#include #include #include #include #include #include #include #include "cryptonote_core/cryptonote_basic.h" #include "cryptonote_core/cryptonote_format_utils.h" #include "cryptonote_protocol/blobdatatype.h" #include "crypto/crypto.h" #include "crypto/hash.h" #include "common/base58.h" #include "serialization/binary_utils.h" #include #define THROW_ERROR_EXCEPTION(x) NanThrowError(x) #define THROW_ERROR_EXCEPTION_WITH_STATUS_CODE(x, y) NanThrowError(x, y) using namespace node; using namespace v8; using namespace cryptonote; blobdata uint64be_to_blob(uint64_t num) { blobdata res = " "; res[0] = num >> 56 & 0xff; res[1] = num >> 48 & 0xff; res[2] = num >> 40 & 0xff; res[3] = num >> 32 & 0xff; res[4] = num >> 24 & 0xff; res[5] = num >> 16 & 0xff; res[6] = num >> 8 & 0xff; res[7] = num & 0xff; return res; } static bool fillExtra(cryptonote::block& block1, const cryptonote::block& block2) { cryptonote::tx_extra_merge_mining_tag mm_tag; mm_tag.depth = 0; if (!cryptonote::get_block_header_hash(block2, mm_tag.merkle_root)) return false; block1.miner_tx.extra.clear(); if (!cryptonote::append_mm_tag_to_extra(block1.miner_tx.extra, mm_tag)) return false; return true; } static bool mergeBlocks(const cryptonote::block& block1, cryptonote::block& block2, const std::vector& branch2) { block2.timestamp = block1.timestamp; block2.parent_block.major_version = block1.major_version; block2.parent_block.minor_version = block1.minor_version; block2.parent_block.prev_id = block1.prev_id; block2.parent_block.nonce = block1.nonce; block2.parent_block.miner_tx = block1.miner_tx; block2.parent_block.number_of_transactions = block1.tx_hashes.size() + 1; block2.parent_block.miner_tx_branch.resize(crypto::tree_depth(block1.tx_hashes.size() + 1)); std::vector transactionHashes; transactionHashes.push_back(cryptonote::get_transaction_hash(block1.miner_tx)); std::copy(block1.tx_hashes.begin(), block1.tx_hashes.end(), std::back_inserter(transactionHashes)); tree_branch(transactionHashes.data(), transactionHashes.size(), block2.parent_block.miner_tx_branch.data()); block2.parent_block.blockchain_branch = branch2; return true; } static bool construct_parent_block(const cryptonote::block& b, cryptonote::block& parent_block) { parent_block.major_version = 1; parent_block.minor_version = 0; parent_block.timestamp = b.timestamp; parent_block.prev_id = b.prev_id; parent_block.nonce = b.parent_block.nonce; parent_block.miner_tx.version = CURRENT_TRANSACTION_VERSION; parent_block.miner_tx.unlock_time = 0; return fillExtra(parent_block, b); } NAN_METHOD(convert_blob) { NanScope(); if (args.Length() < 1) return THROW_ERROR_EXCEPTION("You must provide one argument."); Local target = args[0]->ToObject(); if (!Buffer::HasInstance(target)) return THROW_ERROR_EXCEPTION("Argument should be a buffer object."); blobdata input = std::string(Buffer::Data(target), Buffer::Length(target)); blobdata output = ""; //convert block b = AUTO_VAL_INIT(b); if (!parse_and_validate_block_from_blob(input, b)) return THROW_ERROR_EXCEPTION("Failed to parse block"); if (b.major_version < BLOCK_MAJOR_VERSION_2) { if (!get_block_hashing_blob(b, output)) return THROW_ERROR_EXCEPTION("Failed to create mining block"); } else { block parent_block; if (!construct_parent_block(b, parent_block)) return THROW_ERROR_EXCEPTION("Failed to construct parent block"); if (!get_block_hashing_blob(parent_block, output)) return THROW_ERROR_EXCEPTION("Failed to create mining block"); } NanReturnValue( NanNewBufferHandle(output.data(), output.size()) ); } NAN_METHOD(get_block_id) { NanScope(); if (args.Length() < 1) return THROW_ERROR_EXCEPTION("You must provide one argument."); Local target = args[0]->ToObject(); if (!Buffer::HasInstance(target)) return THROW_ERROR_EXCEPTION("Argument should be a buffer object."); blobdata input = std::string(Buffer::Data(target), Buffer::Length(target)); blobdata output = ""; block b = AUTO_VAL_INIT(b); if (!parse_and_validate_block_from_blob(input, b)) return THROW_ERROR_EXCEPTION("Failed to parse block"); crypto::hash block_id; if (!get_block_hash(b, block_id)) return THROW_ERROR_EXCEPTION("Failed to calculate hash for block"); NanReturnValue( NanNewBufferHandle(reinterpret_cast(&block_id), sizeof(block_id)) ); } NAN_METHOD(construct_block_blob) { NanScope(); if (args.Length() < 2) return THROW_ERROR_EXCEPTION("You must provide two arguments."); Local block_template_buf = args[0]->ToObject(); Local nonce_buf = args[1]->ToObject(); if (!Buffer::HasInstance(block_template_buf) || !Buffer::HasInstance(nonce_buf)) return THROW_ERROR_EXCEPTION("Both arguments should be buffer objects."); if (Buffer::Length(nonce_buf) != 4) return THROW_ERROR_EXCEPTION("Nonce buffer has invalid size."); uint32_t nonce = *reinterpret_cast(Buffer::Data(nonce_buf)); blobdata block_template_blob = std::string(Buffer::Data(block_template_buf), Buffer::Length(block_template_buf)); blobdata output = ""; block b = AUTO_VAL_INIT(b); if (!parse_and_validate_block_from_blob(block_template_blob, b)) return THROW_ERROR_EXCEPTION("Failed to parse block"); b.nonce = nonce; if (b.major_version == BLOCK_MAJOR_VERSION_2) { block parent_block; b.parent_block.nonce = nonce; if (!construct_parent_block(b, parent_block)) return THROW_ERROR_EXCEPTION("Failed to construct parent block"); if (!mergeBlocks(parent_block, b, std::vector())) return THROW_ERROR_EXCEPTION("Failed to postprocess mining block"); } if (!block_to_blob(b, output)) return THROW_ERROR_EXCEPTION("Failed to convert block to blob"); NanReturnValue( NanNewBufferHandle(output.data(), output.size()) ); } NAN_METHOD(convert_blob_bb) { NanScope(); if (args.Length() < 1) return THROW_ERROR_EXCEPTION("You must provide one argument."); Local target = args[0]->ToObject(); if (!Buffer::HasInstance(target)) return THROW_ERROR_EXCEPTION("Argument should be a buffer object."); blobdata input = std::string(Buffer::Data(target), Buffer::Length(target)); blobdata output = ""; //convert bb_block b = AUTO_VAL_INIT(b); if (!parse_and_validate_block_from_blob(input, b)) { return THROW_ERROR_EXCEPTION("Failed to parse block"); } output = get_block_hashing_blob(b); NanReturnValue( NanNewBufferHandle(output.data(), output.size()) ); } NAN_METHOD(address_decode) { NanEscapableScope(); if (args.Length() < 1) return THROW_ERROR_EXCEPTION("You must provide one argument."); Local target = args[0]->ToObject(); if (!Buffer::HasInstance(target)) return THROW_ERROR_EXCEPTION("Argument should be a buffer object."); blobdata input = std::string(Buffer::Data(target), Buffer::Length(target)); blobdata data; uint64_t prefix; if (!tools::base58::decode_addr(input, prefix, data)) NanReturnUndefined(); account_public_address adr; if (!::serialization::parse_binary(data, adr)) NanReturnUndefined(); if (!crypto::check_key(adr.m_spend_public_key) || !crypto::check_key(adr.m_view_public_key)) NanReturnUndefined(); NanReturnValue(NanNew(static_cast(prefix))); } void init(Handle exports) { exports->Set(NanNew("construct_block_blob"), NanNew(construct_block_blob)->GetFunction()); exports->Set(NanNew("get_block_id"), NanNew(get_block_id)->GetFunction()); exports->Set(NanNew("convert_blob"), NanNew(convert_blob)->GetFunction()); exports->Set(NanNew("convert_blob_bb"), NanNew(convert_blob_bb)->GetFunction()); exports->Set(NanNew("address_decode"), NanNew(address_decode)->GetFunction()); } NODE_MODULE(cryptonote, init)