/* This file is part of cpp-ethereum. cpp-ethereum is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. cpp-ethereum is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with cpp-ethereum. If not, see . */ /** @file CodeFragment.h * @author Gav Wood * @date 2014 */ #pragma once #include #include #include #include #include "Exceptions.h" namespace eth { enum AssemblyItemType { UndefinedItem, Operation, Push, PushString, PushTag, PushSub, PushSubSize, Tag, PushData }; class Assembly; class AssemblyItem { friend class Assembly; public: AssemblyItem(u256 _push): m_type(Push), m_data(_push) {} AssemblyItem(Instruction _i): m_type(Operation), m_data((byte)_i) {} AssemblyItem(AssemblyItemType _type, u256 _data = 0): m_type(_type), m_data(_data) {} AssemblyItem tag() const { assert(m_type == PushTag || m_type == Tag); return AssemblyItem(Tag, m_data); } AssemblyItem pushTag() const { assert(m_type == PushTag || m_type == Tag); return AssemblyItem(PushTag, m_data); } AssemblyItemType type() const { return m_type; } u256 data() const { return m_data; } int deposit() const; bool match(AssemblyItem const& _i) const { return _i.m_type == UndefinedItem || (m_type == _i.m_type && (m_type != Operation || m_data == _i.m_data)); } private: AssemblyItemType m_type; u256 m_data; }; typedef std::vector AssemblyItems; typedef vector_ref AssemblyItemsConstRef; std::ostream& operator<<(std::ostream& _out, AssemblyItemsConstRef _i); inline std::ostream& operator<<(std::ostream& _out, AssemblyItems const& _i) { return operator<<(_out, AssemblyItemsConstRef(&_i)); } class Assembly { public: AssemblyItem newTag() { return AssemblyItem(Tag, m_usedTags++); } AssemblyItem newPushTag() { return AssemblyItem(PushTag, m_usedTags++); } AssemblyItem newData(bytes const& _data) { h256 h = (u256)std::hash()(asString(_data)); m_data[h] = _data; return AssemblyItem(PushData, h); } AssemblyItem newSub(Assembly const& _sub) { h256 h = h256::random(s_fixedHashEngine); m_subs[h] = _sub; return AssemblyItem(PushSub, h); } AssemblyItem newPushString(std::string const& _data) { h256 h = (u256)std::hash()(_data); m_strings[h] = _data; return AssemblyItem(PushString, h); } AssemblyItem newPushSubSize(h256 const& _subId) { return AssemblyItem(PushSubSize, _subId); } AssemblyItem append() { return append(newTag()); } void append(Assembly const& _a); void append(Assembly const& _a, int _deposit); AssemblyItem const& append(AssemblyItem const& _i); AssemblyItem const& append(std::string const& _data) { return append(newPushString(_data)); } AssemblyItem const& append(bytes const& _data) { return append(newData(_data)); } AssemblyItem appendSubSize(Assembly const& _asm) { auto ret = newSub(_asm); append(newPushSubSize(ret.data())); return ret; } AssemblyItem appendJump() { auto ret = append(newPushTag()); append(Instruction::JUMP); return ret; } AssemblyItem appendJumpI() { auto ret = append(newPushTag()); append(Instruction::JUMPI); return ret; } AssemblyItem appendJump(AssemblyItem const& _tag) { auto ret = append(_tag.pushTag()); append(Instruction::JUMP); return ret; } AssemblyItem appendJumpI(AssemblyItem const& _tag) { auto ret = append(_tag.pushTag()); append(Instruction::JUMPI); return ret; } template Assembly& operator<<(T const& _d) { append(_d); return *this; } AssemblyItem const& back() { return m_items.back(); } std::string backString() const { return m_items.size() && m_items.back().m_type == PushString ? m_strings.at((h256)m_items.back().m_data) : std::string(); } void onePath() { assert(!m_totalDeposit && !m_baseDeposit); m_baseDeposit = m_deposit; m_totalDeposit = INT_MAX; } void otherPath() { donePath(); m_totalDeposit = m_deposit; m_deposit = m_baseDeposit; } void donePaths() { donePath(); m_totalDeposit = m_baseDeposit = 0; } void ignored() { m_baseDeposit = m_deposit; } void endIgnored() { m_deposit = m_baseDeposit; m_baseDeposit = 0; } void popTo(int _deposit) { while (m_deposit > _deposit) append(Instruction::POP); } void injectStart(AssemblyItem const& _i); std::string out() const { std::stringstream ret; streamOut(ret); return ret.str(); } int deposit() const { return m_deposit; } bytes assemble() const; Assembly& optimise(bool _enable); std::ostream& streamOut(std::ostream& _out, std::string const& _prefix = "") const; private: void donePath() { if (m_totalDeposit != INT_MAX && m_totalDeposit != m_deposit) throw InvalidDeposit(); } unsigned bytesRequired() const; unsigned m_usedTags = 0; AssemblyItems m_items; mutable std::map m_data; std::map m_subs; std::map m_strings; int m_deposit = 0; int m_baseDeposit = 0; int m_totalDeposit = 0; }; inline std::ostream& operator<<(std::ostream& _out, Assembly const& _a) { _a.streamOut(_out); return _out; } }