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|
//! Intermediate representation of variables.
use super::super::codegen::MacroTypeVariation;
use super::context::{BindgenContext, TypeId};
use super::dot::DotAttributes;
use super::function::cursor_mangling;
use super::int::IntKind;
use super::item::Item;
use super::ty::{FloatKind, TypeKind};
use crate::callbacks::MacroParsingBehavior;
use crate::clang;
use crate::clang::ClangToken;
use crate::parse::{ClangSubItemParser, ParseError, ParseResult};
use cexpr;
use std::io;
use std::num::Wrapping;
/// The type for a constant variable.
#[derive(Debug)]
pub enum VarType {
/// A boolean.
Bool(bool),
/// An integer.
Int(i64),
/// A floating point number.
Float(f64),
/// A character.
Char(u8),
/// A string, not necessarily well-formed utf-8.
String(Vec<u8>),
}
/// A `Var` is our intermediate representation of a variable.
#[derive(Debug)]
pub struct Var {
/// The name of the variable.
name: String,
/// The mangled name of the variable.
mangled_name: Option<String>,
/// The type of the variable.
ty: TypeId,
/// The value of the variable, that needs to be suitable for `ty`.
val: Option<VarType>,
/// Whether this variable is const.
is_const: bool,
}
impl Var {
/// Construct a new `Var`.
pub fn new(
name: String,
mangled_name: Option<String>,
ty: TypeId,
val: Option<VarType>,
is_const: bool,
) -> Var {
assert!(!name.is_empty());
Var {
name,
mangled_name,
ty,
val,
is_const,
}
}
/// Is this variable `const` qualified?
pub fn is_const(&self) -> bool {
self.is_const
}
/// The value of this constant variable, if any.
pub fn val(&self) -> Option<&VarType> {
self.val.as_ref()
}
/// Get this variable's type.
pub fn ty(&self) -> TypeId {
self.ty
}
/// Get this variable's name.
pub fn name(&self) -> &str {
&self.name
}
/// Get this variable's mangled name.
pub fn mangled_name(&self) -> Option<&str> {
self.mangled_name.as_deref()
}
}
impl DotAttributes for Var {
fn dot_attributes<W>(
&self,
_ctx: &BindgenContext,
out: &mut W,
) -> io::Result<()>
where
W: io::Write,
{
if self.is_const {
writeln!(out, "<tr><td>const</td><td>true</td></tr>")?;
}
if let Some(ref mangled) = self.mangled_name {
writeln!(
out,
"<tr><td>mangled name</td><td>{}</td></tr>",
mangled
)?;
}
Ok(())
}
}
fn default_macro_constant_type(ctx: &BindgenContext, value: i64) -> IntKind {
if value < 0 ||
ctx.options().default_macro_constant_type ==
MacroTypeVariation::Signed
{
if value < i32::min_value() as i64 || value > i32::max_value() as i64 {
IntKind::I64
} else if !ctx.options().fit_macro_constants ||
value < i16::min_value() as i64 ||
value > i16::max_value() as i64
{
IntKind::I32
} else if value < i8::min_value() as i64 ||
value > i8::max_value() as i64
{
IntKind::I16
} else {
IntKind::I8
}
} else if value > u32::max_value() as i64 {
IntKind::U64
} else if !ctx.options().fit_macro_constants ||
value > u16::max_value() as i64
{
IntKind::U32
} else if value > u8::max_value() as i64 {
IntKind::U16
} else {
IntKind::U8
}
}
/// Parses tokens from a CXCursor_MacroDefinition pointing into a function-like
/// macro, and calls the func_macro callback.
fn handle_function_macro(
cursor: &clang::Cursor,
callbacks: &dyn crate::callbacks::ParseCallbacks,
) {
let is_closing_paren = |t: &ClangToken| {
// Test cheap token kind before comparing exact spellings.
t.kind == clang_sys::CXToken_Punctuation && t.spelling() == b")"
};
let tokens: Vec<_> = cursor.tokens().iter().collect();
if let Some(boundary) = tokens.iter().position(is_closing_paren) {
let mut spelled = tokens.iter().map(ClangToken::spelling);
// Add 1, to convert index to length.
let left = spelled.by_ref().take(boundary + 1);
let left = left.collect::<Vec<_>>().concat();
if let Ok(left) = String::from_utf8(left) {
let right: Vec<_> = spelled.collect();
callbacks.func_macro(&left, &right);
}
}
}
impl ClangSubItemParser for Var {
fn parse(
cursor: clang::Cursor,
ctx: &mut BindgenContext,
) -> Result<ParseResult<Self>, ParseError> {
use cexpr::expr::EvalResult;
use cexpr::literal::CChar;
use clang_sys::*;
match cursor.kind() {
CXCursor_MacroDefinition => {
for callbacks in &ctx.options().parse_callbacks {
match callbacks.will_parse_macro(&cursor.spelling()) {
MacroParsingBehavior::Ignore => {
return Err(ParseError::Continue);
}
MacroParsingBehavior::Default => {}
}
if cursor.is_macro_function_like() {
handle_function_macro(&cursor, callbacks.as_ref());
// We handled the macro, skip macro processing below.
return Err(ParseError::Continue);
}
}
let value = parse_macro(ctx, &cursor);
let (id, value) = match value {
Some(v) => v,
None => return Err(ParseError::Continue),
};
assert!(!id.is_empty(), "Empty macro name?");
let previously_defined = ctx.parsed_macro(&id);
// NB: It's important to "note" the macro even if the result is
// not an integer, otherwise we might loose other kind of
// derived macros.
ctx.note_parsed_macro(id.clone(), value.clone());
if previously_defined {
let name = String::from_utf8(id).unwrap();
warn!("Duplicated macro definition: {}", name);
return Err(ParseError::Continue);
}
// NOTE: Unwrapping, here and above, is safe, because the
// identifier of a token comes straight from clang, and we
// enforce utf8 there, so we should have already panicked at
// this point.
let name = String::from_utf8(id).unwrap();
let (type_kind, val) = match value {
EvalResult::Invalid => return Err(ParseError::Continue),
EvalResult::Float(f) => {
(TypeKind::Float(FloatKind::Double), VarType::Float(f))
}
EvalResult::Char(c) => {
let c = match c {
CChar::Char(c) => {
assert_eq!(c.len_utf8(), 1);
c as u8
}
CChar::Raw(c) => {
assert!(c <= ::std::u8::MAX as u64);
c as u8
}
};
(TypeKind::Int(IntKind::U8), VarType::Char(c))
}
EvalResult::Str(val) => {
let char_ty = Item::builtin_type(
TypeKind::Int(IntKind::U8),
true,
ctx,
);
for callbacks in &ctx.options().parse_callbacks {
callbacks.str_macro(&name, &val);
}
(TypeKind::Pointer(char_ty), VarType::String(val))
}
EvalResult::Int(Wrapping(value)) => {
let kind = ctx
.options()
.last_callback(|c| c.int_macro(&name, value))
.unwrap_or_else(|| {
default_macro_constant_type(ctx, value)
});
(TypeKind::Int(kind), VarType::Int(value))
}
};
let ty = Item::builtin_type(type_kind, true, ctx);
Ok(ParseResult::New(
Var::new(name, None, ty, Some(val), true),
Some(cursor),
))
}
CXCursor_VarDecl => {
let name = cursor.spelling();
if name.is_empty() {
warn!("Empty constant name?");
return Err(ParseError::Continue);
}
let ty = cursor.cur_type();
// TODO(emilio): do we have to special-case constant arrays in
// some other places?
let is_const = ty.is_const() ||
([CXType_ConstantArray, CXType_IncompleteArray]
.contains(&ty.kind()) &&
ty.elem_type()
.map_or(false, |element| element.is_const()));
let ty = match Item::from_ty(&ty, cursor, None, ctx) {
Ok(ty) => ty,
Err(e) => {
assert!(
matches!(ty.kind(), CXType_Auto | CXType_Unexposed),
"Couldn't resolve constant type, and it \
wasn't an nondeductible auto type or unexposed \
type!"
);
return Err(e);
}
};
// Note: Ty might not be totally resolved yet, see
// tests/headers/inner_const.hpp
//
// That's fine because in that case we know it's not a literal.
let canonical_ty = ctx
.safe_resolve_type(ty)
.and_then(|t| t.safe_canonical_type(ctx));
let is_integer = canonical_ty.map_or(false, |t| t.is_integer());
let is_float = canonical_ty.map_or(false, |t| t.is_float());
// TODO: We could handle `char` more gracefully.
// TODO: Strings, though the lookup is a bit more hard (we need
// to look at the canonical type of the pointee too, and check
// is char, u8, or i8 I guess).
let value = if is_integer {
let kind = match *canonical_ty.unwrap().kind() {
TypeKind::Int(kind) => kind,
_ => unreachable!(),
};
let mut val = cursor.evaluate().and_then(|v| v.as_int());
if val.is_none() || !kind.signedness_matches(val.unwrap()) {
val = get_integer_literal_from_cursor(&cursor);
}
val.map(|val| {
if kind == IntKind::Bool {
VarType::Bool(val != 0)
} else {
VarType::Int(val)
}
})
} else if is_float {
cursor
.evaluate()
.and_then(|v| v.as_double())
.map(VarType::Float)
} else {
cursor
.evaluate()
.and_then(|v| v.as_literal_string())
.map(VarType::String)
};
let mangling = cursor_mangling(ctx, &cursor);
let var = Var::new(name, mangling, ty, value, is_const);
Ok(ParseResult::New(var, Some(cursor)))
}
_ => {
/* TODO */
Err(ParseError::Continue)
}
}
}
}
/// Try and parse a macro using all the macros parsed until now.
fn parse_macro(
ctx: &BindgenContext,
cursor: &clang::Cursor,
) -> Option<(Vec<u8>, cexpr::expr::EvalResult)> {
use cexpr::expr;
let cexpr_tokens = cursor.cexpr_tokens();
let parser = expr::IdentifierParser::new(ctx.parsed_macros());
match parser.macro_definition(&cexpr_tokens) {
Ok((_, (id, val))) => Some((id.into(), val)),
_ => None,
}
}
fn parse_int_literal_tokens(cursor: &clang::Cursor) -> Option<i64> {
use cexpr::expr;
use cexpr::expr::EvalResult;
let cexpr_tokens = cursor.cexpr_tokens();
// TODO(emilio): We can try to parse other kinds of literals.
match expr::expr(&cexpr_tokens) {
Ok((_, EvalResult::Int(Wrapping(val)))) => Some(val),
_ => None,
}
}
fn get_integer_literal_from_cursor(cursor: &clang::Cursor) -> Option<i64> {
use clang_sys::*;
let mut value = None;
cursor.visit(|c| {
match c.kind() {
CXCursor_IntegerLiteral | CXCursor_UnaryOperator => {
value = parse_int_literal_tokens(&c);
}
CXCursor_UnexposedExpr => {
value = get_integer_literal_from_cursor(&c);
}
_ => (),
}
if value.is_some() {
CXChildVisit_Break
} else {
CXChildVisit_Continue
}
});
value
}
|
