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ton/crypto/vm/cells/MerkleProof.cpp
ton 9d6853ef24 liteclient signature check support
1. update liteclient/liteserver. Now liteserver sends signatures of
blocks and liteclient checks them. I.e. liteclient completely checks
received data.
2. validator-engine: more GC options
3. blockchain-explorer: show all block transactions (instead of 256)
4. some bugfixes
2019-09-14 18:14:55 +04:00

300 lines
9.1 KiB
C++

/*
This file is part of TON Blockchain Library.
TON Blockchain 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 2 of the License, or
(at your option) any later version.
TON Blockchain 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 TON Blockchain Library. If not, see <http://www.gnu.org/licenses/>.
Copyright 2017-2019 Telegram Systems LLP
*/
#include "vm/cells/MerkleProof.h"
#include "vm/cells/CellBuilder.h"
#include "vm/cells/CellSlice.h"
#include "vm/boc.h"
#include "td/utils/HashMap.h"
#include "td/utils/HashSet.h"
namespace vm {
namespace detail {
class MerkleProofImpl {
public:
explicit MerkleProofImpl(MerkleProof::IsPrunnedFunction is_prunned) : is_prunned_(std::move(is_prunned)) {
}
explicit MerkleProofImpl(CellUsageTree *usage_tree) : usage_tree_(usage_tree) {
}
Ref<Cell> create_from(Ref<Cell> cell) {
if (!is_prunned_) {
CHECK(usage_tree_);
dfs_usage_tree(cell, usage_tree_->root_id());
is_prunned_ = [this](const Ref<Cell> &cell) { return visited_cells_.count(cell->get_hash()) == 0; };
}
return dfs(cell, cell->get_level());
}
private:
using Key = std::pair<Cell::Hash, int>;
td::HashMap<Key, Ref<Cell>> cells_;
td::HashSet<Cell::Hash> visited_cells_;
CellUsageTree *usage_tree_{nullptr};
MerkleProof::IsPrunnedFunction is_prunned_;
void dfs_usage_tree(Ref<Cell> cell, CellUsageTree::NodeId node_id) {
if (!usage_tree_->is_loaded(node_id)) {
return;
}
visited_cells_.insert(cell->get_hash());
CellSlice cs(NoVm(), cell);
for (unsigned i = 0; i < cs.size_refs(); i++) {
dfs_usage_tree(cs.prefetch_ref(i), usage_tree_->get_child(node_id, i));
}
}
Ref<Cell> dfs(Ref<Cell> cell, int merkle_depth) {
CHECK(cell.not_null());
Key key{cell->get_hash(), merkle_depth};
{
auto it = cells_.find(key);
if (it != cells_.end()) {
CHECK(it->second.not_null());
return it->second;
}
}
if (is_prunned_(cell)) {
auto res = CellBuilder::create_pruned_branch(cell, merkle_depth + 1);
CHECK(res.not_null());
cells_.emplace(key, res);
return res;
}
CellSlice cs(NoVm(), cell);
int children_merkle_depth = cs.child_merkle_depth(merkle_depth);
CellBuilder cb;
cb.store_bits(cs.fetch_bits(cs.size()));
for (unsigned i = 0; i < cs.size_refs(); i++) {
cb.store_ref(dfs(cs.prefetch_ref(i), children_merkle_depth));
}
auto res = cb.finalize(cs.is_special());
CHECK(res.not_null());
cells_.emplace(key, res);
return res;
}
};
} // namespace detail
Ref<Cell> MerkleProof::generate_raw(Ref<Cell> cell, IsPrunnedFunction is_prunned) {
return detail::MerkleProofImpl(is_prunned).create_from(cell);
}
Ref<Cell> MerkleProof::generate_raw(Ref<Cell> cell, CellUsageTree *usage_tree) {
return detail::MerkleProofImpl(usage_tree).create_from(cell);
}
Ref<Cell> MerkleProof::virtualize_raw(Ref<Cell> cell, Cell::VirtualizationParameters virt) {
return cell->virtualize(virt);
}
Ref<Cell> MerkleProof::generate(Ref<Cell> cell, IsPrunnedFunction is_prunned) {
int cell_level = cell->get_level();
if (cell_level != 0) {
return {};
}
auto raw = generate_raw(std::move(cell), is_prunned);
return CellBuilder::create_merkle_proof(std::move(raw));
}
Ref<Cell> MerkleProof::generate(Ref<Cell> cell, CellUsageTree *usage_tree) {
int cell_level = cell->get_level();
if (cell_level != 0) {
return {};
}
auto raw = generate_raw(std::move(cell), usage_tree);
return CellBuilder::create_merkle_proof(std::move(raw));
}
td::Result<Ref<Cell>> unpack_proof(Ref<Cell> cell) {
CHECK(cell.not_null());
td::uint8 level = static_cast<td::uint8>(cell->get_level());
if (level != 0) {
return td::Status::Error("Level of MerkleProof must be zero");
}
CellSlice cs(NoVm(), std::move(cell));
if (cs.special_type() != Cell::SpecialType::MerkleProof) {
return td::Status::Error("Not a MekleProof cell");
}
return cs.fetch_ref();
}
Ref<Cell> MerkleProof::virtualize(Ref<Cell> cell, int virtualization) {
auto r_raw = unpack_proof(std::move(cell));
if (r_raw.is_error()) {
return {};
}
return virtualize_raw(r_raw.move_as_ok(), {0 /*level*/, static_cast<td::uint8>(virtualization)});
}
class MerkleProofCombine {
public:
MerkleProofCombine(Ref<Cell> a, Ref<Cell> b) : a_(std::move(a)), b_(std::move(b)) {
}
td::Result<Ref<Cell>> run() {
TRY_RESULT(a, unpack_proof(a_));
TRY_RESULT(b, unpack_proof(b_));
if (a->get_hash(0) != b->get_hash(0)) {
return td::Status::Error("Can't combine MerkleProofs with different roots");
}
dfs(a, 0);
dfs(b, 0);
return CellBuilder::create_merkle_proof(create_A(a, 0, 0));
}
private:
Ref<Cell> a_;
Ref<Cell> b_;
struct Info {
Ref<Cell> cell_;
Ref<Cell> prunned_cells_[Cell::max_level]; // Cache prunned cells with different levels to reuse them
Ref<Cell> get_prunned_cell(int depth) {
if (depth < Cell::max_level) {
return prunned_cells_[depth];
}
return {};
}
Ref<Cell> get_any_cell() const {
if (cell_.not_null()) {
return cell_;
}
for (auto &cell : prunned_cells_) {
if (cell.not_null()) {
return cell;
}
}
UNREACHABLE();
}
};
using Key = std::pair<Cell::Hash, int>;
td::HashMap<Cell::Hash, Info> cells_;
td::HashMap<Key, Ref<Cell>> create_A_res_;
td::HashSet<Key> visited_;
void dfs(Ref<Cell> cell, int merkle_depth) {
if (!visited_.emplace(cell->get_hash(), merkle_depth).second) {
return;
}
auto &info = cells_[cell->get_hash(merkle_depth)];
CellSlice cs(NoVm(), cell);
// check if prunned cell is bounded
if (cs.special_type() == Cell::SpecialType::PrunnedBranch && static_cast<int>(cell->get_level()) > merkle_depth) {
info.prunned_cells_[cell->get_level() - 1] = std::move(cell);
return;
}
info.cell_ = std::move(cell);
auto child_merkle_depth = cs.child_merkle_depth(merkle_depth);
for (size_t i = 0, size = cs.size_refs(); i < size; i++) {
dfs(cs.fetch_ref(), child_merkle_depth);
}
}
Ref<Cell> create_A(Ref<Cell> cell, int merkle_depth, int a_merkle_depth) {
merkle_depth = cell->get_level_mask().apply(merkle_depth).get_level();
auto key = Key(cell->get_hash(merkle_depth), a_merkle_depth);
auto it = create_A_res_.find(key);
if (it != create_A_res_.end()) {
return it->second;
}
auto res = do_create_A(std::move(cell), merkle_depth, a_merkle_depth);
create_A_res_.emplace(key, res);
return res;
}
Ref<Cell> do_create_A(Ref<Cell> cell, int merkle_depth, int a_merkle_depth) {
auto &info = cells_[cell->get_hash(merkle_depth)];
if (info.cell_.is_null()) {
Ref<Cell> res = info.get_prunned_cell(a_merkle_depth);
if (res.is_null()) {
res = CellBuilder::create_pruned_branch(info.get_any_cell(), a_merkle_depth + 1, merkle_depth);
}
return res;
}
CHECK(info.cell_.not_null());
CellSlice cs(NoVm(), info.cell_);
//CHECK(cs.size_refs() != 0);
if (cs.size_refs() == 0) {
return info.cell_;
}
auto child_merkle_depth = cs.child_merkle_depth(merkle_depth);
auto child_a_merkle_depth = cs.child_merkle_depth(a_merkle_depth);
CellBuilder cb;
cb.store_bits(cs.fetch_bits(cs.size()));
for (unsigned i = 0; i < cs.size_refs(); i++) {
cb.store_ref(create_A(cs.prefetch_ref(i), child_merkle_depth, child_a_merkle_depth));
}
return cb.finalize(cs.is_special());
}
};
Ref<Cell> MerkleProof::combine(Ref<Cell> a, Ref<Cell> b) {
auto res = MerkleProofCombine(std::move(a), std::move(b)).run();
if (res.is_error()) {
return {};
}
return res.move_as_ok();
}
MerkleProofBuilder::MerkleProofBuilder(Ref<Cell> root)
: usage_tree(std::make_shared<CellUsageTree>()), orig_root(std::move(root)) {
usage_root = UsageCell::create(orig_root, usage_tree->root_ptr());
}
void MerkleProofBuilder::reset(Ref<Cell> root) {
usage_tree = std::make_shared<CellUsageTree>();
orig_root = std::move(root);
usage_root = UsageCell::create(orig_root, usage_tree->root_ptr());
}
void MerkleProofBuilder::clear() {
usage_tree.reset();
orig_root.clear();
usage_root.clear();
}
Ref<Cell> MerkleProofBuilder::extract_proof() const {
return MerkleProof::generate(orig_root, usage_tree.get());
}
bool MerkleProofBuilder::extract_proof_to(Ref<Cell> &proof_root) const {
return orig_root.not_null() && (proof_root = extract_proof()).not_null();
}
td::Result<td::BufferSlice> MerkleProofBuilder::extract_proof_boc() const {
Ref<Cell> proof_root = extract_proof();
if (proof_root.is_null()) {
return td::Status::Error("cannot create Merkle proof");
} else {
return std_boc_serialize(std::move(proof_root));
}
}
} // namespace vm