// Copyright (c) 2014-2023, The Monero Project // // 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 #pragma once #include #include #include #include // memcmp #include #include #include "serialization/variant.h" #include "serialization/containers.h" #include "serialization/binary_archive.h" #include "serialization/json_archive.h" #include "serialization/debug_archive.h" #include "serialization/crypto.h" #include "serialization/keyvalue_serialization.h" // eepe named serialization #include "cryptonote_config.h" #include "crypto/crypto.h" #include "crypto/hash.h" #include "misc_language.h" #include "ringct/rctTypes.h" #include "device/device.hpp" #include "cryptonote_basic/fwd.h" namespace cryptonote { typedef std::vector ring_signature; /* outputs */ struct txout_to_script { std::vector keys; std::vector script; BEGIN_SERIALIZE_OBJECT() FIELD(keys) FIELD(script) END_SERIALIZE() }; struct txout_to_scripthash { crypto::hash hash; }; // outputs <= HF_VERSION_VIEW_TAGS struct txout_to_key { txout_to_key(): key() { } txout_to_key(const crypto::public_key &_key) : key(_key) { } crypto::public_key key; }; // outputs >= HF_VERSION_VIEW_TAGS struct txout_to_tagged_key { txout_to_tagged_key(): key(), view_tag() { } txout_to_tagged_key(const crypto::public_key &_key, const crypto::view_tag &_view_tag) : key(_key), view_tag(_view_tag) { } crypto::public_key key; crypto::view_tag view_tag; // optimization to reduce scanning time BEGIN_SERIALIZE_OBJECT() FIELD(key) FIELD(view_tag) END_SERIALIZE() }; /* inputs */ struct txin_gen { size_t height; BEGIN_SERIALIZE_OBJECT() VARINT_FIELD(height) END_SERIALIZE() }; struct txin_to_script { crypto::hash prev; size_t prevout; std::vector sigset; BEGIN_SERIALIZE_OBJECT() FIELD(prev) VARINT_FIELD(prevout) FIELD(sigset) END_SERIALIZE() }; struct txin_to_scripthash { crypto::hash prev; size_t prevout; txout_to_script script; std::vector sigset; BEGIN_SERIALIZE_OBJECT() FIELD(prev) VARINT_FIELD(prevout) FIELD(script) FIELD(sigset) END_SERIALIZE() }; struct txin_to_key { uint64_t amount; std::vector key_offsets; crypto::key_image k_image; // double spending protection BEGIN_SERIALIZE_OBJECT() VARINT_FIELD(amount) FIELD(key_offsets) FIELD(k_image) END_SERIALIZE() }; typedef boost::variant txin_v; typedef boost::variant txout_target_v; //typedef std::pair out_t; struct tx_out { uint64_t amount; txout_target_v target; BEGIN_SERIALIZE_OBJECT() VARINT_FIELD(amount) FIELD(target) END_SERIALIZE() }; class transaction_prefix { public: // tx information size_t version; uint64_t unlock_time; //number of block (or time), used as a limitation like: spend this tx not early then block/time std::vector vin; std::vector vout; //extra std::vector extra; BEGIN_SERIALIZE() VARINT_FIELD(version) if((version == 0 || CURRENT_TRANSACTION_VERSION < version)) return false; VARINT_FIELD(unlock_time) FIELD(vin) FIELD(vout) FIELD(extra) END_SERIALIZE() public: transaction_prefix(){ set_null(); } void set_null() { version = 1; unlock_time = 0; vin.clear(); vout.clear(); extra.clear(); } }; class transaction: public transaction_prefix { private: // hash cash mutable std::atomic hash_valid; mutable std::atomic prunable_hash_valid; mutable std::atomic blob_size_valid; public: std::vector > signatures; //count signatures always the same as inputs count rct::rctSig rct_signatures; // hash cash mutable crypto::hash hash; mutable crypto::hash prunable_hash; mutable size_t blob_size; bool pruned; std::atomic unprunable_size; std::atomic prefix_size; transaction(); transaction(const transaction &t); transaction &operator=(const transaction &t); virtual ~transaction(); void set_null(); void invalidate_hashes(); bool is_hash_valid() const { return hash_valid.load(std::memory_order_acquire); } void set_hash_valid(bool v) const { hash_valid.store(v,std::memory_order_release); } bool is_prunable_hash_valid() const { return prunable_hash_valid.load(std::memory_order_acquire); } void set_prunable_hash_valid(bool v) const { prunable_hash_valid.store(v,std::memory_order_release); } bool is_blob_size_valid() const { return blob_size_valid.load(std::memory_order_acquire); } void set_blob_size_valid(bool v) const { blob_size_valid.store(v,std::memory_order_release); } void set_hash(const crypto::hash &h) const { hash = h; set_hash_valid(true); } void set_prunable_hash(const crypto::hash &h) const { prunable_hash = h; set_prunable_hash_valid(true); } void set_blob_size(size_t sz) const { blob_size = sz; set_blob_size_valid(true); } BEGIN_SERIALIZE_OBJECT() if (!typename Archive::is_saving()) { set_hash_valid(false); set_prunable_hash_valid(false); set_blob_size_valid(false); } const auto start_pos = ar.getpos(); FIELDS(*static_cast(this)) if (std::is_same, binary_archive>()) prefix_size = ar.getpos() - start_pos; if (version == 1) { if (std::is_same, binary_archive>()) unprunable_size = ar.getpos() - start_pos; ar.tag("signatures"); ar.begin_array(); PREPARE_CUSTOM_VECTOR_SERIALIZATION(vin.size(), signatures); bool signatures_not_expected = signatures.empty(); if (!signatures_not_expected && vin.size() != signatures.size()) return false; if (!pruned) for (size_t i = 0; i < vin.size(); ++i) { size_t signature_size = get_signature_size(vin[i]); if (signatures_not_expected) { if (0 == signature_size) continue; else return false; } PREPARE_CUSTOM_VECTOR_SERIALIZATION(signature_size, signatures[i]); if (signature_size != signatures[i].size()) return false; FIELDS(signatures[i]); if (vin.size() - i > 1) ar.delimit_array(); } ar.end_array(); } else { ar.tag("rct_signatures"); if (!vin.empty()) { ar.begin_object(); bool r = rct_signatures.serialize_rctsig_base(ar, vin.size(), vout.size()); if (!r || !ar.good()) return false; ar.end_object(); if (std::is_same, binary_archive>()) unprunable_size = ar.getpos() - start_pos; if (!pruned && rct_signatures.type != rct::RCTTypeNull) { ar.tag("rctsig_prunable"); ar.begin_object(); r = rct_signatures.p.serialize_rctsig_prunable(ar, rct_signatures.type, vin.size(), vout.size(), vin.size() > 0 && vin[0].type() == typeid(txin_to_key) ? boost::get(vin[0]).key_offsets.size() - 1 : 0); if (!r || !ar.good()) return false; ar.end_object(); } } } if (!typename Archive::is_saving()) pruned = false; END_SERIALIZE() template class Archive> bool serialize_base(Archive &ar) { FIELDS(*static_cast(this)) if (version == 1) { } else { ar.tag("rct_signatures"); if (!vin.empty()) { ar.begin_object(); bool r = rct_signatures.serialize_rctsig_base(ar, vin.size(), vout.size()); if (!r || !ar.good()) return false; ar.end_object(); } } if (!typename Archive::is_saving()) pruned = true; return ar.good(); } private: static size_t get_signature_size(const txin_v& tx_in); }; inline transaction::transaction(const transaction &t): transaction_prefix(t), hash_valid(false), prunable_hash_valid(false), blob_size_valid(false), signatures(t.signatures), rct_signatures(t.rct_signatures), pruned(t.pruned), unprunable_size(t.unprunable_size.load()), prefix_size(t.prefix_size.load()) { if (t.is_hash_valid()) { hash = t.hash; set_hash_valid(true); } if (t.is_blob_size_valid()) { blob_size = t.blob_size; set_blob_size_valid(true); } if (t.is_prunable_hash_valid()) { prunable_hash = t.prunable_hash; set_prunable_hash_valid(true); } } inline transaction &transaction::operator=(const transaction &t) { transaction_prefix::operator=(t); set_hash_valid(false); set_prunable_hash_valid(false); set_blob_size_valid(false); signatures = t.signatures; rct_signatures = t.rct_signatures; if (t.is_hash_valid()) { hash = t.hash; set_hash_valid(true); } if (t.is_prunable_hash_valid()) { prunable_hash = t.prunable_hash; set_prunable_hash_valid(true); } if (t.is_blob_size_valid()) { blob_size = t.blob_size; set_blob_size_valid(true); } pruned = t.pruned; unprunable_size = t.unprunable_size.load(); prefix_size = t.prefix_size.load(); return *this; } inline transaction::transaction() { set_null(); } inline transaction::~transaction() { } inline void transaction::set_null() { transaction_prefix::set_null(); signatures.clear(); rct_signatures.type = rct::RCTTypeNull; set_hash_valid(false); set_prunable_hash_valid(false); set_blob_size_valid(false); pruned = false; unprunable_size = 0; prefix_size = 0; } inline void transaction::invalidate_hashes() { set_hash_valid(false); set_prunable_hash_valid(false); set_blob_size_valid(false); } inline size_t transaction::get_signature_size(const txin_v& tx_in) { struct txin_signature_size_visitor : public boost::static_visitor { size_t operator()(const txin_gen& txin) const{return 0;} size_t operator()(const txin_to_script& txin) const{return 0;} size_t operator()(const txin_to_scripthash& txin) const{return 0;} size_t operator()(const txin_to_key& txin) const {return txin.key_offsets.size();} }; return boost::apply_visitor(txin_signature_size_visitor(), tx_in); } /************************************************************************/ /* */ /************************************************************************/ struct block_header { uint8_t major_version; uint8_t minor_version; // now used as a voting mechanism, rather than how this particular block is built uint64_t timestamp; crypto::hash prev_id; uint32_t nonce; BEGIN_SERIALIZE() VARINT_FIELD(major_version) VARINT_FIELD(minor_version) VARINT_FIELD(timestamp) FIELD(prev_id) FIELD(nonce) END_SERIALIZE() }; struct block: public block_header { private: // hash cash mutable std::atomic hash_valid; public: block(): block_header(), hash_valid(false) {} block(const block &b): block_header(b), hash_valid(false), miner_tx(b.miner_tx), tx_hashes(b.tx_hashes) { if (b.is_hash_valid()) { hash = b.hash; set_hash_valid(true); } } block &operator=(const block &b) { block_header::operator=(b); hash_valid = false; miner_tx = b.miner_tx; tx_hashes = b.tx_hashes; if (b.is_hash_valid()) { hash = b.hash; set_hash_valid(true); } return *this; } void invalidate_hashes() { set_hash_valid(false); } bool is_hash_valid() const { return hash_valid.load(std::memory_order_acquire); } void set_hash_valid(bool v) const { hash_valid.store(v,std::memory_order_release); } void set_hash(const crypto::hash &h) const { hash = h; set_hash_valid(true); } transaction miner_tx; std::vector tx_hashes; // hash cash mutable crypto::hash hash; BEGIN_SERIALIZE_OBJECT() if (!typename Archive::is_saving()) set_hash_valid(false); FIELDS(*static_cast(this)) FIELD(miner_tx) FIELD(tx_hashes) if (tx_hashes.size() > CRYPTONOTE_MAX_TX_PER_BLOCK) return false; END_SERIALIZE() }; /************************************************************************/ /* */ /************************************************************************/ struct account_public_address { crypto::public_key m_spend_public_key; crypto::public_key m_view_public_key; BEGIN_SERIALIZE_OBJECT() FIELD(m_spend_public_key) FIELD(m_view_public_key) END_SERIALIZE() BEGIN_KV_SERIALIZE_MAP() KV_SERIALIZE_VAL_POD_AS_BLOB_FORCE(m_spend_public_key) KV_SERIALIZE_VAL_POD_AS_BLOB_FORCE(m_view_public_key) END_KV_SERIALIZE_MAP() bool operator==(const account_public_address& rhs) const { return m_spend_public_key == rhs.m_spend_public_key && m_view_public_key == rhs.m_view_public_key; } bool operator!=(const account_public_address& rhs) const { return !(*this == rhs); } }; struct keypair { crypto::public_key pub; crypto::secret_key sec; static inline keypair generate(hw::device &hwdev) { keypair k; hwdev.generate_keys(k.pub, k.sec); return k; } }; //--------------------------------------------------------------- } namespace std { template <> struct hash { std::size_t operator()(const cryptonote::account_public_address& addr) const { // https://stackoverflow.com/a/17017281 size_t res = 17; res = res * 31 + hash()(addr.m_spend_public_key); res = res * 31 + hash()(addr.m_view_public_key); return res; } }; } BLOB_SERIALIZER(cryptonote::txout_to_key); BLOB_SERIALIZER(cryptonote::txout_to_scripthash); VARIANT_TAG(binary_archive, cryptonote::txin_gen, 0xff); VARIANT_TAG(binary_archive, cryptonote::txin_to_script, 0x0); VARIANT_TAG(binary_archive, cryptonote::txin_to_scripthash, 0x1); VARIANT_TAG(binary_archive, cryptonote::txin_to_key, 0x2); VARIANT_TAG(binary_archive, cryptonote::txout_to_script, 0x0); VARIANT_TAG(binary_archive, cryptonote::txout_to_scripthash, 0x1); VARIANT_TAG(binary_archive, cryptonote::txout_to_key, 0x2); VARIANT_TAG(binary_archive, cryptonote::txout_to_tagged_key, 0x3); VARIANT_TAG(binary_archive, cryptonote::transaction, 0xcc); VARIANT_TAG(binary_archive, cryptonote::block, 0xbb); VARIANT_TAG(json_archive, cryptonote::txin_gen, "gen"); VARIANT_TAG(json_archive, cryptonote::txin_to_script, "script"); VARIANT_TAG(json_archive, cryptonote::txin_to_scripthash, "scripthash"); VARIANT_TAG(json_archive, cryptonote::txin_to_key, "key"); VARIANT_TAG(json_archive, cryptonote::txout_to_script, "script"); VARIANT_TAG(json_archive, cryptonote::txout_to_scripthash, "scripthash"); VARIANT_TAG(json_archive, cryptonote::txout_to_key, "key"); VARIANT_TAG(json_archive, cryptonote::txout_to_tagged_key, "tagged_key"); VARIANT_TAG(json_archive, cryptonote::transaction, "tx"); VARIANT_TAG(json_archive, cryptonote::block, "block"); VARIANT_TAG(debug_archive, cryptonote::txin_gen, "gen"); VARIANT_TAG(debug_archive, cryptonote::txin_to_script, "script"); VARIANT_TAG(debug_archive, cryptonote::txin_to_scripthash, "scripthash"); VARIANT_TAG(debug_archive, cryptonote::txin_to_key, "key"); VARIANT_TAG(debug_archive, cryptonote::txout_to_script, "script"); VARIANT_TAG(debug_archive, cryptonote::txout_to_scripthash, "scripthash"); VARIANT_TAG(debug_archive, cryptonote::txout_to_key, "key"); VARIANT_TAG(debug_archive, cryptonote::txout_to_tagged_key, "tagged_key"); VARIANT_TAG(debug_archive, cryptonote::transaction, "tx"); VARIANT_TAG(debug_archive, cryptonote::block, "block");