// // Copyright 2010-2013 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: GPL-3.0-or-later // #include "libusb1_base.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef UHD_TXRX_DEBUG_PRINTS # include # include # include #endif using namespace uhd; using namespace uhd::transport; static const size_t DEFAULT_NUM_XFERS = 16; // num xfers static const size_t DEFAULT_XFER_SIZE = 32 * 512; // bytes //! type for sharing the release queue with managed buffers class libusb_zero_copy_mb; typedef boost::shared_ptr> mb_queue_sptr; /*! * The libusb docs state that status and actual length can only be read in the callback. * Therefore, this struct is intended to store data seen from the callback function. */ struct lut_result_t { lut_result_t(void) { completed = 0; status = LIBUSB_TRANSFER_COMPLETED; actual_length = 0; #ifdef UHD_TXRX_DEBUG_PRINTS start_time = 0; buff_num = -1; #endif } int completed; libusb_transfer_status status; int actual_length; boost::mutex mut; boost::condition_variable usb_transfer_complete; #ifdef UHD_TXRX_DEBUG_PRINTS // These are fore debugging long start_time; int buff_num; bool is_recv; #endif }; // Created to be used as an argument to boost::condition_variable::timed_wait() function struct lut_result_completed { const lut_result_t& _result; lut_result_completed(const lut_result_t& result) : _result(result) {} bool operator()() const { return (_result.completed ? true : false); } }; #ifdef UHD_TXRX_DEBUG_PRINTS static std::string dbg_prefix("libusb1_zero_copy,"); static void libusb1_zerocopy_dbg_print_err(std::string msg) { msg = dbg_prefix + msg; fprintf(stderr, "%s\n", msg.c_str()); } #endif /*! * All libusb callback functions should be marked with the LIBUSB_CALL macro * to ensure that they are compiled with the same calling convention as libusb. */ //! helper function: handles all async callbacks static void LIBUSB_CALL libusb_async_cb(libusb_transfer* lut) { lut_result_t* r = (lut_result_t*)lut->user_data; boost::lock_guard lock(r->mut); r->status = lut->status; r->actual_length = lut->actual_length; r->completed = 1; r->usb_transfer_complete.notify_one(); // wake up thread waiting in // wait_for_completion() member function below #ifdef UHD_TXRX_DEBUG_PRINTS long end_time = boost::get_system_time().time_of_day().total_microseconds(); libusb1_zerocopy_dbg_print_err( (boost::format("libusb_async_cb,%s,%i,%i,%i,%ld,%ld") % (r->is_recv ? "rx" : "tx") % r->buff_num % r->actual_length % r->status % end_time % r->start_time) .str()); #endif } /*********************************************************************** * Reusable managed buffer: * - Associated with a particular libusb transfer struct. * - Submits the transfer to libusb in the release method. **********************************************************************/ class libusb_zero_copy_mb : public managed_buffer { public: libusb_zero_copy_mb(libusb_transfer* lut, const size_t frame_size, boost::function release_cb, const bool is_recv, const std::string& name) : _release_cb(release_cb) , _is_recv(is_recv) , _name(name) , _ctx(libusb::session::get_global_session()->get_context()) , _lut(lut) , _frame_size(frame_size) { /* NOP */ } virtual ~libusb_zero_copy_mb(void); void release(void) { _release_cb(this); } UHD_INLINE void submit(void) { _lut->length = int((_is_recv) ? _frame_size : size()); // always set length #ifdef UHD_TXRX_DEBUG_PRINTS result.start_time = boost::get_system_time().time_of_day().total_microseconds(); result.buff_num = num(); result.is_recv = _is_recv; #endif int ret = libusb_submit_transfer(_lut); if (ret != LIBUSB_SUCCESS) throw uhd::usb_error(ret, str(boost::format("usb %s submit failed: %s") % _name % libusb_error_name(ret))); } template UHD_INLINE typename buffer_type::sptr get_new(const double timeout) { if (wait_for_completion(timeout)) { if (result.status != LIBUSB_TRANSFER_COMPLETED) throw uhd::io_error(str(boost::format("usb %s transfer status: %d") % _name % libusb_error_name(result.status))); result.completed = 0; return make(reinterpret_cast(this), _lut->buffer, (_is_recv) ? size_t(result.actual_length) : _frame_size); } return typename buffer_type::sptr(); } // This is public because it is accessed from the libusb_zero_copy_single constructor lut_result_t result; /*! * Wait for a managed buffer to become complete. * * \param timeout the wait timeout in seconds. A negative value will wait forever. * \return true for completion, false for timeout */ UHD_INLINE bool wait_for_completion(const double timeout) { boost::unique_lock lock(result.mut); if (!result.completed) { if (timeout < 0.0) { result.usb_transfer_complete.wait(lock); } else { const boost::system_time timeout_time = boost::get_system_time() + boost::posix_time::microseconds(long(timeout * 1000000)); result.usb_transfer_complete.timed_wait( lock, timeout_time, lut_result_completed(result)); } } return (result.completed > 0); } private: boost::function _release_cb; const bool _is_recv; const std::string _name; libusb_context* _ctx; libusb_transfer* _lut; const size_t _frame_size; }; libusb_zero_copy_mb::~libusb_zero_copy_mb(void) { /* NOP */ } /*********************************************************************** * USB zero_copy device class **********************************************************************/ class libusb_zero_copy_single { public: libusb_zero_copy_single(libusb::device_handle::sptr handle, const int interface, const unsigned char endpoint, const size_t num_frames, const size_t frame_size) : _handle(handle) , _num_frames(num_frames) , _frame_size(frame_size) , _buffer_pool(buffer_pool::make(_num_frames, _frame_size)) , _enqueued(_num_frames) , _released(_num_frames) , _status(STATUS_RUNNING) { const bool is_recv = (endpoint & 0x80) != 0; const std::string name = str(boost::format("%s%d") % ((is_recv) ? "rx" : "tx") % int(endpoint & 0x7f)); _handle->claim_interface(interface); // flush the buffers out of the recv endpoint // limit the flushing to at most one second if (is_recv) for (size_t i = 0; i < 100; i++) { unsigned char buff[512]; int transfered = 0; const int status = libusb_bulk_transfer(_handle->get(), // dev_handle endpoint, // endpoint static_cast(buff), int(sizeof(buff)), &transfered, // bytes xfered 10 // timeout ms ); if (status == LIBUSB_ERROR_TIMEOUT) break; } // allocate libusb transfer structs and managed buffers for (size_t i = 0; i < get_num_frames(); i++) { libusb_transfer* lut = libusb_alloc_transfer(0); UHD_ASSERT_THROW(lut != NULL); _mb_pool.push_back(boost::make_shared(lut, this->get_frame_size(), boost::bind(&libusb_zero_copy_single::enqueue_buffer, this, _1), is_recv, name)); libusb_fill_bulk_transfer(lut, // transfer _handle->get(), // dev_handle endpoint, // endpoint static_cast(_buffer_pool->at(i)), // buffer int(this->get_frame_size()), // length libusb_transfer_cb_fn(&libusb_async_cb), // callback static_cast(&_mb_pool.back()->result), // user_data 0 // timeout (ms) ); _all_luts.push_back(lut); } // initial release for all buffers for (size_t i = 0; i < get_num_frames(); i++) { libusb_zero_copy_mb& mb = *(_mb_pool[i]); if (is_recv) mb.release(); else { mb.result.completed = 1; _enqueued.push_back(&mb); } } } ~libusb_zero_copy_single(void) { // cancel all transfers for (libusb_transfer* lut : _all_luts) { libusb_cancel_transfer(lut); } // process all transfers until timeout occurs for (libusb_zero_copy_mb* mb : _enqueued) { mb->wait_for_completion(0.01); } // free all transfers for (libusb_transfer* lut : _all_luts) { libusb_free_transfer(lut); } } template UHD_INLINE typename buffer_type::sptr get_buff(double timeout) { typename buffer_type::sptr buff; if (_status == STATUS_ERROR) return buff; // Serialize access to buffers boost::mutex::scoped_lock get_buff_lock(_get_buff_mutex); boost::mutex::scoped_lock queue_lock(_queue_mutex); if (_enqueued.empty()) { _buff_ready_cond.timed_wait( queue_lock, boost::posix_time::microseconds(long(timeout * 1e6))); } if (_enqueued.empty()) return buff; libusb_zero_copy_mb* front = _enqueued.front(); queue_lock.unlock(); buff = front->get_new(timeout); queue_lock.lock(); if (buff) _enqueued.pop_front(); this->submit_what_we_can(); return buff; } UHD_INLINE size_t get_num_frames(void) const { return _num_frames; } UHD_INLINE size_t get_frame_size(void) const { return _frame_size; } private: libusb::device_handle::sptr _handle; const size_t _num_frames, _frame_size; //! Storage for transfer related objects buffer_pool::sptr _buffer_pool; std::vector> _mb_pool; boost::mutex _queue_mutex; boost::condition_variable _buff_ready_cond; boost::mutex _get_buff_mutex; //! why 2 queues? there is room in the future to have > N buffers but only N in flight boost::circular_buffer _enqueued, _released; enum { STATUS_RUNNING, STATUS_ERROR } _status; void enqueue_buffer(libusb_zero_copy_mb* mb) { boost::mutex::scoped_lock l(_queue_mutex); _released.push_back(mb); this->submit_what_we_can(); _buff_ready_cond.notify_one(); } void submit_what_we_can(void) { if (_status == STATUS_ERROR) return; while (not _released.empty() and not _enqueued.full()) { try { _released.front()->submit(); _enqueued.push_back(_released.front()); _released.pop_front(); } catch (uhd::usb_error& e) { _status = STATUS_ERROR; throw e; } } } //! a list of all transfer structs we allocated std::list _all_luts; }; /*********************************************************************** * USB zero_copy device class **********************************************************************/ struct libusb_zero_copy_impl : usb_zero_copy { libusb_zero_copy_impl(libusb::device_handle::sptr handle, const int recv_interface, const unsigned char recv_endpoint, const int send_interface, const unsigned char send_endpoint, const device_addr_t& hints) { _recv_impl.reset(new libusb_zero_copy_single(handle, recv_interface, (recv_endpoint & 0x7f) | 0x80, size_t(hints.cast("num_recv_frames", DEFAULT_NUM_XFERS)), size_t(hints.cast("recv_frame_size", DEFAULT_XFER_SIZE)))); _send_impl.reset(new libusb_zero_copy_single(handle, send_interface, (send_endpoint & 0x7f) | 0x00, size_t(hints.cast("num_send_frames", DEFAULT_NUM_XFERS)), size_t(hints.cast("send_frame_size", DEFAULT_XFER_SIZE)))); } virtual ~libusb_zero_copy_impl(void); managed_recv_buffer::sptr get_recv_buff(double timeout) { boost::mutex::scoped_lock l(_recv_mutex); return _recv_impl->get_buff(timeout); } managed_send_buffer::sptr get_send_buff(double timeout) { boost::mutex::scoped_lock l(_send_mutex); return _send_impl->get_buff(timeout); } size_t get_num_recv_frames(void) const { return _recv_impl->get_num_frames(); } size_t get_num_send_frames(void) const { return _send_impl->get_num_frames(); } size_t get_recv_frame_size(void) const { return _recv_impl->get_frame_size(); } size_t get_send_frame_size(void) const { return _send_impl->get_frame_size(); } boost::shared_ptr _recv_impl, _send_impl; boost::mutex _recv_mutex, _send_mutex; }; libusb_zero_copy_impl::~libusb_zero_copy_impl(void) { /* NOP */ } /*********************************************************************** * USB zero_copy destructor **********************************************************************/ usb_zero_copy::~usb_zero_copy(void) { /* NOP */ } /*********************************************************************** * USB zero_copy make functions **********************************************************************/ usb_zero_copy::sptr usb_zero_copy::make(usb_device_handle::sptr handle, const int recv_interface, const unsigned char recv_endpoint, const int send_interface, const unsigned char send_endpoint, const device_addr_t& hints) { libusb::device_handle::sptr dev_handle(libusb::device_handle::get_cached_handle( boost::static_pointer_cast(handle)->get_device())); return sptr(new libusb_zero_copy_impl( dev_handle, recv_interface, recv_endpoint, send_interface, send_endpoint, hints)); }