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Multidimensional array syntax was wrong, now fixed
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26 KiB
Markdown
873 lines
26 KiB
Markdown
---
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language: Vyper
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filename: learnVyper.vy
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contributors:
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- ["Kenny Peluso", "kennyp.herokuapp.com"]
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---
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> The content of this document is largely inspired by ["Learn Solidity in Y Minutes"](https:#github.com/adambard/learnxinyminutes-docs/blob/master/solidity.html.markdown)
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Vyper lets you program on [Ethereum](https:#www.ethereum.org/), a
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blockchain-based virtual machine that allows the creation and
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execution of smart contracts, without requiring centralized or trusted parties. It was
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designed to improve upon Solidity, another smart contract language for Ethereum, by
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limiting unsafe practices and enhancing readability; Vyper seeks to optimize the
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security and auditability of smart contracts.
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Vyper is an experimental, statically typed, contract programming language meant to
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resemble Python. Like objects in OOP, each contract contains state variables, functions,
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and common data types. Contract-specific features include event notifiers for listeners,
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and custom global variables, global constants.
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Some Ethereum contract examples include crowdfunding, voting, and blind auctions.
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---
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## Table of Contents
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- Intro
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- Example
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1. Data types and associated methods
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2. Data structures
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3. Simple operators
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4. Global variables of note
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5. Functions and more
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a. functions
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b. events
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6. Branching and loops
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7. Objects/contracts
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a. calling external contracts
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b. ERC20 built-in
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c. following an interface
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8. Other keywords
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a. selfdestruct
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9. Contract design notes
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a. obfuscation
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b. storage optimization
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c. data access in blockchain
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d. cron job
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e. observer pattern
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10. Security
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11. Style notes
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12. Natspec comments
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- Other documents
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---
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## Intro
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From [the docs](https://media.readthedocs.org/pdf/vyper/latest/vyper.pdf)
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the foundational tenants of Vyper are:
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1. *Security*
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2. *Language and compiler simplicity*
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3. *Auditability*
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This allows for the following features:
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1. *Bounds and overflow checking*
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- On the arithmetic and array level
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- There are no dynamic arrays in Vyper
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2. *Support for signed integers and decimal fixed point numbers*
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3. *Decidability* - You can always compute precise upper bound on gas cost
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4. *Strong typing* - for built-in and custom types
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5. *Small and understandable compiler code*
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6. *Limited support for pure functions*
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- Anything marked `@constant` is not allowed to change the state
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Following the principles and goals, Vyper does not provide the following features:
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1. *Modifiers* (defining parts of functions elsewhere)
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2. *Class inheritance*
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3. *Inline assembly*
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4. *Function overloading*
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5. *Operator overloading*
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6. *Recursive calling*
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7. *Infinite-length loops*
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8. *Binary fixed point* (decimal fixed point is used for its exactness)
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WITH THE RAPID CHANGES IN ETHEREUM, THIS DOCUMENT IS UNLIKELY TO STAY UP TO
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DATE, SO YOU SHOULD FOLLOW THE LATEST VYPER DOCS AND ETHEREUM BLOG FOR THE LATEST.
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ALL CODE HERE IS PROVIDED AS IS, WITH SUBSTANTIAL RISK OF ERRORS OR DEPRECATED CODE
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PATTERNS.
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This document primarily discusses syntax, and so excludes many
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popular design patterns.
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As Vyper and Ethereum are under active development, experimental or beta
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features are typically marked, and subject to change. Pull requests welcome.
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This document describes Vyper version `0.1.0-beta.8`.
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*All of the following code exists for educational purposes only!*
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*None of the following code should be used in production as-is!*
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## Example
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```python
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# First, a simple todo list contract
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# Implements CRUD operations for tasks
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# todo.vy (note .vy extension)
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### **** START EXAMPLE **** ###
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# Start with Natspec comment
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# used for documentation
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# @title SimpleBank v1
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# @author kennyp
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# @notice This is a simple bank.
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# Vyper contracts must obey a particular order:
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# struct -> interface -> events -> globals and constants -> functions
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# Additionally, like Python, Vyper functions must be defined in the file
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# before they're called.
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# Structs
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struct Task:
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done: bool
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deleted: bool
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task: string[100]
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metadata: bytes32
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# Interfaces
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contract AnotherContract():
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def fetch() -> bytes32: constant
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def inform(_taskId: uint256, _status: uint256) -> bool: modifying
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# Events
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# Events - publicize actions to external listeners
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# `indexed` means that it's easier to search/filter on this field
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TaskStatus: event({_taskId: indexed(uint256), _status: uint256})
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# Global Variables
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# State variables are values which are permanently stored in contract storage
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# State vars consist of any value persisting beyond any function's scope
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# and are permanently stored in contract storage
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# You can define your own, custom, unmutable constants
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CREATED: constant(uint256) = 0
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COMPLETED: constant(uint256) = 1
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DELETED: constant(uint256) = 2
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# The `public` built-in allows for this address to be read externally
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# without defining a `get()` constant function
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owner: public(address)
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other: public(address)
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# uint256 means "unsigned positive integer between 0 and 2^256 - 1"
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# Overflow protection is built-in to Vyper
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taskCount: uint256
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tasks: map(uint256, Task) # dictionary: key=uint256, value: Task struct
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# Private Functions
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# Start each function with Pythonic decorators
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# These decorators resemble Natspec but are actually enforced by Vyper's compiler
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# These decorators are:
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# @public XOR @private (either one or the other)
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# @public (if any contract/user can call it)
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# @private (if only internal functions can call it)
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# @payable (if the function is payable i.e. accepting ETH)
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# @constant (if the function is not modifying anything on-chain)
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@private
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def _changeTaskStatus( \
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_sender: address, \
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_taskId: uint256, \
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_status: uint256, \
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):
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# backslashes (\) allow for multi-line code
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# Natspec comments are particularly helpful for documentation and readibility
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# Natspec can be included using familiar Pythonic docstring syntax
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"""
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@notice
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@dev `_sender` MUST be `self.owner`
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@param _sender Who is triggering this function
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@param _task The description of the task (only useful when task added)
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"""
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# NOTE: Private functions do not have access to `msg.sender`
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# SIDE NOTE: `msg.sender` refers to whoever immediately called the function of
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# immediate scope. In other words, if I call a function that calls another
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# in-contract, public function, then `msg.sender` turns from my address to
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# the address of the current contract.
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assert _sender == self.owner # failed assertions cause calls/transactions to fail
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# Note that unlike Solidity, `self.` is required to query the contract's state
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# Control flow is Pythonic, as is much of Vyper:
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_task: string[100] # initialized to default value
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_data: bytes32 = sha3(convert(_sender, bytes32)) # owner is obfuscated (but still visible in logs)
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if _status == CREATED: # control flow mimics python
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# How a new struct is instantiated:
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self.tasks[_taskId] = Task({ \
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done: False, deleted: False, task: _task, metadata: _data \
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})
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elif _status == COMPLETED:
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# Modifying an existing struct:
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self.tasks[_taskId].done = True
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elif _status == DELETED:
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self.tasks[_taskId].deleted = True
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AnotherContract(self.other).inform(_taskId, _status) # modifying external call
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log.TaskStatus(_taskId, _status) # emit an event
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# Public Functions
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# Pythonic constructor - can receive none or many arguments
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@public
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def __init__(_owner: address, _other_contract: address):
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"""
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@dev Called once and only upon contract depoyment
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"""
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self.owner = _owner
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self.other = _other_contract
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# NOTE: Pythonic whitespace rules are mandated in Vyper
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@public
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def addTask(_task: string[100]) -> uint256:
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"""
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@notice Adds a task to contract
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@param _task Description of task
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@return Id of newly minted task
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"""
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# msg.sender gives the address of who/what contract is calling this function
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self._changeTaskStatus(msg.sender, self.taskCount, CREATED)
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self.tasks[self.taskCount].task = _task
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self.taskCount += 1
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return self.taskCount - 1
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@public
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def addSpecialTask(_task: string[100]) -> uint256:
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"""
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@notice Adds a task with metadata pulled from elsewhere
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@param _task Description of task
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@return Id of newly minted task
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"""
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self._changeTaskStatus(msg.sender, self.taskCount, CREATED)
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self.tasks[self.taskCount].task = _task
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self.tasks[self.taskCount].metadata = AnotherContract(self.other).fetch()
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self.taskCount += 1
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return self.taskCount - 1
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@public
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def completeTask(_taskId: uint256):
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"""
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@notice Marks a task as "completed"
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@param _taskId Id of task to complete
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"""
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self._changeTaskStatus(msg.sender, _taskId, COMPLETED)
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@public
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def deleteTask(_taskId: uint256):
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"""
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@notice Adds a task to contract
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@param _taskId Id of task to delete
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"""
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self._changeTaskStatus(msg.sender, _taskId, DELETED)
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@public
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@constant # allows function to run locally/off blockchain
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def getTask(_taskId: uint256) -> string[100]:
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"""
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@notice Getter for a task's description
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@param _taskId Id of task with desired description
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@return Description of task
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"""
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return self.tasks[_taskId].task
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### **** END EXAMPLE **** ###
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# Now, the basics of Vyper
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# ---
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# 1. DATA TYPES AND ASSOCIATED METHODS
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# uint256 used for currency amount and for dates (in unix time)
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x: uint256
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# int of 128 bits, cannot be changed after contract deployment
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# with 'constant', compiler replaces each occurrence with actual value
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a: constant(int128) = 5
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# All state variables (those outside a function)
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# are by default 'internal' and accessible inside contract
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# Need to explicitly set to 'public' to allow external contracts to access
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# A getter is automatically created, but NOT a setter
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# Can only be called in the contract's scope (not within functions)
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# Add 'public' field to indicate publicly/externally accessible
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a: public(int128)
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# No random functions built in, use other contracts for randomness
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# Type casting is limited but exists
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b: int128 = 5
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x: uint256 = convert(b, uint256)
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# Types of accounts:
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# Contract Account: f(creator_addr, num_transactions)=address set on contract creation
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# External Account: (person/external entity): f(public_key)=address
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# Addresses - An address type can hold an Ethereum address which
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# equates to 20 bytes or 160 bits. It returns in hexadecimal notation
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# with a leading 0x. No arithmetic allowed
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owner: public(address)
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# Members can be invoked on all addresses:
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owner.balance # returns balance of address as `wei_value`
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owner.codesize # returns code size of address as `int128`
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owner.is_contract # `True` if Contract Account
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# All addresses can be sent ether via `send()` built-in
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@public
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@payable
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def sendWei(any_addr: address):
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send(any_addr, msg.value)
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# Bytes available
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a: bytes[2]
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b: bytes[32]
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c: bytes32
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# `b` and `c` are 2 different types
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# Bytes are preferable to strings since Vyper currently offers better
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# support for bytes i.e. more built-ins to deal with `bytes32`, `bytes32`
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# can be returned from functions and strings[] can't be, UTF8 (string encoding)
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# uses more storage, etc.
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# There are no dynamically sized bytes, similar to how there are no
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# dynamic arrays
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# Fixed-size byte arrays (Strings)
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a: string[100]
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b: string[8]
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c: string[108] = concat(a, b) # check the latest docs for more built-ins
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# Time
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t1: timedelta
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t2: timestamp
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# Both types are built-in "custom type" variants of `uint256`
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# `timedelta` values can be added but not `timestamp` values
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# Money
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m: wei_value
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# Also has the base type `uint256` like `timestamp` and `timedelta`
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# 1 unit of WEI (a small amount of ETH i.e. ether)
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# Custom types
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# specify units used in the contract:
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units: {
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cm: "centimeter",
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km: "kilometer"
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}
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# usage:
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a: int128(cm)
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b: uint256(km)
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# BY DEFAULT: all values are set to 0 on instantiation
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# `clear()` can be called on most types
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# Does NOT destroy value, but sets value to 0, the initial value
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# ---
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# 2. DATA STRUCTURES
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# Arrays
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bytes32[5] nicknames; # static array
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bytes32[] names; # dynamic array
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uint newLength = names.push("John"); # adding returns new length of the array
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# Length
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names.length; # get length
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names.length = 1; # lengths can be set (for dynamic arrays in storage only)
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# Multidimensional Arrays
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# At initialization, array dimensions must be hard-coded or constants
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# Initialize a 10-column by 3-row, multidimensional fixed array
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ls: (uint256[10])[3] # parentheses are optional
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@public
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def setToThree():
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# Multidimensional Array Access and Write
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# access indices are reversed
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# set element in row 2 (3rd row) column 5 (6th column) to 3
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self.ls[2][5] = 3
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# Dictionaries (any simple type to any other type including structs)
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theMap: map(uint256, bytes32)
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theMap[5] = sha3("charles")
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# theMap[255] result is 0, all non-set key values return zeroes
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# To make read public, make a getter that accesses the mapping
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@public
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def getMap(_idx: uint256) -> bytes32:
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"""
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@notice Get the value of `theMap` at `_idx`
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"""
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return self.theMap[_idx]
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self.getMap(5) # returns sha3("charles") in bytes32
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# Nested mappings
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aMap: map(address, map(address, uint256))
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# NOTE: Mappings are only allowed as state variables
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# NOTE: Mappings are not iterable; can only be accessed
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# To delete (reset the mapping's value to default at a key)
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clear(balances["John"])
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clear(balances); # sets all elements to 0
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# Unlike other languages, CANNOT iterate through all elements in
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# mapping, without knowing source keys - can build data structure
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# on top to do this
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# Structs
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struct Struct:
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owner: address
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_balance: uint256 # balance is a reserved keyword, is a member for addresses
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exampleStuct: Struct
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@public
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def foo() -> uint256:
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self.exampleStuct = Struct({owner: msg.sender, _balance: 5})
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self.exampleStuct._balance = 10
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self.exampleStuct._balance = 5 # set to new value
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clear(self.exampleStuct._balance)
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clear(self.exampleStuct)
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return self.exampleStuct._balance
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# Data locations: Memory vs. storage vs. calldata - all complex types (arrays,
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# structs) have a data location
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# 'memory' does not persist, 'storage' does
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# Default is 'storage' for local and state variables; 'memory' for func params
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# stack holds small local variables
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# for most types, can explicitly set which data location to use
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# ---
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# 3. SIMPLE OPERATORS
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# Comparisons, bit operators and arithmetic operators are provided
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# exponentiation: **
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# modulo: %
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# maximum: max(x, y)
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# AND: bitwise_and(x, y)
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# bitwise shift: shift(x, _shift)
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# where x,y are uint256
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# _shift is int128
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# 4. GLOBAL VARIABLES OF NOTE
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# ** self **
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self # address of contract
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# often used at end of contract life to transfer remaining balance to party:
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self.balance # balance of current contract
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self.someFunction() # calls func externally via call, not via internal jump
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# ** msg - Current message received by the contract **
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# Ethereum programmers take NOTE: this `msg` object is smaller than elsewhere
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msg.sender # address of sender
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msg.value # amount of ether provided to this contract in wei, the function should be marked `@payable`
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msg.gas # remaining gas
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# ** tx - This transaction **
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# Ethereum programmers take NOTE: this `tx` object is smaller than elsewhere
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tx.origin # address of sender of the transaction
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# ** block - Information about current block **
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block.timestamp # time at current block (uses Unix time)
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# Note that `block.timestamp` can be manipulated by miners, so be careful
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block.number # current block number
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block.difficulty # current block difficulty
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# ** storage - Persistent storage hash **
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storage['abc'] = 'def'; # maps 256 bit words to 256 bit words
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# ---
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# 5. FUNCTIONS AND MORE
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# A. FUNCTIONS
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# Simple function
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function increment(uint x) returns (uint) {
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x += 1;
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return x;
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}
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# Functions can return many arguments
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@public
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@constant
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def increment(x: uint256, y: uint256) -> (uint256, uint256):
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x += 1
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y += 1
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return (x, y)
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# Call previous functon
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@public
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@constant
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def willCall() -> (uint256, uint256):
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return self.increment(1,1)
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# One should never have to call a function / hold any logic outside
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# outside the scope of a function in Vyper
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# '@constant'
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# indicates that function does not/cannot change persistent vars
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# Constant function execute locally, not on blockchain
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y: uint256
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@public
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@constant
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def increment(x: uint256) -> uint256:
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x += 1
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y += 1 # this line would fail
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# y is a state variable => can't be changed in a constant function
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# 'Function Decorators'
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# Used like python decorators but are REQUIRED by Vyper
|
|
# @public - visible externally and internally (default for function)
|
|
# @private - only visible in the current contract
|
|
# @constant - doesn't change state
|
|
# @payable - receive ether/ETH
|
|
# @nonrentant(<unique_key>) - Function can only be called once, both externally
|
|
# and internally. Used to prevent reentrancy attacks
|
|
|
|
# Functions hare not hoisted
|
|
# Functions cannot be assigned to a variable
|
|
# Functions cannot be recursive
|
|
|
|
# All functions that receive ether must be marked 'payable'
|
|
@public
|
|
@payable
|
|
def depositEther():
|
|
self.balances[msg.sender] += msg.value
|
|
|
|
|
|
# B. EVENTS
|
|
# Events are notify external parties; easy to search and
|
|
# access events from outside blockchain (with lightweight clients)
|
|
# typically declare after contract parameters
|
|
|
|
# Declare
|
|
LogSent: event({_from: indexed(address), address: indexed(_to), _amount: uint256})
|
|
# Call
|
|
log.LogSent(from, to, amount)
|
|
|
|
/**
|
|
For an external party (a contract or external entity), to watch using
|
|
the Web3 Javascript library:
|
|
|
|
# The following is Javascript code, not Vyper code
|
|
Coin.LogSent().watch({}, '', function(error, result) {
|
|
if (!error) {
|
|
console.log("Coin transfer: " + result.args.amount +
|
|
" coins were sent from " + result.args.from +
|
|
" to " + result.args.to + ".");
|
|
console.log("Balances now:\n" +
|
|
"Sender: " + Coin.balances.call(result.args.from) +
|
|
"Receiver: " + Coin.balances.call(result.args.to));
|
|
}
|
|
}
|
|
**/
|
|
|
|
# Common paradigm for one contract to depend on another (e.g., a
|
|
# contract that depends on current exchange rate provided by another)
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 6. BRANCHING AND LOOPS
|
|
|
|
# All basic logic blocks from Python work - including if/elif/else, for,
|
|
# while, break, continue, return - but no switch
|
|
|
|
# Syntax same as Python, but no type conversion from non-boolean
|
|
# to boolean (comparison operators must be used to get the boolean val)
|
|
|
|
# REMEMBER: Vyper does not allow resursive calls or infinite loops
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 7. OBJECTS/CONTRACTS
|
|
# REMEMBER: Vyper does not allow for inheritance or imports
|
|
|
|
# A. CALLING EXTERNAL CONTRACTS
|
|
# You must define an interface to an external contract in the current contract
|
|
|
|
contract InfoFeed():
|
|
def getInfo() -> uint256: constant
|
|
|
|
info: uint256
|
|
|
|
@public
|
|
def __init__(_source: address):
|
|
self.info = InfoFeed(_source).getInfo()
|
|
|
|
|
|
# B. ERC20 BUILT-IN
|
|
# Using the `ERC20` keyword implies that the contract at the address
|
|
# follows the ERC20 token standard, allowing you to safely call
|
|
# functions like `transfer()`, etc.
|
|
|
|
tokenAddress: address(ERC20)
|
|
|
|
@public
|
|
def transferIt(_to: address, _amt: uint256(wei)):
|
|
self.tokenAddress.transfer(_to, _amt)
|
|
|
|
|
|
# C. FOLLOWING AN INTERFACE
|
|
# Vyper is experimenting with using the following syntax at the top of
|
|
# a `.vy` file to specify what interfaces are followed by the contract
|
|
# This allows interfaces to be better organized, registered, and recognized
|
|
|
|
import interfaces.some_interface as SomeInterface
|
|
implements: SomeInterface
|
|
# <rest of contract>
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 8. OTHER KEYWORDS
|
|
|
|
# A. selfdestruct()
|
|
# selfdestruct current contract, sending funds to address (often creator)
|
|
selfdestruct(SOME_ADDRESS);
|
|
|
|
# removes storage/code from current/future blocks
|
|
# helps thin clients, but previous data persists in blockchain
|
|
|
|
# Common pattern, lets owner end the contract and receive remaining funds
|
|
@public
|
|
def endItAll() {
|
|
assert msg.sender == self.creator # Only let the contract creator do this
|
|
selfdestruct(self.creator) # Makes contract inactive, returns funds
|
|
|
|
# May want to deactivate contract manually, rather than selfdestruct
|
|
# (ether sent to selfdestructed contract is lost)
|
|
|
|
|
|
# B. sha3()
|
|
# Encrypts strings and other data
|
|
# Very important on the blockchain
|
|
# Takes 1 argument, `concat()` can be called beforehand
|
|
# All strings passed are concatenated before hash action
|
|
sha3(concat("ab", "cd")) # returns bytes32
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 9. CONTRACT DESIGN NOTES
|
|
|
|
# A. Obfuscation
|
|
# All variables are publicly viewable on blockchain, so anything
|
|
# that is private needs to be obfuscated (e.g., hashed w/secret)
|
|
# Oftentimes, a "commit-reveal" scheme is employed
|
|
|
|
# Step 1. Commit
|
|
# Place a commitment by sending output of `sha3()`
|
|
sha3("a secret"); # btyes32 commit
|
|
sha3(concat("secret", "other secret", "salt")); # commit multiple things
|
|
# The `sha3()` calculation should occur off-chain, only the bytes32
|
|
# output should be inputted into some `commit()` function
|
|
commits: map(address, bytes32)
|
|
@public
|
|
def commit(commitment: bytes32):
|
|
self.commits[msg.sender] = commitment
|
|
|
|
# Step 2. Reveal
|
|
# Send your previously committed data so the contract can check
|
|
# if your commitment was honest
|
|
@public
|
|
def reveal(_secret: string[100], _salt: string[100]) -> bool:
|
|
return sha3(concat(_secret, _salt)) == self.commits[msg.sender]
|
|
|
|
|
|
# B. Storage optimization
|
|
# Writing to blockchain can be expensive, as data stored forever; encourages
|
|
# smart ways to use memory (eventually, compilation will be better, but for now
|
|
# benefits to planning data structures - and storing min amount in blockchain)
|
|
|
|
# Cost can often be high for items like multidimensional arrays
|
|
# (cost is for storing data - not declaring unfilled variables)
|
|
|
|
|
|
# C. Data access in blockchain
|
|
# Cannot restrict human or computer from reading contents of
|
|
# transaction or transaction's state
|
|
|
|
# While 'private' prevents other *contracts* from reading data
|
|
# directly - any other party can still read data in blockchain
|
|
|
|
# All data to start of time is stored in blockchain, so
|
|
# anyone can observe all previous data and changes
|
|
|
|
|
|
# D. Cron Job
|
|
# Contracts must be manually called to handle time-based scheduling;
|
|
# can create external code to regularly ping or provide incentives
|
|
# (ether) for others to ping
|
|
|
|
|
|
# E. Observer Pattern
|
|
# An Observer Pattern lets you register as a subscriber and
|
|
# register a function which is called by the oracle (note, the oracle
|
|
# pays for this action to be run)
|
|
# Some similarities to subscription in Pub/sub
|
|
|
|
# This is an abstract contract, both client and server classes import,
|
|
# the client should implement
|
|
|
|
### **** START EXAMPLE **** ###
|
|
|
|
contract SomeOracleCallback():
|
|
def oracleCallback(_value: uint256, _time: timestamp, _info: bytes32): modifying
|
|
|
|
MAX_SUBS: constant(uint256) = 100
|
|
numSubs: public(uint256) # number of subscribers
|
|
subs: map(uint256, address) # enumerates subscribers
|
|
|
|
@public
|
|
def addSub(_sub: address) -> uint256:
|
|
"""
|
|
@notice Add subscriber
|
|
@param _sub Address to add
|
|
@return Id of newly added subscriber
|
|
"""
|
|
self.subs[self.numSubs] = _sub
|
|
self.numSubs += 1
|
|
return self.numSubs - 1
|
|
|
|
@private
|
|
def notify(_value: uint256, _time: timestamp, _info: bytes32) -> bool:
|
|
"""
|
|
@notice Notify all subscribers
|
|
@dev Check `numSubs` first; Watch out for gas costs!
|
|
@param _value whatever
|
|
@param _time what have you
|
|
@param _info what else
|
|
@return True upon successful completion
|
|
"""
|
|
j: uint256
|
|
for i in range(MAX_SUBS):
|
|
j = convert(i, uint256) # `i` is int128 by default
|
|
if j == self.numSubs:
|
|
return True
|
|
SomeOracleCallback(self.subs[j]).oracleCallback(_value, _time, _info)
|
|
|
|
@public
|
|
def doSomething():
|
|
"""
|
|
@notice Do something and notify subscribers
|
|
"""
|
|
# ...something...
|
|
whatever: uint256 = 6
|
|
what_have_you: timestamp
|
|
what_else: bytes32 = sha3("6")
|
|
self.notify(whatever, what_have_you, what_else)
|
|
|
|
# Now, your client contract can addSubscriber by importing SomeOracleCallback
|
|
# and registering with Some Oracle
|
|
|
|
### **** END EXAMPLE **** ###
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 10. SECURITY
|
|
# Bugs can be disastrous in Ethereum contracts - and even popular patterns in
|
|
# Vyper may be found to be antipatterns
|
|
|
|
# See security links at the end of this doc
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 11. STYLE NOTES
|
|
# Based on Python's PEP8 style guide
|
|
# Full Style guide: http:#solidity.readthedocs.io/en/develop/style-guide.html
|
|
|
|
# Quick summary:
|
|
# 4 spaces for indentation
|
|
# Two lines separate contract declarations (and other top level declarations)
|
|
# Avoid extraneous spaces in parentheses
|
|
# Can omit curly braces for one line statement (if, for, etc)
|
|
# else should be placed on own line
|
|
|
|
# Specific to Vyper:
|
|
# arguments: snake_case
|
|
# events, interfaces, structs: PascalCase
|
|
# public functions: camelCase
|
|
# private functions: _prefaceWithUnderscore
|
|
|
|
|
|
# ---
|
|
|
|
|
|
# 12. NATSPEC COMMENTS
|
|
# used for documentation, commenting, and external UIs
|
|
|
|
# Contract natspec - always above contract definition
|
|
# @title Contract title
|
|
# @author Author name
|
|
|
|
# Function natspec
|
|
# Should include in docstring of functions in typical Pythonic fashion
|
|
# @notice Information about what function does; shown when function to execute
|
|
# @dev Function documentation for developer
|
|
|
|
# Function parameter/return value natspec
|
|
# @param someParam Some description of what the param does
|
|
# @return Description of the return value
|
|
|
|
```
|
|
|
|
## Additional resources
|
|
- [Installation](https://vyper.readthedocs.io/en/latest/installing-vyper.html)
|
|
- [Vyper Docs](https://media.readthedocs.org/pdf/vyper/latest/vyper.pdf)
|
|
- [Vyper GitHub (under active dev)](https://github.com/ethereum/vyper)
|
|
- [Tools and Resources](https://github.com/ethereum/vyper/wiki/Vyper-tools-and-resources)
|
|
- [Online Compiler](https://vyper.online/)
|
|
|
|
## Sample contracts
|
|
- [Uniswap](https://github.com/Uniswap/contracts-vyper)
|
|
- [Generalized Governance](https://github.com/kpeluso/gdg)
|
|
- [Dynamic Arrays](https://github.com/kpeluso/vyper-dynamic-array)
|
|
|
|
## Security
|
|
Vyper is secure by design, but it may be helpful to understand what Vyper is
|
|
protecting you from.
|
|
- [Thinking About Smart Contract Security](https:#blog.ethereum.org/2016/06/19/thinking-smart-contract-security/)
|
|
- [Smart Contract Security](https:#blog.ethereum.org/2016/06/10/smart-contract-security/)
|
|
- [Hacking Distributed Blog](http:#hackingdistributed.com/)
|
|
|
|
## Style
|
|
- [Vyper Style Guide WIP](https://github.com/ethereum/vyper/issues/905)
|
|
- Heavily derived from [Solidity's style guide](http:#solidity.readthedocs.io/en/latest/style-guide.html) ...
|
|
- ... which, in turn, is heavily derived from Python's [PEP 8](https:#www.python.org/dev/peps/pep-0008/) style guide.
|
|
|
|
## Editors
|
|
- [Vyper for VS Code (alpha)](https://github.com/p-/vscode-vyper)
|
|
|
|
## Future To Dos
|
|
- Update to current Vyper release
|
|
- List of common design patterns
|
|
|
|
*Feel free to send a pull request with any edits - or email* `pelusoken -/at-/ gmail`
|
|
|