mirror of https://github.com/pezkuwichain/pezkuwi-subxt.git synced 2026-04-26 12:17:58 +00:00

Files

T

Oliver Tale-Yazdi 4a44356773 Improve features dev-ex (#1831 )

Adds a config file that allows to run `zepter` without any arguments in
the workspace to address all issues.
A secondary workflow for the CI is provided as `zepter run check`. Both
the formatting and linting are now in one check for efficiancy.

The latest version also detects some more things that `featalign` was
already showing.

Error message [in the
CI](https://gitlab.parity.io/parity/mirrors/polkadot-sdk/-/jobs/3916205)
now looks like this:
```pre
...
crate 'test-parachains' (/Users/vados/Documents/work/polkadot-sdk/polkadot/parachain/test-parachains/Cargo.toml)
  feature 'std'
    must propagate to:
      parity-scale-codec
Found 55 issues (run with --fix to fix).
Error: Command 'lint propagate-feature' failed with exit code 1

Polkadot-SDK uses the Zepter CLI to detect abnormalities in the feature configuration.
It looks like one more more checks failed; please check the console output. You can try to automatically address them by running `zepter`.
Otherwise please ask directly in the Merge Request, GitHub Discussions or on Matrix Chat, thank you.

For more information, see:
  - https://github.com/paritytech/polkadot-sdk/issues/1831
  - https://github.com/ggwpez/zepter
```

TODO:
- [x] Check that CI fails correctly

---------

Signed-off-by: Oliver Tale-Yazdi <oliver.tale-yazdi@parity.io>

2023-10-24 17:59:38 +02:00

proc-macro

Bump the known_good_semver group with 1 update (#1802 )

2023-10-06 18:07:01 +02:00

src

Support for cfg attributes in host functions definitions (#14189 )

2023-05-25 13:27:34 +02:00

test

Fix build profiles (#1229 )

2023-08-29 13:39:41 +02:00

test-wasm

Improve features dev-ex (#1831 )

2023-10-24 17:59:38 +02:00

test-wasm-deprecated

Fix build profiles (#1229 )

2023-08-29 13:39:41 +02:00

tests

ci: bump ci image to rust 1.73.0 (#1830 )

2023-10-11 19:49:59 +02:00

Cargo.toml

Fix build profiles (#1229 )

2023-08-29 13:39:41 +02:00

README.md

Markdown linter (#1309 )

2023-09-04 12:02:32 +03:00

README.md

Substrate runtime interface

This crate provides types, traits and macros around runtime interfaces. A runtime interface is a fixed interface between a Substrate runtime and a Substrate node. For a native runtime the interface maps to a direct function call of the implementation. For a wasm runtime the interface maps to an external function call. These external functions are exported by the wasm executor and they map to the same implementation as the native calls.

Using a type in a runtime interface

Any type that should be used in a runtime interface as argument or return value needs to implement [RIType]. The associated type FFIType is the type that is used in the FFI function to represent the actual type. For example [T] is represented by an u64. The slice pointer and the length will be mapped to an u64 value. For more information see this table. The FFI function definition is used when calling from the wasm runtime into the node.

Traits are used to convert from a type to the corresponding RIType::FFIType. Depending on where and how a type should be used in a function signature, a combination of the following traits need to be implemented:

Pass as function argument: [wasm::IntoFFIValue] and [host::FromFFIValue]
As function return value: [wasm::FromFFIValue] and [host::IntoFFIValue]
Pass as mutable function argument: [host::IntoPreallocatedFFIValue]

The traits are implemented for most of the common types like [T], Vec<T>, arrays and primitive types.

For custom types, we provide the PassBy trait and strategies that define how a type is passed between the wasm runtime and the node. Each strategy also provides a derive macro to simplify the implementation.

Performance

To not waste any more performance when calling into the node, not all types are SCALE encoded when being passed as arguments between the wasm runtime and the node. For most types that are raw bytes like Vec<u8>, [u8] or [u8; N] we pass them directly, without SCALE encoding them in front of. The implementation of [RIType] each type provides more information on how the data is passed.

Declaring a runtime interface

Declaring a runtime interface is similar to declaring a trait in Rust:

#[sp_runtime_interface::runtime_interface]
trait RuntimeInterface {
    fn some_function(value: &[u8]) -> bool {
        value.iter().all(|v| *v > 125)
    }
}

For more information on declaring a runtime interface, see #[runtime_interface].

FFI type and conversion

The following table documents how values of types are passed between the wasm and the host side and how they are converted into the corresponding type.

Type	FFI type	Conversion
`u8`	`u8`	`Identity`
`u16`	`u16`	`Identity`
`u32`	`u32`	`Identity`
`u64`	`u64`	`Identity`
`i128`	`u32`	`v.as_ptr()` (pointer to a 16 byte array)
`i8`	`i8`	`Identity`
`i16`	`i16`	`Identity`
`i32`	`i32`	`Identity`
`i64`	`i64`	`Identity`
`u128`	`u32`	`v.as_ptr()` (pointer to a 16 byte array)
`bool`	`u8`	`if v { 1 } else { 0 }`
`&str`	`u64`	`v.len() 32bit << 32 \| v.as_ptr() 32bit`
`&[u8]`	`u64`	`v.len() 32bit << 32 \| v.as_ptr() 32bit`
`Vec<u8>`	`u64`	`v.len() 32bit << 32 \| v.as_ptr() 32bit`
`Vec<T> where T: Encode`	`u64`	`let e = v.encode();` `e.len() 32bit << 32 \| e.as_ptr() 32bit`
`&[T] where T: Encode`	`u64`	`let e = v.encode();` `e.len() 32bit << 32 \| e.as_ptr() 32bit`
`[u8; N]`	`u32`	`v.as_ptr()`
`*const T`	`u32`	`Identity`
`Option<T>`	`u64`	`let e = v.encode();` `e.len() 32bit << 32 \| e.as_ptr() 32bit`
`T where T: PassBy<PassBy=Inner>`	Depends on inner	Depends on inner
`T where T: PassBy<PassBy=Codec>`	`u64`	`v.len() 32bit << 32 \| v.as_ptr() 32bit`

Identity means that the value is converted directly into the corresponding FFI type.

License: Apache-2.0