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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ C H 5 --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2014, Free Software Foundation, Inc. --
10 -- --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
20 -- --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
23 -- --
24 ------------------------------------------------------------------------------
68 -- This variable is used when processing if statements, case statements,
69 -- and block statements. It counts the number of exit points that are not
70 -- blocked by unconditional transfer instructions: for IF and CASE, these
71 -- are the branches of the conditional; for a block, they are the statement
72 -- sequence of the block, and the statement sequences of any exception
73 -- handlers that are part of the block. When processing is complete, if
74 -- this count is zero, it means that control cannot fall through the IF,
75 -- CASE or block statement. This is used for the generation of warning
76 -- messages. This variable is recursively saved on entry to processing the
77 -- construct, and restored on exit.
80 -- Determine expected type of range or domain of iteration of Ada 2012
81 -- loop by analyzing separate copy. Do the analysis and resolution of the
82 -- copy of the bound(s) with expansion disabled, to prevent the generation
83 -- of finalization actions. This prevents memory leaks when the bounds
84 -- contain calls to functions returning controlled arrays or when the
85 -- domain of iteration is a container.
87 ------------------------
88 -- Analyze_Assignment --
89 ------------------------
99 -- N is the node for the left hand side of an assignment, and it is not
100 -- a variable. This routine issues an appropriate diagnostic.
103 -- This is called to kill current value settings of a simple variable
104 -- on the left hand side. We call it if we find any error in analyzing
105 -- the assignment, and at the end of processing before setting any new
106 -- current values in place.
108 procedure Set_Assignment_Type
111 -- Opnd is either the Lhs or Rhs of the assignment, and Opnd_Type is the
112 -- nominal subtype. This procedure is used to deal with cases where the
113 -- nominal subtype must be replaced by the actual subtype.
115 -------------------------------
116 -- Diagnose_Non_Variable_Lhs --
117 -------------------------------
120 begin
121 -- Not worth posting another error if left hand side already flagged
122 -- as being illegal in some respect.
127 -- Some special bad cases of entity names
130 declare
133 begin
135 Error_Msg_N
139 -- Renamings of protected private components are turned into
140 -- constants when compiling a protected function. In the case
141 -- of single protected types, the private component appears
142 -- directly.
145 and then
149 or else
152 then
153 Error_Msg_N
163 -- For indexed components, test prefix if it is in array. We do not
164 -- want to recurse for cases where the prefix is a pointer, since we
165 -- may get a message confusing the pointer and what it references.
169 then
173 -- Another special case for assignment to discriminant
178 then
182 -- For selection from record, diagnose prefix, but note that again
183 -- we only do this for a record, not e.g. for a pointer.
191 -- If we fall through, we have no special message to issue
196 --------------
197 -- Kill_Lhs --
198 --------------
201 begin
203 declare
205 begin
213 -------------------------
214 -- Set_Assignment_Type --
215 -------------------------
217 procedure Set_Assignment_Type
220 is
221 begin
224 -- If the assignment operand is an in-out or out parameter, then we
225 -- get the actual subtype (needed for the unconstrained case). If the
226 -- operand is the actual in an entry declaration, then within the
227 -- accept statement it is replaced with a local renaming, which may
228 -- also have an actual subtype.
233 E_In_Out_Parameter,
234 E_Generic_In_Out_Parameter)
235 or else
238 N_Object_Renaming_Declaration
240 N_Accept_Statement))
241 then
244 -- If assignment operand is a component reference, then we get the
245 -- actual subtype of the component for the unconstrained case.
249 then
264 -- For slice, use the constrained subtype created for the slice
271 -- Start of processing for Analyze_Assignment
273 begin
279 -- Ensure that we never do an assignment on a variable marked as
280 -- as Safe_To_Reevaluate.
286 -- Start type analysis for assignment
290 -- In the most general case, both Lhs and Rhs can be overloaded, and we
291 -- must compute the intersection of the possible types on each side.
294 declare
298 begin
306 -- An explicit dereference is overloaded if the prefix
307 -- is. Try to remove the ambiguity on the prefix, the
308 -- error will be posted there if the ambiguity is real.
311 declare
317 begin
323 and then Has_Compatible_Type
325 then
327 PIt :=
332 Error_Msg_N
336 else
341 else
351 else
352 Error_Msg_N
356 else
366 Error_Msg_N
368 Kill_Lhs;
373 -- The resulting assignment type is T1, so now we will resolve the left
374 -- hand side of the assignment using this determined type.
378 -- Cases where Lhs is not a variable
382 -- Ada 2005 (AI-327): Check assignment to the attribute Priority of a
383 -- protected object.
385 declare
389 begin
392 -- Handle chains of renamings
398 loop
405 -- Renamings of the attribute Priority applied to protected
406 -- objects have been previously expanded into calls to the
407 -- Get_Ceiling run-time subprogram.
409 or else
412 or else
414 then
415 -- The enclosing subprogram cannot be a protected function
421 loop
427 then
428 Error_Msg_N
430 Lhs);
433 -- Changes of the ceiling priority of the protected object
434 -- are only effective if the Ceiling_Locking policy is in
435 -- effect (AARM D.5.2 (5/2)).
452 -- Error of assigning to limited type. We do however allow this in
453 -- certain cases where the front end generates the assignments.
459 then
460 -- CPP constructors can only be called in declarations
464 else
465 Error_Msg_N
471 -- Enforce RM 3.9.3 (8): the target of an assignment operation cannot be
472 -- abstract. This is only checked when the assignment Comes_From_Source,
473 -- because in some cases the expander generates such assignments (such
474 -- in the _assign operation for an abstract type).
477 Error_Msg_N
481 -- Resolution may have updated the subtype, in case the left-hand side
482 -- is a private protected component. Use the correct subtype to avoid
483 -- scoping issues in the back-end.
487 -- Ada 2005 (AI-50217, AI-326): Check wrong dereference of incomplete
488 -- type. For example:
490 -- limited with P;
491 -- package Pkg is
492 -- type Acc is access P.T;
493 -- end Pkg;
495 -- with Pkg; use Acc;
496 -- procedure Example is
497 -- A, B : Acc;
498 -- begin
499 -- A.all := B.all; -- ERROR
500 -- end Example;
504 then
506 Kill_Lhs;
510 -- Now we can complete the resolution of the right hand side
515 -- This is the point at which we check for an unset reference
520 -- Remaining steps are skipped if Rhs was syntactically in error
523 Kill_Lhs;
531 Kill_Lhs;
535 -- Ada 2005 (AI-326): In case of explicit dereference of incomplete
536 -- types, use the non-limited view if available
542 then
559 Kill_Lhs;
563 -- If the rhs is class-wide or dynamically tagged, then require the lhs
564 -- to be class-wide. The case where the rhs is a dynamically tagged call
565 -- to a dispatching operation with a controlling access result is
566 -- excluded from this check, since the target has an access type (and
567 -- no tag propagation occurs in that case).
573 then
580 then
584 -- Propagate the tag from a class-wide target to the rhs when the rhs
585 -- is a tag-indeterminate call.
594 then
595 Error_Msg_N
601 and then
603 then
604 Error_Msg_N
610 -- Ada 2005 (AI-385): When the lhs type is an anonymous access type,
611 -- apply an implicit conversion of the rhs to that type to force
612 -- appropriate static and run-time accessibility checks. This applies
613 -- as well to anonymous access-to-subprogram types that are component
614 -- subtypes or formal parameters.
620 -- Handle assignment to an Ada 2012 stand-alone object
621 -- of an anonymous access type.
625 N_Object_Declaration)
627 then
633 -- Ada 2005 (AI-231): Assignment to not null variable
638 then
639 -- Case where we know the right hand side is null
642 Apply_Compile_Time_Constraint_Error
644 Msg =>
648 -- We still mark this as a possible modification, that's necessary
649 -- to reset Is_True_Constant, and desirable for xref purposes.
654 -- If we know the right hand side is non-null, then we convert to the
655 -- target type, since we don't need a run time check in that case.
666 -- For array types, verify that lengths match. If the right hand side
667 -- is a function call that has been inlined, the assignment has been
668 -- rewritten as a block, and the constraint check will be applied to the
669 -- assignment within the block.
676 then
677 -- Assignment verifies that the length of the Lsh and Rhs are equal,
678 -- but of course the indexes do not have to match. If the right-hand
679 -- side is a type conversion to an unconstrained type, a length check
680 -- is performed on the expression itself during expansion. In rare
681 -- cases, the redundant length check is computed on an index type
682 -- with a different representation, triggering incorrect code in the
683 -- back end.
687 else
688 -- Discriminant checks are applied in the course of expansion
693 -- Note: modifications of the Lhs may only be recorded after
694 -- checks have been applied.
698 -- ??? a real accessibility check is needed when ???
700 -- Post warning for redundant assignment or variable to itself
702 if Warn_On_Redundant_Constructs
704 -- We only warn for source constructs
708 -- Where the object is the same on both sides
712 -- But exclude the case where the right side was an operation that
713 -- got rewritten (e.g. JUNK + K, where K was known to be zero). We
714 -- don't want to warn in such a case, since it is reasonable to write
715 -- such expressions especially when K is defined symbolically in some
716 -- other package.
719 then
721 Error_Msg_NE -- CODEFIX
723 else
724 Error_Msg_N -- CODEFIX
729 -- Check for non-allowed composite assignment
731 if not Support_Composite_Assign_On_Target
734 then
738 -- Check elaboration warning for left side if not in elab code
744 -- Set Referenced_As_LHS if appropriate. We only set this flag if the
745 -- assignment is a source assignment in the extended main source unit.
746 -- We are not interested in any reference information outside this
747 -- context, or in compiler generated assignment statements.
751 then
755 -- Final step. If left side is an entity, then we may be able to reset
756 -- the current tracked values to new safe values. We only have something
757 -- to do if the left side is an entity name, and expansion has not
758 -- modified the node into something other than an assignment, and of
759 -- course we only capture values if it is safe to do so.
763 then
764 declare
767 begin
770 -- If simple variable on left side, warn if this assignment
771 -- blots out another one (rendering it useless). We only do
772 -- this for source assignments, otherwise we can generate bogus
773 -- warnings when an assignment is rewritten as another
774 -- assignment, and gets tied up with itself.
776 if Warn_On_Modified_Unread
780 then
784 -- If we are assigning an access type and the left side is an
785 -- entity, then make sure that the Is_Known_[Non_]Null flags
786 -- properly reflect the state of the entity after assignment.
794 then
797 else
805 -- For discrete types, we may be able to set the current value
806 -- if the value is known at compile time.
810 then
812 else
816 -- If not safe to capture values, kill them
818 else
819 Kill_Lhs;
824 -- If assigning to an object in whole or in part, note location of
825 -- assignment in case no one references value. We only do this for
826 -- source assignments, otherwise we can generate bogus warnings when an
827 -- assignment is rewritten as another assignment, and gets tied up with
828 -- itself.
830 declare
832 begin
836 and then Warn_On_Modified_Unread
840 then
848 -----------------------------
849 -- Analyze_Block_Statement --
850 -----------------------------
854 -- Install all entities of return statement scope Scop in the visibility
855 -- chain except for the return object since its entity is reused in a
856 -- renaming.
858 -----------------------------
859 -- Install_Return_Entities --
860 -----------------------------
865 begin
869 -- Do not install the return object
873 then
881 -- Local constants and variables
889 -- Start of processing for Analyze_Block_Statement
891 begin
892 -- In SPARK mode, we reject block statements. Note that the case of
893 -- block statements generated by the expander is fine.
899 -- If no handled statement sequence is present, things are really messed
900 -- up, and we just return immediately (defence against previous errors).
903 Check_Error_Detected;
907 -- Detect whether the block is actually a rewritten return statement of
908 -- a build-in-place function.
910 Is_BIP_Return_Statement :=
914 and then Is_Build_In_Place_Function
917 -- Normal processing with HSS present
919 declare
925 -- Recursively save value of this global, will be restored on exit
927 begin
928 -- Initialize unblocked exit count for statements of begin block
929 -- plus one for each exception handler that is present.
937 -- If a label is present analyze it and mark it as referenced
943 -- An error defense. If we have an identifier, but no entity, then
944 -- something is wrong. If previous errors, then just remove the
945 -- identifier and continue, otherwise raise an exception.
948 Check_Error_Detected;
951 else
962 -- If no entity set, create a label entity
974 -- The block served as an extended return statement. Ensure that any
975 -- entities created during the analysis and expansion of the return
976 -- object declaration are once again visible.
984 Check_Completion;
991 -- If exception handlers are present, then we indicate that enclosing
992 -- scopes contain a block with handlers. We only need to mark non-
993 -- generic scopes.
997 loop
1008 End_Scope;
1013 else
1019 --------------------------------
1020 -- Analyze_Compound_Statement --
1021 --------------------------------
1024 begin
1028 ----------------------------
1029 -- Analyze_Case_Statement --
1030 ----------------------------
1039 -- Indicates if Others was present
1042 -- Don't care about assigned value
1045 -- Set True if at least some statement sequences get analyzed. If False
1046 -- on exit, means we had a serious error that prevented full analysis of
1047 -- the case statement, and as a result it is not a good idea to output
1048 -- warning messages about unreachable code.
1051 -- Recursively save value of this global, will be restored on exit
1054 -- Error routine invoked by the generic instantiation below when the
1055 -- case statement has a non static choice.
1058 -- Analyzes the statements associated with a case alternative. Needed
1059 -- by instantiation below.
1062 Generic_Analyze_Choices
1065 -- Instantiation of the generic choice analysis package
1068 Generic_Check_Choices
1073 -- Instantiation of the generic choice processing package
1075 -----------------------------
1076 -- Non_Static_Choice_Error --
1077 -----------------------------
1080 begin
1081 Flag_Non_Static_Expr
1085 ------------------------
1086 -- Process_Statements --
1087 ------------------------
1093 begin
1097 -- An interesting optimization. If the case statement expression
1098 -- is a simple entity, then we can set the current value within an
1099 -- alternative if the alternative has one possible value.
1101 -- case N is
1102 -- when 1 => alpha
1103 -- when 2 | 3 => beta
1104 -- when others => gamma
1106 -- Here we know that N is initially 1 within alpha, but for beta and
1107 -- gamma, we do not know anything more about the initial value.
1113 E_In_Out_Parameter,
1114 E_Out_Parameter)
1115 then
1119 then
1125 -- After analyzing the case, set the current value to empty
1126 -- since we won't know what it is for the next alternative
1127 -- (unless reset by this same circuit), or after the case.
1134 -- Case where expression is not an entity name of a variable
1139 -- Start of processing for Analyze_Case_Statement
1141 begin
1146 -- The expression must be of any discrete type. In rare cases, the
1147 -- expander constructs a case statement whose expression has a private
1148 -- type whose full view is discrete. This can happen when generating
1149 -- a stream operation for a variant type after the type is frozen,
1150 -- when the partial of view of the type of the discriminant is private.
1151 -- In that case, use the full view to analyze case alternatives.
1158 then
1162 else
1170 -- The expression must be of a discrete type which must be determinable
1171 -- independently of the context in which the expression occurs, but
1172 -- using the fact that the expression must be of a discrete type.
1173 -- Moreover, the type this expression must not be a character literal
1174 -- (which is always ambiguous) or, for Ada-83, a generic formal type.
1176 -- If error already reported by Resolve, nothing more to do
1182 Error_Msg_N
1189 then
1190 Error_Msg_N
1195 -- If the case expression is a formal object of mode in out, then treat
1196 -- it as having a nonstatic subtype by forcing use of the base type
1197 -- (which has to get passed to Check_Case_Choices below). Also use base
1198 -- type when the case expression is parenthesized.
1203 then
1207 -- Call instantiated procedures to analyzwe and check discrete choices
1212 -- Case statement with single OTHERS alternative not allowed in SPARK
1215 Check_SPARK_05_Restriction
1223 -- If all our exits were blocked by unconditional transfers of control,
1224 -- then the entire CASE statement acts as an unconditional transfer of
1225 -- control, so treat it like one, and check unreachable code. Skip this
1226 -- test if we had serious errors preventing any statement analysis.
1231 else
1235 -- If the expander is active it will detect the case of a statically
1236 -- determined single alternative and remove warnings for the case, but
1237 -- if we are not doing expansion, that circuit won't be active. Here we
1238 -- duplicate the effect of removing warnings in the same way, so that
1239 -- we will get the same set of warnings in -gnatc mode.
1241 if not Expander_Active
1244 then
1245 declare
1249 begin
1262 ----------------------------
1263 -- Analyze_Exit_Statement --
1264 ----------------------------
1266 -- If the exit includes a name, it must be the name of a currently open
1267 -- loop. Otherwise there must be an innermost open loop on the stack, to
1268 -- which the statement implicitly refers.
1270 -- Additionally, in SPARK mode:
1272 -- The exit can only name the closest enclosing loop;
1274 -- An exit with a when clause must be directly contained in a loop;
1276 -- An exit without a when clause must be directly contained in an
1277 -- if-statement with no elsif or else, which is itself directly contained
1278 -- in a loop. The exit must be the last statement in the if-statement.
1287 begin
1300 else
1302 Check_SPARK_05_Restriction
1309 else
1324 then
1327 else
1328 Error_Msg_N
1334 -- Verify that if present the condition is a Boolean expression
1341 -- In SPARK mode, verify that the exit statement respects the SPARK
1342 -- restrictions.
1346 Check_SPARK_05_Restriction
1350 else
1353 Check_SPARK_05_Restriction
1355 else
1360 Check_SPARK_05_Restriction
1363 -- First test the presence of ELSE, so that an exit in an ELSE leads
1364 -- to an error mentioning the ELSE.
1369 -- An exit in an ELSIF does not reach here, as it would have been
1370 -- detected in the case (Nkind (Parent (N)) /= N_If_Statement).
1377 -- Chain exit statement to associated loop entity
1382 -- Since the exit may take us out of a loop, any previous assignment
1383 -- statement is not useless, so clear last assignment indications. It
1384 -- is OK to keep other current values, since if the exit statement
1385 -- does not exit, then the current values are still valid.
1390 ----------------------------
1391 -- Analyze_Goto_Statement --
1392 ----------------------------
1400 begin
1403 -- Actual semantic checks
1411 -- Ignore previous error
1414 Check_Error_Detected;
1417 -- We just have a label as the target of a goto
1423 -- Check that the target of the goto is reachable according to Ada
1424 -- scoping rules. Note: the special gotos we generate for optimizing
1425 -- local handling of exceptions would violate these rules, but we mark
1426 -- such gotos as analyzed when built, so this code is never entered.
1433 -- Here if goto passes initial validity checks
1442 then
1444 Error_Msg_N
1455 --------------------------
1456 -- Analyze_If_Statement --
1457 --------------------------
1459 -- A special complication arises in the analysis of if statements
1461 -- The expander has circuitry to completely delete code that it can tell
1462 -- will not be executed (as a result of compile time known conditions). In
1463 -- the analyzer, we ensure that code that will be deleted in this manner
1464 -- is analyzed but not expanded. This is obviously more efficient, but
1465 -- more significantly, difficulties arise if code is expanded and then
1466 -- eliminated (e.g. exception table entries disappear). Similarly, itypes
1467 -- generated in deleted code must be frozen from start, because the nodes
1468 -- on which they depend will not be available at the freeze point.
1474 -- Recursively save value of this global, will be restored on exit
1479 -- This flag gets set True if a True condition has been found, which
1480 -- means that remaining ELSE/ELSIF parts are deleted.
1483 -- This is applied to either the N_If_Statement node itself or to an
1484 -- N_Elsif_Part node. It deals with analyzing the condition and the THEN
1485 -- statements associated with it.
1487 -----------------------
1488 -- Analyze_Cond_Then --
1489 -----------------------
1495 begin
1501 -- If already deleting, then just analyze then statements
1506 -- Compile time known value, not deleting yet
1511 -- If condition is True, then analyze the THEN statements and set
1512 -- no expansion for ELSE and ELSIF parts.
1520 -- If condition is False, analyze THEN with expansion off
1526 Expander_Mode_Restore;
1530 -- Not known at compile time, not deleting, normal analysis
1532 else
1537 -- Start of Analyze_If_Statement
1539 begin
1540 -- Initialize exit count for else statements. If there is no else part,
1541 -- this count will stay non-zero reflecting the fact that the uncovered
1542 -- else case is an unblocked exit.
1547 -- Now to analyze the elsif parts if any are present
1561 -- If all our exits were blocked by unconditional transfers of control,
1562 -- then the entire IF statement acts as an unconditional transfer of
1563 -- control, so treat it like one, and check unreachable code.
1568 else
1573 Expander_Mode_Restore;
1577 if not Expander_Active
1580 then
1592 else
1597 -- Warn on redundant if statement that has no effect
1599 -- Note, we could also check empty ELSIF parts ???
1601 if Warn_On_Redundant_Constructs
1603 -- If statement must be from source
1607 -- Condition must not have obvious side effect
1611 -- No elsif parts of else part
1616 -- Then must be a single null statement
1619 then
1620 -- Go to original node, since we may have rewritten something as
1621 -- a null statement (e.g. a case we could figure the outcome of).
1623 declare
1627 begin
1635 ----------------------------------------
1636 -- Analyze_Implicit_Label_Declaration --
1637 ----------------------------------------
1639 -- An implicit label declaration is generated in the innermost enclosing
1640 -- declarative part. This is done for labels, and block and loop names.
1642 -- Note: any changes in this routine may need to be reflected in
1643 -- Analyze_Label_Entity.
1647 begin
1654 ------------------------------
1655 -- Analyze_Iteration_Scheme --
1656 ------------------------------
1663 begin
1664 -- For an infinite loop, there is no iteration scheme
1682 else
1687 ------------------------------------
1688 -- Analyze_Iterator_Specification --
1689 ------------------------------------
1702 -- For an iteration over a container, if the loop carries the Reverse
1703 -- indicator, verify that the container type has an Iterate aspect that
1704 -- implements the reversible iterator interface.
1706 -----------------------------
1707 -- Check_Reverse_Iteration --
1708 -----------------------------
1711 begin
1715 then
1716 Error_Msg_NE
1721 -- Start of processing for Analyze_iterator_Specification
1723 begin
1729 -- Save type of subtype indication for subsequent check
1733 else
1740 -- Set the kind of the loop variable, which is not visible within
1741 -- the iterator name.
1745 -- Provide a link between the iterator variable and the container, for
1746 -- subsequent use in cross-reference and modification information.
1751 -- For a container, the iterator is specified through the aspect.
1754 declare
1756 Find_Value_Of_Aspect
1762 begin
1769 -- If Iterator is overloaded, use reversible iterator if
1770 -- one is available.
1777 then
1792 -- If the domain of iteration is an expression, create a declaration for
1793 -- it, so that finalization actions are introduced outside of the loop.
1794 -- The declaration must be a renaming because the body of the loop may
1795 -- assign to elements.
1799 -- When the context is a quantified expression, the renaming
1800 -- declaration is delayed until the expansion phase if we are
1801 -- doing expansion.
1806 -- Do not perform this expansion in SPARK mode, since the formal
1807 -- verification directly deals with the source form of the iterator.
1808 -- Ditto for ASIS, where the temporary may hide the transformation
1809 -- of a selected component into a prefixed function call.
1811 and then not GNATprove_Mode
1812 and then not ASIS_Mode
1813 then
1814 declare
1819 begin
1821 -- If the domain of iteration is an array component that depends
1822 -- on a discriminant, create actual subtype for it. Pre-analysis
1823 -- does not generate the actual subtype of a selected component.
1827 then
1828 Act_S :=
1829 Build_Actual_Subtype_Of_Component
1835 else
1839 else
1843 -- Protect against malformed iterator
1854 -- The name in the renaming declaration may be a function call.
1855 -- Indicate that it does not come from source, to suppress
1856 -- spurious warnings on renamings of parameterless functions,
1857 -- a common enough idiom in user-defined iterators.
1859 Decl :=
1863 Name =>
1872 -- Container is an entity or an array with uncontrolled components, or
1873 -- else it is a container iterator given by a function call, typically
1874 -- called Iterate in the case of predefined containers, even though
1875 -- Iterate is not a reserved name. What matters is that the return type
1876 -- of the function is an iterator type.
1882 declare
1887 begin
1891 else
1910 -- Domain of iteration is not overloaded
1912 else
1921 -- Get base type of container, for proper retrieval of Cursor type
1922 -- and primitive operations.
1932 then
1933 Error_Msg_N
1937 -- Here we have a missing Range attribute
1939 else
1940 Error_Msg_N
1943 -- In Ada 2012 mode, this may be an attempt at an iterator
1946 Error_Msg_NE
1951 -- Prevent cascaded errors
1957 -- Check for type error in iterator
1962 -- Iteration over a container
1964 else
1968 -- OF present
1972 declare
1975 begin
1977 Error_Msg_N
1979 else
1984 -- For a predefined container, The type of the loop variable is
1985 -- the Iterator_Element aspect of the container type.
1987 else
1988 declare
1992 begin
1997 else
2000 -- If subtype indication was given, verify that it
2001 -- matches element type of container.
2005 then
2006 Error_Msg_N
2008 Subt);
2011 -- If the container has a variable indexing aspect, the
2012 -- element is a variable and is modifiable in the loop.
2021 -- OF not present
2023 else
2024 -- For an iteration of the form IN, the name must denote an
2025 -- iterator, typically the result of a call to Iterate. Give a
2026 -- useful error message when the name is a container by itself.
2028 -- The type may be a formal container type, which has to have
2029 -- an Iterable aspect detailing the required primitives.
2033 then
2038 Error_Msg_NE
2040 else
2041 Error_Msg_N
2047 else
2048 Error_Msg_NE
2054 -- The result type of Iterate function is the classwide type of
2055 -- the interface parent. We need the specific Cursor type defined
2056 -- in the container package. We obtain it by name for a predefined
2057 -- container, or through the Iterable aspect for a formal one.
2061 Get_Cursor_Type
2063 Typ));
2066 else
2080 -- A loop parameter cannot be effectively volatile. This check is
2081 -- peformed only when SPARK_Mode is on as it is not a standard Ada
2082 -- legality check (SPARK RM 7.1.3(6)).
2084 -- Not clear whether this applies to element iterators, where the
2085 -- cursor is not an explicit entity ???
2090 then
2095 -------------------
2096 -- Analyze_Label --
2097 -------------------
2099 -- Note: the semantic work required for analyzing labels (setting them as
2100 -- reachable) was done in a prepass through the statements in the block,
2101 -- so that forward gotos would be properly handled. See Analyze_Statements
2102 -- for further details. The only processing required here is to deal with
2103 -- optimizations that depend on an assumption of sequential control flow,
2104 -- since of course the occurrence of a label breaks this assumption.
2108 begin
2109 Kill_Current_Values;
2112 --------------------------
2113 -- Analyze_Label_Entity --
2114 --------------------------
2117 begin
2124 ------------------------------------------
2125 -- Analyze_Loop_Parameter_Specification --
2126 ------------------------------------------
2132 -- If the bounds are given by a 'Range reference on a function call
2133 -- that returns a controlled array, introduce an explicit declaration
2134 -- to capture the bounds, so that the function result can be finalized
2135 -- in timely fashion.
2138 -- Diagnose Attempt to iterate through non-static predicate. Note that
2139 -- a type with inherited predicates may have both static and dynamic
2140 -- forms. In this case it is not sufficent to check the static predicate
2141 -- function only, look for a dynamic predicate aspect as well.
2144 -- N is the node for an arbitrary construct. This function searches the
2145 -- construct N to see if any expressions within it contain function
2146 -- calls that use the secondary stack, returning True if any such call
2147 -- is found, and False otherwise.
2150 -- If the iteration is given by a range, create temporaries and
2151 -- assignment statements block to capture the bounds and perform
2152 -- required finalization actions in case a bound includes a function
2153 -- call that uses the temporary stack. We first pre-analyze a copy of
2154 -- the range in order to determine the expected type, and analyze and
2155 -- resolve the original bounds.
2157 --------------------------------------
2158 -- Check_Controlled_Array_Attribute --
2159 --------------------------------------
2162 begin
2167 and then
2169 and then Expander_Active
2170 then
2171 declare
2179 begin
2180 Decl :=
2183 Subtype_Indication =>
2186 Constraint =>
2201 -------------------------
2202 -- Check_Predicate_Use --
2203 -------------------------
2206 begin
2207 -- A predicated subtype is illegal in loops and related constructs
2208 -- if the predicate is not static, or if it is a non-static subtype
2209 -- of a statically predicated subtype.
2216 then
2217 -- Seems a confusing message for the case of a static predicate
2218 -- with a non-static subtype???
2220 Bad_Predicated_Subtype_Use
2230 ------------------------------------
2231 -- Has_Call_Using_Secondary_Stack --
2232 ------------------------------------
2237 -- Check if N is a function call which uses the secondary stack
2239 ----------------
2240 -- Check_Call --
2241 ----------------
2248 begin
2252 -- Call using access to subprogram with explicit dereference
2257 -- Call using a selected component notation or Ada 2005 object
2258 -- operation notation
2263 -- Common case
2265 else
2273 then
2281 -- Continue traversing the tree
2288 -- Start of processing for Has_Call_Using_Secondary_Stack
2290 begin
2294 --------------------
2295 -- Process_Bounds --
2296 --------------------
2301 function One_Bound
2305 -- Capture value of bound and return captured value
2307 ---------------
2308 -- One_Bound --
2309 ---------------
2311 function One_Bound
2315 is
2320 begin
2321 -- If the bound is a constant or an object, no need for a separate
2322 -- declaration. If the bound is the result of previous expansion
2323 -- it is already analyzed and should not be modified. Note that
2324 -- the Bound will be resolved later, if needed, as part of the
2325 -- call to Make_Index (literal bounds may need to be resolved to
2326 -- type Integer).
2332 N_Character_Literal)
2334 then
2339 -- Normally, the best approach is simply to generate a constant
2340 -- declaration that captures the bound. However, there is a nasty
2341 -- case where this is wrong. If the bound is complex, and has a
2342 -- possible use of the secondary stack, we need to generate a
2343 -- separate assignment statement to ensure the creation of a block
2344 -- which will release the secondary stack.
2346 -- We prefer the constant declaration, since it leaves us with a
2347 -- proper trace of the value, useful in optimizations that get rid
2348 -- of junk range checks.
2353 -- Ensure that the bound is valid. This check should not be
2354 -- generated when the range belongs to a quantified expression
2355 -- as the construct is still not expanded into its final form.
2359 then
2369 -- Here we make a declaration with a separate assignment
2370 -- statement, and insert before loop header.
2372 Decl :=
2377 Assign :=
2384 -- Now that this temporary variable is initialized we decorate it
2385 -- as safe-to-reevaluate to inform to the backend that no further
2386 -- asignment will be issued and hence it can be handled as side
2387 -- effect free. Note that this decoration must be done when the
2388 -- assignment has been analyzed because otherwise it will be
2389 -- rejected (see Analyze_Assignment).
2397 else
2409 -- Start of processing for Process_Bounds
2411 begin
2416 -- If the type of the discrete range is Universal_Integer, then the
2417 -- bound's type must be resolved to Integer, and any object used to
2418 -- hold the bound must also have type Integer, unless the literal
2419 -- bounds are constant-folded expressions with a user-defined type.
2425 then
2431 then
2434 else
2444 -- Propagate staticness to loop range itself, in case the
2445 -- corresponding subtype is static.
2456 -- Local variables
2463 -- Start of processing for Analyze_Loop_Parameter_Specification
2465 begin
2468 -- We always consider the loop variable to be referenced, since the loop
2469 -- may be used just for counting purposes.
2473 -- Check for the case of loop variable hiding a local variable (used
2474 -- later on to give a nice warning if the hidden variable is never
2475 -- assigned).
2477 declare
2479 begin
2484 then
2489 -- Loop parameter specification must include subtype mark in SPARK
2492 Check_SPARK_05_Restriction
2496 -- Analyze the subtype definition and create temporaries for the bounds.
2497 -- Do not evaluate the range when preanalyzing a quantified expression
2498 -- because bounds expressed as function calls with side effects will be
2499 -- incorrectly replicated.
2502 and then Expander_Active
2504 then
2507 -- Either the expander not active or the range of iteration is a subtype
2508 -- indication, an entity, or a function call that yields an aggregate or
2509 -- a container.
2511 else
2516 -- Ada 2012: If the domain of iteration is:
2518 -- a) a function call,
2519 -- b) an identifier that is not a type,
2520 -- c) an attribute reference 'Old (within a postcondition)
2521 -- d) an unchecked conversion
2523 -- then it is an iteration over a container. It was classified as
2524 -- a loop specification by the parser, and must be rewritten now
2525 -- to activate container iteration. The last case will occur within
2526 -- an expanded inlined call, where the expansion wraps an actual in
2527 -- an unchecked conversion when needed. The expression of the
2528 -- conversion is always an object.
2538 then
2539 -- This is an iterator specification. Rewrite it as such and
2540 -- analyze it to capture function calls that may require
2541 -- finalization actions.
2543 declare
2552 begin
2557 -- In a generic context, analyze the original domain of
2558 -- iteration, for name capture.
2564 -- Set kind of loop parameter, which may be used in the
2565 -- subsequent analysis of the condition in a quantified
2566 -- expression.
2572 -- Domain of iteration is not a function call, and is side-effect
2573 -- free.
2575 else
2576 -- A quantified expression that appears in a pre/post condition
2577 -- is pre-analyzed several times. If the range is given by an
2578 -- attribute reference it is rewritten as a range, and this is
2579 -- done even with expansion disabled. If the type is already set
2580 -- do not reanalyze, because a range with static bounds may be
2581 -- typed Integer by default.
2585 then
2587 else
2597 -- Some additional checks if we are iterating through a type
2602 then
2603 -- The subtype indication may denote the completion of an incomplete
2604 -- type declaration.
2614 -- Error if not discrete type
2630 -- A quantified expression which appears in a pre- or post-condition may
2631 -- be analyzed multiple times. The analysis of the range creates several
2632 -- itypes which reside in different scopes depending on whether the pre-
2633 -- or post-condition has been expanded. Update the type of the loop
2634 -- variable to reflect the proper itype at each stage of analysis.
2638 or else
2643 N_Quantified_Expression)
2644 then
2648 -- Treat a range as an implicit reference to the type, to inhibit
2649 -- spurious warnings.
2654 -- The loop is not a declarative part, so the loop variable must be
2655 -- frozen explicitly. Do not freeze while preanalyzing a quantified
2656 -- expression because the freeze node will not be inserted into the
2657 -- tree due to flag Is_Spec_Expression being set.
2660 declare
2662 begin
2669 -- Case where we have a range or a subtype, get type bounds
2675 then
2676 declare
2680 begin
2684 else
2685 L :=
2687 H :=
2691 -- Check for null or possibly null range and issue warning. We
2692 -- suppress such messages in generic templates and instances,
2693 -- because in practice they tend to be dubious in these cases. The
2694 -- check applies as well to rewritten array element loops where a
2695 -- null range may be detected statically.
2699 -- Suppress the warning if inside a generic template or
2700 -- instance, since in practice they tend to be dubious in these
2701 -- cases since they can result from intended parameterization.
2705 -- Specialize msg if invalid values could make the loop
2706 -- non-null after all.
2708 if Compile_Time_Compare
2710 then
2711 -- Since we know the range of the loop is null, set the
2712 -- appropriate flag to remove the loop entirely during
2713 -- expansion.
2718 Error_Msg_N
2722 -- Here is where the loop could execute because of
2723 -- invalid values, so issue appropriate message and in
2724 -- this case we do not set the Is_Null_Loop flag since
2725 -- the loop may execute.
2728 Error_Msg_N
2730 DS);
2731 Error_Msg_N
2733 DS);
2737 -- In either case, suppress warnings in the body of the loop,
2738 -- since it is likely that these warnings will be inappropriate
2739 -- if the loop never actually executes, which is likely.
2743 -- The other case for a warning is a reverse loop where the
2744 -- upper bound is the integer literal zero or one, and the
2745 -- lower bound may exceed this value.
2747 -- For example, we have
2749 -- for J in reverse N .. 1 loop
2751 -- In practice, this is very likely to be a case of reversing
2752 -- the bounds incorrectly in the range.
2756 and then
2758 or else
2760 then
2761 -- Lower bound may in fact be known and known not to exceed
2762 -- upper bound (e.g. reverse 0 .. 1) and that's OK.
2766 then
2769 -- Otherwise warning is warranted
2771 else
2777 -- Check if either bound is known to be outside the range of the
2778 -- loop parameter type, this is e.g. the case of a loop from
2779 -- 20..X where the type is 1..19.
2781 -- Such a loop is dubious since either it raises CE or it executes
2782 -- zero times, and that cannot be useful!
2788 then
2789 declare
2796 -- Suspicious loop bound
2798 begin
2799 -- At this stage L, H are the bounds of the type, and LLo
2800 -- Lhi are the low bound and high bound of the loop.
2803 or else
2805 then
2810 or else
2812 then
2817 Error_Msg_N
2820 Error_Msg_N
2827 -- This declare block is about warnings, if we get an exception while
2828 -- testing for warnings, we simply abandon the attempt silently. This
2829 -- most likely occurs as the result of a previous error, but might
2830 -- just be an obscure case we have missed. In either case, not giving
2831 -- the warning is perfectly acceptable.
2833 exception
2838 -- A loop parameter cannot be effectively volatile. This check is
2839 -- peformed only when SPARK_Mode is on as it is not a standard Ada
2840 -- legality check (SPARK RM 7.1.3(6)).
2847 ----------------------------
2848 -- Analyze_Loop_Statement --
2849 ----------------------------
2854 -- Given a loop iteration scheme, determine whether it is an Ada 2012
2855 -- container iteration.
2858 -- Determine whether node N is the sole statement of a block
2860 ---------------------------
2861 -- Is_Container_Iterator --
2862 ---------------------------
2865 begin
2866 -- Infinite loop
2871 -- While loop
2876 -- for Def_Id in [reverse] Name loop
2877 -- for Def_Id [: Subtype_Indication] of [reverse] Name loop
2880 declare
2884 begin
2889 -- The only two options here are iteration over a container or
2890 -- an array.
2895 -- for Def_Id in [reverse] Discrete_Subtype_Definition loop
2897 else
2898 declare
2903 begin
2908 -- Check for a call to Iterate ()
2910 return
2917 -------------------------
2918 -- Is_Wrapped_In_Block --
2919 -------------------------
2924 begin
2925 return
2932 -- Local declarations
2940 -- Start of processing for Analyze_Loop_Statement
2942 begin
2945 -- Make name visible, e.g. for use in exit statements. Loop labels
2946 -- are always considered to be referenced.
2951 -- Guard against serious error (typically, a scope mismatch when
2952 -- semantic analysis is requested) by creating loop entity to
2953 -- continue analysis.
2958 else
2962 -- Verify that the loop name is hot hidden by an unrelated
2963 -- declaration in an inner scope.
2971 then
2976 else
2980 -- If we found a label, mark its type. If not, ignore it, since it
2981 -- means we have a conflicting declaration, which would already
2982 -- have been diagnosed at declaration time. Set Label_Construct
2983 -- of the implicit label declaration, which is not created by the
2984 -- parser for generic units.
2995 -- Case of no identifier present
2997 else
3003 -- Iteration over a container in Ada 2012 involves the creation of a
3004 -- controlled iterator object. Wrap the loop in a block to ensure the
3005 -- timely finalization of the iterator and release of container locks.
3006 -- The same applies to the use of secondary stack when obtaining an
3007 -- iterator.
3012 then
3013 declare
3017 begin
3018 Block_Nod :=
3021 Handled_Statement_Sequence =>
3027 -- The expansion of iterator loops generates an iterator in order
3028 -- to traverse the elements of a container:
3030 -- Iter : <iterator type> := Iterate (Container)'reference;
3032 -- The iterator is controlled and returned on the secondary stack.
3033 -- The analysis of the call to Iterate establishes a transient
3034 -- scope to deal with the secondary stack management, but never
3035 -- really creates a physical block as this would kill the iterator
3036 -- too early (see Wrap_Transient_Declaration). To address this
3037 -- case, mark the generated block as needing secondary stack
3038 -- management.
3048 -- Kill current values on entry to loop, since statements in the body of
3049 -- the loop may have been executed before the loop is entered. Similarly
3050 -- we kill values after the loop, since we do not know that the body of
3051 -- the loop was executed.
3053 Kill_Current_Values;
3057 -- Check for following case which merits a warning if the type E of is
3058 -- a multi-dimensional array (and no explicit subscript ranges present).
3060 -- for J in E'Range
3061 -- for K in E'Range
3065 then
3066 declare
3070 begin
3074 then
3075 declare
3077 begin
3082 then
3083 declare
3090 begin
3095 then
3097 Error_Msg_N
3107 -- Analyze the statements of the body except in the case of an Ada 2012
3108 -- iterator with the expander active. In this case the expander will do
3109 -- a rewrite of the loop into a while loop. We will then analyze the
3110 -- loop body when we analyze this while loop.
3112 -- We need to do this delay because if the container is for indefinite
3113 -- types the actual subtype of the components will only be determined
3114 -- when the cursor declaration is analyzed.
3116 -- If the expander is not active, or in SPARK mode, then we want to
3117 -- analyze the loop body now even in the Ada 2012 iterator case, since
3118 -- the rewriting will not be done. Insert the loop variable in the
3119 -- current scope, if not done when analysing the iteration scheme.
3120 -- Set its kind properly to detect improper uses in the loop body.
3124 then
3126 declare
3130 begin
3135 -- In an element iterator, The loop parameter is a variable if
3136 -- the domain of iteration (container or array) is a variable.
3140 then
3148 else
3150 -- Pre-Ada2012 for-loops and while loops.
3155 -- When the iteration scheme of a loop contains attribute 'Loop_Entry,
3156 -- the loop is transformed into a conditional block. Retrieve the loop.
3164 -- Finish up processing for the loop. We kill all current values, since
3165 -- in general we don't know if the statements in the loop have been
3166 -- executed. We could do a bit better than this with a loop that we
3167 -- know will execute at least once, but it's not worth the trouble and
3168 -- the front end is not in the business of flow tracing.
3171 End_Scope;
3172 Kill_Current_Values;
3174 -- Check for infinite loop. Skip check for generated code, since it
3175 -- justs waste time and makes debugging the routine called harder.
3177 -- Note that we have to wait till the body of the loop is fully analyzed
3178 -- before making this call, since Check_Infinite_Loop_Warning relies on
3179 -- being able to use semantic visibility information to find references.
3185 -- Code after loop is unreachable if the loop has no WHILE or FOR and
3186 -- contains no EXIT statements within the body of the loop.
3193 ----------------------------
3194 -- Analyze_Null_Statement --
3195 ----------------------------
3197 -- Note: the semantics of the null statement is implemented by a single
3198 -- null statement, too bad everything isn't as simple as this.
3202 begin
3206 ------------------------
3207 -- Analyze_Statements --
3208 ------------------------
3214 begin
3215 -- The labels declared in the statement list are reachable from
3216 -- statements in the list. We do this as a prepass so that any goto
3217 -- statement will be properly flagged if its target is not reachable.
3218 -- This is not required, but is nice behavior.
3226 -- If we found a label mark it as reachable
3236 -- If we failed to find a label, it means the implicit declaration
3237 -- of the label was hidden. A for-loop parameter can do this to
3238 -- a label with the same name inside the loop, since the implicit
3239 -- label declaration is in the innermost enclosing body or block
3240 -- statement.
3242 else
3244 Error_Msg_N
3253 -- Perform semantic analysis on all statements
3255 Conditional_Statements_Begin;
3261 -- Remove dimension in all statements
3267 Conditional_Statements_End;
3269 -- Make labels unreachable. Visibility is not sufficient, because labels
3270 -- in one if-branch for example are not reachable from the other branch,
3271 -- even though their declarations are in the enclosing declarative part.
3283 ----------------------------
3284 -- Check_Unreachable_Code --
3285 ----------------------------
3291 begin
3293 declare
3296 begin
3299 -- Skip past pragmas
3305 -- If a label follows us, then we never have dead code, since
3306 -- someone could branch to the label, so we just ignore it, unless
3307 -- we are in formal mode where goto statements are not allowed.
3311 then
3314 -- Otherwise see if we have a real statement following us
3319 then
3320 -- Special very annoying exception. If we have a return that
3321 -- follows a raise, then we allow it without a warning, since
3322 -- the Ada RM annoyingly requires a useless return here.
3326 then
3327 -- The rather strange shenanigans with the warning message
3328 -- here reflects the fact that Kill_Dead_Code is very good
3329 -- at removing warnings in deleted code, and this is one
3330 -- warning we would prefer NOT to have removed.
3334 -- If we have unreachable code, analyze and remove the
3335 -- unreachable code, since it is useless and we don't
3336 -- want to generate junk warnings.
3338 -- We skip this step if we are not in code generation mode
3339 -- or CodePeer mode.
3341 -- This is the one case where we remove dead code in the
3342 -- semantics as opposed to the expander, and we do not want
3343 -- to remove code if we are not in code generation mode,
3344 -- since this messes up the ASIS trees or loses useful
3345 -- information in the CodePeer tree.
3347 -- Note that one might react by moving the whole circuit to
3348 -- exp_ch5, but then we lose the warning in -gnatc mode.
3351 and then not CodePeer_Mode
3352 then
3353 loop
3356 -- Quit deleting when we have nothing more to delete
3357 -- or if we hit a label (since someone could transfer
3358 -- control to a label, so we should not delete it).
3362 -- Statement/declaration is to be deleted
3370 -- Now issue the warning (or error in formal mode)
3373 Check_SPARK_05_Restriction
3375 else
3380 -- If the unconditional transfer of control instruction is the
3381 -- last statement of a sequence, then see if our parent is one of
3382 -- the constructs for which we count unblocked exits, and if so,
3383 -- adjust the count.
3385 else
3388 -- Statements in THEN part or ELSE part of IF statement
3393 -- Statements in ELSIF part of an IF statement
3399 -- Statements in CASE statement alternative
3405 -- Statements in body of block
3409 then
3410 -- The original loop is now placed inside a block statement
3411 -- due to the expansion of attribute 'Loop_Entry. Return as
3412 -- this is not a "real" block for the purposes of exit
3413 -- counting.
3417 then
3421 -- Statements in exception handler in a block
3426 then
3429 -- None of these cases, so return
3431 else
3435 -- This was one of the cases we are looking for (i.e. the
3436 -- parent construct was IF, CASE or block) so decrement count.
3444 ----------------------
3445 -- Preanalyze_Range --
3446 ----------------------
3452 begin
3460 -- Apply preference rules for range of predefined integer types, or
3461 -- diagnose true ambiguity.
3463 declare
3468 begin
3474 else
3481 else
3482 -- Both of them are user-defined
3484 Error_Msg_N
3499 -- Subtype mark in iteration scheme
3504 -- Expression in range, or Ada 2012 iterator
3513 -- Check that the resulting object is an iterable container
3518 then
3521 -- The expression may yield an implicit reference to an iterable
3522 -- container. Insert explicit dereference so that proper type is
3523 -- visible in the loop.
3526 declare
3529 begin
3544 Expander_Mode_Restore;