@ -1,7 +1,11 @@
//! Asyncronous `AsyncRead` wrapper.
//! Asyncronous `AsyncRead` wrapper.
use super ::* ;
use super ::* ;
use tokio ::io ::AsyncRead ;
/// TODO: Document
/// Asyncronous ChaCha source.
/// En/decrypts information from the source async reader.
///
/// This is the `Read` implementing counterpart to `AsyncSink`.
//#[derive(Debug)]
//#[derive(Debug)]
#[ pin_project ]
#[ pin_project ]
pub struct Source < R >
pub struct Source < R >
@ -12,3 +16,134 @@ pub struct Source<R>
buffer : BufferVec , // used to buffer the operation (ad-hoc-buffer wouldn't work for async operations as the buffer may need to be saved over yields.)
buffer : BufferVec , // used to buffer the operation (ad-hoc-buffer wouldn't work for async operations as the buffer may need to be saved over yields.)
}
}
impl < R : fmt ::Debug > fmt ::Debug for Source < R >
{
fn fmt ( & self , f : & mut fmt ::Formatter < ' _ > ) -> fmt ::Result
{
write! ( f , "Source({:?}, ({} buffer cap))" , self . stream , self . buffer . capacity ( ) )
}
}
/// Perform the cipher transform on the inner buffer, writing to the output buffer, returning the number of bytes updated.
fn transform ( crypter : & mut Crypter , buf : & [ u8 ] , buffer : & mut [ u8 ] ) -> Result < usize , ErrorStack >
{
//if buf.len() > self.buffer.len() {
//buf.resize(buffer.len(), 0);
//}
let n = crypter . update ( & buf [ .. ] , & mut buffer [ .. ] ) ? ;
let _f = crypter . finalize ( & mut buffer [ .. n ] ) ? ; // I don't know if this is needed.
debug_assert_eq! ( _f , 0 ) ;
Ok ( n )
}
impl < R : AsyncRead > Source < R >
{
/// Create a new async Chacha Source stream wrapper
#[ inline ] fn new ( stream : R , crypter : Crypter ) -> Self
{
Self { stream , crypter , buffer : BufferVec ::new ( ) }
}
/// Create an encrypting Chacha Source stream wrapper
pub fn encrypt ( stream : R , key : Key , iv : IV ) -> Result < Self , Error >
{
Ok ( Self ::new ( stream , cha ::encrypter ( key , iv ) ? ) )
}
/// Create a decrypting Chacha Source stream wrapper
pub fn decrypt ( stream : R , key : Key , iv : IV ) -> Result < Self , Error >
{
Ok ( Self ::new ( stream , cha ::decrypter ( key , iv ) ? ) )
}
/// Consume into the inner stream
#[ inline ] pub fn into_inner ( self ) -> R
{
self . stream
}
/// Consume into the inner stream and crypter
#[ inline ] pub fn into_parts ( self ) -> ( R , Crypter )
{
( self . stream , self . crypter )
}
/// The crypter of this instance
#[ inline ] pub fn crypter ( & self ) -> & Crypter
{
& self . crypter
}
/// The crypter of this instance
#[ inline ] pub fn crypter_mut ( & mut self ) -> & mut Crypter
{
& mut self . crypter
}
/// The inner stream
#[ inline ] pub fn inner ( & self ) -> & R
{
& self . stream
}
/// The inner stream
#[ inline ] pub fn inner_mut ( & mut self ) -> & mut R
{
& mut self . stream
}
/// Clear the internal buffer while keeping it allocated for further use.
///
/// This does not affect operations at all, all it does is 0 out the left-over temporary buffer from the last operation(s).
#[ inline ]
pub fn prune ( & mut self )
{
#[ cfg(feature= " explicit_clear " ) ]
{
bytes ::explicit_prune ( & mut self . buffer [ .. ] ) ;
return ;
}
#[ cfg(not(feature= " explicit_clear " )) ]
unsafe {
std ::ptr ::write_bytes ( self . buffer . as_mut_ptr ( ) , 0 , self . buffer . len ( ) ) ;
}
}
}
//When implementing `poll`, we check if buffer is empty on poll, and if it isn't, poll backing stream to write it. Then, clear buffer after `Poll::Ready` on backing stream's write.
impl < R : AsyncRead > AsyncRead for Source < R >
{
fn poll_read ( self : Pin < & mut Self > , cx : & mut Context < ' _ > , buf : & mut [ u8 ] ) -> Poll < Result < usize , io ::Error > > {
let this = self . project ( ) ;
if this . buffer . is_empty ( ) {
this . buffer . resize ( buf . len ( ) , 0 ) ;
}
debug_assert_eq! ( buf . len ( ) , this . buffer . len ( ) ) ;
let poll = this . stream . poll_read ( cx , & mut this . buffer [ .. ] ) ;
match poll {
Poll ::Ready ( Ok ( read ) ) = > {
// Data read, perform transform.
let n = transform ( this . crypter , & this . buffer [ .. read ] , & mut buf [ .. read ] ) ? ;
debug_assert_eq! ( n , read ) ;
// Reset buffer size to 0, so we know the next call will be on a new buffer, and we can resize it to the correct size again
if cfg! ( feature = "explicit_clear" ) {
bytes ::explicit_prune ( & mut this . buffer [ .. ] ) ;
} // XXX: Should we blank the buffer here? Or is just a `.clear()` alright?
this . buffer . clear ( ) ;
Poll ::Ready ( Ok ( n ) )
} ,
other = > other
}
}
}