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/*{{{ Banner */ //================================================================= // // host.c // // USB testing - host-side // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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 2 or (at your option) any later version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): bartv // Date: 2001-07-04 //####DESCRIPTIONEND#### //========================================================================== // The overall architecture is as follows. // // The target hardware runs a special application which provides a // particular type of USB application, "Red Hat eCos USB testing". // This will not be recognised by any device driver, so the Linux // kernel will pretty much ignore the device (other host OS's are not // considered at this time). // // This program is the only supported way to interact with that service. // It acts as an extended Tcl interpreter, providing a number of new // Tcl commands for interacting with the target. All test cases can // then be written as Tcl scripts which invoke a series of these commands. // These Tcl commands operate essentially though the LINUX usb devfs // service which allows ordinary application code to perform USB operations // via ioctl()'s. /*}}}*/ /*{{{ #include's */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <ctype.h> #include <limits.h> #include <errno.h> #include <sys/types.h> #include <sys/stat.h> #include <unistd.h> #include <fcntl.h> #include <sys/ioctl.h> #include <time.h> #include <pthread.h> #include <semaphore.h> // Avoid compatibility problems with Tcl 8.4 vs. earlier #define USE_NON_CONST #include <tcl.h> #include <linux/usb.h> #include <linux/usbdevice_fs.h> #include "../tests/protocol.h" /*}}}*/ /*{{{ Statics */ // ---------------------------------------------------------------------------- // Statics. // Has the current batch of tests actually terminated? This flag is // checked by the various test handlers at appropriate intervals, and // helps to handle the case where one of the side has terminated early // because an error has been detected. static int current_tests_terminated = 0; // The next local thread to be allocated for testing. This variable can also // be used to find out how many threads are involved in the current test. // This counter should always be reset to 0 at the end of every test run. static int local_thread_count = 0; // A similar counter for remote threads. static int remote_thread_count = 0; // A file handle for manipulating the USB device at a low level static int usb_master_fd = -1; /*}}}*/ /*{{{ Logging */ // ---------------------------------------------------------------------------- // The user can provide one or more -V/--verbose arguments to increase // the amount of output generated. static int verbose = 0; #define VERBOSE(_level_, _format_, _args_...) \ do { \ if (verbose >= _level_) { \ printf(_format_, ## _args_); \ } \ } while (0); /*}}}*/ /*{{{ Low-level USB access */ // ---------------------------------------------------------------------------- // Low-level access to a USB device. // // The various ioctl() calls require a file handle which corresponds to one // of the /proc/bus/usb/<abc>/<def> entries. <abc> is a bus number, // typically 001 or 001, and <def> is a device number on that bus, // e.g. 003. Figuring out <abc> and <def> requires scanning // /proc/bus/usb/devices, which is a somewhat complicated text file. // // This is all somewhat vulnerable to incompatible changes in the // Linux kernel, specifically the implementation of the /proc/bus/usb. // An alternative approach would be to write a new Linux device driver // and interact with that, but that approach is vulnerable to any // internal kernel API changes affecting USB device drivers. // How to access USB devices from userland #define USB_ROOT "/proc/bus/usb/" // How to identify the eCos test case #define PRODUCT_STRING "Red Hat eCos USB test" // Scan through /proc/bus/usb/devices looking for an entry that // matches what we are after, specifically a line // S: Product=Red Hat eCos USB testcase // The required information can then be obtained from the previous // line: // T: Bus=<abc> ... Dev#= <def> ... // // Of course the T: line is going to come first, so it is necessary // to keep track of the current bus and device numbers. // // Note: this code is duplicated in usbchmod.c. Any changes here // should be propagated. For now the routine is too small to warrant // a separate source file. static int usb_scan_devices(int* bus, int* dev) { FILE* devs_file; int current_bus = -1; int current_dev = -1; int ch; *bus = -1; *dev = -1; VERBOSE(1, "Searching " USB_ROOT "devices for the eCos USB test code\n"); devs_file = fopen(USB_ROOT "devices", "r"); if (NULL == devs_file) { fprintf(stderr, "usbhost: error, unable to access " USB_ROOT "devices\n"); return 0; } ch = getc(devs_file); while (EOF != ch) { if ('T' == ch) { if (2 !=fscanf(devs_file, ": Bus=%d %*[^D\n]Dev#=%d", ¤t_bus, ¤t_dev)) { current_bus = -1; current_dev = -1; } } else if ('S' == ch) { int start = 0, end = 0; if (EOF != fscanf(devs_file, ": Product=%n" PRODUCT_STRING "%n", &start, &end)) { if (start < end) { *bus = current_bus; *dev = current_dev; break; } } } // Move to the end of the current line. do { ch = getc(devs_file); } while ((EOF != ch) && ('\n' != ch)); if (EOF != ch) { ch = getc(devs_file); } } fclose(devs_file); if ((-1 != *bus) && (-1 != *dev)) { VERBOSE(1, "Found eCos USB test code on bus %d, device %d\n", *bus, *dev); return 1; } fprintf(stderr, "usbhost: error, failed to find a USB device \"" PRODUCT_STRING "\"\n"); return 0; } // Actually open the USB device, allowing subsequent ioctl() operations. // // Typically /proc/bus/usb/... will not allow ordinary applications // to perform ioctl()'s. Instead root privileges are required. To work // around this there is a little utility usbchmod, installed suid, // which can be used to get access to the raw device. static int usb_open_device(void) { char devname[_POSIX_PATH_MAX]; static int bus = -1; static int dev = -1; int result; if ((-1 == bus) || (-1 == dev)) { if (!usb_scan_devices(&bus, &dev)) { return -1; } } if (_POSIX_PATH_MAX == snprintf(devname, _POSIX_PATH_MAX, USB_ROOT "%03d/%03d", bus, dev)) { fprintf(stderr, "usbhost: internal error, buffer overflow\n"); exit(EXIT_FAILURE); } VERBOSE(1, "Attempting to access USB target via %s\n", devname); result = open(devname, O_RDWR); if (-1 == result) { // Check for access right problems. If so, try to work around them // by invoking usbchmod. Always look for this in the install tree, // since it is only that version which is likely to have been // chown'ed and chmod'ed to be suid root. if (EACCES == errno) { char command_name[_POSIX_PATH_MAX]; VERBOSE(1, "Insufficient access to USB target, running usbchmod\n"); if (_POSIX_PATH_MAX == snprintf(command_name, _POSIX_PATH_MAX, "%s/usbchmod %d %d", USBAUXDIR, bus, dev)) { fprintf(stderr, "usbhost: internal error, buffer overflow\n"); exit(EXIT_FAILURE); } (void) system(command_name); result = open(devname, O_RDWR); } } if (-1 == result) { fprintf(stderr, "usbhost: error, failed to open \"%s\", errno %d\n", devname, errno); } VERBOSE(1, "USB device now accessible via file descriptor %d\n", result); // Also perform a set-configuration call, to avoid warnings from // the Linux kernel. Target-side testing is always configuration 1 // because only a single configuration is supported. (void) ioctl(result, USBDEVFS_SETCONFIGURATION, 1); return result; } // Exchange a control message with the host. The return value should // be 0, or a small positive number indicating the actual number of // bytes received which may be less than requested. // // There appear to be problems with some hosts, manifesting itself as // an inability to send control messages that involve additional data // from host->target. These problems are not yet well-understood. For // now the workaround is to send multiple packets, each with up to // four bytes encoded in the index and length fields. static int usb_control_message(int fd, int request_type, int request, int value, int index, int length, void* data) { struct usbdevfs_ctrltransfer transfer; int result = 0; VERBOSE(3, "usb_control_message, request %02x, len %d\n", request, length); if (length > USBTEST_MAX_CONTROL_DATA) { fprintf(stderr, "usbhost: internal error, control message involves too much data.\n"); exit(EXIT_FAILURE); } #if 1 // Workaround - send additional data in the index and length fields. if ((length > 0) && (USB_DIR_OUT == (USB_ENDPOINT_DIR_MASK & request_type))) { int i; unsigned char* buf = (unsigned char*) data; for (i = 0; i < length; i+= 4) { int this_len = length - 1; int ioctl_result; transfer.requesttype = USB_TYPE_CLASS | USB_RECIP_DEVICE; if (this_len > 4) { this_len = 4; } switch (this_len) { case 1: transfer.request = USBTEST_CONTROL_DATA1; break; case 2: transfer.request = USBTEST_CONTROL_DATA2; break; case 3: transfer.request = USBTEST_CONTROL_DATA3; break; case 4: transfer.request = USBTEST_CONTROL_DATA4; break; default: fprintf(stderr, "usbhost: internal error, confusion about transfer length.\n"); exit(EXIT_FAILURE); } transfer.value = (buf[i] << 8) | buf[i+1]; // Possible read beyond end of buffer, transfer.index = (buf[i+2] << 8) | buf[i+3]; // but not worth worrying about. transfer.length = 0; transfer.timeout = 10 * 1000; // ten seconds, the target should always accept data faster than this. transfer.data = NULL; // This is too strict, deciding what to do about errors should be // handled by higher-level code. However it will do for now. ioctl_result = ioctl(fd, USBDEVFS_CONTROL, &transfer); if (0 != ioctl_result) { fprintf(stderr, "usbhost: error, failed to send control message (data) to target.\n"); exit(EXIT_FAILURE); } } // There is no more data to be transferred. length = 0; } #endif transfer.requesttype = request_type; transfer.request = request; transfer.value = value; transfer.index = index; transfer.length = length; transfer.timeout = 10000; transfer.data = data; result = ioctl(fd, USBDEVFS_CONTROL, &transfer); return result; } // A variant of the above which can be called when the target should always respond // correctly. This can be used for class control messages. static int usb_reliable_control_message(int fd, int request_type, int request, int value, int index, int length, void* data) { int result = usb_control_message(fd, request_type, request, value, index, length, data); if (-1 == result) { fprintf(stderr, "usbhost: error, failed to send control message %02x to target.\n", request); fprintf(stderr, " : errno %d (%s)\n", errno, strerror(errno)); exit(EXIT_FAILURE); } return result; } // Either send or receive a single bulk message. The top bit of the endpoint // number indicates the direction. static int usb_bulk_message(int fd, int endpoint, unsigned char* buffer, int length) { struct usbdevfs_bulktransfer transfer; int result; transfer.ep = endpoint; transfer.len = length; transfer.timeout = 60 * 60 * 1000; // An hour. These operations should not time out because that // leaves the system in a confused state. Instead there is // higher-level recovery code that should ensure the operation // really does complete, and the return value here is used // by the calling code to determine whether the operation // was successful or whether there was an error and the recovery // code was invoked. transfer.data = buffer; errno = 0; result = ioctl(fd, USBDEVFS_BULK, &transfer); return result; } // Synchronise with the target. This can be used after the host has sent a request that // may take a bit of time, e.g. it may involve waking up a thread. The host will send // synch requests at regular intervals, until the target is ready. // // The limit argument can be used to avoid locking up. -1 means loop forever, otherwise // it means that many iterations of 100ms apiece. static int usb_sync(int fd, int limit) { unsigned char buf[1]; struct timespec delay; int loops = 0; int result = 0; VERBOSE(2, "Synchronizing with target\n"); while (1) { buf[0] = 0; usb_reliable_control_message(fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_SYNCH, 0, 0, 1, buf); if (buf[0]) { result = 1; break; } else { if ((-1 != limit) && (++loops > limit)) { break; } else { VERBOSE(3, "Not yet synchronized, sleeping\n"); delay.tv_sec = 0; delay.tv_nsec = 100000000; // 100 ms nanosleep(&delay, NULL); } } } VERBOSE(2, "%s\n", result ? "Synchronized" : "Not synchronized"); return result; } // Abort the target. Things seem to be completely messed up and there is no easy // way to restore sanity to both target and host. static void usb_abort(int fd) { VERBOSE(2, "Target-side abort operation invoked\n"); usb_reliable_control_message(fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_ABORT, 0, 0, 0, (void*)0); } /*}}}*/ /*{{{ Initialise endpoints */ // ---------------------------------------------------------------------------- // On power-up some endpoints may not be in a sensible state. For example, // with the SA11x0 the hardware may start accepting bulk OUT transfers // before the target-side software has started a receive operation, // so if the host sends a bulk packet before the target is ready then // things get messy. This is especially troublesome if the target-side // attempts any diagnostic output because of verbosity. // // This code loops through the various endpoints and makes sure that // they are all in a reasonable state, before any real tests get run // That means known hardware flaws do not show up as test failures, // but of course they are still documented and application software // will have to do the right thing. static void usb_initialise_control_endpoint(int min_size, int max_size) { // At this time there are no known problems on any hardware // that would need to be addressed } static void usb_initialise_isochronous_in_endpoint(int number, int min_size, int max_size) { // At this time there are no known problems on any hardware // that would need to be addressed } static void usb_initialise_isochronous_out_endpoint(int number, int min_size, int max_size) { // At this time there are no known problems on any hardware // that would need to be addressed } static void usb_initialise_bulk_in_endpoint(int number, int min_size, int max_size, int padding) { // At this time there are no known problems on any hardware // that would need to be addressed } static void usb_initialise_bulk_out_endpoint(int number, int min_size, int max_size) { char buf[1]; // On the SA1110 the hardware comes up with a bogus default value, // causing the hardware to accept packets before the software has // set up DMA or in any way prepared for incoming data. This is // a problem. It is worked around by making the target receive // a single packet, sending that packet, and then performing a // sync. VERBOSE(2, "Performing bulk OUT initialization on endpoint %d\n", number); usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_INIT_BULK_OUT, number, 0, 0, (void*) 0); usb_bulk_message(usb_master_fd, number, buf, 1); usb_sync(usb_master_fd, 10); } static void usb_initialise_interrupt_in_endpoint(int number, int min_size, int max_size) { // At this time there are no known problems on any hardware // that would need to be addressed } static void usb_initialise_interrupt_out_endpoint(int number, int min_size, int max_size) { // At this time there are no known problems on any hardware // that would need to be addressed } /*}}}*/ /*{{{ Host/target common code */ #define HOST #include "../tests/common.c" /*}}}*/ /*{{{ The test cases themselves */ /*{{{ UsbTest definition */ // ---------------------------------------------------------------------------- // All the data associated with a single test. typedef struct UsbTest { // A "unique" identifier to make verbose output easier to understand. int id; // Which file descriptor should be used to access USB. int fd; // Which test should be run. usbtest which_test; // Test-specific details. union { UsbTest_Bulk bulk; UsbTest_ControlIn control_in; } test_params; // How to recover from any problems. Specifically, what kind of message // could the target send or receive that would unlock the thread on this // side. UsbTest_Recovery recovery; int result_pass; char result_message[USBTEST_MAX_MESSAGE]; unsigned char buffer[USBTEST_MAX_BULK_DATA + USBTEST_MAX_BULK_DATA_EXTRA]; } UsbTest; // Reset the information in a given test. This is used by the pool allocation // code. The data union is left alone, filling in the appropriate union // member is left to other code. static void reset_usbtest(UsbTest* test) { static int next_id = 1; test->id = next_id++; test->which_test = usbtest_invalid; usbtest_recovery_reset(&(test->recovery)); test->result_pass = 0; test->result_message[0] = '\0'; } /*}}}*/ /*{{{ bulk OUT */ static void run_test_bulk_out(UsbTest* test) { unsigned char* buf = test->buffer; int i; VERBOSE(1, "Starting test %d, bulk OUT on endpoint %d\n", test->id, test->test_params.bulk.endpoint); for (i = 0; i < test->test_params.bulk.number_packets; i++) { int transferred; int packet_size = test->test_params.bulk.tx_size; test->recovery.endpoint = test->test_params.bulk.endpoint; test->recovery.protocol = USB_ENDPOINT_XFER_BULK; test->recovery.size = packet_size; usbtest_fill_buffer(&(test->test_params.bulk.data), buf, packet_size); if (verbose < 3) { VERBOSE(2, "Bulk OUT test %d: iteration %d, packet size %d\n", test->id, i, packet_size); } else { // Output the first 32 bytes of data as well. char msg[256]; int index; int j; index = snprintf(msg, 255, "Bulk OUT test %d: iteration %d, packet size %d\n Data %s:", test->id, i, packet_size, (usbtestdata_none == test->test_params.bulk.data.format) ? "(uninitialized)" : ""); for (j = 0; ((j + 3) < packet_size) && (j < 32); j+= 4) { index += snprintf(msg+index, 255-index, " %02x%02x%02x%02x", buf[j], buf[j+1], buf[j+2], buf[j+3]); } if (j < 32) { index += snprintf(msg+index, 255-index, " "); for ( ; j < packet_size; j++) { index += snprintf(msg+index, 255-index, "%02x", buf[j]); } } VERBOSE(3, "%s\n", msg); } transferred = usb_bulk_message(test->fd, test->test_params.bulk.endpoint, buf, packet_size); // Has this test run been aborted for some reason? if (current_tests_terminated) { VERBOSE(2, "Bulk OUT test %d: iteration %d, termination detected\n", test->id, i); test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk OUT transfer on endpoint %d: aborted after %d iterations\n", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK, i); return; } // If an error occurred, abort this run. if (-1 == transferred) { char errno_buf[USBTEST_MAX_MESSAGE]; test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk OUT transfer on endpoint %d : host ioctl() system call failed\n errno %d (%s)", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK, errno, strerror_r(errno, errno_buf, USBTEST_MAX_MESSAGE)); VERBOSE(2, "Bulk OUT test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } if (0 != test->test_params.bulk.tx_delay) { struct timespec delay; VERBOSE(2, "Bulk OUT test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, \ i, test->test_params.bulk.tx_delay); // Note that nanosleep() can return early due to incoming signals, // with the unelapsed time returned in a second argument. This // allows for a retry loop. In practice this does not seem // worthwhile, the delays are approximate anyway. delay.tv_sec = test->test_params.bulk.tx_delay / 1000000000; delay.tv_nsec = test->test_params.bulk.tx_delay % 1000000000; nanosleep(&delay, NULL); } // Now move on to the next transfer USBTEST_BULK_NEXT(test->test_params.bulk); } // If all the packets have been transferred this test has passed. if (i >= test->test_params.bulk.number_packets) { test->result_pass = 1; } VERBOSE(1, "Test %d bulk OUT on endpoint %d, result %d\n", test->id, test->test_params.bulk.endpoint, test->result_pass); } /*}}}*/ /*{{{ bulk IN */ static void run_test_bulk_in(UsbTest* test) { unsigned char* buf = test->buffer; int i; VERBOSE(1, "Starting test %d bulk IN on endpoint %d\n", test->id, test->test_params.bulk.endpoint); for (i = 0; i < test->test_params.bulk.number_packets; i++) { int transferred; int tx_size = test->test_params.bulk.tx_size; int rx_size = test->test_params.bulk.rx_size; int size_plus_padding; VERBOSE(2, "Bulk IN test %d: iteration %d, rx size %d, tx size %d\n", test->id, i, rx_size, tx_size); if (rx_size < tx_size) { rx_size = tx_size; VERBOSE(2, "Bulk IN test %d: iteration %d, packet size reset to %d to match tx size\n", test->id, i, rx_size); } test->recovery.endpoint = test->test_params.bulk.endpoint; test->recovery.protocol = USB_ENDPOINT_XFER_BULK; test->recovery.size = rx_size; // Make sure there is no old data lying around if (usbtestdata_none != test->test_params.bulk.data.format) { memset(buf, 0, rx_size); } // And do the actual transfer. size_plus_padding = rx_size; if (size_plus_padding < (tx_size + test->test_params.bulk.rx_padding)) { size_plus_padding += test->test_params.bulk.rx_padding; } do { transferred = usb_bulk_message(test->fd, test->test_params.bulk.endpoint, buf, size_plus_padding); } while (0 == transferred); // Has this test run been aborted for some reason? if (current_tests_terminated) { VERBOSE(2, "Bulk IN test %d: iteration %d, termination detected\n", test->id, i); snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk IN transfer on endpoint %d: aborted after %d iterations\n", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK, i); return; } // If an error occurred, abort this run. if (-1 == transferred) { char errno_buf[USBTEST_MAX_MESSAGE]; test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk IN transfer on endpoint %d : host ioctl() system call failed\n errno %d (%s)", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK, errno, strerror_r(errno, errno_buf, USBTEST_MAX_MESSAGE)); VERBOSE(2, "Bulk IN test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } // Did the target send the expected amount of data? if (transferred < tx_size) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk IN transfer on endpoint %d : the target only sent %d bytes when %d were expected", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK, transferred, tx_size); VERBOSE(2, "Bulk IN test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } if (verbose >= 3) { // Output the first 32 bytes of data char msg[256]; int index; int j; index = snprintf(msg, 255, "Bulk IN test %d: iteration %d, transferred %d\n Data %s:", test->id, i, transferred, (usbtestdata_none == test->test_params.bulk.data.format) ? "(uninitialized)" : ""); for (j = 0; ((j + 3) < transferred) && (j < 32); j+= 4) { index += snprintf(msg+index, 255-index, " %02x%02x%02x%02x", buf[j], buf[j+1], buf[j+2], buf[j+3]); } if (j < 32) { index += snprintf(msg+index, 255-index, " "); for ( ; j < transferred; j++) { index += snprintf(msg+index, 255-index, "%02x", buf[j]); } } VERBOSE(3, "%s\n", msg); } // Is the data correct? if (!usbtest_check_buffer(&(test->test_params.bulk.data), buf, tx_size)) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, bulk IN transfer on endpoint %d : mismatch between received and expected data", test->test_params.bulk.endpoint & USB_ENDPOINT_NUMBER_MASK); VERBOSE(2, "Bulk IN test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } if (0 != test->test_params.bulk.rx_delay) { struct timespec delay; VERBOSE(2, "Bulk IN test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, \ i, test->test_params.bulk.tx_delay); // Note that nanosleep() can return early due to incoming signals, // with the unelapsed time returned in a second argument. This // allows for a retry loop. In practice this does not seem // worthwhile, the delays are approximate anyway. delay.tv_sec = test->test_params.bulk.rx_delay / 1000000000; delay.tv_nsec = test->test_params.bulk.rx_delay % 1000000000; nanosleep(&delay, NULL); } USBTEST_BULK_NEXT(test->test_params.bulk); } // If all the packets have been transferred this test has passed. if (i >= test->test_params.bulk.number_packets) { test->result_pass = 1; } VERBOSE(1, "Test %d bulk IN on endpoint %d, result %d\n", test->id, test->test_params.bulk.endpoint, test->result_pass); } /*}}}*/ /*{{{ control IN */ // Receive appropriate packets via the control endpoint. This is somewhat // different from bulk transfers. It is implemented using reserved control // messages. // // Note: it is not entirely clear that this test is safe. There will be // concurrent control traffic to detect test termination and the like, // and these control messages may interfere with each other. It is not // entirely clear how the Linux kernel handles concurrent control // operations. static void run_test_control_in(UsbTest* test) { unsigned char* buf = test->buffer; int packet_size; int i; packet_size = test->test_params.control_in.packet_size_initial; for (i = 0; i < test->test_params.control_in.number_packets; i++) { int transferred; test->recovery.endpoint = 0; test->recovery.protocol = USB_ENDPOINT_XFER_CONTROL; test->recovery.size = packet_size; // Make sure there is no old data lying around if (usbtestdata_none != test->test_params.control_in.data.format) { memset(buf, 0, packet_size); } // And do the actual transfer. transferred = usb_control_message(test->fd, USB_TYPE_RESERVED | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_RESERVED_CONTROL_IN, 0, 0, packet_size, buf); // Has this test run been aborted for some reason? if (current_tests_terminated) { return; } // If an error occurred, abort this run. if (-1 == transferred) { char errno_buf[USBTEST_MAX_MESSAGE]; test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, control IN transfer: host ioctl() system call failed\n errno %d (%s)", errno, strerror_r(errno, errno_buf, USBTEST_MAX_MESSAGE)); break; } // Did the target send the expected amount of data? if (transferred < packet_size) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, control IN transfer: the target only sent %d bytes when %d were expected", transferred, packet_size); break; } // Is the data correct? if (!usbtest_check_buffer(&(test->test_params.control_in.data), buf, packet_size)) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Host, control IN transfer: mismatch between received and expected data"); break; } USBTEST_CONTROL_NEXT_PACKET_SIZE(packet_size, test->test_params.control_in); } // If all the packets have been transferred this test has passed. if (i >= test->test_params.control_in.number_packets) { test->result_pass = 1; } } /*}}}*/ // FIXME: add more tests /*{{{ run_test() */ // This utility is invoked from a thread in the thread pool whenever there is // work to be done. It simply dispatches to the appropriate handler. static void run_test(UsbTest* test) { switch (test->which_test) { case usbtest_bulk_out: run_test_bulk_out(test); break; case usbtest_bulk_in: run_test_bulk_in(test); break; case usbtest_control_in: run_test_control_in(test); break; default: fprintf(stderr, "usbhost: internal error, attempt to execute an unknown test.\n"); exit(EXIT_FAILURE); } } /*}}}*/ /*}}}*/ /*{{{ The thread pool */ // ---------------------------------------------------------------------------- // A pool of threads and buffers which do the real work. The number of possible // concurrent tests is defined in protocol.h. Each one requires a separate // thread, transfer buffer, semaphore, and some state information. // // Although the application is multi-threaded, in practice there is little // need for synchronization. Tests will only be started while the pool threads // are idle. When the pool threads are running the main thread will be waiting // for them all to finish, with a bit of polling to detect error conditions. // The pool threads do not share any data, apart from the file descriptor for // the USB device. typedef struct PoolEntry { pthread_t thread; sem_t wakeup; int running; UsbTest test; } PoolEntry; static PoolEntry pool[USBTEST_MAX_CONCURRENT_TESTS]; // This is the entry point for every thread in the pool. It just loops forever, // waiting until it is supposed to run a test. These threads never actually // exit, instead there should be a call to exit() somewhere. static void* pool_function(void* arg) { PoolEntry* pool_entry = (PoolEntry*) arg; for ( ; ; ) { sem_wait(&(pool_entry->wakeup)); run_test(&(pool_entry->test)); pool_entry->running = 0; } return NULL; } // Initialize all threads in the pool. static void pool_initialize(void) { int i; for (i = 0; i < USBTEST_MAX_CONCURRENT_TESTS; i++) { pool[i].running = 0; pool[i].test.fd = dup(usb_master_fd); if (0 != sem_init(&(pool[i].wakeup), 0, 0)) { fprintf(stderr, "usbhost: internal error, failed to initialize all semaphores.\n"); exit(EXIT_FAILURE); } if (0 != pthread_create(&(pool[i].thread), NULL, &pool_function, (void*) &(pool[i]))) { fprintf(stderr, "usbhost: internal error, failed to start all threads.\n"); exit(EXIT_FAILURE); } } } // Allocate a single entry in the thread pool. static UsbTest* pool_allocate(void) { UsbTest* result = (UsbTest*) 0; if (local_thread_count == USBTEST_MAX_CONCURRENT_TESTS) { fprintf(stderr, "usbhost: internal error, thread resource exhausted.\n"); exit(EXIT_FAILURE); } result = &(pool[local_thread_count].test); local_thread_count++; reset_usbtest(result); return result; } // Start all the threads that are supposed to be running tests. static void pool_start(void) { int i; for (i = 0; i < local_thread_count; i++) { pool[i].running = 1; sem_post(&(pool[i].wakeup)); } } /*}}}*/ /*{{{ Tcl routines */ // ---------------------------------------------------------------------------- // Tcl routines to provide access to the USB device from inside Tcl // scripts, plus some general utilities. These routines deal mostly // with preparing a test run. The actual work is done in C: the // ioctl() operations are not readily accessible from Tcl, and // operations like filling in buffers and calculating checksums are // cpu-intensive. /*{{{ pass/fail/abort */ // ---------------------------------------------------------------------------- // Some simple routines accessible from Tcl to get the target to report pass/fail or // to make the target abort. static int tcl_target_pass(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_pass <message>\"", TCL_STATIC); return TCL_ERROR; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_PASS, 0, 0, strlen(argv[1]) + 1, argv[1]); usb_sync(usb_master_fd, -1); return TCL_OK; } static int tcl_target_fail(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_fail <message>\"", TCL_STATIC); return TCL_ERROR; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_FAIL, 0, 0, strlen(argv[1]) + 1, argv[1]); usb_sync(usb_master_fd, -1); return TCL_OK; } // The next three routines cause the target to exit, so a usb_sync() is inappropriate. static int tcl_target_pass_exit(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_pass_exit <message>\"", TCL_STATIC); return TCL_ERROR; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_PASS_EXIT, 0, 0, strlen(argv[1]) + 1, argv[1]); return TCL_OK; } static int tcl_target_fail_exit(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_fail_exit <message>\"", TCL_STATIC); return TCL_ERROR; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_FAIL_EXIT, 0, 0, strlen(argv[1]) + 1, argv[1]); return TCL_OK; } static int tcl_target_abort(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv __attribute__ ((unused)) ) { if (1 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_abort\"", TCL_STATIC); return TCL_ERROR; } usb_abort(usb_master_fd); return TCL_OK; } /*}}}*/ /*{{{ start bulk test */ // ---------------------------------------------------------------------------- // Start a bulk test. The real Tcl interface to this functionality is // implemented in Tcl: it takes care of figuring out sensible default // arguments, validating the data, etc. All that this code does is // allocate a thread and fill in the appropriate data, plus request // the target-side to do the same thing. static int tcl_test_bulk(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { int i; int tmp; UsbTest* test; unsigned char request[USBTEST_MAX_CONTROL_DATA]; int request_index; // The data consists of 28 numbers for UsbTest_Bulk itself, and // another 10 numbers for the test data definition. if (39 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::_test_bulk <message>\"", TCL_STATIC); return TCL_ERROR; } for (i = 1; i < 39; i++) { int discard; if (TCL_OK != Tcl_GetInt(interp, argv[i], &discard)) { Tcl_SetResult(interp, "invalid argument: all arguments should be numbers", TCL_STATIC); return TCL_ERROR; } } test = pool_allocate(); Tcl_GetInt(interp, argv[1], &(test->test_params.bulk.number_packets)); Tcl_GetInt(interp, argv[2], &(test->test_params.bulk.endpoint)); test->which_test = (USB_DIR_IN == (test->test_params.bulk.endpoint & USB_ENDPOINT_DIR_MASK)) ? usbtest_bulk_in : usbtest_bulk_out; Tcl_GetInt(interp, argv[ 3], &(test->test_params.bulk.tx_size)); Tcl_GetInt(interp, argv[ 4], &(test->test_params.bulk.tx_size_min)); Tcl_GetInt(interp, argv[ 5], &(test->test_params.bulk.tx_size_max)); Tcl_GetInt(interp, argv[ 6], &(test->test_params.bulk.tx_size_multiplier)); Tcl_GetInt(interp, argv[ 7], &(test->test_params.bulk.tx_size_divisor)); Tcl_GetInt(interp, argv[ 8], &(test->test_params.bulk.tx_size_increment)); Tcl_GetInt(interp, argv[ 9], &(test->test_params.bulk.rx_size)); Tcl_GetInt(interp, argv[10], &(test->test_params.bulk.rx_size_min)); Tcl_GetInt(interp, argv[11], &(test->test_params.bulk.rx_size_max)); Tcl_GetInt(interp, argv[12], &(test->test_params.bulk.rx_size_multiplier)); Tcl_GetInt(interp, argv[13], &(test->test_params.bulk.rx_size_divisor)); Tcl_GetInt(interp, argv[14], &(test->test_params.bulk.rx_size_increment)); Tcl_GetInt(interp, argv[15], &(test->test_params.bulk.rx_padding)); Tcl_GetInt(interp, argv[16], &(test->test_params.bulk.tx_delay)); Tcl_GetInt(interp, argv[17], &(test->test_params.bulk.tx_delay_min)); Tcl_GetInt(interp, argv[18], &(test->test_params.bulk.tx_delay_max)); Tcl_GetInt(interp, argv[19], &(test->test_params.bulk.tx_delay_multiplier)); Tcl_GetInt(interp, argv[20], &(test->test_params.bulk.tx_delay_divisor)); Tcl_GetInt(interp, argv[21], &(test->test_params.bulk.tx_delay_increment)); Tcl_GetInt(interp, argv[22], &(test->test_params.bulk.rx_delay)); Tcl_GetInt(interp, argv[23], &(test->test_params.bulk.rx_delay_min)); Tcl_GetInt(interp, argv[24], &(test->test_params.bulk.rx_delay_max)); Tcl_GetInt(interp, argv[25], &(test->test_params.bulk.rx_delay_multiplier)); Tcl_GetInt(interp, argv[26], &(test->test_params.bulk.rx_delay_divisor)); Tcl_GetInt(interp, argv[27], &(test->test_params.bulk.rx_delay_increment)); Tcl_GetInt(interp, argv[28], &tmp); test->test_params.bulk.io_mechanism = (usb_io_mechanism) tmp; Tcl_GetInt(interp, argv[29], &tmp); test->test_params.bulk.data.format = (usbtestdata) tmp; Tcl_GetInt(interp, argv[30], &(test->test_params.bulk.data.seed)); Tcl_GetInt(interp, argv[31], &(test->test_params.bulk.data.multiplier)); Tcl_GetInt(interp, argv[32], &(test->test_params.bulk.data.increment)); Tcl_GetInt(interp, argv[33], &(test->test_params.bulk.data.transfer_seed_multiplier)); Tcl_GetInt(interp, argv[34], &(test->test_params.bulk.data.transfer_seed_increment)); Tcl_GetInt(interp, argv[35], &(test->test_params.bulk.data.transfer_multiplier_multiplier)); Tcl_GetInt(interp, argv[36], &(test->test_params.bulk.data.transfer_multiplier_increment)); Tcl_GetInt(interp, argv[37], &(test->test_params.bulk.data.transfer_increment_multiplier)); Tcl_GetInt(interp, argv[38], &(test->test_params.bulk.data.transfer_increment_increment)); VERBOSE(3, "Preparing USB bulk test on endpoint %d, direction %s, for %d packets\n", \ test->test_params.bulk.endpoint, \ (usbtest_bulk_in == test->which_test) ? "IN" : "OUT", \ test->test_params.bulk.number_packets); VERBOSE(3, " I/O mechanism is %s\n", \ (usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) ? "low-level USB" : \ (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) ? "devtab" : "<invalid>"); VERBOSE(3, " Data format %s, data1 %d, data* %d, data+ %d, data1* %d, data1+ %d, data** %d, data*+ %d, data+* %d, data++ %d\n",\ (usbtestdata_none == test->test_params.bulk.data.format) ? "none" : \ (usbtestdata_bytefill == test->test_params.bulk.data.format) ? "bytefill" : \ (usbtestdata_wordfill == test->test_params.bulk.data.format) ? "wordfill" : \ (usbtestdata_byteseq == test->test_params.bulk.data.format) ? "byteseq" : \ (usbtestdata_wordseq == test->test_params.bulk.data.format) ? "wordseq" : "<invalid>", \ test->test_params.bulk.data.seed, \ test->test_params.bulk.data.multiplier, \ test->test_params.bulk.data.increment, \ test->test_params.bulk.data.transfer_seed_multiplier, \ test->test_params.bulk.data.transfer_seed_increment, \ test->test_params.bulk.data.transfer_multiplier_multiplier, \ test->test_params.bulk.data.transfer_multiplier_increment, \ test->test_params.bulk.data.transfer_increment_multiplier, \ test->test_params.bulk.data.transfer_increment_increment); VERBOSE(3, " txsize1 %d, txsize>= %d, txsize<= %d, txsize* %d, txsize/ %d, txsize+ %d\n", \ test->test_params.bulk.tx_size, test->test_params.bulk.tx_size_min, \ test->test_params.bulk.tx_size_max, test->test_params.bulk.tx_size_multiplier, \ test->test_params.bulk.tx_size_divisor, test->test_params.bulk.tx_size_increment); VERBOSE(3, " rxsize1 %d, rxsize>= %d, rxsize<= %d, rxsize* %d, rxsize/ %d, rxsize+ %d\n", \ test->test_params.bulk.rx_size, test->test_params.bulk.rx_size_min, \ test->test_params.bulk.rx_size_max, test->test_params.bulk.rx_size_multiplier, \ test->test_params.bulk.rx_size_divisor, test->test_params.bulk.rx_size_increment); VERBOSE(3, " txdelay1 %d, txdelay>= %d, txdelay<= %d, txdelay* %d, txdelay/ %d, txdelay+ %d\n", \ test->test_params.bulk.tx_delay, test->test_params.bulk.tx_delay_min, \ test->test_params.bulk.tx_delay_max, test->test_params.bulk.tx_delay_multiplier, \ test->test_params.bulk.tx_delay_divisor, test->test_params.bulk.tx_delay_increment); VERBOSE(3, " rxdelay1 %d, rxdelay>= %d, rxdelay<= %d, rxdelay* %d, rxdelay/ %d, rxdelay+ %d\n", \ test->test_params.bulk.rx_delay, test->test_params.bulk.rx_delay_min, \ test->test_params.bulk.rx_delay_max, test->test_params.bulk.rx_delay_multiplier, \ test->test_params.bulk.rx_delay_divisor, test->test_params.bulk.rx_delay_increment); // That is all the data converted from Tcl to C, and a local thread is set up to handle this // request. Also set up a thread on the target. request_index = 0; pack_usbtest_bulk(&(test->test_params.bulk), request, &request_index); usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_TEST_BULK, 0, 0, request_index, request); remote_thread_count++; return TCL_OK; } /*}}}*/ /*{{{ start control-in test */ // ---------------------------------------------------------------------------- // Start a control-in test. The real Tcl interface to this // functionality is implemented in Tcl: it takes care of figuring out // sensible default arguments, validating the data, etc. All that this // code does is allocate a thread and fill in the appropriate data, // plus request the target-side to do the same thing. static int tcl_test_control_in(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { int i; int tmp; UsbTest* test; unsigned char request[USBTEST_MAX_CONTROL_DATA]; int request_index; // The data consists of 6 numbers for UsbTest_ControlIn itself, and // another 10 numbers for the test data definition. if (17 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::_test_control_in <message>\"", TCL_STATIC); return TCL_ERROR; } for (i = 1; i < 17; i++) { int discard; if (TCL_OK != Tcl_GetInt(interp, argv[i], &discard)) { Tcl_SetResult(interp, "invalid argument: all arguments should be numbers", TCL_STATIC); return TCL_ERROR; } } test = pool_allocate(); test->which_test = usbtest_control_in; Tcl_GetInt(interp, argv[1], &(test->test_params.control_in.number_packets)); Tcl_GetInt(interp, argv[2], &(test->test_params.control_in.packet_size_initial)); Tcl_GetInt(interp, argv[3], &(test->test_params.control_in.packet_size_min)); Tcl_GetInt(interp, argv[4], &(test->test_params.control_in.packet_size_max)); Tcl_GetInt(interp, argv[5], &(test->test_params.control_in.packet_size_multiplier)); Tcl_GetInt(interp, argv[6], &(test->test_params.control_in.packet_size_increment)); Tcl_GetInt(interp, argv[7], &tmp); test->test_params.bulk.data.format = (usbtestdata) tmp; Tcl_GetInt(interp, argv[ 8], &(test->test_params.control_in.data.seed)); Tcl_GetInt(interp, argv[ 9], &(test->test_params.control_in.data.multiplier)); Tcl_GetInt(interp, argv[10], &(test->test_params.control_in.data.increment)); Tcl_GetInt(interp, argv[11], &(test->test_params.control_in.data.transfer_seed_multiplier)); Tcl_GetInt(interp, argv[12], &(test->test_params.control_in.data.transfer_seed_increment)); Tcl_GetInt(interp, argv[13], &(test->test_params.control_in.data.transfer_multiplier_multiplier)); Tcl_GetInt(interp, argv[14], &(test->test_params.control_in.data.transfer_multiplier_increment)); Tcl_GetInt(interp, argv[15], &(test->test_params.control_in.data.transfer_increment_multiplier)); Tcl_GetInt(interp, argv[16], &(test->test_params.control_in.data.transfer_increment_increment)); // That is all the data converted from Tcl to C, and a local thread is set up to handle this // request. Also set up a thread on the target. request_index = 0; pack_usbtest_control_in(&(test->test_params.control_in), request, &request_index); usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_TEST_CONTROL_IN, 0, 0, request_index, request); remote_thread_count++; return TCL_OK; } /*}}}*/ /*{{{ Cancel the current batch of tests */ static int tcl_cancel(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv __attribute__ ((unused)) ) { if (1 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::cancel\"", TCL_STATIC); return TCL_ERROR; } // Send the request on to the target. usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_CANCEL, 0, 0, 0, (void*)0); // Now cancel all the local tests. This can be done by resetting the counter // of allocated threads: no actual work will have been started yet. local_thread_count = 0; // And synchronise with the target if (!usb_sync(usb_master_fd, 30)) { fprintf(stderr, "usbhost: error, target has failed to process test cancel request.\n"); exit(EXIT_FAILURE); } remote_thread_count = 0; return TCL_OK; } /*}}}*/ /*{{{ Run a batch of tests */ // ---------------------------------------------------------------------------- // This code does an awful lot of the hard work. Start with various utilities. // Has the current batch finished as far as the local threads are concerned? static int local_batch_finished(void) { int result = 1; int i; for (i = 0; i < local_thread_count; i++) { if (pool[i].running) { result = 0; break; } } return result; } // Has the current batch finished as far as remote threads are concerned? static int remote_batch_finished(void) { char buf[1]; usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_FINISHED, 0, 0, 1, (void*) buf); return buf[0]; } // Perform recovery for a thread on the target. This involves asking the // target for recovery information, then performing an appropriate // action. If no data is returned then no recovery is needed for this thread. static void recover_remote(int index) { unsigned char buffer[USBTEST_MAX_CONTROL_DATA]; int buffer_index; UsbTest_Recovery recovery; int i; if (0 != usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_GET_RECOVERY, 0, index, 12, buffer)) { // There is work to be done buffer_index = 0; unpack_usbtest_recovery(&recovery, buffer, &buffer_index); // We have an endpoint, a protocol, and a size. if (0 == recovery.endpoint) { // The target just needs a dummy reserved control message usb_reliable_control_message(usb_master_fd, USB_TYPE_RESERVED | USB_RECIP_DEVICE, USBTEST_RESERVED_CONTROL_IN, 0, 0, 0, (void*) 0); } else if (USB_ENDPOINT_XFER_BULK == recovery.protocol) { // Either we need to send some data to the target, or we need to accept some data. static unsigned char recovery_buffer[USBTEST_MAX_BULK_DATA + USBTEST_MAX_BULK_DATA_EXTRA]; struct usbdevfs_bulktransfer transfer; transfer.ep = recovery.endpoint; transfer.timeout = 2000; // Two seconds. Should be plenty, even for a large bulk transfer. transfer.data = recovery_buffer; if (USB_DIR_IN == (recovery.endpoint & USB_ENDPOINT_DIR_MASK)) { transfer.len = recovery.size; } else { transfer.len = 1; } errno = 0; i = ioctl(usb_master_fd, USBDEVFS_BULK, &transfer); } // There is no recovery support yet for other protocols. } } // Perform recovery for a local thread. This involves extracting the // recovery information from the local thread and asking the target // to take appropriate action. static void recover_local(int index) { unsigned char buffer[USBTEST_MAX_CONTROL_DATA]; int buffer_index; if (pool[index].running) { buffer_index = 0; pack_usbtest_recovery(&(pool[index].test.recovery), buffer, &buffer_index); usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_PERFORM_RECOVERY, 0, 0, buffer_index, (void*) buffer); } } // All done, time for a clean-up on both target and host. The latter // is achieved simply by resetting the thread pool, which actually // just means resetting the counter since all the threads are blocked // waiting for the next batch. static void run_done(void) { usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_BATCH_DONE, 0, 0, 0, (void*) NULL); local_thread_count = 0; remote_thread_count = 0; } // The main routine, as invoked from Tcl. This takes a single // argument, a timeout in seconds. static int tcl_run(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv __attribute__ ((unused)) ) { struct timespec delay; int timeout; time_t start; time_t now; int i, j; unsigned char result_buf[USBTEST_MAX_CONTROL_DATA]; int all_ok; if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::_run <timeout>\"", TCL_STATIC); return TCL_ERROR; } if (TCL_OK != Tcl_GetInt(interp, argv[1], &timeout)) { Tcl_SetResult(interp, "invalid argument: timeout should be numeric", TCL_STATIC); return TCL_ERROR; } VERBOSE(2, "Starting a testrun, timeout %d seconds\n", timeout); // Start the tests running on the target. The target USB hardware // will not actually do anything except in response to packets // from the host, so it is better to start the target before the // local threads. usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_START, 0, 0, 0, (void*) 0); // Now the local threads can get going. current_tests_terminated = 0; pool_start(); // Now leave the various testing threads to do their thing until // either side believes that the batch has finished, or until the // timeout expires. Note that if one side decides that the batch // has finished but the other disagrees, that in itself indicates // a test failure of sorts. // // There is a question of polling frequency. Once a second avoids // excessive polling traffic on the USB bus, and should not impose // intolerable delays for short-duration tests. start = time(NULL); do { VERBOSE(3, "The tests are running, waiting for termination\n"); delay.tv_sec = 1; delay.tv_nsec = 0; nanosleep(&delay, NULL); now = time(NULL); } while (((start + timeout) > now) && !local_batch_finished() && !remote_batch_finished()); VERBOSE(2, "Termination detected, time elapsed %ld\n", (long) now - start); // If either side believes that testing is not complete, things // get messy. Start by setting the terminated flag. Any tests that // are actually still running happily but have not finished within // the timeout should detect this and stop. if (!local_batch_finished() || !remote_batch_finished()) { VERBOSE(2, "Testing is not yet complete, setting TERMINATED flag\n"); current_tests_terminated = 1; usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_SET_TERMINATED, 0, 0, 0, (void*) 0); // And another delay, to give threads a chance to detect the // flag's update delay.tv_sec = 1; delay.tv_nsec = 0; nanosleep(&delay, NULL); } // If there is still are unfinished threads, recovery action // is needed. It is not clear whether it is better to unlock // the local threads first, or the remote threads. For now the // latter approach is taken. if (!remote_batch_finished()) { int i; VERBOSE(2, "Remote threads still running, performing remote recovery\n"); for (i = 0; i < remote_thread_count; i++) { recover_remote(i); } // Allow the recovery actions to take effect delay.tv_sec = 1; delay.tv_nsec = 0; nanosleep(&delay, NULL); } if (!local_batch_finished()) { int i; VERBOSE(2, "Local threads still running, performing local recovery\n"); for (i = 0; i < local_thread_count; i++) { recover_local(i); } // Allow the recovery actions to take effect delay.tv_sec = 1; delay.tv_nsec = 0; nanosleep(&delay, NULL); } // One last check to make sure that everything is finished. If not, // testing has broken down and it is necessary to abort. if (!local_batch_finished() || !remote_batch_finished()) { VERBOSE(2, "Giving local and remote threads another chance to finish.\n"); // Allow the recovery actions to take effect delay.tv_sec = 5; delay.tv_nsec = 0; nanosleep(&delay, NULL); if (!local_batch_finished() || !remote_batch_finished()) { // OK, normality has not been restored. // It would be nice to get hold of and display any error messages. usb_abort(usb_master_fd); fprintf(stderr, "Fatal error: the host test program and the remote target are out of synch.\n"); fprintf(stderr, " recovery has been attempted, without success.\n"); fprintf(stderr, " USB testing cannot continue.\n"); exit(EXIT_FAILURE); } } VERBOSE(2, "Local and remote threads are in synch, collecting results.\n"); // The world is in a coherent state. Time to collect the results. // The return value of this function is a simple boolean. More // detailed results will be held in a Tcl variable as a list of // messages. It is desirable to keep both local and remote results // in order. for (i = 0; i < ((local_thread_count < remote_thread_count) ? local_thread_count : remote_thread_count); i++) { if (!pool[i].test.result_pass) { Tcl_SetVar(interp, "usbtest::results", pool[i].test.result_message, all_ok ? (TCL_GLOBAL_ONLY | TCL_LIST_ELEMENT) : (TCL_GLOBAL_ONLY | TCL_APPEND_VALUE | TCL_LIST_ELEMENT)); all_ok = 0; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_GET_RESULT, 0, i, USBTEST_MAX_CONTROL_DATA, (void*) result_buf); if (!result_buf[0]) { Tcl_SetVar(interp, "usbtest::results", &(result_buf[1]), all_ok ? TCL_GLOBAL_ONLY : (TCL_GLOBAL_ONLY | TCL_APPEND_VALUE | TCL_LIST_ELEMENT)); all_ok = 0; } } for (j = i; j < local_thread_count; j++) { if (!pool[j].test.result_pass) { Tcl_SetVar(interp, "usbtest::results", pool[j].test.result_message, all_ok ? TCL_GLOBAL_ONLY : (TCL_GLOBAL_ONLY | TCL_APPEND_VALUE | TCL_LIST_ELEMENT)); all_ok = 0; } } for (j = i; j < remote_thread_count; j++) { usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_GET_RESULT, 0, i, USBTEST_MAX_CONTROL_DATA, (void*) result_buf); if (!result_buf[0]) { Tcl_SetVar(interp, "usbtest::results", &(result_buf[1]), all_ok ? TCL_GLOBAL_ONLY : (TCL_GLOBAL_ONLY | TCL_APPEND_VALUE | TCL_LIST_ELEMENT)); all_ok = 0; } } VERBOSE(2, "Overall test result %d\n", all_ok); Tcl_SetResult(interp, all_ok ? "1" : "0", TCL_STATIC); run_done(); return TCL_OK; } /*}}}*/ /*{{{ Set verbosity */ // ---------------------------------------------------------------------------- // Allow Tcl scripts to control verbosity levels for both host and target static int tcl_host_verbose(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { int level; if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::host_verbose <level>\"", TCL_STATIC); return TCL_ERROR; } if (TCL_OK != Tcl_GetInt(interp, argv[1], &level)) { Tcl_SetResult(interp, "invalid argument: verbosity level should be numeric", TCL_STATIC); return TCL_ERROR; } verbose = level; return TCL_OK; } static int tcl_target_verbose(ClientData clientData __attribute__ ((unused)), Tcl_Interp* interp, int argc, char** argv) { int level; if (2 != argc) { Tcl_SetResult(interp, "wrong # args: should be \"usbtest::target_verbose <level>\"", TCL_STATIC); return TCL_ERROR; } if (TCL_OK != Tcl_GetInt(interp, argv[1], &level)) { Tcl_SetResult(interp, "invalid argument: verbosity level should be numeric", TCL_STATIC); return TCL_ERROR; } usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE, USBTEST_VERBOSE, level, 0, 0, NULL); usb_sync(usb_master_fd, -1); return TCL_OK; } /*}}}*/ /*}}}*/ /*{{{ AppInit() */ // ---------------------------------------------------------------------------- // Application-specific initialization. We have a bare Tcl interpreter ready // to start executing scripts that define various test cases. However some // additional functions will have to be added to the interpreter, plus // information about the various endpoints. static int usbhost_appinit(Tcl_Interp* interp) { unsigned char buf[USBTEST_MAX_CONTROL_DATA]; int number_of_endpoints; int i; char* location; // Start by creating a usbtest namespace, for use by the various functions // and variables. if (TCL_OK != Tcl_Eval(interp, "namespace eval usbtest {\n" " variable number_of_endpoints 0\n" " array set endpoint [list]\n" "}\n")) { fprintf(stderr, "usbhost: internal error, failed to create Tcl usbtest:: namespace\n"); fprintf(stderr, " Please check Tcl version (8.0b1 or later required).\n"); exit(EXIT_FAILURE); } // Add some information about the install path so that the // main Tcl script can find and execute test scripts. location = getenv("USBHOSTDIR"); if (NULL == location) { location = USBAUXDIR; } Tcl_SetVar(interp, "usbtest::USBAUXDIR", location, TCL_GLOBAL_ONLY); // Also set the verbosity level correctly Tcl_SetVar2Ex(interp, "usbtest::verbose", NULL, Tcl_NewIntObj(verbose), TCL_GLOBAL_ONLY); // Next we need to know the number of endpoints, and for each // endpoint we want additional information such as type. The // results are placed in a Tcl array. usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_ENDPOINT_COUNT, 0, 0, 1, buf); number_of_endpoints = buf[0]; Tcl_SetVar2Ex(interp, "usbtest::endpoint_count", NULL, Tcl_NewIntObj(number_of_endpoints), TCL_GLOBAL_ONLY); for (i = 0; i < number_of_endpoints; i++) { char varname[256]; int result; int endpoint_min_size; int endpoint_max_size; int index; memset(buf, 0, USBTEST_MAX_CONTROL_DATA); result = usb_reliable_control_message(usb_master_fd, USB_TYPE_CLASS | USB_RECIP_DEVICE | USB_DIR_IN, USBTEST_ENDPOINT_DETAILS, 0, i, USBTEST_MAX_CONTROL_DATA, buf); if (result < 13) { fprintf(stderr, "usbhost: error, received insufficient endpoint data back from the target.\n"); exit(EXIT_FAILURE); } // See protocol.h for the encoding used. sprintf(varname, "usbtest::endpoint_data(%d,type)", i); switch(buf[0]) { case USB_ENDPOINT_XFER_CONTROL : Tcl_SetVar(interp, varname, "control", TCL_GLOBAL_ONLY); break; case USB_ENDPOINT_XFER_ISOC : Tcl_SetVar(interp, varname, "isochronous", TCL_GLOBAL_ONLY); break; case USB_ENDPOINT_XFER_BULK : Tcl_SetVar(interp, varname, "bulk", TCL_GLOBAL_ONLY); break; case USB_ENDPOINT_XFER_INT : Tcl_SetVar(interp, varname, "interrupt", TCL_GLOBAL_ONLY); break; } sprintf(varname, "usbtest::endpoint_data(%d,number)", i); Tcl_SetVar2Ex(interp, varname, NULL, Tcl_NewIntObj((int) buf[1]), TCL_GLOBAL_ONLY); sprintf(varname, "usbtest::endpoint_data(%d,direction)", i); if (USB_DIR_OUT == buf[2]) { Tcl_SetVar(interp, varname, "out", TCL_GLOBAL_ONLY); } else { Tcl_SetVar(interp, varname, "in", TCL_GLOBAL_ONLY); } sprintf(varname, "usbtest::endpoint_data(%d,max_in_padding)", i); Tcl_SetVar2Ex(interp, varname, NULL, Tcl_NewIntObj((int) buf[3]), TCL_GLOBAL_ONLY); sprintf(varname, "usbtest::endpoint_data(%d,min_size)", i); index = 4; endpoint_min_size = unpack_int(buf, &index); Tcl_SetVar2Ex(interp, varname, NULL, Tcl_NewIntObj(endpoint_min_size), TCL_GLOBAL_ONLY); sprintf(varname, "usbtest::endpoint_data(%d,max_size)", i); endpoint_max_size = unpack_int(buf, &index); if (USB_ENDPOINT_XFER_CONTROL == buf[0]) { if (endpoint_max_size > USBTEST_MAX_CONTROL_DATA) { endpoint_max_size = USBTEST_MAX_CONTROL_DATA; } } else { if ((-1 == endpoint_max_size) || (endpoint_max_size > USBTEST_MAX_BULK_DATA)) { endpoint_max_size = USBTEST_MAX_BULK_DATA; } } Tcl_SetVar2Ex(interp, varname, NULL, Tcl_NewIntObj(endpoint_max_size), TCL_GLOBAL_ONLY); sprintf(varname, "usbtest::endpoint_data(%d,devtab)", i); Tcl_SetVar(interp, varname, (char*) &(buf[12]), TCL_GLOBAL_ONLY); // Perform any additional endpoint-specific initialization to make // sure host and target can actually communicate via this endpoint. switch(buf[0]) { case USB_ENDPOINT_XFER_CONTROL : { usb_initialise_control_endpoint(endpoint_min_size, endpoint_max_size); break; } case USB_ENDPOINT_XFER_ISOC : { if (USB_DIR_OUT == buf[2]) { usb_initialise_isochronous_out_endpoint(buf[1], endpoint_min_size, endpoint_max_size); } else { usb_initialise_isochronous_in_endpoint(buf[1], endpoint_min_size, endpoint_max_size); } break; } case USB_ENDPOINT_XFER_BULK : { if (USB_DIR_OUT == buf[2]) { usb_initialise_bulk_out_endpoint(buf[1], endpoint_min_size, endpoint_max_size); } else { usb_initialise_bulk_in_endpoint(buf[1], endpoint_min_size, endpoint_max_size, buf[3]); } break; } case USB_ENDPOINT_XFER_INT : { if (USB_DIR_OUT == buf[2]) { usb_initialise_interrupt_out_endpoint(buf[1], endpoint_min_size, endpoint_max_size); } else { usb_initialise_interrupt_in_endpoint(buf[1], endpoint_min_size, endpoint_max_size); } break; } } } // Register appropriate commands with the Tcl interpreter Tcl_CreateCommand(interp, "usbtest::target_pass", &tcl_target_pass, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::target_pass_exit", &tcl_target_pass_exit, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::target_fail", &tcl_target_fail, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::target_fail_exit", &tcl_target_fail_exit, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::target_abort", &tcl_target_abort, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::_test_bulk", &tcl_test_bulk, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::_test_control_in", &tcl_test_control_in, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::_cancel", &tcl_cancel, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::_run", &tcl_run, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::host_verbose", &tcl_host_verbose, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); Tcl_CreateCommand(interp, "usbtest::target_verbose", &tcl_target_verbose, (ClientData) NULL, (Tcl_CmdDeleteProc*) NULL); return TCL_OK; } /*}}}*/ /*{{{ main() */ // ---------------------------------------------------------------------------- // System start-up. After argument processing this code checks that // there is a suitable USB target attached - if not then there is no // point in proceeding. Otherwise further initialization is performed // and then control is passed to a Tcl interpreter. static void usage(void) { printf("usbhost: usage, usbhost [-V|--verbose] [-v|--version] [-h|--help] <test> [args]\n"); printf(" -V, --verbose Make the host-side output additional information\n"); printf(" during test runs. This argument can be repeated to\n"); printf(" increase verbosity.\n"); printf(" -v, --version Output version information for usbhost.\n"); printf(" -h, --help Output this help information.\n"); printf(" <test> The name of a USB test case, for example list.tcl\n"); printf(" [args] Optional additional arguments for the testcase.\n"); exit(0); } static void version(void) { printf("usbhost: version %s\n", USBHOST_VERSION); printf(" : built from USB slave package version %s\n", PKGVERSION); printf(" : support files installed in %s\n", USBAUXDIR); exit(0); } int main(int argc, char** argv) { char* interpreter = argv[0]; char** new_argv; char path[_POSIX_PATH_MAX]; char* location; int i; // Argument processing for (i = 1; i < argc; i++) { if ((0 == strcmp("-h", argv[i])) || (0 == strcmp("-H", argv[i])) || (0 == strcmp("--help", argv[i]))) { usage(); } if ((0 == strcmp("-v", argv[i])) || (0 == strcmp("--version", argv[i]))) { version(); } if ((0 == strcmp("-V", argv[i])) || (0 == strcmp("--verbose", argv[i]))) { verbose++; continue; } // The first unrecognised argument should correspond to the test script. break; } argc = (argc - i) + 1; argv = (argv + i) - 1; if (1 == argc) { fprintf(stderr, "usbhost: at least one test script must be specified on the command line.\n"); exit(EXIT_FAILURE); } usb_master_fd = usb_open_device(); if (-1 == usb_master_fd) { return EXIT_FAILURE; } // There is a valid USB target. Initialize the pool of threads etc. pool_initialize(); // Now start a Tcl interpreter. Tcl_Main() will interpret the // first argument as the name of a Tcl script to execute, // i.e. usbhost.tcl. This can be found in the install tree, // but during development it is inconvenient to run // "make install" every time the Tcl script is edited so an // environment variable can be used to override the location. new_argv = malloc((argc + 2) * sizeof(char*)); if (NULL == new_argv) { fprintf(stderr, "usbhost: internal error, out of memory.\n"); exit(EXIT_FAILURE); } new_argv[0] = interpreter; location = getenv("USBHOSTDIR"); if (NULL == location) { location = USBAUXDIR; } snprintf(path, _POSIX_PATH_MAX, "%s/usbhost.tcl", location); if (0 != access(path, R_OK)) { fprintf(stderr, "usbhost: cannot find or access required Tcl script\n"); fprintf(stderr, " : %s\n", path); exit(EXIT_FAILURE); } new_argv[1] = path; for (i = 1; i < argc; i++) { new_argv[i+1] = argv[i]; } new_argv[i+1] = NULL; Tcl_Main(i+1, new_argv, &usbhost_appinit); return EXIT_SUCCESS; } /*}}}*/
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