| blob | c41519ca8463cc81e85619e33b539c0656f46b54 |
1 /* Tree based points-to analysis
2 Copyright (C) 2005 Free Software Foundation, Inc.
3 Contributed by Daniel Berlin <dberlin@dberlin.org>
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify
8 under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 2 of the License, or
10 (at your option) any later version.
12 GCC 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 GCC; if not, write to the Free Software
19 Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
20 */
53 /* The idea behind this analyzer is to generate set constraints from the
54 program, then solve the resulting constraints in order to generate the
55 points-to sets.
57 Set constraints are a way of modeling program analysis problems that
58 involve sets. They consist of an inclusion constraint language,
59 describing the variables (each variable is a set) and operations that
60 are involved on the variables, and a set of rules that derive facts
61 from these operations. To solve a system of set constraints, you derive
62 all possible facts under the rules, which gives you the correct sets
63 as a consequence.
65 See "Efficient Field-sensitive pointer analysis for C" by "David
66 J. Pearce and Paul H. J. Kelly and Chris Hankin, at
67 http://citeseer.ist.psu.edu/pearce04efficient.html
69 Also see "Ultra-fast Aliasing Analysis using CLA: A Million Lines
70 of C Code in a Second" by ""Nevin Heintze and Olivier Tardieu" at
71 http://citeseer.ist.psu.edu/heintze01ultrafast.html
73 There are three types of constraint expressions, DEREF, ADDRESSOF, and
74 SCALAR. Each constraint expression consists of a constraint type,
75 a variable, and an offset.
77 SCALAR is a constraint expression type used to represent x, whether
78 it appears on the LHS or the RHS of a statement.
79 DEREF is a constraint expression type used to represent *x, whether
80 it appears on the LHS or the RHS of a statement.
81 ADDRESSOF is a constraint expression used to represent &x, whether
82 it appears on the LHS or the RHS of a statement.
84 Each pointer variable in the program is assigned an integer id, and
85 each field of a structure variable is assigned an integer id as well.
87 Structure variables are linked to their list of fields through a "next
88 field" in each variable that points to the next field in offset
89 order.
90 Each variable for a structure field has
92 1. "size", that tells the size in bits of that field.
93 2. "fullsize, that tells the size in bits of the entire structure.
94 3. "offset", that tells the offset in bits from the beginning of the
95 structure to this field.
97 Thus,
98 struct f
99 {
100 int a;
101 int b;
102 } foo;
103 int *bar;
105 looks like
107 foo.a -> id 1, size 32, offset 0, fullsize 64, next foo.b
108 foo.b -> id 2, size 32, offset 32, fullsize 64, next NULL
109 bar -> id 3, size 32, offset 0, fullsize 32, next NULL
112 In order to solve the system of set constraints, the following is
113 done:
115 1. Each constraint variable x has a solution set associated with it,
116 Sol(x).
118 2. Constraints are separated into direct, copy, and complex.
119 Direct constraints are ADDRESSOF constraints that require no extra
120 processing, such as P = &Q
121 Copy constraints are those of the form P = Q.
122 Complex constraints are all the constraints involving dereferences.
124 3. All direct constraints of the form P = &Q are processed, such
125 that Q is added to Sol(P)
127 4. All complex constraints for a given constraint variable are stored in a
128 linked list attached to that variable's node.
130 5. A directed graph is built out of the copy constraints. Each
131 constraint variable is a node in the graph, and an edge from
132 Q to P is added for each copy constraint of the form P = Q
134 6. The graph is then walked, and solution sets are
135 propagated along the copy edges, such that an edge from Q to P
136 causes Sol(P) <- Sol(P) union Sol(Q).
138 7. As we visit each node, all complex constraints associated with
139 that node are processed by adding appropriate copy edges to the graph, or the
140 appropriate variables to the solution set.
142 8. The process of walking the graph is iterated until no solution
143 sets change.
145 Prior to walking the graph in steps 6 and 7, We perform static
146 cycle elimination on the constraint graph, as well
147 as off-line variable substitution.
149 TODO: Adding offsets to pointer-to-structures can be handled (IE not punted
150 on and turned into anything), but isn't. You can just see what offset
151 inside the pointed-to struct it's going to access.
153 TODO: Constant bounded arrays can be handled as if they were structs of the
154 same number of elements.
156 TODO: Modeling heap and incoming pointers becomes much better if we
157 add fields to them as we discover them, which we could do.
159 TODO: We could handle unions, but to be honest, it's probably not
160 worth the pain or slowdown. */
172 static struct constraint_stats
173 {
181 struct variable_info
182 {
183 /* ID of this variable */
186 /* Name of this variable */
189 /* Tree that this variable is associated with. */
190 tree decl;
192 /* Offset of this variable, in bits, from the base variable */
195 /* Size of the variable, in bits. */
198 /* Full size of the base variable, in bits. */
201 /* A link to the variable for the next field in this structure. */
204 /* Node in the graph that represents the constraints and points-to
205 solution for the variable. */
208 /* True if the address of this variable is taken. Needed for
209 variable substitution. */
212 /* True if this variable is the target of a dereference. Needed for
213 variable substitution. */
216 /* True if this is a variable created by the constraint analysis, such as
217 heap variables and constraints we had to break up. */
220 /* True if this is a special variable whose solution set should not be
221 changed. */
224 /* True for variables whose size is not known or variable. */
227 /* True for variables that have unions somewhere in them. */
230 /* True if this is a heap variable. */
233 /* Points-to set for this variable. */
234 bitmap solution;
236 /* Variable ids represented by this node. */
237 bitmap variables;
239 /* Vector of complex constraints for this node. Complex
240 constraints are those involving dereferences. */
242 };
247 /* Pool of variable info structures. */
254 /* Table of variable info structures for constraint variables. Indexed directly
255 by variable info id. */
258 /* Return the varmap element N */
262 {
264 }
266 /* Variable that represents the unknown pointer. */
271 /* Variable that represents the NULL pointer. */
276 /* Variable that represents read only memory. */
281 /* Variable that represents integers. This is used for when people do things
282 like &0->a.b. */
287 /* Variable that represents arbitrary offsets into an object. Used to
288 represent pointer arithmetic, which may not legally escape the
289 bounds of an object. */
294 /* Return a new variable info structure consisting for a variable
295 named NAME, and using constraint graph node NODE. */
297 static varinfo_t
299 {
320 }
324 /* An expression that appears in a constraint. */
326 struct constraint_expr
327 {
328 /* Constraint type. */
329 constraint_expr_type type;
331 /* Variable we are referring to in the constraint. */
334 /* Offset, in bits, of this constraint from the beginning of
335 variables it ends up referring to.
337 IOW, in a deref constraint, we would deref, get the result set,
338 then add OFFSET to each member. */
340 };
344 /* Our set constraints are made up of two constraint expressions, one
345 LHS, and one RHS.
347 As described in the introduction, our set constraints each represent an
348 operation between set valued variables.
349 */
350 struct constraint
351 {
354 };
356 /* List of constraints that we use to build the constraint graph from. */
361 /* An edge in the constraint graph. We technically have no use for
362 the src, since it will always be the same node that we are indexing
363 into the pred/succ arrays with, but it's nice for checking
364 purposes. The edges are weighted, with a bit set in weights for
365 each edge from src to dest with that weight. */
367 struct constraint_edge
368 {
371 bitmap weights;
372 };
377 /* Return a new constraint edge from SRC to DEST. */
379 static constraint_edge_t
381 {
387 }
393 /* The constraint graph is simply a set of adjacency vectors, one per
394 variable. succs[x] is the vector of successors for variable x, and preds[x]
395 is the vector of predecessors for variable x.
396 IOW, all edges are "forward" edges, which is not like our CFG.
397 So remember that
398 preds[x]->src == x, and
399 succs[x]->src == x. */
401 struct constraint_graph
402 {
405 };
411 /* Create a new constraint consisting of LHS and RHS expressions. */
413 static constraint_t
416 {
421 }
423 /* Print out constraint C to FILE. */
425 void
427 {
444 }
446 /* Print out constraint C to stderr. */
448 void
450 {
452 }
454 /* Print out all constraints to FILE */
456 void
458 {
460 constraint_t c;
463 }
465 /* Print out all constraints to stderr. */
467 void
469 {
471 }
473 /* SOLVER FUNCTIONS
475 The solver is a simple worklist solver, that works on the following
476 algorithm:
478 sbitmap changed_nodes = all ones;
479 changed_count = number of nodes;
480 For each node that was already collapsed:
481 changed_count--;
484 while (changed_count > 0)
485 {
486 compute topological ordering for constraint graph
488 find and collapse cycles in the constraint graph (updating
489 changed if necessary)
491 for each node (n) in the graph in topological order:
492 changed_count--;
494 Process each complex constraint associated with the node,
495 updating changed if necessary.
497 For each outgoing edge from n, propagate the solution from n to
498 the destination of the edge, updating changed as necessary.
500 } */
502 /* Return true if two constraint expressions A and B are equal. */
504 static bool
506 {
510 }
512 /* Return true if constraint expression A is less than constraint expression
513 B. This is just arbitrary, but consistent, in order to give them an
514 ordering. */
516 static bool
518 {
520 {
523 else
525 }
526 else
528 }
530 /* Return true if constraint A is less than constraint B. This is just
531 arbitrary, but consistent, in order to give them an ordering. */
533 static bool
535 {
540 else
542 }
544 /* Return true if two constraints A and B are equal. */
546 static bool
548 {
551 }
554 /* Find a constraint LOOKFOR in the sorted constraint vector VEC */
556 static constraint_t
559 {
561 constraint_t found;
573 }
575 /* Union two constraint vectors, TO and FROM. Put the result in TO. */
577 static void
580 {
582 constraint_t c;
585 {
587 {
589 constraint_less);
591 }
592 }
593 }
595 /* Take a solution set SET, add OFFSET to each member of the set, and
596 overwrite SET with the result when done. */
598 static void
600 {
603 bitmap_iterator bi;
606 {
607 /* If this is a properly sized variable, only add offset if it's
608 less than end. Otherwise, it is globbed to a single
609 variable. */
612 {
618 }
622 {
624 }
625 }
629 }
631 /* Union solution sets TO and FROM, and add INC to each member of FROM in the
632 process. */
634 static bool
636 {
639 else
640 {
641 bitmap tmp;
650 }
651 }
653 /* Insert constraint C into the list of complex constraints for VAR. */
655 static void
657 {
660 constraint_less);
662 }
665 /* Compare two constraint edges A and B, return true if they are equal. */
667 static bool
669 {
671 }
673 /* Compare two constraint edges, return true if A is less than B */
675 static bool
677 {
682 else
684 }
686 /* Find the constraint edge that matches LOOKFOR, in VEC.
687 Return the edge, if found, NULL otherwise. */
689 static constraint_edge_t
692 {
694 constraint_edge_t edge;
697 constraint_edge_less);
702 }
704 /* Condense two variable nodes into a single variable node, by moving
705 all associated info from SRC to TO. */
707 static void
709 {
713 constraint_t c;
714 bitmap_iterator bi;
716 /* the src node, and all its variables, are now the to node. */
721 /* Merge the src node variables and the to node variables. */
726 /* Move all complex constraints from src node into to node */
728 {
729 /* In complex constraints for node src, we may have either
730 a = *src, and *src = a. */
734 else
736 }
740 }
742 /* Erase EDGE from GRAPH. This routine only handles self-edges
743 (e.g. an edge from a to a). */
745 static void
747 {
753 /* Remove from the successors. */
755 constraint_edge_less);
757 /* Make sure we found the edge. */
758 #ifdef ENABLE_CHECKING
759 {
762 }
763 #endif
766 /* Remove from the predecessors. */
768 constraint_edge_less);
770 /* Make sure we found the edge. */
771 #ifdef ENABLE_CHECKING
772 {
775 }
776 #endif
778 }
780 /* Remove edges involving NODE from GRAPH. */
782 static void
784 {
787 constraint_edge_t c;
790 /* Walk the successors, erase the associated preds. */
793 {
801 }
802 /* Walk the preds, erase the associated succs. */
805 {
813 }
819 }
823 /* Add edge NEWE to the graph. */
825 static bool
827 {
835 constraint_edge_less);
838 {
840 bitmap weightbitmap;
854 }
855 else
857 }
860 /* Return the bitmap representing the weights of edge LOOKFOR */
862 static bitmap
864 {
865 constraint_edge_t edge;
872 }
875 /* Merge GRAPH nodes FROM and TO into node TO. */
877 static void
880 {
884 constraint_edge_t c;
886 /* Merge all the predecessor edges. */
889 {
893 bitmap temp;
894 bitmap weights;
906 }
908 /* Merge all the successor edges. */
910 {
914 bitmap temp;
915 bitmap weights;
927 }
929 }
931 /* Add a graph edge to GRAPH, going from TO to FROM, with WEIGHT, if
932 it doesn't exist in the graph already.
933 Return false if the edge already existed, true otherwise. */
935 static bool
938 {
940 {
942 }
943 else
944 {
954 }
955 }
958 /* Return true if LOOKFOR is an existing graph edge. */
960 static bool
962 {
964 }
967 /* Build the constraint graph. */
969 static void
971 {
973 constraint_t c;
982 {
986 {
987 /* *x = y or *x = &y (complex) */
990 }
992 {
993 /* !special var= *y */
996 }
998 {
999 /* x = &y */
1001 }
1003 {
1004 /* Ignore 0 weighted self edges, as they can't possibly contribute
1005 anything */
1007 {
1012 /* x = y (simple) */
1016 }
1018 }
1019 }
1020 }
1023 /* Changed variables on the last iteration. */
1031 /* Strongly Connected Component visitation info. */
1033 struct scc_info
1034 {
1035 sbitmap visited;
1036 sbitmap in_component;
1041 };
1044 /* Recursive routine to find strongly connected components in GRAPH.
1045 SI is the SCC info to store the information in, and N is the id of current
1046 graph node we are processing.
1048 This is Tarjan's strongly connected component finding algorithm, as
1049 modified by Nuutila to keep only non-root nodes on the stack.
1050 The algorithm can be found in "On finding the strongly connected
1051 connected components in a directed graph" by Esko Nuutila and Eljas
1052 Soisalon-Soininen, in Information Processing Letters volume 49,
1053 number 1, pages 9-14. */
1055 static void
1057 {
1058 constraint_edge_t c;
1066 /* Visit all the successors. */
1068 {
1069 /* We only want to find and collapse the zero weight edges. */
1071 {
1076 {
1081 }
1082 }
1083 }
1085 /* See if any components have been identified. */
1087 {
1092 {
1096 /* Mark this node for collapsing. */
1098 }
1099 }
1100 else
1102 }
1105 /* Collapse two variables into one variable. */
1107 static void
1109 {
1123 {
1128 }
1132 }
1135 /* Unify nodes in GRAPH that we have found to be part of a cycle.
1136 SI is the Strongly Connected Components information structure that tells us
1137 what components to unify.
1138 UPDATE_CHANGED should be set to true if the changed sbitmap and changed
1139 count should be updated to reflect the unification. */
1141 static void
1144 {
1149 /* We proceed as follows:
1151 For each component in the queue (components are delineated by
1152 when current_queue_element->node != next_queue_element->node):
1154 rep = representative node for component
1156 For each node (tounify) to be unified in the component,
1157 merge the solution for tounify into tmp bitmap
1159 clear solution for tounify
1161 merge edges from tounify into rep
1163 merge complex constraints from tounify into rep
1165 update changed count to note that tounify will never change
1166 again
1168 Merge tmp into solution for rep, marking rep changed if this
1169 changed rep's solution.
1171 Delete any 0 weighted self-edges we now have for rep. */
1173 {
1183 else
1190 {
1194 else
1195 {
1197 changed_count--;
1198 }
1199 }
1204 /* If we've either finished processing the entire queue, or
1205 finished processing all nodes for component n, update the solution for
1206 n. */
1209 {
1212 /* If the solution changes because of the merging, we need to mark
1213 the variable as changed. */
1215 {
1217 {
1219 changed_count++;
1220 }
1221 }
1227 {
1232 }
1233 }
1234 }
1236 }
1239 /* Information needed to compute the topological ordering of a graph. */
1241 struct topo_info
1242 {
1243 /* sbitmap of visited nodes. */
1244 sbitmap visited;
1245 /* Array that stores the topological order of the graph, *in
1246 reverse*. */
1248 };
1251 /* Initialize and return a topological info structure. */
1255 {
1262 }
1265 /* Free the topological sort info pointed to by TI. */
1267 static void
1269 {
1273 }
1275 /* Visit the graph in topological order, and store the order in the
1276 topo_info structure. */
1278 static void
1281 {
1283 constraint_edge_t c;
1287 {
1290 }
1292 }
1294 /* Return true if variable N + OFFSET is a legal field of N. */
1296 static bool
1298 {
1301 /* For things we've globbed to single variables, any offset into the
1302 variable acts like the entire variable, so that it becomes offset
1303 0. */
1307 {
1310 }
1312 }
1314 /* Process a constraint C that represents *x = &y. */
1316 static void
1319 {
1322 bitmap_iterator bi;
1324 /* For each member j of Delta (Sol(x)), add x to Sol(j) */
1326 {
1329 {
1330 /* *x != NULL && *x != ANYTHING*/
1331 varinfo_t v;
1333 bitmap sol;
1342 {
1345 {
1347 changed_count++;
1348 }
1349 }
1350 }
1354 }
1355 }
1357 /* Process a constraint C that represents x = *y, using DELTA as the
1358 starting solution. */
1360 static void
1362 bitmap delta)
1363 {
1368 bitmap_iterator bi;
1370 /* For each variable j in delta (Sol(y)), add
1371 an edge in the graph from j to x, and union Sol(j) into Sol(x). */
1373 {
1376 {
1377 varinfo_t v;
1387 }
1391 }
1393 /* If the LHS solution changed, mark the var as changed. */
1395 {
1398 {
1400 changed_count++;
1401 }
1402 }
1403 }
1405 /* Process a constraint C that represents *x = y. */
1407 static void
1409 {
1414 bitmap_iterator bi;
1416 /* For each member j of delta (Sol(x)), add an edge from y to j and
1417 union Sol(y) into Sol(j) */
1419 {
1422 {
1423 varinfo_t v;
1432 {
1435 {
1438 {
1440 }
1442 {
1444 changed_count++;
1445 }
1446 }
1447 }
1448 }
1451 }
1452 }
1454 /* Handle a non-simple (simple meaning requires no iteration), non-copy
1455 constraint (IE *x = &y, x = *y, and *x = y). */
1457 static void
1459 {
1461 {
1463 {
1464 /* *x = &y */
1466 }
1467 else
1468 {
1469 /* *x = y */
1471 }
1472 }
1473 else
1474 {
1475 /* x = *y */
1478 }
1479 }
1481 /* Initialize and return a new SCC info structure. */
1485 {
1498 }
1500 /* Free an SCC info structure pointed to by SI */
1502 static void
1504 {
1511 }
1514 /* Find cycles in GRAPH that occur, using strongly connected components, and
1515 collapse the cycles into a single representative node. if UPDATE_CHANGED
1516 is true, then update the changed sbitmap to note those nodes whose
1517 solutions have changed as a result of collapsing. */
1519 static void
1521 {
1531 }
1533 /* Compute a topological ordering for GRAPH, and store the result in the
1534 topo_info structure TI. */
1536 static void
1539 {
1546 }
1548 /* Return true if bitmap B is empty, or a bitmap other than bit 0 is set. */
1550 static bool
1552 {
1554 bitmap_iterator bi;
1561 }
1563 /* Perform offline variable substitution.
1565 This is a linear time way of identifying variables that must have
1566 equivalent points-to sets, including those caused by static cycles,
1567 and single entry subgraphs, in the constraint graph.
1569 The technique is described in "Off-line variable substitution for
1570 scaling points-to analysis" by Atanas Rountev and Satish Chandra,
1571 in "ACM SIGPLAN Notices" volume 35, number 5, pages 47-56. */
1573 static void
1575 {
1578 /* Compute the topological ordering of the graph, then visit each
1579 node in topological order. */
1583 {
1590 constraint_edge_t ce;
1591 bitmap tmp;
1593 /* We can't eliminate things whose address is taken, or which is
1594 the target of a dereference. */
1598 /* See if all predecessors of I are ripe for elimination */
1600 {
1601 bitmap weight;
1605 /* We can't eliminate variables that have nonzero weighted
1606 edges between them. */
1608 {
1611 }
1614 /* We can't eliminate the node if one of the predecessors is
1615 part of a different strongly connected component. */
1617 {
1620 }
1622 {
1625 }
1627 /* Theorem 4 in Rountev and Chandra: If i is a direct node,
1628 then Solution(i) is a subset of Solution (w), where w is a
1629 predecessor in the graph.
1630 Corollary: If all predecessors of i have the same
1631 points-to set, then i has that same points-to set as
1632 those predecessors. */
1637 {
1641 }
1643 }
1645 /* See if the root is different than the original node.
1646 If so, we've found an equivalence. */
1648 {
1649 /* Found an equivalence */
1657 }
1658 }
1661 }
1664 /* Solve the constraint graph GRAPH using our worklist solver.
1665 This is based on the PW* family of solvers from the "Efficient Field
1666 Sensitive Pointer Analysis for C" paper.
1667 It works by iterating over all the graph nodes, processing the complex
1668 constraints and propagating the copy constraints, until everything stops
1669 changed. This corresponds to steps 6-8 in the solving list given above. */
1671 static void
1673 {
1681 /* The already collapsed/unreachable nodes will never change, so we
1682 need to account for them in changed_count. */
1685 changed_count--;
1688 {
1696 {
1697 /* We already did cycle elimination once, when we did
1698 variable substitution, so we don't need it again for the
1699 first iteration. */
1704 }
1709 {
1713 /* If the node has changed, we need to process the
1714 complex constraints and outgoing edges again. */
1716 {
1718 constraint_t c;
1719 constraint_edge_t e;
1720 bitmap solution;
1725 changed_count--;
1727 /* Process the complex constraints */
1732 /* Propagate solution to all successors. */
1735 {
1740 bitmap_iterator bi;
1747 {
1750 {
1752 changed_count++;
1753 }
1754 }
1755 }
1756 }
1757 }
1760 }
1763 }
1766 /* CONSTRAINT AND VARIABLE GENERATION FUNCTIONS */
1768 /* Map from trees to variable ids. */
1772 {
1773 tree t;
1777 /* Hash a tree id structure. */
1779 static hashval_t
1781 {
1784 }
1786 /* Return true if the tree in P1 and the tree in P2 are the same. */
1788 static int
1790 {
1794 }
1796 /* Insert ID as the variable id for tree T in the hashtable. */
1798 static void
1800 {
1803 tree_id_t new_pair;
1812 }
1814 /* Find the variable id for tree T in ID_FOR_TREE. If T does not
1815 exist in the hash table, return false, otherwise, return true and
1816 set *ID to the id we found. */
1818 static bool
1820 {
1821 tree_id_t pair;
1830 }
1832 /* Return a printable name for DECL */
1836 {
1846 {
1850 }
1852 {
1854 }
1856 {
1859 }
1861 }
1863 /* Find the variable id for tree T in the hashtable.
1864 If T doesn't exist in the hash table, create an entry for it. */
1866 static unsigned int
1868 {
1869 tree_id_t pair;
1878 }
1880 /* Get a constraint expression from an SSA_VAR_P node. */
1882 static struct constraint_expr
1884 {
1889 /* For parameters, get at the points-to set for the actual parm
1890 decl. */
1899 /* If we determine the result is "anything", and we know this is readonly,
1900 say it points to readonly memory instead. */
1902 {
1905 }
1909 }
1911 /* Process a completed constraint T, and add it to the constraint
1912 list. */
1914 static void
1916 {
1923 /* ANYTHING == ANYTHING is pointless. */
1927 /* If we have &ANYTHING = something, convert to SOMETHING = &ANYTHING) */
1929 {
1934 }
1935 /* This can happen in our IR with things like n->a = *p */
1937 {
1938 /* Split into tmp = *rhs, *lhs = tmp */
1945 /* If this is an aggregate of known size, we should have passed
1946 this off to do_structure_copy, and it should have broken it
1947 up. */
1953 }
1955 {
1956 varinfo_t vi;
1963 }
1964 else
1965 {
1969 }
1970 }
1973 /* Return the position, in bits, of FIELD_DECL from the beginning of its
1974 structure. */
1976 static unsigned HOST_WIDE_INT
1978 {
1986 }
1989 /* Return true if an access to [ACCESSPOS, ACCESSSIZE]
1990 overlaps with a field at [FIELDPOS, FIELDSIZE] */
1992 static bool
1997 {
2006 }
2008 /* Given a COMPONENT_REF T, return the constraint_expr for it. */
2010 static struct constraint_expr
2012 {
2015 HOST_WIDE_INT bitpos;
2020 tree forzero;
2026 /* Some people like to do cute things like take the address of
2027 &0->a.b */
2033 {
2038 }
2044 /* This can also happen due to weird offsetof type macros. */
2048 /* If we know where this goes, then yay. Otherwise, booo. */
2051 {
2053 }
2055 {
2058 }
2059 else
2060 {
2063 }
2066 {
2067 /* In languages like C, you can access one past the end of an
2068 array. You aren't allowed to dereference it, so we can
2069 ignore this constraint. When we handle pointer subtraction,
2070 we may have to do something cute here. */
2073 {
2074 /* It's also not true that the constraint will actually start at the
2075 right offset, it may start in some padding. We only care about
2076 setting the constraint to the first actual field it touches, so
2077 walk to find it. */
2078 varinfo_t curr;
2080 {
2083 {
2087 }
2088 }
2089 /* assert that we found *some* field there. The user couldn't be
2090 accessing *only* padding. */
2093 }
2094 else
2099 }
2102 }
2105 /* Dereference the constraint expression CONS, and return the result.
2106 DEREF (ADDRESSOF) = SCALAR
2107 DEREF (SCALAR) = DEREF
2108 DEREF (DEREF) = (temp = DEREF1; result = DEREF(temp))
2109 This is needed so that we can handle dereferencing DEREF constraints. */
2111 static struct constraint_expr
2113 {
2115 {
2118 }
2120 {
2123 }
2125 {
2131 }
2133 }
2136 /* Given a tree T, return the constraint expression for it. */
2138 static struct constraint_expr
2140 {
2143 /* x = integer is all glommed to a single variable, which doesn't
2144 point to anything by itself. That is, of course, unless it is an
2145 integer constant being treated as a pointer, in which case, we
2146 will return that this is really the addressof anything. This
2147 happens below, since it will fall into the default case. The only
2148 case we know something about an integer treated like a pointer is
2149 when it is the NULL pointer, and then we just say it points to
2150 NULL. */
2153 {
2158 }
2161 {
2166 }
2169 {
2171 {
2173 {
2175 {
2179 else
2182 }
2186 /* XXX: In interprocedural mode, if we didn't have the
2187 body, we would need to do *each pointer argument =
2188 &ANYTHING added. */
2190 {
2191 varinfo_t vi;
2192 tree heapvar;
2206 }
2207 /* FALLTHRU */
2209 {
2214 }
2215 }
2216 }
2218 {
2220 {
2222 {
2226 }
2232 {
2237 }
2238 }
2239 }
2241 {
2243 {
2247 {
2250 /* Cast from non-pointer to pointers are bad news for us.
2251 Anything else, we see through */
2256 /* FALLTHRU */
2257 }
2259 {
2264 }
2265 }
2266 }
2268 {
2270 {
2276 {
2281 }
2282 }
2283 }
2287 {
2292 }
2293 }
2294 }
2297 /* Handle the structure copy case where we have a simple structure copy
2298 between LHS and RHS that is of SIZE (in bits)
2300 For each field of the lhs variable (lhsfield)
2301 For each field of the rhs variable at lhsfield.offset (rhsfield)
2302 add the constraint lhsfield = rhsfield
2303 */
2305 static void
2309 {
2315 {
2316 varinfo_t q;
2327 }
2328 }
2331 /* Handle the structure copy case where we have a structure copy between a
2332 aggregate on the LHS and a dereference of a pointer on the RHS
2333 that is of SIZE (in bits)
2335 For each field of the lhs variable (lhsfield)
2336 rhs.offset = lhsfield->offset
2337 add the constraint lhsfield = rhs
2338 */
2340 static void
2344 {
2351 {
2352 varinfo_t q;
2360 else
2367 }
2368 }
2370 /* Handle the structure copy case where we have a structure copy
2371 between a aggregate on the RHS and a dereference of a pointer on
2372 the LHS that is of SIZE (in bits)
2374 For each field of the rhs variable (rhsfield)
2375 lhs.offset = rhsfield->offset
2376 add the constraint lhs = rhsfield
2377 */
2379 static void
2383 {
2390 {
2391 varinfo_t q;
2399 else
2406 }
2407 }
2410 /* Handle aggregate copies by expanding into copies of the respective
2411 fields of the structures. */
2413 static void
2415 {
2417 varinfo_t p;
2424 /* If we have special var = x, swap it around. */
2426 {
2430 }
2432 /* This is fairly conservative for the RHS == ADDRESSOF case, in that it's
2433 possible it's something we could handle. However, most cases falling
2434 into this are dealing with transparent unions, which are slightly
2435 weird. */
2437 {
2440 }
2442 /* If the RHS is a special var, or an addressof, set all the LHS fields to
2443 that special var. */
2445 {
2447 {
2452 else
2455 }
2456 }
2457 else
2458 {
2464 /* If we have a variably sized types on the rhs or lhs, and a deref
2465 constraint, add the constraint, lhsconstraint = &ANYTHING.
2466 This is conservatively correct because either the lhs is an unknown
2467 sized var (if the constraint is SCALAR), or the lhs is a DEREF
2468 constraint, and every variable it can point to must be unknown sized
2469 anyway, so we don't need to worry about fields at all. */
2472 {
2478 }
2480 /* The size only really matters insofar as we don't set more or less of
2481 the variable. If we hit an unknown size var, the size should be the
2482 whole darn thing. */
2485 else
2490 else
2500 else
2501 {
2503 tree tmpvar;
2509 }
2510 }
2511 }
2513 /* Update related alias information kept in AI. This is used when
2514 building name tags, alias sets and deciding grouping heuristics.
2515 STMT is the statement to process. This function also updates
2516 ADDRESSABLE_VARS. */
2518 static void
2520 {
2521 bitmap addr_taken;
2522 use_operand_p use_p;
2523 ssa_op_iter iter;
2525 tree op;
2527 /* Mark all the variables whose address are taken by the statement. */
2530 {
2533 /* If STMT is an escape point, all the addresses taken by it are
2534 call-clobbered. */
2536 {
2537 bitmap_iterator bi;
2542 }
2543 }
2545 /* Process each operand use. If an operand may be aliased, keep
2546 track of how many times it's being used. For pointers, determine
2547 whether they are dereferenced by the statement, or whether their
2548 value escapes, etc. */
2550 {
2552 var_ann_t v_ann;
2559 /* If STMT is a PHI node, OP may be an ADDR_EXPR. If so, add it
2560 to the set of addressable variables. */
2562 {
2565 /* PHI nodes don't have annotations for pinning the set
2566 of addresses taken, so we collect them here.
2568 FIXME, should we allow PHI nodes to have annotations
2569 so that they can be treated like regular statements?
2570 Currently, they are treated as second-class
2571 statements. */
2574 }
2576 /* Ignore constants. */
2583 /* If the operand's variable may be aliased, keep track of how
2584 many times we've referenced it. This is used for alias
2585 grouping in compute_flow_insensitive_aliasing. */
2589 /* We are only interested in pointers. */
2595 /* Add OP to AI->PROCESSED_PTRS, if it's not there already. */
2597 {
2600 }
2602 /* If STMT is a PHI node, then it will not have pointer
2603 dereferences and it will not be an escape point. */
2607 /* Determine whether OP is a dereferenced pointer, and if STMT
2608 is an escape point, whether OP escapes. */
2611 /* Handle a corner case involving address expressions of the
2612 form '&PTR->FLD'. The problem with these expressions is that
2613 they do not represent a dereference of PTR. However, if some
2614 other transformation propagates them into an INDIRECT_REF
2615 expression, we end up with '*(&PTR->FLD)' which is folded
2616 into 'PTR->FLD'.
2618 So, if the original code had no other dereferences of PTR,
2619 the aliaser will not create memory tags for it, and when
2620 &PTR->FLD gets propagated to INDIRECT_REF expressions, the
2621 memory operations will receive no V_MAY_DEF/VUSE operands.
2623 One solution would be to have count_uses_and_derefs consider
2624 &PTR->FLD a dereference of PTR. But that is wrong, since it
2625 is not really a dereference but an offset calculation.
2627 What we do here is to recognize these special ADDR_EXPR
2628 nodes. Since these expressions are never GIMPLE values (they
2629 are not GIMPLE invariants), they can only appear on the RHS
2630 of an assignment and their base address is always an
2631 INDIRECT_REF expression. */
2636 {
2637 /* If the RHS if of the form &PTR->FLD and PTR == OP, then
2638 this represents a potential dereference of PTR. */
2644 }
2647 {
2648 /* Mark OP as dereferenced. In a subsequent pass,
2649 dereferenced pointers that point to a set of
2650 variables will be assigned a name tag to alias
2651 all the variables OP points to. */
2654 /* Keep track of how many time we've dereferenced each
2655 pointer. */
2658 /* If this is a store operation, mark OP as being
2659 dereferenced to store, otherwise mark it as being
2660 dereferenced to load. */
2663 else
2665 }
2668 {
2669 /* If STMT is an escape point and STMT contains at
2670 least one direct use of OP, then the value of OP
2671 escapes and so the pointed-to variables need to
2672 be marked call-clobbered. */
2675 /* If the statement makes a function call, assume
2676 that pointer OP will be dereferenced in a store
2677 operation inside the called function. */
2679 {
2682 }
2683 }
2684 }
2689 /* Update reference counter for definitions to any
2690 potentially aliased variable. This is used in the alias
2691 grouping heuristics. */
2693 {
2700 }
2702 /* Mark variables in V_MAY_DEF operands as being written to. */
2704 {
2707 }
2708 }
2711 /* Handle pointer arithmetic EXPR when creating aliasing constraints.
2712 Expressions of the type PTR + CST can be handled in two ways:
2714 1- If the constraint for PTR is ADDRESSOF for a non-structure
2715 variable, then we can use it directly because adding or
2716 subtracting a constant may not alter the original ADDRESSOF
2717 constraint (i.e., pointer arithmetic may not legally go outside
2718 an object's boundaries).
2720 2- If the constraint for PTR is ADDRESSOF for a structure variable,
2721 then if CST is a compile-time constant that can be used as an
2722 offset, we can determine which sub-variable will be pointed-to
2723 by the expression.
2725 Return true if the expression is handled. For any other kind of
2726 expression, return false so that each operand can be added as a
2727 separate constraint by the caller. */
2729 static bool
2731 {
2751 }
2754 /* Walk statement T setting up aliasing constraints according to the
2755 references found in T. This function is the main part of the
2756 constraint builder. AI points to auxiliary alias information used
2757 when building alias sets and computing alias grouping heuristics. */
2759 static void
2761 {
2764 /* Update various related attributes like escaped addresses, pointer
2765 dereferences for loads and stores. This is used when creating
2766 name tags and alias sets. */
2769 /* Now build constraints expressions. */
2771 {
2772 /* Only care about pointers and structures containing
2773 pointers. */
2776 {
2781 {
2784 }
2785 }
2786 }
2788 {
2795 {
2797 }
2798 else
2799 {
2800 /* Only care about operations with pointers, structures
2801 containing pointers, dereferences, and call expressions. */
2806 {
2809 {
2810 /* RHS that consist of unary operations,
2811 exceptional types, or bare decls/constants, get
2812 handled directly by get_constraint_for. */
2819 {
2824 /* When taking the address of an aggregate
2825 type, from the LHS we can access any field
2826 of the RHS. */
2830 {
2835 }
2836 }
2840 {
2841 /* For pointer arithmetic of the form
2842 PTR + CST, we can simply use PTR's
2843 constraint because pointer arithmetic is
2844 not allowed to go out of bounds. */
2847 }
2848 /* FALLTHRU */
2850 /* Otherwise, walk each operand. Notice that we
2851 can't use the operand interface because we need
2852 to process expressions other than simple operands
2853 (e.g. INDIRECT_REF, ADDR_EXPR, CALL_EXPR). */
2856 {
2860 }
2861 }
2862 }
2863 }
2864 }
2866 /* After promoting variables and computing aliasing we will
2867 need to re-scan most statements. FIXME: Try to minimize the
2868 number of statements re-scanned. It's not really necessary to
2869 re-scan *all* statements. */
2871 }
2874 /* Find the first varinfo in the same variable as START that overlaps with
2875 OFFSET.
2876 Effectively, walk the chain of fields for the variable START to find the
2877 first field that overlaps with OFFSET.
2878 Return NULL if we can't find one. */
2880 static varinfo_t
2882 {
2885 {
2886 /* We may not find a variable in the field list with the actual
2887 offset when when we have glommed a structure to a variable.
2888 In that case, however, offset should still be within the size
2889 of the variable. */
2893 }
2895 }
2898 /* Insert the varinfo FIELD into the field list for BASE, ordered by
2899 offset. */
2901 static void
2903 {
2908 {
2911 }
2912 else
2913 {
2915 {
2920 }
2923 }
2924 }
2926 /* qsort comparison function for two fieldoff's PA and PB */
2928 static int
2930 {
2941 }
2943 /* Sort a fieldstack according to the field offset and sizes. */
2945 {
2949 fieldoff_compare);
2950 }
2952 /* Given a TYPE, and a vector of field offsets FIELDSTACK, push all the fields
2953 of TYPE onto fieldstack, recording their offsets along the way.
2954 OFFSET is used to keep track of the offset in this entire structure, rather
2955 than just the immediately containing structure. Returns the number
2956 of fields pushed.
2957 HAS_UNION is set to true if we find a union type as a field of
2958 TYPE. */
2960 int
2963 {
2964 tree field;
2969 {
2985 /* Empty structures may have actual size, like in C++. So
2986 see if we didn't push any subfields and the size is
2987 nonzero, push the field onto the stack */
2991 {
2997 count++;
2998 }
2999 else
3001 }
3004 }
3006 static void
3008 {
3019 }
3021 /* Create a varinfo structure for NAME and DECL, and add it to VARMAP.
3022 This will also create any varinfo structures necessary for fields
3023 of DECL. */
3025 static unsigned int
3027 {
3029 varinfo_t vi;
3040 {
3043 {
3046 }
3047 }
3050 /* If the variable doesn't have subvars, we may end up needing to
3051 sort the field list and create fake variables for all the
3052 fields. */
3062 {
3066 }
3067 else
3068 {
3071 }
3080 && !notokay
3083 {
3087 tree field;
3090 {
3095 {
3098 }
3099 }
3101 /* We can't sort them if we have a field with a variable sized type,
3102 which will make notokay = true. In that case, we are going to return
3103 without creating varinfos for the fields anyway, so sorting them is a
3104 waste to boot. */
3112 {
3118 }
3124 {
3125 varinfo_t newvi;
3144 }
3146 }
3148 }
3150 /* Print out the points-to solution for VAR to FILE. */
3152 void
3154 {
3157 bitmap_iterator bi;
3161 {
3163 }
3165 }
3167 /* Print the points-to solution for VAR to stdout. */
3169 void
3171 {
3173 }
3176 /* Create varinfo structures for all of the variables in the
3177 function for intraprocedural mode. */
3179 static void
3181 {
3182 tree t;
3184 /* For each incoming argument arg, ARG = &ANYTHING */
3186 {
3189 varinfo_t p;
3200 {
3204 }
3205 }
3207 }
3209 /* Set bits in INTO corresponding to the variable uids in solution set
3210 FROM */
3212 static void
3214 {
3216 bitmap_iterator bi;
3218 subvar_t sv;
3221 {
3224 /* If we find ANYOFFSET in the solution and the solution
3225 includes SFTs for some structure, then all the SFTs in that
3226 structure will need to be added to the alias set. */
3228 {
3231 }
3233 /* The only artificial variables that are allowed in a may-alias
3234 set are heap variables. */
3239 {
3240 /* Variables containing unions may need to be converted to
3241 their SFT's, because SFT's can have unions and we cannot. */
3244 }
3247 {
3251 {
3252 /* If ANYOFFSET is in the solution set and VI->DECL is
3253 an aggregate variable with sub-variables, then any of
3254 the SFTs inside VI->DECL may have been accessed. Add
3255 all the sub-vars for VI->DECL. */
3258 }
3261 {
3262 /* If VI->DECL is an aggregate for which we created
3263 SFTs, add the SFT corresponding to VI->OFFSET. */
3266 }
3267 else
3268 {
3269 /* Otherwise, just add VI->DECL to the alias set. */
3271 }
3272 }
3273 }
3274 }
3279 /* Given a pointer variable P, fill in its points-to set, or return
3280 false if we can't. */
3282 bool
3284 {
3291 {
3297 /* See if this is a field or a structure. */
3299 {
3300 /* Nothing currently asks about structure fields directly,
3301 but when they do, we need code here to hand back the
3302 points-to set. */
3306 }
3307 else
3308 {
3311 bitmap_iterator bi;
3313 /* This variable may have been collapsed, let's get the real
3314 variable. */
3317 /* Translate artificial variables into SSA_NAME_PTR_INFO
3318 attributes. */
3320 {
3324 {
3325 /* FIXME. READONLY should be handled better so that
3326 flow insensitive aliasing can disregard writable
3327 aliases. */
3338 }
3339 }
3353 }
3354 }
3357 }
3360 /* Initialize things necessary to perform PTA */
3362 static void
3364 {
3366 }
3369 /* Dump points-to information to OUTFILE. */
3371 void
3373 {
3379 {
3388 }
3392 }
3395 /* Debug points-to information to stderr. */
3397 void
3399 {
3401 }
3404 /* Initialize the always-existing constraint variables for NULL
3405 ANYTHING, READONLY, and INTEGER */
3407 static void
3409 {
3412 /* Create the NULL variable, used to represent that a variable points
3413 to NULL. */
3425 /* Create the ANYTHING variable, used to represent that a variable
3426 points to some unknown piece of memory. */
3438 /* Anything points to anything. This makes deref constraints just
3439 work in the presence of linked list and other p = *p type loops,
3440 by saying that *ANYTHING = ANYTHING. */
3450 /* This specifically does not use process_constraint because
3451 process_constraint ignores all anything = anything constraints, since all
3452 but this one are redundant. */
3455 /* Create the READONLY variable, used to represent that a variable
3456 points to readonly memory. */
3469 /* readonly memory points to anything, in order to make deref
3470 easier. In reality, it points to anything the particular
3471 readonly variable can point to, but we don't track this
3472 separately. */
3482 /* Create the INTEGER variable, used to represent that a variable points
3483 to an INTEGER. */
3496 /* *INTEGER = ANYTHING, because we don't know where a dereference of a random
3497 integer will point to. */
3506 /* Create the ANYOFFSET variable, used to represent an arbitrary offset
3507 inside an object. This is similar to ANYTHING, but less drastic.
3508 It means that the pointer can point anywhere inside an object,
3509 but not outside of it. */
3513 anyoffset_id);
3523 /* ANYOFFSET points to ANYOFFSET. */
3531 }
3533 /* Return true if we actually need to solve the constraint graph in order to
3534 get our points-to sets. This is false when, for example, no addresses are
3535 taken other than special vars, or all points-to sets with members already
3536 contain the anything variable and there are no predecessors for other
3537 sets. */
3539 static bool
3541 {
3543 varinfo_t v;
3548 {
3565 }
3568 }
3570 /* Create points-to sets for the current function. See the comments
3571 at the start of the file for an algorithmic overview. */
3573 void
3575 {
3576 basic_block bb;
3598 /* Now walk all statements and derive aliases. */
3600 {
3601 block_stmt_iterator bsi;
3602 tree phi;
3610 }
3615 {
3618 }
3621 {
3633 }
3641 }
3644 /* Delete created points-to sets. */
3646 void
3648 {
3649 varinfo_t v;
3657 {
3661 }
3672 }