| blob | 5ad723898076ea22b678e26b04d5fd950562c4ea |
1 /* Routines to link ECOFF debugging information.
2 Copyright (C) 1993-2022 Free Software Foundation, Inc.
3 Written by Ian Lance Taylor, Cygnus Support, <ian@cygnus.com>.
5 This file is part of BFD, the Binary File Descriptor library.
7 This program is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3 of the License, or
10 (at your option) any later version.
12 This program is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with this program; if not, write to the Free Software
19 Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston,
20 MA 02110-1301, USA. */
35 \f
36 /* Routines to swap auxiliary information in and out. I am assuming
37 that the auxiliary information format is always going to be target
38 independent. */
40 /* Swap in a type information record.
41 BIGEND says whether AUX symbols are big-endian or little-endian; this
42 info comes from the file header record (fh-fBigendian). */
44 void
47 {
52 /* now the fun stuff... */
54 {
71 }
72 else
73 {
90 }
92 #ifdef TEST
95 #endif
96 }
98 /* Swap out a type information record.
99 BIGEND says whether AUX symbols are big-endian or little-endian; this
100 info comes from the file header record (fh-fBigendian). */
102 void
106 {
111 /* now the fun stuff... */
113 {
130 }
131 else
132 {
149 }
151 #ifdef TEST
154 #endif
155 }
157 /* Swap in a relative symbol record. BIGEND says whether it is in
158 big-endian or little-endian format.*/
160 void
164 {
169 /* now the fun stuff... */
171 {
179 }
180 else
181 {
190 }
192 #ifdef TEST
195 #endif
196 }
198 /* Swap out a relative symbol record. BIGEND says whether it is in
199 big-endian or little-endian format.*/
201 void
205 {
210 /* now the fun stuff... */
212 {
220 }
221 else
222 {
230 }
232 #ifdef TEST
235 #endif
236 }
237 \f
238 /* The minimum amount of data to allocate. */
239 #define ALLOC_SIZE (4064)
241 /* Add bytes to a buffer. Return success. */
243 static bool
245 {
253 else
254 {
258 }
265 }
267 /* We keep a hash table which maps strings to numbers. We use it to
268 map FDR names to indices in the output file, and to map local
269 strings when combining stabs debugging information. */
271 struct string_hash_entry
272 {
274 /* FDR index or string table offset. */
276 /* Next entry in string table. */
278 };
280 struct string_hash_table
281 {
283 };
285 /* Routine to create an entry in a string hash table. */
291 {
294 /* Allocate the structure if it has not already been allocated by a
295 subclass. */
302 /* Call the allocation method of the superclass. */
307 {
308 /* Initialize the local fields. */
311 }
314 }
316 /* Look up an entry in an string hash table. */
318 #define string_hash_lookup(t, string, create, copy) \
319 ((struct string_hash_entry *) \
320 bfd_hash_lookup (&(t)->table, (string), (create), (copy)))
322 /* We can't afford to read in all the debugging information when we do
323 a link. Instead, we build a list of these structures to show how
324 different parts of the input file map to the output file. */
326 struct shuffle
327 {
328 /* The next entry in this linked list. */
330 /* The length of the information. */
332 /* Whether this information comes from a file or not. */
334 union
335 {
336 struct
337 {
338 /* The BFD the data comes from. */
340 /* The offset within input_bfd. */
341 file_ptr offset;
343 /* The data to be written out. */
346 };
348 /* This structure holds information across calls to
349 bfd_ecoff_debug_accumulate. */
351 struct accumulate
352 {
353 /* The FDR hash table. */
355 /* The strings hash table. */
357 /* Linked lists describing how to shuffle the input debug
358 information into the output file. We keep a pointer to both the
359 head and the tail. */
378 /* The size of the largest file shuffle. */
380 /* An objalloc for debugging information. */
382 };
384 /* Add a file entry to a shuffle list. */
386 static bool
391 file_ptr offset,
393 {
400 {
401 /* Just merge this entry onto the existing one. */
406 }
411 {
414 }
428 }
430 /* Add a memory entry to a shuffle list. */
432 static bool
438 {
444 {
447 }
458 }
460 /* Initialize the FDR hash table. This returns a handle which is then
461 passed in to bfd_ecoff_debug_accumulate, et. al. */
468 {
501 {
506 /* The first entry in the string table is the empty string. */
508 }
512 {
515 }
518 }
520 /* Free the accumulated debugging information. */
522 void
528 {
539 }
541 /* Accumulate the debugging information from INPUT_BFD into
542 OUTPUT_BFD. The INPUT_DEBUG argument points to some ECOFF
543 debugging information which we want to link into the information
544 pointed to by the OUTPUT_DEBUG argument. OUTPUT_SWAP and
545 INPUT_SWAP point to the swapping information needed. INFO is the
546 linker information structure. HANDLE is returned by
547 bfd_ecoff_debug_init. */
549 bool
558 {
582 bfd_size_type fdr_add;
584 RFDT i;
592 bfd_size_type amt;
594 /* Use section_adjust to hold the value to add to a symbol in a
595 particular section. */
598 #define SET(name, indx) \
599 sec = bfd_get_section_by_name (input_bfd, name); \
600 if (sec != NULL) \
601 section_adjust[indx] = (sec->output_section->vma \
602 + sec->output_offset \
603 - sec->vma);
610 /* scRdata section may be either .rdata or .rodata. */
617 #undef SET
619 /* Find all the debugging information based on the FDR's. We need
620 to handle them whether they are swapped or not. */
622 {
625 }
626 else
627 {
630 }
640 {
643 }
649 /* Look through the FDR's to see which ones we are going to include
650 in the final output. We do not want duplicate FDR information
651 for header files, because ECOFF debugging is often very large.
652 When we find an FDR with no line information which can be merged,
653 we look it up in a hash table to ensure that we only include it
654 once. We keep a table mapping FDR numbers to the final number
655 they get with the BFD, so that we can refer to it when we write
656 out the external symbols. */
660 {
661 FDR fdr;
665 else
668 /* See if this FDR can be merged with an existing one. */
670 {
675 /* We look up a string formed from the file name and the
676 number of symbols and aux entries. Sometimes an include
677 file will conditionally define a typedef or something
678 based on the order of include files. Using the number of
679 symbols and aux entries as a hash reduces the chance that
680 we will merge symbol information that should not be
681 merged. */
696 {
700 /* Don't copy this FDR. */
702 }
705 }
710 }
715 /* Copy over any existing RFD's. RFD's are only created by the
716 linker, so this will only happen for input files which are the
717 result of a partial link. */
723 {
724 RFDT rfd;
731 }
736 /* Look through the FDR's and copy over all associated debugging
737 information. */
741 {
744 }
750 {
751 FDR fdr;
758 {
759 /* We are not copying this FDR. */
761 }
765 else
768 /* FIXME: It is conceivable that this FDR points to the .init or
769 .fini section, in which case this will not do the right
770 thing. */
773 /* Swap in the local symbols, adjust their values, and swap them
774 out again. */
779 {
782 }
784 sz))
790 {
791 SYMR internal_sym;
798 /* Adjust the symbol value if appropriate. */
800 {
804 /* Fall through. */
815 }
817 /* If we are doing a final link, we hash all the strings in
818 the local symbol table together. This reduces the amount
819 of space required by debugging information. We don't do
820 this when performing a relocatable link because it would
821 prevent us from easily merging different FDR's. */
823 {
829 else
832 /* Hash the name into the string table. */
836 else
837 {
844 {
853 }
855 }
858 {
861 }
862 }
866 }
871 /* Copy the information that does not need swapping. */
873 /* FIXME: If we are relaxing, we need to adjust the line
874 numbers. Frankly, forget it. Anybody using stabs debugging
875 information will not use this line number information, and
876 stabs are adjusted correctly. */
878 {
887 }
889 {
898 }
900 {
902 /* When we are hashing strings, we lie about the number of
903 strings attached to each FDR. We need to set cbSs
904 because some versions of dbx apparently use it to decide
905 how much of the string table to read in. */
908 }
910 {
917 }
921 {
922 /* The two BFD's have the same endianness, and we don't have
923 to adjust the PDR addresses, so simply copying the
924 information will suffice. */
927 {
934 }
937 {
944 }
945 }
946 else
947 {
953 /* The two BFD's have different endianness, so we must swap
954 everything in and out. This code would always work, but
955 it would be unnecessarily slow in the normal case. */
964 {
967 }
969 sz))
972 {
973 PDR pdr;
977 }
979 /* Swap over the optimization information. */
988 {
991 }
993 sz))
996 {
997 OPTR opt;
1001 }
1002 }
1010 {
1011 /* Point this FDR at the table of RFD's we created. */
1014 }
1015 else
1016 {
1017 /* Point this FDR at the remapped RFD's. */
1019 }
1024 }
1027 }
1029 /* Add a string to the debugging information we are accumulating.
1030 Return the offset from the fdr string base. */
1032 static long
1038 {
1041 bfd_size_type ret;
1046 {
1053 }
1054 else
1055 {
1062 {
1071 }
1073 }
1076 }
1078 /* Add debugging information from a non-ECOFF file. */
1080 bool
1087 {
1092 FDR fdr;
1106 else
1107 {
1108 /* FIXME: What about .init or .fini? */
1110 }
1120 /* Get the local symbols from the input BFD. */
1132 /* Handle the local symbols. Any external symbols are handled
1133 separately. */
1136 {
1137 SYMR internal_sym;
1151 else
1162 {
1165 }
1172 }
1176 /* Leave everything else in the FDR zeroed out. This will cause
1177 the lang field to be langC. The fBigendian field will
1178 indicate little endian format, but it doesn't matter because
1179 it only applies to aux fields and there are none. */
1183 {
1186 }
1195 }
1197 /* Set up ECOFF debugging information for the external symbols.
1198 FIXME: This is done using a memory buffer, but it should be
1199 probably be changed to use a shuffle structure. The assembler uses
1200 this interface, so that must be changed to do something else. */
1202 bool
1209 {
1219 {
1221 EXTR esym;
1225 /* Get the external symbol information. */
1229 /* If we're producing an executable, move common symbols into
1230 bss. */
1232 {
1237 }
1242 {
1243 /* FIXME: gas does not keep the value of a small undefined
1244 symbol in the symbol itself, because of relocation
1245 problems. */
1250 }
1251 else
1262 }
1265 }
1267 /* Add a single external symbol to the debugging information. */
1269 bool
1275 {
1286 {
1291 }
1295 {
1304 }
1318 }
1320 /* Align the ECOFF debugging information. */
1322 static void
1326 {
1331 /* Adjust the counts so that structures are aligned. */
1338 {
1342 }
1346 {
1350 }
1354 {
1358 }
1362 {
1367 }
1371 {
1377 }
1378 }
1380 /* Return the size required by the ECOFF debugging information. */
1382 bfd_size_type
1386 {
1387 bfd_size_type tot;
1392 #define ADD(count, size) \
1393 tot += debug->symbolic_header.count * size
1407 #undef ADD
1410 }
1412 /* Write out the ECOFF symbolic header, given the file position it is
1413 going to be placed at. This assumes that the counts are set
1414 correctly. */
1416 static bool
1420 file_ptr where)
1421 {
1427 /* Go to the right location in the file. */
1435 /* Fill in the file offsets. */
1436 #define SET(offset, count, size) \
1437 if (symhdr->count == 0) \
1438 symhdr->offset = 0; \
1439 else \
1440 { \
1441 symhdr->offset = where; \
1442 where += symhdr->count * size; \
1443 }
1456 #undef SET
1469 error_return:
1472 }
1474 /* Write out the ECOFF debugging information. This function assumes
1475 that the information (the pointers and counts) in *DEBUG have been
1476 set correctly. WHERE is the position in the file to write the
1477 information to. This function fills in the file offsets in the
1478 symbolic header. */
1480 bool
1484 file_ptr where)
1485 {
1491 #define WRITE(ptr, count, size, offset) \
1492 BFD_ASSERT (symhdr->offset == 0 \
1493 || (bfd_vma) bfd_tell (abfd) == symhdr->offset); \
1494 if (symhdr->count != 0 \
1495 && bfd_bwrite (debug->ptr, \
1496 (bfd_size_type) size * symhdr->count, \
1497 abfd) != size * symhdr->count) \
1498 return false;
1506 cbAuxOffset);
1512 #undef WRITE
1515 }
1517 /* Write out a shuffle list. */
1520 static bool
1525 {
1531 {
1533 {
1537 }
1538 else
1539 {
1545 }
1547 }
1550 {
1560 {
1563 }
1565 }
1568 }
1570 /* Write out debugging information using accumulated linker
1571 information. */
1573 bool
1579 file_ptr where)
1580 {
1583 bfd_size_type amt;
1600 /* The string table is written out from the hash table if this is a
1601 final link. */
1603 {
1607 }
1608 else
1609 {
1611 bfd_byte null;
1623 {
1631 }
1634 {
1644 {
1647 }
1649 }
1650 }
1652 /* The external strings and symbol are not converted over to using
1653 shuffles. FIXME: They probably should be. */
1658 {
1669 {
1672 }
1674 }
1691 error_return:
1694 }
1695 \f
1696 /* Handle the find_nearest_line function for both ECOFF and MIPS ELF
1697 files. */
1699 /* Compare FDR entries. This is called via qsort. */
1701 static int
1703 {
1714 }
1716 /* Each file descriptor (FDR) has a memory address, to simplify
1717 looking up an FDR by address, we build a table covering all FDRs
1718 that have a least one procedure descriptor in them. The final
1719 table will be sorted by address so we can look it up via binary
1720 search. */
1722 static bool
1727 {
1734 bfd_size_type amt;
1739 /* First, let's see how long the table needs to be. */
1741 {
1745 }
1747 /* Now, create and fill in the table. */
1756 {
1760 /* Check whether this file has stabs debugging information. In
1761 a file with stabs debugging information, the second local
1762 symbol is named @stabs. */
1765 {
1767 SYMR sym;
1775 }
1778 {
1779 /* eraxxon: There are at least two problems with this computation:
1780 1) PDRs do *not* contain offsets but full vma's; and typically the
1781 address of the first PDR is the address of the FDR, which will
1782 make (most) of the results of the original computation 0!
1783 2) Once in a wacky while, the Compaq compiler generated PDR
1784 addresses do not equal the FDR vma, but they (the PDR address)
1785 are still vma's and not offsets. Cf. comments in
1786 'lookup_line'. */
1787 /* The address of the first PDR is the offset of that
1788 procedure relative to the beginning of file FDR. */
1790 }
1791 else
1792 {
1793 /* XXX I don't know about stabs, so this is a guess
1794 (davidm@cs.arizona.edu). */
1796 }
1799 }
1801 /* Finally, the table is sorted in increasing memory-address order.
1802 The table is mostly sorted already, but there are cases (e.g.,
1803 static functions in include files), where this does not hold.
1804 Use "odump -PFv" to verify... */
1809 }
1811 /* Return index of first FDR that covers to OFFSET. */
1813 static long
1815 {
1826 {
1833 else
1835 }
1837 /* eraxxon: at this point 'offset' is either lower than the lowest entry or
1838 higher than the highest entry. In the former case high = low = mid = 0;
1839 we want to return -1. In the latter case, low = high and mid = low - 1;
1840 we want to return the index of the highest entry. Only in former case
1841 will the following 'catch-all' test be true. */
1844 /* Last entry is catch-all for all higher addresses. */
1848 find_min:
1850 /* eraxxon: There may be multiple FDRs in the table with the
1851 same base_addr; make sure that we are at the first one. */
1856 }
1858 /* Look up a line given an address, storing the information in
1859 LINE_INFO->cache. */
1861 static bool
1866 {
1868 bfd_vma offset;
1873 /* eraxxon: note that 'offset' is the full vma, not a section offset. */
1876 /* Build FDR table (sorted by object file's base-address) if we
1877 don't have it already. */
1884 /* Find first FDR for address OFFSET. */
1889 /* eraxxon: 'fdrtab_lookup' doesn't give what we want, at least for Compaq's
1890 C++ compiler 6.2. Consider three FDRs with starting addresses of x, y,
1891 and z, respectively, such that x < y < z. Assume further that
1892 y < 'offset' < z. It is possible at times that the PDR for 'offset' is
1893 associated with FDR x and *not* with FDR y. Erg!!
1895 From a binary dump of my C++ test case 'moo' using Compaq's coffobjanl
1896 (output format has been edited for our purposes):
1898 FDR [2]: (main.C): First instruction: 0x12000207c <x>
1899 PDR [5] for File [2]: LoopTest__Xv <0x1200020a0> (a)
1900 PDR [7] for File [2]: foo__Xv <0x120002168>
1901 FDR [1]: (-1): First instruction: 0x1200020e8 <y>
1902 PDR [3] for File [1]: <0x120001ad0> (b)
1903 FDR [6]: (-1): First instruction: 0x1200026f0 <z>
1905 (a) In the case of PDR5, the vma is such that the first few instructions
1906 of the procedure can be found. But since the size of this procedure is
1907 160b, the vma will soon cross into the 'address space' of FDR1 and no
1908 debugging info will be found. How repugnant!
1910 (b) It is also possible for a PDR to have a *lower* vma than its associated
1911 FDR; see FDR1 and PDR3. Gross!
1913 Since the FDRs that are causing so much havok (in this case) 1) do not
1914 describe actual files (fdr.rss == -1), and 2) contain only compiler
1915 generated routines, I thought a simple fix would be to exclude them from
1916 the FDR table in 'mk_fdrtab'. But, besides not knowing for certain
1917 whether this would be correct, it creates an additional problem. If we
1918 happen to ask for source file info on a compiler generated (procedure)
1919 symbol -- which is still in the symbol table -- the result can be
1920 information from a real procedure! This is because compiler generated
1921 procedures with vma's higher than the last FDR in the fdr table will be
1922 associated with a PDR from this FDR, specifically the PDR with the
1923 highest vma. This wasn't a problem before, because each procedure had a
1924 PDR. (Yes, this problem could be eliminated if we kept the size of the
1925 last PDR around, but things are already getting ugly).
1927 Probably, a better solution would be to have a sorted PDR table. Each
1928 PDR would have a pointer to its FDR so file information could still be
1929 obtained. A FDR table could still be constructed if necessary -- since
1930 it only contains pointers, not much extra memory would be used -- but
1931 the PDR table would be searched to locate debugging info.
1933 There is still at least one remaining issue. Sometimes a FDR can have a
1934 bogus name, but contain PDRs that should belong to another FDR with a
1935 real name. E.g:
1937 FDR [3]: 0000000120001b50 (/home/.../Array.H~alt~deccxx_5E5A62AD)
1938 PDR [a] for File [3]: 0000000120001b50
1939 PDR [b] for File [3]: 0000000120001cf0
1940 PDR [c] for File [3]: 0000000120001dc8
1941 PDR [d] for File [3]: 0000000120001e40
1942 PDR [e] for File [3]: 0000000120001eb8
1943 PDR [f] for File [3]: 0000000120001f4c
1944 FDR [4]: 0000000120001b50 (/home/.../Array.H)
1946 Here, FDR4 has the correct name, but should (seemingly) contain PDRa-f.
1947 The symbol table for PDR4 does contain symbols for PDRa-f, but so does
1948 the symbol table for FDR3. However the former is different; perhaps this
1949 can be detected easily. (I'm not sure at this point.) This problem only
1950 seems to be associated with files with templates. I am assuming the idea
1951 is that there is a 'fake' FDR (with PDRs) for each differently typed set
1952 of templates that must be generated. Currently, FDR4 is completely
1953 excluded from the FDR table in 'mk_fdrtab' because it contains no PDRs.
1955 Since I don't have time to prepare a real fix for this right now, be
1956 prepared for 'A Horrible Hack' to force the inspection of all non-stabs
1957 FDRs. It's coming... */
1960 /* Check whether this file has stabs debugging information. In a
1961 file with stabs debugging information, the second local symbol is
1962 named @stabs. */
1965 {
1967 SYMR sym;
1975 }
1978 {
1979 bfd_size_type external_pdr_size;
1984 PDR pdr;
1988 /* This file uses ECOFF debugging information. Each FDR has a
1989 list of procedure descriptors (PDR). The address in the FDR
1990 is the absolute address of the first procedure. The address
1991 in the first PDR gives the offset of that procedure relative
1992 to the object file's base-address. The addresses in
1993 subsequent PDRs specify each procedure's address relative to
1994 the object file's base-address. To make things more juicy,
1995 whenever the PROF bit in the PDR is set, the real entry point
1996 of the procedure may be 16 bytes below what would normally be
1997 the procedure's entry point. Instead, DEC came up with a
1998 wicked scheme to create profiled libraries "on the fly":
1999 instead of shipping a regular and a profiled version of each
2000 library, they insert 16 bytes of unused space in front of
2001 each procedure and set the "prof" bit in the PDR to indicate
2002 that there is a gap there (this is done automagically by "as"
2003 when option "-pg" is specified). Thus, normally, you link
2004 against such a library and, except for lots of 16 byte gaps
2005 between functions, things will behave as usual. However,
2006 when invoking "ld" with option "-pg", it will fill those gaps
2007 with code that calls mcount(). It then moves the function's
2008 entry point down by 16 bytes, and out pops a binary that has
2009 all functions profiled.
2011 NOTE: Neither FDRs nor PDRs are strictly sorted in memory
2012 order. For example, when including header-files that
2013 define functions, the FDRs follow behind the including
2014 file, even though their code may have been generated at
2015 a lower address. File coff-alpha.c from libbfd
2016 illustrates this (use "odump -PFv" to look at a file's
2017 FDR/PDR). Similarly, PDRs are sometimes out of order
2018 as well. An example of this is OSF/1 v3.0 libc's
2019 malloc.c. I'm not sure why this happens, but it could
2020 be due to optimizations that reorder a function's
2021 position within an object-file.
2023 Strategy:
2025 On the first call to this function, we build a table of FDRs
2026 that is sorted by the base-address of the object-file the FDR
2027 is referring to. Notice that each object-file may contain
2028 code from multiple source files (e.g., due to code defined in
2029 include files). Thus, for any given base-address, there may
2030 be multiple FDRs (but this case is, fortunately, uncommon).
2031 lookup(addr) guarantees to return the first FDR that applies
2032 to address ADDR. Thus, after invoking lookup(), we have a
2033 list of FDRs that may contain the PDR for ADDR. Next, we
2034 walk through the PDRs of these FDRs and locate the one that
2035 is closest to ADDR (i.e., for which the difference between
2036 ADDR and the PDR's entry point is positive and minimal).
2037 Once, the right FDR and PDR are located, we simply walk
2038 through the line-number table to lookup the line-number that
2039 best matches ADDR. Obviously, things could be sped up by
2040 keeping a sorted list of PDRs instead of a sorted list of
2041 FDRs. However, this would increase space requirements
2042 considerably, which is undesirable. */
2045 /* eraxxon: The Horrible Hack: Because of the problems above, set 'i'
2046 to 0 so we look through all FDRs.
2048 Because FDR's without any symbols are assumed to be non-stabs,
2049 searching through all FDRs may cause the following code to try to
2050 read stabs FDRs as ECOFF ones. However, I don't think this will
2051 harm anything. */
2054 /* Search FDR list starting at tab[i] for the PDR that best matches
2055 OFFSET. Normally, the FDR list is only one entry long. */
2057 do
2058 {
2059 /* eraxxon: 'dist' and 'min_dist' can be negative now
2060 because we iterate over every FDR rather than just ones
2061 with a base address less than or equal to 'offset'. */
2072 /* Find PDR that is closest to OFFSET. If pdr.prof is set,
2073 the procedure entry-point *may* be 0x10 below pdr.adr. We
2074 simply pretend that pdr.prof *implies* a lower entry-point.
2075 This is safe because it just means that may identify 4 NOPs
2076 in front of the function as belonging to the function. */
2081 {
2083 {
2086 /* eraxxon: 'dist' can be negative now. Note that
2087 'min_dist' can be negative if 'pdr_hold' below is NULL. */
2089 {
2092 }
2093 }
2094 }
2097 {
2101 }
2102 /* Continue looping until base_addr of next entry is different. */
2103 }
2104 /* eraxxon: We want to iterate over all FDRs.
2105 See previous comment about 'fdrtab_lookup'. */
2111 /* Phew, finally we got something that we can hold onto. */
2115 /* Now we can look for the actual line number. The line numbers
2116 are stored in a very funky format, which I won't try to
2117 describe. The search is bounded by the end of the FDRs line
2118 number entries. */
2121 /* Make offset relative to procedure entry. */
2126 {
2136 {
2141 }
2144 {
2147 }
2149 }
2151 /* If fdr_ptr->rss is -1, then this file does not have full
2152 symbols, at least according to gdb/mipsread.c. */
2154 {
2158 else
2159 {
2160 EXTR proc_ext;
2169 }
2170 }
2171 else
2172 {
2173 SYMR proc_sym;
2187 }
2191 }
2192 else
2193 {
2194 bfd_size_type external_sym_size;
2200 bfd_vma low_func_vma;
2201 bfd_vma low_line_vma;
2208 /* This file uses stabs debugging information. When gcc is not
2209 optimizing, it will put the line number information before
2210 the function name stabs entry. When gcc is optimizing, it
2211 will put the stabs entry for all the function first, followed
2212 by the line number information. (This appears to happen
2213 because of the two output files used by the -mgpopt switch,
2214 which is implied by -O). This means that we must keep
2215 looking through the symbols until we find both a line number
2216 and a function name which are beyond the address we want. */
2240 {
2241 SYMR sym;
2246 {
2248 {
2253 /* Check the next symbol to see if it is also an
2254 N_SO symbol. */
2256 {
2257 SYMR nextsym;
2264 {
2269 }
2270 }
2274 current_file_name =
2282 {
2284 function_name =
2286 }
2288 }
2289 }
2291 {
2295 {
2299 }
2300 }
2301 }
2306 /* We need to remove the stuff after the colon in the function
2307 name. We also need to put the directory name and the file
2308 name together. */
2311 else
2320 {
2326 }
2329 {
2337 }
2340 {
2343 else
2344 {
2346 main_file_name);
2348 }
2349 }
2350 }
2353 }
2355 /* Do the work of find_nearest_line. */
2357 bool
2360 bfd_vma offset,
2367 {
2374 {
2379 {
2382 }
2383 }
2390 }
2391 \f
2392 /* These routines copy symbolic information into a memory buffer.
2394 FIXME: The whole point of the shuffle code is to avoid storing
2395 everything in memory, since the linker is such a memory hog. This
2396 code makes that effort useless. It is only called by the MIPS ELF
2397 code when generating a shared library, so it is not that big a
2398 deal, but it should be fixed eventually. */
2400 /* Collect a shuffle into a memory buffer. */
2402 static bool
2404 {
2406 {
2409 else
2410 {
2415 }
2417 }
2420 }
2422 /* Copy PDR information into a memory buffer. */
2424 bool
2427 {
2431 }
2433 /* Copy symbol information into a memory buffer. */
2435 bool
2437 {
2441 }
2443 /* Copy the string table into a memory buffer. */
2445 bool
2447 {
2451 /* The string table is written out from the hash table if this is a
2452 final link. */
2459 {
2465 }
2468 }