

Troubleshooting: If you don't see the "Algorand Explorer" tab, check you created a new Algorand project and not a Pure Python project.

In order to send transactions on the Algorand blockchain, you need to create an account. Basic accounts on Algorand are defined by an address (or public key) and a private key.

The address is completely public and should be given to anybody who needs to send Algos or other assets/tokens to you for example.

The private key is used to authorize transactions from your account by signing them. The private key is usually represented by a 25-word mnemonic. It should be kept secret.

Task: Create two Algorand accounts and report the two addresses in form.md. The accounts will be called account A and B from now on.

There are many ways of creating Algorand accounts. For non-developers, the simplest way is to use a wallet such as My Algo Wallet. After choosing a password, just click on "Add Wallet" and then "Create Wallet" below "New Wallet", and follow the instructions.

For developers, the Python SDK allows you easily to create wallets by running the following code:

import algosdk

# Generate a fresh private key and associated account address
private_key, account_address = algosdk.account.generate_account()

# Convert the private key into a mnemonic which is easier to use
mnemonic = algosdk.mnemonic.from_private_key(private_key)

print("Private key mnemonic: " + mnemonic)
print("Account address: " + account_address)

After running the script, you should see:

Private key mnemonic: six citizen candy robot jacket regular install tell end oven piece problem venture sleep arrow decorate chalk casual patient flat start upset tent abandon bounce
Account address: ZBXIRU3KVUTZMFC2MNDHFZ5RZMEH6FYGYZ32B6BEJHQNKWTUJUBB72WL4Y

Important: Never use this private key mnemonic to hold real Algos (i.e., on MainNet). Only use it for "fake Algos" on TestNet.

Note: Using My Algo Wallet will enable you to do all Steps 1 to 3. But if you want to be able to do the full homework, you will need to know how to use the Python SDK (or another SDK). In that case, we recommend you generate one account with the SDK and one with My Algo Wallet.

Note: Even if you created the account using the SDK, you can then import the mnemonic inside My Algo Wallet, so that you can directly use My Algo Wallet to send transactions. After choosing a password, just click on "Add Wallet" and then "Import Wallet", and follow the instructions.

Note: You can further import your account in other wallets, such as the wallet in AlgoDEA (if you are using AlgoDEA), the official Algorand Wallet (after setting it to TestNet) or AlgoSigner (the equivalent of MetaMask for Algorand).

Note: The developer documentation shows many other ways of creating accounts.

Task: Add 10 Algos to each of the accounts. The Algo is the native cryptocurrency of the Algorand blockchain.

In order to use your accounts, you need to add Algos to them. On MainNet, you would need to buy them for example on an exchange. However, on TestNet, you can just use the dispenser.

For each account, copy the address in the text field, click on/solve the CAPTCHA, and click on Submit. Refresh the page between each account.

Task: Check that the two accounts now have at least 10 Algos.

To check the balance of an account, go to a block explorer (e.g., AlgoExplorer or GoalSeeker), search for your address and look at the balance.

Each account should now have 10 Algos. If this is not the case, go back to Step 1.1.

Remark that it takes less than 5s for the funding transaction to be committed to the blockchain and the balance to be updated. Even more importantly, once the transaction appears in the block explorer (i.e., is committed to a block), the transaction is final and cannot be reversed or cancelled. This is a distinctive property of the Algorand blockchain: immediate finality.

You may remark that the balance of your account increases with time. That is because every account on Algorand receives automatically participation rewards. Note that participation rewards rate on TestNet and MainNet are independent. See the Algorand Foundation FAQ for details.

Task: From accounts A and B, send 1.42 Algos to 4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI with notes my first Algorand transaction and my second Algorand transaction respectively. Write down the corresponding transaction ID (aka, TxID) of the two transactions in form.md.

Any transaction can include an arbitrary "note" of up to 1kB. In other words, notes allow to store small amount of data on the blockchain. For this homework, the notes need to be my first Algorand transaction and my second Algorand transaction respectively.

If your account is in My Algo Wallet, you can send the transactions directly from there. Be careful to switch the network to TestNet by clicking on the button MainNet in the top right. To be able to add a note, click on "Advanced Transaction". See screenshot below.

If you are a developer, we recommend you send at least one transaction using the Python SDK by following the tutorial "Your First Transaction" starting at step "Connect your client". To use the PureStake API service, define algod_client as:

algod_client = algod.AlgodClient(
    algod_token="",
    algod_address="https://testnet-algorand.api.purestake.io/ps2",
    headers={"X-API-Key": "YOUR PURESTAKE API KEY"}
)

You also need to replace the amount and the note by the correct value. Note that the amount is specified in microAlgos: 1,000,000 microAlgo = 1 Algo.

You can confirm the two transactions were committed to the blockchain on any block explorer, by searching for the account address and clicking on the relevant transaction. Check that the amount, the receiver, and the note are correct. See for example a screenshot using AlgoExplorer. Do not forget to copy the transaction ID to form.md (you can use the copy button circled in green).

Beyond adding a memo to a transaction, notes have many use cases. Here are some of them:

• notarization and timestamping of images and digital media to prevent tampering: Attestive
• storing anonymous survey data to build the world's first open database for tracking and understanding COVID‑19: iReport-Covid
• storing data announcing a vote is taking place (the voting process is handled by a smart contract): Block'n'Poll

The Algorand Indexer v2 allows to make advanced queries on the blockchain, such as searching for transactions, accounts, assets, ... In particular, it allows to search for all transactions with a note with a certain prefix. The developer website contains a tutorial about it.

If you do not want to install the indexer, you can use the public PureStake API service:

myindexer = indexer.IndexerClient(
    indexer_token="",
    indexer_address="https://testnet-algorand.api.purestake.io/idx2",
    headers={"X-API-Key": "YOUR PURESTAKE API KEY"}
)

To send a transaction on Algorand, you need to pay a fee. The minimum fee is 0.001 Algo (i.e., 1,000 microAlgos). The required fee may increase in case of congestion. When this homework was written, this never happened. See the developer documentation for details.

The Algorand protocol supports the creation of on-chain assets or tokens that benefit from the same security, compatibility, speed and ease of use as the Algo. The official name for assets on Algorand is Algorand Standard Assets (ASA). ASAs can be used to represent stablecoins, loyalty points, system credits, in-game points, and collectibles, to name just a few. For more details, see the developer documentation.

Task: Create your own asset on Algorand from account A. The creator account must be account A. The total supply (number of tokens) should be at least 10. Choose your preferred asset name and unit name.

Creating an ASA takes less than 1min and can be done 100% online using MyAlgoWallet Asset Manager or AlgoDesk:

1. Go to https://app.algodesk.io/
2. Connect to the appropriate wallet on TestNet
3. Click on "Create Asset"
4. Choose your preferred asset name, unit name, and total supply (anything above 10 for this homework). See screenshot below.
5. Your asset is created in less than 5s! Report the asset ID and asset name in form.md.

You can search for your asset in a block explorer by searching for the asset ID.

If you prefer, you can also create assets using the Python SDK. See the developer documentation or the tutorial Working with ASA using Python.

Before being able to receive an asset, an account must first opt in to the asset.

Task: Make account B opt in to the asset you created. Report the opt-in transaction ID on form.md.

If you are using My Algo Wallet, just go the account B wallet, click on "All" at the top right, then click on "Add Asset", enter the asset ID, and follow the instructions. See screenshot below:

An asset opt-in is just an asset transaction of 0 asset from the account to itself and can be seen on any block explorer.

If you are a developer, you can also send the opt-in transaction using the Python SDK. See the developer documentation or the tutorial Working with ASA using Python.

Now that account B opted in the asset, you can send 1 asset unit from account A to account B.

Task: Send 1 asset unit from account A to account B. Report the transaction ID on form.md

If you are using My Algo Wallet, just go the account A wallet, click on "All" at the top right, then click on the new asset, and click on "Send" to create a transaction of 1 asset from A to B.

You can also use https://app.algodesk.io by clicking on the three dots at the top right of the asset box and on "Send Assets". See screenshot below:

If you are a developer however, we recommend that you send the asset transfer transaction using the Python SDK. See the developer documentation or the tutorial Working with ASA using Python.

Any Algorand account must keep a minimum balance of 0.1 Algo. This is to prevent malicious people to create too many accounts, which could make the size of the account table (stored by all the nodes of the blockchain) explodes. For every asset an account opts in or creates, the minimum balance is increased by 0.1 Algo.

See the developer documentation for more details.

Note: All the previous steps could be done without any programming knowledge. From now on, programming or command line knowledge is necessary.

In the previous steps, we have seen how to transfer Algos, create assets, and transfer assets. In many situations however, we need to trade or exchange x asset for y Algos (or y other assets). For example account A may sell its asset to account B instead of giving it away. One solution is just to have account B first send some Algos to pay for the asset, and then account B to send the asset. But then account B cannot be sure account A will not run with the money.

Atomic transfers completely solve this issue. Atomic transfers allow to group two transactions (transfer of asset from A to B, and transfer of Algos from B to A) in such a way that:

• either both transactions are successful: A gets its Algos and B gets its asset;
• or both transactions fail: A keeps it asset and B keeps its Algos.

Task: Make an atomic transfer where account B sends 1.2 Algos to account A and account A send 1 asset to account B. Report the transaction ID of the first transaction of the atomic transfer on form.md

Follow the tutorial on the developer documentation. Concretely, your Python script needs to:

1. Create a payment transaction of 1.2 Algos from B to A (like in Step 2). Do not sign it yet.
2. Create an asset transfer of 1 asset from A to B (like in Step 3.3). Do not sign it yet.
3. Group the two transactions together. Note that this modifies the transactions to ensure that one cannot be committed without the other. See the developer documentation.
4. Sign the first transaction using the private key of account B (like in Step 2).
5. Sign the second transaction using the private key of account A (like in Step 3.3).
6. Send both transactions together. See the developer documentation.
7. Check on a block explorer that the group transaction was committed properly.

On AlgoExplorer you can see that transactions are grouped in two ways:

1. Each transaction of the group has a group ID, which links to a page with all the transactions of the group. See screenshot below:
2. If multiple transactions in a group involves the same account, on the account page there is a small icon next to the transactions. See screenshot below:

If you do not see the above, it means you sent two independent transactions instead of making an atomic transfer.

While atomic transfers are very useful to trade assets, they require each account involved in the trade to sign the transactions. In some cases, you may want to allow anybody to trade assets with you without having to sign transactions. Smart signatures allow to make an account automatically approve transactions that follow some criteria.

To show the power of smart signatures, we created an exclusive asset for the class "buildweb3" and provided a smart signature that will allow you to receive 1 unit of the asset for just 4.2 Algos! The smart signature approves transactions of 1 unit of the asset if it is in a group of 2 transactions (aka atomic transfer) where:

1. the first transaction sends 4.2 Algos to the smart signature account (this transaction is signed by your account),
2. the second transaction sends 1 unit of the asset "buildweb3" from the smart signature account (this transaction is approved by the smart signature rather than being signed).

Task: Make account A opt in to the asset "buildweb3" with ID 14035004. Report the opt-in transaction ID on form.md.

Remember that opt-in transactions were covered in Step 3.3.

Task: Make an atomic transfer of 4.2 Algos from account A to 4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI and of 1 "buildweb3" asset (ID 14035004) from 4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI to account A, where the second transaction is signed using the signed smart signature (aka delegated logic sig).

This task is similar to Step 4, except that the second transaction is signed using a delegated logic sig / smart signature instead of a normal signature. Concretely, assume txn2 is the second transaction of your atomic transfer Instead of signing it with stxn2 = txn2.sign(private_key), you do the following:

with open("step5.lsig", "rb") as f:
    lsig = encoding.future_msgpack_decode(base64.b64encode(f.read()))
stxn2 = LogicSigTransaction(txn2, lsig)

The full script should look like:

import base64

from algosdk import mnemonic, encoding
from algosdk.v2client import algod
from algosdk.future import transaction
from algosdk.future.transaction import LogicSigTransaction, PaymentTxn, AssetTransferTxn

# Setup algod_client and global variables
...

# Get the suggested parameters
params = algod_client.suggested_params()

# Create the two transactions
txn1 = PaymentTxn(...)
txn2 = AssetTransferTxn(...)

# Group the two transactions
...

# Sign both transactions
stxn1 = txn1.sign(...)
with open("step5.lsig", "rb") as f:
    lsig = encoding.future_msgpack_decode(base64.b64encode(f.read()))
stxn2 = LogicSigTransaction(txn2, lsig)

# Assemble the signed group
signed_group = [stxn1, stxn2]

# Send the signed group
txid = algod_client.send_transactions(signed_group)

# Print the transaction ID of the first transaction of the group
print("Send transaction with txID: {}".format(txid))

This concludes the homework! 🎆

The smart signature in Step 5 is used as a delegated logic sig: it allows a normal account to delegate some abilities to anyone. Here the ability is to send 1 unit of asset in an atomic transfer where the first transaction pays 42 Algos. Anybody knowing the private key of the underlying account can sign arbitrary transactions without any restriction. A delegated logic sig is essentially a compiled smart signature signed by the private key of the underlying account.

Algorand also supports more classical smart signature contract accounts. Smart signature contract accounts are accounts that are only controlled by a smart signature. All transactions must be approved by the smart signature and there is no associated private key.

See the developer documentation for details.

The actual smart signature is step5.teal. It was generated using PyTeal that simplifies the writing of TEAL scripts, the language of smart contracts and smart signatures on Algorand. In other words, step5.teal is the output of step5.teal.py.

Concretely, to generate step5.lsig, the secret key of 4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI was added to kmd using goal account import, and then the following commands were run:

python3 step5.teal.py > step5.teal
goal clerk compile -a 4O6BRAPVLX5ID23AZWV33TICD35TI6JWOHXVLPGO4VRJATO6MZZQRKC7RI -s step5.teal -o step5.lsig

This assumes that PyTeal is installed via python3 -m pip pyteal --upgrade and that the Algorand Command Line Interface Tools were installed.

The smart signatures described previously are used to approve or reject transactions. They cannot store any variables / state on the blockchain.

Algorand also has smart contracts. See the developer documentation for details. The developer websites contain several examples of stateful smart contracts on Algorand:

• Voting dApp.
• Crowdfunding smart contract and its associated frontend.

Most dApps actually now use smart contracts rather than smart signatures. Still smart signatures are useful in some specific use cases like the above simple automated trading (a smart contract would have been slightly more complex) and when very complex operations need to be performed (like slow cryptographic operations).

Many tools have been developed by the community to facilitate development over Algorand. The developer website contains a list of them. Here we highlight some:

• Automate development of smart contracts and assets: https://github.com/scale-it/algorand-builder
• Block explorer: https://goalseeker.purestake.io, https://algoexplorer.io
• Create your first token and smart contract without installing anything on your computer: https://algodesk.io
• Free API services: https://api.algoexplorer.io, https://www.purestake.com/technology/algorand-api (equivalent to Infura for people from the Ethereum world)
• Wallet for distributed applications: https://www.purestake.com/technology/algosigner (equivalent of MetaMask for people from the Ethereum world)
• Write distributed applications in a JavaScript-like language: https://reach.sh (bonus: same code works on Ethereum)