| blob | c73385cc4b8a4f907161eca5258294bea2a9b159 |
1 /*
2 * Setup routines for AGP 3.5 compliant bridges.
3 */
5 #include <linux/list.h>
6 #include <linux/pci.h>
7 #include <linux/agp_backend.h>
8 #include <linux/module.h>
9 #include <linux/slab.h>
13 /* Generic AGP 3.5 enabling routines */
17 u8 capndx;
18 u32 maxbw;
20 };
23 {
31 }
33 }
36 {
40 u32 nistat;
54 }
55 }
57 /*
58 * Initialize all isochronous transfer parameters for an AGP 3.0
59 * node (i.e. a host bridge in combination with the adapters
60 * lying behind it...)
61 */
65 {
66 /*
67 * Convenience structure to make the calculations clearer
68 * here. The field names come straight from the AGP 3.0 spec.
69 */
71 u32 maxbw;
72 u32 n;
73 u32 y;
74 u32 l;
75 u32 rq;
77 };
86 u8 mcapndx;
91 /*
92 * We'll work with an array of isoch_data's (one for each
93 * device in dev_list) throughout this function.
94 */
98 }
100 /*
101 * Sort the device list by maxbw. We need to do this because the
102 * spec suggests that the devices with the smallest requirements
103 * have their resources allocated first, with all remaining resources
104 * falling to the device with the largest requirement.
105 *
106 * We don't exactly do this, we divide target resources by ndevs
107 * and split them amongst the AGP 3.0 devices. The remainder of such
108 * division operations are dropped on the last device, sort of like
109 * the spec mentions it should be done.
110 *
111 * We can't do this sort when we initially construct the dev_list
112 * because we don't know until this function whether isochronous
113 * transfers are enabled and consequently whether maxbw will mean
114 * anything.
115 */
121 /* Extract power-on defaults from the target */
130 /*
131 * Extract power-on defaults for each device in dev_list. Along
132 * the way, calculate the total isochronous bandwidth required
133 * by these devices and the largest requested payload size.
134 */
151 cdev++;
152 }
154 /* Check if this configuration has any chance of working */
157 "by AGP 3.0 devices exceeds that which is supported by "
161 }
165 /*
166 * Write the calculated payload size into the target's NICMD
167 * register. Doing this directly effects the ISOCH_N value
168 * in the target's NISTAT register, so we need to do this now
169 * to get an accurate value for ISOCH_N later.
170 */
176 /* Reread the target's ISOCH_N */
180 /* Calculate the minimum ISOCH_N needed by each master */
186 }
188 /* Exit if the minimal ISOCH_N allocation among the masters is more
189 * than the target can handle. */
192 "transactions per period required by AGP 3.0 devices "
193 "exceeds that which is supported by the AGP 3.0 "
197 }
199 /* Calculate left over ISOCH_N capability in the target. We'll give
200 * this to the hungriest device (as per the spec) */
203 /*
204 * Calculate the minimum isochronous RQ depth needed by each master.
205 * Along the way, distribute the extra ISOCH_N capability calculated
206 * above.
207 */
209 /*
210 * This is a little subtle. If ISOCH_Y > 64B, then ISOCH_Y
211 * byte isochronous writes will be broken into 64B pieces.
212 * This means we need to budget more RQ depth to account for
213 * these kind of writes (each isochronous write is actually
214 * many writes on the AGP bus).
215 */
221 }
224 /* Figure the number of isochronous and asynchronous RQ slots the
225 * target is providing. */
229 /* Exit if the minimal RQ needs of the masters exceeds what the target
230 * can provide. */
233 "required by the isochronous bandwidth requested by "
234 "AGP 3.0 devices exceeds the number provided by the "
238 }
240 /* Calculate asynchronous RQ capability in the target (per master) as
241 * well as the total number of leftover isochronous RQ slots. */
246 /* Distribute the extra RQ slots calculated above and write our
247 * isochronous settings out to the actual devices. */
270 }
272 free_and_exit:
275 get_out:
277 }
279 /*
280 * This function basically allocates request queue slots among the
281 * AGP 3.0 systems in nonisochronous nodes. The algorithm is
282 * pretty stupid, divide the total number of RQ slots provided by the
283 * target by ndevs. Distribute this many slots to each AGP 3.0 device,
284 * giving any left over slots to the last device in dev_list.
285 */
288 {
309 }
310 }
312 /*
313 * Fully configure and enable an AGP 3.0 host bridge and all the devices
314 * lying behind it.
315 */
317 {
319 u8 mcapndx;
322 u32 mmajor;
323 u16 mpstat;
329 /* Extract some power-on defaults from the target */
337 /*
338 * Allocate a head for our AGP 3.5 device list
339 * (multiple AGP v3 devices are allowed behind a single bridge).
340 */
344 }
348 /* Find all AGP devices, and add them to dev_list. */
356 /* Skip bridges. We should call this function for each one. */
360 /* Don't know what this is, but log it for investigation. */
365 }
373 }
378 ndevs++;
383 }
384 }
386 /*
387 * Take an initial pass through the devices lying behind our host
388 * bridge. Make sure each one is actually an AGP 3.0 device, otherwise
389 * exit with an error message. Along the way store the AGP 3.0
390 * cap_ptr for each device
391 */
406 }
408 }
416 }
421 "secondary bus of AGP 3.5 bridge operating "
425 }
433 "operating in AGP 3.x mode on secondary bus "
434 "of AGP 3.5 bridge operating with AGP 3.0 "
438 }
439 }
441 /*
442 * Call functions to divide target resources amongst the AGP 3.0
443 * masters. This process is dramatically different depending on
444 * whether isochronous transfers are supported.
445 */
450 "up isochronous xfers; falling back to "
454 }
455 }
458 free_and_exit:
459 /* Be sure to free the dev_list */
465 }
468 get_out:
470 }