| blob | 2027357fd6329ba327677cbfe54b8a95b6df0537 |
1 /* SCC value numbering for trees
2 Copyright (C) 2006, 2007, 2008, 2009
3 Free Software Foundation, Inc.
4 Contributed by Daniel Berlin <dan@dberlin.org>
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3, or (at your option)
11 any later version.
13 GCC is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
49 /* This algorithm is based on the SCC algorithm presented by Keith
50 Cooper and L. Taylor Simpson in "SCC-Based Value numbering"
51 (http://citeseer.ist.psu.edu/41805.html). In
52 straight line code, it is equivalent to a regular hash based value
53 numbering that is performed in reverse postorder.
55 For code with cycles, there are two alternatives, both of which
56 require keeping the hashtables separate from the actual list of
57 value numbers for SSA names.
59 1. Iterate value numbering in an RPO walk of the blocks, removing
60 all the entries from the hashtable after each iteration (but
61 keeping the SSA name->value number mapping between iterations).
62 Iterate until it does not change.
64 2. Perform value numbering as part of an SCC walk on the SSA graph,
65 iterating only the cycles in the SSA graph until they do not change
66 (using a separate, optimistic hashtable for value numbering the SCC
67 operands).
69 The second is not just faster in practice (because most SSA graph
70 cycles do not involve all the variables in the graph), it also has
71 some nice properties.
73 One of these nice properties is that when we pop an SCC off the
74 stack, we are guaranteed to have processed all the operands coming from
75 *outside of that SCC*, so we do not need to do anything special to
76 ensure they have value numbers.
78 Another nice property is that the SCC walk is done as part of a DFS
79 of the SSA graph, which makes it easy to perform combining and
80 simplifying operations at the same time.
82 The code below is deliberately written in a way that makes it easy
83 to separate the SCC walk from the other work it does.
85 In order to propagate constants through the code, we track which
86 expressions contain constants, and use those while folding. In
87 theory, we could also track expressions whose value numbers are
88 replaced, in case we end up folding based on expression
89 identities.
91 In order to value number memory, we assign value numbers to vuses.
92 This enables us to note that, for example, stores to the same
93 address of the same value from the same starting memory states are
94 equivalent.
95 TODO:
97 1. We can iterate only the changing portions of the SCC's, but
98 I have not seen an SCC big enough for this to be a win.
99 2. If you differentiate between phi nodes for loops and phi nodes
100 for if-then-else, you can properly consider phi nodes in different
101 blocks for equivalence.
102 3. We could value number vuses in more cases, particularly, whole
103 structure copies.
104 */
106 /* The set of hashtables and alloc_pool's for their items. */
109 {
110 htab_t nary;
111 htab_t phis;
112 htab_t references;
114 alloc_pool phis_pool;
115 alloc_pool references_pool;
122 /* Valid hashtables storing information we have proven to be
123 correct. */
127 /* Optimistic hashtables storing information we are making assumptions about
128 during iterations. */
132 /* Pointer to the set of hashtables that is currently being used.
133 Should always point to either the optimistic_info, or the
134 valid_info. */
139 /* Reverse post order index for each basic block. */
143 #define SSA_VAL(x) (VN_INFO ((x))->valnum)
145 /* This represents the top of the VN lattice, which is the universal
146 value. */
148 tree VN_TOP;
150 /* Unique counter for our value ids. */
154 /* Next DFS number and the stack for strongly connected component
155 detection. */
166 /* Table of vn_ssa_aux_t's, one per ssa_name. The vn_ssa_aux_t objects
167 are allocated on an obstack for locality reasons, and to free them
168 without looping over the VEC. */
173 /* Return the value numbering information for a given SSA name. */
175 vn_ssa_aux_t
177 {
182 }
184 /* Set the value numbering info for a given SSA name to a given
185 value. */
189 {
192 }
194 /* Initialize the value numbering info for a given SSA name.
195 This should be called just once for every SSA name. */
197 vn_ssa_aux_t
199 {
200 vn_ssa_aux_t newinfo;
210 }
213 /* Get the representative expression for the SSA_NAME NAME. Returns
214 the representative SSA_NAME if there is no expression associated with it. */
216 tree
218 {
220 gimple def_stmt;
226 /* If the value-number is a constant it is the representative
227 expression. */
231 /* Get to the information of the value of this SSA_NAME. */
234 /* If the value-number is a constant it is the representative
235 expression. */
239 /* Else if we have an expression, return it. */
243 /* Otherwise use the defining statement to build the expression. */
246 /* If the value number is a default-definition or a PHI result
247 use it directly. */
255 /* FIXME tuples. This is incomplete and likely will miss some
256 simplifications. */
258 {
283 }
287 /* Cache the expression. */
291 }
294 /* Free a phi operation structure VP. */
296 static void
298 {
301 }
303 /* Free a reference operation structure VP. */
305 static void
307 {
310 }
312 /* Hash table equality function for vn_constant_t. */
314 static int
316 {
324 }
326 /* Hash table hash function for vn_constant_t. */
328 static hashval_t
330 {
333 }
335 /* Lookup a value id for CONSTANT and return it. If it does not
336 exist returns 0. */
338 unsigned int
340 {
351 }
353 /* Lookup a value id for CONSTANT, and if it does not exist, create a
354 new one and return it. If it does exist, return it. */
356 unsigned int
358 {
367 {
370 }
375 }
377 /* Return true if V is a value id for a constant. */
379 bool
381 {
383 }
385 /* Compare two reference operands P1 and P2 for equality. Return true if
386 they are equal, and false otherwise. */
388 static int
390 {
399 }
401 /* Compute the hash for a reference operand VRO1. */
403 static hashval_t
405 {
414 }
416 /* Return the hashcode for a given reference operation P1. */
418 static hashval_t
420 {
423 }
425 /* Compute a hash for the reference operation VR1 and return it. */
427 hashval_t
429 {
430 hashval_t result;
432 vn_reference_op_t vro;
439 }
441 /* Return true if reference operations P1 and P2 are equivalent. This
442 means they have the same set of operands and vuses. */
444 int
446 {
448 vn_reference_op_t vro;
455 /* Early out if this is not a hash collision. */
459 /* The VOP needs to be the same. */
463 /* If the operands are the same we are done. */
467 /* We require that address operands be canonicalized in a way that
468 two memory references will have the same operands if they are
469 equivalent. */
476 vro))
480 }
482 /* Copy the operations present in load/store REF into RESULT, a vector of
483 vn_reference_op_s's. */
485 void
487 {
489 {
490 vn_reference_op_s temp;
491 tree base;
498 /* We do not care for spurious type qualifications. */
513 }
515 /* For non-calls, store the information that makes up the address. */
518 {
519 vn_reference_op_s temp;
522 /* We do not care for spurious type qualifications. */
527 {
530 /* The only operand is the address, which gets its own
531 vn_reference_op_s structure. */
537 /* Record bits and position. */
542 /* The field decl is enough to unambiguously specify the field,
543 a matching type is not necessary and a mismatching type
544 is always a spurious difference. */
548 /* If this is a reference to a union member, record the union
549 member size as operand. Do so only if we are doing
550 expression insertion (during FRE), as PRE currently gets
551 confused with this. */
562 /* Record index as operand. */
564 /* Always record lower bounds and element size. */
583 {
586 }
587 /* Fallthrough. */
588 /* These are only interesting for their operands, their
589 existence, and their type. They will never be the last
590 ref in the chain of references (IE they require an
591 operand), so we don't have to put anything
592 for op* as it will be handled by the iteration */
599 }
606 else
608 }
609 }
611 /* Build a alias-oracle reference abstraction in *REF from the vn_reference
612 operands in *OPS, the reference alias set SET and the reference type TYPE.
613 Return true if something useful was produced. */
615 bool
619 {
620 vn_reference_op_t op;
625 HOST_WIDE_INT max_size;
629 /* First get the final access size from just the outermost expression. */
632 {
635 else
637 }
640 else
641 {
645 else
647 }
649 {
652 else
654 }
656 /* Initially, maxsize is the same as the accessed element size.
657 In the following it will only grow (or become -1). */
660 /* Compute cumulative bit-offset for nested component-refs and array-refs,
661 and find the ultimate containing object. */
663 {
665 {
666 /* These may be in the reference ops, but we cannot do anything
667 sensible with them here. */
672 /* Record the base objects. */
692 /* And now the usual component-reference style ops. */
698 {
700 /* We do not have a complete COMPONENT_REF tree here so we
701 cannot use component_ref_field_offset. Do the interesting
702 parts manually. */
704 /* Our union trick, done for offset zero only. */
706 ;
710 else
711 {
715 }
717 }
721 /* We recorded the lower bound and the element size. */
726 else
727 {
733 }
757 }
758 }
772 }
774 /* Copy the operations present in load/store/call REF into RESULT, a vector of
775 vn_reference_op_s's. */
777 void
780 {
781 vn_reference_op_s temp;
784 /* Copy the type, opcode, function being called and static chain. */
792 /* Copy the call arguments. As they can be references as well,
793 just chain them together. */
795 {
798 }
799 }
801 /* Create a vector of vn_reference_op_s structures from REF, a
802 REFERENCE_CLASS_P tree. The vector is not shared. */
806 {
811 }
813 /* Create a vector of vn_reference_op_s structures from CALL, a
814 call statement. The vector is not shared. */
818 {
823 }
825 /* Fold *& at position *I_P in a vn_reference_op_s vector *OPS. Updates
826 *I_P to point to the last element of the replacement. */
827 void
830 {
832 vn_reference_op_t op;
836 /* Get ops for the addressed object. */
838 /* ??? If this is our usual typeof &ARRAY vs. &ARRAY[0] problem, work
839 around it to avoid later ICEs. */
842 {
843 vn_reference_op_s aref;
844 tree dom;
854 }
857 /* Do the replacement - we should have at least one op in mem now. */
859 {
863 i--;
864 }
866 {
871 }
873 {
878 /* ??? There is no VEC_splice. */
881 }
882 else
887 }
889 /* Transform any SSA_NAME's in a vector of vn_reference_op_s
890 structures into their value numbers. This is done in-place, and
891 the vector passed in is returned. */
895 {
896 vn_reference_op_t vro;
900 {
903 {
905 /* If it transforms from an SSA_NAME to a constant, update
906 the opcode. */
909 /* If it transforms from an SSA_NAME to an address, fold with
910 a preceding indirect reference. */
914 {
917 }
918 }
923 }
926 }
930 /* Create a vector of vn_reference_op_s structures from REF, a
931 REFERENCE_CLASS_P tree. The vector is shared among all callers of
932 this function. */
936 {
943 }
945 /* Create a vector of vn_reference_op_s structures from CALL, a
946 call statement. The vector is shared among all callers of
947 this function. */
951 {
958 }
960 /* Lookup a SCCVN reference operation VR in the current hash table.
961 Returns the resulting value number if it exists in the hash table,
962 NULL_TREE otherwise. VNRESULT will be filled in with the actual
963 vn_reference_t stored in the hashtable if something is found. */
965 static tree
967 {
969 hashval_t hash;
978 {
982 }
985 }
987 /* Callback for walk_non_aliased_vuses. Adjusts the vn_reference_t VR_
988 with the current VUSE and performs the expression lookup. */
992 {
995 hashval_t hash;
997 /* Fixup vuse and hash. */
1012 }
1014 /* Callback for walk_non_aliased_vuses. Tries to perform a lookup
1015 from the statement defining VUSE and if not successful tries to
1016 translate *REFP and VR_ through an aggregate copy at the defintion
1017 of VUSE. */
1021 {
1024 tree fndecl;
1025 tree base;
1032 /* If we cannot constrain the size of the reference we cannot
1033 test if anything kills it. */
1037 /* def_stmt may-defs *ref. See if we can derive a value for *ref
1038 from that defintion.
1039 1) Memset. */
1048 {
1050 tree base2;
1059 {
1066 }
1067 }
1069 /* 2) Assignment from an empty CONSTRUCTOR. */
1074 {
1075 tree base2;
1082 {
1089 }
1090 }
1092 /* For aggregate copies translate the reference through them if
1093 the copy kills ref. */
1098 {
1099 tree base2;
1103 vn_reference_op_t vro;
1104 ao_ref r;
1106 /* See if the assignment kills REF. */
1114 /* Find the common base of ref and the lhs. */
1122 {
1123 i--;
1124 j--;
1125 }
1128 /* i now points to the first additional op.
1129 ??? LHS may not be completely contained in VR, one or more
1130 VIEW_CONVERT_EXPRs could be in its way. We could at least
1131 try handling outermost VIEW_CONVERT_EXPRs. */
1135 /* Now re-write REF to be based on the rhs of the assignment. */
1137 /* We need to pre-pend vr->operands[0..i] to rhs. */
1140 {
1147 }
1148 else
1156 /* Adjust *ref from the new operands. */
1159 /* This can happen with bitfields. */
1164 /* Keep looking for the adjusted *REF / VR pair. */
1166 }
1168 /* Bail out and stop walking. */
1170 }
1172 /* Lookup a reference operation by it's parts, in the current hash table.
1173 Returns the resulting value number if it exists in the hash table,
1174 NULL_TREE otherwise. VNRESULT will be filled in with the actual
1175 vn_reference_t stored in the hashtable if something is found. */
1177 tree
1181 {
1183 vn_reference_t tmp;
1205 && maywalk
1207 {
1208 ao_ref r;
1212 vn_reference_lookup_2,
1216 }
1222 }
1224 /* Lookup OP in the current hash table, and return the resulting value
1225 number if it exists in the hash table. Return NULL_TREE if it does
1226 not exist in the hash table or if the result field of the structure
1227 was NULL.. VNRESULT will be filled in with the vn_reference_t
1228 stored in the hashtable if one exists. */
1230 tree
1233 {
1248 {
1249 vn_reference_t wvnresult;
1250 ao_ref r;
1252 wvnresult =
1254 vn_reference_lookup_2,
1259 {
1263 }
1266 }
1269 }
1272 /* Insert OP into the current hash table with a value number of
1273 RESULT, and return the resulting reference structure we created. */
1275 vn_reference_t
1277 {
1279 vn_reference_t vr1;
1284 else
1294 INSERT);
1296 /* Because we lookup stores using vuses, and value number failures
1297 using the vdefs (see visit_reference_op_store for how and why),
1298 it's possible that on failure we may try to insert an already
1299 inserted store. This is not wrong, there is no ssa name for a
1300 store that we could use as a differentiator anyway. Thus, unlike
1301 the other lookup functions, you cannot gcc_assert (!*slot)
1302 here. */
1304 /* But free the old slot in case of a collision. */
1310 }
1312 /* Insert a reference by it's pieces into the current hash table with
1313 a value number of RESULT. Return the resulting reference
1314 structure we created. */
1316 vn_reference_t
1321 {
1323 vn_reference_t vr1;
1337 INSERT);
1339 /* At this point we should have all the things inserted that we have
1340 seen before, and we should never try inserting something that
1341 already exists. */
1348 }
1350 /* Compute and return the hash value for nary operation VBO1. */
1352 hashval_t
1354 {
1365 {
1369 }
1375 }
1377 /* Return the computed hashcode for nary operation P1. */
1379 static hashval_t
1381 {
1384 }
1386 /* Compare nary operations P1 and P2 and return true if they are
1387 equivalent. */
1389 int
1391 {
1408 }
1410 /* Lookup a n-ary operation by its pieces and return the resulting value
1411 number if it exists in the hash table. Return NULL_TREE if it does
1412 not exist in the hash table or if the result field of the operation
1413 is NULL. VNRESULT will contain the vn_nary_op_t from the hashtable
1414 if it exists. */
1416 tree
1420 {
1434 NO_INSERT);
1437 NO_INSERT);
1443 }
1445 /* Lookup OP in the current hash table, and return the resulting value
1446 number if it exists in the hash table. Return NULL_TREE if it does
1447 not exist in the hash table or if the result field of the operation
1448 is NULL. VNRESULT will contain the vn_nary_op_t from the hashtable
1449 if it exists. */
1451 tree
1453 {
1467 NO_INSERT);
1470 NO_INSERT);
1476 }
1478 /* Lookup the rhs of STMT in the current hash table, and return the resulting
1479 value number if it exists in the hash table. Return NULL_TREE if
1480 it does not exist in the hash table. VNRESULT will contain the
1481 vn_nary_op_t from the hashtable if it exists. */
1483 tree
1485 {
1503 NO_INSERT);
1506 NO_INSERT);
1512 }
1514 /* Insert a n-ary operation into the current hash table using it's
1515 pieces. Return the vn_nary_op_t structure we created and put in
1516 the hashtable. */
1518 vn_nary_op_t
1522 tree result,
1524 {
1526 vn_nary_op_t vno1;
1546 INSERT);
1552 }
1554 /* Insert OP into the current hash table with a value number of
1555 RESULT. Return the vn_nary_op_t structure we created and put in
1556 the hashtable. */
1558 vn_nary_op_t
1560 {
1563 vn_nary_op_t vno1;
1578 INSERT);
1583 }
1585 /* Insert the rhs of STMT into the current hash table with a value number of
1586 RESULT. */
1588 vn_nary_op_t
1590 {
1593 vn_nary_op_t vno1;
1612 INSERT);
1617 }
1619 /* Compute a hashcode for PHI operation VP1 and return it. */
1623 {
1626 tree phi1op;
1627 tree type;
1631 /* If all PHI arguments are constants we need to distinguish
1632 the PHI node via its type. */
1639 {
1643 }
1646 }
1648 /* Return the computed hashcode for phi operation P1. */
1650 static hashval_t
1652 {
1655 }
1657 /* Compare two phi entries for equality, ignoring VN_TOP arguments. */
1659 static int
1661 {
1669 {
1671 tree phi1op;
1673 /* If the PHI nodes do not have compatible types
1674 they are not the same. */
1679 /* Any phi in the same block will have it's arguments in the
1680 same edge order, because of how we store phi nodes. */
1682 {
1688 }
1690 }
1692 }
1696 /* Lookup PHI in the current hash table, and return the resulting
1697 value number if it exists in the hash table. Return NULL_TREE if
1698 it does not exist in the hash table. */
1700 static tree
1702 {
1709 /* Canonicalize the SSA_NAME's to their value number. */
1711 {
1715 }
1720 NO_INSERT);
1723 NO_INSERT);
1727 }
1729 /* Insert PHI into the current hash table with a value number of
1730 RESULT. */
1732 static vn_phi_t
1734 {
1740 /* Canonicalize the SSA_NAME's to their value number. */
1742 {
1746 }
1754 INSERT);
1756 /* Because we iterate over phi operations more than once, it's
1757 possible the slot might already exist here, hence no assert.*/
1760 }
1763 /* Print set of components in strongly connected component SCC to OUT. */
1765 static void
1767 {
1768 tree var;
1773 {
1776 }
1778 }
1780 /* Set the value number of FROM to TO, return true if it has changed
1781 as a result. */
1785 {
1786 tree currval;
1793 /* The only thing we allow as value numbers are VN_TOP, ssa_names
1794 and invariants. So assert that here. */
1801 {
1806 }
1811 {
1816 }
1820 }
1822 /* Set all definitions in STMT to value number to themselves.
1823 Return true if a value number changed. */
1825 static bool
1827 {
1829 ssa_op_iter iter;
1830 def_operand_p defp;
1833 {
1838 }
1840 }
1845 /* Visit a copy between LHS and RHS, return true if the value number
1846 changed. */
1848 static bool
1850 {
1851 /* Follow chains of copies to their destination. */
1856 /* The copy may have a more interesting constant filled expression
1857 (we don't, since we know our RHS is just an SSA name). */
1859 {
1862 }
1865 }
1867 /* Visit a unary operator RHS, value number it, and return true if the
1868 value number of LHS has changed as a result. */
1870 static bool
1872 {
1877 {
1879 }
1880 else
1881 {
1884 }
1887 }
1889 /* Visit a binary operator RHS, value number it, and return true if the
1890 value number of LHS has changed as a result. */
1892 static bool
1894 {
1899 {
1901 }
1902 else
1903 {
1906 }
1909 }
1911 /* Visit a call STMT storing into LHS. Return true if the value number
1912 of the LHS has changed as a result. */
1914 static bool
1916 {
1919 tree result;
1929 {
1934 }
1935 else
1936 {
1938 vn_reference_t vr2;
1952 }
1955 }
1957 /* Visit a load from a reference operator RHS, part of STMT, value number it,
1958 and return true if the value number of the LHS has changed as a result. */
1960 static bool
1962 {
1966 /* If we have a VCE, try looking up its operand as it might be stored in
1967 a different type. */
1972 /* We handle type-punning through unions by value-numbering based
1973 on offset and size of the access. Be prepared to handle a
1974 type-mismatch here via creating a VIEW_CONVERT_EXPR. */
1977 {
1978 /* We will be setting the value number of lhs to the value number
1979 of VIEW_CONVERT_EXPR <TREE_TYPE (result)> (result).
1980 So first simplify and lookup this expression to see if it
1981 is already available. */
1986 {
1993 }
1998 /* If the expression is not yet available, value-number lhs to
1999 a new SSA_NAME we create. */
2001 {
2003 /* Initialize value-number information properly. */
2009 /* As all "inserted" statements are singleton SCCs, insert
2010 to the valid table. This is strictly needed to
2011 avoid re-generating new value SSA_NAMEs for the same
2012 expression during SCC iteration over and over (the
2013 optimistic table gets cleared after each iteration).
2014 We do not need to insert into the optimistic table, as
2015 lookups there will fall back to the valid table. */
2017 {
2021 }
2022 else
2025 {
2031 }
2032 }
2033 }
2036 {
2040 {
2043 }
2044 }
2045 else
2046 {
2049 }
2052 }
2055 /* Visit a store to a reference operator LHS, part of STMT, value number it,
2056 and return true if the value number of the LHS has changed as a result. */
2058 static bool
2060 {
2062 tree result;
2065 /* First we want to lookup using the *vuses* from the store and see
2066 if there the last store to this location with the same address
2067 had the same value.
2069 The vuses represent the memory state before the store. If the
2070 memory state, address, and value of the store is the same as the
2071 last store to this location, then this store will produce the
2072 same memory state as that store.
2074 In this case the vdef versions for this store are value numbered to those
2075 vuse versions, since they represent the same memory state after
2076 this store.
2078 Otherwise, the vdefs for the store are used when inserting into
2079 the table, since the store generates a new memory state. */
2084 {
2090 }
2093 {
2094 tree vdef;
2097 {
2104 }
2105 /* Have to set value numbers before insert, since insert is
2106 going to valueize the references in-place. */
2108 {
2111 }
2113 /* Do not insert structure copies into the tables. */
2117 }
2118 else
2119 {
2120 /* We had a match, so value number the vdef to have the value
2121 number of the vuse it came from. */
2133 }
2136 }
2138 /* Visit and value number PHI, return true if the value number
2139 changed. */
2141 static bool
2143 {
2145 tree result;
2150 /* TODO: We could check for this in init_sccvn, and replace this
2151 with a gcc_assert. */
2155 /* See if all non-TOP arguments have the same value. TOP is
2156 equivalent to everything, so we can ignore it. */
2158 {
2166 {
2168 }
2169 else
2170 {
2172 {
2175 }
2176 }
2177 }
2179 /* If all value numbered to the same value, the phi node has that
2180 value. */
2182 {
2184 {
2187 }
2188 else
2189 {
2192 }
2198 }
2200 /* Otherwise, see if it is equivalent to a phi node in this block. */
2203 {
2206 else
2208 }
2209 else
2210 {
2215 }
2218 }
2220 /* Return true if EXPR contains constants. */
2222 static bool
2224 {
2226 {
2233 /* Constants inside reference ops are rarely interesting, but
2234 it can take a lot of looking to find them. */
2240 }
2242 }
2244 /* Return true if STMT contains constants. */
2246 static bool
2248 {
2253 {
2261 /* Constants inside reference ops are rarely interesting, but
2262 it can take a lot of looking to find them. */
2266 }
2268 }
2270 /* Replace SSA_NAMES in expr with their value numbers, and return the
2271 result.
2272 This is performed in place. */
2274 static tree
2276 {
2278 {
2294 }
2296 }
2298 /* Simplify the binary expression RHS, and return the result if
2299 simplified. */
2301 static tree
2303 {
2308 /* This will not catch every single case we could combine, but will
2309 catch those with constants. The goal here is to simultaneously
2310 combine constants between expressions, but avoid infinite
2311 expansion of expressions during simplification. */
2313 {
2319 }
2322 {
2327 }
2329 /* Avoid folding if nothing changed. */
2344 /* Make sure result is not a complex expression consisting
2345 of operators of operators (IE (a + b) + (a + c))
2346 Otherwise, we will end up with unbounded expressions if
2347 fold does anything at all. */
2352 }
2354 /* Simplify the unary expression RHS, and return the result if
2355 simplified. */
2357 static tree
2359 {
2363 /* We handle some tcc_reference codes here that are all
2364 GIMPLE_ASSIGN_SINGLE codes. */
2380 {
2381 /* We want to do tree-combining on conversion-like expressions.
2382 Make sure we feed only SSA_NAMEs or constants to fold though. */
2390 }
2392 /* Avoid folding if nothing changed, but remember the expression. */
2399 {
2403 }
2406 }
2408 /* Try to simplify RHS using equivalences and constant folding. */
2410 static tree
2412 {
2413 tree tem;
2415 /* For stores we can end up simplifying a SSA_NAME rhs. Just return
2416 in this case, there is no point in doing extra work. */
2422 {
2430 /* Do not do full-blown reference lookup here, but simplify
2431 reads from constant aggregates. */
2436 /* Fallthrough for some codes that can operate on registers. */
2441 /* We could do a little more with unary ops, if they expand
2442 into binary ops, but it's debatable whether it is worth it. */
2452 }
2455 }
2457 /* Visit and value number USE, return true if the value number
2458 changed. */
2460 static bool
2462 {
2471 {
2476 }
2478 /* Handle uninitialized uses. */
2481 else
2482 {
2490 {
2492 tree simplified;
2494 /* Shortcut for copies. Simplifying copies is pointless,
2495 since we copy the expression and value they represent. */
2499 {
2502 }
2505 {
2507 {
2515 else
2517 }
2518 }
2519 /* Setting value numbers to constants will occasionally
2520 screw up phi congruence because constants are not
2521 uniquely associated with a single ssa name that can be
2522 looked up. */
2526 {
2531 }
2535 {
2538 }
2540 {
2542 {
2544 /* We have to unshare the expression or else
2545 valuizing may change the IL stream. */
2547 }
2548 }
2553 {
2554 /* We reset expr and constantness here because we may
2555 have been value numbering optimistically, and
2556 iterating. They may become non-constant in this case,
2557 even if they were optimistically constant. */
2561 }
2564 /* We can substitute SSA_NAMEs that are live over
2565 abnormal edges with their constant value. */
2568 && !(simplified
2571 /* Stores or copies from SSA_NAMEs that are live over
2572 abnormal edges are a problem. */
2578 {
2580 }
2582 {
2585 || (simplified
2587 {
2591 else
2593 }
2594 else
2595 {
2597 {
2606 {
2608 /* VOP-less references can go through unary case. */
2613 {
2616 }
2617 /* Fallthrough. */
2619 changed = visit_reference_op_load
2624 {
2627 }
2628 /* Fallthrough. */
2631 }
2636 }
2637 }
2638 }
2639 else
2641 }
2643 {
2646 /* ??? We could try to simplify calls. */
2652 {
2653 /* We reset expr and constantness here because we may
2654 have been value numbering optimistically, and
2655 iterating. They may become non-constant in this case,
2656 even if they were optimistically constant. */
2659 }
2664 /* ??? We should handle stores from calls. */
2666 {
2669 else
2671 }
2672 else
2674 }
2675 }
2676 done:
2678 }
2680 /* Compare two operands by reverse postorder index */
2682 static int
2684 {
2689 basic_block bba;
2690 basic_block bbb;
2710 {
2720 else
2722 }
2724 }
2726 /* Sort an array containing members of a strongly connected component
2727 SCC so that the members are ordered by RPO number.
2728 This means that when the sort is complete, iterating through the
2729 array will give you the members in RPO order. */
2731 static void
2733 {
2737 compare_ops);
2738 }
2740 /* Process a strongly connected component in the SSA graph. */
2742 static void
2744 {
2745 /* If the SCC has a single member, just visit it. */
2748 {
2752 }
2753 else
2754 {
2755 tree var;
2760 /* Iterate over the SCC with the optimistic table until it stops
2761 changing. */
2764 {
2766 iterations++;
2767 /* As we are value-numbering optimistically we have to
2768 clear the expression tables and the simplified expressions
2769 in each iteration until we converge. */
2781 }
2785 /* Finally, visit the SCC once using the valid table. */
2789 }
2790 }
2795 /* Pop the components of the found SCC for NAME off the SCC stack
2796 and process them. Returns true if all went well, false if
2797 we run into resource limits. */
2799 static bool
2801 {
2803 tree x;
2805 /* Found an SCC, pop the components off the SCC stack and
2806 process them. */
2807 do
2808 {
2815 /* Bail out of SCCVN in case a SCC turns out to be incredibly large. */
2818 {
2824 }
2837 }
2839 /* Depth first search on NAME to discover and process SCC's in the SSA
2840 graph.
2841 Execution of this algorithm relies on the fact that the SCC's are
2842 popped off the stack in topological order.
2843 Returns true if successful, false if we stopped processing SCC's due
2844 to resource constraints. */
2846 static bool
2848 {
2852 gimple defstmt;
2853 tree use;
2854 ssa_op_iter iter;
2856 start_over:
2857 /* SCC info */
2866 /* Recursively DFS on our operands, looking for SCC's. */
2868 {
2869 /* Push a new iterator. */
2872 else
2874 }
2875 else
2879 {
2880 /* If we are done processing uses of a name, go up the stack
2881 of iterators and process SCCs as we found them. */
2883 {
2884 /* See if we found an SCC. */
2887 {
2891 }
2893 /* Check if we are done. */
2895 {
2899 }
2901 /* Restore the last use walker and continue walking there. */
2908 }
2912 /* Since we handle phi nodes, we will sometimes get
2913 invariants in the use expression. */
2915 {
2917 {
2918 /* Recurse by pushing the current use walking state on
2919 the stack and starting over. */
2925 continue_walking:
2928 }
2931 {
2934 }
2935 }
2938 }
2939 }
2941 /* Allocate a value number table. */
2943 static void
2945 {
2949 free_reference);
2958 }
2960 /* Free a value number table. */
2962 static void
2964 {
2971 }
2973 static void
2975 {
2983 free);
2991 /* VEC_alloc doesn't actually grow it to the right size, it just
2992 preallocates the space to do so. */
3002 /* RPO numbers is an array of rpo ordering, rpo[i] = bb means that
3003 the i'th block in RPO order is bb. We want to map bb's to RPO
3004 numbers, so we need to rearrange this array. */
3012 /* Create the VN_INFO structures, and initialize value numbers to
3013 TOP. */
3015 {
3018 {
3022 }
3023 }
3027 /* Create the valid and optimistic value numbering tables. */
3032 }
3034 void
3036 {
3046 {
3051 }
3060 }
3062 /* Set the value ids in the valid hash tables. */
3064 static void
3066 {
3067 htab_iterator hi;
3068 vn_nary_op_t vno;
3069 vn_reference_t vr;
3070 vn_phi_t vp;
3072 /* Now set the value ids of the things we had put in the hash
3073 table. */
3077 {
3079 {
3084 }
3085 }
3089 {
3091 {
3096 }
3097 }
3101 {
3103 {
3108 }
3109 }
3110 }
3112 /* Do SCCVN. Returns true if it finished, false if we bailed out
3113 due to resource constraints. */
3115 bool
3117 {
3119 tree param;
3128 param;
3130 {
3132 {
3135 }
3136 }
3139 {
3145 {
3149 }
3150 }
3152 /* Initialize the value ids. */
3155 {
3157 vn_ssa_aux_t info;
3166 }
3168 /* Propagate until they stop changing. */
3170 {
3173 {
3175 vn_ssa_aux_t info;
3182 {
3185 }
3186 }
3187 }
3192 {
3195 {
3200 {
3205 }
3206 }
3207 }
3211 }
3213 /* Return the maximum value id we have ever seen. */
3215 unsigned int
3217 {
3219 }
3221 /* Return the next unique value id. */
3223 unsigned int
3225 {
3227 }
3230 /* Compare two expressions E1 and E2 and return true if they are equal. */
3232 bool
3234 {
3235 /* The obvious case. */
3239 /* If only one of them is null, they cannot be equal. */
3243 /* Recurse on elements of lists. */
3245 {
3251 {
3256 }
3258 }
3260 /* Now perform the actual comparison. */
3266 }
3269 /* Return true if the nary operation NARY may trap. This is a copy
3270 of stmt_could_throw_1_p adjusted to the SCCVN IL. */
3272 bool
3274 {
3275 tree type;
3276 tree rhs2;
3287 {
3291 {
3294 }
3298 }
3301 honor_trapv,
3313 }