[TG3]: Set minimal hw interrupt mitigation.
[linux-2.6/verdex.git] / net / irda / wrapper.c
blob87130c1c8693a91e678e418817b6f4bd09c10287
1 /*********************************************************************
3 * Filename: wrapper.c
4 * Version: 1.2
5 * Description: IrDA SIR async wrapper layer
6 * Status: Stable
7 * Author: Dag Brattli <dagb@cs.uit.no>
8 * Created at: Mon Aug 4 20:40:53 1997
9 * Modified at: Fri Jan 28 13:21:09 2000
10 * Modified by: Dag Brattli <dagb@cs.uit.no>
11 * Modified at: Fri May 28 3:11 CST 1999
12 * Modified by: Horst von Brand <vonbrand@sleipnir.valparaiso.cl>
14 * Copyright (c) 1998-2000 Dag Brattli <dagb@cs.uit.no>,
15 * All Rights Reserved.
16 * Copyright (c) 2000-2002 Jean Tourrilhes <jt@hpl.hp.com>
18 * This program is free software; you can redistribute it and/or
19 * modify it under the terms of the GNU General Public License as
20 * published by the Free Software Foundation; either version 2 of
21 * the License, or (at your option) any later version.
23 * Neither Dag Brattli nor University of Tromsø admit liability nor
24 * provide warranty for any of this software. This material is
25 * provided "AS-IS" and at no charge.
27 ********************************************************************/
29 #include <linux/skbuff.h>
30 #include <linux/string.h>
31 #include <linux/module.h>
32 #include <asm/byteorder.h>
34 #include <net/irda/irda.h>
35 #include <net/irda/wrapper.h>
36 #include <net/irda/crc.h>
37 #include <net/irda/irlap.h>
38 #include <net/irda/irlap_frame.h>
39 #include <net/irda/irda_device.h>
41 /************************** FRAME WRAPPING **************************/
43 * Unwrap and unstuff SIR frames
45 * Note : at FIR and MIR, HDLC framing is used and usually handled
46 * by the controller, so we come here only for SIR... Jean II
50 * Function stuff_byte (byte, buf)
52 * Byte stuff one single byte and put the result in buffer pointed to by
53 * buf. The buffer must at all times be able to have two bytes inserted.
55 * This is in a tight loop, better inline it, so need to be prior to callers.
56 * (2000 bytes on P6 200MHz, non-inlined ~370us, inline ~170us) - Jean II
58 static inline int stuff_byte(__u8 byte, __u8 *buf)
60 switch (byte) {
61 case BOF: /* FALLTHROUGH */
62 case EOF: /* FALLTHROUGH */
63 case CE:
64 /* Insert transparently coded */
65 buf[0] = CE; /* Send link escape */
66 buf[1] = byte^IRDA_TRANS; /* Complement bit 5 */
67 return 2;
68 /* break; */
69 default:
70 /* Non-special value, no transparency required */
71 buf[0] = byte;
72 return 1;
73 /* break; */
78 * Function async_wrap (skb, *tx_buff, buffsize)
80 * Makes a new buffer with wrapping and stuffing, should check that
81 * we don't get tx buffer overflow.
83 int async_wrap_skb(struct sk_buff *skb, __u8 *tx_buff, int buffsize)
85 struct irda_skb_cb *cb = (struct irda_skb_cb *) skb->cb;
86 int xbofs;
87 int i;
88 int n;
89 union {
90 __u16 value;
91 __u8 bytes[2];
92 } fcs;
94 /* Initialize variables */
95 fcs.value = INIT_FCS;
96 n = 0;
99 * Send XBOF's for required min. turn time and for the negotiated
100 * additional XBOFS
103 if (cb->magic != LAP_MAGIC) {
105 * This will happen for all frames sent from user-space.
106 * Nothing to worry about, but we set the default number of
107 * BOF's
109 IRDA_DEBUG(1, "%s(), wrong magic in skb!\n", __FUNCTION__);
110 xbofs = 10;
111 } else
112 xbofs = cb->xbofs + cb->xbofs_delay;
114 IRDA_DEBUG(4, "%s(), xbofs=%d\n", __FUNCTION__, xbofs);
116 /* Check that we never use more than 115 + 48 xbofs */
117 if (xbofs > 163) {
118 IRDA_DEBUG(0, "%s(), too many xbofs (%d)\n", __FUNCTION__,
119 xbofs);
120 xbofs = 163;
123 memset(tx_buff + n, XBOF, xbofs);
124 n += xbofs;
126 /* Start of packet character BOF */
127 tx_buff[n++] = BOF;
129 /* Insert frame and calc CRC */
130 for (i=0; i < skb->len; i++) {
132 * Check for the possibility of tx buffer overflow. We use
133 * bufsize-5 since the maximum number of bytes that can be
134 * transmitted after this point is 5.
136 if(n >= (buffsize-5)) {
137 IRDA_ERROR("%s(), tx buffer overflow (n=%d)\n",
138 __FUNCTION__, n);
139 return n;
142 n += stuff_byte(skb->data[i], tx_buff+n);
143 fcs.value = irda_fcs(fcs.value, skb->data[i]);
146 /* Insert CRC in little endian format (LSB first) */
147 fcs.value = ~fcs.value;
148 #ifdef __LITTLE_ENDIAN
149 n += stuff_byte(fcs.bytes[0], tx_buff+n);
150 n += stuff_byte(fcs.bytes[1], tx_buff+n);
151 #else /* ifdef __BIG_ENDIAN */
152 n += stuff_byte(fcs.bytes[1], tx_buff+n);
153 n += stuff_byte(fcs.bytes[0], tx_buff+n);
154 #endif
155 tx_buff[n++] = EOF;
157 return n;
159 EXPORT_SYMBOL(async_wrap_skb);
161 /************************* FRAME UNWRAPPING *************************/
163 * Unwrap and unstuff SIR frames
165 * Complete rewrite by Jean II :
166 * More inline, faster, more compact, more logical. Jean II
167 * (16 bytes on P6 200MHz, old 5 to 7 us, new 4 to 6 us)
168 * (24 bytes on P6 200MHz, old 9 to 10 us, new 7 to 8 us)
169 * (for reference, 115200 b/s is 1 byte every 69 us)
170 * And reduce wrapper.o by ~900B in the process ;-)
172 * Then, we have the addition of ZeroCopy, which is optional
173 * (i.e. the driver must initiate it) and improve final processing.
174 * (2005 B frame + EOF on P6 200MHz, without 30 to 50 us, with 10 to 25 us)
176 * Note : at FIR and MIR, HDLC framing is used and usually handled
177 * by the controller, so we come here only for SIR... Jean II
181 * We can also choose where we want to do the CRC calculation. We can
182 * do it "inline", as we receive the bytes, or "postponed", when
183 * receiving the End-Of-Frame.
184 * (16 bytes on P6 200MHz, inlined 4 to 6 us, postponed 4 to 5 us)
185 * (24 bytes on P6 200MHz, inlined 7 to 8 us, postponed 5 to 7 us)
186 * With ZeroCopy :
187 * (2005 B frame on P6 200MHz, inlined 10 to 25 us, postponed 140 to 180 us)
188 * Without ZeroCopy :
189 * (2005 B frame on P6 200MHz, inlined 30 to 50 us, postponed 150 to 180 us)
190 * (Note : numbers taken with irq disabled)
192 * From those numbers, it's not clear which is the best strategy, because
193 * we end up running through a lot of data one way or another (i.e. cache
194 * misses). I personally prefer to avoid the huge latency spike of the
195 * "postponed" solution, because it come just at the time when we have
196 * lot's of protocol processing to do and it will hurt our ability to
197 * reach low link turnaround times... Jean II
199 //#define POSTPONE_RX_CRC
202 * Function async_bump (buf, len, stats)
204 * Got a frame, make a copy of it, and pass it up the stack! We can try
205 * to inline it since it's only called from state_inside_frame
207 static inline void
208 async_bump(struct net_device *dev,
209 struct net_device_stats *stats,
210 iobuff_t *rx_buff)
212 struct sk_buff *newskb;
213 struct sk_buff *dataskb;
214 int docopy;
216 /* Check if we need to copy the data to a new skb or not.
217 * If the driver doesn't use ZeroCopy Rx, we have to do it.
218 * With ZeroCopy Rx, the rx_buff already point to a valid
219 * skb. But, if the frame is small, it is more efficient to
220 * copy it to save memory (copy will be fast anyway - that's
221 * called Rx-copy-break). Jean II */
222 docopy = ((rx_buff->skb == NULL) ||
223 (rx_buff->len < IRDA_RX_COPY_THRESHOLD));
225 /* Allocate a new skb */
226 newskb = dev_alloc_skb(docopy ? rx_buff->len + 1 : rx_buff->truesize);
227 if (!newskb) {
228 stats->rx_dropped++;
229 /* We could deliver the current skb if doing ZeroCopy Rx,
230 * but this would stall the Rx path. Better drop the
231 * packet... Jean II */
232 return;
235 /* Align IP header to 20 bytes (i.e. increase skb->data)
236 * Note this is only useful with IrLAN, as PPP has a variable
237 * header size (2 or 1 bytes) - Jean II */
238 skb_reserve(newskb, 1);
240 if(docopy) {
241 /* Copy data without CRC (lenght already checked) */
242 memcpy(newskb->data, rx_buff->data, rx_buff->len - 2);
243 /* Deliver this skb */
244 dataskb = newskb;
245 } else {
246 /* We are using ZeroCopy. Deliver old skb */
247 dataskb = rx_buff->skb;
248 /* And hook the new skb to the rx_buff */
249 rx_buff->skb = newskb;
250 rx_buff->head = newskb->data; /* NOT newskb->head */
251 //printk(KERN_DEBUG "ZeroCopy : len = %d, dataskb = %p, newskb = %p\n", rx_buff->len, dataskb, newskb);
254 /* Set proper length on skb (without CRC) */
255 skb_put(dataskb, rx_buff->len - 2);
257 /* Feed it to IrLAP layer */
258 dataskb->dev = dev;
259 dataskb->mac.raw = dataskb->data;
260 dataskb->protocol = htons(ETH_P_IRDA);
262 netif_rx(dataskb);
264 stats->rx_packets++;
265 stats->rx_bytes += rx_buff->len;
267 /* Clean up rx_buff (redundant with async_unwrap_bof() ???) */
268 rx_buff->data = rx_buff->head;
269 rx_buff->len = 0;
273 * Function async_unwrap_bof(dev, byte)
275 * Handle Beginning Of Frame character received within a frame
278 static inline void
279 async_unwrap_bof(struct net_device *dev,
280 struct net_device_stats *stats,
281 iobuff_t *rx_buff, __u8 byte)
283 switch(rx_buff->state) {
284 case LINK_ESCAPE:
285 case INSIDE_FRAME:
286 /* Not supposed to happen, the previous frame is not
287 * finished - Jean II */
288 IRDA_DEBUG(1, "%s(), Discarding incomplete frame\n",
289 __FUNCTION__);
290 stats->rx_errors++;
291 stats->rx_missed_errors++;
292 irda_device_set_media_busy(dev, TRUE);
293 break;
295 case OUTSIDE_FRAME:
296 case BEGIN_FRAME:
297 default:
298 /* We may receive multiple BOF at the start of frame */
299 break;
302 /* Now receiving frame */
303 rx_buff->state = BEGIN_FRAME;
304 rx_buff->in_frame = TRUE;
306 /* Time to initialize receive buffer */
307 rx_buff->data = rx_buff->head;
308 rx_buff->len = 0;
309 rx_buff->fcs = INIT_FCS;
313 * Function async_unwrap_eof(dev, byte)
315 * Handle End Of Frame character received within a frame
318 static inline void
319 async_unwrap_eof(struct net_device *dev,
320 struct net_device_stats *stats,
321 iobuff_t *rx_buff, __u8 byte)
323 #ifdef POSTPONE_RX_CRC
324 int i;
325 #endif
327 switch(rx_buff->state) {
328 case OUTSIDE_FRAME:
329 /* Probably missed the BOF */
330 stats->rx_errors++;
331 stats->rx_missed_errors++;
332 irda_device_set_media_busy(dev, TRUE);
333 break;
335 case BEGIN_FRAME:
336 case LINK_ESCAPE:
337 case INSIDE_FRAME:
338 default:
339 /* Note : in the case of BEGIN_FRAME and LINK_ESCAPE,
340 * the fcs will most likely not match and generate an
341 * error, as expected - Jean II */
342 rx_buff->state = OUTSIDE_FRAME;
343 rx_buff->in_frame = FALSE;
345 #ifdef POSTPONE_RX_CRC
346 /* If we haven't done the CRC as we receive bytes, we
347 * must do it now... Jean II */
348 for(i = 0; i < rx_buff->len; i++)
349 rx_buff->fcs = irda_fcs(rx_buff->fcs,
350 rx_buff->data[i]);
351 #endif
353 /* Test FCS and signal success if the frame is good */
354 if (rx_buff->fcs == GOOD_FCS) {
355 /* Deliver frame */
356 async_bump(dev, stats, rx_buff);
357 break;
358 } else {
359 /* Wrong CRC, discard frame! */
360 irda_device_set_media_busy(dev, TRUE);
362 IRDA_DEBUG(1, "%s(), crc error\n", __FUNCTION__);
363 stats->rx_errors++;
364 stats->rx_crc_errors++;
366 break;
371 * Function async_unwrap_ce(dev, byte)
373 * Handle Character Escape character received within a frame
376 static inline void
377 async_unwrap_ce(struct net_device *dev,
378 struct net_device_stats *stats,
379 iobuff_t *rx_buff, __u8 byte)
381 switch(rx_buff->state) {
382 case OUTSIDE_FRAME:
383 /* Activate carrier sense */
384 irda_device_set_media_busy(dev, TRUE);
385 break;
387 case LINK_ESCAPE:
388 IRDA_WARNING("%s: state not defined\n", __FUNCTION__);
389 break;
391 case BEGIN_FRAME:
392 case INSIDE_FRAME:
393 default:
394 /* Stuffed byte coming */
395 rx_buff->state = LINK_ESCAPE;
396 break;
401 * Function async_unwrap_other(dev, byte)
403 * Handle other characters received within a frame
406 static inline void
407 async_unwrap_other(struct net_device *dev,
408 struct net_device_stats *stats,
409 iobuff_t *rx_buff, __u8 byte)
411 switch(rx_buff->state) {
412 /* This is on the critical path, case are ordered by
413 * probability (most frequent first) - Jean II */
414 case INSIDE_FRAME:
415 /* Must be the next byte of the frame */
416 if (rx_buff->len < rx_buff->truesize) {
417 rx_buff->data[rx_buff->len++] = byte;
418 #ifndef POSTPONE_RX_CRC
419 rx_buff->fcs = irda_fcs(rx_buff->fcs, byte);
420 #endif
421 } else {
422 IRDA_DEBUG(1, "%s(), Rx buffer overflow, aborting\n",
423 __FUNCTION__);
424 rx_buff->state = OUTSIDE_FRAME;
426 break;
428 case LINK_ESCAPE:
430 * Stuffed char, complement bit 5 of byte
431 * following CE, IrLAP p.114
433 byte ^= IRDA_TRANS;
434 if (rx_buff->len < rx_buff->truesize) {
435 rx_buff->data[rx_buff->len++] = byte;
436 #ifndef POSTPONE_RX_CRC
437 rx_buff->fcs = irda_fcs(rx_buff->fcs, byte);
438 #endif
439 rx_buff->state = INSIDE_FRAME;
440 } else {
441 IRDA_DEBUG(1, "%s(), Rx buffer overflow, aborting\n",
442 __FUNCTION__);
443 rx_buff->state = OUTSIDE_FRAME;
445 break;
447 case OUTSIDE_FRAME:
448 /* Activate carrier sense */
449 if(byte != XBOF)
450 irda_device_set_media_busy(dev, TRUE);
451 break;
453 case BEGIN_FRAME:
454 default:
455 rx_buff->data[rx_buff->len++] = byte;
456 #ifndef POSTPONE_RX_CRC
457 rx_buff->fcs = irda_fcs(rx_buff->fcs, byte);
458 #endif
459 rx_buff->state = INSIDE_FRAME;
460 break;
465 * Function async_unwrap_char (dev, rx_buff, byte)
467 * Parse and de-stuff frame received from the IrDA-port
469 * This is the main entry point for SIR drivers.
471 void async_unwrap_char(struct net_device *dev,
472 struct net_device_stats *stats,
473 iobuff_t *rx_buff, __u8 byte)
475 switch(byte) {
476 case CE:
477 async_unwrap_ce(dev, stats, rx_buff, byte);
478 break;
479 case BOF:
480 async_unwrap_bof(dev, stats, rx_buff, byte);
481 break;
482 case EOF:
483 async_unwrap_eof(dev, stats, rx_buff, byte);
484 break;
485 default:
486 async_unwrap_other(dev, stats, rx_buff, byte);
487 break;
490 EXPORT_SYMBOL(async_unwrap_char);