/* -*- c++ -*- */ /* * Copyright 2003,2006 Free Software Foundation, Inc. * * This file is part of GNU Radio * * GNU Radio 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, or (at your option) * any later version. * * GNU Radio 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 GNU Radio; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include static const int USB_TIMEOUT = 1000; // in milliseconds // the following comment and function is from fusb_linux.cc #if 0 // Totally evil and fragile extraction of file descriptor from // guts of libusb. They don't install usbi.h, which is what we'd need // to do this nicely. // // FIXME if everything breaks someday in the future, look here... static int fd_from_usb_dev_handle (usb_dev_handle *udh) { return *((int *) udh); } #endif // the control endpoint doesn't actually do us any good so here is a // new "fragile extraction" static int ep_fd_from_usb_dev_handle (usb_dev_handle *udh, int endpoint) { struct usb_dev_handle_kludge2 { // see also usrp_prims.cc int fd; struct usb_bus *bus; struct usb_device *device; int config; int interface; int altsetting; void *impl_info; }; struct bsd_usb_dev_handle_info_kludge { int ep_fd[USB_MAX_ENDPOINTS]; }; struct bsd_usb_dev_handle_info_kludge *info = (struct bsd_usb_dev_handle_info_kludge *) ((struct usb_dev_handle_kludge2 *)udh)->impl_info; return info->ep_fd[UE_GET_ADDR(endpoint)]; } fusb_devhandle_ra_wb::fusb_devhandle_ra_wb (usb_dev_handle *udh) : fusb_devhandle (udh) { // that's it } fusb_devhandle_ra_wb::~fusb_devhandle_ra_wb () { // nop } fusb_ephandle * fusb_devhandle_ra_wb::make_ephandle (int endpoint, bool input_p, int block_size, int nblocks) { return new fusb_ephandle_ra_wb (this, endpoint, input_p, block_size, nblocks); } // ---------------------------------------------------------------- fusb_ephandle_ra_wb::fusb_ephandle_ra_wb (fusb_devhandle_ra_wb *dh, int endpoint, bool input_p, int block_size, int nblocks) : fusb_ephandle (endpoint, input_p, block_size, nblocks), d_devhandle (dh), d_ra_wb_on (false) { // that's it } fusb_ephandle_ra_wb::~fusb_ephandle_ra_wb () { // nop } bool fusb_ephandle_ra_wb::start () { d_started = true; char buf = '\0'; int fd; // this is to cause libusb to open the endpoint if (!d_input_p) { write(&buf, 0); fd = ep_fd_from_usb_dev_handle (d_devhandle->get_usb_dev_handle(), d_endpoint); } else { read(&buf, 0); fd = ep_fd_from_usb_dev_handle (d_devhandle->get_usb_dev_handle(), d_endpoint|USB_ENDPOINT_IN); } // enable read ahead/write behind int ret; struct usb_bulk_ra_wb_opt opts; int enable = 1; opts.ra_wb_buffer_size = d_block_size*d_nblocks; opts.ra_wb_request_size = d_block_size; // fprintf (stderr, "setting buffer size to %d, request size to %d\n", // opts.ra_wb_buffer_size, opts.ra_wb_request_size); if (!d_input_p) { ret = ioctl (fd, USB_SET_BULK_WB_OPT, &opts); if (ret < 0) fprintf (stderr, "USB_SET_BULK_WB_OPT: %s\n", strerror(errno)); else { ret = ioctl (fd, USB_SET_BULK_WB, &enable); if (ret < 0) fprintf (stderr, "USB_SET_BULK_WB: %s\n", strerror(errno)); else d_ra_wb_on = true; } } else { ret = ioctl (fd, USB_SET_BULK_RA_OPT, &opts); if (ret < 0) fprintf (stderr, "USB_SET_BULK_RA_OPT: %s\n", strerror(errno)); else { ret = ioctl (fd, USB_SET_BULK_RA, &enable); if (ret < 0) fprintf (stderr, "USB_SET_BULK_RA: %s\n", strerror(errno)); else d_ra_wb_on = true; } } return true; } bool fusb_ephandle_ra_wb::stop () { int fd; int ret; int enable = 0; if (d_ra_wb_on) { if (!d_input_p) { fd = ep_fd_from_usb_dev_handle (d_devhandle->get_usb_dev_handle(), d_endpoint); ret = ioctl (fd, USB_SET_BULK_WB, &enable); if (ret < 0) fprintf (stderr, "USB_SET_BULK_WB: %s\n", strerror(errno)); else d_ra_wb_on = false; } else { fd = ep_fd_from_usb_dev_handle (d_devhandle->get_usb_dev_handle(), d_endpoint|USB_ENDPOINT_IN); ret = ioctl (fd, USB_SET_BULK_RA, &enable); if (ret < 0) fprintf (stderr, "USB_SET_BULK_RA: %s\n", strerror(errno)); else d_ra_wb_on = false; } } d_started = false; return true; } int fusb_ephandle_ra_wb::write (const void *buffer, int nbytes) { if (!d_started) return -1; if (d_input_p) return -1; return usb_bulk_write (d_devhandle->get_usb_dev_handle (), d_endpoint, (char *) buffer, nbytes, USB_TIMEOUT); } int fusb_ephandle_ra_wb::read (void *buffer, int nbytes) { if (!d_started) return -1; if (!d_input_p) return -1; return usb_bulk_read (d_devhandle->get_usb_dev_handle (), d_endpoint|USB_ENDPOINT_IN, (char *) buffer, nbytes, USB_TIMEOUT); } void fusb_ephandle_ra_wb::wait_for_completion () { // as the driver is implemented this only makes sense for write if (d_ra_wb_on && !d_input_p) { int fd = ep_fd_from_usb_dev_handle (d_devhandle->get_usb_dev_handle(), d_endpoint); int kq = kqueue(); if (kq < 0) return; struct kevent evt; int nevents; EV_SET (&evt, fd, EVFILT_WRITE, EV_ADD | EV_ENABLE, 0, 0, 0/*NULL*/); nevents = kevent (kq, &evt, 1, &evt, 1, NULL); if (nevents < 1) { close(kq); return; } while (!(evt.flags & EV_ERROR) && evt.data < (d_block_size*d_nblocks)) { // it's a busy loop, but that's all I can do at the moment nevents = kevent (kq, NULL, 0, &evt, 1, NULL); // let's see if this improves the test_usrp_standard_tx throughput & // "CPU usage" by looping less frequently struct timeval timeout; timeout.tv_sec = 0; timeout.tv_usec = 1000; // 1 ms select (0, NULL, NULL, NULL, &timeout); } close (kq); } }