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fuchsia / fuchsia / cafe43e483c36c5bfaa6e2decea566ed245832f8 / . / third_party / rust_crates / vendor / rustc-demangle / src / v0.rs
blob: 7a6c6a2301b7e9e848a38a11fa4421ba82ea6269 [file] [log] [blame]
use core::char;
use core::fmt;
use core::fmt::Display;
/// Representation of a demangled symbol name.
pub struct Demangle<'a> {
inner: &'a str,
}
/// De-mangles a Rust symbol into a more readable version
///
/// This function will take a **mangled** symbol and return a value. When printed,
/// the de-mangled version will be written. If the symbol does not look like
/// a mangled symbol, the original value will be written instead.
pub fn demangle(s: &str) -> Result<(Demangle, &str), Invalid> {
// First validate the symbol. If it doesn't look like anything we're
// expecting, we just print it literally. Note that we must handle non-Rust
// symbols because we could have any function in the backtrace.
let inner;
if s.len() > 2 && s.starts_with("_R") {
inner = &s[2..];
} else if s.len() > 1 && s.starts_with("R") {
// On Windows, dbghelp strips leading underscores, so we accept "R..."
// form too.
inner = &s[1..];
} else if s.len() > 3 && s.starts_with("__R") {
// On OSX, symbols are prefixed with an extra _
inner = &s[3..];
} else {
return Err(Invalid);
}
// Paths always start with uppercase characters.
match inner.as_bytes()[0] {
b'A'...b'Z' => {}
_ => return Err(Invalid),
}
// only work with ascii text
if inner.bytes().any(|c| c & 0x80 != 0) {
return Err(Invalid);
}
// Verify that the symbol is indeed a valid path.
let mut parser = Parser {
sym: inner,
next: 0,
};
try!(parser.skip_path());
// Instantiating crate (paths always start with uppercase characters).
match parser.sym.as_bytes().get(parser.next) {
Some(&b'A'...b'Z') => {
try!(parser.skip_path());
}
_ => {}
}
Ok((Demangle {
inner: inner,
}, &parser.sym[parser.next..]))
}
impl<'s> Display for Demangle<'s> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let mut printer = Printer {
parser: Ok(Parser {
sym: self.inner,
next: 0,
}),
out: f,
bound_lifetime_depth: 0,
};
printer.print_path(true)
}
}
#[derive(PartialEq, Eq)]
pub struct Invalid;
struct Ident<'s> {
/// ASCII part of the identifier.
ascii: &'s str,
/// Punycode insertion codes for Unicode codepoints, if any.
punycode: &'s str,
}
const SMALL_PUNYCODE_LEN: usize = 128;
impl<'s> Ident<'s> {
/// Attempt to decode punycode on the stack (allocation-free),
/// and pass the char slice to the closure, if successful.
/// This supports up to `SMALL_PUNYCODE_LEN` characters.
fn try_small_punycode_decode<F: FnOnce(&[char]) -> R, R>(
&self,
f: F,
) -> Option<R> {
let mut out = ['\0'; SMALL_PUNYCODE_LEN];
let mut out_len = 0;
let r = self.punycode_decode(|i, c| {
// Check there's space left for another character.
try!(out.get(out_len).ok_or(()));
// Move the characters after the insert position.
let mut j = out_len;
out_len += 1;
while j > i {
out[j] = out[j - 1];
j -= 1;
}
// Insert the new character.
out[i] = c;
Ok(())
});
if r.is_ok() {
Some(f(&out[..out_len]))
} else {
None
}
}
/// Decode punycode as insertion positions and characters
/// and pass them to the closure, which can return `Err(())`
/// to stop the decoding process.
fn punycode_decode<F: FnMut(usize, char) -> Result<(), ()>>(
&self,
mut insert: F,
) -> Result<(), ()> {
let mut punycode_bytes = self.punycode.bytes().peekable();
if punycode_bytes.peek().is_none() {
return Err(());
}
let mut len = 0;
// Populate initial output from ASCII fragment.
for c in self.ascii.chars() {
try!(insert(len, c));
len += 1;
}
// Punycode parameters and initial state.
let base = 36;
let t_min = 1;
let t_max = 26;
let skew = 38;
let mut damp = 700;
let mut bias = 72;
let mut i: usize = 0;
let mut n: usize = 0x80;
loop {
// Read one delta value.
let mut delta: usize = 0;
let mut w = 1;
let mut k: usize = 0;
loop {
use core::cmp::{min, max};
k += base;
let t = min(max(k.saturating_sub(bias), t_min), t_max);
let d = match punycode_bytes.next() {
Some(d @ b'a'...b'z') => d - b'a',
Some(d @ b'0'...b'9') => 26 + (d - b'0'),
_ => return Err(()),
};
let d = d as usize;
delta = try!(delta.checked_add(
try!(d.checked_mul(w).ok_or(()))
).ok_or(()));
if d < t {
break;
}
w = try!(w.checked_mul(base - t).ok_or(()));
}
// Compute the new insert position and character.
len += 1;
i = try!(i.checked_add(delta).ok_or(()));
n = try!(n.checked_add(i / len).ok_or(()));
i %= len;
let n_u32 = n as u32;
let c = if n_u32 as usize == n {
try!(char::from_u32(n_u32).ok_or(()))
} else {
return Err(());
};
// Insert the new character and increment the insert position.
try!(insert(i, c));
i += 1;
// If there are no more deltas, decoding is complete.
if punycode_bytes.peek().is_none() {
return Ok(());
}
// Perform bias adaptation.
delta /= damp;
damp = 2;
delta += delta / len;
let mut k = 0;
while delta > ((base - t_min) * t_max) / 2 {
delta /= base - t_min;
k += base;
}
bias = k + ((base - t_min + 1) * delta) / (delta + skew);
}
}
}
impl<'s> Display for Ident<'s> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.try_small_punycode_decode(|chars| {
for &c in chars {
try!(c.fmt(f));
}
Ok(())
}).unwrap_or_else(|| {
if !self.punycode.is_empty() {
try!(f.write_str("punycode{"));
// Reconstruct a standard Punycode encoding,
// by using `-` as the separator.
if !self.ascii.is_empty() {
try!(f.write_str(self.ascii));
try!(f.write_str("-"));
}
try!(f.write_str(self.punycode));
f.write_str("}")
} else {
f.write_str(self.ascii)
}
})
}
}
fn basic_type(tag: u8) -> Option<&'static str> {
Some(match tag {
b'b' => "bool",
b'c' => "char",
b'e' => "str",
b'u' => "()",
b'a' => "i8",
b's' => "i16",
b'l' => "i32",
b'x' => "i64",
b'n' => "i128",
b'i' => "isize",
b'h' => "u8",
b't' => "u16",
b'm' => "u32",
b'y' => "u64",
b'o' => "u128",
b'j' => "usize",
b'f' => "f32",
b'd' => "f64",
b'z' => "!",
b'p' => "_",
b'v' => "...",
_ => return None,
})
}
struct Parser<'s> {
sym: &'s str,
next: usize,
}
impl<'s> Parser<'s> {
fn peek(&self) -> Option<u8> {
self.sym.as_bytes().get(self.next).cloned()
}
fn eat(&mut self, b: u8) -> bool {
if self.peek() == Some(b) {
self.next += 1;
true
} else {
false
}
}
fn next(&mut self) -> Result<u8, Invalid> {
let b = try!(self.peek().ok_or(Invalid));
self.next += 1;
Ok(b)
}
fn hex_nibbles(&mut self) -> Result<&'s str, Invalid> {
let start = self.next;
loop {
match try!(self.next()) {
b'0'...b'9' | b'a'...b'f' => {}
b'_' => break,
_ => return Err(Invalid),
}
}
Ok(&self.sym[start..self.next - 1])
}
fn digit_10(&mut self) -> Result<u8, Invalid> {
let d = match self.peek() {
Some(d @ b'0'...b'9') => d - b'0',
_ => return Err(Invalid),
};
self.next += 1;
Ok(d)
}
fn digit_62(&mut self) -> Result<u8, Invalid> {
let d = match self.peek() {
Some(d @ b'0'...b'9') => d - b'0',
Some(d @ b'a'...b'z') => 10 + (d - b'a'),
Some(d @ b'A'...b'Z') => 10 + 26 + (d - b'A'),
_ => return Err(Invalid),
};
self.next += 1;
Ok(d)
}
fn integer_62(&mut self) -> Result<u64, Invalid> {
if self.eat(b'_') {
return Ok(0);
}
let mut x: u64 = 0;
while !self.eat(b'_') {
let d = try!(self.digit_62()) as u64;
x = try!(x.checked_mul(62).ok_or(Invalid));
x = try!(x.checked_add(d).ok_or(Invalid));
}
x.checked_add(1).ok_or(Invalid)
}
fn opt_integer_62(&mut self, tag: u8) -> Result<u64, Invalid> {
if !self.eat(tag) {
return Ok(0);
}
try!(self.integer_62()).checked_add(1).ok_or(Invalid)
}
fn disambiguator(&mut self) -> Result<u64, Invalid> {
self.opt_integer_62(b's')
}
fn namespace(&mut self) -> Result<Option<char>, Invalid> {
match try!(self.next()) {
// Special namespaces, like closures and shims.
ns @ b'A'...b'Z' => Ok(Some(ns as char)),
// Implementation-specific/unspecified namespaces.
b'a'...b'z' => Ok(None),
_ => Err(Invalid),
}
}
fn backref(&mut self) -> Result<Parser<'s>, Invalid> {
let s_start = self.next - 1;
let i = try!(self.integer_62());
if i >= s_start as u64 {
return Err(Invalid);
}
Ok(Parser {
sym: self.sym,
next: i as usize,
})
}
fn ident(&mut self) -> Result<Ident<'s>, Invalid> {
let is_punycode = self.eat(b'u');
let mut len = try!(self.digit_10()) as usize;
if len != 0 {
loop {
match self.digit_10() {
Ok(d) => {
len = try!(len.checked_mul(10).ok_or(Invalid));
len = try!(len.checked_add(d as usize).ok_or(Invalid));
}
Err(Invalid) => break,
}
}
}
// Skip past the optional `_` separator.
self.eat(b'_');
let start = self.next;
self.next = try!(self.next.checked_add(len).ok_or(Invalid));
if self.next > self.sym.len() {
return Err(Invalid);
}
let ident = &self.sym[start..self.next];
if is_punycode {
let ident = match ident.bytes().rposition(|b| b == b'_') {
Some(i) => Ident {
ascii: &ident[..i],
punycode: &ident[i + 1..],
},
None => Ident {
ascii: "",
punycode: ident,
},
};
if ident.punycode.is_empty() {
return Err(Invalid);
}
Ok(ident)
} else {
Ok(Ident {
ascii: ident,
punycode: "",
})
}
}
fn skip_path(&mut self) -> Result<(), Invalid> {
match try!(self.next()) {
b'C' => {
try!(self.disambiguator());
try!(self.ident());
}
b'N' => {
try!(self.namespace());
try!(self.skip_path());
try!(self.disambiguator());
try!(self.ident());
}
b'M' => {
try!(self.disambiguator());
try!(self.skip_path());
try!(self.skip_type());
}
b'X' => {
try!(self.disambiguator());
try!(self.skip_path());
try!(self.skip_type());
try!(self.skip_path());
}
b'Y' => {
try!(self.skip_type());
try!(self.skip_path());
}
b'I' => {
try!(self.skip_path());
while !self.eat(b'E') {
try!(self.skip_generic_arg());
}
}
b'B' => {
try!(self.backref());
}
_ => return Err(Invalid),
}
Ok(())
}
fn skip_generic_arg(&mut self) -> Result<(), Invalid> {
if self.eat(b'L') {
try!(self.integer_62());
Ok(())
} else if self.eat(b'K') {
self.skip_const()
} else {
self.skip_type()
}
}
fn skip_type(&mut self) -> Result<(), Invalid> {
match try!(self.next()) {
tag if basic_type(tag).is_some() => {}
b'R' | b'Q' => {
if self.eat(b'L') {
try!(self.integer_62());
}
try!(self.skip_type());
}
b'P' | b'O' | b'S' => try!(self.skip_type()),
b'A' => {
try!(self.skip_type());
try!(self.skip_const());
}
b'T' => while !self.eat(b'E') {
try!(self.skip_type());
},
b'F' => {
let _binder = try!(self.opt_integer_62(b'G'));
let _is_unsafe = self.eat(b'U');
if self.eat(b'K') {
let c_abi = self.eat(b'C');
if !c_abi {
let abi = try!(self.ident());
if abi.ascii.is_empty() || !abi.punycode.is_empty() {
return Err(Invalid);
}
}
}
while !self.eat(b'E') {
try!(self.skip_type());
}
try!(self.skip_type());
}
b'D' => {
let _binder = try!(self.opt_integer_62(b'G'));
while !self.eat(b'E') {
try!(self.skip_path());
while self.eat(b'p') {
try!(self.ident());
try!(self.skip_type());
}
}
if !self.eat(b'L') {
return Err(Invalid);
}
try!(self.integer_62());
}
b'B' => {
try!(self.backref());
}
_ => {
// Go back to the tag, so `skip_path` also sees it.
self.next -= 1;
try!(self.skip_path());
}
}
Ok(())
}
fn skip_const(&mut self) -> Result<(), Invalid> {
if self.eat(b'B') {
try!(self.backref());
return Ok(());
}
match try!(self.next()) {
// Unsigned integer types.
b'h' | b't' | b'm' | b'y' | b'o' | b'j' => {}
_ => return Err(Invalid),
}
if self.eat(b'p') {
return Ok(());
}
try!(self.hex_nibbles());
Ok(())
}
}
struct Printer<'a, 'b: 'a, 's> {
parser: Result<Parser<'s>, Invalid>,
out: &'a mut fmt::Formatter<'b>,
bound_lifetime_depth: u32,
}
/// Mark the parser as errored, print `?` and return early.
/// This allows callers to keep printing the approximate
/// syntax of the path/type/const, despite having errors.
/// E.g. `Vec<[(A, ?); ?]>` instead of `Vec<[(A, ?`.
macro_rules! invalid {
($printer:ident) => {{
$printer.parser = Err(Invalid);
return $printer.out.write_str("?");
}}
}
/// Call a parser method (if the parser hasn't errored yet),
/// and mark the parser as errored if it returns `Err(Invalid)`.
///
/// If the parser errored, before or now, prints `?`, and
/// returns early the current function (see `invalid!` above).
macro_rules! parse {
($printer:ident, $method:ident $(($($arg:expr),*))*) => {
match $printer.parser_mut().and_then(|p| p.$method($($($arg),*)*)) {
Ok(x) => x,
Err(Invalid) => invalid!($printer),
}
};
}
impl<'a, 'b, 's> Printer<'a, 'b, 's> {
fn parser_mut<'c>(&'c mut self) -> Result<&'c mut Parser<'s>, Invalid> {
self.parser.as_mut().map_err(|_| Invalid)
}
/// Eat the given character from the parser,
/// returning `false` if the parser errored.
fn eat(&mut self, b: u8) -> bool {
self.parser_mut().map(|p| p.eat(b)) == Ok(true)
}
/// Return a nested parser for a backref.
fn backref_printer<'c>(&'c mut self) -> Printer<'c, 'b, 's> {
Printer {
parser: self.parser_mut().and_then(|p| p.backref()),
out: self.out,
bound_lifetime_depth: self.bound_lifetime_depth,
}
}
/// Print the lifetime according to the previously decoded index.
/// An index of `0` always refers to `'_`, but starting with `1`,
/// indices refer to late-bound lifetimes introduced by a binder.
fn print_lifetime_from_index(&mut self, lt: u64) -> fmt::Result {
try!(self.out.write_str("'"));
if lt == 0 {
return self.out.write_str("_");
}
match (self.bound_lifetime_depth as u64).checked_sub(lt) {
Some(depth) => {
// Try to print lifetimes alphabetically first.
if depth < 26 {
let c = (b'a' + depth as u8) as char;
c.fmt(self.out)
} else {
// Use `'_123` after running out of letters.
try!(self.out.write_str("_"));
depth.fmt(self.out)
}
}
None => invalid!(self),
}
}
/// Optionally enter a binder ('G') for late-bound lifetimes,
/// printing e.g. `for<'a, 'b> ` before calling the closure,
/// and make those lifetimes visible to it (via depth level).
fn in_binder<F>(&mut self, f: F) -> fmt::Result
where F: FnOnce(&mut Self) -> fmt::Result,
{
let bound_lifetimes = parse!(self, opt_integer_62(b'G'));
if bound_lifetimes > 0 {
try!(self.out.write_str("for<"));
for i in 0..bound_lifetimes {
if i > 0 {
try!(self.out.write_str(", "));
}
self.bound_lifetime_depth += 1;
try!(self.print_lifetime_from_index(1));
}
try!(self.out.write_str("> "));
}
let r = f(self);
// Restore `bound_lifetime_depth` to the previous value.
self.bound_lifetime_depth -= bound_lifetimes as u32;
r
}
/// Print list elements using the given closure and separator,
/// until the end of the list ('E') is found, or the parser errors.
/// Returns the number of elements printed.
fn print_sep_list<F>(&mut self, f: F, sep: &str) -> Result<usize, fmt::Error>
where F: Fn(&mut Self) -> fmt::Result,
{
let mut i = 0;
while self.parser.is_ok() && !self.eat(b'E') {
if i > 0 {
try!(self.out.write_str(sep));
}
try!(f(self));
i += 1;
}
Ok(i)
}
fn print_path(&mut self, in_value: bool) -> fmt::Result {
let tag = parse!(self, next);
match tag {
b'C' => {
let dis = parse!(self, disambiguator);
let name = parse!(self, ident);
try!(name.fmt(self.out));
if !self.out.alternate() {
try!(self.out.write_str("["));
try!(fmt::LowerHex::fmt(&dis, self.out));
try!(self.out.write_str("]"));
}
}
b'N' => {
let ns = parse!(self, namespace);
try!(self.print_path(in_value));
let dis = parse!(self, disambiguator);
let name = parse!(self, ident);
match ns {
// Special namespaces, like closures and shims.
Some(ns) => {
try!(self.out.write_str("::{"));
match ns {
'C' => try!(self.out.write_str("closure")),
'S' => try!(self.out.write_str("shim")),
_ => try!(ns.fmt(self.out)),
}
if !name.ascii.is_empty() || !name.punycode.is_empty() {
try!(self.out.write_str(":"));
try!(name.fmt(self.out));
}
try!(self.out.write_str("#"));
try!(dis.fmt(self.out));
try!(self.out.write_str("}"));
}
// Implementation-specific/unspecified namespaces.
None => {
if !name.ascii.is_empty() || !name.punycode.is_empty() {
try!(self.out.write_str("::"));
try!(name.fmt(self.out));
}
}
}
}
b'M' | b'X' | b'Y' => {
if tag != b'Y' {
// Ignore the `impl`'s own path.
parse!(self, disambiguator);
parse!(self, skip_path);
}
try!(self.out.write_str("<"));
try!(self.print_type());
if tag != b'M' {
try!(self.out.write_str(" as "));
try!(self.print_path(false));
}
try!(self.out.write_str(">"));
}
b'I' => {
try!(self.print_path(in_value));
if in_value {
try!(self.out.write_str("::"));
}
try!(self.out.write_str("<"));
try!(self.print_sep_list(Self::print_generic_arg, ", "));
try!(self.out.write_str(">"));
}
b'B' => {
try!(self.backref_printer().print_path(in_value));
}
_ => invalid!(self),
}
Ok(())
}
fn print_generic_arg(&mut self) -> fmt::Result {
if self.eat(b'L') {
let lt = parse!(self, integer_62);
self.print_lifetime_from_index(lt)
} else if self.eat(b'K') {
self.print_const()
} else {
self.print_type()
}
}
fn print_type(&mut self) -> fmt::Result {
let tag = parse!(self, next);
match basic_type(tag) {
Some(ty) => return self.out.write_str(ty),
None => {}
}
match tag {
b'R' | b'Q' => {
try!(self.out.write_str("&"));
if self.eat(b'L') {
let lt = parse!(self, integer_62);
if lt != 0 {
try!(self.print_lifetime_from_index(lt));
try!(self.out.write_str(" "));
}
}
if tag != b'R' {
try!(self.out.write_str("mut "));
}
try!(self.print_type());
}
b'P' | b'O' => {
try!(self.out.write_str("*"));
if tag != b'P' {
try!(self.out.write_str("mut "));
} else {
try!(self.out.write_str("const "));
}
try!(self.print_type());
}
b'A' | b'S' => {
try!(self.out.write_str("["));
try!(self.print_type());
if tag == b'A' {
try!(self.out.write_str("; "));
try!(self.print_const());
}
try!(self.out.write_str("]"));
}
b'T' => {
try!(self.out.write_str("("));
let count = try!(self.print_sep_list(Self::print_type, ", "));
if count == 1 {
try!(self.out.write_str(","));
}
try!(self.out.write_str(")"));
}
b'F' => try!(self.in_binder(|this| {
let is_unsafe = this.eat(b'U');
let abi = if this.eat(b'K') {
if this.eat(b'C') {
Some("C")
} else {
let abi = parse!(this, ident);
if abi.ascii.is_empty() || !abi.punycode.is_empty() {
invalid!(this);
}
Some(abi.ascii)
}
} else {
None
};
if is_unsafe {
try!(this.out.write_str("unsafe "));
}
match abi {
Some(abi) => {
try!(this.out.write_str("extern \""));
// If the ABI had any `-`, they were replaced with `_`,
// so the parts between `_` have to be re-joined with `-`.
let mut parts = abi.split('_');
try!(this.out.write_str(parts.next().unwrap()));
for part in parts {
try!(this.out.write_str("-"));
try!(this.out.write_str(part));
}
try!(this.out.write_str("\" "));
}
None => {}
}
try!(this.out.write_str("fn("));
try!(this.print_sep_list(Self::print_type, ", "));
try!(this.out.write_str(")"));
if this.eat(b'u') {
// Skip printing the return type if it's 'u', i.e. `()`.
} else {
try!(this.out.write_str(" -> "));
try!(this.print_type());
}
Ok(())
})),
b'D' => {
try!(self.out.write_str("dyn "));
try!(self.in_binder(|this| {
try!(this.print_sep_list(Self::print_dyn_trait, " + "));
Ok(())
}));
if !self.eat(b'L') {
invalid!(self);
}
let lt = parse!(self, integer_62);
if lt != 0 {
try!(self.out.write_str(" + "));
try!(self.print_lifetime_from_index(lt));
}
}
b'B' => {
try!(self.backref_printer().print_type());
}
_ => {
// Go back to the tag, so `print_path` also sees it.
let _ = self.parser_mut().map(|p| p.next -= 1);
try!(self.print_path(false));
}
}
Ok(())
}
/// A trait in a trait object may have some "existential projections"
/// (i.e. associated type bindings) after it, which should be printed
/// in the `<...>` of the trait, e.g. `dyn Trait<T, U, Assoc=X>`.
/// To this end, this method will keep the `<...>` of an 'I' path
/// open, by omitting the `>`, and return `Ok(true)` in that case.
fn print_path_maybe_open_generics(&mut self) -> Result<bool, fmt::Error> {
if self.eat(b'B') {
self.backref_printer().print_path_maybe_open_generics()
} else if self.eat(b'I') {
try!(self.print_path(false));
try!(self.out.write_str("<"));
try!(self.print_sep_list(Self::print_generic_arg, ", "));
Ok(true)
} else {
try!(self.print_path(false));
Ok(false)
}
}
fn print_dyn_trait(&mut self) -> fmt::Result {
let mut open = try!(self.print_path_maybe_open_generics());
while self.eat(b'p') {
if !open {
try!(self.out.write_str("<"));
open = true;
} else {
try!(self.out.write_str(", "));
}
let name = parse!(self, ident);
try!(name.fmt(self.out));
try!(self.out.write_str(" = "));
try!(self.print_type());
}
if open {
try!(self.out.write_str(">"));
}
Ok(())
}
fn print_const(&mut self) -> fmt::Result {
if self.eat(b'B') {
return self.backref_printer().print_const();
}
let ty_tag = parse!(self, next);
let ty = match ty_tag {
// Unsigned integer types.
b'h' | b't' | b'm' | b'y' | b'o' | b'j' => {
basic_type(ty_tag).unwrap()
}
_ => invalid!(self),
};
if self.eat(b'p') {
try!(self.out.write_str("_"));
} else {
try!(self.print_const_uint());
}
if !self.out.alternate() {
try!(self.out.write_str(": "));
try!(self.out.write_str(ty));
}
Ok(())
}
fn print_const_uint(&mut self) -> fmt::Result {
let hex = parse!(self, hex_nibbles);
// Print anything that doesn't fit in `u64` verbatim.
if hex.len() > 16 {
try!(self.out.write_str("0x"));
return self.out.write_str(hex);
}
let mut v = 0;
for c in hex.chars() {
v = (v << 4) | (c.to_digit(16).unwrap() as u64);
}
v.fmt(self.out)
}
}
#[cfg(test)]
mod tests {
macro_rules! t_nohash {
($a:expr, $b:expr) => ({
assert_eq!(format!("{:#}", ::demangle($a)), $b);
})
}
macro_rules! t_nohash_type {
($a:expr, $b:expr) => (
t_nohash!(concat!("_RMC0", $a), concat!("<", $b, ">"))
)
}
#[test]
fn demangle_crate_with_leading_digit() {
t_nohash!(
"_RNvC6_123foo3bar",
"123foo::bar"
);
}
#[test]
fn demangle_utf8_idents() {
t_nohash!(
"_RNqCs4fqI2P2rA04_11utf8_identsu30____7hkackfecea1cbdathfdh9hlq6y",
"utf8_idents::საჭმელად_გემრიელი_სადილი"
);
}
#[test]
fn demangle_closure() {
t_nohash!(
"_RNCNCNgCs6DXkGYLi8lr_2cc5spawn00B5_",
"cc::spawn::{closure#0}::{closure#0}"
);
t_nohash!(
"_RNCINkXs25_NgCsbmNqQUJIY6D_4core5sliceINyB9_4IterhENuNgNoBb_4iter8iterator8Iterator9rpositionNCNgNpB9_6memchr7memrchrs_0E0Bb_",
"<core::slice::Iter<u8> as core::iter::iterator::Iterator>::rposition::<core::slice::memchr::memrchr::{closure#1}>::{closure#0}"
);
}
#[test]
fn demangle_dyn_trait() {
t_nohash!(
"_RINbNbCskIICzLVDPPb_5alloc5alloc8box_freeDINbNiB4_5boxed5FnBoxuEp6OutputuEL_ECs1iopQbuBiw2_3std",
"alloc::alloc::box_free::<dyn alloc::boxed::FnBox<(), Output = ()>>"
);
}
#[test]
fn demangle_const_generics() {
// NOTE(eddyb) this was hand-written, before rustc had working
// const generics support (but the mangling format did include them).
t_nohash_type!(
"INtC8arrayvec8ArrayVechKj7b_E",
"arrayvec::ArrayVec<u8, 123>"
);
}
#[test]
fn demangle_exponential_explosion() {
// NOTE(eddyb) because of the prefix added by `t_nohash_type!` is
// 3 bytes long, `B2_` refers to the start of the type, not `B_`.
// 6 backrefs (`B8_E` through `B3_E`) result in 2^6 = 64 copies of `_`.
// Also, because the `p` (`_`) type is after all of the starts of the
// backrefs, it can be replaced with any other type, independently.
t_nohash_type!(
concat!("TTTTTT", "p", "B8_E", "B7_E", "B6_E", "B5_E", "B4_E", "B3_E"),
"((((((_, _), (_, _)), ((_, _), (_, _))), (((_, _), (_, _)), ((_, _), (_, _)))), \
((((_, _), (_, _)), ((_, _), (_, _))), (((_, _), (_, _)), ((_, _), (_, _))))), \
(((((_, _), (_, _)), ((_, _), (_, _))), (((_, _), (_, _)), ((_, _), (_, _)))), \
((((_, _), (_, _)), ((_, _), (_, _))), (((_, _), (_, _)), ((_, _), (_, _))))))"
);
}
#[test]
fn demangle_thinlto() {
t_nohash!("_RC3foo.llvm.9D1C9369", "foo");
t_nohash!("_RC3foo.llvm.9D1C9369@@16", "foo");
t_nohash!("_RNvC9backtrace3foo.llvm.A5310EB9", "backtrace::foo");
}
#[test]
fn demangle_extra_suffix() {
// From alexcrichton/rustc-demangle#27:
t_nohash!(
"_RNvNtNtNtNtCs92dm3009vxr_4rand4rngs7adapter9reseeding4fork23FORK_HANDLER_REGISTERED.0.0",
"rand::rngs::adapter::reseeding::fork::FORK_HANDLER_REGISTERED.0.0"
);
}
}