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sandbox-contract
Advanced tools
A better contract abstraction for Ethereum (formerly EtherPudding)
Better Ethereum contract abstraction, for Node and the browser.
$ npm install truffle-contract
ES6
and async/await
.from
address or gas
.First, set up a new web3 provider instance and initialize your contract, then require("truffle-contract")
. The input to the contract
function is a JSON blob defined by truffle-contract-schema. This JSON blob is structured in a way that can be passed to all truffle-related projects.
var provider = new Web3.providers.HttpProvider("http://localhost:8545");
var contract = require("truffle-contract");
var MyContract = contract({
abi: ...,
unlinked_binary: ...,
address: ..., // optional
// many more
})
MyContract.setProvider(provider);
You now have access to the following functions on MyContract
, as well as many others:
at()
: Create an instance of MyContract
that represents your contract at a specific address.deployed()
: Create an instance of MyContract
that represents the default address managed by MyContract
.new()
: Deploy a new version of this contract to the network, getting an instance of MyContract
that represents the newly deployed instance.Each instance is tied to a specific address on the Ethereum network, and each instance has a 1-to-1 mapping from Javascript functions to contract functions. For instance, if your Solidity contract had a function defined someFunction(uint value) {}
(solidity), then you could execute that function on the network like so:
var deployed;
MyContract.deployed().then(function(instance) {
deployed = instance;
return instance.someFunction(5);
}).then(function(result) {
// Do something with the result or continue with more transactions.
});
or equivalently in ES6 (node.js 8 or newer):
const deployed = await MyContract.deployed();
const result = await instance.someFunction(5);
In your head
element, include truffle-contract:
<script type="text/javascript" src="./dist/truffle-contract.min.js"></script>
Alternatively, you can use the non-minified versions for easier debugging.
With this usage, truffle-contract
will be available via the TruffleContract
object:
var MyContract = TruffleContract(...);
Note: Web3 and its dependencies are now bundled into truffle-contract v4.0.2 or higher.
Let's use truffle-contract
with an example contract from Dapps For Beginners. In this case, the abstraction has been saved to a .sol
file by truffle-artifactor:
// Require the package that was previosly saved by truffle-artifactor
var MetaCoin = require("./path/to/MetaCoin.sol");
// Remember to set the Web3 provider (see above).
MetaCoin.setProvider(provider);
// In this scenario, two users will send MetaCoin back and forth, showing
// how truffle-contract allows for easy control flow.
var account_one = "5b42bd01ff...";
var account_two = "e1fd0d4a52...";
// Note our MetaCoin contract exists at a specific address.
var contract_address = "8e2e2cf785...";
var coin;
MetaCoin.at(contract_address).then(function(instance) {
coin = instance;
// Make a transaction that calls the function `sendCoin`, sending 3 MetaCoin
// to the account listed as account_two.
return coin.sendCoin(account_two, 3, {from: account_one});
}).then(function(result) {
// This code block will not be executed until truffle-contract has verified
// the transaction has been processed and it is included in a mined block.
// truffle-contract will error if the transaction hasn't been processed in 120 seconds.
// Since we're using promises, we can return a promise for a call that will
// check account two's balance.
return coin.balances.call(account_two);
}).then(function(balance_of_account_two) {
alert("Balance of account two is " + balance_of_account_two + "!"); // => 3
// But maybe too much was sent. Let's send some back.
// Like before, will create a transaction that returns a promise, where
// the callback won't be executed until the transaction has been processed.
return coin.sendCoin(account_one, 1.5, {from: account_two});
}).then(function(result) {
// Again, get the balance of account two
return coin.balances.call(account_two)
}).then(function(balance_of_account_two) {
alert("Balance of account two is " + balance_of_account_two + "!") // => 1.5
}).catch(function(err) {
// Easily catch all errors along the whole execution.
alert("ERROR! " + err.message);
});
There are two API's you'll need to be aware of. One is the static Contract Abstraction API and the other is the Contract Instance API. The Abstraction API is a set of functions that exist for all contract abstractions, and those functions exist on the abstraction itself (i.e., MyContract.at()
). In contrast, the Instance API is the API available to contract instances -- i.e., abstractions that represent a specific contract on the network -- and that API is created dynamically based on functions available in your Solidity source file.
Each contract abstraction -- MyContract
in the examples above -- have the following useful functions:
MyContract.new([arg1, arg2, ...], [tx params])
This function take whatever contructor parameters your contract requires and deploys a new instance of the contract to the network. There's an optional last argument which you can use to pass transaction parameters including the transaction from address, gas limit and gas price. This function returns a Promise that resolves into a new instance of the contract abstraction at the newly deployed address.
MyContract.at(address)
This function creates a new instance of the contract abstraction representing the contract at the passed in address. Returns a "thenable" object (not yet an actual Promise for backward compatibility). Resolves to a contract abstraction instance after ensuring code exists at the specified address.
MyContract.deployed()
Creates an instance of the contract abstraction representing the contract at its deployed address. The deployed address is a special value given to truffle-contract that, when set, saves the address internally so that the deployed address can be inferred from the given Ethereum network being used. This allows you to write code referring to a specific deployed contract without having to manage those addresses yourself. Like at()
, deployed()
is thenable, and will resolve to a contract abstraction instance representing the deployed contract after ensuring that code exists at that location and that that address exists on the network being used.
MyContract.link(instance)
Link a library represented by a contract abstraction instance to MyContract. The library must first be deployed and have its deployed address set. The name and deployed address will be inferred from the contract abstraction instance. When this form of MyContract.link()
is used, MyContract will consume all of the linked library's events and will be able to report that those events occurred during the result of a transaction.
Libraries can be linked multiple times and will overwrite their previous linkage.
Note: This method has two other forms, but this form is recommended.
MyContract.link(name, address)
Link a library with a specific name and address to MyContract. The library's events will not be consumed using this form.
MyContract.link(object)
Link multiple libraries denoted by an Object to MyContract. The keys must be strings representing the library names and the values must be strings representing the addresses. Like above, libraries' events will not be consumed using this form.
MyContract.networks()
View a list of network ids this contract abstraction has been set up to represent.
MyContract.setProvider(provider)
Sets the web3 provider this contract abstraction will use to make transactions.
MyContract.setNetwork(network_id)
Sets the network that MyContract is currently representing.
MyContract.hasNetwork(network_id)
Returns a boolean denoting whether or not this contract abstraction is set up to represent a specific network.
MyContract.defaults([new_defaults])
Get's and optionally sets transaction defaults for all instances created from this abstraction. If called without any parameters it will simply return an Object representing current defaults. If an Object is passed, this will set new defaults. Example default transaction values that can be set are:
MyContract.defaults({
from: ...,
gas: ...,
gasPrice: ...,
value: ...
})
Setting a default from
address, for instance, is useful when you have a contract abstraction you intend to represent one user (i.e., one address).
MyContract.clone(network_id)
Clone a contract abstraction to get another object that manages the same contract artifacts, but using a different network_id
. This is useful if you'd like to manage the same contract but on a different network. When using this function, don't forget to set the correct provider afterward.
var MyOtherContract = MyContract.clone(1337);
MyContract.numberFormat = number_type
You can set this property to choose the number format that abstraction methods return. The default behavior is to return BN.
// Choices are: `["BigNumber", "BN", "String"].
var Example = artifacts.require('Example');
Example.numberFormat = 'BigNumber';
MyContract.timeout(block_timeout)
This method allows you to set the block timeout for transactions. Contract instances created from this abstraction will have the specified transaction block timeout. This means that if a transaction does not immediately get mined, it will retry for the specified number of blocks.
MyContract.autoGas = <boolean>
If this is set to true, instances created from this abstraction will use web3.eth.estimateGas
and then apply a gas multiplier to determine the amount of gas to include with the transaction. The default value for this is true
. See gasMultiplier.
MyContract.gasMultiplier(gas_multiplier)
This is the value used when autoGas
is enabled to determine the amount of gas to include with transactions. The gas is computed by using web3.eth.estimateGas
and multiplying it by the gas multiplier. The default value is 1.25
.
Each contract instance is different based on the source Solidity contract, and the API is created dynamically. For the purposes of this documentation, let's use the following Solidity source code below:
contract MyContract {
uint public value;
event ValueSet(uint val);
function setValue(uint val) {
value = val;
emit ValueSet(value);
}
function getValue() view returns (uint) {
return value;
}
}
From Javascript's point of view, this contract has three functions: setValue
, getValue
and value
. This is because value
is public and automatically creates a getter function for it.
When we call setValue()
, this creates a transaction. From Javascript:
instance.setValue(5).then(function(result) {
// result object contains import information about the transaction
console.log("Value was set to", result.logs[0].args.val);
});
The result object that gets returned looks like this:
{
tx: "0x6cb0bbb6466b342ed7bc4a9816f1da8b92db1ccf197c3f91914fc2c721072ebd",
receipt: {
// The return value from web3.eth.getTransactionReceipt(hash)
// See https://github.com/ethereum/wiki/wiki/JavaScript-API#web3ethgettransactionreceipt
},
logs: [
{
address: "0x13274fe19c0178208bcbee397af8167a7be27f6f",
args: {
val: BigNumber(5),
},
blockHash: "0x2f0700b5d039c6ea7cdcca4309a175f97826322beb49aca891bf6ea82ce019e6",
blockNumber: 40,
event: "ValueSet",
logIndex: 0,
transactionHash: "0x6cb0bbb6466b342ed7bc4a9816f1da8b92db1ccf197c3f91914fc2c721072ebd",
transactionIndex: 0,
type:"mined",
},
],
}
Note that if the function being executed in the transaction has a return value, you will not get that
return value inside this result. You must instead use an event (like ValueSet
) and look up the result
in the logs
array.
We can call setValue()
without creating a transaction by explicitly using .call
:
instance.setValue.call(5).then(...);
This isn't very useful in this case, since setValue()
sets things, and the value we pass won't be saved since we're not creating a transaction.
However, we can get the value using getValue()
, using .call()
. Calls are always free and don't cost any Ether, so they're good for calling functions that read data off the blockchain:
instance.getValue.call().then(function(val) {
// val reprsents the `value` storage object in the solidity contract
// since the contract returns that value.
});
Even more helpful, however is we don't even need to use .call
when a function is marked as view
or pure
, because truffle-contract
will automatically know that that function can only be interacted with via a call:
instance.getValue().then(function(val) {
// val reprsents the `value` storage object in the solidity contract
// since the contract returns that value.
});
When you make a transaction, you're given a result
object that gives you a wealth of information about the transaction. You're given the transaction has (result.tx
), the decoded events (also known as logs; result.logs
), and a transaction receipt (result.receipt
). In the below example, you'll recieve the ValueSet()
event because you triggered the event using the setValue()
function:
instance.setValue(5).then(function(result) {
// result.tx => transaction hash, string
// result.logs => array of trigger events (1 item in this case)
// result.receipt => receipt object
});
You can trigger the fallback function by sending a transaction to this function:
instance.sendTransaction({...}).then(function(result) {
// Same result object as above.
});
This is promisified like all available contract instance functions, and has the same API as web3.eth.sendTransaction
without the callback. The to
value will be automatically filled in for you.
If you only want to send Ether to the contract a shorthand is available:
instance.send(web3.toWei(1, "ether")).then(function(result) {
// Same result object as above.
});
Run this function to estimate the gas usage:
instance.setValue.estimateGas(5).then(function(result) {
// result => estimated gas for this transaction
});
This package is the result of breaking up EtherPudding into multiple modules. Tests currently reside within truffle-artifactor but will soon move here.
FAQs
A better contract abstraction for Ethereum (formerly EtherPudding)
The npm package sandbox-contract receives a total of 1 weekly downloads. As such, sandbox-contract popularity was classified as not popular.
We found that sandbox-contract demonstrated a not healthy version release cadence and project activity because the last version was released a year ago. It has 1 open source maintainer collaborating on the project.
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