// // Copyright 2010 Ettus Research LLC // // This program 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. // // This program 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 this program. If not, see . // #include "libusb1_base.hpp" #include #include #include #include #include #include #include #include #include using namespace uhd::transport; static const double CLEANUP_TIMEOUT = 0.2; //seconds static const size_t DEFAULT_NUM_XFERS = 16; //num xfers static const size_t DEFAULT_XFER_SIZE = 32*512; //bytes /*********************************************************************** * Helper functions ***********************************************************************/ /* * Print the values of a libusb_transfer struct * http://libusb.sourceforge.net/api-1.0/structlibusb__transfer.html */ void pp_transfer(libusb_transfer *lut) { std::cout << "Libusb transfer" << std::endl; std::cout << " flags: 0x" << std::hex << (unsigned int) lut->flags << std::endl; std::cout << " endpoint: 0x" << std::hex << (unsigned int) lut->endpoint << std::endl; std::cout << " type: 0x" << std::hex << (unsigned int) lut->type << std::endl; std::cout << " timeout: " << std::dec << lut->timeout << std::endl; std::cout << " status: 0x" << std::hex << lut->status << std::endl; std::cout << " length: " << std::dec << lut->length << std::endl; std::cout << " actual_length: " << std::dec << lut->actual_length << std::endl; } /*********************************************************************** * USB asynchronous zero_copy endpoint * This endpoint implementation provides asynchronous I/O to libusb-1.0 * devices. Each endpoint is directional and two can be combined to * create a bidirectional interface. It is a zero copy implementation * with respect to libusb, however, each send and recv requires a copy * operation from kernel to userspace; this is due to the usbfs * interface provided by the kernel. **********************************************************************/ class usb_endpoint { public: typedef boost::shared_ptr sptr; usb_endpoint( libusb::device_handle::sptr handle, int endpoint, bool input, size_t transfer_size, size_t num_transfers ); ~usb_endpoint(void); // Exposed interface for submitting / retrieving transfer buffers //! Submit a new transfer that was presumably just filled or emptied. void submit(libusb_transfer *lut); /*! * Get an available transfer: * For inputs, this is a just filled transfer. * For outputs, this is a just emptied transfer. * \param timeout the timeout to wait for a lut * \return the transfer pointer or NULL if timeout */ libusb_transfer *get_lut_with_wait(double timeout); //Callback use only void callback_handle_transfer(libusb_transfer *lut); private: libusb::device_handle::sptr _handle; int _endpoint; bool _input; //! hold a bounded buffer of completed transfers typedef bounded_buffer lut_buff_type; lut_buff_type::sptr _completed_list; //! a list of all transfer structs we allocated std::vector _all_luts; //! a block of memory for the transfer buffers boost::shared_array _buffer; // Calls for processing asynchronous I/O libusb_transfer *allocate_transfer(void *mem, size_t len); void print_transfer_status(libusb_transfer *lut); }; /* * Callback function called when submitted transfers complete. * The endpoint upon which the transfer is part of is recovered * and the transfer moved from pending to completed state. * Callbacks occur during the reaping calls where libusb_handle_events() * is used. The callback only modifies the transfer state by moving * it from the pending to completed status list. * \param lut pointer to libusb_transfer */ static void callback(libusb_transfer *lut){ usb_endpoint *endpoint = (usb_endpoint *) lut->user_data; endpoint->callback_handle_transfer(lut); } /* * Accessor call to allow list access from callback space * \param pointer to libusb_transfer */ void usb_endpoint::callback_handle_transfer(libusb_transfer *lut){ boost::this_thread::disable_interruption di; //disable because the wait can throw _completed_list->push_with_wait(lut); } /* * Constructor * Allocate libusb transfers and mark as free. For IN endpoints, * submit the transfers so that they're ready to return when * data is available. */ usb_endpoint::usb_endpoint( libusb::device_handle::sptr handle, int endpoint, bool input, size_t transfer_size, size_t num_transfers ): _handle(handle), _endpoint(endpoint), _input(input) { _completed_list = lut_buff_type::make(num_transfers); _buffer = boost::shared_array(new char[num_transfers*transfer_size]); for (size_t i = 0; i < num_transfers; i++){ _all_luts.push_back(allocate_transfer(_buffer.get() + i*transfer_size, transfer_size)); //input luts are immediately submitted to be filled //output luts go into the completed list as free buffers if (_input) this->submit(_all_luts.back()); else _completed_list->push_with_wait(_all_luts.back()); } } /* * Destructor * Make sure all the memory is freed. Cancel any pending transfers. * When all completed transfers are moved to the free list, release * the transfers. Libusb will deallocate the data buffer held by * each transfer. */ usb_endpoint::~usb_endpoint(void){ //cancel all transfers BOOST_FOREACH(libusb_transfer *lut, _all_luts){ libusb_cancel_transfer(lut); } //collect canceled transfers (drain the queue) while (this->get_lut_with_wait(CLEANUP_TIMEOUT) != NULL){}; //free all transfers BOOST_FOREACH(libusb_transfer *lut, _all_luts){ libusb_free_transfer(lut); } } /* * Allocate a libusb transfer * The allocated transfer - and buffer it contains - is repeatedly * submitted, reaped, and reused and should not be freed until shutdown. * \param mem a pointer to the buffer memory * \param len size of the individual buffer * \return pointer to an allocated libusb_transfer */ libusb_transfer *usb_endpoint::allocate_transfer(void *mem, size_t len){ libusb_transfer *lut = libusb_alloc_transfer(0); UHD_ASSERT_THROW(lut != NULL); unsigned int endpoint = ((_endpoint & 0x7f) | (_input ? 0x80 : 0)); unsigned char *buff = reinterpret_cast(mem); libusb_transfer_cb_fn lut_callback = libusb_transfer_cb_fn(&callback); libusb_fill_bulk_transfer(lut, // transfer _handle->get(), // dev_handle endpoint, // endpoint buff, // buffer len, // length lut_callback, // callback this, // user_data 0); // timeout return lut; } /* * Asynchonous transfer submission * Submit a libusb transfer to libusb add pending status * \param lut pointer to libusb_transfer * \return true on success or false on error */ void usb_endpoint::submit(libusb_transfer *lut){ UHD_ASSERT_THROW(libusb_submit_transfer(lut) == 0); } /* * Print status errors of a completed transfer * \param lut pointer to an libusb_transfer */ void usb_endpoint::print_transfer_status(libusb_transfer *lut){ std::cout << "here " << lut->status << std::endl; switch (lut->status) { case LIBUSB_TRANSFER_COMPLETED: if (lut->actual_length < lut->length) { std::cerr << "USB: transfer completed with short write," << " length = " << lut->length << " actual = " << lut->actual_length << std::endl; } if ((lut->actual_length < 0) || (lut->length < 0)) { std::cerr << "USB: transfer completed with invalid response" << std::endl; } break; case LIBUSB_TRANSFER_CANCELLED: break; case LIBUSB_TRANSFER_NO_DEVICE: std::cerr << "USB: device was disconnected" << std::endl; break; case LIBUSB_TRANSFER_OVERFLOW: std::cerr << "USB: device sent more data than requested" << std::endl; break; case LIBUSB_TRANSFER_TIMED_OUT: std::cerr << "USB: transfer timed out" << std::endl; break; case LIBUSB_TRANSFER_STALL: std::cerr << "USB: halt condition detected (stalled)" << std::endl; break; case LIBUSB_TRANSFER_ERROR: std::cerr << "USB: transfer failed" << std::endl; break; default: std::cerr << "USB: received unknown transfer status" << std::endl; } } libusb_transfer *usb_endpoint::get_lut_with_wait(double timeout){ boost::this_thread::disable_interruption di; //disable because the wait can throw libusb_transfer *lut; if (_completed_list->pop_with_timed_wait(lut, timeout)) return lut; return NULL; } /*********************************************************************** * USB zero_copy device class **********************************************************************/ class libusb_zero_copy_impl : public usb_zero_copy, public boost::enable_shared_from_this { public: libusb_zero_copy_impl( libusb::device_handle::sptr handle, unsigned int recv_endpoint, unsigned int send_endpoint, size_t recv_xfer_size, size_t recv_num_xfers, size_t send_xfer_size, size_t send_num_xfers ); managed_recv_buffer::sptr get_recv_buff(double); managed_send_buffer::sptr get_send_buff(double); size_t get_num_recv_frames(void) const { return _recv_num_frames; } size_t get_num_send_frames(void) const { return _send_num_frames; } private: void release(libusb_transfer *lut){ _recv_ep->submit(lut); } void commit(libusb_transfer *lut, size_t num_bytes){ lut->length = num_bytes; try{ _send_ep->submit(lut); } catch(const std::exception &e){ std::cerr << "Error in commit: " << e.what() << std::endl; } } libusb::device_handle::sptr _handle; size_t _recv_xfer_size, _send_xfer_size; size_t _recv_num_frames, _send_num_frames; usb_endpoint::sptr _recv_ep, _send_ep; }; /* * Constructor * Initializes libusb, opens devices, and sets up interfaces for I/O. * Finally, creates endpoints for asynchronous I/O. */ libusb_zero_copy_impl::libusb_zero_copy_impl( libusb::device_handle::sptr handle, unsigned int recv_endpoint, unsigned int send_endpoint, size_t recv_xfer_size, size_t recv_num_xfers, size_t send_xfer_size, size_t send_num_xfers ){ _handle = handle; //if the sizes are left at 0 (automatic) -> use the defaults if (recv_xfer_size == 0) recv_xfer_size = DEFAULT_XFER_SIZE; if (recv_num_xfers == 0) recv_num_xfers = DEFAULT_NUM_XFERS; if (send_xfer_size == 0) send_xfer_size = DEFAULT_XFER_SIZE; if (send_num_xfers == 0) send_num_xfers = DEFAULT_NUM_XFERS; //store the num xfers for the num frames count _recv_xfer_size = recv_xfer_size; _recv_num_frames = recv_num_xfers; _send_xfer_size = send_xfer_size; _send_num_frames = send_num_xfers; _handle->claim_interface(2 /*in interface*/); _handle->claim_interface(1 /*out interface*/); _recv_ep = usb_endpoint::sptr(new usb_endpoint( _handle, // libusb device_handle recv_endpoint, // USB endpoint number true, // IN endpoint recv_xfer_size, // buffer size per transfer recv_num_xfers // number of libusb transfers )); _send_ep = usb_endpoint::sptr(new usb_endpoint( _handle, // libusb device_handle send_endpoint, // USB endpoint number false, // OUT endpoint send_xfer_size, // buffer size per transfer send_num_xfers // number of libusb transfers )); } /* * Construct a managed receive buffer from a completed libusb transfer * (happy with buffer full of data) obtained from the receive endpoint. * Return empty pointer if no transfer is available (timeout or error). * \return pointer to a managed receive buffer */ managed_recv_buffer::sptr libusb_zero_copy_impl::get_recv_buff(double timeout){ libusb_transfer *lut = _recv_ep->get_lut_with_wait(timeout); if (lut == NULL) { return managed_recv_buffer::sptr(); } else { return managed_recv_buffer::make_safe( boost::asio::const_buffer(lut->buffer, lut->actual_length), boost::bind(&libusb_zero_copy_impl::release, shared_from_this(), lut) ); } } /* * Construct a managed send buffer from a free libusb transfer (with * empty buffer). Return empty pointer of no transfer is available * (timeout or error). * \return pointer to a managed send buffer */ managed_send_buffer::sptr libusb_zero_copy_impl::get_send_buff(double timeout){ libusb_transfer *lut = _send_ep->get_lut_with_wait(timeout); if (lut == NULL) { return managed_send_buffer::sptr(); } else { return managed_send_buffer::make_safe( boost::asio::mutable_buffer(lut->buffer, _send_xfer_size), boost::bind(&libusb_zero_copy_impl::commit, shared_from_this(), lut, _1) ); } } /*********************************************************************** * USB zero_copy make functions **********************************************************************/ usb_zero_copy::sptr usb_zero_copy::make( usb_device_handle::sptr handle, unsigned int recv_endpoint, unsigned int send_endpoint, size_t recv_xfer_size, size_t recv_num_xfers, size_t send_xfer_size, size_t send_num_xfers ){ 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_endpoint, send_endpoint, recv_xfer_size, recv_num_xfers, send_xfer_size, send_num_xfers )); }