use core::str; use cslice::{CSlice, CMutSlice}; use io::{ProtoRead, Read, Write, ProtoWrite, Error}; use self::tag::{Tag, TagIterator, split_tag}; unsafe fn recv_value(reader: &mut R, tag: Tag, data: &mut *mut (), alloc: &dyn Fn(usize) -> Result<*mut (), E>) -> Result<(), E> where R: Read + ?Sized, E: From> { macro_rules! consume_value { ($ty:ty, |$ptr:ident| $map:expr) => ({ let $ptr = (*data) as *mut $ty; *data = $ptr.offset(1) as *mut (); $map }) } match tag { Tag::None => Ok(()), Tag::Bool => consume_value!(u8, |ptr| { *ptr = reader.read_u8()?; Ok(()) }), Tag::Int32 => consume_value!(u32, |ptr| { *ptr = reader.read_u32()?; Ok(()) }), Tag::Int64 | Tag::Float64 => consume_value!(u64, |ptr| { *ptr = reader.read_u64()?; Ok(()) }), Tag::String | Tag::Bytes | Tag::ByteArray => { consume_value!(CMutSlice, |ptr| { let length = reader.read_u32()? as usize; *ptr = CMutSlice::new(alloc(length)? as *mut u8, length); reader.read_exact((*ptr).as_mut())?; Ok(()) }) } Tag::Tuple(it, arity) => { let mut it = it.clone(); for _ in 0..arity { let tag = it.next().expect("truncated tag"); recv_value(reader, tag, data, alloc)? } Ok(()) } Tag::List(it) | Tag::Array(it) => { struct List { elements: *mut (), length: u32 }; consume_value!(List, |ptr| { (*ptr).length = reader.read_u32()?; let tag = it.clone().next().expect("truncated tag"); (*ptr).elements = alloc(tag.size() * (*ptr).length as usize)?; let mut data = (*ptr).elements; for _ in 0..(*ptr).length as usize { recv_value(reader, tag, &mut data, alloc)? } Ok(()) }) } Tag::Range(it) => { let tag = it.clone().next().expect("truncated tag"); recv_value(reader, tag, data, alloc)?; recv_value(reader, tag, data, alloc)?; recv_value(reader, tag, data, alloc)?; Ok(()) } Tag::Keyword(_) => unreachable!(), Tag::Object => unreachable!() } } pub fn recv_return(reader: &mut R, tag_bytes: &[u8], data: *mut (), alloc: &dyn Fn(usize) -> Result<*mut (), E>) -> Result<(), E> where R: Read + ?Sized, E: From> { let mut it = TagIterator::new(tag_bytes); #[cfg(feature = "log")] debug!("recv ...->{}", it); let tag = it.next().expect("truncated tag"); let mut data = data; unsafe { recv_value(reader, tag, &mut data, alloc)? }; Ok(()) } unsafe fn send_value(writer: &mut W, tag: Tag, data: &mut *const ()) -> Result<(), Error> where W: Write + ?Sized { macro_rules! consume_value { ($ty:ty, |$ptr:ident| $map:expr) => ({ let $ptr = (*data) as *const $ty; *data = $ptr.offset(1) as *const (); $map }) } writer.write_u8(tag.as_u8())?; match tag { Tag::None => Ok(()), Tag::Bool => consume_value!(u8, |ptr| writer.write_u8(*ptr)), Tag::Int32 => consume_value!(u32, |ptr| writer.write_u32(*ptr)), Tag::Int64 | Tag::Float64 => consume_value!(u64, |ptr| writer.write_u64(*ptr)), Tag::String => consume_value!(CSlice, |ptr| writer.write_string(str::from_utf8((*ptr).as_ref()).unwrap())), Tag::Bytes | Tag::ByteArray => consume_value!(CSlice, |ptr| writer.write_bytes((*ptr).as_ref())), Tag::Tuple(it, arity) => { let mut it = it.clone(); writer.write_u8(arity)?; for _ in 0..arity { let tag = it.next().expect("truncated tag"); send_value(writer, tag, data)? } Ok(()) } Tag::List(it) | Tag::Array(it) => { struct List { elements: *const (), length: u32 }; consume_value!(List, |ptr| { writer.write_u32((*ptr).length)?; let tag = it.clone().next().expect("truncated tag"); let mut data = (*ptr).elements; for _ in 0..(*ptr).length as usize { send_value(writer, tag, &mut data)?; } Ok(()) }) } Tag::Range(it) => { let tag = it.clone().next().expect("truncated tag"); send_value(writer, tag, data)?; send_value(writer, tag, data)?; send_value(writer, tag, data)?; Ok(()) } Tag::Keyword(it) => { struct Keyword<'a> { name: CSlice<'a, u8> }; consume_value!(Keyword, |ptr| { writer.write_string(str::from_utf8((*ptr).name.as_ref()).unwrap())?; let tag = it.clone().next().expect("truncated tag"); let mut data = ptr.offset(1) as *const (); send_value(writer, tag, &mut data) }) // Tag::Keyword never appears in composite types, so we don't have // to accurately advance data. } Tag::Object => { struct Object { id: u32 }; consume_value!(*const Object, |ptr| writer.write_u32((**ptr).id)) } } } pub fn send_args(writer: &mut W, service: u32, tag_bytes: &[u8], data: *const *const ()) -> Result<(), Error> where W: Write + ?Sized { let (arg_tags_bytes, return_tag_bytes) = split_tag(tag_bytes); let mut args_it = TagIterator::new(arg_tags_bytes); #[cfg(feature = "log")] { let return_it = TagIterator::new(return_tag_bytes); debug!("send<{}>({})->{}", service, args_it, return_it); } writer.write_u32(service)?; for index in 0.. { if let Some(arg_tag) = args_it.next() { let mut data = unsafe { *data.offset(index) }; unsafe { send_value(writer, arg_tag, &mut data)? }; } else { break } } writer.write_u8(0)?; writer.write_bytes(return_tag_bytes)?; Ok(()) } mod tag { use core::fmt; pub fn split_tag(tag_bytes: &[u8]) -> (&[u8], &[u8]) { let tag_separator = tag_bytes.iter() .position(|&b| b == b':') .expect("tag without a return separator"); let (arg_tags_bytes, rest) = tag_bytes.split_at(tag_separator); let return_tag_bytes = &rest[1..]; (arg_tags_bytes, return_tag_bytes) } #[derive(Debug, Clone, Copy)] pub enum Tag<'a> { None, Bool, Int32, Int64, Float64, String, Bytes, ByteArray, Tuple(TagIterator<'a>, u8), List(TagIterator<'a>), Array(TagIterator<'a>), Range(TagIterator<'a>), Keyword(TagIterator<'a>), Object } impl<'a> Tag<'a> { pub fn as_u8(self) -> u8 { match self { Tag::None => b'n', Tag::Bool => b'b', Tag::Int32 => b'i', Tag::Int64 => b'I', Tag::Float64 => b'f', Tag::String => b's', Tag::Bytes => b'B', Tag::ByteArray => b'A', Tag::Tuple(_, _) => b't', Tag::List(_) => b'l', Tag::Array(_) => b'a', Tag::Range(_) => b'r', Tag::Keyword(_) => b'k', Tag::Object => b'O', } } pub fn size(self) -> usize { match self { Tag::None => 0, Tag::Bool => 1, Tag::Int32 => 4, Tag::Int64 => 8, Tag::Float64 => 8, Tag::String => 8, Tag::Bytes => 8, Tag::ByteArray => 8, Tag::Tuple(it, arity) => { let mut size = 0; let mut it = it.clone(); for _ in 0..arity { let tag = it.next().expect("truncated tag"); size += tag.size(); } size } Tag::List(_) => 8, Tag::Array(_) => 8, Tag::Range(it) => { let tag = it.clone().next().expect("truncated tag"); tag.size() * 3 } Tag::Keyword(_) => unreachable!(), Tag::Object => unreachable!(), } } } #[derive(Debug, Clone, Copy)] pub struct TagIterator<'a> { data: &'a [u8] } impl<'a> TagIterator<'a> { pub fn new(data: &'a [u8]) -> TagIterator<'a> { TagIterator { data: data } } pub fn next(&mut self) -> Option> { if self.data.len() == 0 { return None } let tag_byte = self.data[0]; self.data = &self.data[1..]; Some(match tag_byte { b'n' => Tag::None, b'b' => Tag::Bool, b'i' => Tag::Int32, b'I' => Tag::Int64, b'f' => Tag::Float64, b's' => Tag::String, b'B' => Tag::Bytes, b'A' => Tag::ByteArray, b't' => { let count = self.data[0]; self.data = &self.data[1..]; Tag::Tuple(self.sub(count), count) } b'l' => Tag::List(self.sub(1)), b'a' => Tag::Array(self.sub(1)), b'r' => Tag::Range(self.sub(1)), b'k' => Tag::Keyword(self.sub(1)), b'O' => Tag::Object, _ => unreachable!() }) } fn sub(&mut self, count: u8) -> TagIterator<'a> { let data = self.data; for _ in 0..count { self.next().expect("truncated tag"); } TagIterator { data: &data[..(data.len() - self.data.len())] } } } impl<'a> fmt::Display for TagIterator<'a> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let mut it = self.clone(); let mut first = true; while let Some(tag) = it.next() { if first { first = false } else { write!(f, ", ")? } match tag { Tag::None => write!(f, "None")?, Tag::Bool => write!(f, "Bool")?, Tag::Int32 => write!(f, "Int32")?, Tag::Int64 => write!(f, "Int64")?, Tag::Float64 => write!(f, "Float64")?, Tag::String => write!(f, "String")?, Tag::Bytes => write!(f, "Bytes")?, Tag::ByteArray => write!(f, "ByteArray")?, Tag::Tuple(it, _) => { write!(f, "Tuple(")?; it.fmt(f)?; write!(f, ")")?; } Tag::List(it) => { write!(f, "List(")?; it.fmt(f)?; write!(f, ")")?; } Tag::Array(it) => { write!(f, "Array(")?; it.fmt(f)?; write!(f, ")")?; } Tag::Range(it) => { write!(f, "Range(")?; it.fmt(f)?; write!(f, ")")?; } Tag::Keyword(it) => { write!(f, "Keyword(")?; it.fmt(f)?; write!(f, ")")?; } Tag::Object => write!(f, "Object")?, } } Ok(()) } } }