// Copyright (c) 2014-2019, 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 #include #include #include #include #include #include "misc_language.h" #include "syncobj.h" #include "cryptonote_basic_impl.h" #include "cryptonote_format_utils.h" #include "file_io_utils.h" #include "common/command_line.h" #include "string_coding.h" #include "string_tools.h" #include "storages/portable_storage_template_helper.h" #include "boost/logic/tribool.hpp" #ifdef __APPLE__ #include #include #include #include #include #include #include #elif defined(__linux__) #include #include #include #include #elif defined(__FreeBSD__) #include #include #include #include #include #include #include #include #include #include #endif #undef MONERO_DEFAULT_LOG_CATEGORY #define MONERO_DEFAULT_LOG_CATEGORY "miner" #define AUTODETECT_WINDOW 10 // seconds #define AUTODETECT_GAIN_THRESHOLD 1.02f // 2% using namespace epee; #include "miner.h" extern "C" void slow_hash_allocate_state(); extern "C" void slow_hash_free_state(); namespace cryptonote { namespace { const command_line::arg_descriptor arg_extra_messages = {"extra-messages-file", "Specify file for extra messages to include into coinbase transactions", "", true}; const command_line::arg_descriptor arg_start_mining = {"start-mining", "Specify wallet address to mining for", "", true}; const command_line::arg_descriptor arg_mining_threads = {"mining-threads", "Specify mining threads count", 0, true}; const command_line::arg_descriptor arg_bg_mining_enable = {"bg-mining-enable", "enable/disable background mining", true, true}; const command_line::arg_descriptor arg_bg_mining_ignore_battery = {"bg-mining-ignore-battery", "if true, assumes plugged in when unable to query system power status", false, true}; const command_line::arg_descriptor arg_bg_mining_min_idle_interval_seconds = {"bg-mining-min-idle-interval", "Specify min lookback interval in seconds for determining idle state", miner::BACKGROUND_MINING_DEFAULT_MIN_IDLE_INTERVAL_IN_SECONDS, true}; const command_line::arg_descriptor arg_bg_mining_idle_threshold_percentage = {"bg-mining-idle-threshold", "Specify minimum avg idle percentage over lookback interval", miner::BACKGROUND_MINING_DEFAULT_IDLE_THRESHOLD_PERCENTAGE, true}; const command_line::arg_descriptor arg_bg_mining_miner_target_percentage = {"bg-mining-miner-target", "Specify maximum percentage cpu use by miner(s)", miner::BACKGROUND_MINING_DEFAULT_MINING_TARGET_PERCENTAGE, true}; } miner::miner(i_miner_handler* phandler):m_stop(1), m_template(boost::value_initialized()), m_template_no(0), m_diffic(0), m_thread_index(0), m_phandler(phandler), m_height(0), m_pausers_count(0), m_threads_total(0), m_starter_nonce(0), m_last_hr_merge_time(0), m_hashes(0), m_total_hashes(0), m_do_print_hashrate(false), m_do_mining(false), m_current_hash_rate(0), m_is_background_mining_enabled(false), m_min_idle_seconds(BACKGROUND_MINING_DEFAULT_MIN_IDLE_INTERVAL_IN_SECONDS), m_idle_threshold(BACKGROUND_MINING_DEFAULT_IDLE_THRESHOLD_PERCENTAGE), m_mining_target(BACKGROUND_MINING_DEFAULT_MINING_TARGET_PERCENTAGE), m_miner_extra_sleep(BACKGROUND_MINING_DEFAULT_MINER_EXTRA_SLEEP_MILLIS), m_block_reward(0) { } //----------------------------------------------------------------------------------------------------- miner::~miner() { try { stop(); } catch (...) { /* ignore */ } } //----------------------------------------------------------------------------------------------------- bool miner::set_block_template(const block& bl, const difficulty_type& di, uint64_t height, uint64_t block_reward) { CRITICAL_REGION_LOCAL(m_template_lock); m_template = bl; m_diffic = di; m_height = height; m_block_reward = block_reward; ++m_template_no; m_starter_nonce = crypto::rand(); return true; } //----------------------------------------------------------------------------------------------------- bool miner::on_block_chain_update() { if(!is_mining()) return true; return request_block_template(); } //----------------------------------------------------------------------------------------------------- bool miner::request_block_template() { block bl; difficulty_type di = AUTO_VAL_INIT(di); uint64_t height = AUTO_VAL_INIT(height); uint64_t expected_reward; //only used for RPC calls - could possibly be useful here too? cryptonote::blobdata extra_nonce; if(m_extra_messages.size() && m_config.current_extra_message_index < m_extra_messages.size()) { extra_nonce = m_extra_messages[m_config.current_extra_message_index]; } if(!m_phandler->get_block_template(bl, m_mine_address, di, height, expected_reward, extra_nonce)) { LOG_ERROR("Failed to get_block_template(), stopping mining"); return false; } set_block_template(bl, di, height, expected_reward); return true; } //----------------------------------------------------------------------------------------------------- bool miner::on_idle() { m_update_block_template_interval.do_call([&](){ if(is_mining())request_block_template(); return true; }); m_update_merge_hr_interval.do_call([&](){ merge_hr(); return true; }); m_autodetect_interval.do_call([&](){ update_autodetection(); return true; }); return true; } //----------------------------------------------------------------------------------------------------- void miner::do_print_hashrate(bool do_hr) { m_do_print_hashrate = do_hr; } //----------------------------------------------------------------------------------------------------- void miner::merge_hr() { if(m_last_hr_merge_time && is_mining()) { m_current_hash_rate = m_hashes * 1000 / ((misc_utils::get_tick_count() - m_last_hr_merge_time + 1)); CRITICAL_REGION_LOCAL(m_last_hash_rates_lock); m_last_hash_rates.push_back(m_current_hash_rate); if(m_last_hash_rates.size() > 19) m_last_hash_rates.pop_front(); if(m_do_print_hashrate) { uint64_t total_hr = std::accumulate(m_last_hash_rates.begin(), m_last_hash_rates.end(), 0); float hr = static_cast(total_hr)/static_cast(m_last_hash_rates.size()); const auto flags = std::cout.flags(); const auto precision = std::cout.precision(); std::cout << "hashrate: " << std::setprecision(4) << std::fixed << hr << std::setiosflags(flags) << std::setprecision(precision) << ENDL; } } m_last_hr_merge_time = misc_utils::get_tick_count(); m_hashes = 0; } //----------------------------------------------------------------------------------------------------- void miner::update_autodetection() { if (m_threads_autodetect.empty()) return; uint64_t now = epee::misc_utils::get_ns_count(); uint64_t dt = now - m_threads_autodetect.back().first; if (dt < AUTODETECT_WINDOW * 1000000000ull) return; // work out how many more hashes we got m_threads_autodetect.back().first = dt; uint64_t dh = m_total_hashes - m_threads_autodetect.back().second; m_threads_autodetect.back().second = dh; float hs = dh / (dt / (float)1000000000); MGINFO("Mining autodetection: " << m_threads_autodetect.size() << " threads: " << hs << " H/s"); // when we don't increase by at least 2%, stop, otherwise check next // if N and N+1 have mostly the same hash rate, we want to "lighter" one bool found = false; if (m_threads_autodetect.size() > 1) { int previdx = m_threads_autodetect.size() - 2; float previous_hs = m_threads_autodetect[previdx].second / (m_threads_autodetect[previdx].first / (float)1000000000); if (previous_hs > 0 && hs / previous_hs < AUTODETECT_GAIN_THRESHOLD) { m_threads_total = m_threads_autodetect.size() - 1; m_threads_autodetect.clear(); MGINFO("Optimal number of threads seems to be " << m_threads_total); found = true; } } if (!found) { // setup one more thread m_threads_autodetect.push_back({now, m_total_hashes}); m_threads_total = m_threads_autodetect.size(); } // restart all threads { CRITICAL_REGION_LOCAL(m_threads_lock); boost::interprocess::ipcdetail::atomic_write32(&m_stop, 1); for(boost::thread& th: m_threads) th.join(); m_threads.clear(); } boost::interprocess::ipcdetail::atomic_write32(&m_stop, 0); boost::interprocess::ipcdetail::atomic_write32(&m_thread_index, 0); for(size_t i = 0; i != m_threads_total; i++) m_threads.push_back(boost::thread(m_attrs, boost::bind(&miner::worker_thread, this))); } //----------------------------------------------------------------------------------------------------- void miner::init_options(boost::program_options::options_description& desc) { command_line::add_arg(desc, arg_extra_messages); command_line::add_arg(desc, arg_start_mining); command_line::add_arg(desc, arg_mining_threads); command_line::add_arg(desc, arg_bg_mining_enable); command_line::add_arg(desc, arg_bg_mining_ignore_battery); command_line::add_arg(desc, arg_bg_mining_min_idle_interval_seconds); command_line::add_arg(desc, arg_bg_mining_idle_threshold_percentage); command_line::add_arg(desc, arg_bg_mining_miner_target_percentage); } //----------------------------------------------------------------------------------------------------- bool miner::init(const boost::program_options::variables_map& vm, network_type nettype) { if(command_line::has_arg(vm, arg_extra_messages)) { std::string buff; bool r = file_io_utils::load_file_to_string(command_line::get_arg(vm, arg_extra_messages), buff); CHECK_AND_ASSERT_MES(r, false, "Failed to load file with extra messages: " << command_line::get_arg(vm, arg_extra_messages)); std::vector extra_vec; boost::split(extra_vec, buff, boost::is_any_of("\n"), boost::token_compress_on ); m_extra_messages.resize(extra_vec.size()); for(size_t i = 0; i != extra_vec.size(); i++) { string_tools::trim(extra_vec[i]); if(!extra_vec[i].size()) continue; std::string buff = string_encoding::base64_decode(extra_vec[i]); if(buff != "0") m_extra_messages[i] = buff; } m_config_folder_path = boost::filesystem::path(command_line::get_arg(vm, arg_extra_messages)).parent_path().string(); m_config = AUTO_VAL_INIT(m_config); const std::string filename = m_config_folder_path + "/" + MINER_CONFIG_FILE_NAME; CHECK_AND_ASSERT_MES(epee::serialization::load_t_from_json_file(m_config, filename), false, "Failed to load data from " << filename); MINFO("Loaded " << m_extra_messages.size() << " extra messages, current index " << m_config.current_extra_message_index); } if(command_line::has_arg(vm, arg_start_mining)) { address_parse_info info; if(!cryptonote::get_account_address_from_str(info, nettype, command_line::get_arg(vm, arg_start_mining)) || info.is_subaddress) { LOG_ERROR("Target account address " << command_line::get_arg(vm, arg_start_mining) << " has wrong format, starting daemon canceled"); return false; } m_mine_address = info.address; m_threads_total = 1; m_do_mining = true; if(command_line::has_arg(vm, arg_mining_threads)) { m_threads_total = command_line::get_arg(vm, arg_mining_threads); } } // Background mining parameters // Let init set all parameters even if background mining is not enabled, they can start later with params set if(command_line::has_arg(vm, arg_bg_mining_enable)) set_is_background_mining_enabled( command_line::get_arg(vm, arg_bg_mining_enable) ); if(command_line::has_arg(vm, arg_bg_mining_ignore_battery)) set_ignore_battery( command_line::get_arg(vm, arg_bg_mining_ignore_battery) ); if(command_line::has_arg(vm, arg_bg_mining_min_idle_interval_seconds)) set_min_idle_seconds( command_line::get_arg(vm, arg_bg_mining_min_idle_interval_seconds) ); if(command_line::has_arg(vm, arg_bg_mining_idle_threshold_percentage)) set_idle_threshold( command_line::get_arg(vm, arg_bg_mining_idle_threshold_percentage) ); if(command_line::has_arg(vm, arg_bg_mining_miner_target_percentage)) set_mining_target( command_line::get_arg(vm, arg_bg_mining_miner_target_percentage) ); return true; } //----------------------------------------------------------------------------------------------------- bool miner::is_mining() const { return !m_stop; } //----------------------------------------------------------------------------------------------------- const account_public_address& miner::get_mining_address() const { return m_mine_address; } //----------------------------------------------------------------------------------------------------- uint32_t miner::get_threads_count() const { return m_threads_total; } //----------------------------------------------------------------------------------------------------- bool miner::start(const account_public_address& adr, size_t threads_count, const boost::thread::attributes& attrs, bool do_background, bool ignore_battery) { m_block_reward = 0; m_mine_address = adr; m_threads_total = static_cast(threads_count); if (threads_count == 0) { m_threads_autodetect.clear(); m_threads_autodetect.push_back({epee::misc_utils::get_ns_count(), m_total_hashes}); m_threads_total = 1; } m_attrs = attrs; m_starter_nonce = crypto::rand(); CRITICAL_REGION_LOCAL(m_threads_lock); if(is_mining()) { LOG_ERROR("Starting miner but it's already started"); return false; } if(!m_threads.empty()) { LOG_ERROR("Unable to start miner because there are active mining threads"); return false; } request_block_template();//lets update block template boost::interprocess::ipcdetail::atomic_write32(&m_stop, 0); boost::interprocess::ipcdetail::atomic_write32(&m_thread_index, 0); set_is_background_mining_enabled(do_background); set_ignore_battery(ignore_battery); for(size_t i = 0; i != m_threads_total; i++) { m_threads.push_back(boost::thread(attrs, boost::bind(&miner::worker_thread, this))); } if (threads_count == 0) MINFO("Mining has started, autodetecting optimal number of threads, good luck!" ); else MINFO("Mining has started with " << threads_count << " threads, good luck!" ); if( get_is_background_mining_enabled() ) { m_background_mining_thread = boost::thread(attrs, boost::bind(&miner::background_worker_thread, this)); LOG_PRINT_L0("Background mining controller thread started" ); } if(get_ignore_battery()) { MINFO("Ignoring battery"); } return true; } //----------------------------------------------------------------------------------------------------- uint64_t miner::get_speed() const { if(is_mining()) { return m_current_hash_rate; } else { return 0; } } //----------------------------------------------------------------------------------------------------- void miner::send_stop_signal() { boost::interprocess::ipcdetail::atomic_write32(&m_stop, 1); } //----------------------------------------------------------------------------------------------------- bool miner::stop() { MTRACE("Miner has received stop signal"); if (!is_mining()) { MTRACE("Not mining - nothing to stop" ); return true; } send_stop_signal(); CRITICAL_REGION_LOCAL(m_threads_lock); // In case background mining was active and the miner threads are waiting // on the background miner to signal start. m_is_background_mining_started_cond.notify_all(); for(boost::thread& th: m_threads) th.join(); // The background mining thread could be sleeping for a long time, so we // interrupt it just in case m_background_mining_thread.interrupt(); m_background_mining_thread.join(); MINFO("Mining has been stopped, " << m_threads.size() << " finished" ); m_threads.clear(); m_threads_autodetect.clear(); return true; } //----------------------------------------------------------------------------------------------------- bool miner::find_nonce_for_given_block(block& bl, const difficulty_type& diffic, uint64_t height) { for(; bl.nonce != std::numeric_limits::max(); bl.nonce++) { crypto::hash h; get_block_longhash(bl, h, height); if(check_hash(h, diffic)) { bl.invalidate_hashes(); return true; } } bl.invalidate_hashes(); return false; } //----------------------------------------------------------------------------------------------------- void miner::on_synchronized() { if(m_do_mining) { boost::thread::attributes attrs; attrs.set_stack_size(THREAD_STACK_SIZE); start(m_mine_address, m_threads_total, attrs, get_is_background_mining_enabled(), get_ignore_battery()); } } //----------------------------------------------------------------------------------------------------- void miner::pause() { CRITICAL_REGION_LOCAL(m_miners_count_lock); MDEBUG("miner::pause: " << m_pausers_count << " -> " << (m_pausers_count + 1)); ++m_pausers_count; if(m_pausers_count == 1 && is_mining()) MDEBUG("MINING PAUSED"); } //----------------------------------------------------------------------------------------------------- void miner::resume() { CRITICAL_REGION_LOCAL(m_miners_count_lock); MDEBUG("miner::resume: " << m_pausers_count << " -> " << (m_pausers_count - 1)); --m_pausers_count; if(m_pausers_count < 0) { m_pausers_count = 0; MERROR("Unexpected miner::resume() called"); } if(!m_pausers_count && is_mining()) MDEBUG("MINING RESUMED"); } //----------------------------------------------------------------------------------------------------- bool miner::worker_thread() { uint32_t th_local_index = boost::interprocess::ipcdetail::atomic_inc32(&m_thread_index); MLOG_SET_THREAD_NAME(std::string("[miner ") + std::to_string(th_local_index) + "]"); MGINFO("Miner thread was started ["<< th_local_index << "]"); uint32_t nonce = m_starter_nonce + th_local_index; uint64_t height = 0; difficulty_type local_diff = 0; uint32_t local_template_ver = 0; block b; slow_hash_allocate_state(); while(!m_stop) { if(m_pausers_count)//anti split workaround { misc_utils::sleep_no_w(100); continue; } else if( m_is_background_mining_enabled ) { misc_utils::sleep_no_w(m_miner_extra_sleep); while( !m_is_background_mining_started ) { MGINFO("background mining is enabled, but not started, waiting until start triggers"); boost::unique_lock started_lock( m_is_background_mining_started_mutex ); m_is_background_mining_started_cond.wait( started_lock ); if( m_stop ) break; } if( m_stop ) continue; } if(local_template_ver != m_template_no) { CRITICAL_REGION_BEGIN(m_template_lock); b = m_template; local_diff = m_diffic; height = m_height; CRITICAL_REGION_END(); local_template_ver = m_template_no; nonce = m_starter_nonce + th_local_index; } if(!local_template_ver)//no any set_block_template call { LOG_PRINT_L2("Block template not set yet"); epee::misc_utils::sleep_no_w(1000); continue; } b.nonce = nonce; crypto::hash h; get_block_longhash(b, h, height); if(check_hash(h, local_diff)) { //we lucky! ++m_config.current_extra_message_index; MGINFO_GREEN("Found block " << get_block_hash(b) << " at height " << height << " for difficulty: " << local_diff); if(!m_phandler->handle_block_found(b)) { --m_config.current_extra_message_index; }else { //success update, lets update config if (!m_config_folder_path.empty()) epee::serialization::store_t_to_json_file(m_config, m_config_folder_path + "/" + MINER_CONFIG_FILE_NAME); } } nonce+=m_threads_total; ++m_hashes; ++m_total_hashes; } slow_hash_free_state(); MGINFO("Miner thread stopped ["<< th_local_index << "]"); return true; } //----------------------------------------------------------------------------------------------------- bool miner::get_is_background_mining_enabled() const { return m_is_background_mining_enabled; } //----------------------------------------------------------------------------------------------------- bool miner::get_ignore_battery() const { return m_ignore_battery; } //----------------------------------------------------------------------------------------------------- /** * This has differing behaviour depending on if mining has been started/etc. * Note: add documentation */ bool miner::set_is_background_mining_enabled(bool is_background_mining_enabled) { m_is_background_mining_enabled = is_background_mining_enabled; // Extra logic will be required if we make this function public in the future // and allow toggling smart mining without start/stop //m_is_background_mining_enabled_cond.notify_one(); return true; } //----------------------------------------------------------------------------------------------------- void miner::set_ignore_battery(bool ignore_battery) { m_ignore_battery = ignore_battery; } //----------------------------------------------------------------------------------------------------- uint64_t miner::get_min_idle_seconds() const { return m_min_idle_seconds; } //----------------------------------------------------------------------------------------------------- bool miner::set_min_idle_seconds(uint64_t min_idle_seconds) { if(min_idle_seconds > BACKGROUND_MINING_MAX_MIN_IDLE_INTERVAL_IN_SECONDS) return false; if(min_idle_seconds < BACKGROUND_MINING_MIN_MIN_IDLE_INTERVAL_IN_SECONDS) return false; m_min_idle_seconds = min_idle_seconds; return true; } //----------------------------------------------------------------------------------------------------- uint8_t miner::get_idle_threshold() const { return m_idle_threshold; } //----------------------------------------------------------------------------------------------------- bool miner::set_idle_threshold(uint8_t idle_threshold) { if(idle_threshold > BACKGROUND_MINING_MAX_IDLE_THRESHOLD_PERCENTAGE) return false; if(idle_threshold < BACKGROUND_MINING_MIN_IDLE_THRESHOLD_PERCENTAGE) return false; m_idle_threshold = idle_threshold; return true; } //----------------------------------------------------------------------------------------------------- uint8_t miner::get_mining_target() const { return m_mining_target; } //----------------------------------------------------------------------------------------------------- bool miner::set_mining_target(uint8_t mining_target) { if(mining_target > BACKGROUND_MINING_MAX_MINING_TARGET_PERCENTAGE) return false; if(mining_target < BACKGROUND_MINING_MIN_MINING_TARGET_PERCENTAGE) return false; m_mining_target = mining_target; return true; } //----------------------------------------------------------------------------------------------------- bool miner::background_worker_thread() { uint64_t prev_total_time, current_total_time; uint64_t prev_idle_time, current_idle_time; uint64_t previous_process_time = 0, current_process_time = 0; m_is_background_mining_started = false; if(!get_system_times(prev_total_time, prev_idle_time)) { LOG_ERROR("get_system_times call failed, background mining will NOT work!"); return false; } while(!m_stop) { try { // Commenting out the below since we're going with privatizing the bg mining enabled // function, but I'll leave the code/comments here for anyone that wants to modify the // patch in the future // ------------------------------------------------------------------------------------- // All of this might be overkill if we just enforced some simple requirements // about changing this variable before/after the miner starts, but I envision // in the future a checkbox that you can tick on/off for background mining after // you've clicked "start mining". There's still an issue here where if background // mining is disabled when start is called, this thread is never created, and so // enabling after does nothing, something I have to fix in the future. However, // this should take care of the case where mining is started with bg-enabled, // and then the user decides to un-check background mining, and just do // regular full-speed mining. I might just be over-doing it and thinking up // non-existant use-cases, so if the consensus is to simplify, we can remove all this fluff. /* while( !m_is_background_mining_enabled ) { MGINFO("background mining is disabled, waiting until enabled!"); boost::unique_lock enabled_lock( m_is_background_mining_enabled_mutex ); m_is_background_mining_enabled_cond.wait( enabled_lock ); } */ // If we're already mining, then sleep for the miner monitor interval. // If we're NOT mining, then sleep for the idle monitor interval uint64_t sleep_for_seconds = BACKGROUND_MINING_MINER_MONITOR_INVERVAL_IN_SECONDS; if( !m_is_background_mining_started ) sleep_for_seconds = get_min_idle_seconds(); boost::this_thread::sleep_for(boost::chrono::seconds(sleep_for_seconds)); } catch(const boost::thread_interrupted&) { MDEBUG("background miner thread interrupted "); continue; // if interrupted because stop called, loop should end .. } bool on_ac_power = m_ignore_battery; if(!m_ignore_battery) { boost::tribool battery_powered(on_battery_power()); if(!indeterminate( battery_powered )) { on_ac_power = !(bool)battery_powered; } } if( m_is_background_mining_started ) { // figure out if we need to stop, and monitor mining usage // If we get here, then previous values are initialized. // Let's get some current data for comparison. if(!get_system_times(current_total_time, current_idle_time)) { MERROR("get_system_times call failed"); continue; } if(!get_process_time(current_process_time)) { MERROR("get_process_time call failed!"); continue; } uint64_t total_diff = (current_total_time - prev_total_time); uint64_t idle_diff = (current_idle_time - prev_idle_time); uint64_t process_diff = (current_process_time - previous_process_time); uint8_t idle_percentage = get_percent_of_total(idle_diff, total_diff); uint8_t process_percentage = get_percent_of_total(process_diff, total_diff); MGINFO("idle percentage is " << unsigned(idle_percentage) << "\%, miner percentage is " << unsigned(process_percentage) << "\%, ac power : " << on_ac_power); if( idle_percentage + process_percentage < get_idle_threshold() || !on_ac_power ) { MGINFO("cpu is " << unsigned(idle_percentage) << "% idle, idle threshold is " << unsigned(get_idle_threshold()) << "\%, ac power : " << on_ac_power << ", background mining stopping, thanks for your contribution!"); m_is_background_mining_started = false; // reset process times previous_process_time = 0; current_process_time = 0; } else { previous_process_time = current_process_time; // adjust the miner extra sleep variable int64_t miner_extra_sleep_change = (-1 * (get_mining_target() - process_percentage) ); int64_t new_miner_extra_sleep = m_miner_extra_sleep + miner_extra_sleep_change; // if you start the miner with few threads on a multicore system, this could // fall below zero because all the time functions aggregate across all processors. // I'm just hard limiting to 5 millis min sleep here, other options? m_miner_extra_sleep = std::max( new_miner_extra_sleep , (int64_t)5 ); MDEBUG("m_miner_extra_sleep " << m_miner_extra_sleep); } prev_total_time = current_total_time; prev_idle_time = current_idle_time; } else if( on_ac_power ) { // figure out if we need to start if(!get_system_times(current_total_time, current_idle_time)) { MERROR("get_system_times call failed"); continue; } uint64_t total_diff = (current_total_time - prev_total_time); uint64_t idle_diff = (current_idle_time - prev_idle_time); uint8_t idle_percentage = get_percent_of_total(idle_diff, total_diff); MGINFO("idle percentage is " << unsigned(idle_percentage)); if( idle_percentage >= get_idle_threshold() && on_ac_power ) { MGINFO("cpu is " << unsigned(idle_percentage) << "% idle, idle threshold is " << unsigned(get_idle_threshold()) << "\%, ac power : " << on_ac_power << ", background mining started, good luck!"); m_is_background_mining_started = true; m_is_background_mining_started_cond.notify_all(); // Wait for a little mining to happen .. boost::this_thread::sleep_for(boost::chrono::seconds( 1 )); // Starting data ... if(!get_process_time(previous_process_time)) { m_is_background_mining_started = false; MERROR("get_process_time call failed!"); } } prev_total_time = current_total_time; prev_idle_time = current_idle_time; } } return true; } //----------------------------------------------------------------------------------------------------- bool miner::get_system_times(uint64_t& total_time, uint64_t& idle_time) { #ifdef _WIN32 FILETIME idleTime; FILETIME kernelTime; FILETIME userTime; if ( GetSystemTimes( &idleTime, &kernelTime, &userTime ) != -1 ) { total_time = ( (((uint64_t)(kernelTime.dwHighDateTime)) << 32) | ((uint64_t)kernelTime.dwLowDateTime) ) + ( (((uint64_t)(userTime.dwHighDateTime)) << 32) | ((uint64_t)userTime.dwLowDateTime) ); idle_time = ( (((uint64_t)(idleTime.dwHighDateTime)) << 32) | ((uint64_t)idleTime.dwLowDateTime) ); return true; } #elif defined(__linux__) const std::string STAT_FILE_PATH = "/proc/stat"; if( !epee::file_io_utils::is_file_exist(STAT_FILE_PATH) ) { LOG_ERROR("'" << STAT_FILE_PATH << "' file does not exist"); return false; } std::ifstream stat_file_stream(STAT_FILE_PATH); if( stat_file_stream.fail() ) { LOG_ERROR("failed to open '" << STAT_FILE_PATH << "'"); return false; } std::string line; std::getline(stat_file_stream, line); std::istringstream stat_file_iss(line); stat_file_iss.ignore(65536, ' '); // skip cpu label ... uint64_t utime, ntime, stime, itime; if( !(stat_file_iss >> utime && stat_file_iss >> ntime && stat_file_iss >> stime && stat_file_iss >> itime) ) { LOG_ERROR("failed to read '" << STAT_FILE_PATH << "'"); return false; } idle_time = itime; total_time = utime + ntime + stime + itime; return true; #elif defined(__APPLE__) mach_msg_type_number_t count; kern_return_t status; host_cpu_load_info_data_t stats; count = HOST_CPU_LOAD_INFO_COUNT; status = host_statistics(mach_host_self(), HOST_CPU_LOAD_INFO, (host_info_t)&stats, &count); if(status != KERN_SUCCESS) { return false; } idle_time = stats.cpu_ticks[CPU_STATE_IDLE]; total_time = idle_time + stats.cpu_ticks[CPU_STATE_USER] + stats.cpu_ticks[CPU_STATE_SYSTEM]; return true; #elif defined(__FreeBSD__) struct statinfo s; size_t n = sizeof(s.cp_time); if( sysctlbyname("kern.cp_time", s.cp_time, &n, NULL, 0) == -1 ) { LOG_ERROR("sysctlbyname(\"kern.cp_time\"): " << strerror(errno)); return false; } if( n != sizeof(s.cp_time) ) { LOG_ERROR("sysctlbyname(\"kern.cp_time\") output is unexpectedly " << n << " bytes instead of the expected " << sizeof(s.cp_time) << " bytes."); return false; } idle_time = s.cp_time[CP_IDLE]; total_time = s.cp_time[CP_USER] + s.cp_time[CP_NICE] + s.cp_time[CP_SYS] + s.cp_time[CP_INTR] + s.cp_time[CP_IDLE]; return true; #endif return false; // unsupported system } //----------------------------------------------------------------------------------------------------- bool miner::get_process_time(uint64_t& total_time) { #ifdef _WIN32 FILETIME createTime; FILETIME exitTime; FILETIME kernelTime; FILETIME userTime; if ( GetProcessTimes( GetCurrentProcess(), &createTime, &exitTime, &kernelTime, &userTime ) != -1 ) { total_time = ( (((uint64_t)(kernelTime.dwHighDateTime)) << 32) | ((uint64_t)kernelTime.dwLowDateTime) ) + ( (((uint64_t)(userTime.dwHighDateTime)) << 32) | ((uint64_t)userTime.dwLowDateTime) ); return true; } #elif (defined(__linux__) && defined(_SC_CLK_TCK)) || defined(__APPLE__) || defined(__FreeBSD__) struct tms tms; if ( times(&tms) != (clock_t)-1 ) { total_time = tms.tms_utime + tms.tms_stime; return true; } #endif return false; // unsupported system } //----------------------------------------------------------------------------------------------------- uint8_t miner::get_percent_of_total(uint64_t other, uint64_t total) { return (uint8_t)( ceil( (other * 1.f / total * 1.f) * 100) ); } //----------------------------------------------------------------------------------------------------- boost::logic::tribool miner::on_battery_power() { #ifdef _WIN32 SYSTEM_POWER_STATUS power_status; if ( GetSystemPowerStatus( &power_status ) != 0 ) { return boost::logic::tribool(power_status.ACLineStatus != 1); } #elif defined(__APPLE__) #if TARGET_OS_MAC && (!defined(MAC_OS_X_VERSION_MIN_REQUIRED) || MAC_OS_X_VERSION_MIN_REQUIRED >= MAC_OS_X_VERSION_10_7) return boost::logic::tribool(IOPSGetTimeRemainingEstimate() != kIOPSTimeRemainingUnlimited); #else // iOS or OSX <10.7 return boost::logic::tribool(boost::logic::indeterminate); #endif #elif defined(__linux__) // Use the power_supply class http://lxr.linux.no/#linux+v4.10.1/Documentation/power/power_supply_class.txt std::string power_supply_class_path = "/sys/class/power_supply"; boost::tribool on_battery = boost::logic::tribool(boost::logic::indeterminate); if (boost::filesystem::is_directory(power_supply_class_path)) { const boost::filesystem::directory_iterator end_itr; for (boost::filesystem::directory_iterator iter(power_supply_class_path); iter != end_itr; ++iter) { const boost::filesystem::path& power_supply_path = iter->path(); if (boost::filesystem::is_directory(power_supply_path)) { boost::filesystem::path power_supply_type_path = power_supply_path / "type"; if (boost::filesystem::is_regular_file(power_supply_type_path)) { std::ifstream power_supply_type_stream(power_supply_type_path.string()); if (power_supply_type_stream.fail()) { LOG_PRINT_L0("Unable to read from " << power_supply_type_path << " to check power supply type"); continue; } std::string power_supply_type; std::getline(power_supply_type_stream, power_supply_type); // If there is an AC adapter that's present and online we can break early if (boost::starts_with(power_supply_type, "Mains")) { boost::filesystem::path power_supply_online_path = power_supply_path / "online"; if (boost::filesystem::is_regular_file(power_supply_online_path)) { std::ifstream power_supply_online_stream(power_supply_online_path.string()); if (power_supply_online_stream.fail()) { LOG_PRINT_L0("Unable to read from " << power_supply_online_path << " to check ac power supply status"); continue; } if (power_supply_online_stream.get() == '1') { return boost::logic::tribool(false); } } } else if (boost::starts_with(power_supply_type, "Battery") && boost::logic::indeterminate(on_battery)) { boost::filesystem::path power_supply_status_path = power_supply_path / "status"; if (boost::filesystem::is_regular_file(power_supply_status_path)) { std::ifstream power_supply_status_stream(power_supply_status_path.string()); if (power_supply_status_stream.fail()) { LOG_PRINT_L0("Unable to read from " << power_supply_status_path << " to check battery power supply status"); continue; } // Possible status are Charging, Full, Discharging, Not Charging, and Unknown // We are only need to handle negative states right now std::string power_supply_status; std::getline(power_supply_status_stream, power_supply_status); if (boost::starts_with(power_supply_status, "Charging") || boost::starts_with(power_supply_status, "Full")) { on_battery = boost::logic::tribool(false); } if (boost::starts_with(power_supply_status, "Discharging")) { on_battery = boost::logic::tribool(true); } } } } } } } if (boost::logic::indeterminate(on_battery)) { LOG_ERROR("couldn't query power status from " << power_supply_class_path); } return on_battery; #elif defined(__FreeBSD__) int ac; size_t n = sizeof(ac); if( sysctlbyname("hw.acpi.acline", &ac, &n, NULL, 0) == -1 ) { if( errno != ENOENT ) { LOG_ERROR("Cannot query battery status: " << "sysctlbyname(\"hw.acpi.acline\"): " << strerror(errno)); return boost::logic::tribool(boost::logic::indeterminate); } // If sysctl fails with ENOENT, then try querying /dev/apm. static const char* dev_apm = "/dev/apm"; const int fd = open(dev_apm, O_RDONLY); if( fd == -1 ) { LOG_ERROR("Cannot query battery status: " << "open(): " << dev_apm << ": " << strerror(errno)); return boost::logic::tribool(boost::logic::indeterminate); } apm_info info; if( ioctl(fd, APMIO_GETINFO, &info) == -1 ) { close(fd); LOG_ERROR("Cannot query battery status: " << "ioctl(" << dev_apm << ", APMIO_GETINFO): " << strerror(errno)); return boost::logic::tribool(boost::logic::indeterminate); } close(fd); // See apm(8). switch( info.ai_acline ) { case 0: // off-line case 2: // backup power return boost::logic::tribool(true); case 1: // on-line return boost::logic::tribool(false); } switch( info.ai_batt_stat ) { case 0: // high case 1: // low case 2: // critical return boost::logic::tribool(true); case 3: // charging return boost::logic::tribool(false); } LOG_ERROR("Cannot query battery status: " << "sysctl hw.acpi.acline is not available and /dev/apm returns " << "unexpected ac-line status (" << info.ai_acline << ") and " << "battery status (" << info.ai_batt_stat << ")."); return boost::logic::tribool(boost::logic::indeterminate); } if( n != sizeof(ac) ) { LOG_ERROR("sysctlbyname(\"hw.acpi.acline\") output is unexpectedly " << n << " bytes instead of the expected " << sizeof(ac) << " bytes."); return boost::logic::tribool(boost::logic::indeterminate); } return boost::logic::tribool(ac == 0); #endif LOG_ERROR("couldn't query power status"); return boost::logic::tribool(boost::logic::indeterminate); } }