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// SPDX-License-Identifier: MPL-2.0
//! Implements the Ping-Pong Topology described in [VDAF]. This topology assumes there are exactly
//! two aggregators, designated "Leader" and "Helper". This topology is required for implementing
//! the [Distributed Aggregation Protocol][DAP].
//!
use crate::{
codec::{decode_u32_items, encode_u32_items, CodecError, Decode, Encode, ParameterizedDecode},
vdaf::{Aggregator, PrepareTransition, VdafError},
};
use std::fmt::Debug;
/// Errors emitted by this module.
#[derive(Debug, thiserror::Error)]
#[non_exhaustive]
pub enum PingPongError {
/// Error running prepare_init
#[error("vdaf.prepare_init: {0}")]
VdafPrepareInit(VdafError),
/// Error running prepare_shares_to_prepare_message
#[error("vdaf.prepare_shares_to_prepare_message {0}")]
VdafPrepareSharesToPrepareMessage(VdafError),
/// Error running prepare_next
#[error("vdaf.prepare_next {0}")]
VdafPrepareNext(VdafError),
/// Error encoding or decoding a prepare share
#[error("encode/decode prep share {0}")]
CodecPrepShare(CodecError),
/// Error encoding or decoding a prepare message
#[error("encode/decode prep message {0}")]
CodecPrepMessage(CodecError),
/// Host is in an unexpected state
#[error("host state mismatch: in {found} expected {expected}")]
HostStateMismatch {
/// The state the host is in.
found: &'static str,
/// The state the host expected to be in.
expected: &'static str,
},
/// Message from peer indicates it is in an unexpected state
#[error("peer message mismatch: message is {found} expected {expected}")]
PeerMessageMismatch {
/// The state in the message from the peer.
found: &'static str,
/// The message expected from the peer.
expected: &'static str,
},
/// Internal error
#[error("internal error: {0}")]
InternalError(&'static str),
}
/// Corresponds to `struct Message` in [VDAF's Ping-Pong Topology][VDAF]. All of the fields of the
/// variants are opaque byte buffers. This is because the ping-pong routines take responsibility for
/// decoding preparation shares and messages, which usually requires having the preparation state.
///
#[derive(Clone, PartialEq, Eq)]
pub enum PingPongMessage {
/// Corresponds to MessageType.initialize.
Initialize {
/// The leader's initial preparation share.
prep_share: Vec<u8>,
},
/// Corresponds to MessageType.continue.
Continue {
/// The current round's preparation message.
prep_msg: Vec<u8>,
/// The next round's preparation share.
prep_share: Vec<u8>,
},
/// Corresponds to MessageType.finish.
Finish {
/// The current round's preparation message.
prep_msg: Vec<u8>,
},
}
impl PingPongMessage {
fn variant(&self) -> &'static str {
match self {
Self::Initialize { .. } => "Initialize",
Self::Continue { .. } => "Continue",
Self::Finish { .. } => "Finish",
}
}
}
impl Debug for PingPongMessage {
// We want `PingPongMessage` to implement `Debug`, but we don't want that impl to print out
// prepare shares or messages, because (1) their contents are sensitive and (2) their contents
// are long and not intelligible to humans. For both reasons they generally shouldn't get
// logged. Normally, we'd use the `derivative` crate to customize a derived `Debug`, but that
// crate has not been audited (in the `cargo vet` sense) so we can't use it here unless we audit
// 8,000+ lines of proc macros.
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
f.debug_tuple(self.variant()).finish()
}
}
impl Encode for PingPongMessage {
fn encode(&self, bytes: &mut Vec<u8>) -> Result<(), CodecError> {
// The encoding includes an implicit discriminator byte, called MessageType in the VDAF
// spec.
match self {
Self::Initialize { prep_share } => {
0u8.encode(bytes)?;
encode_u32_items(bytes, &(), prep_share)?;
}
Self::Continue {
prep_msg,
prep_share,
} => {
1u8.encode(bytes)?;
encode_u32_items(bytes, &(), prep_msg)?;
encode_u32_items(bytes, &(), prep_share)?;
}
Self::Finish { prep_msg } => {
2u8.encode(bytes)?;
encode_u32_items(bytes, &(), prep_msg)?;
}
}
Ok(())
}
fn encoded_len(&self) -> Option<usize> {
match self {
Self::Initialize { prep_share } => Some(1 + 4 + prep_share.len()),
Self::Continue {
prep_msg,
prep_share,
} => Some(1 + 4 + prep_msg.len() + 4 + prep_share.len()),
Self::Finish { prep_msg } => Some(1 + 4 + prep_msg.len()),
}
}
}
impl Decode for PingPongMessage {
fn decode(bytes: &mut std::io::Cursor<&[u8]>) -> Result<Self, CodecError> {
let message_type = u8::decode(bytes)?;
Ok(match message_type {
0 => {
let prep_share = decode_u32_items(&(), bytes)?;
Self::Initialize { prep_share }
}
1 => {
let prep_msg = decode_u32_items(&(), bytes)?;
let prep_share = decode_u32_items(&(), bytes)?;
Self::Continue {
prep_msg,
prep_share,
}
}
2 => {
let prep_msg = decode_u32_items(&(), bytes)?;
Self::Finish { prep_msg }
}
_ => return Err(CodecError::UnexpectedValue),
})
}
}
/// A transition in the pong-pong topology. This represents the `ping_pong_transition` function
/// defined in [VDAF].
///
/// # Discussion
///
/// The obvious implementation of `ping_pong_transition` would be a method on trait
/// [`PingPongTopology`] that returns `(State, Message)`, and then `ContinuedValue::WithMessage`
/// would contain those values. But then DAP implementations would have to store relatively large
/// VDAF prepare shares between rounds of input preparation.
///
/// Instead, this structure stores just the previous round's prepare state and the current round's
/// preprocessed prepare message. Their encoding is much smaller than the `(State, Message)` tuple,
/// which can always be recomputed with [`Self::evaluate`].
///
#[derive(Clone, Debug, Eq)]
pub struct PingPongTransition<
const VERIFY_KEY_SIZE: usize,
const NONCE_SIZE: usize,
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
> {
previous_prepare_state: A::PrepareState,
current_prepare_message: A::PrepareMessage,
}
impl<
const VERIFY_KEY_SIZE: usize,
const NONCE_SIZE: usize,
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
> PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, A>
{
/// Evaluate this transition to obtain a new [`PingPongState`] and a [`PingPongMessage`] which
/// should be transmitted to the peer.
#[allow(clippy::type_complexity)]
pub fn evaluate(
&self,
vdaf: &A,
) -> Result<
(
PingPongState<VERIFY_KEY_SIZE, NONCE_SIZE, A>,
PingPongMessage,
),
PingPongError,
> {
let prep_msg = self
.current_prepare_message
.get_encoded()
.map_err(PingPongError::CodecPrepMessage)?;
vdaf.prepare_next(
self.previous_prepare_state.clone(),
self.current_prepare_message.clone(),
)
.map_err(PingPongError::VdafPrepareNext)
.and_then(|transition| match transition {
PrepareTransition::Continue(prep_state, prep_share) => Ok((
PingPongState::Continued(prep_state),
PingPongMessage::Continue {
prep_msg,
prep_share: prep_share
.get_encoded()
.map_err(PingPongError::CodecPrepShare)?,
},
)),
PrepareTransition::Finish(output_share) => Ok((
PingPongState::Finished(output_share),
PingPongMessage::Finish { prep_msg },
)),
})
}
}
impl<
const VERIFY_KEY_SIZE: usize,
const NONCE_SIZE: usize,
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
> PartialEq for PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, A>
{
fn eq(&self, other: &Self) -> bool {
self.previous_prepare_state == other.previous_prepare_state
&& self.current_prepare_message == other.current_prepare_message
}
}
impl<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize, A> Encode
for PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, A>
where
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
A::PrepareState: Encode,
{
fn encode(&self, bytes: &mut Vec<u8>) -> Result<(), CodecError> {
self.previous_prepare_state.encode(bytes)?;
self.current_prepare_message.encode(bytes)
}
fn encoded_len(&self) -> Option<usize> {
Some(
self.previous_prepare_state.encoded_len()?
+ self.current_prepare_message.encoded_len()?,
)
}
}
impl<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize, A, PrepareStateDecode>
ParameterizedDecode<PrepareStateDecode> for PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, A>
where
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
A::PrepareState: ParameterizedDecode<PrepareStateDecode> + PartialEq,
A::PrepareMessage: PartialEq,
{
fn decode_with_param(
decoding_param: &PrepareStateDecode,
bytes: &mut std::io::Cursor<&[u8]>,
) -> Result<Self, CodecError> {
let previous_prepare_state = A::PrepareState::decode_with_param(decoding_param, bytes)?;
let current_prepare_message =
A::PrepareMessage::decode_with_param(&previous_prepare_state, bytes)?;
Ok(Self {
previous_prepare_state,
current_prepare_message,
})
}
}
/// Corresponds to the `State` enumeration implicitly defined in [VDAF's Ping-Pong Topology][VDAF].
/// VDAF describes `Start` and `Rejected` states, but the `Start` state is never instantiated in
/// code, and the `Rejected` state is represented as `std::result::Result::Err`, so this enum does
/// not include those variants.
///
#[derive(Clone, Debug, PartialEq, Eq)]
pub enum PingPongState<
const VERIFY_KEY_SIZE: usize,
const NONCE_SIZE: usize,
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
> {
/// Preparation of the report will continue with the enclosed state.
Continued(A::PrepareState),
/// Preparation of the report is finished and has yielded the enclosed output share.
Finished(A::OutputShare),
}
/// Values returned by [`PingPongTopology::leader_continued`] or
/// [`PingPongTopology::helper_continued`].
#[derive(Clone, Debug)]
pub enum PingPongContinuedValue<
const VERIFY_KEY_SIZE: usize,
const NONCE_SIZE: usize,
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
> {
/// The operation resulted in a new state and a message to transmit to the peer.
WithMessage {
/// The transition that will be executed. Call `PingPongTransition::evaluate` to obtain the
/// next
/// [`PingPongState`] and a [`PingPongMessage`] to transmit to the peer.
transition: PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, A>,
},
/// The operation caused the host to finish preparation of the input share, yielding an output
/// share and no message for the peer.
FinishedNoMessage {
/// The output share which may now be accumulated.
output_share: A::OutputShare,
},
}
/// Extension trait on [`crate::vdaf::Aggregator`] which adds the [VDAF Ping-Pong Topology][VDAF].
///
pub trait PingPongTopology<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize>:
Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>
{
/// Specialization of [`PingPongState`] for this VDAF.
type State;
/// Specialization of [`PingPongContinuedValue`] for this VDAF.
type ContinuedValue;
/// Specializaton of [`PingPongTransition`] for this VDAF.
type Transition;
/// Initialize leader state using the leader's input share. Corresponds to
/// `ping_pong_leader_init` in [VDAF].
///
/// If successful, the returned [`PingPongMessage`] (which will always be
/// `PingPongMessage::Initialize`) should be transmitted to the helper. The returned
/// [`PingPongState`] (which will always be `PingPongState::Continued`) should be used by the
/// leader along with the next [`PingPongMessage`] received from the helper as input to
/// [`Self::leader_continued`] to advance to the next round.
///
fn leader_initialized(
&self,
verify_key: &[u8; VERIFY_KEY_SIZE],
agg_param: &Self::AggregationParam,
nonce: &[u8; NONCE_SIZE],
public_share: &Self::PublicShare,
input_share: &Self::InputShare,
) -> Result<(Self::State, PingPongMessage), PingPongError>;
/// Initialize helper state using the helper's input share and the leader's first prepare share.
/// Corresponds to `ping_pong_helper_init` in [VDAF].
///
/// If successful, the returned [`PingPongTransition`] should be evaluated, yielding a
/// [`PingPongMessage`], which should be transmitted to the leader, and a [`PingPongState`].
///
/// If the state is `PingPongState::Continued`, then it should be used by the helper along with
/// the next `PingPongMessage` received from the leader as input to [`Self::helper_continued`]
/// to advance to the next round. The helper may store the `PingPongTransition` between rounds
/// of preparation instead of the `PingPongState` and `PingPongMessage`.
///
/// If the state is `PingPongState::Finished`, then preparation is finished and the output share
/// may be accumulated.
///
/// # Errors
///
/// `inbound` must be `PingPongMessage::Initialize` or the function will fail.
///
fn helper_initialized(
&self,
verify_key: &[u8; VERIFY_KEY_SIZE],
agg_param: &Self::AggregationParam,
nonce: &[u8; NONCE_SIZE],
public_share: &Self::PublicShare,
input_share: &Self::InputShare,
inbound: &PingPongMessage,
) -> Result<PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, Self>, PingPongError>;
/// Continue preparation based on the leader's current state and an incoming [`PingPongMessage`]
/// from the helper. Corresponds to `ping_pong_leader_continued` in [VDAF].
///
/// If successful, the returned [`PingPongContinuedValue`] will either be:
///
/// - `PingPongContinuedValue::WithMessage { transition }`: `transition` should be evaluated,
/// yielding a [`PingPongMessage`], which should be transmitted to the helper, and a
/// [`PingPongState`].
///
/// If the state is `PingPongState::Continued`, then it should be used by the leader along
/// with the next `PingPongMessage` received from the helper as input to
/// [`Self::leader_continued`] to advance to the next round. The leader may store the
/// `PingPongTransition` between rounds of preparation instead of of the `PingPongState` and
/// `PingPongMessage`.
///
/// If the state is `PingPongState::Finished`, then preparation is finished and the output
/// share may be accumulated.
///
/// - `PingPongContinuedValue::FinishedNoMessage`: preparation is finished and the output share
/// may be accumulated. No message needs to be sent to the helper.
///
/// # Errors
///
/// `leader_state` must be `PingPongState::Continued` or the function will fail.
///
/// `inbound` must not be `PingPongMessage::Initialize` or the function will fail.
///
fn leader_continued(
&self,
leader_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError>;
/// PingPongContinue preparation based on the helper's current state and an incoming
/// [`PingPongMessage`] from the leader. Corresponds to `ping_pong_helper_contnued` in [VDAF].
///
/// If successful, the returned [`PingPongContinuedValue`] will either be:
///
/// - `PingPongContinuedValue::WithMessage { transition }`: `transition` should be evaluated,
/// yielding a [`PingPongMessage`], which should be transmitted to the leader, and a
/// [`PingPongState`].
///
/// If the state is `PingPongState::Continued`, then it should be used by the helper along
/// with the next `PingPongMessage` received from the leader as input to
/// [`Self::helper_continued`] to advance to the next round. The helper may store the
/// `PingPongTransition` between rounds of preparation instead of the `PingPongState` and
/// `PingPongMessage`.
///
/// If the state is `PingPongState::Finished`, then preparation is finished and the output
/// share may be accumulated.
///
/// - `PingPongContinuedValue::FinishedNoMessage`: preparation is finished and the output share
/// may be accumulated. No message needs to be sent to the leader.
///
/// # Errors
///
/// `helper_state` must be `PingPongState::Continued` or the function will fail.
///
/// `inbound` must not be `PingPongMessage::Initialize` or the function will fail.
///
fn helper_continued(
&self,
helper_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError>;
}
/// Private interfaces for implementing ping-pong
trait PingPongTopologyPrivate<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize>:
PingPongTopology<VERIFY_KEY_SIZE, NONCE_SIZE>
{
fn continued(
&self,
is_leader: bool,
host_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError>;
}
impl<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize, A>
PingPongTopology<VERIFY_KEY_SIZE, NONCE_SIZE> for A
where
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
{
type State = PingPongState<VERIFY_KEY_SIZE, NONCE_SIZE, Self>;
type ContinuedValue = PingPongContinuedValue<VERIFY_KEY_SIZE, NONCE_SIZE, Self>;
type Transition = PingPongTransition<VERIFY_KEY_SIZE, NONCE_SIZE, Self>;
fn leader_initialized(
&self,
verify_key: &[u8; VERIFY_KEY_SIZE],
agg_param: &Self::AggregationParam,
nonce: &[u8; NONCE_SIZE],
public_share: &Self::PublicShare,
input_share: &Self::InputShare,
) -> Result<(Self::State, PingPongMessage), PingPongError> {
self.prepare_init(
verify_key,
/* Leader */ 0,
agg_param,
nonce,
public_share,
input_share,
)
.map_err(PingPongError::VdafPrepareInit)
.and_then(|(prep_state, prep_share)| {
Ok((
PingPongState::Continued(prep_state),
PingPongMessage::Initialize {
prep_share: prep_share
.get_encoded()
.map_err(PingPongError::CodecPrepShare)?,
},
))
})
}
fn helper_initialized(
&self,
verify_key: &[u8; VERIFY_KEY_SIZE],
agg_param: &Self::AggregationParam,
nonce: &[u8; NONCE_SIZE],
public_share: &Self::PublicShare,
input_share: &Self::InputShare,
inbound: &PingPongMessage,
) -> Result<Self::Transition, PingPongError> {
let (prep_state, prep_share) = self
.prepare_init(
verify_key,
/* Helper */ 1,
agg_param,
nonce,
public_share,
input_share,
)
.map_err(PingPongError::VdafPrepareInit)?;
let inbound_prep_share = if let PingPongMessage::Initialize { prep_share } = inbound {
Self::PrepareShare::get_decoded_with_param(&prep_state, prep_share)
.map_err(PingPongError::CodecPrepShare)?
} else {
return Err(PingPongError::PeerMessageMismatch {
found: inbound.variant(),
expected: "initialize",
});
};
let current_prepare_message = self
.prepare_shares_to_prepare_message(agg_param, [inbound_prep_share, prep_share])
.map_err(PingPongError::VdafPrepareSharesToPrepareMessage)?;
Ok(PingPongTransition {
previous_prepare_state: prep_state,
current_prepare_message,
})
}
fn leader_continued(
&self,
leader_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError> {
self.continued(true, leader_state, agg_param, inbound)
}
fn helper_continued(
&self,
helper_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError> {
self.continued(false, helper_state, agg_param, inbound)
}
}
impl<const VERIFY_KEY_SIZE: usize, const NONCE_SIZE: usize, A>
PingPongTopologyPrivate<VERIFY_KEY_SIZE, NONCE_SIZE> for A
where
A: Aggregator<VERIFY_KEY_SIZE, NONCE_SIZE>,
{
fn continued(
&self,
is_leader: bool,
host_state: Self::State,
agg_param: &Self::AggregationParam,
inbound: &PingPongMessage,
) -> Result<Self::ContinuedValue, PingPongError> {
let host_prep_state = if let PingPongState::Continued(state) = host_state {
state
} else {
return Err(PingPongError::HostStateMismatch {
found: "finished",
expected: "continue",
});
};
let (prep_msg, next_peer_prep_share) = match inbound {
PingPongMessage::Initialize { .. } => {
return Err(PingPongError::PeerMessageMismatch {
found: inbound.variant(),
expected: "continue",
});
}
PingPongMessage::Continue {
prep_msg,
prep_share,
} => (prep_msg, Some(prep_share)),
PingPongMessage::Finish { prep_msg } => (prep_msg, None),
};
let prep_msg = Self::PrepareMessage::get_decoded_with_param(&host_prep_state, prep_msg)
.map_err(PingPongError::CodecPrepMessage)?;
let host_prep_transition = self
.prepare_next(host_prep_state, prep_msg)
.map_err(PingPongError::VdafPrepareNext)?;
match (host_prep_transition, next_peer_prep_share) {
(
PrepareTransition::Continue(next_prep_state, next_host_prep_share),
Some(next_peer_prep_share),
) => {
let next_peer_prep_share = Self::PrepareShare::get_decoded_with_param(
&next_prep_state,
next_peer_prep_share,
)
.map_err(PingPongError::CodecPrepShare)?;
let mut prep_shares = [next_peer_prep_share, next_host_prep_share];
if is_leader {
prep_shares.reverse();
}
let current_prepare_message = self
.prepare_shares_to_prepare_message(agg_param, prep_shares)
.map_err(PingPongError::VdafPrepareSharesToPrepareMessage)?;
Ok(PingPongContinuedValue::WithMessage {
transition: PingPongTransition {
previous_prepare_state: next_prep_state,
current_prepare_message,
},
})
}
(PrepareTransition::Finish(output_share), None) => {
Ok(PingPongContinuedValue::FinishedNoMessage { output_share })
}
(PrepareTransition::Continue(_, _), None) => Err(PingPongError::PeerMessageMismatch {
found: inbound.variant(),
expected: "continue",
}),
(PrepareTransition::Finish(_), Some(_)) => Err(PingPongError::PeerMessageMismatch {
found: inbound.variant(),
expected: "finish",
}),
}
}
}
#[cfg(test)]
mod tests {
use std::io::Cursor;
use super::*;
use crate::vdaf::dummy;
use assert_matches::assert_matches;
#[test]
fn ping_pong_one_round() {
let verify_key = [];
let aggregation_param = dummy::AggregationParam(0);
let nonce = [0; 16];
#[allow(clippy::let_unit_value)]
let public_share = ();
let input_share = dummy::InputShare(0);
let leader = dummy::Vdaf::new(1);
let helper = dummy::Vdaf::new(1);
// Leader inits into round 0
let (leader_state, leader_message) = leader
.leader_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
)
.unwrap();
// Helper inits into round 1
let (helper_state, helper_message) = helper
.helper_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
&leader_message,
)
.unwrap()
.evaluate(&helper)
.unwrap();
// 1 round VDAF: helper should finish immediately.
assert_matches!(helper_state, PingPongState::Finished(_));
let leader_state = leader
.leader_continued(leader_state, &aggregation_param, &helper_message)
.unwrap();
// 1 round VDAF: leader should finish when it gets helper message and emit no message.
assert_matches!(
leader_state,
PingPongContinuedValue::FinishedNoMessage { .. }
);
}
#[test]
fn ping_pong_two_rounds() {
let verify_key = [];
let aggregation_param = dummy::AggregationParam(0);
let nonce = [0; 16];
#[allow(clippy::let_unit_value)]
let public_share = ();
let input_share = dummy::InputShare(0);
let leader = dummy::Vdaf::new(2);
let helper = dummy::Vdaf::new(2);
// Leader inits into round 0
let (leader_state, leader_message) = leader
.leader_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
)
.unwrap();
// Helper inits into round 1
let (helper_state, helper_message) = helper
.helper_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
&leader_message,
)
.unwrap()
.evaluate(&helper)
.unwrap();
// 2 round VDAF, round 1: helper should continue.
assert_matches!(helper_state, PingPongState::Continued(_));
let leader_state = leader
.leader_continued(leader_state, &aggregation_param, &helper_message)
.unwrap();
// 2 round VDAF, round 1: leader should finish and emit a finish message.
let leader_message = assert_matches!(
leader_state, PingPongContinuedValue::WithMessage { transition } => {
let (state, message) = transition.evaluate(&leader).unwrap();
assert_matches!(state, PingPongState::Finished(_));
message
}
);
let helper_state = helper
.helper_continued(helper_state, &aggregation_param, &leader_message)
.unwrap();
// 2 round vdaf, round 1: helper should finish and emit no message.
assert_matches!(
helper_state,
PingPongContinuedValue::FinishedNoMessage { .. }
);
}
#[test]
fn ping_pong_three_rounds() {
let verify_key = [];
let aggregation_param = dummy::AggregationParam(0);
let nonce = [0; 16];
#[allow(clippy::let_unit_value)]
let public_share = ();
let input_share = dummy::InputShare(0);
let leader = dummy::Vdaf::new(3);
let helper = dummy::Vdaf::new(3);
// Leader inits into round 0
let (leader_state, leader_message) = leader
.leader_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
)
.unwrap();
// Helper inits into round 1
let (helper_state, helper_message) = helper
.helper_initialized(
&verify_key,
&aggregation_param,
&nonce,
&public_share,
&input_share,
&leader_message,
)
.unwrap()
.evaluate(&helper)
.unwrap();
// 3 round VDAF, round 1: helper should continue.
assert_matches!(helper_state, PingPongState::Continued(_));
let leader_state = leader
.leader_continued(leader_state, &aggregation_param, &helper_message)
.unwrap();
// 3 round VDAF, round 1: leader should continue and emit a continue message.
let (leader_state, leader_message) = assert_matches!(
leader_state, PingPongContinuedValue::WithMessage { transition } => {
let (state, message) = transition.evaluate(&leader).unwrap();
assert_matches!(state, PingPongState::Continued(_));
(state, message)
}
);
let helper_state = helper
.helper_continued(helper_state, &aggregation_param, &leader_message)
.unwrap();
// 3 round vdaf, round 2: helper should finish and emit a finish message.
let helper_message = assert_matches!(
helper_state, PingPongContinuedValue::WithMessage { transition } => {
let (state, message) = transition.evaluate(&helper).unwrap();
assert_matches!(state, PingPongState::Finished(_));
message
}
);
let leader_state = leader
.leader_continued(leader_state, &aggregation_param, &helper_message)
.unwrap();
// 3 round VDAF, round 2: leader should finish and emit no message.
assert_matches!(
leader_state,
PingPongContinuedValue::FinishedNoMessage { .. }
);
}
#[test]
fn roundtrip_message() {
let messages = [
(
PingPongMessage::Initialize {
prep_share: Vec::from("prepare share"),
},
concat!(
"00", // enum discriminant
concat!(
// prep_share
"0000000d", // length
"70726570617265207368617265", // contents
),
),
),
(
PingPongMessage::Continue {
prep_msg: Vec::from("prepare message"),
prep_share: Vec::from("prepare share"),
},
concat!(
"01", // enum discriminant
concat!(
// prep_msg
"0000000f", // length
"70726570617265206d657373616765", // contents
),
concat!(
// prep_share
"0000000d", // length
"70726570617265207368617265", // contents
),
),
),
(
PingPongMessage::Finish {
prep_msg: Vec::from("prepare message"),
},
concat!(
"02", // enum discriminant
concat!(
// prep_msg
"0000000f", // length
"70726570617265206d657373616765", // contents
),
),
),
];
for (message, expected_hex) in messages {
let mut encoded_val = Vec::new();
message.encode(&mut encoded_val).unwrap();
let got_hex = hex::encode(&encoded_val);
assert_eq!(
&got_hex, expected_hex,
"Couldn't roundtrip (encoded value differs): {message:?}",
);
let decoded_val = PingPongMessage::decode(&mut Cursor::new(&encoded_val)).unwrap();
assert_eq!(
decoded_val, message,
"Couldn't roundtrip (decoded value differs): {message:?}"
);
assert_eq!(
encoded_val.len(),
message.encoded_len().expect("No encoded length hint"),
"Encoded length hint is incorrect: {message:?}"
)
}
}
#[test]
fn roundtrip_transition() {
// VDAF implementations have tests for encoding/decoding their respective PrepareShare and
// PrepareMessage types, so we test here using the dummy VDAF.
let transition = PingPongTransition::<0, 16, dummy::Vdaf> {
previous_prepare_state: dummy::PrepareState::default(),
current_prepare_message: (),
};
let encoded = transition.get_encoded().unwrap();
let hex_encoded = hex::encode(&encoded);
assert_eq!(
hex_encoded,
concat!(
concat!(
// previous_prepare_state
"00", // input_share
"00000000", // current_round
),
// current_prepare_message (0 length encoding)
)
);
let decoded = PingPongTransition::get_decoded_with_param(&(), &encoded).unwrap();
assert_eq!(transition, decoded);
assert_eq!(
encoded.len(),
transition.encoded_len().expect("No encoded length hint"),
);
}
}