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new 0.8.13 | Nov 26, 2024 |
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0.7.7 | Jul 8, 2024 |
0.7.0 | Mar 30, 2024 |
0.3.1 | Jul 30, 2023 |
#625 in Magic Beans
382,829 downloads per month
Used in 207 crates
(59 directly)
730KB
15K
SLoC
alloy-sol-types
Solidity type modeling and ABI and EIP-712 codec implementation.
This crate provides tools for expressing Solidity types in Rust, and for encoding these representations into ABI blobs suitable for smart contract processing. In other words, you can represent your smart contract args in native Rust, easily encode them to pass to a smart contract, and easily decode the smart contract return values.
We do this by representing Solidity types in rust via the SolType
trait.
This trait maps Solidity types to Rust types via the associated
SolType::RustType
.
The ABI encoding and decoding is implemented in the [abi
] module, see its
documentation to learn how it works.
use alloy_sol_types::{sol_data::*, SolType, SolValue};
// Represent a Solidity type in rust
type MySolType = FixedArray<Bool, 2>;
let data = [true, false];
let validate = true;
// SolTypes expose their Solidity name :)
assert_eq!(&MySolType::sol_type_name(), "bool[2]");
// SolTypes are used to transform Rust into ABI blobs, and back.
let encoded: Vec<u8> = MySolType::abi_encode(&data);
let decoded: [bool; 2] = MySolType::abi_decode(&encoded, validate)?;
assert_eq!(data, decoded);
// This is more easily done with the `SolValue` trait:
let encoded: Vec<u8> = data.abi_encode();
let decoded: [bool; 2] = <[bool; 2]>::abi_decode(&encoded, validate)?;
assert_eq!(data, decoded);
# Ok::<_, alloy_sol_types::Error>(())
sol!
The sol!
procedural macro provides a convenient way to define
custom SolType
s and reference primitive ones. See
[its documentation][sol!] for details on how to use it.
SolStruct
The SolStruct
trait primarily provides EIP-712 signing support.
# use alloy_sol_types::{sol, SolStruct};
# use alloy_primitives::U256;
// `sol!` allows you to define struct types!
// You can just paste Solidity into the macro and it should work :)
sol! {
struct MyStruct {
uint256 a;
bytes32 b;
address[] c;
}
}
sol! {
struct MyStruct2 {
MyStruct a;
bytes32 b;
address[] c;
}
}
// All structs generated with `sol!` implement `crate::SolType` &
// `crate::SolStruct`. This means you get eip-712 signing for freeeeee
let my_struct = MyStruct {
a: U256::from(1),
b: [0; 32].into(),
c: vec![Default::default()],
};
// The `eip712_domain` macro lets you easily define an EIP-712 domain
// object :)
let my_domain = alloy_sol_types::eip712_domain!(
name: "MyDomain",
version: "1",
);
// Because all the hard work is done by the `sol!` macro, EIP-712 is as easy
// as calling `eip712_signing_hash` with your domain
let signing_hash = my_struct.eip712_signing_hash(&my_domain);
sol!
User-defined Value Types
Support for user-defined value types is new! These are currently implemented as wrapper types. Watch this space for more features!
# use alloy_sol_types::{sol, sol_data, SolType};
# use alloy_primitives::U256;
// We also also support Solidity value types
sol! {
type MyValueType is uint256;
}
// UDTs are encoded as their underlying type
let mvt = MyValueType::from(U256::from(1));
assert_eq!(mvt.abi_encode(), sol_data::Uint::<256>::abi_encode(&U256::from(1)));
Tokenization/Detokenization
The process of converting from a Rust type to a to an abi token is called
"Tokenization". Typical users will not access tokenizaiton directly.
Power users should use the [SolType::tokenize()
] and
[SolType::detokenize()
] methods.
When implementing your own SolType
, a variety of From
impls have been
provided on the token structs to aid in converting from Rust data to tokens.
Encoding/Decoding
The process of converting from a Token
to a serialized ABI blob is
called "Encoding". It is the reciprocal of decoding.
ABI encoding and decoding operates on sequences of tokens.
The SolType
encoding and decoding methods operate on Rust types. We
recommend users use them wherever possible. We do not recommend that users
interact with Tokens, except when implementing their own SolType
.
Licensing
This crate is an extensive rewrite of the
ethabi crate by the parity team.
That codebase is used under the terms of the MIT license. We have preserved
the original license notice in files incorporating ethabi
code.
Dependencies
~5–8MB
~158K SLoC