Index
- Lesson 1: CryptoZombies
- Chapter 2 Contracts
- Chapter 3: State Variables & Integers
- Chapter 4: Math Operations
- Chapter 5: Structs
- Chapter 6: Arrays
- Chapter 7: Function Declarations
- Chapter 8: Working With Structs and Arrays
- Chapter 9: Private / Public Functions
- Chapter 10: More on Functions
- Chapter 11: Keccak256 and Typecasting
- Chapter 12: Putting It Together
- Chapter 13: Events
- Chapter 14: Web3.js
- Lesson 2: Zombies Attack Their Victims
- Chapter 2: Mappings and Addresses
- Chapter 3: Msg.sender
- Chapter 4: Require
- Chapter 5: Inheritance
- Chapter 6: Import
- Chapter 7: Storage vs Memory
- Chapter 8: Zombie DNA
- Chapter 9: More on Function Visibility
- Chapter 10: What Do Zombies Eat?
- Chapter 11: Using an Interface
- Chapter 12: Handling Multiple Return Values
- Chapter 13: Bonus: Kitty Genes
- Chapter 14: Wrapping It Up
- Lesson 3: Advanced Solidity Concepts
- Chapter 2: Ownable Contracts
- Chapter 3: onlyOwner Function Modifier
- Chapter 4: Gas
- Chapter 5: Time Units
- Chapter 6: Zombie Cooldowns
- Chapter 7: Public Functions & Security
- Chapter 8: More on Function Modifiers
- Chapter 9: Zombie Modifiers
- Chapter 10: Saving Gas With 'View' Functions
- Chapter 11: Storage is Expensive
- Chapter 12: For Loops
- Chapter 13: Wrapping It Up
- Lesson 4: Zombie Battle System
- Chapter 1: Payable
- Chapter 2: Withdraws
- Chapter 3: Zombie Battles
- Chapter 4: Random Numbers
- Chapter 5: Zombie Fightin'
- Chapter 6: Refactoring Common Logic
- Chapter 7: More Refactoring
- Chapter 8: Back to Attack!
- Chapter 9: Zombie Wins and Losses
- Chapter 10: Zombie Victory 😄
- Chapter 11: Zombie Loss 😞
- Lesson 5: ERC721 & Crypto-Collectibles
- Chapter 1: Tokens on Ethereum
- Chapter 2: ERC721 Standard, Multiple Inheritance
- Chapter 3: balanceOf & ownerOf
- Chapter 4: Refactoring
- Chapter 5: ERC721: Transfer Logic
- Chapter 6: ERC721: Transfer Cont'd
- Chapter 7: ERC721: Approve
- Chapter 8: ERC721: Approve
- Chapter 9: Preventing Overflows
- Chapter 10: SafeMath Part 2
- Chapter 11: SafeMath Part 3
- Chapter 12: SafeMath Part 4
- Chapter 13: Comments
- Chapter 14: Wrapping It Up
- App Front-ends & Web3.js
- Chapter 1: Intro to Web3.js
- Chapter 2: Web3 Providers
- Chapter 3: Talking to Contracts
- Chapter 4: Calling Contract Functions
- Chapter 5: Metamask & Accounts
- Chapter 6: Displaying our Zombie Army
- Chapter 7: Sending Transactions
- Chapter 8: Calling Payable Functions
- Chapter 9: Subscribing to Events
- Chapter 10: Wrapping It Up
Chapter 11: Zombie Loss 😞
Chapter 11: Zombie Loss 😞
Now that we've coded what happens when your zombie wins, let's figure out what happens when it loses.
In our game, when zombies lose, they don't level down — they simply add a loss to their
lossCount, and their cooldown is triggered so they have to wait a day before attacking again.To implement this logic, we'll need an
else statement.else statements are written just like in JavaScript and many other languages:if (zombieCoins[msg.sender] > 100000000) {
// You rich!!!
} else {
// We require more ZombieCoins...
}
// You rich!!!
} else {
// We require more ZombieCoins...
}
Put it to the test
1. Add an
else statement. If our zombie loses:a. Increment
myZombie's lossCount.b. Increment
enemyZombie's winCount.c. Run the
_triggerCooldown function on myZombie. This way the zombie can only attack once per day. (Remember, _triggerCooldown is already run inside feedAndMultiply. So the zombie's cooldown will be triggered whether he wins or loses.)pragma solidity ^0.4.25;
import "./zombiehelper.sol";
contract ZombieAttack is ZombieHelper {
uint randNonce = 0;
uint attackVictoryProbability = 70;
function randMod(uint _modulus) internal returns(uint) {
randNonce++;
return uint(keccak256(abi.encodePacked(now, msg.sender, randNonce))) % _modulus;
}
function attack(uint _zombieId, uint _targetId) external ownerOf(_zombieId) {
Zombie storage myZombie = zombies[_zombieId];
Zombie storage enemyZombie = zombies[_targetId];
uint rand = randMod(100);
if (rand <= attackVictoryProbability) {
myZombie.winCount++;
myZombie.level++;
enemyZombie.lossCount++;
feedAndMultiply(_zombieId, enemyZombie.dna, "zombie");
} else {
myZombie.lossCount++;
enemyZombie.winCount++;
_triggerCooldown(myZombie);
}
}
}
import "./zombiehelper.sol";
contract ZombieAttack is ZombieHelper {
uint randNonce = 0;
uint attackVictoryProbability = 70;
function randMod(uint _modulus) internal returns(uint) {
randNonce++;
return uint(keccak256(abi.encodePacked(now, msg.sender, randNonce))) % _modulus;
}
function attack(uint _zombieId, uint _targetId) external ownerOf(_zombieId) {
Zombie storage myZombie = zombies[_zombieId];
Zombie storage enemyZombie = zombies[_targetId];
uint rand = randMod(100);
if (rand <= attackVictoryProbability) {
myZombie.winCount++;
myZombie.level++;
enemyZombie.lossCount++;
feedAndMultiply(_zombieId, enemyZombie.dna, "zombie");
} else {
myZombie.lossCount++;
enemyZombie.winCount++;
_triggerCooldown(myZombie);
}
}
}