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smt: add SparseMerklePath, a compact representation of MerklePath

Browse source 
Co-authored-by: Philipp Gackstatter <PhilippGackstatter@users.noreply.github.com>
This commit is contained in:
Qyriad 2025-02-27 17:26:28 +01:00
parent ac584be654
commit 1aba63de4b
5 changed files with 694 additions and 2 deletions
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1
CHANGELOG.md
View file

@ -16,6 +16,7 @@
- Optimized duplicate key detection in `Smt::with_entries_concurrent` (#395).
- [BREAKING] Moved `rand` to version `0.9` removing the `try_fill_bytes` method (#398).
- [BREAKING] Increment minimum supported Rust version to 1.85 (#399).
- Added `SparseMerklePath`, a compact representation of `MerklePath` which compacts empty nodes into a bitmask (#389).
## 0.13.3 (2025-02-18)

14
Cargo.lock generated
View file

@ -254,7 +254,7 @@ dependencies = [
"clap",
"criterion-plot",
"is-terminal",
"itertools",
"itertools 0.10.5",
"num-traits",
"once_cell",
"oorandom",
@ -275,7 +275,7 @@ source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "6b50826342786a51a89e2da3a28f1c32b06e387201bc2d19791f622c673706b1"
dependencies = [
"cast",
"itertools",
"itertools 0.10.5",
]
[[package]]
@ -453,6 +453,15 @@ dependencies = [
"either",
]
[[package]]
name = "itertools"
version = "0.14.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "2b192c782037fadd9cfa75548310488aabdbf3d2da73885b31bd0abd03351285"
dependencies = [
"either",
]
[[package]]
name = "itoa"
version = "1.0.15"
@ -524,6 +533,7 @@ dependencies = [
"glob",
"hashbrown",
"hex",
"itertools 0.14.0",
"num",
"num-complex",
"proptest",

1
miden-crypto/Cargo.toml
View file

@ -83,6 +83,7 @@ assert_matches = { version = "1.5", default-features = false }
criterion = { version = "0.5", features = ["html_reports"] }
getrandom = { version = "0.3", default-features = false }
hex = { version = "0.4", default-features = false, features = ["alloc"] }
itertools = { version = "0.14" }
proptest = { version = "1.6", default-features = false, features = ["alloc"]}
rand_chacha = { version = "0.9", default-features = false }
rand-utils = { version = "0.12", package = "winter-rand-utils" }

3
miden-crypto/src/merkle/mod.rs
View file

@ -20,6 +20,9 @@ pub use merkle_tree::{MerkleTree, path_to_text, tree_to_text};
mod path;
pub use path::{MerklePath, RootPath, ValuePath};
mod sparse_path;
pub use sparse_path::{SparseMerklePath, SparseValuePath};
mod smt;
pub use smt::{
InnerNode, LeafIndex, MutationSet, NodeMutation, PartialSmt, SMT_DEPTH, SMT_MAX_DEPTH,

677
miden-crypto/src/merkle/sparse_path.rs Normal file
View file

@ -0,0 +1,677 @@
use alloc::{borrow::Cow, vec::Vec};
use core::{
iter::{self, FusedIterator},
num::NonZero,
};
use winter_utils::{Deserializable, DeserializationError, Serializable};
use super::{
EmptySubtreeRoots, MerkleError, MerklePath, RpoDigest, SMT_MAX_DEPTH, ValuePath, Word,
};
/// A different representation of [`MerklePath`] designed for memory efficiency for Merkle paths
/// with empty nodes.
///
/// Empty nodes in the path are stored only as their position, represented with a bitmask. A
/// maximum of 64 nodes (`SMT_MAX_DEPTH`) can be stored (empty and non-empty). The more nodes in a
/// path are empty, the less memory this struct will use. This type calculates empty nodes on-demand
/// when iterated through, converted to a [MerklePath], or an empty node is retrieved with
/// [`SparseMerklePath::at_idx()`] or [`SparseMerklePath::at_depth()`], which will incur overhead.
///
/// NOTE: This type assumes that Merkle paths always span from the root of the tree to a leaf.
/// Partial paths are not supported.
#[derive(Clone, Debug, Default, PartialEq, Eq)]
#[cfg_attr(feature = "serde", derive(serde::Deserialize, serde::Serialize))]
pub struct SparseMerklePath {
/// A bitmask representing empty nodes. The set bit corresponds to the depth of an empty node.
/// The least significant bit (bit 0) describes depth 1 node (root's children).
/// The `bit index + 1` is equal to node's depth.
empty_nodes_mask: u64,
/// The non-empty nodes, stored in depth-order, but not contiguous across depth.
nodes: Vec<RpoDigest>,
}
impl SparseMerklePath {
/// Constructs a sparse Merkle path from an iterator over Merkle nodes that also knows its
/// exact size (such as iterators created with [Vec::into_iter]). The iterator must be in order
/// of deepest to shallowest.
///
/// Knowing the size is necessary to calculate the depth of the tree, which is needed to detect
/// which nodes are empty nodes.
///
/// # Errors
/// Returns [MerkleError::DepthTooBig] if `tree_depth` is greater than [SMT_MAX_DEPTH].
pub fn from_sized_iter<I>(iterator: I) -> Result<Self, MerkleError>
where
I: IntoIterator<IntoIter: ExactSizeIterator, Item = RpoDigest>,
{
let iterator = iterator.into_iter();
// `iterator.len() as u8` will truncate, but not below `SMT_MAX_DEPTH`, which
// `from_iter_with_depth` checks for.
Self::from_iter_with_depth(iterator.len() as u8, iterator)
}
/// Returns the total depth of this path, i.e., the number of nodes this path represents.
pub fn depth(&self) -> u8 {
(self.nodes.len() + self.empty_nodes_mask.count_ones() as usize) as u8
}
/// Get a specific node in this path at a given depth.
///
/// The `depth` parameter is defined in terms of `self.depth()`. Merkle paths conventionally do
/// not include the root, so the shallowest depth is `1`, and the deepest depth is
/// `self.depth()`.
///
/// # Errors
/// Returns [MerkleError::DepthTooBig] if `node_depth` is greater than the total depth of this
/// path.
pub fn at_depth(&self, node_depth: NonZero<u8>) -> Result<RpoDigest, MerkleError> {
if node_depth.get() > self.depth() {
return Err(MerkleError::DepthTooBig(node_depth.get().into()));
}
let node = self
.at_depth_nonempty(node_depth)
.unwrap_or_else(|| *EmptySubtreeRoots::entry(self.depth(), node_depth.get()));
Ok(node)
}
/// Get a specific non-empty node in this path at a given depth, or `None` if the specified
/// node is an empty node.
fn at_depth_nonempty(&self, node_depth: NonZero<u8>) -> Option<RpoDigest> {
assert!(
node_depth.get() <= self.depth(),
"node depth {} cannot be greater than tree depth {}",
node_depth.get(),
self.depth(),
);
if self.is_depth_empty(node_depth) {
return None;
}
// Our index needs to account for all the empty nodes that aren't in `self.nodes`.
let nonempty_index = self.get_nonempty_index(node_depth);
Some(self.nodes[nonempty_index])
}
/// Returns the path node at the specified index, or [None] if the index is out of bounds.
///
/// The node at index 0 is the deepest part of the path.
///
/// ```
/// # use core::num::NonZero;
/// # use miden_crypto::{ZERO, ONE, hash::rpo::RpoDigest, merkle::SparseMerklePath};
/// # let zero = RpoDigest::new([ZERO; 4]);
/// # let one = RpoDigest::new([ONE; 4]);
/// # let sparse_path = SparseMerklePath::from_sized_iter(vec![zero, one, one, zero]).unwrap();
/// let depth = NonZero::new(sparse_path.depth()).unwrap();
/// assert_eq!(
/// sparse_path.at_idx(0).unwrap(),
/// sparse_path.at_depth(depth).unwrap(),
/// );
/// ```
pub fn at_idx(&self, index: usize) -> Option<RpoDigest> {
// If this overflows *or* if the depth is zero then the index was out of bounds.
let depth = NonZero::new(u8::checked_sub(self.depth(), index as u8)?)?;
self.at_depth(depth).ok()
}
// PROVIDERS
// ============================================================================================
/// Constructs a borrowing iterator over the nodes in this path.
pub fn iter(&self) -> impl ExactSizeIterator<Item = RpoDigest> {
self.into_iter()
}
// PRIVATE HELPERS
// ============================================================================================
/// Constructs a sparse Merkle path from a manually specified tree depth, and an iterator over
/// Merkle nodes from deepest to shallowest.
///
/// Knowing the size is necessary to calculate the depth of the tree, which is needed to detect
/// which nodes are empty nodes.
///
/// Warning: this method does not check if the iterator contained more elements.
///
/// # Errors
/// Returns [MerkleError::DepthTooBig] if `tree_depth` is greater than [SMT_MAX_DEPTH].
fn from_iter_with_depth(
tree_depth: u8,
iter: impl IntoIterator<Item = RpoDigest>,
) -> Result<Self, MerkleError> {
if tree_depth > SMT_MAX_DEPTH {
return Err(MerkleError::DepthTooBig(tree_depth as u64));
}
let mut empty_nodes_mask: u64 = 0;
let mut nodes: Vec<RpoDigest> = Default::default();
for (depth, node) in iter::zip(path_depth_iter(tree_depth), iter) {
let &equivalent_empty_node = EmptySubtreeRoots::entry(tree_depth, depth.get());
let is_empty = node == equivalent_empty_node;
let node = if is_empty { None } else { Some(node) };
match node {
Some(node) => nodes.push(node),
None => empty_nodes_mask |= Self::bitmask_for_depth(depth),
}
}
Ok(SparseMerklePath { nodes, empty_nodes_mask })
}
const fn bitmask_for_depth(node_depth: NonZero<u8>) -> u64 {
// - 1 because paths do not include the root.
1 << (node_depth.get() - 1)
}
const fn is_depth_empty(&self, node_depth: NonZero<u8>) -> bool {
(self.empty_nodes_mask & Self::bitmask_for_depth(node_depth)) != 0
}
fn get_nonempty_index(&self, node_depth: NonZero<u8>) -> usize {
let bit_index = node_depth.get() - 1;
let without_shallower = self.empty_nodes_mask >> bit_index;
let empty_deeper = without_shallower.count_ones() as usize;
// The vec index we would use if we didn't have any empty nodes to account for...
let normal_index = (self.depth() - node_depth.get()) as usize;
// subtracted by the number of empty nodes that are deeper than us.
normal_index - empty_deeper
}
}
// SERIALIZATION
// ================================================================================================
impl Serializable for SparseMerklePath {
fn write_into<W: winter_utils::ByteWriter>(&self, target: &mut W) {
target.write_u8(self.depth());
target.write_u64(self.empty_nodes_mask);
target.write_many(&self.nodes);
}
}
impl Deserializable for SparseMerklePath {
fn read_from<R: winter_utils::ByteReader>(
source: &mut R,
) -> Result<Self, DeserializationError> {
let depth = source.read_u8()?;
if depth > SMT_MAX_DEPTH {
return Err(DeserializationError::InvalidValue(format!(
"SparseMerklePath max depth exceeded ({} > {})",
depth, SMT_MAX_DEPTH
)));
}
let empty_nodes_mask = source.read_u64()?;
let empty_nodes_count = empty_nodes_mask.count_ones();
if empty_nodes_count > depth as u32 {
return Err(DeserializationError::InvalidValue(format!(
"SparseMerklePath has more empty nodes ({}) than its full length ({})",
empty_nodes_count, depth
)));
}
let count = depth as u32 - empty_nodes_count;
let nodes = source.read_many::<RpoDigest>(count as usize)?;
Ok(Self { empty_nodes_mask, nodes })
}
}
// CONVERSIONS
// ================================================================================================
impl From<SparseMerklePath> for MerklePath {
fn from(sparse_path: SparseMerklePath) -> Self {
MerklePath::from_iter(sparse_path)
}
}
impl TryFrom<MerklePath> for SparseMerklePath {
type Error = MerkleError;
/// # Errors
///
/// This conversion returns [MerkleError::DepthTooBig] if the path length is greater than
/// [`SMT_MAX_DEPTH`].
fn try_from(path: MerklePath) -> Result<Self, MerkleError> {
SparseMerklePath::from_sized_iter(path)
}
}
impl From<SparseMerklePath> for Vec<RpoDigest> {
fn from(path: SparseMerklePath) -> Self {
Vec::from_iter(path)
}
}
// ITERATORS
// ================================================================================================
/// Iterator for [`SparseMerklePath`].
pub struct SparseMerklePathIter<'p> {
/// The "inner" value we're iterating over.
path: Cow<'p, SparseMerklePath>,
/// The depth a `next()` call will get. `next_depth == 0` indicates that the iterator has been
/// exhausted.
next_depth: u8,
}
impl Iterator for SparseMerklePathIter<'_> {
type Item = RpoDigest;
fn next(&mut self) -> Option<RpoDigest> {
let this_depth = self.next_depth;
// Paths don't include the root, so if `this_depth` is 0 then we keep returning `None`.
let this_depth = NonZero::new(this_depth)?;
self.next_depth = this_depth.get() - 1;
// `this_depth` is only ever decreasing, so it can't ever exceed `self.path.depth()`.
let node = self
.path
.at_depth(this_depth)
.expect("current depth should never exceed the path depth");
Some(node)
}
// SparseMerkleIter always knows its exact size.
fn size_hint(&self) -> (usize, Option<usize>) {
let remaining = ExactSizeIterator::len(self);
(remaining, Some(remaining))
}
}
impl ExactSizeIterator for SparseMerklePathIter<'_> {
fn len(&self) -> usize {
self.next_depth as usize
}
}
impl FusedIterator for SparseMerklePathIter<'_> {}
// TODO: impl DoubleEndedIterator.
impl IntoIterator for SparseMerklePath {
type IntoIter = SparseMerklePathIter<'static>;
type Item = <Self::IntoIter as Iterator>::Item;
fn into_iter(self) -> SparseMerklePathIter<'static> {
let tree_depth = self.depth();
SparseMerklePathIter {
path: Cow::Owned(self),
next_depth: tree_depth,
}
}
}
impl<'p> IntoIterator for &'p SparseMerklePath {
type Item = <SparseMerklePathIter<'p> as Iterator>::Item;
type IntoIter = SparseMerklePathIter<'p>;
fn into_iter(self) -> SparseMerklePathIter<'p> {
let tree_depth = self.depth();
SparseMerklePathIter {
path: Cow::Borrowed(self),
next_depth: tree_depth,
}
}
}
// COMPARISONS
// ================================================================================================
impl PartialEq<MerklePath> for SparseMerklePath {
fn eq(&self, rhs: &MerklePath) -> bool {
if self.depth() != rhs.depth() {
return false;
}
for (node, &rhs_node) in iter::zip(self, rhs.iter()) {
if node != rhs_node {
return false;
}
}
true
}
}
impl PartialEq<SparseMerklePath> for MerklePath {
fn eq(&self, rhs: &SparseMerklePath) -> bool {
rhs == self
}
}
// SPARSE VALUE PATH
// ================================================================================================
/// A container for a [crate::Word] value and its [SparseMerklePath] opening.
#[derive(Clone, Debug, Default, PartialEq, Eq)]
pub struct SparseValuePath {
/// The node value opening for `path`.
pub value: RpoDigest,
/// The path from `value` to `root` (exclusive), using an efficient memory representation for
/// empty nodes.
pub path: SparseMerklePath,
}
impl SparseValuePath {
/// Convenience function to construct a [SparseValuePath].
///
/// `value` is the value `path` leads to, in the tree.
pub fn new(value: RpoDigest, path: SparseMerklePath) -> Self {
Self { value, path }
}
}
impl From<(SparseMerklePath, Word)> for SparseValuePath {
fn from((path, value): (SparseMerklePath, Word)) -> Self {
SparseValuePath::new(value.into(), path)
}
}
impl TryFrom<ValuePath> for SparseValuePath {
type Error = MerkleError;
/// # Errors
///
/// This conversion returns [MerkleError::DepthTooBig] if the path length is greater than
/// [`SMT_MAX_DEPTH`].
fn try_from(other: ValuePath) -> Result<Self, MerkleError> {
let ValuePath { value, path } = other;
let path = SparseMerklePath::try_from(path)?;
Ok(SparseValuePath { value, path })
}
}
impl From<SparseValuePath> for ValuePath {
fn from(other: SparseValuePath) -> Self {
let SparseValuePath { value, path } = other;
ValuePath { value, path: path.into() }
}
}
impl PartialEq<ValuePath> for SparseValuePath {
fn eq(&self, rhs: &ValuePath) -> bool {
self.value == rhs.value && self.path == rhs.path
}
}
impl PartialEq<SparseValuePath> for ValuePath {
fn eq(&self, rhs: &SparseValuePath) -> bool {
rhs == self
}
}
// HELPERS
// ================================================================================================
/// Iterator for path depths, which start at the deepest part of the tree and go the shallowest
/// depth before the root (depth 1).
fn path_depth_iter(tree_depth: u8) -> impl ExactSizeIterator<Item = NonZero<u8>> {
let top_down_iter = (1..=tree_depth).map(|depth| {
// SAFETY: `RangeInclusive<1, _>` cannot ever yield 0. Even if `tree_depth` is 0, then the
// range is `RangeInclusive<1, 0>` will simply not yield any values, and this block won't
// even be reached.
unsafe { NonZero::new_unchecked(depth) }
});
// Reverse the top-down iterator to get a bottom-up iterator.
top_down_iter.rev()
}
// TESTS
// ================================================================================================
#[cfg(test)]
mod tests {
use alloc::vec::Vec;
use core::num::NonZero;
use assert_matches::assert_matches;
use super::SparseMerklePath;
use crate::{
Felt, ONE, Word,
hash::rpo::RpoDigest,
merkle::{
EmptySubtreeRoots, MerkleError, MerklePath, NodeIndex, SMT_DEPTH, Smt,
smt::SparseMerkleTree, sparse_path::path_depth_iter,
},
};
fn make_smt(pair_count: u64) -> Smt {
let entries: Vec<(RpoDigest, Word)> = (0..pair_count)
.map(|n| {
let leaf_index = ((n as f64 / pair_count as f64) * 255.0) as u64;
let key = RpoDigest::new([ONE, ONE, Felt::new(n), Felt::new(leaf_index)]);
let value = [ONE, ONE, ONE, ONE];
(key, value)
})
.collect();
Smt::with_entries(entries).unwrap()
}
#[test]
fn test_roundtrip() {
let tree = make_smt(8192);
for (key, _value) in tree.entries() {
let (control_path, _) = tree.open(key).into_parts();
assert_eq!(control_path.len(), tree.depth() as usize);
let sparse_path = SparseMerklePath::try_from(control_path.clone()).unwrap();
assert_eq!(control_path.depth(), sparse_path.depth());
assert_eq!(sparse_path.depth(), SMT_DEPTH);
let test_path = MerklePath::from_iter(sparse_path.clone().into_iter());
assert_eq!(control_path, test_path);
}
}
/// Manually test the exact bit patterns for a sample path of 8 nodes, including both empty and
/// non-empty nodes.
///
/// This also offers an overview of what each part of the bit-math involved means and
/// represents.
#[test]
fn test_sparse_bits() {
const DEPTH: u8 = 8;
let raw_nodes: [RpoDigest; DEPTH as usize] = [
// Depth 8.
([8u8, 8, 8, 8].into()),
// Depth 7.
*EmptySubtreeRoots::entry(DEPTH, 7),
// Depth 6.
*EmptySubtreeRoots::entry(DEPTH, 6),
// Depth 5.
[5u8, 5, 5, 5].into(),
// Depth 4.
[4u8, 4, 4, 4].into(),
// Depth 3.
*EmptySubtreeRoots::entry(DEPTH, 3),
// Depth 2.
*EmptySubtreeRoots::entry(DEPTH, 2),
// Depth 1.
*EmptySubtreeRoots::entry(DEPTH, 1),
// Root is not included.
];
let sparse_nodes: [Option<RpoDigest>; DEPTH as usize] = [
// Depth 8.
Some([8u8, 8, 8, 8].into()),
// Depth 7.
None,
// Depth 6.
None,
// Depth 5.
Some([5u8, 5, 5, 5].into()),
// Depth 4.
Some([4u8, 4, 4, 4].into()),
// Depth 3.
None,
// Depth 2.
None,
// Depth 1.
None,
// Root is not included.
];
const EMPTY_BITS: u64 = 0b0110_0111;
let sparse_path = SparseMerklePath::from_sized_iter(raw_nodes).unwrap();
assert_eq!(sparse_path.empty_nodes_mask, EMPTY_BITS);
// Keep track of how many non-empty nodes we have seen
let mut nonempty_idx = 0;
// Test starting from the deepest nodes (depth 8)
for depth in (1..=8).rev() {
let idx = (sparse_path.depth() - depth) as usize;
let bit = 1 << (depth - 1);
// Check that the depth bit is set correctly...
let is_set = (sparse_path.empty_nodes_mask & bit) != 0;
assert_eq!(is_set, sparse_nodes.get(idx).unwrap().is_none());
if is_set {
// Check that we don't return digests for empty nodes
let &test_node = sparse_nodes.get(idx).unwrap();
assert_eq!(test_node, None);
} else {
// Check that we can calculate non-empty indices correctly.
let control_node = raw_nodes.get(idx).unwrap();
assert_eq!(
sparse_path.get_nonempty_index(NonZero::new(depth).unwrap()),
nonempty_idx
);
let test_node = sparse_path.nodes.get(nonempty_idx).unwrap();
assert_eq!(test_node, control_node);
nonempty_idx += 1;
}
}
}
#[test]
fn from_sized_iter() {
let tree = make_smt(8192);
for (key, _value) in tree.entries() {
let index = NodeIndex::from(Smt::key_to_leaf_index(key));
let control_path = tree.get_path(key);
for (&control_node, proof_index) in
itertools::zip_eq(&*control_path, index.proof_indices())
{
let proof_node = tree.get_node_hash(proof_index);
assert_eq!(control_node, proof_node);
}
let sparse_path =
SparseMerklePath::from_sized_iter(control_path.clone().into_iter()).unwrap();
for (sparse_node, proof_idx) in
itertools::zip_eq(sparse_path.clone(), index.proof_indices())
{
let proof_node = tree.get_node_hash(proof_idx);
assert_eq!(sparse_node, proof_node);
}
assert_eq!(control_path.depth(), sparse_path.depth());
for (control, sparse) in itertools::zip_eq(control_path, sparse_path) {
assert_eq!(control, sparse);
}
}
}
#[test]
fn test_random_access() {
let tree = make_smt(8192);
for (i, (key, _value)) in tree.entries().enumerate() {
let control_path = tree.get_path(key);
let sparse_path = SparseMerklePath::try_from(control_path.clone()).unwrap();
assert_eq!(control_path.depth(), sparse_path.depth());
assert_eq!(sparse_path.depth(), SMT_DEPTH);
// Test random access by depth.
for depth in path_depth_iter(control_path.depth()) {
let control_node = control_path.at_depth(depth).unwrap();
let sparse_node = sparse_path.at_depth(depth).unwrap();
assert_eq!(control_node, sparse_node, "at depth {depth} for entry {i}");
}
// Test random access by index.
// Letting index get to `control_path.len()` will test that both sides correctly return
// `None` for out of bounds access.
for index in 0..=(control_path.len()) {
let control_node = control_path.at_idx(index);
let sparse_node = sparse_path.at_idx(index);
assert_eq!(control_node, sparse_node);
}
}
}
#[test]
fn test_borrowing_iterator() {
let tree = make_smt(8192);
for (key, _value) in tree.entries() {
let control_path = tree.get_path(key);
let sparse_path = SparseMerklePath::try_from(control_path.clone()).unwrap();
assert_eq!(control_path.depth(), sparse_path.depth());
assert_eq!(sparse_path.depth(), SMT_DEPTH);
// Test that both iterators yield the same amount of the same values.
let mut count: u64 = 0;
for (&control_node, sparse_node) in
itertools::zip_eq(control_path.iter(), sparse_path.iter())
{
count += 1;
assert_eq!(control_node, sparse_node);
}
assert_eq!(count, control_path.depth() as u64);
}
}
#[test]
fn test_owning_iterator() {
let tree = make_smt(8192);
for (key, _value) in tree.entries() {
let control_path = tree.get_path(key);
let path_depth = control_path.depth();
let sparse_path = SparseMerklePath::try_from(control_path.clone()).unwrap();
assert_eq!(control_path.depth(), sparse_path.depth());
assert_eq!(sparse_path.depth(), SMT_DEPTH);
// Test that both iterators yield the same amount of the same values.
let mut count: u64 = 0;
for (control_node, sparse_node) in itertools::zip_eq(control_path, sparse_path) {
count += 1;
assert_eq!(control_node, sparse_node);
}
assert_eq!(count, path_depth as u64);
}
}
#[test]
fn test_zero_sized() {
let nodes: Vec<RpoDigest> = Default::default();
// Sparse paths that don't actually contain any nodes should still be well behaved.
let sparse_path = SparseMerklePath::from_sized_iter(nodes).unwrap();
assert_eq!(sparse_path.depth(), 0);
assert_matches!(
sparse_path.at_depth(NonZero::new(1).unwrap()),
Err(MerkleError::DepthTooBig(1))
);
assert_eq!(sparse_path.at_idx(0), None);
assert_eq!(sparse_path.iter().next(), None);
assert_eq!(sparse_path.into_iter().next(), None);
}
}