//! Generate Rust bindings for C and C++ libraries. //! //! Provide a C/C++ header file, receive Rust FFI code to call into C/C++ //! functions and use types defined in the header. //! //! See the [`Builder`](./struct.Builder.html) struct for usage. //! //! See the [Users Guide](https://rust-lang.github.io/rust-bindgen/) for //! additional documentation. #![deny(missing_docs)] #![deny(unused_extern_crates)] // To avoid rather annoying warnings when matching with CXCursor_xxx as a // constant. #![allow(non_upper_case_globals)] // `quote!` nests quite deeply. #![recursion_limit = "128"] #[macro_use] extern crate bitflags; #[macro_use] extern crate lazy_static; #[macro_use] extern crate quote; #[cfg(feature = "logging")] #[macro_use] extern crate log; #[cfg(not(feature = "logging"))] #[macro_use] mod log_stubs; #[macro_use] mod extra_assertions; // A macro to declare an internal module for which we *must* provide // documentation for. If we are building with the "testing_only_docs" feature, // then the module is declared public, and our `#![deny(missing_docs)]` pragma // applies to it. This feature is used in CI, so we won't let anything slip by // undocumented. Normal builds, however, will leave the module private, so that // we don't expose internals to library consumers. macro_rules! doc_mod { ($m:ident, $doc_mod_name:ident) => { #[cfg(feature = "testing_only_docs")] pub mod $doc_mod_name { //! Autogenerated documentation module. pub use super::$m::*; } }; } mod clang; mod codegen; mod features; mod ir; mod parse; mod regex_set; mod time; pub mod callbacks; doc_mod!(clang, clang_docs); doc_mod!(features, features_docs); doc_mod!(ir, ir_docs); doc_mod!(parse, parse_docs); doc_mod!(regex_set, regex_set_docs); pub use crate::codegen::{AliasVariation, EnumVariation, MacroTypeVariation}; use crate::features::RustFeatures; pub use crate::features::{ RustTarget, LATEST_STABLE_RUST, RUST_TARGET_STRINGS, }; use crate::ir::context::{BindgenContext, ItemId}; use crate::ir::item::Item; use crate::parse::{ClangItemParser, ParseError}; use crate::regex_set::RegexSet; use std::borrow::Cow; use std::fs::{File, OpenOptions}; use std::io::{self, Write}; use std::path::{Path, PathBuf}; use std::process::{Command, Stdio}; use std::{env, iter}; // Some convenient typedefs for a fast hash map and hash set. type HashMap = ::rustc_hash::FxHashMap; type HashSet = ::rustc_hash::FxHashSet; pub(crate) use std::collections::hash_map::Entry; /// Default prefix for the anon fields. pub const DEFAULT_ANON_FIELDS_PREFIX: &'static str = "__bindgen_anon_"; fn file_is_cpp(name_file: &str) -> bool { name_file.ends_with(".hpp") || name_file.ends_with(".hxx") || name_file.ends_with(".hh") || name_file.ends_with(".h++") } fn args_are_cpp(clang_args: &[String]) -> bool { for w in clang_args.windows(2) { if w[0] == "-xc++" || w[1] == "-xc++" { return true; } if w[0] == "-x" && w[1] == "c++" { return true; } if w[0] == "-include" && file_is_cpp(&w[1]) { return true; } } false } bitflags! { /// A type used to indicate which kind of items we have to generate. pub struct CodegenConfig: u32 { /// Whether to generate functions. const FUNCTIONS = 1 << 0; /// Whether to generate types. const TYPES = 1 << 1; /// Whether to generate constants. const VARS = 1 << 2; /// Whether to generate methods. const METHODS = 1 << 3; /// Whether to generate constructors const CONSTRUCTORS = 1 << 4; /// Whether to generate destructors. const DESTRUCTORS = 1 << 5; } } impl CodegenConfig { /// Returns true if functions should be generated. pub fn functions(self) -> bool { self.contains(CodegenConfig::FUNCTIONS) } /// Returns true if types should be generated. pub fn types(self) -> bool { self.contains(CodegenConfig::TYPES) } /// Returns true if constants should be generated. pub fn vars(self) -> bool { self.contains(CodegenConfig::VARS) } /// Returns true if methds should be generated. pub fn methods(self) -> bool { self.contains(CodegenConfig::METHODS) } /// Returns true if constructors should be generated. pub fn constructors(self) -> bool { self.contains(CodegenConfig::CONSTRUCTORS) } /// Returns true if destructors should be generated. pub fn destructors(self) -> bool { self.contains(CodegenConfig::DESTRUCTORS) } } impl Default for CodegenConfig { fn default() -> Self { CodegenConfig::all() } } /// Configure and generate Rust bindings for a C/C++ header. /// /// This is the main entry point to the library. /// /// ```ignore /// use bindgen::builder; /// /// // Configure and generate bindings. /// let bindings = builder().header("path/to/input/header") /// .allowlist_type("SomeCoolClass") /// .allowlist_function("do_some_cool_thing") /// .generate()?; /// /// // Write the generated bindings to an output file. /// bindings.write_to_file("path/to/output.rs")?; /// ``` /// /// # Enums /// /// Bindgen can map C/C++ enums into Rust in different ways. The way bindgen maps enums depends on /// the pattern passed to several methods: /// /// 1. [`constified_enum_module()`](#method.constified_enum_module) /// 2. [`bitfield_enum()`](#method.bitfield_enum) /// 3. [`newtype_enum()`](#method.newtype_enum) /// 4. [`rustified_enum()`](#method.rustified_enum) /// /// For each C enum, bindgen tries to match the pattern in the following order: /// /// 1. Constified enum module /// 2. Bitfield enum /// 3. Newtype enum /// 4. Rustified enum /// /// If none of the above patterns match, then bindgen will generate a set of Rust constants. /// /// # Clang arguments /// /// Extra arguments can be passed to with clang: /// 1. [`clang_arg()`](#method.clang_arg): takes a single argument /// 2. [`clang_args()`](#method.clang_args): takes an iterator of arguments /// 3. `BINDGEN_EXTRA_CLANG_ARGS` environment variable: whitespace separate /// environment variable of arguments /// /// Clang arguments specific to your crate should be added via the /// `clang_arg()`/`clang_args()` methods. /// /// End-users of the crate may need to set the `BINDGEN_EXTRA_CLANG_ARGS` environment variable to /// add additional arguments. For example, to build against a different sysroot a user could set /// `BINDGEN_EXTRA_CLANG_ARGS` to `--sysroot=/path/to/sysroot`. #[derive(Debug, Default)] pub struct Builder { options: BindgenOptions, input_headers: Vec, // Tuples of unsaved file contents of the form (name, contents). input_header_contents: Vec<(String, String)>, } /// Construct a new [`Builder`](./struct.Builder.html). pub fn builder() -> Builder { Default::default() } impl Builder { /// Generates the command line flags use for creating `Builder`. pub fn command_line_flags(&self) -> Vec { let mut output_vector: Vec = Vec::new(); if let Some(header) = self.input_headers.last().cloned() { // Positional argument 'header' output_vector.push(header); } output_vector.push("--rust-target".into()); output_vector.push(self.options.rust_target.into()); // FIXME(emilio): This is a bit hacky, maybe we should stop re-using the // RustFeatures to store the "disable_untagged_union" call, and make it // a different flag that we check elsewhere / in generate(). if !self.options.rust_features.untagged_union && RustFeatures::from(self.options.rust_target).untagged_union { output_vector.push("--disable-untagged-union".into()); } if self.options.default_enum_style != Default::default() { output_vector.push("--default-enum-style".into()); output_vector.push( match self.options.default_enum_style { codegen::EnumVariation::Rust { non_exhaustive: false, } => "rust", codegen::EnumVariation::Rust { non_exhaustive: true, } => "rust_non_exhaustive", codegen::EnumVariation::NewType { is_bitfield: true } => { "bitfield" } codegen::EnumVariation::NewType { is_bitfield: false } => { "newtype" } codegen::EnumVariation::Consts => "consts", codegen::EnumVariation::ModuleConsts => "moduleconsts", } .into(), ) } if self.options.default_macro_constant_type != Default::default() { output_vector.push("--default-macro-constant-type".into()); output_vector .push(self.options.default_macro_constant_type.as_str().into()); } if self.options.default_alias_style != Default::default() { output_vector.push("--default-alias-style".into()); output_vector .push(self.options.default_alias_style.as_str().into()); } let regex_sets = &[ (&self.options.bitfield_enums, "--bitfield-enum"), (&self.options.newtype_enums, "--newtype-enum"), (&self.options.rustified_enums, "--rustified-enum"), ( &self.options.rustified_non_exhaustive_enums, "--rustified-enum-non-exhaustive", ), ( &self.options.constified_enum_modules, "--constified-enum-module", ), (&self.options.constified_enums, "--constified-enum"), (&self.options.type_alias, "--type-alias"), (&self.options.new_type_alias, "--new-type-alias"), (&self.options.new_type_alias_deref, "--new-type-alias-deref"), (&self.options.blocklisted_types, "--blocklist-type"), (&self.options.blocklisted_functions, "--blocklist-function"), (&self.options.blocklisted_items, "--blocklist-item"), (&self.options.opaque_types, "--opaque-type"), (&self.options.allowlisted_functions, "--allowlist-function"), (&self.options.allowlisted_types, "--allowlist-type"), (&self.options.allowlisted_vars, "--allowlist-var"), (&self.options.no_partialeq_types, "--no-partialeq"), (&self.options.no_copy_types, "--no-copy"), (&self.options.no_debug_types, "--no-debug"), (&self.options.no_default_types, "--no-default"), (&self.options.no_hash_types, "--no-hash"), ]; for (set, flag) in regex_sets { for item in set.get_items() { output_vector.push((*flag).to_owned()); output_vector.push(item.to_owned()); } } if !self.options.layout_tests { output_vector.push("--no-layout-tests".into()); } if self.options.impl_debug { output_vector.push("--impl-debug".into()); } if self.options.impl_partialeq { output_vector.push("--impl-partialeq".into()); } if !self.options.derive_copy { output_vector.push("--no-derive-copy".into()); } if !self.options.derive_debug { output_vector.push("--no-derive-debug".into()); } if !self.options.derive_default { output_vector.push("--no-derive-default".into()); } else { output_vector.push("--with-derive-default".into()); } if self.options.derive_hash { output_vector.push("--with-derive-hash".into()); } if self.options.derive_partialord { output_vector.push("--with-derive-partialord".into()); } if self.options.derive_ord { output_vector.push("--with-derive-ord".into()); } if self.options.derive_partialeq { output_vector.push("--with-derive-partialeq".into()); } if self.options.derive_eq { output_vector.push("--with-derive-eq".into()); } if self.options.time_phases { output_vector.push("--time-phases".into()); } if !self.options.generate_comments { output_vector.push("--no-doc-comments".into()); } if !self.options.allowlist_recursively { output_vector.push("--no-recursive-allowlist".into()); } if self.options.objc_extern_crate { output_vector.push("--objc-extern-crate".into()); } if self.options.generate_block { output_vector.push("--generate-block".into()); } if self.options.block_extern_crate { output_vector.push("--block-extern-crate".into()); } if self.options.builtins { output_vector.push("--builtins".into()); } if let Some(ref prefix) = self.options.ctypes_prefix { output_vector.push("--ctypes-prefix".into()); output_vector.push(prefix.clone()); } if self.options.anon_fields_prefix != DEFAULT_ANON_FIELDS_PREFIX { output_vector.push("--anon-fields-prefix".into()); output_vector.push(self.options.anon_fields_prefix.clone()); } if self.options.emit_ast { output_vector.push("--emit-clang-ast".into()); } if self.options.emit_ir { output_vector.push("--emit-ir".into()); } if let Some(ref graph) = self.options.emit_ir_graphviz { output_vector.push("--emit-ir-graphviz".into()); output_vector.push(graph.clone()) } if self.options.enable_cxx_namespaces { output_vector.push("--enable-cxx-namespaces".into()); } if self.options.enable_function_attribute_detection { output_vector.push("--enable-function-attribute-detection".into()); } if self.options.disable_name_namespacing { output_vector.push("--disable-name-namespacing".into()); } if self.options.disable_nested_struct_naming { output_vector.push("--disable-nested-struct-naming".into()); } if self.options.disable_header_comment { output_vector.push("--disable-header-comment".into()); } if !self.options.codegen_config.functions() { output_vector.push("--ignore-functions".into()); } output_vector.push("--generate".into()); //Temporary placeholder for below 4 options let mut options: Vec = Vec::new(); if self.options.codegen_config.functions() { options.push("functions".into()); } if self.options.codegen_config.types() { options.push("types".into()); } if self.options.codegen_config.vars() { options.push("vars".into()); } if self.options.codegen_config.methods() { options.push("methods".into()); } if self.options.codegen_config.constructors() { options.push("constructors".into()); } if self.options.codegen_config.destructors() { options.push("destructors".into()); } output_vector.push(options.join(",")); if !self.options.codegen_config.methods() { output_vector.push("--ignore-methods".into()); } if !self.options.convert_floats { output_vector.push("--no-convert-floats".into()); } if !self.options.prepend_enum_name { output_vector.push("--no-prepend-enum-name".into()); } if self.options.fit_macro_constants { output_vector.push("--fit-macro-constant-types".into()); } if self.options.array_pointers_in_arguments { output_vector.push("--use-array-pointers-in-arguments".into()); } if let Some(ref wasm_import_module_name) = self.options.wasm_import_module_name { output_vector.push("--wasm-import-module-name".into()); output_vector.push(wasm_import_module_name.clone()); } for line in &self.options.raw_lines { output_vector.push("--raw-line".into()); output_vector.push(line.clone()); } for (module, lines) in &self.options.module_lines { for line in lines.iter() { output_vector.push("--module-raw-line".into()); output_vector.push(module.clone()); output_vector.push(line.clone()); } } if self.options.use_core { output_vector.push("--use-core".into()); } if self.options.conservative_inline_namespaces { output_vector.push("--conservative-inline-namespaces".into()); } if self.options.generate_inline_functions { output_vector.push("--generate-inline-functions".into()); } if !self.options.record_matches { output_vector.push("--no-record-matches".into()); } if self.options.size_t_is_usize { output_vector.push("--size_t-is-usize".into()); } if !self.options.rustfmt_bindings { output_vector.push("--no-rustfmt-bindings".into()); } if let Some(path) = self .options .rustfmt_configuration_file .as_ref() .and_then(|f| f.to_str()) { output_vector.push("--rustfmt-configuration-file".into()); output_vector.push(path.into()); } if let Some(ref name) = self.options.dynamic_library_name { output_vector.push("--dynamic-loading".into()); output_vector.push(name.clone()); } if self.options.dynamic_link_require_all { output_vector.push("--dynamic-link-require-all".into()); } if self.options.respect_cxx_access_specs { output_vector.push("--respect-cxx-access-specs".into()); } if self.options.translate_enum_integer_types { output_vector.push("--translate-enum-integer-types".into()); } // Add clang arguments output_vector.push("--".into()); if !self.options.clang_args.is_empty() { output_vector.extend(self.options.clang_args.iter().cloned()); } if self.input_headers.len() > 1 { // To pass more than one header, we need to pass all but the last // header via the `-include` clang arg for header in &self.input_headers[..self.input_headers.len() - 1] { output_vector.push("-include".to_string()); output_vector.push(header.clone()); } } output_vector } /// Add an input C/C++ header to generate bindings for. /// /// This can be used to generate bindings to a single header: /// /// ```ignore /// let bindings = bindgen::Builder::default() /// .header("input.h") /// .generate() /// .unwrap(); /// ``` /// /// Or you can invoke it multiple times to generate bindings to multiple /// headers: /// /// ```ignore /// let bindings = bindgen::Builder::default() /// .header("first.h") /// .header("second.h") /// .header("third.h") /// .generate() /// .unwrap(); /// ``` pub fn header>(mut self, header: T) -> Builder { self.input_headers.push(header.into()); self } /// Add `contents` as an input C/C++ header named `name`. /// /// The file `name` will be added to the clang arguments. pub fn header_contents(mut self, name: &str, contents: &str) -> Builder { // Apparently clang relies on having virtual FS correspondent to // the real one, so we need absolute paths here let absolute_path = env::current_dir() .expect("Cannot retrieve current directory") .join(name) .to_str() .expect("Cannot convert current directory name to string") .to_owned(); self.input_header_contents .push((absolute_path, contents.into())); self } /// Specify the rust target /// /// The default is the latest stable Rust version pub fn rust_target(mut self, rust_target: RustTarget) -> Self { self.options.set_rust_target(rust_target); self } /// Disable support for native Rust unions, if supported. pub fn disable_untagged_union(mut self) -> Self { self.options.rust_features.untagged_union = false; self } /// Disable insertion of bindgen's version identifier into generated /// bindings. pub fn disable_header_comment(mut self) -> Self { self.options.disable_header_comment = true; self } /// Set the output graphviz file. pub fn emit_ir_graphviz>(mut self, path: T) -> Builder { let path = path.into(); self.options.emit_ir_graphviz = Some(path); self } /// Whether the generated bindings should contain documentation comments /// (docstrings) or not. This is set to true by default. /// /// Note that clang by default excludes comments from system headers, pass /// `-fretain-comments-from-system-headers` as /// [`clang_arg`][Builder::clang_arg] to include them. It can also be told /// to process all comments (not just documentation ones) using the /// `-fparse-all-comments` flag. See [slides on clang comment parsing]( /// https://llvm.org/devmtg/2012-11/Gribenko_CommentParsing.pdf) for /// background and examples. pub fn generate_comments(mut self, doit: bool) -> Self { self.options.generate_comments = doit; self } /// Whether to allowlist recursively or not. Defaults to true. /// /// Given that we have explicitly allowlisted the "initiate_dance_party" /// function in this C header: /// /// ```c /// typedef struct MoonBoots { /// int bouncy_level; /// } MoonBoots; /// /// void initiate_dance_party(MoonBoots* boots); /// ``` /// /// We would normally generate bindings to both the `initiate_dance_party` /// function and the `MoonBoots` struct that it transitively references. By /// configuring with `allowlist_recursively(false)`, `bindgen` will not emit /// bindings for anything except the explicitly allowlisted items, and there /// would be no emitted struct definition for `MoonBoots`. However, the /// `initiate_dance_party` function would still reference `MoonBoots`! /// /// **Disabling this feature will almost certainly cause `bindgen` to emit /// bindings that will not compile!** If you disable this feature, then it /// is *your* responsibility to provide definitions for every type that is /// referenced from an explicitly allowlisted item. One way to provide the /// definitions is by using the [`Builder::raw_line`](#method.raw_line) /// method, another would be to define them in Rust and then `include!(...)` /// the bindings immediately afterwards. pub fn allowlist_recursively(mut self, doit: bool) -> Self { self.options.allowlist_recursively = doit; self } /// Deprecated alias for allowlist_recursively. #[deprecated(note = "Use allowlist_recursively instead")] pub fn whitelist_recursively(self, doit: bool) -> Self { self.allowlist_recursively(doit) } /// Generate `#[macro_use] extern crate objc;` instead of `use objc;` /// in the prologue of the files generated from objective-c files pub fn objc_extern_crate(mut self, doit: bool) -> Self { self.options.objc_extern_crate = doit; self } /// Generate proper block signatures instead of void pointers. pub fn generate_block(mut self, doit: bool) -> Self { self.options.generate_block = doit; self } /// Generate `#[macro_use] extern crate block;` instead of `use block;` /// in the prologue of the files generated from apple block files pub fn block_extern_crate(mut self, doit: bool) -> Self { self.options.block_extern_crate = doit; self } /// Whether to use the clang-provided name mangling. This is true by default /// and probably needed for C++ features. /// /// However, some old libclang versions seem to return incorrect results in /// some cases for non-mangled functions, see [1], so we allow disabling it. /// /// [1]: https://github.com/rust-lang/rust-bindgen/issues/528 pub fn trust_clang_mangling(mut self, doit: bool) -> Self { self.options.enable_mangling = doit; self } /// Hide the given type from the generated bindings. Regular expressions are /// supported. #[deprecated(note = "Use blocklist_type instead")] pub fn hide_type>(self, arg: T) -> Builder { self.blocklist_type(arg) } /// Hide the given type from the generated bindings. Regular expressions are /// supported. #[deprecated(note = "Use blocklist_type instead")] pub fn blacklist_type>(self, arg: T) -> Builder { self.blocklist_type(arg) } /// Hide the given type from the generated bindings. Regular expressions are /// supported. /// /// To blocklist types prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn blocklist_type>(mut self, arg: T) -> Builder { self.options.blocklisted_types.insert(arg); self } /// Hide the given function from the generated bindings. Regular expressions /// are supported. #[deprecated(note = "Use blocklist_function instead")] pub fn blacklist_function>(self, arg: T) -> Builder { self.blocklist_function(arg) } /// Hide the given function from the generated bindings. Regular expressions /// are supported. /// /// To blocklist functions prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn blocklist_function>(mut self, arg: T) -> Builder { self.options.blocklisted_functions.insert(arg); self } /// Hide the given item from the generated bindings, regardless of /// whether it's a type, function, module, etc. Regular /// expressions are supported. #[deprecated(note = "Use blocklist_item instead")] pub fn blacklist_item>(mut self, arg: T) -> Builder { self.options.blocklisted_items.insert(arg); self } /// Hide the given item from the generated bindings, regardless of /// whether it's a type, function, module, etc. Regular /// expressions are supported. /// /// To blocklist items prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn blocklist_item>(mut self, arg: T) -> Builder { self.options.blocklisted_items.insert(arg); self } /// Treat the given type as opaque in the generated bindings. Regular /// expressions are supported. /// /// To change types prefixed with "mylib" into opaque, use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn opaque_type>(mut self, arg: T) -> Builder { self.options.opaque_types.insert(arg); self } /// Allowlist the given type so that it (and all types that it transitively /// refers to) appears in the generated bindings. Regular expressions are /// supported. #[deprecated(note = "use allowlist_type instead")] pub fn whitelisted_type>(self, arg: T) -> Builder { self.allowlist_type(arg) } /// Allowlist the given type so that it (and all types that it transitively /// refers to) appears in the generated bindings. Regular expressions are /// supported. #[deprecated(note = "use allowlist_type instead")] pub fn whitelist_type>(self, arg: T) -> Builder { self.allowlist_type(arg) } /// Allowlist the given type so that it (and all types that it transitively /// refers to) appears in the generated bindings. Regular expressions are /// supported. /// /// To allowlist types prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn allowlist_type>(mut self, arg: T) -> Builder { self.options.allowlisted_types.insert(arg); self } /// Allowlist the given function so that it (and all types that it /// transitively refers to) appears in the generated bindings. Regular /// expressions are supported. /// /// To allowlist functions prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn allowlist_function>(mut self, arg: T) -> Builder { self.options.allowlisted_functions.insert(arg); self } /// Allowlist the given function. /// /// Deprecated: use allowlist_function instead. #[deprecated(note = "use allowlist_function instead")] pub fn whitelist_function>(self, arg: T) -> Builder { self.allowlist_function(arg) } /// Allowlist the given function. /// /// Deprecated: use allowlist_function instead. #[deprecated(note = "use allowlist_function instead")] pub fn whitelisted_function>(self, arg: T) -> Builder { self.allowlist_function(arg) } /// Allowlist the given variable so that it (and all types that it /// transitively refers to) appears in the generated bindings. Regular /// expressions are supported. /// /// To allowlist variables prefixed with "mylib" use `"mylib_.*"`. /// For more complicated expressions check /// [regex](https://docs.rs/regex/*/regex/) docs pub fn allowlist_var>(mut self, arg: T) -> Builder { self.options.allowlisted_vars.insert(arg); self } /// Deprecated: use allowlist_var instead. #[deprecated(note = "use allowlist_var instead")] pub fn whitelist_var>(self, arg: T) -> Builder { self.allowlist_var(arg) } /// Allowlist the given variable. /// /// Deprecated: use allowlist_var instead. #[deprecated(note = "use allowlist_var instead")] pub fn whitelisted_var>(self, arg: T) -> Builder { self.allowlist_var(arg) } /// Set the default style of code to generate for enums pub fn default_enum_style( mut self, arg: codegen::EnumVariation, ) -> Builder { self.options.default_enum_style = arg; self } /// Mark the given enum (or set of enums, if using a pattern) as being /// bitfield-like. Regular expressions are supported. /// /// This makes bindgen generate a type that isn't a rust `enum`. Regular /// expressions are supported. /// /// This is similar to the newtype enum style, but with the bitwise /// operators implemented. pub fn bitfield_enum>(mut self, arg: T) -> Builder { self.options.bitfield_enums.insert(arg); self } /// Mark the given enum (or set of enums, if using a pattern) as a newtype. /// Regular expressions are supported. /// /// This makes bindgen generate a type that isn't a Rust `enum`. Regular /// expressions are supported. pub fn newtype_enum>(mut self, arg: T) -> Builder { self.options.newtype_enums.insert(arg); self } /// Mark the given enum (or set of enums, if using a pattern) as a Rust /// enum. /// /// This makes bindgen generate enums instead of constants. Regular /// expressions are supported. /// /// **Use this with caution**, creating this in unsafe code /// (including FFI) with an invalid value will invoke undefined behaviour. /// You may want to use the newtype enum style instead. pub fn rustified_enum>(mut self, arg: T) -> Builder { self.options.rustified_enums.insert(arg); self } /// Mark the given enum (or set of enums, if using a pattern) as a Rust /// enum with the `#[non_exhaustive]` attribute. /// /// This makes bindgen generate enums instead of constants. Regular /// expressions are supported. /// /// **Use this with caution**, creating this in unsafe code /// (including FFI) with an invalid value will invoke undefined behaviour. /// You may want to use the newtype enum style instead. pub fn rustified_non_exhaustive_enum>( mut self, arg: T, ) -> Builder { self.options.rustified_non_exhaustive_enums.insert(arg); self } /// Mark the given enum (or set of enums, if using a pattern) as a set of /// constants that are not to be put into a module. pub fn constified_enum>(mut self, arg: T) -> Builder { self.options.constified_enums.insert(arg); self } /// Mark the given enum (or set of enums, if using a pattern) as a set of /// constants that should be put into a module. /// /// This makes bindgen generate modules containing constants instead of /// just constants. Regular expressions are supported. pub fn constified_enum_module>(mut self, arg: T) -> Builder { self.options.constified_enum_modules.insert(arg); self } /// Set the default type for macro constants pub fn default_macro_constant_type( mut self, arg: codegen::MacroTypeVariation, ) -> Builder { self.options.default_macro_constant_type = arg; self } /// Set the default style of code to generate for typedefs pub fn default_alias_style( mut self, arg: codegen::AliasVariation, ) -> Builder { self.options.default_alias_style = arg; self } /// Mark the given typedef alias (or set of aliases, if using a pattern) to /// use regular Rust type aliasing. /// /// This is the default behavior and should be used if `default_alias_style` /// was set to NewType or NewTypeDeref and you want to override it for a /// set of typedefs. pub fn type_alias>(mut self, arg: T) -> Builder { self.options.type_alias.insert(arg); self } /// Mark the given typedef alias (or set of aliases, if using a pattern) to /// be generated as a new type by having the aliased type be wrapped in a /// #[repr(transparent)] struct. /// /// Used to enforce stricter type checking. pub fn new_type_alias>(mut self, arg: T) -> Builder { self.options.new_type_alias.insert(arg); self } /// Mark the given typedef alias (or set of aliases, if using a pattern) to /// be generated as a new type by having the aliased type be wrapped in a /// #[repr(transparent)] struct and also have an automatically generated /// impl's of `Deref` and `DerefMut` to their aliased type. pub fn new_type_alias_deref>(mut self, arg: T) -> Builder { self.options.new_type_alias_deref.insert(arg); self } /// Add a string to prepend to the generated bindings. The string is passed /// through without any modification. pub fn raw_line>(mut self, arg: T) -> Self { self.options.raw_lines.push(arg.into()); self } /// Add a given line to the beginning of module `mod`. pub fn module_raw_line(mut self, mod_: T, line: U) -> Self where T: Into, U: Into, { self.options .module_lines .entry(mod_.into()) .or_insert_with(Vec::new) .push(line.into()); self } /// Add a given set of lines to the beginning of module `mod`. pub fn module_raw_lines(mut self, mod_: T, lines: I) -> Self where T: Into, I: IntoIterator, I::Item: Into, { self.options .module_lines .entry(mod_.into()) .or_insert_with(Vec::new) .extend(lines.into_iter().map(Into::into)); self } /// Add an argument to be passed straight through to clang. pub fn clang_arg>(mut self, arg: T) -> Builder { self.options.clang_args.push(arg.into()); self } /// Add arguments to be passed straight through to clang. pub fn clang_args(mut self, iter: I) -> Builder where I: IntoIterator, I::Item: AsRef, { for arg in iter { self = self.clang_arg(arg.as_ref()) } self } /// Emit bindings for builtin definitions (for example `__builtin_va_list`) /// in the generated Rust. pub fn emit_builtins(mut self) -> Builder { self.options.builtins = true; self } /// Avoid converting floats to `f32`/`f64` by default. pub fn no_convert_floats(mut self) -> Self { self.options.convert_floats = false; self } /// Set whether layout tests should be generated. pub fn layout_tests(mut self, doit: bool) -> Self { self.options.layout_tests = doit; self } /// Set whether `Debug` should be implemented, if it can not be derived automatically. pub fn impl_debug(mut self, doit: bool) -> Self { self.options.impl_debug = doit; self } /// Set whether `PartialEq` should be implemented, if it can not be derived automatically. pub fn impl_partialeq(mut self, doit: bool) -> Self { self.options.impl_partialeq = doit; self } /// Set whether `Copy` should be derived by default. pub fn derive_copy(mut self, doit: bool) -> Self { self.options.derive_copy = doit; self } /// Set whether `Debug` should be derived by default. pub fn derive_debug(mut self, doit: bool) -> Self { self.options.derive_debug = doit; self } /// Set whether `Default` should be derived by default. pub fn derive_default(mut self, doit: bool) -> Self { self.options.derive_default = doit; self } /// Set whether `Hash` should be derived by default. pub fn derive_hash(mut self, doit: bool) -> Self { self.options.derive_hash = doit; self } /// Set whether `PartialOrd` should be derived by default. /// If we don't compute partialord, we also cannot compute /// ord. Set the derive_ord to `false` when doit is `false`. pub fn derive_partialord(mut self, doit: bool) -> Self { self.options.derive_partialord = doit; if !doit { self.options.derive_ord = false; } self } /// Set whether `Ord` should be derived by default. /// We can't compute `Ord` without computing `PartialOrd`, /// so we set the same option to derive_partialord. pub fn derive_ord(mut self, doit: bool) -> Self { self.options.derive_ord = doit; self.options.derive_partialord = doit; self } /// Set whether `PartialEq` should be derived by default. /// /// If we don't derive `PartialEq`, we also cannot derive `Eq`, so deriving /// `Eq` is also disabled when `doit` is `false`. pub fn derive_partialeq(mut self, doit: bool) -> Self { self.options.derive_partialeq = doit; if !doit { self.options.derive_eq = false; } self } /// Set whether `Eq` should be derived by default. /// /// We can't derive `Eq` without also deriving `PartialEq`, so we also /// enable deriving `PartialEq` when `doit` is `true`. pub fn derive_eq(mut self, doit: bool) -> Self { self.options.derive_eq = doit; if doit { self.options.derive_partialeq = doit; } self } /// Set whether or not to time bindgen phases, and print information to /// stderr. pub fn time_phases(mut self, doit: bool) -> Self { self.options.time_phases = doit; self } /// Emit Clang AST. pub fn emit_clang_ast(mut self) -> Builder { self.options.emit_ast = true; self } /// Emit IR. pub fn emit_ir(mut self) -> Builder { self.options.emit_ir = true; self } /// Enable C++ namespaces. pub fn enable_cxx_namespaces(mut self) -> Builder { self.options.enable_cxx_namespaces = true; self } /// Enable detecting must_use attributes on C functions. /// /// This is quite slow in some cases (see #1465), so it's disabled by /// default. /// /// Note that for this to do something meaningful for now at least, the rust /// target version has to have support for `#[must_use]`. pub fn enable_function_attribute_detection(mut self) -> Self { self.options.enable_function_attribute_detection = true; self } /// Disable name auto-namespacing. /// /// By default, bindgen mangles names like `foo::bar::Baz` to look like /// `foo_bar_Baz` instead of just `Baz`. /// /// This method disables that behavior. /// /// Note that this intentionally does not change the names used for /// allowlisting and blocklisting, which should still be mangled with the /// namespaces. /// /// Note, also, that this option may cause bindgen to generate duplicate /// names. pub fn disable_name_namespacing(mut self) -> Builder { self.options.disable_name_namespacing = true; self } /// Disable nested struct naming. /// /// The following structs have different names for C and C++. In case of C /// they are visible as `foo` and `bar`. In case of C++ they are visible as /// `foo` and `foo::bar`. /// /// ```c /// struct foo { /// struct bar { /// } b; /// }; /// ``` /// /// Bindgen wants to avoid duplicate names by default so it follows C++ naming /// and it generates `foo`/`foo_bar` instead of just `foo`/`bar`. /// /// This method disables this behavior and it is indented to be used only /// for headers that were written for C. pub fn disable_nested_struct_naming(mut self) -> Builder { self.options.disable_nested_struct_naming = true; self } /// Treat inline namespaces conservatively. /// /// This is tricky, because in C++ is technically legal to override an item /// defined in an inline namespace: /// /// ```cpp /// inline namespace foo { /// using Bar = int; /// } /// using Bar = long; /// ``` /// /// Even though referencing `Bar` is a compiler error. /// /// We want to support this (arguably esoteric) use case, but we don't want /// to make the rest of bindgen users pay an usability penalty for that. /// /// To support this, we need to keep all the inline namespaces around, but /// then bindgen usage is a bit more difficult, because you cannot /// reference, e.g., `std::string` (you'd need to use the proper inline /// namespace). /// /// We could complicate a lot of the logic to detect name collisions, and if /// not detected generate a `pub use inline_ns::*` or something like that. /// /// That's probably something we can do if we see this option is needed in a /// lot of cases, to improve it's usability, but my guess is that this is /// not going to be too useful. pub fn conservative_inline_namespaces(mut self) -> Builder { self.options.conservative_inline_namespaces = true; self } /// Whether inline functions should be generated or not. /// /// Note that they will usually not work. However you can use /// `-fkeep-inline-functions` or `-fno-inline-functions` if you are /// responsible of compiling the library to make them callable. pub fn generate_inline_functions(mut self, doit: bool) -> Self { self.options.generate_inline_functions = doit; self } /// Ignore functions. pub fn ignore_functions(mut self) -> Builder { self.options.codegen_config.remove(CodegenConfig::FUNCTIONS); self } /// Ignore methods. pub fn ignore_methods(mut self) -> Builder { self.options.codegen_config.remove(CodegenConfig::METHODS); self } /// Avoid generating any unstable Rust, such as Rust unions, in the generated bindings. #[deprecated(note = "please use `rust_target` instead")] pub fn unstable_rust(self, doit: bool) -> Self { let rust_target = if doit { RustTarget::Nightly } else { LATEST_STABLE_RUST }; self.rust_target(rust_target) } /// Use core instead of libstd in the generated bindings. pub fn use_core(mut self) -> Builder { self.options.use_core = true; self } /// Use the given prefix for the raw types instead of `::std::os::raw`. pub fn ctypes_prefix>(mut self, prefix: T) -> Builder { self.options.ctypes_prefix = Some(prefix.into()); self } /// Use the given prefix for the anon fields. pub fn anon_fields_prefix>(mut self, prefix: T) -> Builder { self.options.anon_fields_prefix = prefix.into(); self } /// Allows configuring types in different situations, see the /// [`ParseCallbacks`](./callbacks/trait.ParseCallbacks.html) documentation. pub fn parse_callbacks( mut self, cb: Box, ) -> Self { self.options.parse_callbacks = Some(cb); self } /// Choose what to generate using a /// [`CodegenConfig`](./struct.CodegenConfig.html). pub fn with_codegen_config(mut self, config: CodegenConfig) -> Self { self.options.codegen_config = config; self } /// Whether to detect include paths using clang_sys. pub fn detect_include_paths(mut self, doit: bool) -> Self { self.options.detect_include_paths = doit; self } /// Whether to try to fit macro constants to types smaller than u32/i32 pub fn fit_macro_constants(mut self, doit: bool) -> Self { self.options.fit_macro_constants = doit; self } /// Prepend the enum name to constant or newtype variants. pub fn prepend_enum_name(mut self, doit: bool) -> Self { self.options.prepend_enum_name = doit; self } /// Set whether `size_t` should be translated to `usize` automatically. pub fn size_t_is_usize(mut self, is: bool) -> Self { self.options.size_t_is_usize = is; self } /// Set whether rustfmt should format the generated bindings. pub fn rustfmt_bindings(mut self, doit: bool) -> Self { self.options.rustfmt_bindings = doit; self } /// Set whether we should record matched items in our regex sets. pub fn record_matches(mut self, doit: bool) -> Self { self.options.record_matches = doit; self } /// Set the absolute path to the rustfmt configuration file, if None, the standard rustfmt /// options are used. pub fn rustfmt_configuration_file(mut self, path: Option) -> Self { self = self.rustfmt_bindings(true); self.options.rustfmt_configuration_file = path; self } /// Sets an explicit path to rustfmt, to be used when rustfmt is enabled. pub fn with_rustfmt>(mut self, path: P) -> Self { self.options.rustfmt_path = Some(path.into()); self } /// Generate the Rust bindings using the options built up thus far. pub fn generate(mut self) -> Result { // Add any extra arguments from the environment to the clang command line. if let Some(extra_clang_args) = env::var("BINDGEN_EXTRA_CLANG_ARGS").ok() { // Try to parse it with shell quoting. If we fail, make it one single big argument. if let Some(strings) = shlex::split(&extra_clang_args) { self.options.clang_args.extend(strings); } else { self.options.clang_args.push(extra_clang_args); }; } // Transform input headers to arguments on the clang command line. self.options.input_header = self.input_headers.pop(); self.options .clang_args .extend(self.input_headers.drain(..).flat_map(|header| { iter::once("-include".into()).chain(iter::once(header)) })); self.options.input_unsaved_files.extend( self.input_header_contents .drain(..) .map(|(name, contents)| { clang::UnsavedFile::new(&name, &contents) }), ); Bindings::generate(self.options) } /// Preprocess and dump the input header files to disk. /// /// This is useful when debugging bindgen, using C-Reduce, or when filing /// issues. The resulting file will be named something like `__bindgen.i` or /// `__bindgen.ii` pub fn dump_preprocessed_input(&self) -> io::Result<()> { let clang = clang_sys::support::Clang::find(None, &[]).ok_or_else(|| { io::Error::new( io::ErrorKind::Other, "Cannot find clang executable", ) })?; // The contents of a wrapper file that includes all the input header // files. let mut wrapper_contents = String::new(); // Whether we are working with C or C++ inputs. let mut is_cpp = args_are_cpp(&self.options.clang_args); // For each input header, add `#include "$header"`. for header in &self.input_headers { is_cpp |= file_is_cpp(header); wrapper_contents.push_str("#include \""); wrapper_contents.push_str(header); wrapper_contents.push_str("\"\n"); } // For each input header content, add a prefix line of `#line 0 "$name"` // followed by the contents. for &(ref name, ref contents) in &self.input_header_contents { is_cpp |= file_is_cpp(name); wrapper_contents.push_str("#line 0 \""); wrapper_contents.push_str(name); wrapper_contents.push_str("\"\n"); wrapper_contents.push_str(contents); } let wrapper_path = PathBuf::from(if is_cpp { "__bindgen.cpp" } else { "__bindgen.c" }); { let mut wrapper_file = File::create(&wrapper_path)?; wrapper_file.write_all(wrapper_contents.as_bytes())?; } let mut cmd = Command::new(&clang.path); cmd.arg("-save-temps") .arg("-E") .arg("-C") .arg("-c") .arg(&wrapper_path) .stdout(Stdio::piped()); for a in &self.options.clang_args { cmd.arg(a); } let mut child = cmd.spawn()?; let mut preprocessed = child.stdout.take().unwrap(); let mut file = File::create(if is_cpp { "__bindgen.ii" } else { "__bindgen.i" })?; io::copy(&mut preprocessed, &mut file)?; if child.wait()?.success() { Ok(()) } else { Err(io::Error::new( io::ErrorKind::Other, "clang exited with non-zero status", )) } } /// Don't derive `PartialEq` for a given type. Regular /// expressions are supported. pub fn no_partialeq>(mut self, arg: T) -> Builder { self.options.no_partialeq_types.insert(arg.into()); self } /// Don't derive `Copy` for a given type. Regular /// expressions are supported. pub fn no_copy>(mut self, arg: T) -> Self { self.options.no_copy_types.insert(arg.into()); self } /// Don't derive `Debug` for a given type. Regular /// expressions are supported. pub fn no_debug>(mut self, arg: T) -> Self { self.options.no_debug_types.insert(arg.into()); self } /// Don't derive/impl `Default` for a given type. Regular /// expressions are supported. pub fn no_default>(mut self, arg: T) -> Self { self.options.no_default_types.insert(arg.into()); self } /// Don't derive `Hash` for a given type. Regular /// expressions are supported. pub fn no_hash>(mut self, arg: T) -> Builder { self.options.no_hash_types.insert(arg.into()); self } /// Set whether `arr[size]` should be treated as `*mut T` or `*mut [T; size]` (same for mut) pub fn array_pointers_in_arguments(mut self, doit: bool) -> Self { self.options.array_pointers_in_arguments = doit; self } /// Set the wasm import module name pub fn wasm_import_module_name>( mut self, import_name: T, ) -> Self { self.options.wasm_import_module_name = Some(import_name.into()); self } /// Specify the dynamic library name if we are generating bindings for a shared library. pub fn dynamic_library_name>( mut self, dynamic_library_name: T, ) -> Self { self.options.dynamic_library_name = Some(dynamic_library_name.into()); self } /// Require successful linkage for all routines in a shared library. /// This allows us to optimize function calls by being able to safely assume function pointers /// are valid. pub fn dynamic_link_require_all(mut self, req: bool) -> Self { self.options.dynamic_link_require_all = req; self } /// Generate bindings as `pub` only if the bound item is publically accessible by C++. pub fn respect_cxx_access_specs(mut self, doit: bool) -> Self { self.options.respect_cxx_access_specs = doit; self } /// Always translate enum integer types to native Rust integer types. /// /// This will result in enums having types such as `u32` and `i16` instead /// of `c_uint` and `c_short`. Types for Rustified enums are always /// translated. pub fn translate_enum_integer_types(mut self, doit: bool) -> Self { self.options.translate_enum_integer_types = doit; self } } /// Configuration options for generated bindings. #[derive(Debug)] struct BindgenOptions { /// The set of types that have been blocklisted and should not appear /// anywhere in the generated code. blocklisted_types: RegexSet, /// The set of functions that have been blocklisted and should not appear /// in the generated code. blocklisted_functions: RegexSet, /// The set of items, regardless of item-type, that have been /// blocklisted and should not appear in the generated code. blocklisted_items: RegexSet, /// The set of types that should be treated as opaque structures in the /// generated code. opaque_types: RegexSet, /// The explicit rustfmt path. rustfmt_path: Option, /// The set of types that we should have bindings for in the generated /// code. /// /// This includes all types transitively reachable from any type in this /// set. One might think of allowlisted types/vars/functions as GC roots, /// and the generated Rust code as including everything that gets marked. allowlisted_types: RegexSet, /// Allowlisted functions. See docs for `allowlisted_types` for more. allowlisted_functions: RegexSet, /// Allowlisted variables. See docs for `allowlisted_types` for more. allowlisted_vars: RegexSet, /// The default style of code to generate for enums default_enum_style: codegen::EnumVariation, /// The enum patterns to mark an enum as a bitfield /// (newtype with bitwise operations). bitfield_enums: RegexSet, /// The enum patterns to mark an enum as a newtype. newtype_enums: RegexSet, /// The enum patterns to mark an enum as a Rust enum. rustified_enums: RegexSet, /// The enum patterns to mark an enum as a non-exhaustive Rust enum. rustified_non_exhaustive_enums: RegexSet, /// The enum patterns to mark an enum as a module of constants. constified_enum_modules: RegexSet, /// The enum patterns to mark an enum as a set of constants. constified_enums: RegexSet, /// The default type for C macro constants. default_macro_constant_type: codegen::MacroTypeVariation, /// The default style of code to generate for typedefs. default_alias_style: codegen::AliasVariation, /// Typedef patterns that will use regular type aliasing. type_alias: RegexSet, /// Typedef patterns that will be aliased by creating a new struct. new_type_alias: RegexSet, /// Typedef patterns that will be wrapped in a new struct and have /// Deref and Deref to their aliased type. new_type_alias_deref: RegexSet, /// Whether we should generate builtins or not. builtins: bool, /// True if we should dump the Clang AST for debugging purposes. emit_ast: bool, /// True if we should dump our internal IR for debugging purposes. emit_ir: bool, /// Output graphviz dot file. emit_ir_graphviz: Option, /// True if we should emulate C++ namespaces with Rust modules in the /// generated bindings. enable_cxx_namespaces: bool, /// True if we should try to find unexposed attributes in functions, in /// order to be able to generate #[must_use] attributes in Rust. enable_function_attribute_detection: bool, /// True if we should avoid mangling names with namespaces. disable_name_namespacing: bool, /// True if we should avoid generating nested struct names. disable_nested_struct_naming: bool, /// True if we should avoid embedding version identifiers into source code. disable_header_comment: bool, /// True if we should generate layout tests for generated structures. layout_tests: bool, /// True if we should implement the Debug trait for C/C++ structures and types /// that do not support automatically deriving Debug. impl_debug: bool, /// True if we should implement the PartialEq trait for C/C++ structures and types /// that do not support automatically deriving PartialEq. impl_partialeq: bool, /// True if we should derive Copy trait implementations for C/C++ structures /// and types. derive_copy: bool, /// True if we should derive Debug trait implementations for C/C++ structures /// and types. derive_debug: bool, /// True if we should derive Default trait implementations for C/C++ structures /// and types. derive_default: bool, /// True if we should derive Hash trait implementations for C/C++ structures /// and types. derive_hash: bool, /// True if we should derive PartialOrd trait implementations for C/C++ structures /// and types. derive_partialord: bool, /// True if we should derive Ord trait implementations for C/C++ structures /// and types. derive_ord: bool, /// True if we should derive PartialEq trait implementations for C/C++ structures /// and types. derive_partialeq: bool, /// True if we should derive Eq trait implementations for C/C++ structures /// and types. derive_eq: bool, /// True if we should avoid using libstd to use libcore instead. use_core: bool, /// An optional prefix for the "raw" types, like `c_int`, `c_void`... ctypes_prefix: Option, /// The prefix for the anon fields. anon_fields_prefix: String, /// Whether to time the bindgen phases. time_phases: bool, /// True if we should generate constant names that are **directly** under /// namespaces. namespaced_constants: bool, /// True if we should use MSVC name mangling rules. msvc_mangling: bool, /// Whether we should convert float types to f32/f64 types. convert_floats: bool, /// The set of raw lines to prepend to the top-level module of generated /// Rust code. raw_lines: Vec, /// The set of raw lines to prepend to each of the modules. /// /// This only makes sense if the `enable_cxx_namespaces` option is set. module_lines: HashMap>, /// The set of arguments to pass straight through to Clang. clang_args: Vec, /// The input header file. input_header: Option, /// Unsaved files for input. input_unsaved_files: Vec, /// A user-provided visitor to allow customizing different kinds of /// situations. parse_callbacks: Option>, /// Which kind of items should we generate? By default, we'll generate all /// of them. codegen_config: CodegenConfig, /// Whether to treat inline namespaces conservatively. /// /// See the builder method description for more details. conservative_inline_namespaces: bool, /// Whether to keep documentation comments in the generated output. See the /// documentation for more details. Defaults to true. generate_comments: bool, /// Whether to generate inline functions. Defaults to false. generate_inline_functions: bool, /// Whether to allowlist types recursively. Defaults to true. allowlist_recursively: bool, /// Instead of emitting 'use objc;' to files generated from objective c files, /// generate '#[macro_use] extern crate objc;' objc_extern_crate: bool, /// Instead of emitting 'use block;' to files generated from objective c files, /// generate '#[macro_use] extern crate block;' generate_block: bool, /// Instead of emitting 'use block;' to files generated from objective c files, /// generate '#[macro_use] extern crate block;' block_extern_crate: bool, /// Whether to use the clang-provided name mangling. This is true and /// probably needed for C++ features. /// /// However, some old libclang versions seem to return incorrect results in /// some cases for non-mangled functions, see [1], so we allow disabling it. /// /// [1]: https://github.com/rust-lang/rust-bindgen/issues/528 enable_mangling: bool, /// Whether to detect include paths using clang_sys. detect_include_paths: bool, /// Whether to try to fit macro constants into types smaller than u32/i32 fit_macro_constants: bool, /// Whether to prepend the enum name to constant or newtype variants. prepend_enum_name: bool, /// Version of the Rust compiler to target rust_target: RustTarget, /// Features to enable, derived from `rust_target` rust_features: RustFeatures, /// Whether we should record which items in the regex sets ever matched. /// /// This may be a bit slower, but will enable reporting of unused allowlist /// items via the `error!` log. record_matches: bool, /// Whether `size_t` should be translated to `usize` automatically. size_t_is_usize: bool, /// Whether rustfmt should format the generated bindings. rustfmt_bindings: bool, /// The absolute path to the rustfmt configuration file, if None, the standard rustfmt /// options are used. rustfmt_configuration_file: Option, /// The set of types that we should not derive `PartialEq` for. no_partialeq_types: RegexSet, /// The set of types that we should not derive `Copy` for. no_copy_types: RegexSet, /// The set of types that we should not derive `Debug` for. no_debug_types: RegexSet, /// The set of types that we should not derive/impl `Default` for. no_default_types: RegexSet, /// The set of types that we should not derive `Hash` for. no_hash_types: RegexSet, /// Decide if C arrays should be regular pointers in rust or array pointers array_pointers_in_arguments: bool, /// Wasm import module name. wasm_import_module_name: Option, /// The name of the dynamic library (if we are generating bindings for a shared library). If /// this is None, no dynamic bindings are created. dynamic_library_name: Option, /// Require successful linkage for all routines in a shared library. /// This allows us to optimize function calls by being able to safely assume function pointers /// are valid. No effect if `dynamic_library_name` is None. dynamic_link_require_all: bool, /// Only make generated bindings `pub` if the items would be publically accessible /// by C++. respect_cxx_access_specs: bool, /// Always translate enum integer types to native Rust integer types. translate_enum_integer_types: bool, } /// TODO(emilio): This is sort of a lie (see the error message that results from /// removing this), but since we don't share references across panic boundaries /// it's ok. impl ::std::panic::UnwindSafe for BindgenOptions {} impl BindgenOptions { fn build(&mut self) { let mut regex_sets = [ &mut self.allowlisted_vars, &mut self.allowlisted_types, &mut self.allowlisted_functions, &mut self.blocklisted_types, &mut self.blocklisted_functions, &mut self.blocklisted_items, &mut self.opaque_types, &mut self.bitfield_enums, &mut self.constified_enums, &mut self.constified_enum_modules, &mut self.newtype_enums, &mut self.rustified_enums, &mut self.rustified_non_exhaustive_enums, &mut self.type_alias, &mut self.new_type_alias, &mut self.new_type_alias_deref, &mut self.no_partialeq_types, &mut self.no_copy_types, &mut self.no_debug_types, &mut self.no_default_types, &mut self.no_hash_types, ]; let record_matches = self.record_matches; for regex_set in &mut regex_sets { regex_set.build(record_matches); } } /// Update rust target version pub fn set_rust_target(&mut self, rust_target: RustTarget) { self.rust_target = rust_target; // Keep rust_features synced with rust_target self.rust_features = rust_target.into(); } /// Get features supported by target Rust version pub fn rust_features(&self) -> RustFeatures { self.rust_features } } impl Default for BindgenOptions { fn default() -> BindgenOptions { let rust_target = RustTarget::default(); BindgenOptions { rust_target, rust_features: rust_target.into(), blocklisted_types: Default::default(), blocklisted_functions: Default::default(), blocklisted_items: Default::default(), opaque_types: Default::default(), rustfmt_path: Default::default(), allowlisted_types: Default::default(), allowlisted_functions: Default::default(), allowlisted_vars: Default::default(), default_enum_style: Default::default(), bitfield_enums: Default::default(), newtype_enums: Default::default(), rustified_enums: Default::default(), rustified_non_exhaustive_enums: Default::default(), constified_enums: Default::default(), constified_enum_modules: Default::default(), default_macro_constant_type: Default::default(), default_alias_style: Default::default(), type_alias: Default::default(), new_type_alias: Default::default(), new_type_alias_deref: Default::default(), builtins: false, emit_ast: false, emit_ir: false, emit_ir_graphviz: None, layout_tests: true, impl_debug: false, impl_partialeq: false, derive_copy: true, derive_debug: true, derive_default: false, derive_hash: false, derive_partialord: false, derive_ord: false, derive_partialeq: false, derive_eq: false, enable_cxx_namespaces: false, enable_function_attribute_detection: false, disable_name_namespacing: false, disable_nested_struct_naming: false, disable_header_comment: false, use_core: false, ctypes_prefix: None, anon_fields_prefix: DEFAULT_ANON_FIELDS_PREFIX.into(), namespaced_constants: true, msvc_mangling: false, convert_floats: true, raw_lines: vec![], module_lines: HashMap::default(), clang_args: vec![], input_header: None, input_unsaved_files: vec![], parse_callbacks: None, codegen_config: CodegenConfig::all(), conservative_inline_namespaces: false, generate_comments: true, generate_inline_functions: false, allowlist_recursively: true, generate_block: false, objc_extern_crate: false, block_extern_crate: false, enable_mangling: true, detect_include_paths: true, fit_macro_constants: false, prepend_enum_name: true, time_phases: false, record_matches: true, rustfmt_bindings: true, size_t_is_usize: false, rustfmt_configuration_file: None, no_partialeq_types: Default::default(), no_copy_types: Default::default(), no_debug_types: Default::default(), no_default_types: Default::default(), no_hash_types: Default::default(), array_pointers_in_arguments: false, wasm_import_module_name: None, dynamic_library_name: None, dynamic_link_require_all: false, respect_cxx_access_specs: false, translate_enum_integer_types: false, } } } #[cfg(feature = "runtime")] fn ensure_libclang_is_loaded() { if clang_sys::is_loaded() { return; } // XXX (issue #350): Ensure that our dynamically loaded `libclang` // doesn't get dropped prematurely, nor is loaded multiple times // across different threads. lazy_static! { static ref LIBCLANG: std::sync::Arc = { clang_sys::load().expect("Unable to find libclang"); clang_sys::get_library().expect( "We just loaded libclang and it had better still be \ here!", ) }; } clang_sys::set_library(Some(LIBCLANG.clone())); } #[cfg(not(feature = "runtime"))] fn ensure_libclang_is_loaded() {} /// Generated Rust bindings. #[derive(Debug)] pub struct Bindings { options: BindgenOptions, module: proc_macro2::TokenStream, } pub(crate) const HOST_TARGET: &'static str = include_str!(concat!(env!("OUT_DIR"), "/host-target.txt")); // Some architecture triplets are different between rust and libclang, see #1211 // and duplicates. fn rust_to_clang_target(rust_target: &str) -> String { if rust_target.starts_with("aarch64-apple-") { let mut clang_target = "arm64-apple-".to_owned(); clang_target.push_str(&rust_target["aarch64-apple-".len()..]); return clang_target; } rust_target.to_owned() } /// Returns the effective target, and whether it was explicitly specified on the /// clang flags. fn find_effective_target(clang_args: &[String]) -> (String, bool) { let mut args = clang_args.iter(); while let Some(opt) = args.next() { if opt.starts_with("--target=") { let mut split = opt.split('='); split.next(); return (split.next().unwrap().to_owned(), true); } if opt == "-target" { if let Some(target) = args.next() { return (target.clone(), true); } } } // If we're running from a build script, try to find the cargo target. if let Ok(t) = env::var("TARGET") { return (rust_to_clang_target(&t), false); } (rust_to_clang_target(HOST_TARGET), false) } impl Bindings { /// Generate bindings for the given options. pub(crate) fn generate( mut options: BindgenOptions, ) -> Result { ensure_libclang_is_loaded(); #[cfg(feature = "runtime")] debug!( "Generating bindings, libclang at {}", clang_sys::get_library().unwrap().path().display() ); #[cfg(not(feature = "runtime"))] debug!("Generating bindings, libclang linked"); options.build(); let (effective_target, explicit_target) = find_effective_target(&options.clang_args); let is_host_build = rust_to_clang_target(HOST_TARGET) == effective_target; // NOTE: The is_host_build check wouldn't be sound normally in some // cases if we were to call a binary (if you have a 32-bit clang and are // building on a 64-bit system for example). But since we rely on // opening libclang.so, it has to be the same architecture and thus the // check is fine. if !explicit_target && !is_host_build { options .clang_args .insert(0, format!("--target={}", effective_target)); }; fn detect_include_paths(options: &mut BindgenOptions) { if !options.detect_include_paths { return; } // Filter out include paths and similar stuff, so we don't incorrectly // promote them to `-isystem`. let clang_args_for_clang_sys = { let mut last_was_include_prefix = false; options .clang_args .iter() .filter(|arg| { if last_was_include_prefix { last_was_include_prefix = false; return false; } let arg = &**arg; // https://clang.llvm.org/docs/ClangCommandLineReference.html // -isystem and -isystem-after are harmless. if arg == "-I" || arg == "--include-directory" { last_was_include_prefix = true; return false; } if arg.starts_with("-I") || arg.starts_with("--include-directory=") { return false; } true }) .cloned() .collect::>() }; debug!( "Trying to find clang with flags: {:?}", clang_args_for_clang_sys ); let clang = match clang_sys::support::Clang::find( None, &clang_args_for_clang_sys, ) { None => return, Some(clang) => clang, }; debug!("Found clang: {:?}", clang); // Whether we are working with C or C++ inputs. let is_cpp = args_are_cpp(&options.clang_args) || options .input_header .as_ref() .map_or(false, |i| file_is_cpp(&i)); let search_paths = if is_cpp { clang.cpp_search_paths } else { clang.c_search_paths }; if let Some(search_paths) = search_paths { for path in search_paths.into_iter() { if let Ok(path) = path.into_os_string().into_string() { options.clang_args.push("-isystem".to_owned()); options.clang_args.push(path); } } } } detect_include_paths(&mut options); #[cfg(unix)] fn can_read(perms: &std::fs::Permissions) -> bool { use std::os::unix::fs::PermissionsExt; perms.mode() & 0o444 > 0 } #[cfg(not(unix))] fn can_read(_: &std::fs::Permissions) -> bool { true } if let Some(h) = options.input_header.as_ref() { if let Ok(md) = std::fs::metadata(h) { if md.is_dir() { eprintln!("error: '{}' is a folder", h); return Err(()); } if !can_read(&md.permissions()) { eprintln!( "error: insufficient permissions to read '{}'", h ); return Err(()); } options.clang_args.push(h.clone()) } else { eprintln!("error: header '{}' does not exist.", h); return Err(()); } } for (idx, f) in options.input_unsaved_files.iter().enumerate() { if idx != 0 || options.input_header.is_some() { options.clang_args.push("-include".to_owned()); } options.clang_args.push(f.name.to_str().unwrap().to_owned()) } debug!("Fixed-up options: {:?}", options); let time_phases = options.time_phases; let mut context = BindgenContext::new(options); if is_host_build { debug_assert_eq!( context.target_pointer_size(), std::mem::size_of::<*mut ()>(), "{:?} {:?}", effective_target, HOST_TARGET ); } { let _t = time::Timer::new("parse").with_output(time_phases); parse(&mut context)?; } let (items, options) = codegen::codegen(context); Ok(Bindings { options, module: quote! { #( #items )* }, }) } /// Convert these bindings into source text (with raw lines prepended). pub fn to_string(&self) -> String { let mut bytes = vec![]; self.write(Box::new(&mut bytes) as Box) .expect("writing to a vec cannot fail"); String::from_utf8(bytes) .expect("we should only write bindings that are valid utf-8") } /// Write these bindings as source text to a file. pub fn write_to_file>(&self, path: P) -> io::Result<()> { let file = OpenOptions::new() .write(true) .truncate(true) .create(true) .open(path.as_ref())?; self.write(Box::new(file))?; Ok(()) } /// Write these bindings as source text to the given `Write`able. pub fn write<'a>(&self, mut writer: Box) -> io::Result<()> { if !self.options.disable_header_comment { let version = Some("0.58.1"); let header = format!( "/* automatically generated by rust-bindgen {} */\n\n", version.unwrap_or("(unknown version)") ); writer.write_all(header.as_bytes())?; } for line in self.options.raw_lines.iter() { writer.write_all(line.as_bytes())?; writer.write_all("\n".as_bytes())?; } if !self.options.raw_lines.is_empty() { writer.write_all("\n".as_bytes())?; } let bindings = self.module.to_string(); match self.rustfmt_generated_string(&bindings) { Ok(rustfmt_bindings) => { writer.write_all(rustfmt_bindings.as_bytes())?; } Err(err) => { eprintln!( "Failed to run rustfmt: {} (non-fatal, continuing)", err ); writer.write_all(bindings.as_bytes())?; } } Ok(()) } /// Gets the rustfmt path to rustfmt the generated bindings. fn rustfmt_path<'a>(&'a self) -> io::Result> { debug_assert!(self.options.rustfmt_bindings); if let Some(ref p) = self.options.rustfmt_path { return Ok(Cow::Borrowed(p)); } if let Ok(rustfmt) = env::var("RUSTFMT") { return Ok(Cow::Owned(rustfmt.into())); } #[cfg(feature = "which-rustfmt")] match which::which("rustfmt") { Ok(p) => Ok(Cow::Owned(p)), Err(e) => { Err(io::Error::new(io::ErrorKind::Other, format!("{}", e))) } } #[cfg(not(feature = "which-rustfmt"))] // No rustfmt binary was specified, so assume that the binary is called // "rustfmt" and that it is in the user's PATH. Ok(Cow::Owned("rustfmt".into())) } /// Checks if rustfmt_bindings is set and runs rustfmt on the string fn rustfmt_generated_string<'a>( &self, source: &'a str, ) -> io::Result> { let _t = time::Timer::new("rustfmt_generated_string") .with_output(self.options.time_phases); if !self.options.rustfmt_bindings { return Ok(Cow::Borrowed(source)); } let rustfmt = self.rustfmt_path()?; let mut cmd = Command::new(&*rustfmt); cmd.stdin(Stdio::piped()).stdout(Stdio::piped()); if let Some(path) = self .options .rustfmt_configuration_file .as_ref() .and_then(|f| f.to_str()) { cmd.args(&["--config-path", path]); } let mut child = cmd.spawn()?; let mut child_stdin = child.stdin.take().unwrap(); let mut child_stdout = child.stdout.take().unwrap(); let source = source.to_owned(); // Write to stdin in a new thread, so that we can read from stdout on this // thread. This keeps the child from blocking on writing to its stdout which // might block us from writing to its stdin. let stdin_handle = ::std::thread::spawn(move || { let _ = child_stdin.write_all(source.as_bytes()); source }); let mut output = vec![]; io::copy(&mut child_stdout, &mut output)?; let status = child.wait()?; let source = stdin_handle.join().expect( "The thread writing to rustfmt's stdin doesn't do \ anything that could panic", ); match String::from_utf8(output) { Ok(bindings) => match status.code() { Some(0) => Ok(Cow::Owned(bindings)), Some(2) => Err(io::Error::new( io::ErrorKind::Other, "Rustfmt parsing errors.".to_string(), )), Some(3) => { warn!("Rustfmt could not format some lines."); Ok(Cow::Owned(bindings)) } _ => Err(io::Error::new( io::ErrorKind::Other, "Internal rustfmt error".to_string(), )), }, _ => Ok(Cow::Owned(source)), } } } /// Determines whether the given cursor is in any of the files matched by the /// options. fn filter_builtins(ctx: &BindgenContext, cursor: &clang::Cursor) -> bool { ctx.options().builtins || !cursor.is_builtin() } /// Parse one `Item` from the Clang cursor. fn parse_one( ctx: &mut BindgenContext, cursor: clang::Cursor, parent: Option, ) -> clang_sys::CXChildVisitResult { if !filter_builtins(ctx, &cursor) { return CXChildVisit_Continue; } use clang_sys::CXChildVisit_Continue; match Item::parse(cursor, parent, ctx) { Ok(..) => {} Err(ParseError::Continue) => {} Err(ParseError::Recurse) => { cursor.visit(|child| parse_one(ctx, child, parent)); } } CXChildVisit_Continue } /// Parse the Clang AST into our `Item` internal representation. fn parse(context: &mut BindgenContext) -> Result<(), ()> { use clang_sys::*; let mut any_error = false; for d in context.translation_unit().diags().iter() { let msg = d.format(); let is_err = d.severity() >= CXDiagnostic_Error; eprintln!("{}, err: {}", msg, is_err); any_error |= is_err; } if any_error { return Err(()); } let cursor = context.translation_unit().cursor(); if context.options().emit_ast { fn dump_if_not_builtin(cur: &clang::Cursor) -> CXChildVisitResult { if !cur.is_builtin() { clang::ast_dump(&cur, 0) } else { CXChildVisit_Continue } } cursor.visit(|cur| dump_if_not_builtin(&cur)); } let root = context.root_module(); context.with_module(root, |context| { cursor.visit(|cursor| parse_one(context, cursor, None)) }); assert!( context.current_module() == context.root_module(), "How did this happen?" ); Ok(()) } /// Extracted Clang version data #[derive(Debug)] pub struct ClangVersion { /// Major and minor semver, if parsing was successful pub parsed: Option<(u32, u32)>, /// full version string pub full: String, } /// Get the major and the minor semver numbers of Clang's version pub fn clang_version() -> ClangVersion { ensure_libclang_is_loaded(); //Debian clang version 11.0.1-2 let raw_v: String = clang::extract_clang_version(); let split_v: Option> = raw_v .split_whitespace() .filter(|t| t.chars().next().map_or(false, |v| v.is_ascii_digit())) .next() .map(|v| v.split('.').collect()); match split_v { Some(v) => { if v.len() >= 2 { let maybe_major = v[0].parse::(); let maybe_minor = v[1].parse::(); match (maybe_major, maybe_minor) { (Ok(major), Ok(minor)) => { return ClangVersion { parsed: Some((major, minor)), full: raw_v.clone(), } } _ => {} } } } None => {} }; ClangVersion { parsed: None, full: raw_v.clone(), } } /// A ParseCallbacks implementation that will act on file includes by echoing a rerun-if-changed /// line /// /// When running in side a `build.rs` script, this can be used to make cargo invalidate the /// generated bindings whenever any of the files included from the header change: /// ``` /// use bindgen::builder; /// let bindings = builder() /// .header("path/to/input/header") /// .parse_callbacks(Box::new(bindgen::CargoCallbacks)) /// .generate(); /// ``` #[derive(Debug)] pub struct CargoCallbacks; impl callbacks::ParseCallbacks for CargoCallbacks { fn include_file(&self, filename: &str) { println!("cargo:rerun-if-changed={}", filename); } } /// Test command_line_flag function. #[test] fn commandline_flag_unit_test_function() { //Test 1 let bindings = crate::builder(); let command_line_flags = bindings.command_line_flags(); let test_cases = vec![ "--rust-target", "--no-derive-default", "--generate", "functions,types,vars,methods,constructors,destructors", ] .iter() .map(|&x| x.into()) .collect::>(); assert!(test_cases .iter() .all(|ref x| command_line_flags.contains(x),)); //Test 2 let bindings = crate::builder() .header("input_header") .allowlist_type("Distinct_Type") .allowlist_function("safe_function"); let command_line_flags = bindings.command_line_flags(); let test_cases = vec![ "--rust-target", "input_header", "--no-derive-default", "--generate", "functions,types,vars,methods,constructors,destructors", "--allowlist-type", "Distinct_Type", "--allowlist-function", "safe_function", ] .iter() .map(|&x| x.into()) .collect::>(); println!("{:?}", command_line_flags); assert!(test_cases .iter() .all(|ref x| command_line_flags.contains(x),)); } #[test] fn test_rust_to_clang_target() { assert_eq!(rust_to_clang_target("aarch64-apple-ios"), "arm64-apple-ios"); }