RTEMS 6.1-rc5
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if_tsec_pub.h
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1
9#ifndef IF_TSEC_PUBLIC_INTERFACE_H
10#define IF_TSEC_PUBLIC_INTERFACE_H
11
12/*
13 * Authorship
14 * ----------
15 * This software ('mvme3100' RTEMS BSP) was created by
16 *
17 * Till Straumann <strauman@slac.stanford.edu>, 2005-2007,
18 * Stanford Linear Accelerator Center, Stanford University.
19 *
20 * Acknowledgement of sponsorship
21 * ------------------------------
22 * The 'mvme3100' BSP was produced by
23 * the Stanford Linear Accelerator Center, Stanford University,
24 * under Contract DE-AC03-76SFO0515 with the Department of Energy.
25 *
26 * Government disclaimer of liability
27 * ----------------------------------
28 * Neither the United States nor the United States Department of Energy,
29 * nor any of their employees, makes any warranty, express or implied, or
30 * assumes any legal liability or responsibility for the accuracy,
31 * completeness, or usefulness of any data, apparatus, product, or process
32 * disclosed, or represents that its use would not infringe privately owned
33 * rights.
34 *
35 * Stanford disclaimer of liability
36 * --------------------------------
37 * Stanford University makes no representations or warranties, express or
38 * implied, nor assumes any liability for the use of this software.
39 *
40 * Stanford disclaimer of copyright
41 * --------------------------------
42 * Stanford University, owner of the copyright, hereby disclaims its
43 * copyright and all other rights in this software. Hence, anyone may
44 * freely use it for any purpose without restriction.
45 *
46 * Maintenance of notices
47 * ----------------------
48 * In the interest of clarity regarding the origin and status of this
49 * SLAC software, this and all the preceding Stanford University notices
50 * are to remain affixed to any copy or derivative of this software made
51 * or distributed by the recipient and are to be affixed to any copy of
52 * software made or distributed by the recipient that contains a copy or
53 * derivative of this software.
54 *
55 * ------------------ SLAC Software Notices, Set 4 OTT.002a, 2004 FEB 03
56 */
57
58#include <rtems.h>
59#include <stdio.h>
60#include <stdint.h>
61
62#ifdef __cplusplus
63extern "C" {
64#endif
65
66/* Opaque driver handle */
67struct tsec_private;
68
69/********** Low-level Driver API ****************/
70
82#define TSEC_TXIRQ ( (1<<(31-9)) | (1<<(31-11)) )
83#define TSEC_RXIRQ ( (1<<(31-0)) | (1<<(31- 3)) | (1<<(31-24)) )
84#define TSEC_LKIRQ ( 1<<(31- 4) )
85/*
86 * Setup an interface.
87 * Allocates resources for descriptor rings and sets up the driver software structure.
88 *
89 * Arguments:
90 * unit:
91 * interface # (1..2). The interface must not be attached to BSD already.
92 *
93 * driver_tid:
94 * ISR posts RTEMS event # ('unit' - 1) to task with ID 'driver_tid' and disables interrupts
95 * from this interface.
96 *
97 * void (*cleanup_txbuf)(void *user_buf, void *cleanup_txbuf_arg, int error_on_tx_occurred):
98 * Pointer to user-supplied callback to release a buffer that had been sent
99 * by BSP_tsec_send_buf() earlier. The callback is passed 'cleanup_txbuf_arg'
100 * and a flag indicating whether the send had been successful.
101 * The driver no longer accesses 'user_buf' after invoking this callback.
102 * CONTEXT: This callback is executed either by BSP_tsec_swipe_tx() or
103 * BSP_tsec_send_buf(), BSP_tsec_init_hw(), BSP_tsec_stop_hw() (the latter
104 * ones calling BSP_tsec_swipe_tx()).
105 * void *cleanup_txbuf_arg:
106 * Closure argument that is passed on to 'cleanup_txbuf()' callback;
107 *
108 * void *(*alloc_rxbuf)(int *p_size, uintptr_t *p_data_addr),
109 * Pointer to user-supplied callback to allocate a buffer for subsequent
110 * insertion into the RX ring by the driver.
111 * RETURNS: opaque handle to the buffer (which may be a more complex object
112 * such as an 'mbuf'). The handle is not used by the driver directly
113 * but passed back to the 'consume_rxbuf()' callback.
114 * Size of the available data area and pointer to buffer's data area
115 * in '*psize' and '*p_data_area', respectively.
116 * If no buffer is available, this routine should return NULL in which
117 * case the driver drops the last packet and re-uses the last buffer
118 * instead of handing it out to 'consume_rxbuf()'.
119 * CONTEXT: Called when initializing the RX ring (BSP_tsec_init_hw()) or when
120 * swiping it (BSP_tsec_swipe_rx()).
121 *
122 *
123 * void (*consume_rxbuf)(void *user_buf, void *consume_rxbuf_arg, int len);
124 * Pointer to user-supplied callback to pass a received buffer back to
125 * the user. The driver no longer accesses the buffer after invoking this
126 * callback (with 'len'>0, see below). 'user_buf' is the buffer handle
127 * previously generated by 'alloc_rxbuf()'.
128 * The callback is passed 'cleanup_rxbuf_arg' and a 'len'
129 * argument giving the number of bytes that were received.
130 * 'len' may be <=0 in which case the 'user_buf' argument is NULL.
131 * 'len' == 0 means that the last 'alloc_rxbuf()' had failed,
132 * 'len' < 0 indicates a receiver error. In both cases, the last packet
133 * was dropped/missed and the last buffer will be re-used by the driver.
134 * NOTE: the data are 'prefixed' with two bytes, i.e., the ethernet packet header
135 * is stored at offset 2 in the buffer's data area. Also, the FCS (4 bytes)
136 * is appended. 'len' accounts for both.
137 * CONTEXT: Called from BSP_tsec_swipe_rx().
138 * void *cleanup_rxbuf_arg:
139 * Closure argument that is passed on to 'consume_rxbuf()' callback;
140 *
141 * rx_ring_size, tx_ring_size:
142 * How many big to make the RX and TX descriptor rings. Note that the sizes
143 * may be 0 in which case a reasonable default will be used.
144 * If either ring size is < 0 then the RX or TX will be disabled.
145 * Note that it is illegal in this case to use BSP_tsec_swipe_rx() or
146 * BSP_tsec_swipe_tx(), respectively.
147 *
148 * irq_mask:
149 * Interrupts to enable. OR of flags from above.
150 *
151 */
152struct tsec_private *
153BSP_tsec_setup(
154 int unit,
155 rtems_id driver_tid,
156 void (*cleanup_txbuf)(void *user_buf, void *cleanup_txbuf_arg, int error_on_tx_occurred),
157 void * cleanup_txbuf_arg,
158 void * (*alloc_rxbuf)(int *p_size, uintptr_t *p_data_addr),
159 void (*consume_rxbuf)(void *user_buf, void *consume_rxbuf_arg, int len),
160 void * consume_rxbuf_arg,
161 int rx_ring_size,
162 int tx_ring_size,
163 int irq_mask
164);
165
166/*
167 * Alternate 'setup' routine allowing the user to install an ISR rather
168 * than a task ID.
169 * All parameters (other than 'isr' / 'isr_arg') and the return value
170 * are identical to the BSP_tsec_setup() entry point.
171 */
172struct tsec_private *
173BSP_tsec_setup_1(
174 int unit,
175 void (*isr)(void *isr_arg),
176 void * isr_arg,
177 void (*cleanup_txbuf)(void *user_buf, void *cleanup_txbuf_arg, int error_on_tx_occurred),
178 void * cleanup_txbuf_arg,
179 void * (*alloc_rxbuf)(int *p_size, uintptr_t *p_data_addr),
180 void (*consume_rxbuf)(void *user_buf, void *consume_rxbuf_arg, int len),
181 void * consume_rxbuf_arg,
182 int rx_ring_size,
183 int tx_ring_size,
184 int irq_mask
185);
186
187
188/*
189 * Descriptor scavenger; cleanup the TX ring, passing all buffers
190 * that have been sent to the cleanup_tx() callback.
191 * This routine is called from BSP_tsec_send_buf(), BSP_tsec_init_hw(),
192 * BSP_tsec_stop_hw().
193 *
194 * RETURNS: number of buffers processed.
195 */
196
197int
198BSP_tsec_swipe_tx(struct tsec_private *mp);
199
200
201/*
202 * Reset statistics counters.
203 */
204void
205BSP_tsec_reset_stats(struct tsec_private *mp);
206
207/*
208 * Initialize interface hardware
209 *
210 * 'mp' handle obtained by from BSP_tsec_setup().
211 * 'promisc' whether to set promiscuous flag.
212 * 'enaddr' pointer to six bytes with MAC address. Read
213 * from the device if NULL.
214 * NOTE: multicast filter is cleared by this routine.
215 */
216void
217BSP_tsec_init_hw(struct tsec_private *mp, int promisc, unsigned char *enaddr);
218
219/*
220 * Clear multicast hash filter. No multicast frames are accepted
221 * after executing this routine (unless the hardware was initialized
222 * in 'promiscuous' mode).
223 *
224 * Reset reference count for all hash-table entries
225 * to zero (see BSP_tsec_mcast_filter_accept_del()).
226 */
227void
228BSP_tsec_mcast_filter_clear(struct tsec_private *mp);
229
230/*
231 * Program multicast filter to accept all multicast frames.
232 *
233 * Increment reference count for all hash-table entries
234 * by one (see BSP_tsec_mcast_filter_accept_del()).
235 */
236void
237BSP_tsec_mcast_filter_accept_all(struct tsec_private *mp);
238
239/*
240 * Add a MAC address to the multicast filter and increment
241 * the reference count for the matching hash-table entry
242 * (see BSP_tsec_mcast_filter_accept_del()).
243 *
244 * Existing entries are not changed but note that
245 * the filter is imperfect, i.e., multiple MAC addresses
246 * may alias to a single filter entry. Hence software
247 * filtering must still be performed.
248 *
249 */
250void
251BSP_tsec_mcast_filter_accept_add(struct tsec_private *mp, unsigned char *enaddr);
252
253/*
254 * Remove a MAC address from the (imperfec) multicast
255 * filter.
256 * Note that the driver maintains an internal reference
257 * counter for each multicast hash. The hash-table
258 * entry is only cleared when the reference count
259 * reaches zero ('del' has been called the same
260 * amount of times as 'add' for an address (or
261 * any alias) that matches a given table entry.
262 * BSP_tsec_mcast_filter_clear() resets all reference
263 * counters to zero.
264 */
265void
266BSP_tsec_mcast_filter_accept_del(struct tsec_private *mp, unsigned char *enaddr);
267
268/*
269 * Dump statistics to FILE 'f'. If NULL, stdout is used.
270 */
271void
272BSP_tsec_dump_stats(struct tsec_private *mp, FILE *f);
273
274/*
275 * Shutdown hardware and clean out the rings
276 */
277void
278BSP_tsec_stop_hw(struct tsec_private *mp);
279
280/*
281 * calls BSP_tsec_stop_hw(), releases all resources and marks the interface
282 * as unused.
283 * RETURNS 0 on success, nonzero on failure.
284 * NOTE: the handle MUST NOT be used after successful execution of this
285 * routine.
286 */
287int
288BSP_tsec_detach(struct tsec_private *mp);
289
290/*
291 * Enqueue a mbuf chain or a raw data buffer for transmission;
292 * RETURN: #bytes sent or -1 if there are not enough free descriptors
293 *
294 * If 'len' is <=0 then 'm_head' is assumed to point to a mbuf chain.
295 * OTOH, a raw data packet (or a different type of buffer)
296 * may be sent (non-BSD driver) by pointing data_p to the start of
297 * the data and passing 'len' > 0.
298 * 'm_head' is passed back to the 'cleanup_txbuf()' callback.
299 *
300 * Comments: software cache-flushing incurs a penalty if the
301 * packet cannot be queued since it is flushed anyways.
302 * The algorithm is slightly more efficient in the normal
303 * case, though.
304 *
305 * RETURNS: # bytes enqueued to device for transmission or -1 if no
306 * space in the TX ring was available.
307 */
308
309int
310BSP_tsec_send_buf(struct tsec_private *mp, void *m_head, void *data_p, int len);
311
312/*
313 * Retrieve all received buffers from the RX ring, replacing them
314 * by fresh ones (obtained from the alloc_rxbuf() callback). The
315 * received buffers are passed to consume_rxbuf().
316 *
317 * RETURNS: number of buffers processed.
318 */
319int
320BSP_tsec_swipe_rx(struct tsec_private *mp);
321
322/* read ethernet address from hw to buffer */
323void
324BSP_tsec_read_eaddr(struct tsec_private *mp, unsigned char *eaddr);
325
326/* Read MII register */
327uint32_t
328BSP_tsec_mdio_rd(struct tsec_private *mp, unsigned reg);
329
330/* Write MII register */
331int
332BSP_tsec_mdio_wr(struct tsec_private *mp, unsigned reg, uint32_t val);
333
334/*
335 * read/write media word.
336 * 'cmd': can be SIOCGIFMEDIA, SIOCSIFMEDIA, 0 or 1. The latter
337 * are aliased to the former for convenience.
338 * 'parg': pointer to media word.
339 *
340 * RETURNS: 0 on success, nonzero on error
341 */
342int
343BSP_tsec_media_ioctl(struct tsec_private *mp, int cmd, int *parg);
344
345/* Interrupt related routines */
346
347/*
348 * When it comes to interrupts the chip has two rather
349 * annoying features:
350 * 1 once an IRQ is pending, clearing the IMASK does not
351 * de-assert the interrupt line.
352 * 2 the chip has three physical interrupt lines even though
353 * all events are reported in a single register. Rather
354 * useless; we must hook 3 ISRs w/o any real benefit.
355 * In fact, it makes our life a bit more difficult:
356 *
357 * Hence, for (1) we would have to mask interrupts at the PIC
358 * but to re-enable them we would have to do that three times
359 * because of (2).
360 *
361 * Therefore, we take the following approach:
362 *
363 * ISR masks all interrupts on the TSEC, acks/clears them
364 * and stores the acked irqs in the device struct where
365 * it is picked up by BSP_tsec_ack_irqs().
366 * Since all interrupts are disabled until the daemon
367 * re-enables them after calling BSP_tsec_ack_irqs()
368 * no interrupts are lost.
369 *
370 * BUT: NO isr (including PHY isrs) MUST INTERRUPT ANY
371 * OTHER ONE, i.e., they all must have the same
372 * priority. Otherwise, integrity of the cached
373 * irq_pending variable may be compromised.
374 */
375
376/* Note: the BSP_tsec_enable/disable/ack_irqs() entry points
377 * are deprecated.
378 * The newer API where the user passes a mask allows
379 * for more selective control.
380 */
381
382/* Enable interrupts at device */
383void
384BSP_tsec_enable_irqs(struct tsec_private *mp);
385
386/* Disable interrupts at device */
387void
388BSP_tsec_disable_irqs(struct tsec_private *mp);
389
390/*
391 * Acknowledge (and clear) interrupts.
392 * RETURNS: interrupts that were raised.
393 */
394uint32_t
395BSP_tsec_ack_irqs(struct tsec_private *mp);
396
397/* Enable interrupts included in 'mask' (leaving
398 * already enabled interrupts on). If the mask includes
399 * bits that were not passed to the 'setup' routine then
400 * the behavior is undefined.
401 */
402void
403BSP_tsec_enable_irq_mask(struct tsec_private *mp, uint32_t irq_mask);
404
405/* Disable interrupts included in 'mask' (leaving
406 * other ones that are currently enabled on). If the mask
407 * includes bits that were not passed to the 'setup' routine
408 * then the behavior is undefined.
409
410 * RETURNS: Bitmask of interrupts that were enabled upon entry
411 * into this routine. This can be used to restore the previous
412 * state.
413 */
414uint32_t
415BSP_tsec_disable_irq_mask(struct tsec_private *mp, uint32_t irq_mask);
416
417/* Acknowledge and clear selected interrupts.
418 *
419 * RETURNS: All pending interrupts.
420 *
421 * NOTE: Only pending interrupts contained in 'mask'
422 * are cleared. Others are left pending.
423 *
424 * This routine can be used to check for pending
425 * interrupts (pass mask == 0) or to clear all
426 * interrupts (pass mask == -1).
427 */
428uint32_t
429BSP_tsec_ack_irq_mask(struct tsec_private *mp, uint32_t mask);
430
431
432/* Retrieve the driver daemon TID that was passed to
433 * BSP_tsec_setup().
434 */
435
437BSP_tsec_get_tid(struct tsec_private *mp);
438
439struct tsec_private *
440BSP_tsec_getp(unsigned index);
441
442/*
443 *
444 * Example driver task loop (note: no synchronization of
445 * buffer access shown!).
446 * RTEMS_EVENTx = 0,1 or 2 depending on IF unit.
447 *
448 * / * setup (obtain handle) and initialize hw here * /
449 *
450 * do {
451 * / * ISR disables IRQs and posts event * /
452 * rtems_event_receive( RTEMS_EVENTx, RTEMS_WAIT | RTEMS_EVENT_ANY, RTEMS_NO_TIMEOUT, &evs );
453 * irqs = BSP_tsec_ack_irqs(handle);
454 * if ( irqs & BSP_TSEC_IRQ_TX ) {
455 * BSP_tsec_swipe_tx(handle); / * cleanup_txbuf() callback executed * /
456 * }
457 * if ( irqs & BSP_TSEC_IRQ_RX ) {
458 * BSP_tsec_swipe_rx(handle); / * alloc_rxbuf() and consume_rxbuf() executed * /
459 * }
460 * BSP_tsec_enable_irqs(handle);
461 * } while (1);
462 *
463 */
464
465/* PUBLIC RTEMS BSDNET ATTACH FUNCTION */
466struct rtems_bsdnet_ifconfig;
467
468int
469rtems_tsec_attach(struct rtems_bsdnet_ifconfig *ifcfg, int attaching);
470
471#ifdef __cplusplus
472}
473#endif
474
475#endif
Objects_Id rtems_id
This type represents RTEMS object identifiers.
Definition: types.h:94
This header file defines the RTEMS Classic API.