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 5: Time Units
Chapter 5: Time Units
The
level property is pretty self-explanatory. Later on, when we create a battle system, zombies who win more battles will level up over time and get access to more abilities.The
readyTime property requires a bit more explanation. The goal is to add a "cooldown period", an amount of time a zombie has to wait after feeding or attacking before it's allowed to feed / attack again. Without this, the zombie could attack and multiply 1,000 times per day, which would make the game way too easy.In order to keep track of how much time a zombie has to wait until it can attack again, we can use Solidity's time units.
Time units
Solidity provides some native units for dealing with time.
The variable
now will return the current unix timestamp of the latest block (the number of seconds that have passed since January 1st 1970). The unix time as I write this is 1515527488.Note: Unix time is traditionally stored in a 32-bit number. This will lead to the "Year 2038" problem, when 32-bit unix timestamps will overflow and break a lot of legacy systems. So if we wanted our DApp to keep running 20 years from now, we could use a 64-bit number instead — but our users would have to spend more gas to use our DApp in the meantime. Design decisions!
Solidity also contains the time units
seconds, minutes, hours, days, weeks and years. These will convert to a uint of the number of seconds in that length of time. So 1 minutes is 60, 1 hours is 3600 (60 seconds x 60 minutes), 1 days is 86400 (24 hours x 60 minutes x 60 seconds), etc.Here's an example of how these time units can be useful:
uint lastUpdated;
// Set `lastUpdated` to `now`
function updateTimestamp() public {
lastUpdated = now;
}
// Will return `true` if 5 minutes have passed since `updateTimestamp` was
// called, `false` if 5 minutes have not passed
function fiveMinutesHavePassed() public view returns (bool) {
return (now >= (lastUpdated + 5 minutes));
}
// Set `lastUpdated` to `now`
function updateTimestamp() public {
lastUpdated = now;
}
// Will return `true` if 5 minutes have passed since `updateTimestamp` was
// called, `false` if 5 minutes have not passed
function fiveMinutesHavePassed() public view returns (bool) {
return (now >= (lastUpdated + 5 minutes));
}
cooldown feature.Put it to the test
Let's add a cooldown time to our DApp, and make it so zombies have to wait 1 day after attacking or feeding to attack again.
1. Declare a
uint called cooldownTime, and set it equal to 1 days. (Forgive the poor grammar — if you set it equal to "1 day", it won't compile!)2. Since we added a
level and readyTime to our Zombie struct in the previous chapter, we need to update _createZombie() to use the correct number of arguments when we create a new Zombie struct.Update the
zombies.push line of code to add 2 more arguments: 1 (for level), and uint32(now + cooldownTime) (for readyTime).Note: The
uint32(...) is necessary because now returns a uint256 by default. So we need to explicitly convert it to a uint32.now + cooldownTime will equal the current unix timestamp (in seconds) plus the number of seconds in 1 day — which will equal the unix timestamp 1 day from now. Later we can compare to see if this zombie's readyTime is greater than now to see if enough time has passed to use the zombie again.We'll implement the functionality to limit actions based on
readyTime in the next chapter.pragma solidity ^0.4.25;
import "./ownable.sol";
contract ZombieFactory is Ownable {
event NewZombie(uint zombieId, string name, uint dna);
uint dnaDigits = 16;
uint dnaModulus = 10 ** dnaDigits;
// 1. Define `cooldownTime` here
uint cooldownTime = 1 days;
struct Zombie {
string name;
uint dna;
uint32 level;
uint32 readyTime;
}
Zombie[] public zombies;
mapping (uint => address) public zombieToOwner;
mapping (address => uint) ownerZombieCount;
function _createZombie(string _name, uint _dna) internal {
// 2. Update the following line:
uint id = zombies.push(Zombie(_name, _dna, 1, uint32(now + cooldownTime))) - 1;
zombieToOwner[id] = msg.sender;
ownerZombieCount[msg.sender]++;
emit NewZombie(id, _name, _dna);
}
function _generateRandomDna(string _str) private view returns (uint) {
uint rand = uint(keccak256(abi.encodePacked(_str)));
return rand % dnaModulus;
}
function createRandomZombie(string _name) public {
require(ownerZombieCount[msg.sender] == 0);
uint randDna = _generateRandomDna(_name);
randDna = randDna - randDna % 100;
_createZombie(_name, randDna);
}
}
import "./ownable.sol";
contract ZombieFactory is Ownable {
event NewZombie(uint zombieId, string name, uint dna);
uint dnaDigits = 16;
uint dnaModulus = 10 ** dnaDigits;
// 1. Define `cooldownTime` here
uint cooldownTime = 1 days;
struct Zombie {
string name;
uint dna;
uint32 level;
uint32 readyTime;
}
Zombie[] public zombies;
mapping (uint => address) public zombieToOwner;
mapping (address => uint) ownerZombieCount;
function _createZombie(string _name, uint _dna) internal {
// 2. Update the following line:
uint id = zombies.push(Zombie(_name, _dna, 1, uint32(now + cooldownTime))) - 1;
zombieToOwner[id] = msg.sender;
ownerZombieCount[msg.sender]++;
emit NewZombie(id, _name, _dna);
}
function _generateRandomDna(string _str) private view returns (uint) {
uint rand = uint(keccak256(abi.encodePacked(_str)));
return rand % dnaModulus;
}
function createRandomZombie(string _name) public {
require(ownerZombieCount[msg.sender] == 0);
uint randDna = _generateRandomDna(_name);
randDna = randDna - randDna % 100;
_createZombie(_name, randDna);
}
}