1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1992-2010, Free Software Foundation, Inc. --
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. --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
24 ------------------------------------------------------------------------------
26 -- Package containing utility procedures used throughout the expander
28 with Exp_Tss
; use Exp_Tss
;
29 with Namet
; use Namet
;
30 with Rtsfind
; use Rtsfind
;
31 with Sinfo
; use Sinfo
;
32 with Types
; use Types
;
36 -----------------------------------------------
37 -- Handling of Actions Associated with Nodes --
38 -----------------------------------------------
40 -- The evaluation of certain expression nodes involves the elaboration
41 -- of associated types and other declarations, and the execution of
42 -- statement sequences. Expansion routines generating such actions must
43 -- find an appropriate place in the tree to hang the actions so that
44 -- they will be evaluated at the appropriate point.
46 -- Some cases are simple:
48 -- For an expression occurring in a simple statement that is in a list
49 -- of statements, the actions are simply inserted into the list before
50 -- the associated statement.
52 -- For an expression occurring in a declaration (declarations always
53 -- appear in lists), the actions are similarly inserted into the list
54 -- just before the associated declaration.
56 -- The following special cases arise:
58 -- For actions associated with the right operand of a short circuit
59 -- form, the actions are first stored in the short circuit form node
60 -- in the Actions field. The expansion of these forms subsequently
61 -- expands the short circuit forms into if statements which can then
62 -- be moved as described above.
64 -- For actions appearing in the Condition expression of a while loop,
65 -- or an elsif clause, the actions are similarly temporarily stored in
66 -- in the node (N_Elsif_Part or N_Iteration_Scheme) associated with
67 -- the expression using the Condition_Actions field. Subsequently, the
68 -- expansion of these nodes rewrites the control structures involved to
69 -- reposition the actions in normal statement sequence.
71 -- For actions appearing in the then or else expression of a conditional
72 -- expression, these actions are similarly placed in the node, using the
73 -- Then_Actions or Else_Actions field as appropriate. Once again the
74 -- expansion of the N_Conditional_Expression node rewrites the node so
75 -- that the actions can be normally positioned.
77 -- Basically what we do is to climb up to the tree looking for the
78 -- proper insertion point, as described by one of the above cases,
79 -- and then insert the appropriate action or actions.
81 -- Note if more than one insert call is made specifying the same
82 -- Assoc_Node, then the actions are elaborated in the order of the
83 -- calls, and this guarantee is preserved for the special cases above.
85 procedure Insert_Action
86 (Assoc_Node
: Node_Id
;
87 Ins_Action
: Node_Id
);
88 -- Insert the action Ins_Action at the appropriate point as described
89 -- above. The action is analyzed using the default checks after it is
90 -- inserted. Assoc_Node is the node with which the action is associated.
92 procedure Insert_Action
93 (Assoc_Node
: Node_Id
;
96 -- Insert the action Ins_Action at the appropriate point as described
97 -- above. The action is analyzed using the default checks as modified
98 -- by the given Suppress argument after it is inserted. Assoc_Node is
99 -- the node with which the action is associated.
101 procedure Insert_Actions
102 (Assoc_Node
: Node_Id
;
103 Ins_Actions
: List_Id
);
104 -- Insert the list of action Ins_Actions at the appropriate point as
105 -- described above. The actions are analyzed using the default checks
106 -- after they are inserted. Assoc_Node is the node with which the actions
107 -- are associated. Ins_Actions may be No_List, in which case the call has
110 procedure Insert_Actions
111 (Assoc_Node
: Node_Id
;
112 Ins_Actions
: List_Id
;
113 Suppress
: Check_Id
);
114 -- Insert the list of action Ins_Actions at the appropriate point as
115 -- described above. The actions are analyzed using the default checks
116 -- as modified by the given Suppress argument after they are inserted.
117 -- Assoc_Node is the node with which the actions are associated.
118 -- Ins_Actions may be No_List, in which case the call has no effect.
120 procedure Insert_Actions_After
121 (Assoc_Node
: Node_Id
;
122 Ins_Actions
: List_Id
);
123 -- Assoc_Node must be a node in a list. Same as Insert_Actions but
124 -- actions will be inserted after N in a manner that is compatible with
125 -- the transient scope mechanism. This procedure must be used instead
126 -- of Insert_List_After if Assoc_Node may be in a transient scope.
128 -- Implementation limitation: Assoc_Node must be a statement. We can
129 -- generalize to expressions if there is a need but this is tricky to
130 -- implement because of short-circuits (among other things).???
132 procedure Insert_Library_Level_Action
(N
: Node_Id
);
133 -- This procedure inserts and analyzes the node N as an action at the
134 -- library level for the current unit (i.e. it is attached to the
135 -- Actions field of the N_Compilation_Aux node for the main unit).
137 procedure Insert_Library_Level_Actions
(L
: List_Id
);
138 -- Similar, but inserts a list of actions
140 -----------------------
141 -- Other Subprograms --
142 -----------------------
144 procedure Adjust_Condition
(N
: Node_Id
);
145 -- The node N is an expression whose root-type is Boolean, and which
146 -- represents a boolean value used as a condition (i.e. a True/False
147 -- value). This routine handles the case of C and Fortran convention
148 -- boolean types, which have zero/non-zero semantics rather than the normal
149 -- 0/1 semantics, and also the case of an enumeration rep clause that
150 -- specifies a non-standard representation. On return, node N always has
151 -- the type Standard.Boolean, with a value that is a standard Boolean
152 -- values of 0/1 for False/True. This procedure is used in two situations.
153 -- First, the processing for a condition field always calls
154 -- Adjust_Condition, so that the boolean value presented to the backend is
155 -- a standard value. Second, for the code for boolean operations such as
156 -- AND, Adjust_Condition is called on both operands, and then the operation
157 -- is done in the domain of Standard_Boolean, then Adjust_Result_Type is
158 -- called on the result to possibly reset the original type. This procedure
159 -- also takes care of validity checking if Validity_Checks = Tests.
161 procedure Adjust_Result_Type
(N
: Node_Id
; T
: Entity_Id
);
162 -- The processing of boolean operations like AND uses the procedure
163 -- Adjust_Condition so that it can operate on Standard.Boolean, which is
164 -- the only boolean type on which the backend needs to be able to implement
165 -- such operators. This means that the result is also of type
166 -- Standard.Boolean. In general the type must be reset back to the original
167 -- type to get proper semantics, and that is the purpose of this procedure.
168 -- N is the node (of type Standard.Boolean), and T is the desired type. As
169 -- an optimization, this procedure leaves the type as Standard.Boolean in
170 -- contexts where this is permissible (in particular for Condition fields,
171 -- and for operands of other logical operations higher up the tree). The
172 -- call to this procedure is completely ignored if the argument N is not of
175 procedure Append_Freeze_Action
(T
: Entity_Id
; N
: Node_Id
);
176 -- Add a new freeze action for the given type. The freeze action is
177 -- attached to the freeze node for the type. Actions will be elaborated in
178 -- the order in which they are added. Note that the added node is not
179 -- analyzed. The analyze call is found in Exp_Ch13.Expand_N_Freeze_Entity.
181 procedure Append_Freeze_Actions
(T
: Entity_Id
; L
: List_Id
);
182 -- Adds the given list of freeze actions (declarations or statements) for
183 -- the given type. The freeze actions are attached to the freeze node for
184 -- the type. Actions will be elaborated in the order in which they are
185 -- added, and the actions within the list will be elaborated in list order.
186 -- Note that the added nodes are not analyzed. The analyze call is found in
187 -- Exp_Ch13.Expand_N_Freeze_Entity.
189 function Build_Runtime_Call
(Loc
: Source_Ptr
; RE
: RE_Id
) return Node_Id
;
190 -- Build an N_Procedure_Call_Statement calling the given runtime entity.
191 -- The call has no parameters. The first argument provides the location
192 -- information for the tree and for error messages. The call node is not
193 -- analyzed on return, the caller is responsible for analyzing it.
195 function Build_Task_Image_Decls
199 In_Init_Proc
: Boolean := False) return List_Id
;
200 -- Build declaration for a variable that holds an identifying string to be
201 -- used as a task name. Id_Ref is an identifier if the task is a variable,
202 -- and a selected or indexed component if the task is component of an
203 -- object. If it is an indexed component, A_Type is the corresponding array
204 -- type. Its index types are used to build the string as an image of the
205 -- index values. For composite types, the result includes two declarations:
206 -- one for a generated function that computes the image without using
207 -- concatenation, and one for the variable that holds the result.
209 -- If In_Init_Proc is true, the call is part of the initialization of
210 -- a component of a composite type, and the enclosing initialization
211 -- procedure must be flagged as using the secondary stack. If In_Init_Proc
212 -- is false, the call is for a stand-alone object, and the generated
213 -- function itself must do its own cleanups.
215 function Component_May_Be_Bit_Aligned
(Comp
: Entity_Id
) return Boolean;
216 -- This function is in charge of detecting record components that may
217 -- cause trouble in the back end if an attempt is made to assign the
218 -- component. The back end can handle such assignments with no problem if
219 -- the components involved are small (64-bits or less) records or scalar
220 -- items (including bit-packed arrays represented with modular types) or
221 -- are both aligned on a byte boundary (starting on a byte boundary, and
222 -- occupying an integral number of bytes).
224 -- However, problems arise for records larger than 64 bits, or for arrays
225 -- (other than bit-packed arrays represented with a modular type) if the
226 -- component starts on a non-byte boundary, or does not occupy an integral
227 -- number of bytes (i.e. there are some bits possibly shared with fields
228 -- at the start or beginning of the component). The back end cannot handle
229 -- loading and storing such components in a single operation.
231 -- This function is used to detect the troublesome situation. it is
232 -- conservative in the sense that it produces True unless it knows for
233 -- sure that the component is safe (as outlined in the first paragraph
234 -- above). The code generation for record and array assignment checks for
235 -- trouble using this function, and if so the assignment is generated
236 -- component-wise, which the back end is required to handle correctly.
238 -- Note that in GNAT 3, the back end will reject such components anyway,
239 -- so the hard work in checking for this case is wasted in GNAT 3, but
240 -- it is harmless, so it is easier to do it in all cases, rather than
241 -- conditionalize it in GNAT 5 or beyond.
243 procedure Convert_To_Actual_Subtype
(Exp
: Node_Id
);
244 -- The Etype of an expression is the nominal type of the expression,
245 -- not the actual subtype. Often these are the same, but not always.
246 -- For example, a reference to a formal of unconstrained type has the
247 -- unconstrained type as its Etype, but the actual subtype is obtained by
248 -- applying the actual bounds. This routine is given an expression, Exp,
249 -- and (if necessary), replaces it using Rewrite, with a conversion to
250 -- the actual subtype, building the actual subtype if necessary. If the
251 -- expression is already of the requested type, then it is unchanged.
253 function Corresponding_Runtime_Package
(Typ
: Entity_Id
) return RTU_Id
;
254 -- Return the id of the runtime package that will provide support for
255 -- concurrent type Typ. Currently only protected types are supported,
256 -- and the returned value is one of the following:
257 -- System_Tasking_Protected_Objects
258 -- System_Tasking_Protected_Objects_Entries
259 -- System_Tasking_Protected_Objects_Single_Entry
261 function Current_Sem_Unit_Declarations
return List_Id
;
262 -- Return the place where it is fine to insert declarations for the
263 -- current semantic unit. If the unit is a package body, return the
264 -- visible declarations of the corresponding spec. For RCI stubs, this
265 -- is necessary because the point at which they are generated may not
266 -- be the earliest point at which they are used.
268 function Duplicate_Subexpr
270 Name_Req
: Boolean := False) return Node_Id
;
271 -- Given the node for a subexpression, this function makes a logical copy
272 -- of the subexpression, and returns it. This is intended for use when the
273 -- expansion of an expression needs to repeat part of it. For example,
274 -- replacing a**2 by a*a requires two references to a which may be a
275 -- complex subexpression. Duplicate_Subexpr guarantees not to duplicate
276 -- side effects. If necessary, it generates actions to save the expression
277 -- value in a temporary, inserting these actions into the tree using
278 -- Insert_Actions with Exp as the insertion location. The original
279 -- expression and the returned result then become references to this saved
280 -- value. Exp must be analyzed on entry. On return, Exp is analyzed, but
281 -- the caller is responsible for analyzing the returned copy after it is
282 -- attached to the tree. The Name_Req flag is set to ensure that the result
283 -- is suitable for use in a context requiring name (e.g. the prefix of an
284 -- attribute reference).
286 -- Note that if there are any run time checks in Exp, these same checks
287 -- will be duplicated in the returned duplicated expression. The two
288 -- following functions allow this behavior to be modified.
290 function Duplicate_Subexpr_No_Checks
292 Name_Req
: Boolean := False) return Node_Id
;
293 -- Identical in effect to Duplicate_Subexpr, except that Remove_Checks
294 -- is called on the result, so that the duplicated expression does not
295 -- include checks. This is appropriate for use when Exp, the original
296 -- expression is unconditionally elaborated before the duplicated
297 -- expression, so that there is no need to repeat any checks.
299 function Duplicate_Subexpr_Move_Checks
301 Name_Req
: Boolean := False) return Node_Id
;
302 -- Identical in effect to Duplicate_Subexpr, except that Remove_Checks is
303 -- called on Exp after the duplication is complete, so that the original
304 -- expression does not include checks. In this case the result returned
305 -- (the duplicated expression) will retain the original checks. This is
306 -- appropriate for use when the duplicated expression is sure to be
307 -- elaborated before the original expression Exp, so that there is no need
308 -- to repeat the checks.
310 procedure Ensure_Defined
(Typ
: Entity_Id
; N
: Node_Id
);
311 -- This procedure ensures that type referenced by Typ is defined. For the
312 -- case of a type other than an Itype, nothing needs to be done, since
313 -- all such types have declaration nodes. For Itypes, an N_Itype_Reference
314 -- node is generated and inserted at the given node N. This is typically
315 -- used to ensure that an Itype is properly defined outside a conditional
316 -- construct when it is referenced in more than one branch.
318 function Entry_Names_OK
return Boolean;
319 -- Determine whether it is appropriate to dynamically allocate strings
320 -- which represent entry [family member] names. These strings are created
321 -- by the compiler and used by GDB.
323 procedure Evolve_And_Then
(Cond
: in out Node_Id
; Cond1
: Node_Id
);
324 -- Rewrites Cond with the expression: Cond and then Cond1. If Cond is
325 -- Empty, then simply returns Cond1 (this allows the use of Empty to
326 -- initialize a series of checks evolved by this routine, with a final
327 -- result of Empty indicating that no checks were required). The Sloc field
328 -- of the constructed N_And_Then node is copied from Cond1.
330 procedure Evolve_Or_Else
(Cond
: in out Node_Id
; Cond1
: Node_Id
);
331 -- Rewrites Cond with the expression: Cond or else Cond1. If Cond is Empty,
332 -- then simply returns Cond1 (this allows the use of Empty to initialize a
333 -- series of checks evolved by this routine, with a final result of Empty
334 -- indicating that no checks were required). The Sloc field of the
335 -- constructed N_Or_Else node is copied from Cond1.
337 procedure Expand_Subtype_From_Expr
339 Unc_Type
: Entity_Id
;
340 Subtype_Indic
: Node_Id
;
342 -- Build a constrained subtype from the initial value in object
343 -- declarations and/or allocations when the type is indefinite (including
346 function Find_Init_Call
348 Rep_Clause
: Node_Id
) return Node_Id
;
349 -- Look for init_proc call for variable Var, either among declarations
350 -- between that of Var and a subsequent Rep_Clause applying to Var, or
351 -- in the list of freeze actions associated with Var, and if found, return
354 function Find_Interface_ADT
356 Iface
: Entity_Id
) return Elmt_Id
;
357 -- Ada 2005 (AI-251): Given a type T implementing the interface Iface,
358 -- return the element of Access_Disp_Table containing the tag of the
361 function Find_Interface_Tag
363 Iface
: Entity_Id
) return Entity_Id
;
364 -- Ada 2005 (AI-251): Given a type T implementing the interface Iface,
365 -- return the record component containing the tag of Iface.
367 function Find_Prim_Op
(T
: Entity_Id
; Name
: Name_Id
) return Entity_Id
;
368 -- Find the first primitive operation of type T whose name is 'Name'.
369 -- This function allows the use of a primitive operation which is not
370 -- directly visible. If T is a class wide type, then the reference is
371 -- to an operation of the corresponding root type. Raises Program_Error
372 -- exception if no primitive operation is found. This is normally an
373 -- internal error, but in some cases is an expected consequence of
374 -- illegalities elsewhere.
376 function Find_Prim_Op
378 Name
: TSS_Name_Type
) return Entity_Id
;
379 -- Find the first primitive operation of type T whose name has the form
380 -- indicated by the name parameter (i.e. is a type support subprogram
381 -- with the indicated suffix). This function allows use of a primitive
382 -- operation which is not directly visible. If T is a class wide type,
383 -- then the reference is to an operation of the corresponding root type.
384 -- Raises Program_Error exception if no primitive operation is found.
385 -- This is normally an internal error, but in some cases is an expected
386 -- consequence of illegalities elsewhere.
388 function Find_Protection_Object
(Scop
: Entity_Id
) return Entity_Id
;
389 -- Traverse the scope stack starting from Scop and look for an entry,
390 -- entry family, or a subprogram that has a Protection_Object and return
391 -- it. Raises Program_Error if no such entity is found since the context
392 -- in which this routine is invoked should always have a protection
395 procedure Force_Evaluation
397 Name_Req
: Boolean := False);
398 -- Force the evaluation of the expression right away. Similar behavior
399 -- to Remove_Side_Effects when Variable_Ref is set to TRUE. That is to
400 -- say, it removes the side-effects and captures the values of the
401 -- variables. Remove_Side_Effects guarantees that multiple evaluations
402 -- of the same expression won't generate multiple side effects, whereas
403 -- Force_Evaluation further guarantees that all evaluations will yield
406 function Fully_Qualified_Name_String
(E
: Entity_Id
) return String_Id
;
407 -- Generates the string literal corresponding to the fully qualified name
408 -- of entity E with an ASCII.NUL appended at the end of the name.
410 procedure Generate_Poll_Call
(N
: Node_Id
);
411 -- If polling is active, then a call to the Poll routine is built,
412 -- and then inserted before the given node N and analyzed.
414 procedure Get_Current_Value_Condition
418 -- This routine processes the Current_Value field of the variable Var. If
419 -- the Current_Value field is null or if it represents a known value, then
420 -- on return Cond is set to N_Empty, and Val is set to Empty.
422 -- The other case is when Current_Value points to an N_If_Statement or an
423 -- N_Elsif_Part or a N_Iteration_Scheme node (see description in Einfo for
424 -- exact details). In this case, Get_Current_Condition digs out the
425 -- condition, and then checks if the condition is known false, known true,
426 -- or not known at all. In the first two cases, Get_Current_Condition will
427 -- return with Op set to the appropriate conditional operator (inverted if
428 -- the condition is known false), and Val set to the constant value. If the
429 -- condition is not known, then Op and Val are set for the empty case
430 -- (N_Empty and Empty).
432 -- The check for whether the condition is true/false unknown depends
435 -- For an IF, the condition is known true in the THEN part, known false
436 -- in any ELSIF or ELSE part, and not known outside the IF statement in
439 -- For an ELSIF, the condition is known true in the ELSIF part, known
440 -- FALSE in any subsequent ELSIF, or ELSE part, and not known before the
441 -- ELSIF, or after the end of the IF statement.
443 -- The caller can use this result to determine the value (for the case of
444 -- N_Op_Eq), or to determine the result of some other test in other cases
445 -- (e.g. no access check required if N_Op_Ne Null).
447 function Has_Controlled_Coextensions
(Typ
: Entity_Id
) return Boolean;
448 -- Determine whether a record type has anonymous access discriminants with
449 -- a controlled designated type.
451 function Has_Following_Address_Clause
(D
: Node_Id
) return Boolean;
452 -- D is the node for an object declaration. This function searches the
453 -- current declarative part to look for an address clause for the object
454 -- being declared, and returns True if one is found.
456 function Homonym_Number
(Subp
: Entity_Id
) return Nat
;
457 -- Here subp is the entity for a subprogram. This routine returns the
458 -- homonym number used to disambiguate overloaded subprograms in the same
459 -- scope (the number is used as part of constructed names to make sure that
460 -- they are unique). The number is the ordinal position on the Homonym
461 -- chain, counting only entries in the current scope. If an entity is not
462 -- overloaded, the returned number will be one.
464 function Inside_Init_Proc
return Boolean;
465 -- Returns True if current scope is within an init proc
467 function In_Unconditional_Context
(Node
: Node_Id
) return Boolean;
468 -- Node is the node for a statement or a component of a statement. This
469 -- function determines if the statement appears in a context that is
470 -- unconditionally executed, i.e. it is not within a loop or a conditional
471 -- or a case statement etc.
473 function Is_All_Null_Statements
(L
: List_Id
) return Boolean;
474 -- Return True if all the items of the list are N_Null_Statement nodes.
475 -- False otherwise. True for an empty list. It is an error to call this
476 -- routine with No_List as the argument.
478 function Is_Fully_Repped_Tagged_Type
(T
: Entity_Id
) return Boolean;
479 -- Tests given type T, and returns True if T is a non-discriminated tagged
480 -- type which has a record representation clause that specifies the layout
481 -- of all the components, including recursively components in all parent
482 -- types. We exclude discriminated types for convenience, it is extremely
483 -- unlikely that the special processing associated with the use of this
484 -- routine is useful for the case of a discriminated type, and testing for
485 -- component overlap would be a pain.
487 function Is_Library_Level_Tagged_Type
(Typ
: Entity_Id
) return Boolean;
488 -- Return True if Typ is a library level tagged type. Currently we use
489 -- this information to build statically allocated dispatch tables.
491 function Is_Ref_To_Bit_Packed_Array
(N
: Node_Id
) return Boolean;
492 -- Determine whether the node P is a reference to a bit packed array, i.e.
493 -- whether the designated object is a component of a bit packed array, or a
494 -- subcomponent of such a component. If so, then all subscripts in P are
495 -- evaluated with a call to Force_Evaluation, and True is returned.
496 -- Otherwise False is returned, and P is not affected.
498 function Is_Ref_To_Bit_Packed_Slice
(N
: Node_Id
) return Boolean;
499 -- Determine whether the node P is a reference to a bit packed slice, i.e.
500 -- whether the designated object is bit packed slice or a component of a
501 -- bit packed slice. Return True if so.
503 function Is_Possibly_Unaligned_Slice
(N
: Node_Id
) return Boolean;
504 -- Determine whether the node P is a slice of an array where the slice
505 -- result may cause alignment problems because it has an alignment that
506 -- is not compatible with the type. Return True if so.
508 function Is_Possibly_Unaligned_Object
(N
: Node_Id
) return Boolean;
509 -- Node N is an object reference. This function returns True if it is
510 -- possible that the object may not be aligned according to the normal
511 -- default alignment requirement for its type (e.g. if it appears in a
512 -- packed record, or as part of a component that has a component clause.)
514 function Is_Renamed_Object
(N
: Node_Id
) return Boolean;
515 -- Returns True if the node N is a renamed object. An expression is
516 -- considered to be a renamed object if either it is the Name of an object
517 -- renaming declaration, or is the prefix of a name which is a renamed
518 -- object. For example, in:
520 -- x : r renames a (1 .. 2) (1);
522 -- We consider that a (1 .. 2) is a renamed object since it is the prefix
523 -- of the name in the renaming declaration.
525 function Is_Untagged_Derivation
(T
: Entity_Id
) return Boolean;
526 -- Returns true if type T is not tagged and is a derived type,
527 -- or is a private type whose completion is such a type.
529 function Is_Volatile_Reference
(N
: Node_Id
) return Boolean;
530 -- Checks if the node N represents a volatile reference, which can be
531 -- either a direct reference to a variable treated as volatile, or an
532 -- indexed/selected component where the prefix is treated as volatile,
533 -- or has Volatile_Components set. A slice of a volatile variable is
536 procedure Kill_Dead_Code
(N
: Node_Id
; Warn
: Boolean := False);
537 -- N represents a node for a section of code that is known to be dead. Any
538 -- exception handler references and warning messages relating to this code
539 -- are removed. If Warn is True, a warning will be output at the start of N
540 -- indicating the deletion of the code. Note that the tree for the deleted
541 -- code is left intact so that e.g. cross-reference data is still valid.
543 procedure Kill_Dead_Code
(L
: List_Id
; Warn
: Boolean := False);
544 -- Like the above procedure, but applies to every element in the given
545 -- list. If Warn is True, a warning will be output at the start of N
546 -- indicating the deletion of the code.
548 function Known_Non_Negative
(Opnd
: Node_Id
) return Boolean;
549 -- Given a node for a subexpression, determines if it represents a value
550 -- that cannot possibly be negative, and if so returns True. A value of
551 -- False means that it is not known if the value is positive or negative.
553 function Known_Non_Null
(N
: Node_Id
) return Boolean;
554 -- Given a node N for a subexpression of an access type, determines if
555 -- this subexpression yields a value that is known at compile time to
556 -- be non-null and returns True if so. Returns False otherwise. It is
557 -- an error to call this function if N is not of an access type.
559 function Known_Null
(N
: Node_Id
) return Boolean;
560 -- Given a node N for a subexpression of an access type, determines if this
561 -- subexpression yields a value that is known at compile time to be null
562 -- and returns True if so. Returns False otherwise. It is an error to call
563 -- this function if N is not of an access type.
565 function Make_Invariant_Call
(Expr
: Node_Id
) return Node_Id
;
566 -- Expr is an object of a type which Has_Invariants set (and which thus
567 -- also has an Invariant_Procedure set). If invariants are enabled, this
568 -- function returns a call to the Invariant procedure passing Expr as the
569 -- argument, and returns it unanalyzed. If invariants are not enabled,
570 -- returns a null statement.
572 function Make_Predicate_Call
574 Expr
: Node_Id
) return Node_Id
;
575 -- Typ is a type with Predicate_Function set. This routine builds a call to
576 -- this function passing Expr as the argument, and returns it unanalyzed.
578 function Make_Predicate_Check
580 Expr
: Node_Id
) return Node_Id
;
581 -- Typ is a type with Predicate_Function set. This routine builds a Check
582 -- pragma whose first argument is Predicate, and the second argument is a
583 -- call to the this predicate function with Expr as the argument.
585 function Make_Subtype_From_Expr
587 Unc_Typ
: Entity_Id
) return Node_Id
;
588 -- Returns a subtype indication corresponding to the actual type of an
589 -- expression E. Unc_Typ is an unconstrained array or record, or
592 function May_Generate_Large_Temp
(Typ
: Entity_Id
) return Boolean;
593 -- Determines if the given type, Typ, may require a large temporary of the
594 -- kind that causes back-end trouble if stack checking is enabled. The
595 -- result is True only the size of the type is known at compile time and
596 -- large, where large is defined heuristically by the body of this routine.
597 -- The purpose of this routine is to help avoid generating troublesome
598 -- temporaries that interfere with stack checking mechanism. Note that the
599 -- caller has to check whether stack checking is actually enabled in order
600 -- to guide the expansion (typically of a function call).
602 function Needs_Constant_Address
604 Typ
: Entity_Id
) return Boolean;
605 -- Check whether the expression in an address clause is restricted to
606 -- consist of constants, when the object has a non-trivial initialization
609 function Non_Limited_Designated_Type
(T
: Entity_Id
) return Entity_Id
;
610 -- An anonymous access type may designate a limited view. Check whether
611 -- non-limited view is available during expansion, to examine components
612 -- or other characteristics of the full type.
614 function OK_To_Do_Constant_Replacement
(E
: Entity_Id
) return Boolean;
615 -- This function is used when testing whether or not to replace a reference
616 -- to entity E by a known constant value. Such replacement must be done
617 -- only in a scope known to be safe for such replacements. In particular,
618 -- if we are within a subprogram and the entity E is declared outside the
619 -- subprogram then we cannot do the replacement, since we do not attempt to
620 -- trace subprogram call flow. It is also unsafe to replace statically
621 -- allocated values (since they can be modified outside the scope), and we
622 -- also inhibit replacement of Volatile or aliased objects since their
623 -- address might be captured in a way we do not detect. A value of True is
624 -- returned only if the replacement is safe.
626 function Possible_Bit_Aligned_Component
(N
: Node_Id
) return Boolean;
627 -- This function is used during processing the assignment of a record or
628 -- indexed component. The argument N is either the left hand or right hand
629 -- side of an assignment, and this function determines if there is a record
630 -- component reference where the record may be bit aligned in a manner that
631 -- causes trouble for the back end (see Component_May_Be_Bit_Aligned for
634 procedure Remove_Side_Effects
636 Name_Req
: Boolean := False;
637 Variable_Ref
: Boolean := False);
638 -- Given the node for a subexpression, this function replaces the node if
639 -- necessary by an equivalent subexpression that is guaranteed to be side
640 -- effect free. This is done by extracting any actions that could cause
641 -- side effects, and inserting them using Insert_Actions into the tree to
642 -- which Exp is attached. Exp must be analyzed and resolved before the call
643 -- and is analyzed and resolved on return. The Name_Req may only be set to
644 -- True if Exp has the form of a name, and the effect is to guarantee that
645 -- any replacement maintains the form of name. If Variable_Ref is set to
646 -- TRUE, a variable is considered as side effect (used in implementing
647 -- Force_Evaluation). Note: after call to Remove_Side_Effects, it is safe
648 -- to call New_Copy_Tree to obtain a copy of the resulting expression.
650 function Represented_As_Scalar
(T
: Entity_Id
) return Boolean;
651 -- Returns True iff the implementation of this type in code generation
652 -- terms is scalar. This is true for scalars in the Ada sense, and for
653 -- packed arrays which are represented by a scalar (modular) type.
655 function Safe_Unchecked_Type_Conversion
(Exp
: Node_Id
) return Boolean;
656 -- Given the node for an N_Unchecked_Type_Conversion, return True if this
657 -- is an unchecked conversion that Gigi can handle directly. Otherwise
658 -- return False if it is one for which the front end must provide a
659 -- temporary. Note that the node need not be analyzed, and thus the Etype
660 -- field may not be set, but in that case it must be the case that the
661 -- Subtype_Mark field of the node is set/analyzed.
663 procedure Set_Current_Value_Condition
(Cnode
: Node_Id
);
664 -- Cnode is N_If_Statement, N_Elsif_Part, or N_Iteration_Scheme (the latter
665 -- when a WHILE condition is present). This call checks whether Condition
666 -- (Cnode) has embedded expressions of a form that should result in setting
667 -- the Current_Value field of one or more entities, and if so sets these
668 -- fields to point to Cnode.
670 procedure Set_Elaboration_Flag
(N
: Node_Id
; Spec_Id
: Entity_Id
);
671 -- N is the node for a subprogram or generic body, and Spec_Id is the
672 -- entity for the corresponding spec. If an elaboration entity is defined,
673 -- then this procedure generates an assignment statement to set it True,
674 -- immediately after the body is elaborated. However, no assignment is
675 -- generated in the case of library level procedures, since the setting of
676 -- the flag in this case is generated in the binder. We do that so that we
677 -- can detect cases where this is the only elaboration action that is
680 procedure Set_Renamed_Subprogram
(N
: Node_Id
; E
: Entity_Id
);
681 -- N is an node which is an entity name that represents the name of a
682 -- renamed subprogram. The node is rewritten to be an identifier that
683 -- refers directly to the renamed subprogram, given by entity E.
685 procedure Silly_Boolean_Array_Not_Test
(N
: Node_Id
; T
: Entity_Id
);
686 -- N is the node for a boolean array NOT operation, and T is the type of
687 -- the array. This routine deals with the silly case where the subtype of
688 -- the boolean array is False..False or True..True, where it is required
689 -- that a Constraint_Error exception be raised (RM 4.5.6(6)).
691 procedure Silly_Boolean_Array_Xor_Test
(N
: Node_Id
; T
: Entity_Id
);
692 -- N is the node for a boolean array XOR operation, and T is the type of
693 -- the array. This routine deals with the silly case where the subtype of
694 -- the boolean array is True..True, where a raise of a Constraint_Error
695 -- exception is required (RM 4.5.6(6)).
697 function Target_Has_Fixed_Ops
698 (Left_Typ
: Entity_Id
;
699 Right_Typ
: Entity_Id
;
700 Result_Typ
: Entity_Id
) return Boolean;
701 -- Returns True if and only if the target machine has direct support
702 -- for fixed-by-fixed multiplications and divisions for the given
703 -- operand and result types. This is called in package Exp_Fixd to
704 -- determine whether to expand such operations.
706 function Type_May_Have_Bit_Aligned_Components
707 (Typ
: Entity_Id
) return Boolean;
708 -- Determines if Typ is a composite type that has within it (looking down
709 -- recursively at any subcomponents), a record type which has component
710 -- that may be bit aligned (see Possible_Bit_Aligned_Component). The result
711 -- is conservative, in that a result of False is decisive. A result of True
712 -- means that such a component may or may not be present.
714 procedure Wrap_Cleanup_Procedure
(N
: Node_Id
);
715 -- Given an N_Subprogram_Body node, this procedure adds an Abort_Defer call
716 -- at the start of the statement sequence, and an Abort_Undefer call at the
717 -- end of the statement sequence. All cleanup routines (i.e. those that are
718 -- called from "at end" handlers) must defer abort on entry and undefer
719 -- abort on exit. Note that it is assumed that the code for the procedure
720 -- does not contain any return statements which would allow the flow of
721 -- control to escape doing the undefer call.
724 pragma Inline
(Duplicate_Subexpr
);
725 pragma Inline
(Force_Evaluation
);
726 pragma Inline
(Is_Library_Level_Tagged_Type
);