Claude-skill-registry blockchain-basics

Master blockchain fundamentals including consensus, cryptography, and distributed systems

install

source · Clone the upstream repo

git clone https://github.com/majiayu000/claude-skill-registry

Claude Code · Install into ~/.claude/skills/

T=$(mktemp -d) && git clone --depth=1 https://github.com/majiayu000/claude-skill-registry "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/data/blockchain-basics" ~/.claude/skills/majiayu000-claude-skill-registry-blockchain-basics && rm -rf "$T"

manifest: skills/data/blockchain-basics/SKILL.md

Blockchain Basics Skill

Master blockchain fundamentals including consensus mechanisms, cryptographic primitives, and distributed systems architecture.

Quick Start

# Invoke this skill for blockchain fundamentals
Skill("blockchain-basics", topic="consensus", depth="intermediate")

Topics Covered

1. Consensus Mechanisms

Learn how distributed networks achieve agreement:

Proof of Work: Mining, hashrate, difficulty adjustment
Proof of Stake: Validators, slashing, finality
Byzantine Fault Tolerance: Leader election, view changes

2. Cryptographic Foundations

Understand the security primitives:

Hash Functions: SHA-256, Keccak-256, properties
Digital Signatures: ECDSA, Ed25519, verification
Merkle Trees: Proof construction, verification

3. Network Architecture

Explore distributed systems:

P2P Networks: Gossip protocols, peer discovery
Node Types: Full nodes, light clients, archives
Block Propagation: Compact blocks, relay networks

4. Transaction Lifecycle

Follow data through the chain:

Transaction Structure: Inputs, outputs, signatures
Mempool: Fee markets, ordering, priority
Confirmation: Finality, reorganization

Code Examples

Verify Merkle Proof

import hashlib

def verify_merkle_proof(leaf: bytes, proof: list, root: bytes) -> bool:
    """Verify a Merkle proof for inclusion"""
    current = leaf
    for sibling, is_left in proof:
        if is_left:
            current = hashlib.sha256(sibling + current).digest()
        else:
            current = hashlib.sha256(current + sibling).digest()
    return current == root

Calculate Block Hash

import hashlib
import struct

def calculate_block_hash(header: dict) -> bytes:
    """Calculate Bitcoin-style block hash"""
    data = struct.pack(
        '<I32s32sIII',
        header['version'],
        bytes.fromhex(header['prev_block']),
        bytes.fromhex(header['merkle_root']),
        header['timestamp'],
        header['bits'],
        header['nonce']
    )
    return hashlib.sha256(hashlib.sha256(data).digest()).digest()[::-1]

Common Pitfalls

Pitfall	Issue	Solution
Finality confusion	PoW is probabilistic	Wait for 6+ confirmations
Hash vs encryption	Hashes are one-way	Use proper encryption for secrets
Timestamp trust	Miners can manipulate	Use block height for precision

Troubleshooting

"Why is my transaction not confirming?"

Check transaction fee vs current mempool
Verify nonce is sequential (no gaps)
Ensure sufficient balance for amount + gas

"How do I verify a signature?"

from eth_account import Account
from eth_account.messages import encode_defunct

message = encode_defunct(text="Hello")
address = Account.recover_message(message, signature=sig)

Learning Path

[Beginner] → Hash Functions → Digital Signatures → Transactions
    ↓
[Intermediate] → Merkle Trees → Consensus → Network Layer
    ↓
[Advanced] → BFT Protocols → Sharding → Cross-chain

Test Yourself

# Unit test template
def test_merkle_root():
    txs = [b"tx1", b"tx2", b"tx3", b"tx4"]
    root = build_merkle_root(txs)
    assert len(root) == 32
    assert verify_merkle_proof(txs[0], get_proof(0), root)

Cross-References

Bonded Agent:
```
01-blockchain-fundamentals
```

Related Skills:

ethereum-development

smart-contract-security

Version History

Version	Date	Changes
2.0.0	2025-01	Production-grade with validation, examples
1.0.0	2024-12	Initial release