use crate::{
cluster_info::MAX_SNAPSHOT_HASHES,
contact_info::ContactInfo,
deprecated,
duplicate_shred::{DuplicateShred, DuplicateShredIndex, MAX_DUPLICATE_SHREDS},
epoch_slots::EpochSlots,
};
use bincode::{serialize, serialized_size};
use rand::{CryptoRng, Rng};
use serde::de::{Deserialize, Deserializer};
use solana_sdk::sanitize::{Sanitize, SanitizeError};
use solana_sdk::timing::timestamp;
use solana_sdk::{
clock::Slot,
hash::Hash,
pubkey::{self, Pubkey},
signature::{Keypair, Signable, Signature, Signer},
transaction::Transaction,
};
use solana_vote_program::vote_transaction::parse_vote_transaction;
use std::{
borrow::{Borrow, Cow},
collections::{hash_map::Entry, BTreeSet, HashMap},
fmt,
};
pub const MAX_WALLCLOCK: u64 = 1_000_000_000_000_000;
pub const MAX_SLOT: u64 = 1_000_000_000_000_000;
pub type VoteIndex = u8;
pub const MAX_VOTES: VoteIndex = 32;
pub type EpochSlotsIndex = u8;
pub const MAX_EPOCH_SLOTS: EpochSlotsIndex = 255;
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample)]
pub struct CrdsValue {
pub signature: Signature,
pub data: CrdsData,
}
impl Sanitize for CrdsValue {
fn sanitize(&self) -> Result<(), SanitizeError> {
self.signature.sanitize()?;
self.data.sanitize()
}
}
impl Signable for CrdsValue {
fn pubkey(&self) -> Pubkey {
self.pubkey()
}
fn signable_data(&self) -> Cow<[u8]> {
Cow::Owned(serialize(&self.data).expect("failed to serialize CrdsData"))
}
fn get_signature(&self) -> Signature {
self.signature
}
fn set_signature(&mut self, signature: Signature) {
self.signature = signature
}
fn verify(&self) -> bool {
self.get_signature()
.verify(&self.pubkey().as_ref(), self.signable_data().borrow())
}
}
#[allow(clippy::large_enum_variant)]
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample, AbiEnumVisitor)]
pub enum CrdsData {
ContactInfo(ContactInfo),
Vote(VoteIndex, Vote),
LowestSlot(u8, LowestSlot),
SnapshotHashes(SnapshotHash),
AccountsHashes(SnapshotHash),
EpochSlots(EpochSlotsIndex, EpochSlots),
LegacyVersion(LegacyVersion),
Version(Version),
NodeInstance(NodeInstance),
DuplicateShred(DuplicateShredIndex, DuplicateShred),
}
impl Sanitize for CrdsData {
fn sanitize(&self) -> Result<(), SanitizeError> {
match self {
CrdsData::ContactInfo(val) => val.sanitize(),
CrdsData::Vote(ix, val) => {
if *ix >= MAX_VOTES {
return Err(SanitizeError::ValueOutOfBounds);
}
val.sanitize()
}
CrdsData::LowestSlot(ix, val) => {
if *ix as usize >= 1 {
return Err(SanitizeError::ValueOutOfBounds);
}
val.sanitize()
}
CrdsData::SnapshotHashes(val) => val.sanitize(),
CrdsData::AccountsHashes(val) => val.sanitize(),
CrdsData::EpochSlots(ix, val) => {
if *ix as usize >= MAX_EPOCH_SLOTS as usize {
return Err(SanitizeError::ValueOutOfBounds);
}
val.sanitize()
}
CrdsData::LegacyVersion(version) => version.sanitize(),
CrdsData::Version(version) => version.sanitize(),
CrdsData::NodeInstance(node) => node.sanitize(),
CrdsData::DuplicateShred(ix, shred) => {
if *ix >= MAX_DUPLICATE_SHREDS {
Err(SanitizeError::ValueOutOfBounds)
} else {
shred.sanitize()
}
}
}
}
}
pub(crate) fn new_rand_timestamp<R: Rng>(rng: &mut R) -> u64 {
const DELAY: u64 = 10 * 60 * 1000;
timestamp() - DELAY + rng.gen_range(0, 2 * DELAY)
}
impl CrdsData {
fn new_rand<R: Rng>(rng: &mut R, pubkey: Option<Pubkey>) -> CrdsData {
let kind = rng.gen_range(0, 6);
match kind {
0 => CrdsData::ContactInfo(ContactInfo::new_rand(rng, pubkey)),
1 => CrdsData::LowestSlot(rng.gen(), LowestSlot::new_rand(rng, pubkey)),
2 => CrdsData::SnapshotHashes(SnapshotHash::new_rand(rng, pubkey)),
3 => CrdsData::AccountsHashes(SnapshotHash::new_rand(rng, pubkey)),
4 => CrdsData::Version(Version::new_rand(rng, pubkey)),
_ => CrdsData::Vote(rng.gen_range(0, MAX_VOTES), Vote::new_rand(rng, pubkey)),
}
}
}
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample)]
pub struct SnapshotHash {
pub from: Pubkey,
pub hashes: Vec<(Slot, Hash)>,
pub wallclock: u64,
}
impl Sanitize for SnapshotHash {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
for (slot, _) in &self.hashes {
if *slot >= MAX_SLOT {
return Err(SanitizeError::ValueOutOfBounds);
}
}
self.from.sanitize()
}
}
impl SnapshotHash {
pub fn new(from: Pubkey, hashes: Vec<(Slot, Hash)>) -> Self {
Self {
from,
hashes,
wallclock: timestamp(),
}
}
pub(crate) fn new_rand<R: Rng>(rng: &mut R, pubkey: Option<Pubkey>) -> Self {
let num_hashes = rng.gen_range(0, MAX_SNAPSHOT_HASHES) + 1;
let hashes = std::iter::repeat_with(|| {
let slot = 47825632 + rng.gen_range(0, 512);
let hash = solana_sdk::hash::new_rand(rng);
(slot, hash)
})
.take(num_hashes)
.collect();
Self {
from: pubkey.unwrap_or_else(pubkey::new_rand),
hashes,
wallclock: new_rand_timestamp(rng),
}
}
}
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample)]
pub struct LowestSlot {
pub from: Pubkey,
root: Slot,
pub lowest: Slot,
slots: BTreeSet<Slot>,
stash: Vec<deprecated::EpochIncompleteSlots>,
pub wallclock: u64,
}
impl LowestSlot {
pub fn new(from: Pubkey, lowest: Slot, wallclock: u64) -> Self {
Self {
from,
root: 0,
lowest,
slots: BTreeSet::new(),
stash: vec![],
wallclock,
}
}
fn new_rand<R: Rng>(rng: &mut R, pubkey: Option<Pubkey>) -> Self {
Self {
from: pubkey.unwrap_or_else(pubkey::new_rand),
root: rng.gen(),
lowest: rng.gen(),
slots: BTreeSet::default(),
stash: Vec::default(),
wallclock: new_rand_timestamp(rng),
}
}
}
impl Sanitize for LowestSlot {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
if self.lowest >= MAX_SLOT {
return Err(SanitizeError::ValueOutOfBounds);
}
if self.root != 0 {
return Err(SanitizeError::InvalidValue);
}
if !self.slots.is_empty() {
return Err(SanitizeError::InvalidValue);
}
if !self.stash.is_empty() {
return Err(SanitizeError::InvalidValue);
}
self.from.sanitize()
}
}
#[derive(Clone, Debug, PartialEq, AbiExample, Serialize)]
pub struct Vote {
pub(crate) from: Pubkey,
transaction: Transaction,
pub(crate) wallclock: u64,
#[serde(skip_serializing)]
slot: Option<Slot>,
}
impl Sanitize for Vote {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
self.from.sanitize()?;
self.transaction.sanitize()
}
}
impl Vote {
pub fn new(from: Pubkey, transaction: Transaction, wallclock: u64) -> Self {
let slot = parse_vote_transaction(&transaction)
.and_then(|(_, vote, _)| vote.slots.last().copied());
Self {
from,
transaction,
wallclock,
slot,
}
}
fn new_rand<R: Rng>(rng: &mut R, pubkey: Option<Pubkey>) -> Self {
Self {
from: pubkey.unwrap_or_else(pubkey::new_rand),
transaction: Transaction::default(),
wallclock: new_rand_timestamp(rng),
slot: None,
}
}
pub(crate) fn transaction(&self) -> &Transaction {
&self.transaction
}
pub(crate) fn slot(&self) -> Option<Slot> {
self.slot
}
}
impl<'de> Deserialize<'de> for Vote {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: Deserializer<'de>,
{
#[derive(Deserialize)]
struct Vote {
from: Pubkey,
transaction: Transaction,
wallclock: u64,
}
let vote = Vote::deserialize(deserializer)?;
let vote = match vote.transaction.sanitize() {
Ok(_) => Self::new(vote.from, vote.transaction, vote.wallclock),
Err(_) => Self {
from: vote.from,
transaction: vote.transaction,
wallclock: vote.wallclock,
slot: None,
},
};
Ok(vote)
}
}
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample)]
pub struct LegacyVersion {
pub from: Pubkey,
pub wallclock: u64,
pub version: solana_version::LegacyVersion,
}
impl Sanitize for LegacyVersion {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
self.from.sanitize()?;
self.version.sanitize()
}
}
#[derive(Serialize, Deserialize, Clone, Debug, PartialEq, AbiExample)]
pub struct Version {
pub from: Pubkey,
pub wallclock: u64,
pub version: solana_version::Version,
}
impl Sanitize for Version {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
self.from.sanitize()?;
self.version.sanitize()
}
}
impl Version {
pub fn new(from: Pubkey) -> Self {
Self {
from,
wallclock: timestamp(),
version: solana_version::Version::default(),
}
}
fn new_rand<R: Rng>(rng: &mut R, pubkey: Option<Pubkey>) -> Self {
Self {
from: pubkey.unwrap_or_else(pubkey::new_rand),
wallclock: new_rand_timestamp(rng),
version: solana_version::Version {
major: rng.gen(),
minor: rng.gen(),
patch: rng.gen(),
commit: Some(rng.gen()),
feature_set: rng.gen(),
},
}
}
}
#[derive(Clone, Debug, PartialEq, AbiExample, Deserialize, Serialize)]
pub struct NodeInstance {
from: Pubkey,
wallclock: u64,
timestamp: u64,
token: u64,
}
impl NodeInstance {
pub fn new<R>(rng: &mut R, pubkey: Pubkey, now: u64) -> Self
where
R: Rng + CryptoRng,
{
Self {
from: pubkey,
wallclock: now,
timestamp: now,
token: rng.gen(),
}
}
pub fn with_wallclock(&self, now: u64) -> Self {
Self {
wallclock: now,
..*self
}
}
pub fn check_duplicate(&self, other: &CrdsValue) -> bool {
match &other.data {
CrdsData::NodeInstance(other) => {
self.token != other.token
&& self.timestamp <= other.timestamp
&& self.from == other.from
}
_ => false,
}
}
}
impl Sanitize for NodeInstance {
fn sanitize(&self) -> Result<(), SanitizeError> {
sanitize_wallclock(self.wallclock)?;
self.from.sanitize()
}
}
#[derive(PartialEq, Hash, Eq, Clone, Debug)]
pub enum CrdsValueLabel {
ContactInfo(Pubkey),
Vote(VoteIndex, Pubkey),
LowestSlot(Pubkey),
SnapshotHashes(Pubkey),
EpochSlots(EpochSlotsIndex, Pubkey),
AccountsHashes(Pubkey),
LegacyVersion(Pubkey),
Version(Pubkey),
NodeInstance(Pubkey, u64 ),
DuplicateShred(DuplicateShredIndex, Pubkey),
}
impl fmt::Display for CrdsValueLabel {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self {
CrdsValueLabel::ContactInfo(_) => write!(f, "ContactInfo({})", self.pubkey()),
CrdsValueLabel::Vote(ix, _) => write!(f, "Vote({}, {})", ix, self.pubkey()),
CrdsValueLabel::LowestSlot(_) => write!(f, "LowestSlot({})", self.pubkey()),
CrdsValueLabel::SnapshotHashes(_) => write!(f, "SnapshotHash({})", self.pubkey()),
CrdsValueLabel::EpochSlots(ix, _) => write!(f, "EpochSlots({}, {})", ix, self.pubkey()),
CrdsValueLabel::AccountsHashes(_) => write!(f, "AccountsHashes({})", self.pubkey()),
CrdsValueLabel::LegacyVersion(_) => write!(f, "LegacyVersion({})", self.pubkey()),
CrdsValueLabel::Version(_) => write!(f, "Version({})", self.pubkey()),
CrdsValueLabel::NodeInstance(pk, token) => write!(f, "NodeInstance({}, {})", pk, token),
CrdsValueLabel::DuplicateShred(ix, pk) => write!(f, "DuplicateShred({}, {})", ix, pk),
}
}
}
impl CrdsValueLabel {
pub fn pubkey(&self) -> Pubkey {
match self {
CrdsValueLabel::ContactInfo(p) => *p,
CrdsValueLabel::Vote(_, p) => *p,
CrdsValueLabel::LowestSlot(p) => *p,
CrdsValueLabel::SnapshotHashes(p) => *p,
CrdsValueLabel::EpochSlots(_, p) => *p,
CrdsValueLabel::AccountsHashes(p) => *p,
CrdsValueLabel::LegacyVersion(p) => *p,
CrdsValueLabel::Version(p) => *p,
CrdsValueLabel::NodeInstance(p, _ ) => *p,
CrdsValueLabel::DuplicateShred(_, p) => *p,
}
}
pub(crate) fn value_space(&self) -> Option<usize> {
match self {
CrdsValueLabel::ContactInfo(_) => Some(1),
CrdsValueLabel::Vote(_, _) => Some(MAX_VOTES as usize),
CrdsValueLabel::LowestSlot(_) => Some(1),
CrdsValueLabel::SnapshotHashes(_) => Some(1),
CrdsValueLabel::EpochSlots(_, _) => Some(MAX_EPOCH_SLOTS as usize),
CrdsValueLabel::AccountsHashes(_) => Some(1),
CrdsValueLabel::LegacyVersion(_) => Some(1),
CrdsValueLabel::Version(_) => Some(1),
CrdsValueLabel::NodeInstance(_, _) => None,
CrdsValueLabel::DuplicateShred(_, _) => Some(MAX_DUPLICATE_SHREDS as usize),
}
}
}
impl CrdsValue {
pub fn new_unsigned(data: CrdsData) -> Self {
Self {
signature: Signature::default(),
data,
}
}
pub fn new_signed(data: CrdsData, keypair: &Keypair) -> Self {
let mut value = Self::new_unsigned(data);
value.sign(keypair);
value
}
pub fn new_rand<R: Rng>(rng: &mut R, keypair: Option<&Keypair>) -> CrdsValue {
match keypair {
None => {
let keypair = Keypair::new();
let data = CrdsData::new_rand(rng, Some(keypair.pubkey()));
Self::new_signed(data, &keypair)
}
Some(keypair) => {
let data = CrdsData::new_rand(rng, Some(keypair.pubkey()));
Self::new_signed(data, keypair)
}
}
}
pub fn wallclock(&self) -> u64 {
match &self.data {
CrdsData::ContactInfo(contact_info) => contact_info.wallclock,
CrdsData::Vote(_, vote) => vote.wallclock,
CrdsData::LowestSlot(_, obj) => obj.wallclock,
CrdsData::SnapshotHashes(hash) => hash.wallclock,
CrdsData::AccountsHashes(hash) => hash.wallclock,
CrdsData::EpochSlots(_, p) => p.wallclock,
CrdsData::LegacyVersion(version) => version.wallclock,
CrdsData::Version(version) => version.wallclock,
CrdsData::NodeInstance(node) => node.wallclock,
CrdsData::DuplicateShred(_, shred) => shred.wallclock,
}
}
pub fn pubkey(&self) -> Pubkey {
match &self.data {
CrdsData::ContactInfo(contact_info) => contact_info.id,
CrdsData::Vote(_, vote) => vote.from,
CrdsData::LowestSlot(_, slots) => slots.from,
CrdsData::SnapshotHashes(hash) => hash.from,
CrdsData::AccountsHashes(hash) => hash.from,
CrdsData::EpochSlots(_, p) => p.from,
CrdsData::LegacyVersion(version) => version.from,
CrdsData::Version(version) => version.from,
CrdsData::NodeInstance(node) => node.from,
CrdsData::DuplicateShred(_, shred) => shred.from,
}
}
pub fn label(&self) -> CrdsValueLabel {
match &self.data {
CrdsData::ContactInfo(_) => CrdsValueLabel::ContactInfo(self.pubkey()),
CrdsData::Vote(ix, _) => CrdsValueLabel::Vote(*ix, self.pubkey()),
CrdsData::LowestSlot(_, _) => CrdsValueLabel::LowestSlot(self.pubkey()),
CrdsData::SnapshotHashes(_) => CrdsValueLabel::SnapshotHashes(self.pubkey()),
CrdsData::AccountsHashes(_) => CrdsValueLabel::AccountsHashes(self.pubkey()),
CrdsData::EpochSlots(ix, _) => CrdsValueLabel::EpochSlots(*ix, self.pubkey()),
CrdsData::LegacyVersion(_) => CrdsValueLabel::LegacyVersion(self.pubkey()),
CrdsData::Version(_) => CrdsValueLabel::Version(self.pubkey()),
CrdsData::NodeInstance(node) => CrdsValueLabel::NodeInstance(node.from, node.token),
CrdsData::DuplicateShred(ix, shred) => CrdsValueLabel::DuplicateShred(*ix, shred.from),
}
}
pub fn contact_info(&self) -> Option<&ContactInfo> {
match &self.data {
CrdsData::ContactInfo(contact_info) => Some(contact_info),
_ => None,
}
}
#[cfg(test)]
fn vote(&self) -> Option<&Vote> {
match &self.data {
CrdsData::Vote(_, vote) => Some(vote),
_ => None,
}
}
pub fn lowest_slot(&self) -> Option<&LowestSlot> {
match &self.data {
CrdsData::LowestSlot(_, slots) => Some(slots),
_ => None,
}
}
pub fn snapshot_hash(&self) -> Option<&SnapshotHash> {
match &self.data {
CrdsData::SnapshotHashes(slots) => Some(slots),
_ => None,
}
}
pub fn accounts_hash(&self) -> Option<&SnapshotHash> {
match &self.data {
CrdsData::AccountsHashes(slots) => Some(slots),
_ => None,
}
}
pub fn epoch_slots(&self) -> Option<&EpochSlots> {
match &self.data {
CrdsData::EpochSlots(_, slots) => Some(slots),
_ => None,
}
}
pub fn legacy_version(&self) -> Option<&LegacyVersion> {
match &self.data {
CrdsData::LegacyVersion(legacy_version) => Some(legacy_version),
_ => None,
}
}
pub fn version(&self) -> Option<&Version> {
match &self.data {
CrdsData::Version(version) => Some(version),
_ => None,
}
}
pub fn size(&self) -> u64 {
serialized_size(&self).expect("unable to serialize contact info")
}
pub fn should_force_push(&self, peer: &Pubkey) -> bool {
match &self.data {
CrdsData::NodeInstance(node) => node.from == *peer,
_ => false,
}
}
}
pub(crate) fn filter_current<'a, I>(values: I) -> impl Iterator<Item = &'a CrdsValue>
where
I: IntoIterator<Item = &'a CrdsValue>,
{
let mut out = HashMap::new();
for value in values {
match out.entry(value.label()) {
Entry::Vacant(entry) => {
entry.insert((value, value.wallclock()));
}
Entry::Occupied(mut entry) => {
let value_wallclock = value.wallclock();
let (_, entry_wallclock) = entry.get();
if *entry_wallclock < value_wallclock {
entry.insert((value, value_wallclock));
}
}
}
}
out.into_iter().map(|(_, (v, _))| v)
}
pub(crate) fn sanitize_wallclock(wallclock: u64) -> Result<(), SanitizeError> {
if wallclock >= MAX_WALLCLOCK {
Err(SanitizeError::ValueOutOfBounds)
} else {
Ok(())
}
}
#[cfg(test)]
mod test {
use super::*;
use crate::contact_info::ContactInfo;
use bincode::{deserialize, Options};
use rand::SeedableRng;
use rand_chacha::ChaChaRng;
use solana_perf::test_tx::test_tx;
use solana_sdk::signature::{Keypair, Signer};
use solana_sdk::timing::timestamp;
use solana_vote_program::{vote_instruction, vote_state};
use std::cmp::Ordering;
use std::iter::repeat_with;
#[test]
fn test_keys_and_values() {
let v = CrdsValue::new_unsigned(CrdsData::ContactInfo(ContactInfo::default()));
assert_eq!(v.wallclock(), 0);
let key = v.contact_info().unwrap().id;
assert_eq!(v.label(), CrdsValueLabel::ContactInfo(key));
let v = CrdsValue::new_unsigned(CrdsData::Vote(
0,
Vote::new(Pubkey::default(), test_tx(), 0),
));
assert_eq!(v.wallclock(), 0);
let key = v.vote().unwrap().from;
assert_eq!(v.label(), CrdsValueLabel::Vote(0, key));
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(
0,
LowestSlot::new(Pubkey::default(), 0, 0),
));
assert_eq!(v.wallclock(), 0);
let key = v.lowest_slot().unwrap().from;
assert_eq!(v.label(), CrdsValueLabel::LowestSlot(key));
}
#[test]
fn test_lowest_slot_sanitize() {
let ls = LowestSlot::new(Pubkey::default(), 0, 0);
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(0, ls.clone()));
assert_eq!(v.sanitize(), Ok(()));
let mut o = ls.clone();
o.root = 1;
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(0, o));
assert_eq!(v.sanitize(), Err(SanitizeError::InvalidValue));
let o = ls.clone();
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(1, o));
assert_eq!(v.sanitize(), Err(SanitizeError::ValueOutOfBounds));
let mut o = ls.clone();
o.slots.insert(1);
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(0, o));
assert_eq!(v.sanitize(), Err(SanitizeError::InvalidValue));
let mut o = ls;
o.stash.push(deprecated::EpochIncompleteSlots::default());
let v = CrdsValue::new_unsigned(CrdsData::LowestSlot(0, o));
assert_eq!(v.sanitize(), Err(SanitizeError::InvalidValue));
}
#[test]
fn test_signature() {
let keypair = Keypair::new();
let wrong_keypair = Keypair::new();
let mut v = CrdsValue::new_unsigned(CrdsData::ContactInfo(ContactInfo::new_localhost(
&keypair.pubkey(),
timestamp(),
)));
verify_signatures(&mut v, &keypair, &wrong_keypair);
v = CrdsValue::new_unsigned(CrdsData::Vote(
0,
Vote::new(keypair.pubkey(), test_tx(), timestamp()),
));
verify_signatures(&mut v, &keypair, &wrong_keypair);
v = CrdsValue::new_unsigned(CrdsData::LowestSlot(
0,
LowestSlot::new(keypair.pubkey(), 0, timestamp()),
));
verify_signatures(&mut v, &keypair, &wrong_keypair);
}
#[test]
fn test_max_vote_index() {
let keypair = Keypair::new();
let vote = CrdsValue::new_signed(
CrdsData::Vote(
MAX_VOTES,
Vote::new(keypair.pubkey(), test_tx(), timestamp()),
),
&keypair,
);
assert!(vote.sanitize().is_err());
}
#[test]
fn test_vote_round_trip() {
let mut rng = rand::thread_rng();
let vote = vote_state::Vote::new(
vec![1, 3, 7],
solana_sdk::hash::new_rand(&mut rng),
);
let ix = vote_instruction::vote(
&Pubkey::new_unique(),
&Pubkey::new_unique(),
vote,
);
let tx = Transaction::new_with_payer(
&[ix],
Some(&Pubkey::new_unique()),
);
let vote = Vote::new(
Pubkey::new_unique(),
tx,
rng.gen(),
);
assert_eq!(vote.slot, Some(7));
let bytes = bincode::serialize(&vote).unwrap();
let other = bincode::deserialize(&bytes[..]).unwrap();
assert_eq!(vote, other);
assert_eq!(other.slot, Some(7));
let bytes = bincode::options().serialize(&vote).unwrap();
let other = bincode::options().deserialize(&bytes[..]).unwrap();
assert_eq!(vote, other);
assert_eq!(other.slot, Some(7));
}
#[test]
fn test_max_epoch_slots_index() {
let keypair = Keypair::new();
let item = CrdsValue::new_signed(
CrdsData::EpochSlots(
MAX_EPOCH_SLOTS,
EpochSlots::new(keypair.pubkey(), timestamp()),
),
&keypair,
);
assert_eq!(item.sanitize(), Err(SanitizeError::ValueOutOfBounds));
}
fn serialize_deserialize_value(value: &mut CrdsValue, keypair: &Keypair) {
let num_tries = 10;
value.sign(keypair);
let original_signature = value.get_signature();
for _ in 0..num_tries {
let serialized_value = serialize(value).unwrap();
let deserialized_value: CrdsValue = deserialize(&serialized_value).unwrap();
let deserialized_signature = deserialized_value.get_signature();
assert_eq!(original_signature, deserialized_signature);
assert!(deserialized_value.verify());
}
}
fn verify_signatures(
value: &mut CrdsValue,
correct_keypair: &Keypair,
wrong_keypair: &Keypair,
) {
assert!(!value.verify());
value.sign(&correct_keypair);
assert!(value.verify());
value.sign(&wrong_keypair);
assert!(!value.verify());
serialize_deserialize_value(value, correct_keypair);
}
#[test]
fn test_filter_current() {
let seed = [48u8; 32];
let mut rng = ChaChaRng::from_seed(seed);
let keys: Vec<_> = repeat_with(Keypair::new).take(16).collect();
let values: Vec<_> = repeat_with(|| {
let index = rng.gen_range(0, keys.len());
CrdsValue::new_rand(&mut rng, Some(&keys[index]))
})
.take(2048)
.collect();
let mut currents = HashMap::new();
for value in filter_current(&values) {
assert!(currents.insert(value.label(), value).is_none());
}
let mut count = 0;
for value in &values {
let current_value = currents.get(&value.label()).unwrap();
match value.wallclock().cmp(¤t_value.wallclock()) {
Ordering::Less => (),
Ordering::Equal => {
if value == *current_value {
count += 1;
}
}
Ordering::Greater => panic!("this should not happen!"),
}
}
assert_eq!(count, currents.len());
assert!(currents.len() <= keys.len() * (5 + MAX_VOTES as usize));
}
#[test]
fn test_node_instance_crds_lable() {
fn make_crds_value(node: NodeInstance) -> CrdsValue {
CrdsValue::new_unsigned(CrdsData::NodeInstance(node))
}
let mut rng = rand::thread_rng();
let now = timestamp();
let pubkey = Pubkey::new_unique();
let node = NodeInstance::new(&mut rng, pubkey, now);
assert_eq!(
make_crds_value(node.clone()).label(),
make_crds_value(node.with_wallclock(now + 8)).label()
);
let other = NodeInstance {
from: Pubkey::new_unique(),
..node
};
assert_ne!(
make_crds_value(node.clone()).label(),
make_crds_value(other).label()
);
let other = NodeInstance {
wallclock: now + 8,
..node
};
assert_eq!(
make_crds_value(node.clone()).label(),
make_crds_value(other).label()
);
let other = NodeInstance {
timestamp: now + 8,
..node
};
assert_eq!(
make_crds_value(node.clone()).label(),
make_crds_value(other).label()
);
let other = NodeInstance {
token: rng.gen(),
..node
};
assert_ne!(
make_crds_value(node).label(),
make_crds_value(other).label()
);
}
#[test]
fn test_check_duplicate_instance() {
fn make_crds_value(node: NodeInstance) -> CrdsValue {
CrdsValue::new_unsigned(CrdsData::NodeInstance(node))
}
let now = timestamp();
let mut rng = rand::thread_rng();
let pubkey = Pubkey::new_unique();
let node = NodeInstance::new(&mut rng, pubkey, now);
assert!(!node.check_duplicate(&make_crds_value(NodeInstance {
from: pubkey,
wallclock: now + 1,
timestamp: now + 1,
token: node.token,
})));
assert!(!node.check_duplicate(&make_crds_value(NodeInstance {
from: pubkey,
wallclock: now + 1,
timestamp: now - 1,
token: rng.gen(),
})));
let other = node.with_wallclock(now + 8);
assert_eq!(
other,
NodeInstance {
from: pubkey,
wallclock: now + 8,
timestamp: now,
token: node.token,
}
);
assert!(!node.check_duplicate(&make_crds_value(other)));
assert!(node.check_duplicate(&make_crds_value(NodeInstance {
from: pubkey,
wallclock: 0,
timestamp: now,
token: rng.gen(),
})));
assert!(!node.check_duplicate(&make_crds_value(NodeInstance {
from: Pubkey::new_unique(),
wallclock: now + 1,
timestamp: now + 1,
token: rng.gen(),
})));
assert!(
!node.check_duplicate(&CrdsValue::new_unsigned(CrdsData::ContactInfo(
ContactInfo::new_rand(&mut rng, Some(pubkey))
)))
);
}
#[test]
fn test_should_force_push() {
let mut rng = rand::thread_rng();
let pubkey = Pubkey::new_unique();
assert!(
!CrdsValue::new_unsigned(CrdsData::ContactInfo(ContactInfo::new_rand(
&mut rng,
Some(pubkey),
)))
.should_force_push(&pubkey)
);
let node = CrdsValue::new_unsigned(CrdsData::NodeInstance(NodeInstance::new(
&mut rng,
pubkey,
timestamp(),
)));
assert!(node.should_force_push(&pubkey));
assert!(!node.should_force_push(&Pubkey::new_unique()));
}
}