/**************************************************************************** * * * GNAT COMPILER COMPONENTS * * * * D E C L * * * * C Implementation File * * * * Copyright (C) 1992-2007, Free Software Foundation, Inc. * * * * GNAT is free software; you can redistribute it and/or modify it under * * terms of the GNU General Public License as published by the Free Soft- * * ware Foundation; either version 2, or (at your option) any later ver- * * sion. GNAT is distributed in the hope that it will be useful, but WITH- * * OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * * for more details. You should have received a copy of the GNU General * * Public License distributed with GNAT; see file COPYING. If not, write * * to the Free Software Foundation, 51 Franklin Street, Fifth Floor, * * Boston, MA 02110-1301, USA. * * * * GNAT was originally developed by the GNAT team at New York University. * * Extensive contributions were provided by Ada Core Technologies Inc. * * * ****************************************************************************/ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "tree.h" #include "flags.h" #include "toplev.h" #include "convert.h" #include "ggc.h" #include "obstack.h" #include "target.h" #include "expr.h" #include "ada.h" #include "types.h" #include "atree.h" #include "elists.h" #include "namet.h" #include "nlists.h" #include "repinfo.h" #include "snames.h" #include "stringt.h" #include "uintp.h" #include "fe.h" #include "sinfo.h" #include "einfo.h" #include "hashtab.h" #include "ada-tree.h" #include "gigi.h" /* Convention_Stdcall should be processed in a specific way on Windows targets only. The macro below is a helper to avoid having to check for a Windows specific attribute throughout this unit. */ #if TARGET_DLLIMPORT_DECL_ATTRIBUTES #define Has_Stdcall_Convention(E) (Convention (E) == Convention_Stdcall) #else #define Has_Stdcall_Convention(E) (0) #endif struct incomplete { struct incomplete *next; tree old_type; Entity_Id full_type; }; /* These variables are used to defer recursively expanding incomplete types while we are processing an array, a record or a subprogram type. */ static int defer_incomplete_level = 0; static struct incomplete *defer_incomplete_list; /* This variable is used to delay expanding From_With_Type types until the end of the spec. */ static struct incomplete *defer_limited_with; /* These variables are used to defer finalizing types. The element of the list is the TYPE_DECL associated with the type. */ static int defer_finalize_level = 0; static VEC (tree,heap) *defer_finalize_list; /* A hash table used to cache the result of annotate_value. */ static GTY ((if_marked ("tree_int_map_marked_p"), param_is (struct tree_int_map))) htab_t annotate_value_cache; static void copy_alias_set (tree, tree); static tree substitution_list (Entity_Id, Entity_Id, tree, bool); static bool allocatable_size_p (tree, bool); static void prepend_one_attribute_to (struct attrib **, enum attr_type, tree, tree, Node_Id); static void prepend_attributes (Entity_Id, struct attrib **); static tree elaborate_expression (Node_Id, Entity_Id, tree, bool, bool, bool); static bool is_variable_size (tree); static tree elaborate_expression_1 (Node_Id, Entity_Id, tree, tree, bool, bool); static tree make_packable_type (tree); static tree gnat_to_gnu_field (Entity_Id, tree, int, bool); static tree gnat_to_gnu_param (Entity_Id, Mechanism_Type, Entity_Id, bool, bool *); static bool same_discriminant_p (Entity_Id, Entity_Id); static void components_to_record (tree, Node_Id, tree, int, bool, tree *, bool, bool, bool, bool); static Uint annotate_value (tree); static void annotate_rep (Entity_Id, tree); static tree compute_field_positions (tree, tree, tree, tree, unsigned int); static tree validate_size (Uint, tree, Entity_Id, enum tree_code, bool, bool); static void set_rm_size (Uint, tree, Entity_Id); static tree make_type_from_size (tree, tree, bool); static unsigned int validate_alignment (Uint, Entity_Id, unsigned int); static void check_ok_for_atomic (tree, Entity_Id, bool); static int compatible_signatures_p (tree ftype1, tree ftype2); /* Given GNAT_ENTITY, an entity in the incoming GNAT tree, return a GCC type corresponding to that entity. GNAT_ENTITY is assumed to refer to an Ada type. */ tree gnat_to_gnu_type (Entity_Id gnat_entity) { tree gnu_decl; /* The back end never attempts to annotate generic types */ if (Is_Generic_Type (gnat_entity) && type_annotate_only) return void_type_node; /* Convert the ada entity type into a GCC TYPE_DECL node. */ gnu_decl = gnat_to_gnu_entity (gnat_entity, NULL_TREE, 0); gcc_assert (TREE_CODE (gnu_decl) == TYPE_DECL); return TREE_TYPE (gnu_decl); } /* Given GNAT_ENTITY, a GNAT defining identifier node, which denotes some Ada entity, this routine returns the equivalent GCC tree for that entity (an ..._DECL node) and associates the ..._DECL node with the input GNAT defining identifier. If GNAT_ENTITY is a variable or a constant declaration, GNU_EXPR gives its initial value (in GCC tree form). This is optional for variables. For renamed entities, GNU_EXPR gives the object being renamed. DEFINITION is nonzero if this call is intended for a definition. This is used for separate compilation where it necessary to know whether an external declaration or a definition should be created if the GCC equivalent was not created previously. The value of 1 is normally used for a nonzero DEFINITION, but a value of 2 is used in special circumstances, defined in the code. */ tree gnat_to_gnu_entity (Entity_Id gnat_entity, tree gnu_expr, int definition) { Entity_Id gnat_equiv_type = Gigi_Equivalent_Type (gnat_entity); tree gnu_entity_id; tree gnu_type = NULL_TREE; /* Contains the gnu XXXX_DECL tree node which is equivalent to the input GNAT tree. This node will be associated with the GNAT node by calling the save_gnu_tree routine at the end of the `switch' statement. */ tree gnu_decl = NULL_TREE; /* true if we have already saved gnu_decl as a gnat association. */ bool saved = false; /* Nonzero if we incremented defer_incomplete_level. */ bool this_deferred = false; /* Nonzero if we incremented force_global. */ bool this_global = false; /* Nonzero if we should check to see if elaborated during processing. */ bool maybe_present = false; /* Nonzero if we made GNU_DECL and its type here. */ bool this_made_decl = false; struct attrib *attr_list = NULL; bool debug_info_p = (Needs_Debug_Info (gnat_entity) || debug_info_level == DINFO_LEVEL_VERBOSE); Entity_Kind kind = Ekind (gnat_entity); Entity_Id gnat_temp; unsigned int esize = ((Known_Esize (gnat_entity) && UI_Is_In_Int_Range (Esize (gnat_entity))) ? MIN (UI_To_Int (Esize (gnat_entity)), IN (kind, Float_Kind) ? fp_prec_to_size (LONG_DOUBLE_TYPE_SIZE) : IN (kind, Access_Kind) ? POINTER_SIZE * 2 : LONG_LONG_TYPE_SIZE) : LONG_LONG_TYPE_SIZE); tree gnu_size = 0; bool imported_p = (Is_Imported (gnat_entity) && No (Address_Clause (gnat_entity))); unsigned int align = 0; /* Since a use of an Itype is a definition, process it as such if it is not in a with'ed unit. */ if (!definition && Is_Itype (gnat_entity) && !present_gnu_tree (gnat_entity) && In_Extended_Main_Code_Unit (gnat_entity)) { /* Ensure that we are in a subprogram mentioned in the Scope chain of this entity, our current scope is global, or that we encountered a task or entry (where we can't currently accurately check scoping). */ if (!current_function_decl || DECL_ELABORATION_PROC_P (current_function_decl)) { process_type (gnat_entity); return get_gnu_tree (gnat_entity); } for (gnat_temp = Scope (gnat_entity); Present (gnat_temp); gnat_temp = Scope (gnat_temp)) { if (Is_Type (gnat_temp)) gnat_temp = Underlying_Type (gnat_temp); if (Ekind (gnat_temp) == E_Subprogram_Body) gnat_temp = Corresponding_Spec (Parent (Declaration_Node (gnat_temp))); if (IN (Ekind (gnat_temp), Subprogram_Kind) && Present (Protected_Body_Subprogram (gnat_temp))) gnat_temp = Protected_Body_Subprogram (gnat_temp); if (Ekind (gnat_temp) == E_Entry || Ekind (gnat_temp) == E_Entry_Family || Ekind (gnat_temp) == E_Task_Type || (IN (Ekind (gnat_temp), Subprogram_Kind) && present_gnu_tree (gnat_temp) && (current_function_decl == gnat_to_gnu_entity (gnat_temp, NULL_TREE, 0)))) { process_type (gnat_entity); return get_gnu_tree (gnat_entity); } } /* This abort means the entity "gnat_entity" has an incorrect scope, i.e. that its scope does not correspond to the subprogram in which it is declared */ gcc_unreachable (); } /* If this is entity 0, something went badly wrong. */ gcc_assert (Present (gnat_entity)); /* If we've already processed this entity, return what we got last time. If we are defining the node, we should not have already processed it. In that case, we will abort below when we try to save a new GCC tree for this object. We also need to handle the case of getting a dummy type when a Full_View exists. */ if (present_gnu_tree (gnat_entity) && (!definition || (Is_Type (gnat_entity) && imported_p))) { gnu_decl = get_gnu_tree (gnat_entity); if (TREE_CODE (gnu_decl) == TYPE_DECL && TYPE_IS_DUMMY_P (TREE_TYPE (gnu_decl)) && IN (kind, Incomplete_Or_Private_Kind) && Present (Full_View (gnat_entity))) { gnu_decl = gnat_to_gnu_entity (Full_View (gnat_entity), NULL_TREE, 0); save_gnu_tree (gnat_entity, NULL_TREE, false); save_gnu_tree (gnat_entity, gnu_decl, false); } return gnu_decl; } /* If this is a numeric or enumeral type, or an access type, a nonzero Esize must be specified unless it was specified by the programmer. */ gcc_assert (!Unknown_Esize (gnat_entity) || Has_Size_Clause (gnat_entity) || (!IN (kind, Numeric_Kind) && !IN (kind, Enumeration_Kind) && (!IN (kind, Access_Kind) || kind == E_Access_Protected_Subprogram_Type || kind == E_Anonymous_Access_Protected_Subprogram_Type || kind == E_Access_Subtype))); /* Likewise, RM_Size must be specified for all discrete and fixed-point types. */ gcc_assert (!IN (kind, Discrete_Or_Fixed_Point_Kind) || !Unknown_RM_Size (gnat_entity)); /* Get the name of the entity and set up the line number and filename of the original definition for use in any decl we make. */ gnu_entity_id = get_entity_name (gnat_entity); Sloc_to_locus (Sloc (gnat_entity), &input_location); /* If we get here, it means we have not yet done anything with this entity. If we are not defining it here, it must be external, otherwise we should have defined it already. */ gcc_assert (definition || Is_Public (gnat_entity) || type_annotate_only || kind == E_Discriminant || kind == E_Component || kind == E_Label || (kind == E_Constant && Present (Full_View (gnat_entity))) || IN (kind, Type_Kind)); /* For cases when we are not defining (i.e., we are referencing from another compilation unit) Public entities, show we are at global level for the purpose of computing scopes. Don't do this for components or discriminants since the relevant test is whether or not the record is being defined. But do this for Imported functions or procedures in all cases. */ if ((!definition && Is_Public (gnat_entity) && !Is_Statically_Allocated (gnat_entity) && kind != E_Discriminant && kind != E_Component) || (Is_Imported (gnat_entity) && (kind == E_Function || kind == E_Procedure))) force_global++, this_global = true; /* Handle any attributes directly attached to the entity. */ if (Has_Gigi_Rep_Item (gnat_entity)) prepend_attributes (gnat_entity, &attr_list); /* Machine_Attributes on types are expected to be propagated to subtypes. The corresponding Gigi_Rep_Items are only attached to the first subtype though, so we handle the propagation here. */ if (Is_Type (gnat_entity) && Base_Type (gnat_entity) != gnat_entity && !Is_First_Subtype (gnat_entity) && Has_Gigi_Rep_Item (First_Subtype (Base_Type (gnat_entity)))) prepend_attributes (First_Subtype (Base_Type (gnat_entity)), &attr_list); switch (kind) { case E_Constant: /* If this is a use of a deferred constant, get its full declaration. */ if (!definition && Present (Full_View (gnat_entity))) { gnu_decl = gnat_to_gnu_entity (Full_View (gnat_entity), gnu_expr, 0); saved = true; break; } /* If we have an external constant that we are not defining, get the expression that is was defined to represent. We may throw that expression away later if it is not a constant. Do not retrieve the expression if it is an aggregate or allocator, because in complex instantiation contexts it may not be expanded */ if (!definition && Present (Expression (Declaration_Node (gnat_entity))) && !No_Initialization (Declaration_Node (gnat_entity)) && (Nkind (Expression (Declaration_Node (gnat_entity))) != N_Aggregate) && (Nkind (Expression (Declaration_Node (gnat_entity))) != N_Allocator)) gnu_expr = gnat_to_gnu (Expression (Declaration_Node (gnat_entity))); /* Ignore deferred constant definitions; they are processed fully in the front-end. For deferred constant references get the full definition. On the other hand, constants that are renamings are handled like variable renamings. If No_Initialization is set, this is not a deferred constant but a constant whose value is built manually. */ if (definition && !gnu_expr && !No_Initialization (Declaration_Node (gnat_entity)) && No (Renamed_Object (gnat_entity))) { gnu_decl = error_mark_node; saved = true; break; } else if (!definition && IN (kind, Incomplete_Or_Private_Kind) && Present (Full_View (gnat_entity))) { gnu_decl = gnat_to_gnu_entity (Full_View (gnat_entity), NULL_TREE, 0); saved = true; break; } goto object; case E_Exception: /* We used to special case VMS exceptions here to directly map them to their associated condition code. Since this code had to be masked dynamically to strip off the severity bits, this caused trouble in the GCC/ZCX case because the "type" pointers we store in the tables have to be static. We now don't special case here anymore, and let the regular processing take place, which leaves us with a regular exception data object for VMS exceptions too. The condition code mapping is taken care of by the front end and the bitmasking by the runtime library. */ goto object; case E_Discriminant: case E_Component: { /* The GNAT record where the component was defined. */ Entity_Id gnat_record = Underlying_Type (Scope (gnat_entity)); /* If the variable is an inherited record component (in the case of extended record types), just return the inherited entity, which must be a FIELD_DECL. Likewise for discriminants. For discriminants of untagged records which have explicit stored discriminants, return the entity for the corresponding stored discriminant. Also use Original_Record_Component if the record has a private extension. */ if (Present (Original_Record_Component (gnat_entity)) && Original_Record_Component (gnat_entity) != gnat_entity) { gnu_decl = gnat_to_gnu_entity (Original_Record_Component (gnat_entity), gnu_expr, definition); saved = true; break; } /* If the enclosing record has explicit stored discriminants, then it is an untagged record. If the Corresponding_Discriminant is not empty then this must be a renamed discriminant and its Original_Record_Component must point to the corresponding explicit stored discriminant (i.e., we should have taken the previous branch). */ else if (Present (Corresponding_Discriminant (gnat_entity)) && Is_Tagged_Type (gnat_record)) { /* A tagged record has no explicit stored discriminants. */ gcc_assert (First_Discriminant (gnat_record) == First_Stored_Discriminant (gnat_record)); gnu_decl = gnat_to_gnu_entity (Corresponding_Discriminant (gnat_entity), gnu_expr, definition); saved = true; break; } else if (Present (CR_Discriminant (gnat_entity)) && type_annotate_only) { gnu_decl = gnat_to_gnu_entity (CR_Discriminant (gnat_entity), gnu_expr, definition); saved = true; break; } /* If the enclosing record has explicit stored discriminants, then it is an untagged record. If the Corresponding_Discriminant is not empty then this must be a renamed discriminant and its Original_Record_Component must point to the corresponding explicit stored discriminant (i.e., we should have taken the first branch). */ else if (Present (Corresponding_Discriminant (gnat_entity)) && (First_Discriminant (gnat_record) != First_Stored_Discriminant (gnat_record))) gcc_unreachable (); /* Otherwise, if we are not defining this and we have no GCC type for the containing record, make one for it. Then we should have made our own equivalent. */ else if (!definition && !present_gnu_tree (gnat_record)) { /* ??? If this is in a record whose scope is a protected type and we have an Original_Record_Component, use it. This is a workaround for major problems in protected type handling. */ Entity_Id Scop = Scope (Scope (gnat_entity)); if ((Is_Protected_Type (Scop) || (Is_Private_Type (Scop) && Present (Full_View (Scop)) && Is_Protected_Type (Full_View (Scop)))) && Present (Original_Record_Component (gnat_entity))) { gnu_decl = gnat_to_gnu_entity (Original_Record_Component (gnat_entity), gnu_expr, 0); saved = true; break; } gnat_to_gnu_entity (Scope (gnat_entity), NULL_TREE, 0); gnu_decl = get_gnu_tree (gnat_entity); saved = true; break; } else /* Here we have no GCC type and this is a reference rather than a definition. This should never happen. Most likely the cause is a reference before declaration in the gnat tree for gnat_entity. */ gcc_unreachable (); } case E_Loop_Parameter: case E_Out_Parameter: case E_Variable: /* Simple variables, loop variables, OUT parameters, and exceptions. */ object: { bool used_by_ref = false; bool const_flag = ((kind == E_Constant || kind == E_Variable) && !Is_Statically_Allocated (gnat_entity) && Is_True_Constant (gnat_entity) && (((Nkind (Declaration_Node (gnat_entity)) == N_Object_Declaration) && Present (Expression (Declaration_Node (gnat_entity)))) || Present (Renamed_Object (gnat_entity)))); bool inner_const_flag = const_flag; bool static_p = Is_Statically_Allocated (gnat_entity); bool mutable_p = false; tree gnu_ext_name = NULL_TREE; tree renamed_obj = NULL_TREE; if (Present (Renamed_Object (gnat_entity)) && !definition) { if (kind == E_Exception) gnu_expr = gnat_to_gnu_entity (Renamed_Entity (gnat_entity), NULL_TREE, 0); else gnu_expr = gnat_to_gnu (Renamed_Object (gnat_entity)); } /* Get the type after elaborating the renamed object. */ gnu_type = gnat_to_gnu_type (Etype (gnat_entity)); /* If this is a loop variable, its type should be the base type. This is because the code for processing a loop determines whether a normal loop end test can be done by comparing the bounds of the loop against those of the base type, which is presumed to be the size used for computation. But this is not correct when the size of the subtype is smaller than the type. */ if (kind == E_Loop_Parameter) gnu_type = get_base_type (gnu_type); /* Reject non-renamed objects whose types are unconstrained arrays or any object whose type is a dummy type or VOID_TYPE. */ if ((TREE_CODE (gnu_type) == UNCONSTRAINED_ARRAY_TYPE && No (Renamed_Object (gnat_entity))) || TYPE_IS_DUMMY_P (gnu_type) || TREE_CODE (gnu_type) == VOID_TYPE) { gcc_assert (type_annotate_only); if (this_global) force_global--; return error_mark_node; } /* If an alignment is specified, use it if valid. Note that exceptions are objects but don't have alignments. We must do this before we validate the size, since the alignment can affect the size. */ if (kind != E_Exception && Known_Alignment (gnat_entity)) { gcc_assert (Present (Alignment (gnat_entity))); align = validate_alignment (Alignment (gnat_entity), gnat_entity, TYPE_ALIGN (gnu_type)); gnu_type = maybe_pad_type (gnu_type, NULL_TREE, align, gnat_entity, "PAD", false, definition, true); } /* If we are defining the object, see if it has a Size value and validate it if so. If we are not defining the object and a Size clause applies, simply retrieve the value. We don't want to ignore the clause and it is expected to have been validated already. Then get the new type, if any. */ if (definition) gnu_size = validate_size (Esize (gnat_entity), gnu_type, gnat_entity, VAR_DECL, false, Has_Size_Clause (gnat_entity)); else if (Has_Size_Clause (gnat_entity)) gnu_size = UI_To_gnu (Esize (gnat_entity), bitsizetype); if (gnu_size) { gnu_type = make_type_from_size (gnu_type, gnu_size, Has_Biased_Representation (gnat_entity)); if (operand_equal_p (TYPE_SIZE (gnu_type), gnu_size, 0)) gnu_size = NULL_TREE; } /* If this object has self-referential size, it must be a record with a default value. We are supposed to allocate an object of the maximum size in this case unless it is a constant with an initializing expression, in which case we can get the size from that. Note that the resulting size may still be a variable, so this may end up with an indirect allocation. */ if (No (Renamed_Object (gnat_entity)) && CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type))) { if (gnu_expr && kind == E_Constant) gnu_size = SUBSTITUTE_PLACEHOLDER_IN_EXPR (TYPE_SIZE (TREE_TYPE (gnu_expr)), gnu_expr); /* We may have no GNU_EXPR because No_Initialization is set even though there's an Expression. */ else if (kind == E_Constant && (Nkind (Declaration_Node (gnat_entity)) == N_Object_Declaration) && Present (Expression (Declaration_Node (gnat_entity)))) gnu_size = TYPE_SIZE (gnat_to_gnu_type (Etype (Expression (Declaration_Node (gnat_entity))))); else { gnu_size = max_size (TYPE_SIZE (gnu_type), true); mutable_p = true; } } /* If the size is zero bytes, make it one byte since some linkers have trouble with zero-sized objects. If the object will have a template, that will make it nonzero so don't bother. Also avoid doing that for an object renaming or an object with an address clause, as we would lose useful information on the view size (e.g. for null array slices) and we are not allocating the object here anyway. */ if (((gnu_size && integer_zerop (gnu_size)) || (TYPE_SIZE (gnu_type) && integer_zerop (TYPE_SIZE (gnu_type)))) && (!Is_Constr_Subt_For_UN_Aliased (Etype (gnat_entity)) || !Is_Array_Type (Etype (gnat_entity))) && !Present (Renamed_Object (gnat_entity)) && !Present (Address_Clause (gnat_entity))) gnu_size = bitsize_unit_node; /* If this is an atomic object with no specified size and alignment, but where the size of the type is a constant, set the alignment to the lowest power of two greater than the size, or to the biggest meaningful alignment, whichever is smaller. */ if (Is_Atomic (gnat_entity) && !gnu_size && align == 0 && TREE_CODE (TYPE_SIZE (gnu_type)) == INTEGER_CST) { if (!host_integerp (TYPE_SIZE (gnu_type), 1) || 0 <= compare_tree_int (TYPE_SIZE (gnu_type), BIGGEST_ALIGNMENT)) align = BIGGEST_ALIGNMENT; else align = ((unsigned int) 1 << (floor_log2 (tree_low_cst (TYPE_SIZE (gnu_type), 1) - 1) + 1)); } /* If the object is set to have atomic components, find the component type and validate it. ??? Note that we ignore Has_Volatile_Components on objects; it's not at all clear what to do in that case. */ if (Has_Atomic_Components (gnat_entity)) { tree gnu_inner = (TREE_CODE (gnu_type) == ARRAY_TYPE ? TREE_TYPE (gnu_type) : gnu_type); while (TREE_CODE (gnu_inner) == ARRAY_TYPE && TYPE_MULTI_ARRAY_P (gnu_inner)) gnu_inner = TREE_TYPE (gnu_inner); check_ok_for_atomic (gnu_inner, gnat_entity, true); } /* Now check if the type of the object allows atomic access. Note that we must test the type, even if this object has size and alignment to allow such access, because we will be going inside the padded record to assign to the object. We could fix this by always copying via an intermediate value, but it's not clear it's worth the effort. */ if (Is_Atomic (gnat_entity)) check_ok_for_atomic (gnu_type, gnat_entity, false); /* If this is an aliased object with an unconstrained nominal subtype, make a type that includes the template. */ if (Is_Constr_Subt_For_UN_Aliased (Etype (gnat_entity)) && Is_Array_Type (Etype (gnat_entity)) && !type_annotate_only) { tree gnu_fat = TREE_TYPE (gnat_to_gnu_type (Base_Type (Etype (gnat_entity)))); gnu_type = build_unc_object_type_from_ptr (gnu_fat, gnu_type, concat_id_with_name (gnu_entity_id, "UNC")); } #ifdef MINIMUM_ATOMIC_ALIGNMENT /* If the size is a constant and no alignment is specified, force the alignment to be the minimum valid atomic alignment. The restriction on constant size avoids problems with variable-size temporaries; if the size is variable, there's no issue with atomic access. Also don't do this for a constant, since it isn't necessary and can interfere with constant replacement. Finally, do not do it for Out parameters since that creates an size inconsistency with In parameters. */ if (align == 0 && MINIMUM_ATOMIC_ALIGNMENT > TYPE_ALIGN (gnu_type) && !FLOAT_TYPE_P (gnu_type) && !const_flag && No (Renamed_Object (gnat_entity)) && !imported_p && No (Address_Clause (gnat_entity)) && kind != E_Out_Parameter && (gnu_size ? TREE_CODE (gnu_size) == INTEGER_CST : TREE_CODE (TYPE_SIZE (gnu_type)) == INTEGER_CST)) align = MINIMUM_ATOMIC_ALIGNMENT; #endif /* Make a new type with the desired size and alignment, if needed. */ gnu_type = maybe_pad_type (gnu_type, gnu_size, align, gnat_entity, "PAD", false, definition, true); /* Make a volatile version of this object's type if we are to make the object volatile. Note that 13.3(19) says that we should treat other types of objects as volatile as well. */ if ((Treat_As_Volatile (gnat_entity) || Is_Exported (gnat_entity) || Is_Imported (gnat_entity)) && !TYPE_VOLATILE (gnu_type)) gnu_type = build_qualified_type (gnu_type, (TYPE_QUALS (gnu_type) | TYPE_QUAL_VOLATILE)); /* Convert the expression to the type of the object except in the case where the object's type is unconstrained or the object's type is a padded record whose field is of self-referential size. In the former case, converting will generate unnecessary evaluations of the CONSTRUCTOR to compute the size and in the latter case, we want to only copy the actual data. */ if (gnu_expr && TREE_CODE (gnu_type) != UNCONSTRAINED_ARRAY_TYPE && !CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type)) && !(TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_type) && (CONTAINS_PLACEHOLDER_P (TYPE_SIZE (TREE_TYPE (TYPE_FIELDS (gnu_type))))))) gnu_expr = convert (gnu_type, gnu_expr); /* If this is a renaming, avoid as much as possible to create a new object. However, in several cases, creating it is required. */ if (Present (Renamed_Object (gnat_entity))) { bool create_normal_object = false; /* If the renamed object had padding, strip off the reference to the inner object and reset our type. */ if ((TREE_CODE (gnu_expr) == COMPONENT_REF && TREE_CODE (TREE_TYPE (TREE_OPERAND (gnu_expr, 0))) == RECORD_TYPE && TYPE_IS_PADDING_P (TREE_TYPE (TREE_OPERAND (gnu_expr, 0)))) /* Strip useless conversions around the object. */ || TREE_CODE (gnu_expr) == NOP_EXPR) { gnu_expr = TREE_OPERAND (gnu_expr, 0); gnu_type = TREE_TYPE (gnu_expr); } /* Case 1: If this is a constant renaming stemming from a function call, treat it as a normal object whose initial value is what is being renamed. RM 3.3 says that the result of evaluating a function call is a constant object. As a consequence, it can be the inner object of a constant renaming. In this case, the renaming must be fully instantiated, i.e. it cannot be a mere reference to (part of) an existing object. */ if (const_flag) { tree inner_object = gnu_expr; while (handled_component_p (inner_object)) inner_object = TREE_OPERAND (inner_object, 0); if (TREE_CODE (inner_object) == CALL_EXPR) create_normal_object = true; } /* Otherwise, see if we can proceed with a stabilized version of the renamed entity or if we need to make a new object. */ if (!create_normal_object) { tree maybe_stable_expr = NULL_TREE; bool stable = false; /* Case 2: If the renaming entity need not be materialized and the renamed expression is something we can stabilize, use that for the renaming. At the global level, we can only do this if we know no SAVE_EXPRs need be made, because the expression we return might be used in arbitrary conditional branches so we must force the SAVE_EXPRs evaluation immediately and this requires a function context. */ if (!Materialize_Entity (gnat_entity) && (!global_bindings_p () || (staticp (gnu_expr) && !TREE_SIDE_EFFECTS (gnu_expr)))) { maybe_stable_expr = maybe_stabilize_reference (gnu_expr, true, &stable); if (stable) { gnu_decl = maybe_stable_expr; /* ??? No DECL_EXPR is created so we need to mark the expression manually lest it is shared. */ if (global_bindings_p ()) TREE_VISITED (gnu_decl) = 1; save_gnu_tree (gnat_entity, gnu_decl, true); saved = true; break; } /* The stabilization failed. Keep maybe_stable_expr untouched here to let the pointer case below know about that failure. */ } /* Case 3: If this is a constant renaming and creating a new object is allowed and cheap, treat it as a normal object whose initial value is what is being renamed. */ if (const_flag && Ekind (Etype (gnat_entity)) != E_Class_Wide_Type && TREE_CODE (gnu_type) != UNCONSTRAINED_ARRAY_TYPE && TYPE_MODE (gnu_type) != BLKmode) ; /* Case 4: Make this into a constant pointer to the object we are to rename and attach the object to the pointer if it is something we can stabilize. From the proper scope, attached objects will be referenced directly instead of indirectly via the pointer to avoid subtle aliasing problems with non-addressable entities. They have to be stable because we must not evaluate the variables in the expression every time the renaming is used. The pointer is called a "renaming" pointer in this case. In the rare cases where we cannot stabilize the renamed object, we just make a "bare" pointer, and the renamed entity is always accessed indirectly through it. */ else { gnu_type = build_reference_type (gnu_type); inner_const_flag = TREE_READONLY (gnu_expr); const_flag = true; /* If the previous attempt at stabilizing failed, there is no point in trying again and we reuse the result without attaching it to the pointer. In this case it will only be used as the initializing expression of the pointer and thus needs no special treatment with regard to multiple evaluations. */ if (maybe_stable_expr) ; /* Otherwise, try to stabilize and attach the expression to the pointer if the stabilization succeeds. Note that this might introduce SAVE_EXPRs and we don't check whether we're at the global level or not. This is fine since we are building a pointer initializer and neither the pointer nor the initializing expression can be accessed before the pointer elaboration has taken place in a correct program. These SAVE_EXPRs will be evaluated at the right place by either the evaluation of the initializer for the non-global case or the elaboration code for the global case, and will be attached to the elaboration procedure in the latter case. */ else { maybe_stable_expr = maybe_stabilize_reference (gnu_expr, true, &stable); if (stable) renamed_obj = maybe_stable_expr; /* Attaching is actually performed downstream, as soon as we have a VAR_DECL for the pointer we make. */ } gnu_expr = build_unary_op (ADDR_EXPR, gnu_type, maybe_stable_expr); gnu_size = NULL_TREE; used_by_ref = true; } } } /* If this is an aliased object whose nominal subtype is unconstrained, the object is a record that contains both the template and the object. If there is an initializer, it will have already been converted to the right type, but we need to create the template if there is no initializer. */ else if (definition && TREE_CODE (gnu_type) == RECORD_TYPE && (TYPE_CONTAINS_TEMPLATE_P (gnu_type) /* Beware that padding might have been introduced via maybe_pad_type above. */ || (TYPE_IS_PADDING_P (gnu_type) && TREE_CODE (TREE_TYPE (TYPE_FIELDS (gnu_type))) == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (TREE_TYPE (TYPE_FIELDS (gnu_type))))) && !gnu_expr) { tree template_field = TYPE_IS_PADDING_P (gnu_type) ? TYPE_FIELDS (TREE_TYPE (TYPE_FIELDS (gnu_type))) : TYPE_FIELDS (gnu_type); gnu_expr = gnat_build_constructor (gnu_type, tree_cons (template_field, build_template (TREE_TYPE (template_field), TREE_TYPE (TREE_CHAIN (template_field)), NULL_TREE), NULL_TREE)); } /* If this is a pointer and it does not have an initializing expression, initialize it to NULL, unless the object is imported. */ if (definition && (POINTER_TYPE_P (gnu_type) || TYPE_FAT_POINTER_P (gnu_type)) && !Is_Imported (gnat_entity) && !gnu_expr) gnu_expr = integer_zero_node; /* If we are defining the object and it has an Address clause we must get the address expression from the saved GCC tree for the object if the object has a Freeze_Node. Otherwise, we elaborate the address expression here since the front-end has guaranteed in that case that the elaboration has no effects. Note that only the latter mechanism is currently in use. */ if (definition && Present (Address_Clause (gnat_entity))) { tree gnu_address = (present_gnu_tree (gnat_entity) ? get_gnu_tree (gnat_entity) : gnat_to_gnu (Expression (Address_Clause (gnat_entity)))); save_gnu_tree (gnat_entity, NULL_TREE, false); /* Ignore the size. It's either meaningless or was handled above. */ gnu_size = NULL_TREE; /* Convert the type of the object to a reference type that can alias everything as per 13.3(19). */ gnu_type = build_reference_type_for_mode (gnu_type, ptr_mode, true); gnu_address = convert (gnu_type, gnu_address); used_by_ref = true; const_flag = !Is_Public (gnat_entity); /* If we don't have an initializing expression for the underlying variable, the initializing expression for the pointer is the specified address. Otherwise, we have to make a COMPOUND_EXPR to assign both the address and the initial value. */ if (!gnu_expr) gnu_expr = gnu_address; else gnu_expr = build2 (COMPOUND_EXPR, gnu_type, build_binary_op (MODIFY_EXPR, NULL_TREE, build_unary_op (INDIRECT_REF, NULL_TREE, gnu_address), gnu_expr), gnu_address); } /* If it has an address clause and we are not defining it, mark it as an indirect object. Likewise for Stdcall objects that are imported. */ if ((!definition && Present (Address_Clause (gnat_entity))) || (Is_Imported (gnat_entity) && Has_Stdcall_Convention (gnat_entity))) { /* Convert the type of the object to a reference type that can alias everything as per 13.3(19). */ gnu_type = build_reference_type_for_mode (gnu_type, ptr_mode, true); gnu_size = NULL_TREE; gnu_expr = NULL_TREE; /* No point in taking the address of an initializing expression that isn't going to be used. */ used_by_ref = true; } /* If we are at top level and this object is of variable size, make the actual type a hidden pointer to the real type and make the initializer be a memory allocation and initialization. Likewise for objects we aren't defining (presumed to be external references from other packages), but there we do not set up an initialization. If the object's size overflows, make an allocator too, so that Storage_Error gets raised. Note that we will never free such memory, so we presume it never will get allocated. */ if (!allocatable_size_p (TYPE_SIZE_UNIT (gnu_type), global_bindings_p () || !definition || static_p) || (gnu_size && ! allocatable_size_p (gnu_size, global_bindings_p () || !definition || static_p))) { gnu_type = build_reference_type (gnu_type); gnu_size = NULL_TREE; used_by_ref = true; const_flag = true; /* In case this was a aliased object whose nominal subtype is unconstrained, the pointer above will be a thin pointer and build_allocator will automatically make the template. If we have a template initializer only (that we made above), pretend there is none and rely on what build_allocator creates again anyway. Otherwise (if we have a full initializer), get the data part and feed that to build_allocator. If we are elaborating a mutable object, tell build_allocator to ignore a possibly simpler size from the initializer, if any, as we must allocate the maximum possible size in this case. */ if (definition) { tree gnu_alloc_type = TREE_TYPE (gnu_type); if (TREE_CODE (gnu_alloc_type) == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (gnu_alloc_type)) { gnu_alloc_type = TREE_TYPE (TREE_CHAIN (TYPE_FIELDS (gnu_alloc_type))); if (TREE_CODE (gnu_expr) == CONSTRUCTOR && 1 == VEC_length (constructor_elt, CONSTRUCTOR_ELTS (gnu_expr))) gnu_expr = 0; else gnu_expr = build_component_ref (gnu_expr, NULL_TREE, TREE_CHAIN (TYPE_FIELDS (TREE_TYPE (gnu_expr))), false); } if (TREE_CODE (TYPE_SIZE_UNIT (gnu_alloc_type)) == INTEGER_CST && TREE_OVERFLOW (TYPE_SIZE_UNIT (gnu_alloc_type)) && !Is_Imported (gnat_entity)) post_error ("?Storage_Error will be raised at run-time!", gnat_entity); gnu_expr = build_allocator (gnu_alloc_type, gnu_expr, gnu_type, 0, 0, gnat_entity, mutable_p); } else { gnu_expr = NULL_TREE; const_flag = false; } } /* If this object would go into the stack and has an alignment larger than the largest stack alignment the back-end can honor, resort to a variable of "aligning type". */ if (!global_bindings_p () && !static_p && definition && !imported_p && TYPE_ALIGN (gnu_type) > BIGGEST_ALIGNMENT) { /* Create the new variable. No need for extra room before the aligned field as this is in automatic storage. */ tree gnu_new_type = make_aligning_type (gnu_type, TYPE_ALIGN (gnu_type), TYPE_SIZE_UNIT (gnu_type), BIGGEST_ALIGNMENT, 0); tree gnu_new_var = create_var_decl (create_concat_name (gnat_entity, "ALIGN"), NULL_TREE, gnu_new_type, NULL_TREE, false, false, false, false, NULL, gnat_entity); /* Initialize the aligned field if we have an initializer. */ if (gnu_expr) add_stmt_with_node (build_binary_op (MODIFY_EXPR, NULL_TREE, build_component_ref (gnu_new_var, NULL_TREE, TYPE_FIELDS (gnu_new_type), false), gnu_expr), gnat_entity); /* And setup this entity as a reference to the aligned field. */ gnu_type = build_reference_type (gnu_type); gnu_expr = build_unary_op (ADDR_EXPR, gnu_type, build_component_ref (gnu_new_var, NULL_TREE, TYPE_FIELDS (gnu_new_type), false)); gnu_size = NULL_TREE; used_by_ref = true; const_flag = true; } if (const_flag) gnu_type = build_qualified_type (gnu_type, (TYPE_QUALS (gnu_type) | TYPE_QUAL_CONST)); /* Convert the expression to the type of the object except in the case where the object's type is unconstrained or the object's type is a padded record whose field is of self-referential size. In the former case, converting will generate unnecessary evaluations of the CONSTRUCTOR to compute the size and in the latter case, we want to only copy the actual data. */ if (gnu_expr && TREE_CODE (gnu_type) != UNCONSTRAINED_ARRAY_TYPE && !CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type)) && !(TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_type) && (CONTAINS_PLACEHOLDER_P (TYPE_SIZE (TREE_TYPE (TYPE_FIELDS (gnu_type))))))) gnu_expr = convert (gnu_type, gnu_expr); /* If this name is external or there was a name specified, use it, unless this is a VMS exception object since this would conflict with the symbol we need to export in addition. Don't use the Interface_Name if there is an address clause (see CD30005). */ if (!Is_VMS_Exception (gnat_entity) && ((Present (Interface_Name (gnat_entity)) && No (Address_Clause (gnat_entity))) || (Is_Public (gnat_entity) && (!Is_Imported (gnat_entity) || Is_Exported (gnat_entity))))) gnu_ext_name = create_concat_name (gnat_entity, 0); /* If this is constant initialized to a static constant and the object has an aggregate type, force it to be statically allocated. */ if (const_flag && gnu_expr && TREE_CONSTANT (gnu_expr) && host_integerp (TYPE_SIZE_UNIT (gnu_type), 1) && (AGGREGATE_TYPE_P (gnu_type) && !(TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_type)))) static_p = true; gnu_decl = create_var_decl (gnu_entity_id, gnu_ext_name, gnu_type, gnu_expr, const_flag, Is_Public (gnat_entity), imported_p || !definition, static_p, attr_list, gnat_entity); DECL_BY_REF_P (gnu_decl) = used_by_ref; DECL_POINTS_TO_READONLY_P (gnu_decl) = used_by_ref && inner_const_flag; if (TREE_CODE (gnu_decl) == VAR_DECL && renamed_obj) { SET_DECL_RENAMED_OBJECT (gnu_decl, renamed_obj); if (global_bindings_p ()) { DECL_RENAMING_GLOBAL_P (gnu_decl) = 1; record_global_renaming_pointer (gnu_decl); } } if (definition && DECL_SIZE (gnu_decl) && get_block_jmpbuf_decl () && (TREE_CODE (DECL_SIZE (gnu_decl)) != INTEGER_CST || (flag_stack_check && !STACK_CHECK_BUILTIN && 0 < compare_tree_int (DECL_SIZE_UNIT (gnu_decl), STACK_CHECK_MAX_VAR_SIZE)))) add_stmt_with_node (build_call_1_expr (update_setjmp_buf_decl, build_unary_op (ADDR_EXPR, NULL_TREE, get_block_jmpbuf_decl ())), gnat_entity); /* If this is a public constant or we're not optimizing and we're not making a VAR_DECL for it, make one just for export or debugger use. Likewise if the address is taken or if either the object or type is aliased. Make an external declaration for a reference, unless this is a Standard entity since there no real symbol at the object level for these. */ if (TREE_CODE (gnu_decl) == CONST_DECL && (definition || Sloc (gnat_entity) > Standard_Location) && (Is_Public (gnat_entity) || optimize == 0 || Address_Taken (gnat_entity) || Is_Aliased (gnat_entity) || Is_Aliased (Etype (gnat_entity)))) { tree gnu_corr_var = create_true_var_decl (gnu_entity_id, gnu_ext_name, gnu_type, gnu_expr, true, Is_Public (gnat_entity), !definition, static_p, NULL, gnat_entity); SET_DECL_CONST_CORRESPONDING_VAR (gnu_decl, gnu_corr_var); } /* If this is declared in a block that contains a block with an exception handler, we must force this variable in memory to suppress an invalid optimization. */ if (Has_Nested_Block_With_Handler (Scope (gnat_entity)) && Exception_Mechanism != Back_End_Exceptions) TREE_ADDRESSABLE (gnu_decl) = 1; gnu_type = TREE_TYPE (gnu_decl); /* Back-annotate Alignment and Esize of the object if not already known, except for when the object is actually a pointer to the real object, since alignment and size of a pointer don't have anything to do with those of the designated object. Note that we pick the values of the type, not those of the object, to shield ourselves from low-level platform-dependent adjustments like alignment promotion. This is both consistent with all the treatment above, where alignment and size are set on the type of the object and not on the object directly, and makes it possible to support confirming representation clauses in all cases. */ if (!used_by_ref && Unknown_Alignment (gnat_entity)) Set_Alignment (gnat_entity, UI_From_Int (TYPE_ALIGN (gnu_type) / BITS_PER_UNIT)); if (!used_by_ref && Unknown_Esize (gnat_entity)) { tree gnu_back_size; if (TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (gnu_type)) gnu_back_size = TYPE_SIZE (TREE_TYPE (TREE_CHAIN (TYPE_FIELDS (gnu_type)))); else gnu_back_size = TYPE_SIZE (gnu_type); Set_Esize (gnat_entity, annotate_value (gnu_back_size)); } } break; case E_Void: /* Return a TYPE_DECL for "void" that we previously made. */ gnu_decl = void_type_decl_node; break; case E_Enumeration_Type: /* A special case, for the types Character and Wide_Character in Standard, we do not list all the literals. So if the literals are not specified, make this an unsigned type. */ if (No (First_Literal (gnat_entity))) { gnu_type = make_unsigned_type (esize); TYPE_NAME (gnu_type) = gnu_entity_id; /* Set the TYPE_STRING_FLAG for Ada Character and Wide_Character types. This is needed by the dwarf-2 debug writer to distinguish between unsigned integer types and character types. */ TYPE_STRING_FLAG (gnu_type) = 1; break; } /* Normal case of non-character type, or non-Standard character type */ { /* Here we have a list of enumeral constants in First_Literal. We make a CONST_DECL for each and build into GNU_LITERAL_LIST the list to be places into TYPE_FIELDS. Each node in the list is a TREE_LIST node whose TREE_VALUE is the literal name and whose TREE_PURPOSE is the value of the literal. Esize contains the number of bits needed to represent the enumeral type, Type_Low_Bound also points to the first literal and Type_High_Bound points to the last literal. */ Entity_Id gnat_literal; tree gnu_literal_list = NULL_TREE; if (Is_Unsigned_Type (gnat_entity)) gnu_type = make_unsigned_type (esize); else gnu_type = make_signed_type (esize); TREE_SET_CODE (gnu_type, ENUMERAL_TYPE); for (gnat_literal = First_Literal (gnat_entity); Present (gnat_literal); gnat_literal = Next_Literal (gnat_literal)) { tree gnu_value = UI_To_gnu (Enumeration_Rep (gnat_literal), gnu_type); tree gnu_literal = create_var_decl (get_entity_name (gnat_literal), NULL_TREE, gnu_type, gnu_value, true, false, false, false, NULL, gnat_literal); save_gnu_tree (gnat_literal, gnu_literal, false); gnu_literal_list = tree_cons (DECL_NAME (gnu_literal), gnu_value, gnu_literal_list); } TYPE_VALUES (gnu_type) = nreverse (gnu_literal_list); /* Note that the bounds are updated at the end of this function because to avoid an infinite recursion when we get the bounds of this type, since those bounds are objects of this type. */ } break; case E_Signed_Integer_Type: case E_Ordinary_Fixed_Point_Type: case E_Decimal_Fixed_Point_Type: /* For integer types, just make a signed type the appropriate number of bits. */ gnu_type = make_signed_type (esize); break; case E_Modular_Integer_Type: /* For modular types, make the unsigned type of the proper number of bits and then set up the modulus, if required. */ { enum machine_mode mode; tree gnu_modulus; tree gnu_high = 0; if (Is_Packed_Array_Type (gnat_entity)) esize = UI_To_Int (RM_Size (gnat_entity)); /* Find the smallest mode at least ESIZE bits wide and make a class using that mode. */ for (mode = GET_CLASS_NARROWEST_MODE (MODE_INT); GET_MODE_BITSIZE (mode) < esize; mode = GET_MODE_WIDER_MODE (mode)) ; gnu_type = make_unsigned_type (GET_MODE_BITSIZE (mode)); TYPE_PACKED_ARRAY_TYPE_P (gnu_type) = Is_Packed_Array_Type (gnat_entity); /* Get the modulus in this type. If it overflows, assume it is because it is equal to 2**Esize. Note that there is no overflow checking done on unsigned type, so we detect the overflow by looking for a modulus of zero, which is otherwise invalid. */ gnu_modulus = UI_To_gnu (Modulus (gnat_entity), gnu_type); if (!integer_zerop (gnu_modulus)) { TYPE_MODULAR_P (gnu_type) = 1; SET_TYPE_MODULUS (gnu_type, gnu_modulus); gnu_high = fold_build2 (MINUS_EXPR, gnu_type, gnu_modulus, convert (gnu_type, integer_one_node)); } /* If we have to set TYPE_PRECISION different from its natural value, make a subtype to do do. Likewise if there is a modulus and it is not one greater than TYPE_MAX_VALUE. */ if (TYPE_PRECISION (gnu_type) != esize || (TYPE_MODULAR_P (gnu_type) && !tree_int_cst_equal (TYPE_MAX_VALUE (gnu_type), gnu_high))) { tree gnu_subtype = make_node (INTEGER_TYPE); TYPE_NAME (gnu_type) = create_concat_name (gnat_entity, "UMT"); TREE_TYPE (gnu_subtype) = gnu_type; TYPE_MIN_VALUE (gnu_subtype) = TYPE_MIN_VALUE (gnu_type); TYPE_MAX_VALUE (gnu_subtype) = TYPE_MODULAR_P (gnu_type) ? gnu_high : TYPE_MAX_VALUE (gnu_type); TYPE_PRECISION (gnu_subtype) = esize; TYPE_UNSIGNED (gnu_subtype) = 1; TYPE_EXTRA_SUBTYPE_P (gnu_subtype) = 1; TYPE_PACKED_ARRAY_TYPE_P (gnu_subtype) = Is_Packed_Array_Type (gnat_entity); layout_type (gnu_subtype); gnu_type = gnu_subtype; } } break; case E_Signed_Integer_Subtype: case E_Enumeration_Subtype: case E_Modular_Integer_Subtype: case E_Ordinary_Fixed_Point_Subtype: case E_Decimal_Fixed_Point_Subtype: /* For integral subtypes, we make a new INTEGER_TYPE. Note that we do not want to call build_range_type since we would like each subtype node to be distinct. This will be important when memory aliasing is implemented. The TREE_TYPE field of the INTEGER_TYPE we make points to the parent type; this fact is used by the arithmetic conversion functions. We elaborate the Ancestor_Subtype if it is not in the current unit and one of our bounds is non-static. We do this to ensure consistent naming in the case where several subtypes share the same bounds by always elaborating the first such subtype first, thus using its name. */ if (!definition && Present (Ancestor_Subtype (gnat_entity)) && !In_Extended_Main_Code_Unit (Ancestor_Subtype (gnat_entity)) && (!Compile_Time_Known_Value (Type_Low_Bound (gnat_entity)) || !Compile_Time_Known_Value (Type_High_Bound (gnat_entity)))) gnat_to_gnu_entity (Ancestor_Subtype (gnat_entity), gnu_expr, 0); gnu_type = make_node (INTEGER_TYPE); if (Is_Packed_Array_Type (gnat_entity)) { esize = UI_To_Int (RM_Size (gnat_entity)); TYPE_PACKED_ARRAY_TYPE_P (gnu_type) = 1; } TYPE_PRECISION (gnu_type) = esize; TREE_TYPE (gnu_type) = get_unpadded_type (Etype (gnat_entity)); TYPE_MIN_VALUE (gnu_type) = convert (TREE_TYPE (gnu_type), elaborate_expression (Type_Low_Bound (gnat_entity), gnat_entity, get_identifier ("L"), definition, 1, Needs_Debug_Info (gnat_entity))); TYPE_MAX_VALUE (gnu_type) = convert (TREE_TYPE (gnu_type), elaborate_expression (Type_High_Bound (gnat_entity), gnat_entity, get_identifier ("U"), definition, 1, Needs_Debug_Info (gnat_entity))); /* One of the above calls might have caused us to be elaborated, so don't blow up if so. */ if (present_gnu_tree (gnat_entity)) { maybe_present = true; break; } TYPE_BIASED_REPRESENTATION_P (gnu_type) = Has_Biased_Representation (gnat_entity); /* This should be an unsigned type if the lower bound is constant and non-negative or if the base type is unsigned; a signed type otherwise. */ TYPE_UNSIGNED (gnu_type) = (TYPE_UNSIGNED (TREE_TYPE (gnu_type)) || (TREE_CODE (TYPE_MIN_VALUE (gnu_type)) == INTEGER_CST && TREE_INT_CST_HIGH (TYPE_MIN_VALUE (gnu_type)) >= 0) || TYPE_BIASED_REPRESENTATION_P (gnu_type) || Is_Unsigned_Type (gnat_entity)); layout_type (gnu_type); /* Inherit our alias set from what we're a subtype of. Subtypes are not different types and a pointer can designate any instance within a subtype hierarchy. */ copy_alias_set (gnu_type, TREE_TYPE (gnu_type)); /* If the type we are dealing with is to represent a packed array, we need to have the bits left justified on big-endian targets and right justified on little-endian targets. We also need to ensure that when the value is read (e.g. for comparison of two such values), we only get the good bits, since the unused bits are uninitialized. Both goals are accomplished by wrapping the modular value in an enclosing struct. */ if (Is_Packed_Array_Type (gnat_entity)) { tree gnu_field_type = gnu_type; tree gnu_field; TYPE_RM_SIZE_NUM (gnu_field_type) = UI_To_gnu (RM_Size (gnat_entity), bitsizetype); gnu_type = make_node (RECORD_TYPE); TYPE_NAME (gnu_type) = create_concat_name (gnat_entity, "JM"); TYPE_ALIGN (gnu_type) = TYPE_ALIGN (gnu_field_type); TYPE_USER_ALIGN (gnu_type) = TYPE_USER_ALIGN (gnu_field_type); TYPE_PACKED (gnu_type) = 1; /* Create a stripped-down declaration of the original type, mainly for debugging. */ create_type_decl (get_entity_name (gnat_entity), gnu_field_type, NULL, true, debug_info_p, gnat_entity); /* Don't notify the field as "addressable", since we won't be taking it's address and it would prevent create_field_decl from making a bitfield. */ gnu_field = create_field_decl (get_identifier ("OBJECT"), gnu_field_type, gnu_type, 1, 0, 0, 0); finish_record_type (gnu_type, gnu_field, 0, false); TYPE_JUSTIFIED_MODULAR_P (gnu_type) = 1; SET_TYPE_ADA_SIZE (gnu_type, bitsize_int (esize)); copy_alias_set (gnu_type, gnu_field_type); } break; case E_Floating_Point_Type: /* If this is a VAX floating-point type, use an integer of the proper size. All the operations will be handled with ASM statements. */ if (Vax_Float (gnat_entity)) { gnu_type = make_signed_type (esize); TYPE_VAX_FLOATING_POINT_P (gnu_type) = 1; SET_TYPE_DIGITS_VALUE (gnu_type, UI_To_gnu (Digits_Value (gnat_entity), sizetype)); break; } /* The type of the Low and High bounds can be our type if this is a type from Standard, so set them at the end of the function. */ gnu_type = make_node (REAL_TYPE); TYPE_PRECISION (gnu_type) = fp_size_to_prec (esize); layout_type (gnu_type); break; case E_Floating_Point_Subtype: if (Vax_Float (gnat_entity)) { gnu_type = gnat_to_gnu_type (Etype (gnat_entity)); break; } { if (!definition && Present (Ancestor_Subtype (gnat_entity)) && !In_Extended_Main_Code_Unit (Ancestor_Subtype (gnat_entity)) && (!Compile_Time_Known_Value (Type_Low_Bound (gnat_entity)) || !Compile_Time_Known_Value (Type_High_Bound (gnat_entity)))) gnat_to_gnu_entity (Ancestor_Subtype (gnat_entity), gnu_expr, 0); gnu_type = make_node (REAL_TYPE); TREE_TYPE (gnu_type) = get_unpadded_type (Etype (gnat_entity)); TYPE_PRECISION (gnu_type) = fp_size_to_prec (esize); TYPE_MIN_VALUE (gnu_type) = convert (TREE_TYPE (gnu_type), elaborate_expression (Type_Low_Bound (gnat_entity), gnat_entity, get_identifier ("L"), definition, 1, Needs_Debug_Info (gnat_entity))); TYPE_MAX_VALUE (gnu_type) = convert (TREE_TYPE (gnu_type), elaborate_expression (Type_High_Bound (gnat_entity), gnat_entity, get_identifier ("U"), definition, 1, Needs_Debug_Info (gnat_entity))); /* One of the above calls might have caused us to be elaborated, so don't blow up if so. */ if (present_gnu_tree (gnat_entity)) { maybe_present = true; break; } layout_type (gnu_type); /* Inherit our alias set from what we're a subtype of, as for integer subtypes. */ copy_alias_set (gnu_type, TREE_TYPE (gnu_type)); } break; /* Array and String Types and Subtypes Unconstrained array types are represented by E_Array_Type and constrained array types are represented by E_Array_Subtype. There are no actual objects of an unconstrained array type; all we have are pointers to that type. The following fields are defined on array types and subtypes: Component_Type Component type of the array. Number_Dimensions Number of dimensions (an int). First_Index Type of first index. */ case E_String_Type: case E_Array_Type: { tree gnu_template_fields = NULL_TREE; tree gnu_template_type = make_node (RECORD_TYPE); tree gnu_ptr_template = build_pointer_type (gnu_template_type); tree gnu_fat_type = make_node (RECORD_TYPE); int ndim = Number_Dimensions (gnat_entity); int firstdim = (Convention (gnat_entity) == Convention_Fortran) ? ndim - 1 : 0; int nextdim = (Convention (gnat_entity) == Convention_Fortran) ? - 1 : 1; tree *gnu_index_types = (tree *) alloca (ndim * sizeof (tree *)); tree *gnu_temp_fields = (tree *) alloca (ndim * sizeof (tree *)); tree gnu_comp_size = 0; tree gnu_max_size = size_one_node; tree gnu_max_size_unit; int index; Entity_Id gnat_ind_subtype; Entity_Id gnat_ind_base_subtype; tree gnu_template_reference; tree tem; TYPE_NAME (gnu_template_type) = create_concat_name (gnat_entity, "XUB"); /* Make a node for the array. If we are not defining the array suppress expanding incomplete types. */ gnu_type = make_node (UNCONSTRAINED_ARRAY_TYPE); if (!definition) defer_incomplete_level++, this_deferred = true; /* Build the fat pointer type. Use a "void *" object instead of a pointer to the array type since we don't have the array type yet (it will reference the fat pointer via the bounds). */ tem = chainon (chainon (NULL_TREE, create_field_decl (get_identifier ("P_ARRAY"), ptr_void_type_node, gnu_fat_type, 0, 0, 0, 0)), create_field_decl (get_identifier ("P_BOUNDS"), gnu_ptr_template, gnu_fat_type, 0, 0, 0, 0)); /* Make sure we can put this into a register. */ TYPE_ALIGN (gnu_fat_type) = MIN (BIGGEST_ALIGNMENT, 2 * POINTER_SIZE); /* Do not finalize this record type since the types of its fields are still incomplete at this point. */ finish_record_type (gnu_fat_type, tem, 0, true); TYPE_IS_FAT_POINTER_P (gnu_fat_type) = 1; /* Build a reference to the template from a PLACEHOLDER_EXPR that is the fat pointer. This will be used to access the individual fields once we build them. */ tem = build3 (COMPONENT_REF, gnu_ptr_template, build0 (PLACEHOLDER_EXPR, gnu_fat_type), TREE_CHAIN (TYPE_FIELDS (gnu_fat_type)), NULL_TREE); gnu_template_reference = build_unary_op (INDIRECT_REF, gnu_template_type, tem); TREE_READONLY (gnu_template_reference) = 1; /* Now create the GCC type for each index and add the fields for that index to the template. */ for (index = firstdim, gnat_ind_subtype = First_Index (gnat_entity), gnat_ind_base_subtype = First_Index (Implementation_Base_Type (gnat_entity)); index < ndim && index >= 0; index += nextdim, gnat_ind_subtype = Next_Index (gnat_ind_subtype), gnat_ind_base_subtype = Next_Index (gnat_ind_base_subtype)) { char field_name[10]; tree gnu_ind_subtype = get_unpadded_type (Base_Type (Etype (gnat_ind_subtype))); tree gnu_base_subtype = get_unpadded_type (Etype (gnat_ind_base_subtype)); tree gnu_base_min = convert (sizetype, TYPE_MIN_VALUE (gnu_base_subtype)); tree gnu_base_max = convert (sizetype, TYPE_MAX_VALUE (gnu_base_subtype)); tree gnu_min_field, gnu_max_field, gnu_min, gnu_max; /* Make the FIELD_DECLs for the minimum and maximum of this type and then make extractions of that field from the template. */ sprintf (field_name, "LB%d", index); gnu_min_field = create_field_decl (get_identifier (field_name), gnu_ind_subtype, gnu_template_type, 0, 0, 0, 0); field_name[0] = 'U'; gnu_max_field = create_field_decl (get_identifier (field_name), gnu_ind_subtype, gnu_template_type, 0, 0, 0, 0); Sloc_to_locus (Sloc (gnat_entity), &DECL_SOURCE_LOCATION (gnu_min_field)); Sloc_to_locus (Sloc (gnat_entity), &DECL_SOURCE_LOCATION (gnu_max_field)); gnu_temp_fields[index] = chainon (gnu_min_field, gnu_max_field); /* We can't use build_component_ref here since the template type isn't complete yet. */ gnu_min = build3 (COMPONENT_REF, gnu_ind_subtype, gnu_template_reference, gnu_min_field, NULL_TREE); gnu_max = build3 (COMPONENT_REF, gnu_ind_subtype, gnu_template_reference, gnu_max_field, NULL_TREE); TREE_READONLY (gnu_min) = TREE_READONLY (gnu_max) = 1; /* Make a range type with the new ranges, but using the Ada subtype. Then we convert to sizetype. */ gnu_index_types[index] = create_index_type (convert (sizetype, gnu_min), convert (sizetype, gnu_max), build_range_type (gnu_ind_subtype, gnu_min, gnu_max), gnat_entity); /* Update the maximum size of the array, in elements. */ gnu_max_size = size_binop (MULT_EXPR, gnu_max_size, size_binop (PLUS_EXPR, size_one_node, size_binop (MINUS_EXPR, gnu_base_max, gnu_base_min))); TYPE_NAME (gnu_index_types[index]) = create_concat_name (gnat_entity, field_name); } for (index = 0; index < ndim; index++) gnu_template_fields = chainon (gnu_template_fields, gnu_temp_fields[index]); /* Install all the fields into the template. */ finish_record_type (gnu_template_type, gnu_template_fields, 0, false); TYPE_READONLY (gnu_template_type) = 1; /* Now make the array of arrays and update the pointer to the array in the fat pointer. Note that it is the first field. */ tem = gnat_to_gnu_type (Component_Type (gnat_entity)); /* Get and validate any specified Component_Size, but if Packed, ignore it since the front end will have taken care of it. */ gnu_comp_size = validate_size (Component_Size (gnat_entity), tem, gnat_entity, (Is_Bit_Packed_Array (gnat_entity) ? TYPE_DECL : VAR_DECL), true, Has_Component_Size_Clause (gnat_entity)); if (Has_Atomic_Components (gnat_entity)) check_ok_for_atomic (tem, gnat_entity, true); /* If the component type is a RECORD_TYPE that has a self-referential size, use the maxium size. */ if (!gnu_comp_size && TREE_CODE (tem) == RECORD_TYPE && CONTAINS_PLACEHOLDER_P (TYPE_SIZE (tem))) gnu_comp_size = max_size (TYPE_SIZE (tem), true); if (!Is_Bit_Packed_Array (gnat_entity) && gnu_comp_size) { tree orig_tem; tem = make_type_from_size (tem, gnu_comp_size, false); orig_tem = tem; tem = maybe_pad_type (tem, gnu_comp_size, 0, gnat_entity, "C_PAD", false, definition, true); /* If a padding record was made, declare it now since it will never be declared otherwise. This is necessary in order to ensure that its subtrees are properly marked. */ if (tem != orig_tem) create_type_decl (TYPE_NAME (tem), tem, NULL, true, false, gnat_entity); } if (Has_Volatile_Components (gnat_entity)) tem = build_qualified_type (tem, TYPE_QUALS (tem) | TYPE_QUAL_VOLATILE); /* If Component_Size is not already specified, annotate it with the size of the component. */ if (Unknown_Component_Size (gnat_entity)) Set_Component_Size (gnat_entity, annotate_value (TYPE_SIZE (tem))); gnu_max_size_unit = size_binop (MAX_EXPR, size_zero_node, size_binop (MULT_EXPR, gnu_max_size, TYPE_SIZE_UNIT (tem))); gnu_max_size = size_binop (MAX_EXPR, bitsize_zero_node, size_binop (MULT_EXPR, convert (bitsizetype, gnu_max_size), TYPE_SIZE (tem))); for (index = ndim - 1; index >= 0; index--) { tem = build_array_type (tem, gnu_index_types[index]); TYPE_MULTI_ARRAY_P (tem) = (index > 0); /* If the type below this is a multi-array type, then this does not have aliased components. But we have to make them addressable if it must be passed by reference or if that is the default. */ if ((TREE_CODE (TREE_TYPE (tem)) == ARRAY_TYPE && TYPE_MULTI_ARRAY_P (TREE_TYPE (tem))) || (!Has_Aliased_Components (gnat_entity) && !must_pass_by_ref (TREE_TYPE (tem)) && !default_pass_by_ref (TREE_TYPE (tem)))) TYPE_NONALIASED_COMPONENT (tem) = 1; } /* If an alignment is specified, use it if valid. But ignore it for types that represent the unpacked base type for packed arrays. */ if (No (Packed_Array_Type (gnat_entity)) && Known_Alignment (gnat_entity)) { gcc_assert (Present (Alignment (gnat_entity))); TYPE_ALIGN (tem) = validate_alignment (Alignment (gnat_entity), gnat_entity, TYPE_ALIGN (tem)); } TYPE_CONVENTION_FORTRAN_P (tem) = (Convention (gnat_entity) == Convention_Fortran); TREE_TYPE (TYPE_FIELDS (gnu_fat_type)) = build_pointer_type (tem); /* The result type is an UNCONSTRAINED_ARRAY_TYPE that indicates the corresponding fat pointer. */ TREE_TYPE (gnu_type) = TYPE_POINTER_TO (gnu_type) = TYPE_REFERENCE_TO (gnu_type) = gnu_fat_type; TYPE_MODE (gnu_type) = BLKmode; TYPE_ALIGN (gnu_type) = TYPE_ALIGN (tem); SET_TYPE_UNCONSTRAINED_ARRAY (gnu_fat_type, gnu_type); /* If the maximum size doesn't overflow, use it. */ if (TREE_CODE (gnu_max_size) == INTEGER_CST && !TREE_OVERFLOW (gnu_max_size)) TYPE_SIZE (tem) = size_binop (MIN_EXPR, gnu_max_size, TYPE_SIZE (tem)); if (TREE_CODE (gnu_max_size_unit) == INTEGER_CST && !TREE_OVERFLOW (gnu_max_size_unit)) TYPE_SIZE_UNIT (tem) = size_binop (MIN_EXPR, gnu_max_size_unit, TYPE_SIZE_UNIT (tem)); create_type_decl (create_concat_name (gnat_entity, "XUA"), tem, NULL, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); /* Give the fat pointer type a name. */ create_type_decl (create_concat_name (gnat_entity, "XUP"), gnu_fat_type, NULL, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); /* Create the type to be used as what a thin pointer designates: an record type for the object and its template with the field offsets shifted to have the template at a negative offset. */ tem = build_unc_object_type (gnu_template_type, tem, create_concat_name (gnat_entity, "XUT")); shift_unc_components_for_thin_pointers (tem); SET_TYPE_UNCONSTRAINED_ARRAY (tem, gnu_type); TYPE_OBJECT_RECORD_TYPE (gnu_type) = tem; /* Give the thin pointer type a name. */ create_type_decl (create_concat_name (gnat_entity, "XUX"), build_pointer_type (tem), NULL, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); } break; case E_String_Subtype: case E_Array_Subtype: /* This is the actual data type for array variables. Multidimensional arrays are implemented in the gnu tree as arrays of arrays. Note that for the moment arrays which have sparse enumeration subtypes as index components create sparse arrays, which is obviously space inefficient but so much easier to code for now. Also note that the subtype never refers to the unconstrained array type, which is somewhat at variance with Ada semantics. First check to see if this is simply a renaming of the array type. If so, the result is the array type. */ gnu_type = gnat_to_gnu_type (Etype (gnat_entity)); if (!Is_Constrained (gnat_entity)) break; else { int index; int array_dim = Number_Dimensions (gnat_entity); int first_dim = ((Convention (gnat_entity) == Convention_Fortran) ? array_dim - 1 : 0); int next_dim = (Convention (gnat_entity) == Convention_Fortran) ? -1 : 1; Entity_Id gnat_ind_subtype; Entity_Id gnat_ind_base_subtype; tree gnu_base_type = gnu_type; tree *gnu_index_type = (tree *) alloca (array_dim * sizeof (tree *)); tree gnu_comp_size = NULL_TREE; tree gnu_max_size = size_one_node; tree gnu_max_size_unit; bool need_index_type_struct = false; bool max_overflow = false; /* First create the gnu types for each index. Create types for debugging information to point to the index types if the are not integer types, have variable bounds, or are wider than sizetype. */ for (index = first_dim, gnat_ind_subtype = First_Index (gnat_entity), gnat_ind_base_subtype = First_Index (Implementation_Base_Type (gnat_entity)); index < array_dim && index >= 0; index += next_dim, gnat_ind_subtype = Next_Index (gnat_ind_subtype), gnat_ind_base_subtype = Next_Index (gnat_ind_base_subtype)) { tree gnu_index_subtype = get_unpadded_type (Etype (gnat_ind_subtype)); tree gnu_min = convert (sizetype, TYPE_MIN_VALUE (gnu_index_subtype)); tree gnu_max = convert (sizetype, TYPE_MAX_VALUE (gnu_index_subtype)); tree gnu_base_subtype = get_unpadded_type (Etype (gnat_ind_base_subtype)); tree gnu_base_min = convert (sizetype, TYPE_MIN_VALUE (gnu_base_subtype)); tree gnu_base_max = convert (sizetype, TYPE_MAX_VALUE (gnu_base_subtype)); tree gnu_base_type = get_base_type (gnu_base_subtype); tree gnu_base_base_min = convert (sizetype, TYPE_MIN_VALUE (gnu_base_type)); tree gnu_base_base_max = convert (sizetype, TYPE_MAX_VALUE (gnu_base_type)); tree gnu_high; tree gnu_this_max; /* If the minimum and maximum values both overflow in SIZETYPE, but the difference in the original type does not overflow in SIZETYPE, ignore the overflow indications. */ if ((TYPE_PRECISION (gnu_index_subtype) > TYPE_PRECISION (sizetype) || TYPE_UNSIGNED (gnu_index_subtype) != TYPE_UNSIGNED (sizetype)) && TREE_CODE (gnu_min) == INTEGER_CST && TREE_CODE (gnu_max) == INTEGER_CST && TREE_OVERFLOW (gnu_min) && TREE_OVERFLOW (gnu_max) && (!TREE_OVERFLOW (fold_build2 (MINUS_EXPR, gnu_index_subtype, TYPE_MAX_VALUE (gnu_index_subtype), TYPE_MIN_VALUE (gnu_index_subtype))))) { TREE_OVERFLOW (gnu_min) = 0; TREE_OVERFLOW (gnu_max) = 0; } /* Similarly, if the range is null, use bounds of 1..0 for the sizetype bounds. */ else if ((TYPE_PRECISION (gnu_index_subtype) > TYPE_PRECISION (sizetype) || TYPE_UNSIGNED (gnu_index_subtype) != TYPE_UNSIGNED (sizetype)) && TREE_CODE (gnu_min) == INTEGER_CST && TREE_CODE (gnu_max) == INTEGER_CST && (TREE_OVERFLOW (gnu_min) || TREE_OVERFLOW (gnu_max)) && tree_int_cst_lt (TYPE_MAX_VALUE (gnu_index_subtype), TYPE_MIN_VALUE (gnu_index_subtype))) gnu_min = size_one_node, gnu_max = size_zero_node; /* Now compute the size of this bound. We need to provide GCC with an upper bound to use but have to deal with the "superflat" case. There are three ways to do this. If we can prove that the array can never be superflat, we can just use the high bound of the index subtype. If we can prove that the low bound minus one can't overflow, we can do this as MAX (hb, lb - 1). Otherwise, we have to use the expression hb >= lb ? hb : lb - 1. */ gnu_high = size_binop (MINUS_EXPR, gnu_min, size_one_node); /* See if the base array type is already flat. If it is, we are probably compiling an ACVC test, but it will cause the code below to malfunction if we don't handle it specially. */ if (TREE_CODE (gnu_base_min) == INTEGER_CST && TREE_CODE (gnu_base_max) == INTEGER_CST && !TREE_OVERFLOW (gnu_base_min) && !TREE_OVERFLOW (gnu_base_max) && tree_int_cst_lt (gnu_base_max, gnu_base_min)) gnu_high = size_zero_node, gnu_min = size_one_node; /* If gnu_high is now an integer which overflowed, the array cannot be superflat. */ else if (TREE_CODE (gnu_high) == INTEGER_CST && TREE_OVERFLOW (gnu_high)) gnu_high = gnu_max; else if (TYPE_UNSIGNED (gnu_base_subtype) || TREE_CODE (gnu_high) == INTEGER_CST) gnu_high = size_binop (MAX_EXPR, gnu_max, gnu_high); else gnu_high = build_cond_expr (sizetype, build_binary_op (GE_EXPR, integer_type_node, gnu_max, gnu_min), gnu_max, gnu_high); gnu_index_type[index] = create_index_type (gnu_min, gnu_high, gnu_index_subtype, gnat_entity); /* Also compute the maximum size of the array. Here we see if any constraint on the index type of the base type can be used in the case of self-referential bound on the index type of the subtype. We look for a non-"infinite" and non-self-referential bound from any type involved and handle each bound separately. */ if ((TREE_CODE (gnu_min) == INTEGER_CST && !TREE_OVERFLOW (gnu_min) && !operand_equal_p (gnu_min, gnu_base_base_min, 0)) || !CONTAINS_PLACEHOLDER_P (gnu_min) || !(TREE_CODE (gnu_base_min) == INTEGER_CST && !TREE_OVERFLOW (gnu_base_min))) gnu_base_min = gnu_min; if ((TREE_CODE (gnu_max) == INTEGER_CST && !TREE_OVERFLOW (gnu_max) && !operand_equal_p (gnu_max, gnu_base_base_max, 0)) || !CONTAINS_PLACEHOLDER_P (gnu_max) || !(TREE_CODE (gnu_base_max) == INTEGER_CST && !TREE_OVERFLOW (gnu_base_max))) gnu_base_max = gnu_max; if ((TREE_CODE (gnu_base_min) == INTEGER_CST && TREE_OVERFLOW (gnu_base_min)) || operand_equal_p (gnu_base_min, gnu_base_base_min, 0) || (TREE_CODE (gnu_base_max) == INTEGER_CST && TREE_OVERFLOW (gnu_base_max)) || operand_equal_p (gnu_base_max, gnu_base_base_max, 0)) max_overflow = true; gnu_base_min = size_binop (MAX_EXPR, gnu_base_min, gnu_min); gnu_base_max = size_binop (MIN_EXPR, gnu_base_max, gnu_max); gnu_this_max = size_binop (MAX_EXPR, size_binop (PLUS_EXPR, size_one_node, size_binop (MINUS_EXPR, gnu_base_max, gnu_base_min)), size_zero_node); if (TREE_CODE (gnu_this_max) == INTEGER_CST && TREE_OVERFLOW (gnu_this_max)) max_overflow = true; gnu_max_size = size_binop (MULT_EXPR, gnu_max_size, gnu_this_max); if (!integer_onep (TYPE_MIN_VALUE (gnu_index_subtype)) || (TREE_CODE (TYPE_MAX_VALUE (gnu_index_subtype)) != INTEGER_CST) || TREE_CODE (gnu_index_subtype) != INTEGER_TYPE || (TREE_TYPE (gnu_index_subtype) && (TREE_CODE (TREE_TYPE (gnu_index_subtype)) != INTEGER_TYPE)) || TYPE_BIASED_REPRESENTATION_P (gnu_index_subtype) || (TYPE_PRECISION (gnu_index_subtype) > TYPE_PRECISION (sizetype))) need_index_type_struct = true; } /* Then flatten: create the array of arrays. */ gnu_type = gnat_to_gnu_type (Component_Type (gnat_entity)); /* One of the above calls might have caused us to be elaborated, so don't blow up if so. */ if (present_gnu_tree (gnat_entity)) { maybe_present = true; break; } /* Get and validate any specified Component_Size, but if Packed, ignore it since the front end will have taken care of it. */ gnu_comp_size = validate_size (Component_Size (gnat_entity), gnu_type, gnat_entity, (Is_Bit_Packed_Array (gnat_entity) ? TYPE_DECL : VAR_DECL), true, Has_Component_Size_Clause (gnat_entity)); /* If the component type is a RECORD_TYPE that has a self-referential size, use the maxium size. */ if (!gnu_comp_size && TREE_CODE (gnu_type) == RECORD_TYPE && CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type))) gnu_comp_size = max_size (TYPE_SIZE (gnu_type), true); if (!Is_Bit_Packed_Array (gnat_entity) && gnu_comp_size) { tree orig_gnu_type; gnu_type = make_type_from_size (gnu_type, gnu_comp_size, false); orig_gnu_type = gnu_type; gnu_type = maybe_pad_type (gnu_type, gnu_comp_size, 0, gnat_entity, "C_PAD", false, definition, true); /* If a padding record was made, declare it now since it will never be declared otherwise. This is necessary in order to ensure that its subtrees are properly marked. */ if (gnu_type != orig_gnu_type) create_type_decl (TYPE_NAME (gnu_type), gnu_type, NULL, true, false, gnat_entity); } if (Has_Volatile_Components (Base_Type (gnat_entity))) gnu_type = build_qualified_type (gnu_type, (TYPE_QUALS (gnu_type) | TYPE_QUAL_VOLATILE)); gnu_max_size_unit = size_binop (MULT_EXPR, gnu_max_size, TYPE_SIZE_UNIT (gnu_type)); gnu_max_size = size_binop (MULT_EXPR, convert (bitsizetype, gnu_max_size), TYPE_SIZE (gnu_type)); for (index = array_dim - 1; index >= 0; index --) { gnu_type = build_array_type (gnu_type, gnu_index_type[index]); TYPE_MULTI_ARRAY_P (gnu_type) = (index > 0); /* If the type below this is a multi-array type, then this does not have aliased components. But we have to make them addressable if it must be passed by reference or if that is the default. */ if ((TREE_CODE (TREE_TYPE (gnu_type)) == ARRAY_TYPE && TYPE_MULTI_ARRAY_P (TREE_TYPE (gnu_type))) || (!Has_Aliased_Components (gnat_entity) && !must_pass_by_ref (TREE_TYPE (gnu_type)) && !default_pass_by_ref (TREE_TYPE (gnu_type)))) TYPE_NONALIASED_COMPONENT (gnu_type) = 1; } /* If we are at file level and this is a multi-dimensional array, we need to make a variable corresponding to the stride of the inner dimensions. */ if (global_bindings_p () && array_dim > 1) { tree gnu_str_name = get_identifier ("ST"); tree gnu_arr_type; for (gnu_arr_type = TREE_TYPE (gnu_type); TREE_CODE (gnu_arr_type) == ARRAY_TYPE; gnu_arr_type = TREE_TYPE (gnu_arr_type), gnu_str_name = concat_id_with_name (gnu_str_name, "ST")) { tree eltype = TREE_TYPE (gnu_arr_type); TYPE_SIZE (gnu_arr_type) = elaborate_expression_1 (gnat_entity, gnat_entity, TYPE_SIZE (gnu_arr_type), gnu_str_name, definition, 0); /* ??? For now, store the size as a multiple of the alignment of the element type in bytes so that we can see the alignment from the tree. */ TYPE_SIZE_UNIT (gnu_arr_type) = build_binary_op (MULT_EXPR, sizetype, elaborate_expression_1 (gnat_entity, gnat_entity, build_binary_op (EXACT_DIV_EXPR, sizetype, TYPE_SIZE_UNIT (gnu_arr_type), size_int (TYPE_ALIGN (eltype) / BITS_PER_UNIT)), concat_id_with_name (gnu_str_name, "A_U"), definition, 0), size_int (TYPE_ALIGN (eltype) / BITS_PER_UNIT)); /* ??? create_type_decl is not invoked on the inner types so the MULT_EXPR node built above will never be marked. */ TREE_VISITED (TYPE_SIZE_UNIT (gnu_arr_type)) = 1; } } /* If we need to write out a record type giving the names of the bounds, do it now. */ if (need_index_type_struct && debug_info_p) { tree gnu_bound_rec_type = make_node (RECORD_TYPE); tree gnu_field_list = NULL_TREE; tree gnu_field; TYPE_NAME (gnu_bound_rec_type) = create_concat_name (gnat_entity, "XA"); for (index = array_dim - 1; index >= 0; index--) { tree gnu_type_name = TYPE_NAME (TYPE_INDEX_TYPE (gnu_index_type[index])); if (TREE_CODE (gnu_type_name) == TYPE_DECL) gnu_type_name = DECL_NAME (gnu_type_name); gnu_field = create_field_decl (gnu_type_name, integer_type_node, gnu_bound_rec_type, 0, NULL_TREE, NULL_TREE, 0); TREE_CHAIN (gnu_field) = gnu_field_list; gnu_field_list = gnu_field; } finish_record_type (gnu_bound_rec_type, gnu_field_list, 0, false); } TYPE_CONVENTION_FORTRAN_P (gnu_type) = (Convention (gnat_entity) == Convention_Fortran); TYPE_PACKED_ARRAY_TYPE_P (gnu_type) = Is_Packed_Array_Type (gnat_entity); /* If our size depends on a placeholder and the maximum size doesn't overflow, use it. */ if (CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type)) && !(TREE_CODE (gnu_max_size) == INTEGER_CST && TREE_OVERFLOW (gnu_max_size)) && !(TREE_CODE (gnu_max_size_unit) == INTEGER_CST && TREE_OVERFLOW (gnu_max_size_unit)) && !max_overflow) { TYPE_SIZE (gnu_type) = size_binop (MIN_EXPR, gnu_max_size, TYPE_SIZE (gnu_type)); TYPE_SIZE_UNIT (gnu_type) = size_binop (MIN_EXPR, gnu_max_size_unit, TYPE_SIZE_UNIT (gnu_type)); } /* Set our alias set to that of our base type. This gives all array subtypes the same alias set. */ copy_alias_set (gnu_type, gnu_base_type); } /* If this is a packed type, make this type the same as the packed array type, but do some adjusting in the type first. */ if (Present (Packed_Array_Type (gnat_entity))) { Entity_Id gnat_index; tree gnu_inner_type; /* First finish the type we had been making so that we output debugging information for it */ gnu_type = build_qualified_type (gnu_type, (TYPE_QUALS (gnu_type) | (TYPE_QUAL_VOLATILE * Treat_As_Volatile (gnat_entity)))); gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); if (!Comes_From_Source (gnat_entity)) DECL_ARTIFICIAL (gnu_decl) = 1; /* Save it as our equivalent in case the call below elaborates this type again. */ save_gnu_tree (gnat_entity, gnu_decl, false); gnu_decl = gnat_to_gnu_entity (Packed_Array_Type (gnat_entity), NULL_TREE, 0); this_made_decl = true; gnu_type = TREE_TYPE (gnu_decl); save_gnu_tree (gnat_entity, NULL_TREE, false); gnu_inner_type = gnu_type; while (TREE_CODE (gnu_inner_type) == RECORD_TYPE && (TYPE_JUSTIFIED_MODULAR_P (gnu_inner_type) || TYPE_IS_PADDING_P (gnu_inner_type))) gnu_inner_type = TREE_TYPE (TYPE_FIELDS (gnu_inner_type)); /* We need to point the type we just made to our index type so the actual bounds can be put into a template. */ if ((TREE_CODE (gnu_inner_type) == ARRAY_TYPE && !TYPE_ACTUAL_BOUNDS (gnu_inner_type)) || (TREE_CODE (gnu_inner_type) == INTEGER_TYPE && !TYPE_HAS_ACTUAL_BOUNDS_P (gnu_inner_type))) { if (TREE_CODE (gnu_inner_type) == INTEGER_TYPE) { /* The TYPE_ACTUAL_BOUNDS field is also used for the modulus. If it is, we need to make another type. */ if (TYPE_MODULAR_P (gnu_inner_type)) { tree gnu_subtype; gnu_subtype = make_node (INTEGER_TYPE); TREE_TYPE (gnu_subtype) = gnu_inner_type; TYPE_MIN_VALUE (gnu_subtype) = TYPE_MIN_VALUE (gnu_inner_type); TYPE_MAX_VALUE (gnu_subtype) = TYPE_MAX_VALUE (gnu_inner_type); TYPE_PRECISION (gnu_subtype) = TYPE_PRECISION (gnu_inner_type); TYPE_UNSIGNED (gnu_subtype) = TYPE_UNSIGNED (gnu_inner_type); TYPE_EXTRA_SUBTYPE_P (gnu_subtype) = 1; layout_type (gnu_subtype); gnu_inner_type = gnu_subtype; } TYPE_HAS_ACTUAL_BOUNDS_P (gnu_inner_type) = 1; } SET_TYPE_ACTUAL_BOUNDS (gnu_inner_type, NULL_TREE); for (gnat_index = First_Index (gnat_entity); Present (gnat_index); gnat_index = Next_Index (gnat_index)) SET_TYPE_ACTUAL_BOUNDS (gnu_inner_type, tree_cons (NULL_TREE, get_unpadded_type (Etype (gnat_index)), TYPE_ACTUAL_BOUNDS (gnu_inner_type))); if (Convention (gnat_entity) != Convention_Fortran) SET_TYPE_ACTUAL_BOUNDS (gnu_inner_type, nreverse (TYPE_ACTUAL_BOUNDS (gnu_inner_type))); if (TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (gnu_type)) TREE_TYPE (TYPE_FIELDS (gnu_type)) = gnu_inner_type; } } /* Abort if packed array with no packed array type field set. */ else gcc_assert (!Is_Packed (gnat_entity)); break; case E_String_Literal_Subtype: /* Create the type for a string literal. */ { Entity_Id gnat_full_type = (IN (Ekind (Etype (gnat_entity)), Private_Kind) && Present (Full_View (Etype (gnat_entity))) ? Full_View (Etype (gnat_entity)) : Etype (gnat_entity)); tree gnu_string_type = get_unpadded_type (gnat_full_type); tree gnu_string_array_type = TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (gnu_string_type)))); tree gnu_string_index_type = get_base_type (TREE_TYPE (TYPE_INDEX_TYPE (TYPE_DOMAIN (gnu_string_array_type)))); tree gnu_lower_bound = convert (gnu_string_index_type, gnat_to_gnu (String_Literal_Low_Bound (gnat_entity))); int length = UI_To_Int (String_Literal_Length (gnat_entity)); tree gnu_length = ssize_int (length - 1); tree gnu_upper_bound = build_binary_op (PLUS_EXPR, gnu_string_index_type, gnu_lower_bound, convert (gnu_string_index_type, gnu_length)); tree gnu_range_type = build_range_type (gnu_string_index_type, gnu_lower_bound, gnu_upper_bound); tree gnu_index_type = create_index_type (convert (sizetype, TYPE_MIN_VALUE (gnu_range_type)), convert (sizetype, TYPE_MAX_VALUE (gnu_range_type)), gnu_range_type, gnat_entity); gnu_type = build_array_type (gnat_to_gnu_type (Component_Type (gnat_entity)), gnu_index_type); copy_alias_set (gnu_type, gnu_string_type); } break; /* Record Types and Subtypes The following fields are defined on record types: Has_Discriminants True if the record has discriminants First_Discriminant Points to head of list of discriminants First_Entity Points to head of list of fields Is_Tagged_Type True if the record is tagged Implementation of Ada records and discriminated records: A record type definition is transformed into the equivalent of a C struct definition. The fields that are the discriminants which are found in the Full_Type_Declaration node and the elements of the Component_List found in the Record_Type_Definition node. The Component_List can be a recursive structure since each Variant of the Variant_Part of the Component_List has a Component_List. Processing of a record type definition comprises starting the list of field declarations here from the discriminants and the calling the function components_to_record to add the rest of the fields from the component list and return the gnu type node. The function components_to_record will call itself recursively as it traverses the tree. */ case E_Record_Type: if (Has_Complex_Representation (gnat_entity)) { gnu_type = build_complex_type (get_unpadded_type (Etype (Defining_Entity (First (Component_Items (Component_List (Type_Definition (Declaration_Node (gnat_entity))))))))); break; } { Node_Id full_definition = Declaration_Node (gnat_entity); Node_Id record_definition = Type_Definition (full_definition); Entity_Id gnat_field; tree gnu_field; tree gnu_field_list = NULL_TREE; tree gnu_get_parent; int packed = Is_Packed (gnat_entity) ? 1 : Component_Alignment (gnat_entity) == Calign_Storage_Unit ? -1 : Known_Alignment (gnat_entity) ? -2 : 0; bool has_rep = Has_Specified_Layout (gnat_entity); bool all_rep = has_rep; bool is_extension = (Is_Tagged_Type (gnat_entity) && Nkind (record_definition) == N_Derived_Type_Definition); /* See if all fields have a rep clause. Stop when we find one that doesn't. */ for (gnat_field = First_Entity (gnat_entity); Present (gnat_field) && all_rep; gnat_field = Next_Entity (gnat_field)) if ((Ekind (gnat_field) == E_Component || Ekind (gnat_field) == E_Discriminant) && No (Component_Clause (gnat_field))) all_rep = false; /* If this is a record extension, go a level further to find the record definition. Also, verify we have a Parent_Subtype. */ if (is_extension) { if (!type_annotate_only || Present (Record_Extension_Part (record_definition))) record_definition = Record_Extension_Part (record_definition); gcc_assert (type_annotate_only || Present (Parent_Subtype (gnat_entity))); } /* Make a node for the record. If we are not defining the record, suppress expanding incomplete types. */ gnu_type = make_node (tree_code_for_record_type (gnat_entity)); TYPE_NAME (gnu_type) = gnu_entity_id; TYPE_PACKED (gnu_type) = (packed != 0) || has_rep; if (!definition) defer_incomplete_level++, this_deferred = true; /* If both a size and rep clause was specified, put the size in the record type now so that it can get the proper mode. */ if (has_rep && Known_Esize (gnat_entity)) TYPE_SIZE (gnu_type) = UI_To_gnu (Esize (gnat_entity), sizetype); /* Always set the alignment here so that it can be used to set the mode, if it is making the alignment stricter. If it is invalid, it will be checked again below. If this is to be Atomic, choose a default alignment of a word unless we know the size and it's smaller. */ if (Known_Alignment (gnat_entity)) TYPE_ALIGN (gnu_type) = validate_alignment (Alignment (gnat_entity), gnat_entity, 0); else if (Is_Atomic (gnat_entity)) TYPE_ALIGN (gnu_type) = (esize >= BITS_PER_WORD ? BITS_PER_WORD : 1 << (floor_log2 (esize - 1) + 1)); else TYPE_ALIGN (gnu_type) = 0; /* If we have a Parent_Subtype, make a field for the parent. If this record has rep clauses, force the position to zero. */ if (Present (Parent_Subtype (gnat_entity))) { Entity_Id gnat_parent = Parent_Subtype (gnat_entity); tree gnu_parent; /* A major complexity here is that the parent subtype will reference our discriminants in its Discriminant_Constraint list. But those must reference the parent component of this record which is of the parent subtype we have not built yet! To break the circle we first build a dummy COMPONENT_REF which represents the "get to the parent" operation and initialize each of those discriminants to a COMPONENT_REF of the above dummy parent referencing the corresponding discriminant of the base type of the parent subtype. */ gnu_get_parent = build3 (COMPONENT_REF, void_type_node, build0 (PLACEHOLDER_EXPR, gnu_type), build_decl (FIELD_DECL, NULL_TREE, void_type_node), NULL_TREE); if (Has_Discriminants (gnat_entity)) for (gnat_field = First_Stored_Discriminant (gnat_entity); Present (gnat_field); gnat_field = Next_Stored_Discriminant (gnat_field)) if (Present (Corresponding_Discriminant (gnat_field))) save_gnu_tree (gnat_field, build3 (COMPONENT_REF, get_unpadded_type (Etype (gnat_field)), gnu_get_parent, gnat_to_gnu_field_decl (Corresponding_Discriminant (gnat_field)), NULL_TREE), true); /* Then we build the parent subtype. */ gnu_parent = gnat_to_gnu_type (gnat_parent); /* Finally we fix up both kinds of twisted COMPONENT_REF we have initially built. The discriminants must reference the fields of the parent subtype and not those of its base type for the placeholder machinery to properly work. */ if (Has_Discriminants (gnat_entity)) for (gnat_field = First_Stored_Discriminant (gnat_entity); Present (gnat_field); gnat_field = Next_Stored_Discriminant (gnat_field)) if (Present (Corresponding_Discriminant (gnat_field))) { Entity_Id field = Empty; for (field = First_Stored_Discriminant (gnat_parent); Present (field); field = Next_Stored_Discriminant (field)) if (same_discriminant_p (gnat_field, field)) break; gcc_assert (Present (field)); TREE_OPERAND (get_gnu_tree (gnat_field), 1) = gnat_to_gnu_field_decl (field); } /* The "get to the parent" COMPONENT_REF must be given its proper type... */ TREE_TYPE (gnu_get_parent) = gnu_parent; /* ...and reference the _parent field of this record. */ gnu_field_list = create_field_decl (get_identifier (Get_Name_String (Name_uParent)), gnu_parent, gnu_type, 0, has_rep ? TYPE_SIZE (gnu_parent) : 0, has_rep ? bitsize_zero_node : 0, 1); DECL_INTERNAL_P (gnu_field_list) = 1; TREE_OPERAND (gnu_get_parent, 1) = gnu_field_list; } /* Make the fields for the discriminants and put them into the record unless it's an Unchecked_Union. */ if (Has_Discriminants (gnat_entity)) for (gnat_field = First_Stored_Discriminant (gnat_entity); Present (gnat_field); gnat_field = Next_Stored_Discriminant (gnat_field)) { /* If this is a record extension and this discriminant is the renaming of another discriminant, we've already handled the discriminant above. */ if (Present (Parent_Subtype (gnat_entity)) && Present (Corresponding_Discriminant (gnat_field))) continue; gnu_field = gnat_to_gnu_field (gnat_field, gnu_type, packed, definition); /* Make an expression using a PLACEHOLDER_EXPR from the FIELD_DECL node just created and link that with the corresponding GNAT defining identifier. Then add to the list of fields. */ save_gnu_tree (gnat_field, build3 (COMPONENT_REF, TREE_TYPE (gnu_field), build0 (PLACEHOLDER_EXPR, DECL_CONTEXT (gnu_field)), gnu_field, NULL_TREE), true); if (!Is_Unchecked_Union (gnat_entity)) { TREE_CHAIN (gnu_field) = gnu_field_list; gnu_field_list = gnu_field; } } /* Put the discriminants into the record (backwards), so we can know the appropriate discriminant to use for the names of the variants. */ TYPE_FIELDS (gnu_type) = gnu_field_list; /* Add the listed fields into the record and finish it up. */ components_to_record (gnu_type, Component_List (record_definition), gnu_field_list, packed, definition, NULL, false, all_rep, false, Is_Unchecked_Union (gnat_entity)); /* We used to remove the associations of the discriminants and _Parent for validity checking, but we may need them if there's Freeze_Node for a subtype used in this record. */ TYPE_VOLATILE (gnu_type) = Treat_As_Volatile (gnat_entity); TYPE_BY_REFERENCE_P (gnu_type) = Is_By_Reference_Type (gnat_entity); /* If it is a tagged record force the type to BLKmode to insure that these objects will always be placed in memory. Do the same thing for limited record types. */ if (Is_Tagged_Type (gnat_entity) || Is_Limited_Record (gnat_entity)) TYPE_MODE (gnu_type) = BLKmode; /* If this is a derived type, we must make the alias set of this type the same as that of the type we are derived from. We assume here that the other type is already frozen. */ if (Etype (gnat_entity) != gnat_entity && !(Is_Private_Type (Etype (gnat_entity)) && Full_View (Etype (gnat_entity)) == gnat_entity)) copy_alias_set (gnu_type, gnat_to_gnu_type (Etype (gnat_entity))); /* Fill in locations of fields. */ annotate_rep (gnat_entity, gnu_type); /* If there are any entities in the chain corresponding to components that we did not elaborate, ensure we elaborate their types if they are Itypes. */ for (gnat_temp = First_Entity (gnat_entity); Present (gnat_temp); gnat_temp = Next_Entity (gnat_temp)) if ((Ekind (gnat_temp) == E_Component || Ekind (gnat_temp) == E_Discriminant) && Is_Itype (Etype (gnat_temp)) && !present_gnu_tree (gnat_temp)) gnat_to_gnu_entity (Etype (gnat_temp), NULL_TREE, 0); } break; case E_Class_Wide_Subtype: /* If an equivalent type is present, that is what we should use. Otherwise, fall through to handle this like a record subtype since it may have constraints. */ if (gnat_equiv_type != gnat_entity) { gnu_decl = gnat_to_gnu_entity (gnat_equiv_type, NULL_TREE, 0); maybe_present = true; break; } /* ... fall through ... */ case E_Record_Subtype: /* If Cloned_Subtype is Present it means this record subtype has identical layout to that type or subtype and we should use that GCC type for this one. The front end guarantees that the component list is shared. */ if (Present (Cloned_Subtype (gnat_entity))) { gnu_decl = gnat_to_gnu_entity (Cloned_Subtype (gnat_entity), NULL_TREE, 0); maybe_present = true; } /* Otherwise, first ensure the base type is elaborated. Then, if we are changing the type, make a new type with each field having the type of the field in the new subtype but having the position computed by transforming every discriminant reference according to the constraints. We don't see any difference between private and nonprivate type here since derivations from types should have been deferred until the completion of the private type. */ else { Entity_Id gnat_base_type = Implementation_Base_Type (gnat_entity); tree gnu_base_type; tree gnu_orig_type; if (!definition) defer_incomplete_level++, this_deferred = true; /* Get the base type initially for its alignment and sizes. But if it is a padded type, we do all the other work with the unpadded type. */ gnu_base_type = gnat_to_gnu_type (gnat_base_type); if (TREE_CODE (gnu_base_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_base_type)) gnu_type = gnu_orig_type = TREE_TYPE (TYPE_FIELDS (gnu_base_type)); else gnu_type = gnu_orig_type = gnu_base_type; if (present_gnu_tree (gnat_entity)) { maybe_present = true; break; } /* When the type has discriminants, and these discriminants affect the shape of what it built, factor them in. If we are making a subtype of an Unchecked_Union (must be an Itype), just return the type. We can't just use Is_Constrained because private subtypes without discriminants of full types with discriminants with default expressions are Is_Constrained but aren't constrained! */ if (IN (Ekind (gnat_base_type), Record_Kind) && !Is_For_Access_Subtype (gnat_entity) && !Is_Unchecked_Union (gnat_base_type) && Is_Constrained (gnat_entity) && Stored_Constraint (gnat_entity) != No_Elist && Present (Discriminant_Constraint (gnat_entity))) { Entity_Id gnat_field; tree gnu_field_list = 0; tree gnu_pos_list = compute_field_positions (gnu_orig_type, NULL_TREE, size_zero_node, bitsize_zero_node, BIGGEST_ALIGNMENT); tree gnu_subst_list = substitution_list (gnat_entity, gnat_base_type, NULL_TREE, definition); tree gnu_temp; gnu_type = make_node (RECORD_TYPE); TYPE_NAME (gnu_type) = gnu_entity_id; TYPE_ALIGN (gnu_type) = TYPE_ALIGN (gnu_base_type); TYPE_VOLATILE (gnu_type) = Treat_As_Volatile (gnat_entity); for (gnat_field = First_Entity (gnat_entity); Present (gnat_field); gnat_field = Next_Entity (gnat_field)) if ((Ekind (gnat_field) == E_Component || Ekind (gnat_field) == E_Discriminant) && (Underlying_Type (Scope (Original_Record_Component (gnat_field))) == gnat_base_type) && (No (Corresponding_Discriminant (gnat_field)) || !Is_Tagged_Type (gnat_base_type))) { tree gnu_old_field = gnat_to_gnu_field_decl (Original_Record_Component (gnat_field)); tree gnu_offset = TREE_VALUE (purpose_member (gnu_old_field, gnu_pos_list)); tree gnu_pos = TREE_PURPOSE (gnu_offset); tree gnu_bitpos = TREE_VALUE (TREE_VALUE (gnu_offset)); tree gnu_field_type = gnat_to_gnu_type (Etype (gnat_field)); tree gnu_size = TYPE_SIZE (gnu_field_type); tree gnu_new_pos = 0; unsigned int offset_align = tree_low_cst (TREE_PURPOSE (TREE_VALUE (gnu_offset)), 1); tree gnu_field; /* If there was a component clause, the field types must be the same for the type and subtype, so copy the data from the old field to avoid recomputation here. Also if the field is justified modular and the optimization in gnat_to_gnu_field was applied. */ if (Present (Component_Clause (Original_Record_Component (gnat_field))) || (TREE_CODE (gnu_field_type) == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (gnu_field_type) && TREE_TYPE (TYPE_FIELDS (gnu_field_type)) == TREE_TYPE (gnu_old_field))) { gnu_size = DECL_SIZE (gnu_old_field); gnu_field_type = TREE_TYPE (gnu_old_field); } /* If this was a bitfield, get the size from the old field. Also ensure the type can be placed into a bitfield. */ else if (DECL_BIT_FIELD (gnu_old_field)) { gnu_size = DECL_SIZE (gnu_old_field); if (TYPE_MODE (gnu_field_type) == BLKmode && TREE_CODE (gnu_field_type) == RECORD_TYPE && host_integerp (TYPE_SIZE (gnu_field_type), 1)) gnu_field_type = make_packable_type (gnu_field_type); } if (CONTAINS_PLACEHOLDER_P (gnu_pos)) for (gnu_temp = gnu_subst_list; gnu_temp; gnu_temp = TREE_CHAIN (gnu_temp)) gnu_pos = substitute_in_expr (gnu_pos, TREE_PURPOSE (gnu_temp), TREE_VALUE (gnu_temp)); /* If the size is now a constant, we can set it as the size of the field when we make it. Otherwise, we need to deal with it specially. */ if (TREE_CONSTANT (gnu_pos)) gnu_new_pos = bit_from_pos (gnu_pos, gnu_bitpos); gnu_field = create_field_decl (DECL_NAME (gnu_old_field), gnu_field_type, gnu_type, 0, gnu_size, gnu_new_pos, !DECL_NONADDRESSABLE_P (gnu_old_field)); if (!TREE_CONSTANT (gnu_pos)) { normalize_offset (&gnu_pos, &gnu_bitpos, offset_align); DECL_FIELD_OFFSET (gnu_field) = gnu_pos; DECL_FIELD_BIT_OFFSET (gnu_field) = gnu_bitpos; SET_DECL_OFFSET_ALIGN (gnu_field, offset_align); DECL_SIZE (gnu_field) = gnu_size; DECL_SIZE_UNIT (gnu_field) = convert (sizetype, size_binop (CEIL_DIV_EXPR, gnu_size, bitsize_unit_node)); layout_decl (gnu_field, DECL_OFFSET_ALIGN (gnu_field)); } DECL_INTERNAL_P (gnu_field) = DECL_INTERNAL_P (gnu_old_field); SET_DECL_ORIGINAL_FIELD (gnu_field, (DECL_ORIGINAL_FIELD (gnu_old_field) ? DECL_ORIGINAL_FIELD (gnu_old_field) : gnu_old_field)); DECL_DISCRIMINANT_NUMBER (gnu_field) = DECL_DISCRIMINANT_NUMBER (gnu_old_field); TREE_THIS_VOLATILE (gnu_field) = TREE_THIS_VOLATILE (gnu_old_field); TREE_CHAIN (gnu_field) = gnu_field_list; gnu_field_list = gnu_field; save_gnu_tree (gnat_field, gnu_field, false); } /* Now go through the entities again looking for Itypes that we have not elaborated but should (e.g., Etypes of fields that have Original_Components). */ for (gnat_field = First_Entity (gnat_entity); Present (gnat_field); gnat_field = Next_Entity (gnat_field)) if ((Ekind (gnat_field) == E_Discriminant || Ekind (gnat_field) == E_Component) && !present_gnu_tree (Etype (gnat_field))) gnat_to_gnu_entity (Etype (gnat_field), NULL_TREE, 0); /* Do not finalize it since we're going to modify it below. */ finish_record_type (gnu_type, nreverse (gnu_field_list), 2, true); /* Now set the size, alignment and alias set of the new type to match that of the old one, doing any substitutions, as above. */ TYPE_ALIGN (gnu_type) = TYPE_ALIGN (gnu_base_type); TYPE_SIZE (gnu_type) = TYPE_SIZE (gnu_base_type); TYPE_SIZE_UNIT (gnu_type) = TYPE_SIZE_UNIT (gnu_base_type); SET_TYPE_ADA_SIZE (gnu_type, TYPE_ADA_SIZE (gnu_base_type)); copy_alias_set (gnu_type, gnu_base_type); if (CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type))) for (gnu_temp = gnu_subst_list; gnu_temp; gnu_temp = TREE_CHAIN (gnu_temp)) TYPE_SIZE (gnu_type) = substitute_in_expr (TYPE_SIZE (gnu_type), TREE_PURPOSE (gnu_temp), TREE_VALUE (gnu_temp)); if (CONTAINS_PLACEHOLDER_P (TYPE_SIZE_UNIT (gnu_type))) for (gnu_temp = gnu_subst_list; gnu_temp; gnu_temp = TREE_CHAIN (gnu_temp)) TYPE_SIZE_UNIT (gnu_type) = substitute_in_expr (TYPE_SIZE_UNIT (gnu_type), TREE_PURPOSE (gnu_temp), TREE_VALUE (gnu_temp)); if (CONTAINS_PLACEHOLDER_P (TYPE_ADA_SIZE (gnu_type))) for (gnu_temp = gnu_subst_list; gnu_temp; gnu_temp = TREE_CHAIN (gnu_temp)) SET_TYPE_ADA_SIZE (gnu_type, substitute_in_expr (TYPE_ADA_SIZE (gnu_type), TREE_PURPOSE (gnu_temp), TREE_VALUE (gnu_temp))); /* Reapply variable_size since we have changed the sizes. */ TYPE_SIZE (gnu_type) = variable_size (TYPE_SIZE (gnu_type)); TYPE_SIZE_UNIT (gnu_type) = variable_size (TYPE_SIZE_UNIT (gnu_type)); /* Recompute the mode of this record type now that we know its actual size. */ compute_record_mode (gnu_type); /* Fill in locations of fields. */ annotate_rep (gnat_entity, gnu_type); /* We've built a new type, make an XVS type to show what this is a subtype of. Some debuggers require the XVS type to be output first, so do it in that order. */ if (debug_info_p) { tree gnu_subtype_marker = make_node (RECORD_TYPE); tree gnu_orig_name = TYPE_NAME (gnu_orig_type); if (TREE_CODE (gnu_orig_name) == TYPE_DECL) gnu_orig_name = DECL_NAME (gnu_orig_name); TYPE_NAME (gnu_subtype_marker) = create_concat_name (gnat_entity, "XVS"); finish_record_type (gnu_subtype_marker, create_field_decl (gnu_orig_name, integer_type_node, gnu_subtype_marker, 0, NULL_TREE, NULL_TREE, 0), 0, false); } /* Now we can finalize it. */ rest_of_record_type_compilation (gnu_type); } /* Otherwise, go down all the components in the new type and make them equivalent to those in the base type. */ else for (gnat_temp = First_Entity (gnat_entity); Present (gnat_temp); gnat_temp = Next_Entity (gnat_temp)) if ((Ekind (gnat_temp) == E_Discriminant && !Is_Unchecked_Union (gnat_base_type)) || Ekind (gnat_temp) == E_Component) save_gnu_tree (gnat_temp, gnat_to_gnu_field_decl (Original_Record_Component (gnat_temp)), false); } break; case E_Access_Subprogram_Type: case E_Anonymous_Access_Subprogram_Type: /* If we are not defining this entity, and we have incomplete entities being processed above us, make a dummy type and fill it in later. */ if (!definition && defer_incomplete_level != 0) { struct incomplete *p = (struct incomplete *) xmalloc (sizeof (struct incomplete)); gnu_type = build_pointer_type (make_dummy_type (Directly_Designated_Type (gnat_entity))); gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); this_made_decl = true; gnu_type = TREE_TYPE (gnu_decl); save_gnu_tree (gnat_entity, gnu_decl, false); saved = true; p->old_type = TREE_TYPE (gnu_type); p->full_type = Directly_Designated_Type (gnat_entity); p->next = defer_incomplete_list; defer_incomplete_list = p; break; } /* ... fall through ... */ case E_Allocator_Type: case E_Access_Type: case E_Access_Attribute_Type: case E_Anonymous_Access_Type: case E_General_Access_Type: { Entity_Id gnat_desig_type = Directly_Designated_Type (gnat_entity); Entity_Id gnat_desig_equiv = Gigi_Equivalent_Type (gnat_desig_type); bool is_from_limited_with = (IN (Ekind (gnat_desig_equiv), Incomplete_Kind) && From_With_Type (gnat_desig_equiv)); /* Get the "full view" of this entity. If this is an incomplete entity from a limited with, treat its non-limited view as the full view. Otherwise, if this is an incomplete or private type, use the full view. In the former case, we might point to a private type, in which case, we need its full view. Also, we want to look at the actual type used for the representation, so this takes a total of three steps. */ Entity_Id gnat_desig_full_direct_first = (is_from_limited_with ? Non_Limited_View (gnat_desig_equiv) : (IN (Ekind (gnat_desig_equiv), Incomplete_Or_Private_Kind) ? Full_View (gnat_desig_equiv) : Empty)); Entity_Id gnat_desig_full_direct = ((Present (gnat_desig_full_direct_first) && IN (Ekind (gnat_desig_full_direct_first), Private_Kind)) ? Full_View (gnat_desig_full_direct_first) : gnat_desig_full_direct_first); Entity_Id gnat_desig_full = Gigi_Equivalent_Type (gnat_desig_full_direct); /* This the type actually used to represent the designated type, either gnat_desig_full or gnat_desig_equiv. */ Entity_Id gnat_desig_rep; /* Nonzero if this is a pointer to an unconstrained array. */ bool is_unconstrained_array; /* We want to know if we'll be seeing the freeze node for any incomplete type we may be pointing to. */ bool in_main_unit = (Present (gnat_desig_full) ? In_Extended_Main_Code_Unit (gnat_desig_full) : In_Extended_Main_Code_Unit (gnat_desig_type)); /* Nonzero if we make a dummy type here. */ bool got_fat_p = false; /* Nonzero if the dummy is a fat pointer. */ bool made_dummy = false; tree gnu_desig_type = NULL_TREE; enum machine_mode p_mode = mode_for_size (esize, MODE_INT, 0); if (!targetm.valid_pointer_mode (p_mode)) p_mode = ptr_mode; /* If either the designated type or its full view is an unconstrained array subtype, replace it with the type it's a subtype of. This avoids problems with multiple copies of unconstrained array types. Likewise, if the designated type is a subtype of an incomplete record type, use the parent type to avoid order of elaboration issues. This can lose some code efficiency, but there is no alternative. */ if (Ekind (gnat_desig_equiv) == E_Array_Subtype && ! Is_Constrained (gnat_desig_equiv)) gnat_desig_equiv = Etype (gnat_desig_equiv); if (Present (gnat_desig_full) && ((Ekind (gnat_desig_full) == E_Array_Subtype && ! Is_Constrained (gnat_desig_full)) || (Ekind (gnat_desig_full) == E_Record_Subtype && Ekind (Etype (gnat_desig_full)) == E_Record_Type))) gnat_desig_full = Etype (gnat_desig_full); /* Now set the type that actually marks the representation of the designated type and also flag whether we have a unconstrained array. */ gnat_desig_rep = gnat_desig_full ? gnat_desig_full : gnat_desig_equiv; is_unconstrained_array = (Is_Array_Type (gnat_desig_rep) && ! Is_Constrained (gnat_desig_rep)); /* If we are pointing to an incomplete type whose completion is an unconstrained array, make a fat pointer type. The two types in our fields will be pointers to dummy nodes and will be replaced in update_pointer_to. Similarly, if the type itself is a dummy type or an unconstrained array. Also make a dummy TYPE_OBJECT_RECORD_TYPE in case we have any thin pointers to it. */ if (is_unconstrained_array && (Present (gnat_desig_full) || (present_gnu_tree (gnat_desig_equiv) && TYPE_IS_DUMMY_P (TREE_TYPE (get_gnu_tree (gnat_desig_equiv)))) || (No (gnat_desig_full) && ! in_main_unit && defer_incomplete_level != 0 && ! present_gnu_tree (gnat_desig_equiv)) || (in_main_unit && is_from_limited_with && Present (Freeze_Node (gnat_desig_rep))))) { tree gnu_old = (present_gnu_tree (gnat_desig_rep) ? TREE_TYPE (get_gnu_tree (gnat_desig_rep)) : make_dummy_type (gnat_desig_rep)); tree fields; /* Show the dummy we get will be a fat pointer. */ got_fat_p = made_dummy = true; /* If the call above got something that has a pointer, that pointer is our type. This could have happened either because the type was elaborated or because somebody else executed the code below. */ gnu_type = TYPE_POINTER_TO (gnu_old); if (!gnu_type) { tree gnu_template_type = make_node (ENUMERAL_TYPE); tree gnu_ptr_template = build_pointer_type (gnu_template_type); tree gnu_array_type = make_node (ENUMERAL_TYPE); tree gnu_ptr_array = build_pointer_type (gnu_array_type); TYPE_NAME (gnu_template_type) = concat_id_with_name (get_entity_name (gnat_desig_equiv), "XUB"); TYPE_DUMMY_P (gnu_template_type) = 1; TYPE_NAME (gnu_array_type) = concat_id_with_name (get_entity_name (gnat_desig_equiv), "XUA"); TYPE_DUMMY_P (gnu_array_type) = 1; gnu_type = make_node (RECORD_TYPE); SET_TYPE_UNCONSTRAINED_ARRAY (gnu_type, gnu_old); TYPE_POINTER_TO (gnu_old) = gnu_type; Sloc_to_locus (Sloc (gnat_entity), &input_location); fields = chainon (chainon (NULL_TREE, create_field_decl (get_identifier ("P_ARRAY"), gnu_ptr_array, gnu_type, 0, 0, 0, 0)), create_field_decl (get_identifier ("P_BOUNDS"), gnu_ptr_template, gnu_type, 0, 0, 0, 0)); /* Make sure we can place this into a register. */ TYPE_ALIGN (gnu_type) = MIN (BIGGEST_ALIGNMENT, 2 * POINTER_SIZE); TYPE_IS_FAT_POINTER_P (gnu_type) = 1; /* Do not finalize this record type since the types of its fields are incomplete. */ finish_record_type (gnu_type, fields, 0, true); TYPE_OBJECT_RECORD_TYPE (gnu_old) = make_node (RECORD_TYPE); TYPE_NAME (TYPE_OBJECT_RECORD_TYPE (gnu_old)) = concat_id_with_name (get_entity_name (gnat_desig_equiv), "XUT"); TYPE_DUMMY_P (TYPE_OBJECT_RECORD_TYPE (gnu_old)) = 1; } } /* If we already know what the full type is, use it. */ else if (Present (gnat_desig_full) && present_gnu_tree (gnat_desig_full)) gnu_desig_type = TREE_TYPE (get_gnu_tree (gnat_desig_full)); /* Get the type of the thing we are to point to and build a pointer to it. If it is a reference to an incomplete or private type with a full view that is a record, make a dummy type node and get the actual type later when we have verified it is safe. */ else if ((! in_main_unit && ! present_gnu_tree (gnat_desig_equiv) && Present (gnat_desig_full) && ! present_gnu_tree (gnat_desig_full) && Is_Record_Type (gnat_desig_full)) /* Likewise if we are pointing to a record or array and we are to defer elaborating incomplete types. We do this since this access type may be the full view of some private type. Note that the unconstrained array case is handled above. */ || ((! in_main_unit || imported_p) && defer_incomplete_level != 0 && ! present_gnu_tree (gnat_desig_equiv) && ((Is_Record_Type (gnat_desig_rep) || Is_Array_Type (gnat_desig_rep)))) /* If this is a reference from a limited_with type back to our main unit and there's a Freeze_Node for it, either we have already processed the declaration and made the dummy type, in which case we just reuse the latter, or we have not yet, in which case we make the dummy type and it will be reused when the declaration is processed. In both cases, the pointer eventually created below will be automatically adjusted when the Freeze_Node is processed. Note that the unconstrained array case is handled above. */ || (in_main_unit && is_from_limited_with && Present (Freeze_Node (gnat_desig_rep)))) { gnu_desig_type = make_dummy_type (gnat_desig_equiv); made_dummy = true; } /* Otherwise handle the case of a pointer to itself. */ else if (gnat_desig_equiv == gnat_entity) { gnu_type = build_pointer_type_for_mode (void_type_node, p_mode, No_Strict_Aliasing (gnat_entity)); TREE_TYPE (gnu_type) = TYPE_POINTER_TO (gnu_type) = gnu_type; } /* If expansion is disabled, the equivalent type of a concurrent type is absent, so build a dummy pointer type. */ else if (type_annotate_only && No (gnat_desig_equiv)) gnu_type = ptr_void_type_node; /* Finally, handle the straightforward case where we can just elaborate our designated type and point to it. */ else gnu_desig_type = gnat_to_gnu_type (gnat_desig_equiv); /* It is possible that a call to gnat_to_gnu_type above resolved our type. If so, just return it. */ if (present_gnu_tree (gnat_entity)) { maybe_present = true; break; } /* If we have a GCC type for the designated type, possibly modify it if we are pointing only to constant objects and then make a pointer to it. Don't do this for unconstrained arrays. */ if (!gnu_type && gnu_desig_type) { if (Is_Access_Constant (gnat_entity) && TREE_CODE (gnu_desig_type) != UNCONSTRAINED_ARRAY_TYPE) { gnu_desig_type = build_qualified_type (gnu_desig_type, TYPE_QUALS (gnu_desig_type) | TYPE_QUAL_CONST); /* Some extra processing is required if we are building a pointer to an incomplete type (in the GCC sense). We might have such a type if we just made a dummy, or directly out of the call to gnat_to_gnu_type above if we are processing an access type for a record component designating the record type itself. */ if (TYPE_MODE (gnu_desig_type) == VOIDmode) { /* We must ensure that the pointer to variant we make will be processed by update_pointer_to when the initial type is completed. Pretend we made a dummy and let further processing act as usual. */ made_dummy = true; /* We must ensure that update_pointer_to will not retrieve the dummy variant when building a properly qualified version of the complete type. We take advantage of the fact that get_qualified_type is requiring TYPE_NAMEs to match to influence build_qualified_type and then also update_pointer_to here. */ TYPE_NAME (gnu_desig_type) = create_concat_name (gnat_desig_type, "INCOMPLETE_CST"); } } gnu_type = build_pointer_type_for_mode (gnu_desig_type, p_mode, No_Strict_Aliasing (gnat_entity)); } /* If we are not defining this object and we made a dummy pointer, save our current definition, evaluate the actual type, and replace the tentative type we made with the actual one. If we are to defer actually looking up the actual type, make an entry in the deferred list. If this is from a limited with, we have to defer to the end of the current spec in two cases: first if the designated type is in the current unit and second if the access type is. */ if ((! in_main_unit || is_from_limited_with) && made_dummy) { tree gnu_old_type = TYPE_FAT_POINTER_P (gnu_type) ? TYPE_UNCONSTRAINED_ARRAY (gnu_type) : TREE_TYPE (gnu_type); if (esize == POINTER_SIZE && (got_fat_p || TYPE_FAT_POINTER_P (gnu_type))) gnu_type = build_pointer_type (TYPE_OBJECT_RECORD_TYPE (TYPE_UNCONSTRAINED_ARRAY (gnu_type))); gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); this_made_decl = true; gnu_type = TREE_TYPE (gnu_decl); save_gnu_tree (gnat_entity, gnu_decl, false); saved = true; if (defer_incomplete_level == 0 && ! (is_from_limited_with && (in_main_unit || In_Extended_Main_Code_Unit (gnat_entity)))) update_pointer_to (TYPE_MAIN_VARIANT (gnu_old_type), gnat_to_gnu_type (gnat_desig_equiv)); /* Note that the call to gnat_to_gnu_type here might have updated gnu_old_type directly, in which case it is not a dummy type any more when we get into update_pointer_to. This may happen for instance when the designated type is a record type, because their elaboration starts with an initial node from make_dummy_type, which may yield the same node as the one we got. Besides, variants of this non-dummy type might have been created along the way. update_pointer_to is expected to properly take care of those situations. */ else { struct incomplete *p = (struct incomplete *) xmalloc (sizeof (struct incomplete)); struct incomplete **head = (is_from_limited_with && (in_main_unit || In_Extended_Main_Code_Unit (gnat_entity)) ? &defer_limited_with : &defer_incomplete_list); p->old_type = gnu_old_type; p->full_type = gnat_desig_equiv; p->next = *head; *head = p; } } } break; case E_Access_Protected_Subprogram_Type: case E_Anonymous_Access_Protected_Subprogram_Type: if (type_annotate_only && No (gnat_equiv_type)) gnu_type = ptr_void_type_node; else { /* The runtime representation is the equivalent type. */ gnu_type = gnat_to_gnu_type (gnat_equiv_type); maybe_present = 1; } if (Is_Itype (Directly_Designated_Type (gnat_entity)) && !present_gnu_tree (Directly_Designated_Type (gnat_entity)) && No (Freeze_Node (Directly_Designated_Type (gnat_entity))) && !Is_Record_Type (Scope (Directly_Designated_Type (gnat_entity)))) gnat_to_gnu_entity (Directly_Designated_Type (gnat_entity), NULL_TREE, 0); break; case E_Access_Subtype: /* We treat this as identical to its base type; any constraint is meaningful only to the front end. The designated type must be elaborated as well, if it does not have its own freeze node. Designated (sub)types created for constrained components of records with discriminants are not frozen by the front end and thus not elaborated by gigi, because their use may appear before the base type is frozen, and because it is not clear that they are needed anywhere in Gigi. With the current model, there is no correct place where they could be elaborated. */ gnu_type = gnat_to_gnu_type (Etype (gnat_entity)); if (Is_Itype (Directly_Designated_Type (gnat_entity)) && !present_gnu_tree (Directly_Designated_Type (gnat_entity)) && Is_Frozen (Directly_Designated_Type (gnat_entity)) && No (Freeze_Node (Directly_Designated_Type (gnat_entity)))) { /* If we are not defining this entity, and we have incomplete entities being processed above us, make a dummy type and elaborate it later. */ if (!definition && defer_incomplete_level != 0) { struct incomplete *p = (struct incomplete *) xmalloc (sizeof (struct incomplete)); tree gnu_ptr_type = build_pointer_type (make_dummy_type (Directly_Designated_Type (gnat_entity))); p->old_type = TREE_TYPE (gnu_ptr_type); p->full_type = Directly_Designated_Type (gnat_entity); p->next = defer_incomplete_list; defer_incomplete_list = p; } else if (!IN (Ekind (Base_Type (Directly_Designated_Type (gnat_entity))), Incomplete_Or_Private_Kind)) gnat_to_gnu_entity (Directly_Designated_Type (gnat_entity), NULL_TREE, 0); } maybe_present = true; break; /* Subprogram Entities The following access functions are defined for subprograms (functions or procedures): First_Formal The first formal parameter. Is_Imported Indicates that the subprogram has appeared in an INTERFACE or IMPORT pragma. For now we assume that the external language is C. Is_Exported Likewise but for an EXPORT pragma. Is_Inlined True if the subprogram is to be inlined. In addition for function subprograms we have: Etype Return type of the function. Each parameter is first checked by calling must_pass_by_ref on its type to determine if it is passed by reference. For parameters which are copied in, if they are Ada IN OUT or OUT parameters, their return value becomes part of a record which becomes the return type of the function (C function - note that this applies only to Ada procedures so there is no Ada return type). Additional code to store back the parameters will be generated on the caller side. This transformation is done here, not in the front-end. The intended result of the transformation can be seen from the equivalent source rewritings that follow: struct temp {int a,b}; procedure P (A,B: IN OUT ...) is temp P (int A,B) begin { .. .. end P; return {A,B}; } temp t; P(X,Y); t = P(X,Y); X = t.a , Y = t.b; For subprogram types we need to perform mainly the same conversions to GCC form that are needed for procedures and function declarations. The only difference is that at the end, we make a type declaration instead of a function declaration. */ case E_Subprogram_Type: case E_Function: case E_Procedure: { /* The first GCC parameter declaration (a PARM_DECL node). The PARM_DECL nodes are chained through the TREE_CHAIN field, so this actually is the head of this parameter list. */ tree gnu_param_list = NULL_TREE; /* Likewise for the stub associated with an exported procedure. */ tree gnu_stub_param_list = NULL_TREE; /* The type returned by a function. If the subprogram is a procedure this type should be void_type_node. */ tree gnu_return_type = void_type_node; /* List of fields in return type of procedure with copy-in copy-out parameters. */ tree gnu_field_list = NULL_TREE; /* Non-null for subprograms containing parameters passed by copy-in copy-out (Ada IN OUT or OUT parameters not passed by reference), in which case it is the list of nodes used to specify the values of the in out/out parameters that are returned as a record upon procedure return. The TREE_PURPOSE of an element of this list is a field of the record and the TREE_VALUE is the PARM_DECL corresponding to that field. This list will be saved in the TYPE_CI_CO_LIST field of the FUNCTION_TYPE node we create. */ tree gnu_return_list = NULL_TREE; /* If an import pragma asks to map this subprogram to a GCC builtin, this is the builtin DECL node. */ tree gnu_builtin_decl = NULL_TREE; /* For the stub associated with an exported procedure. */ tree gnu_stub_type = NULL_TREE, gnu_stub_name = NULL_TREE; tree gnu_ext_name = create_concat_name (gnat_entity, NULL); Entity_Id gnat_param; bool inline_flag = Is_Inlined (gnat_entity); bool public_flag = Is_Public (gnat_entity); bool extern_flag = (Is_Public (gnat_entity) && !definition) || imported_p; bool pure_flag = Is_Pure (gnat_entity); bool volatile_flag = No_Return (gnat_entity); bool returns_by_ref = false; bool returns_unconstrained = false; bool returns_by_target_ptr = false; bool has_copy_in_out = false; bool has_stub = false; int parmnum; if (kind == E_Subprogram_Type && !definition) /* A parameter may refer to this type, so defer completion of any incomplete types. */ defer_incomplete_level++, this_deferred = true; /* If the subprogram has an alias, it is probably inherited, so we can use the original one. If the original "subprogram" is actually an enumeration literal, it may be the first use of its type, so we must elaborate that type now. */ if (Present (Alias (gnat_entity))) { if (Ekind (Alias (gnat_entity)) == E_Enumeration_Literal) gnat_to_gnu_entity (Etype (Alias (gnat_entity)), NULL_TREE, 0); gnu_decl = gnat_to_gnu_entity (Alias (gnat_entity), gnu_expr, 0); /* Elaborate any Itypes in the parameters of this entity. */ for (gnat_temp = First_Formal_With_Extras (gnat_entity); Present (gnat_temp); gnat_temp = Next_Formal_With_Extras (gnat_temp)) if (Is_Itype (Etype (gnat_temp))) gnat_to_gnu_entity (Etype (gnat_temp), NULL_TREE, 0); break; } /* If this subprogram is expectedly bound to a GCC builtin, fetch the corresponding DECL node. We still want the parameter associations to take place because the proper generation of calls depends on it (a GNAT parameter without a corresponding GCC tree has a very specific meaning), so we don't just break here. */ if (Convention (gnat_entity) == Convention_Intrinsic) gnu_builtin_decl = builtin_decl_for (gnu_ext_name); /* ??? What if we don't find the builtin node above ? warn ? err ? In the current state we neither warn nor err, and calls will just be handled as for regular subprograms. */ if (kind == E_Function || kind == E_Subprogram_Type) gnu_return_type = gnat_to_gnu_type (Etype (gnat_entity)); /* If this function returns by reference, make the actual return type of this function the pointer and mark the decl. */ if (Returns_By_Ref (gnat_entity)) { returns_by_ref = true; gnu_return_type = build_pointer_type (gnu_return_type); } /* If the Mechanism is By_Reference, ensure the return type uses the machine's by-reference mechanism, which may not the same as above (e.g., it might be by passing a fake parameter). */ else if (kind == E_Function && Mechanism (gnat_entity) == By_Reference) { TREE_ADDRESSABLE (gnu_return_type) = 1; /* We expect this bit to be reset by gigi shortly, so can avoid a type node copy here. This actually also prevents troubles with the generation of debug information for the function, because we might have issued such info for this type already, and would be attaching a distinct type node to the function if we made a copy here. */ } /* If we are supposed to return an unconstrained array, actually return a fat pointer and make a note of that. Return a pointer to an unconstrained record of variable size. */ else if (TREE_CODE (gnu_return_type) == UNCONSTRAINED_ARRAY_TYPE) { gnu_return_type = TREE_TYPE (gnu_return_type); returns_unconstrained = true; } /* If the type requires a transient scope, the result is allocated on the secondary stack, so the result type of the function is just a pointer. */ else if (Requires_Transient_Scope (Etype (gnat_entity))) { gnu_return_type = build_pointer_type (gnu_return_type); returns_unconstrained = true; } /* If the type is a padded type and the underlying type would not be passed by reference or this function has a foreign convention, return the underlying type. */ else if (TREE_CODE (gnu_return_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_return_type) && (!default_pass_by_ref (TREE_TYPE (TYPE_FIELDS (gnu_return_type))) || Has_Foreign_Convention (gnat_entity))) gnu_return_type = TREE_TYPE (TYPE_FIELDS (gnu_return_type)); /* If the return type is unconstrained, that means it must have a maximum size. We convert the function into a procedure and its caller will pass a pointer to an object of that maximum size as the first parameter when we call the function. */ if (CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_return_type))) { returns_by_target_ptr = true; gnu_param_list = create_param_decl (get_identifier ("TARGET"), build_reference_type (gnu_return_type), true); gnu_return_type = void_type_node; } /* If the return type has a size that overflows, we cannot have a function that returns that type. This usage doesn't make sense anyway, so give an error here. */ if (TYPE_SIZE_UNIT (gnu_return_type) && TREE_CONSTANT (TYPE_SIZE_UNIT (gnu_return_type)) && TREE_OVERFLOW (TYPE_SIZE_UNIT (gnu_return_type))) { post_error ("cannot return type whose size overflows", gnat_entity); gnu_return_type = copy_node (gnu_return_type); TYPE_SIZE (gnu_return_type) = bitsize_zero_node; TYPE_SIZE_UNIT (gnu_return_type) = size_zero_node; TYPE_MAIN_VARIANT (gnu_return_type) = gnu_return_type; TYPE_NEXT_VARIANT (gnu_return_type) = NULL_TREE; } /* Look at all our parameters and get the type of each. While doing this, build a copy-out structure if we need one. */ /* Loop over the parameters and get their associated GCC tree. While doing this, build a copy-out structure if we need one. */ for (gnat_param = First_Formal_With_Extras (gnat_entity), parmnum = 0; Present (gnat_param); gnat_param = Next_Formal_With_Extras (gnat_param), parmnum++) { tree gnu_param_name = get_entity_name (gnat_param); tree gnu_param_type = gnat_to_gnu_type (Etype (gnat_param)); tree gnu_param, gnu_field; bool copy_in_copy_out = false; Mechanism_Type mech = Mechanism (gnat_param); /* Builtins are expanded inline and there is no real call sequence involved. So the type expected by the underlying expander is always the type of each argument "as is". */ if (gnu_builtin_decl) mech = By_Copy; /* Handle the first parameter of a valued procedure specially. */ else if (Is_Valued_Procedure (gnat_entity) && parmnum == 0) mech = By_Copy_Return; /* Otherwise, see if a Mechanism was supplied that forced this parameter to be passed one way or another. */ else if (mech == Default || mech == By_Copy || mech == By_Reference) ; else if (By_Descriptor_Last <= mech && mech <= By_Descriptor) mech = By_Descriptor; else if (mech > 0) { if (TREE_CODE (gnu_param_type) == UNCONSTRAINED_ARRAY_TYPE || TREE_CODE (TYPE_SIZE (gnu_param_type)) != INTEGER_CST || 0 < compare_tree_int (TYPE_SIZE (gnu_param_type), mech)) mech = By_Reference; else mech = By_Copy; } else { post_error ("unsupported mechanism for&", gnat_param); mech = Default; } gnu_param = gnat_to_gnu_param (gnat_param, mech, gnat_entity, Has_Foreign_Convention (gnat_entity), ©_in_copy_out); /* We are returned either a PARM_DECL or a type if no parameter needs to be passed; in either case, adjust the type. */ if (DECL_P (gnu_param)) gnu_param_type = TREE_TYPE (gnu_param); else { gnu_param_type = gnu_param; gnu_param = NULL_TREE; } if (gnu_param) { /* If it's an exported subprogram, we build a parameter list in parallel, in case we need to emit a stub for it. */ if (Is_Exported (gnat_entity)) { gnu_stub_param_list = chainon (gnu_param, gnu_stub_param_list); /* Change By_Descriptor parameter to By_Reference for the internal version of an exported subprogram. */ if (mech == By_Descriptor) { gnu_param = gnat_to_gnu_param (gnat_param, By_Reference, gnat_entity, false, ©_in_copy_out); has_stub = true; } else gnu_param = copy_node (gnu_param); } gnu_param_list = chainon (gnu_param, gnu_param_list); Sloc_to_locus (Sloc (gnat_param), &DECL_SOURCE_LOCATION (gnu_param)); save_gnu_tree (gnat_param, gnu_param, false); /* If a parameter is a pointer, this function may modify memory through it and thus shouldn't be considered a pure function. Also, the memory may be modified between two calls, so they can't be CSE'ed. The latter case also handles by-ref parameters. */ if (POINTER_TYPE_P (gnu_param_type) || TYPE_FAT_POINTER_P (gnu_param_type)) pure_flag = false; } if (copy_in_copy_out) { if (!has_copy_in_out) { gcc_assert (TREE_CODE (gnu_return_type) == VOID_TYPE); gnu_return_type = make_node (RECORD_TYPE); TYPE_NAME (gnu_return_type) = get_identifier ("RETURN"); has_copy_in_out = true; } gnu_field = create_field_decl (gnu_param_name, gnu_param_type, gnu_return_type, 0, 0, 0, 0); Sloc_to_locus (Sloc (gnat_param), &DECL_SOURCE_LOCATION (gnu_field)); TREE_CHAIN (gnu_field) = gnu_field_list; gnu_field_list = gnu_field; gnu_return_list = tree_cons (gnu_field, gnu_param, gnu_return_list); } } /* Do not compute record for out parameters if subprogram is stubbed since structures are incomplete for the back-end. */ if (gnu_field_list && Convention (gnat_entity) != Convention_Stubbed) finish_record_type (gnu_return_type, nreverse (gnu_field_list), 0, false); /* If we have a CICO list but it has only one entry, we convert this function into a function that simply returns that one object. */ if (list_length (gnu_return_list) == 1) gnu_return_type = TREE_TYPE (TREE_PURPOSE (gnu_return_list)); if (Has_Stdcall_Convention (gnat_entity)) prepend_one_attribute_to (&attr_list, ATTR_MACHINE_ATTRIBUTE, get_identifier ("stdcall"), NULL_TREE, gnat_entity); /* The lists have been built in reverse. */ gnu_param_list = nreverse (gnu_param_list); if (has_stub) gnu_stub_param_list = nreverse (gnu_stub_param_list); gnu_return_list = nreverse (gnu_return_list); if (Ekind (gnat_entity) == E_Function) Set_Mechanism (gnat_entity, (returns_by_ref || returns_unconstrained ? By_Reference : By_Copy)); gnu_type = create_subprog_type (gnu_return_type, gnu_param_list, gnu_return_list, returns_unconstrained, returns_by_ref, Function_Returns_With_DSP (gnat_entity), returns_by_target_ptr); if (has_stub) gnu_stub_type = create_subprog_type (gnu_return_type, gnu_stub_param_list, gnu_return_list, returns_unconstrained, returns_by_ref, Function_Returns_With_DSP (gnat_entity), returns_by_target_ptr); /* A subprogram (something that doesn't return anything) shouldn't be considered Pure since there would be no reason for such a subprogram. Note that procedures with Out (or In Out) parameters have already been converted into a function with a return type. */ if (TREE_CODE (gnu_return_type) == VOID_TYPE) pure_flag = false; /* The semantics of "pure" in Ada essentially matches that of "const" in the back-end. In particular, both properties are orthogonal to the "nothrow" property. But this is true only if the EH circuitry is explicit in the internal representation of the back-end. If we are to completely hide the EH circuitry from it, we need to declare that calls to pure Ada subprograms that can throw have side effects since they can trigger an "abnormal" transfer of control flow; thus they can be neither "const" nor "pure" in the back-end sense. */ gnu_type = build_qualified_type (gnu_type, TYPE_QUALS (gnu_type) | (Exception_Mechanism == Back_End_Exceptions ? TYPE_QUAL_CONST * pure_flag : 0) | (TYPE_QUAL_VOLATILE * volatile_flag)); Sloc_to_locus (Sloc (gnat_entity), &input_location); if (has_stub) gnu_stub_type = build_qualified_type (gnu_stub_type, TYPE_QUALS (gnu_stub_type) | (Exception_Mechanism == Back_End_Exceptions ? TYPE_QUAL_CONST * pure_flag : 0) | (TYPE_QUAL_VOLATILE * volatile_flag)); /* If we have a builtin decl for that function, check the signatures compatibilities. If the signatures are compatible, use the builtin decl. If they are not, we expect the checker predicate to have posted the appropriate errors, and just continue with what we have so far. */ if (gnu_builtin_decl) { tree gnu_builtin_type = TREE_TYPE (gnu_builtin_decl); if (compatible_signatures_p (gnu_type, gnu_builtin_type)) { gnu_decl = gnu_builtin_decl; gnu_type = gnu_builtin_type; break; } } /* If there was no specified Interface_Name and the external and internal names of the subprogram are the same, only use the internal name to allow disambiguation of nested subprograms. */ if (No (Interface_Name (gnat_entity)) && gnu_ext_name == gnu_entity_id) gnu_ext_name = NULL_TREE; /* If we are defining the subprogram and it has an Address clause we must get the address expression from the saved GCC tree for the subprogram if it has a Freeze_Node. Otherwise, we elaborate the address expression here since the front-end has guaranteed in that case that the elaboration has no effects. If there is an Address clause and we are not defining the object, just make it a constant. */ if (Present (Address_Clause (gnat_entity))) { tree gnu_address = NULL_TREE; if (definition) gnu_address = (present_gnu_tree (gnat_entity) ? get_gnu_tree (gnat_entity) : gnat_to_gnu (Expression (Address_Clause (gnat_entity)))); save_gnu_tree (gnat_entity, NULL_TREE, false); /* Convert the type of the object to a reference type that can alias everything as per 13.3(19). */ gnu_type = build_reference_type_for_mode (gnu_type, ptr_mode, true); if (gnu_address) gnu_address = convert (gnu_type, gnu_address); gnu_decl = create_var_decl (gnu_entity_id, gnu_ext_name, gnu_type, gnu_address, false, Is_Public (gnat_entity), extern_flag, false, NULL, gnat_entity); DECL_BY_REF_P (gnu_decl) = 1; } else if (kind == E_Subprogram_Type) gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); else { if (has_stub) { gnu_stub_name = gnu_ext_name; gnu_ext_name = create_concat_name (gnat_entity, "internal"); public_flag = false; } gnu_decl = create_subprog_decl (gnu_entity_id, gnu_ext_name, gnu_type, gnu_param_list, inline_flag, public_flag, extern_flag, attr_list, gnat_entity); if (has_stub) { tree gnu_stub_decl = create_subprog_decl (gnu_entity_id, gnu_stub_name, gnu_stub_type, gnu_stub_param_list, inline_flag, true, extern_flag, attr_list, gnat_entity); SET_DECL_FUNCTION_STUB (gnu_decl, gnu_stub_decl); } /* This is unrelated to the stub built right above. */ DECL_STUBBED_P (gnu_decl) = Convention (gnat_entity) == Convention_Stubbed; } } break; case E_Incomplete_Type: case E_Incomplete_Subtype: case E_Private_Type: case E_Private_Subtype: case E_Limited_Private_Type: case E_Limited_Private_Subtype: case E_Record_Type_With_Private: case E_Record_Subtype_With_Private: { /* Get the "full view" of this entity. If this is an incomplete entity from a limited with, treat its non-limited view as the full view. Otherwise, use either the full view or the underlying full view, whichever is present. This is used in all the tests below. */ Entity_Id full_view = (IN (Ekind (gnat_entity), Incomplete_Kind) && From_With_Type (gnat_entity)) ? Non_Limited_View (gnat_entity) : Present (Full_View (gnat_entity)) ? Full_View (gnat_entity) : Underlying_Full_View (gnat_entity); /* If this is an incomplete type with no full view, it must be a Taft Amendment type, in which case we return a dummy type. Otherwise, just get the type from its Etype. */ if (No (full_view)) { if (kind == E_Incomplete_Type) gnu_type = make_dummy_type (gnat_entity); else { gnu_decl = gnat_to_gnu_entity (Etype (gnat_entity), NULL_TREE, 0); maybe_present = true; } break; } /* If we already made a type for the full view, reuse it. */ else if (present_gnu_tree (full_view)) { gnu_decl = get_gnu_tree (full_view); break; } /* Otherwise, if we are not defining the type now, get the type from the full view. But always get the type from the full view for define on use types, since otherwise we won't see them! */ else if (!definition || (Is_Itype (full_view) && No (Freeze_Node (gnat_entity))) || (Is_Itype (gnat_entity) && No (Freeze_Node (full_view)))) { gnu_decl = gnat_to_gnu_entity (full_view, NULL_TREE, 0); maybe_present = true; break; } /* For incomplete types, make a dummy type entry which will be replaced later. */ gnu_type = make_dummy_type (gnat_entity); /* Save this type as the full declaration's type so we can do any needed updates when we see it. */ gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); save_gnu_tree (full_view, gnu_decl, 0); break; } /* Simple class_wide types are always viewed as their root_type by Gigi unless an Equivalent_Type is specified. */ case E_Class_Wide_Type: gnu_decl = gnat_to_gnu_entity (gnat_equiv_type, NULL_TREE, 0); maybe_present = true; break; case E_Task_Type: case E_Task_Subtype: case E_Protected_Type: case E_Protected_Subtype: if (type_annotate_only && No (gnat_equiv_type)) gnu_type = void_type_node; else gnu_type = gnat_to_gnu_type (gnat_equiv_type); maybe_present = true; break; case E_Label: gnu_decl = create_label_decl (gnu_entity_id); break; case E_Block: case E_Loop: /* Nothing at all to do here, so just return an ERROR_MARK and claim we've already saved it, so we don't try to. */ gnu_decl = error_mark_node; saved = true; break; default: gcc_unreachable (); } /* If we had a case where we evaluated another type and it might have defined this one, handle it here. */ if (maybe_present && present_gnu_tree (gnat_entity)) { gnu_decl = get_gnu_tree (gnat_entity); saved = true; } /* If we are processing a type and there is either no decl for it or we just made one, do some common processing for the type, such as handling alignment and possible padding. */ if ((!gnu_decl || this_made_decl) && IN (kind, Type_Kind)) { if (Is_Tagged_Type (gnat_entity) || Is_Class_Wide_Equivalent_Type (gnat_entity)) TYPE_ALIGN_OK (gnu_type) = 1; if (AGGREGATE_TYPE_P (gnu_type) && Is_By_Reference_Type (gnat_entity)) TYPE_BY_REFERENCE_P (gnu_type) = 1; /* ??? Don't set the size for a String_Literal since it is either confirming or we don't handle it properly (if the low bound is non-constant). */ if (!gnu_size && kind != E_String_Literal_Subtype) gnu_size = validate_size (Esize (gnat_entity), gnu_type, gnat_entity, TYPE_DECL, false, Has_Size_Clause (gnat_entity)); /* If a size was specified, see if we can make a new type of that size by rearranging the type, for example from a fat to a thin pointer. */ if (gnu_size) { gnu_type = make_type_from_size (gnu_type, gnu_size, Has_Biased_Representation (gnat_entity)); if (operand_equal_p (TYPE_SIZE (gnu_type), gnu_size, 0) && operand_equal_p (rm_size (gnu_type), gnu_size, 0)) gnu_size = 0; } /* If the alignment hasn't already been processed and this is not an unconstrained array, see if an alignment is specified. If not, we pick a default alignment for atomic objects. */ if (align != 0 || TREE_CODE (gnu_type) == UNCONSTRAINED_ARRAY_TYPE) ; else if (Known_Alignment (gnat_entity)) align = validate_alignment (Alignment (gnat_entity), gnat_entity, TYPE_ALIGN (gnu_type)); else if (Is_Atomic (gnat_entity) && !gnu_size && host_integerp (TYPE_SIZE (gnu_type), 1) && integer_pow2p (TYPE_SIZE (gnu_type))) align = MIN (BIGGEST_ALIGNMENT, tree_low_cst (TYPE_SIZE (gnu_type), 1)); else if (Is_Atomic (gnat_entity) && gnu_size && host_integerp (gnu_size, 1) && integer_pow2p (gnu_size)) align = MIN (BIGGEST_ALIGNMENT, tree_low_cst (gnu_size, 1)); /* See if we need to pad the type. If we did, and made a record, the name of the new type may be changed. So get it back for us when we make the new TYPE_DECL below. */ gnu_type = maybe_pad_type (gnu_type, gnu_size, align, gnat_entity, "PAD", true, definition, false); if (TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_type)) { gnu_entity_id = TYPE_NAME (gnu_type); if (TREE_CODE (gnu_entity_id) == TYPE_DECL) gnu_entity_id = DECL_NAME (gnu_entity_id); } set_rm_size (RM_Size (gnat_entity), gnu_type, gnat_entity); /* If we are at global level, GCC will have applied variable_size to the type, but that won't have done anything. So, if it's not a constant or self-referential, call elaborate_expression_1 to make a variable for the size rather than calculating it each time. Handle both the RM size and the actual size. */ if (global_bindings_p () && TYPE_SIZE (gnu_type) && !TREE_CONSTANT (TYPE_SIZE (gnu_type)) && !CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_type))) { if (TREE_CODE (gnu_type) == RECORD_TYPE && operand_equal_p (TYPE_ADA_SIZE (gnu_type), TYPE_SIZE (gnu_type), 0)) { TYPE_SIZE (gnu_type) = elaborate_expression_1 (gnat_entity, gnat_entity, TYPE_SIZE (gnu_type), get_identifier ("SIZE"), definition, 0); SET_TYPE_ADA_SIZE (gnu_type, TYPE_SIZE (gnu_type)); } else { TYPE_SIZE (gnu_type) = elaborate_expression_1 (gnat_entity, gnat_entity, TYPE_SIZE (gnu_type), get_identifier ("SIZE"), definition, 0); /* ??? For now, store the size as a multiple of the alignment in bytes so that we can see the alignment from the tree. */ TYPE_SIZE_UNIT (gnu_type) = build_binary_op (MULT_EXPR, sizetype, elaborate_expression_1 (gnat_entity, gnat_entity, build_binary_op (EXACT_DIV_EXPR, sizetype, TYPE_SIZE_UNIT (gnu_type), size_int (TYPE_ALIGN (gnu_type) / BITS_PER_UNIT)), get_identifier ("SIZE_A_UNIT"), definition, 0), size_int (TYPE_ALIGN (gnu_type) / BITS_PER_UNIT)); if (TREE_CODE (gnu_type) == RECORD_TYPE) SET_TYPE_ADA_SIZE (gnu_type, elaborate_expression_1 (gnat_entity, gnat_entity, TYPE_ADA_SIZE (gnu_type), get_identifier ("RM_SIZE"), definition, 0)); } } /* If this is a record type or subtype, call elaborate_expression_1 on any field position. Do this for both global and local types. Skip any fields that we haven't made trees for to avoid problems with class wide types. */ if (IN (kind, Record_Kind)) for (gnat_temp = First_Entity (gnat_entity); Present (gnat_temp); gnat_temp = Next_Entity (gnat_temp)) if (Ekind (gnat_temp) == E_Component && present_gnu_tree (gnat_temp)) { tree gnu_field = get_gnu_tree (gnat_temp); /* ??? Unfortunately, GCC needs to be able to prove the alignment of this offset and if it's a variable, it can't. In GCC 3.4, we'll use DECL_OFFSET_ALIGN in some way, but right now, we have to put in an explicit multiply and divide by that value. */ if (!CONTAINS_PLACEHOLDER_P (DECL_FIELD_OFFSET (gnu_field))) { DECL_FIELD_OFFSET (gnu_field) = build_binary_op (MULT_EXPR, sizetype, elaborate_expression_1 (gnat_temp, gnat_temp, build_binary_op (EXACT_DIV_EXPR, sizetype, DECL_FIELD_OFFSET (gnu_field), size_int (DECL_OFFSET_ALIGN (gnu_field) / BITS_PER_UNIT)), get_identifier ("OFFSET"), definition, 0), size_int (DECL_OFFSET_ALIGN (gnu_field) / BITS_PER_UNIT)); /* ??? The context of gnu_field is not necessarily gnu_type so the MULT_EXPR node built above may not be marked by the call to create_type_decl below. Mark it manually for now. */ if (global_bindings_p ()) TREE_VISITED (DECL_FIELD_OFFSET (gnu_field)) = 1; } } gnu_type = build_qualified_type (gnu_type, (TYPE_QUALS (gnu_type) | (TYPE_QUAL_VOLATILE * Treat_As_Volatile (gnat_entity)))); if (Is_Atomic (gnat_entity)) check_ok_for_atomic (gnu_type, gnat_entity, false); if (Present (Alignment_Clause (gnat_entity))) TYPE_USER_ALIGN (gnu_type) = 1; if (Universal_Aliasing (gnat_entity)) TYPE_UNIVERSAL_ALIASING_P (TYPE_MAIN_VARIANT (gnu_type)) = 1; if (!gnu_decl) gnu_decl = create_type_decl (gnu_entity_id, gnu_type, attr_list, !Comes_From_Source (gnat_entity), debug_info_p, gnat_entity); else TREE_TYPE (gnu_decl) = gnu_type; } if (IN (kind, Type_Kind) && !TYPE_IS_DUMMY_P (TREE_TYPE (gnu_decl))) { gnu_type = TREE_TYPE (gnu_decl); /* Back-annotate the Alignment of the type if not already in the tree. Likewise for sizes. */ if (Unknown_Alignment (gnat_entity)) Set_Alignment (gnat_entity, UI_From_Int (TYPE_ALIGN (gnu_type) / BITS_PER_UNIT)); if (Unknown_Esize (gnat_entity) && TYPE_SIZE (gnu_type)) { /* If the size is self-referential, we annotate the maximum value of that size. */ tree gnu_size = TYPE_SIZE (gnu_type); if (CONTAINS_PLACEHOLDER_P (gnu_size)) gnu_size = max_size (gnu_size, true); Set_Esize (gnat_entity, annotate_value (gnu_size)); if (type_annotate_only && Is_Tagged_Type (gnat_entity)) { /* In this mode the tag and the parent components are not generated by the front-end, so the sizes must be adjusted explicitly now. */ int size_offset, new_size; if (Is_Derived_Type (gnat_entity)) { size_offset = UI_To_Int (Esize (Etype (Base_Type (gnat_entity)))); Set_Alignment (gnat_entity, Alignment (Etype (Base_Type (gnat_entity)))); } else size_offset = POINTER_SIZE; new_size = UI_To_Int (Esize (gnat_entity)) + size_offset; Set_Esize (gnat_entity, UI_From_Int (((new_size + (POINTER_SIZE - 1)) / POINTER_SIZE) * POINTER_SIZE)); Set_RM_Size (gnat_entity, Esize (gnat_entity)); } } if (Unknown_RM_Size (gnat_entity) && rm_size (gnu_type)) Set_RM_Size (gnat_entity, annotate_value (rm_size (gnu_type))); } if (!Comes_From_Source (gnat_entity) && DECL_P (gnu_decl)) DECL_ARTIFICIAL (gnu_decl) = 1; if (!debug_info_p && DECL_P (gnu_decl) && TREE_CODE (gnu_decl) != FUNCTION_DECL && No (Renamed_Object (gnat_entity))) DECL_IGNORED_P (gnu_decl) = 1; /* If we haven't already, associate the ..._DECL node that we just made with the input GNAT entity node. */ if (!saved) save_gnu_tree (gnat_entity, gnu_decl, false); /* If this is an enumeral or floating-point type, we were not able to set the bounds since they refer to the type. These bounds are always static. For enumeration types, also write debugging information and declare the enumeration literal table, if needed. */ if ((kind == E_Enumeration_Type && Present (First_Literal (gnat_entity))) || (kind == E_Floating_Point_Type && !Vax_Float (gnat_entity))) { tree gnu_scalar_type = gnu_type; /* If this is a padded type, we need to use the underlying type. */ if (TREE_CODE (gnu_scalar_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_scalar_type)) gnu_scalar_type = TREE_TYPE (TYPE_FIELDS (gnu_scalar_type)); /* If this is a floating point type and we haven't set a floating point type yet, use this in the evaluation of the bounds. */ if (!longest_float_type_node && kind == E_Floating_Point_Type) longest_float_type_node = gnu_type; TYPE_MIN_VALUE (gnu_scalar_type) = gnat_to_gnu (Type_Low_Bound (gnat_entity)); TYPE_MAX_VALUE (gnu_scalar_type) = gnat_to_gnu (Type_High_Bound (gnat_entity)); if (TREE_CODE (gnu_scalar_type) == ENUMERAL_TYPE) { TYPE_STUB_DECL (gnu_scalar_type) = gnu_decl; /* Since this has both a typedef and a tag, avoid outputting the name twice. */ DECL_ARTIFICIAL (gnu_decl) = 1; rest_of_type_compilation (gnu_scalar_type, global_bindings_p ()); } } /* If we deferred processing of incomplete types, re-enable it. If there were no other disables and we have some to process, do so. */ if (this_deferred && --defer_incomplete_level == 0) { if (defer_incomplete_list) { struct incomplete *incp, *next; /* We are back to level 0 for the deferring of incomplete types. But processing these incomplete types below may itself require deferring, so preserve what we have and restart from scratch. */ incp = defer_incomplete_list; defer_incomplete_list = NULL; /* For finalization, however, all types must be complete so we cannot do the same because deferred incomplete types may end up referencing each other. Process them all recursively first. */ defer_finalize_level++; for (; incp; incp = next) { next = incp->next; if (incp->old_type) update_pointer_to (TYPE_MAIN_VARIANT (incp->old_type), gnat_to_gnu_type (incp->full_type)); free (incp); } defer_finalize_level--; } /* All the deferred incomplete types have been processed so we can now proceed with the finalization of the deferred types. */ if (defer_finalize_level == 0 && defer_finalize_list) { int toplev = global_bindings_p (); unsigned int i; tree t; for (i = 0; VEC_iterate (tree, defer_finalize_list, i, t); i++) rest_of_decl_compilation (t, toplev, 0); VEC_free (tree, heap, defer_finalize_list); } } /* If we are not defining this type, see if it's in the incomplete list. If so, handle that list entry now. */ else if (!definition) { struct incomplete *incp; for (incp = defer_incomplete_list; incp; incp = incp->next) if (incp->old_type && incp->full_type == gnat_entity) { update_pointer_to (TYPE_MAIN_VARIANT (incp->old_type), TREE_TYPE (gnu_decl)); incp->old_type = NULL_TREE; } } if (this_global) force_global--; if (Is_Packed_Array_Type (gnat_entity) && Is_Itype (Associated_Node_For_Itype (gnat_entity)) && No (Freeze_Node (Associated_Node_For_Itype (gnat_entity))) && !present_gnu_tree (Associated_Node_For_Itype (gnat_entity))) gnat_to_gnu_entity (Associated_Node_For_Itype (gnat_entity), NULL_TREE, 0); return gnu_decl; } /* Similar, but if the returned value is a COMPONENT_REF, return the FIELD_DECL. */ tree gnat_to_gnu_field_decl (Entity_Id gnat_entity) { tree gnu_field = gnat_to_gnu_entity (gnat_entity, NULL_TREE, 0); if (TREE_CODE (gnu_field) == COMPONENT_REF) gnu_field = TREE_OPERAND (gnu_field, 1); return gnu_field; } /* Wrap up compilation of T, a TYPE_DECL, possibly deferring it. */ void rest_of_type_decl_compilation (tree t) { /* We need to defer finalizing the type if incomplete types are being deferred or if they are being processed. */ if (defer_incomplete_level || defer_finalize_level) VEC_safe_push (tree, heap, defer_finalize_list, t); else rest_of_decl_compilation (t, global_bindings_p (), 0); } /* Finalize any From_With_Type incomplete types. We do this after processing our compilation unit and after processing its spec, if this is a body. */ void finalize_from_with_types (void) { struct incomplete *incp = defer_limited_with; struct incomplete *next; defer_limited_with = 0; for (; incp; incp = next) { next = incp->next; if (incp->old_type != 0) update_pointer_to (TYPE_MAIN_VARIANT (incp->old_type), gnat_to_gnu_type (incp->full_type)); free (incp); } } /* Return the equivalent type to be used for GNAT_ENTITY, if it's a kind of type (such E_Task_Type) that has a different type which Gigi uses for its representation. If the type does not have a special type for its representation, return GNAT_ENTITY. If a type is supposed to exist, but does not, abort unless annotating types, in which case return Empty. If GNAT_ENTITY is Empty, return Empty. */ Entity_Id Gigi_Equivalent_Type (Entity_Id gnat_entity) { Entity_Id gnat_equiv = gnat_entity; if (No (gnat_entity)) return gnat_entity; switch (Ekind (gnat_entity)) { case E_Class_Wide_Subtype: if (Present (Equivalent_Type (gnat_entity))) gnat_equiv = Equivalent_Type (gnat_entity); break; case E_Access_Protected_Subprogram_Type: case E_Anonymous_Access_Protected_Subprogram_Type: gnat_equiv = Equivalent_Type (gnat_entity); break; case E_Class_Wide_Type: gnat_equiv = ((Present (Equivalent_Type (gnat_entity))) ? Equivalent_Type (gnat_entity) : Root_Type (gnat_entity)); break; case E_Task_Type: case E_Task_Subtype: case E_Protected_Type: case E_Protected_Subtype: gnat_equiv = Corresponding_Record_Type (gnat_entity); break; default: break; } gcc_assert (Present (gnat_equiv) || type_annotate_only); return gnat_equiv; } /* Return a GCC tree for a parameter corresponding to GNAT_PARAM and using MECH as its passing mechanism, to be placed in the parameter list built for GNAT_SUBPROG. Assume a foreign convention for the latter if FOREIGN is true. Also set CICO to true if the parameter must use the copy-in copy-out implementation mechanism. The returned tree is a PARM_DECL, except for those cases where no parameter needs to be actually passed to the subprogram; the type of this "shadow" parameter is then returned instead. */ static tree gnat_to_gnu_param (Entity_Id gnat_param, Mechanism_Type mech, Entity_Id gnat_subprog, bool foreign, bool *cico) { tree gnu_param_name = get_entity_name (gnat_param); tree gnu_param_type = gnat_to_gnu_type (Etype (gnat_param)); bool in_param = (Ekind (gnat_param) == E_In_Parameter); bool by_return = false, by_component_ptr = false, by_ref = false; tree gnu_param; /* Copy-return is used only for the first parameter of a valued procedure. It's a copy mechanism for which a parameter is never allocated. */ if (mech == By_Copy_Return) { gcc_assert (Ekind (gnat_param) == E_Out_Parameter); mech = By_Copy; by_return = true; } /* If this is either a foreign function or if the underlying type won't be passed by reference, strip off possible padding type. */ if (TREE_CODE (gnu_param_type) == RECORD_TYPE && TYPE_IS_PADDING_P (gnu_param_type)) { tree unpadded_type = TREE_TYPE (TYPE_FIELDS (gnu_param_type)); if (mech == By_Reference || foreign || (!must_pass_by_ref (unpadded_type) && (mech == By_Copy || !default_pass_by_ref (unpadded_type)))) gnu_param_type = unpadded_type; } /* If this is an IN parameter, it is read-only, so make a variant of the type that is read-only. ??? However, if this is an unconstrained array, that type can be very complex, so skip it for now. Likewise for any other self-referential type. */ if (in_param && TREE_CODE (gnu_param_type) != UNCONSTRAINED_ARRAY_TYPE && !CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_param_type))) gnu_param_type = build_qualified_type (gnu_param_type, (TYPE_QUALS (gnu_param_type) | TYPE_QUAL_CONST)); /* For foreign conventions, pass arrays as pointers to the element type. First check for unconstrained array and get the underlying array. */ if (foreign && TREE_CODE (gnu_param_type) == UNCONSTRAINED_ARRAY_TYPE) gnu_param_type = TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (gnu_param_type)))); /* VMS descriptors are themselves passed by reference. */ if (mech == By_Descriptor) gnu_param_type = build_pointer_type (build_vms_descriptor (gnu_param_type, Mechanism (gnat_param), gnat_subprog)); /* Arrays are passed as pointers to element type for foreign conventions. */ else if (foreign && mech != By_Copy && TREE_CODE (gnu_param_type) == ARRAY_TYPE) { /* Strip off any multi-dimensional entries, then strip off the last array to get the component type. */ while (TREE_CODE (TREE_TYPE (gnu_param_type)) == ARRAY_TYPE && TYPE_MULTI_ARRAY_P (TREE_TYPE (gnu_param_type))) gnu_param_type = TREE_TYPE (gnu_param_type); by_component_ptr = true; gnu_param_type = TREE_TYPE (gnu_param_type); if (in_param) gnu_param_type = build_qualified_type (gnu_param_type, (TYPE_QUALS (gnu_param_type) | TYPE_QUAL_CONST)); gnu_param_type = build_pointer_type (gnu_param_type); } /* Fat pointers are passed as thin pointers for foreign conventions. */ else if (foreign && TYPE_FAT_POINTER_P (gnu_param_type)) gnu_param_type = make_type_from_size (gnu_param_type, size_int (POINTER_SIZE), 0); /* If we must pass or were requested to pass by reference, do so. If we were requested to pass by copy, do so. Otherwise, for foreign conventions, pass IN OUT or OUT parameters or aggregates by reference. For COBOL and Fortran, pass all integer and FP types that way too. For Convention Ada, use the standard Ada default. */ else if (must_pass_by_ref (gnu_param_type) || mech == By_Reference || (mech != By_Copy && ((foreign && (!in_param || AGGREGATE_TYPE_P (gnu_param_type))) || (foreign && (Convention (gnat_subprog) == Convention_Fortran || Convention (gnat_subprog) == Convention_COBOL) && (INTEGRAL_TYPE_P (gnu_param_type) || FLOAT_TYPE_P (gnu_param_type))) || (!foreign && default_pass_by_ref (gnu_param_type))))) { gnu_param_type = build_reference_type (gnu_param_type); by_ref = true; } /* Pass IN OUT or OUT parameters using copy-in copy-out mechanism. */ else if (!in_param) *cico = true; if (mech == By_Copy && (by_ref || by_component_ptr)) post_error ("?cannot pass & by copy", gnat_param); /* If this is an OUT parameter that isn't passed by reference and isn't a pointer or aggregate, we don't make a PARM_DECL for it. Instead, it will be a VAR_DECL created when we process the procedure, so just return its type. For the special parameter of a valued procedure, never pass it in. An exception is made to cover the RM-6.4.1 rule requiring "by copy" OUT parameters with discriminants or implicit initial values to be handled like IN OUT parameters. These type are normally built as aggregates, hence passed by reference, except for some packed arrays which end up encoded in special integer types. The exception we need to make is then for packed arrays of records with discriminants or implicit initial values. We have no light/easy way to check for the latter case, so we merely check for packed arrays of records. This may lead to useless copy-in operations, but in very rare cases only, as these would be exceptions in a set of already exceptional situations. */ if (Ekind (gnat_param) == E_Out_Parameter && !by_ref && (by_return || (mech != By_Descriptor && !POINTER_TYPE_P (gnu_param_type) && !AGGREGATE_TYPE_P (gnu_param_type))) && !(Is_Array_Type (Etype (gnat_param)) && Is_Packed (Etype (gnat_param)) && Is_Composite_Type (Component_Type (Etype (gnat_param))))) return gnu_param_type; gnu_param = create_param_decl (gnu_param_name, gnu_param_type, by_ref || by_component_ptr || in_param); DECL_BY_REF_P (gnu_param) = by_ref; DECL_BY_COMPONENT_PTR_P (gnu_param) = by_component_ptr; DECL_BY_DESCRIPTOR_P (gnu_param) = (mech == By_Descriptor); DECL_POINTS_TO_READONLY_P (gnu_param) = (in_param && (by_ref || by_component_ptr)); /* If no Mechanism was specified, indicate what we're using, then back-annotate it. */ if (mech == Default) mech = (by_ref || by_component_ptr) ? By_Reference : By_Copy; Set_Mechanism (gnat_param, mech); return gnu_param; } /* Return true if DISCR1 and DISCR2 represent the same discriminant. */ static bool same_discriminant_p (Entity_Id discr1, Entity_Id discr2) { while (Present (Corresponding_Discriminant (discr1))) discr1 = Corresponding_Discriminant (discr1); while (Present (Corresponding_Discriminant (discr2))) discr2 = Corresponding_Discriminant (discr2); return Original_Record_Component (discr1) == Original_Record_Component (discr2); } /* Given GNAT_ENTITY, elaborate all expressions that are required to be elaborated at the point of its definition, but do nothing else. */ void elaborate_entity (Entity_Id gnat_entity) { switch (Ekind (gnat_entity)) { case E_Signed_Integer_Subtype: case E_Modular_Integer_Subtype: case E_Enumeration_Subtype: case E_Ordinary_Fixed_Point_Subtype: case E_Decimal_Fixed_Point_Subtype: case E_Floating_Point_Subtype: { Node_Id gnat_lb = Type_Low_Bound (gnat_entity); Node_Id gnat_hb = Type_High_Bound (gnat_entity); /* ??? Tests for avoiding static constraint error expression is needed until the front stops generating bogus conversions on bounds of real types. */ if (!Raises_Constraint_Error (gnat_lb)) elaborate_expression (gnat_lb, gnat_entity, get_identifier ("L"), 1, 0, Needs_Debug_Info (gnat_entity)); if (!Raises_Constraint_Error (gnat_hb)) elaborate_expression (gnat_hb, gnat_entity, get_identifier ("U"), 1, 0, Needs_Debug_Info (gnat_entity)); break; } case E_Record_Type: { Node_Id full_definition = Declaration_Node (gnat_entity); Node_Id record_definition = Type_Definition (full_definition); /* If this is a record extension, go a level further to find the record definition. */ if (Nkind (record_definition) == N_Derived_Type_Definition) record_definition = Record_Extension_Part (record_definition); } break; case E_Record_Subtype: case E_Private_Subtype: case E_Limited_Private_Subtype: case E_Record_Subtype_With_Private: if (Is_Constrained (gnat_entity) && Has_Discriminants (Base_Type (gnat_entity)) && Present (Discriminant_Constraint (gnat_entity))) { Node_Id gnat_discriminant_expr; Entity_Id gnat_field; for (gnat_field = First_Discriminant (Base_Type (gnat_entity)), gnat_discriminant_expr = First_Elmt (Discriminant_Constraint (gnat_entity)); Present (gnat_field); gnat_field = Next_Discriminant (gnat_field), gnat_discriminant_expr = Next_Elmt (gnat_discriminant_expr)) /* ??? For now, ignore access discriminants. */ if (!Is_Access_Type (Etype (Node (gnat_discriminant_expr)))) elaborate_expression (Node (gnat_discriminant_expr), gnat_entity, get_entity_name (gnat_field), 1, 0, 0); } break; } } /* Mark GNAT_ENTITY as going out of scope at this point. Recursively mark any entities on its entity chain similarly. */ void mark_out_of_scope (Entity_Id gnat_entity) { Entity_Id gnat_sub_entity; unsigned int kind = Ekind (gnat_entity); /* If this has an entity list, process all in the list. */ if (IN (kind, Class_Wide_Kind) || IN (kind, Concurrent_Kind) || IN (kind, Private_Kind) || kind == E_Block || kind == E_Entry || kind == E_Entry_Family || kind == E_Function || kind == E_Generic_Function || kind == E_Generic_Package || kind == E_Generic_Procedure || kind == E_Loop || kind == E_Operator || kind == E_Package || kind == E_Package_Body || kind == E_Procedure || kind == E_Record_Type || kind == E_Record_Subtype || kind == E_Subprogram_Body || kind == E_Subprogram_Type) for (gnat_sub_entity = First_Entity (gnat_entity); Present (gnat_sub_entity); gnat_sub_entity = Next_Entity (gnat_sub_entity)) if (Scope (gnat_sub_entity) == gnat_entity && gnat_sub_entity != gnat_entity) mark_out_of_scope (gnat_sub_entity); /* Now clear this if it has been defined, but only do so if it isn't a subprogram or parameter. We could refine this, but it isn't worth it. If this is statically allocated, it is supposed to hang around out of cope. */ if (present_gnu_tree (gnat_entity) && !Is_Statically_Allocated (gnat_entity) && kind != E_Procedure && kind != E_Function && !IN (kind, Formal_Kind)) { save_gnu_tree (gnat_entity, NULL_TREE, true); save_gnu_tree (gnat_entity, error_mark_node, true); } } /* Set the alias set of GNU_NEW_TYPE to be that of GNU_OLD_TYPE. If this is a multi-dimensional array type, do this recursively. */ static void copy_alias_set (tree gnu_new_type, tree gnu_old_type) { /* Remove any padding from GNU_OLD_TYPE. It doesn't matter in the case of a one-dimensional array, since the padding has the same alias set as the field type, but if it's a multi-dimensional array, we need to see the inner types. */ while (TREE_CODE (gnu_old_type) == RECORD_TYPE && (TYPE_JUSTIFIED_MODULAR_P (gnu_old_type) || TYPE_IS_PADDING_P (gnu_old_type))) gnu_old_type = TREE_TYPE (TYPE_FIELDS (gnu_old_type)); /* We need to be careful here in case GNU_OLD_TYPE is an unconstrained array. In that case, it doesn't have the same shape as GNU_NEW_TYPE, so we need to go down to what does. */ if (TREE_CODE (gnu_old_type) == UNCONSTRAINED_ARRAY_TYPE) gnu_old_type = TREE_TYPE (TREE_TYPE (TYPE_FIELDS (TREE_TYPE (gnu_old_type)))); if (TREE_CODE (gnu_new_type) == ARRAY_TYPE && TREE_CODE (TREE_TYPE (gnu_new_type)) == ARRAY_TYPE && TYPE_MULTI_ARRAY_P (TREE_TYPE (gnu_new_type))) copy_alias_set (TREE_TYPE (gnu_new_type), TREE_TYPE (gnu_old_type)); TYPE_ALIAS_SET (gnu_new_type) = get_alias_set (gnu_old_type); record_component_aliases (gnu_new_type); } /* Return a TREE_LIST describing the substitutions needed to reflect discriminant substitutions from GNAT_SUBTYPE to GNAT_TYPE and add them to GNU_LIST. If GNAT_TYPE is not specified, use the base type of GNAT_SUBTYPE. The substitutions can be in any order. TREE_PURPOSE gives the tree for the discriminant and TREE_VALUES is the replacement value. They are in the form of operands to substitute_in_expr. DEFINITION is as in gnat_to_gnu_entity. */ static tree substitution_list (Entity_Id gnat_subtype, Entity_Id gnat_type, tree gnu_list, bool definition) { Entity_Id gnat_discrim; Node_Id gnat_value; if (No (gnat_type)) gnat_type = Implementation_Base_Type (gnat_subtype); if (Has_Discriminants (gnat_type)) for (gnat_discrim = First_Stored_Discriminant (gnat_type), gnat_value = First_Elmt (Stored_Constraint (gnat_subtype)); Present (gnat_discrim); gnat_discrim = Next_Stored_Discriminant (gnat_discrim), gnat_value = Next_Elmt (gnat_value)) /* Ignore access discriminants. */ if (!Is_Access_Type (Etype (Node (gnat_value)))) gnu_list = tree_cons (gnat_to_gnu_field_decl (gnat_discrim), elaborate_expression (Node (gnat_value), gnat_subtype, get_entity_name (gnat_discrim), definition, 1, 0), gnu_list); return gnu_list; } /* Return true if the size represented by GNU_SIZE can be handled by an allocation. If STATIC_P is true, consider only what can be done with a static allocation. */ static bool allocatable_size_p (tree gnu_size, bool static_p) { HOST_WIDE_INT our_size; /* If this is not a static allocation, the only case we want to forbid is an overflowing size. That will be converted into a raise a Storage_Error. */ if (!static_p) return !(TREE_CODE (gnu_size) == INTEGER_CST && TREE_OVERFLOW (gnu_size)); /* Otherwise, we need to deal with both variable sizes and constant sizes that won't fit in a host int. We use int instead of HOST_WIDE_INT since assemblers may not like very large sizes. */ if (!host_integerp (gnu_size, 1)) return false; our_size = tree_low_cst (gnu_size, 1); return (int) our_size == our_size; } /* Prepend to ATTR_LIST an entry for an attribute with provided TYPE, NAME, ARGS and ERROR_POINT. */ static void prepend_one_attribute_to (struct attrib ** attr_list, enum attr_type attr_type, tree attr_name, tree attr_args, Node_Id attr_error_point) { struct attrib * attr = (struct attrib *) xmalloc (sizeof (struct attrib)); attr->type = attr_type; attr->name = attr_name; attr->args = attr_args; attr->error_point = attr_error_point; attr->next = *attr_list; *attr_list = attr; } /* Prepend to ATTR_LIST the list of attributes for GNAT_ENTITY, if any. */ static void prepend_attributes (Entity_Id gnat_entity, struct attrib ** attr_list) { Node_Id gnat_temp; for (gnat_temp = First_Rep_Item (gnat_entity); Present (gnat_temp); gnat_temp = Next_Rep_Item (gnat_temp)) if (Nkind (gnat_temp) == N_Pragma) { tree gnu_arg0 = NULL_TREE, gnu_arg1 = NULL_TREE; Node_Id gnat_assoc = Pragma_Argument_Associations (gnat_temp); enum attr_type etype; if (Present (gnat_assoc) && Present (First (gnat_assoc)) && Present (Next (First (gnat_assoc))) && (Nkind (Expression (Next (First (gnat_assoc)))) == N_String_Literal)) { gnu_arg0 = get_identifier (TREE_STRING_POINTER (gnat_to_gnu (Expression (Next (First (gnat_assoc)))))); if (Present (Next (Next (First (gnat_assoc)))) && (Nkind (Expression (Next (Next (First (gnat_assoc))))) == N_String_Literal)) gnu_arg1 = get_identifier (TREE_STRING_POINTER (gnat_to_gnu (Expression (Next (Next (First (gnat_assoc))))))); } switch (Get_Pragma_Id (Chars (gnat_temp))) { case Pragma_Machine_Attribute: etype = ATTR_MACHINE_ATTRIBUTE; break; case Pragma_Linker_Alias: etype = ATTR_LINK_ALIAS; break; case Pragma_Linker_Section: etype = ATTR_LINK_SECTION; break; case Pragma_Linker_Constructor: etype = ATTR_LINK_CONSTRUCTOR; break; case Pragma_Linker_Destructor: etype = ATTR_LINK_DESTRUCTOR; break; case Pragma_Weak_External: etype = ATTR_WEAK_EXTERNAL; break; default: continue; } /* Prepend to the list now. Make a list of the argument we might have, as GCC expects it. */ prepend_one_attribute_to (attr_list, etype, gnu_arg0, (gnu_arg1 != NULL_TREE) ? build_tree_list (NULL_TREE, gnu_arg1) : NULL_TREE, Present (Next (First (gnat_assoc))) ? Expression (Next (First (gnat_assoc))) : gnat_temp); } } /* Get the unpadded version of a GNAT type. */ tree get_unpadded_type (Entity_Id gnat_entity) { tree type = gnat_to_gnu_type (gnat_entity); if (TREE_CODE (type) == RECORD_TYPE && TYPE_IS_PADDING_P (type)) type = TREE_TYPE (TYPE_FIELDS (type)); return type; } /* Called when we need to protect a variable object using a save_expr. */ tree maybe_variable (tree gnu_operand) { if (TREE_CONSTANT (gnu_operand) || TREE_READONLY (gnu_operand) || TREE_CODE (gnu_operand) == SAVE_EXPR || TREE_CODE (gnu_operand) == NULL_EXPR) return gnu_operand; if (TREE_CODE (gnu_operand) == UNCONSTRAINED_ARRAY_REF) { tree gnu_result = build1 (UNCONSTRAINED_ARRAY_REF, TREE_TYPE (gnu_operand), variable_size (TREE_OPERAND (gnu_operand, 0))); TREE_READONLY (gnu_result) = TREE_STATIC (gnu_result) = TYPE_READONLY (TREE_TYPE (TREE_TYPE (gnu_operand))); return gnu_result; } else return variable_size (gnu_operand); } /* Given a GNAT tree GNAT_EXPR, for an expression which is a value within a type definition (either a bound or a discriminant value) for GNAT_ENTITY, return the GCC tree to use for that expression. GNU_NAME is the qualification to use if an external name is appropriate and DEFINITION is nonzero if this is a definition of GNAT_ENTITY. If NEED_VALUE is nonzero, we need a result. Otherwise, we are just elaborating this for side-effects. If NEED_DEBUG is nonzero we need the symbol for debugging purposes even if it isn't needed for code generation. */ static tree elaborate_expression (Node_Id gnat_expr, Entity_Id gnat_entity, tree gnu_name, bool definition, bool need_value, bool need_debug) { tree gnu_expr; /* If we already elaborated this expression (e.g., it was involved in the definition of a private type), use the old value. */ if (present_gnu_tree (gnat_expr)) return get_gnu_tree (gnat_expr); /* If we don't need a value and this is static or a discriminant, we don't need to do anything. */ else if (!need_value && (Is_OK_Static_Expression (gnat_expr) || (Nkind (gnat_expr) == N_Identifier && Ekind (Entity (gnat_expr)) == E_Discriminant))) return 0; /* Otherwise, convert this tree to its GCC equivalent. */ gnu_expr = elaborate_expression_1 (gnat_expr, gnat_entity, gnat_to_gnu (gnat_expr), gnu_name, definition, need_debug); /* Save the expression in case we try to elaborate this entity again. Since this is not a DECL, don't check it. Don't save if it's a discriminant. */ if (!CONTAINS_PLACEHOLDER_P (gnu_expr)) save_gnu_tree (gnat_expr, gnu_expr, true); return need_value ? gnu_expr : error_mark_node; } /* Similar, but take a GNU expression. */ static tree elaborate_expression_1 (Node_Id gnat_expr, Entity_Id gnat_entity, tree gnu_expr, tree gnu_name, bool definition, bool need_debug) { tree gnu_decl = NULL_TREE; /* Strip any conversions to see if the expression is a readonly variable. ??? This really should remain readonly, but we have to think about the typing of the tree here. */ tree gnu_inner_expr = remove_conversions (gnu_expr, true); bool expr_global = Is_Public (gnat_entity) || global_bindings_p (); bool expr_variable; /* In most cases, we won't see a naked FIELD_DECL here because a discriminant reference will have been replaced with a COMPONENT_REF when the type is being elaborated. However, there are some cases involving child types where we will. So convert it to a COMPONENT_REF here. We have to hope it will be at the highest level of the expression in these cases. */ if (TREE_CODE (gnu_expr) == FIELD_DECL) gnu_expr = build3 (COMPONENT_REF, TREE_TYPE (gnu_expr), build0 (PLACEHOLDER_EXPR, DECL_CONTEXT (gnu_expr)), gnu_expr, NULL_TREE); /* If GNU_EXPR is neither a placeholder nor a constant, nor a variable that is a constant, make a variable that is initialized to contain the bound when the package containing the definition is elaborated. If this entity is defined at top level and a bound or discriminant value isn't a constant or a reference to a discriminant, replace the bound by the variable; otherwise use a SAVE_EXPR if needed. Note that we rely here on the fact that an expression cannot contain both the discriminant and some other variable. */ expr_variable = (!CONSTANT_CLASS_P (gnu_expr) && !(TREE_CODE (gnu_inner_expr) == VAR_DECL && (TREE_READONLY (gnu_inner_expr) || DECL_READONLY_ONCE_ELAB (gnu_inner_expr))) && !CONTAINS_PLACEHOLDER_P (gnu_expr)); /* If this is a static expression or contains a discriminant, we don't need the variable for debugging (and can't elaborate anyway if a discriminant). */ if (need_debug && (Is_OK_Static_Expression (gnat_expr) || CONTAINS_PLACEHOLDER_P (gnu_expr))) need_debug = false; /* Now create the variable if we need it. */ if (need_debug || (expr_variable && expr_global)) gnu_decl = create_var_decl (create_concat_name (gnat_entity, IDENTIFIER_POINTER (gnu_name)), NULL_TREE, TREE_TYPE (gnu_expr), gnu_expr, !need_debug, Is_Public (gnat_entity), !definition, false, NULL, gnat_entity); /* We only need to use this variable if we are in global context since GCC can do the right thing in the local case. */ if (expr_global && expr_variable) return gnu_decl; else if (!expr_variable) return gnu_expr; else return maybe_variable (gnu_expr); } /* Create a record type that contains a SIZE bytes long field of TYPE with a starting bit position so that it is aligned to ALIGN bits, and leaving at least ROOM bytes free before the field. BASE_ALIGN is the alignment the record is guaranteed to get. */ tree make_aligning_type (tree type, unsigned int align, tree size, unsigned int base_align, int room) { /* We will be crafting a record type with one field at a position set to be the next multiple of ALIGN past record'address + room bytes. We use a record placeholder to express record'address. */ tree record_type = make_node (RECORD_TYPE); tree record = build0 (PLACEHOLDER_EXPR, record_type); tree record_addr_st = convert (sizetype, build_unary_op (ADDR_EXPR, NULL_TREE, record)); /* The diagram below summarizes the shape of what we manipulate: <--------- pos ----------> { +------------+-------------+-----------------+ record =>{ |############| ... | field (type) | { +------------+-------------+-----------------+ |<-- room -->|<- voffset ->|<---- size ----->| o o | | record_addr vblock_addr Every length is in sizetype bytes there, except "pos" which has to be set as a bit position in the GCC tree for the record. */ tree room_st = size_int (room); tree vblock_addr_st = size_binop (PLUS_EXPR, record_addr_st, room_st); tree voffset_st, pos, field; tree name = TYPE_NAME (type); if (TREE_CODE (name) == TYPE_DECL) name = DECL_NAME (name); TYPE_NAME (record_type) = concat_id_with_name (name, "_ALIGN"); /* Compute VOFFSET and then POS. The next byte position multiple of some alignment after some address is obtained by "and"ing the alignment minus 1 with the two's complement of the address. */ voffset_st = size_binop (BIT_AND_EXPR, size_diffop (size_zero_node, vblock_addr_st), ssize_int ((align / BITS_PER_UNIT) - 1)); /* POS = (ROOM + VOFFSET) * BIT_PER_UNIT, in bitsizetype. */ pos = size_binop (MULT_EXPR, convert (bitsizetype, size_binop (PLUS_EXPR, room_st, voffset_st)), bitsize_unit_node); /* Craft the GCC record representation. The sizes are set manually to account for the maximum possible value of voffset, which avoids complex self-references in the size expression and corresponds to what should be "alloc"ated for this type anyway. Use -1 as the 'addressable' indication for the field to prevent the creation of a bitfield. We don't need one, it would have damaging consequences on the alignment computation, and create_field_decl would make one without this special argument, for instance because of the complex position expression. */ field = create_field_decl (get_identifier ("F"), type, record_type, 1, size, pos, -1); TYPE_FIELDS (record_type) = field; TYPE_ALIGN (record_type) = base_align; TYPE_USER_ALIGN (record_type) = 1; TYPE_SIZE (record_type) = size_binop (PLUS_EXPR, size_binop (MULT_EXPR, convert (bitsizetype, size), bitsize_unit_node), bitsize_int (align + room * BITS_PER_UNIT)); TYPE_SIZE_UNIT (record_type) = size_binop (PLUS_EXPR, size, size_int (room + align / BITS_PER_UNIT)); copy_alias_set (record_type, type); return record_type; } /* TYPE is a RECORD_TYPE, UNION_TYPE, or QUAL_UNION_TYPE, with BLKmode that's being used as the field type of a packed record. See if we can rewrite it as a record that has a non-BLKmode type, which we can pack tighter. If so, return the new type. If not, return the original type. */ static tree make_packable_type (tree type) { tree new_type = make_node (TREE_CODE (type)); tree field_list = NULL_TREE; tree old_field; /* Copy the name and flags from the old type to that of the new and set the alignment to try for an integral type. For QUAL_UNION_TYPE, also copy the size. */ TYPE_NAME (new_type) = TYPE_NAME (type); TYPE_JUSTIFIED_MODULAR_P (new_type) = TYPE_JUSTIFIED_MODULAR_P (type); TYPE_CONTAINS_TEMPLATE_P (new_type) = TYPE_CONTAINS_TEMPLATE_P (type); if (TREE_CODE (type) == RECORD_TYPE) TYPE_IS_PADDING_P (new_type) = TYPE_IS_PADDING_P (type); else if (TREE_CODE (type) == QUAL_UNION_TYPE) { TYPE_SIZE (new_type) = TYPE_SIZE (type); TYPE_SIZE_UNIT (new_type) = TYPE_SIZE_UNIT (type); } TYPE_ALIGN (new_type) = ((HOST_WIDE_INT) 1 << (floor_log2 (tree_low_cst (TYPE_SIZE (type), 1) - 1) + 1)); TYPE_USER_ALIGN (new_type) = 1; /* Now copy the fields, keeping the position and size. */ for (old_field = TYPE_FIELDS (type); old_field; old_field = TREE_CHAIN (old_field)) { tree new_field_type = TREE_TYPE (old_field); tree new_field; if (TYPE_MODE (new_field_type) == BLKmode && (TREE_CODE (new_field_type) == RECORD_TYPE || TREE_CODE (new_field_type) == UNION_TYPE || TREE_CODE (new_field_type) == QUAL_UNION_TYPE) && host_integerp (TYPE_SIZE (new_field_type), 1)) new_field_type = make_packable_type (new_field_type); new_field = create_field_decl (DECL_NAME (old_field), new_field_type, new_type, TYPE_PACKED (type), DECL_SIZE (old_field), bit_position (old_field), !DECL_NONADDRESSABLE_P (old_field)); DECL_INTERNAL_P (new_field) = DECL_INTERNAL_P (old_field); SET_DECL_ORIGINAL_FIELD (new_field, (DECL_ORIGINAL_FIELD (old_field) ? DECL_ORIGINAL_FIELD (old_field) : old_field)); if (TREE_CODE (new_type) == QUAL_UNION_TYPE) DECL_QUALIFIER (new_field) = DECL_QUALIFIER (old_field); TREE_CHAIN (new_field) = field_list; field_list = new_field; } finish_record_type (new_type, nreverse (field_list), 1, true); copy_alias_set (new_type, type); return TYPE_MODE (new_type) == BLKmode ? type : new_type; } /* Ensure that TYPE has SIZE and ALIGN. Make and return a new padded type if needed. We have already verified that SIZE and TYPE are large enough. GNAT_ENTITY and NAME_TRAILER are used to name the resulting record and to issue a warning. IS_USER_TYPE is true if we must be sure we complete the original type. DEFINITION is true if this type is being defined. SAME_RM_SIZE is true if the RM_Size of the resulting type is to be set to its TYPE_SIZE; otherwise, it's set to the RM_Size of the original type. */ tree maybe_pad_type (tree type, tree size, unsigned int align, Entity_Id gnat_entity, const char *name_trailer, bool is_user_type, bool definition, bool same_rm_size) { tree orig_size = TYPE_SIZE (type); unsigned int orig_align = align; tree record; tree field; /* If TYPE is a padded type, see if it agrees with any size and alignment we were given. If so, return the original type. Otherwise, strip off the padding, since we will either be returning the inner type or repadding it. If no size or alignment is specified, use that of the original padded type. */ if (TREE_CODE (type) == RECORD_TYPE && TYPE_IS_PADDING_P (type)) { if ((!size || operand_equal_p (round_up (size, MAX (align, TYPE_ALIGN (type))), round_up (TYPE_SIZE (type), MAX (align, TYPE_ALIGN (type))), 0)) && (align == 0 || align == TYPE_ALIGN (type))) return type; if (!size) size = TYPE_SIZE (type); if (align == 0) align = TYPE_ALIGN (type); type = TREE_TYPE (TYPE_FIELDS (type)); orig_size = TYPE_SIZE (type); } /* If the size is either not being changed or is being made smaller (which is not done here (and is only valid for bitfields anyway), show the size isn't changing. Likewise, clear the alignment if it isn't being changed. Then return if we aren't doing anything. */ if (size && (operand_equal_p (size, orig_size, 0) || (TREE_CODE (orig_size) == INTEGER_CST && tree_int_cst_lt (size, orig_size)))) size = NULL_TREE; if (align == TYPE_ALIGN (type)) align = 0; if (align == 0 && !size) return type; /* We used to modify the record in place in some cases, but that could generate incorrect debugging information. So make a new record type and name. */ record = make_node (RECORD_TYPE); if (Present (gnat_entity)) TYPE_NAME (record) = create_concat_name (gnat_entity, name_trailer); /* If we were making a type, complete the original type and give it a name. */ if (is_user_type) create_type_decl (get_entity_name (gnat_entity), type, NULL, !Comes_From_Source (gnat_entity), !(TYPE_NAME (type) && TREE_CODE (TYPE_NAME (type)) == TYPE_DECL && DECL_IGNORED_P (TYPE_NAME (type))), gnat_entity); /* If we are changing the alignment and the input type is a record with BLKmode and a small constant size, try to make a form that has an integral mode. That might allow this record to have an integral mode, which will be much more efficient. There is no point in doing this if a size is specified unless it is also smaller than the biggest alignment and it is incorrect to do this if the size of the original type is not a multiple of the alignment. */ if (align != 0 && TREE_CODE (type) == RECORD_TYPE && TYPE_MODE (type) == BLKmode && host_integerp (orig_size, 1) && compare_tree_int (orig_size, BIGGEST_ALIGNMENT) <= 0 && (!size || (TREE_CODE (size) == INTEGER_CST && compare_tree_int (size, BIGGEST_ALIGNMENT) <= 0)) && tree_low_cst (orig_size, 1) % align == 0) type = make_packable_type (type); field = create_field_decl (get_identifier ("F"), type, record, 0, NULL_TREE, bitsize_zero_node, 1); DECL_INTERNAL_P (field) = 1; TYPE_SIZE (record) = size ? size : orig_size; TYPE_SIZE_UNIT (record) = (size ? convert (sizetype, size_binop (CEIL_DIV_EXPR, size, bitsize_unit_node)) : TYPE_SIZE_UNIT (type)); TYPE_ALIGN (record) = align; if (orig_align) TYPE_USER_ALIGN (record) = align; TYPE_IS_PADDING_P (record) = 1; TYPE_VOLATILE (record) = Present (gnat_entity) && Treat_As_Volatile (gnat_entity); /* Do not finalize it until after the auxiliary record is built. */ finish_record_type (record, field, 1, true); /* Keep the RM_Size of the padded record as that of the old record if requested. */ SET_TYPE_ADA_SIZE (record, same_rm_size ? size : rm_size (type)); /* Unless debugging information isn't being written for the input type, write a record that shows what we are a subtype of and also make a variable that indicates our size, if variable. */ if (TYPE_NAME (record) && AGGREGATE_TYPE_P (type) && (TREE_CODE (TYPE_NAME (type)) != TYPE_DECL || !DECL_IGNORED_P (TYPE_NAME (type)))) { tree marker = make_node (RECORD_TYPE); tree name = (TREE_CODE (TYPE_NAME (record)) == TYPE_DECL ? DECL_NAME (TYPE_NAME (record)) : TYPE_NAME (record)); tree orig_name = TYPE_NAME (type); if (TREE_CODE (orig_name) == TYPE_DECL) orig_name = DECL_NAME (orig_name); TYPE_NAME (marker) = concat_id_with_name (name, "XVS"); finish_record_type (marker, create_field_decl (orig_name, integer_type_node, marker, 0, NULL_TREE, NULL_TREE, 0), 0, false); if (size && TREE_CODE (size) != INTEGER_CST && definition) create_var_decl (concat_id_with_name (name, "XVZ"), NULL_TREE, bitsizetype, TYPE_SIZE (record), false, false, false, false, NULL, gnat_entity); } rest_of_record_type_compilation (record); /* If the size was widened explicitly, maybe give a warning. Take the original size as the maximum size of the input if there was an unconstrained record involved and round it up to the specified alignment, if one was specified. */ if (CONTAINS_PLACEHOLDER_P (orig_size)) orig_size = max_size (orig_size, true); if (align) orig_size = round_up (orig_size, align); if (size && Present (gnat_entity) && !operand_equal_p (size, orig_size, 0) && !(TREE_CODE (size) == INTEGER_CST && TREE_CODE (orig_size) == INTEGER_CST && tree_int_cst_lt (size, orig_size))) { Node_Id gnat_error_node = Empty; if (Is_Packed_Array_Type (gnat_entity)) gnat_entity = Associated_Node_For_Itype (gnat_entity); if ((Ekind (gnat_entity) == E_Component || Ekind (gnat_entity) == E_Discriminant) && Present (Component_Clause (gnat_entity))) gnat_error_node = Last_Bit (Component_Clause (gnat_entity)); else if (Present (Size_Clause (gnat_entity))) gnat_error_node = Expression (Size_Clause (gnat_entity)); /* Generate message only for entities that come from source, since if we have an entity created by expansion, the message will be generated for some other corresponding source entity. */ if (Comes_From_Source (gnat_entity) && Present (gnat_error_node)) post_error_ne_tree ("{^ }bits of & unused?", gnat_error_node, gnat_entity, size_diffop (size, orig_size)); else if (*name_trailer == 'C' && !Is_Internal (gnat_entity)) post_error_ne_tree ("component of& padded{ by ^ bits}?", gnat_entity, gnat_entity, size_diffop (size, orig_size)); } return record; } /* Given a GNU tree and a GNAT list of choices, generate an expression to test the value passed against the list of choices. */ tree choices_to_gnu (tree operand, Node_Id choices) { Node_Id choice; Node_Id gnat_temp; tree result = integer_zero_node; tree this_test, low = 0, high = 0, single = 0; for (choice = First (choices); Present (choice); choice = Next (choice)) { switch (Nkind (choice)) { case N_Range: low = gnat_to_gnu (Low_Bound (choice)); high = gnat_to_gnu (High_Bound (choice)); /* There's no good type to use here, so we might as well use integer_type_node. */ this_test = build_binary_op (TRUTH_ANDIF_EXPR, integer_type_node, build_binary_op (GE_EXPR, integer_type_node, operand, low), build_binary_op (LE_EXPR, integer_type_node, operand, high)); break; case N_Subtype_Indication: gnat_temp = Range_Expression (Constraint (choice)); low = gnat_to_gnu (Low_Bound (gnat_temp)); high = gnat_to_gnu (High_Bound (gnat_temp)); this_test = build_binary_op (TRUTH_ANDIF_EXPR, integer_type_node, build_binary_op (GE_EXPR, integer_type_node, operand, low), build_binary_op (LE_EXPR, integer_type_node, operand, high)); break; case N_Identifier: case N_Expanded_Name: /* This represents either a subtype range, an enumeration literal, or a constant Ekind says which. If an enumeration literal or constant, fall through to the next case. */ if (Ekind (Entity (choice)) != E_Enumeration_Literal && Ekind (Entity (choice)) != E_Constant) { tree type = gnat_to_gnu_type (Entity (choice)); low = TYPE_MIN_VALUE (type); high = TYPE_MAX_VALUE (type); this_test = build_binary_op (TRUTH_ANDIF_EXPR, integer_type_node, build_binary_op (GE_EXPR, integer_type_node, operand, low), build_binary_op (LE_EXPR, integer_type_node, operand, high)); break; } /* ... fall through ... */ case N_Character_Literal: case N_Integer_Literal: single = gnat_to_gnu (choice); this_test = build_binary_op (EQ_EXPR, integer_type_node, operand, single); break; case N_Others_Choice: this_test = integer_one_node; break; default: gcc_unreachable (); } result = build_binary_op (TRUTH_ORIF_EXPR, integer_type_node, result, this_test); } return result; } /* Adjust PACKED setting as passed to gnat_to_gnu_field for a field of type FIELD_TYPE to be placed in RECORD_TYPE. Return the result. */ static int adjust_packed (tree field_type, tree record_type, int packed) { /* If the field contains an item of variable size, we cannot pack it because we cannot create temporaries of non-fixed size. */ if (is_variable_size (field_type)) return 0; /* If the alignment of the record is specified and the field type is over-aligned, request Storage_Unit alignment for the field. */ if (packed == -2) { if (TYPE_ALIGN (field_type) > TYPE_ALIGN (record_type)) return -1; else return 0; } return packed; } /* Return a GCC tree for a field corresponding to GNAT_FIELD to be placed in GNU_RECORD_TYPE. PACKED is 1 if the enclosing record is packed, -1 if the enclosing record has Component_Alignment of Storage_Unit, -2 if the enclosing record has a specified alignment. DEFINITION is true if this field is for a record being defined. */ static tree gnat_to_gnu_field (Entity_Id gnat_field, tree gnu_record_type, int packed, bool definition) { tree gnu_field_id = get_entity_name (gnat_field); tree gnu_field_type = gnat_to_gnu_type (Etype (gnat_field)); tree gnu_pos = 0; tree gnu_size = 0; tree gnu_field; bool needs_strict_alignment = (Is_Aliased (gnat_field) || Strict_Alignment (Etype (gnat_field)) || Treat_As_Volatile (gnat_field)); /* If this field requires strict alignment, we cannot pack it because it would very likely be under-aligned in the record. */ if (needs_strict_alignment) packed = 0; else packed = adjust_packed (gnu_field_type, gnu_record_type, packed); /* For packed records, this is one of the few occasions on which we use the official RM size for discrete or fixed-point components, instead of the normal GNAT size stored in Esize. See description in Einfo: "Handling of Type'Size Values" for further details. */ if (packed == 1) gnu_size = validate_size (RM_Size (Etype (gnat_field)), gnu_field_type, gnat_field, FIELD_DECL, false, true); if (Known_Static_Esize (gnat_field)) gnu_size = validate_size (Esize (gnat_field), gnu_field_type, gnat_field, FIELD_DECL, false, true); /* If we have a specified size that's smaller than that of the field type, or a position is specified, and the field type is also a record that's BLKmode and with a small constant size, see if we can get an integral mode form of the type when appropriate. If we can, show a size was specified for the field if there wasn't one already, so we know to make this a bitfield and avoid making things wider. Doing this is first useful if the record is packed because we can then place the field at a non-byte-aligned position and so achieve tighter packing. This is in addition *required* if the field shares a byte with another field and the front-end lets the back-end handle the references, because GCC does not handle BLKmode bitfields properly. We avoid the transformation if it is not required or potentially useful, as it might entail an increase of the field's alignment and have ripple effects on the outer record type. A typical case is a field known to be byte aligned and not to share a byte with another field. Besides, we don't even look the possibility of a transformation in cases known to be in error already, for instance when an invalid size results from a component clause. */ if (TREE_CODE (gnu_field_type) == RECORD_TYPE && TYPE_MODE (gnu_field_type) == BLKmode && host_integerp (TYPE_SIZE (gnu_field_type), 1) && compare_tree_int (TYPE_SIZE (gnu_field_type), BIGGEST_ALIGNMENT) <= 0 && (packed == 1 || (gnu_size && tree_int_cst_lt (gnu_size, TYPE_SIZE (gnu_field_type))) || (Present (Component_Clause (gnat_field)) && gnu_size != 0))) { /* See what the alternate type and size would be. */ tree gnu_packable_type = make_packable_type (gnu_field_type); bool has_byte_aligned_clause = Present (Component_Clause (gnat_field)) && (UI_To_Int (Component_Bit_Offset (gnat_field)) % BITS_PER_UNIT == 0); /* Compute whether we should avoid the substitution. */ bool reject /* There is no point substituting if there is no change... */ = (gnu_packable_type == gnu_field_type) /* ... nor when the field is known to be byte aligned and not to share a byte with another field. */ || (has_byte_aligned_clause && value_factor_p (gnu_size, BITS_PER_UNIT)) /* The size of an aliased field must be an exact multiple of the type's alignment, which the substitution might increase. Reject substitutions that would so invalidate a component clause when the specified position is byte aligned, as the change would have no real benefit from the packing standpoint anyway. */ || (Is_Aliased (gnat_field) && has_byte_aligned_clause && !value_factor_p (gnu_size, TYPE_ALIGN (gnu_packable_type))); /* Substitute unless told otherwise. */ if (!reject) { gnu_field_type = gnu_packable_type; if (gnu_size == 0) gnu_size = rm_size (gnu_field_type); } } /* If we are packing the record and the field is BLKmode, round the size up to a byte boundary. */ if (packed && TYPE_MODE (gnu_field_type) == BLKmode && gnu_size) gnu_size = round_up (gnu_size, BITS_PER_UNIT); if (Present (Component_Clause (gnat_field))) { gnu_pos = UI_To_gnu (Component_Bit_Offset (gnat_field), bitsizetype); gnu_size = validate_size (Esize (gnat_field), gnu_field_type, gnat_field, FIELD_DECL, false, true); /* Ensure the position does not overlap with the parent subtype, if there is one. */ if (Present (Parent_Subtype (Underlying_Type (Scope (gnat_field))))) { tree gnu_parent = gnat_to_gnu_type (Parent_Subtype (Underlying_Type (Scope (gnat_field)))); if (TREE_CODE (TYPE_SIZE (gnu_parent)) == INTEGER_CST && tree_int_cst_lt (gnu_pos, TYPE_SIZE (gnu_parent))) { post_error_ne_tree ("offset of& must be beyond parent{, minimum allowed is ^}", First_Bit (Component_Clause (gnat_field)), gnat_field, TYPE_SIZE_UNIT (gnu_parent)); } } /* If this field needs strict alignment, ensure the record is sufficiently aligned and that that position and size are consistent with the alignment. */ if (needs_strict_alignment) { tree gnu_rounded_size = round_up (rm_size (gnu_field_type), TYPE_ALIGN (gnu_field_type)); TYPE_ALIGN (gnu_record_type) = MAX (TYPE_ALIGN (gnu_record_type), TYPE_ALIGN (gnu_field_type)); /* If Atomic, the size must match exactly that of the field. */ if ((Is_Atomic (gnat_field) || Is_Atomic (Etype (gnat_field))) && !operand_equal_p (gnu_size, TYPE_SIZE (gnu_field_type), 0)) { post_error_ne_tree ("atomic field& must be natural size of type{ (^)}", Last_Bit (Component_Clause (gnat_field)), gnat_field, TYPE_SIZE (gnu_field_type)); gnu_size = NULL_TREE; } /* If Aliased, the size must match exactly the rounded size. We used to be more accommodating here and accept greater sizes, but fully supporting this case on big-endian platforms would require switching to a more involved layout for the field. */ else if (Is_Aliased (gnat_field) && gnu_size && ! operand_equal_p (gnu_size, gnu_rounded_size, 0)) { post_error_ne_tree ("size of aliased field& must be ^ bits", Last_Bit (Component_Clause (gnat_field)), gnat_field, gnu_rounded_size); gnu_size = NULL_TREE; } if (!integer_zerop (size_binop (TRUNC_MOD_EXPR, gnu_pos, bitsize_int (TYPE_ALIGN (gnu_field_type))))) { if (Is_Aliased (gnat_field)) post_error_ne_num ("position of aliased field& must be multiple of ^ bits", First_Bit (Component_Clause (gnat_field)), gnat_field, TYPE_ALIGN (gnu_field_type)); else if (Treat_As_Volatile (gnat_field)) post_error_ne_num ("position of volatile field& must be multiple of ^ bits", First_Bit (Component_Clause (gnat_field)), gnat_field, TYPE_ALIGN (gnu_field_type)); else if (Strict_Alignment (Etype (gnat_field))) post_error_ne_num ("position of & with aliased or tagged components not multiple of ^ bits", First_Bit (Component_Clause (gnat_field)), gnat_field, TYPE_ALIGN (gnu_field_type)); else gcc_unreachable (); gnu_pos = NULL_TREE; } } if (Is_Atomic (gnat_field)) check_ok_for_atomic (gnu_field_type, gnat_field, false); } /* If the record has rep clauses and this is the tag field, make a rep clause for it as well. */ else if (Has_Specified_Layout (Scope (gnat_field)) && Chars (gnat_field) == Name_uTag) { gnu_pos = bitsize_zero_node; gnu_size = TYPE_SIZE (gnu_field_type); } /* We need to make the size the maximum for the type if it is self-referential and an unconstrained type. In that case, we can't pack the field since we can't make a copy to align it. */ if (TREE_CODE (gnu_field_type) == RECORD_TYPE && !gnu_size && CONTAINS_PLACEHOLDER_P (TYPE_SIZE (gnu_field_type)) && !Is_Constrained (Underlying_Type (Etype (gnat_field)))) { gnu_size = max_size (TYPE_SIZE (gnu_field_type), true); packed = 0; } /* If no size is specified (or if there was an error), don't specify a position. */ if (!gnu_size) gnu_pos = NULL_TREE; else { /* If the field's type is justified modular, we would need to remove the wrapper to (better) meet the layout requirements. However we can do so only if the field is not aliased to preserve the unique layout and if the prescribed size is not greater than that of the packed array to preserve the justification. */ if (!needs_strict_alignment && TREE_CODE (gnu_field_type) == RECORD_TYPE && TYPE_JUSTIFIED_MODULAR_P (gnu_field_type) && tree_int_cst_compare (gnu_size, TYPE_ADA_SIZE (gnu_field_type)) <= 0) gnu_field_type = TREE_TYPE (TYPE_FIELDS (gnu_field_type)); gnu_field_type = make_type_from_size (gnu_field_type, gnu_size, Has_Biased_Representation (gnat_field)); gnu_field_type = maybe_pad_type (gnu_field_type, gnu_size, 0, gnat_field, "PAD", false, definition, true); } gcc_assert (TREE_CODE (gnu_field_type) != RECORD_TYPE || !TYPE_CONTAINS_TEMPLATE_P (gnu_field_type)); /* Now create the decl for the field. */ gnu_field = create_field_decl (gnu_field_id, gnu_field_type, gnu_record_type, packed, gnu_size, gnu_pos, Is_Aliased (gnat_field)); Sloc_to_locus (Sloc (gnat_field), &DECL_SOURCE_LOCATION (gnu_field)); TREE_THIS_VOLATILE (gnu_field) = Treat_As_Volatile (gnat_field); if (Ekind (gnat_field) == E_Discriminant) DECL_DISCRIMINANT_NUMBER (gnu_field) = UI_To_gnu (Discriminant_Number (gnat_field), sizetype); return gnu_field; } /* Return true if TYPE is a type with variable size, a padding type with a field of variable size or is a record that has a field such a field. */ static bool is_variable_size (tree type) { tree field; /* We need not be concerned about this at all if we don't have strict alignment. */ if (!STRICT_ALIGNMENT) return false; else if (!TREE_CONSTANT (TYPE_SIZE (type))) return true; else if (TREE_CODE (type) == RECORD_TYPE && TYPE_IS_PADDING_P (type) && !TREE_CONSTANT (DECL_SIZE (TYPE_FIELDS (type)))) return true; else if (TREE_CODE (type) != RECORD_TYPE && TREE_CODE (type) != UNION_TYPE && TREE_CODE (type) != QUAL_UNION_TYPE) return false; for (field = TYPE_FIELDS (type); field; field = TREE_CHAIN (field)) if (is_variable_size (TREE_TYPE (field))) return true; return false; } /* qsort comparer for the bit positions of two record components. */ static int compare_field_bitpos (const PTR rt1, const PTR rt2) { const_tree const field1 = * (const_tree const *) rt1; const_tree const field2 = * (const_tree const *) rt2; const int ret = tree_int_cst_compare (bit_position (field1), bit_position (field2)); return ret ? ret : (int) (DECL_UID (field1) - DECL_UID (field2)); } /* Return a GCC tree for a record type given a GNAT Component_List and a chain of GCC trees for fields that are in the record and have already been processed. When called from gnat_to_gnu_entity during the processing of a record type definition, the GCC nodes for the discriminants will be on the chain. The other calls to this function are recursive calls from itself for the Component_List of a variant and the chain is empty. PACKED is 1 if this is for a packed record, -1 if this is for a record with Component_Alignment of Storage_Unit, -2 if this is for a record with a specified alignment. DEFINITION is true if we are defining this record. P_GNU_REP_LIST, if nonzero, is a pointer to a list to which each field with a rep clause is to be added. If it is nonzero, that is all that should be done with such fields. CANCEL_ALIGNMENT, if true, means the alignment should be zeroed before laying out the record. This means the alignment only serves to force fields to be bitfields, but not require the record to be that aligned. This is used for variants. ALL_REP, if true, means a rep clause was found for all the fields. This simplifies the logic since we know we're not in the mixed case. DO_NOT_FINALIZE, if true, means that the record type is expected to be modified afterwards so it will not be sent to the back-end for finalization. UNCHECKED_UNION, if true, means that we are building a type for a record with a Pragma Unchecked_Union. The processing of the component list fills in the chain with all of the fields of the record and then the record type is finished. */ static void components_to_record (tree gnu_record_type, Node_Id component_list, tree gnu_field_list, int packed, bool definition, tree *p_gnu_rep_list, bool cancel_alignment, bool all_rep, bool do_not_finalize, bool unchecked_union) { Node_Id component_decl; Entity_Id gnat_field; Node_Id variant_part; tree gnu_our_rep_list = NULL_TREE; tree gnu_field, gnu_last; bool layout_with_rep = false; bool all_rep_and_size = all_rep && TYPE_SIZE (gnu_record_type); /* For each variable within each component declaration create a GCC field and add it to the list, skipping any pragmas in the list. */ if (Present (Component_Items (component_list))) for (component_decl = First_Non_Pragma (Component_Items (component_list)); Present (component_decl); component_decl = Next_Non_Pragma (component_decl)) { gnat_field = Defining_Entity (component_decl); if (Chars (gnat_field) == Name_uParent) gnu_field = tree_last (TYPE_FIELDS (gnu_record_type)); else { gnu_field = gnat_to_gnu_field (gnat_field, gnu_record_type, packed, definition); /* If this is the _Tag field, put it before any discriminants, instead of after them as is the case for all other fields. Ignore field of void type if only annotating. */ if (Chars (gnat_field) == Name_uTag) gnu_field_list = chainon (gnu_field_list, gnu_field); else { TREE_CHAIN (gnu_field) = gnu_field_list; gnu_field_list = gnu_field; } } save_gnu_tree (gnat_field, gnu_field, false); } /* At the end of the component list there may be a variant part. */ variant_part = Variant_Part (component_list); /* We create a QUAL_UNION_TYPE for the variant part since the variants are mutually exclusive and should go in the same memory. To do this we need to treat each variant as a record whose elements are created from the component list for the variant. So here we create the records from the lists for the variants and put them all into the QUAL_UNION_TYPE. If this is an Unchecked_Union, we make a UNION_TYPE instead or use GNU_RECORD_TYPE if there are no fields so far. */ if (Present (variant_part)) { tree gnu_discriminant = gnat_to_gnu (Name (variant_part)); Node_Id variant; tree gnu_name = TYPE_NAME (gnu_record_type); tree gnu_var_name = concat_id_with_name (get_identifier (Get_Name_String (Chars (Name (variant_part)))), "XVN"); tree gnu_union_type; tree gnu_union_name; tree gnu_union_field; tree gnu_variant_list = NULL_TREE; if (TREE_CODE (gnu_name) == TYPE_DECL) gnu_name = DECL_NAME (gnu_name); gnu_union_name = concat_id_with_name (gnu_name, IDENTIFIER_POINTER (gnu_var_name)); if (!gnu_field_list && TREE_CODE (gnu_record_type) == UNION_TYPE) gnu_union_type = gnu_record_type; else { gnu_union_type = make_node (unchecked_union ? UNION_TYPE : QUAL_UNION_TYPE); TYPE_NAME (gnu_union_type) = gnu_union_name; TYPE_PACKED (gnu_union_type) = TYPE_PACKED (gnu_record_type); } for (variant = First_Non_Pragma (Variants (variant_part)); Present (variant); variant = Next_Non_Pragma (variant)) { tree gnu_variant_type = make_node (RECORD_TYPE); tree gnu_inner_name; tree gnu_qual; Get_Variant_Encoding (variant); gnu_inner_name = get_identifier (Name_Buffer); TYPE_NAME (gnu_variant_type) = concat_id_with_name (gnu_union_name, IDENTIFIER_POINTER (gnu_inner_name)); /* Set the alignment of the inner type in case we need to make inner objects into bitfields, but then clear it out so the record actually gets only the alignment required. */ TYPE_ALIGN (gnu_variant_type) = TYPE_ALIGN (gnu_record_type); TYPE_PACKED (gnu_variant_type) = TYPE_PACKED (gnu_record_type); /* Similarly, if the outer record has a size specified and all fields have record rep clauses, we can propagate the size into the variant part. */ if (all_rep_and_size) { TYPE_SIZE (gnu_variant_type) = TYPE_SIZE (gnu_record_type); TYPE_SIZE_UNIT (gnu_variant_type) = TYPE_SIZE_UNIT (gnu_record_type); } /* Create the record type for the variant. Note that we defer finalizing it until after we are sure to actually use it. */ components_to_record (gnu_variant_type, Component_List (variant), NULL_TREE, packed, definition, &gnu_our_rep_list, !all_rep_and_size, all_rep, true, unchecked_union); gnu_qual = choices_to_gnu (gnu_discriminant, Discrete_Choices (variant)); Set_Present_Expr (variant, annotate_value (gnu_qual)); /* If this is an Unchecked_Union and we have exactly one field, use that field here. */ if (unchecked_union && TYPE_FIELDS (gnu_variant_type) && !TREE_CHAIN (TYPE_FIELDS (gnu_variant_type))) gnu_field = TYPE_FIELDS (gnu_variant_type); else { /* Deal with packedness like in gnat_to_gnu_field. */ int field_packed = adjust_packed (gnu_variant_type, gnu_record_type, packed); /* Finalize the record type now. We used to throw away empty records but we no longer do that because we need them to generate complete debug info for the variant; otherwise, the union type definition will be lacking the fields associated with these empty variants. */ rest_of_record_type_compilation (gnu_variant_type); gnu_field = create_field_decl (gnu_inner_name, gnu_variant_type, gnu_union_type, field_packed, (all_rep_and_size ? TYPE_SIZE (gnu_variant_type) : 0), (all_rep_and_size ? bitsize_zero_node : 0), 0); DECL_INTERNAL_P (gnu_field) = 1; if (!unchecked_union) DECL_QUALIFIER (gnu_field) = gnu_qual; } TREE_CHAIN (gnu_field) = gnu_variant_list; gnu_variant_list = gnu_field; } /* Only make the QUAL_UNION_TYPE if there are any non-empty variants. */ if (gnu_variant_list) { if (all_rep_and_size) { TYPE_SIZE (gnu_union_type) = TYPE_SIZE (gnu_record_type); TYPE_SIZE_UNIT (gnu_union_type) = TYPE_SIZE_UNIT (gnu_record_type); } finish_record_type (gnu_union_type, nreverse (gnu_variant_list), all_rep_and_size ? 1 : 0, false); /* If GNU_UNION_TYPE is our record type, it means we must have an Unchecked_Union with no fields. Verify that and, if so, just return. */ if (gnu_union_type == gnu_record_type) { gcc_assert (!gnu_field_list && unchecked_union); return; } gnu_union_field = create_field_decl (gnu_var_name, gnu_union_type, gnu_record_type, packed, all_rep ? TYPE_SIZE (gnu_union_type) : 0, all_rep ? bitsize_zero_node : 0, 0); DECL_INTERNAL_P (gnu_union_field) = 1; TREE_CHAIN (gnu_union_field) = gnu_field_list; gnu_field_list = gnu_union_field; } } /* Scan GNU_FIELD_LIST and see if any fields have rep clauses. If they do, pull them out and put them into GNU_OUR_REP_LIST. We have to do this in a separate pass since we want to handle the discriminants but can't play with them until we've used them in debugging data above. ??? Note: if we then reorder them, debugging information will be wrong, but there's nothing that can be done about this at the moment. */ for (gnu_field = gnu_field_list, gnu_last = NULL_TREE; gnu_field; ) { if (DECL_FIELD_OFFSET (gnu_field)) { tree gnu_next = TREE_CHAIN (gnu_field); if (!gnu_last) gnu_field_list = gnu_next; else TREE_CHAIN (gnu_last) = gnu_next; TREE_CHAIN (gnu_field) = gnu_our_rep_list; gnu_our_rep_list = gnu_field; gnu_field = gnu_next; } else { gnu_last = gnu_field; gnu_field = TREE_CHAIN (gnu_field); } } /* If we have any items in our rep'ed field list, it is not the case that all the fields in the record have rep clauses, and P_REP_LIST is nonzero, set it and ignore the items. */ if (gnu_our_rep_list && p_gnu_rep_list && !all_rep) *p_gnu_rep_list = chainon (*p_gnu_rep_list, gnu_our_rep_list); else if (gnu_our_rep_list) { /* Otherwise, sort the fields by bit position and put them into their own record if we have any fields without rep clauses. */ tree gnu_rep_type = (gnu_field_list ? make_node (RECORD_TYPE) : gnu_record_type); int len = list_length (gnu_our_rep_list); tree *gnu_arr = (tree *) alloca (sizeof (tree) * len); int i; for (i = 0, gnu_field = gnu_our_rep_list; gnu_field; gnu_field = TREE_CHAIN (gnu_field), i++) gnu_arr[i] = gnu_field; qsort (gnu_arr, len, sizeof (tree), compare_field_bitpos); /* Put the fields in the list in order of increasing position, which means we start from the end. */ gnu_our_rep_list = NULL_TREE; for (i = len - 1; i >= 0; i--) { TREE_CHAIN (gnu_arr[i]) = gnu_our_rep_list; gnu_our_rep_list = gnu_arr[i]; DECL_CONTEXT (gnu_arr[i]) = gnu_rep_type; } if (gnu_field_list) { finish_record_type (gnu_rep_type, gnu_our_rep_list, 1, false); gnu_field = create_field_decl (get_identifier ("REP"), gnu_rep_type, gnu_record_type, 0, 0, 0, 1); DECL_INTERNAL_P (gnu_field) = 1; gnu_field_list = chainon (gnu_field_list, gnu_field); } else { layout_with_rep = true; gnu_field_list = nreverse (gnu_our_rep_list); } } if (cancel_alignment) TYPE_ALIGN (gnu_record_type) = 0; finish_record_type (gnu_record_type, nreverse (gnu_field_list), layout_with_rep ? 1 : 0, do_not_finalize); } /* Given GNU_SIZE, a GCC tree representing a size, return a Uint to be placed into an Esize, Component_Bit_Offset, or Component_Size value in the GNAT tree. */ static Uint annotate_value (tree gnu_size) { int len = TREE_CODE_LENGTH (TREE_CODE (gnu_size)); TCode tcode; Node_Ref_Or_Val ops[3], ret; int i; int size; struct tree_int_map **h = NULL; /* See if we've already saved the value for this node. */ if (EXPR_P (gnu_size)) { struct tree_int_map in; if (!annotate_value_cache) annotate_value_cache = htab_create_ggc (512, tree_int_map_hash, tree_int_map_eq, 0); in.base.from = gnu_size; h = (struct tree_int_map **) htab_find_slot (annotate_value_cache, &in, INSERT); if (*h) return (Node_Ref_Or_Val) (*h)->to; } /* If we do not return inside this switch, TCODE will be set to the code to use for a Create_Node operand and LEN (set above) will be the number of recursive calls for us to make. */ switch (TREE_CODE (gnu_size)) { case INTEGER_CST: if (TREE_OVERFLOW (gnu_size)) return No_Uint; /* This may have come from a conversion from some smaller type, so ensure this is in bitsizetype. */ gnu_size = convert (bitsizetype, gnu_size); /* For negative values, use NEGATE_EXPR of the supplied value. */ if (tree_int_cst_sgn (gnu_size) < 0) { /* The ridiculous code below is to handle the case of the largest negative integer. */ tree negative_size = size_diffop (bitsize_zero_node, gnu_size); bool adjust = false; tree temp; if (TREE_OVERFLOW (negative_size)) { negative_size = size_binop (MINUS_EXPR, bitsize_zero_node, size_binop (PLUS_EXPR, gnu_size, bitsize_one_node)); adjust = true; } temp = build1 (NEGATE_EXPR, bitsizetype, negative_size); if (adjust) temp = build2 (MINUS_EXPR, bitsizetype, temp, bitsize_one_node); return annotate_value (temp); } if (!host_integerp (gnu_size, 1)) return No_Uint; size = tree_low_cst (gnu_size, 1); /* This peculiar test is to make sure that the size fits in an int on machines where HOST_WIDE_INT is not "int". */ if (tree_low_cst (gnu_size, 1) == size) return UI_From_Int (size); else return No_Uint; case COMPONENT_REF: /* The only case we handle here is a simple discriminant reference. */ if (TREE_CODE (TREE_OPERAND (gnu_size, 0)) == PLACEHOLDER_EXPR && TREE_CODE (TREE_OPERAND (gnu_size, 1)) == FIELD_DECL && DECL_DISCRIMINANT_NUMBER (TREE_OPERAND (gnu_size, 1))) return Create_Node (Discrim_Val, annotate_value (DECL_DISCRIMINANT_NUMBER (TREE_OPERAND (gnu_size, 1))), No_Uint, No_Uint); else return No_Uint; case NOP_EXPR: case CONVERT_EXPR: case NON_LVALUE_EXPR: return annotate_value (TREE_OPERAND (gnu_size, 0)); /* Now just list the operations we handle. */ case COND_EXPR: tcode = Cond_Expr; break; case PLUS_EXPR: tcode = Plus_Expr; break; case MINUS_EXPR: tcode = Minus_Expr; break; case MULT_EXPR: tcode = Mult_Expr; break; case TRUNC_DIV_EXPR: tcode = Trunc_Div_Expr; break; case CEIL_DIV_EXPR: tcode = Ceil_Div_Expr; break; case FLOOR_DIV_EXPR: tcode = Floor_Div_Expr; break; case TRUNC_MOD_EXPR: tcode = Trunc_Mod_Expr; break; case CEIL_MOD_EXPR: tcode = Ceil_Mod_Expr; break; case FLOOR_MOD_EXPR: tcode = Floor_Mod_Expr; break; case EXACT_DIV_EXPR: tcode = Exact_Div_Expr; break; case NEGATE_EXPR: tcode = Negate_Expr; break; case MIN_EXPR: tcode = Min_Expr; break; case MAX_EXPR: tcode = Max_Expr; break; case ABS_EXPR: tcode = Abs_Expr; break; case TRUTH_ANDIF_EXPR: tcode = Truth_Andif_Expr; break; case TRUTH_ORIF_EXPR: tcode = Truth_Orif_Expr; break; case TRUTH_AND_EXPR: tcode = Truth_And_Expr; break; case TRUTH_OR_EXPR: tcode = Truth_Or_Expr; break; case TRUTH_XOR_EXPR: tcode = Truth_Xor_Expr; break; case TRUTH_NOT_EXPR: tcode = Truth_Not_Expr; break; case BIT_AND_EXPR: tcode = Bit_And_Expr; break; case LT_EXPR: tcode = Lt_Expr; break; case LE_EXPR: tcode = Le_Expr; break; case GT_EXPR: tcode = Gt_Expr; break; case GE_EXPR: tcode = Ge_Expr; break; case EQ_EXPR: tcode = Eq_Expr; break; case NE_EXPR: tcode = Ne_Expr; break; default: return No_Uint; } /* Now get each of the operands that's relevant for this code. If any cannot be expressed as a repinfo node, say we can't. */ for (i = 0; i < 3; i++) ops[i] = No_Uint; for (i = 0; i < len; i++) { ops[i] = annotate_value (TREE_OPERAND (gnu_size, i)); if (ops[i] == No_Uint) return No_Uint; } ret = Create_Node (tcode, ops[0], ops[1], ops[2]); /* Save the result in the cache. */ if (h) { *h = ggc_alloc (sizeof (struct tree_int_map)); (*h)->base.from = gnu_size; (*h)->to = ret; } return ret; } /* Given GNAT_ENTITY, a record type, and GNU_TYPE, its corresponding GCC type, set Component_Bit_Offset and Esize to the position and size used by Gigi. */ static void annotate_rep (Entity_Id gnat_entity, tree gnu_type) { tree gnu_list; tree gnu_entry; Entity_Id gnat_field; /* We operate by first making a list of all fields and their positions (we can get the sizes easily at any time) by a recursive call and then update all the sizes into the tree. */ gnu_list = compute_field_positions (gnu_type, NULL_TREE, size_zero_node, bitsize_zero_node, BIGGEST_ALIGNMENT); for (gnat_field = First_Entity (gnat_entity); Present (gnat_field); gnat_field = Next_Entity (gnat_field)) if ((Ekind (gnat_field) == E_Component || (Ekind (gnat_field) == E_Discriminant && !Is_Unchecked_Union (Scope (gnat_field))))) { tree parent_offset = bitsize_zero_node; gnu_entry = purpose_member (gnat_to_gnu_field_decl (gnat_field), gnu_list); if (gnu_entry) { if (type_annotate_only && Is_Tagged_Type (gnat_entity)) { /* In this mode the tag and parent components have not been generated, so we add the appropriate offset to each component. For a component appearing in the current extension, the offset is the size of the parent. */ if (Is_Derived_Type (gnat_entity) && Original_Record_Component (gnat_field) == gnat_field) parent_offset = UI_To_gnu (Esize (Etype (Base_Type (gnat_entity))), bitsizetype); else parent_offset = bitsize_int (POINTER_SIZE); } Set_Component_Bit_Offset (gnat_field, annotate_value (size_binop (PLUS_EXPR, bit_from_pos (TREE_PURPOSE (TREE_VALUE (gnu_entry)), TREE_VALUE (TREE_VALUE (TREE_VALUE (gnu_entry)))), parent_offset))); Set_Esize (gnat_field, annotate_value (DECL_SIZE (TREE_PURPOSE (gnu_entry)))); } else if (Is_Tagged_Type (gnat_entity) && Is_Derived_Type (gnat_entity)) { /* If there is no gnu_entry, this is an inherited component whose position is the same as in the parent type. */ Set_Component_Bit_Offset (gnat_field, Component_Bit_Offset (Original_Record_Component (gnat_field))); Set_Esize (gnat_field, Esize (Original_Record_Component (gnat_field))); } } } /* Scan all fields in GNU_TYPE and build entries where TREE_PURPOSE is the FIELD_DECL and TREE_VALUE a TREE_LIST with TREE_PURPOSE being the byte position and TREE_VALUE being a TREE_LIST with TREE_PURPOSE the value to be placed into DECL_OFFSET_ALIGN and TREE_VALUE the bit position. GNU_POS is to be added to the position, GNU_BITPOS to the bit position, OFFSET_ALIGN is the present value of DECL_OFFSET_ALIGN and GNU_LIST is a list of the entries so far. */ static tree compute_field_positions (tree gnu_type, tree gnu_list, tree gnu_pos, tree gnu_bitpos, unsigned int offset_align) { tree gnu_field; tree gnu_result = gnu_list; for (gnu_field = TYPE_FIELDS (gnu_type); gnu_field; gnu_field = TREE_CHAIN (gnu_field)) { tree gnu_our_bitpos = size_binop (PLUS_EXPR, gnu_bitpos, DECL_FIELD_BIT_OFFSET (gnu_field)); tree gnu_our_offset = size_binop (PLUS_EXPR, gnu_pos, DECL_FIELD_OFFSET (gnu_field)); unsigned int our_offset_align = MIN (offset_align, DECL_OFFSET_ALIGN (gnu_field)); gnu_result = tree_cons (gnu_field, tree_cons (gnu_our_offset, tree_cons (size_int (our_offset_align), gnu_our_bitpos, NULL_TREE), NULL_TREE), gnu_result); if (DECL_INTERNAL_P (gnu_field)) gnu_result = compute_field_positions (TREE_TYPE (gnu_field), gnu_result, gnu_our_offset, gnu_our_bitpos, our_offset_align); } return gnu_result; } /* UINT_SIZE is a Uint giving the specified size for an object of GNU_TYPE corresponding to GNAT_OBJECT. If size is valid, return a tree corresponding to its value. Otherwise return 0. KIND is VAR_DECL is we are specifying the size for an object, TYPE_DECL for the size of a type, and FIELD_DECL for the size of a field. COMPONENT_P is true if we are being called to process the Component_Size of GNAT_OBJECT. This is used for error message handling and to indicate to use the object size of GNU_TYPE. ZERO_OK is true if a size of zero is permitted; if ZERO_OK is false, it means that a size of zero should be treated as an unspecified size. */ static tree validate_size (Uint uint_size, tree gnu_type, Entity_Id gnat_object, enum tree_code kind, bool component_p, bool zero_ok) { Node_Id gnat_error_node; tree type_size = kind == VAR_DECL ? TYPE_SIZE (gnu_type) : rm_size (gnu_type); tree size; /* Find the node to use for errors. */ if ((Ekind (gnat_object) == E_Component || Ekind (gnat_object) == E_Discriminant) && Present (Component_Clause (gnat_object))) gnat_error_node = Last_Bit (Component_Clause (gnat_object)); else if (Present (Size_Clause (gnat_object))) gnat_error_node = Expression (Size_Clause (gnat_object)); else gnat_error_node = gnat_object; /* Return 0 if no size was specified, either because Esize was not Present or the specified size was zero. */ if (No (uint_size) || uint_size == No_Uint) return NULL_TREE; /* Get the size as a tree. Give an error if a size was specified, but cannot be represented as in sizetype. */ size = UI_To_gnu (uint_size, bitsizetype); if (TREE_OVERFLOW (size)) { post_error_ne (component_p ? "component size of & is too large" : "size of & is too large", gnat_error_node, gnat_object); return NULL_TREE; } /* Ignore a negative size since that corresponds to our back-annotation. Also ignore a zero size unless a size clause exists. */ else if (tree_int_cst_sgn (size) < 0 || (integer_zerop (size) && !zero_ok)) return NULL_TREE; /* The size of objects is always a multiple of a byte. */ if (kind == VAR_DECL && !integer_zerop (size_binop (TRUNC_MOD_EXPR, size, bitsize_unit_node))) { if (component_p) post_error_ne ("component size for& is not a multiple of Storage_Unit", gnat_error_node, gnat_object); else post_error_ne ("size for& is not a multiple of Storage_Unit", gnat_error_node, gnat_object); return NULL_TREE; } /* If this is an integral type or a packed array type, the front-end has verified the size, so we need not do it here (which would entail checking against the bounds). However, if this is an aliased object, it may not be smaller than the type of the object. */ if ((INTEGRAL_TYPE_P (gnu_type) || TYPE_IS_PACKED_ARRAY_TYPE_P (gnu_type)) && !(kind == VAR_DECL && Is_Aliased (gnat_object))) return size; /* If the object is a record that contains a template, add the size of the template to the specified size. */ if (TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (gnu_type)) size = size_binop (PLUS_EXPR, DECL_SIZE (TYPE_FIELDS (gnu_type)), size); /* Modify the size of the type to be that of the maximum size if it has a discriminant or the size of a thin pointer if this is a fat pointer. */ if (type_size && CONTAINS_PLACEHOLDER_P (type_size)) type_size = max_size (type_size, true); else if (TYPE_FAT_POINTER_P (gnu_type)) type_size = bitsize_int (POINTER_SIZE); /* If this is an access type, the minimum size is that given by the smallest integral mode that's valid for pointers. */ if (TREE_CODE (gnu_type) == POINTER_TYPE) { enum machine_mode p_mode; for (p_mode = GET_CLASS_NARROWEST_MODE (MODE_INT); !targetm.valid_pointer_mode (p_mode); p_mode = GET_MODE_WIDER_MODE (p_mode)) ; type_size = bitsize_int (GET_MODE_BITSIZE (p_mode)); } /* If the size of the object is a constant, the new size must not be smaller. */ if (TREE_CODE (type_size) != INTEGER_CST || TREE_OVERFLOW (type_size) || tree_int_cst_lt (size, type_size)) { if (component_p) post_error_ne_tree ("component size for& too small{, minimum allowed is ^}", gnat_error_node, gnat_object, type_size); else post_error_ne_tree ("size for& too small{, minimum allowed is ^}", gnat_error_node, gnat_object, type_size); if (kind == VAR_DECL && !component_p && TREE_CODE (rm_size (gnu_type)) == INTEGER_CST && !tree_int_cst_lt (size, rm_size (gnu_type))) post_error_ne_tree_2 ("\\size of ^ is not a multiple of alignment (^ bits)", gnat_error_node, gnat_object, rm_size (gnu_type), TYPE_ALIGN (gnu_type)); else if (INTEGRAL_TYPE_P (gnu_type)) post_error_ne ("\\size would be legal if & were not aliased!", gnat_error_node, gnat_object); return NULL_TREE; } return size; } /* Similarly, but both validate and process a value of RM_Size. This routine is only called for types. */ static void set_rm_size (Uint uint_size, tree gnu_type, Entity_Id gnat_entity) { /* Only give an error if a Value_Size clause was explicitly given. Otherwise, we'd be duplicating an error on the Size clause. */ Node_Id gnat_attr_node = Get_Attribute_Definition_Clause (gnat_entity, Attr_Value_Size); tree old_size = rm_size (gnu_type); tree size; /* Get the size as a tree. Do nothing if none was specified, either because RM_Size was not Present or if the specified size was zero. Give an error if a size was specified, but cannot be represented as in sizetype. */ if (No (uint_size) || uint_size == No_Uint) return; size = UI_To_gnu (uint_size, bitsizetype); if (TREE_OVERFLOW (size)) { if (Present (gnat_attr_node)) post_error_ne ("Value_Size of & is too large", gnat_attr_node, gnat_entity); return; } /* Ignore a negative size since that corresponds to our back-annotation. Also ignore a zero size unless a size clause exists, a Value_Size clause exists, or this is an integer type, in which case the front end will have always set it. */ else if (tree_int_cst_sgn (size) < 0 || (integer_zerop (size) && No (gnat_attr_node) && !Has_Size_Clause (gnat_entity) && !Is_Discrete_Or_Fixed_Point_Type (gnat_entity))) return; /* If the old size is self-referential, get the maximum size. */ if (CONTAINS_PLACEHOLDER_P (old_size)) old_size = max_size (old_size, true); /* If the size of the object is a constant, the new size must not be smaller (the front end checks this for scalar types). */ if (TREE_CODE (old_size) != INTEGER_CST || TREE_OVERFLOW (old_size) || (AGGREGATE_TYPE_P (gnu_type) && tree_int_cst_lt (size, old_size))) { if (Present (gnat_attr_node)) post_error_ne_tree ("Value_Size for& too small{, minimum allowed is ^}", gnat_attr_node, gnat_entity, old_size); return; } /* Otherwise, set the RM_Size. */ if (TREE_CODE (gnu_type) == INTEGER_TYPE && Is_Discrete_Or_Fixed_Point_Type (gnat_entity)) TYPE_RM_SIZE_NUM (gnu_type) = size; else if (TREE_CODE (gnu_type) == ENUMERAL_TYPE) TYPE_RM_SIZE_NUM (gnu_type) = size; else if ((TREE_CODE (gnu_type) == RECORD_TYPE || TREE_CODE (gnu_type) == UNION_TYPE || TREE_CODE (gnu_type) == QUAL_UNION_TYPE) && !TYPE_IS_FAT_POINTER_P (gnu_type)) SET_TYPE_ADA_SIZE (gnu_type, size); } /* Given a type TYPE, return a new type whose size is appropriate for SIZE. If TYPE is the best type, return it. Otherwise, make a new type. We only support new integral and pointer types. BIASED_P is nonzero if we are making a biased type. */ static tree make_type_from_size (tree type, tree size_tree, bool biased_p) { tree new_type; unsigned HOST_WIDE_INT size; bool unsigned_p; /* If size indicates an error, just return TYPE to avoid propagating the error. Likewise if it's too large to represent. */ if (!size_tree || !host_integerp (size_tree, 1)) return type; size = tree_low_cst (size_tree, 1); switch (TREE_CODE (type)) { case INTEGER_TYPE: case ENUMERAL_TYPE: /* Only do something if the type is not already the proper size and is not a packed array type. */ if (TYPE_PACKED_ARRAY_TYPE_P (type) || (TYPE_PRECISION (type) == size && biased_p == (TREE_CODE (type) == INTEGER_CST && TYPE_BIASED_REPRESENTATION_P (type)))) break; biased_p |= (TREE_CODE (type) == INTEGER_TYPE && TYPE_BIASED_REPRESENTATION_P (type)); unsigned_p = TYPE_UNSIGNED (type) || biased_p; size = MIN (size, LONG_LONG_TYPE_SIZE); new_type = unsigned_p ? make_unsigned_type (size) : make_signed_type (size); TREE_TYPE (new_type) = TREE_TYPE (type) ? TREE_TYPE (type) : type; TYPE_MIN_VALUE (new_type) = convert (TREE_TYPE (new_type), TYPE_MIN_VALUE (type)); TYPE_MAX_VALUE (new_type) = convert (TREE_TYPE (new_type), TYPE_MAX_VALUE (type)); TYPE_BIASED_REPRESENTATION_P (new_type) = biased_p; TYPE_RM_SIZE_NUM (new_type) = bitsize_int (size); return new_type; case RECORD_TYPE: /* Do something if this is a fat pointer, in which case we may need to return the thin pointer. */ if (TYPE_IS_FAT_POINTER_P (type) && size < POINTER_SIZE * 2) return build_pointer_type (TYPE_OBJECT_RECORD_TYPE (TYPE_UNCONSTRAINED_ARRAY (type))); break; case POINTER_TYPE: /* Only do something if this is a thin pointer, in which case we may need to return the fat pointer. */ if (TYPE_THIN_POINTER_P (type) && size >= POINTER_SIZE * 2) return build_pointer_type (TYPE_UNCONSTRAINED_ARRAY (TREE_TYPE (type))); break; default: break; } return type; } /* ALIGNMENT is a Uint giving the alignment specified for GNAT_ENTITY, a type or object whose present alignment is ALIGN. If this alignment is valid, return it. Otherwise, give an error and return ALIGN. */ static unsigned int validate_alignment (Uint alignment, Entity_Id gnat_entity, unsigned int align) { Node_Id gnat_error_node = gnat_entity; unsigned int new_align; unsigned int max_allowed_alignment = get_target_maximum_allowed_alignment (); if (Present (Alignment_Clause (gnat_entity))) gnat_error_node = Expression (Alignment_Clause (gnat_entity)); /* Don't worry about checking alignment if alignment was not specified by the source program and we already posted an error for this entity. */ if (Error_Posted (gnat_entity) && !Has_Alignment_Clause (gnat_entity)) return align; /* Within GCC, an alignment is an integer, so we must make sure a value is specified that fits in that range. Also, there is an upper bound to alignments we can support/allow. */ if (! UI_Is_In_Int_Range (alignment) || ((new_align = UI_To_Int (alignment)) > max_allowed_alignment)) post_error_ne_num ("largest supported alignment for& is ^", gnat_error_node, gnat_entity, max_allowed_alignment); else if (!(Present (Alignment_Clause (gnat_entity)) && From_At_Mod (Alignment_Clause (gnat_entity))) && new_align * BITS_PER_UNIT < align) post_error_ne_num ("alignment for& must be at least ^", gnat_error_node, gnat_entity, align / BITS_PER_UNIT); else align = MAX (align, new_align == 0 ? 1 : new_align * BITS_PER_UNIT); return align; } /* Verify that OBJECT, a type or decl, is something we can implement atomically. If not, give an error for GNAT_ENTITY. COMP_P is true if we require atomic components. */ static void check_ok_for_atomic (tree object, Entity_Id gnat_entity, bool comp_p) { Node_Id gnat_error_point = gnat_entity; Node_Id gnat_node; enum machine_mode mode; unsigned int align; tree size; /* There are three case of what OBJECT can be. It can be a type, in which case we take the size, alignment and mode from the type. It can be a declaration that was indirect, in which case the relevant values are that of the type being pointed to, or it can be a normal declaration, in which case the values are of the decl. The code below assumes that OBJECT is either a type or a decl. */ if (TYPE_P (object)) { mode = TYPE_MODE (object); align = TYPE_ALIGN (object); size = TYPE_SIZE (object); } else if (DECL_BY_REF_P (object)) { mode = TYPE_MODE (TREE_TYPE (TREE_TYPE (object))); align = TYPE_ALIGN (TREE_TYPE (TREE_TYPE (object))); size = TYPE_SIZE (TREE_TYPE (TREE_TYPE (object))); } else { mode = DECL_MODE (object); align = DECL_ALIGN (object); size = DECL_SIZE (object); } /* Consider all floating-point types atomic and any types that that are represented by integers no wider than a machine word. */ if (GET_MODE_CLASS (mode) == MODE_FLOAT || ((GET_MODE_CLASS (mode) == MODE_INT || GET_MODE_CLASS (mode) == MODE_PARTIAL_INT) && GET_MODE_BITSIZE (mode) <= BITS_PER_WORD)) return; /* For the moment, also allow anything that has an alignment equal to its size and which is smaller than a word. */ if (size && TREE_CODE (size) == INTEGER_CST && compare_tree_int (size, align) == 0 && align <= BITS_PER_WORD) return; for (gnat_node = First_Rep_Item (gnat_entity); Present (gnat_node); gnat_node = Next_Rep_Item (gnat_node)) { if (!comp_p && Nkind (gnat_node) == N_Pragma && Get_Pragma_Id (Chars (gnat_node)) == Pragma_Atomic) gnat_error_point = First (Pragma_Argument_Associations (gnat_node)); else if (comp_p && Nkind (gnat_node) == N_Pragma && (Get_Pragma_Id (Chars (gnat_node)) == Pragma_Atomic_Components)) gnat_error_point = First (Pragma_Argument_Associations (gnat_node)); } if (comp_p) post_error_ne ("atomic access to component of & cannot be guaranteed", gnat_error_point, gnat_entity); else post_error_ne ("atomic access to & cannot be guaranteed", gnat_error_point, gnat_entity); } /* Check if FTYPE1 and FTYPE2, two potentially different function type nodes, have compatible signatures so that a call using one type may be safely issued if the actual target function type is the other. Return 1 if it is the case, 0 otherwise, and post errors on the incompatibilities. This is used when an Ada subprogram is mapped onto a GCC builtin, to ensure that calls to the subprogram will have arguments suitable for the later underlying builtin expansion. */ static int compatible_signatures_p (tree ftype1, tree ftype2) { /* As of now, we only perform very trivial tests and consider it's the programmer's responsibility to ensure the type correctness in the Ada declaration, as in the regular Import cases. Mismatches typically result in either error messages from the builtin expander, internal compiler errors, or in a real call sequence. This should be refined to issue diagnostics helping error detection and correction. */ /* Almost fake test, ensuring a use of each argument. */ if (ftype1 == ftype2) return 1; return 1; } /* Given a type T, a FIELD_DECL F, and a replacement value R, return a new type with all size expressions that contain F updated by replacing F with R. If F is NULL_TREE, always make a new RECORD_TYPE, even if nothing has changed. */ tree substitute_in_type (tree t, tree f, tree r) { tree new = t; tree tem; switch (TREE_CODE (t)) { case INTEGER_TYPE: case ENUMERAL_TYPE: case BOOLEAN_TYPE: if (CONTAINS_PLACEHOLDER_P (TYPE_MIN_VALUE (t)) || CONTAINS_PLACEHOLDER_P (TYPE_MAX_VALUE (t))) { tree low = SUBSTITUTE_IN_EXPR (TYPE_MIN_VALUE (t), f, r); tree high = SUBSTITUTE_IN_EXPR (TYPE_MAX_VALUE (t), f, r); if (low == TYPE_MIN_VALUE (t) && high == TYPE_MAX_VALUE (t)) return t; new = build_range_type (TREE_TYPE (t), low, high); if (TYPE_INDEX_TYPE (t)) SET_TYPE_INDEX_TYPE (new, substitute_in_type (TYPE_INDEX_TYPE (t), f, r)); return new; } return t; case REAL_TYPE: if (CONTAINS_PLACEHOLDER_P (TYPE_MIN_VALUE (t)) || CONTAINS_PLACEHOLDER_P (TYPE_MAX_VALUE (t))) { tree low = NULL_TREE, high = NULL_TREE; if (TYPE_MIN_VALUE (t)) low = SUBSTITUTE_IN_EXPR (TYPE_MIN_VALUE (t), f, r); if (TYPE_MAX_VALUE (t)) high = SUBSTITUTE_IN_EXPR (TYPE_MAX_VALUE (t), f, r); if (low == TYPE_MIN_VALUE (t) && high == TYPE_MAX_VALUE (t)) return t; t = copy_type (t); TYPE_MIN_VALUE (t) = low; TYPE_MAX_VALUE (t) = high; } return t; case COMPLEX_TYPE: tem = substitute_in_type (TREE_TYPE (t), f, r); if (tem == TREE_TYPE (t)) return t; return build_complex_type (tem); case OFFSET_TYPE: case METHOD_TYPE: case FUNCTION_TYPE: case LANG_TYPE: /* Don't know how to do these yet. */ gcc_unreachable (); case ARRAY_TYPE: { tree component = substitute_in_type (TREE_TYPE (t), f, r); tree domain = substitute_in_type (TYPE_DOMAIN (t), f, r); if (component == TREE_TYPE (t) && domain == TYPE_DOMAIN (t)) return t; new = build_array_type (component, domain); TYPE_SIZE (new) = 0; TYPE_MULTI_ARRAY_P (new) = TYPE_MULTI_ARRAY_P (t); TYPE_CONVENTION_FORTRAN_P (new) = TYPE_CONVENTION_FORTRAN_P (t); layout_type (new); TYPE_ALIGN (new) = TYPE_ALIGN (t); TYPE_USER_ALIGN (new) = TYPE_USER_ALIGN (t); /* If we had bounded the sizes of T by a constant, bound the sizes of NEW by the same constant. */ if (TREE_CODE (TYPE_SIZE (t)) == MIN_EXPR) TYPE_SIZE (new) = size_binop (MIN_EXPR, TREE_OPERAND (TYPE_SIZE (t), 1), TYPE_SIZE (new)); if (TREE_CODE (TYPE_SIZE_UNIT (t)) == MIN_EXPR) TYPE_SIZE_UNIT (new) = size_binop (MIN_EXPR, TREE_OPERAND (TYPE_SIZE_UNIT (t), 1), TYPE_SIZE_UNIT (new)); return new; } case RECORD_TYPE: case UNION_TYPE: case QUAL_UNION_TYPE: { tree field; bool changed_field = (f == NULL_TREE && !TREE_CONSTANT (TYPE_SIZE (t))); bool field_has_rep = false; tree last_field = NULL_TREE; tree new = copy_type (t); /* Start out with no fields, make new fields, and chain them in. If we haven't actually changed the type of any field, discard everything we've done and return the old type. */ TYPE_FIELDS (new) = NULL_TREE; TYPE_SIZE (new) = NULL_TREE; for (field = TYPE_FIELDS (t); field; field = TREE_CHAIN (field)) { tree new_field = copy_node (field); TREE_TYPE (new_field) = substitute_in_type (TREE_TYPE (new_field), f, r); if (DECL_HAS_REP_P (field) && !DECL_INTERNAL_P (field)) field_has_rep = true; else if (TREE_TYPE (new_field) != TREE_TYPE (field)) changed_field = true; /* If this is an internal field and the type of this field is a UNION_TYPE or RECORD_TYPE with no elements, ignore it. If the type just has one element, treat that as the field. But don't do this if we are processing a QUAL_UNION_TYPE. */ if (TREE_CODE (t) != QUAL_UNION_TYPE && DECL_INTERNAL_P (new_field) && (TREE_CODE (TREE_TYPE (new_field)) == UNION_TYPE || TREE_CODE (TREE_TYPE (new_field)) == RECORD_TYPE)) { if (!TYPE_FIELDS (TREE_TYPE (new_field))) continue; if (!TREE_CHAIN (TYPE_FIELDS (TREE_TYPE (new_field)))) { tree next_new_field = copy_node (TYPE_FIELDS (TREE_TYPE (new_field))); /* Make sure omitting the union doesn't change the layout. */ DECL_ALIGN (next_new_field) = DECL_ALIGN (new_field); new_field = next_new_field; } } DECL_CONTEXT (new_field) = new; SET_DECL_ORIGINAL_FIELD (new_field, (DECL_ORIGINAL_FIELD (field) ? DECL_ORIGINAL_FIELD (field) : field)); /* If the size of the old field was set at a constant, propagate the size in case the type's size was variable. (This occurs in the case of a variant or discriminated record with a default size used as a field of another record.) */ DECL_SIZE (new_field) = TREE_CODE (DECL_SIZE (field)) == INTEGER_CST ? DECL_SIZE (field) : NULL_TREE; DECL_SIZE_UNIT (new_field) = TREE_CODE (DECL_SIZE_UNIT (field)) == INTEGER_CST ? DECL_SIZE_UNIT (field) : NULL_TREE; if (TREE_CODE (t) == QUAL_UNION_TYPE) { tree new_q = SUBSTITUTE_IN_EXPR (DECL_QUALIFIER (field), f, r); if (new_q != DECL_QUALIFIER (new_field)) changed_field = true; /* Do the substitution inside the qualifier and if we find that this field will not be present, omit it. */ DECL_QUALIFIER (new_field) = new_q; if (integer_zerop (DECL_QUALIFIER (new_field))) continue; } if (!last_field) TYPE_FIELDS (new) = new_field; else TREE_CHAIN (last_field) = new_field; last_field = new_field; /* If this is a qualified type and this field will always be present, we are done. */ if (TREE_CODE (t) == QUAL_UNION_TYPE && integer_onep (DECL_QUALIFIER (new_field))) break; } /* If this used to be a qualified union type, but we now know what field will be present, make this a normal union. */ if (changed_field && TREE_CODE (new) == QUAL_UNION_TYPE && (!TYPE_FIELDS (new) || integer_onep (DECL_QUALIFIER (TYPE_FIELDS (new))))) TREE_SET_CODE (new, UNION_TYPE); else if (!changed_field) return t; gcc_assert (!field_has_rep); layout_type (new); /* If the size was originally a constant use it. */ if (TYPE_SIZE (t) && TREE_CODE (TYPE_SIZE (t)) == INTEGER_CST && TREE_CODE (TYPE_SIZE (new)) != INTEGER_CST) { TYPE_SIZE (new) = TYPE_SIZE (t); TYPE_SIZE_UNIT (new) = TYPE_SIZE_UNIT (t); SET_TYPE_ADA_SIZE (new, TYPE_ADA_SIZE (t)); } return new; } default: return t; } } /* Return the "RM size" of GNU_TYPE. This is the actual number of bits needed to represent the object. */ tree rm_size (tree gnu_type) { /* For integer types, this is the precision. For record types, we store the size explicitly. For other types, this is just the size. */ if (INTEGRAL_TYPE_P (gnu_type) && TYPE_RM_SIZE (gnu_type)) return TYPE_RM_SIZE (gnu_type); else if (TREE_CODE (gnu_type) == RECORD_TYPE && TYPE_CONTAINS_TEMPLATE_P (gnu_type)) /* Return the rm_size of the actual data plus the size of the template. */ return size_binop (PLUS_EXPR, rm_size (TREE_TYPE (TREE_CHAIN (TYPE_FIELDS (gnu_type)))), DECL_SIZE (TYPE_FIELDS (gnu_type))); else if ((TREE_CODE (gnu_type) == RECORD_TYPE || TREE_CODE (gnu_type) == UNION_TYPE || TREE_CODE (gnu_type) == QUAL_UNION_TYPE) && !TYPE_IS_FAT_POINTER_P (gnu_type) && TYPE_ADA_SIZE (gnu_type)) return TYPE_ADA_SIZE (gnu_type); else return TYPE_SIZE (gnu_type); } /* Return an identifier representing the external name to be used for GNAT_ENTITY. If SUFFIX is specified, the name is followed by "___" and the specified suffix. */ tree create_concat_name (Entity_Id gnat_entity, const char *suffix) { Entity_Kind kind = Ekind (gnat_entity); const char *str = (!suffix ? "" : suffix); String_Template temp = {1, strlen (str)}; Fat_Pointer fp = {str, &temp}; Get_External_Name_With_Suffix (gnat_entity, fp); /* A variable using the Stdcall convention (meaning we are running on a Windows box) live in a DLL. Here we adjust its name to use the jump-table, the _imp__NAME contains the address for the NAME variable. */ if ((kind == E_Variable || kind == E_Constant) && Has_Stdcall_Convention (gnat_entity)) { const char *prefix = "_imp__"; int k, plen = strlen (prefix); for (k = 0; k <= Name_Len; k++) Name_Buffer [Name_Len - k + plen] = Name_Buffer [Name_Len - k]; strncpy (Name_Buffer, prefix, plen); } return get_identifier (Name_Buffer); } /* Return the name to be used for GNAT_ENTITY. If a type, create a fully-qualified name, possibly with type information encoding. Otherwise, return the name. */ tree get_entity_name (Entity_Id gnat_entity) { Get_Encoded_Name (gnat_entity); return get_identifier (Name_Buffer); } /* Given GNU_ID, an IDENTIFIER_NODE containing a name and SUFFIX, a string, return a new IDENTIFIER_NODE that is the concatenation of the name in GNU_ID and SUFFIX. */ tree concat_id_with_name (tree gnu_id, const char *suffix) { int len = IDENTIFIER_LENGTH (gnu_id); strncpy (Name_Buffer, IDENTIFIER_POINTER (gnu_id), IDENTIFIER_LENGTH (gnu_id)); strncpy (Name_Buffer + len, "___", 3); len += 3; strcpy (Name_Buffer + len, suffix); return get_identifier (Name_Buffer); } #include "gt-ada-decl.h"