source: pacpussensors/trunk/CanGateway/driver/kvaser/linux/canlib.h@ 102

Last change on this file since 102 was 97, checked in by DHERBOMEZ Gérald, 9 years ago

add include files for kvaser

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1/**
2 * \section LICENSE
3 * <pre style="white-space: pre-wrap">
4 * This software is dual licensed under the following two licenses:
5 * BSD-new and GPLv2. You may use either one. See the included
6 * COPYING file for details.
7 *
8 * License: BSD-new
9 * ===============================================================================
10 * Redistribution and use in source and binary forms, with or without
11 * modification, are permitted provided that the following conditions are met:
12 * * Redistributions of source code must retain the above copyright
13 * notice, this list of conditions and the following disclaimer.
14 * * Redistributions in binary form must reproduce the above copyright
15 * notice, this list of conditions and the following disclaimer in the
16 * documentation and/or other materials provided with the distribution.
17 * * Neither the name of the <organization> nor the
18 * names of its contributors may be used to endorse or promote products
19 * derived from this software without specific prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
22 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
23 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
24 * DISCLAIMED. IN NO EVENT SHALL <COPYRIGHT HOLDER> BE LIABLE FOR ANY
25 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
26 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
27 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
28 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
29 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
30 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
31 *
32 *
33 * License: GPLv2
34 * ===============================================================================
35 * This program is free software; you can redistribute it and/or
36 * modify it under the terms of the GNU General Public License
37 * as published by the Free Software Foundation; either version 2
38 * of the License, or (at your option) any later version.
39 *
40 * This program is distributed in the hope that it will be useful,
41 * but WITHOUT ANY WARRANTY; without even the implied warranty of
42 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
43 * GNU General Public License for more details.
44 *
45 * You should have received a copy of the GNU General Public License
46 * along with this program; if not, write to the Free Software
47 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
48 *
49 * ---------------------------------------------------------------------------
50 * </pre>
51 *
52 * \section DESCRIPTION
53 *
54 * Definitions for the CANLIB API.
55 *
56 * \file canlib.h
57 * \author Kvaser AB
58 *
59 * \defgroup General General
60 * \defgroup CAN CAN
61 * \defgroup ObjectBuffers Object buffers
62 */
63
64#ifndef _CANLIB_H_
65#define _CANLIB_H_
66
67#include <stdlib.h>
68
69# define CANLIB_DECLARE_ALL
70typedef unsigned char BYTE;
71typedef unsigned int DWORD;
72typedef unsigned int HANDLE;
73typedef unsigned int BOOL;
74#include "canstat.h"
75
76/** Handle to an opened circuit. */
77typedef int canHandle;
78/** Handle to an opened circuit. */
79 typedef canHandle CanHandle;
80
81/**
82 * \ingroup CAN
83 */
84typedef struct canNotifyData {
85 void *tag;
86 int eventType;
87 union {
88 struct {
89 unsigned long time;
90 } busErr;
91 struct {
92 long id;
93 unsigned long time;
94 } rx;
95 struct {
96 long id;
97 unsigned long time;
98 } tx;
99 struct {
100 unsigned char busStatus;
101 unsigned char txErrorCounter;
102 unsigned char rxErrorCounter;
103 unsigned long time;
104 } status;
105 } info;
106} canNotifyData;
107
108
109/** Notify message sent to the application window */
110# define WM__CANLIB 648
111
112/**
113 * \name canOPEN_xxx
114 * \anchor canOPEN_xxx
115 *
116 * These defines are used in \ref canOpenChannel().
117 *
118 * @{
119 */
120
121// The canWANT_xxx names are also obsolete, use canOPEN_xxx instead for new developments.
122#define canWANT_EXCLUSIVE 0x0008
123#define canWANT_EXTENDED 0x0010
124#define canWANT_VIRTUAL 0x0020
125
126/**
127 * Don't allow sharing of this circuit between applications.
128 *
129 * This define is used in \ref canOpenChannel()
130 */
131#define canOPEN_EXCLUSIVE 0x0008
132
133/**
134 * This flag causes two things to happen:
135 *
136 * \li The call will fail if the specified circuit doesn't allow extended CAN
137 * (CAN 2.0B).
138 *
139 * \li If no frame-type flag is specified in a call to \ref canWrite, it is assumed
140 * that extended CAN should be used.
141 *
142 * This define is used in \ref canOpenChannel().
143 */
144#define canOPEN_REQUIRE_EXTENDED 0x0010
145
146/**
147 * Allow opening of virtual channels as well as physical channels.
148 *
149 * This define is used in \ref canOpenChannel().
150 *
151 * \sa \ref page_user_guide_virtual_info
152 */
153# define canOPEN_ACCEPT_VIRTUAL 0x0020
154
155
156/**
157 * The channel will accept messages with DLC (Data Length Code) greater than
158 * 8. If this flag is not used, a message with DLC > 8 will always be
159 * reported or transmitted as a message with DLC = 8. If the
160 * \ref canOPEN_ACCEPT_LARGE_DLC flag is used, the message will be sent and/or
161 * received with the true DLC, which can be at most 15.
162 *
163 * \note The length of the message is always at most 8.
164 *
165 * This define is used in \ref canOpenChannel().
166 */
167# define canOPEN_ACCEPT_LARGE_DLC 0x0200 // DLC can be greater than 8
168
169/**
170 * The channel will use the CAN FD protocol.
171 *
172 * This define is used in \ref canOpenChannel().
173 */
174# define canOPEN_CAN_FD 0x0400
175
176/**
177 * The channel will use the CAN FD NON-ISO protocol.
178 *
179 * This define is used in \ref canOpenChannel().
180 */
181# define canOPEN_CAN_FD_NONISO 0x0800
182/** @} */
183
184/**
185 * \ingroup CAN
186 * \name canFILTER_xxx
187 * \anchor canFILTER_xxx
188 *
189 * Flags for \ref canAccept().
190 *
191 * @{
192 */
193#define canFILTER_ACCEPT 1
194#define canFILTER_REJECT 2
195/** Sets the code for standard (11-bit) identifiers. */
196#define canFILTER_SET_CODE_STD 3
197/** Sets the mask for standard (11-bit) identifiers. */
198#define canFILTER_SET_MASK_STD 4
199/** Sets the code for extended (29-bit) identifiers. */
200#define canFILTER_SET_CODE_EXT 5
201/** Sets the mask for extended (29-bit) identifiers. */
202#define canFILTER_SET_MASK_EXT 6
203
204#define canFILTER_NULL_MASK 0L
205/** @} */
206
207
208/**
209 * \ingroup CAN
210 * \name canDRIVER_xxx
211 * \anchor canDRIVER_xxx
212 *
213 * CAN driver types - not all are supported on all cards.
214 *
215 * @{
216 */
217
218/**
219 * The "normal" driver type (push-pull). This is the default.
220 */
221#define canDRIVER_NORMAL 4
222
223/**
224 * Sets the CAN controller in Silent Mode; that is, it doesn't send anything,
225 * not even ACK bits, on the bus. Reception works as usual.
226 *
227 * \note The values 2,3,5,6,7 are reserved values for compatibility reasons.
228 */
229#define canDRIVER_SILENT 1
230
231/**
232 * Self-reception. Not implemented.
233 */
234#define canDRIVER_SELFRECEPTION 8
235
236/**
237 * The driver is turned off. Not implemented in all types of hardware.
238 */
239#define canDRIVER_OFF 0
240
241/** @} */
242
243
244/**
245 * \ingroup CAN
246 * \anchor BAUD_xxx
247 * \anchor canBITRATE_xxx
248 * \name canBITRATE_xxx
249 *
250 * Common bus speeds. Used in \ref canSetBusParams() and \ref canSetBusParamsC200().
251 * The values are translated in canlib, \ref canTranslateBaud().
252 *
253 * \note The \ref BAUD_xxx names are only retained for compability.
254 *
255 * \sa \ref page_user_guide_misc_bitrate
256 *
257 * @{
258 */
259
260
261/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 1 Mbit/s. */
262#define canBITRATE_1M (-1)
263/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 500 kbit/s. */
264#define canBITRATE_500K (-2)
265/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 250 kbit/s. */
266#define canBITRATE_250K (-3)
267/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 125 kbit/s. */
268#define canBITRATE_125K (-4)
269/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 100 kbit/s. */
270#define canBITRATE_100K (-5)
271/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 62 kbit/s. */
272#define canBITRATE_62K (-6)
273/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 50 kbit/s. */
274#define canBITRATE_50K (-7)
275/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 83 kbit/s. */
276#define canBITRATE_83K (-8)
277/** Used in \ref canSetBusParams() and \ref canSetBusParamsC200(). Indicate a bitrate of 10 kbit/s. */
278#define canBITRATE_10K (-9)
279
280// CAN FD Bit Rates
281/** Used in \ref canSetBusParamsFd(). Indicates a bitrate of 0.5 Mbit/s and sampling point at 80%. */
282#define canFD_BITRATE_500K_80P (-1001)
283/** Used in \ref canSetBusParamsFd(). Indicates a bitrate of 1.0 Mbit/s and sampling point at 80%. */
284#define canFD_BITRATE_1M_80P (-1002)
285/** Used in \ref canSetBusParamsFd(). Indicates a bitrate of 2.0 Mbit/s and sampling point at 80%. */
286#define canFD_BITRATE_2M_80P (-1003)
287
288/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_1M instead. */
289#define BAUD_1M (-1)
290/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_500K instead. */
291#define BAUD_500K (-2)
292/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_250K instead. */
293#define BAUD_250K (-3)
294/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_125K instead. */
295#define BAUD_125K (-4)
296/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_100K instead. */
297#define BAUD_100K (-5)
298/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_62K instead. */
299#define BAUD_62K (-6)
300/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_50K instead. */
301#define BAUD_50K (-7)
302/** The \ref BAUD_xxx names are deprecated, use \ref canBITRATE_83K instead. */
303#define BAUD_83K (-8)
304/** @} */
305
306
307//
308// Define CANLIBAPI unless it's done already.
309// (canlib.c provides its own definitions of CANLIBAPI, DLLIMPORT
310// and DLLEXPORT before including this file.)
311//
312#ifndef CANLIBAPI
313# define CANLIBAPI
314# define __stdcall
315#endif
316
317
318#ifdef __cplusplus
319extern "C" {
320#endif
321
322/**
323 * \ingroup General
324 *
325 * \source_cs <b>static void canInitializeLibrary(void);</b>
326 *
327 * \source_delphi <b>procedure canInitializeLibrary; </b>
328 * \source_end
329 * This function must be called before any other functions is used. It will
330 * initialize the driver.
331 *
332 * You may call \ref canInitializeLibrary() more than once. The actual
333 * initialization will take place only once.
334 *
335 * Any errors encountered during library initialization will be "silent" and an
336 * appropriate \ref canERR_xxx error code will be returned later on when
337 * \ref canOpenChannel() (or any other API call that requires initialization) is
338 * called.
339 *
340 * \note This call replaces the \ref canLocateHardware() API call and serves the
341 * same purpose.
342 *
343 * \sa \ref page_code_snippets_examples
344 *
345 */
346void CANLIBAPI canInitializeLibrary (void);
347
348/**
349 * \ingroup CAN
350 *
351 * \source_cs <b>static Canlib.canStatus canClose(int handle);</b>
352 *
353 * \source_delphi <b>function canClose(handle: canHandle): canStatus;</b>
354 * \source_end
355 *
356 * Closes the channel associated with the handle. If no other threads
357 * are using the CAN circuit, it is taken off bus. The handle can not be
358 * used for further references to the channel, so any variable containing
359 * it should be zeroed.
360 *
361 * \ref canClose() will almost always return \ref canOK; the specified handle is closed
362 * on an best-effort basis.
363 *
364 * \param[in] hnd An open handle to a CAN channel.
365 *
366 * \return \ref canOK (zero) if success
367 * \return \ref canERR_xxx (negative) if failure
368 *
369 * \sa \ref page_code_snippets_examples
370 * \sa \ref canOpenChannel(), \ref canBusOn(), \ref canBusOff()
371 */
372canStatus CANLIBAPI canClose (const CanHandle hnd);
373
374/**
375 * \ingroup CAN
376 *
377 * \source_cs <b>static Canlib.canStatus canBusOn(int handle);</b>
378 *
379 * \source_delphi <b>function canBusOn(handle: canHandle): canStatus; </b>
380 * \source_end
381 *
382 * Takes the specified channel on-bus.
383 *
384 * If you are using multiple handles to the same physical channel, for example
385 * if you are writing a threaded application, you must call \ref canBusOn() once for
386 * each handle. The same applies to \ref canBusOff() - the physical channel will not
387 * go off bus until the last handle to the channel goes off bus.
388 *
389 * \param[in] hnd An open handle to a CAN channel.
390 *
391 * \return \ref canOK (zero) if success
392 * \return \ref canERR_xxx (negative) if failure
393 *
394 * \sa \ref page_code_snippets_examples
395 * \sa \ref canBusOff(), \ref canResetBus()
396 *
397 */
398canStatus CANLIBAPI canBusOn (const CanHandle hnd);
399
400/**
401 * \ingroup CAN
402 *
403 * \source_cs <b>static Canlib.canStatus canBusOff(int handle);</b>
404 *
405 * \source_delphi <b>function canBusOff(handle: canHandle): canStatus; </b>
406 * \source_end
407 *
408 * Takes the specified channel off-bus.
409 *
410 * \param[in] hnd An open handle to a CAN channel.
411 *
412 * \return \ref canOK (zero) if success
413 * \return \ref canERR_xxx (negative) if failure
414 *
415 * \sa \ref page_code_snippets_examples
416 * \sa \ref canBusOn(), \ref canResetBus()
417 *
418 */
419canStatus CANLIBAPI canBusOff (const CanHandle hnd);
420
421/**
422 * \ingroup CAN
423 *
424 * \source_cs <b>static Canlib.canStatus canSetBusParams(int handle, int freq, int tseg1, int tseg2, int sjw, int noSamp, int syncmode); </b>
425 *
426 * \source_delphi <b>function canSetBusParams(handle: canHandle; freq: Longint; tseg1, tseg2, sjw, noSamp, syncmode: Cardinal): canStatus; </b>
427 * \source_end
428 *
429 * This function sets the bus timing parameters for the specified CAN controller.
430 *
431 * The library provides default values for \a tseg1, \a tseg2, \a sjw and \a
432 * noSamp when \a freq is specified to one of the
433 * pre-defined constants, \ref canBITRATE_xxx.
434 *
435 * If \a freq is any other value, no default values are supplied by the
436 * library.
437 *
438 * If you are using multiple handles to the same physical channel, for example
439 * if you are writing a threaded application, you must call \ref canBusOff() once
440 * for each handle. The same applies to \ref canBusOn() - the physical channel will
441 * not go off bus until the last handle to the channel goes off bus.
442 *
443 * \note Use \ref canSetBusParamsC200() to set the bus timing parameters in the
444 * ubiquitous 82c200 bit-timing register format.
445 *
446 * \param[in] hnd An open handle to a CAN controller.
447 * \param[in] freq Bit rate (measured in bits per second); or one of the
448 * predefined constants \ref canBITRATE_xxx, which are described below.
449 * \param[in] tseg1 Time segment 1, that is, the number of quanta from (but not
450 * including) the Sync Segment to the sampling point.
451 * \param[in] tseg2 Time segment 2, that is, the number of quanta from the sampling
452 * point to the end of the bit.
453 * \param[in] sjw The Synchronization Jump Width; can be 1,2,3, or 4.
454 * \param[in] noSamp The number of sampling points; can be 1 or 3.
455 * \param[in] syncmode Unsupported and ignored.
456 *
457 * \return \ref canOK (zero) if success
458 * \return \ref canERR_xxx (negative) if failure
459 *
460 * \sa \ref page_code_snippets_bit_rate, \ref page_user_guide_misc_bitrate,
461 * \ref page_user_guide_init_bit_rate, \ref page_code_snippets_examples
462 * \sa \ref canSetBusParamsC200(), \ref canGetBusParams()
463 *
464 */
465canStatus CANLIBAPI canSetBusParams (const CanHandle hnd,
466 long freq,
467 unsigned int tseg1,
468 unsigned int tseg2,
469 unsigned int sjw,
470 unsigned int noSamp,
471 unsigned int syncmode);
472
473/**
474 * \ingroup CAN
475 *
476 * \source_cs <b>static Canlib.canStatus canSetBusParamsFd(int hnd, int freq_brs, int tseg1_brs, int tseg2_brs, int sjw_brs);</b>
477 *
478 * \source_delphi <b>function canSetBusParamsFd(hnd: canHandle; freq_brs: Longint; tseg1_brs, tseg2_brs, sjw_brs): canStatus;</b>
479 * \source_end
480 *
481 * This function sets the bus timing parameters for the specified
482 * CAN FD controller.
483 *
484 * The library provides default values for \a tseg1_brs, \a tseg2_brs,
485 * \a sjw_brs and \a freq_brs is specified to one of the pre-defined
486 * constants, \ref canBITRATE_xxx.
487 *
488 * If \a freq_brs is any other value, no default values are supplied
489 * by the library.
490 *
491 * \param[in] hnd An open handle to a CAN controller.
492 * \param[in] freq_brs Bit rate (measured in bits per second); or one of the
493 * predefined constants \ref canBITRATE_xxx, which are described below.
494 * \param[in] tseg1_brs Time segment 1, that is, the number of quanta from (but not
495 * including) the Sync Segment to the sampling point.
496 * \param[in] tseg2_brs Time segment 2, that is, the number of quanta from the sampling
497 * point to the end of the bit.
498 * \param[in] sjw_brs The Synchronization Jump Width; can be 1,2,3, or 4.
499 *
500 * \return \ref canOK (zero) if success
501 * \return \ref canERR_xxx (negative) if failure
502 */
503canStatus CANLIBAPI canSetBusParamsFd(const CanHandle hnd,
504 long freq_brs,
505 unsigned int tseg1_brs,
506 unsigned int tseg2_brs,
507 unsigned int sjw_brs);
508
509/**
510 * \ingroup CAN
511 * \name canFD_SSP_xxx
512 * \anchor canFD_SSP_xxx
513 *
514 * Flags for \ref canFdSecondarySamplePoint().
515 *
516 * @{
517 */
518/** Secondary sample point is automatically adjusted dynamically. */
519#define canFD_SSP_AUTO 0
520/** Set secondary sample point. */
521#define canFD_SSP_SET 1
522/** Get secondary sample point. */
523#define canFD_SSP_GET 2
524/** @} */
525
526/**
527 * \ingroup CAN
528 *
529 * \source_cs <b>static Canlib.canStatus canFdSecondarySamplePoint(int hnd, ref int ns, int mode);</b>
530 *
531 * \source_delphi <b>function canFdSecondarySamplePoint(hnd: canHandle; var ns: Cardinal; mode: Cardinal): canStatus;</b>
532 * \source_end
533 *
534 * This function sets or retrieves the secondary sampling point for
535 * the specified CAN FD controller.
536 *
537 * If \a mode is canFD_SSP_AUTO, the \a ns argument is ignored, and
538 * the secondary sampling point is automatically adjusted dynamically.
539 * If \a mode is canFD_SSP_SET, the secondary sampling point is set to
540 * \a ns, and if \a mode is canFD_SSP_GET, it is retrived and stored
541 * in \a ns.
542 *
543 * \param[in] hnd An open handle to a CAN controller.
544 * \param[in,out] ns Secondary sampling point delay, in nanoseconds.
545 * \param[in] mode One of canFD_SSP_AUTO, canFD_SSP_GET, or
546 * canFD_SSP_SET.
547 *
548 * \return \ref canOK (zero) if success
549 * \return \ref canERR_xxx (negative) if failure
550 */
551canStatus CANLIBAPI canFdSecondarySamplePoint(const CanHandle hnd,
552 unsigned int *ns,
553 int mode);
554
555/**
556 * \ingroup CAN
557 *
558 * \source_cs <b>static Canlib.canStatus canGetBusParams(int handle, out long freq, out int tseg1, out int tseg2, out int sjw, out int noSamp, out int syncmode);</b>
559 *
560 * \source_delphi <b>function canGetBusParams(handle: canHandle; var freq: Longint; var tseg1, tseg2, sjw, noSamp, syncmode: Cardinal): canStatus; </b>
561 * \source_end
562 *
563 * This function retrieves the current bus parameters for the specified
564 * channel.
565 *
566 * The anatomy of a CAN bit is discussed in detail at Kvaser's
567 * web site at <a href="http://www.kvaser.com">www.kvaser.com</a>.
568 *
569 * \param[in] hnd An open handle to a CAN controller.
570 * \param[out] freq Bit rate (bits per second).
571 * \param[out] tseg1 Time segment 1, that is, the number of quanta from (but not
572 * including) the Sync Segment to the sampling point.
573 * \param[out] tseg2 Time segment 2, that is, the number of quanta from the sampling
574 * point to the end of the bit.
575 * \param[out] sjw The Synchronization Jump Width; can be 1,2,3, or 4.
576 * \param[out] noSamp The number of sampling points; can be 1 or 3.
577 * \param[out] syncmode Unsupported, always read as zero.
578 *
579 * \return \ref canOK (zero) if success
580 * \return \ref canERR_xxx (negative) if failure
581 *
582 * \sa \ref page_code_snippets_bit_rate, \ref page_user_guide_init_bit_rate
583 * \sa \ref canSetBusParams(), \ref canSetBusParamsC200()
584 *
585 */
586canStatus CANLIBAPI canGetBusParams (const CanHandle hnd,
587 long *freq,
588 unsigned int *tseg1,
589 unsigned int *tseg2,
590 unsigned int *sjw,
591 unsigned int *noSamp,
592 unsigned int *syncmode);
593
594
595/**
596 * \ingroup CAN
597 *
598 * \source_cs <b>static Canlib.canStatus canGetBusParamsFd(int hnd, out long freq_brs, out int tseg1_brs, out int tseg2_brs, out int sjw_brs);</b>
599 *
600 * \source_delphi <b>function canGetBusParamsFd(hnd: canHandle; var freq_brs: Longint; var tseg1_brs, tseg2_brs, sjw_brs): canStatus;</b>
601 * \source_end
602 *
603 * This function retrieves the current bus parameters for the specified
604 * CAN FD channel.
605 *
606 * \param[in] hnd An open handle to a CAN FD controller.
607 * \param[out] freq_brs Bit rate (bits per second).
608 * \param[out] tseg1_brs Time segment 1, that is, the number of quanta from (but not
609 * including) the Sync Segment to the sampling point.
610 * \param[out] tseg2_brs Time segment 2, that is, the number of quanta from the sampling
611 * point to the end of the bit.
612 * \param[out] sjw_brs The Synchronization Jump Width; can be 1,2,3, or 4.
613 *
614 * \return \ref canOK (zero) if success
615 * \return \ref canERR_xxx (negative) if failure
616 */
617canStatus CANLIBAPI canGetBusParamsFd(const CanHandle hnd,
618 long *freq_brs,
619 unsigned int *tseg1_brs,
620 unsigned int *tseg2_brs,
621 unsigned int *sjw_brs);
622/**
623 * \ingroup CAN
624 *
625 * \source_cs <b>static Canlib.canStatus canSetBusOutputControl(int handle, int drivertype);</b>
626 *
627 * \source_delphi <b>function canSetBusOutputControl(handle: canHandle; drivertype: Cardinal): canStatus; </b>
628 * \source_end
629 *
630 * This function sets the driver type for a CAN controller. This corresponds
631 * loosely to the bus output control register in the CAN controller, hence the
632 * name of this function. CANLIB does not allow for direct manipulation of the
633 * bus output control register; instead, symbolic constants are used to select
634 * the desired driver type.
635 *
636 * \note Not all CAN driver types are supported on all cards.
637 *
638 * \param[in] hnd A handle to an open circuit.
639 * \param[out] drivertype Can driver type, \ref canDRIVER_xxx)
640 *
641 * \return \ref canOK (zero) if success
642 * \return \ref canERR_xxx (negative) if failure
643 *
644 * \sa \ref canGetBusOutputControl()
645 */
646canStatus CANLIBAPI canSetBusOutputControl (const CanHandle hnd,
647 const unsigned int drivertype);
648
649/**
650 * \ingroup CAN
651 *
652 * \source_cs <b>static Canlib.canStatus canGetBusOutputControl(int handle, out int drivertype);</b>
653 *
654 * \source_delphi <b>function canGetBusOutputControl(handle: canHandle; var drivertype: Cardinal): canStatus; </b>
655 * \source_end
656 *
657 * This function retrieves the current CAN controller driver type.
658 * This corresponds loosely to the bus output control register in the
659 * CAN controller, hence the name of this function. CANLIB does not
660 * allow for direct manipulation of the bus output control register;
661 * instead, symbolic constants are used to select the desired driver
662 * type.
663 *
664 * \note Don't confuse the CAN controller driver type with the bus driver
665 * type. The CAN controller is not connected directly to the CAN bus;
666 * instead, it is connected to a bus transceiver circuit which interfaces
667 * directly to the bus. The "CAN controller driver type" we are talking
668 * about here refers to the mode which the CAN controller uses to drive
669 * the bus transceiver circuit.
670 *
671 * \note Silent Mode is not supported by all CAN controllers.
672 *
673 * \param[in] hnd An open handle to a CAN circuit.
674 * \param[in] drivertype A pointer to an unsigned int which receives the
675 * current driver type. The driver type can be either
676 * \ref canDRIVER_NORMAL or \ref canDRIVER_SILENT.
677 *
678 * \return \ref canOK (zero) if success
679 * \return \ref canERR_xxx (negative) if failure
680 *
681 * \sa \ref canSetBusOutputControl()
682 */
683canStatus CANLIBAPI canGetBusOutputControl (const CanHandle hnd,
684 unsigned int *drivertype);
685
686/**
687 * \ingroup CAN
688 *
689 * \source_cs <b>static Canlib.canStatus canAccept(int handle, int envelope, int flag);</b>
690 *
691 * \source_delphi <b>function canAccept(handle: canHandle; envelope: Longint; flag: Cardinal): canStatus; </b>
692 * \source_end
693 *
694 * This routine sets the message acceptance filters on a CAN channel.
695 *
696 * On some boards the acceptance filtering is done by the CAN hardware; on
697 * other boards (typically those with an embedded CPU,) the acceptance
698 * filtering is done by software. \ref canAccept() behaves in the same way for all
699 * boards, however.
700 *
701 * \ref canSetAcceptanceFilter() and \ref canAccept() both serve the same purpose but the
702 * former can set the code and mask in just one call.
703 *
704 * If you want to remove a filter, call \ref canAccept() with the mask set to 0.
705 *
706 * \note You can set the extended code and mask only on CAN boards that support
707 * extended identifiers.
708 *
709 * \note Not all CAN boards support different masks for standard and extended
710 * CAN identifiers.
711 *
712 * \param[in] hnd An open handle to a CAN circuit.
713 * \param[in] envelope The mask or code to set.
714 * \param[in] flag Any of \ref canFILTER_SET_CODE_STD,
715 * \ref canFILTER_SET_MASK_STD,
716 * \ref canFILTER_SET_CODE_EXT or
717 * \ref canFILTER_SET_MASK_EXT
718 *
719 * \return \ref canOK (zero) if success
720 * \return \ref canERR_xxx (negative) if failure
721 *
722 * \sa \ref page_user_guide_misc_code_and_mask,
723 * \ref page_user_guide_send_recv_filters,
724 * \ref page_code_snippets_examples
725 */
726canStatus CANLIBAPI canAccept (const CanHandle hnd,
727 const long envelope,
728 const unsigned int flag);
729
730/**
731 * \ingroup CAN
732 *
733 * \source_cs <b>static Canlib.canStatus canReadStatus(int handle, out long flags);</b>
734 *
735 * \source_delphi <b>function canReadStatus(handle: canHandle; var flags: Longint): canStatus; </b>
736 * \source_end
737 *
738 * Returns the status for the specified circuit. flags points to a longword
739 * which receives a combination of the \ref canSTAT_xxx flags.
740 *
741 * \note \ref canReadStatus() returns the latest known status of the specified
742 * circuit. If a status change happens precisely when \ref canReadStatus() is
743 * called, it may not be reflected in the returned result.
744 *
745 * \param[in] hnd A handle to an open circuit.
746 * \param[out] flags Pointer to a \c DWORD which receives the status flags;
747 * this is a combination of any of the \ref canSTAT_xxx.
748 *
749 * \return \ref canOK (zero) if success
750 * \return \ref canERR_xxx (negative) if failure
751 *
752 */
753canStatus CANLIBAPI canReadStatus (const CanHandle hnd,
754 unsigned long *const flags);
755
756/**
757 * \ingroup CAN
758 *
759 * \source_cs <b>static Canlib.canStatus canReadErrorCounters(int handle, out int txErr, out int rxErr, out int ovErr);</b>
760 *
761 * \source_delphi <b>function canReadErrorCounters(handle: canHandle; var txErr, rxErr, ovErr: Cardinal): canStatus; </b>
762 * \source_end
763 *
764 * Reads the error counters of the CAN controller.
765 *
766 * \ref canReadErrorCounters() returns the latest known values of the error counters
767 * in the specified circuit. If the error counters change values precisely when
768 * \ref canReadErrorCounters() is called, it may not be reflected in the returned
769 * result.
770 *
771 * It is allowed to pass \c NULL as the value of the \a txErr, \a rxErr, and \a
772 * ovErr parameters.
773 *
774 * Use \ref canIoCtl() to clear the counters.
775 *
776 * \note Not all CAN controllers provide access to the error counters;
777 * in this case, an educated guess is returned.
778 *
779 * \param[in] hnd A handle to an open circuit.
780 * \param[out] txErr A pointer to a \c DWORD which receives the transmit error
781 * counter.
782 * \param[out] rxErr A pointer to a \c DWORD which receives the receive error
783 * counter.
784 * \param[out] ovErr A pointer to a \c DWORD which receives the number of
785 * overrun errors.
786 *
787 * \return \ref canOK (zero) if success
788 * \return \ref canERR_xxx (negative) if failure
789 *
790 * \sa \ref canIoCtl()
791 */
792canStatus CANLIBAPI canReadErrorCounters (const CanHandle hnd,
793 unsigned int *txErr,
794 unsigned int *rxErr,
795 unsigned int *ovErr);
796
797/**
798 * \ingroup CAN
799 *
800 * \source_cs <b>static Canlib.canStatus canWrite(int handle, int id, byte[] msg, int dlc, int flag);</b>
801 *
802 * \source_delphi <b>function canWrite(handle: canHandle; id: Longint; msg: Pointer; dlc: Cardinal; flag: Cardinal): canStatus; </b>
803 * \source_end
804 *
805 * This function sends a CAN message. The call returns immediately after queuing
806 * the message to the driver.
807 *
808 * If you are using the same channel via multiple handles, note that the
809 * default behaviour is that the different handles will "hear" each other just as
810 * if each handle referred to a channel of its own. If you open, say, channel 0
811 * from thread A and thread B and then send a message from thread A, it will be
812 * "received" by thread B.
813 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
814 *
815 * \note The message has been queued for transmission when this calls return.
816 * It has not necessarily been sent.
817 *
818 * \param[in] hnd A handle to an open CAN circuit.
819 * \param[in] id The identifier of the CAN message to send.
820 * \param[in] msg A pointer to the message data, or \c NULL.
821 * \param[in] dlc The length of the message. Can be at most 8.
822 * \param[in] flag A combination of message flags, \ref canMSG_xxx.
823 * Use this parameter to send extended (29-bit) frames
824 * and/or remote frames. Use \ref canMSG_EXT and/or
825 * \ref canMSG_RTR for this purpose.
826 *
827 * \return \ref canOK (zero) if success
828 * \return \ref canERR_xxx (negative) if failure
829 *
830 * \sa \ref page_user_guide_send_recv_sending, \ref page_code_snippets_examples
831 * \sa \ref canWriteSync(), \ref canWriteWait()
832 *
833 */
834canStatus CANLIBAPI canWrite (const CanHandle hnd,
835 long id,
836 void *msg,
837 unsigned int dlc,
838 unsigned int flag);
839
840/**
841 * \ingroup CAN
842 *
843 * \source_cs <b>static Canlib.canStatus canWriteSync(int handle, long timeout);</b>
844 *
845 * \source_delphi <b>function canWriteSync(handle: canHandle; timeout: Longint): canStatus; </b>
846 * \source_end
847 *
848 * Waits until all CAN messages for the specified handle are sent, or the
849 * timeout period expires.
850 *
851 * \param[in] hnd A handle to an open CAN circuit.
852 * \param[in] timeout The timeout in milliseconds. 0xFFFFFFFF gives an
853 * infinite timeout.
854 *
855 * \return \ref canOK (zero) if the queue emptied before the timeout period came to
856 * its end.
857 * \return \ref canERR_TIMEOUT (negative) not all messages were transmitted when
858 * the timeout occurred.
859 * \return \ref canERR_PARAM (negative) This could be caused by an erroneous
860 * parameter, or if you have turned TXACKs off (by using \ref canIoCtl())
861 * because if you do you can't use this call. The driver simply doesn't
862 * know when all the messages are sent!
863 * \return \ref canERR_xxx (negative) if failure
864 *
865 * \sa \ref canWrite(), \ref canWriteWait()
866 */
867canStatus CANLIBAPI canWriteSync (const CanHandle hnd, unsigned long timeout);
868
869/**
870 * \ingroup CAN
871 *
872 * \source_cs <b>static Canlib.canStatus canRead(int handle, out int id, byte[] msg, out int dlc, out int flag, out long time);</b>
873 *
874 * \source_delphi <b>function canRead(handle: canHandle; var id: Longint; msg: Pointer; var dlc: Cardinal; var flag: Cardinal; var time: Longint): canStatus; </b>
875 * \source_end
876 *
877 * Reads a message from the receive buffer. If no message is available, the
878 * function returns immediately with return code \ref canERR_NOMSG.
879 *
880 * If you are using the same channel via multiple handles, note that the
881 * default behaviour is that the different handles will "hear" each other just as
882 * if each handle referred to a channel of its own. If you open, say, channel 0
883 * from thread A and thread B and then send a message from thread A, it will be
884 * "received" by thread B.
885 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
886 *
887 * It is allowed to pass \c NULL as the value of \a id, \a msg, \a dlc, \a
888 * flag, and \a time.
889 *
890 * \param[in] hnd A handle to an open circuit.
891 * \param[out] id Pointer to a buffer which receives the CAN identifier.
892 * This buffer will only get the identifier. To determine
893 * whether this identifier was standard (11-bit) or extended
894 * (29-bit), and/or whether it was remote or not, or if it
895 * was an error frame, examine the contents of the flag
896 * argument.
897 * \param[out] msg Pointer to the buffer which receives the message data.
898 * This buffer must be large enough (i.e. 8 bytes.) Only the
899 * message data is copied; the rest of the buffer is left
900 * as-is.
901 * \param[out] dlc Pointer to a buffer which receives the message length.
902 * \param[out] flag Pointer to a buffer which receives the message flags,
903 * which is a combination of the \ref canMSG_xxx and
904 * \ref canMSGERR_xxx values.
905 * \param[out] time Pointer to a buffer which receives the message time stamp.
906 *
907 * \return \ref canOK (zero) if a message was read.
908 * \return \ref canERR_NOMSG (negative) if there was no message available.
909 * \return \ref canERR_xxx (negative) if failure
910 *
911 * \sa \ref page_user_guide_send_recv_reading, \ref
912 * page_user_guide_send_recv_mailboxes, \ref page_code_snippets_examples,
913 * \ref page_user_guide_time_accuracy_and_resolution
914 * \sa \ref canReadSpecific(), \ref canReadSpecificSkip(), \ref canReadSync(),
915 * \ref canReadSyncSpecific(), \ref canReadWait()
916 *
917 */
918canStatus CANLIBAPI canRead (const CanHandle hnd,
919 long *id,
920 void *msg,
921 unsigned int *dlc,
922 unsigned int *flag,
923 unsigned long *time);
924
925/**
926 * \ingroup CAN
927 *
928 * \source_cs <b>static Canlib.canStatus canReadWait(int handle, out int id, byte[] msg, out int dlc, out int flag, out long time, long timeout);</b>
929 *
930 * \source_delphi <b>function canReadWait(handle: canHandle; var id: Longint; msg: Pointer; var dlc: Cardinal; var flag: Cardinal; var time: Longint; timeout: Longint): canStatus; </b>
931 * \source_end
932 *
933 * Reads a message from the receive buffer. If no message is available, the
934 * function waits until a message arrives or a timeout occurs.
935 *
936 * If you are using the same channel via multiple handles, note that the
937 * default behaviour is that the different handles will "hear" each other just as
938 * if each handle referred to a channel of its own. If you open, say, channel 0
939 * from thread A and thread B and then send a message from thread A, it will be
940 * "received" by thread B.
941 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
942 *
943 * It is allowed to pass \c NULL as the value of \a id, \a msg, \a dlc, \a
944 * flag, and \a time.
945 *
946 * \param[in] hnd A handle to an open circuit.
947 * \param[out] id Pointer to a buffer which receives the CAN identifier.
948 * This buffer will only get the identifier. To determine
949 * whether this identifier was standard (11-bit) or extended
950 * (29-bit), and/or whether it was remote or not, or if it
951 * was an error frame, examine the contents of the flag
952 * argument.
953 * \param[out] msg Pointer to the buffer which receives the message data.
954 * This buffer must be large enough (i.e. 8 bytes.).
955 * \param[out] dlc Pointer to a buffer which receives the message length.
956 * \param[out] flag Pointer to a buffer which receives the message flags,
957 * which is a combination of the \ref canMSG_xxx and
958 * \ref canMSGERR_xxx values.
959 * \param[out] time Pointer to a buffer which receives the message time stamp.
960 * \param[in] timeout If no message is immediately available, this parameter
961 * gives the number of milliseconds to wait for a message
962 * before returning. 0xFFFFFFFF gives an infinite timeout.
963 *
964 * \return \ref canOK (zero) if a message was read.
965 * \return \ref canERR_NOMSG (negative) if there was no message available.
966 * \return \ref canERR_xxx (negative) if failure
967 *
968 * \sa \ref canRead(),\win_start \ref canReadSpecific(), \ref canReadSpecificSkip(),
969 * \ref canReadSyncSpecific(),\win_end \ref canReadSync()
970 *
971 * \sa \ref page_user_guide_time_accuracy_and_resolution
972 */
973canStatus CANLIBAPI canReadWait (const CanHandle hnd,
974 long *id,
975 void *msg,
976 unsigned int *dlc,
977 unsigned int *flag,
978 unsigned long *time,
979 unsigned long timeout);
980
981#if defined(CANLIB_DECLARE_ALL)
982/**
983 * \ingroup CAN
984 *
985 * \source_cs <b>static Canlib.canStatus canReadSync(int handle, long timeout);</b>
986 *
987 * \source_delphi <b>function canReadSync(handle: canHandle; timeout: Longint): canStatus; </b>
988 * \source_end
989 *
990 * Waits until the receive buffer contains at least one message or a timeout
991 * occurs.
992 *
993 * If you are using the same channel via multiple handles, note that the
994 * default behaviour is that the different handles will "hear" each other just as
995 * if each handle referred to a channel of its own. If you open, say, channel 0
996 * from thread A and thread B and then send a message from thread A, it will be
997 * "received" by thread B.
998 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
999 *
1000 * \param[in] hnd A handle to an open circuit.
1001 * \param[in] timeout The timeout in milliseconds. 0xFFFFFFFF gives an
1002 * infinite timeout.
1003 *
1004 * \return \ref canOK (zero) if the queue contains the desired message.
1005 * \return \ref canERR_TIMEOUT (negative) if a timeout occurs before a message
1006 * arrived.
1007 * \return \ref canERR_xxx (negative) if the call fails.
1008 *
1009 * \sa \ref canRead(), \win_start \ref canReadSpecific(), \ref canReadSpecificSkip(),
1010 * \ref canReadSyncSpecific(),\win_end \ref canReadWait()
1011 */
1012canStatus CANLIBAPI canReadSync (const CanHandle hnd, unsigned long timeout);
1013
1014#endif
1015
1016/**
1017 * \ingroup CAN
1018 *
1019 * \todo Rewrite, this is just guessing from windows version
1020 *
1021 * \source_cs <b>static Canlib.canStatus canSetNotify(int handle, IntPtr win_handle, int aNotifyFlags);</b>
1022 *
1023 * \source_delphi <b>function canSetNotify(handle: canHandle; aHWnd: HWND; aNotifyFlags: Cardinal): canStatus; </b>
1024 * \source_end
1025 *
1026 * This function associates a callback function with the CAN circuit.
1027 *
1028 * \param[in] hnd A handle to an open CAN circuit.
1029 * \param[in] callback Handle to callback routine.
1030 * \param[in] notifyFlags The events specified with \ref canNOTIFY_xxx, for
1031 * which callback should be called.
1032 * \param[in] tag Pointer to user defined data. Passed to callback in the \ref canNotifyData struct.
1033 *
1034 * \return \ref canOK (zero) if success
1035 * \return \ref canERR_xxx (negative) if failure
1036 *
1037 */
1038canStatus CANLIBAPI canSetNotify (const CanHandle hnd,
1039 void (*callback)(canNotifyData *),
1040 unsigned int notifyFlags,
1041 void *tag);
1042
1043/**
1044 * \ingroup CAN
1045 *
1046 * Returns raw handle/file descriptor for use in system calls.
1047 * \note Use this function with caution.
1048 *
1049 * \param[in] hnd CanHandle
1050 * \param[out] pvFd Pointer to raw can data.
1051 *
1052 * \return \ref canOK (zero) if success
1053 * \return \ref canERR_xxx (negative) if failure
1054 *
1055 */
1056canStatus CANLIBAPI canGetRawHandle (const CanHandle hnd, void *pvFd);
1057
1058/**
1059 * \ingroup CAN
1060 *
1061 * \source_cs <b>static Canlib.canStatus canTranslateBaud(ref int freq, out int tseg1, out int tseg2, out int sjw, out int nosamp, out int syncMode);</b>
1062 *
1063 * \source_delphi <b>function canTranslateBaud(var freq: longint; var tseg1, tseg2, sjw, noSamp, syncMode: Cardinal): canStatus; </b>
1064 * \source_end
1065 *
1066 * This function translates the \ref canBITRATE_xxx constants to their corresponding
1067 * bus parameter values. At return, this \a freq contains the actual bit rate
1068 * (in bits per second). \a TSeg1 is the number of quanta (less one) in a bit
1069 * before the sampling point. \a TSeg2 is the number of quanta after the
1070 * sampling point.
1071 *
1072 * \param[in] freq A pointer to a \c DWORD which contains the \ref canBITRATE_xxx
1073 * constant to translate
1074 * \param[in] tseg1 A pointer to a buffer which receives the Time segment 1,
1075 * that is, the number of quanta from (but not including)
1076 * the Sync Segment to the sampling point.
1077 * \param[in] tseg2 A pointer to a buffer which receives the Time segment 2,
1078 * that is, the number of quanta from the sampling point to
1079 * the end of the bit.
1080 * \param[in] sjw A pointer to a buffer which receives the Synchronization
1081 * Jump Width; can be 1,2,3, or 4.
1082 * \param[in] nosamp A pointer to a buffer which receives the number of
1083 * sampling points; can be 1 or 3.
1084 * \param[in] syncMode Unsupported, always read as zero.
1085 *
1086 * \return \ref canOK (zero) if success
1087 * \return \ref canERR_xxx (negative) if failure
1088 *
1089 * \sa \ref canSetBusParams()
1090 */
1091canStatus CANLIBAPI canTranslateBaud (long *const freq,
1092 unsigned int *const tseg1,
1093 unsigned int *const tseg2,
1094 unsigned int *const sjw,
1095 unsigned int *const nosamp,
1096 unsigned int *const syncMode);
1097
1098/**
1099 * \ingroup General
1100 *
1101 * \source_cs <b>static Canlib.canStatus canGetErrorText(Canlib.canStatus err, out string buf_str);</b>
1102 *
1103 * \source_delphi <b>function canGetErrorText(err: canStatus; buf: PChar; bufsiz: Cardinal): canStatus; </b>
1104 * \source_end
1105 *
1106 * This function translates an error code (\ref canERR_xxx)
1107 * to a human-readable, English text.
1108 *
1109 * \param[in] err The error code.
1110 * \param[in,out] buf The buffer which is to receive the text, which is a
1111 * zero-terminated string (provided the buffer is large enough.)
1112 * \param[in] bufsiz The length of the input buffer.
1113 *
1114 * \return \ref canOK (zero) if success
1115 * \return \ref canERR_xxx (negative) if failure
1116 *
1117 * \sa \ref page_code_snippets_examples
1118 *
1119 */
1120canStatus CANLIBAPI canGetErrorText (canStatus err, char *buf, unsigned int bufsiz);
1121
1122/**
1123 * \ingroup General
1124 *
1125 * \source_cs <b>static short canGetVersion();</b>
1126 *
1127 * \source_delphi <b>function canGetVersion: Word; </b>
1128 * \source_end
1129 *
1130 * \win_start
1131 * This API call returns the version of the CANLIB API DLL (canlib32.dll). The
1132 * most significant byte is the major version number and the least significant
1133 * byte is the minor version number.
1134 *
1135 * The actual version of the different driver files can be obtained by studying
1136 * the version resources in each of the files.
1137 *
1138 * \note The version number of the canlib32.dll file is not related to the
1139 * product version of CANLIB you are using. CANLIB consists of several
1140 * driver and DLL files. To obtain the product version, use
1141 * \ref canGetVersionEx().
1142 *
1143 * \return version number of canlib32.dll
1144 *
1145 * \sa \ref page_user_guide_build_driver_version
1146 * \sa \ref canGetVersionEx(), \ref canProbeVersion()
1147 *
1148 * \win_end
1149 *
1150 * \linux_start
1151 * This API call returns the version of the CANLIB API library (libcanlib.so.x.y). The
1152 * most significant byte is the major version number and the least significant
1153 * byte is the minor version number.
1154 *
1155 * \return version number of libcanlib.so.x.y
1156 *
1157 * \linux_end
1158 *
1159 *
1160 */
1161unsigned short CANLIBAPI canGetVersion (void);
1162
1163/**
1164 * \ingroup General
1165 *
1166 * \source_cs <b>static Canlib.canStatus canIoCtl(int handle, int func, int val);<br>
1167 static Canlib.canStatus canIoCtl(int handle, int func, out int val);<br>
1168 static Canlib.canStatus canIoCtl(int handle, int func, out string str_buf);<br>
1169 static Canlib.canStatus canIoCtl(int handle, int func, ref object obj_buf);</b>
1170 *
1171 * \source_delphi <b>function canIoCtl(handle: canHandle; func: Cardinal; buf: Pointer; buflen: Cardinal): canStatus; </b>
1172 * \source_end
1173 *
1174 * This API call performs several different functions; these are described
1175 * below. The functions are handle-specific unless otherwise noted; this means
1176 * that they affect only the handle you pass to \ref canIoCtl(), whereas other open
1177 * handles will remain unaffected. The contents of \a buf after the call is
1178 * dependent on the function code you specified.
1179 *
1180 * \param[in] hnd A handle to an open circuit.
1181 * \param[in] func A \ref canIOCTL_xxx function code
1182 * \param[in,out] buf Pointer to a buffer containing function-dependent data;
1183 or a \c NULL pointer for certain function codes. The
1184 buffer can be used for both input and output
1185 depending on the function code. See \ref canIOCTL_xxx.
1186 * \param[in] buflen The length of the buffer.
1187 *
1188 * \return \ref canOK (zero) if success
1189 * \return \ref canERR_xxx (negative) if failure
1190 *
1191 */
1192canStatus CANLIBAPI canIoCtl (const CanHandle hnd,
1193 unsigned int func,
1194 void *buf,
1195 unsigned int buflen);
1196
1197/* Note the difference from the windows version */
1198
1199/**
1200 * \ingroup CAN
1201 *
1202 * \source_cs <b>static canStatus canReadTimer(int hnd, long time);</b>
1203 *
1204 * \source_delphi <b>function canReadTimer(handle: canHandle; time: longint): canStatus; </b>
1205 * \source_end
1206 *
1207 * Reads the current time from the clock used to timestamp the
1208 * messages for the indicated circuit.
1209 *
1210 * This API may return \ref canERR_INVHANDLE and/or \ref canERR_NOTINITIALIZED!
1211 * This happens if \a hnd is invalid, or if the library was not initialized.
1212 *
1213 * \note The clock used to timestamp the messages may not be available for
1214 * direct reading on all platforms. In such cases, the PC's clock is used
1215 * to return an approximation of the current time. Note that clock drift might
1216 * occur in this case.
1217 *
1218 * \param[in] hnd A handle to an open circuit.
1219 * \param[out] time The current time, with the prevailing time resolution.
1220 *
1221 * \return \ref canOK (zero) if success
1222 * \return \ref canERR_xxx (negative) if failure
1223 *
1224 * \sa \ref page_user_guide_time_accuracy_and_resolution
1225 * \sa \ref kvReadTimer()
1226 */
1227canStatus CANLIBAPI canReadTimer (const CanHandle hnd, unsigned long *time);
1228
1229/**
1230 * \ingroup CAN
1231 *
1232 * \source_cs <b>static int canOpenChannel(int channel, int flags);</b>
1233 *
1234 * \source_delphi <b>function canOpenChannel(channel: Integer; flags: Integer): canHandle; </b>
1235 * \source_end
1236 *
1237 * Opens a CAN channel (circuit) and returns a handle which is used
1238 * in subsequent calls to CANLIB.
1239 *
1240 *
1241 * Channel numbering is dependent on the installed hardware. The first channel
1242 * always has number 0.
1243 *
1244 * For example,
1245 *
1246 * \li If you have a single LAPcan, the channels are numbered 0 and 1.
1247 *
1248 * \li If you have a USBcan Professional, the channels are numbered 0-1
1249 * according to the labels on the cables.
1250 *
1251 * \li The virtual channels come after all physical channels.
1252 *
1253 * If you are using multiple threads, note that the returned handle is usable
1254 * only in the context of the thread that created it. That is, you must call
1255 * \ref canOpenChannel() in each of the threads in your application that uses the
1256 * CAN bus. You can open the same channel from multiple threads, but you must
1257 * call \ref canOpenChannel() once per thread.
1258 *
1259 * If you are using the same channel via multiple handles, note that the
1260 * default behaviour is that the different handles will "hear" each other just as
1261 * if each handle referred to a channel of its own. If you open, say, channel 0
1262 * from thread A and thread B and then send a message from thread A, it will be
1263 * "received" by thread B.
1264 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
1265 *
1266 * \note The handle returned may be zero which is perfectly valid.
1267 *
1268 * \note This call replaces the \ref canOpen() API call and serves the same purpose.
1269 *
1270 * \param[in] channel The number of the channel. Channel numbering is hardware
1271 * dependent.
1272 * \param[in] flags A combination of \ref canOPEN_xxx flags
1273 *
1274 * \return Returns a handle to the opened circuit, or \ref canERR_xxx
1275 * (negative) if the call failed.
1276 *
1277 * \sa \ref page_code_snippets_examples, \ref page_user_guide_virtual_info
1278 * \sa \ref canGetNumberOfChannels(), \ref canGetChannelData(), \ref canIoCtl()
1279 *
1280 */
1281CanHandle CANLIBAPI canOpenChannel (int channel, int flags);
1282
1283/**
1284 * \ingroup General
1285 *
1286 * \source_cs <b>static Canlib.canStatus canGetNumberOfChannels(out int channelCount);</b>
1287 *
1288 * \source_delphi <b>function canGetNumberOfChannels(var channelCount: Integer): canStatus; </b>
1289 * \source_end
1290 *
1291 * This function returns the number of available CAN channels in the
1292 * computer. The virtual channels are included in this number.
1293 *
1294 * \param[out] channelCount A pointer to a \c DWORD which will receive the current
1295 * number of channels.
1296 *
1297 * \return \ref canOK (zero) if success
1298 * \return \ref canERR_xxx (negative) if failure
1299 *
1300 * \sa \ref page_code_snippets_examples, \ref page_user_guide_virtual_info
1301 * \sa \ref canGetChannelData()
1302 */
1303canStatus CANLIBAPI canGetNumberOfChannels (int *channelCount);
1304
1305/**
1306 * \ingroup General
1307 *
1308 * \source_cs <b>static Canlib.canStatus canGetChannelData(int channel, int item, out object buffer);</b>
1309 *
1310 * \source_delphi <b>function canGetChannelData(channel, item: Integer; var buffer; bufsize: Cardinal): canStatus; </b>
1311 * \source_end
1312 *
1313 * This function can be used to retrieve certain pieces of information about a channel.
1314 *
1315 * \note You must pass a channel number and not a channel handle.
1316 *
1317 * \param[in] channel The number of the channel you are interested in. Channel
1318 * numbers are integers in the interval beginning at 0
1319 * (zero) and ending at the value returned by
1320 * \ref canGetNumberOfChannels() minus 1.
1321 * \param[in] item This parameter specifies what data to obtain for the
1322 * specified channel. The value is one of the constants
1323 * \ref canCHANNELDATA_xxx.
1324 * \param[in,out] buffer The address of a buffer which is to receive the data.
1325 * \param[in] bufsize The size of the buffer to which the buffer parameter
1326 * points.
1327 *
1328 * \return \ref canOK (zero) if success
1329 * \return \ref canERR_xxx (negative) if failure
1330 *
1331 * \sa \ref page_code_snippets_examples
1332 * \sa \ref canGetNumberOfChannels()
1333 */
1334canStatus CANLIBAPI canGetChannelData (int channel,
1335 int item,
1336 void *buffer,
1337 size_t bufsize);
1338
1339/**
1340 * \ingroup General
1341 * \anchor canCHANNELDATA_xxx
1342 * \name canCHANNELDATA_xxx
1343 *
1344 * These defines are used in \ref canGetChannelData().
1345 *
1346 * @{
1347 */
1348
1349 /**
1350 * This define is used in \ref canGetChannelData(), \a buffer
1351 * mentioned below refers to this functions argument.
1352 *
1353 * \a buffer points to a 32-bit unsigned integer that receives the
1354 * capabilities of the CAN controller; this is a combination of the \ref
1355 * canCHANNEL_CAP_xxx flags.
1356 */
1357#define canCHANNELDATA_CHANNEL_CAP 1
1358
1359 /**
1360 * This define is used in \ref canGetChannelData(), \a buffer
1361 * mentioned below refers to this functions argument.
1362 *
1363 * \a buffer points to a 32-bit unsigned integer that receives the
1364 * capabilities of the CAN transceiver; this is a combination of the
1365 * \ref canDRIVER_CAP_xxx flags.
1366 */
1367#define canCHANNELDATA_TRANS_CAP 2
1368
1369 /**
1370 * This define is used in \ref canGetChannelData(), \a buffer
1371 * mentioned below refers to this functions argument.
1372 *
1373 * \note Currently not implemented.
1374 */
1375#define canCHANNELDATA_CHANNEL_FLAGS 3 // available, etc
1376
1377 /**
1378 * This define is used in \ref canGetChannelData(), \a buffer
1379 * mentioned below refers to this functions argument.
1380 *
1381 * \a buffer points to a 32-bit unsigned integer that receives the hardware
1382 * type of the card. This value is any one of the \ref canHWTYPE_xxx
1383 * constants.
1384 */
1385#define canCHANNELDATA_CARD_TYPE 4
1386
1387 /**
1388 * This define is used in \ref canGetChannelData(), \a buffer
1389 * mentioned below refers to this functions argument.
1390 *
1391 * \a buffer points to a 32-bit unsigned integer that receives the card's
1392 * number in the computer. Each card type is numbered separately. For
1393 * example, the first LAPcan card in a machine will have number 0, the second
1394 * LAPcan number 1, etc.
1395 */
1396#define canCHANNELDATA_CARD_NUMBER 5
1397
1398 /**
1399 * This define is used in \ref canGetChannelData(), \a buffer
1400 * mentioned below refers to this functions argument.
1401 *
1402 * \a buffer points to a 32-bit unsigned integer which receives the channel
1403 * number on the card.
1404 */
1405#define canCHANNELDATA_CHAN_NO_ON_CARD 6
1406
1407 /**
1408 * This define is used in \ref canGetChannelData(), \a buffer
1409 * mentioned below refers to this functions argument.
1410 *
1411 * \a buffer points to a 64-bit (8 bytes) area which receives the serial
1412 * number of the card. If the card doesn't have a serial number, 0 is
1413 * returned. The serial number is an 8-byte unsigned integer. Currently, no
1414 * products are using all 8 bytes; at most 4 bytes are used.
1415 */
1416#define canCHANNELDATA_CARD_SERIAL_NO 7
1417
1418 /**
1419 * This define is used in \ref canGetChannelData(), \a buffer
1420 * mentioned below refers to this functions argument.
1421 *
1422 * \a buffer points to a 64-bit (8 bytes) area which receives the serial
1423 * number of the transceiver. The serial number is an 8-byte unsigned
1424 * integer. If the transceiver doesn't have a serial number, 0 is returned.
1425 */
1426#define canCHANNELDATA_TRANS_SERIAL_NO 8
1427
1428 /**
1429 * This define is used in \ref canGetChannelData(), \a buffer
1430 * mentioned below refers to this functions argument.
1431 *
1432 * \a buffer points to a 64-bit (8 bytes) area which receives the firmware
1433 * revision number on the card. This number consists of four 16-bit words:
1434 * the major revision, the minor revision, the release number and the build
1435 * number, listed in order from the most significant to the least
1436 * significant.
1437 */
1438#define canCHANNELDATA_CARD_FIRMWARE_REV 9
1439
1440 /**
1441 * This define is used in \ref canGetChannelData(), \a buffer
1442 * mentioned below refers to this functions argument.
1443 *
1444 * \a buffer points to a 64-bit (8 bytes) area which receives the hardware
1445 * revision number on the card. This number consists of four 16-bit words;
1446 * the two most significant are always 0, and the two least significant are
1447 * the major revision and the minor revision, listed in order from the most
1448 * significant to the least significant.
1449 */
1450#define canCHANNELDATA_CARD_HARDWARE_REV 10
1451
1452 /**
1453 * This define is used in \ref canGetChannelData(), \a buffer
1454 * mentioned below refers to this functions argument.
1455 *
1456 * \a buffer points to a 8-byte area which receives the UPC (EAN) number for
1457 * the card. If there is no UPC number, the buffer is filled with zeros. The
1458 * UPC (EAN) number is coded as a BCD string with the LSB first, so
1459 * e.g. 733-0130-00122-0 is coded as 0x30001220 0x00073301.
1460 */
1461#define canCHANNELDATA_CARD_UPC_NO 11
1462
1463 /**
1464 * This define is used in \ref canGetChannelData(), \a buffer
1465 * mentioned below refers to this functions argument.
1466 *
1467 * \a buffer points to a 8-byte area which receives the UPC (EAN) number for
1468 * the transceiver. If there is no UPC number, the buffer is filled with
1469 * zeros. The UPC (EAN) number is coded as a BCD string with the LSB first,
1470 * so e.g. 733-0130-00122-0 is coded as 0x30001220 0x00073301.
1471 */
1472#define canCHANNELDATA_TRANS_UPC_NO 12
1473
1474 /**
1475 * This define is used in \ref canGetChannelData(), \a buffer
1476 * mentioned below refers to this functions argument.
1477 *
1478 * \a buffer points to an area which receives a zero-terminated string with a
1479 * clear-text name of the channel.
1480 *
1481 * \note Use of this item code is no longer recommended. The returned
1482 * channel name doesn't contain the exact hardware type (it just contains
1483 * the device family) and uses zero-based channel numbering, which is not
1484 * user friendly. Instead, use e.g. \ref canCHANNELDATA_DEVDESCR_ASCII and
1485 * \ref canCHANNELDATA_CHAN_NO_ON_CARD to build your own channel name.
1486 *
1487 *\win_start
1488 * \sa \ref canCHANNELDATA_DEVNAME_ASCII
1489 *\win_end
1490 */
1491#define canCHANNELDATA_CHANNEL_NAME 13
1492#if defined(CANLIB_DECLARE_ALL)
1493
1494 /**
1495 * This define is used in \ref canGetChannelData(), \a buffer
1496 * mentioned below refers to this functions argument.
1497 *
1498 * \a buffer points to an array of 4 16-bit unsigned integers which receives
1499 * the file version number of the second-level DLL driver file, i.e. the DLL
1500 * that interfaces between CANLIB32.DLL and the driver proper.
1501 *
1502 * Contents depening on index:
1503 *
1504 * \li 0: 0
1505 * \li 1: The build number
1506 * \li 2: The minor revision number
1507 * \li 3: The major revision number
1508 */
1509# define canCHANNELDATA_DLL_FILE_VERSION 14
1510
1511 /**
1512 * This define is used in \ref canGetChannelData(), \a buffer
1513 * mentioned below refers to this functions argument.
1514 *
1515 * \a buffer points to an array of 4 16-bit unsigned integers which receives
1516 * the product version number of the second-level DLL driver file, i.e. the
1517 * DLL that interfaces between CANLIB32.DLL and the driver proper.
1518 *
1519 * Contents depening on index:
1520 *
1521 * \li 0: 0
1522 * \li 1: 1
1523 * \li 2: The minor revision number
1524 * \li 3: The major revision number
1525 */
1526# define canCHANNELDATA_DLL_PRODUCT_VERSION 15
1527
1528 /**
1529 * This define is used in \ref canGetChannelData(), \a buffer
1530 * mentioned below refers to this functions argument.
1531 *
1532 * \a buffer points to a 32-bit unsigned integer which receives a number that
1533 * identifies the second-level DLL driver file, i.e. the DLL that interfaces
1534 * between CANLIB32.DLL and the driver proper.
1535 *
1536 * Values:
1537 *
1538 * \li 1: kvalapw.dll - used with CANLIB up to 2.29.
1539 *
1540 * \li 2: kvalapw2.dll - used with CANLIB from 3.0 and on.
1541 */
1542# define canCHANNELDATA_DLL_FILETYPE 16
1543
1544 /**
1545 * This define is used in \ref canGetChannelData(), \a buffer
1546 * mentioned below refers to this functions argument.
1547 *
1548 * \a buffer points to a 32-bit unsigned integer which receives the CAN
1549 * transceiver type of the specified channel. This value is one of the
1550 * \ref canTRANSCEIVER_TYPE_xxx
1551 */
1552# define canCHANNELDATA_TRANS_TYPE 17
1553
1554 /**
1555 * This define is used in \ref canGetChannelData(), \a buffer
1556 * mentioned below refers to this functions argument.
1557 *
1558 * \a buffer points to a 32-bit unsigned integer which receives an address
1559 * indicating where the device is located on its underlying bus. The
1560 * interpretation of this number is bus-specific. If the address is unknown
1561 * or the bus driver does not support an address, the bus driver leaves this
1562 * member at its default value of 0xFFFFFFFF.
1563 *
1564 * The following list describes the information certain bus drivers store in
1565 * the Address field for their child devices:
1566 *
1567 * \li ISA: Does not supply an address. Defaults to 0xFFFFFFFF.
1568 *
1569 * \li PC Card (PCMCIA): The socket number (typically 0x00 or 0x40)
1570 *
1571 * \li PCI: The device number in the high word and the function number in the
1572 * low word.
1573 *
1574 * \li USB: The port number.
1575 */
1576# define canCHANNELDATA_DEVICE_PHYSICAL_POSITION 18
1577
1578 /**
1579 * This define is used in \ref canGetChannelData(), \a buffer
1580 * mentioned below refers to this functions argument.
1581 *
1582 * \a buffer points to a 32-bit unsigned integer which receives a number
1583 * associated with the device that can be displayed in the user
1584 * interface. This number is typically a user-perceived slot number, such as
1585 * a number printed next to the slot on the board, or some other number that
1586 * makes locating the physical device easier for the user. For buses with no
1587 * such convention, or when the UI number is unknown, 0xFFFFFFFF is returned.
1588 */
1589# define canCHANNELDATA_UI_NUMBER 19
1590
1591 /**
1592 * This define is used in \ref canGetChannelData(), \a buffer
1593 * mentioned below refers to this functions argument.
1594 *
1595 * \a buffer points to a 32-bit unsigned integer which is set to 0, if the
1596 * legacy time synchronization is not currently enabled for the specified
1597 * channel, and 1, if the legacy time synchronization is currently enabled
1598 * for the specified channel.
1599 *
1600 * Legacy time synchronization is a mechanism that will keep the PC and CAN
1601 * channel clocks in sync. The synchronization is done in the driver, which
1602 * periodically calculates the difference between the PC clock and the CAN
1603 * device clock and compensates for the clock drift by recalculating the CAN
1604 * message time stamps. You need to enable clock synchronization in the
1605 * Control Panel using the Kvaser Hardware applet.
1606 *
1607 * \note Legacy time synchronization is implemented only on LAPcan and LAPcan
1608 * II. It is not related to Kvaser MagiSync&tm; which is implemented in the
1609 * high-end members of the Kvaser Leaf family. Kvaser MagiSync&tm; is always
1610 * enabled and allows for much more accurate time synchronization.
1611 *
1612 */
1613# define canCHANNELDATA_TIMESYNC_ENABLED 20
1614
1615 /**
1616 * This define is used in \ref canGetChannelData(), \a buffer
1617 * mentioned below refers to this functions argument.
1618 *
1619 * \a buffer points to an array of four 16-bit unsigned integers which
1620 * receives the file version number of the kernel-mode driver.
1621 *
1622 * Contents depening on index:
1623 *
1624 * \li 0: The build number
1625 * \li 1: 0
1626 * \li 2: The minor revision number
1627 * \li 3: The major revision number
1628 */
1629# define canCHANNELDATA_DRIVER_FILE_VERSION 21
1630
1631 /**
1632 * This define is used in \ref canGetChannelData(), \a buffer
1633 * mentioned below refers to this functions argument.
1634 *
1635 * \a buffer points to an array of four 16-bit unsigned integers which
1636 * receives the product version number of the kernel-mode driver.
1637 *
1638 * Contents depening on index:
1639 *
1640 * \li 0: 0
1641 * \li 1: 0
1642 * \li 2: The minor revision number
1643 * \li 3: The major revision number
1644 */
1645# define canCHANNELDATA_DRIVER_PRODUCT_VERSION 22
1646
1647 /**
1648 * This define is used in \ref canGetChannelData(), \a buffer
1649 * mentioned below refers to this functions argument.
1650 *
1651 * \a buffer points to a buffer which receives the device manufacturer's name
1652 * as a zero-terminated Unicode string.
1653 */
1654# define canCHANNELDATA_MFGNAME_UNICODE 23
1655
1656 /**
1657 * This define is used in \ref canGetChannelData(), \a buffer
1658 * mentioned below refers to this functions argument.
1659 *
1660 * \a buffer points to a buffer which receives the device manufacturer's name
1661 * as a zero-terminated ASCII string.
1662 */
1663# define canCHANNELDATA_MFGNAME_ASCII 24
1664
1665 /**
1666 * This define is used in \ref canGetChannelData(), \a buffer
1667 * mentioned below refers to this functions argument.
1668 *
1669 * \a buffer points to a buffer which receives the product name of the device
1670 * as a zero-terminated Unicode string.
1671 */
1672# define canCHANNELDATA_DEVDESCR_UNICODE 25
1673
1674 /**
1675 * This define is used in \ref canGetChannelData(), \a buffer
1676 * mentioned below refers to this functions argument.
1677 *
1678 * \a buffer points to a buffer which receives the product name of the device
1679 * as a zero-terminated ASCII string.
1680 */
1681# define canCHANNELDATA_DEVDESCR_ASCII 26
1682
1683 /**
1684 * This define is used in \ref canGetChannelData(), \a buffer
1685 * mentioned below refers to this functions argument.
1686 *
1687 * \a buffer points to a buffer which receives the name of the device
1688 * driver (e.g. "kcans") as a zero-terminated ASCII string.
1689 *
1690 * \note The device driver names have no special meanings and may change
1691 * from a release to another.
1692 */
1693# define canCHANNELDATA_DRIVER_NAME 27
1694
1695#endif
1696
1697 /** @} */
1698
1699
1700/**
1701 * \name canCHANNEL_IS_xxx
1702 * \anchor canCHANNEL_IS_xxx
1703 *
1704 * These channelFlags are used in \ref canGetChannelData() and in conjunction with \ref
1705 * canCHANNELDATA_CHANNEL_FLAGS.
1706 * @{
1707 */
1708/** Used with \ref canCHANNELDATA_CHANNEL_FLAGS, indicates that the channel is
1709 opened exclusively. */
1710#define canCHANNEL_IS_EXCLUSIVE 0x0001
1711/** Used with \ref canCHANNELDATA_CHANNEL_FLAGS, indicates that the channel is
1712 opened. */
1713#define canCHANNEL_IS_OPEN 0x0002
1714
1715/** Used with \ref canCHANNELDATA_CHANNEL_FLAGS, indicates that the channel is
1716 * opened as CAN FD. */
1717
1718#define canCHANNEL_IS_CANFD 0x0004
1719 /** @} */
1720
1721
1722/**
1723 * \name canHWTYPE_xxx
1724 * \anchor canHWTYPE_xxx
1725 *
1726 * The following constants can be returned from \ref canGetChannelData(), using the
1727 * \ref canCHANNELDATA_CARD_TYPE item code. They identify the hardware type for
1728 * the channel specified in the call to \ref canGetChannelData().
1729 *
1730 * \note They indicate a hardware type, but not necessarily a specific
1731 * product. For example, \ref canHWTYPE_LAPCAN is returned both for LAPcan and
1732 * LAPcan II. (You can use \ref canGetChannelData() to obtain the UPC/EAN code for
1733 * the device. This number uniquely identifies the product.)
1734 *
1735 * @{
1736 */
1737#define canHWTYPE_NONE 0 ///< Unknown or undefined
1738#define canHWTYPE_VIRTUAL 1 ///< The virtual CAN bus
1739#define canHWTYPE_LAPCAN 2 ///< LAPcan Family
1740#define canHWTYPE_CANPARI 3 ///< CANpari (obsolete).
1741#define canHWTYPE_PCCAN 8 ///< PCcan Family
1742#define canHWTYPE_PCICAN 9 ///< PCIcan Family
1743#define canHWTYPE_USBCAN 11 ///< USBcan (obsolete).
1744#define canHWTYPE_PCICAN_II 40 ///< PCIcan II family
1745#define canHWTYPE_USBCAN_II 42 ///< USBcan II, USBcan Rugged, Kvaser Memorator
1746#define canHWTYPE_SIMULATED 44 ///< Simulated CAN bus for Kvaser Creator (obsolete).
1747#define canHWTYPE_ACQUISITOR 46 ///< Kvaser Acquisitor (obsolete).
1748#define canHWTYPE_LEAF 48 ///< Kvaser Leaf Family
1749#define canHWTYPE_PC104_PLUS 50 ///< Kvaser PC104+
1750#define canHWTYPE_PCICANX_II 52 ///< Kvaser PCIcanx II
1751#define canHWTYPE_MEMORATOR_II 54 ///< Kvaser Memorator Professional family
1752#define canHWTYPE_MEMORATOR_PRO 54 ///< Kvaser Memorator Professional family
1753#define canHWTYPE_USBCAN_PRO 56 ///< Kvaser USBcan Professional
1754#define canHWTYPE_IRIS 58 ///< Obsolete name, use canHWTYPE_BLACKBIRD instead
1755#define canHWTYPE_BLACKBIRD 58 ///< Kvaser BlackBird
1756#define canHWTYPE_MEMORATOR_LIGHT 60 ///< Kvaser Memorator Light
1757#define canHWTYPE_MINIHYDRA 62 ///< Obsolete name, use canHWTYPE_EAGLE instead
1758#define canHWTYPE_EAGLE 62 ///< Kvaser Eagle family
1759#define canHWTYPE_BAGEL 64 ///< Obsolete name, use canHWTYPE_BLACKBIRD_V2 instead
1760#define canHWTYPE_BLACKBIRD_V2 64 ///< Kvaser BlackBird v2
1761#define canHWTYPE_MINIPCIE 66 ///< Kvaser Mini PCI Express
1762#define canHWTYPE_USBCAN_KLINE 68 ///< USBcan Pro HS/K-Line
1763#define canHWTYPE_ETHERCAN 70 ///< Kvaser Ethercan
1764#define canHWTYPE_USBCAN_LIGHT 72 ///< Kvaser USBcan Light
1765#define canHWTYPE_USBCAN_PRO2 74 ///< Kvaser USBcan Pro 5xHS and variants
1766#define canHWTYPE_PCIE_V2 76 ///< Kvaser PCIEcan 4xHS and variants
1767#define canHWTYPE_MEMORATOR_PRO2 78 ///< Kvaser Memorator Pro 5xHS and variants
1768#define canHWTYPE_LEAF2 80 ///< Kvaser Leaf Pro HS v2 and variants
1769#define canHWTYPE_MEMORATOR_LIGHT2 82 ///< Kvaser Memorator Light (2nd generation)
1770
1771
1772/** @} */
1773
1774/**
1775 * \name canCHANNEL_CAP_xxx
1776 * \anchor canCHANNEL_CAP_xxx
1777 *
1778 * Channel capabilities.
1779 */
1780#define canCHANNEL_CAP_EXTENDED_CAN 0x00000001L ///< Can use extended identifiers
1781#define canCHANNEL_CAP_BUS_STATISTICS 0x00000002L ///< Can report busload etc
1782#define canCHANNEL_CAP_ERROR_COUNTERS 0x00000004L ///< Can return error counters
1783#define canCHANNEL_CAP_CAN_DIAGNOSTICS 0x00000008L ///< Can report CAN diagnostics
1784#define canCHANNEL_CAP_GENERATE_ERROR 0x00000010L ///< Can send error frames
1785#define canCHANNEL_CAP_GENERATE_OVERLOAD 0x00000020L ///< Can send CAN overload frame
1786#define canCHANNEL_CAP_TXREQUEST 0x00000040L ///< Can report when a CAN messsage transmission is initiated
1787#define canCHANNEL_CAP_TXACKNOWLEDGE 0x00000080L ///< Can report when a CAN messages has been transmitted
1788#define canCHANNEL_CAP_VIRTUAL 0x00010000L ///< Virtual CAN channel
1789#define canCHANNEL_CAP_SIMULATED 0x00020000L ///< Simulated CAN channel
1790#define canCHANNEL_CAP_REMOTE 0x00040000L ///< Remote CAN channel (e.g. BlackBird).
1791#define canCHANNEL_CAP_CAN_FD 0x00080000L ///< CAN-FD channel
1792#define canCHANNEL_CAP_CAN_FD_NONISO 0x00100000L ///< Supports Non-ISO CAN-FD channel
1793
1794/** @} */
1795
1796/**
1797 * \name canDRIVER_CAP_xxx
1798 * \anchor canDRIVER_CAP_xxx
1799 *
1800 * Driver (transceiver) capabilities.
1801 * @{
1802 */
1803/** Used with \ref canCHANNELDATA_TRANS_CAP */
1804#define canDRIVER_CAP_HIGHSPEED 0x00000001L
1805/** @} */
1806
1807/**
1808 * \ingroup General
1809 * \name canIOCTL_xxx
1810 * \anchor canIOCTL_xxx
1811 *
1812 * These defines are used in \ref canIoCtl().
1813 *
1814 * @{
1815 */
1816
1817
1818 /**
1819 * This define is used in \ref canIoCtl(), \a buf and \a buflen refers to this
1820 * functions arguments.
1821 *
1822 * Tells CANLIB to "prefer" extended identifiers; that is, if you send a
1823 * message with \ref canWrite() and don't specify \ref canMSG_EXT nor \ref canMSG_STD,
1824 * \ref canMSG_EXT will be assumed. The contents of \a buf and \a buflen are
1825 * ignored. \ref canRead() et al will set \ref canMSG_EXT and/or \ref canMSG_STD as usual
1826 * and are not affected by this call.
1827 */
1828#define canIOCTL_PREFER_EXT 1
1829
1830 /**
1831 * This define is used in \ref canIoCtl(), \a buf and \a buflen refers to this
1832 * functions arguments.
1833 *
1834 * Tells CANLIB to "prefer" standard identifiers; that is, if you send a
1835 * message with \ref canWrite() and don't specify \ref canMSG_EXT nor \ref canMSG_STD,
1836 * \ref canMSG_STD will be assumed. The contents of \a buf and \a buflen are
1837 * ignored. \ref canRead() et al will set \ref canMSG_EXT and/or \ref canMSG_STD as usual
1838 * and are not affected by this call.
1839 */
1840#define canIOCTL_PREFER_STD 2
1841// 3,4 reserved.
1842
1843 /**
1844 * This define is used in \ref canIoCtl(), \a buf and \a buflen refers to this
1845 * functions arguments.
1846 *
1847 * Tells CANLIB to clear the CAN error counters. The contents of \a buf and \a
1848 * buflen are ignored.
1849 *
1850 * \note Not all CAN controllers support this operation (and if they don't,
1851 * nothing will happen.)
1852 */
1853#define canIOCTL_CLEAR_ERROR_COUNTERS 5
1854
1855 /**
1856 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1857 * functions argument.
1858 *
1859 * \a buf points to a DWORD which contains the desired time-stamp clock
1860 * resolution in microseconds. The default value is 1000 microseconds, i.e.
1861 * one millisecond.
1862 *
1863 * \note The accuracy of the clock isn't affected.
1864 */
1865#define canIOCTL_SET_TIMER_SCALE 6
1866
1867 /**
1868 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1869 * functions argument.
1870 *
1871 * \a buf points to a DWORD which contains
1872 *
1873 * \li 0: to turn Transmit Acknowledges off.
1874 * \li 1: to turn Transmit Acknowledges on.
1875 * \li 2: to turn Transmit Acknowledges off, even for the driver's internal
1876 * usage. This might enhance performance but will cause some other APIs to
1877 * stop working (for example, the current size of the transmit queue can not
1878 * be read when this mode is active.)
1879 *
1880 * The default value is 0, Transmit Acknowledge is off.
1881 */
1882#define canIOCTL_SET_TXACK 7
1883
1884 /**
1885 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1886 * functions argument.
1887 *
1888 * \a buf points at a \c DWORD which receives the current RX queue level. The
1889 * returned value is approximative (this is because not all hardware supports
1890 * retrieving the queue levels. In that case a best-effort guess is
1891 * returned. Also note that a device with embedded CPU will report its queue
1892 * levels to the host computer after a short delay that depends on the bus
1893 * traffic intensity, and consequently the value returned by the call to
1894 * \ref canIoCtl() might be a few milliseconds old.)
1895 */
1896#define canIOCTL_GET_RX_BUFFER_LEVEL 8
1897
1898 /**
1899 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1900 * functions argument.
1901 *
1902 * \a buf points at a \c DWORD which receives the current TX queue level. The
1903 * returned value is approximative (this is because not all hardware supports
1904 * retrieving the queue levels. In that case a best-effort guess is
1905 * returned. Also note that a device with embedded CPU will report its queue
1906 * levels to the host computer after a short delay that depends on the bus
1907 * traffic intensity, and consequently the value returned by the call to
1908 * \ref canIoCtl() might be a few milliseconds old.)
1909 */
1910#define canIOCTL_GET_TX_BUFFER_LEVEL 9
1911
1912 /**
1913 * This define is used in \ref canIoCtl(), \a buf and \a buflen refers to this
1914 * functions arguments.
1915 *
1916 * Discard the current contents of the RX queue. The values of \a buf and \a
1917 * buflen are ignored.
1918 *
1919 * \note This is the same thing as calling \ref canFlushReceiveQueue()
1920 */
1921#define canIOCTL_FLUSH_RX_BUFFER 10
1922
1923 /**
1924 * This define is used in \ref canIoCtl(), \a buf and \a buflen refers to this
1925 * functions arguments.
1926 *
1927 * Discard the current contents of the TX queue. The values of \a buf and \a
1928 * buflen are ignored.
1929 *
1930 * \note This is the same thing as calling \ref canFlushTransmitQueue().
1931 */
1932#define canIOCTL_FLUSH_TX_BUFFER 11
1933
1934 /**
1935 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1936 * functions argument.
1937 *
1938 * \a buf points to a \c DWORD which contains the desired time-stamp clock
1939 * resolution in microseconds. Note that the accuracy of the clock isn't
1940 * affected. The default value is 1000 microseconds, i.e. one millisecond.
1941 */
1942#define canIOCTL_GET_TIMER_SCALE 12
1943
1944 /**
1945 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1946 * functions argument.
1947 *
1948 * \a buf points to a \c DWORD which contains
1949 *
1950 * \li \c 0 to turn Transmit Requests off.
1951 * \li \c 1 to turn Transmit Requests on.
1952 *
1953 * Default value is \c 0, Transmit Requests off.
1954 */
1955#define canIOCTL_SET_TXRQ 13
1956
1957 /**
1958 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1959 * functions argument.
1960 *
1961 * \a buf points at a \c DWORD which receives a Windows Event handle which can
1962 * be passed to the Win32 API \c WaitForSingleObject. The event is signaled
1963 * when "something" (typically that a CAN message has been received or
1964 * transmitted) happens in the driver.
1965 *
1966 * \note There is no more information available as to what happened when this
1967 * call returns. The call may return on an "internal" event in CANLIB and your
1968 * application must be prepared to handle this (i.e. go to sleep again.)
1969 * \note If \ref canWaitForEvent() returns with success status (\ref canOK), you must call
1970 * \ref canRead() repeatedly until it returns \ref canERR_NOMSG, before calling
1971 * \ref canWaitForEvent() again. This will flush the driver's internal event queues.
1972 * Failure to call \ref canRead() can cause \ref canWaitForEvent() to get stuck in a state
1973 * where it always sleeps for the specified timeout and then returns with
1974 * \ref canERR_TIMEOUT.
1975 *
1976 * \sa \ref canWaitForEvent()
1977 *
1978 * \note You must not set, reset, nor close this handle. Waiting on it is
1979 * the only supported operation.
1980 */
1981#define canIOCTL_GET_EVENTHANDLE 14
1982
1983 /**
1984 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
1985 * functions argument.
1986 *
1987 * \note Not yet implemented.
1988 */
1989#define canIOCTL_SET_BYPASS_MODE 15
1990
1991 /**
1992 * This define is used in \ref canIoCtl().
1993 *
1994 * This is only intended for internal use.
1995 */
1996#define canIOCTL_SET_WAKEUP 16
1997
1998#if defined(CANLIB_DECLARE_ALL)
1999
2000 /**
2001 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2002 * functions argument.
2003 *
2004 * \a buf points to a HANDLE which receives the Windows handle related to the
2005 * CANLIB handle.
2006 */
2007# define canIOCTL_GET_DRIVERHANDLE 17
2008
2009 /**
2010 * This define is used in \ref canIoCtl().
2011 *
2012 * This is only intended for internal use.
2013 */
2014# define canIOCTL_MAP_RXQUEUE 18
2015
2016 /**
2017 * This define is used in \ref canIoCtl().
2018 *
2019 * This is only intended for internal use.
2020 */
2021# define canIOCTL_GET_WAKEUP 19
2022
2023 /**
2024 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2025 * functions argument.
2026 *
2027 * \a buf points to a BYTE which contains
2028 *
2029 * \li \c 0 to turn access error reporting off, and
2030 * \li \c 1 to turn access error reporting on.
2031 *
2032 * Default value is \c 0, access error reporting off.
2033 */
2034# define canIOCTL_SET_REPORT_ACCESS_ERRORS 20
2035
2036 /**
2037 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2038 * functions argument.
2039 *
2040 * \a buf points to a BYTE which receives the current setting of the access
2041 * error reporting (0 or 1.)
2042 */
2043# define canIOCTL_GET_REPORT_ACCESS_ERRORS 21
2044
2045 /**
2046 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2047 * functions argument.
2048 *
2049 * Connects the handle to the virtual bus number (0..31) which the \a buf
2050 * points to.
2051 */
2052# define canIOCTL_CONNECT_TO_VIRTUAL_BUS 22
2053
2054 /**
2055 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2056 * functions argument.
2057 *
2058 * Disonnects the handle from the virtual bus number (0..31) which the \a buf
2059 * points to.
2060 */
2061# define canIOCTL_DISCONNECT_FROM_VIRTUAL_BUS 23
2062
2063 /**
2064 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2065 * functions argument.
2066 *
2067 * \a buf points to a \ref canUserIoPortData struct that contains a port number
2068 * and a port value to set. This is used by special hardware only.
2069 */
2070# define canIOCTL_SET_USER_IOPORT 24
2071
2072 /**
2073 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2074 * functions argument.
2075 *
2076 * \a buf points to a \ref canUserIoPortData struct that contains a port
2077 * number. After the call, the struct will contain the current value of the
2078 * I/O port. This is used by special hardware only.
2079 */
2080# define canIOCTL_GET_USER_IOPORT 25
2081
2082 /**
2083 * This define is used in \ref canIoCtl().
2084 *
2085 * This is only intended for internal use.
2086 */
2087# define canIOCTL_SET_BUFFER_WRAPAROUND_MODE 26
2088
2089 /**
2090 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2091 * functions argument.
2092 *
2093 * Use this function code to set the size of the receive buffer for a
2094 * specific handle. \a buf points to an unsigned integer which contains the
2095 * new size (number of messages) of the receive buffer.
2096 *
2097 * \note The receive buffer consumes system nonpaged pool memory, which is a
2098 * limited resource. Do not increase the receive buffer size unless you
2099 * have good reasons to do so.
2100 *
2101 * \note You can't use this function code when the channel is on bus.
2102 */
2103# define canIOCTL_SET_RX_QUEUE_SIZE 27
2104
2105 /**
2106 * This define is used in \ref canIoCtl().
2107 *
2108 * This is only intended for internal use.
2109 */
2110# define canIOCTL_SET_USB_THROTTLE 28
2111
2112 /**
2113 * This define is used in \ref canIoCtl().
2114 *
2115 * This is only intended for internal use.
2116 */
2117# define canIOCTL_GET_USB_THROTTLE 29
2118
2119 /**
2120 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2121 * functions argument.
2122 *
2123 * \a buf points to a DWORD. If the value is zero, the CAN clock will not be
2124 * reset at buson for the handle. Otherwise, the CAN clock will be reset at
2125 * buson.
2126 *
2127 * Default value is \c 1, the CAN clock will be reset at buson.
2128 */
2129# define canIOCTL_SET_BUSON_TIME_AUTO_RESET 30
2130
2131 /**
2132 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2133 * functions argument.
2134 *
2135 * Returns the state of the Transmit Acknowledge as a DWORD in \a buf:
2136 *
2137 * \li 0: Transmit Acknowledges is turned off.
2138 * \li 1: Transmit Acknowledges is turned on.
2139 * \li 2: Transmit Acknowledges is turned off, even for the driver's internal
2140 * usage.
2141 */
2142# define canIOCTL_GET_TXACK 31
2143
2144 /**
2145 * This define is used in \ref canIoCtl(), \a buf mentioned below refers to this
2146 * functions argument.
2147 *
2148 * \a buf points to an unsigned byte. If the value is zero, the local transmit
2149 * echo is turned off for the handle. Otherwise, local transmit echo is turned
2150 * on.
2151 *
2152 * Local transmit echo is turned on by default on all handles. This means
2153 * that if two handles are open on the same channel, and a message is
2154 * transmitted on the first handle, it will be received as a normal message
2155 * on the second handle. Use the \ref canIOCTL_SET_LOCAL_TXECHO function code to
2156 * turn this function off, if it is not desired on a certain handle.
2157 */
2158# define canIOCTL_SET_LOCAL_TXECHO 32
2159
2160#endif
2161 /** @} */
2162
2163#if defined(CANLIB_DECLARE_ALL)
2164/** Used in \ref canIOCTL_SET_USER_IOPORT and \ref canIOCTL_GET_USER_IOPORT. */
2165typedef struct {
2166 unsigned int portNo; ///< Port number used in e.g. \ref canIOCTL_SET_USER_IOPORT
2167 unsigned int portValue; ///< Port value used in e.g. \ref canIOCTL_SET_USER_IOPORT
2168} canUserIoPortData;
2169
2170#endif
2171
2172#if defined(CANLIB_DECLARE_ALL)
2173#endif
2174
2175/**
2176 * \ingroup CAN
2177 *
2178 * \source_cs <b>static Canlib.canStatus canSetBusParamsC200(int hnd, byte btr0, byte btr1);</b>
2179 *
2180 * \source_delphi <b>function canSetBusParamsC200(hnd: canHandle; btr0, btr1: byte): canStatus; </b>
2181 * \source_end
2182 *
2183 * This function sets the bus timing parameters using the same
2184 * convention as the 82c200 CAN controller (which is the same as many
2185 * other CAN controllers, for example, the 82527.)
2186 *
2187 * To calculate the bit timing parameters, you can use the bit timing
2188 * calculator that is included with CANLIB SDK. Look in the BIN directory.
2189 *
2190 * 82c200 Bit Timing
2191 *
2192 * \li \a btr0 [b7..b6]: SJW - 1
2193 * \li \a btr0 [b5..b0]: Prescaler -1
2194 * \li \a btr1 [b7]: \c 1: 3 samples, \c 0: 1 samples
2195 * \li \a btr1 [b6..b4]: tseg2 - 1
2196 * \li \a btr1 [b3..b0]: tseg1 - 2
2197 *
2198 * \note CANLIB will always behave as if the clock frequency is 16 MHz. It does
2199 * not matter if the device has a different physical clock, since this will be
2200 * compensated for by the driver.
2201 *
2202 * \param[in] hnd A handle to an open CAN circuit.
2203 * \param[in] btr0 The desired bit timing, formatted as the contents of the
2204 * BTR0 register in the 82c200.
2205 * \param[in] btr1 The desired bit timing, formatted as the contents of the
2206 * BTR1 register in the 82c200.
2207 *
2208 * \return \ref canOK (zero) if success
2209 * \return \ref canERR_xxx (negative) if failure
2210 *
2211 *
2212 * \sa \ref page_code_snippets_bit_rate, \ref page_user_guide_misc_bitrate
2213 * \sa \ref canSetBusParams()
2214 */
2215canStatus CANLIBAPI canSetBusParamsC200 (const CanHandle hnd, BYTE btr0, BYTE btr1);
2216
2217#if defined(CANLIB_DECLARE_ALL)
2218#endif
2219
2220
2221#if defined(CANLIB_DECLARE_ALL)
2222/**
2223 * \ingroup ObjectBuffers
2224 *
2225 * \source_cs <b>static Canlib.canStatus canObjBufFreeAll(int handle);</b>
2226 *
2227 * \source_delphi <b>function canObjBufFreeAll(handle: canHandle): canStatus; </b>
2228 * \source_end
2229 *
2230 * Deallocates all object buffers on the specified handle. The
2231 * buffers cannot be referenced after this operation.
2232 *
2233 * \param[in] hnd An open handle to a CAN circuit.
2234 *
2235 * \return \ref canOK (zero) if success
2236 * \return \ref canERR_xxx (negative) if failure
2237 *
2238 * \sa \ref page_user_guide_send_recv_obj_buf
2239 * \sa \ref canObjBufFree(), \ref canObjBufAllocate()
2240 */
2241canStatus CANLIBAPI canObjBufFreeAll (const CanHandle hnd);
2242
2243/**
2244 * \ingroup ObjectBuffers
2245 *
2246 * \source_cs <b>static Canlib.canStatus canObjBufAllocate(int handle, int type);</b>
2247 *
2248 * \source_delphi <b>function canObjBufAllocate(handle: canHandle; tp: Integer): canStatus; </b>
2249 * \source_end
2250 *
2251 * Allocates an object buffer associated with a handle to a CAN
2252 * circuit.
2253 *
2254 * \param[in] hnd An open handle to a CAN circuit.
2255 * \param[in] type The type of the buffer. Must be one of \ref canOBJBUF_TYPE_xxx
2256 *
2257 * \return A buffer index (zero or positive) if success.
2258 * \return \ref canERR_xxx (negative) if failure
2259 *
2260 * \sa \ref page_user_guide_send_recv_obj_buf
2261 * \sa \ref canObjBufFree(), \ref canObjBufFreeAll()
2262 */
2263canStatus CANLIBAPI canObjBufAllocate (const CanHandle hnd, int type);
2264
2265 /**
2266 * \name canOBJBUF_TYPE_xxx
2267 * \anchor canOBJBUF_TYPE_xxx
2268 *
2269 * Used in \ref canObjBufAllocate().
2270 *
2271 * @{
2272 */
2273#define canOBJBUF_TYPE_AUTO_RESPONSE 0x01 ///< The buffer is an auto-response buffer.
2274#define canOBJBUF_TYPE_PERIODIC_TX 0x02 ///< The buffer is an auto-transmit buffer.
2275 /** @} */
2276
2277/**
2278 * \ingroup ObjectBuffers
2279 *
2280 * \source_cs <b>static Canlib.canStatus canObjBufFree(int handle, int idx);</b>
2281 *
2282 * \source_delphi <b>function canObjBufFree(handle: canHandle; idx: Integer): canStatus; </b>
2283 * \source_end
2284 *
2285 * Deallocates the object buffer with the specified index. The buffer
2286 * can not be referenced after this operation.
2287 *
2288 * \param[in] hnd An open handle to a CAN circuit.
2289 * \param[in] idx The object buffer to deallocate.
2290 *
2291 * \return \ref canOK (zero) if success
2292 * \return \ref canERR_xxx (negative) if failure
2293 *
2294 * \sa \ref page_user_guide_send_recv_obj_buf
2295 * \sa \ref canObjBufFreeAll(), \ref canObjBufAllocate(),
2296 */
2297canStatus CANLIBAPI canObjBufFree (const CanHandle hnd, int idx);
2298
2299// Writes CAN data to the object buffer with the specified index.
2300
2301/**
2302 * \ingroup ObjectBuffers
2303 *
2304 * \source_cs <b>static Canlib.canStatus canObjBufWrite(int handle, int idx, int id, byte[] msg, int dlc, int flags);</b>
2305 *
2306 * \source_delphi <b>function canObjBufWrite(handle: canHandle; idx, id: Integer; var msg; dlc, flags: cardinal): canStatus; </b>
2307 * \source_end
2308 *
2309 * Defines the contents of a specific object buffer.
2310 *
2311 * \param[in] hnd An open handle to a CAN circuit.
2312 * \param[in] idx The index of the object buffer whose contents is to be
2313 * defined.
2314 * \param[in] id The CAN identifier of the message.
2315 * \param[in] msg Points to the contents of the message.
2316 * \param[in] dlc The length of the message. Must be at least 0 and at most 8
2317 * bytes.
2318 * \param[in] flags Message flags; a combination of the \ref canMSG_xxx flags.
2319 *
2320 * \return \ref canOK (zero) if success
2321 * \return \ref canERR_xxx (negative) if failure
2322 *
2323 * \sa \ref page_user_guide_send_recv_obj_buf
2324 */
2325canStatus CANLIBAPI canObjBufWrite (const CanHandle hnd,
2326 int idx,
2327 int id,
2328 void* msg,
2329 unsigned int dlc,
2330 unsigned int flags);
2331
2332/**
2333 * \ingroup ObjectBuffers
2334 *
2335 * \source_cs <b>static Canlib.canStatus canObjBufSetFilter(int handle, int idx, int code, int mask);</b>
2336 *
2337 * \source_delphi <b>function canObjBufSetFilter(handle: canHandle; idx: Integer; code, mask: Cardinal): canStatus; </b>
2338 * \source_end
2339 *
2340 * Defines a message reception filter on the specified object buffer.
2341 * Messages not matching the filter are discarded.
2342 *
2343 * \note For an auto response buffer, set the code and mask that together define
2344 * the identifier(s) that trigger(s) the automatic response.
2345 *
2346 * \param[in] hnd An open handle to a CAN circuit.
2347 * \param[in] idx The index of the object buffer on which the filter is to be
2348 * set.
2349 * \param[in] code The acceptance code in the filter.
2350 * \param[in] mask The acceptance mask in the filter.
2351 *
2352 * \return \ref canOK (zero) if success
2353 * \return \ref canERR_xxx (negative) if failure
2354 *
2355 * \sa \ref page_user_guide_misc_code_and_mask,
2356 * \ref page_user_guide_send_recv_obj_buf
2357 */
2358canStatus CANLIBAPI canObjBufSetFilter (const CanHandle hnd,
2359 int idx,
2360 unsigned int code,
2361 unsigned int mask);
2362
2363/**
2364 * \ingroup ObjectBuffers
2365 *
2366 * \source_cs <b>static Canlib.canStatus canObjBufSetFlags(int handle, int idx, int flags);</b>
2367 *
2368 * \source_delphi <b>function canObjBufSetFlags(handle: canHandle; idx: Integer; flags: Cardinal): canStatus; </b>
2369 * \source_end
2370 *
2371 * Sets object buffer flags on a specified object buffer.
2372 *
2373 * \param[in] hnd An open handle to a CAN circuit.
2374 * \param[in] idx The buffer on which the flags are to be set.
2375 * \param[in] flags Specifies a combination of zero or more of the
2376 * \ref canOBJBUF_AUTO_RESPONSE_xxx flag values
2377 *
2378 * \return \ref canOK (zero) if success
2379 * \return \ref canERR_xxx (negative) if failure
2380 *
2381 * \sa \ref page_user_guide_send_recv_obj_buf
2382 */
2383canStatus CANLIBAPI canObjBufSetFlags (const CanHandle hnd,
2384 int idx,
2385 unsigned int flags);
2386
2387/**
2388 * \name canOBJBUF_AUTO_RESPONSE_xxx
2389 * \anchor canOBJBUF_AUTO_RESPONSE_xxx
2390 *
2391 * These defines are used in \ref canObjBufSetFlags().
2392 *
2393 * @{
2394 */
2395 /**
2396 * This define is used in \ref canObjBufSetFlags().
2397 *
2398 * For auto-response buffers only. When this flag is in effect, the buffer
2399 * will auto-respond to remote requests only. If this flag is not in effect,
2400 * the buffer will auto-respond to both remote requests and ordinary data
2401 * frames.
2402 *
2403 */
2404# define canOBJBUF_AUTO_RESPONSE_RTR_ONLY 0x01
2405 /** @} */
2406
2407/**
2408 * \ingroup ObjectBuffers
2409 *
2410 * \source_cs <b>static Canlib.canStatus canObjBufSetPeriod(int hnd, int idx, int period);</b>
2411 *
2412 * \source_delphi <b>function canObjBufSetPeriod(handle: canHandle; idx: Integer; period: Cardinal): canStatus; </b>
2413 * \source_end
2414 *
2415 * The \ref canObjBufSetPeriod function sets the transmission period for an auto
2416 * transmission object buffer.
2417 *
2418 * \param[in] hnd An open handle to a CAN channel.
2419 * \param[in] idx The index of a CAN object buffer.
2420 * \param[in] period The transmission interval, in microseconds.
2421 *
2422 * \return \ref canOK (zero) if success
2423 * \return \ref canERR_xxx (negative) if failure
2424 *
2425 * \sa \ref page_user_guide_send_recv_obj_buf
2426 */
2427canStatus CANLIBAPI canObjBufSetPeriod (const CanHandle hnd,
2428 int idx,
2429 unsigned int period);
2430
2431/**
2432 * \ingroup ObjectBuffers
2433 *
2434 * \source_cs <b>static Canlib.canStatus canObjBufSetMsgCount(int hnd, int idx, int count);</b>
2435 *
2436 * \source_delphi <b>function canObjBufSetMsgCount(handle: canHandle; idx: Integer; count: Cardinal): canStatus; </b>
2437 * \source_end
2438 *
2439 * The \ref canObjBufSetMsgCount function sets the message count for an auto
2440 * transmit object buffer.
2441 *
2442 * \param[in] hnd An open handle to a CAN channel.
2443 * \param[in] idx The index of a CAN object buffer.
2444 * \param[in] count The message count.
2445 *
2446 * \return \ref canOK (zero) if success
2447 * \return \ref canERR_xxx (negative) if failure
2448 *
2449 * \sa \ref page_user_guide_send_recv_obj_buf
2450 */
2451canStatus CANLIBAPI canObjBufSetMsgCount (const CanHandle hnd,
2452 int idx,
2453 unsigned int count);
2454
2455/**
2456 * \ingroup ObjectBuffers
2457 *
2458 * \source_cs <b>static Canlib.canStatus canObjBufEnable(int handle, int idx);</b>
2459 *
2460 * \source_delphi <b>function canObjBufEnable(handle: canHandle; idx: Integer): canStatus; </b>
2461 * \source_end
2462 *
2463 * Enables the object buffer with the specified index.
2464 *
2465 * \param[in] hnd An open handle to a CAN circuit.
2466 * \param[in] idx The index of the object buffer to enable.
2467 *
2468 * \return \ref canOK (zero) if success
2469 * \return \ref canERR_xxx (negative) if failure
2470 *
2471 * \sa \ref page_user_guide_send_recv_obj_buf
2472 * \sa \ref canObjBufDisable()
2473 */
2474canStatus CANLIBAPI canObjBufEnable (const CanHandle hnd, int idx);
2475
2476/**
2477 * \ingroup ObjectBuffers
2478 *
2479 * \source_cs <b>static Canlib.canStatus canObjBufDisable(int handle, int idx);</b>
2480 *
2481 * \source_delphi <b>function canObjBufDisable(handle: canHandle; idx: Integer): canStatus; </b>
2482 * \source_end
2483 *
2484 * Disables the object buffer with the specified index.
2485 *
2486 * \param[in] hnd An open handle to a CAN circuit.
2487 * \param[in] idx The index of the buffer.
2488 *
2489 * \return \ref canOK (zero) if success
2490 * \return \ref canERR_xxx (negative) if failure
2491 *
2492 * \sa \ref page_user_guide_send_recv_obj_buf
2493 * \sa \ref canObjBufEnable()
2494 */
2495canStatus CANLIBAPI canObjBufDisable (const CanHandle hnd, int idx);
2496
2497/**
2498 * \ingroup ObjectBuffers
2499 *
2500 * \source_cs <b>static Canlib.canStatus canObjBufSendBurst(int hnd, int idx, int burstlen);</b>
2501 *
2502 * \source_delphi <b>function canObjBufSendBurst(handle: canHandle; idx: Integer; burstLen: Cardinal): canStatus; </b>
2503 * \source_end
2504 *
2505 * The canObjBufSendBurst function sends a burst of CAN messages. You have to
2506 * set up an object buffer first with the message to send. The messages will be
2507 * sent as fast as possible from the hardware.
2508 *
2509 * This function is inteneded for certain diagnostic applications.
2510 *
2511 * \param[in] hnd An open handle to a CAN channel.
2512 * \param[in] idx The index of a CAN object buffer.
2513 * \param[in] burstlen The number of messages to send.
2514 *
2515 * \return \ref canOK (zero) if success
2516 * \return \ref canERR_xxx (negative) if failure
2517 *
2518 * \sa \ref page_user_guide_send_recv_obj_buf
2519 */
2520canStatus CANLIBAPI canObjBufSendBurst (const CanHandle hnd,
2521 int idx,
2522 unsigned int burstlen);
2523
2524#endif
2525
2526/**
2527 * \ingroup CAN
2528 *
2529 * \source_cs <b>static Canlib.canStatus canResetBus(int handle);</b>
2530 *
2531 * \source_delphi <b>function canResetBus(handle: canHandle): canStatus; </b>
2532 * \source_end
2533 *
2534 * This function tries to reset a CAN bus controller by taking the channel off
2535 * bus and then on bus again (if it was on bus before the call to \ref canResetBus().)
2536 *
2537 * This function will affect the hardware (and cause a real reset of the CAN
2538 * chip) only if \a hnd is the only handle open on the channel. If there
2539 * are other open handles, this operation will not affect the hardware.
2540 *
2541 * \param[in] hnd A handle to an open circuit.
2542 *
2543 * \return \ref canOK (zero) if success
2544 * \return \ref canERR_xxx (negative) if failure
2545 *
2546 * \sa \ref canBusOn(), \ref canBusOff()
2547 */
2548canStatus CANLIBAPI canResetBus (const CanHandle hnd);
2549
2550/**
2551 * \ingroup CAN
2552 *
2553 * \source_cs <b>static Canlib.canStatus canWriteWait(int handle, int id, byte[] msg, int dlc, int flag, long timeout);</b>
2554 *
2555 * \source_delphi <b>function canWriteWait(handle: canHandle; id: longint; var msg; dlc, flag, timeout : Cardinal): canStatus; </b>
2556 * \source_end
2557 *
2558 * This function sends a CAN message. It returns when the message is sent, or
2559 * the timeout expires.
2560 *
2561 * This is a convenience function that combines \ref canWrite() and \ref canWriteSync().
2562 *
2563 * If you are using the same channel via multiple handles, note that the
2564 * default behaviour is that the different handles will "hear" each other just as
2565 * if each handle referred to a channel of its own. If you open, say, channel 0
2566 * from thread A and thread B and then send a message from thread A, it will be
2567 * "received" by thread B.
2568 * This behaviour can be changed using \ref canIOCTL_SET_LOCAL_TXECHO.
2569 *
2570 * \param[in] hnd A handle to an open CAN circuit.
2571 * \param[in] id The identifier of the CAN message to send.
2572 * \param[in] msg A pointer to the message data, or \c NULL.
2573 * \param[in] dlc The length of the message. Can be at most 8.
2574 * \param[in] flag A combination of message flags, \ref canMSG_xxx.
2575 * Use this parameter to send extended (29-bit) frames
2576 * and/or remote frames. Use \ref canMSG_EXT and/or
2577 * \ref canMSG_RTR for this purpose.
2578 * \param[in] timeout The timeout, in milliseconds. 0xFFFFFFFF gives an
2579 * infinite timeout.
2580 *
2581 * \return \ref canOK (zero) if success
2582 * \return \ref canERR_xxx (negative) if failure
2583 */
2584canStatus CANLIBAPI canWriteWait (const CanHandle hnd,
2585 long id,
2586 void *msg,
2587 unsigned int dlc,
2588 unsigned int flag,
2589 unsigned long timeout);
2590
2591
2592#if defined(CANLIB_DECLARE_ALL)
2593
2594/**
2595 * \ingroup CAN
2596 *
2597 * \source_cs <b>static Canlib.canStatus canFlushReceiveQueue(int hnd);</b>
2598 *
2599 * \source_delphi <b>function canFlushReceiveQueue(handle: canHandle): canStatus; </b>
2600 * \source_end
2601 *
2602 * This function removes all received messages from the handle's receive queue.
2603 * Other handles open to the same channel are not affcted by this
2604 * operation. That is, only the messages belonging to the handle you are
2605 * passing to \ref canFlushReceiveQueue are discarded.
2606 *
2607 * \note This call has the same effect as calling \ref canIoCtl() with a function
2608 * code of \ref canIOCTL_FLUSH_RX_BUFFER.
2609 *
2610 * \param[in] hnd A handle to an open circuit.
2611 *
2612 * \return \ref canOK (zero) if success
2613 * \return \ref canERR_xxx (negative) if failure
2614 *
2615 * \sa \ref canFlushTransmitQueue()
2616 */
2617canStatus CANLIBAPI canFlushReceiveQueue (const CanHandle hnd);
2618
2619/**
2620 * \ingroup CAN
2621 *
2622 * \source_cs <b>static Canlib.canStatus canFlushTransmitQueue(int hnd);</b>
2623 *
2624 * \source_delphi <b>function canFlushTransmitQueue(handle: canHandle): canStatus; </b>
2625 * \source_end
2626 *
2627 * This function removes all messages pending transmission from the
2628 * transmit queue of the circuit.
2629 *
2630 * \note If there are other handles open to the same circuit, they are also
2631 * flushed.
2632 *
2633 * \note This call has the same effect as calling \ref canIoCtl() with a function
2634 * code of \ref canIOCTL_FLUSH_TX_BUFFER.
2635 *
2636 * \param[in] hnd A handle to an open circuit.
2637 *
2638 * \return \ref canOK (zero) if success
2639 * \return \ref canERR_xxx (negative) if failure
2640 *
2641 * \sa \ref canFlushReceiveQueue()
2642 */
2643canStatus CANLIBAPI canFlushTransmitQueue (const CanHandle hnd);
2644
2645
2646/** Contains status codes according to \ref canSTAT_xxx. */
2647typedef canStatus kvStatus;
2648
2649/**
2650 * \name kvCallback_t
2651 * \anchor kvCallback_t
2652 * \ref kvCallback_t is used by the function \ref kvSetNotifyCallback()
2653 *
2654 * The callback function is called with the following arguments:
2655 * \li hnd - the handle of the CAN channel where the event happened.
2656 * \li context - the context pointer you passed to \ref kvSetNotifyCallback().
2657 * \li notifyEvent - one of the \ref canNOTIFY_xxx notification codes.
2658 *
2659 * \note It is really the \ref canNOTIFY_xxx codes, and not the \ref
2660 * \ref canEVENT_xxx codes that the \ref canSetNotify() API is using.
2661 *
2662 * \param[in] hnd An open handle to a CAN channel.
2663 * \param[in] context Arbitrary user-defined context data which
2664 * is passed to the callback function.
2665 * \param[in] notifyEvent One or more of the \ref canEVENT_xxx flags.
2666 *
2667 */
2668typedef void (CANLIBAPI *kvCallback_t) (CanHandle hnd, void* context, unsigned int notifyEvent);
2669
2670/**
2671 * \ingroup General
2672 *
2673 * \source_cs <b>static Canlib.canStatus kvSetNotifyCallback(int hnd, Canlib.kvCallbackDelegate callback, IntPtr context, uint notifyFlags);</b>
2674 *
2675 * \source_delphi <b>function kvSetNotifyCallback(handle: canHandle; callback: kvCallback_t; context: Pointer; notifyFlags: Cardinal): canStatus; </b>
2676 * \source_end
2677 *
2678 * The \ref kvSetNotifyCallback() function registers a callback function which is
2679 * called when certain events occur.
2680 *
2681 * You can register at most one callback function per handle at any time.
2682 *
2683 * To remove the callback, call \ref kvSetNotifyCallback() with a \c NULL pointer in
2684 * the callback argument.
2685 *
2686 * \note The callback function is called in the context of a high-priority
2687 * thread created by CANLIB. You should take precaution not to do any time
2688 * consuming tasks in the callback. You must also arrange the synchronization
2689 * between the callback and your other threads yourself.
2690 *
2691 * \param[in] hnd An open handle to a CAN channel.
2692 * \param[in] callback A pointer to a callback function of type
2693 * \ref kvCallback_t
2694 * \param[in] context A pointer to arbitrary user-defined context data which
2695 * is passed to the callback function.
2696 * \param[in] notifyFlags One or more of the \ref canNOTIFY_xxx flags.
2697 *
2698 * \return \ref canOK (zero) if success
2699 * \return \ref canERR_xxx (negative) if failure
2700 *
2701 * \sa \ref canSetNotify()
2702 */
2703kvStatus CANLIBAPI kvSetNotifyCallback (const CanHandle hnd,
2704 kvCallback_t callback,
2705 void* context,
2706 unsigned int notifyFlags);
2707
2708/** @} */
2709#endif
2710
2711#ifdef __cplusplus
2712}
2713#endif
2714
2715
2716#endif
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