| blob | f5f75844954cf829641774ec940307fd8e71b635 |
1 /*
2 * Macintosh Nubus Interface Code
3 *
4 * Originally by Alan Cox
5 *
6 * Mostly rewritten by David Huggins-Daines, C. Scott Ananian,
7 * and others.
8 */
10 #include <linux/types.h>
11 #include <linux/kernel.h>
12 #include <linux/string.h>
13 #include <linux/nubus.h>
14 #include <linux/errno.h>
15 #include <linux/init.h>
16 #include <linux/delay.h>
17 #include <linux/module.h>
18 #include <asm/setup.h>
19 #include <asm/system.h>
20 #include <asm/page.h>
21 #include <asm/hwtest.h>
22 #include <linux/proc_fs.h>
23 #include <asm/mac_via.h>
24 #include <asm/mac_oss.h>
29 /* Constants */
31 /* This is, of course, the size in bytelanes, rather than the size in
32 actual bytes */
33 #define FORMAT_BLOCK_SIZE 20
34 #define ROM_DIR_OFFSET 0x24
36 #define NUBUS_TEST_PATTERN 0x5A932BC7
38 /* Define this if you like to live dangerously - it is known not to
39 work on pretty much every machine except the Quadra 630 and the LC
40 III. */
41 #undef I_WANT_TO_PROBE_SLOT_ZERO
43 /* This sometimes helps combat failure to boot */
44 #undef TRY_TO_DODGE_WSOD
46 /* Globals */
51 /* Meaning of "bytelanes":
53 The card ROM may appear on any or all bytes of each long word in
54 NuBus memory. The low 4 bits of the "map" value found in the
55 format block (at the top of the slot address space, as well as at
56 the top of the MacOS ROM) tells us which bytelanes, i.e. which byte
57 offsets within each longword, are valid. Thus:
59 A map of 0x0f, as found in the MacOS ROM, means that all bytelanes
60 are valid.
62 A map of 0xf0 means that no bytelanes are valid (We pray that we
63 will never encounter this, but stranger things have happened)
65 A map of 0xe1 means that only the MSB of each long word is actually
66 part of the card ROM. (We hope to never encounter NuBus on a
67 little-endian machine. Again, stranger things have happened)
69 A map of 0x78 means that only the LSB of each long word is valid.
71 Etcetera, etcetera. Hopefully this clears up some confusion over
72 what the following code actually does. */
75 {
81 }
84 {
85 /* This will hold the result */
90 {
93 p++;
95 len--;
96 }
99 }
102 {
105 /* Sanity check */
109 {
110 do
111 {
112 p--;
113 }
115 len--;
116 }
118 }
121 {
126 {
128 p++;
129 p++;
130 len--;
131 }
133 }
136 {
141 }
143 /* Now, functions to read the sResource tree */
145 /* Each sResource entry consists of a 1-byte ID and a 3-byte data
146 field. If that data field contains an offset, then obviously we
147 have to expand it from a 24-bit signed number to a 32-bit signed
148 number. */
151 {
155 }
158 {
159 /*
160 * Returns the first byte after the card. We then walk
161 * backwards to get the lane register and the config
162 */
164 }
167 {
169 /* Essentially, just step over the bytelanes using whatever
170 offset we might have found */
172 /* And return the value */
174 }
176 /* These two are for pulling resource data blocks (i.e. stuff that's
177 pointed to with offsets) out of the card ROM. */
181 {
185 {
187 len--;
188 }
189 }
194 {
198 {
202 len--;
203 }
204 }
209 {
214 }
217 /* This is a slyly renamed version of the above */
220 {
225 }
230 {
237 /* Now dereference it (the first directory is always the board
238 directory) */
244 }
249 {
254 }
258 {
259 u32 resid;
263 /* Do this first, otherwise nubus_rewind & co are off by 4 */
266 /* This moves nd->ptr forward */
269 /* EOL marker, as per the Apple docs */
271 {
272 /* Mark it as done */
275 }
277 /* First byte is the resource ID */
279 /* Low 3 bytes might contain data (or might not) */
283 }
287 {
290 }
293 /* Driver interface functions, more or less like in pci.c */
301 {
312 }
314 }
321 {
330 }
332 }
338 {
346 }
348 }
351 int
354 {
358 }
360 }
363 /* Initialization functions - decide which slots contain stuff worth
364 looking at, and print out lots and lots of information from the
365 resource blocks. */
367 /* FIXME: A lot of this stuff will eventually be useful after
368 initialization, for intelligently probing Ethernet and video chips,
369 among other things. The rest of it should go in the /proc code.
370 For now, we just use it to give verbose boot logs. */
374 {
386 }
388 }
392 {
395 {
406 }
410 }
412 }
416 {
419 {
425 }
427 {
433 }
437 }
439 }
443 {
457 }
459 }
465 {
473 /* Apple seems to have botched the ROM on the IIx */
481 /* Actually we should probably panic if this fails */
489 {
491 {
493 {
503 }
505 {
509 }
511 {
512 /* MacOS driver. If we were NetBSD we might
513 use this :-) */
522 }
524 /* We will need this in order to support
525 multiple framebuffers. It might be handy
526 for Ethernet as well */
532 /* Ditto */
546 /* Local/Private resources have their own
547 function */
549 }
550 }
553 }
555 /* This is cool. */
558 {
561 /* FIXME: obviously we want to put this in a header file soon */
563 u32 size;
564 /* Don't know what this is yet */
565 u16 id;
566 /* Longest one I've seen so far is 26 characters */
568 };
577 {
579 u32 size;
581 /* First get the length */
584 /* Now clobber the whole thing */
591 }
593 }
595 /* This is *really* cool. */
598 {
599 /* Should be 32x32 if my memory serves me correctly */
606 /* We should actually plot these somewhere in the framebuffer
607 init. This is just to demonstrate that they do, in fact,
608 exist */
615 else
617 }
619 }
621 }
625 {
638 {
641 /* These are all strings, we think */
647 }
649 }
653 {
663 {
666 {
668 /* This type is always the same, and is not
669 useful except insofar as it tells us that
670 we really are looking at a board resource. */
679 }
705 /* WTF isn't this in the functional resources? */
709 /* Same goes for this */
717 }
718 }
720 }
722 /* Attempt to bypass the somewhat non-obvious arrangement of
723 sResources in the motherboard ROM */
725 {
731 /* Check for the extra directory just under the format block */
735 /* OK, the ROM was telling the truth */
741 }
743 /* On "slot zero", you have to walk down a few more
744 directories to get to the equivalent of a real card's root
745 directory. We don't know what they were smoking when they
746 came up with this. */
753 /* This one points to an "Unknown Macintosh" directory */
759 /* This one takes us to where we want to go. */
766 /* Resource ID 01, also an "Unknown Macintosh" */
772 /* FIXME: the first one is *not* always the right one. We
773 suspect this has something to do with the ROM revision.
774 "The HORROR ROM" (LC-series) uses 0x7e, while "The HORROR
775 Continues" (Q630) uses 0x7b. The DAFB Macs evidently use
776 something else. Please run "Slots" on your Mac (see
777 include/linux/nubus.h for where to get this program) and
778 tell us where the 'SiDirPtr' for Slot 0 is. If you feel
779 brave, you should also use MacsBug to walk down the ROM
780 directories like this function does and try to find the
781 path to that address... */
787 /* Bwahahahaha... */
792 /* Even more evil laughter... */
793 badrom:
797 }
799 /* Add a board (might be many devices) to the list */
801 {
810 /* Move to the start of the format block */
814 /* Actually we should probably panic if this fails */
819 /* Dump the format block for debugging purposes */
830 }
833 }
838 /* rom_length is *supposed* to be the total length of the
839 * ROM. In practice it is the "amount of ROM used to compute
840 * the CRC." So some jokers decide to set it to zero and
841 * set the crc to zero so they don't have to do any math.
842 * See the Performa 460 ROM, for example. Those Apple "engineers".
843 */
850 /* Directory offset should be small and negative... */
857 /*
858 * I wonder how the CRC is meant to work -
859 * any takers ?
860 * CSA: According to MAC docs, not all cards pass the CRC anyway,
861 * since the initial Macintosh ROM releases skipped the check.
862 */
864 /* Attempt to work around slot zero weirdness */
868 /* We're ready to rock */
871 /* Each slot should have one board resource and any number of
872 functional resources. So we'll fill in some fields in the
873 struct nubus_board from the board resource, then walk down
874 the list of functional resources, spinning out a nubus_dev
875 for each of them. */
877 /* We can't have this! */
883 }
885 /* Aaaarrrrgghh! The LC III motherboard has *two* board
886 resources. I have no idea WTF to do about this. */
895 /* We zeroed this out above */
899 /* Put it on the global NuBus device chain. Keep entries in order. */
904 }
906 /* Put it on the global NuBus board chain. Keep entries in order. */
913 }
916 {
923 {
927 rp--;
940 /* The last byte of the format block consists of two
941 nybbles which are "mirror images" of each other.
942 These show us the valid bytelanes */
945 /* Check that this value is actually *on* one of the
946 bytelanes it claims are valid! */
950 /* Looks promising. Let's put it on the list. */
954 }
955 }
957 #if defined(CONFIG_PROC_FS)
959 /* /proc/nubus stuff */
962 {
970 }
974 {
980 /* Walk the list of NuBus boards */
982 {
990 }
993 }
1004 }
1005 #endif
1008 {
1010 /* This might not work on your machine */
1011 #ifdef I_WANT_TO_PROBE_SLOT_ZERO
1013 #endif
1015 {
1017 }
1018 }
1021 {
1025 /* Initialize the NuBus interrupts */
1030 }
1032 #ifdef TRY_TO_DODGE_WSOD
1033 /* Rogue Ethernet interrupts can kill the machine if we don't
1034 do this. Obviously this is bogus. Hopefully the local VIA
1035 gurus can fix the real cause of the problem. */
1037 #endif
1039 /* And probe */
1045 #ifdef CONFIG_PROC_FS
1048 #endif
1050 }