------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- A T R E E -- -- -- -- S p e c -- -- -- -- Copyright (C) 1992-2013, 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 3, 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. -- -- -- -- As a special exception under Section 7 of GPL version 3, you are granted -- -- additional permissions described in the GCC Runtime Library Exception, -- -- version 3.1, as published by the Free Software Foundation. -- -- -- -- You should have received a copy of the GNU General Public License and -- -- a copy of the GCC Runtime Library Exception along with this program; -- -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see -- -- . -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ with Alloc; with Sinfo; use Sinfo; with Einfo; use Einfo; with Namet; use Namet; with Types; use Types; with Snames; use Snames; with System; use System; with Table; with Uintp; use Uintp; with Urealp; use Urealp; with Unchecked_Conversion; package Atree is -- This package defines the format of the tree used to represent the Ada -- program internally. Syntactic and semantic information is combined in -- this tree. There is no separate symbol table structure. -- WARNING: There is a C version of this package. Any changes to this source -- file must be properly reflected in the C header file atree.h -- Package Atree defines the basic structure of the tree and its nodes and -- provides the basic abstract interface for manipulating the tree. Two other -- packages use this interface to define the representation of Ada programs -- using this tree format. The package Sinfo defines the basic representation -- of the syntactic structure of the program, as output by the parser. The -- package Einfo defines the semantic information which is added to the tree -- nodes that represent declared entities (i.e. the information which might -- typically be described in a separate symbol table structure). -- The front end of the compiler first parses the program and generates a -- tree that is simply a syntactic representation of the program in abstract -- syntax tree format. Subsequent processing in the front end traverses the -- tree, transforming it in various ways and adding semantic information. ---------------------- -- Size of Entities -- ---------------------- -- Currently entities are composed of 6 sequentially allocated 32-byte -- nodes, considered as a single record. The following definition gives -- the number of extension nodes. Num_Extension_Nodes : Node_Id := 5; -- This value is increased by one if debug flag -gnatd.N is set. This is -- for testing performance impact of adding a new extension node. We make -- this of type Node_Id for easy reference in loops using this value. ---------------------------------------- -- Definitions of Fields in Tree Node -- ---------------------------------------- -- The representation of the tree is completely hidden, using a functional -- interface for accessing and modifying the contents of nodes. Logically -- a node contains a number of fields, much as though the nodes were -- defined as a record type. The fields in a node are as follows: -- Nkind Indicates the kind of the node. This field is present -- in all nodes. The type is Node_Kind, which is declared -- in the package Sinfo. -- Sloc Location (Source_Ptr) of the corresponding token -- in the Source buffer. The individual node definitions -- show which token is referenced by this pointer. -- In_List A flag used to indicate if the node is a member -- of a node list. -- Rewrite_Ins A flag set if a node is marked as a rewrite inserted -- node as a result of a call to Mark_Rewrite_Insertion. -- Paren_Count A 2-bit count used in sub-expression nodes to indicate -- the level of parentheses. The settings are 0,1,2 and -- 3 for many. If the value is 3, then an auxiliary table -- is used to indicate the real value. Set to zero for -- non-subexpression nodes. -- Note: the required parentheses surrounding conditional -- and quantified expressions count as a level of parens -- for this purpose, so e.g. in X := (if A then B else C); -- Paren_Count for the right side will be 1. -- Comes_From_Source -- This flag is present in all nodes. It is set if the -- node is built by the scanner or parser, and clear if -- the node is built by the analyzer or expander. It -- indicates that the node corresponds to a construct -- that appears in the original source program. -- Analyzed This flag is present in all nodes. It is set when -- a node is analyzed, and is used to avoid analyzing -- the same node twice. Analysis includes expansion if -- expansion is active, so in this case if the flag is -- set it means the node has been analyzed and expanded. -- Error_Posted This flag is present in all nodes. It is set when -- an error message is posted which is associated with -- the flagged node. This is used to avoid posting more -- than one message on the same node. -- Field1 -- Field2 -- Field3 -- Field4 -- Field5 Five fields holding Union_Id values -- ElistN Synonym for FieldN typed as Elist_Id (Empty = No_Elist) -- ListN Synonym for FieldN typed as List_Id -- NameN Synonym for FieldN typed as Name_Id -- NodeN Synonym for FieldN typed as Node_Id -- StrN Synonym for FieldN typed as String_Id -- UintN Synonym for FieldN typed as Uint (Empty = Uint_0) -- UrealN Synonym for FieldN typed as Ureal -- Note: in the case of ElistN and UintN fields, it is common that we -- end up with a value of Union_Id'(0) as the default value. This value -- is meaningless as a Uint or Elist_Id value. We have two choices here. -- We could require that all Uint and Elist fields be initialized to an -- appropriate value, but that's error prone, since it would be easy to -- miss an initialization. So instead we have the retrieval functions -- generate an appropriate default value (Uint_0 or No_Elist). Probably -- it would be cleaner to generate No_Uint in the Uint case but we got -- stuck with representing an "unset" size value as zero early on, and -- it will take a bit of fiddling to change that ??? -- Note: the actual usage of FieldN (i.e. whether it contains a Elist_Id, -- List_Id, Name_Id, Node_Id, String_Id, Uint or Ureal) depends on the -- value in Nkind. Generally the access to this field is always via the -- functional interface, so the field names ElistN, ListN, NameN, NodeN, -- StrN, UintN and UrealN are used only in the bodies of the access -- functions (i.e. in the bodies of Sinfo and Einfo). These access -- functions contain debugging code that checks that the use is -- consistent with Nkind and Ekind values. -- However, in specialized circumstances (examples are the circuit in -- generic instantiation to copy trees, and in the tree dump routine), -- it is useful to be able to do untyped traversals, and an internal -- package in Atree allows for direct untyped accesses in such cases. -- Flag0 Nineteen Boolean flags (use depends on Nkind and -- Flag1 Ekind, as described for FieldN). Again the access -- Flag2 is usually via subprograms in Sinfo and Einfo which -- Flag3 provide high-level synonyms for these flags, and -- Flag4 contain debugging code that checks that the values -- Flag5 in Nkind and Ekind are appropriate for the access. -- Flag6 -- Flag7 -- Flag8 -- Flag9 -- Flag10 -- Flag11 Note that Flag0-3 are stored separately in the Flags -- Flag12 table, but that's a detail of the implementation which -- Flag13 is entirely hidden by the funcitonal interface. -- Flag14 -- Flag15 -- Flag16 -- Flag17 -- Flag18 -- Link For a node, points to the Parent. For a list, points -- to the list header. Note that in the latter case, a -- client cannot modify the link field. This field is -- private to the Atree package (but is also modified -- by the Nlists package). -- The following additional fields are present in extended nodes used -- for entities (Nkind in N_Entity). -- Ekind Entity type. This field indicates the type of the -- entity, it is of type Entity_Kind which is defined -- in package Einfo. -- Flag19 299 additional flags -- ... -- Flag317 -- Convention Entity convention (Convention_Id value) -- Field6 Additional Union_Id value stored in tree -- Node6 Synonym for Field6 typed as Node_Id -- Elist6 Synonym for Field6 typed as Elist_Id (Empty = No_Elist) -- Uint6 Synonym for Field6 typed as Uint (Empty = Uint_0) -- Similar definitions for Field7 to Field35 (and also Node7-Node35, -- Elist7-Elist35, Uint7-Uint35, Ureal7-Ureal35). Note that not all -- these functions are defined, only the ones that are actually used. function Last_Node_Id return Node_Id; pragma Inline (Last_Node_Id); -- Returns Id of last allocated node Id function Nodes_Address return System.Address; -- Return address of Nodes table (used in Back_End for Gigi call) function Flags_Address return System.Address; -- Return address of Flags table (used in Back_End for Gigi call) function Num_Nodes return Nat; -- Total number of nodes allocated, where an entity counts as a single -- node. This count is incremented every time a node or entity is -- allocated, and decremented every time a node or entity is deleted. -- This value is used by Xref and by Treepr to allocate hash tables of -- suitable size for hashing Node_Id values. ----------------------- -- Use of Empty Node -- ----------------------- -- The special Node_Id Empty is used to mark missing fields. Whenever the -- syntax has an optional component, then the corresponding field will be -- set to Empty if the component is missing. -- Note: Empty is not used to describe an empty list. Instead in this -- case the node field contains a list which is empty, and these cases -- should be distinguished (essentially from a type point of view, Empty -- is a Node, and is thus not a list). -- Note: Empty does in fact correspond to an allocated node. Only the -- Nkind field of this node may be referenced. It contains N_Empty, which -- uniquely identifies the empty case. This allows the Nkind field to be -- dereferenced before the check for Empty which is sometimes useful. ----------------------- -- Use of Error Node -- ----------------------- -- The Error node is used during syntactic and semantic analysis to -- indicate that the corresponding piece of syntactic structure or -- semantic meaning cannot properly be represented in the tree because -- of an illegality in the program. -- If an Error node is encountered, then you know that a previous -- illegality has been detected. The proper reaction should be to -- avoid posting related cascaded error messages, and to propagate -- the error node if necessary. ------------------------ -- Current_Error_Node -- ------------------------ -- The current error node is a global location indicating the current -- node that is being processed for the purposes of placing a compiler -- abort message. This is not necessarily perfectly accurate, it is -- just a reasonably accurate best guess. It is used to output the -- source location in the abort message by Comperr, and also to -- implement the d3 debugging flag. This is also used by Rtsfind -- to generate error messages for high integrity mode. -- There are two ways this gets set. During parsing, when new source -- nodes are being constructed by calls to New_Node and New_Entity, -- either one of these calls sets Current_Error_Node to the newly -- created node. During semantic analysis, this mechanism is not -- used, and instead Current_Error_Node is set by the subprograms in -- Debug_A that mark the start and end of analysis/expansion of a -- node in the tree. Current_Error_Node : Node_Id; -- Node to place error messages ------------------ -- Error Counts -- ------------------ -- The following variables denote the count of errors of various kinds -- detected in the tree. Note that these might be more logically located -- in Err_Vars, but we put it to deal with licensing issues (we need this -- to have the GPL exception licensing, since Check_Error_Detected can -- be called from units with this licensing). Serious_Errors_Detected : Nat := 0; -- This is a count of errors that are serious enough to stop expansion, -- and hence to prevent generation of an object file even if the -- switch -gnatQ is set. Initialized to zero at the start of compilation. -- Initialized for -gnatVa use, see comment above. Total_Errors_Detected : Nat := 0; -- Number of errors detected so far. Includes count of serious errors and -- non-serious errors, so this value is always greater than or equal to the -- Serious_Errors_Detected value. Initialized to zero at the start of -- compilation. Initialized for -gnatVa use, see comment above. Warnings_Detected : Nat := 0; -- Number of warnings detected. Initialized to zero at the start of -- compilation. Initialized for -gnatVa use, see comment above. Warnings_Treated_As_Errors : Nat := 0; -- Number of warnings changed into errors as a result of matching a pattern -- given in a Warning_As_Error configuration pragma. Configurable_Run_Time_Violations : Nat := 0; -- Count of configurable run time violations so far. This is used to -- suppress certain cascaded error messages when we know that we may not -- have fully expanded some items, due to high integrity violations (e.g. -- the use of constructs not permitted by the library in use, or improper -- constructs in No_Run_Time mode). procedure Check_Error_Detected; -- When an anomaly is found in the tree, many semantic routines silently -- bail out, assuming that the anomaly was caused by a previously detected -- serious error (or configurable run time violation). This routine should -- be called in these cases, and will raise an exception if no such error -- has been detected. This ensure that the anomaly is never allowed to go -- unnoticed. ------------------------------- -- Default Setting of Fields -- ------------------------------- -- Nkind is set to N_Unused_At_Start -- Ekind is set to E_Void -- Sloc is always set, there is no default value -- Field1-5 fields are set to Empty -- Field6-35 fields in extended nodes are set to Empty -- Parent is set to Empty -- All Boolean flag fields are set to False -- Note: the value Empty is used in Field1-Field35 to indicate a null node. -- The usage varies. The common uses are to indicate absence of an optional -- clause or a completely unused Field1-35 field. ------------------------------------- -- Use of Synonyms for Node Fields -- ------------------------------------- -- A subpackage Atree.Unchecked_Access provides routines for reading and -- writing the fields defined above (Field1-35, Node1-35, Flag0-317 etc). -- These unchecked access routines can be used for untyped traversals. -- In addition they are used in the implementations of the Sinfo and -- Einfo packages. These packages both provide logical synonyms for -- the generic fields, together with an appropriate set of access routines. -- Normally access to information within tree nodes uses these synonyms, -- providing a high level typed interface to the tree information. -------------------------------------------------- -- Node Allocation and Modification Subprograms -- -------------------------------------------------- -- Generally the parser builds the tree and then it is further decorated -- (e.g. by setting the entity fields), but not fundamentally modified. -- However, there are cases in which the tree must be restructured by -- adding and rearranging nodes, as a result of disambiguating cases -- which the parser could not parse correctly, and adding additional -- semantic information (e.g. making constraint checks explicit). The -- following subprograms are used for constructing the tree in the first -- place, and then for subsequent modifications as required. procedure Initialize; -- Called at the start of compilation to initialize the allocation of -- the node and list tables and make the standard entries for Empty, -- Error and Error_List. Note that Initialize must not be called if -- Tree_Read is used. procedure Lock; -- Called before the back end is invoked to lock the nodes table -- Also called after Unlock to relock??? procedure Unlock; -- Unlocks nodes table, in cases where the back end needs to modify it procedure Tree_Read; -- Initializes internal tables from current tree file using the relevant -- Table.Tree_Read routines. Note that Initialize should not be called if -- Tree_Read is used. Tree_Read includes all necessary initialization. procedure Tree_Write; -- Writes out internal tables to current tree file using the relevant -- Table.Tree_Write routines. function New_Node (New_Node_Kind : Node_Kind; New_Sloc : Source_Ptr) return Node_Id; -- Allocates a completely new node with the given node type and source -- location values. All other fields are set to their standard defaults: -- -- Empty for all FieldN fields -- False for all FlagN fields -- -- The usual approach is to build a new node using this function and -- then, using the value returned, use the Set_xxx functions to set -- fields of the node as required. New_Node can only be used for -- non-entity nodes, i.e. it never generates an extended node. -- -- If we are currently parsing, as indicated by a previous call to -- Set_Comes_From_Source_Default (True), then this call also resets -- the value of Current_Error_Node. function New_Entity (New_Node_Kind : Node_Kind; New_Sloc : Source_Ptr) return Entity_Id; -- Similar to New_Node, except that it is used only for entity nodes -- and returns an extended node. procedure Set_Comes_From_Source_Default (Default : Boolean); -- Sets value of Comes_From_Source flag to be used in all subsequent -- New_Node and New_Entity calls until another call to this procedure -- changes the default. This value is set True during parsing and -- False during semantic analysis. This is also used to determine -- if New_Node and New_Entity should set Current_Error_Node. function Get_Comes_From_Source_Default return Boolean; pragma Inline (Get_Comes_From_Source_Default); -- Gets the current value of the Comes_From_Source flag procedure Preserve_Comes_From_Source (NewN, OldN : Node_Id); pragma Inline (Preserve_Comes_From_Source); -- When a node is rewritten, it is sometimes appropriate to preserve the -- original comes from source indication. This is true when the rewrite -- essentially corresponds to a transformation corresponding exactly to -- semantics in the reference manual. This procedure copies the setting -- of Comes_From_Source from OldN to NewN. function Has_Extension (N : Node_Id) return Boolean; pragma Inline (Has_Extension); -- Returns True if the given node has an extension (i.e. was created by -- a call to New_Entity rather than New_Node, and Nkind is in N_Entity) procedure Change_Node (N : Node_Id; New_Node_Kind : Node_Kind); -- This procedure replaces the given node by setting its Nkind field to -- the indicated value and resetting all other fields to their default -- values except for Sloc, which is unchanged, and the Parent pointer -- and list links, which are also unchanged. All other information in -- the original node is lost. The new node has an extension if the -- original node had an extension. procedure Copy_Node (Source : Node_Id; Destination : Node_Id); -- Copy the entire contents of the source node to the destination node. -- The contents of the source node is not affected. If the source node -- has an extension, then the destination must have an extension also. -- The parent pointer of the destination and its list link, if any, are -- not affected by the copy. Note that parent pointers of descendents -- are not adjusted, so the descendents of the destination node after -- the Copy_Node is completed have dubious parent pointers. Note that -- this routine does NOT copy aspect specifications, the Has_Aspects -- flag in the returned node will always be False. The caller must deal -- with copying aspect specifications where this is required. function New_Copy (Source : Node_Id) return Node_Id; -- This function allocates a completely new node, and then initializes -- it by copying the contents of the source node into it. The contents of -- the source node is not affected. The target node is always marked as -- not being in a list (even if the source is a list member), and not -- overloaded. The new node will have an extension if the source has -- an extension. New_Copy (Empty) returns Empty, and New_Copy (Error) -- returns Error. Note that, unlike Copy_Separate_Tree, New_Copy does not -- recursively copy any descendents, so in general parent pointers are not -- set correctly for the descendents of the copied node. Both normal and -- extended nodes (entities) may be copied using New_Copy. function Relocate_Node (Source : Node_Id) return Node_Id; -- Source is a non-entity node that is to be relocated. A new node is -- allocated, and the contents of Source are copied to this node, using -- New_Copy. The parent pointers of descendents of the node are then -- adjusted to point to the relocated copy. The original node is not -- modified, but the parent pointers of its descendents are no longer -- valid. The new copy is always marked as not overloaded. This routine is -- used in conjunction with the tree rewrite routines (see descriptions of -- Replace/Rewrite). -- -- Note that the resulting node has the same parent as the source node, and -- is thus still attached to the tree. It is valid for Source to be Empty, -- in which case Relocate_Node simply returns Empty as the result. function Copy_Separate_Tree (Source : Node_Id) return Node_Id; -- Given a node that is the root of a subtree, Copy_Separate_Tree copies -- the entire syntactic subtree, including recursively any descendants -- whose parent field references a copied node (descendants not linked to -- a copied node by the parent field are also copied.) The parent pointers -- in the copy are properly set. Copy_Separate_Tree (Empty/Error) returns -- Empty/Error. The new subtree does not share entities with the source, -- but has new entities with the same name. -- -- Most of the time this routine is called on an unanalyzed tree, and no -- semantic information is copied. However, to ensure that no entities -- are shared between the two when the source is already analyzed, and -- that the result looks like an unanalyzed tree from the parser, Entity -- fields and Etype fields are set to Empty, and Analyzed flags set False. -- -- In addition, Expanded_Name nodes are converted back into the original -- parser form (where they are Selected_Components), so that reanalysis -- does the right thing. function Copy_Separate_List (Source : List_Id) return List_Id; -- Applies Copy_Separate_Tree to each element of the Source list, returning -- a new list of the results of these copy operations. procedure Exchange_Entities (E1 : Entity_Id; E2 : Entity_Id); -- Exchange the contents of two entities. The parent pointers are switched -- as well as the Defining_Identifier fields in the parents, so that the -- entities point correctly to their original parents. The effect is thus -- to leave the tree completely unchanged in structure, except that the -- entity ID values of the two entities are interchanged. Neither of the -- two entities may be list members. Note that entities appear on two -- semantic chains: Homonym and Next_Entity: the corresponding links must -- be adjusted by the caller, according to context. function Extend_Node (Node : Node_Id) return Entity_Id; -- This function returns a copy of its input node with an extension added. -- The fields of the extension are set to Empty. Due to the way extensions -- are handled (as four consecutive array elements), it may be necessary -- to reallocate the node, so that the returned value is not the same as -- the input value, but where possible the returned value will be the same -- as the input value (i.e. the extension will occur in place). It is the -- caller's responsibility to ensure that any pointers to the original node -- are appropriately updated. This function is used only by Sinfo.CN to -- change nodes into their corresponding entities. type Report_Proc is access procedure (Target : Node_Id; Source : Node_Id); procedure Set_Reporting_Proc (P : Report_Proc); -- Register a procedure that is invoked when a node is allocated, replaced -- or rewritten. type Traverse_Result is (Abandon, OK, OK_Orig, Skip); -- This is the type of the result returned by the Process function passed -- to Traverse_Func and Traverse_Proc. See below for details. subtype Traverse_Final_Result is Traverse_Result range Abandon .. OK; -- This is the type of the final result returned Traverse_Func, based on -- the results of Process calls. See below for details. generic with function Process (N : Node_Id) return Traverse_Result is <>; function Traverse_Func (Node : Node_Id) return Traverse_Final_Result; -- This is a generic function that, given the parent node for a subtree, -- traverses all syntactic nodes of this tree, calling the given function -- Process on each one, in pre order (i.e. top-down). The order of -- traversing subtrees is arbitrary. The traversal is controlled as follows -- by the result returned by Process: -- OK The traversal continues normally with the syntactic -- children of the node just processed. -- OK_Orig The traversal continues normally with the syntactic -- children of the original node of the node just processed. -- Skip The children of the node just processed are skipped and -- excluded from the traversal, but otherwise processing -- continues elsewhere in the tree. -- Abandon The entire traversal is immediately abandoned, and the -- original call to Traverse returns Abandon. -- The result returned by Traverse is Abandon if processing was terminated -- by a call to Process returning Abandon, otherwise it is OK (meaning that -- all calls to process returned either OK, OK_Orig, or Skip). generic with function Process (N : Node_Id) return Traverse_Result is <>; procedure Traverse_Proc (Node : Node_Id); pragma Inline (Traverse_Proc); -- This is the same as Traverse_Func except that no result is returned, -- i.e. Traverse_Func is called and the result is simply discarded. --------------------------- -- Node Access Functions -- --------------------------- -- The following functions return the contents of the indicated field of -- the node referenced by the argument, which is a Node_Id. function Nkind (N : Node_Id) return Node_Kind; pragma Inline (Nkind); function Analyzed (N : Node_Id) return Boolean; pragma Inline (Analyzed); function Has_Aspects (N : Node_Id) return Boolean; pragma Inline (Has_Aspects); function Comes_From_Source (N : Node_Id) return Boolean; pragma Inline (Comes_From_Source); function Error_Posted (N : Node_Id) return Boolean; pragma Inline (Error_Posted); function Sloc (N : Node_Id) return Source_Ptr; pragma Inline (Sloc); function Paren_Count (N : Node_Id) return Nat; pragma Inline (Paren_Count); function Parent (N : Node_Id) return Node_Id; pragma Inline (Parent); -- Returns the parent of a node if the node is not a list member, or else -- the parent of the list containing the node if the node is a list member. function No (N : Node_Id) return Boolean; pragma Inline (No); -- Tests given Id for equality with the Empty node. This allows notations -- like "if No (Variant_Part)" as opposed to "if Variant_Part = Empty". function Present (N : Node_Id) return Boolean; pragma Inline (Present); -- Tests given Id for inequality with the Empty node. This allows notations -- like "if Present (Statement)" as opposed to "if Statement /= Empty". --------------------- -- Node_Kind Tests -- --------------------- -- These are like the functions in Sinfo, but the first argument is a -- Node_Id, and the tested field is Nkind (N). function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind; V5 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind; V5 : Node_Kind; V6 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind; V5 : Node_Kind; V6 : Node_Kind; V7 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind; V5 : Node_Kind; V6 : Node_Kind; V7 : Node_Kind; V8 : Node_Kind) return Boolean; function Nkind_In (N : Node_Id; V1 : Node_Kind; V2 : Node_Kind; V3 : Node_Kind; V4 : Node_Kind; V5 : Node_Kind; V6 : Node_Kind; V7 : Node_Kind; V8 : Node_Kind; V9 : Node_Kind) return Boolean; pragma Inline (Nkind_In); -- Inline all above functions ----------------------- -- Entity_Kind_Tests -- ----------------------- -- Utility functions to test whether an Entity_Kind value, either given -- directly as the first argument, or the Ekind field of an Entity give -- as the first argument, matches any of the given list of Entity_Kind -- values. Return True if any match, False if no match. function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind; V7 : Entity_Kind) return Boolean; function Ekind_In (E : Entity_Id; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind; V7 : Entity_Kind; V8 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind; V7 : Entity_Kind) return Boolean; function Ekind_In (T : Entity_Kind; V1 : Entity_Kind; V2 : Entity_Kind; V3 : Entity_Kind; V4 : Entity_Kind; V5 : Entity_Kind; V6 : Entity_Kind; V7 : Entity_Kind; V8 : Entity_Kind) return Boolean; pragma Inline (Ekind_In); -- Inline all above functions ----------------------------- -- Entity Access Functions -- ----------------------------- -- The following functions apply only to Entity_Id values, i.e. -- to extended nodes. function Ekind (E : Entity_Id) return Entity_Kind; pragma Inline (Ekind); function Convention (E : Entity_Id) return Convention_Id; pragma Inline (Convention); ---------------------------- -- Node Update Procedures -- ---------------------------- -- The following functions set a specified field in the node whose Id is -- passed as the first argument. The second parameter is the new value -- to be set in the specified field. Note that Set_Nkind is in the next -- section, since its use is restricted. procedure Set_Sloc (N : Node_Id; Val : Source_Ptr); pragma Inline (Set_Sloc); procedure Set_Paren_Count (N : Node_Id; Val : Nat); pragma Inline (Set_Paren_Count); procedure Set_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Parent); procedure Set_Analyzed (N : Node_Id; Val : Boolean := True); pragma Inline (Set_Analyzed); procedure Set_Error_Posted (N : Node_Id; Val : Boolean := True); pragma Inline (Set_Error_Posted); procedure Set_Comes_From_Source (N : Node_Id; Val : Boolean); pragma Inline (Set_Comes_From_Source); -- Note that this routine is very rarely used, since usually the -- default mechanism provided sets the right value, but in some -- unusual cases, the value needs to be reset (e.g. when a source -- node is copied, and the copy must not have Comes_From_Source set). procedure Set_Has_Aspects (N : Node_Id; Val : Boolean := True); pragma Inline (Set_Has_Aspects); procedure Set_Original_Node (N : Node_Id; Val : Node_Id); pragma Inline (Set_Original_Node); -- Note that this routine is used only in very peculiar cases. In normal -- cases, the Original_Node link is set by calls to Rewrite. We currently -- use it in ASIS mode to manually set the link from pragma expressions -- to their aspect original source expressions, so that the original source -- expressions accessed by ASIS are also semantically analyzed. ------------------------------ -- Entity Update Procedures -- ------------------------------ -- The following procedures apply only to Entity_Id values, i.e. -- to extended nodes. procedure Basic_Set_Convention (E : Entity_Id; Val : Convention_Id); pragma Inline (Basic_Set_Convention); -- Clients should use Sem_Util.Set_Convention rather than calling this -- routine directly, as Set_Convention also deals with the special -- processing required for access types. procedure Set_Ekind (E : Entity_Id; Val : Entity_Kind); pragma Inline (Set_Ekind); --------------------------- -- Tree Rewrite Routines -- --------------------------- -- During the compilation process it is necessary in a number of situations -- to rewrite the tree. In some cases, such rewrites do not affect the -- structure of the tree, for example, when an indexed component node is -- replaced by the corresponding call node (the parser cannot distinguish -- between these two cases). -- In other situations, the rewrite does affect the structure of the -- tree. Examples are the replacement of a generic instantiation by the -- instantiated spec and body, and the static evaluation of expressions. -- If such structural modifications are done by the expander, there are -- no difficulties, since the form of the tree after the expander has no -- special significance, except as input to the backend of the compiler. -- However, if these modifications are done by the semantic phase, then -- it is important that they be done in a manner which allows the original -- tree to be preserved. This is because tools like pretty printers need -- to have this original tree structure available. -- The subprograms in this section allow rewriting of the tree by either -- insertion of new nodes in an existing list, or complete replacement of -- a subtree. The resulting tree for most purposes looks as though it has -- been really changed, and there is no trace of the original. However, -- special subprograms, also defined in this section, allow the original -- tree to be reconstructed if necessary. -- For tree modifications done in the expander, it is permissible to -- destroy the original tree, although it is also allowable to use the -- tree rewrite routines where it is convenient to do so. procedure Mark_Rewrite_Insertion (New_Node : Node_Id); pragma Inline (Mark_Rewrite_Insertion); -- This procedure marks the given node as an insertion made during a tree -- rewriting operation. Only the root needs to be marked. The call does -- not do the actual insertion, which must be done using one of the normal -- list insertion routines. The node is treated normally in all respects -- except for its response to Is_Rewrite_Insertion. The function of these -- calls is to be able to get an accurate original tree. This helps the -- accuracy of Sprint.Sprint_Node, and in particular, when stubs are being -- generated, it is essential that the original tree be accurate. function Is_Rewrite_Insertion (Node : Node_Id) return Boolean; pragma Inline (Is_Rewrite_Insertion); -- Tests whether the given node was marked using Mark_Rewrite_Insertion. -- This is used in reconstructing the original tree (where such nodes are -- to be eliminated). procedure Rewrite (Old_Node, New_Node : Node_Id); -- This is used when a complete subtree is to be replaced. Old_Node is the -- root of the old subtree to be replaced, and New_Node is the root of the -- newly constructed replacement subtree. The actual mechanism is to swap -- the contents of these two nodes fixing up the parent pointers of the -- replaced node (we do not attempt to preserve parent pointers for the -- original node). Neither Old_Node nor New_Node can be extended nodes. -- -- Note: New_Node may not contain references to Old_Node, for example as -- descendents, since the rewrite would make such references invalid. If -- New_Node does need to reference Old_Node, then these references should -- be to a relocated copy of Old_Node (see Relocate_Node procedure). -- -- Note: The Original_Node function applied to Old_Node (which has now -- been replaced by the contents of New_Node), can be used to obtain the -- original node, i.e. the old contents of Old_Node. procedure Replace (Old_Node, New_Node : Node_Id); -- This is similar to Rewrite, except that the old value of Old_Node is -- not saved, and the New_Node is deleted after the replace, since it -- is assumed that it can no longer be legitimately needed. The flag -- Is_Rewrite_Substitution will be False for the resulting node, unless -- it was already true on entry, and Original_Node will not return the -- original contents of the Old_Node, but rather the New_Node value (unless -- Old_Node had already been rewritten using Rewrite). Replace also -- preserves the setting of Comes_From_Source. -- -- Note, New_Node may not contain references to Old_Node, for example as -- descendents, since the rewrite would make such references invalid. If -- New_Node does need to reference Old_Node, then these references should -- be to a relocated copy of Old_Node (see Relocate_Node procedure). -- -- Replace is used in certain circumstances where it is desirable to -- suppress any history of the rewriting operation. Notably, it is used -- when the parser has mis-classified a node (e.g. a task entry call -- that the parser has parsed as a procedure call). function Is_Rewrite_Substitution (Node : Node_Id) return Boolean; pragma Inline (Is_Rewrite_Substitution); -- Return True iff Node has been rewritten (i.e. if Node is the root -- of a subtree which was installed using Rewrite). function Original_Node (Node : Node_Id) return Node_Id; pragma Inline (Original_Node); -- If Node has not been rewritten, then returns its input argument -- unchanged, else returns the Node for the original subtree. Note that -- this is used extensively by ASIS on the trees constructed in ASIS mode -- to reconstruct the original semantic tree. See section in sinfo.ads -- for requirements on original nodes returned by this function. -- -- Note: Parents are not preserved in original tree nodes that are -- retrieved in this way (i.e. their children may have children whose -- pointers which reference some other node). This needs more details??? -- -- Note: there is no direct mechanism for deleting an original node (in -- a manner that can be reversed later). One possible approach is to use -- Rewrite to substitute a null statement for the node to be deleted. ----------------------------------- -- Generic Field Access Routines -- ----------------------------------- -- This subpackage provides the functions for accessing and procedures for -- setting fields that are normally referenced by wrapper subprograms (e.g. -- logical synonyms defined in packages Sinfo and Einfo, or specialized -- routines such as Rewrite (for Original_Node), or the node creation -- routines (for Set_Nkind). The implementations of these wrapper -- subprograms use the package Atree.Unchecked_Access as do various -- special case accesses where no wrapper applies. Documentation is always -- required for such a special case access explaining why it is needed. package Unchecked_Access is -- Functions to allow interpretation of Union_Id values as Uint and -- Ureal values. function To_Union is new Unchecked_Conversion (Uint, Union_Id); function To_Union is new Unchecked_Conversion (Ureal, Union_Id); function From_Union is new Unchecked_Conversion (Union_Id, Uint); function From_Union is new Unchecked_Conversion (Union_Id, Ureal); -- Functions to fetch contents of indicated field. It is an error to -- attempt to read the value of a field which is not present. function Field1 (N : Node_Id) return Union_Id; pragma Inline (Field1); function Field2 (N : Node_Id) return Union_Id; pragma Inline (Field2); function Field3 (N : Node_Id) return Union_Id; pragma Inline (Field3); function Field4 (N : Node_Id) return Union_Id; pragma Inline (Field4); function Field5 (N : Node_Id) return Union_Id; pragma Inline (Field5); function Field6 (N : Node_Id) return Union_Id; pragma Inline (Field6); function Field7 (N : Node_Id) return Union_Id; pragma Inline (Field7); function Field8 (N : Node_Id) return Union_Id; pragma Inline (Field8); function Field9 (N : Node_Id) return Union_Id; pragma Inline (Field9); function Field10 (N : Node_Id) return Union_Id; pragma Inline (Field10); function Field11 (N : Node_Id) return Union_Id; pragma Inline (Field11); function Field12 (N : Node_Id) return Union_Id; pragma Inline (Field12); function Field13 (N : Node_Id) return Union_Id; pragma Inline (Field13); function Field14 (N : Node_Id) return Union_Id; pragma Inline (Field14); function Field15 (N : Node_Id) return Union_Id; pragma Inline (Field15); function Field16 (N : Node_Id) return Union_Id; pragma Inline (Field16); function Field17 (N : Node_Id) return Union_Id; pragma Inline (Field17); function Field18 (N : Node_Id) return Union_Id; pragma Inline (Field18); function Field19 (N : Node_Id) return Union_Id; pragma Inline (Field19); function Field20 (N : Node_Id) return Union_Id; pragma Inline (Field20); function Field21 (N : Node_Id) return Union_Id; pragma Inline (Field21); function Field22 (N : Node_Id) return Union_Id; pragma Inline (Field22); function Field23 (N : Node_Id) return Union_Id; pragma Inline (Field23); function Field24 (N : Node_Id) return Union_Id; pragma Inline (Field24); function Field25 (N : Node_Id) return Union_Id; pragma Inline (Field25); function Field26 (N : Node_Id) return Union_Id; pragma Inline (Field26); function Field27 (N : Node_Id) return Union_Id; pragma Inline (Field27); function Field28 (N : Node_Id) return Union_Id; pragma Inline (Field28); function Field29 (N : Node_Id) return Union_Id; pragma Inline (Field29); function Field30 (N : Node_Id) return Union_Id; pragma Inline (Field30); function Field31 (N : Node_Id) return Union_Id; pragma Inline (Field31); function Field32 (N : Node_Id) return Union_Id; pragma Inline (Field32); function Field33 (N : Node_Id) return Union_Id; pragma Inline (Field33); function Field34 (N : Node_Id) return Union_Id; pragma Inline (Field34); function Field35 (N : Node_Id) return Union_Id; pragma Inline (Field35); function Node1 (N : Node_Id) return Node_Id; pragma Inline (Node1); function Node2 (N : Node_Id) return Node_Id; pragma Inline (Node2); function Node3 (N : Node_Id) return Node_Id; pragma Inline (Node3); function Node4 (N : Node_Id) return Node_Id; pragma Inline (Node4); function Node5 (N : Node_Id) return Node_Id; pragma Inline (Node5); function Node6 (N : Node_Id) return Node_Id; pragma Inline (Node6); function Node7 (N : Node_Id) return Node_Id; pragma Inline (Node7); function Node8 (N : Node_Id) return Node_Id; pragma Inline (Node8); function Node9 (N : Node_Id) return Node_Id; pragma Inline (Node9); function Node10 (N : Node_Id) return Node_Id; pragma Inline (Node10); function Node11 (N : Node_Id) return Node_Id; pragma Inline (Node11); function Node12 (N : Node_Id) return Node_Id; pragma Inline (Node12); function Node13 (N : Node_Id) return Node_Id; pragma Inline (Node13); function Node14 (N : Node_Id) return Node_Id; pragma Inline (Node14); function Node15 (N : Node_Id) return Node_Id; pragma Inline (Node15); function Node16 (N : Node_Id) return Node_Id; pragma Inline (Node16); function Node17 (N : Node_Id) return Node_Id; pragma Inline (Node17); function Node18 (N : Node_Id) return Node_Id; pragma Inline (Node18); function Node19 (N : Node_Id) return Node_Id; pragma Inline (Node19); function Node20 (N : Node_Id) return Node_Id; pragma Inline (Node20); function Node21 (N : Node_Id) return Node_Id; pragma Inline (Node21); function Node22 (N : Node_Id) return Node_Id; pragma Inline (Node22); function Node23 (N : Node_Id) return Node_Id; pragma Inline (Node23); function Node24 (N : Node_Id) return Node_Id; pragma Inline (Node24); function Node25 (N : Node_Id) return Node_Id; pragma Inline (Node25); function Node26 (N : Node_Id) return Node_Id; pragma Inline (Node26); function Node27 (N : Node_Id) return Node_Id; pragma Inline (Node27); function Node28 (N : Node_Id) return Node_Id; pragma Inline (Node28); function Node29 (N : Node_Id) return Node_Id; pragma Inline (Node29); function Node30 (N : Node_Id) return Node_Id; pragma Inline (Node30); function Node31 (N : Node_Id) return Node_Id; pragma Inline (Node31); function Node32 (N : Node_Id) return Node_Id; pragma Inline (Node32); function Node33 (N : Node_Id) return Node_Id; pragma Inline (Node33); function Node34 (N : Node_Id) return Node_Id; pragma Inline (Node34); function Node35 (N : Node_Id) return Node_Id; pragma Inline (Node35); function List1 (N : Node_Id) return List_Id; pragma Inline (List1); function List2 (N : Node_Id) return List_Id; pragma Inline (List2); function List3 (N : Node_Id) return List_Id; pragma Inline (List3); function List4 (N : Node_Id) return List_Id; pragma Inline (List4); function List5 (N : Node_Id) return List_Id; pragma Inline (List5); function List10 (N : Node_Id) return List_Id; pragma Inline (List10); function List14 (N : Node_Id) return List_Id; pragma Inline (List14); function List25 (N : Node_Id) return List_Id; pragma Inline (List25); function Elist1 (N : Node_Id) return Elist_Id; pragma Inline (Elist1); function Elist2 (N : Node_Id) return Elist_Id; pragma Inline (Elist2); function Elist3 (N : Node_Id) return Elist_Id; pragma Inline (Elist3); function Elist4 (N : Node_Id) return Elist_Id; pragma Inline (Elist4); function Elist5 (N : Node_Id) return Elist_Id; pragma Inline (Elist5); function Elist8 (N : Node_Id) return Elist_Id; pragma Inline (Elist8); function Elist9 (N : Node_Id) return Elist_Id; pragma Inline (Elist9); function Elist10 (N : Node_Id) return Elist_Id; pragma Inline (Elist10); function Elist13 (N : Node_Id) return Elist_Id; pragma Inline (Elist13); function Elist15 (N : Node_Id) return Elist_Id; pragma Inline (Elist15); function Elist16 (N : Node_Id) return Elist_Id; pragma Inline (Elist16); function Elist18 (N : Node_Id) return Elist_Id; pragma Inline (Elist18); function Elist21 (N : Node_Id) return Elist_Id; pragma Inline (Elist21); function Elist23 (N : Node_Id) return Elist_Id; pragma Inline (Elist23); function Elist24 (N : Node_Id) return Elist_Id; pragma Inline (Elist24); function Elist25 (N : Node_Id) return Elist_Id; pragma Inline (Elist25); function Elist26 (N : Node_Id) return Elist_Id; pragma Inline (Elist26); function Name1 (N : Node_Id) return Name_Id; pragma Inline (Name1); function Name2 (N : Node_Id) return Name_Id; pragma Inline (Name2); function Str3 (N : Node_Id) return String_Id; pragma Inline (Str3); -- Note: the following Uintnn functions have a special test for the -- Field value being Empty. If an Empty value is found then Uint_0 is -- returned. This avoids the rather tricky requirement of initializing -- all Uint fields in nodes and entities. function Uint2 (N : Node_Id) return Uint; pragma Inline (Uint2); function Uint3 (N : Node_Id) return Uint; pragma Inline (Uint3); function Uint4 (N : Node_Id) return Uint; pragma Inline (Uint4); function Uint5 (N : Node_Id) return Uint; pragma Inline (Uint5); function Uint8 (N : Node_Id) return Uint; pragma Inline (Uint8); function Uint9 (N : Node_Id) return Uint; pragma Inline (Uint9); function Uint10 (N : Node_Id) return Uint; pragma Inline (Uint10); function Uint11 (N : Node_Id) return Uint; pragma Inline (Uint11); function Uint12 (N : Node_Id) return Uint; pragma Inline (Uint12); function Uint13 (N : Node_Id) return Uint; pragma Inline (Uint13); function Uint14 (N : Node_Id) return Uint; pragma Inline (Uint14); function Uint15 (N : Node_Id) return Uint; pragma Inline (Uint15); function Uint16 (N : Node_Id) return Uint; pragma Inline (Uint16); function Uint17 (N : Node_Id) return Uint; pragma Inline (Uint17); function Uint22 (N : Node_Id) return Uint; pragma Inline (Uint22); function Ureal3 (N : Node_Id) return Ureal; pragma Inline (Ureal3); function Ureal18 (N : Node_Id) return Ureal; pragma Inline (Ureal18); function Ureal21 (N : Node_Id) return Ureal; pragma Inline (Ureal21); function Flag0 (N : Node_Id) return Boolean; pragma Inline (Flag0); function Flag1 (N : Node_Id) return Boolean; pragma Inline (Flag1); function Flag2 (N : Node_Id) return Boolean; pragma Inline (Flag2); function Flag3 (N : Node_Id) return Boolean; pragma Inline (Flag3); function Flag4 (N : Node_Id) return Boolean; pragma Inline (Flag4); function Flag5 (N : Node_Id) return Boolean; pragma Inline (Flag5); function Flag6 (N : Node_Id) return Boolean; pragma Inline (Flag6); function Flag7 (N : Node_Id) return Boolean; pragma Inline (Flag7); function Flag8 (N : Node_Id) return Boolean; pragma Inline (Flag8); function Flag9 (N : Node_Id) return Boolean; pragma Inline (Flag9); function Flag10 (N : Node_Id) return Boolean; pragma Inline (Flag10); function Flag11 (N : Node_Id) return Boolean; pragma Inline (Flag11); function Flag12 (N : Node_Id) return Boolean; pragma Inline (Flag12); function Flag13 (N : Node_Id) return Boolean; pragma Inline (Flag13); function Flag14 (N : Node_Id) return Boolean; pragma Inline (Flag14); function Flag15 (N : Node_Id) return Boolean; pragma Inline (Flag15); function Flag16 (N : Node_Id) return Boolean; pragma Inline (Flag16); function Flag17 (N : Node_Id) return Boolean; pragma Inline (Flag17); function Flag18 (N : Node_Id) return Boolean; pragma Inline (Flag18); function Flag19 (N : Node_Id) return Boolean; pragma Inline (Flag19); function Flag20 (N : Node_Id) return Boolean; pragma Inline (Flag20); function Flag21 (N : Node_Id) return Boolean; pragma Inline (Flag21); function Flag22 (N : Node_Id) return Boolean; pragma Inline (Flag22); function Flag23 (N : Node_Id) return Boolean; pragma Inline (Flag23); function Flag24 (N : Node_Id) return Boolean; pragma Inline (Flag24); function Flag25 (N : Node_Id) return Boolean; pragma Inline (Flag25); function Flag26 (N : Node_Id) return Boolean; pragma Inline (Flag26); function Flag27 (N : Node_Id) return Boolean; pragma Inline (Flag27); function Flag28 (N : Node_Id) return Boolean; pragma Inline (Flag28); function Flag29 (N : Node_Id) return Boolean; pragma Inline (Flag29); function Flag30 (N : Node_Id) return Boolean; pragma Inline (Flag30); function Flag31 (N : Node_Id) return Boolean; pragma Inline (Flag31); function Flag32 (N : Node_Id) return Boolean; pragma Inline (Flag32); function Flag33 (N : Node_Id) return Boolean; pragma Inline (Flag33); function Flag34 (N : Node_Id) return Boolean; pragma Inline (Flag34); function Flag35 (N : Node_Id) return Boolean; pragma Inline (Flag35); function Flag36 (N : Node_Id) return Boolean; pragma Inline (Flag36); function Flag37 (N : Node_Id) return Boolean; pragma Inline (Flag37); function Flag38 (N : Node_Id) return Boolean; pragma Inline (Flag38); function Flag39 (N : Node_Id) return Boolean; pragma Inline (Flag39); function Flag40 (N : Node_Id) return Boolean; pragma Inline (Flag40); function Flag41 (N : Node_Id) return Boolean; pragma Inline (Flag41); function Flag42 (N : Node_Id) return Boolean; pragma Inline (Flag42); function Flag43 (N : Node_Id) return Boolean; pragma Inline (Flag43); function Flag44 (N : Node_Id) return Boolean; pragma Inline (Flag44); function Flag45 (N : Node_Id) return Boolean; pragma Inline (Flag45); function Flag46 (N : Node_Id) return Boolean; pragma Inline (Flag46); function Flag47 (N : Node_Id) return Boolean; pragma Inline (Flag47); function Flag48 (N : Node_Id) return Boolean; pragma Inline (Flag48); function Flag49 (N : Node_Id) return Boolean; pragma Inline (Flag49); function Flag50 (N : Node_Id) return Boolean; pragma Inline (Flag50); function Flag51 (N : Node_Id) return Boolean; pragma Inline (Flag51); function Flag52 (N : Node_Id) return Boolean; pragma Inline (Flag52); function Flag53 (N : Node_Id) return Boolean; pragma Inline (Flag53); function Flag54 (N : Node_Id) return Boolean; pragma Inline (Flag54); function Flag55 (N : Node_Id) return Boolean; pragma Inline (Flag55); function Flag56 (N : Node_Id) return Boolean; pragma Inline (Flag56); function Flag57 (N : Node_Id) return Boolean; pragma Inline (Flag57); function Flag58 (N : Node_Id) return Boolean; pragma Inline (Flag58); function Flag59 (N : Node_Id) return Boolean; pragma Inline (Flag59); function Flag60 (N : Node_Id) return Boolean; pragma Inline (Flag60); function Flag61 (N : Node_Id) return Boolean; pragma Inline (Flag61); function Flag62 (N : Node_Id) return Boolean; pragma Inline (Flag62); function Flag63 (N : Node_Id) return Boolean; pragma Inline (Flag63); function Flag64 (N : Node_Id) return Boolean; pragma Inline (Flag64); function Flag65 (N : Node_Id) return Boolean; pragma Inline (Flag65); function Flag66 (N : Node_Id) return Boolean; pragma Inline (Flag66); function Flag67 (N : Node_Id) return Boolean; pragma Inline (Flag67); function Flag68 (N : Node_Id) return Boolean; pragma Inline (Flag68); function Flag69 (N : Node_Id) return Boolean; pragma Inline (Flag69); function Flag70 (N : Node_Id) return Boolean; pragma Inline (Flag70); function Flag71 (N : Node_Id) return Boolean; pragma Inline (Flag71); function Flag72 (N : Node_Id) return Boolean; pragma Inline (Flag72); function Flag73 (N : Node_Id) return Boolean; pragma Inline (Flag73); function Flag74 (N : Node_Id) return Boolean; pragma Inline (Flag74); function Flag75 (N : Node_Id) return Boolean; pragma Inline (Flag75); function Flag76 (N : Node_Id) return Boolean; pragma Inline (Flag76); function Flag77 (N : Node_Id) return Boolean; pragma Inline (Flag77); function Flag78 (N : Node_Id) return Boolean; pragma Inline (Flag78); function Flag79 (N : Node_Id) return Boolean; pragma Inline (Flag79); function Flag80 (N : Node_Id) return Boolean; pragma Inline (Flag80); function Flag81 (N : Node_Id) return Boolean; pragma Inline (Flag81); function Flag82 (N : Node_Id) return Boolean; pragma Inline (Flag82); function Flag83 (N : Node_Id) return Boolean; pragma Inline (Flag83); function Flag84 (N : Node_Id) return Boolean; pragma Inline (Flag84); function Flag85 (N : Node_Id) return Boolean; pragma Inline (Flag85); function Flag86 (N : Node_Id) return Boolean; pragma Inline (Flag86); function Flag87 (N : Node_Id) return Boolean; pragma Inline (Flag87); function Flag88 (N : Node_Id) return Boolean; pragma Inline (Flag88); function Flag89 (N : Node_Id) return Boolean; pragma Inline (Flag89); function Flag90 (N : Node_Id) return Boolean; pragma Inline (Flag90); function Flag91 (N : Node_Id) return Boolean; pragma Inline (Flag91); function Flag92 (N : Node_Id) return Boolean; pragma Inline (Flag92); function Flag93 (N : Node_Id) return Boolean; pragma Inline (Flag93); function Flag94 (N : Node_Id) return Boolean; pragma Inline (Flag94); function Flag95 (N : Node_Id) return Boolean; pragma Inline (Flag95); function Flag96 (N : Node_Id) return Boolean; pragma Inline (Flag96); function Flag97 (N : Node_Id) return Boolean; pragma Inline (Flag97); function Flag98 (N : Node_Id) return Boolean; pragma Inline (Flag98); function Flag99 (N : Node_Id) return Boolean; pragma Inline (Flag99); function Flag100 (N : Node_Id) return Boolean; pragma Inline (Flag100); function Flag101 (N : Node_Id) return Boolean; pragma Inline (Flag101); function Flag102 (N : Node_Id) return Boolean; pragma Inline (Flag102); function Flag103 (N : Node_Id) return Boolean; pragma Inline (Flag103); function Flag104 (N : Node_Id) return Boolean; pragma Inline (Flag104); function Flag105 (N : Node_Id) return Boolean; pragma Inline (Flag105); function Flag106 (N : Node_Id) return Boolean; pragma Inline (Flag106); function Flag107 (N : Node_Id) return Boolean; pragma Inline (Flag107); function Flag108 (N : Node_Id) return Boolean; pragma Inline (Flag108); function Flag109 (N : Node_Id) return Boolean; pragma Inline (Flag109); function Flag110 (N : Node_Id) return Boolean; pragma Inline (Flag110); function Flag111 (N : Node_Id) return Boolean; pragma Inline (Flag111); function Flag112 (N : Node_Id) return Boolean; pragma Inline (Flag112); function Flag113 (N : Node_Id) return Boolean; pragma Inline (Flag113); function Flag114 (N : Node_Id) return Boolean; pragma Inline (Flag114); function Flag115 (N : Node_Id) return Boolean; pragma Inline (Flag115); function Flag116 (N : Node_Id) return Boolean; pragma Inline (Flag116); function Flag117 (N : Node_Id) return Boolean; pragma Inline (Flag117); function Flag118 (N : Node_Id) return Boolean; pragma Inline (Flag118); function Flag119 (N : Node_Id) return Boolean; pragma Inline (Flag119); function Flag120 (N : Node_Id) return Boolean; pragma Inline (Flag120); function Flag121 (N : Node_Id) return Boolean; pragma Inline (Flag121); function Flag122 (N : Node_Id) return Boolean; pragma Inline (Flag122); function Flag123 (N : Node_Id) return Boolean; pragma Inline (Flag123); function Flag124 (N : Node_Id) return Boolean; pragma Inline (Flag124); function Flag125 (N : Node_Id) return Boolean; pragma Inline (Flag125); function Flag126 (N : Node_Id) return Boolean; pragma Inline (Flag126); function Flag127 (N : Node_Id) return Boolean; pragma Inline (Flag127); function Flag128 (N : Node_Id) return Boolean; pragma Inline (Flag128); function Flag129 (N : Node_Id) return Boolean; pragma Inline (Flag129); function Flag130 (N : Node_Id) return Boolean; pragma Inline (Flag130); function Flag131 (N : Node_Id) return Boolean; pragma Inline (Flag131); function Flag132 (N : Node_Id) return Boolean; pragma Inline (Flag132); function Flag133 (N : Node_Id) return Boolean; pragma Inline (Flag133); function Flag134 (N : Node_Id) return Boolean; pragma Inline (Flag134); function Flag135 (N : Node_Id) return Boolean; pragma Inline (Flag135); function Flag136 (N : Node_Id) return Boolean; pragma Inline (Flag136); function Flag137 (N : Node_Id) return Boolean; pragma Inline (Flag137); function Flag138 (N : Node_Id) return Boolean; pragma Inline (Flag138); function Flag139 (N : Node_Id) return Boolean; pragma Inline (Flag139); function Flag140 (N : Node_Id) return Boolean; pragma Inline (Flag140); function Flag141 (N : Node_Id) return Boolean; pragma Inline (Flag141); function Flag142 (N : Node_Id) return Boolean; pragma Inline (Flag142); function Flag143 (N : Node_Id) return Boolean; pragma Inline (Flag143); function Flag144 (N : Node_Id) return Boolean; pragma Inline (Flag144); function Flag145 (N : Node_Id) return Boolean; pragma Inline (Flag145); function Flag146 (N : Node_Id) return Boolean; pragma Inline (Flag146); function Flag147 (N : Node_Id) return Boolean; pragma Inline (Flag147); function Flag148 (N : Node_Id) return Boolean; pragma Inline (Flag148); function Flag149 (N : Node_Id) return Boolean; pragma Inline (Flag149); function Flag150 (N : Node_Id) return Boolean; pragma Inline (Flag150); function Flag151 (N : Node_Id) return Boolean; pragma Inline (Flag151); function Flag152 (N : Node_Id) return Boolean; pragma Inline (Flag152); function Flag153 (N : Node_Id) return Boolean; pragma Inline (Flag153); function Flag154 (N : Node_Id) return Boolean; pragma Inline (Flag154); function Flag155 (N : Node_Id) return Boolean; pragma Inline (Flag155); function Flag156 (N : Node_Id) return Boolean; pragma Inline (Flag156); function Flag157 (N : Node_Id) return Boolean; pragma Inline (Flag157); function Flag158 (N : Node_Id) return Boolean; pragma Inline (Flag158); function Flag159 (N : Node_Id) return Boolean; pragma Inline (Flag159); function Flag160 (N : Node_Id) return Boolean; pragma Inline (Flag160); function Flag161 (N : Node_Id) return Boolean; pragma Inline (Flag161); function Flag162 (N : Node_Id) return Boolean; pragma Inline (Flag162); function Flag163 (N : Node_Id) return Boolean; pragma Inline (Flag163); function Flag164 (N : Node_Id) return Boolean; pragma Inline (Flag164); function Flag165 (N : Node_Id) return Boolean; pragma Inline (Flag165); function Flag166 (N : Node_Id) return Boolean; pragma Inline (Flag166); function Flag167 (N : Node_Id) return Boolean; pragma Inline (Flag167); function Flag168 (N : Node_Id) return Boolean; pragma Inline (Flag168); function Flag169 (N : Node_Id) return Boolean; pragma Inline (Flag169); function Flag170 (N : Node_Id) return Boolean; pragma Inline (Flag170); function Flag171 (N : Node_Id) return Boolean; pragma Inline (Flag171); function Flag172 (N : Node_Id) return Boolean; pragma Inline (Flag172); function Flag173 (N : Node_Id) return Boolean; pragma Inline (Flag173); function Flag174 (N : Node_Id) return Boolean; pragma Inline (Flag174); function Flag175 (N : Node_Id) return Boolean; pragma Inline (Flag175); function Flag176 (N : Node_Id) return Boolean; pragma Inline (Flag176); function Flag177 (N : Node_Id) return Boolean; pragma Inline (Flag177); function Flag178 (N : Node_Id) return Boolean; pragma Inline (Flag178); function Flag179 (N : Node_Id) return Boolean; pragma Inline (Flag179); function Flag180 (N : Node_Id) return Boolean; pragma Inline (Flag180); function Flag181 (N : Node_Id) return Boolean; pragma Inline (Flag181); function Flag182 (N : Node_Id) return Boolean; pragma Inline (Flag182); function Flag183 (N : Node_Id) return Boolean; pragma Inline (Flag183); function Flag184 (N : Node_Id) return Boolean; pragma Inline (Flag184); function Flag185 (N : Node_Id) return Boolean; pragma Inline (Flag185); function Flag186 (N : Node_Id) return Boolean; pragma Inline (Flag186); function Flag187 (N : Node_Id) return Boolean; pragma Inline (Flag187); function Flag188 (N : Node_Id) return Boolean; pragma Inline (Flag188); function Flag189 (N : Node_Id) return Boolean; pragma Inline (Flag189); function Flag190 (N : Node_Id) return Boolean; pragma Inline (Flag190); function Flag191 (N : Node_Id) return Boolean; pragma Inline (Flag191); function Flag192 (N : Node_Id) return Boolean; pragma Inline (Flag192); function Flag193 (N : Node_Id) return Boolean; pragma Inline (Flag193); function Flag194 (N : Node_Id) return Boolean; pragma Inline (Flag194); function Flag195 (N : Node_Id) return Boolean; pragma Inline (Flag195); function Flag196 (N : Node_Id) return Boolean; pragma Inline (Flag196); function Flag197 (N : Node_Id) return Boolean; pragma Inline (Flag197); function Flag198 (N : Node_Id) return Boolean; pragma Inline (Flag198); function Flag199 (N : Node_Id) return Boolean; pragma Inline (Flag199); function Flag200 (N : Node_Id) return Boolean; pragma Inline (Flag200); function Flag201 (N : Node_Id) return Boolean; pragma Inline (Flag201); function Flag202 (N : Node_Id) return Boolean; pragma Inline (Flag202); function Flag203 (N : Node_Id) return Boolean; pragma Inline (Flag203); function Flag204 (N : Node_Id) return Boolean; pragma Inline (Flag204); function Flag205 (N : Node_Id) return Boolean; pragma Inline (Flag205); function Flag206 (N : Node_Id) return Boolean; pragma Inline (Flag206); function Flag207 (N : Node_Id) return Boolean; pragma Inline (Flag207); function Flag208 (N : Node_Id) return Boolean; pragma Inline (Flag208); function Flag209 (N : Node_Id) return Boolean; pragma Inline (Flag209); function Flag210 (N : Node_Id) return Boolean; pragma Inline (Flag210); function Flag211 (N : Node_Id) return Boolean; pragma Inline (Flag211); function Flag212 (N : Node_Id) return Boolean; pragma Inline (Flag212); function Flag213 (N : Node_Id) return Boolean; pragma Inline (Flag213); function Flag214 (N : Node_Id) return Boolean; pragma Inline (Flag214); function Flag215 (N : Node_Id) return Boolean; pragma Inline (Flag215); function Flag216 (N : Node_Id) return Boolean; pragma Inline (Flag216); function Flag217 (N : Node_Id) return Boolean; pragma Inline (Flag217); function Flag218 (N : Node_Id) return Boolean; pragma Inline (Flag218); function Flag219 (N : Node_Id) return Boolean; pragma Inline (Flag219); function Flag220 (N : Node_Id) return Boolean; pragma Inline (Flag220); function Flag221 (N : Node_Id) return Boolean; pragma Inline (Flag221); function Flag222 (N : Node_Id) return Boolean; pragma Inline (Flag222); function Flag223 (N : Node_Id) return Boolean; pragma Inline (Flag223); function Flag224 (N : Node_Id) return Boolean; pragma Inline (Flag224); function Flag225 (N : Node_Id) return Boolean; pragma Inline (Flag225); function Flag226 (N : Node_Id) return Boolean; pragma Inline (Flag226); function Flag227 (N : Node_Id) return Boolean; pragma Inline (Flag227); function Flag228 (N : Node_Id) return Boolean; pragma Inline (Flag228); function Flag229 (N : Node_Id) return Boolean; pragma Inline (Flag229); function Flag230 (N : Node_Id) return Boolean; pragma Inline (Flag230); function Flag231 (N : Node_Id) return Boolean; pragma Inline (Flag231); function Flag232 (N : Node_Id) return Boolean; pragma Inline (Flag232); function Flag233 (N : Node_Id) return Boolean; pragma Inline (Flag233); function Flag234 (N : Node_Id) return Boolean; pragma Inline (Flag234); function Flag235 (N : Node_Id) return Boolean; pragma Inline (Flag235); function Flag236 (N : Node_Id) return Boolean; pragma Inline (Flag236); function Flag237 (N : Node_Id) return Boolean; pragma Inline (Flag237); function Flag238 (N : Node_Id) return Boolean; pragma Inline (Flag238); function Flag239 (N : Node_Id) return Boolean; pragma Inline (Flag239); function Flag240 (N : Node_Id) return Boolean; pragma Inline (Flag240); function Flag241 (N : Node_Id) return Boolean; pragma Inline (Flag241); function Flag242 (N : Node_Id) return Boolean; pragma Inline (Flag242); function Flag243 (N : Node_Id) return Boolean; pragma Inline (Flag243); function Flag244 (N : Node_Id) return Boolean; pragma Inline (Flag244); function Flag245 (N : Node_Id) return Boolean; pragma Inline (Flag245); function Flag246 (N : Node_Id) return Boolean; pragma Inline (Flag246); function Flag247 (N : Node_Id) return Boolean; pragma Inline (Flag247); function Flag248 (N : Node_Id) return Boolean; pragma Inline (Flag248); function Flag249 (N : Node_Id) return Boolean; pragma Inline (Flag249); function Flag250 (N : Node_Id) return Boolean; pragma Inline (Flag250); function Flag251 (N : Node_Id) return Boolean; pragma Inline (Flag251); function Flag252 (N : Node_Id) return Boolean; pragma Inline (Flag252); function Flag253 (N : Node_Id) return Boolean; pragma Inline (Flag253); function Flag254 (N : Node_Id) return Boolean; pragma Inline (Flag254); function Flag255 (N : Node_Id) return Boolean; pragma Inline (Flag255); function Flag256 (N : Node_Id) return Boolean; pragma Inline (Flag256); function Flag257 (N : Node_Id) return Boolean; pragma Inline (Flag257); function Flag258 (N : Node_Id) return Boolean; pragma Inline (Flag258); function Flag259 (N : Node_Id) return Boolean; pragma Inline (Flag259); function Flag260 (N : Node_Id) return Boolean; pragma Inline (Flag260); function Flag261 (N : Node_Id) return Boolean; pragma Inline (Flag261); function Flag262 (N : Node_Id) return Boolean; pragma Inline (Flag262); function Flag263 (N : Node_Id) return Boolean; pragma Inline (Flag263); function Flag264 (N : Node_Id) return Boolean; pragma Inline (Flag264); function Flag265 (N : Node_Id) return Boolean; pragma Inline (Flag265); function Flag266 (N : Node_Id) return Boolean; pragma Inline (Flag266); function Flag267 (N : Node_Id) return Boolean; pragma Inline (Flag267); function Flag268 (N : Node_Id) return Boolean; pragma Inline (Flag268); function Flag269 (N : Node_Id) return Boolean; pragma Inline (Flag269); function Flag270 (N : Node_Id) return Boolean; pragma Inline (Flag270); function Flag271 (N : Node_Id) return Boolean; pragma Inline (Flag271); function Flag272 (N : Node_Id) return Boolean; pragma Inline (Flag272); function Flag273 (N : Node_Id) return Boolean; pragma Inline (Flag273); function Flag274 (N : Node_Id) return Boolean; pragma Inline (Flag274); function Flag275 (N : Node_Id) return Boolean; pragma Inline (Flag275); function Flag276 (N : Node_Id) return Boolean; pragma Inline (Flag276); function Flag277 (N : Node_Id) return Boolean; pragma Inline (Flag277); function Flag278 (N : Node_Id) return Boolean; pragma Inline (Flag278); function Flag279 (N : Node_Id) return Boolean; pragma Inline (Flag279); function Flag280 (N : Node_Id) return Boolean; pragma Inline (Flag280); function Flag281 (N : Node_Id) return Boolean; pragma Inline (Flag281); function Flag282 (N : Node_Id) return Boolean; pragma Inline (Flag282); function Flag283 (N : Node_Id) return Boolean; pragma Inline (Flag283); function Flag284 (N : Node_Id) return Boolean; pragma Inline (Flag284); function Flag285 (N : Node_Id) return Boolean; pragma Inline (Flag285); function Flag286 (N : Node_Id) return Boolean; pragma Inline (Flag286); function Flag287 (N : Node_Id) return Boolean; pragma Inline (Flag287); function Flag288 (N : Node_Id) return Boolean; pragma Inline (Flag288); function Flag289 (N : Node_Id) return Boolean; pragma Inline (Flag289); function Flag290 (N : Node_Id) return Boolean; pragma Inline (Flag290); function Flag291 (N : Node_Id) return Boolean; pragma Inline (Flag291); function Flag292 (N : Node_Id) return Boolean; pragma Inline (Flag292); function Flag293 (N : Node_Id) return Boolean; pragma Inline (Flag293); function Flag294 (N : Node_Id) return Boolean; pragma Inline (Flag294); function Flag295 (N : Node_Id) return Boolean; pragma Inline (Flag295); function Flag296 (N : Node_Id) return Boolean; pragma Inline (Flag296); function Flag297 (N : Node_Id) return Boolean; pragma Inline (Flag297); function Flag298 (N : Node_Id) return Boolean; pragma Inline (Flag298); function Flag299 (N : Node_Id) return Boolean; pragma Inline (Flag299); function Flag300 (N : Node_Id) return Boolean; pragma Inline (Flag300); function Flag301 (N : Node_Id) return Boolean; pragma Inline (Flag301); function Flag302 (N : Node_Id) return Boolean; pragma Inline (Flag302); function Flag303 (N : Node_Id) return Boolean; pragma Inline (Flag303); function Flag304 (N : Node_Id) return Boolean; pragma Inline (Flag304); function Flag305 (N : Node_Id) return Boolean; pragma Inline (Flag305); function Flag306 (N : Node_Id) return Boolean; pragma Inline (Flag306); function Flag307 (N : Node_Id) return Boolean; pragma Inline (Flag307); function Flag308 (N : Node_Id) return Boolean; pragma Inline (Flag308); function Flag309 (N : Node_Id) return Boolean; pragma Inline (Flag309); function Flag310 (N : Node_Id) return Boolean; pragma Inline (Flag310); function Flag311 (N : Node_Id) return Boolean; pragma Inline (Flag311); function Flag312 (N : Node_Id) return Boolean; pragma Inline (Flag312); function Flag313 (N : Node_Id) return Boolean; pragma Inline (Flag313); function Flag314 (N : Node_Id) return Boolean; pragma Inline (Flag314); function Flag315 (N : Node_Id) return Boolean; pragma Inline (Flag315); function Flag316 (N : Node_Id) return Boolean; pragma Inline (Flag316); function Flag317 (N : Node_Id) return Boolean; pragma Inline (Flag317); -- Procedures to set value of indicated field procedure Set_Nkind (N : Node_Id; Val : Node_Kind); pragma Inline (Set_Nkind); procedure Set_Field1 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field1); procedure Set_Field2 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field2); procedure Set_Field3 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field3); procedure Set_Field4 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field4); procedure Set_Field5 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field5); procedure Set_Field6 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field6); procedure Set_Field7 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field7); procedure Set_Field8 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field8); procedure Set_Field9 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field9); procedure Set_Field10 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field10); procedure Set_Field11 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field11); procedure Set_Field12 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field12); procedure Set_Field13 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field13); procedure Set_Field14 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field14); procedure Set_Field15 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field15); procedure Set_Field16 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field16); procedure Set_Field17 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field17); procedure Set_Field18 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field18); procedure Set_Field19 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field19); procedure Set_Field20 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field20); procedure Set_Field21 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field21); procedure Set_Field22 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field22); procedure Set_Field23 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field23); procedure Set_Field24 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field24); procedure Set_Field25 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field25); procedure Set_Field26 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field26); procedure Set_Field27 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field27); procedure Set_Field28 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field28); procedure Set_Field29 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field29); procedure Set_Field30 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field30); procedure Set_Field31 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field31); procedure Set_Field32 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field32); procedure Set_Field33 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field33); procedure Set_Field34 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field34); procedure Set_Field35 (N : Node_Id; Val : Union_Id); pragma Inline (Set_Field35); procedure Set_Node1 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node1); procedure Set_Node2 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node2); procedure Set_Node3 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node3); procedure Set_Node4 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node4); procedure Set_Node5 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node5); procedure Set_Node6 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node6); procedure Set_Node7 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node7); procedure Set_Node8 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node8); procedure Set_Node9 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node9); procedure Set_Node10 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node10); procedure Set_Node11 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node11); procedure Set_Node12 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node12); procedure Set_Node13 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node13); procedure Set_Node14 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node14); procedure Set_Node15 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node15); procedure Set_Node16 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node16); procedure Set_Node17 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node17); procedure Set_Node18 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node18); procedure Set_Node19 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node19); procedure Set_Node20 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node20); procedure Set_Node21 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node21); procedure Set_Node22 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node22); procedure Set_Node23 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node23); procedure Set_Node24 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node24); procedure Set_Node25 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node25); procedure Set_Node26 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node26); procedure Set_Node27 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node27); procedure Set_Node28 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node28); procedure Set_Node29 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node29); procedure Set_Node30 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node30); procedure Set_Node31 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node31); procedure Set_Node32 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node32); procedure Set_Node33 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node33); procedure Set_Node34 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node34); procedure Set_Node35 (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node35); procedure Set_List1 (N : Node_Id; Val : List_Id); pragma Inline (Set_List1); procedure Set_List2 (N : Node_Id; Val : List_Id); pragma Inline (Set_List2); procedure Set_List3 (N : Node_Id; Val : List_Id); pragma Inline (Set_List3); procedure Set_List4 (N : Node_Id; Val : List_Id); pragma Inline (Set_List4); procedure Set_List5 (N : Node_Id; Val : List_Id); pragma Inline (Set_List5); procedure Set_List10 (N : Node_Id; Val : List_Id); pragma Inline (Set_List10); procedure Set_List14 (N : Node_Id; Val : List_Id); pragma Inline (Set_List14); procedure Set_List25 (N : Node_Id; Val : List_Id); pragma Inline (Set_List25); procedure Set_Elist1 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist1); procedure Set_Elist2 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist2); procedure Set_Elist3 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist3); procedure Set_Elist4 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist4); procedure Set_Elist5 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist5); procedure Set_Elist8 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist8); procedure Set_Elist9 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist9); procedure Set_Elist10 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist10); procedure Set_Elist13 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist13); procedure Set_Elist15 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist15); procedure Set_Elist16 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist16); procedure Set_Elist18 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist18); procedure Set_Elist21 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist21); procedure Set_Elist23 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist23); procedure Set_Elist24 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist24); procedure Set_Elist25 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist25); procedure Set_Elist26 (N : Node_Id; Val : Elist_Id); pragma Inline (Set_Elist26); procedure Set_Name1 (N : Node_Id; Val : Name_Id); pragma Inline (Set_Name1); procedure Set_Name2 (N : Node_Id; Val : Name_Id); pragma Inline (Set_Name2); procedure Set_Str3 (N : Node_Id; Val : String_Id); pragma Inline (Set_Str3); procedure Set_Uint2 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint2); procedure Set_Uint3 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint3); procedure Set_Uint4 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint4); procedure Set_Uint5 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint5); procedure Set_Uint8 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint8); procedure Set_Uint9 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint9); procedure Set_Uint10 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint10); procedure Set_Uint11 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint11); procedure Set_Uint12 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint12); procedure Set_Uint13 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint13); procedure Set_Uint14 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint14); procedure Set_Uint15 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint15); procedure Set_Uint16 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint16); procedure Set_Uint17 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint17); procedure Set_Uint22 (N : Node_Id; Val : Uint); pragma Inline (Set_Uint22); procedure Set_Ureal3 (N : Node_Id; Val : Ureal); pragma Inline (Set_Ureal3); procedure Set_Ureal18 (N : Node_Id; Val : Ureal); pragma Inline (Set_Ureal18); procedure Set_Ureal21 (N : Node_Id; Val : Ureal); pragma Inline (Set_Ureal21); procedure Set_Flag0 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag0); procedure Set_Flag1 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag1); procedure Set_Flag2 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag2); procedure Set_Flag3 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag3); procedure Set_Flag4 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag4); procedure Set_Flag5 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag5); procedure Set_Flag6 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag6); procedure Set_Flag7 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag7); procedure Set_Flag8 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag8); procedure Set_Flag9 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag9); procedure Set_Flag10 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag10); procedure Set_Flag11 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag11); procedure Set_Flag12 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag12); procedure Set_Flag13 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag13); procedure Set_Flag14 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag14); procedure Set_Flag15 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag15); procedure Set_Flag16 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag16); procedure Set_Flag17 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag17); procedure Set_Flag18 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag18); procedure Set_Flag19 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag19); procedure Set_Flag20 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag20); procedure Set_Flag21 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag21); procedure Set_Flag22 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag22); procedure Set_Flag23 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag23); procedure Set_Flag24 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag24); procedure Set_Flag25 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag25); procedure Set_Flag26 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag26); procedure Set_Flag27 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag27); procedure Set_Flag28 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag28); procedure Set_Flag29 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag29); procedure Set_Flag30 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag30); procedure Set_Flag31 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag31); procedure Set_Flag32 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag32); procedure Set_Flag33 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag33); procedure Set_Flag34 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag34); procedure Set_Flag35 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag35); procedure Set_Flag36 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag36); procedure Set_Flag37 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag37); procedure Set_Flag38 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag38); procedure Set_Flag39 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag39); procedure Set_Flag40 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag40); procedure Set_Flag41 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag41); procedure Set_Flag42 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag42); procedure Set_Flag43 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag43); procedure Set_Flag44 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag44); procedure Set_Flag45 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag45); procedure Set_Flag46 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag46); procedure Set_Flag47 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag47); procedure Set_Flag48 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag48); procedure Set_Flag49 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag49); procedure Set_Flag50 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag50); procedure Set_Flag51 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag51); procedure Set_Flag52 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag52); procedure Set_Flag53 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag53); procedure Set_Flag54 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag54); procedure Set_Flag55 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag55); procedure Set_Flag56 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag56); procedure Set_Flag57 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag57); procedure Set_Flag58 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag58); procedure Set_Flag59 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag59); procedure Set_Flag60 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag60); procedure Set_Flag61 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag61); procedure Set_Flag62 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag62); procedure Set_Flag63 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag63); procedure Set_Flag64 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag64); procedure Set_Flag65 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag65); procedure Set_Flag66 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag66); procedure Set_Flag67 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag67); procedure Set_Flag68 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag68); procedure Set_Flag69 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag69); procedure Set_Flag70 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag70); procedure Set_Flag71 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag71); procedure Set_Flag72 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag72); procedure Set_Flag73 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag73); procedure Set_Flag74 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag74); procedure Set_Flag75 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag75); procedure Set_Flag76 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag76); procedure Set_Flag77 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag77); procedure Set_Flag78 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag78); procedure Set_Flag79 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag79); procedure Set_Flag80 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag80); procedure Set_Flag81 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag81); procedure Set_Flag82 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag82); procedure Set_Flag83 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag83); procedure Set_Flag84 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag84); procedure Set_Flag85 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag85); procedure Set_Flag86 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag86); procedure Set_Flag87 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag87); procedure Set_Flag88 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag88); procedure Set_Flag89 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag89); procedure Set_Flag90 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag90); procedure Set_Flag91 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag91); procedure Set_Flag92 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag92); procedure Set_Flag93 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag93); procedure Set_Flag94 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag94); procedure Set_Flag95 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag95); procedure Set_Flag96 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag96); procedure Set_Flag97 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag97); procedure Set_Flag98 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag98); procedure Set_Flag99 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag99); procedure Set_Flag100 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag100); procedure Set_Flag101 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag101); procedure Set_Flag102 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag102); procedure Set_Flag103 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag103); procedure Set_Flag104 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag104); procedure Set_Flag105 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag105); procedure Set_Flag106 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag106); procedure Set_Flag107 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag107); procedure Set_Flag108 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag108); procedure Set_Flag109 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag109); procedure Set_Flag110 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag110); procedure Set_Flag111 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag111); procedure Set_Flag112 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag112); procedure Set_Flag113 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag113); procedure Set_Flag114 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag114); procedure Set_Flag115 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag115); procedure Set_Flag116 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag116); procedure Set_Flag117 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag117); procedure Set_Flag118 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag118); procedure Set_Flag119 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag119); procedure Set_Flag120 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag120); procedure Set_Flag121 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag121); procedure Set_Flag122 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag122); procedure Set_Flag123 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag123); procedure Set_Flag124 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag124); procedure Set_Flag125 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag125); procedure Set_Flag126 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag126); procedure Set_Flag127 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag127); procedure Set_Flag128 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag128); procedure Set_Flag129 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag129); procedure Set_Flag130 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag130); procedure Set_Flag131 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag131); procedure Set_Flag132 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag132); procedure Set_Flag133 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag133); procedure Set_Flag134 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag134); procedure Set_Flag135 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag135); procedure Set_Flag136 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag136); procedure Set_Flag137 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag137); procedure Set_Flag138 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag138); procedure Set_Flag139 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag139); procedure Set_Flag140 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag140); procedure Set_Flag141 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag141); procedure Set_Flag142 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag142); procedure Set_Flag143 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag143); procedure Set_Flag144 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag144); procedure Set_Flag145 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag145); procedure Set_Flag146 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag146); procedure Set_Flag147 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag147); procedure Set_Flag148 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag148); procedure Set_Flag149 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag149); procedure Set_Flag150 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag150); procedure Set_Flag151 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag151); procedure Set_Flag152 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag152); procedure Set_Flag153 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag153); procedure Set_Flag154 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag154); procedure Set_Flag155 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag155); procedure Set_Flag156 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag156); procedure Set_Flag157 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag157); procedure Set_Flag158 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag158); procedure Set_Flag159 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag159); procedure Set_Flag160 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag160); procedure Set_Flag161 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag161); procedure Set_Flag162 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag162); procedure Set_Flag163 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag163); procedure Set_Flag164 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag164); procedure Set_Flag165 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag165); procedure Set_Flag166 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag166); procedure Set_Flag167 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag167); procedure Set_Flag168 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag168); procedure Set_Flag169 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag169); procedure Set_Flag170 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag170); procedure Set_Flag171 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag171); procedure Set_Flag172 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag172); procedure Set_Flag173 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag173); procedure Set_Flag174 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag174); procedure Set_Flag175 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag175); procedure Set_Flag176 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag176); procedure Set_Flag177 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag177); procedure Set_Flag178 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag178); procedure Set_Flag179 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag179); procedure Set_Flag180 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag180); procedure Set_Flag181 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag181); procedure Set_Flag182 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag182); procedure Set_Flag183 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag183); procedure Set_Flag184 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag184); procedure Set_Flag185 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag185); procedure Set_Flag186 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag186); procedure Set_Flag187 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag187); procedure Set_Flag188 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag188); procedure Set_Flag189 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag189); procedure Set_Flag190 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag190); procedure Set_Flag191 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag191); procedure Set_Flag192 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag192); procedure Set_Flag193 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag193); procedure Set_Flag194 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag194); procedure Set_Flag195 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag195); procedure Set_Flag196 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag196); procedure Set_Flag197 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag197); procedure Set_Flag198 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag198); procedure Set_Flag199 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag199); procedure Set_Flag200 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag200); procedure Set_Flag201 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag201); procedure Set_Flag202 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag202); procedure Set_Flag203 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag203); procedure Set_Flag204 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag204); procedure Set_Flag205 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag205); procedure Set_Flag206 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag206); procedure Set_Flag207 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag207); procedure Set_Flag208 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag208); procedure Set_Flag209 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag209); procedure Set_Flag210 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag210); procedure Set_Flag211 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag211); procedure Set_Flag212 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag212); procedure Set_Flag213 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag213); procedure Set_Flag214 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag214); procedure Set_Flag215 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag215); procedure Set_Flag216 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag216); procedure Set_Flag217 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag217); procedure Set_Flag218 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag218); procedure Set_Flag219 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag219); procedure Set_Flag220 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag220); procedure Set_Flag221 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag221); procedure Set_Flag222 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag222); procedure Set_Flag223 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag223); procedure Set_Flag224 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag224); procedure Set_Flag225 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag225); procedure Set_Flag226 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag226); procedure Set_Flag227 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag227); procedure Set_Flag228 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag228); procedure Set_Flag229 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag229); procedure Set_Flag230 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag230); procedure Set_Flag231 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag231); procedure Set_Flag232 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag232); procedure Set_Flag233 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag233); procedure Set_Flag234 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag234); procedure Set_Flag235 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag235); procedure Set_Flag236 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag236); procedure Set_Flag237 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag237); procedure Set_Flag238 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag238); procedure Set_Flag239 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag239); procedure Set_Flag240 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag240); procedure Set_Flag241 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag241); procedure Set_Flag242 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag242); procedure Set_Flag243 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag243); procedure Set_Flag244 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag244); procedure Set_Flag245 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag245); procedure Set_Flag246 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag246); procedure Set_Flag247 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag247); procedure Set_Flag248 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag248); procedure Set_Flag249 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag249); procedure Set_Flag250 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag250); procedure Set_Flag251 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag251); procedure Set_Flag252 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag252); procedure Set_Flag253 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag253); procedure Set_Flag254 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag254); procedure Set_Flag255 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag255); procedure Set_Flag256 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag256); procedure Set_Flag257 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag257); procedure Set_Flag258 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag258); procedure Set_Flag259 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag259); procedure Set_Flag260 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag260); procedure Set_Flag261 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag261); procedure Set_Flag262 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag262); procedure Set_Flag263 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag263); procedure Set_Flag264 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag264); procedure Set_Flag265 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag265); procedure Set_Flag266 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag266); procedure Set_Flag267 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag267); procedure Set_Flag268 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag268); procedure Set_Flag269 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag269); procedure Set_Flag270 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag270); procedure Set_Flag271 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag271); procedure Set_Flag272 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag272); procedure Set_Flag273 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag273); procedure Set_Flag274 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag274); procedure Set_Flag275 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag275); procedure Set_Flag276 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag276); procedure Set_Flag277 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag277); procedure Set_Flag278 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag278); procedure Set_Flag279 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag279); procedure Set_Flag280 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag280); procedure Set_Flag281 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag281); procedure Set_Flag282 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag282); procedure Set_Flag283 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag283); procedure Set_Flag284 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag284); procedure Set_Flag285 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag285); procedure Set_Flag286 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag286); procedure Set_Flag287 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag287); procedure Set_Flag288 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag288); procedure Set_Flag289 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag289); procedure Set_Flag290 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag290); procedure Set_Flag291 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag291); procedure Set_Flag292 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag292); procedure Set_Flag293 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag293); procedure Set_Flag294 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag294); procedure Set_Flag295 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag295); procedure Set_Flag296 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag296); procedure Set_Flag297 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag297); procedure Set_Flag298 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag298); procedure Set_Flag299 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag299); procedure Set_Flag300 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag300); procedure Set_Flag301 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag301); procedure Set_Flag302 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag302); procedure Set_Flag303 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag303); procedure Set_Flag304 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag304); procedure Set_Flag305 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag305); procedure Set_Flag306 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag306); procedure Set_Flag307 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag307); procedure Set_Flag308 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag308); procedure Set_Flag309 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag309); procedure Set_Flag310 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag310); procedure Set_Flag311 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag311); procedure Set_Flag312 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag312); procedure Set_Flag313 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag313); procedure Set_Flag314 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag314); procedure Set_Flag315 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag315); procedure Set_Flag316 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag316); procedure Set_Flag317 (N : Node_Id; Val : Boolean); pragma Inline (Set_Flag317); -- The following versions of Set_Noden also set the parent pointer of -- the referenced node if it is not Empty. procedure Set_Node1_With_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node1_With_Parent); procedure Set_Node2_With_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node2_With_Parent); procedure Set_Node3_With_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node3_With_Parent); procedure Set_Node4_With_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node4_With_Parent); procedure Set_Node5_With_Parent (N : Node_Id; Val : Node_Id); pragma Inline (Set_Node5_With_Parent); -- The following versions of Set_Listn also set the parent pointer of -- the referenced node if it is not Empty. procedure Set_List1_With_Parent (N : Node_Id; Val : List_Id); pragma Inline (Set_List1_With_Parent); procedure Set_List2_With_Parent (N : Node_Id; Val : List_Id); pragma Inline (Set_List2_With_Parent); procedure Set_List3_With_Parent (N : Node_Id; Val : List_Id); pragma Inline (Set_List3_With_Parent); procedure Set_List4_With_Parent (N : Node_Id; Val : List_Id); pragma Inline (Set_List4_With_Parent); procedure Set_List5_With_Parent (N : Node_Id; Val : List_Id); pragma Inline (Set_List5_With_Parent); end Unchecked_Access; ----------------------------- -- Private Part Subpackage -- ----------------------------- -- The following package contains the definition of the data structure -- used by the implementation of the Atree package. Logically it really -- corresponds to the private part, hence the name. The reason that it -- is defined as a sub-package is to allow special access from clients -- that need to see the internals of the data structures. package Atree_Private_Part is ------------------------- -- Tree Representation -- ------------------------- -- The nodes of the tree are stored in a table (i.e. an array). In the -- case of extended nodes six consecutive components in the array are -- used. There are thus two formats for array components. One is used -- for non-extended nodes, and for the first component of extended -- nodes. The other is used for the extension parts (second, third, -- fourth, fifth, and sixth components) of an extended node. A variant -- record structure is used to distinguish the two formats. type Node_Record (Is_Extension : Boolean := False) is record -- Logically, the only field in the common part is the above -- Is_Extension discriminant (a single bit). However, Gigi cannot -- yet handle such a structure, so we fill out the common part of -- the record with fields that are used in different ways for -- normal nodes and node extensions. Pflag1, Pflag2 : Boolean; -- The Paren_Count field is represented using two boolean flags, -- where Pflag1 is worth 1, and Pflag2 is worth 2. This is done -- because we need to be easily able to reuse this field for -- extra flags in the extended node case. In_List : Boolean; -- Flag used to indicate if node is a member of a list. -- This field is considered private to the Atree package. Has_Aspects : Boolean; -- Flag used to indicate that a node has aspect specifications that -- are associated with the node. See Aspects package for details. Rewrite_Ins : Boolean; -- Flag set by Mark_Rewrite_Insertion procedure. -- This field is considered private to the Atree package. Analyzed : Boolean; -- Flag to indicate the node has been analyzed (and expanded) Comes_From_Source : Boolean; -- Flag to indicate that node comes from the source program (i.e. -- was built by the parser or scanner, not the analyzer or expander). Error_Posted : Boolean; -- Flag to indicate that an error message has been posted on the -- node (to avoid duplicate flags on the same node) Flag4 : Boolean; Flag5 : Boolean; Flag6 : Boolean; Flag7 : Boolean; Flag8 : Boolean; Flag9 : Boolean; Flag10 : Boolean; Flag11 : Boolean; Flag12 : Boolean; Flag13 : Boolean; Flag14 : Boolean; Flag15 : Boolean; Flag16 : Boolean; Flag17 : Boolean; Flag18 : Boolean; -- Flags 4-18 for a normal node. Note that Flags 0-3 are stored -- separately in the Flags array. -- The above fields are used as follows in components 2-6 of -- an extended node entry. -- In_List used as Flag19,Flag40,Flag129,Flag216,Flag287 -- Has_Aspects used as Flag20,Flag41,Flag130,Flag217,Flag288 -- Rewrite_Ins used as Flag21,Flag42,Flag131,Flag218,Flag289 -- Analyzed used as Flag22,Flag43,Flag132,Flag219,Flag290 -- Comes_From_Source used as Flag23,Flag44,Flag133,Flag220,Flag291 -- Error_Posted used as Flag24,Flag45,Flag134,Flag221,Flag292 -- Flag4 used as Flag25,Flag46,Flag135,Flag222,Flag293 -- Flag5 used as Flag26,Flag47,Flag136,Flag223,Flag294 -- Flag6 used as Flag27,Flag48,Flag137,Flag224,Flag295 -- Flag7 used as Flag28,Flag49,Flag138,Flag225,Flag296 -- Flag8 used as Flag29,Flag50,Flag139,Flag226,Flag297 -- Flag9 used as Flag30,Flag51,Flag140,Flag227,Flag298 -- Flag10 used as Flag31,Flag52,Flag141,Flag228,Flag299 -- Flag11 used as Flag32,Flag53,Flag142,Flag229,Flag300 -- Flag12 used as Flag33,Flag54,Flag143,Flag230,Flag301 -- Flag13 used as Flag34,Flag55,Flag144,Flag231,Flag302 -- Flag14 used as Flag35,Flag56,Flag145,Flag232,Flag303 -- Flag15 used as Flag36,Flag57,Flag146,Flag233,Flag304 -- Flag16 used as Flag37,Flag58,Flag147,Flag234,Flag305 -- Flag17 used as Flag38,Flag59,Flag148,Flag235,Flag306 -- Flag18 used as Flag39,Flag60,Flag149,Flag236,Flag307 -- Pflag1 used as Flag61,Flag62,Flag150,Flag237,Flag308 -- Pflag2 used as Flag63,Flag64,Flag151,Flag238,Flag309 Nkind : Node_Kind; -- For a non-extended node, or the initial section of an extended -- node, this field holds the Node_Kind value. For an extended node, -- The Nkind field is used as follows: -- -- Second entry: holds the Ekind field of the entity -- Third entry: holds 8 additional flags (Flag65-Flag72) -- Fourth entry: holds 8 additional flags (Flag239-246) -- Fifth entry: holds 8 additional flags (Flag247-254) -- Sixth entry: holds 8 additional flags (Flag310-317) -- Now finally (on an 32-bit boundary) comes the variant part case Is_Extension is -- Non-extended node, or first component of extended node when False => Sloc : Source_Ptr; -- Source location for this node Link : Union_Id; -- This field is used either as the Parent pointer (if In_List -- is False), or to point to the list header (if In_List is -- True). This field is considered private and can be modified -- only by Atree or by Nlists. Field1 : Union_Id; Field2 : Union_Id; Field3 : Union_Id; Field4 : Union_Id; Field5 : Union_Id; -- Five general use fields, which can contain Node_Id, List_Id, -- Elist_Id, String_Id, or Name_Id values depending on the -- values in Nkind and (for extended nodes), in Ekind. See -- packages Sinfo and Einfo for details of their use. -- Extension (second component) of extended node when True => Field6 : Union_Id; Field7 : Union_Id; Field8 : Union_Id; Field9 : Union_Id; Field10 : Union_Id; Field11 : Union_Id; Field12 : Union_Id; -- Seven additional general fields available only for entities -- See package Einfo for details of their use (which depends -- on the value in the Ekind field). -- In the third component, the extension format as described -- above is used to hold additional general fields and flags -- as follows: -- Field6-11 Holds Field13-Field18 -- Field12 Holds Flag73-Flag96 and Convention -- In the fourth component, the extension format as described -- above is used to hold additional general fields and flags -- as follows: -- Field6-10 Holds Field19-Field23 -- Field11 Holds Flag152-Flag183 -- Field12 Holds Flag97-Flag128 -- In the fifth component, the extension format as described -- above is used to hold additional general fields and flags -- as follows: -- Field6-11 Holds Field24-Field29 -- Field12 Holds Flag184-Flag215 -- In the sixth component, the extension format as described -- above is used to hold additional general fields and flags -- as follows: -- Field6-11 Holds Field30-Field35 -- Field12 Holds Flag255-Flag286 end case; end record; pragma Pack (Node_Record); for Node_Record'Size use 8*32; for Node_Record'Alignment use 4; function E_To_N is new Unchecked_Conversion (Entity_Kind, Node_Kind); function N_To_E is new Unchecked_Conversion (Node_Kind, Entity_Kind); -- Default value used to initialize default nodes. Note that some of the -- fields get overwritten, and in particular, Nkind always gets reset. Default_Node : Node_Record := ( Is_Extension => False, Pflag1 => False, Pflag2 => False, In_List => False, Has_Aspects => False, Rewrite_Ins => False, Analyzed => False, Comes_From_Source => False, -- modified by Set_Comes_From_Source_Default Error_Posted => False, Flag4 => False, Flag5 => False, Flag6 => False, Flag7 => False, Flag8 => False, Flag9 => False, Flag10 => False, Flag11 => False, Flag12 => False, Flag13 => False, Flag14 => False, Flag15 => False, Flag16 => False, Flag17 => False, Flag18 => False, Nkind => N_Unused_At_Start, Sloc => No_Location, Link => Empty_List_Or_Node, Field1 => Empty_List_Or_Node, Field2 => Empty_List_Or_Node, Field3 => Empty_List_Or_Node, Field4 => Empty_List_Or_Node, Field5 => Empty_List_Or_Node); -- Default value used to initialize node extensions (i.e. the second -- through sixth components of an extended node). Note we are cheating -- a bit here when it comes to Node12, which really holds flags and (for -- the third component), the convention. But it works because Empty, -- False, Convention_Ada, all happen to be all zero bits. Default_Node_Extension : constant Node_Record := ( Is_Extension => True, Pflag1 => False, Pflag2 => False, In_List => False, Has_Aspects => False, Rewrite_Ins => False, Analyzed => False, Comes_From_Source => False, Error_Posted => False, Flag4 => False, Flag5 => False, Flag6 => False, Flag7 => False, Flag8 => False, Flag9 => False, Flag10 => False, Flag11 => False, Flag12 => False, Flag13 => False, Flag14 => False, Flag15 => False, Flag16 => False, Flag17 => False, Flag18 => False, Nkind => E_To_N (E_Void), Field6 => Empty_List_Or_Node, Field7 => Empty_List_Or_Node, Field8 => Empty_List_Or_Node, Field9 => Empty_List_Or_Node, Field10 => Empty_List_Or_Node, Field11 => Empty_List_Or_Node, Field12 => Empty_List_Or_Node); -- The following defines the extendable array used for the nodes table -- Nodes with extensions use six consecutive entries in the array package Nodes is new Table.Table ( Table_Component_Type => Node_Record, Table_Index_Type => Node_Id'Base, Table_Low_Bound => First_Node_Id, Table_Initial => Alloc.Nodes_Initial, Table_Increment => Alloc.Nodes_Increment, Table_Name => "Nodes"); -- The following is a parallel table to Nodes, which provides 8 more -- bits of space that logically belong to the corresponding node. This -- is currently used to implement Flags 0,1,2,3 for normal nodes, or -- the first component of an extended node (four bits unused). Entries -- for extending components are completely unused. type Flags_Byte is record Flag0 : Boolean; Flag1 : Boolean; Flag2 : Boolean; Flag3 : Boolean; Spare0 : Boolean; Spare1 : Boolean; Spare2 : Boolean; Spare3 : Boolean; end record; for Flags_Byte'Size use 8; pragma Pack (Flags_Byte); Default_Flags : constant Flags_Byte := (others => False); -- Default value used to initialize new entries package Flags is new Table.Table ( Table_Component_Type => Flags_Byte, Table_Index_Type => Node_Id'Base, Table_Low_Bound => First_Node_Id, Table_Initial => Alloc.Nodes_Initial, Table_Increment => Alloc.Nodes_Increment, Table_Name => "Flags"); end Atree_Private_Part; end Atree;