// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license. // Think of Resources as File Descriptors. They are integers that are allocated // by the privileged side of Deno which refer to various rust objects that need // to be persisted between various ops. For example, network sockets are // resources. Resources may or may not correspond to a real operating system // file descriptor (hence the different name). use crate::error::bad_resource_id; use crate::error::not_supported; use crate::io::BufMutView; use crate::io::BufView; use crate::io::WriteOutcome; use anyhow::Error; use futures::Future; use std::any::type_name; use std::any::Any; use std::any::TypeId; use std::borrow::Cow; use std::collections::BTreeMap; use std::iter::Iterator; use std::pin::Pin; use std::rc::Rc; /// Returned by resource read/write/shutdown methods pub type AsyncResult = Pin>>>; /// Resources are Rust objects that are attached to a [deno_core::JsRuntime]. /// They are identified in JS by a numeric ID (the resource ID, or rid). /// Resources can be created in ops. Resources can also be retrieved in ops by /// their rid. Resources are not thread-safe - they can only be accessed from /// the thread that the JsRuntime lives on. /// /// Resources are reference counted in Rust. This means that they can be /// cloned and passed around. When the last reference is dropped, the resource /// is automatically closed. As long as the resource exists in the resource /// table, the reference count is at least 1. /// /// ### Readable /// /// Readable resources are resources that can have data read from. Examples of /// this are files, sockets, or HTTP streams. /// /// Readables can be read from from either JS or Rust. In JS one can use /// `Deno.core.read()` to read from a single chunk of data from a readable. In /// Rust one can directly call `read()` or `read_byob()`. The Rust side code is /// used to implement ops like `op_slice`. /// /// A distinction can be made between readables that produce chunks of data /// themselves (they allocate the chunks), and readables that fill up /// bring-your-own-buffers (BYOBs). The former is often the case for framed /// protocols like HTTP, while the latter is often the case for kernel backed /// resources like files and sockets. /// /// All readables must implement `read()`. If resources can support an optimized /// path for BYOBs, they should also implement `read_byob()`. For kernel backed /// resources it often makes sense to implement `read_byob()` first, and then /// implement `read()` as an operation that allocates a new chunk with /// `len == limit`, then calls `read_byob()`, and then returns a chunk sliced to /// the number of bytes read. Kernel backed resources can use the /// [deno_core::impl_readable_byob] macro to implement optimized `read_byob()` /// and `read()` implementations from a single `Self::read()` method. /// /// ### Writable /// /// Writable resources are resources that can have data written to. Examples of /// this are files, sockets, or HTTP streams. /// /// Writables can be written to from either JS or Rust. In JS one can use /// `Deno.core.write()` to write to a single chunk of data to a writable. In /// Rust one can directly call `write()`. The latter is used to implement ops /// like `op_slice`. pub trait Resource: Any + 'static { /// Returns a string representation of the resource which is made available /// to JavaScript code through `op_resources`. The default implementation /// returns the Rust type name, but specific resource types may override this /// trait method. fn name(&self) -> Cow { type_name::().into() } /// Read a single chunk of data from the resource. This operation returns a /// `BufView` that represents the data that was read. If a zero length buffer /// is returned, it indicates that the resource has reached EOF. /// /// If this method is not implemented, the default implementation will error /// with a "not supported" error. /// /// If a readable can provide an optimized path for BYOBs, it should also /// implement `read_byob()`. fn read(self: Rc, limit: usize) -> AsyncResult { _ = limit; Box::pin(futures::future::err(not_supported())) } /// Read a single chunk of data from the resource into the provided `BufMutView`. /// /// This operation returns the number of bytes read. If zero bytes are read, /// it indicates that the resource has reached EOF. /// /// If this method is not implemented explicitly, the default implementation /// will call `read()` and then copy the data into the provided buffer. For /// readable resources that can provide an optimized path for BYOBs, it is /// strongly recommended to override this method. fn read_byob( self: Rc, mut buf: BufMutView, ) -> AsyncResult<(usize, BufMutView)> { Box::pin(async move { let read = self.read(buf.len()).await?; let nread = read.len(); buf[..nread].copy_from_slice(&read); Ok((nread, buf)) }) } /// Write a single chunk of data to the resource. The operation may not be /// able to write the entire chunk, in which case it should return the number /// of bytes written. Additionally it should return the `BufView` that was /// passed in. /// /// If this method is not implemented, the default implementation will error /// with a "not supported" error. fn write(self: Rc, buf: BufView) -> AsyncResult { _ = buf; Box::pin(futures::future::err(not_supported())) } /// Write an entire chunk of data to the resource. Unlike `write()`, this will /// ensure the entire chunk is written. If the operation is not able to write /// the entire chunk, an error is to be returned. /// /// By default this method will call `write()` repeatedly until the entire /// chunk is written. Resources that can write the entire chunk in a single /// operation using an optimized path should override this method. fn write_all(self: Rc, view: BufView) -> AsyncResult<()> { Box::pin(async move { let mut view = view; let this = self; while !view.is_empty() { let resp = this.clone().write(view).await?; match resp { WriteOutcome::Partial { nwritten, view: new_view, } => { view = new_view; view.advance_cursor(nwritten); } WriteOutcome::Full { .. } => break, } } Ok(()) }) } /// The shutdown method can be used to asynchronously close the resource. It /// is not automatically called when the resource is dropped or closed. /// /// If this method is not implemented, the default implementation will error /// with a "not supported" error. fn shutdown(self: Rc) -> AsyncResult<()> { Box::pin(futures::future::err(not_supported())) } /// Resources may implement the `close()` trait method if they need to do /// resource specific clean-ups, such as cancelling pending futures, after a /// resource has been removed from the resource table. fn close(self: Rc) {} /// Resources backed by a file descriptor can let ops know to allow for /// low-level optimizations. #[cfg(unix)] fn backing_fd(self: Rc) -> Option { None } fn size_hint(&self) -> (u64, Option) { (0, None) } } impl dyn Resource { #[inline(always)] fn is(&self) -> bool { self.type_id() == TypeId::of::() } #[inline(always)] #[allow(clippy::needless_lifetimes)] pub fn downcast_rc<'a, T: Resource>(self: &'a Rc) -> Option<&'a Rc> { if self.is::() { let ptr = self as *const Rc<_> as *const Rc; // TODO(piscisaureus): safety comment #[allow(clippy::undocumented_unsafe_blocks)] Some(unsafe { &*ptr }) } else { None } } } /// A `ResourceId` is an integer value referencing a resource. It could be /// considered to be the Deno equivalent of a `file descriptor` in POSIX like /// operating systems. Elsewhere in the code base it is commonly abbreviated /// to `rid`. // TODO: use `u64` instead? pub type ResourceId = u32; /// Map-like data structure storing Deno's resources (equivalent to file /// descriptors). /// /// Provides basic methods for element access. A resource can be of any type. /// Different types of resources can be stored in the same map, and provided /// with a name for description. /// /// Each resource is identified through a _resource ID (rid)_, which acts as /// the key in the map. #[derive(Default)] pub struct ResourceTable { index: BTreeMap>, next_rid: ResourceId, } impl ResourceTable { /// Inserts resource into the resource table, which takes ownership of it. /// /// The resource type is erased at runtime and must be statically known /// when retrieving it through `get()`. /// /// Returns a unique resource ID, which acts as a key for this resource. pub fn add(&mut self, resource: T) -> ResourceId { self.add_rc(Rc::new(resource)) } /// Inserts a `Rc`-wrapped resource into the resource table. /// /// The resource type is erased at runtime and must be statically known /// when retrieving it through `get()`. /// /// Returns a unique resource ID, which acts as a key for this resource. pub fn add_rc(&mut self, resource: Rc) -> ResourceId { let resource = resource as Rc; self.add_rc_dyn(resource) } pub fn add_rc_dyn(&mut self, resource: Rc) -> ResourceId { let rid = self.next_rid; let removed_resource = self.index.insert(rid, resource); assert!(removed_resource.is_none()); self.next_rid += 1; rid } /// Returns true if any resource with the given `rid` exists. pub fn has(&self, rid: ResourceId) -> bool { self.index.contains_key(&rid) } /// Returns a reference counted pointer to the resource of type `T` with the /// given `rid`. If `rid` is not present or has a type different than `T`, /// this function returns `None`. pub fn get(&self, rid: ResourceId) -> Result, Error> { self .index .get(&rid) .and_then(|rc| rc.downcast_rc::()) .map(Clone::clone) .ok_or_else(bad_resource_id) } pub fn get_any(&self, rid: ResourceId) -> Result, Error> { self .index .get(&rid) .map(Clone::clone) .ok_or_else(bad_resource_id) } /// Replaces a resource with a new resource. /// /// Panics if the resource does not exist. pub fn replace(&mut self, rid: ResourceId, resource: T) { let result = self .index .insert(rid, Rc::new(resource) as Rc); assert!(result.is_some()); } /// Removes a resource of type `T` from the resource table and returns it. /// If a resource with the given `rid` exists but its type does not match `T`, /// it is not removed from the resource table. Note that the resource's /// `close()` method is *not* called. /// /// Also note that there might be a case where /// the returned `Rc` is referenced by other variables. That is, we cannot /// assume that `Rc::strong_count(&returned_rc)` is always equal to 1 on success. /// In particular, be really careful when you want to extract the inner value of /// type `T` from `Rc`. pub fn take(&mut self, rid: ResourceId) -> Result, Error> { let resource = self.get::(rid)?; self.index.remove(&rid); Ok(resource) } /// Removes a resource from the resource table and returns it. Note that the /// resource's `close()` method is *not* called. /// /// Also note that there might be a /// case where the returned `Rc` is referenced by other variables. That is, /// we cannot assume that `Rc::strong_count(&returned_rc)` is always equal to 1 /// on success. In particular, be really careful when you want to extract the /// inner value of type `T` from `Rc`. pub fn take_any( &mut self, rid: ResourceId, ) -> Result, Error> { self.index.remove(&rid).ok_or_else(bad_resource_id) } /// Removes the resource with the given `rid` from the resource table. If the /// only reference to this resource existed in the resource table, this will /// cause the resource to be dropped. However, since resources are reference /// counted, therefore pending ops are not automatically cancelled. A resource /// may implement the `close()` method to perform clean-ups such as canceling /// ops. pub fn close(&mut self, rid: ResourceId) -> Result<(), Error> { self .index .remove(&rid) .ok_or_else(bad_resource_id) .map(|resource| resource.close()) } /// Returns an iterator that yields a `(id, name)` pair for every resource /// that's currently in the resource table. This can be used for debugging /// purposes or to implement the `op_resources` op. Note that the order in /// which items appear is not specified. /// /// # Example /// /// ``` /// # use deno_core::ResourceTable; /// # let resource_table = ResourceTable::default(); /// let resource_names = resource_table.names().collect::>(); /// ``` pub fn names(&self) -> impl Iterator)> { self .index .iter() .map(|(&id, resource)| (id, resource.name())) } } #[macro_export] macro_rules! impl_readable_byob { () => { fn read(self: Rc, limit: usize) -> AsyncResult<$crate::BufView> { Box::pin(async move { let mut vec = vec![0; limit]; let nread = self.read(&mut vec).await?; if nread != vec.len() { vec.truncate(nread); } let view = $crate::BufView::from(vec); Ok(view) }) } fn read_byob( self: Rc, mut buf: $crate::BufMutView, ) -> AsyncResult<(usize, $crate::BufMutView)> { Box::pin(async move { let nread = self.read(buf.as_mut()).await?; Ok((nread, buf)) }) } }; } #[macro_export] macro_rules! impl_writable { (__write) => { fn write( self: Rc, view: $crate::BufView, ) -> AsyncResult<$crate::WriteOutcome> { Box::pin(async move { let nwritten = self.write(&view).await?; Ok($crate::WriteOutcome::Partial { nwritten, view }) }) } }; (__write_all) => { fn write_all(self: Rc, view: $crate::BufView) -> AsyncResult<()> { Box::pin(async move { self.write_all(&view).await?; Ok(()) }) } }; () => { $crate::impl_writable!(__write); }; (with_all) => { $crate::impl_writable!(__write); $crate::impl_writable!(__write_all); }; }