fix: compilation errors

2026-01-12 00:51:29 +01:00 · 2023-06-13 22:43:08 -07:00
parent 53d52b8adc
commit fe5cac9edc
9 changed files with 84 additions and 88 deletions
--- a/src/merkle/partial_mt/tests.rs
+++ b/src/merkle/partial_mt/tests.rs
@@ -1,6 +1,6 @@
 use super::{
-    super::{int_to_node, MerkleStore, MerkleTree, NodeIndex, PartialMerkleTree},
-    ValuePath, Vec, Word,
+    super::{digests_to_words, int_to_node, MerkleStore, MerkleTree, NodeIndex, PartialMerkleTree},
+    RpoDigest, ValuePath, Vec,
 };

 // TEST DATA
@@ -18,7 +18,7 @@ const NODE31: NodeIndex = NodeIndex::new_unchecked(3, 1);
 const NODE32: NodeIndex = NodeIndex::new_unchecked(3, 2);
 const NODE33: NodeIndex = NodeIndex::new_unchecked(3, 3);

-const VALUES8: [Word; 8] = [
+const VALUES8: [RpoDigest; 8] = [
    int_to_node(30),
    int_to_node(31),
    int_to_node(32),
@@ -44,22 +44,21 @@ const VALUES8: [Word; 8] = [
 // (30)  (31)    (32)  (33)    (34)  (35)    (36)  (37)
 //
 // Where node number is a concatenation of its depth and index. For example, node with
-// NodeIndex(3, 5) will be labled as `35`. Leaves of the tree are shown as nodes with parenthesis
+// NodeIndex(3, 5) will be labeled as `35`. Leaves of the tree are shown as nodes with parenthesis
 // (33).

 /// Checks that root returned by `root()` function is equal to the expected one.
 #[test]
 fn get_root() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);
-
    let path33 = ms.get_path(expected_root, NODE33).unwrap();

-    let pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

-    assert_eq!(pmt.root(), expected_root.into());
+    assert_eq!(pmt.root(), expected_root);
 }

 /// This test checks correctness of the `add_path()` and `get_path()` functions. First it creates a
@@ -67,7 +66,7 @@ fn get_root() {
 /// it checks that paths returned by `get_path()` function are equal to the expected ones.
 #[test]
 fn add_and_get_paths() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);
@@ -76,10 +75,8 @@ fn add_and_get_paths() {
    let expected_path22 = ms.get_path(expected_root, NODE22).unwrap();

    let mut pmt = PartialMerkleTree::new();
-    pmt.add_path(3, expected_path33.value.into(), expected_path33.path.clone())
-        .unwrap();
-    pmt.add_path(2, expected_path22.value.into(), expected_path22.path.clone())
-        .unwrap();
+    pmt.add_path(3, expected_path33.value, expected_path33.path.clone()).unwrap();
+    pmt.add_path(2, expected_path22.value, expected_path22.path.clone()).unwrap();

    let path33 = pmt.get_path(NODE33).unwrap();
    let path22 = pmt.get_path(NODE22).unwrap();
@@ -87,58 +84,58 @@ fn add_and_get_paths() {

    assert_eq!(expected_path33.path, path33);
    assert_eq!(expected_path22.path, path22);
-    assert_eq!(expected_root, *actual_root);
+    assert_eq!(expected_root, actual_root);
 }

 /// Checks that function `get_node` used on nodes 10 and 32 returns expected values.
 #[test]
 fn get_node() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);

    let path33 = ms.get_path(expected_root, NODE33).unwrap();

-    let pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

-    assert_eq!(ms.get_node(expected_root, NODE32).unwrap(), *pmt.get_node(NODE32).unwrap());
-    assert_eq!(ms.get_node(expected_root, NODE10).unwrap(), *pmt.get_node(NODE10).unwrap());
+    assert_eq!(ms.get_node(expected_root, NODE32).unwrap(), pmt.get_node(NODE32).unwrap());
+    assert_eq!(ms.get_node(expected_root, NODE10).unwrap(), pmt.get_node(NODE10).unwrap());
 }

 /// Updates leaves of the PMT using `update_leaf()` function and checks that new root of the tree
 /// is equal to the expected one.
 #[test]
 fn update_leaf() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let root = mt.root();

    let mut ms = MerkleStore::from(&mt);
    let path33 = ms.get_path(root, NODE33).unwrap();

-    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

    let new_value32 = int_to_node(132);
    let expected_root = ms.set_node(root, NODE32, new_value32).unwrap().root;

-    pmt.update_leaf(NODE32, new_value32.into()).unwrap();
+    pmt.update_leaf(NODE32, new_value32).unwrap();
    let actual_root = pmt.root();

-    assert_eq!(expected_root, *actual_root);
+    assert_eq!(expected_root, actual_root);

    let new_value20 = int_to_node(120);
    let expected_root = ms.set_node(expected_root, NODE20, new_value20).unwrap().root;

-    pmt.update_leaf(NODE20, new_value20.into()).unwrap();
+    pmt.update_leaf(NODE20, new_value20).unwrap();
    let actual_root = pmt.root();

-    assert_eq!(expected_root, *actual_root);
+    assert_eq!(expected_root, actual_root);
 }

 /// Checks that paths of the PMT returned by `paths()` function are equal to the expected ones.
 #[test]
 fn get_paths() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);
@@ -147,8 +144,8 @@ fn get_paths() {
    let path22 = ms.get_path(expected_root, NODE22).unwrap();

    let mut pmt = PartialMerkleTree::new();
-    pmt.add_path(3, path33.value.into(), path33.path.clone()).unwrap();
-    pmt.add_path(2, path22.value.into(), path22.path.clone()).unwrap();
+    pmt.add_path(3, path33.value, path33.path).unwrap();
+    pmt.add_path(2, path22.value, path22.path).unwrap();
    // After PMT creation with path33 (33; 32, 20, 11) and path22 (22; 23, 10) we will have this
    // tree:
    //
@@ -170,7 +167,7 @@ fn get_paths() {
            (
                leaf,
                ValuePath {
-                    value: mt.get_node(leaf).unwrap().into(),
+                    value: mt.get_node(leaf).unwrap(),
                    path: mt.get_path(leaf).unwrap(),
                },
            )
@@ -185,7 +182,7 @@ fn get_paths() {
 // Checks correctness of leaves determination when using the `leaves()` function.
 #[test]
 fn leaves() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);
@@ -193,7 +190,7 @@ fn leaves() {
    let path33 = ms.get_path(expected_root, NODE33).unwrap();
    let path22 = ms.get_path(expected_root, NODE22).unwrap();

-    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();
    // After PMT creation with path33 (33; 32, 20, 11) we will have this tree:
    //
    //           ______root______
@@ -206,17 +203,17 @@ fn leaves() {
    //
    // Which have leaf nodes 11, 20, 32 and 33.

-    let value11 = mt.get_node(NODE11).unwrap().into();
-    let value20 = mt.get_node(NODE20).unwrap().into();
-    let value32 = mt.get_node(NODE32).unwrap().into();
-    let value33 = mt.get_node(NODE33).unwrap().into();
+    let value11 = mt.get_node(NODE11).unwrap();
+    let value20 = mt.get_node(NODE20).unwrap();
+    let value32 = mt.get_node(NODE32).unwrap();
+    let value33 = mt.get_node(NODE33).unwrap();

    let leaves = vec![(NODE11, value11), (NODE20, value20), (NODE32, value32), (NODE33, value33)];

-    let expected_leaves = leaves.iter().map(|&tuple| tuple);
+    let expected_leaves = leaves.iter().copied();
    assert!(expected_leaves.eq(pmt.leaves()));

-    pmt.add_path(2, path22.value.into(), path22.path).unwrap();
+    pmt.add_path(2, path22.value, path22.path).unwrap();
    // After adding the path22 (22; 23, 10) to the existing PMT we will have this tree:
    //
    //           ______root______
@@ -229,11 +226,11 @@ fn leaves() {
    //
    // Which have leaf nodes 20, 22, 23, 32 and 33.

-    let value20 = mt.get_node(NODE20).unwrap().into();
-    let value22 = mt.get_node(NODE22).unwrap().into();
-    let value23 = mt.get_node(NODE23).unwrap().into();
-    let value32 = mt.get_node(NODE32).unwrap().into();
-    let value33 = mt.get_node(NODE33).unwrap().into();
+    let value20 = mt.get_node(NODE20).unwrap();
+    let value22 = mt.get_node(NODE22).unwrap();
+    let value23 = mt.get_node(NODE23).unwrap();
+    let value32 = mt.get_node(NODE32).unwrap();
+    let value33 = mt.get_node(NODE33).unwrap();

    let leaves = vec![
        (NODE20, value20),
@@ -243,7 +240,7 @@ fn leaves() {
        (NODE33, value33),
    ];

-    let expected_leaves = leaves.iter().map(|&tuple| tuple);
+    let expected_leaves = leaves.iter().copied();
    assert!(expected_leaves.eq(pmt.leaves()));
 }

@@ -254,22 +251,22 @@ fn err_add_path() {
    let path22 = vec![int_to_node(4), int_to_node(5)].into();

    let mut pmt = PartialMerkleTree::new();
-    pmt.add_path(3, int_to_node(6).into(), path33).unwrap();
+    pmt.add_path(3, int_to_node(6), path33).unwrap();

-    assert!(pmt.add_path(2, int_to_node(7).into(), path22).is_err());
+    assert!(pmt.add_path(2, int_to_node(7), path22).is_err());
 }

 /// Checks that the request of the node which is not in the PMT will cause an error.
 #[test]
 fn err_get_node() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);

    let path33 = ms.get_path(expected_root, NODE33).unwrap();

-    let pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

    assert!(pmt.get_node(NODE22).is_err());
    assert!(pmt.get_node(NODE23).is_err());
@@ -280,14 +277,14 @@ fn err_get_node() {
 /// Checks that the request of the path from the leaf which is not in the PMT will cause an error.
 #[test]
 fn err_get_path() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);

    let path33 = ms.get_path(expected_root, NODE33).unwrap();

-    let pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

    assert!(pmt.get_path(NODE22).is_err());
    assert!(pmt.get_path(NODE23).is_err());
@@ -297,17 +294,17 @@ fn err_get_path() {

 #[test]
 fn err_update_leaf() {
-    let mt = MerkleTree::new(VALUES8.to_vec()).unwrap();
+    let mt = MerkleTree::new(digests_to_words(&VALUES8)).unwrap();
    let expected_root = mt.root();

    let ms = MerkleStore::from(&mt);

    let path33 = ms.get_path(expected_root, NODE33).unwrap();

-    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value.into(), path33.path)]).unwrap();
+    let mut pmt = PartialMerkleTree::with_paths([(3, path33.value, path33.path)]).unwrap();

-    assert!(pmt.update_leaf(NODE22, int_to_node(22).into()).is_err());
-    assert!(pmt.update_leaf(NODE23, int_to_node(23).into()).is_err());
-    assert!(pmt.update_leaf(NODE30, int_to_node(30).into()).is_err());
-    assert!(pmt.update_leaf(NODE31, int_to_node(31).into()).is_err());
+    assert!(pmt.update_leaf(NODE22, int_to_node(22)).is_err());
+    assert!(pmt.update_leaf(NODE23, int_to_node(23)).is_err());
+    assert!(pmt.update_leaf(NODE30, int_to_node(30)).is_err());
+    assert!(pmt.update_leaf(NODE31, int_to_node(31)).is_err());
 }