| blob | f575078e1fa7f4878d06d4777393f3c51c19520f |
1 /* Implements exception handling.
2 Copyright (C) 1989, 1992, 1993, 1994, 1995, 1996, 1997, 1998,
3 1999, 2000, 2001 Free Software Foundation, Inc.
4 Contributed by Mike Stump <mrs@cygnus.com>.
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 2, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING. If not, write to the Free
20 Software Foundation, 59 Temple Place - Suite 330, Boston, MA
21 02111-1307, USA. */
24 /* An exception is an event that can be signaled from within a
25 function. This event can then be "caught" or "trapped" by the
26 callers of this function. This potentially allows program flow to
27 be transferred to any arbitrary code associated with a function call
28 several levels up the stack.
30 The intended use for this mechanism is for signaling "exceptional
31 events" in an out-of-band fashion, hence its name. The C++ language
32 (and many other OO-styled or functional languages) practically
33 requires such a mechanism, as otherwise it becomes very difficult
34 or even impossible to signal failure conditions in complex
35 situations. The traditional C++ example is when an error occurs in
36 the process of constructing an object; without such a mechanism, it
37 is impossible to signal that the error occurs without adding global
38 state variables and error checks around every object construction.
40 The act of causing this event to occur is referred to as "throwing
41 an exception". (Alternate terms include "raising an exception" or
42 "signaling an exception".) The term "throw" is used because control
43 is returned to the callers of the function that is signaling the
44 exception, and thus there is the concept of "throwing" the
45 exception up the call stack.
47 [ Add updated documentation on how to use this. ] */
74 /* Provide defaults for stuff that may not be defined when using
75 sjlj exceptions. */
76 #ifndef EH_RETURN_STACKADJ_RTX
77 #define EH_RETURN_STACKADJ_RTX 0
78 #endif
79 #ifndef EH_RETURN_HANDLER_RTX
80 #define EH_RETURN_HANDLER_RTX 0
81 #endif
82 #ifndef EH_RETURN_DATA_REGNO
83 #define EH_RETURN_DATA_REGNO(N) INVALID_REGNUM
84 #endif
87 /* Nonzero means enable synchronous exceptions for non-call instructions. */
90 /* Protect cleanup actions with must-not-throw regions, with a call
91 to the given failure handler. */
94 /* Return true if type A catches type B. */
97 /* Map a type to a runtime object to match type. */
100 /* A list of labels used for exception handlers. */
101 rtx exception_handler_labels;
107 /* Describe the SjLj_Function_Context structure. */
114 \f
115 /* Describes one exception region. */
116 struct eh_region
117 {
118 /* The immediately surrounding region. */
121 /* The list of immediately contained regions. */
125 /* An identifier for this region. */
128 /* Each region does exactly one thing. */
129 enum eh_region_type
130 {
132 ERT_CLEANUP,
133 ERT_TRY,
134 ERT_CATCH,
135 ERT_ALLOWED_EXCEPTIONS,
136 ERT_MUST_NOT_THROW,
137 ERT_THROW,
138 ERT_FIXUP
141 /* Holds the action to perform based on the preceding type. */
143 /* A list of catch blocks, a surrounding try block,
144 and the label for continuing after a catch. */
149 rtx continue_label;
152 /* The list through the catch handlers, the list of type objects
153 matched, and the list of associated filters. */
157 tree type_list;
158 tree filter_list;
161 /* A tree_list of allowed types. */
163 tree type_list;
167 /* The type given by a call to "throw foo();", or discovered
168 for a throw. */
170 tree type;
173 /* Retain the cleanup expression even after expansion so that
174 we can match up fixup regions. */
176 tree exp;
179 /* The real region (by expression and by pointer) that fixup code
180 should live in. */
182 tree cleanup_exp;
187 /* Entry point for this region's handler before landing pads are built. */
188 rtx label;
190 /* Entry point for this region's handler from the runtime eh library. */
191 rtx landing_pad;
193 /* Entry point for this region's handler from an inner region. */
194 rtx post_landing_pad;
196 /* The RESX insn for handing off control to the next outermost handler,
197 if appropriate. */
198 rtx resume;
199 };
201 /* Used to save exception status for each function. */
202 struct eh_status
203 {
204 /* The tree of all regions for this function. */
207 /* The same information as an indexable array. */
210 /* The most recently open region. */
213 /* This is the region for which we are processing catch blocks. */
216 /* A stack (TREE_LIST) of lists of handlers. The TREE_VALUE of each
217 node is itself a TREE_CHAINed list of handlers for regions that
218 are not yet closed. The TREE_VALUE of each entry contains the
219 handler for the corresponding entry on the ehstack. */
220 tree protect_list;
222 rtx filter;
223 rtx exc_ptr;
228 varray_type ttype_data;
229 varray_type ehspec_data;
230 varray_type action_record_data;
232 struct call_site_record
233 {
234 rtx landing_pad;
240 rtx ehr_stackadj;
241 rtx ehr_handler;
242 rtx ehr_label;
244 rtx sjlj_fc;
245 rtx sjlj_exit_after;
246 };
248 \f
280 tree));
287 static bool sjlj_find_directly_reachable_regions
289 static void sjlj_assign_call_site_values
291 static void sjlj_mark_call_sites
295 static void sjlj_emit_dispatch_table
304 /* The return value of reachable_next_level. */
305 enum reachable_code
306 {
307 /* The given exception is not processed by the given region. */
308 RNL_NOT_CAUGHT,
309 /* The given exception may need processing by the given region. */
310 RNL_MAYBE_CAUGHT,
311 /* The given exception is completely processed by the given region. */
312 RNL_CAUGHT,
313 /* The given exception is completely processed by the runtime. */
314 RNL_BLOCKED
315 };
318 static void add_reachable_handler
321 static enum reachable_code reachable_next_level
335 #ifndef HAVE_AS_LEB128
338 #endif
342 \f
343 /* Routine to see if exception handling is turned on.
344 DO_WARN is non-zero if we want to inform the user that exception
345 handling is turned off.
347 This is used to ensure that -fexceptions has been specified if the
348 compiler tries to use any exception-specific functions. */
350 int
353 {
355 {
358 {
361 }
363 }
365 }
367 \f
368 void
370 {
379 /* Create the SjLj_Function_Context structure. This should match
380 the definition in unwind-sjlj.c. */
382 {
393 integer_type_node);
402 ptr_type_node);
406 ptr_type_node);
409 #ifdef DONT_USE_BUILTIN_SETJMP
410 #ifdef JMP_BUF_SIZE
412 #else
413 /* Should be large enough for most systems, if it is not,
414 JMP_BUF_SIZE should be defined with the proper value. It will
415 also tend to be larger than necessary for most systems, a more
416 optimal port will define JMP_BUF_SIZE. */
418 #endif
419 #else
420 /* This is 2 for builtin_setjmp, plus whatever the target requires
421 via STACK_SAVEAREA_MODE (SAVE_NONLOCAL). */
424 #endif
428 #ifdef DONT_USE_BUILTIN_SETJMP
429 /* We don't know what the alignment requirements of the
430 runtime's jmp_buf has. Overestimate. */
433 #endif
445 /* Cache the interesting field offsets so that we have
446 easy access from rtl. */
447 sjlj_fc_call_site_ofs
450 sjlj_fc_data_ofs
453 sjlj_fc_personality_ofs
456 sjlj_fc_lsda_ofs
459 sjlj_fc_jbuf_ofs
462 }
463 }
465 void
467 {
469 }
471 /* Mark EH for GC. */
473 static void
476 {
481 {
483 /* This can happen if a nested function is inside the body of a region
484 and we do a GC as part of processing it. */
509 }
515 }
517 void
520 {
526 /* If we've called collect_eh_region_array, use it. Otherwise walk
527 the tree non-recursively. */
529 {
531 {
535 }
536 }
538 {
541 {
547 else
548 {
555 }
556 }
557 tree_done:;
558 }
566 {
569 }
577 }
579 void
582 {
586 {
589 {
591 /* Mind we don't free a region struct more than once. */
594 }
596 }
598 {
601 {
605 {
609 }
610 else
611 {
622 }
623 }
624 tree_done:;
625 }
635 }
637 \f
638 /* Start an exception handling region. All instructions emitted
639 after this point are considered to be part of the region until
640 expand_eh_region_end is invoked. */
642 void
644 {
647 rtx note;
652 /* Insert a new blank region as a leaf in the tree. */
657 {
660 }
661 else
662 {
665 }
668 /* Create a note marking the start of this region. */
672 }
674 /* Common code to end a region. Returns the region just ended. */
678 {
680 rtx note;
682 /* Create a note marking the end of this region. */
686 /* Pop. */
690 }
692 /* End an exception handling region for a cleanup. HANDLER is an
693 expression to expand for the cleanup. */
695 void
697 tree handler;
698 {
700 tree protect_cleanup_actions;
701 rtx around_label;
717 /* Give the language a chance to specify an action to be taken if an
718 exception is thrown that would propagate out of the HANDLER. */
719 protect_cleanup_actions
720 = (lang_protect_cleanup_actions
727 /* In case this cleanup involves an inline destructor with a try block in
728 it, we need to save the EH return data registers around it. */
742 /* We need any stack adjustment complete before the around_label. */
745 /* We delay the generation of the _Unwind_Resume until we generate
746 landing pads. We emit a marker here so as to get good control
747 flow data in the meantime. */
748 region->resume
753 }
755 /* End an exception handling region for a try block, and prepares
756 for subsequent calls to expand_start_catch. */
758 void
760 {
774 }
776 /* Begin a catch clause. TYPE is the type caught, a list of such types, or
777 null if this is a catch-all clause. Providing a type list enables to
778 associate the catch region with potentially several exception types, which
779 is useful e.g. for Ada. */
781 void
783 tree type_or_list;
784 {
786 tree type_list;
794 {
795 /* Ensure to always end up with a type list to normalize further
796 processing, then register each type against the runtime types
797 map. */
798 tree type_node;
806 }
820 else
825 }
827 /* End a catch clause. Control will resume after the try/catch block. */
829 void
831 {
841 }
843 /* End a sequence of catch handlers for a try block. */
845 void
847 {
857 }
859 /* End an exception region for an exception type filter. ALLOWED is a
860 TREE_LIST of types to be matched by the runtime. FAILURE is an
861 expression to invoke if a mismatch occurs.
863 ??? We could use these semantics for calls to rethrow, too; if we can
864 see the surrounding catch clause, we know that the exception we're
865 rethrowing satisfies the "filter" of the catch type. */
867 void
870 {
872 rtx around_label;
885 /* We must emit the call to FAILURE here, so that if this function
886 throws a different exception, that it will be processed by the
887 correct region. */
894 /* We must adjust the stack before we reach the AROUND_LABEL because
895 the call to FAILURE does not occur on all paths to the
896 AROUND_LABEL. */
900 }
902 /* End an exception region for a must-not-throw filter. FAILURE is an
903 expression invoke if an uncaught exception propagates this far.
905 This is conceptually identical to expand_eh_region_end_allowed with
906 an empty allowed list (if you passed "std::terminate" instead of
907 "__cxa_call_unexpected"), but they are represented differently in
908 the C++ LSDA. */
910 void
912 tree failure;
913 {
915 rtx around_label;
924 /* We must emit the call to FAILURE here, so that if this function
925 throws a different exception, that it will be processed by the
926 correct region. */
935 }
937 /* End an exception region for a throw. No handling goes on here,
938 but it's the easiest way for the front-end to indicate what type
939 is being thrown. */
941 void
943 tree type;
944 {
953 }
955 /* End a fixup region. Within this region the cleanups for the immediately
956 enclosing region are _not_ run. This is used for goto cleanup to avoid
957 destroying an object twice.
959 This would be an extraordinarily simple prospect, were it not for the
960 fact that we don't actually know what the immediately enclosing region
961 is. This surprising fact is because expand_cleanups is currently
962 generating a sequence that it will insert somewhere else. We collect
963 the proper notion of "enclosing" in convert_from_eh_region_ranges. */
965 void
967 tree handler;
968 {
977 }
979 /* Return an rtl expression for a pointer to the exception object
980 within a handler. */
982 rtx
985 {
988 {
991 }
993 }
995 /* Return an rtl expression for the exception dispatch filter
996 within a handler. */
998 static rtx
1001 {
1004 {
1007 }
1009 }
1010 \f
1011 /* Begin a region that will contain entries created with
1012 add_partial_entry. */
1014 void
1016 {
1017 /* Push room for a new list. */
1020 }
1022 /* Start a new exception region for a region of code that has a
1023 cleanup action and push the HANDLER for the region onto
1024 protect_list. All of the regions created with add_partial_entry
1025 will be ended when end_protect_partials is invoked.
1027 ??? The only difference between this purpose and that of
1028 expand_decl_cleanup is that in this case, we only want the cleanup to
1029 run if an exception is thrown. This should also be handled using
1030 binding levels. */
1032 void
1034 tree handler;
1035 {
1038 /* ??? This comment was old before the most recent rewrite. We
1039 really ought to fix the callers at some point. */
1040 /* For backwards compatibility, we allow callers to omit calls to
1041 begin_protect_partials for the outermost region. So, we must
1042 explicitly do so here. */
1046 /* Add this entry to the front of the list. */
1049 }
1051 /* End all the pending exception regions on protect_list. */
1053 void
1055 {
1056 tree t;
1058 /* ??? This comment was old before the most recent rewrite. We
1059 really ought to fix the callers at some point. */
1060 /* For backwards compatibility, we allow callers to omit the call to
1061 begin_protect_partials for the outermost region. So,
1062 PROTECT_LIST may be NULL. */
1066 /* Pop the topmost entry. */
1070 /* End all the exception regions. */
1073 }
1075 \f
1076 /* This section is for the exception handling specific optimization pass. */
1078 /* Random access the exception region tree. It's just as simple to
1079 collect the regions this way as in expand_eh_region_start, but
1080 without having to realloc memory. */
1082 static void
1084 {
1095 {
1098 /* If there are sub-regions, process them. */
1101 /* If there are peers, process them. */
1104 /* Otherwise, step back up the tree to the next peer. */
1105 else
1106 {
1113 }
1114 }
1115 }
1117 static void
1119 {
1123 {
1131 {
1136 }
1141 }
1142 }
1144 /* Now that we've discovered what region actually encloses a fixup,
1145 we can shuffle pointers and remove them from the tree. */
1147 static void
1149 {
1154 /* Walk the insn chain and adjust the REG_EH_REGION numbers
1155 for instructions referencing fixup regions. This is only
1156 strictly necessary for fixup regions with no parent, but
1157 doesn't hurt to do it for all regions. */
1164 {
1167 else
1169 }
1171 /* Remove the fixup regions from the tree. */
1173 {
1178 /* Allow GC to maybe free some memory. */
1186 {
1191 /* Fix up the children's parent pointers; find the end of
1192 the list. */
1194 {
1198 }
1200 /* In the tree of cleanups, only outer-inner ordering matters.
1201 So link the children back in anywhere at the correct level. */
1204 else
1209 }
1212 }
1213 }
1215 /* Turn NOTE_INSN_EH_REGION notes into REG_EH_REGION notes for each
1216 can_throw instruction in the region. */
1218 static void
1223 {
1228 {
1231 {
1235 {
1237 {
1245 {
1248 }
1250 {
1253 }
1254 }
1255 else
1258 /* Removing the first insn of a CALL_PLACEHOLDER sequence
1259 requires extra care to adjust sequence start. */
1264 }
1265 }
1267 {
1270 /* Calls can always potentially throw exceptions, unless
1271 they have a REG_EH_REGION note with a value of 0 or less.
1272 Which should be the only possible kind so far. */
1274 /* If we wanted exceptions for non-call insns, then
1275 any may_trap_p instruction could throw. */
1276 || (flag_non_call_exceptions
1280 {
1283 }
1287 {
1294 }
1295 }
1296 }
1300 }
1302 void
1304 {
1306 rtx insns;
1317 }
1319 void
1321 {
1331 {
1333 rtx lab;
1339 else
1344 }
1346 /* For sjlj exceptions, need the return label to remain live until
1347 after landing pad generation. */
1352 }
1354 \f
1359 {
1367 {
1392 }
1397 {
1401 }
1404 }
1406 static void
1410 {
1414 {
1429 }
1437 }
1439 int
1443 {
1454 {
1459 }
1461 {
1466 }
1471 {
1474 {
1478 }
1479 else
1485 }
1486 else
1487 {
1490 {
1494 }
1495 else
1497 }
1504 }
1506 \f
1507 static int
1511 {
1516 }
1518 static hashval_t
1521 {
1524 }
1526 static int
1529 PTR data ATTRIBUTE_UNUSED;
1530 {
1534 }
1536 static void
1538 PTR addr;
1539 {
1541 }
1543 static void
1545 tree type;
1546 {
1552 {
1555 }
1556 }
1558 static tree
1560 tree type;
1561 {
1567 /* We should have always inserted the data earlier. */
1569 }
1571 \f
1572 /* Represent an entry in @TTypes for either catch actions
1573 or exception filter actions. */
1574 struct ttypes_filter
1575 {
1576 tree t;
1578 };
1580 /* Compare ENTRY (a ttypes_filter entry in the hash table) with DATA
1581 (a tree) for a @TTypes type node we are thinking about adding. */
1583 static int
1587 {
1592 }
1594 static hashval_t
1597 {
1600 }
1602 /* Compare ENTRY with DATA (both struct ttypes_filter) for a @TTypes
1603 exception specification list we are thinking about adding. */
1604 /* ??? Currently we use the type lists in the order given. Someone
1605 should put these in some canonical order. */
1607 static int
1611 {
1616 }
1618 /* Hash function for exception specification lists. */
1620 static hashval_t
1623 {
1626 tree list;
1631 }
1633 /* Add TYPE to cfun->eh->ttype_data, using TYPES_HASH to speed
1634 up the search. Return the filter value to be used. */
1636 static int
1638 htab_t ttypes_hash;
1639 tree type;
1640 {
1647 {
1648 /* Filter value is a 1 based table index. */
1656 }
1659 }
1661 /* Add LIST to cfun->eh->ehspec_data, using EHSPEC_HASH and TYPES_HASH
1662 to speed up the search. Return the filter value to be used. */
1664 static int
1666 htab_t ehspec_hash;
1667 htab_t ttypes_hash;
1668 tree list;
1669 {
1678 {
1679 /* Filter value is a -1 based byte index into a uleb128 buffer. */
1686 /* Look up each type in the list and encode its filter
1687 value as a uleb128. Terminate the list with 0. */
1692 }
1695 }
1697 /* Generate the action filter values to be used for CATCH and
1698 ALLOWED_EXCEPTIONS regions. When using dwarf2 exception regions,
1699 we use lots of landing pads, and so every type or list can share
1700 the same filter value, which saves table space. */
1702 static void
1704 {
1715 {
1718 /* Mind we don't process a region more than once. */
1723 {
1725 /* Whatever type_list is (NULL or true list), we build a list
1726 of filters for the region. */
1730 {
1731 /* Get a filter value for each of the types caught and store
1732 them in the region's dedicated list. */
1736 {
1742 }
1743 }
1744 else
1745 {
1746 /* Get a filter value for the NULL list also since it will need
1747 an action record anyway. */
1753 }
1764 }
1765 }
1769 }
1771 static void
1773 {
1777 {
1779 rtx seq;
1781 /* Mind we don't process a region more than once. */
1786 {
1788 /* ??? Collect the set of all non-overlapping catch handlers
1789 all the way up the chain until blocked by a cleanup. */
1790 /* ??? Outer try regions can share landing pads with inner
1791 try regions if the types are completely non-overlapping,
1792 and there are no intervening cleanups. */
1800 /* ??? It is mighty inconvenient to call back into the
1801 switch statement generation code in expand_end_case.
1802 Rapid prototyping sez a sequence of ifs. */
1803 {
1806 {
1807 /* ??? _Unwind_ForcedUnwind wants no match here. */
1810 else
1811 {
1812 /* Need for one cmp/jump per type caught. Each type
1813 list entry has a matching entry in the filter list
1814 (see assign_filter_values). */
1819 {
1820 emit_cmp_and_jump_insns
1827 }
1828 }
1829 }
1830 }
1832 /* We delay the generation of the _Unwind_Resume until we generate
1833 landing pads. We emit a marker here so as to get good control
1834 flow data in the meantime. */
1835 region->resume
1856 /* We delay the generation of the _Unwind_Resume until we generate
1857 landing pads. We emit a marker here so as to get good control
1858 flow data in the meantime. */
1859 region->resume
1876 /* Nothing to do. */
1881 }
1882 }
1883 }
1885 /* Replace RESX patterns with jumps to the next handler if any, or calls to
1886 _Unwind_Resume otherwise. */
1888 static void
1890 {
1894 {
1897 rtx seq;
1899 /* Mind we don't process a region more than once. */
1903 /* If there is no RESX, or it has been deleted by flow, there's
1904 nothing to fix up. */
1908 /* Search for another landing pad in this function. */
1917 else
1925 }
1926 }
1928 \f
1929 static void
1931 {
1936 {
1938 rtx seq;
1941 /* Mind we don't process a region more than once. */
1955 #ifdef HAVE_exception_receiver
1958 else
1959 #endif
1960 #ifdef HAVE_nonlocal_goto_receiver
1963 else
1964 #endif
1967 /* If the eh_return data registers are call-saved, then we
1968 won't have considered them clobbered from the call that
1969 threw. Kill them now. */
1971 {
1976 {
1979 }
1980 }
1983 {
1984 /* @@@ This is a kludge. Not all machine descriptions define a
1985 blockage insn, but we must not allow the code we just generated
1986 to be reordered by scheduling. So emit an ASM_INPUT to act as
1987 blockage insn. */
1989 }
2000 }
2001 }
2003 \f
2004 struct sjlj_lp_info
2005 {
2010 };
2012 static bool
2015 {
2016 rtx insn;
2020 {
2023 tree type_thrown;
2024 rtx note;
2037 {
2040 }
2042 /* Find the first containing region that might handle the exception.
2043 That's the landing pad to which we will transfer control. */
2046 {
2050 }
2052 {
2055 }
2056 }
2059 }
2061 static void
2063 rtx dispatch_label;
2065 {
2066 htab_t ar_hash;
2069 /* First task: build the action table. */
2076 {
2082 }
2086 /* Next: assign dispatch values. In dwarf2 terms, this would be the
2087 landing pad label for the region. For sjlj though, there is one
2088 common landing pad from which we dispatch to the post-landing pads.
2090 A region receives a dispatch index if it is directly reachable
2091 and requires in-function processing. Regions that share post-landing
2092 pads may share dispatch indices. */
2093 /* ??? Post-landing pad sharing doesn't actually happen at the moment
2094 (see build_post_landing_pads) so we don't bother checking for it. */
2101 /* Finally: assign call-site values. If dwarf2 terms, this would be
2102 the region number assigned by convert_to_eh_region_ranges, but
2103 handles no-action and must-not-throw differently. */
2108 {
2111 /* Map must-not-throw to otherwise unused call-site index 0. */
2114 /* Map no-action to otherwise unused call-site index -1. */
2117 /* Otherwise, look it up in the table. */
2118 else
2122 }
2123 }
2125 static void
2128 {
2133 {
2138 /* Reset value tracking at extended basic block boundaries. */
2147 {
2148 /* Calls (and trapping insns) without notes are outside any
2149 exception handling region in this function. Mark them as
2150 no action. */
2152 || (flag_non_call_exceptions
2155 else
2157 }
2158 else
2159 {
2160 /* Calls that are known to not throw need not be marked. */
2166 }
2171 /* Don't separate a call from it's argument loads. */
2178 sjlj_fc_call_site_ofs);
2185 }
2186 }
2188 /* Construct the SjLj_Function_Context. */
2190 static void
2192 rtx dispatch_label;
2193 {
2200 /* We're storing this libcall's address into memory instead of
2201 calling it directly. Thus, we must call assemble_external_libcall
2202 here, as we can not depend on emit_library_call to do it for us. */
2209 {
2213 }
2214 else
2217 #ifdef DONT_USE_BUILTIN_SETJMP
2218 {
2230 }
2231 #else
2233 dispatch_label);
2234 #endif
2242 /* ??? Instead of doing this at the beginning of the function,
2243 do this in a block that is at loop level 0 and dominates all
2244 can_throw_internal instructions. */
2251 }
2253 /* Call back from expand_function_end to know where we should put
2254 the call to unwind_sjlj_unregister_libfunc if needed. */
2256 void
2258 rtx after;
2259 {
2261 }
2263 static void
2265 {
2266 rtx seq;
2276 /* ??? Really this can be done in any block at loop level 0 that
2277 post-dominates all can_throw_internal instructions. This is
2278 the last possible moment. */
2281 }
2283 static void
2285 rtx dispatch_label;
2287 {
2297 #ifndef DONT_USE_BUILTIN_SETJMP
2299 #endif
2301 /* Load up dispatch index, exc_ptr and filter values from the
2302 function context. */
2304 sjlj_fc_call_site_ofs);
2309 {
2310 #ifdef POINTERS_EXTEND_UNSIGNED
2312 #else
2314 #endif
2315 }
2321 /* Jump to one of the directly reachable regions. */
2322 /* ??? This really ought to be using a switch statement. */
2326 {
2331 {
2334 }
2339 }
2346 }
2348 static void
2350 {
2357 {
2371 }
2374 }
2376 void
2378 {
2379 /* Nothing to do if no regions created. */
2383 /* The object here is to provide find_basic_blocks with detailed
2384 information (via reachable_handlers) on how exception control
2385 flows within the function. In this first pass, we can include
2386 type information garnered from ERT_THROW and ERT_ALLOWED_EXCEPTIONS
2387 regions, and hope that it will be useful in deleting unreachable
2388 handlers. Subsequently, we will generate landing pads which will
2389 connect many of the handlers, and then type information will not
2390 be effective. Still, this is a win over previous implementations. */
2396 /* These registers are used by the landing pads. Make sure they
2397 have been generated. */
2401 /* Construct the landing pads. */
2408 else
2413 /* We've totally changed the CFG. Start over. */
2418 }
2419 \f
2420 /* This section handles removing dead code for flow. */
2422 /* Remove LABEL from the exception_handler_labels list. */
2424 static void
2426 rtx label;
2427 {
2437 }
2439 /* Splice REGION from the region tree etc. */
2441 static void
2444 {
2446 rtx lab;
2449 /* For the benefit of efficiently handling REG_EH_REGION notes,
2450 replace this region in the region array with its containing
2451 region. Note that previous region deletions may result in
2452 multiple copies of this region in the array, so we have to
2453 search the whole thing. */
2460 else
2467 else
2473 {
2479 }
2480 else
2484 {
2499 else
2503 else
2504 {
2508 }
2509 }
2512 }
2514 /* LABEL heads a basic block that is about to be deleted. If this
2515 label corresponds to an exception region, we may be able to
2516 delete the region. */
2518 void
2520 rtx label;
2521 {
2524 /* ??? After generating landing pads, it's not so simple to determine
2525 if the region data is completely unused. One must examine the
2526 landing pad and the post landing pad, and whether an inner try block
2527 is referencing the catch handlers directly. */
2532 {
2535 {
2536 /* Flow will want to remove MUST_NOT_THROW regions as unreachable
2537 because there is no path to the fallback call to terminate.
2538 But the region continues to affect call-site data until there
2539 are no more contained calls, which we don't see here. */
2541 {
2544 }
2545 else
2548 }
2549 }
2550 }
2552 \f
2553 /* This section describes CFG exception edges for flow. */
2555 /* For communicating between calls to reachable_next_level. */
2556 struct reachable_info
2557 {
2558 tree types_caught;
2559 tree types_allowed;
2560 rtx handlers;
2561 };
2563 /* A subroutine of reachable_next_level. Return true if TYPE, or a
2564 base class of TYPE, is in HANDLED. */
2566 static int
2569 {
2570 tree t;
2572 /* We can check for exact matches without front-end help. */
2574 {
2578 }
2579 else
2580 {
2584 }
2587 }
2589 /* A subroutine of reachable_next_level. If we are collecting a list
2590 of handlers, add one. After landing pad generation, reference
2591 it instead of the handlers themselves. Further, the handlers are
2592 all wired together, so by referencing one, we've got them all.
2593 Before landing pad generation we reference each handler individually.
2595 LP_REGION contains the landing pad; REGION is the handler. */
2597 static void
2602 {
2607 {
2610 }
2611 else
2613 }
2615 /* Process one level of exception regions for reachability.
2616 If TYPE_THROWN is non-null, then it is the *exact* type being
2617 propagated. If INFO is non-null, then collect handler labels
2618 and caught/allowed type information between invocations. */
2620 static enum reachable_code
2623 tree type_thrown;
2625 {
2627 {
2629 /* Before landing-pad generation, we model control flow
2630 directly to the individual handlers. In this way we can
2631 see that catch handler types may shadow one another. */
2636 {
2641 {
2642 /* A catch-all handler ends the search. */
2643 /* ??? _Unwind_ForcedUnwind will want outer cleanups
2644 to be run as well. */
2646 {
2649 }
2652 {
2653 /* If we have a at least one type match, end the search. */
2657 {
2661 || (lang_eh_type_covers
2663 {
2666 }
2667 }
2669 /* If we have definitive information of a match failure,
2670 the catch won't trigger. */
2673 }
2675 /* At this point, we either don't know what type is thrown or
2676 don't have front-end assistance to help deciding if it is
2677 covered by one of the types in the list for this region.
2679 We'd then like to add this region to the list of reachable
2680 handlers since it is indeed potentially reachable based on the
2681 information we have.
2683 Actually, this handler is for sure not reachable if all the
2684 types it matches have already been caught. That is, it is only
2685 potentially reachable if at least one of the types it catches
2686 has not been previously caught. */
2690 else
2691 {
2695 /* Compute the potential reachability of this handler and
2696 update the list of types caught at the same time. */
2698 {
2702 {
2703 info->types_caught
2707 }
2708 }
2711 {
2714 /* ??? If the catch type is a base class of every allowed
2715 type, then we know we can stop the search. */
2717 }
2718 }
2719 }
2722 }
2725 /* An empty list of types definitely ends the search. */
2727 {
2730 }
2732 /* Collect a list of lists of allowed types for use in detecting
2733 when a catch may be transformed into a catch-all. */
2739 /* If we have definitive information about the type hierarchy,
2740 then we can tell if the thrown type will pass through the
2741 filter. */
2743 {
2746 else
2747 {
2750 }
2751 }
2757 /* Catch regions are handled by their controling try region. */
2761 /* Here we end our search, since no exceptions may propagate.
2762 If we've touched down at some landing pad previous, then the
2763 explicit function call we generated may be used. Otherwise
2764 the call is made by the runtime. */
2766 {
2769 }
2770 else
2776 /* Shouldn't see these here. */
2778 }
2781 }
2783 /* Retrieve a list of labels of exception handlers which can be
2784 reached by a given insn. */
2786 rtx
2788 rtx insn;
2789 {
2792 tree type_thrown;
2798 else
2799 {
2804 }
2813 {
2814 /* A RESX leaves a region instead of entering it. Thus the
2815 region itself may have been deleted out from under us. */
2819 }
2821 {
2824 }
2831 }
2833 /* Determine if the given INSN can throw an exception that is caught
2834 within the function. */
2836 bool
2838 rtx insn;
2839 {
2841 tree type_thrown;
2842 rtx note;
2853 {
2856 {
2861 }
2863 }
2865 /* Every insn that might throw has an EH_REGION note. */
2874 {
2877 }
2879 /* If this exception is ignored by each and every containing region,
2880 then control passes straight out. The runtime may handle some
2881 regions, which also do not require processing internally. */
2883 {
2889 }
2892 }
2894 /* Determine if the given INSN can throw an exception that is
2895 visible outside the function. */
2897 bool
2899 rtx insn;
2900 {
2902 tree type_thrown;
2903 rtx note;
2914 {
2917 {
2922 }
2924 }
2928 {
2929 /* Calls (and trapping insns) without notes are outside any
2930 exception handling region in this function. We have to
2931 assume it might throw. Given that the front end and middle
2932 ends mark known NOTHROW functions, this isn't so wildly
2933 inaccurate. */
2935 || (flag_non_call_exceptions
2937 }
2945 {
2948 }
2950 /* If the exception is caught or blocked by any containing region,
2951 then it is not seen by any calling function. */
2957 }
2959 /* True if nothing in this function can throw outside this function. */
2961 bool
2963 {
2964 rtx insn;
2978 }
2980 \f
2981 /* Various hooks for unwind library. */
2983 /* Do any necessary initialization to access arbitrary stack frames.
2984 On the SPARC, this means flushing the register windows. */
2986 void
2988 {
2989 /* Set this so all the registers get saved in our frame; we need to be
2990 able to copy the saved values for any registers from frames we unwind. */
2993 #ifdef SETUP_FRAME_ADDRESSES
2995 #endif
2996 }
2998 rtx
3000 tree arglist;
3001 {
3006 {
3009 }
3016 #ifdef DWARF_FRAME_REGNUM
3018 #else
3020 #endif
3023 }
3025 /* Given a value extracted from the return address register or stack slot,
3026 return the actual address encoded in that value. */
3028 rtx
3030 tree addr_tree;
3031 {
3034 /* First mask out any unwanted bits. */
3035 #ifdef MASK_RETURN_ADDR
3037 #endif
3039 /* Then adjust to find the real return address. */
3040 #if defined (RETURN_ADDR_OFFSET)
3042 #endif
3045 }
3047 /* Given an actual address in addr_tree, do any necessary encoding
3048 and return the value to be stored in the return address register or
3049 stack slot so the epilogue will return to that address. */
3051 rtx
3053 tree addr_tree;
3054 {
3057 #ifdef POINTERS_EXTEND_UNSIGNED
3060 #endif
3062 #ifdef RETURN_ADDR_OFFSET
3065 #endif
3068 }
3070 /* Set up the epilogue with the magic bits we'll need to return to the
3071 exception handler. */
3073 void
3076 {
3082 #ifdef POINTERS_EXTEND_UNSIGNED
3088 #endif
3091 {
3095 }
3096 else
3097 {
3102 }
3105 }
3107 void
3109 {
3117 {
3120 }
3131 #ifdef HAVE_eh_return
3134 else
3135 #endif
3136 {
3139 {
3142 }
3146 }
3149 }
3150 \f
3151 /* In the following functions, we represent entries in the action table
3152 as 1-based indices. Special cases are:
3154 0: null action record, non-null landing pad; implies cleanups
3155 -1: null action record, null landing pad; implies no action
3156 -2: no call-site entry; implies must_not_throw
3157 -3: we have yet to process outer regions
3159 Further, no special cases apply to the "next" field of the record.
3160 For next, 0 means end of list. */
3162 struct action_record
3163 {
3167 };
3169 static int
3173 {
3177 }
3179 static hashval_t
3182 {
3185 }
3187 static int
3189 htab_t ar_hash;
3191 {
3199 {
3206 /* The filter value goes in untouched. The link to the next
3207 record is a "self-relative" byte offset, or zero to indicate
3208 that there is no next record. So convert the absolute 1 based
3209 indices we've been carrying around into a displacement. */
3215 }
3218 }
3220 static int
3222 htab_t ar_hash;
3224 {
3228 /* If we've reached the top of the region chain, then we have
3229 no actions, and require no landing pad. */
3234 {
3236 /* A cleanup adds a zero filter to the beginning of the chain, but
3237 there are special cases to look out for. If there are *only*
3238 cleanups along a path, then it compresses to a zero action.
3239 Further, if there are multiple cleanups along a path, we only
3240 need to represent one of them, as that is enough to trigger
3241 entry to the landing pad at runtime. */
3251 /* Process the associated catch regions in reverse order.
3252 If there's a catch-all handler, then we don't need to
3253 search outer regions. Use a magic -3 value to record
3254 that we haven't done the outer search. */
3257 {
3259 {
3260 /* Retrieve the filter from the head of the filter list
3261 where we have stored it (see assign_filter_values). */
3262 int filter
3266 }
3267 else
3268 {
3269 /* Once the outer search is done, trigger an action record for
3270 each filter we have. */
3271 tree flt_node;
3274 {
3277 /* If there is no next action, terminate the chain. */
3280 /* If all outer actions are cleanups or must_not_throw,
3281 we'll have no action record for it, since we had wanted
3282 to encode these states in the call-site record directly.
3283 Add a cleanup action to the chain to catch these. */
3286 }
3290 {
3293 }
3294 }
3295 }
3299 /* An exception specification adds its filter to the
3300 beginning of the chain. */
3306 /* A must-not-throw region with no inner handlers or cleanups
3307 requires no call-site entry. Note that this differs from
3308 the no handler or cleanup case in that we do require an lsda
3309 to be generated. Return a magic -2 value to record this. */
3314 /* CATCH regions are handled in TRY above. THROW regions are
3315 for optimization information only and produce no output. */
3320 }
3321 }
3323 static int
3325 rtx landing_pad;
3327 {
3333 {
3339 }
3347 }
3349 /* Turn REG_EH_REGION notes back into NOTE_INSN_EH_REGION notes.
3350 The new note numbers will not refer to region numbers, but
3351 instead to call site entries. */
3353 void
3355 {
3357 htab_t ar_hash;
3373 {
3376 rtx this_landing_pad;
3385 {
3387 || (flag_non_call_exceptions
3392 }
3393 else
3394 {
3399 }
3401 /* Existence of catch handlers, or must-not-throw regions
3402 implies that an lsda is needed (even if empty). */
3406 /* Delay creation of region notes for no-action regions
3407 until we're sure that an lsda will be required. */
3409 {
3412 }
3414 /* Cleanups and handlers may share action chains but not
3415 landing pads. Collect the landing pad for this region. */
3417 {
3422 }
3423 else
3426 /* Differing actions or landing pads implies a change in call-site
3427 info, which implies some EH_REGION note should be emitted. */
3430 {
3431 /* If we'd not seen a previous action (-3) or the previous
3432 action was must-not-throw (-2), then we do not need an
3433 end note. */
3435 {
3436 /* If we delayed the creation of the begin, do it now. */
3438 {
3441 first_no_action_insn);
3444 }
3447 last_action_insn);
3449 }
3451 /* If the new action is must-not-throw, then no region notes
3452 are created. */
3454 {
3459 }
3463 }
3465 }
3468 {
3471 }
3474 }
3476 \f
3477 static void
3481 {
3482 do
3483 {
3489 }
3491 }
3493 static void
3497 {
3501 do
3502 {
3510 }
3512 }
3514 \f
3515 #ifndef HAVE_AS_LEB128
3516 static int
3518 {
3524 {
3527 }
3530 }
3532 static int
3534 {
3540 {
3544 }
3547 }
3548 #endif
3550 static void
3552 {
3559 {
3572 /* ??? Perhaps use insn length scaling if the assembler supports
3573 generic arithmetic. */
3574 /* ??? Perhaps use attr_length to choose data1 or data2 instead of
3575 data4 if the function is small enough. */
3576 #ifdef HAVE_AS_LEB128
3584 else
3586 #else
3593 else
3595 #endif
3597 }
3600 }
3602 static void
3604 {
3609 {
3615 }
3618 }
3620 void
3622 {
3624 #ifdef HAVE_AS_LEB128
3628 #else
3630 #endif
3635 /* Not all functions need anything. */
3639 funcdef_number = (USING_SJLJ_EXCEPTIONS
3640 ? sjlj_funcdef_number
3643 #ifdef IA64_UNWIND_INFO
3647 /* Note that varasm still thinks we're in the function's code section.
3648 The ".endp" directive that will immediately follow will take us back. */
3649 #else
3651 #endif
3656 /* Indicate the format of the @TType entries. */
3659 else
3660 {
3662 #ifdef HAVE_AS_LEB128
3664 #endif
3668 }
3672 /* The LSDA header. */
3674 /* Indicate the format of the landing pad start pointer. An omitted
3675 field implies @LPStart == @Start. */
3676 /* Currently we always put @LPStart == @Start. This field would
3677 be most useful in moving the landing pads completely out of
3678 line to another section, but it could also be used to minimize
3679 the size of uleb128 landing pad offsets. */
3684 /* @LPStart pointer would go here. */
3689 #ifndef HAVE_AS_LEB128
3692 else
3694 #endif
3696 /* A pc-relative 4-byte displacement to the @TType data. */
3698 {
3699 #ifdef HAVE_AS_LEB128
3702 funcdef_number);
3706 #else
3707 /* Ug. Alignment queers things. */
3712 + call_site_len
3718 do
3719 {
3727 else
3730 }
3734 #endif
3735 }
3737 /* Indicate the format of the call-site offsets. */
3738 #ifdef HAVE_AS_LEB128
3740 #else
3742 #endif
3746 #ifdef HAVE_AS_LEB128
3748 funcdef_number);
3750 funcdef_number);
3756 else
3759 #else
3763 else
3765 #endif
3767 /* ??? Decode and interpret the data for flag_debug_asm. */
3778 {
3780 rtx value;
3784 else
3791 else
3793 }
3795 #ifdef HAVE_AS_LEB128
3798 #endif
3800 /* ??? Decode and interpret the data for flag_debug_asm. */
3810 }