URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [io/] [usb/] [slave/] [v2_0/] [tests/] [usbtarget.c] - Rev 646
Go to most recent revision | Compare with Previous | Blame | View Log
/*{{{ Banner */ /*================================================================= // // target.c // // USB testing - target-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#### // // This program performs appropriate USB initialization and initializes // itself as a specific type of USB peripheral, Red Hat eCos testing. // There is no actual host-side device driver for this, instead there is // a test application which performs ioctl's on /proc/bus/usb/... and // makes appropriate functionality available to a Tcl script. // // Author(s): bartv // Date: 2001-07-04 //####DESCRIPTIONEND#### //========================================================================== */ /*}}}*/ /*{{{ #include's */ #include <stdio.h> #include <cyg/infra/cyg_ass.h> #include <cyg/infra/diag.h> #include <cyg/kernel/kapi.h> #include <cyg/hal/hal_arch.h> #include <cyg/io/io.h> #include <cyg/io/usb/usbs.h> #include <cyg/infra/testcase.h> #include "protocol.h" /*}}}*/ /*{{{ Statics */ // ---------------------------------------------------------------------------- // Statics. // The number of endpoints supported by the device driver. static int number_endpoints = 0; // The control endpoint static usbs_control_endpoint* control_endpoint = (usbs_control_endpoint*) 0; // Buffers for incoming and outgoing data, and a length field. static unsigned char class_request[USBTEST_MAX_CONTROL_DATA + 1]; static unsigned char class_reply[USBTEST_MAX_CONTROL_DATA + 1]; static int class_request_size = 0; // This semaphore is used by DSRs to wake up the main thread when work has to // be done at thread level. static cyg_sem_t main_wakeup; // And this function pointer identifies the work that has to be done. static void (*main_thread_action)(void) = (void (*)(void)) 0; // Is the system still busy processing a previous request? This variable is // checked in response to the synch request. It may get updated in // DSRs as well as at thread level, hence volatile. static volatile int idle = 1; // Are any tests currently running? static int running = 0; // Has the current batch of tests been terminated by the host? 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; // A counter for the number of threads involved in the current batch of tests. static int thread_counter = 0; // An extra buffer for recovery operations, for example to accept and discard // data which the host is still trying to send. static unsigned char recovery_buffer[USBTEST_MAX_BULK_DATA + USBTEST_MAX_BULK_DATA_EXTRA]; /*}}}*/ /*{{{ Logging */ // ---------------------------------------------------------------------------- // The target-side code can provide various levels of run-time logging. // Obviously the verbose flag cannot be controlled by a command-line // argument, but it can be set from inside gdb or alternatively by // a request from the host. // // NOTE: is printf() the best I/O routine to use here? static int verbose = 0; #define VERBOSE(_level_, _format_, _args_...) \ do { \ if (verbose >= _level_) { \ diag_printf(_format_, ## _args_); \ } \ } while (0); /*}}}*/ /*{{{ Utilities */ // ---------------------------------------------------------------------------- // A reimplementation of nanosleep, to avoid having to pull in the // POSIX compatibility testing for USB testing. static void usbs_nanosleep(int delay) { cyg_tick_count_t ticks; cyg_resolution_t resolution = cyg_clock_get_resolution(cyg_real_time_clock()); // (resolution.dividend/resolution.divisor) == nanoseconds/tick // e.g. 1000000000/100, i.e. 10000000 ns or 10 ms per tick // So ticks = (delay * divisor) / dividend // e.g. (10000000 * 100) / 1000000000 // with a likely value of 0 for delays of less than the clock resolution, // so round those up to one tick. cyg_uint64 tmp = (cyg_uint64) delay; tmp *= (cyg_uint64) resolution.divisor; tmp /= (cyg_uint64) resolution.dividend; ticks = (int) tmp; if (0 != ticks) { cyg_thread_delay(ticks); } } // ---------------------------------------------------------------------------- // Fix any problems in the driver-supplied endpoint data // // Maximum transfer sizes are limited not just by the capabilities // of the driver but also by the testing code itself, since e.g. // buffers for transfers are statically allocated. static void fix_driver_endpoint_data(void) { int i; for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) { if (USB_ENDPOINT_DESCRIPTOR_ATTR_BULK == usbs_testing_endpoints[i].endpoint_type) { if ((-1 == usbs_testing_endpoints[i].max_size) || (usbs_testing_endpoints[i].max_size > USBTEST_MAX_BULK_DATA)) { usbs_testing_endpoints[i].max_size = USBTEST_MAX_BULK_DATA; } } } } // ---------------------------------------------------------------------------- // A heartbeat thread. // // USB tests can run for a long time with no traffic on the debug channel, // which can cause problems. To avoid problems it is possible to have a // heartbeat thread running in the background, sending output at one // second intervals. // // Depending on the configuration the output may still be line-buffered, // but that is still sufficient to keep things happy. static cyg_bool heartbeat = false; static cyg_thread heartbeat_data; static cyg_handle_t heartbeat_handle; static char heartbeat_stack[CYGNUM_HAL_STACK_SIZE_TYPICAL]; static void heartbeat_function(cyg_addrword_t arg __attribute((unused))) { char* message = "alive\n"; int i; for ( i = 0; ; i = (i + 1) % 6) { usbs_nanosleep(1000000000); if (heartbeat) { diag_write_char(message[i]); } } } static void start_heartbeat(void) { cyg_thread_create( 0, &heartbeat_function, 0, "heartbeat", heartbeat_stack, CYGNUM_HAL_STACK_SIZE_TYPICAL, &heartbeat_handle, &heartbeat_data); cyg_thread_resume(heartbeat_handle); } /*}}}*/ /*{{{ Endpoint usage */ // ---------------------------------------------------------------------------- // It is important to keep track of which endpoints are currently in use, // because the behaviour of the USB I/O routines is undefined if there are // concurrent attempts to communicate on the same endpoint. Normally this is // not a problem because the host will ensure that a given endpoint is used // for only one endpoint at a time, but when performing recovery action it // is important that the system is sure that a given endpoint can be accessed // safely. static cyg_bool in_endpoint_in_use[16]; static cyg_bool out_endpoint_in_use[16]; // Lock the given endpoint. In theory this is only ever accessed from a single // test thread at a time, but just in case... static void lock_endpoint(int endpoint, int direction) { CYG_ASSERTC((endpoint >=0) && (endpoint < 16)); CYG_ASSERTC((USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) || (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT == direction)); cyg_scheduler_lock(); if (0 == endpoint) { // Comms traffic on endpoint 0 is implemented using reserved control messages. // It is not really possible to have concurrent IN and OUT operations because // the two would interfere with each other. CYG_ASSERTC(!in_endpoint_in_use[0] && !out_endpoint_in_use[0]); in_endpoint_in_use[0] = true; out_endpoint_in_use[0] = true; } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) { CYG_ASSERTC(!in_endpoint_in_use[endpoint]); in_endpoint_in_use[endpoint] = true; } else { CYG_ASSERTC(!out_endpoint_in_use[endpoint]); out_endpoint_in_use[endpoint] = true; } cyg_scheduler_unlock(); } static void unlock_endpoint(int endpoint, int direction) { CYG_ASSERTC((endpoint >= 0) && (endpoint < 16)); CYG_ASSERTC((USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) || (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT == direction)); if (0 == endpoint) { CYG_ASSERTC(in_endpoint_in_use[0] && out_endpoint_in_use[0]); in_endpoint_in_use[0] = false; out_endpoint_in_use[0] = false; } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) { CYG_ASSERTC(in_endpoint_in_use[endpoint]); in_endpoint_in_use[endpoint] = false; } else { CYG_ASSERTC(out_endpoint_in_use[endpoint]); out_endpoint_in_use[endpoint] = false; } } static cyg_bool is_endpoint_locked(int endpoint, int direction) { cyg_bool result = false; if (0 == endpoint) { result = in_endpoint_in_use[0]; } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) { result = in_endpoint_in_use[endpoint]; } else { result = out_endpoint_in_use[endpoint]; } return result; } // For a given endpoint number, direction and protocol, search through the table // supplied by the device driver of all available endpoints. This can be used // to e.g. get hold of the name of the devtab entry or a pointer to the endpoint // data structure itself. static int lookup_endpoint(int endpoint_number, int direction, int protocol) { int result = -1; int i; for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) { if ((usbs_testing_endpoints[i].endpoint_type == protocol) && (usbs_testing_endpoints[i].endpoint_number == endpoint_number) && (usbs_testing_endpoints[i].endpoint_direction == direction)) { result = i; break; } } return result; } /*}}}*/ /*{{{ Enumeration data */ // ---------------------------------------------------------------------------- // The enumeration data. // // For simplicity this configuration involves just a single interface. // The target has to list all the endpoints, or the Linux kernel will // not allow application code to access them. Hence the information // provided by the device drivers has to be turned into endpoint descriptors. usb_configuration_descriptor usb_configuration = { length: USB_CONFIGURATION_DESCRIPTOR_LENGTH, type: USB_CONFIGURATION_DESCRIPTOR_TYPE, total_length_lo: USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_LO(1, 0), total_length_hi: USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_HI(1, 0), number_interfaces: 1, configuration_id: 1, // id 0 is special according to the spec configuration_str: 0, attributes: USB_CONFIGURATION_DESCRIPTOR_ATTR_REQUIRED | USB_CONFIGURATION_DESCRIPTOR_ATTR_SELF_POWERED, max_power: 50 }; usb_interface_descriptor usb_interface = { length: USB_INTERFACE_DESCRIPTOR_LENGTH, type: USB_INTERFACE_DESCRIPTOR_TYPE, interface_id: 0, alternate_setting: 0, number_endpoints: 0, interface_class: USB_INTERFACE_DESCRIPTOR_CLASS_VENDOR, interface_subclass: USB_INTERFACE_DESCRIPTOR_SUBCLASS_VENDOR, interface_protocol: USB_INTERFACE_DESCRIPTOR_PROTOCOL_VENDOR, interface_str: 0 }; usb_endpoint_descriptor usb_endpoints[USBTEST_MAX_ENDPOINTS]; const unsigned char* usb_strings[] = { "\004\003\011\004", "\020\003R\000e\000d\000 \000H\000a\000t\000", "\054\003R\000e\000d\000 \000H\000a\000t\000 \000e\000C\000o\000s\000 \000" "U\000S\000B\000 \000t\000e\000s\000t\000" }; usbs_enumeration_data usb_enum_data = { { length: USB_DEVICE_DESCRIPTOR_LENGTH, type: USB_DEVICE_DESCRIPTOR_TYPE, usb_spec_lo: USB_DEVICE_DESCRIPTOR_USB11_LO, usb_spec_hi: USB_DEVICE_DESCRIPTOR_USB11_HI, device_class: USB_DEVICE_DESCRIPTOR_CLASS_VENDOR, device_subclass: USB_DEVICE_DESCRIPTOR_SUBCLASS_VENDOR, device_protocol: USB_DEVICE_DESCRIPTOR_PROTOCOL_VENDOR, max_packet_size: 8, vendor_lo: 0x42, // Note: this is not an allocated vendor id vendor_hi: 0x42, product_lo: 0x00, product_hi: 0x01, device_lo: 0x00, device_hi: 0x01, manufacturer_str: 1, product_str: 2, serial_number_str: 0, number_configurations: 1 }, total_number_interfaces: 1, total_number_endpoints: 0, total_number_strings: 3, configurations: &usb_configuration, interfaces: &usb_interface, endpoints: usb_endpoints, strings: usb_strings }; static void provide_endpoint_enumeration_data(void) { int enum_endpoint_count = 0; int i; for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) { // The control endpoint need not appear in the enumeration data. if (USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL == usbs_testing_endpoints[i].endpoint_type) { continue; } usb_endpoints[enum_endpoint_count].length = USB_ENDPOINT_DESCRIPTOR_LENGTH; usb_endpoints[enum_endpoint_count].type = USB_ENDPOINT_DESCRIPTOR_TYPE; usb_endpoints[enum_endpoint_count].endpoint = usbs_testing_endpoints[i].endpoint_number | usbs_testing_endpoints[i].endpoint_direction; switch (usbs_testing_endpoints[i].endpoint_type) { case USB_ENDPOINT_DESCRIPTOR_ATTR_BULK: usb_endpoints[enum_endpoint_count].attributes = USB_ENDPOINT_DESCRIPTOR_ATTR_BULK; usb_endpoints[enum_endpoint_count].max_packet_lo = 64; usb_endpoints[enum_endpoint_count].max_packet_hi = 0; usb_endpoints[enum_endpoint_count].interval = 0; break; case USB_ENDPOINT_DESCRIPTOR_ATTR_ISOCHRONOUS: usb_endpoints[enum_endpoint_count].attributes = USB_ENDPOINT_DESCRIPTOR_ATTR_ISOCHRONOUS; usb_endpoints[enum_endpoint_count].max_packet_lo = usbs_testing_endpoints[i].max_size & 0x0FF; usb_endpoints[enum_endpoint_count].max_packet_hi = (usbs_testing_endpoints[i].max_size >> 8) & 0x0FF; usb_endpoints[enum_endpoint_count].interval = 1; break; case USB_ENDPOINT_DESCRIPTOR_ATTR_INTERRUPT: usb_endpoints[enum_endpoint_count].attributes = USB_ENDPOINT_DESCRIPTOR_ATTR_INTERRUPT; usb_endpoints[enum_endpoint_count].max_packet_lo = (unsigned char) usbs_testing_endpoints[i].max_size; usb_endpoints[enum_endpoint_count].max_packet_hi = 0; usb_endpoints[enum_endpoint_count].interval = 1; // NOTE: possibly incorrect break; } enum_endpoint_count++; } usb_interface.number_endpoints = enum_endpoint_count; usb_enum_data.total_number_endpoints = enum_endpoint_count; usb_configuration.total_length_lo = USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_LO(1, enum_endpoint_count); usb_configuration.total_length_hi = USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_HI(1, enum_endpoint_count); } /*}}}*/ /*{{{ Host/target common code */ #define TARGET #include "common.c" /*}}}*/ /*{{{ The tests */ /*{{{ UsbTest structure */ // ---------------------------------------------------------------------------- // All the information associated with a particular testcase. Much of this // is identical to the equivalent host-side structure, but some additional // information is needed so the structure and associated routines are not // shared. typedef struct UsbTest { // A unique identifier to make verbose output easier to understand int id; // 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; // The test result, to be collected and passed back to the host. int result_pass; char result_message[USBTEST_MAX_MESSAGE]; // Support for synchronization. This allows the UsbTest structure to be // used as the callback data for low-level USB calls. cyg_sem_t sem; int transferred; // Some tests may need extra cancellation support void (*cancel_fn)(struct UsbTest*); 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'; cyg_semaphore_init(&(test->sem), 0); test->transferred = 0; test->cancel_fn = (void (*)(UsbTest*)) 0; } // Forward declaration. The pool code depends on run_test(), setting up a test requires the pool. static UsbTest* pool_allocate(void); /*}}}*/ /*{{{ Bulk transfers */ /*{{{ handle_test_bulk() */ // Prepare for a bulk transfer test. This means allocating a thread to do // the work, and extracting the test parameters from the current buffer. // The thread allocation code does not require any locking since all worker // threads should be idle when starting a new thread, so the work can be // done entirely at DSR level and no synch is required. static usbs_control_return handle_test_bulk(usb_devreq* req) { UsbTest* test; int index = 0; test = pool_allocate(); unpack_usbtest_bulk(&(test->test_params.bulk), class_request, &index); test->which_test = (USB_DEVREQ_DIRECTION_IN == (test->test_params.bulk.endpoint & USB_DEVREQ_DIRECTION_MASK)) ? usbtest_bulk_in : usbtest_bulk_out; VERBOSE(3, "Preparing USB bulk test on endpoint %d, direction %s, for %d packets\n", \ test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK, \ (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); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ run_test_bulk_out() */ // The same callback can be used for IN and OUT transfers. Note that // starting the next transfer is left to the thread, it is not done // at DSR level. static void run_test_bulk_in_out_callback(void* callback_arg, int transferred) { UsbTest* test = (UsbTest*) callback_arg; test->transferred = transferred; cyg_semaphore_post(&(test->sem)); } // OUT transfers, i.e. the host will be sending some number of // packets. The I/O can happen in a number of different ways, e.g. via // the low-level USB API or via devtab routines. static void run_test_bulk_out(UsbTest* test) { unsigned char* buf; int endpoint_number = test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK; int ep_index; usbs_rx_endpoint* endpoint = 0; cyg_io_handle_t io_handle = (cyg_io_handle_t)0; int alignment; int transferred; int i; VERBOSE(1, "Starting test %d, bulk out on endpoint %d\n", test->id, endpoint_number); ep_index = lookup_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK); if (ep_index == -1) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk OUT transfer on endpoint %d: no such bulk endpoint", endpoint_number); return; } endpoint = (usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint; alignment = usbs_testing_endpoints[ep_index].alignment; if (0 != alignment) { buf = (unsigned char*) ((((cyg_uint32)test->buffer) + alignment - 1) & ~(alignment - 1)); } else { buf = test->buffer; } CYG_ASSERTC((usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) || \ (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism)); if (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) { if (((const char*)0 == usbs_testing_endpoints[ep_index].devtab_entry) || (0 != cyg_io_lookup(usbs_testing_endpoints[ep_index].devtab_entry, &io_handle))) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk OUT transfer on endpoint %d: no devtab entry", endpoint_number); return; } } // Make sure nobody else is using this endpoint lock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT); for (i = 0; i < test->test_params.bulk.number_packets; i++) { int rx_size = test->test_params.bulk.rx_size; int tx_size = test->test_params.bulk.tx_size; VERBOSE(2, "Bulk OUT 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 OUT test %d: iteration %d, packet size reset to %d to match tx size\n", test->id, i, rx_size); } test->recovery.endpoint = endpoint_number | USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT; test->recovery.protocol = USB_ENDPOINT_DESCRIPTOR_ATTR_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); } // Do the actual transfer, using the I/O mechanism specified for this test. switch (test->test_params.bulk.io_mechanism) { case usb_io_mechanism_usb : { test->transferred = 0; usbs_start_rx_buffer(endpoint, buf, rx_size, &run_test_bulk_in_out_callback, (void*) test); cyg_semaphore_wait(&(test->sem)); transferred = test->transferred; break; } case usb_io_mechanism_dev : { int result; transferred = rx_size; result = cyg_io_read(io_handle, (void*) buf, &transferred); if (result < 0) { transferred = result; } break; } default: CYG_FAIL("Invalid test mechanism specified"); break; } // Has this test 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, "Target, bulk OUT transfer on endpoint %d: transfer aborted after iteration %d", endpoint_number, i); break; } // If an error occurred, abort this run if (transferred < 0) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk OUT transfer on endpoint %d: transfer failed with %d", endpoint_number, transferred); VERBOSE(2, "Bulk OUT test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } // Did the host send the expected amount of data? if (transferred < test->test_params.bulk.tx_size) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk OUT transfer on endpoint %d : the host only sent %d bytes when %d were expected", endpoint_number, transferred, tx_size); VERBOSE(2, "Bulk OUT 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 OUT 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, transferred)) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk OUT transfer on endpoint %d : mismatch between received and expected data", endpoint_number); 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.rx_delay) { VERBOSE(2, "Bulk OUT test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, \ i, test->test_params.bulk.rx_delay); usbs_nanosleep(test->test_params.bulk.rx_delay); } // Move on to the next transfer USBTEST_BULK_NEXT(test->test_params.bulk); } // Always unlock the endpoint on completion unlock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT); // 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, endpoint_number, test->result_pass); } /*}}}*/ /*{{{ run_test_bulk_in() */ // IN transfers, i.e. the host is expected to receive some data. These are slightly // easier than OUT transfers because it is the host that will do the checking. static void run_test_bulk_in(UsbTest* test) { unsigned char* buf; int endpoint_number = test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK; int ep_index; usbs_tx_endpoint* endpoint = 0; cyg_io_handle_t io_handle = (cyg_io_handle_t)0; int alignment; int transferred; int i; VERBOSE(1, "Starting test %d, bulk IN on endpoint %d\n", test->id, endpoint_number); ep_index = lookup_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK); if (ep_index == -1) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk IN transfer on endpoint %d: no such bulk endpoint", endpoint_number); return; } endpoint = (usbs_tx_endpoint*) usbs_testing_endpoints[ep_index].endpoint; alignment = usbs_testing_endpoints[ep_index].alignment; if (0 != alignment) { buf = (unsigned char*) ((((cyg_uint32)test->buffer) + alignment - 1) & ~(alignment - 1)); } else { buf = test->buffer; } CYG_ASSERTC((usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) || \ (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism)); if (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) { if (((const char*)0 == usbs_testing_endpoints[ep_index].devtab_entry) || (0 != cyg_io_lookup(usbs_testing_endpoints[ep_index].devtab_entry, &io_handle))) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk IN transfer on endpoint %d: no devtab entry", endpoint_number); return; } } // Make sure nobody else is using this endpoint lock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN); for (i = 0; i < test->test_params.bulk.number_packets; i++) { int packet_size = test->test_params.bulk.tx_size; test->recovery.endpoint = endpoint_number | USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN; test->recovery.protocol = USB_ENDPOINT_DESCRIPTOR_ATTR_BULK; test->recovery.size = packet_size + usbs_testing_endpoints[ep_index].max_in_padding; // Make sure the buffer contains the data expected by the host 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 IN 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); } // Do the actual transfer, using the I/O mechanism specified for this test. switch (test->test_params.bulk.io_mechanism) { case usb_io_mechanism_usb : { test->transferred = 0; usbs_start_tx_buffer(endpoint, buf, packet_size, &run_test_bulk_in_out_callback, (void*) test); cyg_semaphore_wait(&(test->sem)); transferred = test->transferred; break; } case usb_io_mechanism_dev : { int result; transferred = packet_size; result = cyg_io_write(io_handle, (void*) buf, &transferred); if (result < 0) { transferred = result; } break; } default: CYG_FAIL("Invalid test mechanism specified"); break; } // Has this test been aborted for some reason? if (current_tests_terminated) { VERBOSE(2, "Bulk IN test %d: iteration %d, termination detected\n", test->id, i); test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk IN transfer on endpoint %d : terminated on iteration %d, packet_size %d\n", endpoint_number, i, packet_size); break; } // If an error occurred, abort this run if (transferred < 0) { test->result_pass = 0; snprintf(test->result_message, USBTEST_MAX_MESSAGE, "Target, bulk IN transfer on endpoint %d: transfer failed with %d", endpoint_number, transferred); VERBOSE(2, "Bulk IN test %d: iteration %d, error:\n %s\n", test->id, i, test->result_message); break; } // No need to check the transfer size, the USB code is only // allowed to send the exact amount of data requested. if (0 != test->test_params.bulk.tx_delay) { VERBOSE(2, "Bulk IN test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, i, \ test->test_params.bulk.tx_delay); usbs_nanosleep(test->test_params.bulk.tx_delay); } // Move on to the next transfer USBTEST_BULK_NEXT(test->test_params.bulk); } // Always unlock the endpoint on completion unlock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN); // 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, endpoint_number, test->result_pass); } /*}}}*/ /*}}}*/ /*{{{ Control IN transfers */ // Control-IN transfers. These have to be handled a little bit differently // from bulk transfers. The target never actually initiates anything. Instead // the host will send reserved control messages which are handled at DSR // level and passed to handle_reserved_control_messages() below. Assuming // a control-IN test is in progress, that will take appropriate action. The // thread will be woken up only once all packets have been transferred, or // on abnormal termination. // Is a control-IN test currently in progress? static UsbTest* control_in_test = 0; // What is the expected packet size? static int control_in_test_packet_size = 0; // How many packets have been transferred so far? static int control_in_packets_transferred = 0; // Cancel a control-in test. handle_test_control_in() will have updated the static // control_in_test so that handle_reserved_control_messages() knows what to do. // If the test is not actually going to be run then system consistency demands // that this update be undone. Also, the endpoint will have been locked to // detect concurrent tests on the control endpoint. static void cancel_test_control_in(UsbTest* test) { CYG_ASSERTC(test == control_in_test); control_in_test = (UsbTest*) 0; control_in_test_packet_size = 0; control_in_packets_transferred = 0; unlock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN); test->cancel_fn = (void (*)(UsbTest*)) 0; } // Prepare for a control-IN transfer test. static usbs_control_return handle_test_control_in(usb_devreq* req) { UsbTest* test; int index = 0; CYG_ASSERTC((UsbTest*)0 == control_in_test); test = pool_allocate(); unpack_usbtest_control_in(&(test->test_params.control_in), class_request, &index); lock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN); test->which_test = usbtest_control_in; test->recovery.endpoint = 0; test->recovery.protocol = USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL; test->recovery.size = 0; // Does not actually matter test->cancel_fn = &cancel_test_control_in; // Assume a pass. Failures are easy to detect. test->result_pass = 1; control_in_test = test; control_in_test_packet_size = test->test_params.control_in.packet_size_initial; control_in_packets_transferred = 0; return USBS_CONTROL_RETURN_HANDLED; } // The thread for a control-in test. Actually all the hard work is done at DSR // level, so this thread serves simply to detect when the test has completed // and to perform some clean-ups. static void run_test_control_in(UsbTest* test) { CYG_ASSERTC(test == control_in_test); cyg_semaphore_wait(&(test->sem)); // The DSR has detected that the test is complete. control_in_test = (UsbTest*) 0; control_in_test_packet_size = 0; control_in_packets_transferred = 0; test->cancel_fn = (void (*)(UsbTest*)) 0; unlock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN); } // ---------------------------------------------------------------------------- // This is installed from inside main() as the handler for reserved // control messages. static usbs_control_return handle_reserved_control_messages(usbs_control_endpoint* endpoint, void* data) { usb_devreq* req = (usb_devreq*) endpoint->control_buffer; usbs_control_return result; CYG_ASSERT(endpoint == control_endpoint, "control endpoint mismatch"); switch(req->request) { case USBTEST_RESERVED_CONTROL_IN: { unsigned char* buf; int len; if ((UsbTest*)0 == control_in_test) { result = USBS_CONTROL_RETURN_STALL; break; } // Is this test over? If so indicate a failure because we // cannot have received all the control packets. if (current_tests_terminated) { control_in_test->result_pass = 0; snprintf(control_in_test->result_message, USBTEST_MAX_MESSAGE, "Target, control IN transfer: not all packets received."); cyg_semaphore_post(&(control_in_test->sem)); control_in_test = (UsbTest*) 0; result = USBS_CONTROL_RETURN_STALL; break; } // A control-IN test is indeed in progress, and the current state is // held in control_in_test and control_in_test_packet_size. Check that // the packet size matches up, i.e. that host and target are in sync. len = (req->length_hi << 8) || req->length_lo; if (control_in_test_packet_size != len) { control_in_test->result_pass = 0; snprintf(control_in_test->result_message, USBTEST_MAX_MESSAGE, "Target, control IN transfer on endpoint %d : the host only requested %d bytes instead of %d", len, control_in_test_packet_size); cyg_semaphore_post(&(control_in_test->sem)); control_in_test = (UsbTest*) 0; result = USBS_CONTROL_RETURN_STALL; break; } // Prepare a suitable reply buffer. This is happening at // DSR level so runtime is important, but with an upper // bound of 255 bytes the buffer should be small enough. buf = control_in_test->buffer; usbtest_fill_buffer(&(control_in_test->test_params.control_in.data), buf, control_in_test_packet_size); control_endpoint->buffer_size = control_in_test_packet_size; control_endpoint->buffer = buf; USBTEST_CONTROL_NEXT_PACKET_SIZE(control_in_test_packet_size, control_in_test->test_params.control_in); // Have all the packets been transferred? control_in_packets_transferred++; if (control_in_packets_transferred == control_in_test->test_params.control_in.number_packets) { cyg_semaphore_post(&(control_in_test->sem)); control_in_test = (UsbTest*) 0; } result = USBS_CONTROL_RETURN_HANDLED; break; } default: CYG_FAIL("Unexpected reserved control message"); break; } return result; } /*}}}*/ // FIXME: add more tests. // 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: CYG_TEST_FAIL_EXIT("Internal error, attempt to run unknown test.\n"); break; } } /*}}}*/ /*{{{ The thread pool */ // ---------------------------------------------------------------------------- // Just like on the host side, it is desirable to have a pool of // threads available to perform test operations. Strictly speaking // some tests will run without needing a separate thread, since many // operations can be performed at DSR level. However typical // application code will involve threads and it is desirable for test // code to behave the same way. Also, some operations like validating // the transferred data are expensive, and best done in thread context. typedef struct PoolEntry { cyg_sem_t wakeup; cyg_thread thread_data; cyg_handle_t thread_handle; char thread_name[16]; char thread_stack[2 * CYGNUM_HAL_STACK_SIZE_TYPICAL]; cyg_bool in_use; cyg_bool running; UsbTest test; } PoolEntry; // This array must be uninitialized, or the executable size would // be ludicrous. PoolEntry pool[USBTEST_MAX_CONCURRENT_TESTS]; // The entry point for every thread in the pool. It just loops forever, // waiting until it is supposed to run a test. static void pool_thread_function(cyg_addrword_t arg) { PoolEntry* pool_entry = (PoolEntry*) arg; for ( ; ; ) { cyg_semaphore_wait(&(pool_entry->wakeup)); run_test(&(pool_entry->test)); pool_entry->running = 0; } } // Initialize all threads in the pool. static void pool_initialize(void) { int i; for (i = 0; i < USBTEST_MAX_CONCURRENT_TESTS; i++) { cyg_semaphore_init(&(pool[i].wakeup), 0); pool[i].in_use = 0; pool[i].running = 0; sprintf(pool[i].thread_name, "worker%d", i); cyg_thread_create( 0, &pool_thread_function, (cyg_addrword_t) &(pool[i]), pool[i].thread_name, pool[i].thread_stack, 2 * CYGNUM_HAL_STACK_SIZE_TYPICAL, &(pool[i].thread_handle), &(pool[i].thread_data)); cyg_thread_resume(pool[i].thread_handle); } } // Allocate a single entry in the thread pool static UsbTest* pool_allocate(void) { UsbTest* result = (UsbTest*) 0; if (thread_counter == USBTEST_MAX_CONCURRENT_TESTS) { CYG_TEST_FAIL_EXIT("Internal error, thread resources exhaused.\n"); } result = &(pool[thread_counter].test); thread_counter++; 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 < thread_counter; i++) { pool[i].running = 1; cyg_semaphore_post(&(pool[i].wakeup)); } } /*}}}*/ /*{{{ Class control messages */ // ---------------------------------------------------------------------------- // Handle class control messages. These provide the primary form of // communication between host and target. There are requests to find out // the number of endpoints, details of each endpoint, prepare a test run, // abort a test run, get status, terminate the target-side, and so on. // The handlers for starting specific test cases are kept alongside // the test cases themselves. // // Note that these handlers will typically be invoked from DSR context // and hence they are subject to the usual DSR restrictions. // // Problems have been experienced in some hosts sending control messages // that involve additional host->target data. An ugly workaround is // in place whereby any such data is sent in advance using separate // control messages. /*{{{ endpoint count */ // How many endpoints are supported by this device? That information is // determined during initialization. static usbs_control_return handle_endpoint_count(usb_devreq* req) { CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \ ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); class_reply[0] = (unsigned char) number_endpoints; control_endpoint->buffer = class_reply; control_endpoint->buffer_size = 1; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ endpoint details */ // The host wants to know the details of a specific USB endpoint. // The format is specified in protocol.h static usbs_control_return handle_endpoint_details(usb_devreq* req) { int buf_index; CYG_ASSERTC((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN); CYG_ASSERTC((USBTEST_MAX_CONTROL_DATA == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC(req->index_lo < number_endpoints); CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); class_reply[0] = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_type; class_reply[1] = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_number; class_reply[2] = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_direction; class_reply[3] = (unsigned char) usbs_testing_endpoints[req->index_lo].max_in_padding; buf_index = 4; pack_int(usbs_testing_endpoints[req->index_lo].min_size, class_reply, &buf_index); pack_int(usbs_testing_endpoints[req->index_lo].max_size, class_reply, &buf_index); if (NULL == usbs_testing_endpoints[req->index_lo].devtab_entry) { class_reply[buf_index] = '\0'; control_endpoint->buffer_size = buf_index + 1; } else { int len = strlen(usbs_testing_endpoints[req->index_lo].devtab_entry) + buf_index + 1; if (len > USBTEST_MAX_CONTROL_DATA) { return USBS_CONTROL_RETURN_STALL; } else { strcpy(&(class_reply[buf_index]), usbs_testing_endpoints[req->index_lo].devtab_entry); control_endpoint->buffer_size = len; } } control_endpoint->buffer = class_reply; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ sync */ // The host wants to know whether or not the target is currently busy doing // stuff. This information is held in a static. static usbs_control_return handle_sync(usb_devreq* req) { CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \ ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A sync operation should not involve any data"); class_reply[0] = (unsigned char) idle; control_endpoint->buffer = class_reply; control_endpoint->buffer_size = 1; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ pass/fail */ // Allow the host to generate some pass or fail messages, and // optionally terminate the test. These are synchronous requests // so the data can be left in class_request. static int passfail_request = 0; // Invoked from thread context static void handle_passfail_action(void) { switch (passfail_request) { case USBTEST_PASS: CYG_TEST_PASS(class_request); break; case USBTEST_PASS_EXIT: CYG_TEST_PASS(class_request); CYG_TEST_EXIT("Exiting normally as requested by the host"); break; case USBTEST_FAIL: CYG_TEST_FAIL(class_request); break; case USBTEST_FAIL_EXIT: CYG_TEST_FAIL(class_request); CYG_TEST_EXIT("Exiting normally as requested by the host"); break; default: CYG_FAIL("Bogus invocation of usbtest_main_passfail"); break; } } // Invoked from DSR context static usbs_control_return handle_passfail(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(class_request_size > 0, "A pass/fail message should be supplied"); CYG_ASSERT(idle, "Pass/fail messages are only allowed when idle"); CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending."); passfail_request = req->request; idle = false; main_thread_action = &handle_passfail_action; cyg_semaphore_post(&main_wakeup); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ abort */ // The host has concluded that there is no easy way to get both target and // host back to a sensible state. For example there may be a thread that // is blocked waiting for some I/O that is not going to complete. The abort // should be handled at thread level, not DSR level, so that the host // still sees the low-level USB handshake. static void handle_abort_action(void) { CYG_TEST_FAIL_EXIT("Test abort requested by host application"); } static usbs_control_return handle_abort(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(idle, "Abort messages are only allowed when idle"); CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending."); idle = false; main_thread_action = &handle_abort_action; cyg_semaphore_post(&main_wakeup); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ cancel */ // Invoked from thread context // Cancelling pending test cases simply involves iterating over the allocated // entries in the pool, invoking any cancellation functions that have been // defined, and then resetting the tread count. The actual tests have not // yet started so none of the threads will be active. static void handle_cancel_action(void) { int i; for (i = 0; i < thread_counter; i++) { if ((void (*)(UsbTest*))0 != pool[i].test.cancel_fn) { (*(pool[i].test.cancel_fn))(&(pool[i].test)); pool[i].test.cancel_fn = (void (*)(UsbTest*)) 0; } } thread_counter = 0; } // Invoked from DSR context static usbs_control_return handle_cancel(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A cancel operation should not involve any data"); CYG_ASSERT(idle, "Cancel requests are only allowed when idle"); CYG_ASSERT(!running, "Cancel requests cannot be sent once the system is running"); CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending."); idle = false; main_thread_action = &handle_cancel_action; cyg_semaphore_post(&main_wakeup); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ start */ // Start the tests running. This just involves waking up the pool threads // and setting the running flag, with the latter serving primarily for // assertions. static usbs_control_return handle_start(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A start operation should not involve any data"); CYG_ASSERT(!running, "Start requests cannot be sent if the system is already running"); current_tests_terminated = false; running = true; pool_start(); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ finished */ // Have all the tests finished? This involves checking all the threads // involved in the current batch of tests and seeing whether or not // their running flag is still set. static usbs_control_return handle_finished(usb_devreq* req) { int i; int result = 1; CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \ ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A finished operation should not involve any data"); CYG_ASSERT(running, "Finished requests can only be sent if the system is already running"); for (i = 0; i < thread_counter; i++) { if (pool[i].running) { result = 0; break; } } class_reply[0] = (unsigned char) result; control_endpoint->buffer = class_reply; control_endpoint->buffer_size = 1; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ set terminated */ // A timeout has occurred, or there is some other failure. The first step // in recovery is to set the terminated flag so that as recovery action // takes place and the threads wake up they make no attempt to continue // doing more transfers. static usbs_control_return handle_set_terminated(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A set-terminated operation should not involve any data"); CYG_ASSERT(running, "The terminated flag can only be set when there are running tests"); current_tests_terminated = 1; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ get recovery */ // Return the recovery information for one of the threads involved in the // current batch of tests, so that the host can perform a USB operation // that will sort out that thread. static usbs_control_return handle_get_recovery(usb_devreq* req) { int buffer_index; CYG_ASSERT(current_tests_terminated, "Recovery should only be attempted when the terminated flag is set"); CYG_ASSERT(running, "If there are no tests running then recovery is impossible"); CYG_ASSERTC((12 == req->length_lo) && (0 == req->length_hi) && \ ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN)); CYG_ASSERTC(req->index_lo <= thread_counter); CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A get-recovery operation should not involve any data"); control_endpoint->buffer = class_reply; if (!pool[req->index_lo].running) { // Actually, this particular thread has terminated so no recovery is needed. control_endpoint->buffer_size = 0; } else { buffer_index = 0; pack_usbtest_recovery(&(pool[req->index_lo].test.recovery), class_reply, &buffer_index); control_endpoint->buffer_size = buffer_index; } return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ perform recovery */ // The host has identified a course of action that could unlock a thread // on the host-side that is currently blocked performing a USB operation. // Typically this involves either sending or accepting some data. If the // endpoint is still locked, in other words if there is a still a local // thread attempting to communicate on the specified endpoint, then // things are messed up: both sides are trying to communicate, but nothing // is happening. The eCos USB API is such that attempting multiple // concurrent operations on a single endpoint is disallowed, so // the recovery request has to be ignored. If things do not sort themselves // out then the whole test run will have to be aborted. // A dummy completion function for when a recovery operation has completed. static void recovery_callback(void* callback_arg, int transferred) { CYG_UNUSED_PARAM(void*, callback_arg); CYG_UNUSED_PARAM(int, transferred); } static usbs_control_return handle_perform_recovery(usb_devreq* req) { int buffer_index; int endpoint_number; int endpoint_direction; UsbTest_Recovery recovery; CYG_ASSERT(current_tests_terminated, "Recovery should only be attempted when the terminated flag is set"); CYG_ASSERT(running, "If there are no tests running then recovery is impossible"); CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(12 == class_request_size, "A perform-recovery operation requires recovery data"); buffer_index = 0; unpack_usbtest_recovery(&recovery, class_request, &buffer_index); endpoint_number = recovery.endpoint & ~USB_DEVREQ_DIRECTION_MASK; endpoint_direction = recovery.endpoint & USB_DEVREQ_DIRECTION_MASK; if (!is_endpoint_locked(endpoint_number, endpoint_direction)) { // Locking the endpoint here would be good, but the endpoint would then // have to be unlocked again - probably in the recovery callback. // This complication is ignored for now. if (USB_ENDPOINT_DESCRIPTOR_ATTR_BULK == recovery.protocol) { int ep_index = lookup_endpoint(endpoint_number, endpoint_direction, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK); CYG_ASSERTC(-1 != ep_index); if (USB_DEVREQ_DIRECTION_IN == endpoint_direction) { // The host wants some data. Supply it. A single byte will do fine to // complete the transfer. usbs_start_tx_buffer((usbs_tx_endpoint*) usbs_testing_endpoints[ep_index].endpoint, recovery_buffer, 1, &recovery_callback, (void*) 0); } else { // The host is trying to send some data. Accept all of it. usbs_start_rx_buffer((usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint, recovery_buffer, recovery.size, &recovery_callback, (void*) 0); } } // No support for isochronous or interrupt transfers yet. // handle_reserved_control_messages() should generate stalls which // have the desired effect. } return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ get result */ // Return the result of one the tests. This can be a single byte for // a pass, or a single byte plus a message for a failure. static usbs_control_return handle_get_result(usb_devreq* req) { CYG_ASSERTC((USBTEST_MAX_CONTROL_DATA == req->length_lo) && (0 == req->length_hi) && \ ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN)); CYG_ASSERTC(req->index_lo <= thread_counter); CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A get-result operation should not involve any data"); CYG_ASSERT(running, "Results can only be sent if a run is in progress"); CYG_ASSERT(!pool[req->index_lo].running, "Cannot request results for a test that has not completed"); class_reply[0] = pool[req->index_lo].test.result_pass; if (class_reply[0]) { control_endpoint->buffer_size = 1; } else { strncpy(&(class_reply[1]), pool[req->index_lo].test.result_message, USBTEST_MAX_CONTROL_DATA - 2); class_reply[USBTEST_MAX_CONTROL_DATA - 1] = '\0'; control_endpoint->buffer_size = 1 + strlen(&(class_reply[1])) + 1; } control_endpoint->buffer = class_reply; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ batch done */ // A batch of test has been completed - at least, the host thinks so. // If the host is correct then all that is required here is to reset // the thread pool and clear the global running flag - that is sufficient // to allow a new batch of tests to be started. static usbs_control_return handle_batch_done(usb_devreq* req) { int i; CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi)); CYG_ASSERT(0 == class_request_size, "A batch-done operation should not involve any data"); CYG_ASSERT(running, "There must be a current batch of tests"); for (i = 0; i < thread_counter; i++) { CYG_ASSERTC(!pool[i].running); } thread_counter = 0; running = false; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ verbosity */ static usbs_control_return handle_verbose(usb_devreq* req) { CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi)); CYG_ASSERT(0 == class_request_size, "A set-verbosity operation should not involve any data"); verbose = (req->value_hi << 8) + req->value_lo; return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ initialise bulk out endpoint */ // ---------------------------------------------------------------------------- // Accept an initial endpoint on a bulk endpoint. This avoids problems // on some hardware such as the SA11x0 which can start to accept data // before the software is ready for it. static void handle_init_callback(void* arg, int result) { idle = true; } static usbs_control_return handle_init_bulk_out(usb_devreq* req) { static char buf[64]; int ep_index; usbs_rx_endpoint* endpoint; CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi)); CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi)); CYG_ASSERTC((0 == req->value_hi) && (0 < req->value_lo) && (req->value_lo < 16)); CYG_ASSERT(0 == class_request_size, "An init_bulk_out operation should not involve any data"); ep_index = lookup_endpoint(req->value_lo, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK); CYG_ASSERTC(-1 != ep_index); endpoint = (usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint; idle = false; usbs_start_rx_buffer(endpoint, buf, 64, &handle_init_callback, (void*) 0); return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ /*{{{ additional control data */ // Accumulate some more data in the control buffer, ahead of an upcoming // request. static usbs_control_return handle_control_data(usb_devreq* req) { class_request[class_request_size + 0] = req->value_hi; class_request[class_request_size + 1] = req->value_lo; class_request[class_request_size + 2] = req->index_hi; class_request[class_request_size + 3] = req->index_lo; switch(req->request) { case USBTEST_CONTROL_DATA1 : class_request_size += 1; break; case USBTEST_CONTROL_DATA2 : class_request_size += 2; break; case USBTEST_CONTROL_DATA3 : class_request_size += 3; break; case USBTEST_CONTROL_DATA4 : class_request_size += 4; break; } return USBS_CONTROL_RETURN_HANDLED; } /*}}}*/ typedef struct class_handler { int request; usbs_control_return (*handler)(usb_devreq*); } class_handler; static class_handler class_handlers[] = { { USBTEST_ENDPOINT_COUNT, &handle_endpoint_count }, { USBTEST_ENDPOINT_DETAILS, &handle_endpoint_details }, { USBTEST_PASS, &handle_passfail }, { USBTEST_PASS_EXIT, &handle_passfail }, { USBTEST_FAIL, &handle_passfail }, { USBTEST_FAIL_EXIT, &handle_passfail }, { USBTEST_SYNCH, &handle_sync }, { USBTEST_ABORT, &handle_abort }, { USBTEST_CANCEL, &handle_cancel }, { USBTEST_START, &handle_start }, { USBTEST_FINISHED, &handle_finished }, { USBTEST_SET_TERMINATED, &handle_set_terminated }, { USBTEST_GET_RECOVERY, &handle_get_recovery }, { USBTEST_PERFORM_RECOVERY, &handle_perform_recovery }, { USBTEST_GET_RESULT, &handle_get_result }, { USBTEST_BATCH_DONE, &handle_batch_done }, { USBTEST_VERBOSE, &handle_verbose }, { USBTEST_INIT_BULK_OUT, &handle_init_bulk_out }, { USBTEST_TEST_BULK, &handle_test_bulk }, { USBTEST_TEST_CONTROL_IN, &handle_test_control_in }, { USBTEST_CONTROL_DATA1, &handle_control_data }, { USBTEST_CONTROL_DATA2, &handle_control_data }, { USBTEST_CONTROL_DATA3, &handle_control_data }, { USBTEST_CONTROL_DATA4, &handle_control_data }, { -1, (usbs_control_return (*)(usb_devreq*)) 0 } }; static usbs_control_return handle_class_control_messages(usbs_control_endpoint* endpoint, void* data) { usb_devreq* req = (usb_devreq*) endpoint->control_buffer; int request = req->request; usbs_control_return result; int i; VERBOSE(3, "Received control message %02x\n", request); CYG_ASSERT(endpoint == control_endpoint, "control endpoint mismatch"); result = USBS_CONTROL_RETURN_UNKNOWN; for (i = 0; (usbs_control_return (*)(usb_devreq*))0 != class_handlers[i].handler; i++) { if (request == class_handlers[i].request) { result = (*(class_handlers[i].handler))(req); if ((USBTEST_CONTROL_DATA1 != request) && (USBTEST_CONTROL_DATA2 != request) && (USBTEST_CONTROL_DATA3 != request) && (USBTEST_CONTROL_DATA4 != request)) { // Reset the request data buffer after all normal requests. class_request_size = 0; } break; } } CYG_UNUSED_PARAM(void*, data); if (USBS_CONTROL_RETURN_HANDLED != result) { VERBOSE(1, "Control message %02x not handled\n", request); } return result; } /*}}}*/ /*{{{ main() */ // ---------------------------------------------------------------------------- // Initialization. int main(int argc, char** argv) { int i; CYG_TEST_INIT(); // The USB device driver should have provided an array of endpoint // descriptors, usbs_testing_endpoints(). One entry in this array // should be a control endpoint, which is needed for initialization. // It is also useful to know how many endpoints there are. for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) { if ((0 == usbs_testing_endpoints[i].endpoint_number) && (USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL== usbs_testing_endpoints[i].endpoint_type)) { CYG_ASSERT((usbs_control_endpoint*)0 == control_endpoint, "There should be only one control endpoint"); control_endpoint = (usbs_control_endpoint*) usbs_testing_endpoints[i].endpoint; } } if ((usbs_control_endpoint*)0 == control_endpoint) { CYG_TEST_FAIL_EXIT("Unable to find a USB control endpoint"); } number_endpoints = i; CYG_ASSERT(number_endpoints <= USBTEST_MAX_ENDPOINTS, "impossible number of endpoints"); // Some of the information provided may not match the actual capabilities // of the testing code, e.g. max_size limits. fix_driver_endpoint_data(); // This semaphore is used for communication between the DSRs that process control // messages and the main thread cyg_semaphore_init(&main_wakeup, 0); // Take care of the pool of threads and related data. pool_initialize(); // Start the heartbeat thread, to make sure that the gdb session stays // alive. start_heartbeat(); // Now it is possible to start up the USB device driver. The host can detect // this, connect, get the enumeration data, and then testing will proceed // in response to class control messages. provide_endpoint_enumeration_data(); control_endpoint->enumeration_data = &usb_enum_data; control_endpoint->class_control_fn = &handle_class_control_messages; control_endpoint->reserved_control_fn = &handle_reserved_control_messages; usbs_start(control_endpoint); // Now it is over to the host to detect this target and start performing tests. // Much of this is handled at DSR level, in response to USB control messages. // Some of those control messages require action at thread level, and that is // achieved by signalling a semaphore and waking up this thread. A static // function pointer is used to keep track of what operation is actually required. for (;;) { void (*handler)(void); cyg_semaphore_wait(&main_wakeup); handler = main_thread_action; main_thread_action = 0; CYG_CHECK_FUNC_PTR(handler, "Main thread woken up when there is nothing to be done"); (*handler)(); idle = true; } } /*}}}*/
Go to most recent revision | Compare with Previous | Blame | View Log