Game Theory for Crypto
Strategic analysis framework for understanding and designing incentive systems in web3.
"Every protocol is a game. Every token is an incentive. Every user is a player. Understand the rules, or become the played."
When to Use This Skill
Analyzing tokenomics for exploits or misaligned incentives
Evaluating governance proposals and voting mechanisms
Understanding MEV and adversarial transaction ordering
Designing auction mechanisms (NFT drops, token sales, liquidations)
Predicting how rational actors will behave in a system
Identifying attack vectors in DeFi protocols
Modeling liquidity provision strategies
Assessing protocol sustainability
Core Framework
The Five Questions
For any protocol or mechanism, ask:
Who are the players? (Users, LPs, validators, searchers, governance token holders)
What are their strategies? (Actions available to each player)
What are the payoffs? (How does each outcome affect each player?)
What information do they have? (Complete, incomplete, asymmetric?)
What's the equilibrium? (Where do rational actors end up?)
Analysis Template
## Protocol: [Name]
### Players
- Player A: [Role, objectives, constraints]
- Player B: [Role, objectives, constraints]
- ...
### Strategy Space
- Player A can: [List possible actions]
- Player B can: [List possible actions]
### Payoff Structure
- If (A does X, B does Y): A gets [payoff], B gets [payoff]
- ...
### Information Structure
- Public information: [What everyone knows]
- Private information: [What only some players know]
- Observable actions: [What can be seen on-chain]
### Equilibrium Analysis
- Nash equilibrium: [Stable outcome where no player wants to deviate]
- Dominant strategies: [Strategies that are always best regardless of others]
- Potential exploits: [Deviations that benefit attackers]
### Recommendations
- [Design changes to improve incentive alignment]
Reference Documents
| Document | Use Case |
|---|---|
| Nash Equilibrium | Finding stable outcomes in strategic interactions |
| Mechanism Design | Designing systems with desired equilibria |
| Auction Theory | Token sales, NFT drops, liquidations |
| MEV Game Theory | Adversarial transaction ordering |
| Tokenomics Analysis | Evaluating token incentive structures |
| Governance Attacks | Voting manipulation and capture |
| Liquidity Games | LP strategies and impermanent loss |
| Information Economics | Asymmetric information and signaling |
Quick Concepts
Nash Equilibrium
A state where no player can improve their payoff by unilaterally changing strategy. The "stable" outcome of a game.
Crypto application: In a staking system, Nash equilibrium determines the stake distribution across validators.
Dominant Strategy
A strategy that's optimal regardless of what others do.
Crypto application: In a second-price auction, bidding your true value is dominant.
Pareto Efficiency
An outcome where no one can be made better off without making someone worse off.
Crypto application: AMM fee structures try to be Pareto efficient for traders and LPs.
Mechanism Design
"Reverse game theory" - designing rules to achieve desired outcomes.
Crypto application: Designing token vesting schedules to align long-term incentives.
Schelling Point
A solution people converge on without communication.
Crypto application: Why certain price levels act as psychological support/resistance.
Incentive Compatibility
When truthful behavior is optimal for participants.
Crypto application: Oracle designs where honest reporting is the dominant strategy.
Common Knowledge
Everyone knows X, everyone knows everyone knows X, infinitely recursive.
Crypto application: Public blockchain state creates common knowledge of balances/positions.
Analysis Patterns
Pattern 1: The Tragedy of the Commons
Structure: Shared resource, individual incentive to overuse, collective harm.
Crypto examples:
Gas price bidding during congestion
Governance token voting apathy
MEV extraction degrading UX
Solution approaches:
Harberger taxes
Quadratic mechanisms
Commitment schemes
Pattern 2: The Prisoner's Dilemma
Structure: Individual rationality leads to collective irrationality.
Crypto examples:
Liquidity mining mercenaries (farm and dump)
Race-to-bottom validator fees
Bridge security (each chain wants others to secure)
Solution approaches:
Repeated games (reputation)
Commitment mechanisms (staking/slashing)
Mechanism redesign
Pattern 3: The Coordination Game
Structure: Multiple equilibria, players want to coordinate but may fail.
Crypto examples:
Which L2 to use?
Token standard adoption
Hard fork coordination
Solution approaches:
Focal points (Schelling points)
Sequential moves (first mover advantage)
Communication mechanisms
Pattern 4: The Principal-Agent Problem
Structure: One party acts on behalf of another with misaligned incentives.
Crypto examples:
Protocol team vs token holders
Delegates in governance
Fund managers
Solution approaches:
Incentive alignment (token vesting)
Monitoring (transparency)
Bonding (skin in game)
Pattern 5: Adverse Selection
Structure: Information asymmetry leads to market breakdown.
Crypto examples:
Token launches (team knows more than buyers)
Insurance protocols (risky users more likely to buy)
Lending (borrowers know their risk better)
Solution approaches:
Signaling (lock-ups, audits)
Screening (credit scores, history)
Pooling equilibria
Pattern 6: Moral Hazard
Structure: Hidden action after agreement leads to risk-taking.
Crypto examples:
Protocols with insurance may take more risk
Bailout expectations encourage leverage
Anonymous teams may rug
Solution approaches:
Monitoring and transparency
Incentive alignment
Reputation systems
Common Crypto Games
The MEV Game
Players: Users, searchers, builders, validators Key insight: Transaction ordering is a game; users are often the losers
See: MEV Strategies
The Liquidity Game
Players: LPs, traders, arbitrageurs Key insight: Impermanent loss is the cost of being adversely selected against
See: Liquidity Games
The Governance Game
Players: Token holders, delegates, protocol team Key insight: Rational apathy + concentrated interests = capture
See: Governance Attacks
The Staking Game
Players: Stakers, validators, delegators Key insight: Security budget must exceed attack profit
See: Tokenomics Analysis
The Oracle Game
Players: Data providers, consumers, attackers Key insight: Profit from manipulation must be less than cost
See: Mechanism Design
Red Flags in Protocol Design
Tokenomics Red Flags
Insiders can sell before others (vesting asymmetry)
Inflation benefits few, dilutes many
No sink mechanisms (perpetual selling pressure)
Rewards without risk (free money = someone else paying)
Governance Red Flags
Low quorum thresholds (minority capture)
No time delay (flash loan attacks)
Token voting only (plutocracy)
Delegates with no skin in game
Mechanism Red Flags
First-come-first-served (bot advantage)
Sealed bids without commitment (frontrunning)
Rebates/refunds (MEV extraction)
Complex formulas (hidden exploits)
Advanced Topics
Repeated Games and Reputation
Single-shot games often have bad equilibria. Repetition enables cooperation through:
Trigger strategies (cooperate until defection)
Reputation building (costly to destroy)
Future value (patient players cooperate more)
Crypto application: Why anonymous actors behave worse than doxxed teams.
Evolutionary Game Theory
Strategies that survive competitive selection. Relevant for:
Which protocols survive long-term
Memetic competition between narratives
Bot strategy evolution
Bayesian Games
Games with incomplete information. Players have beliefs about others' types.
Crypto application: Trading with unknown counterparties, evaluating anonymous teams.
Cooperative Game Theory
When players can form binding coalitions.
Crypto application: MEV extraction coalitions, validator cartels, governance blocs.
Algorithmic Game Theory
Computational aspects of game theory.
Crypto application: On-chain game computation limits, gas-efficient mechanism design.
Methodology
Step 1: Model the Game
Identify all players (including those not obvious)
Map complete strategy spaces
Define payoff functions precisely
Specify information structure
Step 2: Find Equilibria
Check for dominant strategies
Compute Nash equilibria
Identify Pareto improvements
Consider trembling-hand perfection
Step 3: Stress Test
What if players collude?
What if new players enter?
What if information leaks?
What if parameters change?
Step 4: Recommend
Mechanism changes to improve equilibrium
Monitoring to detect deviations
Parameter bounds to maintain stability
Resources
Foundational Texts
"Theory of Games and Economic Behavior" - von Neumann & Morgenstern
"A Beautiful Mind" (Nash's life, accessible intro)
"The Strategy of Conflict" - Schelling
"Mechanism Design Theory" - Myerson (Nobel lecture)
Crypto-Specific
"Flash Boys 2.0" - MEV paper
"SoK: DeFi Attacks" - Systemization of DeFi exploits
"Clockwork Finance" - MEV and mechanism design
Paradigm research blog
Tools
Nashpy (Python game theory library)
Gambit (game theory software)
Agent-based modeling frameworks