Google Git
Sign in
third-party-mirror / cbindgen / 9a26cd0114a633fa05ece30bd3f1b13149f496f2 / . / cbindgen-0.24.5 / src / bindgen / ir / structure.rs
blob: 9f77739a6650137369627a3b61bf442544972a55 [file] [log] [blame]
/* 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/. */
use std::io::Write;
use syn::ext::IdentExt;
use crate::bindgen::config::{Config, Language, LayoutConfig};
use crate::bindgen::declarationtyperesolver::DeclarationTypeResolver;
use crate::bindgen::dependencies::Dependencies;
use crate::bindgen::ir::{
AnnotationSet, Cfg, ConditionWrite, Constant, Documentation, Field, GenericArgument,
GenericParams, Item, ItemContainer, Path, Repr, ReprAlign, ReprStyle, ToCondition, Type,
Typedef,
};
use crate::bindgen::library::Library;
use crate::bindgen::mangle;
use crate::bindgen::monomorph::Monomorphs;
use crate::bindgen::rename::{IdentifierType, RenameRule};
use crate::bindgen::reserved;
use crate::bindgen::utilities::IterHelpers;
use crate::bindgen::writer::{ListType, Source, SourceWriter};
#[derive(Debug, Clone)]
pub struct Struct {
pub path: Path,
pub export_name: String,
pub generic_params: GenericParams,
pub fields: Vec<Field>,
/// Whether there's a tag field on the body of this struct. When this is
/// true, is_enum_variant_body is also guaranteed to be true.
pub has_tag_field: bool,
/// Whether this is an enum variant body.
pub is_enum_variant_body: bool,
pub alignment: Option<ReprAlign>,
pub is_transparent: bool,
pub cfg: Option<Cfg>,
pub annotations: AnnotationSet,
pub documentation: Documentation,
pub associated_constants: Vec<Constant>,
}
impl Struct {
/// Whether this struct can derive operator== / operator!=.
pub fn can_derive_eq(&self) -> bool {
!self.fields.is_empty() && self.fields.iter().all(|x| x.ty.can_cmp_eq())
}
pub fn add_associated_constant(&mut self, c: Constant) {
self.associated_constants.push(c);
}
pub fn load(
layout_config: &LayoutConfig,
item: &syn::ItemStruct,
mod_cfg: Option<&Cfg>,
) -> Result<Self, String> {
let repr = Repr::load(&item.attrs)?;
let is_transparent = match repr.style {
ReprStyle::C => false,
ReprStyle::Transparent => true,
_ => {
return Err("Struct is not marked #[repr(C)] or #[repr(transparent)].".to_owned());
}
};
let path = Path::new(item.ident.unraw().to_string());
// Ensure we can safely represent the struct given the configuration.
if let Some(align) = repr.align {
layout_config.ensure_safe_to_represent(&align)?;
}
let fields = match item.fields {
syn::Fields::Unit => Vec::new(),
syn::Fields::Named(ref fields) => fields
.named
.iter()
.try_skip_map(|field| Field::load(field, &path))?,
syn::Fields::Unnamed(ref fields) => {
let mut out = Vec::new();
let mut current = 0;
for field in fields.unnamed.iter() {
if let Some(mut ty) = Type::load(&field.ty)? {
ty.replace_self_with(&path);
out.push(Field {
name: format!("{}", current),
ty,
cfg: Cfg::load(&field.attrs),
annotations: AnnotationSet::load(&field.attrs)?,
documentation: Documentation::load(&field.attrs),
});
current += 1;
}
}
out
}
};
let has_tag_field = false;
let is_enum_variant_body = false;
Ok(Struct::new(
path,
GenericParams::load(&item.generics)?,
fields,
has_tag_field,
is_enum_variant_body,
repr.align,
is_transparent,
Cfg::append(mod_cfg, Cfg::load(&item.attrs)),
AnnotationSet::load(&item.attrs)?,
Documentation::load(&item.attrs),
))
}
#[allow(clippy::too_many_arguments)]
pub fn new(
path: Path,
generic_params: GenericParams,
fields: Vec<Field>,
has_tag_field: bool,
is_enum_variant_body: bool,
alignment: Option<ReprAlign>,
is_transparent: bool,
cfg: Option<Cfg>,
annotations: AnnotationSet,
documentation: Documentation,
) -> Self {
let export_name = path.name().to_owned();
Self {
path,
export_name,
generic_params,
fields,
has_tag_field,
is_enum_variant_body,
alignment,
is_transparent,
cfg,
annotations,
documentation,
associated_constants: vec![],
}
}
pub fn simplify_standard_types(&mut self, config: &Config) {
for field in &mut self.fields {
field.ty.simplify_standard_types(config);
}
}
pub fn is_generic(&self) -> bool {
self.generic_params.len() > 0
}
pub fn add_monomorphs(&self, library: &Library, out: &mut Monomorphs) {
// Generic structs can instantiate monomorphs only once they've been
// instantiated. See `instantiate_monomorph` for more details.
if self.is_generic() {
return;
}
for field in &self.fields {
field.ty.add_monomorphs(library, out);
}
}
pub fn mangle_paths(&mut self, monomorphs: &Monomorphs) {
for field in &mut self.fields {
field.ty.mangle_paths(monomorphs);
}
}
pub fn specialize(
&self,
generic_values: &[GenericArgument],
mappings: &[(&Path, &GenericArgument)],
config: &Config,
) -> Self {
let mangled_path = mangle::mangle_path(&self.path, generic_values, &config.export.mangle);
Struct::new(
mangled_path,
GenericParams::default(),
self.fields
.iter()
.map(|field| Field {
name: field.name.clone(),
ty: field.ty.specialize(mappings),
cfg: field.cfg.clone(),
annotations: field.annotations.clone(),
documentation: field.documentation.clone(),
})
.collect(),
self.has_tag_field,
self.is_enum_variant_body,
self.alignment,
self.is_transparent,
self.cfg.clone(),
self.annotations.clone(),
self.documentation.clone(),
)
}
fn emit_bitflags_binop<F: Write>(
&self,
constexpr_prefix: &str,
operator: char,
other: &str,
out: &mut SourceWriter<F>,
) {
out.new_line();
write!(
out,
"{}{} operator{}(const {}& {}) const",
constexpr_prefix,
self.export_name(),
operator,
self.export_name(),
other
);
out.open_brace();
write!(
out,
"return {} {{ static_cast<decltype(bits)>(this->bits {} {}.bits) }};",
self.export_name(),
operator,
other
);
out.close_brace(false);
out.new_line();
write!(
out,
"{}& operator{}=(const {}& {})",
self.export_name(),
operator,
self.export_name(),
other
);
out.open_brace();
write!(out, "*this = (*this {} {});", operator, other);
out.new_line();
write!(out, "return *this;");
out.close_brace(false);
}
}
impl Item for Struct {
fn path(&self) -> &Path {
&self.path
}
fn export_name(&self) -> &str {
&self.export_name
}
fn cfg(&self) -> Option<&Cfg> {
self.cfg.as_ref()
}
fn annotations(&self) -> &AnnotationSet {
&self.annotations
}
fn annotations_mut(&mut self) -> &mut AnnotationSet {
&mut self.annotations
}
fn container(&self) -> ItemContainer {
ItemContainer::Struct(self.clone())
}
fn collect_declaration_types(&self, resolver: &mut DeclarationTypeResolver) {
if self.is_transparent {
resolver.add_none(&self.path);
} else {
resolver.add_struct(&self.path);
}
}
fn resolve_declaration_types(&mut self, resolver: &DeclarationTypeResolver) {
for field in &mut self.fields {
field.ty.resolve_declaration_types(resolver);
}
}
fn rename_for_config(&mut self, config: &Config) {
// Rename the name of the struct
if !(self.has_tag_field && config.language == Language::Cxx) {
config.export.rename(&mut self.export_name);
}
// Rename the types used in fields
{
let fields = self.fields.iter_mut().skip(self.has_tag_field as usize);
for field in fields {
field.ty.rename_for_config(config, &self.generic_params);
}
}
// Apply renaming rules to fields in the following order
// 1. `cbindgen::field-names` annotation
// 2. `cbindgen::rename-all` annotation
// 3. config struct rename rule
// If the struct is a tuple struct and we have not renamed the
// fields, then prefix each of them with an underscore.
// If any field is a reserved keyword, then postfix it with an
// underscore.
// Scope for mutable borrow of fields
{
let names = self.fields.iter_mut().map(|field| &mut field.name);
let field_rules = self
.annotations
.parse_atom::<RenameRule>("rename-all")
.unwrap_or(config.structure.rename_fields);
if let Some(o) = self.annotations.list("field-names") {
for (dest, src) in names.zip(o) {
*dest = src;
}
} else if let Some(r) = field_rules.not_none() {
for name in names {
*name = r.apply(name, IdentifierType::StructMember).into_owned();
}
} else {
// If we don't have any rules for a tuple struct, prefix them with
// an underscore so it still compiles.
for name in names {
if name.starts_with(|c: char| c.is_ascii_digit()) {
name.insert(0, '_');
}
}
}
}
for field in &mut self.fields {
reserved::escape(&mut field.name);
}
for c in self.associated_constants.iter_mut() {
c.rename_for_config(config);
}
}
fn add_dependencies(&self, library: &Library, out: &mut Dependencies) {
let mut fields = self.fields.iter();
// If there is a tag field, skip it
if self.has_tag_field {
fields.next();
}
for field in fields {
field
.ty
.add_dependencies_ignoring_generics(&self.generic_params, library, out);
}
for c in &self.associated_constants {
c.add_dependencies(library, out);
}
}
fn instantiate_monomorph(
&self,
generic_values: &[GenericArgument],
library: &Library,
out: &mut Monomorphs,
) {
let mappings = self.generic_params.call(self.path.name(), generic_values);
let monomorph = self.specialize(generic_values, &mappings, library.get_config());
out.insert_struct(library, self, monomorph, generic_values.to_owned());
}
}
impl Source for Struct {
fn write<F: Write>(&self, config: &Config, out: &mut SourceWriter<F>) {
if self.is_transparent {
let typedef = Typedef {
path: self.path.clone(),
export_name: self.export_name.to_owned(),
generic_params: self.generic_params.clone(),
aliased: self.fields[0].ty.clone(),
cfg: self.cfg.clone(),
annotations: self.annotations.clone(),
documentation: self.documentation.clone(),
};
typedef.write(config, out);
for constant in &self.associated_constants {
out.new_line();
constant.write(config, out, Some(self));
}
return;
}
let condition = self.cfg.to_condition(config);
condition.write_before(config, out);
self.documentation.write(config, out);
if !self.is_enum_variant_body {
self.generic_params.write(config, out);
}
// The following results in
// C++ or C with Tag as style:
// struct Name {
// C with Type only style:
// typedef struct {
// C with Both as style:
// typedef struct Name {
match config.language {
Language::C if config.style.generate_typedef() => out.write("typedef "),
Language::C | Language::Cxx => {}
Language::Cython => out.write(config.style.cython_def()),
}
// Cython extern declarations don't manage layouts, layouts are defined entierly by the
// corresponding C code. So this `packed` is only for documentation, and missing
// `aligned(n)` is also not a problem.
if config.language == Language::Cython {
if let Some(align) = self.alignment {
match align {
ReprAlign::Packed => out.write("packed "),
ReprAlign::Align(_) => {} // Not supported
}
}
}
out.write("struct");
if config.language != Language::Cython {
if let Some(align) = self.alignment {
match align {
ReprAlign::Packed => {
if let Some(ref anno) = config.layout.packed {
write!(out, " {}", anno);
}
}
ReprAlign::Align(n) => {
if let Some(ref anno) = config.layout.aligned_n {
write!(out, " {}({})", anno, n);
}
}
}
}
}
if self.annotations.must_use(config) {
if let Some(ref anno) = config.structure.must_use {
write!(out, " {}", anno);
}
}
if config.language != Language::C || config.style.generate_tag() {
write!(out, " {}", self.export_name());
}
out.open_brace();
// Emit the pre_body section, if relevant
if let Some(body) = config.export.pre_body(&self.path) {
out.write_raw_block(body);
out.new_line();
}
out.write_vertical_source_list(&self.fields, ListType::Cap(";"));
if config.language == Language::Cython && self.fields.is_empty() {
out.write("pass");
}
if config.language == Language::Cxx {
let mut wrote_start_newline = false;
if config.structure.derive_constructor(&self.annotations) && !self.fields.is_empty() {
if !wrote_start_newline {
wrote_start_newline = true;
out.new_line();
}
out.new_line();
let arg_renamer = |name: &str| {
config
.function
.rename_args
.apply(name, IdentifierType::FunctionArg)
.into_owned()
};
write!(out, "{}(", self.export_name());
let vec: Vec<_> = self
.fields
.iter()
.map(|field| {
Field::from_name_and_type(
// const-ref args to constructor
format!("const& {}", arg_renamer(&field.name)),
field.ty.clone(),
)
})
.collect();
out.write_vertical_source_list(&vec[..], ListType::Join(","));
write!(out, ")");
out.new_line();
write!(out, " : ");
let vec: Vec<_> = self
.fields
.iter()
.map(|field| format!("{}({})", field.name, arg_renamer(&field.name)))
.collect();
out.write_vertical_source_list(&vec[..], ListType::Join(","));
out.new_line();
write!(out, "{{}}");
out.new_line();
}
let other = config
.function
.rename_args
.apply("other", IdentifierType::FunctionArg);
if self
.annotations
.bool("internal-derive-bitflags")
.unwrap_or(false)
{
if !wrote_start_newline {
wrote_start_newline = true;
out.new_line();
}
let constexpr_prefix = if config.constant.allow_constexpr {
"constexpr "
} else {
""
};
out.new_line();
write!(out, "{}explicit operator bool() const", constexpr_prefix);
out.open_brace();
write!(out, "return !!bits;");
out.close_brace(false);
out.new_line();
write!(
out,
"{}{} operator~() const",
constexpr_prefix,
self.export_name()
);
out.open_brace();
write!(
out,
"return {} {{ static_cast<decltype(bits)>(~bits) }};",
self.export_name()
);
out.close_brace(false);
self.emit_bitflags_binop(constexpr_prefix, '|', &other, out);
self.emit_bitflags_binop(constexpr_prefix, '&', &other, out);
self.emit_bitflags_binop(constexpr_prefix, '^', &other, out);
}
// Generate a serializer function that allows dumping this struct
// to an std::ostream. It's defined as a friend function inside the
// struct definition, and doesn't need the `inline` keyword even
// though it's implemented right in the generated header file.
if config.structure.derive_ostream(&self.annotations) {
if !wrote_start_newline {
wrote_start_newline = true;
out.new_line();
}
out.new_line();
let stream = config
.function
.rename_args
.apply("stream", IdentifierType::FunctionArg);
let instance = config
.function
.rename_args
.apply("instance", IdentifierType::FunctionArg);
write!(
out,
"friend std::ostream& operator<<(std::ostream& {}, const {}& {})",
stream,
self.export_name(),
instance,
);
out.open_brace();
write!(out, "return {} << \"{{ \"", stream);
let vec: Vec<_> = self
.fields
.iter()
.map(|x| format!(" << \"{}=\" << {}.{}", x.name, instance, x.name))
.collect();
out.write_vertical_source_list(&vec[..], ListType::Join(" << \", \""));
out.write(" << \" }\";");
out.close_brace(false);
}
let skip_fields = self.has_tag_field as usize;
macro_rules! emit_op {
($op_name:expr, $op:expr, $conjuc:expr) => {{
if !wrote_start_newline {
#[allow(unused_assignments)]
{
wrote_start_newline = true;
}
out.new_line();
}
out.new_line();
if let Some(Some(attrs)) =
self.annotations.atom(concat!($op_name, "-attributes"))
{
write!(out, "{} ", attrs);
}
write!(
out,
"bool operator{}(const {}& {}) const",
$op,
self.export_name(),
other
);
out.open_brace();
out.write("return ");
let vec: Vec<_> = self
.fields
.iter()
.skip(skip_fields)
.map(|field| format!("{} {} {}.{}", field.name, $op, other, field.name))
.collect();
out.write_vertical_source_list(
&vec[..],
ListType::Join(&format!(" {}", $conjuc)),
);
out.write(";");
out.close_brace(false);
}};
}
if config.structure.derive_eq(&self.annotations) && self.can_derive_eq() {
emit_op!("eq", "==", "&&");
}
if config.structure.derive_neq(&self.annotations) && self.can_derive_eq() {
emit_op!("neq", "!=", "||");
}
if config.structure.derive_lt(&self.annotations)
&& self.fields.len() == 1
&& self.fields[0].ty.can_cmp_order()
{
emit_op!("lt", "<", "&&");
}
if config.structure.derive_lte(&self.annotations)
&& self.fields.len() == 1
&& self.fields[0].ty.can_cmp_order()
{
emit_op!("lte", "<=", "&&");
}
if config.structure.derive_gt(&self.annotations)
&& self.fields.len() == 1
&& self.fields[0].ty.can_cmp_order()
{
emit_op!("gt", ">", "&&");
}
if config.structure.derive_gte(&self.annotations)
&& self.fields.len() == 1
&& self.fields[0].ty.can_cmp_order()
{
emit_op!("gte", ">=", "&&");
}
}
// Emit the post_body section, if relevant
if let Some(body) = config.export.post_body(&self.path) {
out.new_line();
out.write_raw_block(body);
}
if config.language == Language::Cxx
&& config.structure.associated_constants_in_body
&& config.constant.allow_static_const
{
for constant in &self.associated_constants {
out.new_line();
constant.write_declaration(config, out, self);
}
}
if config.language == Language::C && config.style.generate_typedef() {
out.close_brace(false);
write!(out, " {};", self.export_name());
} else {
out.close_brace(true);
}
for constant in &self.associated_constants {
out.new_line();
constant.write(config, out, Some(self));
}
condition.write_after(config, out);
}
}