arti-rpcserver 0.43.0

Backend functionality for Arti's RPC service
Documentation
//! An object mapper for looking up `rpc::Object`s by ID.
//!
//! This mapper stores strong or weak references, and uses a generational index
//! to keep track of names for them.
//!
//! TODO RPC: Add an object diagram here once the implementation settles down.

use std::sync::{Arc, Weak};

use rand::RngExt;

use slotmap_careful::{Key as _, KeyData, SlotMap};
use tor_rpcbase as rpc;

pub(crate) mod methods;

slotmap_careful::new_key_type! {
    pub(crate) struct GenIdx;

}

/// A weak or a strong reference to an RPC object.
//
// Note: This type does not pack very efficiently, due to Rust's current lack
// of alignment-based niche optimization.
// If this ever matters, we can either use two slotmaps, or we can implement
// some kind of kludgey hack on our own.
#[derive(Clone, derive_more::From)]
enum ObjectRef {
    /// A strong reference.
    Strong(Arc<dyn rpc::Object>),
    /// A weak reference reference.
    Weak(Weak<dyn rpc::Object>),
}

impl ObjectRef {
    /// Return this reference as an Arc, if it is present.
    fn get(&self) -> Option<Arc<dyn rpc::Object>> {
        match self {
            ObjectRef::Strong(s) => Some(Arc::clone(s)),
            ObjectRef::Weak(w) => w.upgrade(),
        }
    }
}

/// A mechanism to look up RPC `Objects` by their `ObjectId`.
#[derive(Default)]
pub(crate) struct ObjMap {
    /// Generationally indexed arena of strong object references.
    arena: SlotMap<GenIdx, ObjectRef>,
}

/// Encoding functions for GenIdx.
///
/// The encoding is deliberately nondeterministic: we want to avoid situations
/// where applications depend on the details of our ObjectIds, or hardcode the
/// ObjectIds they expect, or rely on the same  weak generational index getting
/// encoded the same way every time they see it.
///
/// The encoding is deliberately non-cryptographic: we do not want to imply
/// that this gives any security. It is just a mild deterrent to misuse.
///
/// If you find yourself wanting to reverse-engineer this code so that you can
/// analyze these object IDs, please contact the Arti developers instead and let
/// us give you a better way to do whatever you want.
impl GenIdx {
    /// The length of a byte-encoded (but not base-64 encoded) GenIdx.
    pub(crate) const BYTE_LEN: usize = 16;

    /// Encode `self` into an rpc::ObjectId that we can give to a client.
    pub(crate) fn encode(self) -> rpc::ObjectId {
        self.encode_with_rng(&mut rand::rng())
    }

    /// As `encode`, but take a Rng as an argument. For testing.
    fn encode_with_rng<R: rand::Rng>(self, rng: &mut R) -> rpc::ObjectId {
        use base64ct::Encoding;
        let bytes = self.to_bytes(rng);
        rpc::ObjectId::from(base64ct::Base64UrlUnpadded::encode_string(&bytes[..]))
    }

    /// As `encode_with_rng`, but return an array of bytes.
    pub(crate) fn to_bytes<R: rand::Rng>(self, rng: &mut R) -> [u8; Self::BYTE_LEN] {
        use tor_bytes::Writer;
        let ffi_idx = self.data().as_ffi();
        let x = rng.random::<u64>();
        let mut bytes = Vec::with_capacity(Self::BYTE_LEN);
        bytes.write_u64(x);
        bytes.write_u64(ffi_idx.wrapping_add(x));

        bytes.try_into().expect("Length was wrong!")
    }

    /// Attempt to decode `id` into a `GenIdx` than an ObjMap can use.
    pub(crate) fn try_decode(id: &rpc::ObjectId) -> Result<Self, rpc::LookupError> {
        use base64ct::Encoding;

        let bytes = base64ct::Base64UrlUnpadded::decode_vec(id.as_ref())
            .map_err(|_| rpc::LookupError::NoObject(id.clone()))?;
        Self::from_bytes(&bytes).ok_or_else(|| rpc::LookupError::NoObject(id.clone()))
    }

    /// As `try_decode`, but take a slice of bytes.
    pub(crate) fn from_bytes(bytes: &[u8]) -> Option<Self> {
        use tor_bytes::Reader;
        let mut r = Reader::from_slice(bytes);
        let x = r.take_u64().ok()?;
        let ffi_idx = r.take_u64().ok()?;
        r.should_be_exhausted().ok()?;

        let ffi_idx = ffi_idx.wrapping_sub(x);
        Some(GenIdx::from(KeyData::from_ffi(ffi_idx)))
    }
}

impl ObjMap {
    /// Create a new empty ObjMap.
    pub(crate) fn new() -> Self {
        Self::default()
    }

    /// Unconditionally insert a strong entry for `value` in self, and return its index.
    pub(crate) fn insert_strong(&mut self, value: Arc<dyn rpc::Object>) -> GenIdx {
        self.arena.insert(ObjectRef::Strong(value))
    }

    /// Unconditionally insert a weak entry for `value` in self, and return its index.
    pub(crate) fn insert_weak(&mut self, value: &Arc<dyn rpc::Object>) -> GenIdx {
        self.arena.insert(ObjectRef::Weak(Arc::downgrade(value)))
    }

    /// Return the entry from this ObjMap for `idx`.
    pub(crate) fn lookup(&self, idx: GenIdx) -> Result<Arc<dyn rpc::Object>, LookupError> {
        self.arena
            .get(idx)
            .ok_or(LookupError::NoObject)?
            .get()
            .ok_or(LookupError::Expired)
    }

    /// Remove the entry at `idx`.
    ///
    /// Return true if anything was removed.
    pub(crate) fn remove(&mut self, idx: GenIdx) -> bool {
        self.arena.remove(idx).is_some()
    }

    /// Testing only: Assert that every invariant for this structure is met.
    #[cfg(test)]
    fn assert_okay(&self) {}
}

/// A failure from ObjMap::lookup.
///
/// (This type is immediately returned into rpc::LookupError before we return it.)
#[derive(Clone, Debug, thiserror::Error)]
pub(crate) enum LookupError {
    /// There was no object with the given ID.
    #[error("Object not found")]
    NoObject,

    /// The object was present, but it was a weak reference that expired.
    #[error("Object expired")]
    Expired,
}

impl LookupError {
    /// Convert this `LookupError` into an [`rpc::LookupError`]
    pub(crate) fn to_rpc_lookup_error(&self, id: rpc::ObjectId) -> rpc::LookupError {
        match self {
            LookupError::NoObject => rpc::LookupError::NoObject(id),
            LookupError::Expired => rpc::LookupError::Expired(id),
        }
    }
}

#[cfg(test)]
mod test {
    // @@ begin test lint list maintained by maint/add_warning @@
    #![allow(clippy::bool_assert_comparison)]
    #![allow(clippy::clone_on_copy)]
    #![allow(clippy::dbg_macro)]
    #![allow(clippy::mixed_attributes_style)]
    #![allow(clippy::print_stderr)]
    #![allow(clippy::print_stdout)]
    #![allow(clippy::single_char_pattern)]
    #![allow(clippy::unwrap_used)]
    #![allow(clippy::unchecked_time_subtraction)]
    #![allow(clippy::useless_vec)]
    #![allow(clippy::needless_pass_by_value)]
    //! <!-- @@ end test lint list maintained by maint/add_warning @@ -->

    use super::*;
    use derive_deftly::Deftly;
    use tor_rpcbase::templates::*;

    #[derive(Clone, Debug, Deftly)]
    #[derive_deftly(Object)]
    struct ExampleObject(#[allow(unused)] String);

    #[test]
    fn map_basics() {
        // Insert an object, make sure it gets inserted twice, and look it up.
        let obj1 = Arc::new(ExampleObject("abcdef".to_string()));
        let mut map = ObjMap::new();
        map.assert_okay();
        let id1 = map.insert_strong(obj1.clone());
        let id2 = map.insert_strong(obj1.clone());
        assert_ne!(id1, id2);
        let obj1: Arc<dyn rpc::Object> = obj1;
        let obj_out1 = map.lookup(id1).unwrap();
        let obj_out2 = map.lookup(id2).unwrap();
        assert!(Arc::ptr_eq(&obj1, &obj_out1));
        assert!(Arc::ptr_eq(&obj1, &obj_out2));
        map.assert_okay();

        map.remove(id1);
        assert!(map.lookup(id1).is_err());
        let obj_out2b = map.lookup(id2).unwrap();
        assert!(Arc::ptr_eq(&obj_out2, &obj_out2b));

        map.assert_okay();
    }

    #[test]
    fn strong_and_weak() {
        // Make sure that a strong object behaves like one, and so does a weak
        // object.
        let obj1: Arc<dyn rpc::Object> = Arc::new(ExampleObject("hello".to_string()));
        let obj2: Arc<dyn rpc::Object> = Arc::new(ExampleObject("world".to_string()));
        let mut map = ObjMap::new();
        let id1 = map.insert_strong(obj1.clone());
        let id2 = map.insert_weak(&obj2);

        {
            let out1 = map.lookup(id1).unwrap();
            let out2 = map.lookup(id2).unwrap();
            assert!(Arc::ptr_eq(&obj1, &out1));
            assert!(Arc::ptr_eq(&obj2, &out2));
        }
        map.assert_okay();

        // Now drop every object we've got, and see what we can still find.
        drop(obj1);
        drop(obj2);
        {
            let out1 = map.lookup(id1);
            let out2 = map.lookup(id2);

            // This one was strong, so it is still there.
            assert!(out1.is_ok());

            // This one is weak so it went away.
            assert!(out2.is_err());
        }
        map.assert_okay();
    }

    #[test]
    fn remove() {
        // Make sure that removing an object makes it go away.
        let obj1: Arc<dyn rpc::Object> = Arc::new(ExampleObject("hello".to_string()));
        let obj2: Arc<dyn rpc::Object> = Arc::new(ExampleObject("world".to_string()));
        let mut map = ObjMap::new();
        let id1 = map.insert_strong(obj1.clone());
        let id2 = map.insert_weak(&obj2);
        map.assert_okay();

        map.remove(id1);
        map.assert_okay();
        assert!(map.lookup(id1).is_err());
        assert!(map.lookup(id2).is_ok());

        map.remove(id2);
        map.assert_okay();
        assert!(map.lookup(id1).is_err());
        assert!(map.lookup(id2).is_err());
    }

    #[test]
    fn duplicates() {
        let obj1: Arc<dyn rpc::Object> = Arc::new(ExampleObject("hello".to_string()));
        let obj2: Arc<dyn rpc::Object> = Arc::new(ExampleObject("world".to_string()));
        let mut map = ObjMap::new();
        let id1 = map.insert_strong(obj1.clone());
        let id2 = map.insert_weak(&obj2);

        {
            assert_ne!(id2, map.insert_weak(&obj1));
            assert_ne!(id2, map.insert_weak(&obj2));
        }

        {
            assert_ne!(id1, map.insert_strong(obj1.clone()));
            assert_ne!(id2, map.insert_strong(obj2.clone()));
        }
    }

    #[test]
    fn objid_encoding() {
        fn test_roundtrip(a: u32, b: u32, rng: &mut tor_basic_utils::test_rng::TestingRng) {
            let a: u64 = a.into();
            let b: u64 = b.into();
            let data = KeyData::from_ffi((a << 33) | (1_u64 << 32) | b);
            let idx = GenIdx::from(data);
            let s1 = idx.encode_with_rng(rng);
            let s2 = idx.encode_with_rng(rng);
            assert_ne!(s1, s2);
            assert_eq!(idx, GenIdx::try_decode(&s1).unwrap());
            assert_eq!(idx, GenIdx::try_decode(&s2).unwrap());
        }
        let mut rng = tor_basic_utils::test_rng::testing_rng();

        test_roundtrip(0, 1, &mut rng);
        test_roundtrip(0, 2, &mut rng);
        test_roundtrip(1, 1, &mut rng);
        test_roundtrip(0xffffffff, 0xffffffff, &mut rng);

        for _ in 0..256 {
            test_roundtrip(rng.random(), rng.random(), &mut rng);
        }
    }
}