/* EVMC: Ethereum Client-VM Connector API. * Copyright 2018-2020 The EVMC Authors. * Licensed under the Apache License, Version 2.0. */ #pragma once #include #include #include #include #include /// EVMC C++ API - wrappers and bindings for C++ /// @ingroup cpp namespace evmc { /// The big-endian 160-bit hash suitable for keeping an Ethereum address. /// /// This type wraps C ::evmc_address to make sure objects of this type are always initialized. struct address : evmc_address { /// Default and converting constructor. /// /// Initializes bytes to zeros if not other @p init value provided. constexpr address(evmc_address init = {}) noexcept : evmc_address{init} {} /// Converting constructor from unsigned integer value. /// /// This constructor assigns the @p v value to the last 8 bytes [12:19] /// in big-endian order. constexpr explicit address(uint64_t v) noexcept : evmc_address{{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, static_cast(v >> 56), static_cast(v >> 48), static_cast(v >> 40), static_cast(v >> 32), static_cast(v >> 24), static_cast(v >> 16), static_cast(v >> 8), static_cast(v >> 0)}} {} /// Explicit operator converting to bool. inline constexpr explicit operator bool() const noexcept; }; /// The fixed size array of 32 bytes for storing 256-bit EVM values. /// /// This type wraps C ::evmc_bytes32 to make sure objects of this type are always initialized. struct bytes32 : evmc_bytes32 { /// Default and converting constructor. /// /// Initializes bytes to zeros if not other @p init value provided. constexpr bytes32(evmc_bytes32 init = {}) noexcept : evmc_bytes32{init} {} /// Converting constructor from unsigned integer value. /// /// This constructor assigns the @p v value to the last 8 bytes [24:31] /// in big-endian order. constexpr explicit bytes32(uint64_t v) noexcept : evmc_bytes32{{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, static_cast(v >> 56), static_cast(v >> 48), static_cast(v >> 40), static_cast(v >> 32), static_cast(v >> 24), static_cast(v >> 16), static_cast(v >> 8), static_cast(v >> 0)}} {} /// Explicit operator converting to bool. constexpr inline explicit operator bool() const noexcept; }; /// The alias for evmc::bytes32 to represent a big-endian 256-bit integer. using uint256be = bytes32; /// Loads 64 bits / 8 bytes of data from the given @p data array in big-endian order. inline constexpr uint64_t load64be(const uint8_t* data) noexcept { return (uint64_t{data[0]} << 56) | (uint64_t{data[1]} << 48) | (uint64_t{data[2]} << 40) | (uint64_t{data[3]} << 32) | (uint64_t{data[4]} << 24) | (uint64_t{data[5]} << 16) | (uint64_t{data[6]} << 8) | uint64_t{data[7]}; } /// Loads 64 bits / 8 bytes of data from the given @p data array in little-endian order. inline constexpr uint64_t load64le(const uint8_t* data) noexcept { return uint64_t{data[0]} | (uint64_t{data[1]} << 8) | (uint64_t{data[2]} << 16) | (uint64_t{data[3]} << 24) | (uint64_t{data[4]} << 32) | (uint64_t{data[5]} << 40) | (uint64_t{data[6]} << 48) | (uint64_t{data[7]} << 56); } /// Loads 32 bits / 4 bytes of data from the given @p data array in big-endian order. inline constexpr uint32_t load32be(const uint8_t* data) noexcept { return (uint32_t{data[0]} << 24) | (uint32_t{data[1]} << 16) | (uint32_t{data[2]} << 8) | uint32_t{data[3]}; } /// Loads 32 bits / 4 bytes of data from the given @p data array in little-endian order. inline constexpr uint32_t load32le(const uint8_t* data) noexcept { return uint32_t{data[0]} | (uint32_t{data[1]} << 8) | (uint32_t{data[2]} << 16) | (uint32_t{data[3]} << 24); } namespace fnv { constexpr auto prime = 0x100000001b3; ///< The 64-bit FNV prime number. constexpr auto offset_basis = 0xcbf29ce484222325; ///< The 64-bit FNV offset basis. /// The hashing transformation for 64-bit inputs based on the FNV-1a formula. inline constexpr uint64_t fnv1a_by64(uint64_t h, uint64_t x) noexcept { return (h ^ x) * prime; } } // namespace fnv /// The "equal to" comparison operator for the evmc::address type. inline constexpr bool operator==(const address& a, const address& b) noexcept { return load64le(&a.bytes[0]) == load64le(&b.bytes[0]) && load64le(&a.bytes[8]) == load64le(&b.bytes[8]) && load32le(&a.bytes[16]) == load32le(&b.bytes[16]); } /// The "not equal to" comparison operator for the evmc::address type. inline constexpr bool operator!=(const address& a, const address& b) noexcept { return !(a == b); } /// The "less than" comparison operator for the evmc::address type. inline constexpr bool operator<(const address& a, const address& b) noexcept { return load64be(&a.bytes[0]) < load64be(&b.bytes[0]) || (load64be(&a.bytes[0]) == load64be(&b.bytes[0]) && (load64be(&a.bytes[8]) < load64be(&b.bytes[8]) || (load64be(&a.bytes[8]) == load64be(&b.bytes[8]) && load32be(&a.bytes[16]) < load32be(&b.bytes[16])))); } /// The "greater than" comparison operator for the evmc::address type. inline constexpr bool operator>(const address& a, const address& b) noexcept { return b < a; } /// The "less than or equal to" comparison operator for the evmc::address type. inline constexpr bool operator<=(const address& a, const address& b) noexcept { return !(b < a); } /// The "greater than or equal to" comparison operator for the evmc::address type. inline constexpr bool operator>=(const address& a, const address& b) noexcept { return !(a < b); } /// The "equal to" comparison operator for the evmc::bytes32 type. inline constexpr bool operator==(const bytes32& a, const bytes32& b) noexcept { return load64le(&a.bytes[0]) == load64le(&b.bytes[0]) && load64le(&a.bytes[8]) == load64le(&b.bytes[8]) && load64le(&a.bytes[16]) == load64le(&b.bytes[16]) && load64le(&a.bytes[24]) == load64le(&b.bytes[24]); } /// The "not equal to" comparison operator for the evmc::bytes32 type. inline constexpr bool operator!=(const bytes32& a, const bytes32& b) noexcept { return !(a == b); } /// The "less than" comparison operator for the evmc::bytes32 type. inline constexpr bool operator<(const bytes32& a, const bytes32& b) noexcept { return load64be(&a.bytes[0]) < load64be(&b.bytes[0]) || (load64be(&a.bytes[0]) == load64be(&b.bytes[0]) && (load64be(&a.bytes[8]) < load64be(&b.bytes[8]) || (load64be(&a.bytes[8]) == load64be(&b.bytes[8]) && (load64be(&a.bytes[16]) < load64be(&b.bytes[16]) || (load64be(&a.bytes[16]) == load64be(&b.bytes[16]) && load64be(&a.bytes[24]) < load64be(&b.bytes[24])))))); } /// The "greater than" comparison operator for the evmc::bytes32 type. inline constexpr bool operator>(const bytes32& a, const bytes32& b) noexcept { return b < a; } /// The "less than or equal to" comparison operator for the evmc::bytes32 type. inline constexpr bool operator<=(const bytes32& a, const bytes32& b) noexcept { return !(b < a); } /// The "greater than or equal to" comparison operator for the evmc::bytes32 type. inline constexpr bool operator>=(const bytes32& a, const bytes32& b) noexcept { return !(a < b); } /// Checks if the given address is the zero address. inline constexpr bool is_zero(const address& a) noexcept { return a == address{}; } inline constexpr address::operator bool() const noexcept { return !is_zero(*this); } /// Checks if the given bytes32 object has all zero bytes. inline constexpr bool is_zero(const bytes32& a) noexcept { return a == bytes32{}; } inline constexpr bytes32::operator bool() const noexcept { return !is_zero(*this); } namespace literals { namespace internal { constexpr int from_hex(char c) noexcept { return (c >= 'a' && c <= 'f') ? c - ('a' - 10) : (c >= 'A' && c <= 'F') ? c - ('A' - 10) : c - '0'; } constexpr uint8_t byte(const char* s, size_t i) noexcept { return static_cast((from_hex(s[2 * i]) << 4) | from_hex(s[2 * i + 1])); } template T from_hex(const char*) noexcept; template <> constexpr bytes32 from_hex(const char* s) noexcept { return { {{byte(s, 0), byte(s, 1), byte(s, 2), byte(s, 3), byte(s, 4), byte(s, 5), byte(s, 6), byte(s, 7), byte(s, 8), byte(s, 9), byte(s, 10), byte(s, 11), byte(s, 12), byte(s, 13), byte(s, 14), byte(s, 15), byte(s, 16), byte(s, 17), byte(s, 18), byte(s, 19), byte(s, 20), byte(s, 21), byte(s, 22), byte(s, 23), byte(s, 24), byte(s, 25), byte(s, 26), byte(s, 27), byte(s, 28), byte(s, 29), byte(s, 30), byte(s, 31)}}}; } template <> constexpr address from_hex
(const char* s) noexcept { return { {{byte(s, 0), byte(s, 1), byte(s, 2), byte(s, 3), byte(s, 4), byte(s, 5), byte(s, 6), byte(s, 7), byte(s, 8), byte(s, 9), byte(s, 10), byte(s, 11), byte(s, 12), byte(s, 13), byte(s, 14), byte(s, 15), byte(s, 16), byte(s, 17), byte(s, 18), byte(s, 19)}}}; } template constexpr T from_literal() noexcept { constexpr auto size = sizeof...(c); constexpr char literal[] = {c...}; constexpr bool is_simple_zero = size == 1 && literal[0] == '0'; static_assert(is_simple_zero || (literal[0] == '0' && literal[1] == 'x'), "literal must be in hexadecimal notation"); static_assert(is_simple_zero || size == 2 * sizeof(T) + 2, "literal must match the result type size"); return is_simple_zero ? T{} : from_hex(&literal[2]); } } // namespace internal /// Literal for evmc::address. template constexpr address operator""_address() noexcept { return internal::from_literal(); } /// Literal for evmc::bytes32. template constexpr bytes32 operator""_bytes32() noexcept { return internal::from_literal(); } } // namespace literals using namespace literals; /// Alias for evmc_make_result(). constexpr auto make_result = evmc_make_result; /// @copydoc evmc_result /// /// This is a RAII wrapper for evmc_result and objects of this type /// automatically release attached resources. class result : private evmc_result { public: using evmc_result::create_address; using evmc_result::gas_left; using evmc_result::output_data; using evmc_result::output_size; using evmc_result::status_code; /// Creates the result from the provided arguments. /// /// The provided output is copied to memory allocated with malloc() /// and the evmc_result::release function is set to one invoking free(). /// /// @param _status_code The status code. /// @param _gas_left The amount of gas left. /// @param _output_data The pointer to the output. /// @param _output_size The output size. result(evmc_status_code _status_code, int64_t _gas_left, const uint8_t* _output_data, size_t _output_size) noexcept : evmc_result{make_result(_status_code, _gas_left, _output_data, _output_size)} {} /// Converting constructor from raw evmc_result. explicit result(evmc_result const& res) noexcept : evmc_result{res} {} /// Destructor responsible for automatically releasing attached resources. ~result() noexcept { if (release != nullptr) release(this); } /// Move constructor. result(result&& other) noexcept : evmc_result{other} { other.release = nullptr; // Disable releasing of the rvalue object. } /// Move assignment operator. /// /// The self-assigment MUST never happen. /// /// @param other The other result object. /// @return The reference to the left-hand side object. result& operator=(result&& other) noexcept { this->~result(); // Release this object. static_cast(*this) = other; // Copy data. other.release = nullptr; // Disable releasing of the rvalue object. return *this; } /// Releases the ownership and returns the raw copy of evmc_result. /// /// This method drops the ownership of the result /// (result's resources are not going to be released when this object is destructed). /// It is the caller's responsibility having the returned copy of the result to release it. /// This object MUST NOT be used after this method is invoked. /// /// @return The copy of this object converted to raw evmc_result. evmc_result release_raw() noexcept { const auto out = evmc_result{*this}; // Copy data. this->release = nullptr; // Disable releasing of this object. return out; } }; /// The EVMC Host interface class HostInterface { public: virtual ~HostInterface() noexcept = default; /// @copydoc evmc_host_interface::account_exists virtual bool account_exists(const address& addr) const noexcept = 0; /// @copydoc evmc_host_interface::get_storage virtual bytes32 get_storage(const address& addr, const bytes32& key) const noexcept = 0; /// @copydoc evmc_host_interface::set_storage virtual evmc_storage_status set_storage(const address& addr, const bytes32& key, const bytes32& value) noexcept = 0; /// @copydoc evmc_host_interface::get_balance virtual uint256be get_balance(const address& addr) const noexcept = 0; /// @copydoc evmc_host_interface::get_code_size virtual size_t get_code_size(const address& addr) const noexcept = 0; /// @copydoc evmc_host_interface::get_code_hash virtual bytes32 get_code_hash(const address& addr) const noexcept = 0; /// @copydoc evmc_host_interface::copy_code virtual size_t copy_code(const address& addr, size_t code_offset, uint8_t* buffer_data, size_t buffer_size) const noexcept = 0; /// @copydoc evmc_host_interface::selfdestruct virtual void selfdestruct(const address& addr, const address& beneficiary) noexcept = 0; /// @copydoc evmc_host_interface::call virtual result call(const evmc_message& msg) noexcept = 0; /// @copydoc evmc_host_interface::get_tx_context virtual evmc_tx_context get_tx_context() const noexcept = 0; /// @copydoc evmc_host_interface::get_block_hash virtual bytes32 get_block_hash(int64_t block_number) const noexcept = 0; /// @copydoc evmc_host_interface::emit_log virtual void emit_log(const address& addr, const uint8_t* data, size_t data_size, const bytes32 topics[], size_t num_topics) noexcept = 0; }; /// Wrapper around EVMC host context / host interface. /// /// To be used by VM implementations as better alternative to using ::evmc_host_context directly. class HostContext : public HostInterface { const evmc_host_interface* host = nullptr; evmc_host_context* context = nullptr; mutable evmc_tx_context tx_context = {}; public: /// Default constructor for null Host context. HostContext() = default; /// Constructor from the EVMC Host primitives. /// @param interface The reference to the Host interface. /// @param ctx The pointer to the Host context object. This parameter MAY be null. HostContext(const evmc_host_interface& interface, evmc_host_context* ctx) noexcept : host{&interface}, context{ctx} {} bool account_exists(const address& address) const noexcept final { return host->account_exists(context, &address); } bytes32 get_storage(const address& address, const bytes32& key) const noexcept final { return host->get_storage(context, &address, &key); } evmc_storage_status set_storage(const address& address, const bytes32& key, const bytes32& value) noexcept final { return host->set_storage(context, &address, &key, &value); } uint256be get_balance(const address& address) const noexcept final { return host->get_balance(context, &address); } size_t get_code_size(const address& address) const noexcept final { return host->get_code_size(context, &address); } bytes32 get_code_hash(const address& address) const noexcept final { return host->get_code_hash(context, &address); } size_t copy_code(const address& address, size_t code_offset, uint8_t* buffer_data, size_t buffer_size) const noexcept final { return host->copy_code(context, &address, code_offset, buffer_data, buffer_size); } void selfdestruct(const address& addr, const address& beneficiary) noexcept final { host->selfdestruct(context, &addr, &beneficiary); } result call(const evmc_message& message) noexcept final { return result{host->call(context, &message)}; } /// @copydoc HostInterface::get_tx_context() /// /// The implementation caches the received transaction context /// by assuming that the block timestamp should never be zero. /// /// @return The cached transaction context. evmc_tx_context get_tx_context() const noexcept final { if (tx_context.block_timestamp == 0) tx_context = host->get_tx_context(context); return tx_context; } bytes32 get_block_hash(int64_t number) const noexcept final { return host->get_block_hash(context, number); } void emit_log(const address& addr, const uint8_t* data, size_t data_size, const bytes32 topics[], size_t topics_count) noexcept final { host->emit_log(context, &addr, data, data_size, topics, topics_count); } }; /// Abstract class to be used by Host implementations. /// /// When implementing EVMC Host, you can directly inherit from the evmc::Host class. /// This way your implementation will be simpler by avoiding manual handling /// of the ::evmc_host_context and the ::evmc_host_interface. class Host : public HostInterface { public: /// Provides access to the global host interface. /// @returns Reference to the host interface object. static const evmc_host_interface& get_interface() noexcept; /// Converts the Host object to the opaque host context pointer. /// @returns Pointer to evmc_host_context. evmc_host_context* to_context() noexcept { return reinterpret_cast(this); } /// Converts the opaque host context pointer back to the original Host object. /// @tparam DerivedClass The class derived from the Host class. /// @param context The opaque host context pointer. /// @returns The pointer to DerivedClass. template static DerivedClass* from_context(evmc_host_context* context) noexcept { // Get pointer of the Host base class. auto* h = reinterpret_cast(context); // Additional downcast, only possible if DerivedClass inherits from Host. return static_cast(h); } }; /// @copybrief evmc_vm /// /// This is a RAII wrapper for evmc_vm, and object of this type /// automatically destroys the VM instance. class VM { public: VM() noexcept = default; /// Converting constructor from evmc_vm. explicit VM(evmc_vm* vm) noexcept : m_instance{vm} {} /// Destructor responsible for automatically destroying the VM instance. ~VM() noexcept { if (m_instance != nullptr) m_instance->destroy(m_instance); } VM(const VM&) = delete; VM& operator=(const VM&) = delete; /// Move constructor. VM(VM&& other) noexcept : m_instance{other.m_instance} { other.m_instance = nullptr; } /// Move assignment operator. VM& operator=(VM&& other) noexcept { this->~VM(); m_instance = other.m_instance; other.m_instance = nullptr; return *this; } /// The constructor that captures a VM instance and configures the instance /// with the provided list of options. inline VM(evmc_vm* vm, std::initializer_list> options) noexcept; /// Checks if contains a valid pointer to the VM instance. explicit operator bool() const noexcept { return m_instance != nullptr; } /// Checks whenever the VM instance is ABI compatible with the current EVMC API. bool is_abi_compatible() const noexcept { return m_instance->abi_version == EVMC_ABI_VERSION; } /// @copydoc evmc_vm::name char const* name() const noexcept { return m_instance->name; } /// @copydoc evmc_vm::version char const* version() const noexcept { return m_instance->version; } /// Checks if the VM has the given capability. bool has_capability(evmc_capabilities capability) const noexcept { return (get_capabilities() & static_cast(capability)) != 0; } /// @copydoc evmc_vm::get_capabilities evmc_capabilities_flagset get_capabilities() const noexcept { return m_instance->get_capabilities(m_instance); } /// @copydoc evmc_set_option() evmc_set_option_result set_option(const char name[], const char value[]) noexcept { return evmc_set_option(m_instance, name, value); } /// @copydoc evmc_execute() result execute(const evmc_host_interface& host, evmc_host_context* ctx, evmc_revision rev, const evmc_message& msg, const uint8_t* code, size_t code_size) noexcept { return result{m_instance->execute(m_instance, &host, ctx, rev, &msg, code, code_size)}; } /// Convenient variant of the VM::execute() that takes reference to evmc::Host class. result execute(Host& host, evmc_revision rev, const evmc_message& msg, const uint8_t* code, size_t code_size) noexcept { return execute(Host::get_interface(), host.to_context(), rev, msg, code, code_size); } /// Executes code without the Host context. /// /// The same as /// execute(const evmc_host_interface&, evmc_host_context*, evmc_revision, /// const evmc_message&, const uint8_t*, size_t), /// but without providing the Host context and interface. /// This method is for experimental precompiles support where execution is /// guaranteed not to require any Host access. result execute(evmc_revision rev, const evmc_message& msg, const uint8_t* code, size_t code_size) noexcept { return result{ m_instance->execute(m_instance, nullptr, nullptr, rev, &msg, code, code_size)}; } /// Returns the pointer to C EVMC struct representing the VM. /// /// Gives access to the C EVMC VM struct to allow advanced interaction with the VM not supported /// by the C++ interface. Use as the last resort. /// This object still owns the VM after returning the pointer. The returned pointer MAY be null. evmc_vm* get_raw_pointer() const noexcept { return m_instance; } private: evmc_vm* m_instance = nullptr; }; inline VM::VM(evmc_vm* vm, std::initializer_list> options) noexcept : m_instance{vm} { // This constructor is implemented outside of the class definition to workaround a doxygen bug. for (const auto& option : options) set_option(option.first, option.second); } namespace internal { inline bool account_exists(evmc_host_context* h, const evmc_address* addr) noexcept { return Host::from_context(h)->account_exists(*addr); } inline evmc_bytes32 get_storage(evmc_host_context* h, const evmc_address* addr, const evmc_bytes32* key) noexcept { return Host::from_context(h)->get_storage(*addr, *key); } inline evmc_storage_status set_storage(evmc_host_context* h, const evmc_address* addr, const evmc_bytes32* key, const evmc_bytes32* value) noexcept { return Host::from_context(h)->set_storage(*addr, *key, *value); } inline evmc_uint256be get_balance(evmc_host_context* h, const evmc_address* addr) noexcept { return Host::from_context(h)->get_balance(*addr); } inline size_t get_code_size(evmc_host_context* h, const evmc_address* addr) noexcept { return Host::from_context(h)->get_code_size(*addr); } inline evmc_bytes32 get_code_hash(evmc_host_context* h, const evmc_address* addr) noexcept { return Host::from_context(h)->get_code_hash(*addr); } inline size_t copy_code(evmc_host_context* h, const evmc_address* addr, size_t code_offset, uint8_t* buffer_data, size_t buffer_size) noexcept { return Host::from_context(h)->copy_code(*addr, code_offset, buffer_data, buffer_size); } inline void selfdestruct(evmc_host_context* h, const evmc_address* addr, const evmc_address* beneficiary) noexcept { Host::from_context(h)->selfdestruct(*addr, *beneficiary); } inline evmc_result call(evmc_host_context* h, const evmc_message* msg) noexcept { return Host::from_context(h)->call(*msg).release_raw(); } inline evmc_tx_context get_tx_context(evmc_host_context* h) noexcept { return Host::from_context(h)->get_tx_context(); } inline evmc_bytes32 get_block_hash(evmc_host_context* h, int64_t block_number) noexcept { return Host::from_context(h)->get_block_hash(block_number); } inline void emit_log(evmc_host_context* h, const evmc_address* addr, const uint8_t* data, size_t data_size, const evmc_bytes32 topics[], size_t num_topics) noexcept { Host::from_context(h)->emit_log(*addr, data, data_size, static_cast(topics), num_topics); } } // namespace internal inline const evmc_host_interface& Host::get_interface() noexcept { static constexpr evmc_host_interface interface{ ::evmc::internal::account_exists, ::evmc::internal::get_storage, ::evmc::internal::set_storage, ::evmc::internal::get_balance, ::evmc::internal::get_code_size, ::evmc::internal::get_code_hash, ::evmc::internal::copy_code, ::evmc::internal::selfdestruct, ::evmc::internal::call, ::evmc::internal::get_tx_context, ::evmc::internal::get_block_hash, ::evmc::internal::emit_log}; return interface; } } // namespace evmc namespace std { /// Hash operator template specialization for evmc::address. Needed for unordered containers. template <> struct hash { /// Hash operator using FNV1a-based folding. constexpr size_t operator()(const evmc::address& s) const noexcept { using namespace evmc; using namespace fnv; return static_cast(fnv1a_by64( fnv1a_by64(fnv1a_by64(fnv::offset_basis, load64le(&s.bytes[0])), load64le(&s.bytes[8])), load32le(&s.bytes[16]))); } }; /// Hash operator template specialization for evmc::bytes32. Needed for unordered containers. template <> struct hash { /// Hash operator using FNV1a-based folding. constexpr size_t operator()(const evmc::bytes32& s) const noexcept { using namespace evmc; using namespace fnv; return static_cast( fnv1a_by64(fnv1a_by64(fnv1a_by64(fnv1a_by64(fnv::offset_basis, load64le(&s.bytes[0])), load64le(&s.bytes[8])), load64le(&s.bytes[16])), load64le(&s.bytes[24]))); } }; } // namespace std