// Copyright 2015 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package trie import ( "bytes" crand "crypto/rand" mrand "math/rand" "testing" "time" "github.com/tangerine-network/go-tangerine/common" "github.com/tangerine-network/go-tangerine/crypto" "github.com/tangerine-network/go-tangerine/ethdb" ) func init() { mrand.Seed(time.Now().Unix()) } // makeProvers creates Merkle trie provers based on different implementations to // test all variations. func makeProvers(trie *Trie) []func(key []byte) *ethdb.MemDatabase { var provers []func(key []byte) *ethdb.MemDatabase // Create a direct trie based Merkle prover provers = append(provers, func(key []byte) *ethdb.MemDatabase { proof := ethdb.NewMemDatabase() trie.Prove(key, 0, proof) return proof }) // Create a leaf iterator based Merkle prover provers = append(provers, func(key []byte) *ethdb.MemDatabase { proof := ethdb.NewMemDatabase() if it := NewIterator(trie.NodeIterator(key)); it.Next() && bytes.Equal(key, it.Key) { for _, p := range it.Prove() { proof.Put(crypto.Keccak256(p), p) } } return proof }) return provers } func TestProof(t *testing.T) { trie, vals := randomTrie(500) root := trie.Hash() for i, prover := range makeProvers(trie) { for _, kv := range vals { proof := prover(kv.k) if proof == nil { t.Fatalf("prover %d: missing key %x while constructing proof", i, kv.k) } val, _, err := VerifyProof(root, kv.k, proof) if err != nil { t.Fatalf("prover %d: failed to verify proof for key %x: %v\nraw proof: %x", i, kv.k, err, proof) } if !bytes.Equal(val, kv.v) { t.Fatalf("prover %d: verified value mismatch for key %x: have %x, want %x", i, kv.k, val, kv.v) } } } } func TestOneElementProof(t *testing.T) { trie := new(Trie) updateString(trie, "k", "v") for i, prover := range makeProvers(trie) { proof := prover([]byte("k")) if proof == nil { t.Fatalf("prover %d: nil proof", i) } if proof.Len() != 1 { t.Errorf("prover %d: proof should have one element", i) } val, _, err := VerifyProof(trie.Hash(), []byte("k"), proof) if err != nil { t.Fatalf("prover %d: failed to verify proof: %v\nraw proof: %x", i, err, proof) } if !bytes.Equal(val, []byte("v")) { t.Fatalf("prover %d: verified value mismatch: have %x, want 'k'", i, val) } } } func TestBadProof(t *testing.T) { trie, vals := randomTrie(800) root := trie.Hash() for i, prover := range makeProvers(trie) { for _, kv := range vals { proof := prover(kv.k) if proof == nil { t.Fatalf("prover %d: nil proof", i) } key := proof.Keys()[mrand.Intn(proof.Len())] val, _ := proof.Get(key) proof.Delete(key) mutateByte(val) proof.Put(crypto.Keccak256(val), val) if _, _, err := VerifyProof(root, kv.k, proof); err == nil { t.Fatalf("prover %d: expected proof to fail for key %x", i, kv.k) } } } } // Tests that missing keys can also be proven. The test explicitly uses a single // entry trie and checks for missing keys both before and after the single entry. func TestMissingKeyProof(t *testing.T) { trie := new(Trie) updateString(trie, "k", "v") for i, key := range []string{"a", "j", "l", "z"} { proof := ethdb.NewMemDatabase() trie.Prove([]byte(key), 0, proof) if proof.Len() != 1 { t.Errorf("test %d: proof should have one element", i) } val, _, err := VerifyProof(trie.Hash(), []byte(key), proof) if err != nil { t.Fatalf("test %d: failed to verify proof: %v\nraw proof: %x", i, err, proof) } if val != nil { t.Fatalf("test %d: verified value mismatch: have %x, want nil", i, val) } } } // mutateByte changes one byte in b. func mutateByte(b []byte) { for r := mrand.Intn(len(b)); ; { new := byte(mrand.Intn(255)) if new != b[r] { b[r] = new break } } } func BenchmarkProve(b *testing.B) { trie, vals := randomTrie(100) var keys []string for k := range vals { keys = append(keys, k) } b.ResetTimer() for i := 0; i < b.N; i++ { kv := vals[keys[i%len(keys)]] proofs := ethdb.NewMemDatabase() if trie.Prove(kv.k, 0, proofs); len(proofs.Keys()) == 0 { b.Fatalf("zero length proof for %x", kv.k) } } } func BenchmarkVerifyProof(b *testing.B) { trie, vals := randomTrie(100) root := trie.Hash() var keys []string var proofs []*ethdb.MemDatabase for k := range vals { keys = append(keys, k) proof := ethdb.NewMemDatabase() trie.Prove([]byte(k), 0, proof) proofs = append(proofs, proof) } b.ResetTimer() for i := 0; i < b.N; i++ { im := i % len(keys) if _, _, err := VerifyProof(root, []byte(keys[im]), proofs[im]); err != nil { b.Fatalf("key %x: %v", keys[im], err) } } } func randomTrie(n int) (*Trie, map[string]*kv) { trie := new(Trie) vals := make(map[string]*kv) for i := byte(0); i < 100; i++ { value := &kv{common.LeftPadBytes([]byte{i}, 32), []byte{i}, false} value2 := &kv{common.LeftPadBytes([]byte{i + 10}, 32), []byte{i}, false} trie.Update(value.k, value.v) trie.Update(value2.k, value2.v) vals[string(value.k)] = value vals[string(value2.k)] = value2 } for i := 0; i < n; i++ { value := &kv{randBytes(32), randBytes(20), false} trie.Update(value.k, value.v) vals[string(value.k)] = value } return trie, vals } func randBytes(n int) []byte { r := make([]byte, n) crand.Read(r) return r }