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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [io/] [usb/] [slave/] [v2_0/] [tests/] [usbtarget.c] - Blame information for rev 646

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/*{{{  Banner                                                   */
2
 
3
/*=================================================================
4
//
5
//        target.c
6
//
7
//        USB testing - target-side
8
//
9
//==========================================================================
10
//####ECOSGPLCOPYRIGHTBEGIN####
11
// -------------------------------------------
12
// This file is part of eCos, the Embedded Configurable Operating System.
13
// Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc.
14
//
15
// eCos is free software; you can redistribute it and/or modify it under
16
// the terms of the GNU General Public License as published by the Free
17
// Software Foundation; either version 2 or (at your option) any later version.
18
//
19
// eCos is distributed in the hope that it will be useful, but WITHOUT ANY
20
// WARRANTY; without even the implied warranty of MERCHANTABILITY or
21
// FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
22
// for more details.
23
//
24
// You should have received a copy of the GNU General Public License along
25
// with eCos; if not, write to the Free Software Foundation, Inc.,
26
// 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
27
//
28
// As a special exception, if other files instantiate templates or use macros
29
// or inline functions from this file, or you compile this file and link it
30
// with other works to produce a work based on this file, this file does not
31
// by itself cause the resulting work to be covered by the GNU General Public
32
// License. However the source code for this file must still be made available
33
// in accordance with section (3) of the GNU General Public License.
34
//
35
// This exception does not invalidate any other reasons why a work based on
36
// this file might be covered by the GNU General Public License.
37
//
38
// Alternative licenses for eCos may be arranged by contacting Red Hat, Inc.
39
// at http://sources.redhat.com/ecos/ecos-license/
40
// -------------------------------------------
41
//####ECOSGPLCOPYRIGHTEND####
42
//==========================================================================
43
//#####DESCRIPTIONBEGIN####
44
//
45
// This program performs appropriate USB initialization and initializes
46
// itself as a specific type of USB peripheral, Red Hat eCos testing.
47
// There is no actual host-side device driver for this, instead there is
48
// a test application which performs ioctl's on /proc/bus/usb/... and
49
// makes appropriate functionality available to a Tcl script.
50
//
51
// Author(s):     bartv
52
// Date:          2001-07-04
53
//####DESCRIPTIONEND####
54
//==========================================================================
55
*/
56
 
57
/*}}}*/
58
/*{{{  #include's                                               */
59
 
60
#include <stdio.h>
61
#include <cyg/infra/cyg_ass.h>
62
#include <cyg/infra/diag.h>
63
#include <cyg/kernel/kapi.h>
64
#include <cyg/hal/hal_arch.h>
65
#include <cyg/io/io.h>
66
#include <cyg/io/usb/usbs.h>
67
#include <cyg/infra/testcase.h>
68
#include "protocol.h"
69
 
70
/*}}}*/
71
 
72
/*{{{  Statics                                                  */
73
 
74
// ----------------------------------------------------------------------------
75
// Statics.
76
 
77
// The number of endpoints supported by the device driver.
78
static int number_endpoints     = 0;
79
 
80
// The control endpoint
81
static usbs_control_endpoint* control_endpoint = (usbs_control_endpoint*) 0;
82
 
83
// Buffers for incoming and outgoing data, and a length field.
84
static unsigned char class_request[USBTEST_MAX_CONTROL_DATA + 1];
85
static unsigned char class_reply[USBTEST_MAX_CONTROL_DATA + 1];
86
static int           class_request_size  = 0;
87
 
88
// This semaphore is used by DSRs to wake up the main thread when work has to
89
// be done at thread level.
90
static cyg_sem_t    main_wakeup;
91
 
92
// And this function pointer identifies the work that has to be done.
93
static void         (*main_thread_action)(void)  = (void (*)(void)) 0;
94
 
95
// Is the system still busy processing a previous request? This variable is
96
// checked in response to the synch request. It may get updated in
97
// DSRs as well as at thread level, hence volatile.
98
static volatile int idle    = 1;
99
 
100
// Are any tests currently running?
101
static int          running = 0;
102
 
103
// Has the current batch of tests been terminated by the host? This
104
// flag is checked by the various test handlers at appropriate
105
// intervals, and helps to handle the case where one of the side has
106
// terminated early because an error has been detected.
107
static int          current_tests_terminated = 0;
108
 
109
// A counter for the number of threads involved in the current batch of tests.
110
static int          thread_counter    = 0;
111
 
112
// An extra buffer for recovery operations, for example to accept and discard
113
// data which the host is still trying to send.
114
static unsigned char recovery_buffer[USBTEST_MAX_BULK_DATA + USBTEST_MAX_BULK_DATA_EXTRA];
115
 
116
/*}}}*/
117
/*{{{  Logging                                                  */
118
 
119
// ----------------------------------------------------------------------------
120
// The target-side code can provide various levels of run-time logging.
121
// Obviously the verbose flag cannot be controlled by a command-line
122
// argument, but it can be set from inside gdb or alternatively by
123
// a request from the host.
124
//
125
// NOTE: is printf() the best I/O routine to use here?
126
 
127
static int verbose = 0;
128
 
129
#define VERBOSE(_level_, _format_, _args_...)   \
130
    do {                                        \
131
        if (verbose >= _level_) {               \
132
            diag_printf(_format_, ## _args_);        \
133
        }                                       \
134
    } while (0);
135
 
136
/*}}}*/
137
/*{{{  Utilities                                                */
138
 
139
// ----------------------------------------------------------------------------
140
// A reimplementation of nanosleep, to avoid having to pull in the
141
// POSIX compatibility testing for USB testing.
142
static void
143
usbs_nanosleep(int delay)
144
{
145
    cyg_tick_count_t ticks;
146
    cyg_resolution_t resolution = cyg_clock_get_resolution(cyg_real_time_clock());
147
 
148
    // (resolution.dividend/resolution.divisor) == nanoseconds/tick
149
    //   e.g. 1000000000/100, i.e. 10000000 ns or 10 ms per tick
150
    // So ticks = (delay * divisor) / dividend
151
    //   e.g. (10000000 * 100) / 1000000000
152
    // with a likely value of 0 for delays of less than the clock resolution,
153
    // so round those up to one tick.
154
 
155
    cyg_uint64 tmp = (cyg_uint64) delay;
156
    tmp *= (cyg_uint64) resolution.divisor;
157
    tmp /= (cyg_uint64) resolution.dividend;
158
 
159
    ticks = (int) tmp;
160
    if (0 != ticks) {
161
        cyg_thread_delay(ticks);
162
    }
163
}
164
 
165
// ----------------------------------------------------------------------------
166
// Fix any problems in the driver-supplied endpoint data
167
//
168
// Maximum transfer sizes are limited not just by the capabilities
169
// of the driver but also by the testing code itself, since e.g.
170
// buffers for transfers are statically allocated.
171
static void
172
fix_driver_endpoint_data(void)
173
{
174
    int i;
175
 
176
    for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) {
177
        if (USB_ENDPOINT_DESCRIPTOR_ATTR_BULK == usbs_testing_endpoints[i].endpoint_type) {
178
            if ((-1 == usbs_testing_endpoints[i].max_size) ||
179
                (usbs_testing_endpoints[i].max_size > USBTEST_MAX_BULK_DATA)) {
180
                usbs_testing_endpoints[i].max_size = USBTEST_MAX_BULK_DATA;
181
            }
182
        }
183
    }
184
}
185
 
186
// ----------------------------------------------------------------------------
187
// A heartbeat thread.
188
//
189
// USB tests can run for a long time with no traffic on the debug channel,
190
// which can cause problems. To avoid problems it is possible to have a
191
// heartbeat thread running in the background, sending output at one
192
// second intervals.
193
//
194
// Depending on the configuration the output may still be line-buffered,
195
// but that is still sufficient to keep things happy.
196
 
197
static cyg_bool     heartbeat = false;
198
static cyg_thread   heartbeat_data;
199
static cyg_handle_t heartbeat_handle;
200
static char         heartbeat_stack[CYGNUM_HAL_STACK_SIZE_TYPICAL];
201
 
202
static void
203
heartbeat_function(cyg_addrword_t arg __attribute((unused)))
204
{
205
    char* message = "alive\n";
206
    int i;
207
 
208
    for ( i = 0; ; i = (i + 1) % 6) {
209
        usbs_nanosleep(1000000000);
210
        if (heartbeat) {
211
            diag_write_char(message[i]);
212
        }
213
    }
214
}
215
 
216
static void
217
start_heartbeat(void)
218
{
219
    cyg_thread_create( 0, &heartbeat_function, 0,
220
                       "heartbeat", heartbeat_stack, CYGNUM_HAL_STACK_SIZE_TYPICAL,
221
                       &heartbeat_handle, &heartbeat_data);
222
    cyg_thread_resume(heartbeat_handle);
223
}
224
 
225
 
226
/*}}}*/
227
/*{{{  Endpoint usage                                           */
228
 
229
// ----------------------------------------------------------------------------
230
// It is important to keep track of which endpoints are currently in use,
231
// because the behaviour of the USB I/O routines is undefined if there are
232
// concurrent attempts to communicate on the same endpoint. Normally this is
233
// not a problem because the host will ensure that a given endpoint is used
234
// for only one endpoint at a time, but when performing recovery action it
235
// is important that the system is sure that a given endpoint can be accessed
236
// safely.
237
 
238
static cyg_bool in_endpoint_in_use[16];
239
static cyg_bool out_endpoint_in_use[16];
240
 
241
// Lock the given endpoint. In theory this is only ever accessed from a single
242
// test thread at a time, but just in case...
243
static void
244
lock_endpoint(int endpoint, int direction)
245
{
246
    CYG_ASSERTC((endpoint >=0) && (endpoint < 16));
247
    CYG_ASSERTC((USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) || (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT == direction));
248
 
249
    cyg_scheduler_lock();
250
    if (0 == endpoint) {
251
        // Comms traffic on endpoint 0 is implemented using reserved control messages.
252
        // It is not really possible to have concurrent IN and OUT operations because
253
        // the two would interfere with each other.
254
        CYG_ASSERTC(!in_endpoint_in_use[0] && !out_endpoint_in_use[0]);
255
        in_endpoint_in_use[0]  = true;
256
        out_endpoint_in_use[0] = true;
257
    } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) {
258
        CYG_ASSERTC(!in_endpoint_in_use[endpoint]);
259
        in_endpoint_in_use[endpoint] = true;
260
    } else {
261
        CYG_ASSERTC(!out_endpoint_in_use[endpoint]);
262
        out_endpoint_in_use[endpoint] = true;
263
    }
264
    cyg_scheduler_unlock();
265
}
266
 
267
static void
268
unlock_endpoint(int endpoint, int direction)
269
{
270
    CYG_ASSERTC((endpoint >= 0) && (endpoint < 16));
271
    CYG_ASSERTC((USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) || (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT == direction));
272
 
273
    if (0 == endpoint) {
274
        CYG_ASSERTC(in_endpoint_in_use[0] && out_endpoint_in_use[0]);
275
        in_endpoint_in_use[0]   = false;
276
        out_endpoint_in_use[0]  = false;
277
    } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) {
278
        CYG_ASSERTC(in_endpoint_in_use[endpoint]);
279
        in_endpoint_in_use[endpoint] = false;
280
    } else {
281
        CYG_ASSERTC(out_endpoint_in_use[endpoint]);
282
        out_endpoint_in_use[endpoint] = false;
283
    }
284
}
285
 
286
static cyg_bool
287
is_endpoint_locked(int endpoint, int direction)
288
{
289
    cyg_bool    result = false;
290
 
291
    if (0 == endpoint) {
292
        result = in_endpoint_in_use[0];
293
    } else if (USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN == direction) {
294
        result = in_endpoint_in_use[endpoint];
295
    } else {
296
        result = out_endpoint_in_use[endpoint];
297
    }
298
    return result;
299
}
300
 
301
// For a given endpoint number, direction and protocol, search through the table 
302
// supplied by the device driver of all available endpoints. This can be used
303
// to e.g. get hold of the name of the devtab entry or a pointer to the endpoint
304
// data structure itself.
305
static int
306
lookup_endpoint(int endpoint_number, int direction, int protocol)
307
{
308
    int result = -1;
309
    int i;
310
 
311
    for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) {
312
        if ((usbs_testing_endpoints[i].endpoint_type        == protocol)        &&
313
            (usbs_testing_endpoints[i].endpoint_number      == endpoint_number) &&
314
            (usbs_testing_endpoints[i].endpoint_direction   == direction)) {
315
            result = i;
316
            break;
317
        }
318
    }
319
    return result;
320
}
321
 
322
/*}}}*/
323
/*{{{  Enumeration data                                         */
324
 
325
// ----------------------------------------------------------------------------
326
// The enumeration data.
327
//
328
// For simplicity this configuration involves just a single interface.
329
// The target has to list all the endpoints, or the Linux kernel will
330
// not allow application code to access them. Hence the information
331
// provided by the device drivers has to be turned into endpoint descriptors.
332
 
333
usb_configuration_descriptor usb_configuration = {
334
    length:             USB_CONFIGURATION_DESCRIPTOR_LENGTH,
335
    type:               USB_CONFIGURATION_DESCRIPTOR_TYPE,
336
    total_length_lo:    USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_LO(1, 0),
337
    total_length_hi:    USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_HI(1, 0),
338
    number_interfaces:  1,
339
    configuration_id:   1,      // id 0 is special according to the spec
340
    configuration_str:  0,
341
    attributes:         USB_CONFIGURATION_DESCRIPTOR_ATTR_REQUIRED |
342
                        USB_CONFIGURATION_DESCRIPTOR_ATTR_SELF_POWERED,
343
    max_power:          50
344
};
345
 
346
usb_interface_descriptor usb_interface = {
347
    length:             USB_INTERFACE_DESCRIPTOR_LENGTH,
348
    type:               USB_INTERFACE_DESCRIPTOR_TYPE,
349
    interface_id:       0,
350
    alternate_setting:  0,
351
    number_endpoints:   0,
352
    interface_class:    USB_INTERFACE_DESCRIPTOR_CLASS_VENDOR,
353
    interface_subclass: USB_INTERFACE_DESCRIPTOR_SUBCLASS_VENDOR,
354
    interface_protocol: USB_INTERFACE_DESCRIPTOR_PROTOCOL_VENDOR,
355
    interface_str:      0
356
};
357
 
358
usb_endpoint_descriptor usb_endpoints[USBTEST_MAX_ENDPOINTS];
359
 
360
const unsigned char* usb_strings[] = {
361
    "\004\003\011\004",
362
    "\020\003R\000e\000d\000 \000H\000a\000t\000",
363
    "\054\003R\000e\000d\000 \000H\000a\000t\000 \000e\000C\000o\000s\000 \000"
364
    "U\000S\000B\000 \000t\000e\000s\000t\000"
365
};
366
 
367
usbs_enumeration_data usb_enum_data = {
368
    {
369
        length:                 USB_DEVICE_DESCRIPTOR_LENGTH,
370
        type:                   USB_DEVICE_DESCRIPTOR_TYPE,
371
        usb_spec_lo:            USB_DEVICE_DESCRIPTOR_USB11_LO,
372
        usb_spec_hi:            USB_DEVICE_DESCRIPTOR_USB11_HI,
373
        device_class:           USB_DEVICE_DESCRIPTOR_CLASS_VENDOR,
374
        device_subclass:        USB_DEVICE_DESCRIPTOR_SUBCLASS_VENDOR,
375
        device_protocol:        USB_DEVICE_DESCRIPTOR_PROTOCOL_VENDOR,
376
        max_packet_size:        8,
377
        vendor_lo:              0x42,   // Note: this is not an allocated vendor id
378
        vendor_hi:              0x42,
379
        product_lo:             0x00,
380
        product_hi:             0x01,
381
        device_lo:              0x00,
382
        device_hi:              0x01,
383
        manufacturer_str:       1,
384
        product_str:            2,
385
        serial_number_str:      0,
386
        number_configurations:  1
387
    },
388
    total_number_interfaces:    1,
389
    total_number_endpoints:     0,
390
    total_number_strings:       3,
391
    configurations:             &usb_configuration,
392
    interfaces:                 &usb_interface,
393
    endpoints:                  usb_endpoints,
394
    strings:                    usb_strings
395
};
396
 
397
static void
398
provide_endpoint_enumeration_data(void)
399
{
400
    int enum_endpoint_count = 0;
401
    int i;
402
 
403
    for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) {
404
 
405
        // The control endpoint need not appear in the enumeration data.
406
        if (USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL == usbs_testing_endpoints[i].endpoint_type) {
407
            continue;
408
        }
409
 
410
        usb_endpoints[enum_endpoint_count].length          = USB_ENDPOINT_DESCRIPTOR_LENGTH;
411
        usb_endpoints[enum_endpoint_count].type            = USB_ENDPOINT_DESCRIPTOR_TYPE;
412
        usb_endpoints[enum_endpoint_count].endpoint        = usbs_testing_endpoints[i].endpoint_number |
413
                                                             usbs_testing_endpoints[i].endpoint_direction;
414
 
415
        switch (usbs_testing_endpoints[i].endpoint_type) {
416
          case USB_ENDPOINT_DESCRIPTOR_ATTR_BULK:
417
            usb_endpoints[enum_endpoint_count].attributes      = USB_ENDPOINT_DESCRIPTOR_ATTR_BULK;
418
            usb_endpoints[enum_endpoint_count].max_packet_lo   = 64;
419
            usb_endpoints[enum_endpoint_count].max_packet_hi   = 0;
420
            usb_endpoints[enum_endpoint_count].interval        = 0;
421
            break;
422
 
423
          case USB_ENDPOINT_DESCRIPTOR_ATTR_ISOCHRONOUS:
424
            usb_endpoints[enum_endpoint_count].attributes      = USB_ENDPOINT_DESCRIPTOR_ATTR_ISOCHRONOUS;
425
            usb_endpoints[enum_endpoint_count].max_packet_lo   = usbs_testing_endpoints[i].max_size & 0x0FF;
426
            usb_endpoints[enum_endpoint_count].max_packet_hi   = (usbs_testing_endpoints[i].max_size >> 8) & 0x0FF;
427
            usb_endpoints[enum_endpoint_count].interval        = 1;
428
            break;
429
 
430
          case USB_ENDPOINT_DESCRIPTOR_ATTR_INTERRUPT:
431
            usb_endpoints[enum_endpoint_count].attributes      = USB_ENDPOINT_DESCRIPTOR_ATTR_INTERRUPT;
432
            usb_endpoints[enum_endpoint_count].max_packet_lo   = (unsigned char) usbs_testing_endpoints[i].max_size;
433
            usb_endpoints[enum_endpoint_count].max_packet_hi   = 0;
434
            usb_endpoints[enum_endpoint_count].interval        = 1;    // NOTE: possibly incorrect
435
            break;
436
        }
437
 
438
        enum_endpoint_count++;
439
    }
440
 
441
    usb_interface.number_endpoints          = enum_endpoint_count;
442
    usb_enum_data.total_number_endpoints    = enum_endpoint_count;
443
    usb_configuration.total_length_lo       = USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_LO(1, enum_endpoint_count);
444
    usb_configuration.total_length_hi       = USB_CONFIGURATION_DESCRIPTOR_TOTAL_LENGTH_HI(1, enum_endpoint_count);
445
}
446
 
447
/*}}}*/
448
/*{{{  Host/target common code                                  */
449
 
450
#define TARGET
451
#include "common.c"
452
 
453
/*}}}*/
454
/*{{{  The tests                                                */
455
 
456
/*{{{  UsbTest structure                                        */
457
 
458
// ----------------------------------------------------------------------------
459
// All the information associated with a particular testcase. Much of this
460
// is identical to the equivalent host-side structure, but some additional
461
// information is needed so the structure and associated routines are not
462
// shared.
463
typedef struct UsbTest {
464
 
465
    // A unique identifier to make verbose output easier to understand
466
    int                 id;
467
 
468
    // Which test should be run
469
    usbtest             which_test;
470
 
471
    // Test-specific details.
472
    union {
473
        UsbTest_Bulk        bulk;
474
        UsbTest_ControlIn   control_in;
475
    } test_params;
476
 
477
    // How to recover from any problems. Specifically, what kind of message
478
    // could the target send or receive that would unlock the thread on this
479
    // side.
480
    UsbTest_Recovery    recovery;
481
 
482
    // The test result, to be collected and passed back to the host.
483
    int                 result_pass;
484
    char                result_message[USBTEST_MAX_MESSAGE];
485
 
486
    // Support for synchronization. This allows the UsbTest structure to be
487
    // used as the callback data for low-level USB calls.
488
    cyg_sem_t           sem;
489
    int                 transferred;
490
 
491
    // Some tests may need extra cancellation support
492
    void                (*cancel_fn)(struct UsbTest*);
493
    unsigned char       buffer[USBTEST_MAX_BULK_DATA + USBTEST_MAX_BULK_DATA_EXTRA];
494
} UsbTest;
495
 
496
// Reset the information in a given test. This is used by the pool allocation
497
// code. The data union is left alone, filling in the appropriate union
498
// member is left to other code.
499
static void
500
reset_usbtest(UsbTest* test)
501
{
502
    static int next_id = 1;
503
    test->id                    = next_id++;
504
    test->which_test            = usbtest_invalid;
505
    usbtest_recovery_reset(&(test->recovery));
506
    test->result_pass           = 0;
507
    test->result_message[0]     = '\0';
508
    cyg_semaphore_init(&(test->sem), 0);
509
    test->transferred           = 0;
510
    test->cancel_fn             = (void (*)(UsbTest*)) 0;
511
}
512
 
513
// Forward declaration. The pool code depends on run_test(), setting up a test requires the pool.
514
static UsbTest* pool_allocate(void);
515
 
516
/*}}}*/
517
/*{{{  Bulk transfers                                           */
518
 
519
/*{{{  handle_test_bulk()                                       */
520
 
521
// Prepare for a bulk transfer test. This means allocating a thread to do
522
// the work, and extracting the test parameters from the current buffer.
523
// The thread allocation code does not require any locking since all worker
524
// threads should be idle when starting a new thread, so the work can be
525
// done entirely at DSR level and no synch is required.
526
static usbs_control_return
527
handle_test_bulk(usb_devreq* req)
528
{
529
    UsbTest*    test;
530
    int         index   = 0;
531
 
532
    test = pool_allocate();
533
    unpack_usbtest_bulk(&(test->test_params.bulk), class_request, &index);
534
    test->which_test = (USB_DEVREQ_DIRECTION_IN == (test->test_params.bulk.endpoint & USB_DEVREQ_DIRECTION_MASK)) ?
535
        usbtest_bulk_in : usbtest_bulk_out;
536
 
537
    VERBOSE(3, "Preparing USB bulk test on endpoint %d, direction %s, for %d packets\n", \
538
            test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK,                \
539
            (usbtest_bulk_in == test->which_test) ? "IN" : "OUT",                           \
540
            test->test_params.bulk.number_packets);
541
    VERBOSE(3, "  I/O mechanism is %s\n", \
542
            (usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) ? "low-level USB" : \
543
            (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) ? "devtab" : "<invalid>");
544
    VERBOSE(3, "  Data format %s, data1 %d, data* %d, data+ %d, data1* %d, data1+ %d, data** %d, data*+ %d, data+* %d, data++ %d\n",\
545
            (usbtestdata_none     == test->test_params.bulk.data.format) ? "none" :     \
546
            (usbtestdata_bytefill == test->test_params.bulk.data.format) ? "bytefill" : \
547
            (usbtestdata_wordfill == test->test_params.bulk.data.format) ? "wordfill" : \
548
            (usbtestdata_byteseq  == test->test_params.bulk.data.format) ? "byteseq"  : \
549
            (usbtestdata_wordseq  == test->test_params.bulk.data.format) ? "wordseq"  : "<invalid>", \
550
            test->test_params.bulk.data.seed,                            \
551
            test->test_params.bulk.data.multiplier,                      \
552
            test->test_params.bulk.data.increment,                       \
553
            test->test_params.bulk.data.transfer_seed_multiplier,        \
554
            test->test_params.bulk.data.transfer_seed_increment,         \
555
            test->test_params.bulk.data.transfer_multiplier_multiplier,  \
556
            test->test_params.bulk.data.transfer_multiplier_increment,   \
557
            test->test_params.bulk.data.transfer_increment_multiplier,   \
558
            test->test_params.bulk.data.transfer_increment_increment);
559
    VERBOSE(3, "  txsize1 %d, txsize>= %d, txsize<= %d, txsize* %d, txsize/ %d, txsize+ %d\n", \
560
            test->test_params.bulk.tx_size,         test->test_params.bulk.tx_size_min,        \
561
            test->test_params.bulk.tx_size_max,     test->test_params.bulk.tx_size_multiplier, \
562
            test->test_params.bulk.tx_size_divisor, test->test_params.bulk.tx_size_increment);
563
    VERBOSE(3, "  rxsize1 %d, rxsize>= %d, rxsize<= %d, rxsize* %d, rxsize/ %d, rxsize+ %d\n", \
564
            test->test_params.bulk.rx_size,         test->test_params.bulk.rx_size_min,        \
565
            test->test_params.bulk.rx_size_max,     test->test_params.bulk.rx_size_multiplier, \
566
            test->test_params.bulk.rx_size_divisor, test->test_params.bulk.rx_size_increment);
567
    VERBOSE(3, "  txdelay1 %d, txdelay>= %d, txdelay<= %d, txdelay* %d, txdelay/ %d, txdelay+ %d\n", \
568
            test->test_params.bulk.tx_delay,         test->test_params.bulk.tx_delay_min,            \
569
            test->test_params.bulk.tx_delay_max,     test->test_params.bulk.tx_delay_multiplier,     \
570
            test->test_params.bulk.tx_delay_divisor, test->test_params.bulk.tx_delay_increment);
571
    VERBOSE(3, "  rxdelay1 %d, rxdelay>= %d, rxdelay<= %d, rxdelay* %d, rxdelay/ %d, rxdelay+ %d\n", \
572
            test->test_params.bulk.rx_delay,         test->test_params.bulk.rx_delay_min,            \
573
            test->test_params.bulk.rx_delay_max,     test->test_params.bulk.rx_delay_multiplier,     \
574
            test->test_params.bulk.rx_delay_divisor, test->test_params.bulk.rx_delay_increment);
575
 
576
    return USBS_CONTROL_RETURN_HANDLED;
577
}
578
 
579
/*}}}*/
580
/*{{{  run_test_bulk_out()                                      */
581
 
582
// The same callback can be used for IN and OUT transfers. Note that
583
// starting the next transfer is left to the thread, it is not done
584
// at DSR level.
585
static void
586
run_test_bulk_in_out_callback(void* callback_arg, int transferred)
587
{
588
    UsbTest*    test    = (UsbTest*) callback_arg;
589
    test->transferred   = transferred;
590
    cyg_semaphore_post(&(test->sem));
591
}
592
 
593
// OUT transfers, i.e. the host will be sending some number of
594
// packets. The I/O can happen in a number of different ways, e.g. via
595
// the low-level USB API or via devtab routines.
596
static void
597
run_test_bulk_out(UsbTest* test)
598
{
599
    unsigned char*      buf;
600
    int                 endpoint_number = test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK;
601
    int                 ep_index;
602
    usbs_rx_endpoint*   endpoint        = 0;
603
    cyg_io_handle_t     io_handle       = (cyg_io_handle_t)0;
604
    int                 alignment;
605
    int                 transferred;
606
    int                 i;
607
 
608
    VERBOSE(1, "Starting test %d, bulk out on endpoint %d\n", test->id, endpoint_number);
609
 
610
    ep_index = lookup_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK);
611
    if (ep_index == -1) {
612
            test->result_pass   = 0;
613
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
614
                     "Target, bulk OUT transfer on endpoint %d: no such bulk endpoint", endpoint_number);
615
            return;
616
    }
617
    endpoint    = (usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint;
618
    alignment   = usbs_testing_endpoints[ep_index].alignment;
619
    if (0 != alignment) {
620
        buf         = (unsigned char*) ((((cyg_uint32)test->buffer) + alignment - 1) & ~(alignment - 1));
621
    } else {
622
        buf = test->buffer;
623
    }
624
 
625
    CYG_ASSERTC((usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) || \
626
                (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism));
627
    if (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) {
628
        if (((const char*)0 == usbs_testing_endpoints[ep_index].devtab_entry) ||
629
            (0 != cyg_io_lookup(usbs_testing_endpoints[ep_index].devtab_entry, &io_handle))) {
630
 
631
            test->result_pass   = 0;
632
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
633
                     "Target, bulk OUT transfer on endpoint %d: no devtab entry", endpoint_number);
634
            return;
635
        }
636
    }
637
 
638
    // Make sure nobody else is using this endpoint
639
    lock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT);
640
 
641
    for (i = 0; i < test->test_params.bulk.number_packets; i++) {
642
        int rx_size = test->test_params.bulk.rx_size;
643
        int tx_size = test->test_params.bulk.tx_size;
644
 
645
        VERBOSE(2, "Bulk OUT test %d: iteration %d, rx size %d, tx size %d\n", test->id, i, rx_size, tx_size);
646
 
647
        if (rx_size < tx_size) {
648
            rx_size = tx_size;
649
            VERBOSE(2, "Bulk OUT test %d: iteration %d, packet size reset to %d to match tx size\n",
650
                    test->id, i, rx_size);
651
        }
652
 
653
        test->recovery.endpoint     = endpoint_number | USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT;
654
        test->recovery.protocol     = USB_ENDPOINT_DESCRIPTOR_ATTR_BULK;
655
        test->recovery.size         = rx_size;
656
 
657
        // Make sure there is no old data lying around
658
        if (usbtestdata_none != test->test_params.bulk.data.format) {
659
            memset(buf, 0, rx_size);
660
        }
661
 
662
        // Do the actual transfer, using the I/O mechanism specified for this test.
663
        switch (test->test_params.bulk.io_mechanism)
664
        {
665
          case usb_io_mechanism_usb :
666
          {
667
              test->transferred = 0;
668
              usbs_start_rx_buffer(endpoint, buf, rx_size, &run_test_bulk_in_out_callback, (void*) test);
669
              cyg_semaphore_wait(&(test->sem));
670
              transferred = test->transferred;
671
              break;
672
          }
673
 
674
          case usb_io_mechanism_dev :
675
          {
676
              int result;
677
              transferred   = rx_size;
678
              result = cyg_io_read(io_handle, (void*) buf, &transferred);
679
              if (result < 0) {
680
                  transferred = result;
681
              }
682
              break;
683
          }
684
 
685
          default:
686
            CYG_FAIL("Invalid test mechanism specified");
687
            break;
688
        }
689
 
690
        // Has this test been aborted for some reason?
691
        if (current_tests_terminated) {
692
            VERBOSE(2, "Bulk OUT test %d: iteration %d, termination detected\n", test->id, i);
693
            test->result_pass = 0;
694
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
695
                     "Target, bulk OUT transfer on endpoint %d: transfer aborted after iteration %d", endpoint_number, i);
696
            break;
697
        }
698
 
699
        // If an error occurred, abort this run
700
        if (transferred < 0) {
701
            test->result_pass   = 0;
702
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
703
                     "Target, bulk OUT transfer on endpoint %d: transfer failed with %d", endpoint_number, transferred);
704
            VERBOSE(2, "Bulk OUT test %d: iteration %d, error:\n    %s\n", test->id, i, test->result_message);
705
            break;
706
        }
707
 
708
        // Did the host send the expected amount of data?
709
        if (transferred < test->test_params.bulk.tx_size) {
710
            test->result_pass   = 0;
711
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
712
                     "Target, bulk OUT transfer on endpoint %d : the host only sent %d bytes when %d were expected",
713
                     endpoint_number, transferred, tx_size);
714
            VERBOSE(2, "Bulk OUT test %d: iteration %d, error:\n    %s\n", test->id, i, test->result_message);
715
            break;
716
        }
717
 
718
        if (verbose >= 3) {
719
            // Output the first 32 bytes of data
720
            char msg[256];
721
            int  index;
722
            int  j;
723
            index = snprintf(msg, 255, "Bulk OUT test %d: iteration %d, transferred %d\n    Data %s:",
724
                             test->id, i, transferred,
725
                             (usbtestdata_none == test->test_params.bulk.data.format) ? "(uninitialized)" : "");
726
 
727
            for (j = 0; ((j + 3) < transferred) && (j < 32); j+= 4) {
728
                index += snprintf(msg+index, 255-index, " %02x%02x%02x%02x",
729
                                  buf[j], buf[j+1], buf[j+2], buf[j+3]);
730
            }
731
            if (j < 32) {
732
                index += snprintf(msg+index, 255-index, " ");
733
                for ( ; j < transferred; j++) {
734
                    index += snprintf(msg+index, 255-index, "%02x", buf[j]);
735
                }
736
 
737
            }
738
            VERBOSE(3, "%s\n", msg);
739
        }
740
 
741
        // Is the data correct?
742
        if (!usbtest_check_buffer(&(test->test_params.bulk.data), buf, transferred)) {
743
            test->result_pass   = 0;
744
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
745
                     "Target, bulk OUT transfer on endpoint %d : mismatch between received and expected data", endpoint_number);
746
            VERBOSE(2, "Bulk OUt test %d: iteration %d, error:\n    %s\n", test->id, i, test->result_message);
747
            break;
748
        }
749
 
750
        if (0 != test->test_params.bulk.rx_delay) {
751
            VERBOSE(2, "Bulk OUT test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, \
752
                    i, test->test_params.bulk.rx_delay);
753
            usbs_nanosleep(test->test_params.bulk.rx_delay);
754
        }
755
 
756
        // Move on to the next transfer
757
        USBTEST_BULK_NEXT(test->test_params.bulk);
758
    }
759
 
760
    // Always unlock the endpoint on completion
761
    unlock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT);
762
 
763
    // If all the packets have been transferred this test has passed.
764
    if (i >= test->test_params.bulk.number_packets) {
765
        test->result_pass   = 1;
766
    }
767
 
768
    VERBOSE(1, "Test %d bulk OUT on endpoint %d, result %d\n", test->id, endpoint_number, test->result_pass);
769
}
770
 
771
/*}}}*/
772
/*{{{  run_test_bulk_in()                                       */
773
 
774
// IN transfers, i.e. the host is expected to receive some data. These are slightly
775
// easier than OUT transfers because it is the host that will do the checking.
776
static void
777
run_test_bulk_in(UsbTest* test)
778
{
779
    unsigned char*      buf;
780
    int                 endpoint_number = test->test_params.bulk.endpoint & ~USB_DEVREQ_DIRECTION_MASK;
781
    int                 ep_index;
782
    usbs_tx_endpoint*   endpoint        = 0;
783
    cyg_io_handle_t     io_handle       = (cyg_io_handle_t)0;
784
    int                 alignment;
785
    int                 transferred;
786
    int                 i;
787
 
788
    VERBOSE(1, "Starting test %d, bulk IN on endpoint %d\n", test->id, endpoint_number);
789
 
790
    ep_index = lookup_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK);
791
    if (ep_index == -1) {
792
            test->result_pass   = 0;
793
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
794
                     "Target, bulk IN transfer on endpoint %d: no such bulk endpoint", endpoint_number);
795
            return;
796
    }
797
    endpoint    = (usbs_tx_endpoint*) usbs_testing_endpoints[ep_index].endpoint;
798
    alignment   = usbs_testing_endpoints[ep_index].alignment;
799
    if (0 != alignment) {
800
        buf         = (unsigned char*) ((((cyg_uint32)test->buffer) + alignment - 1) & ~(alignment - 1));
801
    } else {
802
        buf = test->buffer;
803
    }
804
 
805
    CYG_ASSERTC((usb_io_mechanism_usb == test->test_params.bulk.io_mechanism) || \
806
                (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism));
807
    if (usb_io_mechanism_dev == test->test_params.bulk.io_mechanism) {
808
        if (((const char*)0 == usbs_testing_endpoints[ep_index].devtab_entry) ||
809
            (0 != cyg_io_lookup(usbs_testing_endpoints[ep_index].devtab_entry, &io_handle))) {
810
 
811
            test->result_pass   = 0;
812
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
813
                     "Target, bulk IN transfer on endpoint %d: no devtab entry", endpoint_number);
814
            return;
815
        }
816
    }
817
 
818
    // Make sure nobody else is using this endpoint
819
    lock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN);
820
 
821
    for (i = 0; i < test->test_params.bulk.number_packets; i++) {
822
        int packet_size = test->test_params.bulk.tx_size;
823
 
824
        test->recovery.endpoint     = endpoint_number | USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN;
825
        test->recovery.protocol     = USB_ENDPOINT_DESCRIPTOR_ATTR_BULK;
826
        test->recovery.size         = packet_size + usbs_testing_endpoints[ep_index].max_in_padding;
827
 
828
        // Make sure the buffer contains the data expected by the host
829
        usbtest_fill_buffer(&(test->test_params.bulk.data), buf, packet_size);
830
 
831
        if (verbose < 3) {
832
            VERBOSE(2, "Bulk OUT test %d: iteration %d, packet size %d\n", test->id, i, packet_size);
833
        } else {
834
            // Output the first 32 bytes of data as well.
835
            char msg[256];
836
            int  index;
837
            int  j;
838
            index = snprintf(msg, 255, "Bulk IN test %d: iteration %d, packet size %d\n    Data %s:",
839
                             test->id, i, packet_size,
840
                             (usbtestdata_none == test->test_params.bulk.data.format) ? "(uninitialized)" : "");
841
 
842
            for (j = 0; ((j + 3) < packet_size) && (j < 32); j+= 4) {
843
                index += snprintf(msg+index, 255-index, " %02x%02x%02x%02x",
844
                                  buf[j], buf[j+1], buf[j+2], buf[j+3]);
845
            }
846
            if (j < 32) {
847
                index += snprintf(msg+index, 255-index, " ");
848
                for ( ; j < packet_size; j++) {
849
                    index += snprintf(msg+index, 255-index, "%02x", buf[j]);
850
                }
851
 
852
            }
853
            VERBOSE(3, "%s\n", msg);
854
        }
855
 
856
        // Do the actual transfer, using the I/O mechanism specified for this test.
857
        switch (test->test_params.bulk.io_mechanism)
858
        {
859
          case usb_io_mechanism_usb :
860
          {
861
              test->transferred = 0;
862
              usbs_start_tx_buffer(endpoint, buf, packet_size, &run_test_bulk_in_out_callback, (void*) test);
863
              cyg_semaphore_wait(&(test->sem));
864
              transferred = test->transferred;
865
              break;
866
          }
867
 
868
          case usb_io_mechanism_dev :
869
          {
870
              int result;
871
              transferred   = packet_size;
872
              result = cyg_io_write(io_handle, (void*) buf, &transferred);
873
              if (result < 0) {
874
                  transferred = result;
875
              }
876
              break;
877
          }
878
 
879
          default:
880
            CYG_FAIL("Invalid test mechanism specified");
881
            break;
882
        }
883
 
884
        // Has this test been aborted for some reason?
885
        if (current_tests_terminated) {
886
            VERBOSE(2, "Bulk IN test %d: iteration %d, termination detected\n", test->id, i);
887
            test->result_pass   = 0;
888
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
889
                     "Target, bulk IN transfer on endpoint %d : terminated on iteration %d, packet_size %d\n",
890
                     endpoint_number, i, packet_size);
891
            break;
892
        }
893
 
894
        // If an error occurred, abort this run
895
        if (transferred < 0) {
896
            test->result_pass   = 0;
897
            snprintf(test->result_message, USBTEST_MAX_MESSAGE,
898
                     "Target, bulk IN transfer on endpoint %d: transfer failed with %d", endpoint_number, transferred);
899
            VERBOSE(2, "Bulk IN test %d: iteration %d, error:\n    %s\n", test->id, i, test->result_message);
900
            break;
901
        }
902
 
903
        // No need to check the transfer size, the USB code is only
904
        // allowed to send the exact amount of data requested.
905
 
906
        if (0 != test->test_params.bulk.tx_delay) {
907
            VERBOSE(2, "Bulk IN test %d: iteration %d, sleeping for %d nanoseconds\n", test->id, i, \
908
                    test->test_params.bulk.tx_delay);
909
            usbs_nanosleep(test->test_params.bulk.tx_delay);
910
        }
911
 
912
        // Move on to the next transfer
913
        USBTEST_BULK_NEXT(test->test_params.bulk);
914
    }
915
 
916
    // Always unlock the endpoint on completion
917
    unlock_endpoint(endpoint_number, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN);
918
 
919
    // If all the packets have been transferred this test has passed.
920
    if (i >= test->test_params.bulk.number_packets) {
921
        test->result_pass   = 1;
922
    }
923
 
924
    VERBOSE(1, "Test %d bulk IN on endpoint %d, result %d\n", test->id, endpoint_number, test->result_pass);
925
}
926
 
927
/*}}}*/
928
 
929
/*}}}*/
930
/*{{{  Control IN transfers                                     */
931
 
932
// Control-IN transfers. These have to be handled a little bit differently
933
// from bulk transfers. The target never actually initiates anything. Instead
934
// the host will send reserved control messages which are handled at DSR
935
// level and passed to handle_reserved_control_messages() below. Assuming
936
// a control-IN test is in progress, that will take appropriate action. The
937
// thread will be woken up only once all packets have been transferred, or
938
// on abnormal termination.
939
 
940
// Is a control-IN test currently in progress?
941
static UsbTest* control_in_test    = 0;
942
 
943
// What is the expected packet size?
944
static int      control_in_test_packet_size = 0;
945
 
946
// How many packets have been transferred so far?
947
static int      control_in_packets_transferred  = 0;
948
 
949
// Cancel a control-in test. handle_test_control_in() will have updated the static
950
// control_in_test so that handle_reserved_control_messages() knows what to do.
951
// If the test is not actually going to be run then system consistency demands
952
// that this update be undone. Also, the endpoint will have been locked to
953
// detect concurrent tests on the control endpoint.
954
static void
955
cancel_test_control_in(UsbTest* test)
956
{
957
    CYG_ASSERTC(test == control_in_test);
958
    control_in_test = (UsbTest*) 0;
959
    control_in_test_packet_size = 0;
960
    control_in_packets_transferred = 0;
961
    unlock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN);
962
    test->cancel_fn = (void (*)(UsbTest*)) 0;
963
}
964
 
965
// Prepare for a control-IN transfer test.
966
static usbs_control_return
967
handle_test_control_in(usb_devreq* req)
968
{
969
    UsbTest*    test;
970
    int         index   = 0;
971
 
972
    CYG_ASSERTC((UsbTest*)0 == control_in_test);
973
 
974
    test = pool_allocate();
975
    unpack_usbtest_control_in(&(test->test_params.control_in), class_request, &index);
976
 
977
    lock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN);
978
    test->which_test            = usbtest_control_in;
979
    test->recovery.endpoint     = 0;
980
    test->recovery.protocol     = USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL;
981
    test->recovery.size         = 0;    // Does not actually matter
982
    test->cancel_fn             = &cancel_test_control_in;
983
 
984
    // Assume a pass. Failures are easy to detect.
985
    test->result_pass   = 1;
986
 
987
    control_in_test = test;
988
    control_in_test_packet_size = test->test_params.control_in.packet_size_initial;
989
    control_in_packets_transferred  = 0;
990
 
991
    return USBS_CONTROL_RETURN_HANDLED;
992
}
993
 
994
// The thread for a control-in test. Actually all the hard work is done at DSR
995
// level, so this thread serves simply to detect when the test has completed
996
// and to perform some clean-ups.
997
static void
998
run_test_control_in(UsbTest* test)
999
{
1000
    CYG_ASSERTC(test == control_in_test);
1001
 
1002
    cyg_semaphore_wait(&(test->sem));
1003
 
1004
    // The DSR has detected that the test is complete.
1005
    control_in_test = (UsbTest*) 0;
1006
    control_in_test_packet_size = 0;
1007
    control_in_packets_transferred = 0;
1008
    test->cancel_fn = (void (*)(UsbTest*)) 0;
1009
    unlock_endpoint(0, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN);
1010
}
1011
 
1012
// ----------------------------------------------------------------------------
1013
// This is installed from inside main() as the handler for reserved
1014
// control messages.
1015
static usbs_control_return
1016
handle_reserved_control_messages(usbs_control_endpoint* endpoint, void* data)
1017
{
1018
    usb_devreq*         req = (usb_devreq*) endpoint->control_buffer;
1019
    usbs_control_return result;
1020
 
1021
    CYG_ASSERT(endpoint == control_endpoint, "control endpoint mismatch");
1022
    switch(req->request) {
1023
      case USBTEST_RESERVED_CONTROL_IN:
1024
        {
1025
            unsigned char*  buf;
1026
            int             len;
1027
 
1028
            if ((UsbTest*)0 == control_in_test) {
1029
                result = USBS_CONTROL_RETURN_STALL;
1030
                break;
1031
            }
1032
 
1033
            // Is this test over? If so indicate a failure because we
1034
            // cannot have received all the control packets.
1035
            if (current_tests_terminated) {
1036
                control_in_test->result_pass   = 0;
1037
                snprintf(control_in_test->result_message, USBTEST_MAX_MESSAGE,
1038
                         "Target, control IN transfer: not all packets received.");
1039
                cyg_semaphore_post(&(control_in_test->sem));
1040
                control_in_test = (UsbTest*) 0;
1041
                result = USBS_CONTROL_RETURN_STALL;
1042
                break;
1043
            }
1044
 
1045
            // A control-IN test is indeed in progress, and the current state is
1046
            // held in control_in_test and control_in_test_packet_size. Check that
1047
            // the packet size matches up, i.e. that host and target are in sync.
1048
            len = (req->length_hi << 8) || req->length_lo;
1049
            if (control_in_test_packet_size != len) {
1050
                control_in_test->result_pass   = 0;
1051
                snprintf(control_in_test->result_message, USBTEST_MAX_MESSAGE,
1052
                         "Target, control IN transfer on endpoint %d : the host only requested %d bytes instead of %d",
1053
                         len, control_in_test_packet_size);
1054
                cyg_semaphore_post(&(control_in_test->sem));
1055
                control_in_test = (UsbTest*) 0;
1056
                result = USBS_CONTROL_RETURN_STALL;
1057
                break;
1058
            }
1059
 
1060
            // Prepare a suitable reply buffer. This is happening at
1061
            // DSR level so runtime is important, but with an upper
1062
            // bound of 255 bytes the buffer should be small enough.
1063
            buf = control_in_test->buffer;
1064
            usbtest_fill_buffer(&(control_in_test->test_params.control_in.data), buf, control_in_test_packet_size);
1065
            control_endpoint->buffer_size   = control_in_test_packet_size;
1066
            control_endpoint->buffer        = buf;
1067
            USBTEST_CONTROL_NEXT_PACKET_SIZE(control_in_test_packet_size, control_in_test->test_params.control_in);
1068
 
1069
            // Have all the packets been transferred?
1070
            control_in_packets_transferred++;
1071
            if (control_in_packets_transferred == control_in_test->test_params.control_in.number_packets) {
1072
                cyg_semaphore_post(&(control_in_test->sem));
1073
                control_in_test = (UsbTest*) 0;
1074
            }
1075
            result = USBS_CONTROL_RETURN_HANDLED;
1076
            break;
1077
      }
1078
      default:
1079
        CYG_FAIL("Unexpected reserved control message");
1080
        break;
1081
    }
1082
 
1083
    return result;
1084
}
1085
 
1086
/*}}}*/
1087
 
1088
// FIXME: add more tests.
1089
 
1090
// This utility is invoked from a thread in the thread pool whenever there is
1091
// work to be done. It simply dispatches to the appropriate handler.
1092
static void
1093
run_test(UsbTest* test)
1094
{
1095
    switch(test->which_test)
1096
    {
1097
      case usbtest_bulk_out :       run_test_bulk_out(test); break;
1098
      case usbtest_bulk_in :        run_test_bulk_in(test); break;
1099
      case usbtest_control_in:      run_test_control_in(test); break;
1100
      default:
1101
        CYG_TEST_FAIL_EXIT("Internal error, attempt to run unknown test.\n");
1102
        break;
1103
    }
1104
}
1105
 
1106
/*}}}*/
1107
/*{{{  The thread pool                                          */
1108
 
1109
// ----------------------------------------------------------------------------
1110
// Just like on the host side, it is desirable to have a pool of
1111
// threads available to perform test operations. Strictly speaking
1112
// some tests will run without needing a separate thread, since many
1113
// operations can be performed at DSR level. However typical
1114
// application code will involve threads and it is desirable for test
1115
// code to behave the same way. Also, some operations like validating
1116
// the transferred data are expensive, and best done in thread context.
1117
 
1118
typedef struct PoolEntry {
1119
    cyg_sem_t           wakeup;
1120
    cyg_thread          thread_data;
1121
    cyg_handle_t        thread_handle;
1122
    char                thread_name[16];
1123
    char                thread_stack[2 * CYGNUM_HAL_STACK_SIZE_TYPICAL];
1124
    cyg_bool            in_use;
1125
    cyg_bool            running;
1126
    UsbTest             test;
1127
} PoolEntry;
1128
 
1129
// This array must be uninitialized, or the executable size would
1130
// be ludicrous.
1131
PoolEntry  pool[USBTEST_MAX_CONCURRENT_TESTS];
1132
 
1133
// The entry point for every thread in the pool. It just loops forever,
1134
// waiting until it is supposed to run a test.
1135
static void
1136
pool_thread_function(cyg_addrword_t arg)
1137
{
1138
    PoolEntry*  pool_entry  = (PoolEntry*) arg;
1139
 
1140
    for ( ; ; ) {
1141
        cyg_semaphore_wait(&(pool_entry->wakeup));
1142
        run_test(&(pool_entry->test));
1143
        pool_entry->running = 0;
1144
    }
1145
}
1146
 
1147
// Initialize all threads in the pool.
1148
static void
1149
pool_initialize(void)
1150
{
1151
    int i;
1152
    for (i = 0; i < USBTEST_MAX_CONCURRENT_TESTS; i++) {
1153
        cyg_semaphore_init(&(pool[i].wakeup), 0);
1154
        pool[i].in_use  = 0;
1155
        pool[i].running = 0;
1156
        sprintf(pool[i].thread_name, "worker%d", i);
1157
        cyg_thread_create( 0, &pool_thread_function, (cyg_addrword_t) &(pool[i]),
1158
                           pool[i].thread_name, pool[i].thread_stack, 2 * CYGNUM_HAL_STACK_SIZE_TYPICAL,
1159
                           &(pool[i].thread_handle), &(pool[i].thread_data));
1160
        cyg_thread_resume(pool[i].thread_handle);
1161
    }
1162
}
1163
 
1164
// Allocate a single entry in the thread pool
1165
static UsbTest*
1166
pool_allocate(void)
1167
{
1168
    UsbTest*    result  = (UsbTest*) 0;
1169
 
1170
    if (thread_counter == USBTEST_MAX_CONCURRENT_TESTS) {
1171
        CYG_TEST_FAIL_EXIT("Internal error, thread resources exhaused.\n");
1172
    }
1173
 
1174
    result = &(pool[thread_counter].test);
1175
    thread_counter++;
1176
    reset_usbtest(result);
1177
    return result;
1178
}
1179
 
1180
// Start all the threads that are supposed to be running tests.
1181
static void
1182
pool_start(void)
1183
{
1184
    int i;
1185
    for (i = 0; i < thread_counter; i++) {
1186
        pool[i].running = 1;
1187
        cyg_semaphore_post(&(pool[i].wakeup));
1188
    }
1189
}
1190
 
1191
/*}}}*/
1192
/*{{{  Class control messages                                   */
1193
 
1194
// ----------------------------------------------------------------------------
1195
// Handle class control messages. These provide the primary form of
1196
// communication between host and target. There are requests to find out
1197
// the number of endpoints, details of each endpoint, prepare a test run,
1198
// abort a test run, get status, terminate the target-side, and so on.
1199
// The handlers for starting specific test cases are kept alongside
1200
// the test cases themselves.
1201
//
1202
// Note that these handlers will typically be invoked from DSR context
1203
// and hence they are subject to the usual DSR restrictions.
1204
//
1205
// Problems have been experienced in some hosts sending control messages
1206
// that involve additional host->target data. An ugly workaround is
1207
// in place whereby any such data is sent in advance using separate
1208
// control messages.
1209
 
1210
/*{{{  endpoint count                                           */
1211
 
1212
// How many endpoints are supported by this device? That information is
1213
// determined during initialization.
1214
static usbs_control_return
1215
handle_endpoint_count(usb_devreq* req)
1216
{
1217
    CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \
1218
                ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN));
1219
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1220
 
1221
    class_reply[0]                  = (unsigned char) number_endpoints;
1222
    control_endpoint->buffer        = class_reply;
1223
    control_endpoint->buffer_size   = 1;
1224
    return USBS_CONTROL_RETURN_HANDLED;
1225
}
1226
 
1227
/*}}}*/
1228
/*{{{  endpoint details                                         */
1229
 
1230
// The host wants to know the details of a specific USB endpoint.
1231
// The format is specified in protocol.h
1232
static usbs_control_return
1233
handle_endpoint_details(usb_devreq* req)
1234
{
1235
    int buf_index;
1236
 
1237
    CYG_ASSERTC((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN);
1238
    CYG_ASSERTC((USBTEST_MAX_CONTROL_DATA == req->length_lo) && (0 == req->length_hi));
1239
    CYG_ASSERTC(req->index_lo < number_endpoints);
1240
    CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1241
 
1242
    class_reply[0]  = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_type;
1243
    class_reply[1]  = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_number;
1244
    class_reply[2]  = (unsigned char) usbs_testing_endpoints[req->index_lo].endpoint_direction;
1245
    class_reply[3]  = (unsigned char) usbs_testing_endpoints[req->index_lo].max_in_padding;
1246
    buf_index = 4;
1247
    pack_int(usbs_testing_endpoints[req->index_lo].min_size, class_reply, &buf_index);
1248
    pack_int(usbs_testing_endpoints[req->index_lo].max_size, class_reply, &buf_index);
1249
    if (NULL == usbs_testing_endpoints[req->index_lo].devtab_entry) {
1250
        class_reply[buf_index]    = '\0';
1251
        control_endpoint->buffer_size   = buf_index + 1;
1252
    } else {
1253
        int len = strlen(usbs_testing_endpoints[req->index_lo].devtab_entry) + buf_index + 1;
1254
        if (len > USBTEST_MAX_CONTROL_DATA) {
1255
            return USBS_CONTROL_RETURN_STALL;
1256
        } else {
1257
            strcpy(&(class_reply[buf_index]), usbs_testing_endpoints[req->index_lo].devtab_entry);
1258
            control_endpoint->buffer_size   = len;
1259
        }
1260
    }
1261
    control_endpoint->buffer        = class_reply;
1262
    return USBS_CONTROL_RETURN_HANDLED;
1263
}
1264
 
1265
/*}}}*/
1266
/*{{{  sync                                                     */
1267
 
1268
// The host wants to know whether or not the target is currently busy doing
1269
// stuff. This information is held in a static.
1270
static usbs_control_return
1271
handle_sync(usb_devreq* req)
1272
{
1273
    CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \
1274
                ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN));
1275
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1276
    CYG_ASSERT(0 == class_request_size, "A sync operation should not involve any data");
1277
 
1278
    class_reply[0]                  = (unsigned char) idle;
1279
    control_endpoint->buffer        = class_reply;
1280
    control_endpoint->buffer_size   = 1;
1281
    return USBS_CONTROL_RETURN_HANDLED;
1282
}
1283
 
1284
/*}}}*/
1285
/*{{{  pass/fail                                                */
1286
 
1287
// Allow the host to generate some pass or fail messages, and
1288
// optionally terminate the test. These are synchronous requests
1289
// so the data can be left in class_request.
1290
 
1291
static int passfail_request   = 0;
1292
 
1293
// Invoked from thread context
1294
static void
1295
handle_passfail_action(void)
1296
{
1297
    switch (passfail_request) {
1298
      case USBTEST_PASS:
1299
        CYG_TEST_PASS(class_request);
1300
        break;
1301
      case USBTEST_PASS_EXIT:
1302
        CYG_TEST_PASS(class_request);
1303
        CYG_TEST_EXIT("Exiting normally as requested by the host");
1304
        break;
1305
      case USBTEST_FAIL:
1306
        CYG_TEST_FAIL(class_request);
1307
        break;
1308
      case USBTEST_FAIL_EXIT:
1309
        CYG_TEST_FAIL(class_request);
1310
        CYG_TEST_EXIT("Exiting normally as requested by the host");
1311
        break;
1312
      default:
1313
        CYG_FAIL("Bogus invocation of usbtest_main_passfail");
1314
        break;
1315
    }
1316
}
1317
 
1318
// Invoked from DSR context
1319
static usbs_control_return
1320
handle_passfail(usb_devreq* req)
1321
{
1322
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1323
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1324
    CYG_ASSERT(class_request_size > 0, "A pass/fail message should be supplied");
1325
    CYG_ASSERT(idle, "Pass/fail messages are only allowed when idle");
1326
    CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending.");
1327
 
1328
    passfail_request    = req->request;
1329
    idle                = false;
1330
    main_thread_action  = &handle_passfail_action;
1331
    cyg_semaphore_post(&main_wakeup);
1332
 
1333
    return USBS_CONTROL_RETURN_HANDLED;
1334
}
1335
 
1336
/*}}}*/
1337
/*{{{  abort                                                    */
1338
 
1339
// The host has concluded that there is no easy way to get both target and
1340
// host back to a sensible state. For example there may be a thread that
1341
// is blocked waiting for some I/O that is not going to complete. The abort
1342
// should be handled at thread level, not DSR level, so that the host
1343
// still sees the low-level USB handshake.
1344
 
1345
static void
1346
handle_abort_action(void)
1347
{
1348
    CYG_TEST_FAIL_EXIT("Test abort requested by host application");
1349
}
1350
 
1351
static usbs_control_return
1352
handle_abort(usb_devreq* req)
1353
{
1354
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1355
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1356
    CYG_ASSERT(idle, "Abort messages are only allowed when idle");
1357
    CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending.");
1358
 
1359
    idle                = false;
1360
    main_thread_action  = &handle_abort_action;
1361
    cyg_semaphore_post(&main_wakeup);
1362
 
1363
    return USBS_CONTROL_RETURN_HANDLED;
1364
}
1365
 
1366
/*}}}*/
1367
/*{{{  cancel                                                   */
1368
 
1369
// Invoked from thread context
1370
// Cancelling pending test cases simply involves iterating over the allocated
1371
// entries in the pool, invoking any cancellation functions that have been
1372
// defined, and then resetting the tread count. The actual tests have not
1373
// yet started so none of the threads will be active.
1374
static void
1375
handle_cancel_action(void)
1376
{
1377
    int i;
1378
    for (i = 0; i < thread_counter; i++) {
1379
        if ((void (*)(UsbTest*))0 != pool[i].test.cancel_fn) {
1380
            (*(pool[i].test.cancel_fn))(&(pool[i].test));
1381
            pool[i].test.cancel_fn  = (void (*)(UsbTest*)) 0;
1382
        }
1383
    }
1384
    thread_counter    = 0;
1385
}
1386
 
1387
// Invoked from DSR context
1388
static usbs_control_return
1389
handle_cancel(usb_devreq* req)
1390
{
1391
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1392
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1393
    CYG_ASSERT(0 == class_request_size, "A cancel operation should not involve any data");
1394
    CYG_ASSERT(idle, "Cancel requests are only allowed when idle");
1395
    CYG_ASSERT(!running, "Cancel requests cannot be sent once the system is running");
1396
    CYG_ASSERT((void (*)(void))0 == main_thread_action, "No thread operation should be pending.");
1397
 
1398
    idle                = false;
1399
    main_thread_action = &handle_cancel_action;
1400
    cyg_semaphore_post(&main_wakeup);
1401
 
1402
    return USBS_CONTROL_RETURN_HANDLED;
1403
}
1404
 
1405
/*}}}*/
1406
/*{{{  start                                                    */
1407
 
1408
// Start the tests running. This just involves waking up the pool threads
1409
// and setting the running flag, with the latter serving primarily for
1410
// assertions. 
1411
 
1412
static usbs_control_return
1413
handle_start(usb_devreq* req)
1414
{
1415
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1416
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1417
    CYG_ASSERT(0 == class_request_size, "A start operation should not involve any data");
1418
    CYG_ASSERT(!running, "Start requests cannot be sent if the system is already running");
1419
 
1420
    current_tests_terminated = false;
1421
    running = true;
1422
    pool_start();
1423
 
1424
    return USBS_CONTROL_RETURN_HANDLED;
1425
}
1426
 
1427
/*}}}*/
1428
/*{{{  finished                                                 */
1429
 
1430
// Have all the tests finished? This involves checking all the threads
1431
// involved in the current batch of tests and seeing whether or not
1432
// their running flag is still set.
1433
 
1434
static usbs_control_return
1435
handle_finished(usb_devreq* req)
1436
{
1437
    int i;
1438
    int result = 1;
1439
 
1440
    CYG_ASSERTC((1 == req->length_lo) && (0 == req->length_hi) && \
1441
                ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN));
1442
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1443
    CYG_ASSERT(0 == class_request_size, "A finished operation should not involve any data");
1444
    CYG_ASSERT(running, "Finished requests can only be sent if the system is already running");
1445
 
1446
    for (i = 0; i < thread_counter; i++) {
1447
        if (pool[i].running) {
1448
            result = 0;
1449
            break;
1450
        }
1451
    }
1452
    class_reply[0]                  = (unsigned char) result;
1453
    control_endpoint->buffer        = class_reply;
1454
    control_endpoint->buffer_size   = 1;
1455
    return USBS_CONTROL_RETURN_HANDLED;
1456
}
1457
 
1458
/*}}}*/
1459
/*{{{  set terminated                                           */
1460
 
1461
// A timeout has occurred, or there is some other failure. The first step
1462
// in recovery is to set the terminated flag so that as recovery action
1463
// takes place and the threads wake up they make no attempt to continue
1464
// doing more transfers.
1465
 
1466
static usbs_control_return
1467
handle_set_terminated(usb_devreq* req)
1468
{
1469
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1470
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1471
    CYG_ASSERT(0 == class_request_size, "A set-terminated operation should not involve any data");
1472
    CYG_ASSERT(running, "The terminated flag can only be set when there are running tests");
1473
 
1474
    current_tests_terminated = 1;
1475
 
1476
    return USBS_CONTROL_RETURN_HANDLED;
1477
}
1478
 
1479
/*}}}*/
1480
/*{{{  get recovery                                             */
1481
 
1482
// Return the recovery information for one of the threads involved in the
1483
// current batch of tests, so that the host can perform a USB operation
1484
// that will sort out that thread.
1485
static usbs_control_return
1486
handle_get_recovery(usb_devreq* req)
1487
{
1488
    int buffer_index;
1489
 
1490
    CYG_ASSERT(current_tests_terminated, "Recovery should only be attempted when the terminated flag is set");
1491
    CYG_ASSERT(running, "If there are no tests running then recovery is impossible");
1492
    CYG_ASSERTC((12 == req->length_lo) && (0 == req->length_hi) && \
1493
                ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN));
1494
    CYG_ASSERTC(req->index_lo <= thread_counter);
1495
    CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1496
    CYG_ASSERT(0 == class_request_size, "A get-recovery operation should not involve any data");
1497
 
1498
    control_endpoint->buffer        = class_reply;
1499
    if (!pool[req->index_lo].running) {
1500
        // Actually, this particular thread has terminated so no recovery is needed.
1501
        control_endpoint->buffer_size   = 0;
1502
    } else {
1503
        buffer_index    = 0;
1504
        pack_usbtest_recovery(&(pool[req->index_lo].test.recovery), class_reply, &buffer_index);
1505
        control_endpoint->buffer_size   = buffer_index;
1506
    }
1507
 
1508
    return USBS_CONTROL_RETURN_HANDLED;
1509
}
1510
 
1511
/*}}}*/
1512
/*{{{  perform recovery                                         */
1513
 
1514
// The host has identified a course of action that could unlock a thread
1515
// on the host-side that is currently blocked performing a USB operation.
1516
// Typically this involves either sending or accepting some data. If the
1517
// endpoint is still locked, in other words if there is a still a local
1518
// thread attempting to communicate on the specified endpoint, then
1519
// things are messed up: both sides are trying to communicate, but nothing
1520
// is happening. The eCos USB API is such that attempting multiple
1521
// concurrent operations on a single endpoint is disallowed, so
1522
// the recovery request has to be ignored. If things do not sort themselves
1523
// out then the whole test run will have to be aborted.
1524
 
1525
// A dummy completion function for when a recovery operation has completed.
1526
static void
1527
recovery_callback(void* callback_arg, int transferred)
1528
{
1529
    CYG_UNUSED_PARAM(void*, callback_arg);
1530
    CYG_UNUSED_PARAM(int, transferred);
1531
}
1532
 
1533
static usbs_control_return
1534
handle_perform_recovery(usb_devreq* req)
1535
{
1536
    int                 buffer_index;
1537
    int                 endpoint_number;
1538
    int                 endpoint_direction;
1539
    UsbTest_Recovery    recovery;
1540
 
1541
    CYG_ASSERT(current_tests_terminated, "Recovery should only be attempted when the terminated flag is set");
1542
    CYG_ASSERT(running, "If there are no tests running then recovery is impossible");
1543
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1544
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1545
    CYG_ASSERT(12 == class_request_size, "A perform-recovery operation requires recovery data");
1546
 
1547
    buffer_index = 0;
1548
    unpack_usbtest_recovery(&recovery, class_request, &buffer_index);
1549
    endpoint_number     = recovery.endpoint & ~USB_DEVREQ_DIRECTION_MASK;
1550
    endpoint_direction  = recovery.endpoint & USB_DEVREQ_DIRECTION_MASK;
1551
 
1552
    if (!is_endpoint_locked(endpoint_number, endpoint_direction)) {
1553
        // Locking the endpoint here would be good, but the endpoint would then
1554
        // have to be unlocked again - probably in the recovery callback.
1555
        // This complication is ignored for now.
1556
 
1557
        if (USB_ENDPOINT_DESCRIPTOR_ATTR_BULK == recovery.protocol) {
1558
            int ep_index = lookup_endpoint(endpoint_number, endpoint_direction, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK);
1559
            CYG_ASSERTC(-1 != ep_index);
1560
 
1561
            if (USB_DEVREQ_DIRECTION_IN == endpoint_direction) {
1562
                // The host wants some data. Supply it. A single byte will do fine to
1563
                // complete the transfer.
1564
                usbs_start_tx_buffer((usbs_tx_endpoint*) usbs_testing_endpoints[ep_index].endpoint,
1565
                                     recovery_buffer, 1, &recovery_callback, (void*) 0);
1566
            } else {
1567
                // The host is trying to send some data. Accept all of it.
1568
                usbs_start_rx_buffer((usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint,
1569
                                     recovery_buffer, recovery.size, &recovery_callback, (void*) 0);
1570
            }
1571
        }
1572
 
1573
        // No support for isochronous or interrupt transfers yet.
1574
        // handle_reserved_control_messages() should generate stalls which
1575
        // have the desired effect.
1576
    }
1577
 
1578
    return USBS_CONTROL_RETURN_HANDLED;
1579
}
1580
 
1581
/*}}}*/
1582
/*{{{  get result                                               */
1583
 
1584
// Return the result of one the tests. This can be a single byte for
1585
// a pass, or a single byte plus a message for a failure.
1586
 
1587
static usbs_control_return
1588
handle_get_result(usb_devreq* req)
1589
{
1590
    CYG_ASSERTC((USBTEST_MAX_CONTROL_DATA == req->length_lo) && (0 == req->length_hi) && \
1591
                ((req->type & USB_DEVREQ_DIRECTION_MASK) == USB_DEVREQ_DIRECTION_IN));
1592
    CYG_ASSERTC(req->index_lo <= thread_counter);
1593
    CYG_ASSERTC((0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1594
    CYG_ASSERT(0 == class_request_size, "A get-result operation should not involve any data");
1595
    CYG_ASSERT(running, "Results can only be sent if a run is in progress");
1596
    CYG_ASSERT(!pool[req->index_lo].running, "Cannot request results for a test that has not completed");
1597
 
1598
    class_reply[0]  = pool[req->index_lo].test.result_pass;
1599
    if (class_reply[0]) {
1600
        control_endpoint->buffer_size = 1;
1601
    } else {
1602
        strncpy(&(class_reply[1]), pool[req->index_lo].test.result_message, USBTEST_MAX_CONTROL_DATA - 2);
1603
        class_reply[USBTEST_MAX_CONTROL_DATA - 1] = '\0';
1604
        control_endpoint->buffer_size = 1 + strlen(&(class_reply[1])) + 1;
1605
    }
1606
    control_endpoint->buffer = class_reply;
1607
    return USBS_CONTROL_RETURN_HANDLED;
1608
}
1609
 
1610
/*}}}*/
1611
/*{{{  batch done                                               */
1612
 
1613
// A batch of test has been completed - at least, the host thinks so.
1614
// If the host is correct then all that is required here is to reset
1615
// the thread pool and clear the global running flag - that is sufficient
1616
// to allow a new batch of tests to be started.
1617
 
1618
static usbs_control_return
1619
handle_batch_done(usb_devreq* req)
1620
{
1621
    int i;
1622
 
1623
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1624
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi) && (0 == req->value_lo) && (0 == req->value_hi));
1625
    CYG_ASSERT(0 == class_request_size, "A batch-done operation should not involve any data");
1626
    CYG_ASSERT(running, "There must be a current batch of tests");
1627
 
1628
    for (i = 0; i < thread_counter; i++) {
1629
        CYG_ASSERTC(!pool[i].running);
1630
    }
1631
    thread_counter  = 0;
1632
    running         = false;
1633
 
1634
    return USBS_CONTROL_RETURN_HANDLED;
1635
 
1636
}
1637
 
1638
/*}}}*/
1639
/*{{{  verbosity                                                */
1640
 
1641
static usbs_control_return
1642
handle_verbose(usb_devreq* req)
1643
{
1644
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1645
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi));
1646
    CYG_ASSERT(0 == class_request_size, "A set-verbosity operation should not involve any data");
1647
 
1648
    verbose = (req->value_hi << 8) + req->value_lo;
1649
 
1650
    return USBS_CONTROL_RETURN_HANDLED;
1651
}
1652
 
1653
/*}}}*/
1654
/*{{{  initialise bulk out endpoint                             */
1655
 
1656
// ----------------------------------------------------------------------------
1657
// Accept an initial endpoint on a bulk endpoint. This avoids problems
1658
// on some hardware such as the SA11x0 which can start to accept data
1659
// before the software is ready for it.
1660
 
1661
static void handle_init_callback(void* arg, int result)
1662
{
1663
    idle = true;
1664
}
1665
 
1666
static usbs_control_return
1667
handle_init_bulk_out(usb_devreq* req)
1668
{
1669
    static char         buf[64];
1670
    int                 ep_index;
1671
    usbs_rx_endpoint*   endpoint;
1672
 
1673
    CYG_ASSERTC((0 == req->length_lo) && (0 == req->length_hi));
1674
    CYG_ASSERTC((0 == req->index_lo) && (0 == req->index_hi));
1675
    CYG_ASSERTC((0 == req->value_hi) && (0 < req->value_lo) && (req->value_lo < 16));
1676
    CYG_ASSERT(0 == class_request_size, "An init_bulk_out operation should not involve any data");
1677
 
1678
    ep_index = lookup_endpoint(req->value_lo, USB_ENDPOINT_DESCRIPTOR_ENDPOINT_OUT, USB_ENDPOINT_DESCRIPTOR_ATTR_BULK);
1679
    CYG_ASSERTC(-1 != ep_index);
1680
    endpoint = (usbs_rx_endpoint*) usbs_testing_endpoints[ep_index].endpoint;
1681
 
1682
    idle = false;
1683
    usbs_start_rx_buffer(endpoint, buf, 64, &handle_init_callback, (void*) 0);
1684
 
1685
    return USBS_CONTROL_RETURN_HANDLED;
1686
}
1687
 
1688
/*}}}*/
1689
/*{{{  additional control data                                  */
1690
 
1691
// Accumulate some more data in the control buffer, ahead of an upcoming
1692
// request.
1693
static usbs_control_return
1694
handle_control_data(usb_devreq* req)
1695
{
1696
    class_request[class_request_size + 0] = req->value_hi;
1697
    class_request[class_request_size + 1] = req->value_lo;
1698
    class_request[class_request_size + 2] = req->index_hi;
1699
    class_request[class_request_size + 3] = req->index_lo;
1700
 
1701
    switch(req->request) {
1702
      case USBTEST_CONTROL_DATA1 : class_request_size += 1; break;
1703
      case USBTEST_CONTROL_DATA2 : class_request_size += 2; break;
1704
      case USBTEST_CONTROL_DATA3 : class_request_size += 3; break;
1705
      case USBTEST_CONTROL_DATA4 : class_request_size += 4; break;
1706
    }
1707
 
1708
    return USBS_CONTROL_RETURN_HANDLED;
1709
}
1710
 
1711
/*}}}*/
1712
 
1713
typedef struct class_handler {
1714
    int     request;
1715
    usbs_control_return (*handler)(usb_devreq*);
1716
} class_handler;
1717
static class_handler class_handlers[] = {
1718
    { USBTEST_ENDPOINT_COUNT,   &handle_endpoint_count },
1719
    { USBTEST_ENDPOINT_DETAILS, &handle_endpoint_details },
1720
    { USBTEST_PASS,             &handle_passfail },
1721
    { USBTEST_PASS_EXIT,        &handle_passfail },
1722
    { USBTEST_FAIL,             &handle_passfail },
1723
    { USBTEST_FAIL_EXIT,        &handle_passfail },
1724
    { USBTEST_SYNCH,            &handle_sync },
1725
    { USBTEST_ABORT,            &handle_abort },
1726
    { USBTEST_CANCEL,           &handle_cancel },
1727
    { USBTEST_START,            &handle_start },
1728
    { USBTEST_FINISHED,         &handle_finished },
1729
    { USBTEST_SET_TERMINATED,   &handle_set_terminated },
1730
    { USBTEST_GET_RECOVERY,     &handle_get_recovery },
1731
    { USBTEST_PERFORM_RECOVERY, &handle_perform_recovery },
1732
    { USBTEST_GET_RESULT,       &handle_get_result },
1733
    { USBTEST_BATCH_DONE,       &handle_batch_done },
1734
    { USBTEST_VERBOSE,          &handle_verbose },
1735
    { USBTEST_INIT_BULK_OUT,    &handle_init_bulk_out },
1736
    { USBTEST_TEST_BULK,        &handle_test_bulk },
1737
    { USBTEST_TEST_CONTROL_IN,  &handle_test_control_in },
1738
    { USBTEST_CONTROL_DATA1,    &handle_control_data },
1739
    { USBTEST_CONTROL_DATA2,    &handle_control_data },
1740
    { USBTEST_CONTROL_DATA3,    &handle_control_data },
1741
    { USBTEST_CONTROL_DATA4,    &handle_control_data },
1742
    { -1,                       (usbs_control_return (*)(usb_devreq*)) 0 }
1743
};
1744
 
1745
static usbs_control_return
1746
handle_class_control_messages(usbs_control_endpoint* endpoint, void* data)
1747
{
1748
    usb_devreq*         req = (usb_devreq*) endpoint->control_buffer;
1749
    int                 request = req->request;
1750
    usbs_control_return result;
1751
    int                 i;
1752
 
1753
    VERBOSE(3, "Received control message %02x\n", request);
1754
 
1755
    CYG_ASSERT(endpoint == control_endpoint, "control endpoint mismatch");
1756
    result  = USBS_CONTROL_RETURN_UNKNOWN;
1757
    for (i = 0; (usbs_control_return (*)(usb_devreq*))0 != class_handlers[i].handler; i++) {
1758
        if (request == class_handlers[i].request) {
1759
            result = (*(class_handlers[i].handler))(req);
1760
            if ((USBTEST_CONTROL_DATA1 != request) &&
1761
                (USBTEST_CONTROL_DATA2 != request) &&
1762
                (USBTEST_CONTROL_DATA3 != request) &&
1763
                (USBTEST_CONTROL_DATA4 != request)) {
1764
                // Reset the request data buffer after all normal requests.
1765
                class_request_size = 0;
1766
            }
1767
            break;
1768
        }
1769
    }
1770
    CYG_UNUSED_PARAM(void*, data);
1771
    if (USBS_CONTROL_RETURN_HANDLED != result) {
1772
        VERBOSE(1, "Control message %02x not handled\n", request);
1773
    }
1774
 
1775
    return result;
1776
}
1777
 
1778
/*}}}*/
1779
/*{{{  main()                                                   */
1780
 
1781
// ----------------------------------------------------------------------------
1782
// Initialization.
1783
int
1784
main(int argc, char** argv)
1785
{
1786
    int i;
1787
 
1788
    CYG_TEST_INIT();
1789
 
1790
    // The USB device driver should have provided an array of endpoint
1791
    // descriptors, usbs_testing_endpoints(). One entry in this array
1792
    // should be a control endpoint, which is needed for initialization.
1793
    // It is also useful to know how many endpoints there are.
1794
    for (i = 0; !USBS_TESTING_ENDPOINTS_IS_TERMINATOR(usbs_testing_endpoints[i]); i++) {
1795
        if ((0 == usbs_testing_endpoints[i].endpoint_number) &&
1796
            (USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL== usbs_testing_endpoints[i].endpoint_type)) {
1797
            CYG_ASSERT((usbs_control_endpoint*)0 == control_endpoint, "There should be only one control endpoint");
1798
            control_endpoint = (usbs_control_endpoint*) usbs_testing_endpoints[i].endpoint;
1799
        }
1800
    }
1801
    if ((usbs_control_endpoint*)0 == control_endpoint) {
1802
        CYG_TEST_FAIL_EXIT("Unable to find a USB control endpoint");
1803
    }
1804
    number_endpoints = i;
1805
    CYG_ASSERT(number_endpoints <= USBTEST_MAX_ENDPOINTS, "impossible number of endpoints");
1806
 
1807
    // Some of the information provided may not match the actual capabilities
1808
    // of the testing code, e.g. max_size limits.
1809
    fix_driver_endpoint_data();
1810
 
1811
    // This semaphore is used for communication between the DSRs that process control
1812
    // messages and the main thread
1813
    cyg_semaphore_init(&main_wakeup, 0);
1814
 
1815
    // Take care of the pool of threads and related data.
1816
    pool_initialize();
1817
 
1818
    // Start the heartbeat thread, to make sure that the gdb session stays
1819
    // alive.
1820
    start_heartbeat();
1821
 
1822
    // Now it is possible to start up the USB device driver. The host can detect
1823
    // this, connect, get the enumeration data, and then testing will proceed
1824
    // in response to class control messages.
1825
    provide_endpoint_enumeration_data();
1826
    control_endpoint->enumeration_data      = &usb_enum_data;
1827
    control_endpoint->class_control_fn      = &handle_class_control_messages;
1828
    control_endpoint->reserved_control_fn   = &handle_reserved_control_messages;
1829
    usbs_start(control_endpoint);
1830
 
1831
    // Now it is over to the host to detect this target and start performing tests.
1832
    // Much of this is handled at DSR level, in response to USB control messages.
1833
    // Some of those control messages require action at thread level, and that is
1834
    // achieved by signalling a semaphore and waking up this thread. A static
1835
    // function pointer is used to keep track of what operation is actually required.
1836
    for (;;) {
1837
        void (*handler)(void);
1838
 
1839
        cyg_semaphore_wait(&main_wakeup);
1840
        handler = main_thread_action;
1841
        main_thread_action   = 0;
1842
        CYG_CHECK_FUNC_PTR(handler, "Main thread woken up when there is nothing to be done");
1843
        (*handler)();
1844
        idle = true;
1845
    }
1846
}
1847
 
1848
/*}}}*/

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