mod.rs - mozsearch

Enable keyboard shortcuts

/* This Source Code Form is subject to the terms of the Mozilla Public

 * License, v. 2.0. If a copy of the MPL was not distributed with this

 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

//! # Swift bindings backend for UniFFI

//!

//! This module generates Swift bindings from a [`crate::ComponentInterface`] definition,

//! using Swift's builtin support for loading C header files.

//!

//! Conceptually, the generated bindings are split into two Swift modules, one for the low-level

//! C FFI layer and one for the higher-level Swift bindings. For a UniFFI component named "example"

//! we generate:

//!

//!   * A C header file `exampleFFI.h` declaring the low-level structs and functions for calling

//!    into Rust, along with a corresponding `exampleFFI.modulemap` to expose them to Swift.

//!

//!   * A Swift source file `example.swift` that imports the `exampleFFI` module and wraps it

//!    to provide the higher-level Swift API.

//!

//! Most of the concepts in a [`crate::ComponentInterface`] have an obvious counterpart in Swift,

//! with the details documented in inline comments where appropriate.

//!

//! To handle lifting/lowering/serializing types across the FFI boundary, the Swift code

//! defines a `protocol ViaFfi` that is analogous to the `uniffi::ViaFfi` Rust trait.

//! Each type that can traverse the FFI conforms to the `ViaFfi` protocol, which specifies:

//!

//!  * The corresponding low-level type.

//!  * How to lift from and lower into into that type.

//!  * How to read from and write into a byte buffer.

//!

use crate::{BindingGenerator, Component, GenerationSettings};

use anyhow::{Context, Result};

use camino::Utf8PathBuf;

use fs_err as fs;

use std::process::Command;

mod gen_swift;

use gen_swift::{generate_bindings, generate_header, generate_modulemap, generate_swift, Config};

#[cfg(feature = "bindgen-tests")]

pub mod test;

/// The Swift bindings generated from a [`crate::ComponentInterface`].

///

struct Bindings {

    /// The contents of the generated `.swift` file, as a string.

    library: String,

    /// The contents of the generated `.h` file, as a string.

    header: String,

    /// The contents of the generated `.modulemap` file, as a string.

    modulemap: Option<String>,

pub struct SwiftBindingGenerator;

impl BindingGenerator for SwiftBindingGenerator {

    type Config = Config;

    fn new_config(&self, root_toml: &toml::Value) -> Result<Self::Config> {

Ok(

            match root_toml.get("bindings").and_then(|b| b.get("swift")) {

                Some(v) => v.clone().try_into()?,

                None => Default::default(),

},

    fn update_component_configs(

        &self,

        _settings: &GenerationSettings,

        components: &mut Vec<Component<Self::Config>>,

    ) -> Result<()> {

        for c in &mut *components {

            c.config

                .module_name

                .get_or_insert_with(|| c.ci.namespace().into());

        Ok(())

    /// Unlike other target languages, binding to Rust code from Swift involves more than just

    /// generating a `.swift` file. We also need to produce a `.h` file with the C-level API

    /// declarations, and a `.modulemap` file to tell Swift how to use it.

    fn write_bindings(

        &self,

        settings: &GenerationSettings,

        components: &[Component<Self::Config>],

    ) -> Result<()> {

        for Component { ci, config, .. } in components {

            let Bindings {

                header,

                library,

                modulemap,

            } = generate_bindings(config, ci)?;

            let source_file = settings

                .out_dir

                .join(format!("{}.swift", config.module_name()));

            fs::write(&source_file, library)?;

            let header_file = settings.out_dir.join(config.header_filename());

            fs::write(header_file, header)?;

            if let Some(modulemap) = modulemap {

                let modulemap_file = settings.out_dir.join(config.modulemap_filename());

                fs::write(modulemap_file, modulemap)?;

            if settings.try_format_code {

                if let Err(e) = Command::new("swiftformat")

                    .arg(source_file.as_str())

                    .output()

                    println!(

                        "Warning: Unable to auto-format {} using swiftformat: {e:?}",

                        source_file.file_name().unwrap(),

);

        Ok(())

/// Generate Swift bindings

///

/// This is used by the uniffi-bindgen-swift command, which supports Swift-specific options.

///

/// In the future, we may want to replace the generalized `uniffi-bindgen` with a set of

/// specialized `uniffi-bindgen-[language]` commands.

pub fn generate_swift_bindings(options: SwiftBindingsOptions) -> Result<()> {

    #[cfg(feature = "cargo-metadata")]

    let config_supplier = {

        use crate::cargo_metadata::CrateConfigSupplier;

        let mut cmd = cargo_metadata::MetadataCommand::new();

        if options.metadata_no_deps {

            cmd.no_deps();

        let metadata = cmd.exec().context("error running cargo metadata")?;

        CrateConfigSupplier::from(metadata)

};

    #[cfg(not(feature = "cargo-metadata"))]

    let config_supplier = crate::EmptyCrateConfigSupplier;

    fs::create_dir_all(&options.out_dir)?;

    let mut components =

        crate::library_mode::find_components(&options.library_path, &config_supplier)?

            // map the TOML configs into a our Config struct

            .into_iter()

            .map(|Component { ci, config }| {

                let config = SwiftBindingGenerator.new_config(&config.into())?;

                Ok(Component { ci, config })

})

            .collect::<Result<Vec<_>>>()?;

    SwiftBindingGenerator

        .update_component_configs(&GenerationSettings::default(), &mut components)?;

    for Component { ci, config } in &components {

        if options.generate_swift_sources {

            let source_file = options

                .out_dir

                .join(format!("{}.swift", config.module_name()));

            fs::write(&source_file, generate_swift(config, ci)?)?;

        if options.generate_headers {

            let header_file = options.out_dir.join(config.header_filename());

            fs::write(header_file, generate_header(config, ci)?)?;

    // find the library name by stripping the extension and leading `lib` from the library path

    let library_name = {

        let stem = options

            .library_path

            .file_stem()

            .with_context(|| format!("Invalid library path {}", options.library_path))?;

        match stem.strip_prefix("lib") {

            Some(name) => name,

            None => stem,

};

    let module_name = options

        .module_name

        .unwrap_or_else(|| library_name.to_string());

    let modulemap_filename = options

        .modulemap_filename

        .unwrap_or_else(|| format!("{library_name}.modulemap"));

    if options.generate_modulemap {

        let mut header_filenames: Vec<_> = components

            .iter()

            .map(|Component { config, .. }| config.header_filename())

            .collect();

        header_filenames.sort();

        let modulemap_source =

            generate_modulemap(module_name, header_filenames, options.xcframework)?;

        let modulemap_path = options.out_dir.join(modulemap_filename);

        fs::write(modulemap_path, modulemap_source)?;

    Ok(())

#[derive(Debug)]

pub struct SwiftBindingsOptions {

    pub generate_swift_sources: bool,

    pub generate_headers: bool,

    pub generate_modulemap: bool,

    pub library_path: Utf8PathBuf,

    pub out_dir: Utf8PathBuf,

    pub xcframework: bool,

    pub module_name: Option<String>,

    pub modulemap_filename: Option<String>,

    pub metadata_no_deps: bool,