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Merge branch 'for-4.2' of git://git.kernel.org/pub/scm/linux/kernel/git/tj/libata
[karo-tx-linux.git] / drivers / atm / he.c
1 /*
2
3   he.c
4
5   ForeRunnerHE ATM Adapter driver for ATM on Linux
6   Copyright (C) 1999-2001  Naval Research Laboratory
7
8   This library is free software; you can redistribute it and/or
9   modify it under the terms of the GNU Lesser General Public
10   License as published by the Free Software Foundation; either
11   version 2.1 of the License, or (at your option) any later version.
12
13   This library is distributed in the hope that it will be useful,
14   but WITHOUT ANY WARRANTY; without even the implied warranty of
15   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
16   Lesser General Public License for more details.
17
18   You should have received a copy of the GNU Lesser General Public
19   License along with this library; if not, write to the Free Software
20   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
21
22 */
23
24 /*
25
26   he.c
27
28   ForeRunnerHE ATM Adapter driver for ATM on Linux
29   Copyright (C) 1999-2001  Naval Research Laboratory
30
31   Permission to use, copy, modify and distribute this software and its
32   documentation is hereby granted, provided that both the copyright
33   notice and this permission notice appear in all copies of the software,
34   derivative works or modified versions, and any portions thereof, and
35   that both notices appear in supporting documentation.
36
37   NRL ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" CONDITION AND
38   DISCLAIMS ANY LIABILITY OF ANY KIND FOR ANY DAMAGES WHATSOEVER
39   RESULTING FROM THE USE OF THIS SOFTWARE.
40
41   This driver was written using the "Programmer's Reference Manual for
42   ForeRunnerHE(tm)", MANU0361-01 - Rev. A, 08/21/98.
43
44   AUTHORS:
45         chas williams <chas@cmf.nrl.navy.mil>
46         eric kinzie <ekinzie@cmf.nrl.navy.mil>
47
48   NOTES:
49         4096 supported 'connections'
50         group 0 is used for all traffic
51         interrupt queue 0 is used for all interrupts
52         aal0 support (based on work from ulrich.u.muller@nokia.com)
53
54  */
55
56 #include <linux/module.h>
57 #include <linux/kernel.h>
58 #include <linux/skbuff.h>
59 #include <linux/pci.h>
60 #include <linux/errno.h>
61 #include <linux/types.h>
62 #include <linux/string.h>
63 #include <linux/delay.h>
64 #include <linux/init.h>
65 #include <linux/mm.h>
66 #include <linux/sched.h>
67 #include <linux/timer.h>
68 #include <linux/interrupt.h>
69 #include <linux/dma-mapping.h>
70 #include <linux/bitmap.h>
71 #include <linux/slab.h>
72 #include <asm/io.h>
73 #include <asm/byteorder.h>
74 #include <asm/uaccess.h>
75
76 #include <linux/atmdev.h>
77 #include <linux/atm.h>
78 #include <linux/sonet.h>
79
80 #undef USE_SCATTERGATHER
81 #undef USE_CHECKSUM_HW                  /* still confused about this */
82 /* #undef HE_DEBUG */
83
84 #include "he.h"
85 #include "suni.h"
86 #include <linux/atm_he.h>
87
88 #define hprintk(fmt,args...)    printk(KERN_ERR DEV_LABEL "%d: " fmt, he_dev->number , ##args)
89
90 #ifdef HE_DEBUG
91 #define HPRINTK(fmt,args...)    printk(KERN_DEBUG DEV_LABEL "%d: " fmt, he_dev->number , ##args)
92 #else /* !HE_DEBUG */
93 #define HPRINTK(fmt,args...)    do { } while (0)
94 #endif /* HE_DEBUG */
95
96 /* declarations */
97
98 static int he_open(struct atm_vcc *vcc);
99 static void he_close(struct atm_vcc *vcc);
100 static int he_send(struct atm_vcc *vcc, struct sk_buff *skb);
101 static int he_ioctl(struct atm_dev *dev, unsigned int cmd, void __user *arg);
102 static irqreturn_t he_irq_handler(int irq, void *dev_id);
103 static void he_tasklet(unsigned long data);
104 static int he_proc_read(struct atm_dev *dev,loff_t *pos,char *page);
105 static int he_start(struct atm_dev *dev);
106 static void he_stop(struct he_dev *dev);
107 static void he_phy_put(struct atm_dev *, unsigned char, unsigned long);
108 static unsigned char he_phy_get(struct atm_dev *, unsigned long);
109
110 static u8 read_prom_byte(struct he_dev *he_dev, int addr);
111
112 /* globals */
113
114 static struct he_dev *he_devs;
115 static bool disable64;
116 static short nvpibits = -1;
117 static short nvcibits = -1;
118 static short rx_skb_reserve = 16;
119 static bool irq_coalesce = true;
120 static bool sdh;
121
122 /* Read from EEPROM = 0000 0011b */
123 static unsigned int readtab[] = {
124         CS_HIGH | CLK_HIGH,
125         CS_LOW | CLK_LOW,
126         CLK_HIGH,               /* 0 */
127         CLK_LOW,
128         CLK_HIGH,               /* 0 */
129         CLK_LOW,
130         CLK_HIGH,               /* 0 */
131         CLK_LOW,
132         CLK_HIGH,               /* 0 */
133         CLK_LOW,
134         CLK_HIGH,               /* 0 */
135         CLK_LOW,
136         CLK_HIGH,               /* 0 */
137         CLK_LOW | SI_HIGH,
138         CLK_HIGH | SI_HIGH,     /* 1 */
139         CLK_LOW | SI_HIGH,
140         CLK_HIGH | SI_HIGH      /* 1 */
141 };     
142  
143 /* Clock to read from/write to the EEPROM */
144 static unsigned int clocktab[] = {
145         CLK_LOW,
146         CLK_HIGH,
147         CLK_LOW,
148         CLK_HIGH,
149         CLK_LOW,
150         CLK_HIGH,
151         CLK_LOW,
152         CLK_HIGH,
153         CLK_LOW,
154         CLK_HIGH,
155         CLK_LOW,
156         CLK_HIGH,
157         CLK_LOW,
158         CLK_HIGH,
159         CLK_LOW,
160         CLK_HIGH,
161         CLK_LOW
162 };     
163
164 static struct atmdev_ops he_ops =
165 {
166         .open =         he_open,
167         .close =        he_close,       
168         .ioctl =        he_ioctl,       
169         .send =         he_send,
170         .phy_put =      he_phy_put,
171         .phy_get =      he_phy_get,
172         .proc_read =    he_proc_read,
173         .owner =        THIS_MODULE
174 };
175
176 #define he_writel(dev, val, reg)        do { writel(val, (dev)->membase + (reg)); wmb(); } while (0)
177 #define he_readl(dev, reg)              readl((dev)->membase + (reg))
178
179 /* section 2.12 connection memory access */
180
181 static __inline__ void
182 he_writel_internal(struct he_dev *he_dev, unsigned val, unsigned addr,
183                                                                 unsigned flags)
184 {
185         he_writel(he_dev, val, CON_DAT);
186         (void) he_readl(he_dev, CON_DAT);               /* flush posted writes */
187         he_writel(he_dev, flags | CON_CTL_WRITE | CON_CTL_ADDR(addr), CON_CTL);
188         while (he_readl(he_dev, CON_CTL) & CON_CTL_BUSY);
189 }
190
191 #define he_writel_rcm(dev, val, reg)                            \
192                         he_writel_internal(dev, val, reg, CON_CTL_RCM)
193
194 #define he_writel_tcm(dev, val, reg)                            \
195                         he_writel_internal(dev, val, reg, CON_CTL_TCM)
196
197 #define he_writel_mbox(dev, val, reg)                           \
198                         he_writel_internal(dev, val, reg, CON_CTL_MBOX)
199
200 static unsigned
201 he_readl_internal(struct he_dev *he_dev, unsigned addr, unsigned flags)
202 {
203         he_writel(he_dev, flags | CON_CTL_READ | CON_CTL_ADDR(addr), CON_CTL);
204         while (he_readl(he_dev, CON_CTL) & CON_CTL_BUSY);
205         return he_readl(he_dev, CON_DAT);
206 }
207
208 #define he_readl_rcm(dev, reg) \
209                         he_readl_internal(dev, reg, CON_CTL_RCM)
210
211 #define he_readl_tcm(dev, reg) \
212                         he_readl_internal(dev, reg, CON_CTL_TCM)
213
214 #define he_readl_mbox(dev, reg) \
215                         he_readl_internal(dev, reg, CON_CTL_MBOX)
216
217
218 /* figure 2.2 connection id */
219
220 #define he_mkcid(dev, vpi, vci)         (((vpi << (dev)->vcibits) | vci) & 0x1fff)
221
222 /* 2.5.1 per connection transmit state registers */
223
224 #define he_writel_tsr0(dev, val, cid) \
225                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 0)
226 #define he_readl_tsr0(dev, cid) \
227                 he_readl_tcm(dev, CONFIG_TSRA | (cid << 3) | 0)
228
229 #define he_writel_tsr1(dev, val, cid) \
230                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 1)
231
232 #define he_writel_tsr2(dev, val, cid) \
233                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 2)
234
235 #define he_writel_tsr3(dev, val, cid) \
236                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 3)
237
238 #define he_writel_tsr4(dev, val, cid) \
239                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 4)
240
241         /* from page 2-20
242          *
243          * NOTE While the transmit connection is active, bits 23 through 0
244          *      of this register must not be written by the host.  Byte
245          *      enables should be used during normal operation when writing
246          *      the most significant byte.
247          */
248
249 #define he_writel_tsr4_upper(dev, val, cid) \
250                 he_writel_internal(dev, val, CONFIG_TSRA | (cid << 3) | 4, \
251                                                         CON_CTL_TCM \
252                                                         | CON_BYTE_DISABLE_2 \
253                                                         | CON_BYTE_DISABLE_1 \
254                                                         | CON_BYTE_DISABLE_0)
255
256 #define he_readl_tsr4(dev, cid) \
257                 he_readl_tcm(dev, CONFIG_TSRA | (cid << 3) | 4)
258
259 #define he_writel_tsr5(dev, val, cid) \
260                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 5)
261
262 #define he_writel_tsr6(dev, val, cid) \
263                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 6)
264
265 #define he_writel_tsr7(dev, val, cid) \
266                 he_writel_tcm(dev, val, CONFIG_TSRA | (cid << 3) | 7)
267
268
269 #define he_writel_tsr8(dev, val, cid) \
270                 he_writel_tcm(dev, val, CONFIG_TSRB | (cid << 2) | 0)
271
272 #define he_writel_tsr9(dev, val, cid) \
273                 he_writel_tcm(dev, val, CONFIG_TSRB | (cid << 2) | 1)
274
275 #define he_writel_tsr10(dev, val, cid) \
276                 he_writel_tcm(dev, val, CONFIG_TSRB | (cid << 2) | 2)
277
278 #define he_writel_tsr11(dev, val, cid) \
279                 he_writel_tcm(dev, val, CONFIG_TSRB | (cid << 2) | 3)
280
281
282 #define he_writel_tsr12(dev, val, cid) \
283                 he_writel_tcm(dev, val, CONFIG_TSRC | (cid << 1) | 0)
284
285 #define he_writel_tsr13(dev, val, cid) \
286                 he_writel_tcm(dev, val, CONFIG_TSRC | (cid << 1) | 1)
287
288
289 #define he_writel_tsr14(dev, val, cid) \
290                 he_writel_tcm(dev, val, CONFIG_TSRD | cid)
291
292 #define he_writel_tsr14_upper(dev, val, cid) \
293                 he_writel_internal(dev, val, CONFIG_TSRD | cid, \
294                                                         CON_CTL_TCM \
295                                                         | CON_BYTE_DISABLE_2 \
296                                                         | CON_BYTE_DISABLE_1 \
297                                                         | CON_BYTE_DISABLE_0)
298
299 /* 2.7.1 per connection receive state registers */
300
301 #define he_writel_rsr0(dev, val, cid) \
302                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 0)
303 #define he_readl_rsr0(dev, cid) \
304                 he_readl_rcm(dev, 0x00000 | (cid << 3) | 0)
305
306 #define he_writel_rsr1(dev, val, cid) \
307                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 1)
308
309 #define he_writel_rsr2(dev, val, cid) \
310                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 2)
311
312 #define he_writel_rsr3(dev, val, cid) \
313                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 3)
314
315 #define he_writel_rsr4(dev, val, cid) \
316                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 4)
317
318 #define he_writel_rsr5(dev, val, cid) \
319                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 5)
320
321 #define he_writel_rsr6(dev, val, cid) \
322                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 6)
323
324 #define he_writel_rsr7(dev, val, cid) \
325                 he_writel_rcm(dev, val, 0x00000 | (cid << 3) | 7)
326
327 static __inline__ struct atm_vcc*
328 __find_vcc(struct he_dev *he_dev, unsigned cid)
329 {
330         struct hlist_head *head;
331         struct atm_vcc *vcc;
332         struct sock *s;
333         short vpi;
334         int vci;
335
336         vpi = cid >> he_dev->vcibits;
337         vci = cid & ((1 << he_dev->vcibits) - 1);
338         head = &vcc_hash[vci & (VCC_HTABLE_SIZE -1)];
339
340         sk_for_each(s, head) {
341                 vcc = atm_sk(s);
342                 if (vcc->dev == he_dev->atm_dev &&
343                     vcc->vci == vci && vcc->vpi == vpi &&
344                     vcc->qos.rxtp.traffic_class != ATM_NONE) {
345                                 return vcc;
346                 }
347         }
348         return NULL;
349 }
350
351 static int he_init_one(struct pci_dev *pci_dev,
352                        const struct pci_device_id *pci_ent)
353 {
354         struct atm_dev *atm_dev = NULL;
355         struct he_dev *he_dev = NULL;
356         int err = 0;
357
358         printk(KERN_INFO "ATM he driver\n");
359
360         if (pci_enable_device(pci_dev))
361                 return -EIO;
362         if (dma_set_mask_and_coherent(&pci_dev->dev, DMA_BIT_MASK(32)) != 0) {
363                 printk(KERN_WARNING "he: no suitable dma available\n");
364                 err = -EIO;
365                 goto init_one_failure;
366         }
367
368         atm_dev = atm_dev_register(DEV_LABEL, &pci_dev->dev, &he_ops, -1, NULL);
369         if (!atm_dev) {
370                 err = -ENODEV;
371                 goto init_one_failure;
372         }
373         pci_set_drvdata(pci_dev, atm_dev);
374
375         he_dev = kzalloc(sizeof(struct he_dev),
376                                                         GFP_KERNEL);
377         if (!he_dev) {
378                 err = -ENOMEM;
379                 goto init_one_failure;
380         }
381         he_dev->pci_dev = pci_dev;
382         he_dev->atm_dev = atm_dev;
383         he_dev->atm_dev->dev_data = he_dev;
384         atm_dev->dev_data = he_dev;
385         he_dev->number = atm_dev->number;
386         tasklet_init(&he_dev->tasklet, he_tasklet, (unsigned long) he_dev);
387         spin_lock_init(&he_dev->global_lock);
388
389         if (he_start(atm_dev)) {
390                 he_stop(he_dev);
391                 err = -ENODEV;
392                 goto init_one_failure;
393         }
394         he_dev->next = NULL;
395         if (he_devs)
396                 he_dev->next = he_devs;
397         he_devs = he_dev;
398         return 0;
399
400 init_one_failure:
401         if (atm_dev)
402                 atm_dev_deregister(atm_dev);
403         kfree(he_dev);
404         pci_disable_device(pci_dev);
405         return err;
406 }
407
408 static void he_remove_one(struct pci_dev *pci_dev)
409 {
410         struct atm_dev *atm_dev;
411         struct he_dev *he_dev;
412
413         atm_dev = pci_get_drvdata(pci_dev);
414         he_dev = HE_DEV(atm_dev);
415
416         /* need to remove from he_devs */
417
418         he_stop(he_dev);
419         atm_dev_deregister(atm_dev);
420         kfree(he_dev);
421
422         pci_disable_device(pci_dev);
423 }
424
425
426 static unsigned
427 rate_to_atmf(unsigned rate)             /* cps to atm forum format */
428 {
429 #define NONZERO (1 << 14)
430
431         unsigned exp = 0;
432
433         if (rate == 0)
434                 return 0;
435
436         rate <<= 9;
437         while (rate > 0x3ff) {
438                 ++exp;
439                 rate >>= 1;
440         }
441
442         return (NONZERO | (exp << 9) | (rate & 0x1ff));
443 }
444
445 static void he_init_rx_lbfp0(struct he_dev *he_dev)
446 {
447         unsigned i, lbm_offset, lbufd_index, lbuf_addr, lbuf_count;
448         unsigned lbufs_per_row = he_dev->cells_per_row / he_dev->cells_per_lbuf;
449         unsigned lbuf_bufsize = he_dev->cells_per_lbuf * ATM_CELL_PAYLOAD;
450         unsigned row_offset = he_dev->r0_startrow * he_dev->bytes_per_row;
451         
452         lbufd_index = 0;
453         lbm_offset = he_readl(he_dev, RCMLBM_BA);
454
455         he_writel(he_dev, lbufd_index, RLBF0_H);
456
457         for (i = 0, lbuf_count = 0; i < he_dev->r0_numbuffs; ++i) {
458                 lbufd_index += 2;
459                 lbuf_addr = (row_offset + (lbuf_count * lbuf_bufsize)) / 32;
460
461                 he_writel_rcm(he_dev, lbuf_addr, lbm_offset);
462                 he_writel_rcm(he_dev, lbufd_index, lbm_offset + 1);
463
464                 if (++lbuf_count == lbufs_per_row) {
465                         lbuf_count = 0;
466                         row_offset += he_dev->bytes_per_row;
467                 }
468                 lbm_offset += 4;
469         }
470                 
471         he_writel(he_dev, lbufd_index - 2, RLBF0_T);
472         he_writel(he_dev, he_dev->r0_numbuffs, RLBF0_C);
473 }
474
475 static void he_init_rx_lbfp1(struct he_dev *he_dev)
476 {
477         unsigned i, lbm_offset, lbufd_index, lbuf_addr, lbuf_count;
478         unsigned lbufs_per_row = he_dev->cells_per_row / he_dev->cells_per_lbuf;
479         unsigned lbuf_bufsize = he_dev->cells_per_lbuf * ATM_CELL_PAYLOAD;
480         unsigned row_offset = he_dev->r1_startrow * he_dev->bytes_per_row;
481         
482         lbufd_index = 1;
483         lbm_offset = he_readl(he_dev, RCMLBM_BA) + (2 * lbufd_index);
484
485         he_writel(he_dev, lbufd_index, RLBF1_H);
486
487         for (i = 0, lbuf_count = 0; i < he_dev->r1_numbuffs; ++i) {
488                 lbufd_index += 2;
489                 lbuf_addr = (row_offset + (lbuf_count * lbuf_bufsize)) / 32;
490
491                 he_writel_rcm(he_dev, lbuf_addr, lbm_offset);
492                 he_writel_rcm(he_dev, lbufd_index, lbm_offset + 1);
493
494                 if (++lbuf_count == lbufs_per_row) {
495                         lbuf_count = 0;
496                         row_offset += he_dev->bytes_per_row;
497                 }
498                 lbm_offset += 4;
499         }
500                 
501         he_writel(he_dev, lbufd_index - 2, RLBF1_T);
502         he_writel(he_dev, he_dev->r1_numbuffs, RLBF1_C);
503 }
504
505 static void he_init_tx_lbfp(struct he_dev *he_dev)
506 {
507         unsigned i, lbm_offset, lbufd_index, lbuf_addr, lbuf_count;
508         unsigned lbufs_per_row = he_dev->cells_per_row / he_dev->cells_per_lbuf;
509         unsigned lbuf_bufsize = he_dev->cells_per_lbuf * ATM_CELL_PAYLOAD;
510         unsigned row_offset = he_dev->tx_startrow * he_dev->bytes_per_row;
511         
512         lbufd_index = he_dev->r0_numbuffs + he_dev->r1_numbuffs;
513         lbm_offset = he_readl(he_dev, RCMLBM_BA) + (2 * lbufd_index);
514
515         he_writel(he_dev, lbufd_index, TLBF_H);
516
517         for (i = 0, lbuf_count = 0; i < he_dev->tx_numbuffs; ++i) {
518                 lbufd_index += 1;
519                 lbuf_addr = (row_offset + (lbuf_count * lbuf_bufsize)) / 32;
520
521                 he_writel_rcm(he_dev, lbuf_addr, lbm_offset);
522                 he_writel_rcm(he_dev, lbufd_index, lbm_offset + 1);
523
524                 if (++lbuf_count == lbufs_per_row) {
525                         lbuf_count = 0;
526                         row_offset += he_dev->bytes_per_row;
527                 }
528                 lbm_offset += 2;
529         }
530                 
531         he_writel(he_dev, lbufd_index - 1, TLBF_T);
532 }
533
534 static int he_init_tpdrq(struct he_dev *he_dev)
535 {
536         he_dev->tpdrq_base = dma_zalloc_coherent(&he_dev->pci_dev->dev,
537                                                  CONFIG_TPDRQ_SIZE * sizeof(struct he_tpdrq),
538                                                  &he_dev->tpdrq_phys, GFP_KERNEL);
539         if (he_dev->tpdrq_base == NULL) {
540                 hprintk("failed to alloc tpdrq\n");
541                 return -ENOMEM;
542         }
543
544         he_dev->tpdrq_tail = he_dev->tpdrq_base;
545         he_dev->tpdrq_head = he_dev->tpdrq_base;
546
547         he_writel(he_dev, he_dev->tpdrq_phys, TPDRQ_B_H);
548         he_writel(he_dev, 0, TPDRQ_T);  
549         he_writel(he_dev, CONFIG_TPDRQ_SIZE - 1, TPDRQ_S);
550
551         return 0;
552 }
553
554 static void he_init_cs_block(struct he_dev *he_dev)
555 {
556         unsigned clock, rate, delta;
557         int reg;
558
559         /* 5.1.7 cs block initialization */
560
561         for (reg = 0; reg < 0x20; ++reg)
562                 he_writel_mbox(he_dev, 0x0, CS_STTIM0 + reg);
563
564         /* rate grid timer reload values */
565
566         clock = he_is622(he_dev) ? 66667000 : 50000000;
567         rate = he_dev->atm_dev->link_rate;
568         delta = rate / 16 / 2;
569
570         for (reg = 0; reg < 0x10; ++reg) {
571                 /* 2.4 internal transmit function
572                  *
573                  * we initialize the first row in the rate grid.
574                  * values are period (in clock cycles) of timer
575                  */
576                 unsigned period = clock / rate;
577
578                 he_writel_mbox(he_dev, period, CS_TGRLD0 + reg);
579                 rate -= delta;
580         }
581
582         if (he_is622(he_dev)) {
583                 /* table 5.2 (4 cells per lbuf) */
584                 he_writel_mbox(he_dev, 0x000800fa, CS_ERTHR0);
585                 he_writel_mbox(he_dev, 0x000c33cb, CS_ERTHR1);
586                 he_writel_mbox(he_dev, 0x0010101b, CS_ERTHR2);
587                 he_writel_mbox(he_dev, 0x00181dac, CS_ERTHR3);
588                 he_writel_mbox(he_dev, 0x00280600, CS_ERTHR4);
589
590                 /* table 5.3, 5.4, 5.5, 5.6, 5.7 */
591                 he_writel_mbox(he_dev, 0x023de8b3, CS_ERCTL0);
592                 he_writel_mbox(he_dev, 0x1801, CS_ERCTL1);
593                 he_writel_mbox(he_dev, 0x68b3, CS_ERCTL2);
594                 he_writel_mbox(he_dev, 0x1280, CS_ERSTAT0);
595                 he_writel_mbox(he_dev, 0x68b3, CS_ERSTAT1);
596                 he_writel_mbox(he_dev, 0x14585, CS_RTFWR);
597
598                 he_writel_mbox(he_dev, 0x4680, CS_RTATR);
599
600                 /* table 5.8 */
601                 he_writel_mbox(he_dev, 0x00159ece, CS_TFBSET);
602                 he_writel_mbox(he_dev, 0x68b3, CS_WCRMAX);
603                 he_writel_mbox(he_dev, 0x5eb3, CS_WCRMIN);
604                 he_writel_mbox(he_dev, 0xe8b3, CS_WCRINC);
605                 he_writel_mbox(he_dev, 0xdeb3, CS_WCRDEC);
606                 he_writel_mbox(he_dev, 0x68b3, CS_WCRCEIL);
607
608                 /* table 5.9 */
609                 he_writel_mbox(he_dev, 0x5, CS_OTPPER);
610                 he_writel_mbox(he_dev, 0x14, CS_OTWPER);
611         } else {
612                 /* table 5.1 (4 cells per lbuf) */
613                 he_writel_mbox(he_dev, 0x000400ea, CS_ERTHR0);
614                 he_writel_mbox(he_dev, 0x00063388, CS_ERTHR1);
615                 he_writel_mbox(he_dev, 0x00081018, CS_ERTHR2);
616                 he_writel_mbox(he_dev, 0x000c1dac, CS_ERTHR3);
617                 he_writel_mbox(he_dev, 0x0014051a, CS_ERTHR4);
618
619                 /* table 5.3, 5.4, 5.5, 5.6, 5.7 */
620                 he_writel_mbox(he_dev, 0x0235e4b1, CS_ERCTL0);
621                 he_writel_mbox(he_dev, 0x4701, CS_ERCTL1);
622                 he_writel_mbox(he_dev, 0x64b1, CS_ERCTL2);
623                 he_writel_mbox(he_dev, 0x1280, CS_ERSTAT0);
624                 he_writel_mbox(he_dev, 0x64b1, CS_ERSTAT1);
625                 he_writel_mbox(he_dev, 0xf424, CS_RTFWR);
626
627                 he_writel_mbox(he_dev, 0x4680, CS_RTATR);
628
629                 /* table 5.8 */
630                 he_writel_mbox(he_dev, 0x000563b7, CS_TFBSET);
631                 he_writel_mbox(he_dev, 0x64b1, CS_WCRMAX);
632                 he_writel_mbox(he_dev, 0x5ab1, CS_WCRMIN);
633                 he_writel_mbox(he_dev, 0xe4b1, CS_WCRINC);
634                 he_writel_mbox(he_dev, 0xdab1, CS_WCRDEC);
635                 he_writel_mbox(he_dev, 0x64b1, CS_WCRCEIL);
636
637                 /* table 5.9 */
638                 he_writel_mbox(he_dev, 0x6, CS_OTPPER);
639                 he_writel_mbox(he_dev, 0x1e, CS_OTWPER);
640         }
641
642         he_writel_mbox(he_dev, 0x8, CS_OTTLIM);
643
644         for (reg = 0; reg < 0x8; ++reg)
645                 he_writel_mbox(he_dev, 0x0, CS_HGRRT0 + reg);
646
647 }
648
649 static int he_init_cs_block_rcm(struct he_dev *he_dev)
650 {
651         unsigned (*rategrid)[16][16];
652         unsigned rate, delta;
653         int i, j, reg;
654
655         unsigned rate_atmf, exp, man;
656         unsigned long long rate_cps;
657         int mult, buf, buf_limit = 4;
658
659         rategrid = kmalloc( sizeof(unsigned) * 16 * 16, GFP_KERNEL);
660         if (!rategrid)
661                 return -ENOMEM;
662
663         /* initialize rate grid group table */
664
665         for (reg = 0x0; reg < 0xff; ++reg)
666                 he_writel_rcm(he_dev, 0x0, CONFIG_RCMABR + reg);
667
668         /* initialize rate controller groups */
669
670         for (reg = 0x100; reg < 0x1ff; ++reg)
671                 he_writel_rcm(he_dev, 0x0, CONFIG_RCMABR + reg);
672         
673         /* initialize tNrm lookup table */
674
675         /* the manual makes reference to a routine in a sample driver
676            for proper configuration; fortunately, we only need this
677            in order to support abr connection */
678         
679         /* initialize rate to group table */
680
681         rate = he_dev->atm_dev->link_rate;
682         delta = rate / 32;
683
684         /*
685          * 2.4 transmit internal functions
686          * 
687          * we construct a copy of the rate grid used by the scheduler
688          * in order to construct the rate to group table below
689          */
690
691         for (j = 0; j < 16; j++) {
692                 (*rategrid)[0][j] = rate;
693                 rate -= delta;
694         }
695
696         for (i = 1; i < 16; i++)
697                 for (j = 0; j < 16; j++)
698                         if (i > 14)
699                                 (*rategrid)[i][j] = (*rategrid)[i - 1][j] / 4;
700                         else
701                                 (*rategrid)[i][j] = (*rategrid)[i - 1][j] / 2;
702
703         /*
704          * 2.4 transmit internal function
705          *
706          * this table maps the upper 5 bits of exponent and mantissa
707          * of the atm forum representation of the rate into an index
708          * on rate grid  
709          */
710
711         rate_atmf = 0;
712         while (rate_atmf < 0x400) {
713                 man = (rate_atmf & 0x1f) << 4;
714                 exp = rate_atmf >> 5;
715
716                 /* 
717                         instead of '/ 512', use '>> 9' to prevent a call
718                         to divdu3 on x86 platforms
719                 */
720                 rate_cps = (unsigned long long) (1 << exp) * (man + 512) >> 9;
721
722                 if (rate_cps < 10)
723                         rate_cps = 10;  /* 2.2.1 minimum payload rate is 10 cps */
724
725                 for (i = 255; i > 0; i--)
726                         if ((*rategrid)[i/16][i%16] >= rate_cps)
727                                 break;   /* pick nearest rate instead? */
728
729                 /*
730                  * each table entry is 16 bits: (rate grid index (8 bits)
731                  * and a buffer limit (8 bits)
732                  * there are two table entries in each 32-bit register
733                  */
734
735 #ifdef notdef
736                 buf = rate_cps * he_dev->tx_numbuffs /
737                                 (he_dev->atm_dev->link_rate * 2);
738 #else
739                 /* this is pretty, but avoids _divdu3 and is mostly correct */
740                 mult = he_dev->atm_dev->link_rate / ATM_OC3_PCR;
741                 if (rate_cps > (272 * mult))
742                         buf = 4;
743                 else if (rate_cps > (204 * mult))
744                         buf = 3;
745                 else if (rate_cps > (136 * mult))
746                         buf = 2;
747                 else if (rate_cps > (68 * mult))
748                         buf = 1;
749                 else
750                         buf = 0;
751 #endif
752                 if (buf > buf_limit)
753                         buf = buf_limit;
754                 reg = (reg << 16) | ((i << 8) | buf);
755
756 #define RTGTBL_OFFSET 0x400
757           
758                 if (rate_atmf & 0x1)
759                         he_writel_rcm(he_dev, reg,
760                                 CONFIG_RCMABR + RTGTBL_OFFSET + (rate_atmf >> 1));
761
762                 ++rate_atmf;
763         }
764
765         kfree(rategrid);
766         return 0;
767 }
768
769 static int he_init_group(struct he_dev *he_dev, int group)
770 {
771         struct he_buff *heb, *next;
772         dma_addr_t mapping;
773         int i;
774
775         he_writel(he_dev, 0x0, G0_RBPS_S + (group * 32));
776         he_writel(he_dev, 0x0, G0_RBPS_T + (group * 32));
777         he_writel(he_dev, 0x0, G0_RBPS_QI + (group * 32));
778         he_writel(he_dev, RBP_THRESH(0x1) | RBP_QSIZE(0x0),
779                   G0_RBPS_BS + (group * 32));
780
781         /* bitmap table */
782         he_dev->rbpl_table = kmalloc(BITS_TO_LONGS(RBPL_TABLE_SIZE)
783                                      * sizeof(unsigned long), GFP_KERNEL);
784         if (!he_dev->rbpl_table) {
785                 hprintk("unable to allocate rbpl bitmap table\n");
786                 return -ENOMEM;
787         }
788         bitmap_zero(he_dev->rbpl_table, RBPL_TABLE_SIZE);
789
790         /* rbpl_virt 64-bit pointers */
791         he_dev->rbpl_virt = kmalloc(RBPL_TABLE_SIZE
792                                     * sizeof(struct he_buff *), GFP_KERNEL);
793         if (!he_dev->rbpl_virt) {
794                 hprintk("unable to allocate rbpl virt table\n");
795                 goto out_free_rbpl_table;
796         }
797
798         /* large buffer pool */
799         he_dev->rbpl_pool = dma_pool_create("rbpl", &he_dev->pci_dev->dev,
800                                             CONFIG_RBPL_BUFSIZE, 64, 0);
801         if (he_dev->rbpl_pool == NULL) {
802                 hprintk("unable to create rbpl pool\n");
803                 goto out_free_rbpl_virt;
804         }
805
806         he_dev->rbpl_base = dma_zalloc_coherent(&he_dev->pci_dev->dev,
807                                                 CONFIG_RBPL_SIZE * sizeof(struct he_rbp),
808                                                 &he_dev->rbpl_phys, GFP_KERNEL);
809         if (he_dev->rbpl_base == NULL) {
810                 hprintk("failed to alloc rbpl_base\n");
811                 goto out_destroy_rbpl_pool;
812         }
813
814         INIT_LIST_HEAD(&he_dev->rbpl_outstanding);
815
816         for (i = 0; i < CONFIG_RBPL_SIZE; ++i) {
817
818                 heb = dma_pool_alloc(he_dev->rbpl_pool, GFP_KERNEL, &mapping);
819                 if (!heb)
820                         goto out_free_rbpl;
821                 heb->mapping = mapping;
822                 list_add(&heb->entry, &he_dev->rbpl_outstanding);
823
824                 set_bit(i, he_dev->rbpl_table);
825                 he_dev->rbpl_virt[i] = heb;
826                 he_dev->rbpl_hint = i + 1;
827                 he_dev->rbpl_base[i].idx =  i << RBP_IDX_OFFSET;
828                 he_dev->rbpl_base[i].phys = mapping + offsetof(struct he_buff, data);
829         }
830         he_dev->rbpl_tail = &he_dev->rbpl_base[CONFIG_RBPL_SIZE - 1];
831
832         he_writel(he_dev, he_dev->rbpl_phys, G0_RBPL_S + (group * 32));
833         he_writel(he_dev, RBPL_MASK(he_dev->rbpl_tail),
834                                                 G0_RBPL_T + (group * 32));
835         he_writel(he_dev, (CONFIG_RBPL_BUFSIZE - sizeof(struct he_buff))/4,
836                                                 G0_RBPL_BS + (group * 32));
837         he_writel(he_dev,
838                         RBP_THRESH(CONFIG_RBPL_THRESH) |
839                         RBP_QSIZE(CONFIG_RBPL_SIZE - 1) |
840                         RBP_INT_ENB,
841                                                 G0_RBPL_QI + (group * 32));
842
843         /* rx buffer ready queue */
844
845         he_dev->rbrq_base = dma_zalloc_coherent(&he_dev->pci_dev->dev,
846                                                 CONFIG_RBRQ_SIZE * sizeof(struct he_rbrq),
847                                                 &he_dev->rbrq_phys, GFP_KERNEL);
848         if (he_dev->rbrq_base == NULL) {
849                 hprintk("failed to allocate rbrq\n");
850                 goto out_free_rbpl;
851         }
852
853         he_dev->rbrq_head = he_dev->rbrq_base;
854         he_writel(he_dev, he_dev->rbrq_phys, G0_RBRQ_ST + (group * 16));
855         he_writel(he_dev, 0, G0_RBRQ_H + (group * 16));
856         he_writel(he_dev,
857                 RBRQ_THRESH(CONFIG_RBRQ_THRESH) | RBRQ_SIZE(CONFIG_RBRQ_SIZE - 1),
858                                                 G0_RBRQ_Q + (group * 16));
859         if (irq_coalesce) {
860                 hprintk("coalescing interrupts\n");
861                 he_writel(he_dev, RBRQ_TIME(768) | RBRQ_COUNT(7),
862                                                 G0_RBRQ_I + (group * 16));
863         } else
864                 he_writel(he_dev, RBRQ_TIME(0) | RBRQ_COUNT(1),
865                                                 G0_RBRQ_I + (group * 16));
866
867         /* tx buffer ready queue */
868
869         he_dev->tbrq_base = dma_zalloc_coherent(&he_dev->pci_dev->dev,
870                                                 CONFIG_TBRQ_SIZE * sizeof(struct he_tbrq),
871                                                 &he_dev->tbrq_phys, GFP_KERNEL);
872         if (he_dev->tbrq_base == NULL) {
873                 hprintk("failed to allocate tbrq\n");
874                 goto out_free_rbpq_base;
875         }
876
877         he_dev->tbrq_head = he_dev->tbrq_base;
878
879         he_writel(he_dev, he_dev->tbrq_phys, G0_TBRQ_B_T + (group * 16));
880         he_writel(he_dev, 0, G0_TBRQ_H + (group * 16));
881         he_writel(he_dev, CONFIG_TBRQ_SIZE - 1, G0_TBRQ_S + (group * 16));
882         he_writel(he_dev, CONFIG_TBRQ_THRESH, G0_TBRQ_THRESH + (group * 16));
883
884         return 0;
885
886 out_free_rbpq_base:
887         dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_RBRQ_SIZE *
888                           sizeof(struct he_rbrq), he_dev->rbrq_base,
889                           he_dev->rbrq_phys);
890 out_free_rbpl:
891         list_for_each_entry_safe(heb, next, &he_dev->rbpl_outstanding, entry)
892                 dma_pool_free(he_dev->rbpl_pool, heb, heb->mapping);
893
894         dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_RBPL_SIZE *
895                           sizeof(struct he_rbp), he_dev->rbpl_base,
896                           he_dev->rbpl_phys);
897 out_destroy_rbpl_pool:
898         dma_pool_destroy(he_dev->rbpl_pool);
899 out_free_rbpl_virt:
900         kfree(he_dev->rbpl_virt);
901 out_free_rbpl_table:
902         kfree(he_dev->rbpl_table);
903
904         return -ENOMEM;
905 }
906
907 static int he_init_irq(struct he_dev *he_dev)
908 {
909         int i;
910
911         /* 2.9.3.5  tail offset for each interrupt queue is located after the
912                     end of the interrupt queue */
913
914         he_dev->irq_base = dma_zalloc_coherent(&he_dev->pci_dev->dev,
915                                                (CONFIG_IRQ_SIZE + 1)
916                                                * sizeof(struct he_irq),
917                                                &he_dev->irq_phys,
918                                                GFP_KERNEL);
919         if (he_dev->irq_base == NULL) {
920                 hprintk("failed to allocate irq\n");
921                 return -ENOMEM;
922         }
923         he_dev->irq_tailoffset = (unsigned *)
924                                         &he_dev->irq_base[CONFIG_IRQ_SIZE];
925         *he_dev->irq_tailoffset = 0;
926         he_dev->irq_head = he_dev->irq_base;
927         he_dev->irq_tail = he_dev->irq_base;
928
929         for (i = 0; i < CONFIG_IRQ_SIZE; ++i)
930                 he_dev->irq_base[i].isw = ITYPE_INVALID;
931
932         he_writel(he_dev, he_dev->irq_phys, IRQ0_BASE);
933         he_writel(he_dev,
934                 IRQ_SIZE(CONFIG_IRQ_SIZE) | IRQ_THRESH(CONFIG_IRQ_THRESH),
935                                                                 IRQ0_HEAD);
936         he_writel(he_dev, IRQ_INT_A | IRQ_TYPE_LINE, IRQ0_CNTL);
937         he_writel(he_dev, 0x0, IRQ0_DATA);
938
939         he_writel(he_dev, 0x0, IRQ1_BASE);
940         he_writel(he_dev, 0x0, IRQ1_HEAD);
941         he_writel(he_dev, 0x0, IRQ1_CNTL);
942         he_writel(he_dev, 0x0, IRQ1_DATA);
943
944         he_writel(he_dev, 0x0, IRQ2_BASE);
945         he_writel(he_dev, 0x0, IRQ2_HEAD);
946         he_writel(he_dev, 0x0, IRQ2_CNTL);
947         he_writel(he_dev, 0x0, IRQ2_DATA);
948
949         he_writel(he_dev, 0x0, IRQ3_BASE);
950         he_writel(he_dev, 0x0, IRQ3_HEAD);
951         he_writel(he_dev, 0x0, IRQ3_CNTL);
952         he_writel(he_dev, 0x0, IRQ3_DATA);
953
954         /* 2.9.3.2 interrupt queue mapping registers */
955
956         he_writel(he_dev, 0x0, GRP_10_MAP);
957         he_writel(he_dev, 0x0, GRP_32_MAP);
958         he_writel(he_dev, 0x0, GRP_54_MAP);
959         he_writel(he_dev, 0x0, GRP_76_MAP);
960
961         if (request_irq(he_dev->pci_dev->irq,
962                         he_irq_handler, IRQF_SHARED, DEV_LABEL, he_dev)) {
963                 hprintk("irq %d already in use\n", he_dev->pci_dev->irq);
964                 return -EINVAL;
965         }   
966
967         he_dev->irq = he_dev->pci_dev->irq;
968
969         return 0;
970 }
971
972 static int he_start(struct atm_dev *dev)
973 {
974         struct he_dev *he_dev;
975         struct pci_dev *pci_dev;
976         unsigned long membase;
977
978         u16 command;
979         u32 gen_cntl_0, host_cntl, lb_swap;
980         u8 cache_size, timer;
981         
982         unsigned err;
983         unsigned int status, reg;
984         int i, group;
985
986         he_dev = HE_DEV(dev);
987         pci_dev = he_dev->pci_dev;
988
989         membase = pci_resource_start(pci_dev, 0);
990         HPRINTK("membase = 0x%lx  irq = %d.\n", membase, pci_dev->irq);
991
992         /*
993          * pci bus controller initialization 
994          */
995
996         /* 4.3 pci bus controller-specific initialization */
997         if (pci_read_config_dword(pci_dev, GEN_CNTL_0, &gen_cntl_0) != 0) {
998                 hprintk("can't read GEN_CNTL_0\n");
999                 return -EINVAL;
1000         }
1001         gen_cntl_0 |= (MRL_ENB | MRM_ENB | IGNORE_TIMEOUT);
1002         if (pci_write_config_dword(pci_dev, GEN_CNTL_0, gen_cntl_0) != 0) {
1003                 hprintk("can't write GEN_CNTL_0.\n");
1004                 return -EINVAL;
1005         }
1006
1007         if (pci_read_config_word(pci_dev, PCI_COMMAND, &command) != 0) {
1008                 hprintk("can't read PCI_COMMAND.\n");
1009                 return -EINVAL;
1010         }
1011
1012         command |= (PCI_COMMAND_MEMORY | PCI_COMMAND_MASTER | PCI_COMMAND_INVALIDATE);
1013         if (pci_write_config_word(pci_dev, PCI_COMMAND, command) != 0) {
1014                 hprintk("can't enable memory.\n");
1015                 return -EINVAL;
1016         }
1017
1018         if (pci_read_config_byte(pci_dev, PCI_CACHE_LINE_SIZE, &cache_size)) {
1019                 hprintk("can't read cache line size?\n");
1020                 return -EINVAL;
1021         }
1022
1023         if (cache_size < 16) {
1024                 cache_size = 16;
1025                 if (pci_write_config_byte(pci_dev, PCI_CACHE_LINE_SIZE, cache_size))
1026                         hprintk("can't set cache line size to %d\n", cache_size);
1027         }
1028
1029         if (pci_read_config_byte(pci_dev, PCI_LATENCY_TIMER, &timer)) {
1030                 hprintk("can't read latency timer?\n");
1031                 return -EINVAL;
1032         }
1033
1034         /* from table 3.9
1035          *
1036          * LAT_TIMER = 1 + AVG_LAT + BURST_SIZE/BUS_SIZE
1037          * 
1038          * AVG_LAT: The average first data read/write latency [maximum 16 clock cycles]
1039          * BURST_SIZE: 1536 bytes (read) for 622, 768 bytes (read) for 155 [192 clock cycles]
1040          *
1041          */ 
1042 #define LAT_TIMER 209
1043         if (timer < LAT_TIMER) {
1044                 HPRINTK("latency timer was %d, setting to %d\n", timer, LAT_TIMER);
1045                 timer = LAT_TIMER;
1046                 if (pci_write_config_byte(pci_dev, PCI_LATENCY_TIMER, timer))
1047                         hprintk("can't set latency timer to %d\n", timer);
1048         }
1049
1050         if (!(he_dev->membase = ioremap(membase, HE_REGMAP_SIZE))) {
1051                 hprintk("can't set up page mapping\n");
1052                 return -EINVAL;
1053         }
1054
1055         /* 4.4 card reset */
1056         he_writel(he_dev, 0x0, RESET_CNTL);
1057         he_writel(he_dev, 0xff, RESET_CNTL);
1058
1059         msleep(16);     /* 16 ms */
1060         status = he_readl(he_dev, RESET_CNTL);
1061         if ((status & BOARD_RST_STATUS) == 0) {
1062                 hprintk("reset failed\n");
1063                 return -EINVAL;
1064         }
1065
1066         /* 4.5 set bus width */
1067         host_cntl = he_readl(he_dev, HOST_CNTL);
1068         if (host_cntl & PCI_BUS_SIZE64)
1069                 gen_cntl_0 |= ENBL_64;
1070         else
1071                 gen_cntl_0 &= ~ENBL_64;
1072
1073         if (disable64 == 1) {
1074                 hprintk("disabling 64-bit pci bus transfers\n");
1075                 gen_cntl_0 &= ~ENBL_64;
1076         }
1077
1078         if (gen_cntl_0 & ENBL_64)
1079                 hprintk("64-bit transfers enabled\n");
1080
1081         pci_write_config_dword(pci_dev, GEN_CNTL_0, gen_cntl_0);
1082
1083         /* 4.7 read prom contents */
1084         for (i = 0; i < PROD_ID_LEN; ++i)
1085                 he_dev->prod_id[i] = read_prom_byte(he_dev, PROD_ID + i);
1086
1087         he_dev->media = read_prom_byte(he_dev, MEDIA);
1088
1089         for (i = 0; i < 6; ++i)
1090                 dev->esi[i] = read_prom_byte(he_dev, MAC_ADDR + i);
1091
1092         hprintk("%s%s, %pM\n", he_dev->prod_id,
1093                 he_dev->media & 0x40 ? "SM" : "MM", dev->esi);
1094         he_dev->atm_dev->link_rate = he_is622(he_dev) ?
1095                                                 ATM_OC12_PCR : ATM_OC3_PCR;
1096
1097         /* 4.6 set host endianess */
1098         lb_swap = he_readl(he_dev, LB_SWAP);
1099         if (he_is622(he_dev))
1100                 lb_swap &= ~XFER_SIZE;          /* 4 cells */
1101         else
1102                 lb_swap |= XFER_SIZE;           /* 8 cells */
1103 #ifdef __BIG_ENDIAN
1104         lb_swap |= DESC_WR_SWAP | INTR_SWAP | BIG_ENDIAN_HOST;
1105 #else
1106         lb_swap &= ~(DESC_WR_SWAP | INTR_SWAP | BIG_ENDIAN_HOST |
1107                         DATA_WR_SWAP | DATA_RD_SWAP | DESC_RD_SWAP);
1108 #endif /* __BIG_ENDIAN */
1109         he_writel(he_dev, lb_swap, LB_SWAP);
1110
1111         /* 4.8 sdram controller initialization */
1112         he_writel(he_dev, he_is622(he_dev) ? LB_64_ENB : 0x0, SDRAM_CTL);
1113
1114         /* 4.9 initialize rnum value */
1115         lb_swap |= SWAP_RNUM_MAX(0xf);
1116         he_writel(he_dev, lb_swap, LB_SWAP);
1117
1118         /* 4.10 initialize the interrupt queues */
1119         if ((err = he_init_irq(he_dev)) != 0)
1120                 return err;
1121
1122         /* 4.11 enable pci bus controller state machines */
1123         host_cntl |= (OUTFF_ENB | CMDFF_ENB |
1124                                 QUICK_RD_RETRY | QUICK_WR_RETRY | PERR_INT_ENB);
1125         he_writel(he_dev, host_cntl, HOST_CNTL);
1126
1127         gen_cntl_0 |= INT_PROC_ENBL|INIT_ENB;
1128         pci_write_config_dword(pci_dev, GEN_CNTL_0, gen_cntl_0);
1129
1130         /*
1131          * atm network controller initialization
1132          */
1133
1134         /* 5.1.1 generic configuration state */
1135
1136         /*
1137          *              local (cell) buffer memory map
1138          *                    
1139          *             HE155                          HE622
1140          *                                                      
1141          *        0 ____________1023 bytes  0 _______________________2047 bytes
1142          *         |            |            |                   |   |
1143          *         |  utility   |            |        rx0        |   |
1144          *        5|____________|         255|___________________| u |
1145          *        6|            |         256|                   | t |
1146          *         |            |            |                   | i |
1147          *         |    rx0     |     row    |        tx         | l |
1148          *         |            |            |                   | i |
1149          *         |            |         767|___________________| t |
1150          *      517|____________|         768|                   | y |
1151          * row  518|            |            |        rx1        |   |
1152          *         |            |        1023|___________________|___|
1153          *         |            |
1154          *         |    tx      |
1155          *         |            |
1156          *         |            |
1157          *     1535|____________|
1158          *     1536|            |
1159          *         |    rx1     |
1160          *     2047|____________|
1161          *
1162          */
1163
1164         /* total 4096 connections */
1165         he_dev->vcibits = CONFIG_DEFAULT_VCIBITS;
1166         he_dev->vpibits = CONFIG_DEFAULT_VPIBITS;
1167
1168         if (nvpibits != -1 && nvcibits != -1 && nvpibits+nvcibits != HE_MAXCIDBITS) {
1169                 hprintk("nvpibits + nvcibits != %d\n", HE_MAXCIDBITS);
1170                 return -ENODEV;
1171         }
1172
1173         if (nvpibits != -1) {
1174                 he_dev->vpibits = nvpibits;
1175                 he_dev->vcibits = HE_MAXCIDBITS - nvpibits;
1176         }
1177
1178         if (nvcibits != -1) {
1179                 he_dev->vcibits = nvcibits;
1180                 he_dev->vpibits = HE_MAXCIDBITS - nvcibits;
1181         }
1182
1183
1184         if (he_is622(he_dev)) {
1185                 he_dev->cells_per_row = 40;
1186                 he_dev->bytes_per_row = 2048;
1187                 he_dev->r0_numrows = 256;
1188                 he_dev->tx_numrows = 512;
1189                 he_dev->r1_numrows = 256;
1190                 he_dev->r0_startrow = 0;
1191                 he_dev->tx_startrow = 256;
1192                 he_dev->r1_startrow = 768;
1193         } else {
1194                 he_dev->cells_per_row = 20;
1195                 he_dev->bytes_per_row = 1024;
1196                 he_dev->r0_numrows = 512;
1197                 he_dev->tx_numrows = 1018;
1198                 he_dev->r1_numrows = 512;
1199                 he_dev->r0_startrow = 6;
1200                 he_dev->tx_startrow = 518;
1201                 he_dev->r1_startrow = 1536;
1202         }
1203
1204         he_dev->cells_per_lbuf = 4;
1205         he_dev->buffer_limit = 4;
1206         he_dev->r0_numbuffs = he_dev->r0_numrows *
1207                                 he_dev->cells_per_row / he_dev->cells_per_lbuf;
1208         if (he_dev->r0_numbuffs > 2560)
1209                 he_dev->r0_numbuffs = 2560;
1210
1211         he_dev->r1_numbuffs = he_dev->r1_numrows *
1212                                 he_dev->cells_per_row / he_dev->cells_per_lbuf;
1213         if (he_dev->r1_numbuffs > 2560)
1214                 he_dev->r1_numbuffs = 2560;
1215
1216         he_dev->tx_numbuffs = he_dev->tx_numrows *
1217                                 he_dev->cells_per_row / he_dev->cells_per_lbuf;
1218         if (he_dev->tx_numbuffs > 5120)
1219                 he_dev->tx_numbuffs = 5120;
1220
1221         /* 5.1.2 configure hardware dependent registers */
1222
1223         he_writel(he_dev, 
1224                 SLICE_X(0x2) | ARB_RNUM_MAX(0xf) | TH_PRTY(0x3) |
1225                 RH_PRTY(0x3) | TL_PRTY(0x2) | RL_PRTY(0x1) |
1226                 (he_is622(he_dev) ? BUS_MULTI(0x28) : BUS_MULTI(0x46)) |
1227                 (he_is622(he_dev) ? NET_PREF(0x50) : NET_PREF(0x8c)),
1228                                                                 LBARB);
1229
1230         he_writel(he_dev, BANK_ON |
1231                 (he_is622(he_dev) ? (REF_RATE(0x384) | WIDE_DATA) : REF_RATE(0x150)),
1232                                                                 SDRAMCON);
1233
1234         he_writel(he_dev,
1235                 (he_is622(he_dev) ? RM_BANK_WAIT(1) : RM_BANK_WAIT(0)) |
1236                                                 RM_RW_WAIT(1), RCMCONFIG);
1237         he_writel(he_dev,
1238                 (he_is622(he_dev) ? TM_BANK_WAIT(2) : TM_BANK_WAIT(1)) |
1239                                                 TM_RW_WAIT(1), TCMCONFIG);
1240
1241         he_writel(he_dev, he_dev->cells_per_lbuf * ATM_CELL_PAYLOAD, LB_CONFIG);
1242
1243         he_writel(he_dev, 
1244                 (he_is622(he_dev) ? UT_RD_DELAY(8) : UT_RD_DELAY(0)) |
1245                 (he_is622(he_dev) ? RC_UT_MODE(0) : RC_UT_MODE(1)) |
1246                 RX_VALVP(he_dev->vpibits) |
1247                 RX_VALVC(he_dev->vcibits),                       RC_CONFIG);
1248
1249         he_writel(he_dev, DRF_THRESH(0x20) |
1250                 (he_is622(he_dev) ? TX_UT_MODE(0) : TX_UT_MODE(1)) |
1251                 TX_VCI_MASK(he_dev->vcibits) |
1252                 LBFREE_CNT(he_dev->tx_numbuffs),                TX_CONFIG);
1253
1254         he_writel(he_dev, 0x0, TXAAL5_PROTO);
1255
1256         he_writel(he_dev, PHY_INT_ENB |
1257                 (he_is622(he_dev) ? PTMR_PRE(67 - 1) : PTMR_PRE(50 - 1)),
1258                                                                 RH_CONFIG);
1259
1260         /* 5.1.3 initialize connection memory */
1261
1262         for (i = 0; i < TCM_MEM_SIZE; ++i)
1263                 he_writel_tcm(he_dev, 0, i);
1264
1265         for (i = 0; i < RCM_MEM_SIZE; ++i)
1266                 he_writel_rcm(he_dev, 0, i);
1267
1268         /*
1269          *      transmit connection memory map
1270          *
1271          *                  tx memory
1272          *          0x0 ___________________
1273          *             |                   |
1274          *             |                   |
1275          *             |       TSRa        |
1276          *             |                   |
1277          *             |                   |
1278          *       0x8000|___________________|
1279          *             |                   |
1280          *             |       TSRb        |
1281          *       0xc000|___________________|
1282          *             |                   |
1283          *             |       TSRc        |
1284          *       0xe000|___________________|
1285          *             |       TSRd        |
1286          *       0xf000|___________________|
1287          *             |       tmABR       |
1288          *      0x10000|___________________|
1289          *             |                   |
1290          *             |       tmTPD       |
1291          *             |___________________|
1292          *             |                   |
1293          *                      ....
1294          *      0x1ffff|___________________|
1295          *
1296          *
1297          */
1298
1299         he_writel(he_dev, CONFIG_TSRB, TSRB_BA);
1300         he_writel(he_dev, CONFIG_TSRC, TSRC_BA);
1301         he_writel(he_dev, CONFIG_TSRD, TSRD_BA);
1302         he_writel(he_dev, CONFIG_TMABR, TMABR_BA);
1303         he_writel(he_dev, CONFIG_TPDBA, TPD_BA);
1304
1305
1306         /*
1307          *      receive connection memory map
1308          *
1309          *          0x0 ___________________
1310          *             |                   |
1311          *             |                   |
1312          *             |       RSRa        |
1313          *             |                   |
1314          *             |                   |
1315          *       0x8000|___________________|
1316          *             |                   |
1317          *             |             rx0/1 |
1318          *             |       LBM         |   link lists of local
1319          *             |             tx    |   buffer memory 
1320          *             |                   |
1321          *       0xd000|___________________|
1322          *             |                   |
1323          *             |      rmABR        |
1324          *       0xe000|___________________|
1325          *             |                   |
1326          *             |       RSRb        |
1327          *             |___________________|
1328          *             |                   |
1329          *                      ....
1330          *       0xffff|___________________|
1331          */
1332
1333         he_writel(he_dev, 0x08000, RCMLBM_BA);
1334         he_writel(he_dev, 0x0e000, RCMRSRB_BA);
1335         he_writel(he_dev, 0x0d800, RCMABR_BA);
1336
1337         /* 5.1.4 initialize local buffer free pools linked lists */
1338
1339         he_init_rx_lbfp0(he_dev);
1340         he_init_rx_lbfp1(he_dev);
1341
1342         he_writel(he_dev, 0x0, RLBC_H);
1343         he_writel(he_dev, 0x0, RLBC_T);
1344         he_writel(he_dev, 0x0, RLBC_H2);
1345
1346         he_writel(he_dev, 512, RXTHRSH);        /* 10% of r0+r1 buffers */
1347         he_writel(he_dev, 256, LITHRSH);        /* 5% of r0+r1 buffers */
1348
1349         he_init_tx_lbfp(he_dev);
1350
1351         he_writel(he_dev, he_is622(he_dev) ? 0x104780 : 0x800, UBUFF_BA);
1352
1353         /* 5.1.5 initialize intermediate receive queues */
1354
1355         if (he_is622(he_dev)) {
1356                 he_writel(he_dev, 0x000f, G0_INMQ_S);
1357                 he_writel(he_dev, 0x200f, G0_INMQ_L);
1358
1359                 he_writel(he_dev, 0x001f, G1_INMQ_S);
1360                 he_writel(he_dev, 0x201f, G1_INMQ_L);
1361
1362                 he_writel(he_dev, 0x002f, G2_INMQ_S);
1363                 he_writel(he_dev, 0x202f, G2_INMQ_L);
1364
1365                 he_writel(he_dev, 0x003f, G3_INMQ_S);
1366                 he_writel(he_dev, 0x203f, G3_INMQ_L);
1367
1368                 he_writel(he_dev, 0x004f, G4_INMQ_S);
1369                 he_writel(he_dev, 0x204f, G4_INMQ_L);
1370
1371                 he_writel(he_dev, 0x005f, G5_INMQ_S);
1372                 he_writel(he_dev, 0x205f, G5_INMQ_L);
1373
1374                 he_writel(he_dev, 0x006f, G6_INMQ_S);
1375                 he_writel(he_dev, 0x206f, G6_INMQ_L);
1376
1377                 he_writel(he_dev, 0x007f, G7_INMQ_S);
1378                 he_writel(he_dev, 0x207f, G7_INMQ_L);
1379         } else {
1380                 he_writel(he_dev, 0x0000, G0_INMQ_S);
1381                 he_writel(he_dev, 0x0008, G0_INMQ_L);
1382
1383                 he_writel(he_dev, 0x0001, G1_INMQ_S);
1384                 he_writel(he_dev, 0x0009, G1_INMQ_L);
1385
1386                 he_writel(he_dev, 0x0002, G2_INMQ_S);
1387                 he_writel(he_dev, 0x000a, G2_INMQ_L);
1388
1389                 he_writel(he_dev, 0x0003, G3_INMQ_S);
1390                 he_writel(he_dev, 0x000b, G3_INMQ_L);
1391
1392                 he_writel(he_dev, 0x0004, G4_INMQ_S);
1393                 he_writel(he_dev, 0x000c, G4_INMQ_L);
1394
1395                 he_writel(he_dev, 0x0005, G5_INMQ_S);
1396                 he_writel(he_dev, 0x000d, G5_INMQ_L);
1397
1398                 he_writel(he_dev, 0x0006, G6_INMQ_S);
1399                 he_writel(he_dev, 0x000e, G6_INMQ_L);
1400
1401                 he_writel(he_dev, 0x0007, G7_INMQ_S);
1402                 he_writel(he_dev, 0x000f, G7_INMQ_L);
1403         }
1404
1405         /* 5.1.6 application tunable parameters */
1406
1407         he_writel(he_dev, 0x0, MCC);
1408         he_writel(he_dev, 0x0, OEC);
1409         he_writel(he_dev, 0x0, DCC);
1410         he_writel(he_dev, 0x0, CEC);
1411         
1412         /* 5.1.7 cs block initialization */
1413
1414         he_init_cs_block(he_dev);
1415
1416         /* 5.1.8 cs block connection memory initialization */
1417         
1418         if (he_init_cs_block_rcm(he_dev) < 0)
1419                 return -ENOMEM;
1420
1421         /* 5.1.10 initialize host structures */
1422
1423         he_init_tpdrq(he_dev);
1424
1425         he_dev->tpd_pool = dma_pool_create("tpd", &he_dev->pci_dev->dev,
1426                                            sizeof(struct he_tpd), TPD_ALIGNMENT, 0);
1427         if (he_dev->tpd_pool == NULL) {
1428                 hprintk("unable to create tpd dma_pool\n");
1429                 return -ENOMEM;         
1430         }
1431
1432         INIT_LIST_HEAD(&he_dev->outstanding_tpds);
1433
1434         if (he_init_group(he_dev, 0) != 0)
1435                 return -ENOMEM;
1436
1437         for (group = 1; group < HE_NUM_GROUPS; ++group) {
1438                 he_writel(he_dev, 0x0, G0_RBPS_S + (group * 32));
1439                 he_writel(he_dev, 0x0, G0_RBPS_T + (group * 32));
1440                 he_writel(he_dev, 0x0, G0_RBPS_QI + (group * 32));
1441                 he_writel(he_dev, RBP_THRESH(0x1) | RBP_QSIZE(0x0),
1442                                                 G0_RBPS_BS + (group * 32));
1443
1444                 he_writel(he_dev, 0x0, G0_RBPL_S + (group * 32));
1445                 he_writel(he_dev, 0x0, G0_RBPL_T + (group * 32));
1446                 he_writel(he_dev, RBP_THRESH(0x1) | RBP_QSIZE(0x0),
1447                                                 G0_RBPL_QI + (group * 32));
1448                 he_writel(he_dev, 0x0, G0_RBPL_BS + (group * 32));
1449
1450                 he_writel(he_dev, 0x0, G0_RBRQ_ST + (group * 16));
1451                 he_writel(he_dev, 0x0, G0_RBRQ_H + (group * 16));
1452                 he_writel(he_dev, RBRQ_THRESH(0x1) | RBRQ_SIZE(0x0),
1453                                                 G0_RBRQ_Q + (group * 16));
1454                 he_writel(he_dev, 0x0, G0_RBRQ_I + (group * 16));
1455
1456                 he_writel(he_dev, 0x0, G0_TBRQ_B_T + (group * 16));
1457                 he_writel(he_dev, 0x0, G0_TBRQ_H + (group * 16));
1458                 he_writel(he_dev, TBRQ_THRESH(0x1),
1459                                                 G0_TBRQ_THRESH + (group * 16));
1460                 he_writel(he_dev, 0x0, G0_TBRQ_S + (group * 16));
1461         }
1462
1463         /* host status page */
1464
1465         he_dev->hsp = dma_zalloc_coherent(&he_dev->pci_dev->dev,
1466                                           sizeof(struct he_hsp),
1467                                           &he_dev->hsp_phys, GFP_KERNEL);
1468         if (he_dev->hsp == NULL) {
1469                 hprintk("failed to allocate host status page\n");
1470                 return -ENOMEM;
1471         }
1472         he_writel(he_dev, he_dev->hsp_phys, HSP_BA);
1473
1474         /* initialize framer */
1475
1476 #ifdef CONFIG_ATM_HE_USE_SUNI
1477         if (he_isMM(he_dev))
1478                 suni_init(he_dev->atm_dev);
1479         if (he_dev->atm_dev->phy && he_dev->atm_dev->phy->start)
1480                 he_dev->atm_dev->phy->start(he_dev->atm_dev);
1481 #endif /* CONFIG_ATM_HE_USE_SUNI */
1482
1483         if (sdh) {
1484                 /* this really should be in suni.c but for now... */
1485                 int val;
1486
1487                 val = he_phy_get(he_dev->atm_dev, SUNI_TPOP_APM);
1488                 val = (val & ~SUNI_TPOP_APM_S) | (SUNI_TPOP_S_SDH << SUNI_TPOP_APM_S_SHIFT);
1489                 he_phy_put(he_dev->atm_dev, val, SUNI_TPOP_APM);
1490                 he_phy_put(he_dev->atm_dev, SUNI_TACP_IUCHP_CLP, SUNI_TACP_IUCHP);
1491         }
1492
1493         /* 5.1.12 enable transmit and receive */
1494
1495         reg = he_readl_mbox(he_dev, CS_ERCTL0);
1496         reg |= TX_ENABLE|ER_ENABLE;
1497         he_writel_mbox(he_dev, reg, CS_ERCTL0);
1498
1499         reg = he_readl(he_dev, RC_CONFIG);
1500         reg |= RX_ENABLE;
1501         he_writel(he_dev, reg, RC_CONFIG);
1502
1503         for (i = 0; i < HE_NUM_CS_STPER; ++i) {
1504                 he_dev->cs_stper[i].inuse = 0;
1505                 he_dev->cs_stper[i].pcr = -1;
1506         }
1507         he_dev->total_bw = 0;
1508
1509
1510         /* atm linux initialization */
1511
1512         he_dev->atm_dev->ci_range.vpi_bits = he_dev->vpibits;
1513         he_dev->atm_dev->ci_range.vci_bits = he_dev->vcibits;
1514
1515         he_dev->irq_peak = 0;
1516         he_dev->rbrq_peak = 0;
1517         he_dev->rbpl_peak = 0;
1518         he_dev->tbrq_peak = 0;
1519
1520         HPRINTK("hell bent for leather!\n");
1521
1522         return 0;
1523 }
1524
1525 static void
1526 he_stop(struct he_dev *he_dev)
1527 {
1528         struct he_buff *heb, *next;
1529         struct pci_dev *pci_dev;
1530         u32 gen_cntl_0, reg;
1531         u16 command;
1532
1533         pci_dev = he_dev->pci_dev;
1534
1535         /* disable interrupts */
1536
1537         if (he_dev->membase) {
1538                 pci_read_config_dword(pci_dev, GEN_CNTL_0, &gen_cntl_0);
1539                 gen_cntl_0 &= ~(INT_PROC_ENBL | INIT_ENB);
1540                 pci_write_config_dword(pci_dev, GEN_CNTL_0, gen_cntl_0);
1541
1542                 tasklet_disable(&he_dev->tasklet);
1543
1544                 /* disable recv and transmit */
1545
1546                 reg = he_readl_mbox(he_dev, CS_ERCTL0);
1547                 reg &= ~(TX_ENABLE|ER_ENABLE);
1548                 he_writel_mbox(he_dev, reg, CS_ERCTL0);
1549
1550                 reg = he_readl(he_dev, RC_CONFIG);
1551                 reg &= ~(RX_ENABLE);
1552                 he_writel(he_dev, reg, RC_CONFIG);
1553         }
1554
1555 #ifdef CONFIG_ATM_HE_USE_SUNI
1556         if (he_dev->atm_dev->phy && he_dev->atm_dev->phy->stop)
1557                 he_dev->atm_dev->phy->stop(he_dev->atm_dev);
1558 #endif /* CONFIG_ATM_HE_USE_SUNI */
1559
1560         if (he_dev->irq)
1561                 free_irq(he_dev->irq, he_dev);
1562
1563         if (he_dev->irq_base)
1564                 dma_free_coherent(&he_dev->pci_dev->dev, (CONFIG_IRQ_SIZE + 1)
1565                                   * sizeof(struct he_irq), he_dev->irq_base, he_dev->irq_phys);
1566
1567         if (he_dev->hsp)
1568                 dma_free_coherent(&he_dev->pci_dev->dev, sizeof(struct he_hsp),
1569                                   he_dev->hsp, he_dev->hsp_phys);
1570
1571         if (he_dev->rbpl_base) {
1572                 list_for_each_entry_safe(heb, next, &he_dev->rbpl_outstanding, entry)
1573                         dma_pool_free(he_dev->rbpl_pool, heb, heb->mapping);
1574
1575                 dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_RBPL_SIZE
1576                                   * sizeof(struct he_rbp), he_dev->rbpl_base, he_dev->rbpl_phys);
1577         }
1578
1579         kfree(he_dev->rbpl_virt);
1580         kfree(he_dev->rbpl_table);
1581
1582         if (he_dev->rbpl_pool)
1583                 dma_pool_destroy(he_dev->rbpl_pool);
1584
1585         if (he_dev->rbrq_base)
1586                 dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_RBRQ_SIZE * sizeof(struct he_rbrq),
1587                                   he_dev->rbrq_base, he_dev->rbrq_phys);
1588
1589         if (he_dev->tbrq_base)
1590                 dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_TBRQ_SIZE * sizeof(struct he_tbrq),
1591                                   he_dev->tbrq_base, he_dev->tbrq_phys);
1592
1593         if (he_dev->tpdrq_base)
1594                 dma_free_coherent(&he_dev->pci_dev->dev, CONFIG_TBRQ_SIZE * sizeof(struct he_tbrq),
1595                                   he_dev->tpdrq_base, he_dev->tpdrq_phys);
1596
1597         if (he_dev->tpd_pool)
1598                 dma_pool_destroy(he_dev->tpd_pool);
1599
1600         if (he_dev->pci_dev) {
1601                 pci_read_config_word(he_dev->pci_dev, PCI_COMMAND, &command);
1602                 command &= ~(PCI_COMMAND_MEMORY | PCI_COMMAND_MASTER);
1603                 pci_write_config_word(he_dev->pci_dev, PCI_COMMAND, command);
1604         }
1605         
1606         if (he_dev->membase)
1607                 iounmap(he_dev->membase);
1608 }
1609
1610 static struct he_tpd *
1611 __alloc_tpd(struct he_dev *he_dev)
1612 {
1613         struct he_tpd *tpd;
1614         dma_addr_t mapping;
1615
1616         tpd = dma_pool_alloc(he_dev->tpd_pool, GFP_ATOMIC, &mapping);
1617         if (tpd == NULL)
1618                 return NULL;
1619                         
1620         tpd->status = TPD_ADDR(mapping);
1621         tpd->reserved = 0; 
1622         tpd->iovec[0].addr = 0; tpd->iovec[0].len = 0;
1623         tpd->iovec[1].addr = 0; tpd->iovec[1].len = 0;
1624         tpd->iovec[2].addr = 0; tpd->iovec[2].len = 0;
1625
1626         return tpd;
1627 }
1628
1629 #define AAL5_LEN(buf,len)                                               \
1630                         ((((unsigned char *)(buf))[(len)-6] << 8) |     \
1631                                 (((unsigned char *)(buf))[(len)-5]))
1632
1633 /* 2.10.1.2 receive
1634  *
1635  * aal5 packets can optionally return the tcp checksum in the lower
1636  * 16 bits of the crc (RSR0_TCP_CKSUM)
1637  */
1638
1639 #define TCP_CKSUM(buf,len)                                              \
1640                         ((((unsigned char *)(buf))[(len)-2] << 8) |     \
1641                                 (((unsigned char *)(buf))[(len-1)]))
1642
1643 static int
1644 he_service_rbrq(struct he_dev *he_dev, int group)
1645 {
1646         struct he_rbrq *rbrq_tail = (struct he_rbrq *)
1647                                 ((unsigned long)he_dev->rbrq_base |
1648                                         he_dev->hsp->group[group].rbrq_tail);
1649         unsigned cid, lastcid = -1;
1650         struct sk_buff *skb;
1651         struct atm_vcc *vcc = NULL;
1652         struct he_vcc *he_vcc;
1653         struct he_buff *heb, *next;
1654         int i;
1655         int pdus_assembled = 0;
1656         int updated = 0;
1657
1658         read_lock(&vcc_sklist_lock);
1659         while (he_dev->rbrq_head != rbrq_tail) {
1660                 ++updated;
1661
1662                 HPRINTK("%p rbrq%d 0x%x len=%d cid=0x%x %s%s%s%s%s%s\n",
1663                         he_dev->rbrq_head, group,
1664                         RBRQ_ADDR(he_dev->rbrq_head),
1665                         RBRQ_BUFLEN(he_dev->rbrq_head),
1666                         RBRQ_CID(he_dev->rbrq_head),
1667                         RBRQ_CRC_ERR(he_dev->rbrq_head) ? " CRC_ERR" : "",
1668                         RBRQ_LEN_ERR(he_dev->rbrq_head) ? " LEN_ERR" : "",
1669                         RBRQ_END_PDU(he_dev->rbrq_head) ? " END_PDU" : "",
1670                         RBRQ_AAL5_PROT(he_dev->rbrq_head) ? " AAL5_PROT" : "",
1671                         RBRQ_CON_CLOSED(he_dev->rbrq_head) ? " CON_CLOSED" : "",
1672                         RBRQ_HBUF_ERR(he_dev->rbrq_head) ? " HBUF_ERR" : "");
1673
1674                 i = RBRQ_ADDR(he_dev->rbrq_head) >> RBP_IDX_OFFSET;
1675                 heb = he_dev->rbpl_virt[i];
1676
1677                 cid = RBRQ_CID(he_dev->rbrq_head);
1678                 if (cid != lastcid)
1679                         vcc = __find_vcc(he_dev, cid);
1680                 lastcid = cid;
1681
1682                 if (vcc == NULL || (he_vcc = HE_VCC(vcc)) == NULL) {
1683                         hprintk("vcc/he_vcc == NULL  (cid 0x%x)\n", cid);
1684                         if (!RBRQ_HBUF_ERR(he_dev->rbrq_head)) {
1685                                 clear_bit(i, he_dev->rbpl_table);
1686                                 list_del(&heb->entry);
1687                                 dma_pool_free(he_dev->rbpl_pool, heb, heb->mapping);
1688                         }
1689                                         
1690                         goto next_rbrq_entry;
1691                 }
1692
1693                 if (RBRQ_HBUF_ERR(he_dev->rbrq_head)) {
1694                         hprintk("HBUF_ERR!  (cid 0x%x)\n", cid);
1695                                 atomic_inc(&vcc->stats->rx_drop);
1696                         goto return_host_buffers;
1697                 }
1698
1699                 heb->len = RBRQ_BUFLEN(he_dev->rbrq_head) * 4;
1700                 clear_bit(i, he_dev->rbpl_table);
1701                 list_move_tail(&heb->entry, &he_vcc->buffers);
1702                 he_vcc->pdu_len += heb->len;
1703
1704                 if (RBRQ_CON_CLOSED(he_dev->rbrq_head)) {
1705                         lastcid = -1;
1706                         HPRINTK("wake_up rx_waitq  (cid 0x%x)\n", cid);
1707                         wake_up(&he_vcc->rx_waitq);
1708                         goto return_host_buffers;
1709                 }
1710
1711                 if (!RBRQ_END_PDU(he_dev->rbrq_head))
1712                         goto next_rbrq_entry;
1713
1714                 if (RBRQ_LEN_ERR(he_dev->rbrq_head)
1715                                 || RBRQ_CRC_ERR(he_dev->rbrq_head)) {
1716                         HPRINTK("%s%s (%d.%d)\n",
1717                                 RBRQ_CRC_ERR(he_dev->rbrq_head)
1718                                                         ? "CRC_ERR " : "",
1719                                 RBRQ_LEN_ERR(he_dev->rbrq_head)
1720                                                         ? "LEN_ERR" : "",
1721                                                         vcc->vpi, vcc->vci);
1722                         atomic_inc(&vcc->stats->rx_err);
1723                         goto return_host_buffers;
1724                 }
1725
1726                 skb = atm_alloc_charge(vcc, he_vcc->pdu_len + rx_skb_reserve,
1727                                                         GFP_ATOMIC);
1728                 if (!skb) {
1729                         HPRINTK("charge failed (%d.%d)\n", vcc->vpi, vcc->vci);
1730                         goto return_host_buffers;
1731                 }
1732
1733                 if (rx_skb_reserve > 0)
1734                         skb_reserve(skb, rx_skb_reserve);
1735
1736                 __net_timestamp(skb);
1737
1738                 list_for_each_entry(heb, &he_vcc->buffers, entry)
1739                         memcpy(skb_put(skb, heb->len), &heb->data, heb->len);
1740
1741                 switch (vcc->qos.aal) {
1742                         case ATM_AAL0:
1743                                 /* 2.10.1.5 raw cell receive */
1744                                 skb->len = ATM_AAL0_SDU;
1745                                 skb_set_tail_pointer(skb, skb->len);
1746                                 break;
1747                         case ATM_AAL5:
1748                                 /* 2.10.1.2 aal5 receive */
1749
1750                                 skb->len = AAL5_LEN(skb->data, he_vcc->pdu_len);
1751                                 skb_set_tail_pointer(skb, skb->len);
1752 #ifdef USE_CHECKSUM_HW
1753                                 if (vcc->vpi == 0 && vcc->vci >= ATM_NOT_RSV_VCI) {
1754                                         skb->ip_summed = CHECKSUM_COMPLETE;
1755                                         skb->csum = TCP_CKSUM(skb->data,
1756                                                         he_vcc->pdu_len);
1757                                 }
1758 #endif
1759                                 break;
1760                 }
1761
1762 #ifdef should_never_happen
1763                 if (skb->len > vcc->qos.rxtp.max_sdu)
1764                         hprintk("pdu_len (%d) > vcc->qos.rxtp.max_sdu (%d)!  cid 0x%x\n", skb->len, vcc->qos.rxtp.max_sdu, cid);
1765 #endif
1766
1767 #ifdef notdef
1768                 ATM_SKB(skb)->vcc = vcc;
1769 #endif
1770                 spin_unlock(&he_dev->global_lock);
1771                 vcc->push(vcc, skb);
1772                 spin_lock(&he_dev->global_lock);
1773
1774                 atomic_inc(&vcc->stats->rx);
1775
1776 return_host_buffers:
1777                 ++pdus_assembled;
1778
1779                 list_for_each_entry_safe(heb, next, &he_vcc->buffers, entry)
1780                         dma_pool_free(he_dev->rbpl_pool, heb, heb->mapping);
1781                 INIT_LIST_HEAD(&he_vcc->buffers);
1782                 he_vcc->pdu_len = 0;
1783
1784 next_rbrq_entry:
1785                 he_dev->rbrq_head = (struct he_rbrq *)
1786                                 ((unsigned long) he_dev->rbrq_base |
1787                                         RBRQ_MASK(he_dev->rbrq_head + 1));
1788
1789         }
1790         read_unlock(&vcc_sklist_lock);
1791
1792         if (updated) {
1793                 if (updated > he_dev->rbrq_peak)
1794                         he_dev->rbrq_peak = updated;
1795
1796                 he_writel(he_dev, RBRQ_MASK(he_dev->rbrq_head),
1797                                                 G0_RBRQ_H + (group * 16));
1798         }
1799
1800         return pdus_assembled;
1801 }
1802
1803 static void
1804 he_service_tbrq(struct he_dev *he_dev, int group)
1805 {
1806         struct he_tbrq *tbrq_tail = (struct he_tbrq *)
1807                                 ((unsigned long)he_dev->tbrq_base |
1808                                         he_dev->hsp->group[group].tbrq_tail);
1809         struct he_tpd *tpd;
1810         int slot, updated = 0;
1811         struct he_tpd *__tpd;
1812
1813         /* 2.1.6 transmit buffer return queue */
1814
1815         while (he_dev->tbrq_head != tbrq_tail) {
1816                 ++updated;
1817
1818                 HPRINTK("tbrq%d 0x%x%s%s\n",
1819                         group,
1820                         TBRQ_TPD(he_dev->tbrq_head), 
1821                         TBRQ_EOS(he_dev->tbrq_head) ? " EOS" : "",
1822                         TBRQ_MULTIPLE(he_dev->tbrq_head) ? " MULTIPLE" : "");
1823                 tpd = NULL;
1824                 list_for_each_entry(__tpd, &he_dev->outstanding_tpds, entry) {
1825                         if (TPD_ADDR(__tpd->status) == TBRQ_TPD(he_dev->tbrq_head)) {
1826                                 tpd = __tpd;
1827                                 list_del(&__tpd->entry);
1828                                 break;
1829                         }
1830                 }
1831
1832                 if (tpd == NULL) {
1833                         hprintk("unable to locate tpd for dma buffer %x\n",
1834                                                 TBRQ_TPD(he_dev->tbrq_head));
1835                         goto next_tbrq_entry;
1836                 }
1837
1838                 if (TBRQ_EOS(he_dev->tbrq_head)) {
1839                         HPRINTK("wake_up(tx_waitq) cid 0x%x\n",
1840                                 he_mkcid(he_dev, tpd->vcc->vpi, tpd->vcc->vci));
1841                         if (tpd->vcc)
1842                                 wake_up(&HE_VCC(tpd->vcc)->tx_waitq);
1843
1844                         goto next_tbrq_entry;
1845                 }
1846
1847                 for (slot = 0; slot < TPD_MAXIOV; ++slot) {
1848                         if (tpd->iovec[slot].addr)
1849                                 dma_unmap_single(&he_dev->pci_dev->dev,
1850                                         tpd->iovec[slot].addr,
1851                                         tpd->iovec[slot].len & TPD_LEN_MASK,
1852                                                         DMA_TO_DEVICE);
1853                         if (tpd->iovec[slot].len & TPD_LST)
1854                                 break;
1855                                 
1856                 }
1857
1858                 if (tpd->skb) { /* && !TBRQ_MULTIPLE(he_dev->tbrq_head) */
1859                         if (tpd->vcc && tpd->vcc->pop)
1860                                 tpd->vcc->pop(tpd->vcc, tpd->skb);
1861                         else
1862                                 dev_kfree_skb_any(tpd->skb);
1863                 }
1864
1865 next_tbrq_entry:
1866                 if (tpd)
1867                         dma_pool_free(he_dev->tpd_pool, tpd, TPD_ADDR(tpd->status));
1868                 he_dev->tbrq_head = (struct he_tbrq *)
1869                                 ((unsigned long) he_dev->tbrq_base |
1870                                         TBRQ_MASK(he_dev->tbrq_head + 1));
1871         }
1872
1873         if (updated) {
1874                 if (updated > he_dev->tbrq_peak)
1875                         he_dev->tbrq_peak = updated;
1876
1877                 he_writel(he_dev, TBRQ_MASK(he_dev->tbrq_head),
1878                                                 G0_TBRQ_H + (group * 16));
1879         }
1880 }
1881
1882 static void
1883 he_service_rbpl(struct he_dev *he_dev, int group)
1884 {
1885         struct he_rbp *new_tail;
1886         struct he_rbp *rbpl_head;
1887         struct he_buff *heb;
1888         dma_addr_t mapping;
1889         int i;
1890         int moved = 0;
1891
1892         rbpl_head = (struct he_rbp *) ((unsigned long)he_dev->rbpl_base |
1893                                         RBPL_MASK(he_readl(he_dev, G0_RBPL_S)));
1894
1895         for (;;) {
1896                 new_tail = (struct he_rbp *) ((unsigned long)he_dev->rbpl_base |
1897                                                 RBPL_MASK(he_dev->rbpl_tail+1));
1898
1899                 /* table 3.42 -- rbpl_tail should never be set to rbpl_head */
1900                 if (new_tail == rbpl_head)
1901                         break;
1902
1903                 i = find_next_zero_bit(he_dev->rbpl_table, RBPL_TABLE_SIZE, he_dev->rbpl_hint);
1904                 if (i > (RBPL_TABLE_SIZE - 1)) {
1905                         i = find_first_zero_bit(he_dev->rbpl_table, RBPL_TABLE_SIZE);
1906                         if (i > (RBPL_TABLE_SIZE - 1))
1907                                 break;
1908                 }
1909                 he_dev->rbpl_hint = i + 1;
1910
1911                 heb = dma_pool_alloc(he_dev->rbpl_pool, GFP_ATOMIC, &mapping);
1912                 if (!heb)
1913                         break;
1914                 heb->mapping = mapping;
1915                 list_add(&heb->entry, &he_dev->rbpl_outstanding);
1916                 he_dev->rbpl_virt[i] = heb;
1917                 set_bit(i, he_dev->rbpl_table);
1918                 new_tail->idx = i << RBP_IDX_OFFSET;
1919                 new_tail->phys = mapping + offsetof(struct he_buff, data);
1920
1921                 he_dev->rbpl_tail = new_tail;
1922                 ++moved;
1923         } 
1924
1925         if (moved)
1926                 he_writel(he_dev, RBPL_MASK(he_dev->rbpl_tail), G0_RBPL_T);
1927 }
1928
1929 static void
1930 he_tasklet(unsigned long data)
1931 {
1932         unsigned long flags;
1933         struct he_dev *he_dev = (struct he_dev *) data;
1934         int group, type;
1935         int updated = 0;
1936
1937         HPRINTK("tasklet (0x%lx)\n", data);
1938         spin_lock_irqsave(&he_dev->global_lock, flags);
1939
1940         while (he_dev->irq_head != he_dev->irq_tail) {
1941                 ++updated;
1942
1943                 type = ITYPE_TYPE(he_dev->irq_head->isw);
1944                 group = ITYPE_GROUP(he_dev->irq_head->isw);
1945
1946                 switch (type) {
1947                         case ITYPE_RBRQ_THRESH:
1948                                 HPRINTK("rbrq%d threshold\n", group);
1949                                 /* fall through */
1950                         case ITYPE_RBRQ_TIMER:
1951                                 if (he_service_rbrq(he_dev, group))
1952                                         he_service_rbpl(he_dev, group);
1953                                 break;
1954                         case ITYPE_TBRQ_THRESH:
1955                                 HPRINTK("tbrq%d threshold\n", group);
1956                                 /* fall through */
1957                         case ITYPE_TPD_COMPLETE:
1958                                 he_service_tbrq(he_dev, group);
1959                                 break;
1960                         case ITYPE_RBPL_THRESH:
1961                                 he_service_rbpl(he_dev, group);
1962                                 break;
1963                         case ITYPE_RBPS_THRESH:
1964                                 /* shouldn't happen unless small buffers enabled */
1965                                 break;
1966                         case ITYPE_PHY:
1967                                 HPRINTK("phy interrupt\n");
1968 #ifdef CONFIG_ATM_HE_USE_SUNI
1969                                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
1970                                 if (he_dev->atm_dev->phy && he_dev->atm_dev->phy->interrupt)
1971                                         he_dev->atm_dev->phy->interrupt(he_dev->atm_dev);
1972                                 spin_lock_irqsave(&he_dev->global_lock, flags);
1973 #endif
1974                                 break;
1975                         case ITYPE_OTHER:
1976                                 switch (type|group) {
1977                                         case ITYPE_PARITY:
1978                                                 hprintk("parity error\n");
1979                                                 break;
1980                                         case ITYPE_ABORT:
1981                                                 hprintk("abort 0x%x\n", he_readl(he_dev, ABORT_ADDR));
1982                                                 break;
1983                                 }
1984                                 break;
1985                         case ITYPE_TYPE(ITYPE_INVALID):
1986                                 /* see 8.1.1 -- check all queues */
1987
1988                                 HPRINTK("isw not updated 0x%x\n", he_dev->irq_head->isw);
1989
1990                                 he_service_rbrq(he_dev, 0);
1991                                 he_service_rbpl(he_dev, 0);
1992                                 he_service_tbrq(he_dev, 0);
1993                                 break;
1994                         default:
1995                                 hprintk("bad isw 0x%x?\n", he_dev->irq_head->isw);
1996                 }
1997
1998                 he_dev->irq_head->isw = ITYPE_INVALID;
1999
2000                 he_dev->irq_head = (struct he_irq *) NEXT_ENTRY(he_dev->irq_base, he_dev->irq_head, IRQ_MASK);
2001         }
2002
2003         if (updated) {
2004                 if (updated > he_dev->irq_peak)
2005                         he_dev->irq_peak = updated;
2006
2007                 he_writel(he_dev,
2008                         IRQ_SIZE(CONFIG_IRQ_SIZE) |
2009                         IRQ_THRESH(CONFIG_IRQ_THRESH) |
2010                         IRQ_TAIL(he_dev->irq_tail), IRQ0_HEAD);
2011                 (void) he_readl(he_dev, INT_FIFO); /* 8.1.2 controller errata; flush posted writes */
2012         }
2013         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2014 }
2015
2016 static irqreturn_t
2017 he_irq_handler(int irq, void *dev_id)
2018 {
2019         unsigned long flags;
2020         struct he_dev *he_dev = (struct he_dev * )dev_id;
2021         int handled = 0;
2022
2023         if (he_dev == NULL)
2024                 return IRQ_NONE;
2025
2026         spin_lock_irqsave(&he_dev->global_lock, flags);
2027
2028         he_dev->irq_tail = (struct he_irq *) (((unsigned long)he_dev->irq_base) |
2029                                                 (*he_dev->irq_tailoffset << 2));
2030
2031         if (he_dev->irq_tail == he_dev->irq_head) {
2032                 HPRINTK("tailoffset not updated?\n");
2033                 he_dev->irq_tail = (struct he_irq *) ((unsigned long)he_dev->irq_base |
2034                         ((he_readl(he_dev, IRQ0_BASE) & IRQ_MASK) << 2));
2035                 (void) he_readl(he_dev, INT_FIFO);      /* 8.1.2 controller errata */
2036         }
2037
2038 #ifdef DEBUG
2039         if (he_dev->irq_head == he_dev->irq_tail /* && !IRQ_PENDING */)
2040                 hprintk("spurious (or shared) interrupt?\n");
2041 #endif
2042
2043         if (he_dev->irq_head != he_dev->irq_tail) {
2044                 handled = 1;
2045                 tasklet_schedule(&he_dev->tasklet);
2046                 he_writel(he_dev, INT_CLEAR_A, INT_FIFO);       /* clear interrupt */
2047                 (void) he_readl(he_dev, INT_FIFO);              /* flush posted writes */
2048         }
2049         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2050         return IRQ_RETVAL(handled);
2051
2052 }
2053
2054 static __inline__ void
2055 __enqueue_tpd(struct he_dev *he_dev, struct he_tpd *tpd, unsigned cid)
2056 {
2057         struct he_tpdrq *new_tail;
2058
2059         HPRINTK("tpdrq %p cid 0x%x -> tpdrq_tail %p\n",
2060                                         tpd, cid, he_dev->tpdrq_tail);
2061
2062         /* new_tail = he_dev->tpdrq_tail; */
2063         new_tail = (struct he_tpdrq *) ((unsigned long) he_dev->tpdrq_base |
2064                                         TPDRQ_MASK(he_dev->tpdrq_tail+1));
2065
2066         /*
2067          * check to see if we are about to set the tail == head
2068          * if true, update the head pointer from the adapter
2069          * to see if this is really the case (reading the queue
2070          * head for every enqueue would be unnecessarily slow)
2071          */
2072
2073         if (new_tail == he_dev->tpdrq_head) {
2074                 he_dev->tpdrq_head = (struct he_tpdrq *)
2075                         (((unsigned long)he_dev->tpdrq_base) |
2076                                 TPDRQ_MASK(he_readl(he_dev, TPDRQ_B_H)));
2077
2078                 if (new_tail == he_dev->tpdrq_head) {
2079                         int slot;
2080
2081                         hprintk("tpdrq full (cid 0x%x)\n", cid);
2082                         /*
2083                          * FIXME
2084                          * push tpd onto a transmit backlog queue
2085                          * after service_tbrq, service the backlog
2086                          * for now, we just drop the pdu
2087                          */
2088                         for (slot = 0; slot < TPD_MAXIOV; ++slot) {
2089                                 if (tpd->iovec[slot].addr)
2090                                         dma_unmap_single(&he_dev->pci_dev->dev,
2091                                                 tpd->iovec[slot].addr,
2092                                                 tpd->iovec[slot].len & TPD_LEN_MASK,
2093                                                                 DMA_TO_DEVICE);
2094                         }
2095                         if (tpd->skb) {
2096                                 if (tpd->vcc->pop)
2097                                         tpd->vcc->pop(tpd->vcc, tpd->skb);
2098                                 else
2099                                         dev_kfree_skb_any(tpd->skb);
2100                                 atomic_inc(&tpd->vcc->stats->tx_err);
2101                         }
2102                         dma_pool_free(he_dev->tpd_pool, tpd, TPD_ADDR(tpd->status));
2103                         return;
2104                 }
2105         }
2106
2107         /* 2.1.5 transmit packet descriptor ready queue */
2108         list_add_tail(&tpd->entry, &he_dev->outstanding_tpds);
2109         he_dev->tpdrq_tail->tpd = TPD_ADDR(tpd->status);
2110         he_dev->tpdrq_tail->cid = cid;
2111         wmb();
2112
2113         he_dev->tpdrq_tail = new_tail;
2114
2115         he_writel(he_dev, TPDRQ_MASK(he_dev->tpdrq_tail), TPDRQ_T);
2116         (void) he_readl(he_dev, TPDRQ_T);               /* flush posted writes */
2117 }
2118
2119 static int
2120 he_open(struct atm_vcc *vcc)
2121 {
2122         unsigned long flags;
2123         struct he_dev *he_dev = HE_DEV(vcc->dev);
2124         struct he_vcc *he_vcc;
2125         int err = 0;
2126         unsigned cid, rsr0, rsr1, rsr4, tsr0, tsr0_aal, tsr4, period, reg, clock;
2127         short vpi = vcc->vpi;
2128         int vci = vcc->vci;
2129
2130         if (vci == ATM_VCI_UNSPEC || vpi == ATM_VPI_UNSPEC)
2131                 return 0;
2132
2133         HPRINTK("open vcc %p %d.%d\n", vcc, vpi, vci);
2134
2135         set_bit(ATM_VF_ADDR, &vcc->flags);
2136
2137         cid = he_mkcid(he_dev, vpi, vci);
2138
2139         he_vcc = kmalloc(sizeof(struct he_vcc), GFP_ATOMIC);
2140         if (he_vcc == NULL) {
2141                 hprintk("unable to allocate he_vcc during open\n");
2142                 return -ENOMEM;
2143         }
2144
2145         INIT_LIST_HEAD(&he_vcc->buffers);
2146         he_vcc->pdu_len = 0;
2147         he_vcc->rc_index = -1;
2148
2149         init_waitqueue_head(&he_vcc->rx_waitq);
2150         init_waitqueue_head(&he_vcc->tx_waitq);
2151
2152         vcc->dev_data = he_vcc;
2153
2154         if (vcc->qos.txtp.traffic_class != ATM_NONE) {
2155                 int pcr_goal;
2156
2157                 pcr_goal = atm_pcr_goal(&vcc->qos.txtp);
2158                 if (pcr_goal == 0)
2159                         pcr_goal = he_dev->atm_dev->link_rate;
2160                 if (pcr_goal < 0)       /* means round down, technically */
2161                         pcr_goal = -pcr_goal;
2162
2163                 HPRINTK("open tx cid 0x%x pcr_goal %d\n", cid, pcr_goal);
2164
2165                 switch (vcc->qos.aal) {
2166                         case ATM_AAL5:
2167                                 tsr0_aal = TSR0_AAL5;
2168                                 tsr4 = TSR4_AAL5;
2169                                 break;
2170                         case ATM_AAL0:
2171                                 tsr0_aal = TSR0_AAL0_SDU;
2172                                 tsr4 = TSR4_AAL0_SDU;
2173                                 break;
2174                         default:
2175                                 err = -EINVAL;
2176                                 goto open_failed;
2177                 }
2178
2179                 spin_lock_irqsave(&he_dev->global_lock, flags);
2180                 tsr0 = he_readl_tsr0(he_dev, cid);
2181                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2182
2183                 if (TSR0_CONN_STATE(tsr0) != 0) {
2184                         hprintk("cid 0x%x not idle (tsr0 = 0x%x)\n", cid, tsr0);
2185                         err = -EBUSY;
2186                         goto open_failed;
2187                 }
2188
2189                 switch (vcc->qos.txtp.traffic_class) {
2190                         case ATM_UBR:
2191                                 /* 2.3.3.1 open connection ubr */
2192
2193                                 tsr0 = TSR0_UBR | TSR0_GROUP(0) | tsr0_aal |
2194                                         TSR0_USE_WMIN | TSR0_UPDATE_GER;
2195                                 break;
2196
2197                         case ATM_CBR:
2198                                 /* 2.3.3.2 open connection cbr */
2199
2200                                 /* 8.2.3 cbr scheduler wrap problem -- limit to 90% total link rate */
2201                                 if ((he_dev->total_bw + pcr_goal)
2202                                         > (he_dev->atm_dev->link_rate * 9 / 10))
2203                                 {
2204                                         err = -EBUSY;
2205                                         goto open_failed;
2206                                 }
2207
2208                                 spin_lock_irqsave(&he_dev->global_lock, flags);                 /* also protects he_dev->cs_stper[] */
2209
2210                                 /* find an unused cs_stper register */
2211                                 for (reg = 0; reg < HE_NUM_CS_STPER; ++reg)
2212                                         if (he_dev->cs_stper[reg].inuse == 0 || 
2213                                             he_dev->cs_stper[reg].pcr == pcr_goal)
2214                                                         break;
2215
2216                                 if (reg == HE_NUM_CS_STPER) {
2217                                         err = -EBUSY;
2218                                         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2219                                         goto open_failed;
2220                                 }
2221
2222                                 he_dev->total_bw += pcr_goal;
2223
2224                                 he_vcc->rc_index = reg;
2225                                 ++he_dev->cs_stper[reg].inuse;
2226                                 he_dev->cs_stper[reg].pcr = pcr_goal;
2227
2228                                 clock = he_is622(he_dev) ? 66667000 : 50000000;
2229                                 period = clock / pcr_goal;
2230                                 
2231                                 HPRINTK("rc_index = %d period = %d\n",
2232                                                                 reg, period);
2233
2234                                 he_writel_mbox(he_dev, rate_to_atmf(period/2),
2235                                                         CS_STPER0 + reg);
2236                                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2237
2238                                 tsr0 = TSR0_CBR | TSR0_GROUP(0) | tsr0_aal |
2239                                                         TSR0_RC_INDEX(reg);
2240
2241                                 break;
2242                         default:
2243                                 err = -EINVAL;
2244                                 goto open_failed;
2245                 }
2246
2247                 spin_lock_irqsave(&he_dev->global_lock, flags);
2248
2249                 he_writel_tsr0(he_dev, tsr0, cid);
2250                 he_writel_tsr4(he_dev, tsr4 | 1, cid);
2251                 he_writel_tsr1(he_dev, TSR1_MCR(rate_to_atmf(0)) |
2252                                         TSR1_PCR(rate_to_atmf(pcr_goal)), cid);
2253                 he_writel_tsr2(he_dev, TSR2_ACR(rate_to_atmf(pcr_goal)), cid);
2254                 he_writel_tsr9(he_dev, TSR9_OPEN_CONN, cid);
2255
2256                 he_writel_tsr3(he_dev, 0x0, cid);
2257                 he_writel_tsr5(he_dev, 0x0, cid);
2258                 he_writel_tsr6(he_dev, 0x0, cid);
2259                 he_writel_tsr7(he_dev, 0x0, cid);
2260                 he_writel_tsr8(he_dev, 0x0, cid);
2261                 he_writel_tsr10(he_dev, 0x0, cid);
2262                 he_writel_tsr11(he_dev, 0x0, cid);
2263                 he_writel_tsr12(he_dev, 0x0, cid);
2264                 he_writel_tsr13(he_dev, 0x0, cid);
2265                 he_writel_tsr14(he_dev, 0x0, cid);
2266                 (void) he_readl_tsr0(he_dev, cid);              /* flush posted writes */
2267                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2268         }
2269
2270         if (vcc->qos.rxtp.traffic_class != ATM_NONE) {
2271                 unsigned aal;
2272
2273                 HPRINTK("open rx cid 0x%x (rx_waitq %p)\n", cid,
2274                                                 &HE_VCC(vcc)->rx_waitq);
2275
2276                 switch (vcc->qos.aal) {
2277                         case ATM_AAL5:
2278                                 aal = RSR0_AAL5;
2279                                 break;
2280                         case ATM_AAL0:
2281                                 aal = RSR0_RAWCELL;
2282                                 break;
2283                         default:
2284                                 err = -EINVAL;
2285                                 goto open_failed;
2286                 }
2287
2288                 spin_lock_irqsave(&he_dev->global_lock, flags);
2289
2290                 rsr0 = he_readl_rsr0(he_dev, cid);
2291                 if (rsr0 & RSR0_OPEN_CONN) {
2292                         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2293
2294                         hprintk("cid 0x%x not idle (rsr0 = 0x%x)\n", cid, rsr0);
2295                         err = -EBUSY;
2296                         goto open_failed;
2297                 }
2298
2299                 rsr1 = RSR1_GROUP(0) | RSR1_RBPL_ONLY;
2300                 rsr4 = RSR4_GROUP(0) | RSR4_RBPL_ONLY;
2301                 rsr0 = vcc->qos.rxtp.traffic_class == ATM_UBR ? 
2302                                 (RSR0_EPD_ENABLE|RSR0_PPD_ENABLE) : 0;
2303
2304 #ifdef USE_CHECKSUM_HW
2305                 if (vpi == 0 && vci >= ATM_NOT_RSV_VCI)
2306                         rsr0 |= RSR0_TCP_CKSUM;
2307 #endif
2308
2309                 he_writel_rsr4(he_dev, rsr4, cid);
2310                 he_writel_rsr1(he_dev, rsr1, cid);
2311                 /* 5.1.11 last parameter initialized should be
2312                           the open/closed indication in rsr0 */
2313                 he_writel_rsr0(he_dev,
2314                         rsr0 | RSR0_START_PDU | RSR0_OPEN_CONN | aal, cid);
2315                 (void) he_readl_rsr0(he_dev, cid);              /* flush posted writes */
2316
2317                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2318         }
2319
2320 open_failed:
2321
2322         if (err) {
2323                 kfree(he_vcc);
2324                 clear_bit(ATM_VF_ADDR, &vcc->flags);
2325         }
2326         else
2327                 set_bit(ATM_VF_READY, &vcc->flags);
2328
2329         return err;
2330 }
2331
2332 static void
2333 he_close(struct atm_vcc *vcc)
2334 {
2335         unsigned long flags;
2336         DECLARE_WAITQUEUE(wait, current);
2337         struct he_dev *he_dev = HE_DEV(vcc->dev);
2338         struct he_tpd *tpd;
2339         unsigned cid;
2340         struct he_vcc *he_vcc = HE_VCC(vcc);
2341 #define MAX_RETRY 30
2342         int retry = 0, sleep = 1, tx_inuse;
2343
2344         HPRINTK("close vcc %p %d.%d\n", vcc, vcc->vpi, vcc->vci);
2345
2346         clear_bit(ATM_VF_READY, &vcc->flags);
2347         cid = he_mkcid(he_dev, vcc->vpi, vcc->vci);
2348
2349         if (vcc->qos.rxtp.traffic_class != ATM_NONE) {
2350                 int timeout;
2351
2352                 HPRINTK("close rx cid 0x%x\n", cid);
2353
2354                 /* 2.7.2.2 close receive operation */
2355
2356                 /* wait for previous close (if any) to finish */
2357
2358                 spin_lock_irqsave(&he_dev->global_lock, flags);
2359                 while (he_readl(he_dev, RCC_STAT) & RCC_BUSY) {
2360                         HPRINTK("close cid 0x%x RCC_BUSY\n", cid);
2361                         udelay(250);
2362                 }
2363
2364                 set_current_state(TASK_UNINTERRUPTIBLE);
2365                 add_wait_queue(&he_vcc->rx_waitq, &wait);
2366
2367                 he_writel_rsr0(he_dev, RSR0_CLOSE_CONN, cid);
2368                 (void) he_readl_rsr0(he_dev, cid);              /* flush posted writes */
2369                 he_writel_mbox(he_dev, cid, RXCON_CLOSE);
2370                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2371
2372                 timeout = schedule_timeout(30*HZ);
2373
2374                 remove_wait_queue(&he_vcc->rx_waitq, &wait);
2375                 set_current_state(TASK_RUNNING);
2376
2377                 if (timeout == 0)
2378                         hprintk("close rx timeout cid 0x%x\n", cid);
2379
2380                 HPRINTK("close rx cid 0x%x complete\n", cid);
2381
2382         }
2383
2384         if (vcc->qos.txtp.traffic_class != ATM_NONE) {
2385                 volatile unsigned tsr4, tsr0;
2386                 int timeout;
2387
2388                 HPRINTK("close tx cid 0x%x\n", cid);
2389                 
2390                 /* 2.1.2
2391                  *
2392                  * ... the host must first stop queueing packets to the TPDRQ
2393                  * on the connection to be closed, then wait for all outstanding
2394                  * packets to be transmitted and their buffers returned to the
2395                  * TBRQ. When the last packet on the connection arrives in the
2396                  * TBRQ, the host issues the close command to the adapter.
2397                  */
2398
2399                 while (((tx_inuse = atomic_read(&sk_atm(vcc)->sk_wmem_alloc)) > 1) &&
2400                        (retry < MAX_RETRY)) {
2401                         msleep(sleep);
2402                         if (sleep < 250)
2403                                 sleep = sleep * 2;
2404
2405                         ++retry;
2406                 }
2407
2408                 if (tx_inuse > 1)
2409                         hprintk("close tx cid 0x%x tx_inuse = %d\n", cid, tx_inuse);
2410
2411                 /* 2.3.1.1 generic close operations with flush */
2412
2413                 spin_lock_irqsave(&he_dev->global_lock, flags);
2414                 he_writel_tsr4_upper(he_dev, TSR4_FLUSH_CONN, cid);
2415                                         /* also clears TSR4_SESSION_ENDED */
2416
2417                 switch (vcc->qos.txtp.traffic_class) {
2418                         case ATM_UBR:
2419                                 he_writel_tsr1(he_dev, 
2420                                         TSR1_MCR(rate_to_atmf(200000))
2421                                         | TSR1_PCR(0), cid);
2422                                 break;
2423                         case ATM_CBR:
2424                                 he_writel_tsr14_upper(he_dev, TSR14_DELETE, cid);
2425                                 break;
2426                 }
2427                 (void) he_readl_tsr4(he_dev, cid);              /* flush posted writes */
2428
2429                 tpd = __alloc_tpd(he_dev);
2430                 if (tpd == NULL) {
2431                         hprintk("close tx he_alloc_tpd failed cid 0x%x\n", cid);
2432                         goto close_tx_incomplete;
2433                 }
2434                 tpd->status |= TPD_EOS | TPD_INT;
2435                 tpd->skb = NULL;
2436                 tpd->vcc = vcc;
2437                 wmb();
2438
2439                 set_current_state(TASK_UNINTERRUPTIBLE);
2440                 add_wait_queue(&he_vcc->tx_waitq, &wait);
2441                 __enqueue_tpd(he_dev, tpd, cid);
2442                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2443
2444                 timeout = schedule_timeout(30*HZ);
2445
2446                 remove_wait_queue(&he_vcc->tx_waitq, &wait);
2447                 set_current_state(TASK_RUNNING);
2448
2449                 spin_lock_irqsave(&he_dev->global_lock, flags);
2450
2451                 if (timeout == 0) {
2452                         hprintk("close tx timeout cid 0x%x\n", cid);
2453                         goto close_tx_incomplete;
2454                 }
2455
2456                 while (!((tsr4 = he_readl_tsr4(he_dev, cid)) & TSR4_SESSION_ENDED)) {
2457                         HPRINTK("close tx cid 0x%x !TSR4_SESSION_ENDED (tsr4 = 0x%x)\n", cid, tsr4);
2458                         udelay(250);
2459                 }
2460
2461                 while (TSR0_CONN_STATE(tsr0 = he_readl_tsr0(he_dev, cid)) != 0) {
2462                         HPRINTK("close tx cid 0x%x TSR0_CONN_STATE != 0 (tsr0 = 0x%x)\n", cid, tsr0);
2463                         udelay(250);
2464                 }
2465
2466 close_tx_incomplete:
2467
2468                 if (vcc->qos.txtp.traffic_class == ATM_CBR) {
2469                         int reg = he_vcc->rc_index;
2470
2471                         HPRINTK("cs_stper reg = %d\n", reg);
2472
2473                         if (he_dev->cs_stper[reg].inuse == 0)
2474                                 hprintk("cs_stper[%d].inuse = 0!\n", reg);
2475                         else
2476                                 --he_dev->cs_stper[reg].inuse;
2477
2478                         he_dev->total_bw -= he_dev->cs_stper[reg].pcr;
2479                 }
2480                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2481
2482                 HPRINTK("close tx cid 0x%x complete\n", cid);
2483         }
2484
2485         kfree(he_vcc);
2486
2487         clear_bit(ATM_VF_ADDR, &vcc->flags);
2488 }
2489
2490 static int
2491 he_send(struct atm_vcc *vcc, struct sk_buff *skb)
2492 {
2493         unsigned long flags;
2494         struct he_dev *he_dev = HE_DEV(vcc->dev);
2495         unsigned cid = he_mkcid(he_dev, vcc->vpi, vcc->vci);
2496         struct he_tpd *tpd;
2497 #ifdef USE_SCATTERGATHER
2498         int i, slot = 0;
2499 #endif
2500
2501 #define HE_TPD_BUFSIZE 0xffff
2502
2503         HPRINTK("send %d.%d\n", vcc->vpi, vcc->vci);
2504
2505         if ((skb->len > HE_TPD_BUFSIZE) ||
2506             ((vcc->qos.aal == ATM_AAL0) && (skb->len != ATM_AAL0_SDU))) {
2507                 hprintk("buffer too large (or small) -- %d bytes\n", skb->len );
2508                 if (vcc->pop)
2509                         vcc->pop(vcc, skb);
2510                 else
2511                         dev_kfree_skb_any(skb);
2512                 atomic_inc(&vcc->stats->tx_err);
2513                 return -EINVAL;
2514         }
2515
2516 #ifndef USE_SCATTERGATHER
2517         if (skb_shinfo(skb)->nr_frags) {
2518                 hprintk("no scatter/gather support\n");
2519                 if (vcc->pop)
2520                         vcc->pop(vcc, skb);
2521                 else
2522                         dev_kfree_skb_any(skb);
2523                 atomic_inc(&vcc->stats->tx_err);
2524                 return -EINVAL;
2525         }
2526 #endif
2527         spin_lock_irqsave(&he_dev->global_lock, flags);
2528
2529         tpd = __alloc_tpd(he_dev);
2530         if (tpd == NULL) {
2531                 if (vcc->pop)
2532                         vcc->pop(vcc, skb);
2533                 else
2534                         dev_kfree_skb_any(skb);
2535                 atomic_inc(&vcc->stats->tx_err);
2536                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2537                 return -ENOMEM;
2538         }
2539
2540         if (vcc->qos.aal == ATM_AAL5)
2541                 tpd->status |= TPD_CELLTYPE(TPD_USERCELL);
2542         else {
2543                 char *pti_clp = (void *) (skb->data + 3);
2544                 int clp, pti;
2545
2546                 pti = (*pti_clp & ATM_HDR_PTI_MASK) >> ATM_HDR_PTI_SHIFT; 
2547                 clp = (*pti_clp & ATM_HDR_CLP);
2548                 tpd->status |= TPD_CELLTYPE(pti);
2549                 if (clp)
2550                         tpd->status |= TPD_CLP;
2551
2552                 skb_pull(skb, ATM_AAL0_SDU - ATM_CELL_PAYLOAD);
2553         }
2554
2555 #ifdef USE_SCATTERGATHER
2556         tpd->iovec[slot].addr = dma_map_single(&he_dev->pci_dev->dev, skb->data,
2557                                 skb_headlen(skb), DMA_TO_DEVICE);
2558         tpd->iovec[slot].len = skb_headlen(skb);
2559         ++slot;
2560
2561         for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) {
2562                 skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
2563
2564                 if (slot == TPD_MAXIOV) {       /* queue tpd; start new tpd */
2565                         tpd->vcc = vcc;
2566                         tpd->skb = NULL;        /* not the last fragment
2567                                                    so dont ->push() yet */
2568                         wmb();
2569
2570                         __enqueue_tpd(he_dev, tpd, cid);
2571                         tpd = __alloc_tpd(he_dev);
2572                         if (tpd == NULL) {
2573                                 if (vcc->pop)
2574                                         vcc->pop(vcc, skb);
2575                                 else
2576                                         dev_kfree_skb_any(skb);
2577                                 atomic_inc(&vcc->stats->tx_err);
2578                                 spin_unlock_irqrestore(&he_dev->global_lock, flags);
2579                                 return -ENOMEM;
2580                         }
2581                         tpd->status |= TPD_USERCELL;
2582                         slot = 0;
2583                 }
2584
2585                 tpd->iovec[slot].addr = dma_map_single(&he_dev->pci_dev->dev,
2586                         (void *) page_address(frag->page) + frag->page_offset,
2587                                 frag->size, DMA_TO_DEVICE);
2588                 tpd->iovec[slot].len = frag->size;
2589                 ++slot;
2590
2591         }
2592
2593         tpd->iovec[slot - 1].len |= TPD_LST;
2594 #else
2595         tpd->address0 = dma_map_single(&he_dev->pci_dev->dev, skb->data, skb->len, DMA_TO_DEVICE);
2596         tpd->length0 = skb->len | TPD_LST;
2597 #endif
2598         tpd->status |= TPD_INT;
2599
2600         tpd->vcc = vcc;
2601         tpd->skb = skb;
2602         wmb();
2603         ATM_SKB(skb)->vcc = vcc;
2604
2605         __enqueue_tpd(he_dev, tpd, cid);
2606         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2607
2608         atomic_inc(&vcc->stats->tx);
2609
2610         return 0;
2611 }
2612
2613 static int
2614 he_ioctl(struct atm_dev *atm_dev, unsigned int cmd, void __user *arg)
2615 {
2616         unsigned long flags;
2617         struct he_dev *he_dev = HE_DEV(atm_dev);
2618         struct he_ioctl_reg reg;
2619         int err = 0;
2620
2621         switch (cmd) {
2622                 case HE_GET_REG:
2623                         if (!capable(CAP_NET_ADMIN))
2624                                 return -EPERM;
2625
2626                         if (copy_from_user(&reg, arg,
2627                                            sizeof(struct he_ioctl_reg)))
2628                                 return -EFAULT;
2629
2630                         spin_lock_irqsave(&he_dev->global_lock, flags);
2631                         switch (reg.type) {
2632                                 case HE_REGTYPE_PCI:
2633                                         if (reg.addr >= HE_REGMAP_SIZE) {
2634                                                 err = -EINVAL;
2635                                                 break;
2636                                         }
2637
2638                                         reg.val = he_readl(he_dev, reg.addr);
2639                                         break;
2640                                 case HE_REGTYPE_RCM:
2641                                         reg.val =
2642                                                 he_readl_rcm(he_dev, reg.addr);
2643                                         break;
2644                                 case HE_REGTYPE_TCM:
2645                                         reg.val =
2646                                                 he_readl_tcm(he_dev, reg.addr);
2647                                         break;
2648                                 case HE_REGTYPE_MBOX:
2649                                         reg.val =
2650                                                 he_readl_mbox(he_dev, reg.addr);
2651                                         break;
2652                                 default:
2653                                         err = -EINVAL;
2654                                         break;
2655                         }
2656                         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2657                         if (err == 0)
2658                                 if (copy_to_user(arg, &reg,
2659                                                         sizeof(struct he_ioctl_reg)))
2660                                         return -EFAULT;
2661                         break;
2662                 default:
2663 #ifdef CONFIG_ATM_HE_USE_SUNI
2664                         if (atm_dev->phy && atm_dev->phy->ioctl)
2665                                 err = atm_dev->phy->ioctl(atm_dev, cmd, arg);
2666 #else /* CONFIG_ATM_HE_USE_SUNI */
2667                         err = -EINVAL;
2668 #endif /* CONFIG_ATM_HE_USE_SUNI */
2669                         break;
2670         }
2671
2672         return err;
2673 }
2674
2675 static void
2676 he_phy_put(struct atm_dev *atm_dev, unsigned char val, unsigned long addr)
2677 {
2678         unsigned long flags;
2679         struct he_dev *he_dev = HE_DEV(atm_dev);
2680
2681         HPRINTK("phy_put(val 0x%x, addr 0x%lx)\n", val, addr);
2682
2683         spin_lock_irqsave(&he_dev->global_lock, flags);
2684         he_writel(he_dev, val, FRAMER + (addr*4));
2685         (void) he_readl(he_dev, FRAMER + (addr*4));             /* flush posted writes */
2686         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2687 }
2688  
2689         
2690 static unsigned char
2691 he_phy_get(struct atm_dev *atm_dev, unsigned long addr)
2692
2693         unsigned long flags;
2694         struct he_dev *he_dev = HE_DEV(atm_dev);
2695         unsigned reg;
2696
2697         spin_lock_irqsave(&he_dev->global_lock, flags);
2698         reg = he_readl(he_dev, FRAMER + (addr*4));
2699         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2700
2701         HPRINTK("phy_get(addr 0x%lx) =0x%x\n", addr, reg);
2702         return reg;
2703 }
2704
2705 static int
2706 he_proc_read(struct atm_dev *dev, loff_t *pos, char *page)
2707 {
2708         unsigned long flags;
2709         struct he_dev *he_dev = HE_DEV(dev);
2710         int left, i;
2711 #ifdef notdef
2712         struct he_rbrq *rbrq_tail;
2713         struct he_tpdrq *tpdrq_head;
2714         int rbpl_head, rbpl_tail;
2715 #endif
2716         static long mcc = 0, oec = 0, dcc = 0, cec = 0;
2717
2718
2719         left = *pos;
2720         if (!left--)
2721                 return sprintf(page, "ATM he driver\n");
2722
2723         if (!left--)
2724                 return sprintf(page, "%s%s\n\n",
2725                         he_dev->prod_id, he_dev->media & 0x40 ? "SM" : "MM");
2726
2727         if (!left--)
2728                 return sprintf(page, "Mismatched Cells  VPI/VCI Not Open  Dropped Cells  RCM Dropped Cells\n");
2729
2730         spin_lock_irqsave(&he_dev->global_lock, flags);
2731         mcc += he_readl(he_dev, MCC);
2732         oec += he_readl(he_dev, OEC);
2733         dcc += he_readl(he_dev, DCC);
2734         cec += he_readl(he_dev, CEC);
2735         spin_unlock_irqrestore(&he_dev->global_lock, flags);
2736
2737         if (!left--)
2738                 return sprintf(page, "%16ld  %16ld  %13ld  %17ld\n\n", 
2739                                                         mcc, oec, dcc, cec);
2740
2741         if (!left--)
2742                 return sprintf(page, "irq_size = %d  inuse = ?  peak = %d\n",
2743                                 CONFIG_IRQ_SIZE, he_dev->irq_peak);
2744
2745         if (!left--)
2746                 return sprintf(page, "tpdrq_size = %d  inuse = ?\n",
2747                                                 CONFIG_TPDRQ_SIZE);
2748
2749         if (!left--)
2750                 return sprintf(page, "rbrq_size = %d  inuse = ?  peak = %d\n",
2751                                 CONFIG_RBRQ_SIZE, he_dev->rbrq_peak);
2752
2753         if (!left--)
2754                 return sprintf(page, "tbrq_size = %d  peak = %d\n",
2755                                         CONFIG_TBRQ_SIZE, he_dev->tbrq_peak);
2756
2757
2758 #ifdef notdef
2759         rbpl_head = RBPL_MASK(he_readl(he_dev, G0_RBPL_S));
2760         rbpl_tail = RBPL_MASK(he_readl(he_dev, G0_RBPL_T));
2761
2762         inuse = rbpl_head - rbpl_tail;
2763         if (inuse < 0)
2764                 inuse += CONFIG_RBPL_SIZE * sizeof(struct he_rbp);
2765         inuse /= sizeof(struct he_rbp);
2766
2767         if (!left--)
2768                 return sprintf(page, "rbpl_size = %d  inuse = %d\n\n",
2769                                                 CONFIG_RBPL_SIZE, inuse);
2770 #endif
2771
2772         if (!left--)
2773                 return sprintf(page, "rate controller periods (cbr)\n                 pcr  #vc\n");
2774
2775         for (i = 0; i < HE_NUM_CS_STPER; ++i)
2776                 if (!left--)
2777                         return sprintf(page, "cs_stper%-2d  %8ld  %3d\n", i,
2778                                                 he_dev->cs_stper[i].pcr,
2779                                                 he_dev->cs_stper[i].inuse);
2780
2781         if (!left--)
2782                 return sprintf(page, "total bw (cbr): %d  (limit %d)\n",
2783                         he_dev->total_bw, he_dev->atm_dev->link_rate * 10 / 9);
2784
2785         return 0;
2786 }
2787
2788 /* eeprom routines  -- see 4.7 */
2789
2790 static u8 read_prom_byte(struct he_dev *he_dev, int addr)
2791 {
2792         u32 val = 0, tmp_read = 0;
2793         int i, j = 0;
2794         u8 byte_read = 0;
2795
2796         val = readl(he_dev->membase + HOST_CNTL);
2797         val &= 0xFFFFE0FF;
2798        
2799         /* Turn on write enable */
2800         val |= 0x800;
2801         he_writel(he_dev, val, HOST_CNTL);
2802        
2803         /* Send READ instruction */
2804         for (i = 0; i < ARRAY_SIZE(readtab); i++) {
2805                 he_writel(he_dev, val | readtab[i], HOST_CNTL);
2806                 udelay(EEPROM_DELAY);
2807         }
2808        
2809         /* Next, we need to send the byte address to read from */
2810         for (i = 7; i >= 0; i--) {
2811                 he_writel(he_dev, val | clocktab[j++] | (((addr >> i) & 1) << 9), HOST_CNTL);
2812                 udelay(EEPROM_DELAY);
2813                 he_writel(he_dev, val | clocktab[j++] | (((addr >> i) & 1) << 9), HOST_CNTL);
2814                 udelay(EEPROM_DELAY);
2815         }
2816        
2817         j = 0;
2818
2819         val &= 0xFFFFF7FF;      /* Turn off write enable */
2820         he_writel(he_dev, val, HOST_CNTL);
2821        
2822         /* Now, we can read data from the EEPROM by clocking it in */
2823         for (i = 7; i >= 0; i--) {
2824                 he_writel(he_dev, val | clocktab[j++], HOST_CNTL);
2825                 udelay(EEPROM_DELAY);
2826                 tmp_read = he_readl(he_dev, HOST_CNTL);
2827                 byte_read |= (unsigned char)
2828                            ((tmp_read & ID_DOUT) >> ID_DOFFSET << i);
2829                 he_writel(he_dev, val | clocktab[j++], HOST_CNTL);
2830                 udelay(EEPROM_DELAY);
2831         }
2832        
2833         he_writel(he_dev, val | ID_CS, HOST_CNTL);
2834         udelay(EEPROM_DELAY);
2835
2836         return byte_read;
2837 }
2838
2839 MODULE_LICENSE("GPL");
2840 MODULE_AUTHOR("chas williams <chas@cmf.nrl.navy.mil>");
2841 MODULE_DESCRIPTION("ForeRunnerHE ATM Adapter driver");
2842 module_param(disable64, bool, 0);
2843 MODULE_PARM_DESC(disable64, "disable 64-bit pci bus transfers");
2844 module_param(nvpibits, short, 0);
2845 MODULE_PARM_DESC(nvpibits, "numbers of bits for vpi (default 0)");
2846 module_param(nvcibits, short, 0);
2847 MODULE_PARM_DESC(nvcibits, "numbers of bits for vci (default 12)");
2848 module_param(rx_skb_reserve, short, 0);
2849 MODULE_PARM_DESC(rx_skb_reserve, "padding for receive skb (default 16)");
2850 module_param(irq_coalesce, bool, 0);
2851 MODULE_PARM_DESC(irq_coalesce, "use interrupt coalescing (default 1)");
2852 module_param(sdh, bool, 0);
2853 MODULE_PARM_DESC(sdh, "use SDH framing (default 0)");
2854
2855 static struct pci_device_id he_pci_tbl[] = {
2856         { PCI_VDEVICE(FORE, PCI_DEVICE_ID_FORE_HE), 0 },
2857         { 0, }
2858 };
2859
2860 MODULE_DEVICE_TABLE(pci, he_pci_tbl);
2861
2862 static struct pci_driver he_driver = {
2863         .name =         "he",
2864         .probe =        he_init_one,
2865         .remove =       he_remove_one,
2866         .id_table =     he_pci_tbl,
2867 };
2868
2869 module_pci_driver(he_driver);
Linux kernel for KaRo TX COM modules