extern crate mozpdb;
extern crate getopts;
use mozpdb as pdb;
use pdb::FallibleIterator;
use std::env;
use std::fmt;
use std::io::Write;
use std::collections::BTreeSet;
type TypeSet = BTreeSet<pdb::TypeIndex>;
pub fn type_name<'p>(type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet) -> pdb::Result<String> {
let mut name = match type_finder.find(type_index)?.parse()? {
pdb::TypeData::Primitive(data) => {
let mut name = match data.kind {
pdb::PrimitiveKind::Void => "void".to_string(),
pdb::PrimitiveKind::Char => "char".to_string(),
pdb::PrimitiveKind::UChar => "unsigned char".to_string(),
pdb::PrimitiveKind::I8 => "int8_t".to_string(),
pdb::PrimitiveKind::U8 => "uint8_t".to_string(),
pdb::PrimitiveKind::I16 => "int16_t".to_string(),
pdb::PrimitiveKind::U16 => "uint16_t".to_string(),
pdb::PrimitiveKind::I32 => "int32_t".to_string(),
pdb::PrimitiveKind::U32 => "uint32_t".to_string(),
pdb::PrimitiveKind::I64 => "int64_t".to_string(),
pdb::PrimitiveKind::U64 => "uint64_t".to_string(),
pdb::PrimitiveKind::F32 => "float".to_string(),
pdb::PrimitiveKind::F64 => "double".to_string(),
pdb::PrimitiveKind::Bool8 => "bool".to_string(),
_ => format!("unhandled_primitive.kind /* {:?} */", data.kind),
};
match data.indirection {
pdb::Indirection::None => {},
_ => { name.push(' '); name.push('*'); },
}
name
},
pdb::TypeData::Class(data) => {
needed_types.insert(type_index);
data.name.to_string().into_owned()
},
pdb::TypeData::Enumeration(data) => {
needed_types.insert(type_index);
data.name.to_string().into_owned()
},
pdb::TypeData::Union(data) => {
needed_types.insert(type_index);
data.name.to_string().into_owned()
},
pdb::TypeData::Pointer(data) => {
format!("{}*", type_name(type_finder, data.underlying_type, needed_types)?)
},
pdb::TypeData::Modifier(data) => {
if data.constant {
format!("const {}", type_name(type_finder, data.underlying_type, needed_types)?)
} else if data.volatile {
format!("volatile {}", type_name(type_finder, data.underlying_type, needed_types)?)
} else {
type_name(type_finder, data.underlying_type, needed_types)?
}
},
pdb::TypeData::Array(data) => {
let mut name = type_name(type_finder, data.element_type, needed_types)?;
for size in data.dimensions {
name = format!("{}[{}]", name, size);
}
name
},
_ => format!("Type{} /* TODO: figure out how to name it */", type_index)
};
if name == "std::basic_string<char,std::char_traits<char>,std::allocator<char> >" {
name = "std::string".to_string();
}
Ok(name)
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct Class<'p> {
kind: pdb::ClassKind,
name: pdb::RawString<'p>,
base_classes: Vec<BaseClass>,
fields: Vec<Field<'p>>,
instance_methods: Vec<Method<'p>>,
static_methods: Vec<Method<'p>>,
}
impl<'p> Class<'p> {
fn add_derived_from(&mut self, _: &pdb::TypeFinder<'p>, _: pdb::TypeIndex, _: &mut TypeSet) -> pdb::Result<()> {
Ok(())
}
fn add_fields(&mut self, type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet) -> pdb::Result<()> {
match type_finder.find(type_index)?.parse()? {
pdb::TypeData::FieldList(data) => {
for ref field in data.fields {
self.add_field(type_finder, field, needed_types)?;
}
if let Some(continuation) = data.continuation {
self.add_fields(type_finder, continuation, needed_types)?;
}
}
other => {
println!("trying to Class::add_fields() got {} -> {:?}", type_index, other);
panic!("unexpected type in Class::add_fields()");
}
}
Ok(())
}
fn add_field(&mut self, type_finder: &pdb::TypeFinder<'p>, field: &pdb::TypeData<'p>, needed_types: &mut TypeSet) -> pdb::Result<()> {
match field {
&pdb::TypeData::Member(ref data) => {
self.fields.push(Field{
type_name: type_name(type_finder, data.field_type, needed_types)?,
name: data.name.clone(),
offset: data.offset,
});
},
&pdb::TypeData::Method(ref data) => {
let method = Method::find(data.name.clone(), data.attributes, type_finder, data.method_type, needed_types)?;
if data.attributes.is_static() {
self.static_methods.push(method);
} else {
self.instance_methods.push(method);
}
},
&pdb::TypeData::OverloadedMethod(ref data) => {
match type_finder.find(data.method_list)?.parse()? {
pdb::TypeData::MethodList(method_list) => {
let mut iter = method_list.methods.into_iter();
while let Some(pdb::MethodListEntry { attributes, method_type, .. }) = iter.next() {
let method = Method::find(data.name.clone(), attributes, type_finder, method_type, needed_types)?;
if attributes.is_static() {
self.static_methods.push(method);
} else {
self.instance_methods.push(method);
}
}
}
other => {
println!("processing OverloadedMethod, expected MethodList, got {} -> {:?}", data.method_list, other);
panic!("unexpected type in Class::add_field()");
}
}
},
&pdb::TypeData::BaseClass(ref data) => {
self.base_classes.push(BaseClass{
type_name: type_name(type_finder, data.base_class, needed_types)?,
offset: data.offset,
})
},
&pdb::TypeData::VirtualBaseClass(ref data) => {
self.base_classes.push(BaseClass{
type_name: type_name(type_finder, data.base_class, needed_types)?,
offset: data.base_pointer_offset,
})
},
_ => {
}
}
Ok(())
}
}
impl<'p> fmt::Display for Class<'p> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{} {} ", match self.kind {
pdb::ClassKind::Class => "class",
pdb::ClassKind::Struct => "struct",
pdb::ClassKind::Interface => "interface", }, self.name.to_string())?;
if self.base_classes.len() > 0 {
for (i, base) in self.base_classes.iter().enumerate() {
let prefix = match i {
0 => ":",
_ => ","
};
write!(f, "{} {}", prefix, base.type_name)?;
}
}
writeln!(f, " {{")?;
for base in &self.base_classes {
writeln!(f, "\t/* offset {:3} */ /* fields for {} */", base.offset, base.type_name)?;
}
for ref field in &self.fields {
writeln!(f, "\t/* offset {:3} */ {} {};", field.offset, field.type_name, field.name.to_string())?;
}
if !self.instance_methods.is_empty() {
writeln!(f, "\t")?;
for method in self.instance_methods.iter() {
writeln!(f, "\t{}{} {}({});",
if method.is_virtual { "virtual " } else { "" },
method.return_type_name,
method.name.to_string(),
method.arguments.join(", ")
)?;
}
}
if !self.static_methods.is_empty() {
writeln!(f, "\t")?;
for method in self.static_methods.iter() {
writeln!(f, "\t{}static {} {}({});",
if method.is_virtual { "virtual " } else { "" },
method.return_type_name,
method.name.to_string(),
method.arguments.join(", ")
)?;
}
}
writeln!(f, "}}")?;
Ok(())
}
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct BaseClass {
type_name: String,
offset: u32,
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct Field<'p> {
type_name: String,
name: pdb::RawString<'p>,
offset: u16,
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct Method<'p> {
name: pdb::RawString<'p>,
return_type_name: String,
arguments: Vec<String>,
is_virtual: bool,
}
impl<'p> Method<'p> {
fn find(
name: pdb::RawString<'p>, attributes: pdb::FieldAttributes,
type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet
) -> pdb::Result<Method<'p>>
{
match type_finder.find(type_index)?.parse()? {
pdb::TypeData::MemberFunction(data) => {
Ok(Method{
name: name,
return_type_name: type_name(type_finder, data.return_type, needed_types)?,
arguments: argument_list(type_finder, data.argument_list, needed_types)?,
is_virtual: attributes.is_virtual(),
})
},
other => {
println!("other: {:?}", other);
Err(pdb::Error::UnimplementedFeature("that"))
}
}
}
}
fn argument_list<'p>(type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet) -> pdb::Result<Vec<String>> {
match type_finder.find(type_index)?.parse()? {
pdb::TypeData::ArgumentList(data) => {
let mut args: Vec<String> = Vec::new();
for arg_type in data.arguments {
args.push(type_name(type_finder, arg_type, needed_types)?);
}
Ok(args)
}
_ => {
Err(pdb::Error::UnimplementedFeature("argument list of non-argument-list type"))
}
}
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct Enum<'p> {
name: pdb::RawString<'p>,
underlying_type_name: String,
values: Vec<EnumValue<'p>>,
}
impl<'p> Enum<'p> {
fn add_fields(&mut self, type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet) -> pdb::Result<()> {
match type_finder.find(type_index)?.parse()? {
pdb::TypeData::FieldList(data) => {
for ref field in data.fields {
self.add_field(type_finder, field, needed_types)?;
}
if let Some(continuation) = data.continuation {
self.add_fields(type_finder, continuation, needed_types)?;
}
}
other => {
println!("trying to Enum::add_fields() got {} -> {:?}", type_index, other);
panic!("unexpected type in Enum::add_fields()");
}
}
Ok(())
}
fn add_field(&mut self, _: &pdb::TypeFinder<'p>, field: &pdb::TypeData<'p>, _: &mut TypeSet) -> pdb::Result<()> {
match field {
&pdb::TypeData::Enumerate(ref data) => {
self.values.push(EnumValue{
name: data.name.clone(),
value: data.value,
});
},
_ => {
}
}
Ok(())
}
}
impl<'p> fmt::Display for Enum<'p> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
writeln!(f, "enum {} /* stored as {} */ {{", self.name.to_string(), self.underlying_type_name)?;
for value in &self.values {
writeln!(f, "\t{} = {},", value.name.to_string(), match value.value {
pdb::Variant::U8(v) => format!("0x{:02x}", v),
pdb::Variant::U16(v) => format!("0x{:04x}", v),
pdb::Variant::U32(v) => format!("0x{:08x}", v),
pdb::Variant::U64(v) => format!("0x{:16x}", v),
pdb::Variant::I8(v) => format!("{}", v),
pdb::Variant::I16(v) => format!("{}", v),
pdb::Variant::I32(v) => format!("{}", v),
pdb::Variant::I64(v) => format!("{}", v),
})?;
}
writeln!(f, "}}")?;
Ok(())
}
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct EnumValue<'p> {
name: pdb::RawString<'p>,
value: pdb::Variant,
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct ForwardReference<'p> {
kind: pdb::ClassKind,
name: pdb::RawString<'p>,
}
impl<'p> fmt::Display for ForwardReference<'p> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
writeln!(f, "{} {};", match self.kind {
pdb::ClassKind::Class => "class",
pdb::ClassKind::Struct => "struct",
pdb::ClassKind::Interface => "interface", }, self.name.to_string())
}
}
#[derive(Debug,Clone,PartialEq,Eq)]
struct Data<'p> {
forward_references: Vec<ForwardReference<'p>>,
classes: Vec<Class<'p>>,
enums: Vec<Enum<'p>>,
}
impl<'p> fmt::Display for Data<'p> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
writeln!(f, "// automatically generated by pdb2hpp\n// do not edit")?;
if !self.forward_references.is_empty() {
writeln!(f, "")?;
for e in self.forward_references.iter() {
e.fmt(f)?;
}
}
for e in self.enums.iter() {
writeln!(f, "")?;
e.fmt(f)?;
}
for class in self.classes.iter() {
writeln!(f, "")?;
class.fmt(f)?;
}
Ok(())
}
}
impl<'p> Data<'p> {
fn new() -> Data<'p> {
Data{
forward_references: Vec::new(),
classes: Vec::new(),
enums: Vec::new(),
}
}
fn add(&mut self, type_finder: &pdb::TypeFinder<'p>, type_index: pdb::TypeIndex, needed_types: &mut TypeSet) -> pdb::Result<()> {
match type_finder.find(type_index)?.parse()? {
pdb::TypeData::Class(data) => {
if data.properties.forward_reference() {
self.forward_references.push(ForwardReference{
kind: data.kind,
name: data.name,
});
return Ok(());
}
let mut class = Class{
kind: data.kind,
name: data.name,
fields: Vec::new(),
base_classes: Vec::new(),
instance_methods: Vec::new(),
static_methods: Vec::new(),
};
if let Some(derived_from) = data.derived_from {
class.add_derived_from(type_finder, derived_from, needed_types)?;
}
if let Some(fields) = data.fields {
class.add_fields(type_finder, fields, needed_types)?;
}
self.classes.insert(0, class);
}
pdb::TypeData::Enumeration(data) => {
let mut e = Enum{
name: data.name,
underlying_type_name: type_name(type_finder, data.underlying_type, needed_types)?,
values: Vec::new(),
};
e.add_fields(type_finder, data.fields, needed_types)?;
self.enums.insert(0, e);
}
other => {
writeln!(&mut std::io::stderr(), "warning: don't know how to add {:?}", other).expect("stderr write");;
}
}
Ok(())
}
}
fn write_class(filename: &str, class_name: &str) -> pdb::Result<()> {
let file = std::fs::File::open(filename)?;
let mut pdb = pdb::PDB::open(file)?;
let type_information = pdb.type_information()?;
let mut type_finder = type_information.new_type_finder();
let mut needed_types = TypeSet::new();
let mut data = Data::new();
let mut type_iter = type_information.iter();
while let Some(typ) = type_iter.next()? {
type_finder.update(&type_iter);
if let Ok(pdb::TypeData::Class(class)) = typ.parse() {
if class.name.as_bytes() == class_name.as_bytes() && !class.properties.forward_reference() {
data.add(&type_finder, typ.type_index(), &mut needed_types)?;
break;
}
}
}
loop {
let last = match needed_types.iter().next_back() {
Some(n) => Some(*n),
None => None
};
if let Some(type_index) = last {
needed_types.remove(&type_index);
data.add(&type_finder, type_index, &mut needed_types)?;
} else {
break
}
}
if data.classes.len() == 0 {
writeln!(&mut std::io::stderr(), "sorry, class {} was not found", class_name)
.expect("stderr write");
} else {
println!("{}", data);
}
Ok(())
}
fn print_usage(program: &str, opts: getopts::Options) {
let brief = format!("Usage: {} input.pdb ClassName", program);
print!("{}", opts.usage(&brief));
}
fn main() {
let args: Vec<String> = env::args().collect();
let program = args[0].clone();
let mut opts = getopts::Options::new();
opts.optflag("h", "help", "print this help menu");
let matches = match opts.parse(&args[1..]) {
Ok(m) => { m }
Err(f) => { panic!(f.to_string()) }
};
let (filename, class_name) = if matches.free.len() == 2 {
(&matches.free[0], &matches.free[1])
} else {
print_usage(&program, opts);
return;
};
match write_class(&filename, &class_name) {
Ok(_) => {}
Err(e) => {
writeln!(&mut std::io::stderr(), "error dumping PDB: {}", e)
.expect("stderr write");
}
}
}