/* Copyright (c) 2017, BitTorrent Inc. Copyright (c) 2019-2020, Steven Siloti Copyright (c) 2020-2021, Arvid Norberg All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the author nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "libtorrent/hash_picker.hpp" #include "libtorrent/peer_connection_interface.hpp" #include "libtorrent/stat.hpp" #include "libtorrent/aux_/merkle.hpp" #include "libtorrent/hex.hpp" #include "libtorrent/disk_interface.hpp" // for default_block_size #include "test.hpp" #include "test_utils.hpp" using namespace lt; #if 0 struct mock_peer_connection final : peer_connection_interface { tcp::endpoint const& remote() const override { return m_remote; } tcp::endpoint local_endpoint() const override { return {}; } void disconnect(error_code const&, operation_t, disconnect_severity_t) override {} peer_id const& pid() const override { return m_pid; } peer_id our_pid() const override { return m_pid; } void set_holepunch_mode() override {} torrent_peer* peer_info_struct() const override { return m_torrent_peer; } void set_peer_info(torrent_peer* pi) override { m_torrent_peer = pi; } bool is_outgoing() const override { return false; } void add_stat(std::int64_t, std::int64_t) override {} bool fast_reconnect() const override { return false; } bool is_choked() const override { return false; } bool failed() const override { return false; } lt::stat const& statistics() const override { return m_stat; } void get_peer_info(peer_info&) const override {} #ifndef TORRENT_DISABLE_LOGGING bool should_log(peer_log_alert::direction_t) const override { return true; } void peer_log(peer_log_alert::direction_t , char const*, char const*, ...) const noexcept override TORRENT_FORMAT(4, 5) {} #endif #if TORRENT_USE_I2P std::string const& destination() const override { static std::string const empty; return empty; } std::string const& local_i2p_endpoint() const override { static std::string const empty; return empty; } #endif torrent_peer* m_torrent_peer; lt::stat m_stat; tcp::endpoint m_remote; peer_id m_pid; }; TORRENT_TEST(pick_piece_layer) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); fs.add_file("test/tmp2", 4 * 512 * 16 * 1024); aux::vector trees; trees.push_back(aux::merkle_tree(merkle_num_nodes(merkle_num_leafs(4 * 512)))); aux::from_hex("0000000000000000000000000000000000000000000000000000000000000001", trees.back()[0].data()); trees.push_back(aux::merkle_tree(merkle_num_nodes(merkle_num_leafs(4 * 512)))); aux::from_hex("0000000000000000000000000000000000000000000000000000000000000001", trees.back()[0].data()); hash_picker picker(fs, trees); typed_bitfield pieces; pieces.resize(8 * 512); pieces.set_all(); mock_peer_connection mock_peer1, mock_peer2; mock_peer1.m_torrent_peer = (torrent_peer*)0x1; mock_peer2.m_torrent_peer = (torrent_peer*)0x2; auto picked = picker.pick_hashes(pieces, 2, &mock_peer1); TEST_EQUAL(int(picked.size()), 2); TEST_EQUAL(picked[0].file, 0_file); TEST_EQUAL(picked[0].base, 0); TEST_EQUAL(picked[0].count, 512); TEST_EQUAL(picked[0].index, 0); TEST_EQUAL(picked[0].proof_layers, 10); TEST_EQUAL(picked[1].file, 0_file); TEST_EQUAL(picked[1].base, 0); TEST_EQUAL(picked[1].count, 512); TEST_EQUAL(picked[1].index, 512); TEST_EQUAL(picked[1].proof_layers, 10); picked = picker.pick_hashes(pieces, 3, &mock_peer2); TEST_EQUAL(int(picked.size()), 3); TEST_EQUAL(picked[0].file, 0_file); TEST_EQUAL(picked[0].base, 0); TEST_EQUAL(picked[0].count, 512); TEST_EQUAL(picked[0].index, 1024); TEST_EQUAL(picked[0].proof_layers, 10); TEST_EQUAL(picked[1].file, 0_file); TEST_EQUAL(picked[1].base, 0); TEST_EQUAL(picked[1].count, 512); TEST_EQUAL(picked[1].index, 1536); TEST_EQUAL(picked[1].proof_layers, 10); TEST_EQUAL(picked[2].file, 1_file); TEST_EQUAL(picked[2].base, 0); TEST_EQUAL(picked[2].count, 512); TEST_EQUAL(picked[2].index, 0); TEST_EQUAL(picked[2].proof_layers, 10); picked = picker.pick_hashes(pieces, 4, &mock_peer1); TEST_EQUAL(int(picked.size()), 3); TEST_EQUAL(picked[0].file, 1_file); TEST_EQUAL(picked[0].base, 0); TEST_EQUAL(picked[0].count, 512); TEST_EQUAL(picked[0].index, 512); TEST_EQUAL(picked[0].proof_layers, 10); TEST_EQUAL(picked[1].file, 1_file); TEST_EQUAL(picked[1].base, 0); TEST_EQUAL(picked[1].count, 512); TEST_EQUAL(picked[1].index, 1024); TEST_EQUAL(picked[1].proof_layers, 10); TEST_EQUAL(picked[2].file, 1_file); TEST_EQUAL(picked[2].base, 0); TEST_EQUAL(picked[2].count, 512); TEST_EQUAL(picked[2].index, 1536); TEST_EQUAL(picked[2].proof_layers, 10); } #endif namespace { sha256_hash from_hex(span str) { sha256_hash ret; aux::from_hex(str, ret.data()); return ret; } } TORRENT_TEST(reject_piece_request) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto const root = from_hex("0000000000000000000000000000000000000000000000000000000000000001"); trees.emplace_back(4 * 512, 1, root.data()); hash_picker picker(fs, trees); typed_bitfield const pieces(4 * 512, true); auto const picked = picker.pick_hashes(pieces); picker.hashes_rejected(picked); auto const picked2 = picker.pick_hashes(pieces); TEST_CHECK(picked == picked2); } TORRENT_TEST(add_leaf_hashes) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 512); sha256_hash const root = full_tree[0]; trees.emplace_back(4 * 512, 1, root.data()); hash_picker picker(fs, trees); std::vector hashes; auto const pieces_start = full_tree.end_index() - merkle_num_leafs(4 * 512); for (int i = 0; i < 512; ++i) hashes.push_back(full_tree[pieces_start + i]); for (int i = 3; i > 0; i = merkle_get_parent(i)) { hashes.push_back(full_tree[merkle_get_sibling(i)]); } add_hashes_result result = picker.add_hashes(hash_request(0_file, 0, 0, 512, 10) , hashes); TEST_CHECK(result.valid); result = picker.add_hashes(hash_request(0_file, 0, 512, 512, 0) , span(full_tree).last(merkle_num_leafs(4 * 512) - 512).first(512)); TEST_CHECK(result.valid); hashes.clear(); for (int i = 1024; i < 1536; ++i) hashes.push_back(full_tree[pieces_start + i]); for (int i = 5; i > 0; i = merkle_get_parent(i)) { hashes.push_back(full_tree[merkle_get_sibling(i)]); } result = picker.add_hashes(hash_request(0_file, 0, 1024, 512, 10) , hashes); TEST_CHECK(result.valid); result = picker.add_hashes(hash_request(0_file, 0, 1536, 512, 0) , span(full_tree).last(merkle_num_leafs(4 * 512) - 1536).first(512)); TEST_CHECK(result.valid); TEST_CHECK(trees.front().build_vector() == full_tree); } TORRENT_TEST(add_piece_hashes) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 1024 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 1024); sha256_hash const root = full_tree[0]; trees.emplace_back(4 * 1024, 4, root.data()); hash_picker picker(fs, trees); auto pieces_start = full_tree.begin() + merkle_num_nodes(1024) - 1024; std::vector hashes; std::copy(pieces_start, pieces_start + 512, std::back_inserter(hashes)); hashes.push_back(full_tree[2]); add_hashes_result result = picker.add_hashes(hash_request(0_file, 2, 0, 512, 9), hashes); TEST_CHECK(result.valid); hashes.clear(); std::copy(pieces_start + 512, pieces_start + 1024, std::back_inserter(hashes)); result = picker.add_hashes(hash_request(0_file, 2, 512, 512, 8), hashes); TEST_CHECK(result.valid); auto const cmp = trees.front().build_vector(); TEST_CHECK(std::equal(cmp.begin(), cmp.begin() + merkle_num_nodes(1024), full_tree.begin())); } TORRENT_TEST(add_piece_hashes_padded) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 1029 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 1029); sha256_hash const root = full_tree[0]; trees.emplace_back(4 * 1029, 4, root.data()); hash_picker picker(fs, trees); auto pieces_start = merkle_num_nodes(merkle_num_leafs(1029)) - merkle_num_leafs(1029); std::vector hashes; // 5 hashes left after 1024 rounds up to 8, 1024 + 8 = 1032 std::copy(full_tree.begin() + pieces_start + 1024, full_tree.begin() + pieces_start + 1032 , std::back_inserter(hashes)); auto proof = merkle_get_parent(merkle_get_parent(merkle_get_parent(pieces_start + 1024))); while (proof > 0) { hashes.push_back(full_tree[merkle_get_sibling(proof)]); proof = merkle_get_parent(proof); } add_hashes_result result = picker.add_hashes(hash_request(0_file, 2, 1024, 8, 10), hashes); TEST_CHECK(result.valid); } TORRENT_TEST(add_piece_hashes_unpadded) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 1029 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 1029); sha256_hash const root = full_tree[0]; trees.emplace_back(4 * 1029, 4, root.data()); hash_picker picker(fs, trees); auto pieces_start = merkle_num_nodes(merkle_num_leafs(1029)) - merkle_num_leafs(1029); std::vector hashes; std::copy(full_tree.begin() + pieces_start + 1024, full_tree.begin() + pieces_start + 1029 , std::back_inserter(hashes)); auto proof = merkle_get_parent(merkle_get_parent(merkle_get_parent(pieces_start + 1024))); while (proof > 0) { hashes.push_back(full_tree[merkle_get_sibling(proof)]); proof = merkle_get_parent(proof); } add_hashes_result result = picker.add_hashes(hash_request(0_file, 2, 1024, 5, 10), hashes); TEST_CHECK(result.valid); } TORRENT_TEST(add_bad_hashes) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 512); sha256_hash const root = full_tree[0]; trees.emplace_back(4 * 512, 4, root.data()); hash_picker picker(fs, trees); // totally bogus hashes std::vector hashes(512); auto result = picker.add_hashes(hash_request(0_file, 2, 0, 512, 0), hashes); TEST_CHECK(!result.valid); // bad proof hash hashes.clear(); auto const pieces_start = full_tree.end_index() - 512; for (int i = 0; i < 512; ++i) hashes.push_back(full_tree[pieces_start + i]); hashes.back()[1] ^= 0xaa; result = picker.add_hashes(hash_request(0_file, 2, 0, 512, 0), hashes); TEST_CHECK(!result.valid); } TORRENT_TEST(bad_block_hash) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); auto const full_tree = build_tree(4 * 512); aux::vector trees; trees.emplace_back(4 * 512, 1, full_tree[0].data()); sha256_hash hash; aux::from_hex("0000000000000000000000000000000000000000000000000000000000000001" , hash.data()); trees.front().set_block(1, hash); hash_picker picker(fs, trees); std::vector hashes; auto leafs_start = full_tree.end() - merkle_num_leafs(4 * 512); std::copy(leafs_start, leafs_start + 512, std::back_inserter(hashes)); for (int i = 3; i > 0; i = merkle_get_parent(i)) { hashes.push_back(full_tree[merkle_get_sibling(i)]); } add_hashes_result result = picker.add_hashes(hash_request(0_file, 0, 0, 512, 10) , hashes); TEST_CHECK(result.valid); TEST_CHECK((result.hash_failed == std::vector>>{{1_piece, {0}}})); } TORRENT_TEST(set_block_hash) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto const full_tree = build_tree(4 * 512); trees.emplace_back(4 * 512, 4, full_tree[0].data()); trees.front().load_tree(full_tree, std::vector(std::size_t(merkle_num_leafs(4 * 512)), false)); int const first_leaf = full_tree.end_index() - merkle_num_leafs(4 * 512); hash_picker picker(fs, trees); auto result = picker.set_block_hash(1_piece, default_block_size , full_tree[first_leaf + 5]); TEST_CHECK(result.status == set_block_hash_result::result::success); result = picker.set_block_hash(2_piece, default_block_size * 2 , full_tree[first_leaf + 10]); TEST_CHECK(result.status == set_block_hash_result::result::success); result = picker.set_block_hash(2_piece, default_block_size * 2 , sha256_hash("01234567890123456789012345678901")); TEST_CHECK(result.status == set_block_hash_result::result::block_hash_failed); } TORRENT_TEST(set_block_hash_fail) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto full_tree = build_tree(4 * 512); trees.emplace_back(4 * 512, 4, full_tree[0].data()); // zero out the inner nodes for a piece along with a single leaf node // then add a bogus hash for the leaf int const first_leaf = full_tree.end_index() - merkle_num_leafs(4 * 512); full_tree[merkle_get_parent(first_leaf + 12)].clear(); full_tree[merkle_get_parent(first_leaf + 14)].clear(); full_tree[first_leaf + 13].clear(); trees.front().load_tree(full_tree, std::vector(std::size_t(merkle_num_leafs(4 * 512)), false)); hash_picker picker(fs, trees); TEST_CHECK(picker.set_block_hash(3_piece, 0, full_tree[first_leaf + 12]).status == lt::set_block_hash_result::result::unknown); TEST_CHECK(picker.set_block_hash(3_piece, 2 * default_block_size, full_tree[first_leaf + 14]).status == lt::set_block_hash_result::result::unknown); TEST_CHECK(picker.set_block_hash(3_piece, 3 * default_block_size, full_tree[first_leaf + 15]).status == lt::set_block_hash_result::result::unknown); auto const result = picker.set_block_hash(3_piece, default_block_size, sha256_hash("01234567890123456789012345678901")); TEST_CHECK(result.status == set_block_hash_result::result::piece_hash_failed); TEST_CHECK(trees.front()[merkle_get_parent(first_leaf + 12)].is_all_zeros()); TEST_CHECK(trees.front()[merkle_get_parent(first_leaf + 13)].is_all_zeros()); TEST_CHECK(trees.front()[merkle_get_parent(first_leaf + 14)].is_all_zeros()); TEST_CHECK(trees.front()[merkle_get_parent(first_leaf + 15)].is_all_zeros()); } TORRENT_TEST(set_block_hash_pass) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; auto full_tree = build_tree(4 * 512); trees.emplace_back(4 * 512, 4, full_tree[0].data()); // zero out the inner nodes for a piece along with a single leaf node // then add a bogus hash for the leaf int const first_leaf = full_tree.end_index() - merkle_num_leafs(4 * 512); full_tree[merkle_get_parent(first_leaf + 12)].clear(); full_tree[merkle_get_parent(first_leaf + 14)].clear(); auto const orig_hash = full_tree[first_leaf + 13]; full_tree[first_leaf + 13].clear(); trees.front().load_tree(full_tree, std::vector(std::size_t(merkle_num_leafs(4 * 512)), false)); hash_picker picker(fs, trees); TEST_CHECK(picker.set_block_hash(3_piece, 0, full_tree[first_leaf + 12]).status == lt::set_block_hash_result::result::unknown); TEST_CHECK(picker.set_block_hash(3_piece, 2 * default_block_size, full_tree[first_leaf + 14]).status == lt::set_block_hash_result::result::unknown); TEST_CHECK(picker.set_block_hash(3_piece, 3 * default_block_size, full_tree[first_leaf + 15]).status == lt::set_block_hash_result::result::unknown); auto const result = picker.set_block_hash(3_piece, default_block_size, orig_hash); TEST_CHECK(result.status == set_block_hash_result::result::success); } TORRENT_TEST(pass_piece) { file_storage fs; fs.set_piece_length(4 * 16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); auto const full_tree = build_tree(4 * 512); aux::vector trees; sha256_hash root = full_tree[0]; trees.emplace_back(4 * 512, 4, root.data()); hash_picker picker(fs, trees); int const first_leaf = full_tree.end_index() - merkle_num_leafs(4 * 512); for (int i = 0; i < 4; ++i) { auto result = picker.set_block_hash(0_piece, default_block_size * i , full_tree[first_leaf + i]); TEST_CHECK(result.status == set_block_hash_result::result::unknown); } auto const pieces_start = full_tree.begin() + merkle_num_nodes(512) - 512; std::vector hashes; std::copy(pieces_start, pieces_start + 512, std::back_inserter(hashes)); add_hashes_result result = picker.add_hashes(hash_request(0_file, 2, 0, 512, 8), hashes); TEST_CHECK(result.valid); TEST_EQUAL(result.hash_passed.size(), 1); if (result.hash_passed.size() == 1) { TEST_EQUAL(result.hash_passed[0], 0_piece); } } TORRENT_TEST(only_pick_have_pieces) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 4 * 512 * 16 * 1024); aux::vector trees; sha256_hash root = from_hex("0000000000000000000000000000000000000000000000000000000000000001"); trees.emplace_back(4 * 512, 1, root.data()); hash_picker picker(fs, trees); typed_bitfield pieces; pieces.resize(4 * 512); pieces.set_bit(512_piece); pieces.set_bit(1537_piece); std::vector picked; for (int i = 0; i < 3; ++i) picked.push_back(picker.pick_hashes(pieces)); TEST_EQUAL(picked[0].file, 0_file); TEST_EQUAL(picked[0].base, 0); TEST_EQUAL(picked[0].count, 512); TEST_EQUAL(picked[0].index, 512); TEST_EQUAL(picked[0].proof_layers, 10); TEST_EQUAL(picked[1].file, 0_file); TEST_EQUAL(picked[1].base, 0); TEST_EQUAL(picked[1].count, 512); TEST_EQUAL(picked[1].index, 1536); TEST_EQUAL(picked[1].proof_layers, 10); TEST_EQUAL(picked[2].count, 0); } TORRENT_TEST(validate_hash_request) { file_storage fs; fs.set_piece_length(16 * 1024); fs.add_file("test/tmp1", 2048 * 16 * 1024); // the merkle tree for this file has 2048 blocks int const num_leaves = merkle_num_leafs(2048); int const num_layers = merkle_num_layers(num_leaves); int const max = std::numeric_limits::max(); int const min = std::numeric_limits::min(); // hash_request make function // (file_index_t const f, int const b, int const i, int const c, int const p) TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 0, 1, 0), fs)); // file index out-of-range TEST_CHECK(!validate_hash_request(hash_request(file_index_t{1}, 0, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{-1}, 0, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{max}, 0, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{min}, 0, 0, 1, 0), fs)); // base out-of-range TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, -1, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, num_layers, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, max, 0, 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, min, 0, 1, 0), fs)); // base in-range TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 0, 1, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, num_layers-1, 0, 1, 0), fs)); // count out-of-range // the upper limit of count depends on base and index TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, 0, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, num_leaves + 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 100, num_leaves - 100 + 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, 8193, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, min, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, max, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 1, 0, num_leaves / 2 + 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 2, 0, num_leaves / 4 + 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 3, 0, num_leaves / 8 + 1, 0), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 3, 5, num_leaves / 8 - 5 + 1, 0), fs)); // count in-range TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 100, num_leaves - 100, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 0, 1, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 0, num_leaves, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 1, 0, num_leaves / 2, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 2, 0, num_leaves / 4, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 3, 0, num_leaves / 8, 0), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 3, 5, num_leaves / 8 - 5, 0), fs)); // proof_layers out-of-range TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 0, 0, 1, num_layers), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 1, 0, 1, num_layers), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 1, 0, 1, min), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 1, 0, 1, max), fs)); TEST_CHECK(!validate_hash_request(hash_request(file_index_t{0}, 1, 0, 1, -1), fs)); // proof_layers in-range TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 0, 0, 1, num_layers - 1), fs)); TEST_CHECK(validate_hash_request(hash_request(file_index_t{0}, 1, 0, 1, num_layers - 2), fs)); }