| blob | 8314a49b6b9a9e195250c92729a0f77168f6f44c |
1 /*
2 * Copyright 2005-2006 Erik Waling
3 * Copyright 2006 Stephane Marchesin
4 * Copyright 2007-2009 Stuart Bennett
5 *
6 * Permission is hereby granted, free of charge, to any person obtaining a
7 * copy of this software and associated documentation files (the "Software"),
8 * to deal in the Software without restriction, including without limitation
9 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
10 * and/or sell copies of the Software, and to permit persons to whom the
11 * Software is furnished to do so, subject to the following conditions:
12 *
13 * The above copyright notice and this permission notice shall be included in
14 * all copies or substantial portions of the Software.
15 *
16 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
17 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
18 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
19 * THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
20 * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF
21 * OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
22 * SOFTWARE.
23 */
26 #define NV_DEBUG_NOTRACE
31 #include <linux/io-mapping.h>
33 /* these defines are made up */
34 #define NV_CIO_CRE_44_HEADA 0x0
35 #define NV_CIO_CRE_44_HEADB 0x3
37 #define LEGACY_I2C_CRT 0x80
38 #define LEGACY_I2C_PANEL 0x81
39 #define LEGACY_I2C_TV 0x82
41 #define EDID1_LEN 128
43 #define BIOSLOG(sip, fmt, arg...) NV_DEBUG(sip->dev, fmt, ##arg)
44 #define LOG_OLD_VALUE(x)
49 };
52 {
53 /*
54 * There's a few checksums in the BIOS, so here's a generic checking
55 * function.
56 */
67 }
69 static int
71 {
75 }
79 /* if a ro image is somewhat bad, it's probably all rubbish */
85 }
88 {
96 else
99 /* enable ROM access */
104 /* bail if no rom signature */
109 /* additional check (see note below) - read PCI record header */
118 /* on some 6600GT/6800LE prom reads are messed up. nvclock alleges a
119 * a good read may be obtained by waiting or re-reading (cargocult: 5x)
120 * each byte. we'll hope pramin has something usable instead
121 */
125 out:
126 /* disable ROM access */
129 }
132 {
145 }
147 /* bail if no rom signature */
155 out:
158 }
161 {
176 out:
178 }
181 {
192 ROM_BIOS_PAGE);
195 }
197 }
203 };
210 };
211 #define NUM_SHADOW_METHODS ARRAY_SIZE(shadow_methods)
214 {
231 }
234 }
244 }
253 }
254 }
255 }
259 }
264 /* Return:
265 * > 0: success, length of opcode
266 * 0: success, but abort further parsing of table (INIT_DONE etc)
267 * < 0: failure, table parsing will be aborted
268 */
270 };
274 #define MACRO_INDEX_SIZE 2
275 #define MACRO_SIZE 8
276 #define CONDITION_SIZE 12
277 #define IO_FLAG_CONDITION_SIZE 9
278 #define IO_CONDITION_SIZE 5
279 #define MEM_INIT_SIZE 66
282 {
283 #if 0
286 #endif
287 }
289 static uint32_t
291 {
304 }
308 }
310 static int
312 {
316 /* C51 has misaligned regs on purpose. Marvellous */
321 /* warn on C51 regs that haven't been verified accessible in tracing */
325 reg);
330 }
333 }
335 static bool
337 {
341 /*
342 * If adding more ports here, the read/write functions below will need
343 * updating so that the correct mmio range (PRMCIO, PRMDIO, PRMVIO) is
344 * used for the port in question
345 */
354 }
357 port);
360 }
362 static bool
364 {
367 /*
368 * If adding more ports here, the read/write functions below will need
369 * updating so that the correct mmio range (PRMCIO, PRMDIO, PRMVIO) is
370 * used for the port in question
371 */
378 }
380 static uint32_t
382 {
389 /*
390 * C51 sometimes uses regs with bit0 set in the address. For these
391 * cases there should exist a translation in a BIOS table to an IO
392 * port address which the BIOS uses for accessing the reg
393 *
394 * These only seem to appear for the power control regs to a flat panel,
395 * and the GPIO regs at 0x60081*. In C51 mmio traces the normal regs
396 * for 0x1308 and 0x1310 are used - hence the mask below. An S3
397 * suspend-resume mmio trace from a C51 will be required to see if this
398 * is true for the power microcode in 0x14.., or whether the direct IO
399 * port access method is needed
400 */
409 }
411 static void
413 {
420 /* see note in bios_rd32 */
430 }
431 }
433 static uint8_t
435 {
453 }
459 }
461 static void
463 {
470 /*
471 * The current head is maintained in the nvbios member state.crtchead.
472 * We trap changes to CR44 and update the head variable and hence the
473 * register set written.
474 * As CR44 only exists on CRTC0, we update crtchead to head0 in advance
475 * of the write, and to head1 after the write
476 */
502 }
507 }
509 static uint8_t
511 {
523 }
525 static void
527 {
542 }
544 static bool
546 {
547 /*
548 * The IO flag condition entry has 2 bytes for the CRTC port; 1 byte
549 * for the CRTC index; 1 byte for the mask to apply to the value
550 * retrieved from the CRTC; 1 byte for the shift right to apply to the
551 * masked CRTC value; 2 bytes for the offset to the flag array, to
552 * which the shifted value is added; 1 byte for the mask applied to the
553 * value read from the flag array; and 1 byte for the value to compare
554 * against the masked byte from the flag table.
555 */
568 "Shift: 0x%02X, FlagArray: 0x%04X, FAMask: 0x%02X, "
581 }
583 static bool
585 {
586 /*
587 * The condition table entry has 4 bytes for the address of the
588 * register to check, 4 bytes for a mask to apply to the register and
589 * 4 for a test comparison value
590 */
607 }
609 static bool
611 {
612 /*
613 * The IO condition entry has 2 bytes for the IO port address; 1 byte
614 * for the index to write to io_port; 1 byte for the mask to apply to
615 * the byte read from io_port+1; and 1 byte for the value to compare
616 * against the masked byte.
617 */
631 }
633 static int
635 {
658 }
661 }
663 static int
665 {
668 /* clk in kHz */
676 /* high regs (such as in the mac g5 table) are not -= 4 */
688 }
691 }
694 {
698 /*
699 * For the results of this function to be correct, CR44 must have been
700 * set (using bios_idxprt_wr to set crtchead), CR58 set for CR57 = 0,
701 * and the DCB table parsed, before the script calling the function is
702 * run. run_digital_op_script is example of how to do such setup
703 */
711 }
714 }
716 static int
717 read_dcb_i2c_entry(struct drm_device *dev, int dcb_version, uint8_t *i2ctable, int index, struct dcb_i2c_entry *i2c)
718 {
736 else
738 "DCB I2C table has more entries than indexable "
740 DCB_MAX_NUM_I2C_ENTRIES);
742 /* [4] is i2c_default_indices, read in parse_dcb_table() */
743 }
744 /*
745 * It's your own fault if you call this function on a DCB 1.1 BIOS --
746 * the test below is for DCB 1.2
747 */
752 }
760 }
764 }
769 /*
770 * Fixup for chips using same address offset for read and
771 * write.
772 */
777 }
784 }
791 }
795 {
800 /* note: dcb_entry_idx_from_crtchead needs pre-script set-up */
808 }
811 else
818 }
820 /* Make sure i2c table entry has been parsed, it may not
821 * have been if this is a bus not referenced by a DCB encoder
822 */
827 }
829 static uint32_t
831 {
832 /*
833 * For mlv < 0x80, it is an index into a table of TMDS base addresses.
834 * For mlv == 0x80 use the "or" value of the dcb_entry indexed by
835 * CR58 for CR57 = 0 to index a table of offsets to the basic
836 * 0x6808b0 address.
837 * For mlv == 0x81 use the "or" value of the dcb_entry indexed by
838 * CR58 for CR57 = 0 to index a table of offsets to the basic
839 * 0x6808b0 address, and then flip the offset by 8.
840 */
852 /* note: dcb_entry_idx_from_crtchead needs pre-script set-up */
863 mlv);
865 }
867 }
868 }
870 static int
873 {
874 /*
875 * INIT_IO_RESTRICT_PROG opcode: 0x32 ('2')
876 *
877 * offset (8 bit): opcode
878 * offset + 1 (16 bit): CRTC port
879 * offset + 3 (8 bit): CRTC index
880 * offset + 4 (8 bit): mask
881 * offset + 5 (8 bit): shift
882 * offset + 6 (8 bit): count
883 * offset + 7 (32 bit): register
884 * offset + 11 (32 bit): configuration 1
885 * ...
886 *
887 * Starting at offset + 11 there are "count" 32 bit values.
888 * To find out which value to use read index "CRTC index" on "CRTC
889 * port", AND this value with "mask" and then bit shift right "shift"
890 * bits. Read the appropriate value using this index and write to
891 * "register"
892 */
917 }
926 }
928 static int
930 {
931 /*
932 * INIT_REPEAT opcode: 0x33 ('3')
933 *
934 * offset (8 bit): opcode
935 * offset + 1 (8 bit): count
936 *
937 * Execute script following this opcode up to INIT_REPEAT_END
938 * "count" times
939 */
944 /* no iexec->execute check by design */
951 /*
952 * count - 1, as the script block will execute once when we leave this
953 * opcode -- this is compatible with bios behaviour as:
954 * a) the block is always executed at least once, even if count == 0
955 * b) the bios interpreter skips to the op following INIT_END_REPEAT,
956 * while we don't
957 */
964 }
966 static int
969 {
970 /*
971 * INIT_IO_RESTRICT_PLL opcode: 0x34 ('4')
972 *
973 * offset (8 bit): opcode
974 * offset + 1 (16 bit): CRTC port
975 * offset + 3 (8 bit): CRTC index
976 * offset + 4 (8 bit): mask
977 * offset + 5 (8 bit): shift
978 * offset + 6 (8 bit): IO flag condition index
979 * offset + 7 (8 bit): count
980 * offset + 8 (32 bit): register
981 * offset + 12 (16 bit): frequency 1
982 * ...
983 *
984 * Starting at offset + 12 there are "count" 16 bit frequencies (10kHz).
985 * Set PLL register "register" to coefficients for frequency n,
986 * selected by reading index "CRTC index" of "CRTC port" ANDed with
987 * "mask" and shifted right by "shift".
988 *
989 * If "IO flag condition index" > 0, and condition met, double
990 * frequency before setting it.
991 */
1008 "Shift: 0x%02X, IO Flag Condition: 0x%02X, "
1019 }
1031 }
1039 }
1041 static int
1043 {
1044 /*
1045 * INIT_END_REPEAT opcode: 0x36 ('6')
1046 *
1047 * offset (8 bit): opcode
1048 *
1049 * Marks the end of the block for INIT_REPEAT to repeat
1050 */
1052 /* no iexec->execute check by design */
1054 /*
1055 * iexec->repeat flag necessary to go past INIT_END_REPEAT opcode when
1056 * we're not in repeat mode
1057 */
1062 }
1064 static int
1066 {
1067 /*
1068 * INIT_COPY opcode: 0x37 ('7')
1069 *
1070 * offset (8 bit): opcode
1071 * offset + 1 (32 bit): register
1072 * offset + 5 (8 bit): shift
1073 * offset + 6 (8 bit): srcmask
1074 * offset + 7 (16 bit): CRTC port
1075 * offset + 9 (8 bit): CRTC index
1076 * offset + 10 (8 bit): mask
1077 *
1078 * Read index "CRTC index" on "CRTC port", AND with "mask", OR with
1079 * (REGVAL("register") >> "shift" & "srcmask") and write-back to CRTC
1080 * port
1081 */
1103 else
1113 }
1115 static int
1117 {
1118 /*
1119 * INIT_NOT opcode: 0x38 ('8')
1120 *
1121 * offset (8 bit): opcode
1122 *
1123 * Invert the current execute / no-execute condition (i.e. "else")
1124 */
1127 else
1132 }
1134 static int
1137 {
1138 /*
1139 * INIT_IO_FLAG_CONDITION opcode: 0x39 ('9')
1140 *
1141 * offset (8 bit): opcode
1142 * offset + 1 (8 bit): condition number
1143 *
1144 * Check condition "condition number" in the IO flag condition table.
1145 * If condition not met skip subsequent opcodes until condition is
1146 * inverted (INIT_NOT), or we hit INIT_RESUME
1147 */
1159 }
1162 }
1164 static int
1166 {
1167 /*
1168 * INIT_DP_CONDITION opcode: 0x3A ('')
1169 *
1170 * offset (8 bit): opcode
1171 * offset + 1 (8 bit): "sub" opcode
1172 * offset + 2 (8 bit): unknown
1173 *
1174 */
1191 }
1195 {
1201 }
1209 {
1217 }
1223 }
1227 }
1232 }
1236 else
1240 }
1242 static int
1244 {
1245 /*
1246 * INIT_3B opcode: 0x3B ('')
1247 *
1248 * offset (8 bit): opcode
1249 * offset + 1 (8 bit): crtc index
1250 *
1251 */
1263 }
1265 static int
1267 {
1268 /*
1269 * INIT_3C opcode: 0x3C ('')
1270 *
1271 * offset (8 bit): opcode
1272 * offset + 1 (8 bit): crtc index
1273 *
1274 */
1286 }
1288 static int
1291 {
1292 /*
1293 * INIT_INDEX_ADDRESS_LATCHED opcode: 0x49 ('I')
1294 *
1295 * offset (8 bit): opcode
1296 * offset + 1 (32 bit): control register
1297 * offset + 5 (32 bit): data register
1298 * offset + 9 (32 bit): mask
1299 * offset + 13 (32 bit): data
1300 * offset + 17 (8 bit): count
1301 * offset + 18 (8 bit): address 1
1302 * offset + 19 (8 bit): data 1
1303 * ...
1304 *
1305 * For each of "count" address and data pairs, write "data n" to
1306 * "data register", read the current value of "control register",
1307 * and write it back once ANDed with "mask", ORed with "data",
1308 * and ORed with "address n"
1309 */
1339 }
1342 }
1344 static int
1347 {
1348 /*
1349 * INIT_IO_RESTRICT_PLL2 opcode: 0x4A ('J')
1350 *
1351 * offset (8 bit): opcode
1352 * offset + 1 (16 bit): CRTC port
1353 * offset + 3 (8 bit): CRTC index
1354 * offset + 4 (8 bit): mask
1355 * offset + 5 (8 bit): shift
1356 * offset + 6 (8 bit): count
1357 * offset + 7 (32 bit): register
1358 * offset + 11 (32 bit): frequency 1
1359 * ...
1360 *
1361 * Starting at offset + 11 there are "count" 32 bit frequencies (kHz).
1362 * Set PLL register "register" to coefficients for frequency n,
1363 * selected by reading index "CRTC index" of "CRTC port" ANDed with
1364 * "mask" and shifted right by "shift".
1365 */
1393 }
1403 }
1405 static int
1407 {
1408 /*
1409 * INIT_PLL2 opcode: 0x4B ('K')
1410 *
1411 * offset (8 bit): opcode
1412 * offset + 1 (32 bit): register
1413 * offset + 5 (32 bit): freq
1414 *
1415 * Set PLL register "register" to coefficients for frequency "freq"
1416 */
1429 }
1431 static int
1433 {
1434 /*
1435 * INIT_I2C_BYTE opcode: 0x4C ('L')
1436 *
1437 * offset (8 bit): opcode
1438 * offset + 1 (8 bit): DCB I2C table entry index
1439 * offset + 2 (8 bit): I2C slave address
1440 * offset + 3 (8 bit): count
1441 * offset + 4 (8 bit): I2C register 1
1442 * offset + 5 (8 bit): mask 1
1443 * offset + 6 (8 bit): data 1
1444 * ...
1445 *
1446 * For each of "count" registers given by "I2C register n" on the device
1447 * addressed by "I2C slave address" on the I2C bus given by
1448 * "DCB I2C table entry index", read the register, AND the result with
1449 * "mask n" and OR it with "data n" before writing it back to the device
1450 */
1471 }
1485 }
1502 }
1503 }
1506 }
1508 static int
1510 {
1511 /*
1512 * INIT_ZM_I2C_BYTE opcode: 0x4D ('M')
1513 *
1514 * offset (8 bit): opcode
1515 * offset + 1 (8 bit): DCB I2C table entry index
1516 * offset + 2 (8 bit): I2C slave address
1517 * offset + 3 (8 bit): count
1518 * offset + 4 (8 bit): I2C register 1
1519 * offset + 5 (8 bit): data 1
1520 * ...
1521 *
1522 * For each of "count" registers given by "I2C register n" on the device
1523 * addressed by "I2C slave address" on the I2C bus given by
1524 * "DCB I2C table entry index", set the register to "data n"
1525 */
1546 }
1566 }
1567 }
1570 }
1572 static int
1574 {
1575 /*
1576 * INIT_ZM_I2C opcode: 0x4E ('N')
1577 *
1578 * offset (8 bit): opcode
1579 * offset + 1 (8 bit): DCB I2C table entry index
1580 * offset + 2 (8 bit): I2C slave address
1581 * offset + 3 (8 bit): count
1582 * offset + 4 (8 bit): data 1
1583 * ...
1584 *
1585 * Send "count" bytes ("data n") to the device addressed by "I2C slave
1586 * address" on the I2C bus given by "DCB I2C table entry index"
1587 */
1610 }
1616 }
1627 }
1628 }
1631 }
1633 static int
1635 {
1636 /*
1637 * INIT_TMDS opcode: 0x4F ('O') (non-canon name)
1638 *
1639 * offset (8 bit): opcode
1640 * offset + 1 (8 bit): magic lookup value
1641 * offset + 2 (8 bit): TMDS address
1642 * offset + 3 (8 bit): mask
1643 * offset + 4 (8 bit): data
1644 *
1645 * Read the data reg for TMDS address "TMDS address", AND it with mask
1646 * and OR it with data, then write it back
1647 * "magic lookup value" determines which TMDS base address register is
1648 * used -- see get_tmds_index_reg()
1649 */
1669 }
1678 }
1680 static int
1683 {
1684 /*
1685 * INIT_ZM_TMDS_GROUP opcode: 0x50 ('P') (non-canon name)
1686 *
1687 * offset (8 bit): opcode
1688 * offset + 1 (8 bit): magic lookup value
1689 * offset + 2 (8 bit): count
1690 * offset + 3 (8 bit): addr 1
1691 * offset + 4 (8 bit): data 1
1692 * ...
1693 *
1694 * For each of "count" TMDS address and data pairs write "data n" to
1695 * "addr n". "magic lookup value" determines which TMDS base address
1696 * register is used -- see get_tmds_index_reg()
1697 */
1716 }
1724 }
1727 }
1729 static int
1732 {
1733 /*
1734 * INIT_CR_INDEX_ADDRESS_LATCHED opcode: 0x51 ('Q')
1735 *
1736 * offset (8 bit): opcode
1737 * offset + 1 (8 bit): CRTC index1
1738 * offset + 2 (8 bit): CRTC index2
1739 * offset + 3 (8 bit): baseaddr
1740 * offset + 4 (8 bit): count
1741 * offset + 5 (8 bit): data 1
1742 * ...
1743 *
1744 * For each of "count" address and data pairs, write "baseaddr + n" to
1745 * "CRTC index1" and "data n" to "CRTC index2"
1746 * Once complete, restore initial value read from "CRTC index1"
1747 */
1770 }
1775 }
1777 static int
1779 {
1780 /*
1781 * INIT_CR opcode: 0x52 ('R')
1782 *
1783 * offset (8 bit): opcode
1784 * offset + 1 (8 bit): CRTC index
1785 * offset + 2 (8 bit): mask
1786 * offset + 3 (8 bit): data
1787 *
1788 * Assign the value of at "CRTC index" ANDed with mask and ORed with
1789 * data back to "CRTC index"
1790 */
1808 }
1810 static int
1812 {
1813 /*
1814 * INIT_ZM_CR opcode: 0x53 ('S')
1815 *
1816 * offset (8 bit): opcode
1817 * offset + 1 (8 bit): CRTC index
1818 * offset + 2 (8 bit): value
1819 *
1820 * Assign "value" to CRTC register with index "CRTC index".
1821 */
1832 }
1834 static int
1836 {
1837 /*
1838 * INIT_ZM_CR_GROUP opcode: 0x54 ('T')
1839 *
1840 * offset (8 bit): opcode
1841 * offset + 1 (8 bit): count
1842 * offset + 2 (8 bit): CRTC index 1
1843 * offset + 3 (8 bit): value 1
1844 * ...
1845 *
1846 * For "count", assign "value n" to CRTC register with index
1847 * "CRTC index n".
1848 */
1861 }
1863 static int
1866 {
1867 /*
1868 * INIT_CONDITION_TIME opcode: 0x56 ('V')
1869 *
1870 * offset (8 bit): opcode
1871 * offset + 1 (8 bit): condition number
1872 * offset + 2 (8 bit): retries / 50
1873 *
1874 * Check condition "condition number" in the condition table.
1875 * Bios code then sleeps for 2ms if the condition is not met, and
1876 * repeats up to "retries" times, but on one C51 this has proved
1877 * insufficient. In mmiotraces the driver sleeps for 20ms, so we do
1878 * this, and bail after "retries" times, or 2s, whichever is less.
1879 * If still not met after retries, clear execution flag for this table.
1880 */
1901 offset);
1906 offset);
1908 }
1909 }
1913 "0x%04X: Condition still not met after %dms, "
1916 }
1919 }
1921 static int
1923 {
1924 /*
1925 * INIT_LTIME opcode: 0x57 ('V')
1926 *
1927 * offset (8 bit): opcode
1928 * offset + 1 (16 bit): time
1929 *
1930 * Sleep for "time" milliseconds.
1931 */
1944 }
1946 static int
1949 {
1950 /*
1951 * INIT_ZM_REG_SEQUENCE opcode: 0x58 ('X')
1952 *
1953 * offset (8 bit): opcode
1954 * offset + 1 (32 bit): base register
1955 * offset + 5 (8 bit): count
1956 * offset + 6 (32 bit): value 1
1957 * ...
1958 *
1959 * Starting at offset + 6 there are "count" 32 bit values.
1960 * For "count" iterations set "base register" + 4 * current_iteration
1961 * to "value current_iteration"
1962 */
1980 }
1983 }
1985 static int
1987 {
1988 /*
1989 * INIT_SUB_DIRECT opcode: 0x5B ('[')
1990 *
1991 * offset (8 bit): opcode
1992 * offset + 1 (16 bit): subroutine offset (in bios)
1993 *
1994 * Calls a subroutine that will execute commands until INIT_DONE
1995 * is found.
1996 */
2011 }
2013 static int
2015 {
2016 /*
2017 * INIT_I2C_IF opcode: 0x5E ('^')
2018 *
2019 * offset (8 bit): opcode
2020 * offset + 1 (8 bit): DCB I2C table entry index
2021 * offset + 2 (8 bit): I2C slave address
2022 * offset + 3 (8 bit): I2C register
2023 * offset + 4 (8 bit): mask
2024 * offset + 5 (8 bit): data
2025 *
2026 * Read the register given by "I2C register" on the device addressed
2027 * by "I2C slave address" on the I2C bus given by "DCB I2C table
2028 * entry index". Compare the result AND "mask" to "data".
2029 * If they're not equal, skip subsequent opcodes until condition is
2030 * inverted (INIT_NOT), or we hit INIT_RESUME
2031 */
2042 /* no execute check by design */
2060 }
2069 }
2071 static int
2073 {
2074 /*
2075 * INIT_COPY_NV_REG opcode: 0x5F ('_')
2076 *
2077 * offset (8 bit): opcode
2078 * offset + 1 (32 bit): src reg
2079 * offset + 5 (8 bit): shift
2080 * offset + 6 (32 bit): src mask
2081 * offset + 10 (32 bit): xor
2082 * offset + 14 (32 bit): dst reg
2083 * offset + 18 (32 bit): dst mask
2084 *
2085 * Shift REGVAL("src reg") right by (signed) "shift", AND result with
2086 * "src mask", then XOR with "xor". Write this OR'd with
2087 * (REGVAL("dst reg") AND'd with "dst mask") to "dst reg"
2088 */
2109 else
2119 }
2121 static int
2123 {
2124 /*
2125 * INIT_ZM_INDEX_IO opcode: 0x62 ('b')
2126 *
2127 * offset (8 bit): opcode
2128 * offset + 1 (16 bit): CRTC port
2129 * offset + 3 (8 bit): CRTC index
2130 * offset + 4 (8 bit): data
2131 *
2132 * Write "data" to index "CRTC index" of "CRTC port"
2133 */
2144 }
2149 {
2151 }
2153 static uint32_t
2156 {
2166 }
2169 }
2171 static void
2174 {
2183 }
2184 }
2189 {
2192 }
2194 static int
2196 {
2202 /* Map the framebuffer aperture */
2208 /* Sequencer and refresh off */
2213 NV04_PFB_BOOT_0_RAM_AMOUNT_16MB |
2214 NV04_PFB_BOOT_0_RAM_WIDTH_128 |
2215 NV04_PFB_BOOT_0_RAM_TYPE_SGRAM_16MBIT);
2224 NV04_PFB_BOOT_0_RAM_TYPE_SDRAM_16MBIT);
2233 NV04_PFB_BOOT_0_RAM_WIDTH_128 |
2234 NV04_PFB_BOOT_0_RAM_AMOUNT,
2235 NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
2240 NV04_PFB_BOOT_0_RAM_WIDTH_128 |
2241 NV04_PFB_BOOT_0_RAM_AMOUNT,
2242 NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
2247 NV04_PFB_BOOT_0_RAM_AMOUNT,
2248 NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
2249 else
2251 NV04_PFB_BOOT_0_RAM_AMOUNT,
2252 NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
2255 NV04_PFB_BOOT_0_RAM_TYPE_SGRAM_8MBIT);
2259 NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
2261 }
2263 /* Refresh on, sequencer on */
2269 }
2273 {
2274 /* Defaults for BIOSes lacking a memory config table */
2284 };
2290 else
2292 }
2294 static int
2296 {
2303 /* Map the framebuffer aperture */
2309 /* Sequencer off */
2317 /* If present load the hardcoded scrambling table */
2325 }
2327 /* Set memory type/width/length defaults depending on the straps */
2336 /* Probe memory bus width */
2344 /* Probe memory length */
2351 NV04_PFB_BOOT_0_RAM_AMOUNT_16MB);
2356 NV04_PFB_BOOT_0_RAM_AMOUNT_8MB);
2360 NV04_PFB_BOOT_0_RAM_AMOUNT_4MB);
2362 out:
2363 /* Sequencer on */
2368 }
2370 static int
2372 {
2381 /* Map the framebuffer aperture */
2389 /* Probe memory bus width */
2402 }
2403 }
2405 mem_width_found:
2408 /* Probe amount of installed memory */
2422 }
2424 /* IC missing - disable the upper half memory space. */
2427 amount_found:
2430 }
2432 static int
2434 {
2441 /* Map the framebuffer aperture */
2449 /* Allow full addressing */
2458 /* IC missing - disable the upper half memory space. */
2463 }
2465 static int
2467 {
2468 /*
2469 * INIT_COMPUTE_MEM opcode: 0x63 ('c')
2470 *
2471 * offset (8 bit): opcode
2472 *
2473 * This opcode is meant to set the PFB memory config registers
2474 * appropriately so that we can correctly calculate how much VRAM it
2475 * has (on nv10 and better chipsets the amount of installed VRAM is
2476 * subsequently reported in NV_PFB_CSTATUS (0x10020C)).
2477 *
2478 * The implementation of this opcode in general consists of several
2479 * parts:
2480 *
2481 * 1) Determination of memory type and density. Only necessary for
2482 * really old chipsets, the memory type reported by the strap bits
2483 * (0x101000) is assumed to be accurate on nv05 and newer.
2484 *
2485 * 2) Determination of the memory bus width. Usually done by a cunning
2486 * combination of writes to offsets 0x1c and 0x3c in the fb, and
2487 * seeing whether the written values are read back correctly.
2488 *
2489 * Only necessary on nv0x-nv1x and nv34, on the other cards we can
2490 * trust the straps.
2491 *
2492 * 3) Determination of how many of the card's RAM pads have ICs
2493 * attached, usually done by a cunning combination of writes to an
2494 * offset slightly less than the maximum memory reported by
2495 * NV_PFB_CSTATUS, then seeing if the test pattern can be read back.
2496 *
2497 * This appears to be a NOP on IGPs and NV4x or newer chipsets, both io
2498 * logs of the VBIOS and kmmio traces of the binary driver POSTing the
2499 * card show nothing being done for this opcode. Why is it still listed
2500 * in the table?!
2501 */
2503 /* no iexec->execute check by design */
2519 else
2526 }
2528 static int
2530 {
2531 /*
2532 * INIT_RESET opcode: 0x65 ('e')
2533 *
2534 * offset (8 bit): opcode
2535 * offset + 1 (32 bit): register
2536 * offset + 5 (32 bit): value1
2537 * offset + 9 (32 bit): value2
2538 *
2539 * Assign "value1" to "register", then assign "value2" to "register"
2540 */
2547 /* no iexec->execute check by design */
2564 }
2566 static int
2569 {
2570 /*
2571 * INIT_CONFIGURE_MEM opcode: 0x66 ('f')
2572 *
2573 * offset (8 bit): opcode
2574 *
2575 * Equivalent to INIT_DONE on bios version 3 or greater.
2576 * For early bios versions, sets up the memory registers, using values
2577 * taken from the memory init table
2578 */
2580 /* no iexec->execute check by design */
2582 uint16_t meminitoffs = bios->legacy.mem_init_tbl_ptr + MEM_INIT_SIZE * (bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_SCRATCH4__INDEX) >> 4);
2614 }
2617 }
2620 }
2622 static int
2625 {
2626 /*
2627 * INIT_CONFIGURE_CLK opcode: 0x67 ('g')
2628 *
2629 * offset (8 bit): opcode
2630 *
2631 * Equivalent to INIT_DONE on bios version 3 or greater.
2632 * For early bios versions, sets up the NVClk and MClk PLLs, using
2633 * values taken from the memory init table
2634 */
2636 /* no iexec->execute check by design */
2638 uint16_t meminitoffs = bios->legacy.mem_init_tbl_ptr + MEM_INIT_SIZE * (bios_idxprt_rd(bios, NV_CIO_CRX__COLOR, NV_CIO_CRE_SCRATCH4__INDEX) >> 4);
2653 }
2655 static int
2658 {
2659 /*
2660 * INIT_CONFIGURE_PREINIT opcode: 0x68 ('h')
2661 *
2662 * offset (8 bit): opcode
2663 *
2664 * Equivalent to INIT_DONE on bios version 3 or greater.
2665 * For early bios versions, does early init, loading ram and crystal
2666 * configuration from straps into CR3C
2667 */
2669 /* no iexec->execute check by design */
2681 }
2683 static int
2685 {
2686 /*
2687 * INIT_IO opcode: 0x69 ('i')
2688 *
2689 * offset (8 bit): opcode
2690 * offset + 1 (16 bit): CRTC port
2691 * offset + 3 (8 bit): mask
2692 * offset + 4 (8 bit): data
2693 *
2694 * Assign ((IOVAL("crtc port") & "mask") | "data") to "crtc port"
2695 */
2708 /*
2709 * I have no idea what this does, but NVIDIA do this magic sequence
2710 * in the places where this INIT_IO happens..
2711 */
2763 }
2766 data);
2768 }
2770 static int
2772 {
2773 /*
2774 * INIT_SUB opcode: 0x6B ('k')
2775 *
2776 * offset (8 bit): opcode
2777 * offset + 1 (8 bit): script number
2778 *
2779 * Execute script number "script number", as a subroutine
2780 */
2791 iexec);
2796 }
2798 static int
2801 {
2802 /*
2803 * INIT_RAM_CONDITION opcode: 0x6D ('m')
2804 *
2805 * offset (8 bit): opcode
2806 * offset + 1 (8 bit): mask
2807 * offset + 2 (8 bit): cmpval
2808 *
2809 * Test if (NV04_PFB_BOOT_0 & "mask") equals "cmpval".
2810 * If condition not met skip subsequent opcodes until condition is
2811 * inverted (INIT_NOT), or we hit INIT_RESUME
2812 */
2831 }
2834 }
2836 static int
2838 {
2839 /*
2840 * INIT_NV_REG opcode: 0x6E ('n')
2841 *
2842 * offset (8 bit): opcode
2843 * offset + 1 (32 bit): register
2844 * offset + 5 (32 bit): mask
2845 * offset + 9 (32 bit): data
2846 *
2847 * Assign ((REGVAL("register") & "mask") | "data") to "register"
2848 */
2863 }
2865 static int
2867 {
2868 /*
2869 * INIT_MACRO opcode: 0x6F ('o')
2870 *
2871 * offset (8 bit): opcode
2872 * offset + 1 (8 bit): macro number
2873 *
2874 * Look up macro index "macro number" in the macro index table.
2875 * The macro index table entry has 1 byte for the index in the macro
2876 * table, and 1 byte for the number of times to repeat the macro.
2877 * The macro table entry has 4 bytes for the register address and
2878 * 4 bytes for the value to write to that register
2879 */
2902 }
2905 }
2907 static int
2909 {
2910 /*
2911 * INIT_DONE opcode: 0x71 ('q')
2912 *
2913 * offset (8 bit): opcode
2914 *
2915 * End the current script
2916 */
2918 /* mild retval abuse to stop parsing this table */
2920 }
2922 static int
2924 {
2925 /*
2926 * INIT_RESUME opcode: 0x72 ('r')
2927 *
2928 * offset (8 bit): opcode
2929 *
2930 * End the current execute / no-execute condition
2931 */
2940 }
2942 static int
2944 {
2945 /*
2946 * INIT_TIME opcode: 0x74 ('t')
2947 *
2948 * offset (8 bit): opcode
2949 * offset + 1 (16 bit): time
2950 *
2951 * Sleep for "time" microseconds.
2952 */
2964 else
2968 }
2970 static int
2972 {
2973 /*
2974 * INIT_CONDITION opcode: 0x75 ('u')
2975 *
2976 * offset (8 bit): opcode
2977 * offset + 1 (8 bit): condition number
2978 *
2979 * Check condition "condition number" in the condition table.
2980 * If condition not met skip subsequent opcodes until condition is
2981 * inverted (INIT_NOT), or we hit INIT_RESUME
2982 */
2996 }
2999 }
3001 static int
3003 {
3004 /*
3005 * INIT_IO_CONDITION opcode: 0x76
3006 *
3007 * offset (8 bit): opcode
3008 * offset + 1 (8 bit): condition number
3009 *
3010 * Check condition "condition number" in the io condition table.
3011 * If condition not met skip subsequent opcodes until condition is
3012 * inverted (INIT_NOT), or we hit INIT_RESUME
3013 */
3027 }
3030 }
3032 static int
3034 {
3035 /*
3036 * INIT_INDEX_IO opcode: 0x78 ('x')
3037 *
3038 * offset (8 bit): opcode
3039 * offset + 1 (16 bit): CRTC port
3040 * offset + 3 (8 bit): CRTC index
3041 * offset + 4 (8 bit): mask
3042 * offset + 5 (8 bit): data
3043 *
3044 * Read value at index "CRTC index" on "CRTC port", AND with "mask",
3045 * OR with "data", write-back
3046 */
3065 }
3067 static int
3069 {
3070 /*
3071 * INIT_PLL opcode: 0x79 ('y')
3072 *
3073 * offset (8 bit): opcode
3074 * offset + 1 (32 bit): register
3075 * offset + 5 (16 bit): freq
3076 *
3077 * Set PLL register "register" to coefficients for frequency (10kHz)
3078 * "freq"
3079 */
3092 }
3094 static int
3096 {
3097 /*
3098 * INIT_ZM_REG opcode: 0x7A ('z')
3099 *
3100 * offset (8 bit): opcode
3101 * offset + 1 (32 bit): register
3102 * offset + 5 (32 bit): value
3103 *
3104 * Assign "value" to "register"
3105 */
3119 }
3121 static int
3124 {
3125 /*
3126 * INIT_RAM_RESTRICT_PLL opcode: 0x87 ('')
3127 *
3128 * offset (8 bit): opcode
3129 * offset + 1 (8 bit): PLL type
3130 * offset + 2 (32 bit): frequency 0
3131 *
3132 * Uses the RAMCFG strap of PEXTDEV_BOOT as an index into the table at
3133 * ram_restrict_table_ptr. The value read from there is used to select
3134 * a frequency from the table starting at 'frequency 0' to be
3135 * programmed into the PLL corresponding to 'type'.
3136 *
3137 * The PLL limits table on cards using this opcode has a mapping of
3138 * 'type' to the relevant registers.
3139 */
3156 }
3169 }
3170 }
3174 }
3176 static int
3178 {
3179 /*
3180 * INIT_8C opcode: 0x8C ('')
3181 *
3182 * NOP so far....
3183 *
3184 */
3187 }
3189 static int
3191 {
3192 /*
3193 * INIT_8D opcode: 0x8D ('')
3194 *
3195 * NOP so far....
3196 *
3197 */
3200 }
3202 static int
3204 {
3205 /*
3206 * INIT_GPIO opcode: 0x8E ('')
3207 *
3208 * offset (8 bit): opcode
3209 *
3210 * Loop over all entries in the DCB GPIO table, and initialise
3211 * each GPIO according to various values listed in each entry
3212 */
3222 }
3238 /* The NVIDIA binary driver doesn't appear to actually do
3239 * any of this, my VBIOS does however.
3240 */
3241 /* Not a clue, needs de-magicing */
3254 }
3256 }
3259 }
3261 static int
3264 {
3265 /*
3266 * INIT_RAM_RESTRICT_ZM_REG_GROUP opcode: 0x8F ('')
3267 *
3268 * offset (8 bit): opcode
3269 * offset + 1 (32 bit): reg
3270 * offset + 5 (8 bit): regincrement
3271 * offset + 6 (8 bit): count
3272 * offset + 7 (32 bit): value 1,1
3273 * ...
3274 *
3275 * Use the RAMCFG strap of PEXTDEV_BOOT as an index into the table at
3276 * ram_restrict_table_ptr. The value read from here is 'n', and
3277 * "value 1,n" gets written to "reg". This repeats "count" times and on
3278 * each iteration 'm', "reg" increases by "regincrement" and
3279 * "value m,n" is used. The extent of n is limited by a number read
3280 * from the 'M' BIT table, herein called "blocklen"
3281 */
3287 /* previously set by 'M' BIT table */
3296 "0x%04X: Zero block length - has the M table "
3299 }
3317 }
3320 }
3322 static int
3324 {
3325 /*
3326 * INIT_COPY_ZM_REG opcode: 0x90 ('')
3327 *
3328 * offset (8 bit): opcode
3329 * offset + 1 (32 bit): src reg
3330 * offset + 5 (32 bit): dst reg
3331 *
3332 * Put contents of "src reg" into "dst reg"
3333 */
3344 }
3346 static int
3349 {
3350 /*
3351 * INIT_ZM_REG_GROUP_ADDRESS_LATCHED opcode: 0x91 ('')
3352 *
3353 * offset (8 bit): opcode
3354 * offset + 1 (32 bit): dst reg
3355 * offset + 5 (8 bit): count
3356 * offset + 6 (32 bit): data 1
3357 * ...
3358 *
3359 * For each of "count" values write "data n" to "dst reg"
3360 */
3373 }
3376 }
3378 static int
3380 {
3381 /*
3382 * INIT_RESERVED opcode: 0x92 ('')
3383 *
3384 * offset (8 bit): opcode
3385 *
3386 * Seemingly does nothing
3387 */
3390 }
3392 static int
3394 {
3395 /*
3396 * INIT_96 opcode: 0x96 ('')
3397 *
3398 * offset (8 bit): opcode
3399 * offset + 1 (32 bit): sreg
3400 * offset + 5 (8 bit): sshift
3401 * offset + 6 (8 bit): smask
3402 * offset + 7 (8 bit): index
3403 * offset + 8 (32 bit): reg
3404 * offset + 12 (32 bit): mask
3405 * offset + 16 (8 bit): shift
3406 *
3407 */
3417 else
3429 }
3431 static int
3433 {
3434 /*
3435 * INIT_97 opcode: 0x97 ('')
3436 *
3437 * offset (8 bit): opcode
3438 * offset + 1 (32 bit): register
3439 * offset + 5 (32 bit): mask
3440 * offset + 9 (32 bit): value
3441 *
3442 * Adds "value" to "register" preserving the fields specified
3443 * by "mask"
3444 */
3459 }
3461 static int
3463 {
3464 /*
3465 * INIT_AUXCH opcode: 0x98 ('')
3466 *
3467 * offset (8 bit): opcode
3468 * offset + 1 (32 bit): address
3469 * offset + 5 (8 bit): count
3470 * offset + 6 (8 bit): mask 0
3471 * offset + 7 (8 bit): data 0
3472 * ...
3473 *
3474 */
3486 }
3493 }
3506 }
3515 }
3516 }
3519 }
3521 static int
3523 {
3524 /*
3525 * INIT_ZM_AUXCH opcode: 0x99 ('')
3526 *
3527 * offset (8 bit): opcode
3528 * offset + 1 (32 bit): address
3529 * offset + 5 (8 bit): count
3530 * offset + 6 (8 bit): data 0
3531 * ...
3532 *
3533 */
3545 }
3552 }
3563 }
3564 }
3567 }
3569 static int
3571 {
3572 /*
3573 * INIT_I2C_LONG_IF opcode: 0x9A ('')
3574 *
3575 * offset (8 bit): opcode
3576 * offset + 1 (8 bit): DCB I2C table entry index
3577 * offset + 2 (8 bit): I2C slave address
3578 * offset + 3 (16 bit): I2C register
3579 * offset + 5 (8 bit): mask
3580 * offset + 6 (8 bit): data
3581 *
3582 * Read the register given by "I2C register" on the device addressed
3583 * by "I2C slave address" on the I2C bus given by "DCB I2C table
3584 * entry index". Compare the result AND "mask" to "data".
3585 * If they're not equal, skip subsequent opcodes until condition is
3586 * inverted (INIT_NOT), or we hit INIT_RESUME
3587 */
3601 };
3604 /* no execute check by design */
3621 }
3630 }
3633 /* command name , id , length , offset , mult , command handler */
3634 /* INIT_PROG (0x31, 15, 10, 4) removed due to no example of use */
3660 /* INIT_INDIRECT_REG (0x5A, 7, 0, 0) removed due to no example of use */
3677 /* INIT_RAM_CONDITION2 (0x73, 9, 0, 0) removed due to no example of use */
3698 };
3700 #define MAX_TABLE_OPS 1000
3702 static int
3705 {
3706 /*
3707 * Parses all commands in an init table.
3708 *
3709 * We start out executing all commands found in the init table. Some
3710 * opcodes may change the status of iexec->execute to SKIP, which will
3711 * cause the following opcodes to perform no operation until the value
3712 * is changed back to EXECUTE.
3713 */
3718 /*
3719 * Loop until INIT_DONE causes us to break out of the loop
3720 * (or until offset > bios length just in case... )
3721 * (and no more than MAX_TABLE_OPS iterations, just in case... )
3722 */
3726 /* Find matching id in itbl_entry */
3728 ;
3732 "0x%04X: Init table command not found: "
3735 }
3740 /* execute eventual command handler */
3746 }
3751 /*
3752 * Add the offset of the current command including all data
3753 * of that command. The offset will then be pointing on the
3754 * next op code.
3755 */
3757 }
3761 "Offset 0x%04X greater than known bios image length. "
3765 "More than %d opcodes to a table is unlikely, "
3769 }
3771 static void
3773 {
3774 /* Loops and calls parse_init_table() for each present table. */
3787 }
3797 }
3798 }
3801 {
3807 else
3819 }
3820 i++;
3824 }
3826 static void
3829 {
3835 scriptptr);
3838 /* note: if dcb entries have been merged, index may be misleading */
3843 }
3845 static int call_lvds_manufacturer_script(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script)
3846 {
3849 uint8_t sub = bios->data[bios->fp.xlated_entry + script] + (bios->fp.link_c_increment && dcbent->or & OUTPUT_C ? 1 : 0);
3858 /* off-on delay in ms */
3860 }
3861 #ifdef __powerpc__
3862 /* Powerbook specific quirks */
3867 #endif
3870 }
3872 static int run_lvds_table(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script, int pxclk)
3873 {
3874 /*
3875 * The BIT LVDS table's header has the information to setup the
3876 * necessary registers. Following the standard 4 byte header are:
3877 * A bitmask byte and a dual-link transition pxclk value for use in
3878 * selecting the init script when not using straps; 4 script pointers
3879 * for panel power, selected by output and on/off; and 8 table pointers
3880 * for panel init, the needed one determined by output, and bits in the
3881 * conf byte. These tables are similar to the TMDS tables, consisting
3882 * of a list of pxclks and script pointers.
3883 */
3889 /*
3890 * For now we assume version 3.0 table - g80 support will need some
3891 * changes
3892 */
3916 /* using EDID */
3922 }
3926 }
3932 }
3934 }
3939 }
3943 }
3945 int call_lvds_script(struct drm_device *dev, struct dcb_entry *dcbent, int head, enum LVDS_script script, int pxclk)
3946 {
3947 /*
3948 * LVDS operations are multiplexed in an effort to present a single API
3949 * which works with two vastly differing underlying structures.
3950 * This acts as the demux
3951 */
3966 }
3975 /* don't let script change pll->head binding */
3980 else
3987 /* some scripts set a value in NV_PBUS_POWERCTRL_2 and break video overlay */
3991 }
3995 };
3997 static int parse_lvds_manufacturer_table_header(struct drm_device *dev, struct nvbios *bios, struct lvdstableheader *lth)
3998 {
3999 /*
4000 * BMP version (0xa) LVDS table has a simple header of version and
4001 * record length. The BIT LVDS table has the typical BIT table header:
4002 * version byte, header length byte, record length byte, and a byte for
4003 * the maximum number of records that can be held in the table.
4004 */
4013 }
4027 }
4035 }
4043 }
4050 }
4052 static int
4054 {
4057 /*
4058 * The fp strap is normally dictated by the "User Strap" in
4059 * PEXTDEV_BOOT_0[20:16], but on BMP cards when bit 2 of the
4060 * Internal_Flags struct at 0x48 is set, the user strap gets overriden
4061 * by the PCI subsystem ID during POST, but not before the previous user
4062 * strap has been committed to CR58 for CR57=0xf on head A, which may be
4063 * read and used instead
4064 */
4071 else
4073 }
4076 {
4083 /* Apple cards don't have the fp table; the laptops use DDC */
4084 /* The table is also missing on some x86 IGPs */
4085 #ifndef __powerpc__
4087 #endif
4090 }
4096 /*
4097 * BMP version 0x5.0x11 BIOSen have version 1 like tables, but no
4098 * version field, and miss one of the spread spectrum/PWM bytes.
4099 * This could affect early GF2Go parts (not seen any appropriate ROMs
4100 * though). Here we assume that a version of 0x05 matches this case
4101 * (combining with a BMP version check would be better), as the
4102 * common case for the panel type field is 0x0005, and that is in
4103 * fact what we are reading the first byte of.
4104 */
4117 /*
4118 * fptable[4] is the minimum
4119 * RAMDAC_FP_HCRTC -> RAMDAC_FP_HSYNC_START gap
4120 */
4129 }
4142 }
4146 }
4156 }
4158 /* nv4x cards need both a strap value and fpindex of 0xf to use DDC */
4162 /*
4163 * If either the strap or xlated fpindex value are 0xf there is no
4164 * panel using a strap-derived bios mode present. this condition
4165 * includes, but is different from, the DDC panel indicator above
4166 */
4179 }
4182 {
4191 /*
4192 * For version 1.0 (version in byte 0):
4193 * bytes 1-2 are "panel type", including bits on whether Colour/mono,
4194 * single/dual link, and type (TFT etc.)
4195 * bytes 3-6 are bits per colour in RGBX
4196 */
4198 /* bytes 9-10 is HActive */
4200 /*
4201 * bytes 13-14 is HValid Start
4202 * bytes 15-16 is HValid End
4203 */
4207 /* bytes 23-24, 27-30 similarly, but vertical */
4216 /*
4217 * bytes 38-39 relate to spread spectrum settings
4218 * bytes 40-43 are something to do with PWM
4219 */
4225 }
4227 int nouveau_bios_parse_lvds_table(struct drm_device *dev, int pxclk, bool *dl, bool *if_is_24bit)
4228 {
4229 /*
4230 * The LVDS table header is (mostly) described in
4231 * parse_lvds_manufacturer_table_header(): the BIT header additionally
4232 * contains the dual-link transition pxclk (in 10s kHz), at byte 5 - if
4233 * straps are not being used for the panel, this specifies the frequency
4234 * at which modes should be set up in the dual link style.
4235 *
4236 * Following the header, the BMP (ver 0xa) table has several records,
4237 * indexed by a separate xlat table, indexed in turn by the fp strap in
4238 * EXTDEV_BOOT. Each record had a config byte, followed by 6 script
4239 * numbers for use by INIT_SUB which controlled panel init and power,
4240 * and finally a dword of ms to sleep between power off and on
4241 * operations.
4242 *
4243 * In the BIT versions, the table following the header serves as an
4244 * integrated config and xlat table: the records in the table are
4245 * indexed by the FP strap nibble in EXTDEV_BOOT, and each record has
4246 * two bytes - the first as a config byte, the second for indexing the
4247 * fp mode table pointed to by the BIT 'D' table
4248 *
4249 * DDC is not used until after card init, so selecting the correct table
4250 * entry and setting the dual link flag for EDID equipped panels,
4251 * requiring tests against the native-mode pixel clock, cannot be done
4252 * until later, when this function should be called with non-zero pxclk
4253 */
4269 fpstrapping];
4271 /* we're done if this isn't the EDID panel case */
4276 /* nv17 behaviour
4277 *
4278 * It seems the old style lvds script pointer is reused
4279 * to select 18/24 bit colour depth for EDID panels.
4280 */
4281 lvdsmanufacturerindex =
4285 lvdsmanufacturerindex++;
4287 /* nv28 behaviour (off-chip encoder)
4288 *
4289 * nv28 does a complex dance of first using byte 121 of
4290 * the EDID to choose the lvdsmanufacturerindex, then
4291 * later attempting to match the EDID manufacturer and
4292 * product IDs in a table (signature 'pidt' (panel id
4293 * table?)), setting an lvdsmanufacturerindex of 0 and
4294 * an fp strap of the match index (or 0xf if none)
4295 */
4298 /* nv31, nv34 behaviour */
4304 }
4306 /*
4307 * nvidia set the high nibble of (cr57=f, cr58) to
4308 * lvdsmanufacturerindex in this case; we don't
4309 */
4318 }
4320 lvdsofs = bios->fp.xlated_entry = bios->fp.lvdsmanufacturerpointer + lth.headerlen + lth.recordlen * lvdsmanufacturerindex;
4331 /*
4332 * No sign of the "power off for reset" or "reset for panel
4333 * on" bits, but it's safer to assume we should
4334 */
4338 /*
4339 * It's ok lvdsofs is wrong for nv4x edid case; dual_link is
4340 * over-written, and if_is_24bit isn't used
4341 */
4345 bios->fp.duallink_transition_clk = ROM16(bios->data[bios->fp.lvdsmanufacturerpointer + 5]) * 10;
4347 }
4349 /* Dell Latitude D620 reports a too-high value for the dual-link
4350 * transition freq, causing us to program the panel incorrectly.
4351 *
4352 * It doesn't appear the VBIOS actually uses its transition freq
4353 * (90000kHz), instead it uses the "Number of LVDS channels" field
4354 * out of the panel ID structure (http://www.spwg.org/).
4355 *
4356 * For the moment, a quirk will do :)
4357 */
4361 /* set dual_link flag for EDID case */
4368 }
4374 {
4389 }
4401 }
4416 }
4419 }
4424 {
4432 }
4439 }
4445 }
4447 int
4450 {
4451 /*
4452 * The display script table is located by the BIT 'U' table.
4453 *
4454 * It contains an array of pointers to various tables describing
4455 * a particular output type. The first 32-bits of the output
4456 * tables contains similar information to a DCB entry, and is
4457 * used to decide whether that particular table is suitable for
4458 * the output you want to access.
4459 *
4460 * The "record header length" field here seems to indicate the
4461 * offset of the first configuration entry in the output tables.
4462 * This is 10 on most cards I've seen, but 12 has been witnessed
4463 * on DP cards, and there's another script pointer within the
4464 * header.
4465 *
4466 * offset + 0 ( 8 bits): version
4467 * offset + 1 ( 8 bits): header length
4468 * offset + 2 ( 8 bits): record length
4469 * offset + 3 ( 8 bits): number of records
4470 * offset + 4 ( 8 bits): record header length
4471 * offset + 5 (16 bits): pointer to first output script table
4472 */
4484 }
4486 /*
4487 * Nothing useful has been in any of the pre-2.0 tables I've seen,
4488 * so until they are, we really don't need to care.
4489 */
4497 }
4499 /*
4500 * The output script tables describing a particular output type
4501 * look as follows:
4502 *
4503 * offset + 0 (32 bits): output this table matches (hash of DCB)
4504 * offset + 4 ( 8 bits): unknown
4505 * offset + 5 ( 8 bits): number of configurations
4506 * offset + 6 (16 bits): pointer to some script
4507 * offset + 8 (16 bits): pointer to some script
4508 *
4509 * headerlen == 10
4510 * offset + 10 : configuration 0
4511 *
4512 * headerlen == 12
4513 * offset + 10 : pointer to some script
4514 * offset + 12 : configuration 0
4515 *
4516 * Each config entry is as follows:
4517 *
4518 * offset + 0 (16 bits): unknown, assumed to be a match value
4519 * offset + 2 (16 bits): pointer to script table (clock set?)
4520 * offset + 4 (16 bits): pointer to script table (reset?)
4521 *
4522 * There doesn't appear to be a count value to say how many
4523 * entries exist in each script table, instead, a 0 value in
4524 * the first 16-bit word seems to indicate both the end of the
4525 * list and the default entry. The second 16-bit word in the
4526 * script tables is a pointer to the script to execute.
4527 */
4537 }
4540 /* Try to find matching script table entry */
4544 }
4551 }
4552 }
4559 }
4569 }
4577 else
4582 }
4594 }
4606 }
4610 }
4613 }
4617 {
4618 /*
4619 * the pxclk parameter is in kHz
4620 *
4621 * This runs the TMDS regs setting code found on BIT bios cards
4622 *
4623 * For ffs(or) == 1 use the first table, for ffs(or) == 2 and
4624 * ffs(or) == 3, use the second.
4625 */
4633 /* pre-nv17 off-chip tmds uses scripts, post nv17 doesn't */
4646 }
4651 }
4658 }
4660 /* don't let script change pll->head binding */
4667 }
4670 u8 type;
4671 u32 reg;
4672 };
4679 {}
4680 };
4687 {}
4688 };
4700 {}
4701 };
4711 {}
4712 };
4714 u32
4716 {
4724 else
4735 }
4738 }
4742 else
4744 }
4749 map++;
4750 }
4753 }
4756 {
4757 /*
4758 * PLL limits table
4759 *
4760 * Version 0x10: NV30, NV31
4761 * One byte header (version), one record of 24 bytes
4762 * Version 0x11: NV36 - Not implemented
4763 * Seems to have same record style as 0x10, but 3 records rather than 1
4764 * Version 0x20: Found on Geforce 6 cards
4765 * Trivial 4 byte BIT header. 31 (0x1f) byte record length
4766 * Version 0x21: Found on Geforce 7, 8 and some Geforce 6 cards
4767 * 5 byte header, fifth byte of unknown purpose. 35 (0x23) byte record
4768 * length in general, some (integrated) have an extra configuration byte
4769 * Version 0x30: Found on Geforce 8, separates the register mapping
4770 * from the limits tables.
4771 */
4784 }
4789 /* open coded dev->twoHeads test */
4793 crystal_strap_mask;
4796 /*
4797 * We use version 0 to indicate a pre limit table bios (single stage
4798 * pll) and load the hard coded limits instead.
4799 */
4804 /*
4805 * Strictly v0x11 has 3 entries, but the last two don't seem
4806 * to get used.
4807 */
4825 }
4827 /* initialize all members to zero */
4830 /* if we were passed a type rather than a register, figure
4831 * out the register and store it
4832 */
4839 }
4852 /* these values taken from nv30/31/36 */
4860 /*
4861 * On nv30, 31, 36 (i.e. all cards with two stage PLLs with this
4862 * table version (apart from nv35)), N2 is compared to
4863 * maxN2 (0x46) and 10 * maxM2 (0x4), so set maxN2 to 0x28 and
4864 * save a comparison
4865 */
4868 /* only 5 bits available for N2 on nv30/35 */
4879 /*
4880 * First entry is default match, if nothing better. warn if
4881 * reg field nonzero
4882 */
4891 }
4897 }
4904 /*
4905 * Frequencies are stored in tables in MHz, kHz are more
4906 * useful, so we convert.
4907 */
4909 /* What output frequencies can each VCO generate? */
4915 /* What input frequencies they accept (past the m-divider)? */
4921 /* What values are accepted as multiplier and divider? */
4933 /* pll decoding in nv_hw.c assumes never > 7 */
4948 /* C51 special not seen elsewhere */
4956 else
4958 }
4959 }
4972 }
4973 }
4979 }
5012 }
5013 }
5019 }
5031 /* where did this go to?? */
5034 else
5036 }
5038 /*
5039 * By now any valid limit table ought to have set a max frequency for
5040 * vco1, so if it's zero it's either a pre limit table bios, or one
5041 * with an empty limit table (seen on nv18)
5042 */
5052 /* nv05 does this, nv11 doesn't, nv10 unknown */
5060 }
5063 else
5066 }
5082 }
5101 }
5108 }
5112 }
5115 {
5116 /*
5117 * offset + 0 (8 bits): Micro version
5118 * offset + 1 (8 bits): Minor version
5119 * offset + 2 (8 bits): Chip version
5120 * offset + 3 (8 bits): Major version
5121 */
5128 }
5131 {
5132 /*
5133 * Parses the init table segment for pointers used in script execution.
5134 *
5135 * offset + 0 (16 bits): init script tables pointer
5136 * offset + 2 (16 bits): macro index table pointer
5137 * offset + 4 (16 bits): macro table pointer
5138 * offset + 6 (16 bits): condition table pointer
5139 * offset + 8 (16 bits): io condition table pointer
5140 * offset + 10 (16 bits): io flag condition table pointer
5141 * offset + 12 (16 bits): init function table pointer
5142 */
5151 }
5153 static int parse_bit_A_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5154 {
5155 /*
5156 * Parses the load detect values for g80 cards.
5157 *
5158 * offset + 0 (16 bits): loadval table pointer
5159 */
5167 }
5174 }
5182 }
5191 }
5193 /* First entry is normal dac, 2nd tv-out perhaps? */
5197 }
5199 static int parse_bit_C_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5200 {
5201 /*
5202 * offset + 8 (16 bits): PLL limits table pointer
5203 *
5204 * There's more in here, but that's unknown.
5205 */
5210 }
5215 }
5217 static int parse_bit_display_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5218 {
5219 /*
5220 * Parses the flat panel table segment that the bit entry points to.
5221 * Starting at bitentry->offset:
5222 *
5223 * offset + 0 (16 bits): ??? table pointer - seems to have 18 byte
5224 * records beginning with a freq.
5225 * offset + 2 (16 bits): mode table pointer
5226 */
5231 }
5236 }
5238 static int parse_bit_init_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5239 {
5240 /*
5241 * Parses the init table segment that the bit entry points to.
5242 *
5243 * See parse_script_table_pointers for layout
5244 */
5249 }
5259 }
5261 static int parse_bit_i_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5262 {
5263 /*
5264 * BIT 'i' (info?) table
5265 *
5266 * offset + 0 (32 bits): BIOS version dword (as in B table)
5267 * offset + 5 (8 bits): BIOS feature byte (same as for BMP?)
5268 * offset + 13 (16 bits): pointer to table containing DAC load
5269 * detection comparison values
5270 *
5271 * There's other things in the table, purpose unknown
5272 */
5280 }
5284 /*
5285 * bit 4 seems to indicate a mobile bios (doesn't suffer from BMP's
5286 * Quadro identity crisis), other bits possibly as for BMP feature byte
5287 */
5295 }
5299 /* doesn't exist on g80 */
5303 /*
5304 * The first value in the table, following the header, is the
5305 * comparison value, the second entry is a comparison value for
5306 * TV load detection.
5307 */
5316 }
5322 }
5324 static int parse_bit_lvds_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5325 {
5326 /*
5327 * Parses the LVDS table segment that the bit entry points to.
5328 * Starting at bitentry->offset:
5329 *
5330 * offset + 0 (16 bits): LVDS strap xlate table pointer
5331 */
5336 }
5338 /*
5339 * No idea if it's still called the LVDS manufacturer table, but
5340 * the concept's close enough.
5341 */
5345 }
5347 static int
5350 {
5351 /*
5352 * offset + 2 (8 bits): number of options in an
5353 * INIT_RAM_RESTRICT_ZM_REG_GROUP opcode option set
5354 * offset + 3 (16 bits): pointer to strap xlate table for RAM
5355 * restrict option selection
5356 *
5357 * There's a bunch of bits in this table other than the RAM restrict
5358 * stuff that we don't use - their use currently unknown
5359 */
5361 /*
5362 * Older bios versions don't have a sufficiently long table for
5363 * what we want
5364 */
5374 }
5377 }
5379 static int parse_bit_tmds_tbl_entry(struct drm_device *dev, struct nvbios *bios, struct bit_entry *bitentry)
5380 {
5381 /*
5382 * Parses the pointer to the TMDS table
5383 *
5384 * Starting at bitentry->offset:
5385 *
5386 * offset + 0 (16 bits): TMDS table pointer
5387 *
5388 * The TMDS table is typically found just before the DCB table, with a
5389 * characteristic signature of 0x11,0x13 (1.1 being version, 0x13 being
5390 * length?)
5391 *
5392 * At offset +7 is a pointer to a script, which I don't know how to
5393 * run yet.
5394 * At offset +9 is a pointer to another script, likewise
5395 * Offset +11 has a pointer to a table where the first word is a pxclk
5396 * frequency and the second word a pointer to a script, which should be
5397 * run if the comparison pxclk frequency is less than the pxclk desired.
5398 * This repeats for decreasing comparison frequencies
5399 * Offset +13 has a pointer to a similar table
5400 * The selection of table (and possibly +7/+9 script) is dictated by
5401 * "or" from the DCB.
5402 */
5409 }
5415 }
5420 /* nv50+ has v2.0, but we don't parse it atm */
5424 /*
5425 * These two scripts are odd: they don't seem to get run even when
5426 * they are not stubbed.
5427 */
5437 }
5439 static int
5442 {
5443 /*
5444 * Parses the pointer to the G80 output script tables
5445 *
5446 * Starting at bitentry->offset:
5447 *
5448 * offset + 0 (16 bits): output script table pointer
5449 */
5456 }
5461 }
5463 static int
5466 {
5469 }
5474 };
5476 #define BIT_TABLE(id, funcid) ((struct bit_table){ id, parse_bit_##funcid##_tbl_entry })
5478 int
5480 {
5495 }
5498 }
5501 }
5503 static int
5506 {
5515 }
5517 static int
5519 {
5522 /*
5523 * The only restriction on parsing order currently is having 'i' first
5524 * for use of bios->*_version or bios->feature_byte while parsing;
5525 * functions shouldn't be actually *doing* anything apart from pulling
5526 * data from the image into the bios struct, thus no interdependencies
5527 */
5547 }
5549 static int parse_bmp_structure(struct drm_device *dev, struct nvbios *bios, unsigned int offset)
5550 {
5551 /*
5552 * Parses the BMP structure for useful things, but does not act on them
5553 *
5554 * offset + 5: BMP major version
5555 * offset + 6: BMP minor version
5556 * offset + 9: BMP feature byte
5557 * offset + 10: BCD encoded BIOS version
5558 *
5559 * offset + 18: init script table pointer (for bios versions < 5.10h)
5560 * offset + 20: extra init script table pointer (for bios
5561 * versions < 5.10h)
5562 *
5563 * offset + 24: memory init table pointer (used on early bios versions)
5564 * offset + 26: SDR memory sequencing setup data table
5565 * offset + 28: DDR memory sequencing setup data table
5566 *
5567 * offset + 54: index of I2C CRTC pair to use for CRT output
5568 * offset + 55: index of I2C CRTC pair to use for TV output
5569 * offset + 56: index of I2C CRTC pair to use for flat panel output
5570 * offset + 58: write CRTC index for I2C pair 0
5571 * offset + 59: read CRTC index for I2C pair 0
5572 * offset + 60: write CRTC index for I2C pair 1
5573 * offset + 61: read CRTC index for I2C pair 1
5574 *
5575 * offset + 67: maximum internal PLL frequency (single stage PLL)
5576 * offset + 71: minimum internal PLL frequency (single stage PLL)
5577 *
5578 * offset + 75: script table pointers, as described in
5579 * parse_script_table_pointers
5580 *
5581 * offset + 89: TMDS single link output A table pointer
5582 * offset + 91: TMDS single link output B table pointer
5583 * offset + 95: LVDS single link output A table pointer
5584 * offset + 105: flat panel timings table pointer
5585 * offset + 107: flat panel strapping translation table pointer
5586 * offset + 117: LVDS manufacturer panel config table pointer
5587 * offset + 119: LVDS manufacturer strapping translation table pointer
5588 *
5589 * offset + 142: PLL limits table pointer
5590 *
5591 * offset + 156: minimum pixel clock for LVDS dual link
5592 */
5598 /* load needed defaults in case we can't parse this info */
5614 /*
5615 * Make sure that 0x36 is blank and can't be mistaken for a DCB
5616 * pointer on early versions
5617 */
5621 /*
5622 * Seems that the minor version was 1 for all major versions prior
5623 * to 5. Version 6 could theoretically exist, but I suspect BIT
5624 * happened instead.
5625 */
5630 }
5633 /* nothing that's currently useful in this version */
5641 /* guessed - mem init tables added in this version */
5643 /* don't know if 5.0 exists... */
5645 /* guessed - BMP I2C indices added in version 4*/
5655 /*
5656 * Not sure of version where pll limits came in;
5657 * certainly exist by 0x24 though.
5658 */
5659 /* length not exact: this is long enough to get lvds members */
5662 /*
5663 * Length not exact: this is long enough to get pll limit
5664 * member
5665 */
5667 else
5668 /*
5669 * Length not exact: this is long enough to get dual link
5670 * transition clock.
5671 */
5674 /* checksum */
5678 }
5680 /*
5681 * Bit 4 seems to indicate either a mobile bios or a quadro card --
5682 * mobile behaviour consistent (nv11+), quadro only seen nv18gl-nv36gl
5683 * (not nv10gl), bit 5 that the flat panel tables are present, and
5684 * bit 6 a tv bios.
5685 */
5702 }
5722 }
5728 /*
5729 * Never observed in use with lvds scripts, but is reused for
5730 * 18/24 bit panel interface default for EDID equipped panels
5731 * (if_is_24bit not set directly to avoid any oscillation).
5732 */
5734 }
5739 }
5743 }
5751 }
5754 {
5763 }
5766 }
5770 {
5777 }
5780 }
5784 {
5794 }
5797 }
5799 static void
5801 {
5828 /* No GPIO table present, parse the TVDAC GPIO data. */
5836 }
5842 }
5856 }
5866 }
5872 }
5873 }
5875 no_table:
5876 /* Apple iMac G4 NV18 */
5882 }
5883 }
5884 }
5888 {
5901 }
5903 static enum dcb_connector_type
5905 {
5913 }
5918 else
5924 else
5935 }
5938 }
5940 static void
5942 {
5946 /* Gigabyte NX85T */
5950 }
5951 }
5956 };
5958 static void
5960 {
5971 }
5979 }
5989 else
6006 /* check for known types, fallback to guessing the type
6007 * from attached encoders if we hit an unknown.
6008 */
6026 }
6032 }
6034 }
6035 }
6038 {
6045 }
6049 {
6058 }
6060 static bool
6063 {
6075 /*
6076 * Although the rest of a CRT conf dword is usually
6077 * zeros, mac biosen have stuff there so we must mask
6078 */
6084 {
6090 /*
6091 * The laptop in bug 14567 lies and claims to not use
6092 * straps when it does, so assume all DCB 2.0 laptops
6093 * use straps, until a broken EDID using one is produced
6094 */
6096 /*
6097 * Both 0x4 and 0x8 show up in v2.0 tables; assume they
6098 * mean the same thing (probably wrong, but might work)
6099 */
6109 }
6111 /*
6112 * Until we even try to use these on G8x, it's
6113 * useless reporting unknown bits. They all are.
6114 */
6120 }
6122 }
6124 {
6127 else
6131 }
6145 }
6157 /* weird g80 mobile type that "nv" treats as a terminator */
6162 }
6165 /* Normal entries consist of a single bit, but dual link has
6166 * the next most significant bit set too
6167 */
6172 }
6174 /* unsure what DCB version introduces this, 3.0? */
6179 }
6181 static bool
6184 {
6196 else
6205 }
6228 }
6231 }
6235 {
6241 else
6250 }
6252 static
6254 {
6255 /*
6256 * DCB v2.0 lists each output combination separately.
6257 * Here we merge compatible entries to have fewer outputs, with
6258 * more options
6259 */
6273 /* merge heads field when all other fields the same */
6282 }
6283 }
6284 }
6286 /* Compact entries merged into others out of dcb */
6294 }
6295 newentries++;
6296 }
6299 }
6301 static bool
6303 {
6307 /* Dell Precision M6300
6308 * DCB entry 2: 02025312 00000010
6309 * DCB entry 3: 02026312 00000020
6310 *
6311 * Identical, except apparently a different connector on a
6312 * different SOR link. Not a clue how we're supposed to know
6313 * which one is in use if it even shares an i2c line...
6314 *
6315 * Ignore the connector on the second SOR link to prevent
6316 * nasty problems until this is sorted (assuming it's not a
6317 * VBIOS bug).
6318 */
6322 }
6324 /* GeForce3 Ti 200
6325 *
6326 * DCB reports an LVDS output that should be TMDS:
6327 * DCB entry 1: f2005014 ffffffff
6328 */
6333 }
6334 }
6337 }
6339 static void
6341 {
6345 #ifdef __powerpc__
6346 /* Apple iMac G4 NV17 */
6351 }
6352 #endif
6354 /* Make up some sane defaults */
6365 }
6367 static int
6369 {
6379 /* get the offset from 0x36 */
6384 }
6386 /* this situation likely means a really old card, pre DCB */
6390 }
6394 /* get DCB version */
6414 }
6420 }
6433 }
6435 /*
6436 * v1.4 (some NV15/16, NV11+) seems the same as v1.5, but always
6437 * has the same single (crt) entry, even when tv-out present, so
6438 * the conclusion is this version cannot really be used.
6439 * v1.2 tables (some NV6/10, and NV15+) normally have the same
6440 * 5 entries, which are not specific to the card and so no use.
6441 * v1.2 does have an I2C table that read_dcb_i2c_table can
6442 * handle, but cards exist (nv11 in #14821) with a bad i2c table
6443 * pointer, so use the indices parsed in parse_bmp_structure.
6444 * v1.1 (NV5+, maybe some NV4) is entirely unhelpful
6445 */
6450 }
6459 /*
6460 * Parse the "management" I2C bus, used for hardware
6461 * monitoring and some external TMDS transmitters.
6462 */
6470 }
6471 }
6483 /* seen on an NV11 with DCB v1.5 */
6487 /* seen on an NV17 with DCB v2.0 */
6502 }
6504 /*
6505 * apart for v2.1+ not being known for requiring merging, this
6506 * guarantees dcbent->index is the index of the entry in the rom image
6507 */
6517 }
6519 static void
6521 {
6525 /*
6526 * DCB 3.0 also has the table in most cases, but there are some cards
6527 * where the table is filled with stub entries, and the DCB entriy
6528 * indices are all 0. We don't need the connector indices on pre-G80
6529 * chips (yet?) so limit the use to DCB 4.0 and above.
6530 */
6536 /*
6537 * No known connector info before v3.0, so make it up. the rule here
6538 * is: anything on the same i2c bus is considered to be on the same
6539 * connector. any output without an associated i2c bus is assigned
6540 * its own unique connector index.
6541 */
6543 /*
6544 * Ignore the I2C index for on-chip TV-out, as there
6545 * are cards with bogus values (nv31m in bug 23212),
6546 * and it's otherwise useless.
6547 */
6556 }
6561 }
6563 /* Fake the connector table as well as just connector indices */
6568 }
6569 }
6571 static void
6573 {
6584 }
6585 }
6587 static int load_nv17_hwsq_ucode_entry(struct drm_device *dev, struct nvbios *bios, uint16_t hwsq_offset, int entry)
6588 {
6589 /*
6590 * The header following the "HWSQ" signature has the number of entries,
6591 * and the entry size
6592 *
6593 * An entry consists of a dword to write to the sequencer control reg
6594 * (0x00001304), followed by the ucode bytes, written sequentially,
6595 * starting at reg 0x00001400
6596 */
6606 }
6613 }
6619 /* set sequencer control */
6623 /* write ucode */
6627 /* twiddle NV_PBUS_DEBUG_4 */
6631 }
6635 {
6636 /*
6637 * BMP based cards, from NV17, need a microcode loading to correctly
6638 * control the GPIO etc for LVDS panels
6639 *
6640 * BIT based cards seem to do this directly in the init scripts
6641 *
6642 * The microcode entries are found by the "HWSQ" signature.
6643 */
6653 /* always use entry 0? */
6655 }
6658 {
6680 offset++;
6681 }
6686 }
6688 void
6691 {
6701 }
6704 {
6717 }
6720 {
6734 }
6743 }
6747 }
6749 int
6751 {
6756 /* Reset the BIOS head to 0. */
6765 }
6769 /*
6770 * Runs some additional script seen on G8x VBIOSen. The VBIOS'
6771 * parser will run this right after the init tables, the binary
6772 * driver appears to run it at some point later.
6773 */
6780 }
6787 }
6788 }
6791 }
6793 static void
6795 {
6804 }
6806 static bool
6808 {
6817 }
6826 }
6828 int
6830 {
6852 /* init script execution disabled */
6855 /* ... unless card isn't POSTed already */
6860 }
6868 /* feature_byte on BMP is poor, but init always sets CR4B */
6872 /* all BIT systems need p_f_m_t for digital_min_front_porch */
6876 /* allow subsequent scripts to execute */
6880 }
6882 void
6884 {
6886 }