// Copyright 2019 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tlog
import (
"bytes"
"crypto/sha256"
"fmt"
"testing"
)
type testHashStorage []Hash
func (t testHashStorage) ReadHash(level int, n int64) (Hash, error) {
return t[StoredHashIndex(level, n)], nil
}
func (t testHashStorage) ReadHashes(index []int64) ([]Hash, error) {
// It's not required by HashReader that indexes be in increasing order,
// but check that the functions we are testing only ever ask for
// indexes in increasing order.
for i := 1; i < len(index); i++ {
if index[i-1] >= index[i] {
panic("indexes out of order")
}
}
out := make([]Hash, len(index))
for i, x := range index {
out[i] = t[x]
}
return out, nil
}
type testTilesStorage struct {
unsaved int
m map[Tile][]byte
}
func (t testTilesStorage) Height() int {
return 2
}
func (t *testTilesStorage) SaveTiles(tiles []Tile, data [][]byte) {
t.unsaved -= len(tiles)
}
func (t *testTilesStorage) ReadTiles(tiles []Tile) ([][]byte, error) {
out := make([][]byte, len(tiles))
for i, tile := range tiles {
out[i] = t.m[tile]
}
t.unsaved += len(tiles)
return out, nil
}
func TestTree(t *testing.T) {
var trees []Hash
var leafhashes []Hash
var storage testHashStorage
tiles := make(map[Tile][]byte)
const testH = 2
for i := int64(0); i < 100; i++ {
data := []byte(fmt.Sprintf("leaf %d", i))
hashes, err := StoredHashes(i, data, storage)
if err != nil {
t.Fatal(err)
}
leafhashes = append(leafhashes, RecordHash(data))
oldStorage := len(storage)
storage = append(storage, hashes...)
if count := StoredHashCount(i + 1); count != int64(len(storage)) {
t.Errorf("StoredHashCount(%d) = %d, have %d StoredHashes", i+1, count, len(storage))
}
th, err := TreeHash(i+1, storage)
if err != nil {
t.Fatal(err)
}
for _, tile := range NewTiles(testH, i, i+1) {
data, err := ReadTileData(tile, storage)
if err != nil {
t.Fatal(err)
}
old := Tile{H: tile.H, L: tile.L, N: tile.N, W: tile.W - 1}
oldData := tiles[old]
if len(oldData) != len(data)-HashSize || !bytes.Equal(oldData, data[:len(oldData)]) {
t.Fatalf("tile %v not extending earlier tile %v", tile.Path(), old.Path())
}
tiles[tile] = data
}
for _, tile := range NewTiles(testH, 0, i+1) {
data, err := ReadTileData(tile, storage)
if err != nil {
t.Fatal(err)
}
if !bytes.Equal(tiles[tile], data) {
t.Fatalf("mismatch at %+v", tile)
}
}
for _, tile := range NewTiles(testH, i/2, i+1) {
data, err := ReadTileData(tile, storage)
if err != nil {
t.Fatal(err)
}
if !bytes.Equal(tiles[tile], data) {
t.Fatalf("mismatch at %+v", tile)
}
}
// Check that all the new hashes are readable from their tiles.
for j := oldStorage; j < len(storage); j++ {
tile := TileForIndex(testH, int64(j))
data, ok := tiles[tile]
if !ok {
t.Log(NewTiles(testH, 0, i+1))
t.Fatalf("TileForIndex(%d, %d) = %v, not yet stored (i=%d, stored %d)", testH, j, tile.Path(), i, len(storage))
continue
}
h, err := HashFromTile(tile, data, int64(j))
if err != nil {
t.Fatal(err)
}
if h != storage[j] {
t.Errorf("HashFromTile(%v, %d) = %v, want %v", tile.Path(), int64(j), h, storage[j])
}
}
trees = append(trees, th)
// Check that leaf proofs work, for all trees and leaves so far.
for j := int64(0); j <= i; j++ {
p, err := ProveRecord(i+1, j, storage)
if err != nil {
t.Fatalf("ProveRecord(%d, %d): %v", i+1, j, err)
}
if err := CheckRecord(p, i+1, th, j, leafhashes[j]); err != nil {
t.Fatalf("CheckRecord(%d, %d): %v", i+1, j, err)
}
for k := range p {
p[k][0] ^= 1
if err := CheckRecord(p, i+1, th, j, leafhashes[j]); err == nil {
t.Fatalf("CheckRecord(%d, %d) succeeded with corrupt proof hash #%d!", i+1, j, k)
}
p[k][0] ^= 1
}
}
// Check that leaf proofs work using TileReader.
// To prove a leaf that way, all you have to do is read and verify its hash.
storage := &testTilesStorage{m: tiles}
thr := TileHashReader(Tree{i + 1, th}, storage)
for j := int64(0); j <= i; j++ {
h, err := thr.ReadHashes([]int64{StoredHashIndex(0, j)})
if err != nil {
t.Fatalf("TileHashReader(%d).ReadHashes(%d): %v", i+1, j, err)
}
if h[0] != leafhashes[j] {
t.Fatalf("TileHashReader(%d).ReadHashes(%d) returned wrong hash", i+1, j)
}
// Even though reading the hash suffices,
// check we can generate the proof too.
p, err := ProveRecord(i+1, j, thr)
if err != nil {
t.Fatalf("ProveRecord(%d, %d, TileHashReader(%d)): %v", i+1, j, i+1, err)
}
if err := CheckRecord(p, i+1, th, j, leafhashes[j]); err != nil {
t.Fatalf("CheckRecord(%d, %d, TileHashReader(%d)): %v", i+1, j, i+1, err)
}
}
if storage.unsaved != 0 {
t.Fatalf("TileHashReader(%d) did not save %d tiles", i+1, storage.unsaved)
}
// Check that ReadHashes will give an error if the index is not in the tree.
if _, err := thr.ReadHashes([]int64{(i + 1) * 2}); err == nil {
t.Fatalf("TileHashReader(%d).ReadHashes(%d) for index not in tree <nil>, want err", i, i+1)
}
if storage.unsaved != 0 {
t.Fatalf("TileHashReader(%d) did not save %d tiles", i+1, storage.unsaved)
}
// Check that tree proofs work, for all trees so far, using TileReader.
// To prove a tree that way, all you have to do is compute and verify its hash.
for j := int64(0); j <= i; j++ {
h, err := TreeHash(j+1, thr)
if err != nil {
t.Fatalf("TreeHash(%d, TileHashReader(%d)): %v", j, i+1, err)
}
if h != trees[j] {
t.Fatalf("TreeHash(%d, TileHashReader(%d)) = %x, want %x (%v)", j, i+1, h[:], trees[j][:], trees[j])
}
// Even though computing the subtree hash suffices,
// check that we can generate the proof too.
p, err := ProveTree(i+1, j+1, thr)
if err != nil {
t.Fatalf("ProveTree(%d, %d): %v", i+1, j+1, err)
}
if err := CheckTree(p, i+1, th, j+1, trees[j]); err != nil {
t.Fatalf("CheckTree(%d, %d): %v [%v]", i+1, j+1, err, p)
}
for k := range p {
p[k][0] ^= 1
if err := CheckTree(p, i+1, th, j+1, trees[j]); err == nil {
t.Fatalf("CheckTree(%d, %d) succeeded with corrupt proof hash #%d!", i+1, j+1, k)
}
p[k][0] ^= 1
}
}
if storage.unsaved != 0 {
t.Fatalf("TileHashReader(%d) did not save %d tiles", i+1, storage.unsaved)
}
}
}
func TestSplitStoredHashIndex(t *testing.T) {
for l := 0; l < 10; l++ {
for n := int64(0); n < 100; n++ {
x := StoredHashIndex(l, n)
l1, n1 := SplitStoredHashIndex(x)
if l1 != l || n1 != n {
t.Fatalf("StoredHashIndex(%d, %d) = %d, but SplitStoredHashIndex(%d) = %d, %d", l, n, x, x, l1, n1)
}
}
}
}
// TODO(rsc): Test invalid paths too, like "tile/3/5/123/456/078".
var tilePaths = []struct {
path string
tile Tile
}{
{"tile/4/0/001", Tile{4, 0, 1, 16}},
{"tile/4/0/001.p/5", Tile{4, 0, 1, 5}},
{"tile/3/5/x123/x456/078", Tile{3, 5, 123456078, 8}},
{"tile/3/5/x123/x456/078.p/2", Tile{3, 5, 123456078, 2}},
{"tile/1/0/x003/x057/500", Tile{1, 0, 3057500, 2}},
{"tile/3/5/123/456/078", Tile{}},
{"tile/3/-1/123/456/078", Tile{}},
{"tile/1/data/x003/x057/500", Tile{1, -1, 3057500, 2}},
}
func TestTilePath(t *testing.T) {
for _, tt := range tilePaths {
if tt.tile.H > 0 {
p := tt.tile.Path()
if p != tt.path {
t.Errorf("%+v.Path() = %q, want %q", tt.tile, p, tt.path)
}
}
tile, err := ParseTilePath(tt.path)
if err != nil {
if tt.tile.H == 0 {
// Expected error.
continue
}
t.Errorf("ParseTilePath(%q): %v", tt.path, err)
} else if tile != tt.tile {
if tt.tile.H == 0 {
t.Errorf("ParseTilePath(%q): expected error, got %+v", tt.path, tt.tile)
continue
}
t.Errorf("ParseTilePath(%q) = %+v, want %+v", tt.path, tile, tt.tile)
}
}
}
func TestEmptyTree(t *testing.T) {
h, err := TreeHash(0, nil)
if err != nil {
t.Fatal(err)
}
if h != sha256.Sum256(nil) {
t.Fatalf("TreeHash(0) = %x, want SHA-256('')", h)
}
}