monero/tests/unit_tests/serialization.cpp

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// Copyright (c) 2014-2020, The Monero Project
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//
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without modification, are
// permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice, this list of
// conditions and the following disclaimer.
//
// 2. 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.
//
// 3. Neither the name of the copyright holder 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 HOLDER 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.
//
// Parts of this file are originally copyright (c) 2012-2013 The Cryptonote developers
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#include <cstring>
#include <cstdint>
#include <cstdio>
#include <iostream>
#include <vector>
#include <boost/foreach.hpp>
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#include <boost/archive/portable_binary_iarchive.hpp>
#include "cryptonote_basic/cryptonote_basic.h"
#include "cryptonote_basic/cryptonote_basic_impl.h"
#include "ringct/rctSigs.h"
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#include "serialization/binary_archive.h"
#include "serialization/json_archive.h"
#include "serialization/debug_archive.h"
#include "serialization/variant.h"
#include "serialization/containers.h"
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#include "serialization/binary_utils.h"
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#include "wallet/wallet2.h"
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#include "gtest/gtest.h"
#include "unit_tests_utils.h"
#include "device/device.hpp"
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using namespace std;
using namespace crypto;
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struct Struct
{
int32_t a;
int32_t b;
char blob[8];
};
template <class Archive>
struct serializer<Archive, Struct>
{
static bool serialize(Archive &ar, Struct &s) {
ar.begin_object();
ar.tag("a");
ar.serialize_int(s.a);
ar.tag("b");
ar.serialize_int(s.b);
ar.tag("blob");
ar.serialize_blob(s.blob, sizeof(s.blob));
ar.end_object();
return true;
}
};
struct Struct1
{
vector<boost::variant<Struct, int32_t>> si;
vector<int16_t> vi;
BEGIN_SERIALIZE_OBJECT()
FIELD(si)
FIELD(vi)
END_SERIALIZE()
/*template <bool W, template <bool> class Archive>
bool do_serialize(Archive<W> &ar)
{
ar.begin_object();
ar.tag("si");
::do_serialize(ar, si);
ar.tag("vi");
::do_serialize(ar, vi);
ar.end_object();
}*/
};
struct Blob
{
uint64_t a;
uint32_t b;
bool operator==(const Blob& rhs) const
{
return a == rhs.a;
}
};
VARIANT_TAG(binary_archive, Struct, 0xe0);
VARIANT_TAG(binary_archive, int, 0xe1);
VARIANT_TAG(json_archive, Struct, "struct");
VARIANT_TAG(json_archive, int, "int");
VARIANT_TAG(debug_archive, Struct1, "struct1");
VARIANT_TAG(debug_archive, Struct, "struct");
VARIANT_TAG(debug_archive, int, "int");
BLOB_SERIALIZER(Blob);
bool try_parse(const string &blob)
{
Struct1 s1;
return serialization::parse_binary(blob, s1);
}
TEST(Serialization, BinaryArchiveInts) {
uint64_t x = 0xff00000000, x1;
ostringstream oss;
binary_archive<true> oar(oss);
oar.serialize_int(x);
ASSERT_TRUE(oss.good());
ASSERT_EQ(8, oss.str().size());
ASSERT_EQ(string("\0\0\0\0\xff\0\0\0", 8), oss.str());
binary_archive<false> iar{epee::strspan<std::uint8_t>(oss.str())};
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iar.serialize_int(x1);
ASSERT_EQ(8, iar.getpos());
ASSERT_TRUE(iar.good());
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ASSERT_EQ(x, x1);
}
TEST(Serialization, BinaryArchiveVarInts) {
uint64_t x = 0xff00000000, x1;
ostringstream oss;
binary_archive<true> oar(oss);
oar.serialize_varint(x);
ASSERT_TRUE(oss.good());
ASSERT_EQ(6, oss.str().size());
ASSERT_EQ(string("\x80\x80\x80\x80\xF0\x1F", 6), oss.str());
binary_archive<false> iar{epee::strspan<std::uint8_t>(oss.str())};
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iar.serialize_varint(x1);
ASSERT_TRUE(iar.good());
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ASSERT_EQ(x, x1);
}
TEST(Serialization, Test1) {
ostringstream str;
binary_archive<true> ar(str);
Struct1 s1;
s1.si.push_back(0);
{
Struct s;
s.a = 5;
s.b = 65539;
std::memcpy(s.blob, "12345678", 8);
s1.si.push_back(s);
}
s1.si.push_back(1);
s1.vi.push_back(10);
s1.vi.push_back(22);
string blob;
ASSERT_TRUE(serialization::dump_binary(s1, blob));
ASSERT_TRUE(try_parse(blob));
ASSERT_EQ('\xE0', blob[6]);
blob[6] = '\xE1';
ASSERT_FALSE(try_parse(blob));
blob[6] = '\xE2';
ASSERT_FALSE(try_parse(blob));
}
TEST(Serialization, Overflow) {
Blob x = { 0xff00000000 };
Blob x1;
string blob;
ASSERT_TRUE(serialization::dump_binary(x, blob));
ASSERT_EQ(sizeof(Blob), blob.size());
ASSERT_TRUE(serialization::parse_binary(blob, x1));
ASSERT_EQ(x, x1);
vector<Blob> bigvector;
ASSERT_FALSE(serialization::parse_binary(blob, bigvector));
ASSERT_EQ(0, bigvector.size());
}
TEST(Serialization, serializes_vector_uint64_as_varint)
{
std::vector<uint64_t> v;
string blob;
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(1, blob.size());
// +1 byte
v.push_back(0);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(2, blob.size());
// +1 byte
v.push_back(1);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(3, blob.size());
// +2 bytes
v.push_back(0x80);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(5, blob.size());
// +2 bytes
v.push_back(0xFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(7, blob.size());
// +2 bytes
v.push_back(0x3FFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(9, blob.size());
// +3 bytes
v.push_back(0x40FF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(12, blob.size());
// +10 bytes
v.push_back(0xFFFFFFFFFFFFFFFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(22, blob.size());
}
TEST(Serialization, serializes_vector_int64_as_fixed_int)
{
std::vector<int64_t> v;
string blob;
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(1, blob.size());
// +8 bytes
v.push_back(0);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(9, blob.size());
// +8 bytes
v.push_back(1);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(17, blob.size());
// +8 bytes
v.push_back(0x80);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(25, blob.size());
// +8 bytes
v.push_back(0xFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(33, blob.size());
// +8 bytes
v.push_back(0x3FFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(41, blob.size());
// +8 bytes
v.push_back(0x40FF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(49, blob.size());
// +8 bytes
v.push_back(0xFFFFFFFFFFFFFFFF);
ASSERT_TRUE(serialization::dump_binary(v, blob));
ASSERT_EQ(57, blob.size());
}
namespace
{
template<typename T>
std::vector<T> linearize_vector2(const std::vector< std::vector<T> >& vec_vec)
{
std::vector<T> res;
BOOST_FOREACH(const auto& vec, vec_vec)
{
res.insert(res.end(), vec.begin(), vec.end());
}
return res;
}
}
TEST(Serialization, serializes_transacion_signatures_correctly)
{
using namespace cryptonote;
transaction tx;
transaction tx1;
string blob;
// Empty tx
tx.set_null();
ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_EQ(5, blob.size()); // 5 bytes + 0 bytes extra + 0 bytes signatures
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Miner tx without signatures
txin_gen txin_gen1;
txin_gen1.height = 0;
tx.set_null();
tx.vin.push_back(txin_gen1);
ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_EQ(7, blob.size()); // 5 bytes + 2 bytes vin[0] + 0 bytes extra + 0 bytes signatures
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Miner tx with empty signatures 2nd vector
tx.signatures.resize(1);
tx.invalidate_hashes();
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ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_EQ(7, blob.size()); // 5 bytes + 2 bytes vin[0] + 0 bytes extra + 0 bytes signatures
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Miner tx with one signature
tx.signatures[0].resize(1);
ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Miner tx with 2 empty vectors
tx.signatures.resize(2);
tx.signatures[0].resize(0);
tx.signatures[1].resize(0);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Miner tx with 2 signatures
tx.signatures[0].resize(1);
tx.signatures[1].resize(1);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Two txin_gen, no signatures
tx.vin.push_back(txin_gen1);
tx.signatures.resize(0);
tx.invalidate_hashes();
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ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_EQ(9, blob.size()); // 5 bytes + 2 * 2 bytes vins + 0 bytes extra + 0 bytes signatures
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Two txin_gen, signatures vector contains only one empty element
tx.signatures.resize(1);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Two txin_gen, signatures vector contains two empty elements
tx.signatures.resize(2);
tx.invalidate_hashes();
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ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_EQ(9, blob.size()); // 5 bytes + 2 * 2 bytes vins + 0 bytes extra + 0 bytes signatures
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Two txin_gen, signatures vector contains three empty elements
tx.signatures.resize(3);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Two txin_gen, signatures vector contains two non empty elements
tx.signatures.resize(2);
tx.signatures[0].resize(1);
tx.signatures[1].resize(1);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// A few bytes instead of signature
tx.vin.clear();
tx.vin.push_back(txin_gen1);
tx.signatures.clear();
tx.invalidate_hashes();
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ASSERT_TRUE(serialization::dump_binary(tx, blob));
blob.append(std::string(sizeof(crypto::signature) / 2, 'x'));
ASSERT_FALSE(serialization::parse_binary(blob, tx1));
// blob contains one signature
blob.append(std::string(sizeof(crypto::signature) / 2, 'y'));
ASSERT_FALSE(serialization::parse_binary(blob, tx1));
// Not enough signature vectors for all inputs
txin_to_key txin_to_key1;
txin_to_key1.amount = 1;
memset(&txin_to_key1.k_image, 0x42, sizeof(crypto::key_image));
txin_to_key1.key_offsets.push_back(12);
txin_to_key1.key_offsets.push_back(3453);
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tx.vin.clear();
tx.vin.push_back(txin_to_key1);
tx.vin.push_back(txin_to_key1);
tx.signatures.resize(1);
tx.signatures[0].resize(2);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// Too much signatures for two inputs
tx.signatures.resize(3);
tx.signatures[0].resize(2);
tx.signatures[1].resize(2);
tx.signatures[2].resize(2);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// First signatures vector contains too little elements
tx.signatures.resize(2);
tx.signatures[0].resize(1);
tx.signatures[1].resize(2);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// First signatures vector contains too much elements
tx.signatures.resize(2);
tx.signatures[0].resize(3);
tx.signatures[1].resize(2);
tx.invalidate_hashes();
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ASSERT_FALSE(serialization::dump_binary(tx, blob));
// There are signatures for each input
tx.signatures.resize(2);
tx.signatures[0].resize(2);
tx.signatures[1].resize(2);
tx.invalidate_hashes();
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ASSERT_TRUE(serialization::dump_binary(tx, blob));
ASSERT_TRUE(serialization::parse_binary(blob, tx1));
ASSERT_EQ(tx, tx1);
ASSERT_EQ(linearize_vector2(tx.signatures), linearize_vector2(tx1.signatures));
// Blob doesn't contain enough data
blob.resize(blob.size() - sizeof(crypto::signature) / 2);
ASSERT_FALSE(serialization::parse_binary(blob, tx1));
// Blob contains too much data
blob.resize(blob.size() + sizeof(crypto::signature));
ASSERT_FALSE(serialization::parse_binary(blob, tx1));
// Blob contains one excess signature
blob.resize(blob.size() + sizeof(crypto::signature) / 2);
ASSERT_FALSE(serialization::parse_binary(blob, tx1));
}
TEST(Serialization, serializes_ringct_types)
{
string blob;
rct::key key0, key1;
rct::keyV keyv0, keyv1;
rct::keyM keym0, keym1;
rct::ctkey ctkey0, ctkey1;
rct::ctkeyV ctkeyv0, ctkeyv1;
rct::ctkeyM ctkeym0, ctkeym1;
rct::ecdhTuple ecdh0, ecdh1;
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rct::boroSig boro0, boro1;
rct::mgSig mg0, mg1;
rct::clsag clsag0, clsag1;
rct::Bulletproof bp0, bp1;
rct::rctSig s0, s1;
cryptonote::transaction tx0, tx1;
key0 = rct::skGen();
ASSERT_TRUE(serialization::dump_binary(key0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, key1));
ASSERT_TRUE(key0 == key1);
keyv0 = rct::skvGen(30);
for (size_t n = 0; n < keyv0.size(); ++n)
keyv0[n] = rct::skGen();
ASSERT_TRUE(serialization::dump_binary(keyv0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, keyv1));
ASSERT_TRUE(keyv0.size() == keyv1.size());
for (size_t n = 0; n < keyv0.size(); ++n)
{
ASSERT_TRUE(keyv0[n] == keyv1[n]);
}
keym0 = rct::keyMInit(9, 12);
for (size_t n = 0; n < keym0.size(); ++n)
for (size_t i = 0; i < keym0[n].size(); ++i)
keym0[n][i] = rct::skGen();
ASSERT_TRUE(serialization::dump_binary(keym0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, keym1));
ASSERT_TRUE(keym0.size() == keym1.size());
for (size_t n = 0; n < keym0.size(); ++n)
{
ASSERT_TRUE(keym0[n].size() == keym1[n].size());
for (size_t i = 0; i < keym0[n].size(); ++i)
{
ASSERT_TRUE(keym0[n][i] == keym1[n][i]);
}
}
rct::skpkGen(ctkey0.dest, ctkey0.mask);
ASSERT_TRUE(serialization::dump_binary(ctkey0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, ctkey1));
ASSERT_TRUE(!memcmp(&ctkey0, &ctkey1, sizeof(ctkey0)));
ctkeyv0 = std::vector<rct::ctkey>(14);
for (size_t n = 0; n < ctkeyv0.size(); ++n)
rct::skpkGen(ctkeyv0[n].dest, ctkeyv0[n].mask);
ASSERT_TRUE(serialization::dump_binary(ctkeyv0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, ctkeyv1));
ASSERT_TRUE(ctkeyv0.size() == ctkeyv1.size());
for (size_t n = 0; n < ctkeyv0.size(); ++n)
{
ASSERT_TRUE(!memcmp(&ctkeyv0[n], &ctkeyv1[n], sizeof(ctkeyv0[n])));
}
ctkeym0 = std::vector<rct::ctkeyV>(9);
for (size_t n = 0; n < ctkeym0.size(); ++n)
{
ctkeym0[n] = std::vector<rct::ctkey>(11);
for (size_t i = 0; i < ctkeym0[n].size(); ++i)
rct::skpkGen(ctkeym0[n][i].dest, ctkeym0[n][i].mask);
}
ASSERT_TRUE(serialization::dump_binary(ctkeym0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, ctkeym1));
ASSERT_TRUE(ctkeym0.size() == ctkeym1.size());
for (size_t n = 0; n < ctkeym0.size(); ++n)
{
ASSERT_TRUE(ctkeym0[n].size() == ctkeym1[n].size());
for (size_t i = 0; i < ctkeym0.size(); ++i)
{
ASSERT_TRUE(!memcmp(&ctkeym0[n][i], &ctkeym1[n][i], sizeof(ctkeym0[n][i])));
}
}
ecdh0.mask = rct::skGen();
ecdh0.amount = rct::skGen();
ASSERT_TRUE(serialization::dump_binary(ecdh0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, ecdh1));
ASSERT_TRUE(!memcmp(&ecdh0.mask, &ecdh1.mask, sizeof(ecdh0.mask)));
ASSERT_TRUE(!memcmp(&ecdh0.amount, &ecdh1.amount, sizeof(ecdh0.amount)));
for (size_t n = 0; n < 64; ++n)
{
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boro0.s0[n] = rct::skGen();
boro0.s1[n] = rct::skGen();
}
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boro0.ee = rct::skGen();
ASSERT_TRUE(serialization::dump_binary(boro0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, boro1));
ASSERT_TRUE(!memcmp(&boro0, &boro1, sizeof(boro0)));
// create a full rct signature to use its innards
vector<uint64_t> inamounts;
rct::ctkeyV sc, pc;
rct::ctkey sctmp, pctmp;
inamounts.push_back(6000);
tie(sctmp, pctmp) = rct::ctskpkGen(inamounts.back());
sc.push_back(sctmp);
pc.push_back(pctmp);
inamounts.push_back(7000);
tie(sctmp, pctmp) = rct::ctskpkGen(inamounts.back());
sc.push_back(sctmp);
pc.push_back(pctmp);
vector<uint64_t> amounts;
rct::keyV amount_keys;
//add output 500
amounts.push_back(500);
amount_keys.push_back(rct::hash_to_scalar(rct::zero()));
rct::keyV destinations;
rct::key Sk, Pk;
rct::skpkGen(Sk, Pk);
destinations.push_back(Pk);
//add output for 12500
amounts.push_back(12500);
amount_keys.push_back(rct::hash_to_scalar(rct::zero()));
rct::skpkGen(Sk, Pk);
destinations.push_back(Pk);
//compute rct data with mixin 3
const rct::RCTConfig rct_config{ rct::RangeProofPaddedBulletproof, 2 };
s0 = rct::genRctSimple(rct::zero(), sc, pc, destinations, inamounts, amounts, amount_keys, NULL, NULL, 0, 3, rct_config, hw::get_device("default"));
ASSERT_FALSE(s0.p.MGs.empty());
ASSERT_TRUE(s0.p.CLSAGs.empty());
mg0 = s0.p.MGs[0];
ASSERT_TRUE(serialization::dump_binary(mg0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, mg1));
ASSERT_TRUE(mg0.ss.size() == mg1.ss.size());
for (size_t n = 0; n < mg0.ss.size(); ++n)
{
ASSERT_TRUE(mg0.ss[n] == mg1.ss[n]);
}
ASSERT_TRUE(mg0.cc == mg1.cc);
// mixRing and II are not serialized, they are meant to be reconstructed
ASSERT_TRUE(mg1.II.empty());
ASSERT_FALSE(s0.p.bulletproofs.empty());
bp0 = s0.p.bulletproofs.front();
ASSERT_TRUE(serialization::dump_binary(bp0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, bp1));
bp1.V = bp0.V; // this is not saved, as it is reconstructed from other tx data
ASSERT_EQ(bp0, bp1);
const rct::RCTConfig rct_config_clsag{ rct::RangeProofPaddedBulletproof, 3 };
s0 = rct::genRctSimple(rct::zero(), sc, pc, destinations, inamounts, amounts, amount_keys, NULL, NULL, 0, 3, rct_config_clsag, hw::get_device("default"));
ASSERT_FALSE(s0.p.CLSAGs.empty());
ASSERT_TRUE(s0.p.MGs.empty());
clsag0 = s0.p.CLSAGs[0];
ASSERT_TRUE(serialization::dump_binary(clsag0, blob));
ASSERT_TRUE(serialization::parse_binary(blob, clsag1));
ASSERT_TRUE(clsag0.s.size() == clsag1.s.size());
for (size_t n = 0; n < clsag0.s.size(); ++n)
{
ASSERT_TRUE(clsag0.s[n] == clsag1.s[n]);
}
ASSERT_TRUE(clsag0.c1 == clsag1.c1);
// I is not serialized, they are meant to be reconstructed
ASSERT_TRUE(clsag0.D == clsag1.D);
}
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TEST(Serialization, portability_wallet)
{
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const cryptonote::network_type nettype = cryptonote::TESTNET;
tools::wallet2 w(nettype);
const boost::filesystem::path wallet_file = unit_test::data_dir / "wallet_9svHk1";
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string password = "test";
bool r = false;
try
{
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w.load(wallet_file.string(), password);
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r = true;
}
catch (const exception& e)
{}
ASSERT_TRUE(r);
/*
fields of tools::wallet2 to be checked:
std::vector<crypto::hash> m_blockchain
std::vector<transfer_details> m_transfers // TODO
cryptonote::account_public_address m_account_public_address
std::unordered_map<crypto::key_image, size_t> m_key_images
std::unordered_map<crypto::hash, unconfirmed_transfer_details> m_unconfirmed_txs
std::unordered_multimap<crypto::hash, payment_details> m_payments
std::unordered_map<crypto::hash, crypto::secret_key> m_tx_keys
std::unordered_map<crypto::hash, confirmed_transfer_details> m_confirmed_txs
std::unordered_map<crypto::hash, std::string> m_tx_notes
std::unordered_map<crypto::hash, payment_details> m_unconfirmed_payments
std::unordered_map<crypto::public_key, size_t> m_pub_keys
std::vector<tools::wallet2::address_book_row> m_address_book
*/
// blockchain
ASSERT_TRUE(w.m_blockchain.size() == 1);
ASSERT_TRUE(epee::string_tools::pod_to_hex(w.m_blockchain[0]) == "48ca7cd3c8de5b6a4d53d2861fbdaedca141553559f9be9520068053cda8430b");
// transfers (TODO)
ASSERT_TRUE(w.m_transfers.size() == 3);
// account public address
ASSERT_TRUE(epee::string_tools::pod_to_hex(w.m_account_public_address.m_view_public_key) == "e47d4b6df6ab7339539148c2a03ad3e2f3434e5ab2046848e1f21369a3937cad");
ASSERT_TRUE(epee::string_tools::pod_to_hex(w.m_account_public_address.m_spend_public_key) == "13daa2af00ad26a372d317195de0bdd716f7a05d33bc4d7aff1664b6ee93c060");
// key images
ASSERT_TRUE(w.m_key_images.size() == 3);
{
crypto::key_image ki[3];
epee::string_tools::hex_to_pod("c5680d3735b90871ca5e3d90cd82d6483eed1151b9ab75c2c8c3a7d89e00a5a8", ki[0]);
epee::string_tools::hex_to_pod("d54cbd435a8d636ad9b01b8d4f3eb13bd0cf1ce98eddf53ab1617f9b763e66c0", ki[1]);
epee::string_tools::hex_to_pod("6c3cd6af97c4070a7aef9b1344e7463e29c7cd245076fdb65da447a34da3ca76", ki[2]);
ASSERT_EQ_MAP(0, w.m_key_images, ki[0]);
ASSERT_EQ_MAP(1, w.m_key_images, ki[1]);
ASSERT_EQ_MAP(2, w.m_key_images, ki[2]);
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}
// unconfirmed txs
ASSERT_TRUE(w.m_unconfirmed_txs.size() == 0);
// payments
ASSERT_TRUE(w.m_payments.size() == 2);
{
auto pd0 = w.m_payments.begin();
auto pd1 = pd0;
++pd1;
ASSERT_TRUE(epee::string_tools::pod_to_hex(pd0->first) == "0000000000000000000000000000000000000000000000000000000000000000");
ASSERT_TRUE(epee::string_tools::pod_to_hex(pd1->first) == "0000000000000000000000000000000000000000000000000000000000000000");
if (epee::string_tools::pod_to_hex(pd0->second.m_tx_hash) == "ec34c9bb12b99af33d49691384eee5bed9171498ff04e59516505f35d1fc5efc")
swap(pd0, pd1);
ASSERT_TRUE(epee::string_tools::pod_to_hex(pd0->second.m_tx_hash) == "15024343b38e77a1a9860dfed29921fa17e833fec837191a6b04fa7cb9605b8e");
ASSERT_TRUE(epee::string_tools::pod_to_hex(pd1->second.m_tx_hash) == "ec34c9bb12b99af33d49691384eee5bed9171498ff04e59516505f35d1fc5efc");
ASSERT_TRUE(pd0->second.m_amount == 13400845012231);
ASSERT_TRUE(pd1->second.m_amount == 1200000000000);
ASSERT_TRUE(pd0->second.m_block_height == 818424);
ASSERT_TRUE(pd1->second.m_block_height == 818522);
ASSERT_TRUE(pd0->second.m_unlock_time == 818484);
ASSERT_TRUE(pd1->second.m_unlock_time == 0);
ASSERT_TRUE(pd0->second.m_timestamp == 1483263366);
ASSERT_TRUE(pd1->second.m_timestamp == 1483272963);
}
// tx keys
ASSERT_TRUE(w.m_tx_keys.size() == 2);
{
const std::vector<std::pair<std::string, std::string>> txid_txkey =
{
{"b9aac8c020ab33859e0c0b6331f46a8780d349e7ac17b067116e2d87bf48daad", "bf3614c6de1d06c09add5d92a5265d8c76af706f7bc6ac830d6b0d109aa87701"},
{"6e7013684d35820f66c6679197ded9329bfe0e495effa47e7b25258799858dba", "e556884246df5a787def6732c6ea38f1e092fa13e5ea98f732b99c07a6332003"},
};
for (size_t i = 0; i < txid_txkey.size(); ++i)
{
crypto::hash txid;
crypto::secret_key txkey;
epee::string_tools::hex_to_pod(txid_txkey[i].first, txid);
epee::string_tools::hex_to_pod(txid_txkey[i].second, txkey);
ASSERT_EQ_MAP(txkey, w.m_tx_keys, txid);
}
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}
// confirmed txs
ASSERT_TRUE(w.m_confirmed_txs.size() == 1);
// tx notes
ASSERT_TRUE(w.m_tx_notes.size() == 2);
{
crypto::hash h[2];
epee::string_tools::hex_to_pod("15024343b38e77a1a9860dfed29921fa17e833fec837191a6b04fa7cb9605b8e", h[0]);
epee::string_tools::hex_to_pod("6e7013684d35820f66c6679197ded9329bfe0e495effa47e7b25258799858dba", h[1]);
ASSERT_EQ_MAP("sample note", w.m_tx_notes, h[0]);
ASSERT_EQ_MAP("sample note 2", w.m_tx_notes, h[1]);
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}
// unconfirmed payments
ASSERT_TRUE(w.m_unconfirmed_payments.size() == 0);
// pub keys
ASSERT_TRUE(w.m_pub_keys.size() == 3);
{
crypto::public_key pubkey[3];
epee::string_tools::hex_to_pod("33f75f264574cb3a9ea5b24220a5312e183d36dc321c9091dfbb720922a4f7b0", pubkey[0]);
epee::string_tools::hex_to_pod("5066ff2ce9861b1d131cf16eeaa01264933a49f28242b97b153e922ec7b4b3cb", pubkey[1]);
epee::string_tools::hex_to_pod("0d8467e16e73d16510452b78823e082e05ee3a63788d40de577cf31eb555f0c8", pubkey[2]);
ASSERT_EQ_MAP(0, w.m_pub_keys, pubkey[0]);
ASSERT_EQ_MAP(1, w.m_pub_keys, pubkey[1]);
ASSERT_EQ_MAP(2, w.m_pub_keys, pubkey[2]);
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}
// address book
ASSERT_TRUE(w.m_address_book.size() == 1);
{
auto address_book_row = w.m_address_book.begin();
ASSERT_TRUE(epee::string_tools::pod_to_hex(address_book_row->m_address.m_spend_public_key) == "9bc53a6ff7b0831c9470f71b6b972dbe5ad1e8606f72682868b1dda64e119fb3");
ASSERT_TRUE(epee::string_tools::pod_to_hex(address_book_row->m_address.m_view_public_key) == "49fece1ef97dc0c0f7a5e2106e75e96edd910f7e86b56e1e308cd0cf734df191");
ASSERT_TRUE(address_book_row->m_description == "testnet wallet 9y52S6");
}
}
#define OUTPUT_EXPORT_FILE_MAGIC "Monero output export\003"
TEST(Serialization, portability_outputs)
{
// read file
const boost::filesystem::path filename = unit_test::data_dir / "outputs";
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std::string data;
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bool r = epee::file_io_utils::load_file_to_string(filename.string(), data);
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ASSERT_TRUE(r);
const size_t magiclen = strlen(OUTPUT_EXPORT_FILE_MAGIC);
ASSERT_FALSE(data.size() < magiclen || memcmp(data.data(), OUTPUT_EXPORT_FILE_MAGIC, magiclen));
// decrypt (copied from wallet2::decrypt)
auto decrypt = [] (const std::string &ciphertext, const crypto::secret_key &skey, bool authenticated) -> string
{
const size_t prefix_size = sizeof(chacha_iv) + (authenticated ? sizeof(crypto::signature) : 0);
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if(ciphertext.size() < prefix_size)
return {};
crypto::chacha_key key;
crypto::generate_chacha_key(&skey, sizeof(skey), key, 1);
const crypto::chacha_iv &iv = *(const crypto::chacha_iv*)&ciphertext[0];
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std::string plaintext;
plaintext.resize(ciphertext.size() - prefix_size);
if (authenticated)
{
crypto::hash hash;
crypto::cn_fast_hash(ciphertext.data(), ciphertext.size() - sizeof(signature), hash);
crypto::public_key pkey;
crypto::secret_key_to_public_key(skey, pkey);
const crypto::signature &signature = *(const crypto::signature*)&ciphertext[ciphertext.size() - sizeof(crypto::signature)];
if(!crypto::check_signature(hash, pkey, signature))
return {};
}
crypto::chacha8(ciphertext.data() + sizeof(iv), ciphertext.size() - prefix_size, key, iv, &plaintext[0]);
return plaintext;
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};
crypto::secret_key view_secret_key;
epee::string_tools::hex_to_pod("339673bb1187e2f73ba7841ab6841c5553f96e9f13f8fe6612e69318db4e9d0a", view_secret_key);
bool authenticated = true;
data = decrypt(std::string(data, magiclen), view_secret_key, authenticated);
ASSERT_FALSE(data.empty());
// check public view/spend keys
const size_t headerlen = 2 * sizeof(crypto::public_key);
ASSERT_FALSE(data.size() < headerlen);
const crypto::public_key &public_spend_key = *(const crypto::public_key*)&data[0];
const crypto::public_key &public_view_key = *(const crypto::public_key*)&data[sizeof(crypto::public_key)];
ASSERT_TRUE(epee::string_tools::pod_to_hex(public_spend_key) == "13daa2af00ad26a372d317195de0bdd716f7a05d33bc4d7aff1664b6ee93c060");
ASSERT_TRUE(epee::string_tools::pod_to_hex(public_view_key) == "e47d4b6df6ab7339539148c2a03ad3e2f3434e5ab2046848e1f21369a3937cad");
r = false;
std::vector<tools::wallet2::transfer_details> outputs;
try
{
std::istringstream iss(std::string(data, headerlen));
boost::archive::portable_binary_iarchive ar(iss);
ar >> outputs;
r = true;
}
catch (...)
{}
ASSERT_TRUE(r);
/*
fields of tools::wallet2::transfer_details to be checked:
uint64_t m_block_height
cryptonote::transaction_prefix m_tx // TODO
crypto::hash m_txid
size_t m_internal_output_index
uint64_t m_global_output_index
bool m_spent
uint64_t m_spent_height
crypto::key_image m_key_image
rct::key m_mask
uint64_t m_amount
bool m_rct
bool m_key_image_known
size_t m_pk_index
*/
ASSERT_TRUE(outputs.size() == 3);
auto& td0 = outputs[0];
auto& td1 = outputs[1];
auto& td2 = outputs[2];
ASSERT_TRUE(td0.m_block_height == 818424);
ASSERT_TRUE(td1.m_block_height == 818522);
ASSERT_TRUE(td2.m_block_height == 818522);
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_txid) == "15024343b38e77a1a9860dfed29921fa17e833fec837191a6b04fa7cb9605b8e");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_txid) == "ec34c9bb12b99af33d49691384eee5bed9171498ff04e59516505f35d1fc5efc");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_txid) == "6e7013684d35820f66c6679197ded9329bfe0e495effa47e7b25258799858dba");
ASSERT_TRUE(td0.m_internal_output_index == 0);
ASSERT_TRUE(td1.m_internal_output_index == 0);
ASSERT_TRUE(td2.m_internal_output_index == 1);
ASSERT_TRUE(td0.m_global_output_index == 19642);
ASSERT_TRUE(td1.m_global_output_index == 19757);
ASSERT_TRUE(td2.m_global_output_index == 19760);
ASSERT_TRUE (td0.m_spent);
ASSERT_FALSE(td1.m_spent);
ASSERT_FALSE(td2.m_spent);
ASSERT_TRUE(td0.m_spent_height == 0);
ASSERT_TRUE(td1.m_spent_height == 0);
ASSERT_TRUE(td2.m_spent_height == 0);
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_key_image) == "c5680d3735b90871ca5e3d90cd82d6483eed1151b9ab75c2c8c3a7d89e00a5a8");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_key_image) == "d54cbd435a8d636ad9b01b8d4f3eb13bd0cf1ce98eddf53ab1617f9b763e66c0");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_key_image) == "6c3cd6af97c4070a7aef9b1344e7463e29c7cd245076fdb65da447a34da3ca76");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_mask) == "0100000000000000000000000000000000000000000000000000000000000000");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_mask) == "d3997a7b27fa199a377643b88cbd3f20f447496746dabe92d288730ecaeda007");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_mask) == "789bafff169ef206aa21219342c69ca52ce1d78d776c10b21d14bdd960fc7703");
ASSERT_TRUE(td0.m_amount == 13400845012231);
ASSERT_TRUE(td1.m_amount == 1200000000000);
ASSERT_TRUE(td2.m_amount == 11066009260865);
ASSERT_TRUE(td0.m_rct);
ASSERT_TRUE(td1.m_rct);
ASSERT_TRUE(td2.m_rct);
ASSERT_TRUE(td0.m_key_image_known);
ASSERT_TRUE(td1.m_key_image_known);
ASSERT_TRUE(td2.m_key_image_known);
ASSERT_TRUE(td0.m_pk_index == 0);
ASSERT_TRUE(td1.m_pk_index == 0);
ASSERT_TRUE(td2.m_pk_index == 0);
}
struct unsigned_tx_set
{
std::vector<tools::wallet2::tx_construction_data> txes;
tools::wallet2::transfer_container transfers;
};
template <class Archive>
inline void serialize(Archive &a, unsigned_tx_set &x, const boost::serialization::version_type ver)
{
a & x.txes;
a & x.transfers;
}
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#define UNSIGNED_TX_PREFIX "Monero unsigned tx set\003"
TEST(Serialization, portability_unsigned_tx)
{
const boost::filesystem::path filename = unit_test::data_dir / "unsigned_monero_tx";
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std::string s;
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const cryptonote::network_type nettype = cryptonote::TESTNET;
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bool r = epee::file_io_utils::load_file_to_string(filename.string(), s);
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ASSERT_TRUE(r);
const size_t magiclen = strlen(UNSIGNED_TX_PREFIX);
ASSERT_FALSE(strncmp(s.c_str(), UNSIGNED_TX_PREFIX, magiclen));
unsigned_tx_set exported_txs;
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s = s.substr(magiclen);
r = false;
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> exported_txs;
r = true;
}
catch (...)
{}
ASSERT_TRUE(r);
/*
fields of tools::wallet2::unsigned_tx_set to be checked:
std::vector<tx_construction_data> txes
std::vector<wallet2::transfer_details> m_transfers
fields of toolw::wallet2::tx_construction_data to be checked:
std::vector<cryptonote::tx_source_entry> sources
cryptonote::tx_destination_entry change_dts
std::vector<cryptonote::tx_destination_entry> splitted_dsts
std::list<size_t> selected_transfers
std::vector<uint8_t> extra
uint64_t unlock_time
bool use_rct
std::vector<cryptonote::tx_destination_entry> dests
fields of cryptonote::tx_source_entry to be checked:
std::vector<std::pair<uint64_t, rct::ctkey>> outputs
size_t real_output
crypto::public_key real_out_tx_key
size_t real_output_in_tx_index
uint64_t amount
bool rct
rct::key mask
fields of cryptonote::tx_destination_entry to be checked:
uint64_t amount
account_public_address addr
*/
// txes
ASSERT_TRUE(exported_txs.txes.size() == 1);
auto& tcd = exported_txs.txes[0];
// tcd.sources
ASSERT_TRUE(tcd.sources.size() == 1);
auto& tse = tcd.sources[0];
// tcd.sources[0].outputs
ASSERT_TRUE(tse.outputs.size() == 5);
auto& out0 = tse.outputs[0];
auto& out1 = tse.outputs[1];
auto& out2 = tse.outputs[2];
auto& out3 = tse.outputs[3];
auto& out4 = tse.outputs[4];
ASSERT_TRUE(out0.first == 6295);
ASSERT_TRUE(out1.first == 14302);
ASSERT_TRUE(out2.first == 17598);
ASSERT_TRUE(out3.first == 18671);
ASSERT_TRUE(out4.first == 19760);
ASSERT_TRUE(epee::string_tools::pod_to_hex(out0.second) == "e7272cb589954ddeedd20de9411ed57265f154d41f33cec9ff69e5d642e09814096490b0ac85308342acf436cc0270d53abef9dc04c6202f2459e879bfd40ce6");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out1.second) == "c3a9f49d1fe75939cc3feb39871ce0a7366c2879a63faa1a5cf34e65723b120a272ff0c7d84ab8b6ee3528d196450b0e28b3fed276bc2597a2b5b17afb9354ab");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out2.second) == "176e239c8c39000c2275e2f63ed7d55c55e0843524091522bbd3d3b869044969021fad70fc1244115449d4754829ae7c47346342ee5d52a2cdd47dfc351d0ab0");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out3.second) == "ef12d7946302fb064f2ba9df1a73d72233ac74664ed3b370580fa3bdc377542ad93f64898bd95851d6efe0d7bf2dbbea9b7c6b3c57e2c807e7b17d55b4622259");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out4.second) == "0d8467e16e73d16510452b78823e082e05ee3a63788d40de577cf31eb555f0c8525096cbc88d00a841eed66f3cdb6f0a018e6ce9fb9433ed61afba15cbbebd04");
// tcd.sources[0].{real_output, real_out_tx_key, real_output_in_tx_index, amount, rct, mask}
ASSERT_TRUE(tse.real_output == 4);
ASSERT_TRUE(epee::string_tools::pod_to_hex(tse.real_out_tx_key) == "4d86c7ba1c285fe4bc1cd7b54ba894fa89fa02fc6b0bbeea67d53251acd14a05");
ASSERT_TRUE(tse.real_output_in_tx_index == 1);
ASSERT_TRUE(tse.amount == 11066009260865);
ASSERT_TRUE(tse.rct);
ASSERT_TRUE(epee::string_tools::pod_to_hex(tse.mask) == "789bafff169ef206aa21219342c69ca52ce1d78d776c10b21d14bdd960fc7703");
// tcd.change_dts
ASSERT_TRUE(tcd.change_dts.amount == 9631208773403);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, tcd.change_dts.addr) == "9svHk1wHPo3ULf2AZykghzcye6sitaRE4MaDjPC6uanTHCynHjJHZaiAb922PojE1GexhhRt1LVf5DC43feyrRZMLXQr3mk");
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// tcd.splitted_dsts
ASSERT_TRUE(tcd.splitted_dsts.size() == 2);
auto& splitted_dst0 = tcd.splitted_dsts[0];
auto& splitted_dst1 = tcd.splitted_dsts[1];
ASSERT_TRUE(splitted_dst0.amount == 1400000000000);
ASSERT_TRUE(splitted_dst1.amount == 9631208773403);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, splitted_dst0.addr) == "9xnhrMczQkPeoGi6dyu6BgKAYX4tZsDs6KHCkyTStDBKL4M4pM1gfCR3utmTAcSaKHGa1R5o266FbdnubErmij3oMdLyYgA");
ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, splitted_dst1.addr) == "9svHk1wHPo3ULf2AZykghzcye6sitaRE4MaDjPC6uanTHCynHjJHZaiAb922PojE1GexhhRt1LVf5DC43feyrRZMLXQr3mk");
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// tcd.selected_transfers
ASSERT_TRUE(tcd.selected_transfers.size() == 1);
ASSERT_TRUE(tcd.selected_transfers.front() == 2);
// tcd.extra
ASSERT_TRUE(tcd.extra.size() == 68);
// tcd.{unlock_time, use_rct}
ASSERT_TRUE(tcd.unlock_time == 0);
ASSERT_TRUE(tcd.use_rct);
// tcd.dests
ASSERT_TRUE(tcd.dests.size() == 1);
auto& dest = tcd.dests[0];
ASSERT_TRUE(dest.amount == 1400000000000);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, dest.addr) == "9xnhrMczQkPeoGi6dyu6BgKAYX4tZsDs6KHCkyTStDBKL4M4pM1gfCR3utmTAcSaKHGa1R5o266FbdnubErmij3oMdLyYgA");
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// transfers
ASSERT_TRUE(exported_txs.transfers.size() == 3);
auto& td0 = exported_txs.transfers[0];
auto& td1 = exported_txs.transfers[1];
auto& td2 = exported_txs.transfers[2];
ASSERT_TRUE(td0.m_block_height == 818424);
ASSERT_TRUE(td1.m_block_height == 818522);
ASSERT_TRUE(td2.m_block_height == 818522);
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_txid) == "15024343b38e77a1a9860dfed29921fa17e833fec837191a6b04fa7cb9605b8e");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_txid) == "ec34c9bb12b99af33d49691384eee5bed9171498ff04e59516505f35d1fc5efc");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_txid) == "6e7013684d35820f66c6679197ded9329bfe0e495effa47e7b25258799858dba");
ASSERT_TRUE(td0.m_internal_output_index == 0);
ASSERT_TRUE(td1.m_internal_output_index == 0);
ASSERT_TRUE(td2.m_internal_output_index == 1);
ASSERT_TRUE(td0.m_global_output_index == 19642);
ASSERT_TRUE(td1.m_global_output_index == 19757);
ASSERT_TRUE(td2.m_global_output_index == 19760);
ASSERT_TRUE (td0.m_spent);
ASSERT_FALSE(td1.m_spent);
ASSERT_FALSE(td2.m_spent);
ASSERT_TRUE(td0.m_spent_height == 0);
ASSERT_TRUE(td1.m_spent_height == 0);
ASSERT_TRUE(td2.m_spent_height == 0);
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_key_image) == "c5680d3735b90871ca5e3d90cd82d6483eed1151b9ab75c2c8c3a7d89e00a5a8");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_key_image) == "d54cbd435a8d636ad9b01b8d4f3eb13bd0cf1ce98eddf53ab1617f9b763e66c0");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_key_image) == "6c3cd6af97c4070a7aef9b1344e7463e29c7cd245076fdb65da447a34da3ca76");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td0.m_mask) == "0100000000000000000000000000000000000000000000000000000000000000");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td1.m_mask) == "d3997a7b27fa199a377643b88cbd3f20f447496746dabe92d288730ecaeda007");
ASSERT_TRUE(epee::string_tools::pod_to_hex(td2.m_mask) == "789bafff169ef206aa21219342c69ca52ce1d78d776c10b21d14bdd960fc7703");
ASSERT_TRUE(td0.m_amount == 13400845012231);
ASSERT_TRUE(td1.m_amount == 1200000000000);
ASSERT_TRUE(td2.m_amount == 11066009260865);
ASSERT_TRUE(td0.m_rct);
ASSERT_TRUE(td1.m_rct);
ASSERT_TRUE(td2.m_rct);
ASSERT_TRUE(td0.m_key_image_known);
ASSERT_TRUE(td1.m_key_image_known);
ASSERT_TRUE(td2.m_key_image_known);
ASSERT_TRUE(td0.m_pk_index == 0);
ASSERT_TRUE(td1.m_pk_index == 0);
ASSERT_TRUE(td2.m_pk_index == 0);
}
#define SIGNED_TX_PREFIX "Monero signed tx set\003"
TEST(Serialization, portability_signed_tx)
{
const boost::filesystem::path filename = unit_test::data_dir / "signed_monero_tx";
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const cryptonote::network_type nettype = cryptonote::TESTNET;
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std::string s;
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bool r = epee::file_io_utils::load_file_to_string(filename.string(), s);
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ASSERT_TRUE(r);
const size_t magiclen = strlen(SIGNED_TX_PREFIX);
ASSERT_FALSE(strncmp(s.c_str(), SIGNED_TX_PREFIX, magiclen));
tools::wallet2::signed_tx_set exported_txs;
s = s.substr(magiclen);
r = false;
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> exported_txs;
r = true;
}
catch (...)
{}
ASSERT_TRUE(r);
/*
fields of tools::wallet2::signed_tx_set to be checked:
std::vector<pending_tx> ptx
std::vector<crypto::key_image> key_images
fields of tools::walllet2::pending_tx to be checked:
cryptonote::transaction tx // TODO
uint64_t dust
uint64_t fee
bool dust_added_to_fee
cryptonote::tx_destination_entry change_dts
std::list<size_t> selected_transfers
std::string key_images
crypto::secret_key tx_key
std::vector<cryptonote::tx_destination_entry> dests
tx_construction_data construction_data
*/
// ptx
ASSERT_TRUE(exported_txs.ptx.size() == 1);
auto& ptx = exported_txs.ptx[0];
// ptx.{dust, fee, dust_added_to_fee}
ASSERT_TRUE (ptx.dust == 0);
ASSERT_TRUE (ptx.fee == 34800487462);
ASSERT_FALSE(ptx.dust_added_to_fee);
// ptx.change.{amount, addr}
ASSERT_TRUE(ptx.change_dts.amount == 9631208773403);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, ptx.change_dts.addr) == "9svHk1wHPo3ULf2AZykghzcye6sitaRE4MaDjPC6uanTHCynHjJHZaiAb922PojE1GexhhRt1LVf5DC43feyrRZMLXQr3mk");
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// ptx.selected_transfers
ASSERT_TRUE(ptx.selected_transfers.size() == 1);
ASSERT_TRUE(ptx.selected_transfers.front() == 2);
// ptx.{key_images, tx_key}
ASSERT_TRUE(ptx.key_images == "<6c3cd6af97c4070a7aef9b1344e7463e29c7cd245076fdb65da447a34da3ca76> ");
ASSERT_TRUE(epee::string_tools::pod_to_hex(ptx.tx_key) == "0100000000000000000000000000000000000000000000000000000000000000");
// ptx.dests
ASSERT_TRUE(ptx.dests.size() == 1);
ASSERT_TRUE(ptx.dests[0].amount == 1400000000000);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, ptx.dests[0].addr) == "9xnhrMczQkPeoGi6dyu6BgKAYX4tZsDs6KHCkyTStDBKL4M4pM1gfCR3utmTAcSaKHGa1R5o266FbdnubErmij3oMdLyYgA");
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// ptx.construction_data
auto& tcd = ptx.construction_data;
ASSERT_TRUE(tcd.sources.size() == 1);
auto& tse = tcd.sources[0];
// ptx.construction_data.sources[0].outputs
ASSERT_TRUE(tse.outputs.size() == 5);
auto& out0 = tse.outputs[0];
auto& out1 = tse.outputs[1];
auto& out2 = tse.outputs[2];
auto& out3 = tse.outputs[3];
auto& out4 = tse.outputs[4];
ASSERT_TRUE(out0.first == 6295);
ASSERT_TRUE(out1.first == 14302);
ASSERT_TRUE(out2.first == 17598);
ASSERT_TRUE(out3.first == 18671);
ASSERT_TRUE(out4.first == 19760);
ASSERT_TRUE(epee::string_tools::pod_to_hex(out0.second) == "e7272cb589954ddeedd20de9411ed57265f154d41f33cec9ff69e5d642e09814096490b0ac85308342acf436cc0270d53abef9dc04c6202f2459e879bfd40ce6");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out1.second) == "c3a9f49d1fe75939cc3feb39871ce0a7366c2879a63faa1a5cf34e65723b120a272ff0c7d84ab8b6ee3528d196450b0e28b3fed276bc2597a2b5b17afb9354ab");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out2.second) == "176e239c8c39000c2275e2f63ed7d55c55e0843524091522bbd3d3b869044969021fad70fc1244115449d4754829ae7c47346342ee5d52a2cdd47dfc351d0ab0");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out3.second) == "ef12d7946302fb064f2ba9df1a73d72233ac74664ed3b370580fa3bdc377542ad93f64898bd95851d6efe0d7bf2dbbea9b7c6b3c57e2c807e7b17d55b4622259");
ASSERT_TRUE(epee::string_tools::pod_to_hex(out4.second) == "0d8467e16e73d16510452b78823e082e05ee3a63788d40de577cf31eb555f0c8525096cbc88d00a841eed66f3cdb6f0a018e6ce9fb9433ed61afba15cbbebd04");
// ptx.construction_data.sources[0].{real_output, real_out_tx_key, real_output_in_tx_index, amount, rct, mask}
ASSERT_TRUE(tse.real_output == 4);
ASSERT_TRUE(epee::string_tools::pod_to_hex(tse.real_out_tx_key) == "4d86c7ba1c285fe4bc1cd7b54ba894fa89fa02fc6b0bbeea67d53251acd14a05");
ASSERT_TRUE(tse.real_output_in_tx_index == 1);
ASSERT_TRUE(tse.amount == 11066009260865);
ASSERT_TRUE(tse.rct);
ASSERT_TRUE(epee::string_tools::pod_to_hex(tse.mask) == "789bafff169ef206aa21219342c69ca52ce1d78d776c10b21d14bdd960fc7703");
// ptx.construction_data.change_dts
ASSERT_TRUE(tcd.change_dts.amount == 9631208773403);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, tcd.change_dts.addr) == "9svHk1wHPo3ULf2AZykghzcye6sitaRE4MaDjPC6uanTHCynHjJHZaiAb922PojE1GexhhRt1LVf5DC43feyrRZMLXQr3mk");
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// ptx.construction_data.splitted_dsts
ASSERT_TRUE(tcd.splitted_dsts.size() == 2);
auto& splitted_dst0 = tcd.splitted_dsts[0];
auto& splitted_dst1 = tcd.splitted_dsts[1];
ASSERT_TRUE(splitted_dst0.amount == 1400000000000);
ASSERT_TRUE(splitted_dst1.amount == 9631208773403);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, splitted_dst0.addr) == "9xnhrMczQkPeoGi6dyu6BgKAYX4tZsDs6KHCkyTStDBKL4M4pM1gfCR3utmTAcSaKHGa1R5o266FbdnubErmij3oMdLyYgA");
ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, splitted_dst1.addr) == "9svHk1wHPo3ULf2AZykghzcye6sitaRE4MaDjPC6uanTHCynHjJHZaiAb922PojE1GexhhRt1LVf5DC43feyrRZMLXQr3mk");
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// ptx.construction_data.selected_transfers
ASSERT_TRUE(tcd.selected_transfers.size() == 1);
ASSERT_TRUE(tcd.selected_transfers.front() == 2);
// ptx.construction_data.extra
ASSERT_TRUE(tcd.extra.size() == 68);
// ptx.construction_data.{unlock_time, use_rct}
ASSERT_TRUE(tcd.unlock_time == 0);
ASSERT_TRUE(tcd.use_rct);
// ptx.construction_data.dests
ASSERT_TRUE(tcd.dests.size() == 1);
auto& dest = tcd.dests[0];
ASSERT_TRUE(dest.amount == 1400000000000);
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ASSERT_TRUE(cryptonote::get_account_address_as_str(nettype, false, dest.addr) == "9xnhrMczQkPeoGi6dyu6BgKAYX4tZsDs6KHCkyTStDBKL4M4pM1gfCR3utmTAcSaKHGa1R5o266FbdnubErmij3oMdLyYgA");
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// key_images
ASSERT_TRUE(exported_txs.key_images.size() == 3);
auto& ki0 = exported_txs.key_images[0];
auto& ki1 = exported_txs.key_images[1];
auto& ki2 = exported_txs.key_images[2];
ASSERT_TRUE(epee::string_tools::pod_to_hex(ki0) == "c5680d3735b90871ca5e3d90cd82d6483eed1151b9ab75c2c8c3a7d89e00a5a8");
ASSERT_TRUE(epee::string_tools::pod_to_hex(ki1) == "d54cbd435a8d636ad9b01b8d4f3eb13bd0cf1ce98eddf53ab1617f9b763e66c0");
ASSERT_TRUE(epee::string_tools::pod_to_hex(ki2) == "6c3cd6af97c4070a7aef9b1344e7463e29c7cd245076fdb65da447a34da3ca76");
}
TEST(Serialization, difficulty_type)
{
std::vector<cryptonote::difficulty_type> v_original;
for(int i = 0; i != 100; i++)
{
v_original.push_back(cryptonote::difficulty_type("117868131154734361989189100"));
if(v_original.size() > 1)
v_original.back() *= v_original[v_original.size()-2];
}
std::stringstream ss;
boost::archive::portable_binary_oarchive a(ss);
a << v_original;
std::vector<cryptonote::difficulty_type> v_unserialized;
boost::archive::portable_binary_iarchive a2(ss);
a2 >> v_unserialized;
ASSERT_EQ(v_original, v_unserialized);
}