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lot49.cpp
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lot49.cpp
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#include "bls.hpp"
#include "MeshNode.hpp"
#include "Ledger.hpp"
#include "ImpliedTransaction.hpp"
#include "Utils.hpp"
#include <algorithm>
using namespace std;
using namespace lot49;
// TODO: use 48 byte signatures, not 96 byte: https://twitter.com/sorgente711/status/1025451092610433024
bool testBLS();
void test1();
void test2();
void test3();
void TestRoute(HGID inSender, HGID inReceiver, std::string& inMessage)
{
// send a message and receive delivery receipt
cout << std::hex << endl << "Node " << std::setw(4) << std::setfill('0') << inSender << ": send a message to Node " << std::setw(4) << inReceiver << endl;
std::vector<uint8_t> data(inMessage.begin(), inMessage.end());
assert(data.size() == inMessage.size());
MeshNode::FromHGID(inSender).OriginateMessage(inReceiver, data);
}
int main(int argc, char* argv[])
{
cout << "testBLS(): " << (testBLS() ? "success!" : "failed!") << endl;
// test with pre-defined paths
//test1();
// test randomly moving nodes
test2();
// test aggregation of specific keys and messages
//test3();
};
// test aggregation of specific keys and messages
void test3()
{
int s1 = 7;
int s2 = 1;
std::vector<uint8_t> seed1(32, s1);
std::vector<uint8_t> seed2(32, s2);
bls::PrivateKey sk1 = bls::PrivateKey::FromSeed(seed1.data(), seed1.size());
cout << "sk" << s1 << " = " << std::hex;
for (auto byte : seed1 ) { cout << std::setw(2) << std::setfill('0') << static_cast<int>(byte);}
cout << endl;
bls::PublicKey pk1 = sk1.GetPublicKey();
cout << "pk" << s1 << " = " << std::hex << pk1 << endl;
bls::PrivateKey sk2 = bls::PrivateKey::FromSeed(seed2.data(), seed2.size());
cout << "sk" << s2 << " = " << std::hex;
for (auto byte : seed2 ) { cout << std::setw(2) << std::setfill('0') << static_cast<int>(byte);}
cout << endl;
bls::PublicKey pk2 = sk2.GetPublicKey();
cout << "pk" << s2 << " = " << std::hex << pk2 << endl;
std::vector<uint8_t> refund_tx = lot49::HexToBytes("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");
std::vector<uint8_t> setup_tx = lot49::HexToBytes("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");
std::vector<uint8_t> update1_tx = lot49::HexToBytes("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");
std::vector<uint8_t> update2_tx = lot49::HexToBytes("04857958fe97f040075ef324bfd46a0d2031ea3c28fe8bda1ea2542cf4ffff3b2ca23ea8d216cf33881789fcd0ff9f7bc78f62165173f9087a003c04de96bd3ef09cd84b7b7c53c4f77aa8870594dea08d41ab8fb1db7e48bdc4bae1dd6b141270857958fe97f040075ef324bfd46a0d2031ea3c28fe8bda1ea2542cf4ffff3b2ca23ea8d216cf33881789fcd0ff9f7bc78f62165173f9087a003c04de96bd3ef09cd84b7b7c53c4f77aa8870594dea08d41ab8fb1db7e48bdc4bae1dd6b141270ce00020007028f62165173f9087a003c04de96bd3ef09cd84b7b7c53c4f77aa8870594dea08d41ab8fb1db7e48bdc4bae1dd6b1412700000000000000000000000000000000000000000000000000000000000000000");
// SUCCEED
std::vector<uint8_t> sig_refund_test = lot49::HexToBytes("038da3bdcdf4838137f88268e3bb532f873671d53ac19807e0806888e082df1e9f2d6ab6d632c94993a7db257c21a98509ceef38d5f195037a9fa2444979c6c03654d9f4a309dc159aa2a7c73f7f2be1f984c29755e45f2b288d32f08542b25b");
// SUCCEED
std::vector<uint8_t> sig_update1_test = lot49::HexToBytes("15ad5f8a75b0c3c18a6efbb298a6db788bc6049a2eab7d01454d03f50383f648935f045e3749da5296052ac43ff430aa05d66916f70a23eff3a5de65663e34f4e94cc42ae81909868b5d240ebbb01ac78ec2f2a068a586ab88a3139bd1d2f78b");
// FAIL?
std::vector<uint8_t> sig_update2_test = lot49::HexToBytes("99b850d5d360b0a6c61fa7ea909750546bf53b3acc78549d8804e709c9dd77ecdf23320c7f65de52d5e9303d0fd06a7602d90a3d19d45bfb6b59d9824db30e183bf2a797d2a1bee21c9fc80d53ca46d562a6ed281f33113f6fd8466ab5bf5b32");
std::vector<uint8_t> refund_hash(bls::BLS::MESSAGE_HASH_LEN);
bls::Util::Hash256(refund_hash.data(), reinterpret_cast<const uint8_t*>(refund_tx.data()), refund_tx.size());
std::vector<uint8_t> setup_hash(bls::BLS::MESSAGE_HASH_LEN);
bls::Util::Hash256(setup_hash.data(), reinterpret_cast<const uint8_t*>(setup_tx.data()), setup_tx.size());
std::vector<uint8_t> update1_hash(bls::BLS::MESSAGE_HASH_LEN);
bls::Util::Hash256(update1_hash.data(), reinterpret_cast<const uint8_t*>(update1_tx.data()), update1_tx.size());
std::vector<uint8_t> update2_hash(bls::BLS::MESSAGE_HASH_LEN);
bls::Util::Hash256(update2_hash.data(), reinterpret_cast<const uint8_t*>(update2_tx.data()), update2_tx.size());
// Create signatures
bls::Signature sig_refund_sk1 = sk1.Sign(refund_tx.data(), refund_tx.size());
bls::Signature sig_setup_sk2 = sk2.Sign(setup_tx.data(), setup_tx.size());
bls::Signature sig_update1_sk2 = sk2.Sign(update1_tx.data(), update1_tx.size());
bls::Signature sig_update1_sk1 = sk1.Sign(update1_tx.data(), update1_tx.size());
bls::Signature sig_update2_sk1 = sk1.Sign(update2_tx.data(), update2_tx.size());
cout << "sig_refund = " << std::hex << sig_refund_sk1 << endl << endl;
assert(sig_refund_sk1 == bls::Signature::FromBytes(sig_refund_test.data()));
// Create aggregate signature for update1 test
vector<bls::Signature> update1_sigs = {sig_refund_sk1, sig_setup_sk2, sig_update1_sk2};
{
cout << "update 1 test" << endl;
bls::Signature agg_sig = bls::Signature::AggregateSigs(update1_sigs);
cout << "agg_sig = " << std::hex << agg_sig << endl;
bool ok = agg_sig.Verify();
cout << "agg_sig.Verify() = " << (ok ? "true" : "false") << endl;
assert(agg_sig == bls::Signature::FromBytes(sig_update1_test.data()));
update1_sigs.clear();
update1_sigs.push_back(agg_sig);
cout << endl;
}
// Create aggregate signature for update1 test and added update2 signatures
{
cout << "update 1 + update 2 test" << endl;
bls::AggregationInfo a1 = bls::AggregationInfo::FromMsgHash(pk1, refund_hash.data());
bls::AggregationInfo a2 = bls::AggregationInfo::FromMsgHash(pk2, setup_hash.data());
bls::AggregationInfo a3 = bls::AggregationInfo::FromMsgHash(pk2, update1_hash.data());
vector<bls::AggregationInfo> infos = {a1, a2, a3};
bls::AggregationInfo agg_info = bls::AggregationInfo::MergeInfos(infos);
bls::Signature agg_sig = bls::Signature::FromBytes(update1_sigs.back().Serialize().data());
agg_sig.SetAggregationInfo(agg_info);
cout << "agg_sig = " << std::hex << agg_sig << endl;
bool ok = agg_sig.Verify();
cout << "agg_sig.Verify() = " << (ok ? "true" : "false") << endl;
assert(agg_sig == bls::Signature::FromBytes(sig_update1_test.data()));
cout << endl;
std::vector<bls::Signature> sigs = {agg_sig, sig_update1_sk1, sig_update2_sk1};
agg_sig = bls::Signature::AggregateSigs(sigs);
cout << "agg_sig = " << std::hex << agg_sig << endl;
ok = agg_sig.Verify();
cout << "agg_sig.Verify() = " << (ok ? "true" : "false") << endl;
//assert(agg_sig == bls::Signature::FromBytes(sig_update2_test.data()));
cout << endl;
}
// Create aggreage signature for update2 test
vector<bls::Signature> update2_sigs;
{
cout << "update 2 test" << endl;
std::vector<bls::Signature> sigs = {sig_refund_sk1, sig_setup_sk2, sig_update1_sk2};
bls::Signature agg_sig = bls::Signature::AggregateSigs(sigs);
cout << "agg_sig = " << std::hex << agg_sig << endl;
cout << "agg_sig.Verify() = " << (agg_sig.Verify() ? "true" : "false") << endl;
sigs = {agg_sig, sig_update1_sk1, sig_update2_sk1};
agg_sig = bls::Signature::AggregateSigs(sigs);
cout << "agg_sig = " << std::hex << agg_sig << endl;
cout << "agg_sig.Verify() = " << (agg_sig.Verify() ? "true" : "false") << endl;
assert(agg_sig == bls::Signature::FromBytes(sig_update2_test.data()));
update2_sigs.push_back(agg_sig);
cout << endl;
}
// use aggregation information with deserialize sig for update 2
{
bls::AggregationInfo a1 = bls::AggregationInfo::FromMsgHash(pk1, refund_hash.data());
bls::AggregationInfo a2 = bls::AggregationInfo::FromMsgHash(pk2, setup_hash.data());
bls::AggregationInfo a3 = bls::AggregationInfo::FromMsgHash(pk2, update1_hash.data());
bls::AggregationInfo a4 = bls::AggregationInfo::FromMsgHash(pk1, update1_hash.data());
bls::AggregationInfo a5 = bls::AggregationInfo::FromMsgHash(pk1, update2_hash.data());
vector<bls::AggregationInfo> infos = {a1};
bls::AggregationInfo agg_info = bls::AggregationInfo::MergeInfos(infos);
infos = {agg_info, a2, a3};
agg_info = bls::AggregationInfo::MergeInfos(infos);
infos = {agg_info, a4, a5};
agg_info = bls::AggregationInfo::MergeInfos(infos);
// reconstruct signature from serialized data
cout << "update 2 test from serialized aggregate signature" << endl;
vector<bls::Signature> sigs = {sig_refund_sk1, sig_setup_sk2, sig_update1_sk2};
bls::Signature agg_sig = bls::Signature::AggregateSigs(sigs);
sigs = {agg_sig, sig_update1_sk1, sig_update2_sk1};
agg_sig = bls::Signature::AggregateSigs(sigs);
// strip aggregation data
agg_sig = bls::Signature::FromBytes(agg_sig.Serialize().data());
// add reconstructed aggregation data
agg_sig.SetAggregationInfo(agg_info);
cout << "agg_sig = " << std::hex << agg_sig << endl;
cout << "agg_sig.Verify() = " << (agg_sig.Verify() ? "true" : "false") << endl;
assert(agg_sig == bls::Signature::FromBytes(sig_update2_test.data()));
}
}
// test randomly moving nodes
void test2()
{
auto t = std::time(nullptr);
auto tm = *std::localtime(&t);
const size_t MAX_NODES = 30;
const size_t MAX_TIME = 480; // 8 hrs of simulation
std::vector<int> sides = {2928}; // {5477, 4472, 3873, 3464, 3162, 2928};
for (auto side : sides) {
std::ostringstream oss;
oss << "results/";
oss << std::put_time(&tm, "%y%m%d_%H%M%S");
oss << "_side-" << side;
oss << "_nodes-" << MAX_NODES << "_";
MeshNode::sParametersString = oss.str();
MeshNode::sMaxSize = side;
MeshNode::CreateNodes(MAX_NODES);
for (int i = 0; i < MAX_NODES; i++) {
bls::PublicKey pk = MeshNode::FromIndex(i).GetPublicKey();
Ledger::sInstance.Issue(pk, COMMITTED_TOKENS, MAX_NODES);
}
for (int i = 0; i < MAX_TIME; i++) {
MeshNode::UpdateSimulation();
}
CloseLogs();
}
}
// test with pre-defined paths
void test1()
{
const size_t MAX_NODES = 6;
MeshNode::CreateNodes(MAX_NODES);
// create linear route: A <-> B <-> C <-> D1
MeshRoute route1;
for (int i = 0; i < MAX_NODES-1; i++) {
HGID hgid = MeshNode::FromIndex(i).GetHGID();
route1.push_back(hgid);
}
auto iter = route1.begin();
HGID A = *iter++;
HGID B = *iter++;
HGID C = *iter++;
HGID D1 = route1.back();
MeshRoute route2 = route1;
route2.pop_back();
HGID D2 = MeshNode::FromIndex(MAX_NODES-1).GetHGID();
route2.push_back(D2);
// add route to gateway
HGID gateway = MeshNode::FromIndex(MAX_NODES).GetHGID();
route1.push_back(gateway);
route2.push_back(gateway);
MeshNode::AddGateway(gateway);
// add route from first to D1 node A->B->C->D1
MeshNode::AddRoute(route1);
// add route from first to D2 node A->B-C->D2
MeshNode::AddRoute(route2);
cout << "----------------------------------------------" << endl << endl;
// send a message from route 0 [A to C], and receive delivery receipt
std::string payload = "TEST TEST TEST";
TestRoute(A, B, payload);
TestRoute(A, C, payload);
cout << "----------------------------------------------" << endl << endl;
// send a message from route 1 [A to D1], and receive delivery receipt
//payload = "Mr. Watson - come here - I want to see you.";
//TestRoute(A, D1, payload);
cout << "----------------------------------------------" << endl << endl;
// send a message from route 2 [A to D2], and receive delivery receipt
payload = "The Times 03/Jan/2009 Chancellor on brink of second bailout for banks.";
TestRoute(A, D2, payload);
cout << "----------------------------------------------" << endl << endl;
// send a message from reverse of route 1 [D2 to A], and receive delivery receipt
//payload = "The computer can be used as a tool to liberate and protect people, rather than to control them.";
//TestRoute(D2, A, payload);
}
bool testBLS()
{
//
// Creating keys and signatures
//
// Example seed, used to generate private key. Always use
// a secure RNG with sufficient entropy to generate a seed.
uint8_t seed[] = {0, 50, 6, 244, 24, 199, 1, 25, 52, 88, 192,
19, 18, 12, 89, 6, 220, 18, 102, 58, 209,
82, 12, 62, 89, 110, 182, 9, 44, 20, 254, 22};
bls::PrivateKey sk = bls::PrivateKey::FromSeed(seed, sizeof(seed));
bls::PublicKey pk = sk.GetPublicKey();
//
// Serializing keys and signatures to bytes
//
uint8_t skBytes[bls::PrivateKey::PRIVATE_KEY_SIZE]; // 32 byte array
uint8_t pkBytes[bls::PublicKey::PUBLIC_KEY_SIZE]; // 96 byte array
uint8_t sigBytes[bls::Signature::SIGNATURE_SIZE]; // 48 byte array
pk.Serialize(pkBytes); // 96 bytes
// Takes array of 96 bytes
pk = bls::PublicKey::FromBytes(pkBytes);
sk.Serialize(skBytes); // 32 bytes
uint8_t msg[] = {100, 2, 254, 88, 90, 45, 23};
bls::Signature sig = sk.Sign(msg, sizeof(msg));
sig.Serialize(sigBytes); // 48 bytes
//
// Loading keys and signatures from bytes
//
// Takes array of 32 bytes
sk = bls::PrivateKey::FromBytes(skBytes);
// Takes array of 96 bytes
pk = bls::PublicKey::FromBytes(pkBytes);
// Takes array of 48 bytes
sig = bls::Signature::FromBytes(sigBytes);
//
// Verifying signatures
//
// Add information required for verification, to sig object
sig.SetAggregationInfo(bls::AggregationInfo::FromMsg(pk, msg, sizeof(msg)));
bool ok = sig.Verify();
//
// Aggregate signatures for a single message
//
{
// Generate some more private keys
seed[0] = 1;
bls::PrivateKey sk1 = bls::PrivateKey::FromSeed(seed, sizeof(seed));
seed[0] = 2;
bls::PrivateKey sk2 = bls::PrivateKey::FromSeed(seed, sizeof(seed));
// Generate first sig
bls::PublicKey pk1 = sk1.GetPublicKey();
bls::Signature sig1 = sk1.Sign(msg, sizeof(msg));
// Generate second sig
bls::PublicKey pk2 = sk2.GetPublicKey();
bls::Signature sig2 = sk2.Sign(msg, sizeof(msg));
// Aggregate signatures together
vector<bls::Signature> sigs = {sig1, sig2};
bls::Signature aggSig = bls::Signature::AggregateSigs(sigs);
// For same message, public keys can be aggregated into one.
// The signature can be verified the same as a single signature,
// using this public key.
vector<bls::PublicKey> pubKeys = {pk1, pk2};
bls::PublicKey aggPubKey = bls::PublicKey::Aggregate(pubKeys);
}
//
// Aggregate signatures for different messages
//
// Generate one more key and message
seed[0] = 1;
bls::PrivateKey sk1 = bls::PrivateKey::FromSeed(seed, sizeof(seed));
bls::PublicKey pk1 = sk1.GetPublicKey();
seed[0] = 2;
bls::PrivateKey sk2 = bls::PrivateKey::FromSeed(seed, sizeof(seed));
bls::PublicKey pk2 = sk2.GetPublicKey();
seed[0] = 3;
bls::PrivateKey sk3 = bls::PrivateKey::FromSeed(seed, sizeof(seed));
bls::PublicKey pk3 = sk3.GetPublicKey();
uint8_t msg2[] = {100, 2, 254, 88, 90, 45, 23};
// Generate the signatures, assuming we have 3 private keys
bls::Signature sig1 = sk1.Sign(msg, sizeof(msg));
bls::Signature sig2 = sk2.Sign(msg, sizeof(msg));
bls::Signature sig3 = sk3.Sign(msg2, sizeof(msg2));
// They can be noninteractively combined by anyone
// Aggregation below can also be done by the verifier, to
// make batch verification more efficient
vector<bls::Signature> sigsL = {sig1, sig2};
bls::Signature aggSigL = bls::Signature::AggregateSigs(sigsL);
// Arbitrary trees of aggregates
vector<bls::Signature> sigsFinal = {aggSigL, sig3};
bls::Signature aggSigFinal = bls::Signature::AggregateSigs(sigsFinal);
// Serialize the final signature
aggSigFinal.Serialize(sigBytes);
//
// Verify aggregate signature for different messages
//
// Deserialize aggregate signature
aggSigFinal = bls::Signature::FromBytes(sigBytes);
// Create aggregation information (or deserialize it)
bls::AggregationInfo a1 = bls::AggregationInfo::FromMsg(pk1, msg, sizeof(msg));
bls::AggregationInfo a2 = bls::AggregationInfo::FromMsg(pk2, msg, sizeof(msg));
bls::AggregationInfo a3 = bls::AggregationInfo::FromMsg(pk3, msg2, sizeof(msg2));
vector<bls::AggregationInfo> infos = {a1, a2};
bls::AggregationInfo a1a2 = bls::AggregationInfo::MergeInfos(infos);
vector<bls::AggregationInfo> infos2 = {a1a2, a3};
bls::AggregationInfo aFinal = bls::AggregationInfo::MergeInfos(infos2);
// Verify final signature using the aggregation info
aggSigFinal.SetAggregationInfo(aFinal);
ok = aggSigFinal.Verify();
// If you previously verified a signature, you can also divide
// the aggregate signature by the signature you already verified.
ok = aggSigL.Verify();
vector<bls::Signature> cache = {aggSigL};
aggSigFinal = aggSigFinal.DivideBy(cache);
// Final verification is now more efficient
ok = aggSigFinal.Verify();
return ok;
}