------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- S I N F O -- -- -- -- S p e c -- -- -- -- Copyright (C) 1992-2005, Free Software Foundation, Inc. -- -- -- -- GNAT is free software; you can redistribute it and/or modify it under -- -- terms of the GNU General Public License as published by the Free Soft- -- -- ware Foundation; either version 2, or (at your option) any later ver- -- -- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License -- -- for more details. You should have received a copy of the GNU General -- -- Public License distributed with GNAT; see file COPYING. If not, write -- -- to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, -- -- MA 02111-1307, USA. -- -- -- -- As a special exception, if other files instantiate generics from this -- -- unit, or you link this unit with other files to produce an executable, -- -- this unit does not by itself cause the resulting executable to be -- -- covered by the GNU General Public License. This exception does not -- -- however invalidate any other reasons why the executable file might be -- -- covered by the GNU Public License. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ -- This package defines the structure of the abstract syntax tree. The Tree -- package provides a basic tree structure. Sinfo describes how this -- structure is used to represent the syntax of an Ada program. -- Note: the grammar used here is taken from Version 5.95 of the RM, dated -- November 1994. The grammar in the RM is followed very closely in the tree -- design, and is repeated as part of this source file. -- The tree contains not only the full syntactic representation of the -- program, but also the results of semantic analysis. In particular, the -- nodes for defining identifiers, defining character literals and defining -- operator symbols, collectively referred to as entities, represent what -- would normally be regarded as the symbol table information. In addition -- a number of the tree nodes contain semantic information. -- WARNING: There is a C version of this package. Any changes to this -- source file must be properly reflected in this C header file sinfo.h -- which is created automatically from sinfo.ads using xsinfo.adb. with Types; use Types; with Uintp; use Uintp; with Urealp; use Urealp; package Sinfo is --------------------------------- -- Making Changes to This File -- --------------------------------- -- If changes are made to this file, a number of related steps must be -- carried out to ensure consistency. First, if a field access function -- is added, it appears in seven places: -- The documentation associated with the node -- The spec of the access function in sinfo.ads -- The body of the access function in sinfo.adb -- The pragma Inline at the end of sinfo.ads for the access function -- The spec of the set procedure in sinfo.ads -- The body of the set procedure in sinfo.adb -- The pragma Inline at the end of sinfo.ads for the set procedure -- The field chosen must be consistent in all places, and, for a node -- that is a subexpression, must not overlap any of the standard -- expression fields. -- In addition, if any of the standard expression fields is changed, then -- the utiliy program which creates the Treeprs spec (in file treeprs.ads) -- must be updated appropriately, since it special cases expression fields. -- If a new tree node is added, then the following changes are made -- Add it to the documentation in the appropriate place -- Add its fields to this documentation section -- Define it in the appropriate classification in Node_Kind -- In the body (sinfo), add entries to the access functions for all -- its fields (except standard expression fields) to include the new -- node in the checks. -- Add an appropriate section to the case statement in sprint.adb -- Add an appropriate section to the case statement in sem.adb -- Add an appropraite section to the case statement in exp_util.adb -- (Insert_Actions procedure) -- For a subexpression, add an appropriate sections to the case -- statement in sem_eval.adb -- For a subexpression, add an appropriate sections to the case -- statement in sem_res.adb -- Finally, four utility programs must be run: -- Run CSinfo to check that you have made the changes consistently. -- It checks most of the rules given above, with clear error messages. -- This utility reads sinfo.ads and sinfo.adb and generates a report -- to standard output. -- Run XSinfo to create a-sinfo.h, the corresponding C header. This -- utility reads sinfo.ads and generates a-sinfo.h. Note that it -- does not need to read sinfo.adb, since the contents of the body -- are algorithmically determinable from the spec. -- Run XTreeprs to create treeprs.ads, an updated version of -- the module that is used to drive the tree print routine. This -- utility reads (but does not modify) treeprs.adt, the template -- that provides the basic structure of the file, and then fills -- in the data from the comments in sinfo.ads. -- Run XNmake to create nmake.ads and nmake.adb, the package body -- and spec of the Nmake package which contains functions for -- constructing nodes. -- Note: sometime we could write a utility that actually generated the -- body of sinfo from the spec instead of simply checking it, since, as -- noted above, the contents of the body can be determined from the spec. -------------------------------- -- Implicit Nodes in the Tree -- -------------------------------- -- Generally the structure of the tree very closely follows the grammar -- as defined in the RM. However, certain nodes are omitted to save -- space and simplify semantic processing. Two general classes of such -- omitted nodes are as follows: -- If the only possibilities for a non-terminal are one or more other -- non terminals (i.e. the rule is a "skinny" rule), then usually the -- corresponding node is omitted from the tree, and the target construct -- appears directly. For example, a real type definition is either a -- floating point definition or a fixed point definition. No explicit -- node appears for real type definition. Instead either the floating -- point definition or fixed point definition appears directly. -- If a non-terminal corresponds to a list of some other non-terminal -- (possibly with separating punctuation), then usually it is omitted -- from the tree, and a list of components appears instead. For -- example, sequence of statements does not appear explicitly in the -- tree. Instead a list of statements appears directly. -- Some additional cases of omitted nodes occur and are documented -- individually. In particular, many nodes are omitted in the tree -- generated for an expression. ------------------------------------------- -- Handling of Defining Identifier Lists -- ------------------------------------------- -- In several declarative forms in the syntax, lists of defining -- identifiers appear (object declarations, component declarations, -- number declarations etc.) -- The semantics of such statements are equivalent to a series of -- identical declarations of single defining identifiers (except that -- conformance checks require the same grouping of identifiers in the -- parameter case). -- To simplify semantic processing, the parser breaks down such multiple -- declaration cases into sequences of single declarations, duplicating -- type and initialization information as required. The flags More_Ids -- and Prev_Ids are used to record the original form of the source in -- the case where the original source used a list of names, More_Ids -- being set on all but the last name and Prev_Ids being set on all -- but the first name. These flags are used to reconstruct the original -- source (e.g. in the Sprint package), and also are included in the -- conformance checks, but otherwise have no semantic significance. -- Note: the reason that we use More_Ids and Prev_Ids rather than -- First_Name and Last_Name flags is so that the flags are off in the -- normal one identifier case, which minimizes tree print output. ----------------------- -- Use of Node Lists -- ----------------------- -- With a few exceptions, if a construction of the form {non-terminal} -- appears in the tree, lists are used in the corresponding tree node -- (see package Nlists for handling of node lists). In this case a field -- of the parent node points to a list of nodes for the non-terminal. The -- field name for such fields has a plural name which always ends in "s". -- For example, a case statement has a field Alternatives pointing to a -- list of case statement alternative nodes. -- Only fields pointing to lists have names ending in "s", so generally -- the structure is strongly typed, fields not ending in s point to -- single nodes, and fields ending in s point to lists. -- The following example shows how a traversal of a list is written. We -- suppose here that Stmt points to a N_Case_Statement node which has -- a list field called Alternatives: -- Alt := First (Alternatives (Stmt)); -- while Present (Alt) loop -- .. -- -- processing for case statement alternative Alt -- .. -- Alt := Next (Alt); -- end loop; -- The Present function tests for Empty, which in this case signals the -- end of the list. First returns Empty immediately if the list is empty. -- Present is defined in Atree, First and Next are defined in Nlists. -- The exceptions to this rule occur with {DEFINING_IDENTIFIERS} in all -- contexts, which is handled as described in the previous section, and -- with {,library_unit_NAME} in the N_With_Clause mode, which is handled -- using the First_Name and Last_Name flags, as further detailed in the -- description of the N_With_Clause node. ------------- -- Pragmas -- ------------- -- Pragmas can appear in many different context, but are not included -- in the grammar. Still they must appear in the tree, so they can be -- properly processed. -- Two approaches are used. In some cases, an extra field is defined -- in an appropriate node that contains a list of pragmas appearing -- in the expected context. For example pragmas can appear before an -- Accept_Alternative in a Selective_Accept_Statement, and these pragmas -- appear in the Pragmas_Before field of the N_Accept_Alternative node. -- The other approach is to simply allow pragmas to appear in syntactic -- lists where the grammar (of course) does not include the possibility. -- For example, the Variants field of an N_Variant_Part node points to -- a list that can contain both N_Pragma and N_Variant nodes. -- To make processing easier in the latter case, the Nlists package -- provides a set of routines (First_Non_Pragma, Last_Non_Pragma, -- Next_Non_Pragma, Prev_Non_Pragma) that allow such lists to be -- handled ignoring all pragmas. -- In the case of the variants list, we can either write: -- Variant := First (Variants (N)); -- while Present (Variant) loop -- ... -- Variant := Next (Variant); -- end loop; -- or -- Variant := First_Non_Pragma (Variants (N)); -- while Present (Variant) loop -- ... -- Variant := Next_Non_Pragma (Variant); -- end loop; -- In the first form of the loop, Variant can either be an N_Pragma or -- an N_Variant node. In the second form, Variant can only be N_Variant -- since all pragmas are skipped. --------------------- -- Optional Fields -- --------------------- -- Fields which correspond to a section of the syntax enclosed in square -- brackets are generally omitted (and the corresponding field set to -- Empty for a node, or No_List for a list). The documentation of such -- fields notes these cases. One exception to this rule occurs in the -- case of possibly empty statement sequences (such as the sequence of -- statements in an entry call alternative). Such cases appear in the -- syntax rules as [SEQUENCE_OF_STATEMENTS] and the fields corresponding -- to such optional statement sequences always contain an empty list (not -- No_List) if no statements are present. -- Note: the utility program that constructs the body and spec of the -- Nmake package relies on the format of the comments to determine if -- a field should have a default value in the corresponding make routine. -- The rule is that if the first line of the description of the field -- contains the string "(set to xxx if", then a default value of xxx is -- provided for this field in the corresponding Make_yyy routine. ----------------------------------- -- Note on Body/Spec Terminology -- ----------------------------------- -- In informal discussions about Ada, it is customary to refer to package -- and subprogram specs and bodies. However, this is not technically -- correct, what is normally referred to as a spec or specification is in -- fact a package declaration or subprogram declaration. We are careful -- in GNAT to use the correct terminology and in particular, the full -- word specification is never used as an incorrect substitute for -- declaration. The structure and terminology used in the tree also -- reflects the grammar and thus uses declaration and specification in -- the technically correct manner. -- However, there are contexts in which the informal terminology is -- useful. We have the word "body" to refer to the Interp_Etype declared by -- the declaration of a unit body, and in some contexts we need a -- similar term to refer to the entity declared by the package or -- subprogram declaration, and simply using declaration can be confusing -- since the body also has a declaration. -- An example of such a context is the link between the package body -- and its declaration. With_Declaration is confusing, since -- the package body itself is a declaration. -- To deal with this problem, we reserve the informal term Spec, i.e. -- the popular abbreviation used in this context, to refer to the entity -- declared by the package or subprogram declaration. So in the above -- example case, the field in the body is called With_Spec. -- Another important context for the use of the word Spec is in error -- messages, where a hyper-correct use of declaration would be confusing -- to a typical Ada programmer, and even for an expert programmer can -- cause confusion since the body has a declaration as well. -- So, to summarize: -- Declaration always refers to the syntactic entity that is called -- a declaration. In particular, subprogram declaration -- and package declaration are used to describe the -- syntactic entity that includes the semicolon. -- Specification always refers to the syntactic entity that is called -- a specification. In particular, the terms procedure -- specification, function specification, package -- specification, subprogram specification always refer -- to the syntactic entity that has no semicolon. -- Spec is an informal term, used to refer to the entity -- that is declared by a task declaration, protected -- declaration, generic declaration, subprogram -- declaration or package declaration. -- This convention is followed throughout the GNAT documentation -- both internal and external, and in all error message text. ------------------------ -- Internal Use Nodes -- ------------------------ -- These are Node_Kind settings used in the internal implementation -- which are not logically part of the specification. -- N_Unused_At_Start -- Completely unused entry at the start of the enumeration type. This -- is inserted so that no legitimate value is zero, which helps to get -- better debugging behavior, since zero is a likely uninitialized value). -- N_Unused_At_End -- Completely unused entry at the end of the enumeration type. This is -- handy so that arrays with Node_Kind as the index type have an extra -- entry at the end (see for example the use of the Pchar_Pos_Array in -- Treepr, where the extra entry provides the limit value when dealing -- with the last used entry in the array). ----------------------------------------- -- Note on the settings of Sloc fields -- ----------------------------------------- -- The Sloc field of nodes that come from the source is set by the -- parser. For internal nodes, and nodes generated during expansion -- the Sloc is usually set in the call to the constructor for the node. -- In general the Sloc value chosen for an internal node is the Sloc of -- the source node whose processing is responsible for the expansion. For -- example, the Sloc of an inherited primitive operation is the Sloc of -- the corresponding derived type declaration. -- For the nodes of a generic instantiation, the Sloc value is encoded -- to represent both the original Sloc in the generic unit, and the Sloc -- of the instantiation itself. See Sinput.ads for details. -- Subprogram instances create two callable entities: one is the visible -- subprogram instance, and the other is an anonymous subprogram nested -- within a wrapper package that contains the renamings for the actuals. -- Both of these entities have the Sloc of the defining entity in the -- instantiation node. This simplifies some ASIS queries. ----------------------- -- Field Definitions -- ----------------------- -- In the following node definitions, all fields, both syntactic and -- semantic, are documented. The one exception is in the case of entities -- (defining indentifiers, character literals and operator symbols), -- where the usage of the fields depends on the entity kind. Entity -- fields are fully documented in the separate package Einfo. -- In the node definitions, three common sets of fields are abbreviated -- to save both space in the documentation, and also space in the string -- (defined in Tree_Print_Strings) used to print trees. The following -- abbreviations are used: -- Note: the utility program that creates the Treeprs spec (in the file -- xtreeprs.adb) knows about the special fields here, so it must be -- modified if any change is made to these fields. -- "plus fields for binary operator" -- Chars (Name1) Name_Id for the operator -- Left_Opnd (Node2) left operand expression -- Right_Opnd (Node3) right operand expression -- Entity (Node4-Sem) defining entity for operator -- Associated_Node (Node4-Sem) for generic processing -- Do_Overflow_Check (Flag17-Sem) set if overflow check needed -- Has_Private_View (Flag11-Sem) set in generic units. -- "plus fields for unary operator" -- Chars (Name1) Name_Id for the operator -- Right_Opnd (Node3) right operand expression -- Entity (Node4-Sem) defining entity for operator -- Associated_Node (Node4-Sem) for generic processing -- Do_Overflow_Check (Flag17-Sem) set if overflow check needed -- Has_Private_View (Flag11-Sem) set in generic units. -- "plus fields for expression" -- Paren_Count number of parentheses levels -- Etype (Node5-Sem) type of the expression -- Is_Overloaded (Flag5-Sem) >1 type interpretation exists -- Is_Static_Expression (Flag6-Sem) set for static expression -- Raises_Constraint_Error (Flag7-Sem) evaluation raises CE -- Must_Not_Freeze (Flag8-Sem) set if must not freeze -- Do_Range_Check (Flag9-Sem) set if a range check needed -- Assignment_OK (Flag15-Sem) set if modification is OK -- Is_Controlling_Actual (Flag16-Sem) set for controlling argument -- Note: see under (EXPRESSION) for further details on the use of -- the Paren_Count field to record the number of parentheses levels. -- Node_Kind is the type used in the Nkind field to indicate the node -- kind. The actual definition of this type is given later (the reason -- for this is that we want the descriptions ordered by logical chapter -- in the RM, but the type definition is reordered to facilitate the -- definition of some subtype ranges. The individual descriptions of -- the nodes show how the various fields are used in each node kind, -- as well as providing logical names for the fields. Functions and -- procedures are provided for accessing and setting these fields -- using these logical names. ----------------------- -- Gigi Restrictions -- ----------------------- -- The tree passed to Gigi is more restricted than the general tree form. -- For example, as a result of expansion, most of the tasking nodes can -- never appear. For each node to which either a complete or partial -- restriction applies, a note entitled "Gigi restriction" appears which -- documents the restriction. -- Note that most of these restrictions apply only to trees generated when -- code is being generated, since they involved expander actions that -- destroy the tree. ------------------------ -- Common Flag Fields -- ------------------------ -- The following flag fields appear in all nodes -- Analyzed -- This flag is used to indicate that a node (and all its children -- have been analyzed. It is used to avoid reanalysis of a node that -- has already been analyzed, both for efficiency and functional -- correctness reasons. -- Error_Posted -- This flag is used to avoid multiple error messages being posted -- on or referring to the same node. This flag is set if an error -- message refers to a node or is posted on its source location, -- and has the effect of inhibiting further messages involving -- this same node. -- Comes_From_Source -- This flag is on for any nodes built by the scanner or parser from -- the source program, and off for any nodes built by the analyzer or -- expander. It indicates that a node comes from the original source. -- This flag is defined in Atree. -- Has_Dynamic_Length_Check and Has_Dynamic_Range_Check also appear on -- all nodes. They are fully described in the next section. ------------------------------------ -- Description of Semantic Fields -- ------------------------------------ -- The meaning of the syntactic fields is generally clear from their -- names without any further description, since the names are chosen -- to correspond very closely to the syntax in the reference manual. -- This section describes the usage of the semantic fields, which are -- used to contain additional information determined during semantic -- analysis. -- ABE_Is_Certain (Flag18-Sem) -- This flag is set in an instantiation node or a call node is -- determined to be sure to raise an ABE. This is used to trigger -- special handling of such cases, particularly in the instantiation -- case where we avoid instantiating the body if this flag is set. -- This flag is also present in an N_Formal_Package_Declaration_Node -- since formal package declarations are treated like instantiations, -- but it is always set to False in this context. -- Accept_Handler_Records (List5-Sem) -- This field is present only in an N_Accept_Alternative node. It is -- used to temporarily hold the exception handler records from an -- accept statement in a selective accept. These exception handlers -- will eventually be placed in the Handler_Records list of the -- procedure built for this accept (see Expand_N_Selective_Accept -- procedure in Exp_Ch9 for further details). -- Access_Types_To_Process (Elist2-Sem) -- Present in N_Freeze_Entity nodes for Incomplete or private types. -- Contains the list of access types which may require specific -- treatment when the nature of the type completion is completely -- known. An example of such treatement is the generation of the -- associated_final_chain. -- Actions (List1-Sem) -- This field contains a sequence of actions that are associated -- with the node holding the field. See the individual node types -- for details of how this field is used, as well as the description -- of the specific use for a particular node type. -- Activation_Chain_Entity (Node3-Sem) -- This is used in tree nodes representing task activators (blocks, -- subprogram bodies, package declarations, and task bodies). It is -- initially Empty, and then gets set to point to the entity for the -- declared Activation_Chain variable when the first task is declared. -- When tasks are declared in the corresponding declarative region -- this entity is located by name (its name is always _Chain) and -- the declared tasks are added to the chain. -- Acts_As_Spec (Flag4-Sem) -- A flag set in the N_Subprogram_Body node for a subprogram body -- which is acting as its own spec. This flag also appears in the -- compilation unit node at the library level for such a subprogram -- (see further description in spec of Lib package). -- Aggregate_Bounds (Node3-Sem) -- Present in array N_Aggregate nodes. If the aggregate contains -- component associations this field points to an N_Range node whose -- bounds give the lowest and highest discrete choice values. If the -- named aggregate contains a dynamic or null choice this field is -- empty. If the aggregate contains positional elements this field -- points to an N_Integer_Literal node giving the number of positional -- elements. Note that if the aggregate contains positional elements -- and an other choice the N_Integer_Literal only accounts for the -- number of positional elements. -- All_Others (Flag11-Sem) -- Present in an N_Others_Choice node. This flag is set in the case -- of an others exception where all exceptions are to be caught, even -- those that are not normally handled (in particular the tasking abort -- signal). This is used for translation of the at end handler into -- a normal exception handler. -- Assignment_OK (Flag15-Sem) -- This flag is set in a subexpression node for an object, indicating -- that the associated object can be modified, even if this would not -- normally be permissible (either by direct assignment, or by being -- passed as an out or in-out parameter). This is used by the expander -- for a number of purposes, including initialzation of constants and -- limited type objects (such as tasks), setting discriminant fields, -- setting tag values, etc. N_Object_Declaration nodes also have this -- flag defined. Here it is used to indicate that an initialization -- expression is valid, even where it would normally not be allowed -- (e.g. where the type involved is limited). -- Associated_Node (Node4-Sem) -- Present in nodes that can denote an entity: identifiers, character -- literals, operator symbols, expanded names, operator nodes, and -- attribute reference nodes (all these nodes have an Entity field). -- This field is also present in N_Aggregate, N_Selected_Component, -- and N_Extension_Aggregate nodes. This field is used in generic -- processing to create links between the generic template and the -- generic copy. See Sem_Ch12.Get_Associated_Node for full details. -- Note that this field overlaps Entity, which is fine, since, as -- explained in Sem_Ch12, the normal function of Entity is not -- required at the point where the Associated_Node is set. Note -- also, that in generic templates, this means that the Entity field -- does not necessarily point to an Entity. Since the back end is -- expected to ignore generic templates, this is harmless. -- At_End_Proc (Node1) -- This field is present in an N_Handled_Sequence_Of_Statements node. -- It contains an identifier reference for the cleanup procedure to -- be called. See description of this node for further details. -- Backwards_OK (Flag6-Sem) -- A flag present in the N_Assignment_Statement node. It is used only -- if the type being assigned is an array type, and is set if analysis -- determines that it is definitely safe to do the copy backwards, i.e. -- starting at the highest addressed element. Note that if neither of -- the flags Forwards_OK or Backwards_OK is set, it means that the -- front end could not determine that either direction is definitely -- safe, and a runtime check is required. -- Body_To_Inline (Node3-Sem) -- present in subprogram declarations. Denotes analyzed but unexpanded -- body of subprogram, to be used when inlining calls. Present when the -- subprogram has an Inline pragma and inlining is enabled. If the -- declaration is completed by a renaming_as_body, and the renamed en- -- tity is a subprogram, the Body_To_Inline is the name of that entity, -- which is used directly in later calls to the original subprogram. -- Body_Required (Flag13-Sem) -- A flag that appears in the N_Compilation_Unit node indicating that -- the corresponding unit requires a body. For the package case, this -- indicates that a completion is required. In Ada 95, if the flag -- is not set for the package case, then a body may not be present. -- In Ada 83, if the flag is not set for the package case, then a -- body is optional. For a subprogram declaration, the flag is set -- except in the case where a pragma Import or Interface applies, -- in which case no body is permitted (in Ada 83 or Ada 95). -- By_Ref (Flag5-Sem) -- A flag present in the N_Return_Statement_Node. It is set when the -- returned expression is already allocated on the secondary stack -- and thus the result is passed by reference rather than copied -- another time. -- Check_Address_Alignment (Flag11-Sem) -- A flag present in N_Attribute_Definition clause for a 'Address -- attribute definition. This flag is set if a dynamic check should -- be generated at the freeze point for the entity to which this -- address clause applies. The reason that we need this flag is that -- we want to check for range checks being suppressed at the point -- where the attribute definition clause is given, rather than -- testing this at the freeze point. -- Compile_Time_Known_Aggregate (Flag18-Sem) -- Present in N_Aggregate nodes. Set for aggregates which can be -- fully evaluated at compile time without raising constraint error. -- Such aggregates can be passed as is to Gigi without any expansion. -- See Sem_Aggr for the specific conditions under which an aggregate -- has this flag set. See also the flag Static_Processing_OK. -- Condition_Actions (List3-Sem) -- This field appears in else-if nodes and in the iteration scheme -- node for while loops. This field is only used during semantic -- processing to temporarily hold actions inserted into the tree. -- In the tree passed to gigi, the condition actions field is always -- set to No_List. For details on how this field is used, see the -- routine Insert_Actions in package Exp_Util, and also the expansion -- routines for the relevant nodes. -- Controlling_Argument (Node1-Sem) -- This field is set in procedure and function call nodes if the call -- is a dispatching call (it is Empty for a non-dispatching call). -- It indicates the source of the controlling tag for the call. For -- Procedure calls, the Controlling_Argument is one of the actuals. -- For a function that has a dispatching result, it is an entity in -- the context of the call that can provide a tag, or else it is the -- tag of the root type of the class. It can also specify a tag -- directly rather than being a tagged object. The latter is needed -- by the implementations of AI-239 and AI-260. -- Conversion_OK (Flag14-Sem) -- A flag set on type conversion nodes to indicate that the conversion -- is to be considered as being valid, even though it is the case that -- the conversion is not valid Ada. This is used for the Enum_Rep, -- Fixed_Value and Integer_Value attributes, for internal conversions -- done for fixed-point operations, and for certain conversions for -- calls to initialization procedures. If Conversion_OK is set, then -- Etype must be set (the analyzer assumes that Etype has been set). -- For the case of fixed-point operands, it also indicates that the -- conversion is to be a direct conversion of the underlying integer -- result, with no regard to the small operand. -- Corresponding_Body (Node5-Sem) -- This field is set in subprogram declarations, package declarations, -- entry declarations of protected types, and in generic units. It -- points to the defining entity for the corresponding body (NOT the -- node for the body itself). -- Corresponding_Formal_Spec (Node3-Sem) -- This field is set in subprogram renaming declarations, where it points -- to the defining entity for a formal subprogram in the case where the -- renaming corresponds to a generic formal subprogram association in an -- instantiation. The field is Empty if the renaming does not correspond -- to such a formal association. -- Corresponding_Generic_Association (Node5-Sem) -- This field is defined for object declarations and object renaming -- declarations. It is set for the declarations within an instance that -- map generic formals to their actuals. If set, the field points to -- a generic_association which is the original parent of the expression -- or name appearing in the declaration. This simplifies ASIS queries. -- Corresponding_Integer_Value (Uint4-Sem) -- This field is set in real literals of fixed-point types (it is not -- used for floating-point types). It contains the integer value used -- to represent the fixed-point value. It is also set on the universal -- real literals used to represent bounds of fixed-point base types -- and their first named subtypes. -- Corresponding_Spec (Node5-Sem) -- This field is set in subprogram, package, task, and protected body -- nodes, where it points to the defining entity in the corresponding -- spec. The attribute is also set in N_With_Clause nodes, where -- it points to the defining entity for the with'ed spec, and in -- a subprogram renaming declaration when it is a Renaming_As_Body. -- The field is Empty if there is no corresponding spec, as in the -- case of a subprogram body that serves as its own spec. -- Corresponding_Stub (Node3-Sem) -- This field is present in an N_Subunit node. It holds the node in -- the parent unit that is the stub declaration for the subunit. it is -- set when analysis of the stub forces loading of the proper body. If -- expansion of the proper body creates new declarative nodes, they are -- inserted at the point of the corresponding_stub. -- Dcheck_Function (Node5-Sem) -- This field is present in an N_Variant node, It references the entity -- for the discriminant checking function for the variant. -- Debug_Statement (Node3) -- This field is present in an N_Pragma node. It is used only for -- a Debug pragma or pragma Assert with a second parameter. The -- parameter is of the form of an expression, as required by the -- pragma syntax, but is actually a procedure call. To simplify -- semantic processing, the parser creates a copy of the argument -- rearranged into a procedure call statement and places it in the -- Debug_Statement field. Note that this field is considered a -- syntactic field, since it is created by the parser. -- Default_Expression (Node5-Sem) -- This field is Empty if there is no default expression. If there -- is a simple default expression (one with no side effects), then -- this field simply contains a copy of the Expression field (both -- point to the tree for the default expression). Default_Expression -- is used for conformance checking. -- Delay_Finalize_Attach (Flag14-Sem) -- This flag is present in an N_Object_Declaration node. If it is set, -- then in the case of a controlled type being declared and initialized, -- the normal code for attaching the result to the appropriate local -- finalization list is suppressed. This is used for functions that -- return controlled types without using the secondary stack, where -- it is the caller who must do the attachment. -- Discr_Check_Funcs_Built (Flag11-Sem) -- This flag is present in N_Full_Type_Declaration nodes. It is set when -- discriminant checking functions are constructed. The purpose is to -- avoid attempting to set these functions more than once. -- Do_Accessibility_Check (Flag13-Sem) -- This flag is set on N_Parameter_Specification nodes to indicate -- that an accessibility check is required for the parameter. It is -- not yet decided who takes care of this check (TBD ???). -- Do_Discriminant_Check (Flag13-Sem) -- This flag is set on N_Selected_Component nodes to indicate that a -- discriminant check is required using the discriminant check routine -- associated with the selector. The actual check is generated by the -- expander when processing selected components. -- Do_Division_Check (Flag13-Sem) -- This flag is set on a division operator (/ mod rem) to indicate -- that a zero divide check is required. The actual check is dealt -- with by the backend (all the front end does is to set the flag). -- Do_Length_Check (Flag4-Sem) -- This flag is set in an N_Assignment_Statement, N_Op_And, N_Op_Or, -- N_Op_Xor, or N_Type_Conversion node to indicate that a length check -- is required. It is not determined who deals with this flag (???). -- Do_Overflow_Check (Flag17-Sem) -- This flag is set on an operator where an overflow check is required -- on the operation. The actual check is dealt with by the backend -- (all the front end does is to set the flag). The other cases where -- this flag is used is on a Type_Conversion node and for attribute -- reference nodes. For a type conversion, it means that the conversion -- is from one base type to another, and the value may not fit in the -- target base type. See also the description of Do_Range_Check for -- this case. The only attribute references which use this flag are -- Pred and Succ, where it means that the result should be checked -- for going outside the base range. -- Do_Range_Check (Flag9-Sem) -- This flag is set on an expression which appears in a context where -- a range check is required. The target type is clear from the -- context. The contexts in which this flag can appear are limited to -- the following. -- Right side of an assignment. In this case the target type is -- taken from the left side of the assignment, which is referenced -- by the Name of the N_Assignment_Statement node. -- Subscript expressions in an indexed component. In this case the -- target type is determined from the type of the array, which is -- referenced by the Prefix of the N_Indexed_Component node. -- Argument expression for a parameter, appearing either directly -- in the Parameter_Associations list of a call or as the Expression -- of an N_Parameter_Association node that appears in this list. In -- either case, the check is against the type of the formal. Note -- that the flag is relevant only in IN and IN OUT parameters, and -- will be ignored for OUT parameters, where no check is required -- in the call, and if a check is required on the return, it is -- generated explicitly with a type conversion. -- Initialization expression for the initial value in an object -- declaration. In this case the Do_Range_Check flag is set on -- the initialization expression, and the check is against the -- range of the type of the object being declared. -- The expression of a type conversion. In this case the range check -- is against the target type of the conversion. See also the use of -- Do_Overflow_Check on a type conversion. The distinction is that -- the overflow check protects against a value that is outside the -- range of the target base type, whereas a range check checks that -- the resulting value (which is a value of the base type of the -- target type), satisfies the range constraint of the target type. -- Note: when a range check is required in contexts other than those -- listed above (e.g. in a return statement), an additional type -- conversion node is introduced to represent the required check. -- Do_Storage_Check (Flag17-Sem) -- This flag is set in an N_Allocator node to indicate that a storage -- check is required for the allocation, or in an N_Subprogram_Body -- node to indicate that a stack check is required in the subprogram -- prolog. The N_Allocator case is handled by the routine that expands -- the call to the runtime routine. The N_Subprogram_Body case is -- handled by the backend, and all the semantics does is set the flag. -- Do_Tag_Check (Flag13-Sem) -- This flag is set on an N_Assignment_Statement, N_Function_Call, -- N_Procedure_Call_Statement, N_Type_Conversion or N_Return_Statememt -- node to indicate that the tag check can be suppressed. It is not -- yet decided how this flag is used (TBD ???). -- Elaborate_Present (Flag4-Sem) -- This flag is set in the N_With_Clause node to indicate that a -- pragma Elaborate pragma appears for the with'ed units. -- Elaborate_All_Present (Flag14-Sem) -- This flag is set in the N_With_Clause node to indicate that a -- pragma Elaborate_All pragma appears for the with'ed units. -- Elaboration_Boolean (Node2-Sem) -- This field is present in function and procedure specification -- nodes. If set, it points to the entity for a Boolean flag that -- must be tested for certain calls to check for access before -- elaboration. See body of Sem_Elab for further details. This -- field is Empty if no elaboration boolean is required. -- Else_Actions (List3-Sem) -- This field is present in conditional expression nodes. During code -- expansion we use the Insert_Actions procedure (in Exp_Util) to insert -- actions at an appropriate place in the tree to get elaborated at the -- right time. For conditional expressions, we have to be sure that the -- actions for the Else branch are only elaborated if the condition is -- False. The Else_Actions field is used as a temporary parking place -- for these actions. The final tree is always rewritten to eliminate -- the need for this field, so in the tree passed to Gigi, this field -- is always set to No_List. -- Enclosing_Variant (Node2-Sem) -- This field is present in the N_Variant node and identifies the -- Node_Id corresponding to the immediately enclosing variant when -- the variant is nested, and N_Empty otherwise. Set during semantic -- processing of the variant part of a record type. -- Entity (Node4-Sem) -- Appears in all direct names (identifier, character literal, -- operator symbol), as well as expanded names, and attributes that -- denote entities, such as 'Class. Points to the entity for the -- corresponding defining occurrence. Set after name resolution. -- In the case of identifiers in a WITH list, the corresponding -- defining occurrence is in a separately compiled file, and this -- pointer must be set using the library Load procedure. Note that -- during name resolution, the value in Entity may be temporarily -- incorrect (e.g. during overload resolution, Entity is initially -- set to the first possible correct interpretation, and then later -- modified if necessary to contain the correct value after resolution). -- Note that this field overlaps Associated_Node, which is used during -- generic processing (see Sem_Ch12 for details). Note also that in -- generic templates, this means that the Entity field does not always -- point to an Entity. Since the back end is expected to ignore -- generic templates, this is harmless. -- Entity_Or_Associated_Node (Node4-Sem) -- A synonym for both Entity and Associated_Node. Used by convention -- in the code when referencing this field in cases where it is not -- known whether the field contains an Entity or an Associated_Node. -- Etype (Node5-Sem) -- Appears in all expression nodes, all direct names, and all -- entities. Points to the entity for the related type. Set after -- type resolution. Normally this is the actual subtype of the -- expression. However, in certain contexts such as the right side -- of an assignment, subscripts, arguments to calls, returned value -- in a function, initial value etc. it is the desired target type. -- In the event that this is different from the actual type, the -- Do_Range_Check flag will be set if a range check is required. -- Note: if the Is_Overloaded flag is set, then Etype points to -- an essentially arbitrary choice from the possible set of types. -- Exception_Junk (Flag11-Sem) -- This flag is set in a various nodes appearing in a statement -- sequence to indicate that the corresponding node is an artifact -- of the generated code for exception handling, and should be -- ignored when analyzing the control flow of the relevant sequence -- of statements (e.g. to check that it does not end with a bad -- return statement). -- Expansion_Delayed (Flag11-Sem) -- Set on aggregates and extension aggregates that need a top-down -- rather than bottom up expansion. Typically aggregate expansion -- happens bottom up. For nested aggregates the expansion is delayed -- until the enclosing aggregate itself is expanded, e.g. in the context -- of a declaration. To delay it we set this flag. This is done to -- avoid creating a temporary for each level of a nested aggregates, -- and also to prevent the premature generation of constraint checks. -- This is also a requirement if we want to generate the proper -- attachment to the internal finalization lists (for record with -- controlled components). Top down expansion of aggregates is also -- used for in-place array aggregate assignment or initialization. -- When the full context is known, the target of the assignment or -- initialization is used to generate the left-hand side of individual -- assignment to each sub-component. -- First_Inlined_Subprogram (Node3-Sem) -- Present in the N_Compilation_Unit node for the main program. Points -- to a chain of entities for subprograms that are to be inlined. The -- Next_Inlined_Subprogram field of these entities is used as a link -- pointer with Empty marking the end of the list. This field is Empty -- if there are no inlined subprograms or inlining is not active. -- First_Named_Actual (Node4-Sem) -- Present in procedure call statement and function call nodes, and -- also in Intrinsic nodes. Set during semantic analysis to point to -- the first named parameter where parameters are ordered by declaration -- order (as opposed to the actual order in the call which may be -- different due to named associations). Note: this field points to the -- explicit actual parameter itself, not the N_Parameter_Association -- node (its parent). -- First_Real_Statement (Node2-Sem) -- Present in N_Handled_Sequence_Of_Statements node. Normally set to -- Empty. Used only when declarations are moved into the statement -- part of a construct as a result of wrapping an AT END handler that -- is required to cover the declarations. In this case, this field is -- used to remember the location in the statements list of the first -- real statement, i.e. the statement that used to be first in the -- statement list before the declarations were prepended. -- First_Subtype_Link (Node5-Sem) -- Present in N_Freeze_Entity node for an anonymous base type that -- is implicitly created by the declaration of a first subtype. It -- points to the entity for the first subtype. -- Float_Truncate (Flag11-Sem) -- A flag present in type conversion nodes. This is used for float -- to integer conversions where truncation is required rather than -- rounding. Note that Gigi does not handle type conversions from real -- to integer with rounding (see Expand_N_Type_Conversion). -- Forwards_OK (Flag5-Sem) -- A flag present in the N_Assignment_Statement node. It is used only -- if the type being assigned is an array type, and is set if analysis -- determines that it is definitely safe to do the copy forwards, i.e. -- starting at the lowest addressed element. Note that if neither of -- the flags Forwards_OK or Backwards_OK is set, it means that the -- front end could not determine that either direction is definitely -- safe, and a runtime check is required. -- From_At_Mod (Flag4-Sem) -- This flag is set on the attribute definition clause node that is -- generated by a transformation of an at mod phrase in a record -- representation clause. This is used to give slightly different -- (Ada 83 compatible) semantics to such a clause, namely it is -- used to specify a minimum acceptable alignment for the base type -- and all subtypes. In Ada 95 terms, the actual alignment of the -- base type and all subtypes must be a multiple of the given value, -- and the representation clause is considered to be type specific -- instead of subtype specific. -- From_Default (Flag6-Sem) -- This flag is set on the subprogram renaming declaration created in -- an instance for a formal subprogram, when the formal is declared -- with a box, and there is no explicit actual. If the flag is present, -- the declaration is treated as an implicit reference to the formal in -- the ali file. -- Generic_Parent (Node5-Sem) -- Generic_parent is defined on declaration nodes that are instances. -- The value of Generic_Parent is the generic entity from which the -- instance is obtained. Generic_Parent is also defined for the renaming -- declarations and object declarations created for the actuals in an -- instantiation. The generic parent of such a declaration is the -- corresponding generic association in the Instantiation node. -- Generic_Parent_Type (Node4-Sem) -- Generic_Parent_Type is defined on Subtype_Declaration nodes for -- the actuals of formal private and derived types. Within the instance, -- the operations on the actual are those inherited from the parent. -- For a formal private type, the parent type is the generic type -- itself. The Generic_Parent_Type is also used in an instance to -- determine whether a private operation overrides an inherited one. -- Handler_List_Entry (Node2-Sem) -- This field is present in N_Object_Declaration nodes. It is set only -- for the Handler_Record entry generated for an exception in zero cost -- exception handling mode. It references the corresponding item in the -- handler list, and is used to delete this entry if the corresponding -- handler is deleted during optimization. For further details on why -- this is required, see Exp_Ch11.Remove_Handler_Entries. -- Has_Dynamic_Length_Check (Flag10-Sem) -- This flag is present on all nodes. It is set to indicate that one -- of the routines in unit Checks has generated a length check action -- which has been inserted at the flagged node. This is used to avoid -- the generation of duplicate checks. -- Has_Dynamic_Range_Check (Flag12-Sem) -- This flag is present on all nodes. It is set to indicate that one -- of the routines in unit Checks has generated a range check action -- which has been inserted at the flagged node. This is used to avoid -- the generation of duplicate checks. -- Has_No_Elaboration_Code (Flag17-Sem) -- A flag that appears in the N_Compilation_Unit node to indicate -- whether or not elaboration code is present for this unit. It is -- initially set true for subprogram specs and bodies and for all -- generic units and false for non-generic package specs and bodies. -- Gigi may set the flag in the non-generic package case if it -- determines that no elaboration code is generated. Note that this -- flag is not related to the Is_Preelaborated status, there can be -- preelaborated packages that generate elaboration code, and non- -- preelaborated packages which do not generate elaboration code. -- Has_Priority_Pragma (Flag6-Sem) -- A flag present in N_Subprogram_Body, N_Task_Definition and -- N_Protected_Definition nodes to flag the presence of either -- a Priority or Interrupt_Priority pragma in the declaration -- sequence (public or private in the task and protected cases) -- Has_Private_View (Flag11-Sem) -- A flag present in generic nodes that have an entity, to indicate -- that the node has a private type. Used to exchange private -- and full declarations if the visibility at instantiation is -- different from the visibility at generic definition. -- Has_Storage_Size_Pragma (Flag5-Sem) -- A flag present in an N_Task_Definition node to flag the presence -- of a Storage_Size pragma -- Has_Task_Info_Pragma (Flag7-Sem) -- A flag present in an N_Task_Definition node to flag the presence -- of a Task_Info pragma. Used to detect duplicate pragmas. -- Has_Task_Name_Pragma (Flag8-Sem) -- A flag present in N_Task_Definition nodes to flag the presence -- of a Task_Name pragma in the declaration sequence for the task. -- Has_Wide_Character (Flag11-Sem) -- Present in string literals, set if any wide character (i.e. a -- character code outside the Character range) appears in the string. -- Hidden_By_Use_Clause (Elist4-Sem) -- An entity list present in use clauses that appear within -- instantiations. For the resolution of local entities, entities -- introduced by these use clauses have priority over global ones, -- and outer entities must be explicitly hidden/restored on exit. -- Implicit_With (Flag16-Sem) -- This flag is set in the N_With_Clause node that is implicitly -- generated for runtime units that are loaded by the expander, and -- also for package System, if it is loaded implicitly by a use of -- the 'Address or 'Tag attribute -- Includes_Infinities (Flag11-Sem) -- This flag is present in N_Range nodes. It is set for the range -- of unconstrained float types defined in Standard, which include -- not only the given range of values, but also legtitimately can -- include infinite values. This flag is false for any float type -- for which an explicit range is given by the programmer, even if -- that range is identical to the range for float. -- Instance_Spec (Node5-Sem) -- This field is present in generic instantiation nodes, and also in -- formal package declaration nodes (formal package declarations are -- treated in a manner very similar to package instantiations). It -- points to the node for the spec of the instance, inserted as part -- of the semantic processing for instantiations in Sem_Ch12. -- Is_Asynchronous_Call_Block (Flag7-Sem) -- A flag set in a Block_Statement node to indicate that it is the -- expansion of an asynchronous entry call. Such a block needs a -- cleanup handler to assure that the call is cancelled. -- Is_Component_Left_Opnd (Flag13-Sem) -- Is_Component_Right_Opnd (Flag14-Sem) -- Present in concatenation nodes, to indicate that the corresponding -- operand is of the component type of the result. Used in resolving -- concatenation nodes in instances. -- Is_Controlling_Actual (Flag16-Sem) -- This flag is set on in an expression that is a controlling argument -- in a dispatching call. It is off in all other cases. See Sem_Disp -- for details of its use. -- Is_In_Discriminant_Check (Flag11-Sem) -- This flag is present in a selected component, and is used to -- indicate that the reference occurs within a discriminant check. -- The significance is that optimizations based on assuming that -- the discriminant check has a correct value cannot be performed -- in this case (or the disriminant check may be optimized away!) -- Is_Machine_Number (Flag11-Sem) -- This flag is set in an N_Real_Literal node to indicate that the -- value is a machine number. This avoids some unnecessary cases -- of converting real literals to machine numbers. -- Is_Null_Loop (Flag16-Sem) -- This flag is set in an N_Loop_Statement node if the corresponding -- loop can be determined to be null at compile time. This is used to -- suppress any warnings that would otherwise be issued inside the -- loop since they are probably not useful. -- Is_Power_Of_2_For_Shift (Flag13-Sem) -- A flag present only in N_Op_Expon nodes. It is set when the -- exponentiation is of the forma 2 ** N, where the type of N is -- an unsigned integral subtype whose size does not exceed the size -- of Standard_Integer (i.e. a type that can be safely converted to -- Natural), and the exponentiation appears as the right operand of -- an integer multiplication or an integer division where the dividend -- is unsigned. It is also required that overflow checking is off for -- both the exponentiation and the multiply/divide node. If this set -- of conditions holds, and the flag is set, then the division or -- multiplication can be (and is) converted to a shift. -- Is_Overloaded (Flag5-Sem) -- A flag present in all expression nodes. Used temporarily during -- overloading determination. The setting of this flag is not -- relevant once overloading analysis is complete. -- Is_Protected_Subprogram_Body (Flag7-Sem) -- A flag set in a Subprogram_Body block to indicate that it is the -- implemenation of a protected subprogram. Such a body needs a -- cleanup handler to make sure that the associated protected object -- is unlocked when the subprogram completes. -- Is_Static_Expression (Flag6-Sem) -- Indicates that an expression is a static expression (RM 4.9). See -- spec of package Sem_Eval for full details on the use of this flag. -- Is_Subprogram_Descriptor (Flag16-Sem) -- Present in N_Object_Declaration, and set only for the object -- declaration generated for a subprogram descriptor in fast exception -- mode. See Exp_Ch11 for details of use. -- Is_Task_Allocation_Block (Flag6-Sem) -- A flag set in a Block_Statement node to indicate that it is the -- expansion of a task allocator, or the allocator of an object -- containing tasks. Such a block requires a cleanup handler to call -- Expunge_Unactivted_Tasks to complete any tasks that have been -- allocated but not activated when the allocator completes abnormally. -- Is_Task_Master (Flag5-Sem) -- A flag set in a Subprogram_Body, Block_Statement or Task_Body node -- to indicate that the construct is a task master (i.e. has declared -- tasks or declares an access to a task type). -- Itype (Node1-Sem) -- Used in N_Itype_Reference node to reference an itype for which it -- is important to ensure that it is defined. See description of this -- node for further details. -- Kill_Range_Check (Flag11-Sem) -- Used in an N_Unchecked_Type_Conversion node to indicate that the -- result should not be subjected to range checks. This is used for -- the implementation of Normalize_Scalars. -- Label_Construct (Node2-Sem) -- Used in an N_Implicit_Label_Declaration node. Refers to an N_Label, -- N_Block_Statement or N_Loop_Statement node to which the label -- declaration applies. This is not currently used in the compiler -- itself, but it is useful in the implementation of ASIS queries. -- Library_Unit (Node4-Sem) -- In a stub node, the Library_Unit field points to the compilation unit -- node of the corresponding subunit. -- -- In a with clause node, the Library_Unit field points to the spec -- of the with'ed unit. -- -- In a compilation unit node, the use of this field depends on -- the unit type: -- -- For a subprogram body, the Library_Unit field points to the -- compilation unit node of the corresponding spec, unless -- Acts_As_Spec is set, in which case it points to itself. -- -- For a package body, the Library_Unit field points to the -- compilation unit node of the corresponding spec. -- -- For a subprogram spec to which pragma Inline applies, the -- Library_Unit field points to the compilation unit node of -- the corresponding body, if inlining is active. -- -- For a generic declaration, the Library_Unit field points -- to the compilation unit node of the corresponding generic body. -- -- For a subunit, the Library_Unit field points to the compilation -- unit node of the parent body. -- -- Note that this field is not used to hold the parent pointer for a -- child unit (which might in any case need to use it for some other -- purpose as described above). Instead for a child unit, implicit -- with's are generated for all parents. -- Loop_Actions (List2-Sem) -- A list present in Component_Association nodes in array aggregates. -- Used to collect actions that must be executed within the loop because -- they may need to be evaluated anew each time through. -- Limited_View_Installed (Flag18-Sem) -- Present in With_Clauses and in package specifications. If set on a -- with_clause, it indicates that this clause has created the current -- limited view of the designated package. On a package specification, -- it indicates that the limited view has already been created because -- the package is mentioned in a limited_with_clause in the closure of -- the unit being compiled. -- Must_Be_Byte_Aligned (Flag14-Sem) -- This flag is present in N_Attribute_Reference nodes. It can be set -- only for the Address and Unrestricted_Access attributes. If set it -- means that the object for which the address/access is given must be -- on a byte (more accurately a storage unit) boundary. If necessary, -- a copy of the object is to be made before taking the address (this -- copy is in the current scope on the stack frame). This is used for -- certain cases of code generated by the expander that passes -- parameters by address. -- -- The reason the copy is not made by the front end is that the back -- end has more information about type layout and may be able to (but -- is not guaranteed to) prevent making unnecessary copies. -- Must_Not_Freeze (Flag8-Sem) -- A flag present in all expression nodes. Normally expressions cause -- freezing as described in the RM. If this flag is set, then this -- is inhibited. This is used by the analyzer and expander to label -- nodes that are created by semantic analysis or expansion and which -- must not cause freezing even though they normally would. This flag -- is also present in an N_Subtype_Indication node, since we also use -- these in calls to Freeze_Expression. -- Next_Entity (Node2-Sem) -- Present in defining identifiers, defining character literals and -- defining operator symbols (i.e. in all entities). The entities of -- a scope are chained, and this field is used as the forward pointer -- for this list. See Einfo for further details. -- Next_Named_Actual (Node4-Sem) -- Present in parameter association node. Set during semantic -- analysis to point to the next named parameter, where parameters -- are ordered by declaration order (as opposed to the actual order -- in the call, which may be different due to named associations). -- Not that this field points to the explicit actual parameter itself, -- not to the N_Parameter_Association node (its parent). -- Next_Rep_Item (Node4-Sem) -- Present in pragma nodes and attribute definition nodes. Used to -- link representation items that apply to an entity. See description -- of First_Rep_Item field in Einfo for full details. -- Next_Use_Clause (Node3-Sem) -- While use clauses are active during semantic processing, they -- are chained from the scope stack entry, using Next_Use_Clause -- as a link pointer, with Empty marking the end of the list. The -- head pointer is in the scope stack entry (First_Use_Clause). At -- the end of semantic processing (i.e. when Gigi sees the tree, -- the contents of this field is undefined and should not be read). -- No_Ctrl_Actions (Flag7-Sem) -- Present in N_Assignment_Statement to indicate that no finalize nor -- nor adjust should take place on this assignment eventhough the rhs -- is controlled. This is used in init procs and aggregate expansions -- where the generated assignments are more initialisations than real -- assignments. -- No_Elaboration_Check (Flag14-Sem) -- Present in N_Function_Call and N_Procedure_Call_Statement. Indicates -- that no elaboration check is needed on the call, because it appears -- in the context of a local Suppress pragma. This is used on calls -- within task bodies, where the actual elaboration checks are applied -- after analysis, when the local scope stack is not present. -- No_Entities_Ref_In_Spec (Flag8-Sem) -- Present in N_With_Clause nodes. Set if the with clause is on the -- package or subprogram spec where the main unit is the corresponding -- body, and no entities of the with'ed unit are referenced by the spec -- (an entity may still be referenced in the body, so this flag is used -- to generate the proper message (see Sem_Util.Check_Unused_Withs for -- full details) -- No_Initialization (Flag13-Sem) -- Present in N_Object_Declaration & N_Allocator to indicate -- that the object must not be initialized (by Initialize or a -- call to an init proc). This is needed for controlled aggregates. -- When the Object declaration has an expression, this flag means -- that this expression should not be taken into account (needed -- for in place initialization with aggregates) -- No_Truncation (Flag17-Sem) -- Present in N_Unchecked_Type_Conversion node. This flag has an effect -- only if the RM_Size of the source is greater than the RM_Size of the -- target for scalar operands. Normally in such a case we truncate some -- higher order bits of the source, and then sign/zero extend the result -- to form the output value. But if this flag is set, then we do not do -- any truncation, so for example, if an 8 bit input is converted to a -- 5 bit result which is in fact stored in 8 bits, then the high order -- three bits of the target result will be copied from the source. This -- is used for properly setting out of range values for use by pragmas -- Initialize_Scalars and Normalize_Scalars. -- OK_For_Stream (Flag4-Sem) -- Present in N_Attribute_Definition clauses for stream attributes. If -- set, indicates that the attribute is permitted even though the type -- involved is a limited type. In the case of a protected type, the -- result is to stream all components (including discriminants) in -- lexical order. For other limited types, the effect is simply to -- use the corresponding stream routine for the full type. This flag -- is used for internally generated code, where the streaming of these -- types is required, even though not normally allowed by the language. -- Original_Discriminant (Node2-Sem) -- Present in identifiers. Used in references to discriminants that -- appear in generic units. Because the names of the discriminants -- may be different in an instance, we use this field to recover the -- position of the discriminant in the original type, and replace it -- with the discriminant at the same position in the instantiated type. -- Original_Entity (Node2-Sem) -- Present in numeric literals. Used to denote the named number that -- has been constant-folded into the given literal. If literal is from -- source, or the result of some other constant-folding operation, then -- Original_Entity is empty. This field is needed to handle properly -- named numbers in generic units, where the Associated_Node field -- interferes with the Entity field, making it impossible to preserve -- the original entity at the point of instantiation (ASIS problem). -- Others_Discrete_Choices (List1-Sem) -- When a case statement or variant is analyzed, the semantic checks -- determine the actual list of choices that correspond to an others -- choice. This list is materialized for later use by the expander -- and the Others_Discrete_Choices field of an N_Others_Choice node -- points to this materialized list of choices, which is in standard -- format for a list of discrete choices, except that of course it -- cannot contain an N_Others_Choice entry. -- Parameter_List_Truncated (Flag17-Sem) -- Present in N_Function_Call and N_Procedure_Call_Statement nodes. -- Set (for OpenVMS ports of GNAT only) if the parameter list is -- truncated as a result of a First_Optional_Parameter specification -- in an Import_Function, Import_Procedure, or Import_Valued_Procedure -- pragma. The truncation is done by the expander by removing trailing -- parameters from the argument list, in accordance with the set of -- rules allowing such parameter removal. In particular, parameters -- can be removed working from the end of the parameter list backwards -- up to and including the entry designated by First_Optional_Parameter -- in the Import pragma. Parameters can be removed if they are implicit -- and the default value is a known-at-compile-time value, including -- the use of the Null_Parameter attribute, or if explicit parameter -- values are present that match the corresponding defaults. -- Parent_Spec (Node4-Sem) -- For a library unit that is a child unit spec (package or subprogram -- declaration, generic declaration or instantiation, or library level -- rename, this field points to the compilation unit node for the parent -- package specification. This field is Empty for library bodies (the -- parent spec in this case can be found from the corresponding spec). -- Present_Expr (Uint3-Sem) -- Present in an N_Variant node. This has a meaningful value only after -- Gigi has back annotated the tree with representation information. -- At this point, it contains a reference to a gcc expression that -- depends on the values of one or more discriminants. Give a set of -- discriminant values, this expression evaluates to False (zero) if -- variant is not present, and True (non-zero) if it is present. See -- unit Repinfo for further details on gigi back annotation. This -- field is used during ASIS processing (data decomposition annex) -- to determine if a field is present or not. -- Print_In_Hex (Flag13-Sem) -- Set on an N_Integer_Literal node to indicate that the value should -- be printed in hexadecimal in the sprint listing. Has no effect on -- legality or semantics of program, only on the displayed output. -- This is used to clarify output from the packed array cases. -- Procedure_To_Call (Node4-Sem) -- Present in N_Allocator, N_Free_Statement, and N_Return_Statement -- nodes. References the entity for the declaration of the procedure -- to be called to accomplish the required operation (i.e. for the -- Allocate procedure in the case of N_Allocator and N_Return_Statement -- (for allocating the return value), and for the Deallocate procedure -- in the case of N_Free_Statement. -- Raises_Constraint_Error (Flag7-Sem) -- Set on an expression whose evaluation will definitely fail a -- constraint error check. In the case of static expressions, this -- flag must be set accurately (and if it is set, the expression is -- typically illegal unless it appears as a non-elaborated branch of -- a short-circuit form). For a non-static expression, this flag may -- be set whenever an expression (e.g. an aggregate) is known to raise -- constraint error. If set, the expression definitely will raise CE -- if elaborated at runtime. If not set, the expression may or may -- not raise CE. In other words, on static expressions, the flag is -- set accurately, on non-static expressions it is set conservatively. -- Redundant_Use (Flag13-Sem) -- A flag present in nodes that can appear as an operand in a use -- clause or use type clause (identifiers, expanded names, attribute -- references). Set to indicate that a use is redundant (and therefore -- need not be undone on scope exit). -- Return_Type (Node2-Sem) -- Present in N_Return_Statement node. For a procedure, this is set -- to Standard_Void_Type. For a function it references the entity -- for the returned type. -- Rounded_Result (Flag18-Sem) -- Present in N_Type_Conversion, N_Op_Divide and N_Op_Multiply nodes. -- Used in the fixed-point cases to indicate that the result must be -- rounded as a result of the use of the 'Round attribute. Also used -- for integer N_Op_Divide nodes to indicate that the result should -- be rounded to the nearest integer (breaking ties away from zero), -- rather than truncated towards zero as usual. These rounded integer -- operations are the result of expansion of rounded fixed-point -- divide, conersion and multiplication operations. -- Scope (Node3-Sem) -- Present in defining identifiers, defining character literals and -- defining operator symbols (i.e. in all entities). The entities of -- a scope all use this field to reference the corresponding scope -- entity. See Einfo for further details. -- Shift_Count_OK (Flag4-Sem) -- A flag present in shift nodes to indicate that the shift count is -- known to be in range, i.e. is in the range from zero to word length -- minus one. If this flag is not set, then the shift count may be -- outside this range, i.e. larger than the word length, and the code -- must ensure that such shift counts give the appropriate result. -- Source_Type (Node1-Sem) -- Used in an N_Validate_Unchecked_Conversion node to point to the -- source type entity for the unchecked conversion instantiation -- which gigi must do size validation for. -- Static_Processing_OK (Flag4-Sem) -- Present in N_Aggregate nodes. When the Compile_Time_Known_Aggregate -- flag is set, the full value of the aggregate can be determined at -- compile time and the aggregate can be passed as is to the back-end. -- In this event it is irrelevant whether this flag is set or not. -- However, if the Compile_Time_Known_Aggregate flag is not set but -- Static_Processing_OK is set, the aggregate can (but need not) be -- converted into a compile time known aggregate by the expander. -- See Sem_Aggr for the specific conditions under which an aggregate -- has its Static_Processing_OK flag set. -- Storage_Pool (Node1-Sem) -- Present in N_Allocator, N_Free_Statement and N_Return_Statement -- nodes. References the entity for the storage pool to be used for -- the allocate or free call or for the allocation of the returned -- value from a function. Empty indicates that the global default -- default pool is to be used. Note that in the case of a return -- statement, this field is set only if the function returns a -- value of a type whose size is not known at compile time on the -- secondary stack. It is never set on targets for which the target -- parameter Targparm.Functions_Return_By_DSP_On_Target is True. -- Target_Type (Node2-Sem) -- Used in an N_Validate_Unchecked_Conversion node to point to the -- target type entity for the unchecked conversion instantiation -- which gigi must do size validation for. -- Task_Body_Procedure (Node2-Sem) -- Present in task type declaration nodes. Points to the entity for -- the task body procedure (as further described in Exp_Ch9, task -- bodies are expanded into procedures). A convenient function to -- retrieve this field is Sem_Util.Get_Task_Body_Procedure. -- Then_Actions (List3-Sem) -- This field is present in conditional expression nodes. During code -- expansion we use the Insert_Actions procedure (in Exp_Util) to insert -- actions at an appropriate place in the tree to get elaborated at the -- right time. For conditional expressions, we have to be sure that the -- actions for the Then branch are only elaborated if the condition is -- True. The Then_Actions field is used as a temporary parking place -- for these actions. The final tree is always rewritten to eliminate -- the need for this field, so in the tree passed to Gigi, this field -- is always set to No_List. -- Treat_Fixed_As_Integer (Flag14-Sem) -- This flag appears in operator nodes for divide, multiply, mod and -- rem on fixed-point operands. It indicates that the operands are -- to be treated as integer values, ignoring small values. This flag -- is only set as a result of expansion of fixed-point operations. -- Typically a fixed-point multplication in the source generates -- subsidiary multiplication and division operations that work with -- the underlying integer values and have this flag set. Note that -- this flag is not needed on other arithmetic operations (add, neg, -- subtract etc) since in these cases it is always the case that fixed -- is treated as integer. The Etype field MUST be set if this flag -- is set. The analyzer knows to leave such nodes alone, and whoever -- makes them must set the correct Etype value. -- TSS_Elist (Elist3-Sem) -- Present in N_Freeze_Entity nodes. Holds an element list containing -- entries for each TSS (type support subprogram) associated with the -- frozen type. The elements of the list are the entities for the -- subprograms (see package Exp_TSS for further details). Set to -- No_Elist if there are no type support subprograms for the type -- or if the freeze node is not for a type. -- Unreferenced_In_Spec (Flag7-Sem) -- Present in N_With_Clause nodes. Set if the with clause is on the -- package or subprogram spec where the main unit is the corresponding -- body, and is not referenced by the spec (it may still be referenced -- by the body, so this flag is used to generate the proper message -- (see Sem_Util.Check_Unused_Withs for details) -- Was_Originally_Stub (Flag13-Sem) -- This flag is set in the node for a proper body that replaces a -- stub. During the analysis procedure, stubs in some situations -- get rewritten by the corresponding bodies, and we set this flag -- to remember that this happened. Note that it is not good enough -- to rely on the use of Original_Node here because of the case of -- nested instantiations where the substituted node can be copied. -- Zero_Cost_Handling (Flag5-Sem) -- This flag is set in all handled sequence of statement and exception -- handler nodes if eceptions are to be handled using the zero-cost -- mechanism (see Ada.Exceptions and System.Exceptions in files -- a-except.ads/adb and s-except.ads for full details). What gigi -- needs to do for such a handler is simply to put the code in the -- handler somewhere. The front end has generated all necessary labels. -------------------------------------------------- -- Note on Use of End_Label and End_Span Fields -- -------------------------------------------------- -- Several constructs have end lines: -- Loop Statement end loop [loop_IDENTIFIER]; -- Package Specification end [[PARENT_UNIT_NAME .] IDENTIFIER] -- Task Definition end [task_IDENTIFIER] -- Protected Definition end [protected_IDENTIFIER] -- Protected Body end [protected_IDENTIFIER] -- Block Statement end [block_IDENTIFIER]; -- Subprogram Body end [DESIGNATOR]; -- Package Body end [[PARENT_UNIT_NAME .] IDENTIFIER]; -- Task Body end [task_IDENTIFIER]; -- Accept Statement end [entry_IDENTIFIER]]; -- Entry Body end [entry_IDENTIFIER]; -- If Statement end if; -- Case Statement end case; -- Record Definition end record; -- Enumeration Definition ); -- The End_Label and End_Span fields are used to mark the locations -- of these lines, and also keep track of the label in the case where -- a label is present. -- For the first group above, the End_Label field of the corresponding -- node is used to point to the label identifier. In the case where -- there is no label in the source, the parser supplies a dummy -- identifier (with Comes_From_Source set to False), and the Sloc -- of this dummy identifier marks the location of the token following -- the END token. -- For the second group, the use of End_Label is similar, but the -- End_Label is found in the N_Handled_Sequence_Of_Statements node. -- This is done simply because in some cases there is no room in -- the parent node. -- For the third group, there is never any label, and instead of -- using End_Label, we use the End_Span field which gives the -- location of the token following END, relative to the starting -- Sloc of the construct, i.e. add Sloc (Node) + End_Span (Node) -- to get the Sloc of the IF or CASE following the End_Label. -- The record definition case is handled specially, we treat it -- as though it required an optional label which is never present, -- and so the parser always builds a dummy identifier with Comes -- From Source set False. The reason we do this, rather than using -- End_Span in this case, is that we want to generate a cross-ref -- entry for the end of a record, since it represents a scope for -- name declaration purposes. -- The enumeration definition case is handled in an exactly similar -- manner, building a dummy identifier to get a cross-reference. -- Note: the reason we store the difference as a Uint, instead of -- storing the Source_Ptr value directly, is that Source_Ptr values -- cannot be distinguished from other types of values, and we count -- on all general use fields being self describing. To make things -- easier for clients, note that we provide function End_Location, -- and procedure Set_End_Location to allow access to the logical -- value (which is the Source_Ptr value for the end token). --------------------- -- Syntactic Nodes -- --------------------- --------------------- -- 2.3 Identifier -- --------------------- -- IDENTIFIER ::= IDENTIFIER_LETTER {[UNDERLINE] LETTER_OR_DIGIT} -- LETTER_OR_DIGIT ::= IDENTIFIER_LETTER | DIGIT -- An IDENTIFIER shall not be a reserved word -- In the Ada grammar identifiers are the bottom level tokens which -- have very few semantics. Actual program identifiers are direct -- names. If we were being 100% honest with the grammar, then we would -- have a node called N_Direct_Name which would point to an identifier. -- However, that's too many extra nodes, so we just use the N_Identifier -- node directly as a direct name, and it contains the expression fields -- and Entity field that correspond to its use as a direct name. In -- those few cases where identifiers appear in contexts where they are -- not direct names (pragmas, pragma argument associations, attribute -- references and attribute definition clauses), the Chars field of the -- node contains the Name_Id for the identifier name. -- Note: in GNAT, a reserved word can be treated as an identifier -- in two cases. First, an incorrect use of a reserved word as an -- identifier is diagnosed and then treated as a normal identifier. -- Second, an attribute designator of the form of a reserved word -- (access, delta, digits, range) is treated as an identifier. -- Note: The set of letters that is permitted in an identifier depends -- on the character set in use. See package Csets for full details. -- N_Identifier -- Sloc points to identifier -- Chars (Name1) contains the Name_Id for the identifier -- Entity (Node4-Sem) -- Associated_Node (Node4-Sem) -- Original_Discriminant (Node2-Sem) -- Redundant_Use (Flag13-Sem) -- Has_Private_View (Flag11-Sem) (set in generic units) -- plus fields for expression -------------------------- -- 2.4 Numeric Literal -- -------------------------- -- NUMERIC_LITERAL ::= DECIMAL_LITERAL | BASED_LITERAL ---------------------------- -- 2.4.1 Decimal Literal -- ---------------------------- -- DECIMAL_LITERAL ::= NUMERAL [.NUMERAL] [EXPONENT] -- NUMERAL ::= DIGIT {[UNDERLINE] DIGIT} -- EXPONENT ::= E [+] NUMERAL | E - NUMERAL -- Decimal literals appear in the tree as either integer literal nodes -- or real literal nodes, depending on whether a period is present. -- Note: literal nodes appear as a result of direct use of literals -- in the source program, and also as the result of evaluating -- expressions at compile time. In the latter case, it is possible -- to construct real literals that have no syntactic representation -- using the standard literal format. Such literals are listed by -- Sprint using the notation [numerator / denominator]. -- Note: the value of an integer literal node created by the front end -- is never outside the range of values of the base type. However, it -- can be the case that the value is outside the range of the -- particular subtype. This happens in the case of integer overflows -- with checks suppressed. -- N_Integer_Literal -- Sloc points to literal -- Original_Entity (Node2-Sem) If not Empty, holds Named_Number that -- has been constant-folded into its literal value. -- Intval (Uint3) contains integer value of literal -- plus fields for expression -- Print_In_Hex (Flag13-Sem) -- N_Real_Literal -- Sloc points to literal -- Original_Entity (Node2-Sem) If not Empty, holds Named_Number that -- has been constant-folded into its literal value. -- Realval (Ureal3) contains real value of literal -- Corresponding_Integer_Value (Uint4-Sem) -- Is_Machine_Number (Flag11-Sem) -- plus fields for expression -------------------------- -- 2.4.2 Based Literal -- -------------------------- -- BASED_LITERAL ::= -- BASE # BASED_NUMERAL [.BASED_NUMERAL] # [EXPONENT] -- BASE ::= NUMERAL -- BASED_NUMERAL ::= -- EXTENDED_DIGIT {[UNDERLINE] EXTENDED_DIGIT} -- EXTENDED_DIGIT ::= DIGIT | A | B | C | D | E | F -- Based literals appear in the tree as either integer literal nodes -- or real literal nodes, depending on whether a period is present. ---------------------------- -- 2.5 Character Literal -- ---------------------------- -- CHARACTER_LITERAL ::= ' GRAPHIC_CHARACTER ' -- N_Character_Literal -- Sloc points to literal -- Chars (Name1) contains the Name_Id for the identifier -- Char_Literal_Value (Uint2) contains the literal value -- Entity (Node4-Sem) -- Associated_Node (Node4-Sem) -- Has_Private_View (Flag11-Sem) set in generic units. -- plus fields for expression -- Note: the Entity field will be missing (and set to Empty) for -- character literals whose type is Standard.Wide_Character or -- Standard.Character or a type derived from one of these two. -- In this case the character literal stands for its own coding. -- The reason we take this irregular short cut is to avoid the -- need to build lots of junk defining character literal nodes. ------------------------- -- 2.6 String Literal -- ------------------------- -- STRING LITERAL ::= "{STRING_ELEMENT}" -- A STRING_ELEMENT is either a pair of quotation marks ("), or a -- single GRAPHIC_CHARACTER other than a quotation mark. -- N_String_Literal -- Sloc points to literal -- Strval (Str3) contains Id of string value -- Has_Wide_Character (Flag11-Sem) -- plus fields for expression ------------------ -- 2.7 Comment -- ------------------ -- A COMMENT starts with two adjacent hyphens and extends up to the -- end of the line. A COMMENT may appear on any line of a program. -- Comments are skipped by the scanner and do not appear in the tree. -- It is possible to reconstruct the position of comments with respect -- to the elements of the tree by using the source position (Sloc) -- pointers that appear in every tree node. ----------------- -- 2.8 Pragma -- ----------------- -- PRAGMA ::= pragma IDENTIFIER -- [(PRAGMA_ARGUMENT_ASSOCIATION {, PRAGMA_ARGUMENT_ASSOCIATION})]; -- Note that a pragma may appear in the tree anywhere a declaration -- or a statement may appear, as well as in some other situations -- which are explicitly documented. -- N_Pragma -- Sloc points to PRAGMA -- Chars (Name1) identifier name from pragma identifier -- Pragma_Argument_Associations (List2) (set to No_List if none) -- Debug_Statement (Node3) (set to Empty if not Debug, Assert) -- Next_Rep_Item (Node4-Sem) -- Note: we should have a section on what pragmas are passed on to -- the back end to be processed. This section should note that pragma -- Psect_Object is always converted to Common_Object, but there are -- undoubtedly many other similar notes required ??? -------------------------------------- -- 2.8 Pragma Argument Association -- -------------------------------------- -- PRAGMA_ARGUMENT_ASSOCIATION ::= -- [pragma_argument_IDENTIFIER =>] NAME -- | [pragma_argument_IDENTIFIER =>] EXPRESSION -- N_Pragma_Argument_Association -- Sloc points to first token in association -- Chars (Name1) (set to No_Name if no pragma argument identifier) -- Expression (Node3) ------------------------ -- 2.9 Reserved Word -- ------------------------ -- Reserved words are parsed by the scanner, and returned as the -- corresponding token types (e.g. PACKAGE is returned as Tok_Package) ---------------------------- -- 3.1 Basic Declaration -- ---------------------------- -- BASIC_DECLARATION ::= -- TYPE_DECLARATION | SUBTYPE_DECLARATION -- | OBJECT_DECLARATION | NUMBER_DECLARATION -- | SUBPROGRAM_DECLARATION | ABSTRACT_SUBPROGRAM_DECLARATION -- | PACKAGE_DECLARATION | RENAMING_DECLARATION -- | EXCEPTION_DECLARATION | GENERIC_DECLARATION -- | GENERIC_INSTANTIATION -- Basic declaration also includes IMPLICIT_LABEL_DECLARATION -- see further description in section on semantic nodes. -- Also, in the tree that is constructed, a pragma may appear -- anywhere that a declaration may appear. ------------------------------ -- 3.1 Defining Identifier -- ------------------------------ -- DEFINING_IDENTIFIER ::= IDENTIFIER -- A defining identifier is an entity, which has additional fields -- depending on the setting of the Ekind field. These additional -- fields are defined (and access subprograms declared) in package -- Einfo. -- Note: N_Defining_Identifier is an extended node whose fields are -- deliberate layed out to match the layout of fields in an ordinary -- N_Identifier node allowing for easy alteration of an identifier -- node into a defining identifier node. For details, see procedure -- Sinfo.CN.Change_Identifier_To_Defining_Identifier. -- N_Defining_Identifier -- Sloc points to identifier -- Chars (Name1) contains the Name_Id for the identifier -- Next_Entity (Node2-Sem) -- Scope (Node3-Sem) -- Etype (Node5-Sem) ----------------------------- -- 3.2.1 Type Declaration -- ----------------------------- -- TYPE_DECLARATION ::= -- FULL_TYPE_DECLARATION -- | INCOMPLETE_TYPE_DECLARATION -- | PRIVATE_TYPE_DECLARATION -- | PRIVATE_EXTENSION_DECLARATION ---------------------------------- -- 3.2.1 Full Type Declaration -- ---------------------------------- -- FULL_TYPE_DECLARATION ::= -- type DEFINING_IDENTIFIER [KNOWN_DISCRIMINANT_PART] -- is TYPE_DEFINITION; -- | TASK_TYPE_DECLARATION -- | PROTECTED_TYPE_DECLARATION -- The full type declaration node is used only for the first case. The -- second case (concurrent type declaration), is represented directly -- by a task type declaration or a protected type declaration. -- N_Full_Type_Declaration -- Sloc points to TYPE -- Defining_Identifier (Node1) -- Discriminant_Specifications (List4) (set to No_List if none) -- Type_Definition (Node3) -- Discr_Check_Funcs_Built (Flag11-Sem) ---------------------------- -- 3.2.1 Type Definition -- ---------------------------- -- TYPE_DEFINITION ::= -- ENUMERATION_TYPE_DEFINITION | INTEGER_TYPE_DEFINITION -- | REAL_TYPE_DEFINITION | ARRAY_TYPE_DEFINITION -- | RECORD_TYPE_DEFINITION | ACCESS_TYPE_DEFINITION -- | DERIVED_TYPE_DEFINITION -------------------------------- -- 3.2.2 Subtype Declaration -- -------------------------------- -- SUBTYPE_DECLARATION ::= -- subtype DEFINING_IDENTIFIER is [NULL_EXCLUSION] SUBTYPE_INDICATION; -- The subtype indication field is set to Empty for subtypes -- declared in package Standard (Positive, Natural). -- N_Subtype_Declaration -- Sloc points to SUBTYPE -- Defining_Identifier (Node1) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Subtype_Indication (Node5) -- Generic_Parent_Type (Node4-Sem) (set for an actual derived type). -- Exception_Junk (Flag11-Sem) ------------------------------- -- 3.2.2 Subtype Indication -- ------------------------------- -- SUBTYPE_INDICATION ::= SUBTYPE_MARK [CONSTRAINT] -- Note: if no constraint is present, the subtype indication appears -- directly in the tree as a subtype mark. The N_Subtype_Indication -- node is used only if a constraint is present. -- Note: [For Ada 2005 (AI-231)]: Because Ada 2005 extends this rule -- with the null-exclusion part (see AI-231), we had to introduce a new -- attribute in all the parents of subtype_indication nodes to indicate -- if the null-exclusion is present. -- Note: the reason that this node has expression fields is that a -- subtype indication can appear as an operand of a membership test. -- N_Subtype_Indication -- Sloc points to first token of subtype mark -- Subtype_Mark (Node4) -- Constraint (Node3) -- Etype (Node5-Sem) -- Must_Not_Freeze (Flag8-Sem) -- Note: Etype is a copy of the Etype field of the Subtype_Mark. The -- reason for this redundancy is so that in a list of array index types, -- the Etype can be uniformly accessed to determine the subscript type. -- This means that no Itype is constructed for the actual subtype that -- is created by the subtype indication. If such an Itype is required, -- it is constructed in the context in which the indication appears. ------------------------- -- 3.2.2 Subtype Mark -- ------------------------- -- SUBTYPE_MARK ::= subtype_NAME ----------------------- -- 3.2.2 Constraint -- ----------------------- -- CONSTRAINT ::= SCALAR_CONSTRAINT | COMPOSITE_CONSTRAINT ------------------------------ -- 3.2.2 Scalar Constraint -- ------------------------------ -- SCALAR_CONSTRAINT ::= -- RANGE_CONSTRAINT | DIGITS_CONSTRAINT | DELTA_CONSTRAINT --------------------------------- -- 3.2.2 Composite Constraint -- --------------------------------- -- COMPOSITE_CONSTRAINT ::= -- INDEX_CONSTRAINT | DISCRIMINANT_CONSTRAINT ------------------------------- -- 3.3.1 Object Declaration -- ------------------------------- -- OBJECT_DECLARATION ::= -- DEFINING_IDENTIFIER_LIST : [aliased] [constant] -- [NULL_EXCLUSION] SUBTYPE_INDICATION [:= EXPRESSION]; -- | DEFINING_IDENTIFIER_LIST : [aliased] [constant] -- ARRAY_TYPE_DEFINITION [:= EXPRESSION]; -- | SINGLE_TASK_DECLARATION -- | SINGLE_PROTECTED_DECLARATION -- Note: aliased is not permitted in Ada 83 mode -- The N_Object_Declaration node is only for the first two cases. -- Single task declaration is handled by P_Task (9.1) -- Single protected declaration is handled by P_protected (9.5) -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive declarations were given with -- identical type definition and expression components. To simplify -- semantic processing, the parser represents a multiple declaration -- case as a sequence of single declarations, using the More_Ids and -- Prev_Ids flags to preserve the original source form as described -- in the section on "Handling of Defining Identifier Lists". -- Note: if a range check is required for the initialization -- expression then the Do_Range_Check flag is set in the Expression, -- with the check being done against the type given by the object -- definition, which is also the Etype of the defining identifier. -- Note: the contents of the Expression field must be ignored (i.e. -- treated as though it were Empty) if No_Initialization is set True. -- Note: the back end places some restrictions on the form of the -- Expression field. If the object being declared is Atomic, then -- the Expression may not have the form of an aggregate (since this -- might cause the back end to generate separate assignments). It -- also cannot be a reference to an object marked as a true constant -- (Is_True_Constant flag set), where the object is itself initalized -- with an aggregate. If necessary the front end must generate an -- extra temporary (with Is_True_Constant set False), and initialize -- this temporary as required (the temporary itself is not atomic). -- N_Object_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Aliased_Present (Flag4) set if ALIASED appears -- Constant_Present (Flag17) set if CONSTANT appears -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Object_Definition (Node4) subtype indication/array type definition -- Expression (Node3) (set to Empty if not present) -- Handler_List_Entry (Node2-Sem) -- Corresponding_Generic_Association (Node5-Sem) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) -- No_Initialization (Flag13-Sem) -- Assignment_OK (Flag15-Sem) -- Exception_Junk (Flag11-Sem) -- Delay_Finalize_Attach (Flag14-Sem) -- Is_Subprogram_Descriptor (Flag16-Sem) ------------------------------------- -- 3.3.1 Defining Identifier List -- ------------------------------------- -- DEFINING_IDENTIFIER_LIST ::= -- DEFINING_IDENTIFIER {, DEFINING_IDENTIFIER} ------------------------------- -- 3.3.2 Number Declaration -- ------------------------------- -- NUMBER_DECLARATION ::= -- DEFINING_IDENTIFIER_LIST : constant := static_EXPRESSION; -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive declarations were given with -- identical expressions. To simplify semantic processing, the parser -- represents a multiple declaration case as a sequence of single -- declarations, using the More_Ids and Prev_Ids flags to preserve -- the original source form as described in the section on "Handling -- of Defining Identifier Lists". -- N_Number_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Expression (Node3) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) ---------------------------------- -- 3.4 Derived Type Definition -- ---------------------------------- -- DERIVED_TYPE_DEFINITION ::= -- [abstract] new [NULL_EXCLUSION] parent_SUBTYPE_INDICATION -- [RECORD_EXTENSION_PART] -- Note: ABSTRACT, record extension part not permitted in Ada 83 mode -- Note: a record extension part is required if ABSTRACT is present -- N_Derived_Type_Definition -- Sloc points to NEW -- Abstract_Present (Flag4) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Subtype_Indication (Node5) -- Record_Extension_Part (Node3) (set to Empty if not present) --------------------------- -- 3.5 Range Constraint -- --------------------------- -- RANGE_CONSTRAINT ::= range RANGE -- N_Range_Constraint -- Sloc points to RANGE -- Range_Expression (Node4) ---------------- -- 3.5 Range -- ---------------- -- RANGE ::= -- RANGE_ATTRIBUTE_REFERENCE -- | SIMPLE_EXPRESSION .. SIMPLE_EXPRESSION -- Note: the case of a range given as a range attribute reference -- appears directly in the tree as an attribute reference. -- Note: the field name for a reference to a range is Range_Expression -- rather than Range, because range is a reserved keyword in Ada! -- Note: the reason that this node has expression fields is that a -- range can appear as an operand of a membership test. The Etype -- field is the type of the range (we do NOT construct an implicit -- subtype to represent the range exactly). -- N_Range -- Sloc points to .. -- Low_Bound (Node1) -- High_Bound (Node2) -- Includes_Infinities (Flag11) -- plus fields for expression -- Note: if the range appears in a context, such as a subtype -- declaration, where range checks are required on one or both of -- the expression fields, then type conversion nodes are inserted -- to represent the required checks. ---------------------------------------- -- 3.5.1 Enumeration Type Definition -- ---------------------------------------- -- ENUMERATION_TYPE_DEFINITION ::= -- (ENUMERATION_LITERAL_SPECIFICATION -- {, ENUMERATION_LITERAL_SPECIFICATION}) -- Note: the Literals field in the node described below is null for -- the case of the standard types CHARACTER and WIDE_CHARACTER, for -- which special processing handles these types as special cases. -- N_Enumeration_Type_Definition -- Sloc points to left parenthesis -- Literals (List1) (Empty for CHARACTER or WIDE_CHARACTER) -- End_Label (Node4) (set to Empty if internally generated record) ---------------------------------------------- -- 3.5.1 Enumeration Literal Specification -- ---------------------------------------------- -- ENUMERATION_LITERAL_SPECIFICATION ::= -- DEFINING_IDENTIFIER | DEFINING_CHARACTER_LITERAL --------------------------------------- -- 3.5.1 Defining Character Literal -- --------------------------------------- -- DEFINING_CHARACTER_LITERAL ::= CHARACTER_LITERAL -- A defining character literal is an entity, which has additional -- fields depending on the setting of the Ekind field. These -- additional fields are defined (and access subprograms declared) -- in package Einfo. -- Note: N_Defining_Character_Literal is an extended node whose fields -- are deliberate layed out to match the layout of fields in an ordinary -- N_Character_Literal node allowing for easy alteration of a character -- literal node into a defining character literal node. For details, see -- Sinfo.CN.Change_Character_Literal_To_Defining_Character_Literal. -- N_Defining_Character_Literal -- Sloc points to literal -- Chars (Name1) contains the Name_Id for the identifier -- Next_Entity (Node2-Sem) -- Scope (Node3-Sem) -- Etype (Node5-Sem) ------------------------------------ -- 3.5.4 Integer Type Definition -- ------------------------------------ -- Note: there is an error in this rule in the latest version of the -- grammar, so we have retained the old rule pending clarification. -- INTEGER_TYPE_DEFINITION ::= -- SIGNED_INTEGER_TYPE_DEFINITION -- | MODULAR_TYPE_DEFINITION ------------------------------------------- -- 3.5.4 Signed Integer Type Definition -- ------------------------------------------- -- SIGNED_INTEGER_TYPE_DEFINITION ::= -- range static_SIMPLE_EXPRESSION .. static_SIMPLE_EXPRESSION -- Note: the Low_Bound and High_Bound fields are set to Empty -- for integer types defined in package Standard. -- N_Signed_Integer_Type_Definition -- Sloc points to RANGE -- Low_Bound (Node1) -- High_Bound (Node2) ------------------------------------ -- 3.5.4 Modular Type Definition -- ------------------------------------ -- MODULAR_TYPE_DEFINITION ::= mod static_EXPRESSION -- N_Modular_Type_Definition -- Sloc points to MOD -- Expression (Node3) --------------------------------- -- 3.5.6 Real Type Definition -- --------------------------------- -- REAL_TYPE_DEFINITION ::= -- FLOATING_POINT_DEFINITION | FIXED_POINT_DEFINITION -------------------------------------- -- 3.5.7 Floating Point Definition -- -------------------------------------- -- FLOATING_POINT_DEFINITION ::= -- digits static_SIMPLE_EXPRESSION [REAL_RANGE_SPECIFICATION] -- Note: The Digits_Expression and Real_Range_Specifications fields -- are set to Empty for floating-point types declared in Standard. -- N_Floating_Point_Definition -- Sloc points to DIGITS -- Digits_Expression (Node2) -- Real_Range_Specification (Node4) (set to Empty if not present) ------------------------------------- -- 3.5.7 Real Range Specification -- ------------------------------------- -- REAL_RANGE_SPECIFICATION ::= -- range static_SIMPLE_EXPRESSION .. static_SIMPLE_EXPRESSION -- N_Real_Range_Specification -- Sloc points to RANGE -- Low_Bound (Node1) -- High_Bound (Node2) ----------------------------------- -- 3.5.9 Fixed Point Definition -- ----------------------------------- -- FIXED_POINT_DEFINITION ::= -- ORDINARY_FIXED_POINT_DEFINITION | DECIMAL_FIXED_POINT_DEFINITION -------------------------------------------- -- 3.5.9 Ordinary Fixed Point Definition -- -------------------------------------------- -- ORDINARY_FIXED_POINT_DEFINITION ::= -- delta static_EXPRESSION REAL_RANGE_SPECIFICATION -- Note: In Ada 83, the EXPRESSION must be a SIMPLE_EXPRESSION -- N_Ordinary_Fixed_Point_Definition -- Sloc points to DELTA -- Delta_Expression (Node3) -- Real_Range_Specification (Node4) ------------------------------------------- -- 3.5.9 Decimal Fixed Point Definition -- ------------------------------------------- -- DECIMAL_FIXED_POINT_DEFINITION ::= -- delta static_EXPRESSION -- digits static_EXPRESSION [REAL_RANGE_SPECIFICATION] -- Note: decimal types are not permitted in Ada 83 mode -- N_Decimal_Fixed_Point_Definition -- Sloc points to DELTA -- Delta_Expression (Node3) -- Digits_Expression (Node2) -- Real_Range_Specification (Node4) (set to Empty if not present) ------------------------------ -- 3.5.9 Digits Constraint -- ------------------------------ -- DIGITS_CONSTRAINT ::= -- digits static_EXPRESSION [RANGE_CONSTRAINT] -- Note: in Ada 83, the EXPRESSION must be a SIMPLE_EXPRESSION -- Note: in Ada 95, reduced accuracy subtypes are obsolescent -- N_Digits_Constraint -- Sloc points to DIGITS -- Digits_Expression (Node2) -- Range_Constraint (Node4) (set to Empty if not present) -------------------------------- -- 3.6 Array Type Definition -- -------------------------------- -- ARRAY_TYPE_DEFINITION ::= -- UNCONSTRAINED_ARRAY_DEFINITION | CONSTRAINED_ARRAY_DEFINITION ----------------------------------------- -- 3.6 Unconstrained Array Definition -- ----------------------------------------- -- UNCONSTRAINED_ARRAY_DEFINITION ::= -- array (INDEX_SUBTYPE_DEFINITION {, INDEX_SUBTYPE_DEFINITION}) of -- COMPONENT_DEFINITION -- Note: dimensionality of array is indicated by number of entries in -- the Subtype_Marks list, which has one entry for each dimension. -- N_Unconstrained_Array_Definition -- Sloc points to ARRAY -- Subtype_Marks (List2) -- Component_Definition (Node4) ----------------------------------- -- 3.6 Index Subtype Definition -- ----------------------------------- -- INDEX_SUBTYPE_DEFINITION ::= SUBTYPE_MARK range <> -- There is no explicit node in the tree for an index subtype -- definition since the N_Unconstrained_Array_Definition node -- incorporates the type marks which appear in this context. --------------------------------------- -- 3.6 Constrained Array Definition -- --------------------------------------- -- CONSTRAINED_ARRAY_DEFINITION ::= -- array (DISCRETE_SUBTYPE_DEFINITION -- {, DISCRETE_SUBTYPE_DEFINITION}) -- of COMPONENT_DEFINITION -- Note: dimensionality of array is indicated by number of entries -- in the Discrete_Subtype_Definitions list, which has one entry -- for each dimension. -- N_Constrained_Array_Definition -- Sloc points to ARRAY -- Discrete_Subtype_Definitions (List2) -- Component_Definition (Node4) -------------------------------------- -- 3.6 Discrete Subtype Definition -- -------------------------------------- -- DISCRETE_SUBTYPE_DEFINITION ::= -- discrete_SUBTYPE_INDICATION | RANGE ------------------------------- -- 3.6 Component Definition -- ------------------------------- -- COMPONENT_DEFINITION ::= -- [aliased] [NULL_EXCLUSION] SUBTYPE_INDICATION | ACCESS_DEFINITION -- Note: although the syntax does not permit a component definition to -- be an anonymous array (and the parser will diagnose such an attempt -- with an appropriate message), it is possible for anonymous arrays -- to appear as component definitions. The semantics and back end handle -- this case properly, and the expander in fact generates such cases. -- Access_Definition is an optional field that gives support to -- Ada 2005 (AI-230). The parser generates nodes that have either the -- Subtype_Indication field or else the Access_Definition field. -- N_Component_Definition -- Sloc points to ALIASED, ACCESS or to first token of subtype mark -- Aliased_Present (Flag4) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Subtype_Indication (Node5) (set to Empty if not present) -- Access_Definition (Node3) (set to Empty if not present) ----------------------------- -- 3.6.1 Index Constraint -- ----------------------------- -- INDEX_CONSTRAINT ::= (DISCRETE_RANGE {, DISCRETE_RANGE}) -- It is not in general possible to distinguish between discriminant -- constraints and index constraints at parse time, since a simple -- name could be either the subtype mark of a discrete range, or an -- expression in a discriminant association with no name. Either -- entry appears simply as the name, and the semantic parse must -- distinguish between the two cases. Thus we use a common tree -- node format for both of these constraint types. -- See Discriminant_Constraint for format of node --------------------------- -- 3.6.1 Discrete Range -- --------------------------- -- DISCRETE_RANGE ::= discrete_SUBTYPE_INDICATION | RANGE ---------------------------- -- 3.7 Discriminant Part -- ---------------------------- -- DISCRIMINANT_PART ::= -- UNKNOWN_DISCRIMINANT_PART | KNOWN_DISCRIMINANT_PART ------------------------------------ -- 3.7 Unknown Discriminant Part -- ------------------------------------ -- UNKNOWN_DISCRIMINANT_PART ::= (<>) -- Note: unknown discriminant parts are not permitted in Ada 83 mode -- There is no explicit node in the tree for an unknown discriminant -- part. Instead the Unknown_Discriminants_Present flag is set in the -- parent node. ---------------------------------- -- 3.7 Known Discriminant Part -- ---------------------------------- -- KNOWN_DISCRIMINANT_PART ::= -- (DISCRIMINANT_SPECIFICATION {; DISCRIMINANT_SPECIFICATION}) ------------------------------------- -- 3.7 Discriminant Specification -- ------------------------------------- -- DISCRIMINANT_SPECIFICATION ::= -- DEFINING_IDENTIFIER_LIST : [NULL_EXCLUSION] SUBTYPE_MARK -- [:= DEFAULT_EXPRESSION] -- | DEFINING_IDENTIFIER_LIST : ACCESS_DEFINITION -- [:= DEFAULT_EXPRESSION] -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive specifications were given with -- identical type definition and expression components. To simplify -- semantic processing, the parser represents a multiple declaration -- case as a sequence of single specifications, using the More_Ids and -- Prev_Ids flags to preserve the original source form as described -- in the section on "Handling of Defining Identifier Lists". -- N_Discriminant_Specification -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Discriminant_Type (Node5) subtype mark or -- access parameter definition -- Expression (Node3) (set to Empty if no default expression) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) ----------------------------- -- 3.7 Default Expression -- ----------------------------- -- DEFAULT_EXPRESSION ::= EXPRESSION ------------------------------------ -- 3.7.1 Discriminant Constraint -- ------------------------------------ -- DISCRIMINANT_CONSTRAINT ::= -- (DISCRIMINANT_ASSOCIATION {, DISCRIMINANT_ASSOCIATION}) -- It is not in general possible to distinguish between discriminant -- constraints and index constraints at parse time, since a simple -- name could be either the subtype mark of a discrete range, or an -- expression in a discriminant association with no name. Either -- entry appears simply as the name, and the semantic parse must -- distinguish between the two cases. Thus we use a common tree -- node format for both of these constraint types. -- N_Index_Or_Discriminant_Constraint -- Sloc points to left paren -- Constraints (List1) points to list of discrete ranges or -- discriminant associations ------------------------------------- -- 3.7.1 Discriminant Association -- ------------------------------------- -- DISCRIMINANT_ASSOCIATION ::= -- [discriminant_SELECTOR_NAME -- {| discriminant_SELECTOR_NAME} =>] EXPRESSION -- Note: a discriminant association that has no selector name list -- appears directly as an expression in the tree. -- N_Discriminant_Association -- Sloc points to first token of discriminant association -- Selector_Names (List1) (always non-empty, since if no selector -- names are present, this node is not used, see comment above) -- Expression (Node3) --------------------------------- -- 3.8 Record Type Definition -- --------------------------------- -- RECORD_TYPE_DEFINITION ::= -- [[abstract] tagged] [limited] RECORD_DEFINITION -- Note: ABSTRACT, TAGGED, LIMITED are not permitted in Ada 83 mode -- There is no explicit node in the tree for a record type definition. -- Instead the flags for Tagged_Present and Limited_Present appear in -- the N_Record_Definition node for a record definition appearing in -- the context of a record type definition. ---------------------------- -- 3.8 Record Definition -- ---------------------------- -- RECORD_DEFINITION ::= -- record -- COMPONENT_LIST -- end record -- | null record -- Note: the Abstract_Present, Tagged_Present and Limited_Present -- flags appear only for a record definition appearing in a record -- type definition. -- Note: the NULL RECORD case is not permitted in Ada 83 -- N_Record_Definition -- Sloc points to RECORD or NULL -- End_Label (Node4) (set to Empty if internally generated record) -- Abstract_Present (Flag4) -- Tagged_Present (Flag15) -- Limited_Present (Flag17) -- Component_List (Node1) empty in null record case -- Null_Present (Flag13) set in null record case ------------------------- -- 3.8 Component List -- ------------------------- -- COMPONENT_LIST ::= -- COMPONENT_ITEM {COMPONENT_ITEM} -- | {COMPONENT_ITEM} VARIANT_PART -- | null; -- N_Component_List -- Sloc points to first token of component list -- Component_Items (List3) -- Variant_Part (Node4) (set to Empty if no variant part) -- Null_Present (Flag13) ------------------------- -- 3.8 Component Item -- ------------------------- -- COMPONENT_ITEM ::= COMPONENT_DECLARATION | REPRESENTATION_CLAUSE -- Note: A component item can also be a pragma, and in the tree -- that is obtained after semantic processing, a component item -- can be an N_Null node resulting from a non-recognized pragma. -------------------------------- -- 3.8 Component Declaration -- -------------------------------- -- COMPONENT_DECLARATION ::= -- DEFINING_IDENTIFIER_LIST : COMPONENT_DEFINITION -- [:= DEFAULT_EXPRESSION] -- Note: although the syntax does not permit a component definition to -- be an anonymous array (and the parser will diagnose such an attempt -- with an appropriate message), it is possible for anonymous arrays -- to appear as component definitions. The semantics and back end handle -- this case properly, and the expander in fact generates such cases. -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive declarations were given with the -- same component definition and expression components. To simplify -- semantic processing, the parser represents a multiple declaration -- case as a sequence of single declarations, using the More_Ids and -- Prev_Ids flags to preserve the original source form as described -- in the section on "Handling of Defining Identifier Lists". -- N_Component_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Component_Definition (Node4) -- Expression (Node3) (set to Empty if no default expression) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) ------------------------- -- 3.8.1 Variant Part -- ------------------------- -- VARIANT_PART ::= -- case discriminant_DIRECT_NAME is -- VARIANT -- {VARIANT} -- end case; -- Note: the variants list can contain pragmas as well as variants. -- In a properly formed program there is at least one variant. -- N_Variant_Part -- Sloc points to CASE -- Name (Node2) -- Variants (List1) -------------------- -- 3.8.1 Variant -- -------------------- -- VARIANT ::= -- when DISCRETE_CHOICE_LIST => -- COMPONENT_LIST -- N_Variant -- Sloc points to WHEN -- Discrete_Choices (List4) -- Component_List (Node1) -- Enclosing_Variant (Node2-Sem) -- Present_Expr (Uint3-Sem) -- Dcheck_Function (Node5-Sem) --------------------------------- -- 3.8.1 Discrete Choice List -- --------------------------------- -- DISCRETE_CHOICE_LIST ::= DISCRETE_CHOICE {| DISCRETE_CHOICE} ---------------------------- -- 3.8.1 Discrete Choice -- ---------------------------- -- DISCRETE_CHOICE ::= EXPRESSION | DISCRETE_RANGE | others -- Note: in Ada 83 mode, the expression must be a simple expression -- The only choice that appears explicitly is the OTHERS choice, as -- defined here. Other cases of discrete choice (expression and -- discrete range) appear directly. This production is also used -- for the OTHERS possibility of an exception choice. -- Note: in accordance with the syntax, the parser does not check that -- OTHERS appears at the end on its own in a choice list context. This -- is a semantic check. -- N_Others_Choice -- Sloc points to OTHERS -- Others_Discrete_Choices (List1-Sem) -- All_Others (Flag11-Sem) ---------------------------------- -- 3.9.1 Record Extension Part -- ---------------------------------- -- RECORD_EXTENSION_PART ::= with RECORD_DEFINITION -- Note: record extension parts are not permitted in Ada 83 mode ---------------------------------- -- 3.10 Access Type Definition -- ---------------------------------- -- ACCESS_TYPE_DEFINITION ::= -- ACCESS_TO_OBJECT_DEFINITION -- | ACCESS_TO_SUBPROGRAM_DEFINITION -------------------------- -- 3.10 Null Exclusion -- -------------------------- -- NULL_EXCLUSION ::= not null --------------------------------------- -- 3.10 Access To Object Definition -- --------------------------------------- -- ACCESS_TO_OBJECT_DEFINITION ::= -- [NULL_EXCLUSION] access [GENERAL_ACCESS_MODIFIER] -- SUBTYPE_INDICATION -- N_Access_To_Object_Definition -- Sloc points to ACCESS -- All_Present (Flag15) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Subtype_Indication (Node5) -- Constant_Present (Flag17) ----------------------------------- -- 3.10 General Access Modifier -- ----------------------------------- -- GENERAL_ACCESS_MODIFIER ::= all | constant -- Note: general access modifiers are not permitted in Ada 83 mode -- There is no explicit node in the tree for general access modifier. -- Instead the All_Present or Constant_Present flags are set in the -- parent node. ------------------------------------------- -- 3.10 Access To Subprogram Definition -- ------------------------------------------- -- ACCESS_TO_SUBPROGRAM_DEFINITION -- [NULL_EXCLUSION] access [protected] procedure PARAMETER_PROFILE -- | [NULL_EXCLUSION] access [protected] function -- PARAMETER_AND_RESULT_PROFILE -- Note: access to subprograms are not permitted in Ada 83 mode -- N_Access_Function_Definition -- Sloc points to ACCESS -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Protected_Present (Flag15) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Subtype_Mark (Node4) result subtype -- N_Access_Procedure_Definition -- Sloc points to ACCESS -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Protected_Present (Flag15) -- Parameter_Specifications (List3) (set to No_List if no formal part) ----------------------------- -- 3.10 Access Definition -- ----------------------------- -- ACCESS_DEFINITION ::= -- [NULL_EXCLUSION] access [GENERAL_ACCESS_MODIFIER] SUBTYPE_MARK -- | ACCESS_TO_SUBPROGRAM_DEFINITION -- Note: access to subprograms are an Ada 2005 (AI-254) extension -- N_Access_Definition -- Sloc points to ACCESS -- Null_Exclusion_Present (Flag9) (set to False if not present) -- All_Present (Flag15) -- Constant_Present (Flag17) -- Subtype_Mark (Node4) -- Access_To_Subprogram_Definition (Node3) (set to Empty if not present) ----------------------------------------- -- 3.10.1 Incomplete Type Declaration -- ----------------------------------------- -- INCOMPLETE_TYPE_DECLARATION ::= -- type DEFINING_IDENTIFIER [DISCRIMINANT_PART]; -- N_Incomplete_Type_Declaration -- Sloc points to TYPE -- Defining_Identifier (Node1) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part, or if the discriminant part is an -- unknown discriminant part) -- Unknown_Discriminants_Present (Flag13) set if (<>) discriminant ---------------------------- -- 3.11 Declarative Part -- ---------------------------- -- DECLARATIVE_PART ::= {DECLARATIVE_ITEM} -- Note: although the parser enforces the syntactic requirement that -- a declarative part can contain only declarations, the semantic -- processing may add statements to the list of actions in a -- declarative part, so the code generator should be prepared -- to accept a statement in this position. ---------------------------- -- 3.11 Declarative Item -- ---------------------------- -- DECLARATIVE_ITEM ::= BASIC_DECLARATIVE_ITEM | BODY ---------------------------------- -- 3.11 Basic Declarative Item -- ---------------------------------- -- BASIC_DECLARATIVE_ITEM ::= -- BASIC_DECLARATION | REPRESENTATION_CLAUSE | USE_CLAUSE ---------------- -- 3.11 Body -- ---------------- -- BODY ::= PROPER_BODY | BODY_STUB ----------------------- -- 3.11 Proper Body -- ----------------------- -- PROPER_BODY ::= -- SUBPROGRAM_BODY | PACKAGE_BODY | TASK_BODY | PROTECTED_BODY --------------- -- 4.1 Name -- --------------- -- NAME ::= -- DIRECT_NAME | EXPLICIT_DEREFERENCE -- | INDEXED_COMPONENT | SLICE -- | SELECTED_COMPONENT | ATTRIBUTE_REFERENCE -- | TYPE_CONVERSION | FUNCTION_CALL -- | CHARACTER_LITERAL ---------------------- -- 4.1 Direct Name -- ---------------------- -- DIRECT_NAME ::= IDENTIFIER | OPERATOR_SYMBOL ----------------- -- 4.1 Prefix -- ----------------- -- PREFIX ::= NAME | IMPLICIT_DEREFERENCE ------------------------------- -- 4.1 Explicit Dereference -- ------------------------------- -- EXPLICIT_DEREFERENCE ::= NAME . all -- N_Explicit_Dereference -- Sloc points to ALL -- Prefix (Node3) -- plus fields for expression ------------------------------- -- 4.1 Implicit Dereference -- ------------------------------- -- IMPLICIT_DEREFERENCE ::= NAME ------------------------------ -- 4.1.1 Indexed Component -- ------------------------------ -- INDEXED_COMPONENT ::= PREFIX (EXPRESSION {, EXPRESSION}) -- Note: the parser may generate this node in some situations where it -- should be a function call. The semantic pass must correct this -- misidentification (which is inevitable at the parser level). -- N_Indexed_Component -- Sloc contains a copy of the Sloc value of the Prefix -- Prefix (Node3) -- Expressions (List1) -- plus fields for expression -- Note: if any of the subscripts requires a range check, then the -- Do_Range_Check flag is set on the corresponding expression, with -- the index type being determined from the type of the Prefix, which -- references the array being indexed. -- Note: in a fully analyzed and expanded indexed component node, and -- hence in any such node that gigi sees, if the prefix is an access -- type, then an explicit dereference operation has been inserted. ------------------ -- 4.1.2 Slice -- ------------------ -- SLICE ::= PREFIX (DISCRETE_RANGE) -- Note: an implicit subtype is created to describe the resulting -- type, so that the bounds of this type are the bounds of the slice. -- N_Slice -- Sloc points to first token of prefix -- Prefix (Node3) -- Discrete_Range (Node4) -- plus fields for expression ------------------------------- -- 4.1.3 Selected Component -- ------------------------------- -- SELECTED_COMPONENT ::= PREFIX . SELECTOR_NAME -- Note: selected components that are semantically expanded names get -- changed during semantic processing into the separate N_Expanded_Name -- node. See description of this node in the section on semantic nodes. -- N_Selected_Component -- Sloc points to period -- Prefix (Node3) -- Selector_Name (Node2) -- Associated_Node (Node4-Sem) -- Do_Discriminant_Check (Flag13-Sem) -- Is_In_Discriminant_Check (Flag11-Sem) -- plus fields for expression -------------------------- -- 4.1.3 Selector Name -- -------------------------- -- SELECTOR_NAME ::= IDENTIFIER | CHARACTER_LITERAL | OPERATOR_SYMBOL -------------------------------- -- 4.1.4 Attribute Reference -- -------------------------------- -- ATTRIBUTE_REFERENCE ::= PREFIX ' ATTRIBUTE_DESIGNATOR -- Note: the syntax is quite ambiguous at this point. Consider: -- A'Length (X) X is part of the attribute designator -- A'Pos (X) X is an explicit actual parameter of function A'Pos -- A'Class (X) X is the expression of a type conversion -- It would be possible for the parser to distinguish these cases -- by looking at the attribute identifier. However, that would mean -- more work in introducing new implementation defined attributes, -- and also it would mean that special processing for attributes -- would be scattered around, instead of being centralized in the -- semantic routine that handles an N_Attribute_Reference node. -- Consequently, the parser in all the above cases stores the -- expression (X in these examples) as a single element list in -- in the Expressions field of the N_Attribute_Reference node. -- Similarly, for attributes like Max which take two arguments, -- we store the two arguments as a two element list in the -- Expressions field. Of course it is clear at parse time that -- this case is really a function call with an attribute as the -- prefix, but it turns out to be convenient to handle the two -- argument case in a similar manner to the one argument case, -- and indeed in general the parser will accept any number of -- expressions in this position and store them as a list in the -- attribute reference node. This allows for future addition of -- attributes that take more than two arguments. -- Note: named associates are not permitted in function calls where -- the function is an attribute (see RM 6.4(3)) so it is legitimate -- to skip the normal subprogram argument processing. -- Note: for the attributes whose designators are technically keywords, -- i.e. digits, access, delta, range, the Attribute_Name field contains -- the corresponding name, even though no identifier is involved. -- The flag OK_For_Stream is used in generated code to indicate that -- a stream attribute is permissible for a limited type, and results -- in the use of the stream attribute for the underlying full type, -- or in the case of a protected type, the components (including any -- disriminants) are merely streamed in order. -- See Exp_Attr for a complete description of which attributes are -- passed onto Gigi, and which are handled entirely by the front end. -- Gigi restriction: For the Pos attribute, the prefix cannot be -- a non-standard enumeration type or a nonzero/zero semantics -- boolean type, so the value is simply the stored representation. -- Note: In generated code, the Address and Unrestricted_Access -- attributes can be applied to any expression, and the meaning is -- to create an object containing the value (the object is in the -- current stack frame), and pass the address of this value. If the -- Must_Be_Byte_Aligned flag is set, then the object whose address -- is taken must be on a byte (storage unit) boundary, and if it is -- not (or may not be), then the generated code must create a copy -- that is byte aligned, and pass the address of this copy. -- N_Attribute_Reference -- Sloc points to apostrophe -- Prefix (Node3) -- Attribute_Name (Name2) identifier name from attribute designator -- Expressions (List1) (set to No_List if no associated expressions) -- Entity (Node4-Sem) used if the attribute yields a type -- Associated_Node (Node4-Sem) -- Do_Overflow_Check (Flag17-Sem) -- Redundant_Use (Flag13-Sem) -- OK_For_Stream (Flag4-Sem) -- Must_Be_Byte_Aligned (Flag14) -- plus fields for expression --------------------------------- -- 4.1.4 Attribute Designator -- --------------------------------- -- ATTRIBUTE_DESIGNATOR ::= -- IDENTIFIER [(static_EXPRESSION)] -- | access | delta | digits -- There is no explicit node in the tree for an attribute designator. -- Instead the Attribute_Name and Expressions fields of the parent -- node (N_Attribute_Reference node) hold the information. -- Note: if ACCESS, DELTA or DIGITS appears in an attribute -- designator, then they are treated as identifiers internally -- rather than the keywords of the same name. -------------------------------------- -- 4.1.4 Range Attribute Reference -- -------------------------------------- -- RANGE_ATTRIBUTE_REFERENCE ::= PREFIX ' RANGE_ATTRIBUTE_DESIGNATOR -- A range attribute reference is represented in the tree using the -- normal N_Attribute_Reference node. --------------------------------------- -- 4.1.4 Range Attribute Designator -- --------------------------------------- -- RANGE_ATTRIBUTE_DESIGNATOR ::= Range [(static_EXPRESSION)] -- A range attribute designator is represented in the tree using the -- normal N_Attribute_Reference node. -------------------- -- 4.3 Aggregate -- -------------------- -- AGGREGATE ::= -- RECORD_AGGREGATE | EXTENSION_AGGREGATE | ARRAY_AGGREGATE ----------------------------- -- 4.3.1 Record Aggregate -- ----------------------------- -- RECORD_AGGREGATE ::= (RECORD_COMPONENT_ASSOCIATION_LIST) -- N_Aggregate -- Sloc points to left parenthesis -- Expressions (List1) (set to No_List if none or null record case) -- Component_Associations (List2) (set to No_List if none) -- Null_Record_Present (Flag17) -- Aggregate_Bounds (Node3-Sem) -- Associated_Node (Node4-Sem) -- Static_Processing_OK (Flag4-Sem) -- Compile_Time_Known_Aggregate (Flag18-Sem) -- Expansion_Delayed (Flag11-Sem) -- plus fields for expression -- Note: this structure is used for both record and array aggregates -- since the two cases are not separable by the parser. The parser -- makes no attempt to enforce consistency here, so it is up to the -- semantic phase to make sure that the aggregate is consistent (i.e. -- that it is not a "half-and-half" case that mixes record and array -- syntax. In particular, for a record aggregate, the expressions -- field will be set if there are positional associations. -- Note: gigi/gcc can handle array aggregates correctly providing that -- they are entirely positional, and the array subtype involved has a -- known at compile time length and is not bit packed, or a convention -- Fortran array with more than one dimension. If these conditions -- are not met, then the front end must translate the aggregate into -- an appropriate set of assignments into a temporary. -- Note: for the record aggregate case, gigi/gcc can handle all cases -- of record aggregates, including those for packed, and rep-claused -- records, and also variant records, providing that there are no -- variable length fields whose size is not known at runtime, and -- providing that the aggregate is presented in fully named form. ---------------------------------------------- -- 4.3.1 Record Component Association List -- ---------------------------------------------- -- RECORD_COMPONENT_ASSOCIATION_LIST ::= -- RECORD_COMPONENT_ASSOCIATION {, RECORD_COMPONENT_ASSOCIATION} -- | null record -- There is no explicit node in the tree for a record component -- association list. Instead the Null_Record_Present flag is set in -- the parent node for the NULL RECORD case. ------------------------------------------------------ -- 4.3.1 Record Component Association (also 4.3.3) -- ------------------------------------------------------ -- RECORD_COMPONENT_ASSOCIATION ::= -- [COMPONENT_CHOICE_LIST =>] EXPRESSION -- N_Component_Association -- Sloc points to first selector name -- Choices (List1) -- Loop_Actions (List2-Sem) -- Expression (Node3) -- Box_Present (Flag15) -- Note: this structure is used for both record component associations -- and array component associations, since the two cases aren't always -- separable by the parser. The choices list may represent either a -- list of selector names in the record aggregate case, or a list of -- discrete choices in the array aggregate case or an N_Others_Choice -- node (which appears as a singleton list). Box_Present gives support -- to Ada 2005 (AI-287). ----------------------------------- -- 4.3.1 Commponent Choice List -- ----------------------------------- -- COMPONENT_CHOICE_LIST ::= -- component_SELECTOR_NAME {| component_SELECTOR_NAME} -- | others -- The entries of a component choice list appear in the Choices list -- of the associated N_Component_Association, as either selector -- names, or as an N_Others_Choice node. -------------------------------- -- 4.3.2 Extension Aggregate -- -------------------------------- -- EXTENSION_AGGREGATE ::= -- (ANCESTOR_PART with RECORD_COMPONENT_ASSOCIATION_LIST) -- Note: extension aggregates are not permitted in Ada 83 mode -- N_Extension_Aggregate -- Sloc points to left parenthesis -- Ancestor_Part (Node3) -- Associated_Node (Node4-Sem) -- Expressions (List1) (set to No_List if none or null record case) -- Component_Associations (List2) (set to No_List if none) -- Null_Record_Present (Flag17) -- Expansion_Delayed (Flag11-Sem) -- plus fields for expression -------------------------- -- 4.3.2 Ancestor Part -- -------------------------- -- ANCESTOR_PART ::= EXPRESSION | SUBTYPE_MARK ---------------------------- -- 4.3.3 Array Aggregate -- ---------------------------- -- ARRAY_AGGREGATE ::= -- POSITIONAL_ARRAY_AGGREGATE | NAMED_ARRAY_AGGREGATE --------------------------------------- -- 4.3.3 Positional Array Aggregate -- --------------------------------------- -- POSITIONAL_ARRAY_AGGREGATE ::= -- (EXPRESSION, EXPRESSION {, EXPRESSION}) -- | (EXPRESSION {, EXPRESSION}, others => EXPRESSION) -- See Record_Aggregate (4.3.1) for node structure ---------------------------------- -- 4.3.3 Named Array Aggregate -- ---------------------------------- -- NAMED_ARRAY_AGGREGATE ::= -- | (ARRAY_COMPONENT_ASSOCIATION {, ARRAY_COMPONENT_ASSOCIATION}) -- See Record_Aggregate (4.3.1) for node structure ---------------------------------------- -- 4.3.3 Array Component Association -- ---------------------------------------- -- ARRAY_COMPONENT_ASSOCIATION ::= -- DISCRETE_CHOICE_LIST => EXPRESSION -- See Record_Component_Association (4.3.1) for node structure -------------------------------------------------- -- 4.4 Expression/Relation/Term/Factor/Primary -- -------------------------------------------------- -- EXPRESSION ::= -- RELATION {and RELATION} | RELATION {and then RELATION} -- | RELATION {or RELATION} | RELATION {or else RELATION} -- | RELATION {xor RELATION} -- RELATION ::= -- SIMPLE_EXPRESSION [RELATIONAL_OPERATOR SIMPLE_EXPRESSION] -- | SIMPLE_EXPRESSION [not] in RANGE -- | SIMPLE_EXPRESSION [not] in SUBTYPE_MARK -- SIMPLE_EXPRESSION ::= -- [UNARY_ADDING_OPERATOR] TERM {BINARY_ADDING_OPERATOR TERM} -- TERM ::= FACTOR {MULTIPLYING_OPERATOR FACTOR} -- FACTOR ::= PRIMARY [** PRIMARY] | abs PRIMARY | not PRIMARY -- No nodes are generated for any of these constructs. Instead, the -- node for the operator appears directly. When we refer to an -- expression in this description, we mean any of the possible -- consistuent components of an expression (e.g. identifier is -- an example of an expression). ------------------ -- 4.4 Primary -- ------------------ -- PRIMARY ::= -- NUMERIC_LITERAL | null -- | STRING_LITERAL | AGGREGATE -- | NAME | QUALIFIED_EXPRESSION -- | ALLOCATOR | (EXPRESSION) -- Usually there is no explicit node in the tree for primary. Instead -- the constituent (e.g. AGGREGATE) appears directly. There are two -- exceptions. First, there is an explicit node for a null primary. -- N_Null -- Sloc points to NULL -- plus fields for expression -- Second, the case of (EXPRESSION) is handled specially. Ada requires -- that the parser keep track of which subexpressions are enclosed -- in parentheses, and how many levels of parentheses are used. This -- information is required for optimization purposes, and also for -- some semantic checks (e.g. (((1))) in a procedure spec does not -- conform with ((((1)))) in the body). -- The parentheses are recorded by keeping a Paren_Count field in every -- subexpression node (it is actually present in all nodes, but only -- used in subexpression nodes). This count records the number of -- levels of parentheses. If the number of levels in the source exceeds -- the maximum accomodated by this count, then the count is simply left -- at the maximum value. This means that there are some pathalogical -- cases of failure to detect conformance failures (e.g. an expression -- with 500 levels of parens will conform with one with 501 levels), -- but we do not need to lose sleep over this. -- Historical note: in versions of GNAT prior to 1.75, there was a node -- type N_Parenthesized_Expression used to accurately record unlimited -- numbers of levels of parentheses. However, it turned out to be a -- real nuisance to have to take into account the possible presence of -- this node during semantic analysis, since basically parentheses have -- zero relevance to semantic analysis. -- Note: the level of parentheses always present in things like -- aggregates does not count, only the parentheses in the primary -- (EXPRESSION) affect the setting of the Paren_Count field. -- 2nd Note: the contents of the Expression field must be ignored (i.e. -- treated as though it were Empty) if No_Initialization is set True. -------------------------------------- -- 4.5 Short Circuit Control Forms -- -------------------------------------- -- EXPRESSION ::= -- RELATION {and then RELATION} | RELATION {or else RELATION} -- Gigi restriction: For both these control forms, the operand and -- result types are always Standard.Boolean. The expander inserts the -- required conversion operations where needed to ensure this is the -- case. -- N_And_Then -- Sloc points to AND of AND THEN -- Left_Opnd (Node2) -- Right_Opnd (Node3) -- Actions (List1-Sem) -- plus fields for expression -- N_Or_Else -- Sloc points to OR of OR ELSE -- Left_Opnd (Node2) -- Right_Opnd (Node3) -- Actions (List1-Sem) -- plus fields for expression -- Note: The Actions field is used to hold actions associated with -- the right hand operand. These have to be treated specially since -- they are not unconditionally executed. See Insert_Actions for a -- more detailed description of how these actions are handled. --------------------------- -- 4.5 Membership Tests -- --------------------------- -- RELATION ::= -- SIMPLE_EXPRESSION [not] in RANGE -- | SIMPLE_EXPRESSION [not] in SUBTYPE_MARK -- Note: although the grammar above allows only a range or a -- subtype mark, the parser in fact will accept any simple -- expression in place of a subtype mark. This means that the -- semantic analyzer must be prepared to deal with, and diagnose -- a simple expression other than a name for the right operand. -- This simplifies error recovery in the parser. -- N_In -- Sloc points to IN -- Left_Opnd (Node2) -- Right_Opnd (Node3) -- plus fields for expression -- N_Not_In -- Sloc points to NOT of NOT IN -- Left_Opnd (Node2) -- Right_Opnd (Node3) -- plus fields for expression -------------------- -- 4.5 Operators -- -------------------- -- LOGICAL_OPERATOR ::= and | or | xor -- RELATIONAL_OPERATOR ::= = | /= | < | <= | > | >= -- BINARY_ADDING_OPERATOR ::= + | - | & -- UNARY_ADDING_OPERATOR ::= + | - -- MULTIPLYING_OPERATOR ::= * | / | mod | rem -- HIGHEST_PRECEDENCE_OPERATOR ::= ** | abs | not -- Sprint syntax if Treat_Fixed_As_Integer is set: -- x #* y -- x #/ y -- x #mod y -- x #rem y -- Gigi restriction: For * / mod rem with fixed-point operands, Gigi -- will only be given nodes with the Treat_Fixed_As_Integer flag set. -- All handling of smalls for multiplication and division is handled -- by the front end (mod and rem result only from expansion). Gigi -- thus never needs to worry about small values (for other operators -- operating on fixed-point, e.g. addition, the small value does not -- have any semantic effect anyway, these are always integer operations. -- Gigi restriction: For all operators taking Boolean operands, the -- type is always Standard.Boolean. The expander inserts the required -- conversion operations where needed to ensure this is the case. -- N_Op_And -- Sloc points to AND -- Do_Length_Check (Flag4-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Or -- Sloc points to OR -- Do_Length_Check (Flag4-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Xor -- Sloc points to XOR -- Do_Length_Check (Flag4-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Eq -- Sloc points to = -- plus fields for binary operator -- plus fields for expression -- N_Op_Ne -- Sloc points to /= -- plus fields for binary operator -- plus fields for expression -- N_Op_Lt -- Sloc points to < -- plus fields for binary operator -- plus fields for expression -- N_Op_Le -- Sloc points to <= -- plus fields for binary operator -- plus fields for expression -- N_Op_Gt -- Sloc points to > -- plus fields for binary operator -- plus fields for expression -- N_Op_Ge -- Sloc points to >= -- plus fields for binary operator -- plus fields for expression -- N_Op_Add -- Sloc points to + (binary) -- plus fields for binary operator -- plus fields for expression -- N_Op_Subtract -- Sloc points to - (binary) -- plus fields for binary operator -- plus fields for expression -- N_Op_Concat -- Sloc points to & -- Is_Component_Left_Opnd (Flag13-Sem) -- Is_Component_Right_Opnd (Flag14-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Multiply -- Sloc points to * -- Treat_Fixed_As_Integer (Flag14-Sem) -- Rounded_Result (Flag18-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Divide -- Sloc points to / -- Treat_Fixed_As_Integer (Flag14-Sem) -- Do_Division_Check (Flag13-Sem) -- Rounded_Result (Flag18-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Mod -- Sloc points to MOD -- Treat_Fixed_As_Integer (Flag14-Sem) -- Do_Division_Check (Flag13-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Rem -- Sloc points to REM -- Treat_Fixed_As_Integer (Flag14-Sem) -- Do_Division_Check (Flag13-Sem) -- plus fields for binary operator -- plus fields for expression -- N_Op_Expon -- Is_Power_Of_2_For_Shift (Flag13-Sem) -- Sloc points to ** -- plus fields for binary operator -- plus fields for expression -- N_Op_Plus -- Sloc points to + (unary) -- plus fields for unary operator -- plus fields for expression -- N_Op_Minus -- Sloc points to - (unary) -- plus fields for unary operator -- plus fields for expression -- N_Op_Abs -- Sloc points to ABS -- plus fields for unary operator -- plus fields for expression -- N_Op_Not -- Sloc points to NOT -- plus fields for unary operator -- plus fields for expression -- See also shift operators in section B.2 -- Note on fixed-point operations passed to Gigi: For adding operators, -- the semantics is to treat these simply as integer operations, with -- the small values being ignored (the bounds are already stored in -- units of small, so that constraint checking works as usual). For the -- case of multiply/divide/rem/mod operations, Gigi will only see fixed -- point operands if the Treat_Fixed_As_Integer flag is set and will -- thus treat these nodes in identical manner, ignoring small values. -------------------------- -- 4.6 Type Conversion -- -------------------------- -- TYPE_CONVERSION ::= -- SUBTYPE_MARK (EXPRESSION) | SUBTYPE_MARK (NAME) -- In the (NAME) case, the name is stored as the expression -- Note: the parser never generates a type conversion node, since it -- looks like an indexed component which is generated by preference. -- The semantic pass must correct this misidentification. -- Gigi handles conversions that involve no change in the root type, -- and also all conversions from integer to floating-point types. -- Conversions from floating-point to integer are only handled in -- the case where Float_Truncate flag set. Other conversions from -- floating-point to integer (involving rounding) and all conversions -- involving fixed-point types are handled by the expander. -- Sprint syntax if Float_Truncate set: X^(Y) -- Sprint syntax if Conversion_OK set X?(Y) -- Sprint syntax if both flags set X?^(Y) -- Note: If either the operand or result type is fixed-point, Gigi will -- only see a type conversion node with Conversion_OK set. The front end -- takes care of all handling of small's for fixed-point conversions. -- N_Type_Conversion -- Sloc points to first token of subtype mark -- Subtype_Mark (Node4) -- Expression (Node3) -- Do_Tag_Check (Flag13-Sem) -- Do_Length_Check (Flag4-Sem) -- Do_Overflow_Check (Flag17-Sem) -- Float_Truncate (Flag11-Sem) -- Rounded_Result (Flag18-Sem) -- Conversion_OK (Flag14-Sem) -- plus fields for expression -- Note: if a range check is required, then the Do_Range_Check flag -- is set in the Expression with the check being done against the -- target type range (after the base type conversion, if any). ------------------------------- -- 4.7 Qualified Expression -- ------------------------------- -- QUALIFIED_EXPRESSION ::= -- SUBTYPE_MARK ' (EXPRESSION) | SUBTYPE_MARK ' AGGREGATE -- Note: the parentheses in the (EXPRESSION) case are deemed to enclose -- the expression, so the Expression field of this node always points -- to a parenthesized expression in this case (i.e. Paren_Count will -- always be non-zero for the referenced expression if it is not an -- aggregate). -- N_Qualified_Expression -- Sloc points to apostrophe -- Subtype_Mark (Node4) -- Expression (Node3) expression or aggregate -- plus fields for expression -------------------- -- 4.8 Allocator -- -------------------- -- ALLOCATOR ::= -- new [NULL_EXCLUSION] SUBTYPE_INDICATION | new QUALIFIED_EXPRESSION -- Sprint syntax (when storage pool present) -- new xxx (storage_pool = pool) -- N_Allocator -- Sloc points to NEW -- Expression (Node3) subtype indication or qualified expression -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Storage_Pool (Node1-Sem) -- Procedure_To_Call (Node4-Sem) -- No_Initialization (Flag13-Sem) -- Do_Storage_Check (Flag17-Sem) -- plus fields for expression --------------------------------- -- 5.1 Sequence Of Statements -- --------------------------------- -- SEQUENCE_OF_STATEMENTS ::= STATEMENT {STATEMENT} -- Note: Although the parser will not accept a declaration as a -- statement, the semantic analyzer may insert declarations (e.g. -- declarations of implicit types needed for execution of other -- statements) into a sequence of statements, so the code genmerator -- should be prepared to accept a declaration where a statement is -- expected. Note also that pragmas can appear as statements. -------------------- -- 5.1 Statement -- -------------------- -- STATEMENT ::= -- {LABEL} SIMPLE_STATEMENT | {LABEL} COMPOUND_STATEMENT -- There is no explicit node in the tree for a statement. Instead, the -- individual statement appears directly. Labels are treated as a -- kind of statement, i.e. they are linked into a statement list at -- the point they appear, so the labeled statement appears following -- the label or labels in the statement list. --------------------------- -- 5.1 Simple Statement -- --------------------------- -- SIMPLE_STATEMENT ::= NULL_STATEMENT -- | ASSIGNMENT_STATEMENT | EXIT_STATEMENT -- | GOTO_STATEMENT | PROCEDURE_CALL_STATEMENT -- | RETURN_STATEMENT | ENTRY_CALL_STATEMENT -- | REQUEUE_STATEMENT | DELAY_STATEMENT -- | ABORT_STATEMENT | RAISE_STATEMENT -- | CODE_STATEMENT ----------------------------- -- 5.1 Compound Statement -- ----------------------------- -- COMPOUND_STATEMENT ::= -- IF_STATEMENT | CASE_STATEMENT -- | LOOP_STATEMENT | BLOCK_STATEMENT -- | ACCEPT_STATEMENT | SELECT_STATEMENT ------------------------- -- 5.1 Null Statement -- ------------------------- -- NULL_STATEMENT ::= null; -- N_Null_Statement -- Sloc points to NULL ---------------- -- 5.1 Label -- ---------------- -- LABEL ::= <> -- Note that the occurrence of a label is not a defining identifier, -- but rather a referencing occurrence. The defining occurrence is -- in the implicit label declaration which occurs in the innermost -- enclosing block. -- N_Label -- Sloc points to << -- Identifier (Node1) direct name of statement identifier -- Exception_Junk (Flag11-Sem) ------------------------------- -- 5.1 Statement Identifier -- ------------------------------- -- STATEMENT_INDENTIFIER ::= DIRECT_NAME -- The IDENTIFIER of a STATEMENT_IDENTIFIER shall be an identifier -- (not an OPERATOR_SYMBOL) ------------------------------- -- 5.2 Assignment Statement -- ------------------------------- -- ASSIGNMENT_STATEMENT ::= -- variable_NAME := EXPRESSION; -- N_Assignment_Statement -- Sloc points to := -- Name (Node2) -- Expression (Node3) -- Do_Tag_Check (Flag13-Sem) -- Do_Length_Check (Flag4-Sem) -- Forwards_OK (Flag5-Sem) -- Backwards_OK (Flag6-Sem) -- No_Ctrl_Actions (Flag7-Sem) -- Note: if a range check is required, then the Do_Range_Check flag -- is set in the Expression (right hand side), with the check being -- done against the type of the Name (left hand side). -- Note: the back end places some restrictions on the form of the -- Expression field. If the object being assigned to is Atomic, then -- the Expression may not have the form of an aggregate (since this -- might cause the back end to generate separate assignments). It -- also cannot be a reference to an object marked as a true constant -- (Is_True_Constant flag set), where the object is itself initalized -- with an aggregate. If necessary the front end must generate an -- extra temporary (with Is_True_Constant set False), and initialize -- this temporary as required (the temporary itself is not atomic). ----------------------- -- 5.3 If Statement -- ----------------------- -- IF_STATEMENT ::= -- if CONDITION then -- SEQUENCE_OF_STATEMENTS -- {elsif CONDITION then -- SEQUENCE_OF_STATEMENTS} -- [else -- SEQUENCE_OF_STATEMENTS] -- end if; -- Gigi restriction: This expander ensures that the type of the -- Condition fields is always Standard.Boolean, even if the type -- in the source is some non-standard boolean type. -- N_If_Statement -- Sloc points to IF -- Condition (Node1) -- Then_Statements (List2) -- Elsif_Parts (List3) (set to No_List if none present) -- Else_Statements (List4) (set to No_List if no else part present) -- End_Span (Uint5) (set to No_Uint if expander generated) -- N_Elsif_Part -- Sloc points to ELSIF -- Condition (Node1) -- Then_Statements (List2) -- Condition_Actions (List3-Sem) -------------------- -- 5.3 Condition -- -------------------- -- CONDITION ::= boolean_EXPRESSION ------------------------- -- 5.4 Case Statement -- ------------------------- -- CASE_STATEMENT ::= -- case EXPRESSION is -- CASE_STATEMENT_ALTERNATIVE -- {CASE_STATEMENT_ALTERNATIVE} -- end case; -- Note: the Alternatives can contain pragmas. These only occur at -- the start of the list, since any pragmas occurring after the first -- alternative are absorbed into the corresponding statement sequence. -- N_Case_Statement -- Sloc points to CASE -- Expression (Node3) -- Alternatives (List4) -- End_Span (Uint5) (set to No_Uint if expander generated) ------------------------------------- -- 5.4 Case Statement Alternative -- ------------------------------------- -- CASE_STATEMENT_ALTERNATIVE ::= -- when DISCRETE_CHOICE_LIST => -- SEQUENCE_OF_STATEMENTS -- N_Case_Statement_Alternative -- Sloc points to WHEN -- Discrete_Choices (List4) -- Statements (List3) ------------------------- -- 5.5 Loop Statement -- ------------------------- -- LOOP_STATEMENT ::= -- [loop_STATEMENT_IDENTIFIER :] -- [ITERATION_SCHEME] loop -- SEQUENCE_OF_STATEMENTS -- end loop [loop_IDENTIFIER]; -- Note: The occurrence of a loop label is not a defining identifier -- but rather a referencing occurrence. The defining occurrence is in -- the implicit label declaration which occurs in the innermost -- enclosing block. -- Note: there is always a loop statement identifier present in -- the tree, even if none was given in the source. In the case where -- no loop identifier is given in the source, the parser creates -- a name of the form _Loop_n, where n is a decimal integer (the -- two underlines ensure that the loop names created in this manner -- do not conflict with any user defined identifiers), and the flag -- Has_Created_Identifier is set to True. The only exception to the -- rule that all loop statement nodes have identifiers occurs for -- loops constructed by the expander, and the semantic analyzer will -- create and supply dummy loop identifiers in these cases. -- N_Loop_Statement -- Sloc points to LOOP -- Identifier (Node1) loop identifier (set to Empty if no identifier) -- Iteration_Scheme (Node2) (set to Empty if no iteration scheme) -- Statements (List3) -- End_Label (Node4) -- Has_Created_Identifier (Flag15) -- Is_Null_Loop (Flag16) -------------------------- -- 5.5 Iteration Scheme -- -------------------------- -- ITERATION_SCHEME ::= -- while CONDITION | for LOOP_PARAMETER_SPECIFICATION -- Gigi restriction: This expander ensures that the type of the -- Condition field is always Standard.Boolean, even if the type -- in the source is some non-standard boolean type. -- N_Iteration_Scheme -- Sloc points to WHILE or FOR -- Condition (Node1) (set to Empty if FOR case) -- Condition_Actions (List3-Sem) -- Loop_Parameter_Specification (Node4) (set to Empty if WHILE case) --------------------------------------- -- 5.5 Loop parameter specification -- --------------------------------------- -- LOOP_PARAMETER_SPECIFICATION ::= -- DEFINING_IDENTIFIER in [reverse] DISCRETE_SUBTYPE_DEFINITION -- N_Loop_Parameter_Specification -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Reverse_Present (Flag15) -- Discrete_Subtype_Definition (Node4) -------------------------- -- 5.6 Block Statement -- -------------------------- -- BLOCK_STATEMENT ::= -- [block_STATEMENT_IDENTIFIER:] -- [declare -- DECLARATIVE_PART] -- begin -- HANDLED_SEQUENCE_OF_STATEMENTS -- end [block_IDENTIFIER]; -- Note that the occurrence of a block identifier is not a defining -- identifier, but rather a referencing occurrence. The defining -- occurrence is in the implicit label declaration which occurs in -- the innermost enclosing block. -- Note: there is always a block statement identifier present in -- the tree, even if none was given in the source. In the case where -- no block identifier is given in the source, the parser creates -- a name of the form _Block_n, where n is a decimal integer (the -- two underlines ensure that the block names created in this manner -- do not conflict with any user defined identifiers), and the flag -- Has_Created_Identifier is set to True. The only exception to the -- rule that all loop statement nodes have identifiers occurs for -- blocks constructed by the expander, and the semantic analyzer -- creates and supplies dummy names for the blocks). -- N_Block_Statement -- Sloc points to DECLARE or BEGIN -- Identifier (Node1) block direct name (set to Empty if not present) -- Declarations (List2) (set to No_List if no DECLARE part) -- Handled_Statement_Sequence (Node4) -- Is_Task_Master (Flag5-Sem) -- Activation_Chain_Entity (Node3-Sem) -- Has_Created_Identifier (Flag15) -- Is_Task_Allocation_Block (Flag6) -- Is_Asynchronous_Call_Block (Flag7) ------------------------- -- 5.7 Exit Statement -- ------------------------- -- EXIT_STATEMENT ::= exit [loop_NAME] [when CONDITION]; -- Gigi restriction: This expander ensures that the type of the -- Condition field is always Standard.Boolean, even if the type -- in the source is some non-standard boolean type. -- N_Exit_Statement -- Sloc points to EXIT -- Name (Node2) (set to Empty if no loop name present) -- Condition (Node1) (set to Empty if no when part present) ------------------------- -- 5.9 Goto Statement -- ------------------------- -- GOTO_STATEMENT ::= goto label_NAME; -- N_Goto_Statement -- Sloc points to GOTO -- Name (Node2) -- Exception_Junk (Flag11-Sem) --------------------------------- -- 6.1 Subprogram Declaration -- --------------------------------- -- SUBPROGRAM_DECLARATION ::= SUBPROGRAM_SPECIFICATION; -- N_Subprogram_Declaration -- Sloc points to FUNCTION or PROCEDURE -- Specification (Node1) -- Body_To_Inline (Node3-Sem) -- Corresponding_Body (Node5-Sem) -- Parent_Spec (Node4-Sem) ------------------------------------------ -- 6.1 Abstract Subprogram Declaration -- ------------------------------------------ -- ABSTRACT_SUBPROGRAM_DECLARATION ::= -- SUBPROGRAM_SPECIFICATION is abstract; -- N_Abstract_Subprogram_Declaration -- Sloc points to ABSTRACT -- Specification (Node1) ----------------------------------- -- 6.1 Subprogram Specification -- ----------------------------------- -- SUBPROGRAM_SPECIFICATION ::= -- procedure DEFINING_PROGRAM_UNIT_NAME PARAMETER_PROFILE -- | function DEFINING_DESIGNATOR PARAMETER_AND_RESULT_PROFILE -- Note: there are no separate nodes for the profiles, instead the -- information appears directly in the following nodes. -- N_Function_Specification -- Sloc points to FUNCTION -- Defining_Unit_Name (Node1) (the designator) -- Elaboration_Boolean (Node2-Sem) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Subtype_Mark (Node4) for return type -- Generic_Parent (Node5-Sem) -- N_Procedure_Specification -- Sloc points to PROCEDURE -- Defining_Unit_Name (Node1) -- Elaboration_Boolean (Node2-Sem) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Generic_Parent (Node5-Sem) --------------------- -- 6.1 Designator -- --------------------- -- DESIGNATOR ::= -- [PARENT_UNIT_NAME .] IDENTIFIER | OPERATOR_SYMBOL -- Designators that are simply identifiers or operator symbols appear -- directly in the tree in this form. The following node is used only -- in the case where the designator has a parent unit name component. -- N_Designator -- Sloc points to period -- Name (Node2) holds the parent unit name. Note that this is always -- non-Empty, since this node is only used for the case where a -- parent library unit package name is present. -- Identifier (Node1) -- Note that the identifier can also be an operator symbol here. ------------------------------ -- 6.1 Defining Designator -- ------------------------------ -- DEFINING_DESIGNATOR ::= -- DEFINING_PROGRAM_UNIT_NAME | DEFINING_OPERATOR_SYMBOL ------------------------------------- -- 6.1 Defining Program Unit Name -- ------------------------------------- -- DEFINING_PROGRAM_UNIT_NAME ::= -- [PARENT_UNIT_NAME .] DEFINING_IDENTIFIER -- The parent unit name is present only in the case of a child unit -- name (permissible only for Ada 95 for a library level unit, i.e. -- a unit at scope level one). If no such name is present, the defining -- program unit name is represented simply as the defining identifier. -- In the child unit case, the following node is used to represent the -- child unit name. -- N_Defining_Program_Unit_Name -- Sloc points to period -- Name (Node2) holds the parent unit name. Note that this is always -- non-Empty, since this node is only used for the case where a -- parent unit name is present. -- Defining_Identifier (Node1) -------------------------- -- 6.1 Operator Symbol -- -------------------------- -- OPERATOR_SYMBOL ::= STRING_LITERAL -- Note: the fields of the N_Operator_Symbol node are laid out to -- match the corresponding fields of an N_Character_Literal node. This -- allows easy conversion of the operator symbol node into a character -- literal node in the case where a string constant of the form of an -- operator symbol is scanned out as such, but turns out semantically -- to be a string literal that is not an operator. For details see -- Sinfo.CN.Change_Operator_Symbol_To_String_Literal. -- N_Operator_Symbol -- Sloc points to literal -- Chars (Name1) contains the Name_Id for the operator symbol -- Strval (Str3) Id of string value. This is used if the operator -- symbol turns out to be a normal string after all. -- Entity (Node4-Sem) -- Associated_Node (Node4-Sem) -- Has_Private_View (Flag11-Sem) set in generic units. -- Etype (Node5-Sem) -- Note: the Strval field may be set to No_String for generated -- operator symbols that are known not to be string literals -- semantically. ----------------------------------- -- 6.1 Defining Operator Symbol -- ----------------------------------- -- DEFINING_OPERATOR_SYMBOL ::= OPERATOR_SYMBOL -- A defining operator symbol is an entity, which has additional -- fields depending on the setting of the Ekind field. These -- additional fields are defined (and access subprograms declared) -- in package Einfo. -- Note: N_Defining_Operator_Symbol is an extended node whose fields -- are deliberately layed out to match the layout of fields in an -- ordinary N_Operator_Symbol node allowing for easy alteration of -- an operator symbol node into a defining operator symbol node. -- See Sinfo.CN.Change_Operator_Symbol_To_Defining_Operator_Symbol -- for further details. -- N_Defining_Operator_Symbol -- Sloc points to literal -- Chars (Name1) contains the Name_Id for the operator symbol -- Next_Entity (Node2-Sem) -- Scope (Node3-Sem) -- Etype (Node5-Sem) ---------------------------- -- 6.1 Parameter Profile -- ---------------------------- -- PARAMETER_PROFILE ::= [FORMAL_PART] --------------------------------------- -- 6.1 Parameter and Result Profile -- --------------------------------------- -- PARAMETER_AND_RESULT_PROFILE ::= [FORMAL_PART] return SUBTYPE_MARK -- There is no explicit node in the tree for a parameter and result -- profile. Instead the information appears directly in the parent. ---------------------- -- 6.1 Formal part -- ---------------------- -- FORMAL_PART ::= -- (PARAMETER_SPECIFICATION {; PARAMETER_SPECIFICATION}) ---------------------------------- -- 6.1 Parameter specification -- ---------------------------------- -- PARAMETER_SPECIFICATION ::= -- DEFINING_IDENTIFIER_LIST : MODE [NULL_EXCLUSION] SUBTYPE_MARK -- [:= DEFAULT_EXPRESSION] -- | DEFINING_IDENTIFIER_LIST : ACCESS_DEFINITION -- [:= DEFAULT_EXPRESSION] -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive specifications were given with -- identical type definition and expression components. To simplify -- semantic processing, the parser represents a multiple declaration -- case as a sequence of single Specifications, using the More_Ids and -- Prev_Ids flags to preserve the original source form as described -- in the section on "Handling of Defining Identifier Lists". -- N_Parameter_Specification -- Sloc points to first identifier -- Defining_Identifier (Node1) -- In_Present (Flag15) -- Out_Present (Flag17) -- Null_Exclusion_Present (Flag9) (set to False if not present) -- Parameter_Type (Node2) subtype mark or access definition -- Expression (Node3) (set to Empty if no default expression present) -- Do_Accessibility_Check (Flag13-Sem) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) -- Default_Expression (Node5-Sem) --------------- -- 6.1 Mode -- --------------- -- MODE ::= [in] | in out | out -- There is no explicit node in the tree for the Mode. Instead the -- In_Present and Out_Present flags are set in the parent node to -- record the presence of keywords specifying the mode. -------------------------- -- 6.3 Subprogram Body -- -------------------------- -- SUBPROGRAM_BODY ::= -- SUBPROGRAM_SPECIFICATION is -- DECLARATIVE_PART -- begin -- HANDLED_SEQUENCE_OF_STATEMENTS -- end [DESIGNATOR]; -- N_Subprogram_Body -- Sloc points to FUNCTION or PROCEDURE -- Specification (Node1) -- Declarations (List2) -- Handled_Statement_Sequence (Node4) -- Activation_Chain_Entity (Node3-Sem) -- Corresponding_Spec (Node5-Sem) -- Acts_As_Spec (Flag4-Sem) -- Bad_Is_Detected (Flag15) used only by parser -- Do_Storage_Check (Flag17-Sem) -- Has_Priority_Pragma (Flag6-Sem) -- Is_Protected_Subprogram_Body (Flag7-Sem) -- Is_Task_Master (Flag5-Sem) -- Was_Originally_Stub (Flag13-Sem) ----------------------------------- -- 6.4 Procedure Call Statement -- ----------------------------------- -- PROCEDURE_CALL_STATEMENT ::= -- procedure_NAME; | procedure_PREFIX ACTUAL_PARAMETER_PART; -- Note: the reason that a procedure call has expression fields is -- that it semantically resembles an expression, e.g. overloading is -- allowed and a type is concocted for semantic processing purposes. -- Certain of these fields, such as Parens are not relevant, but it -- is easier to just supply all of them together! -- N_Procedure_Call_Statement -- Sloc points to first token of name or prefix -- Name (Node2) stores name or prefix -- Parameter_Associations (List3) (set to No_List if no -- actual parameter part) -- First_Named_Actual (Node4-Sem) -- Controlling_Argument (Node1-Sem) (set to Empty if not dispatching) -- Do_Tag_Check (Flag13-Sem) -- No_Elaboration_Check (Flag14-Sem) -- Parameter_List_Truncated (Flag17-Sem) -- ABE_Is_Certain (Flag18-Sem) -- plus fields for expression -- If any IN parameter requires a range check, then the corresponding -- argument expression has the Do_Range_Check flag set, and the range -- check is done against the formal type. Note that this argument -- expression may appear directly in the Parameter_Associations list, -- or may be a descendent of an N_Parameter_Association node that -- appears in this list. ------------------------ -- 6.4 Function Call -- ------------------------ -- FUNCTION_CALL ::= -- function_NAME | function_PREFIX ACTUAL_PARAMETER_PART -- Note: the parser may generate an indexed component node or simply -- a name node instead of a function call node. The semantic pass must -- correct this misidentification. -- N_Function_Call -- Sloc points to first token of name or prefix -- Name (Node2) stores name or prefix -- Parameter_Associations (List3) (set to No_List if no -- actual parameter part) -- First_Named_Actual (Node4-Sem) -- Controlling_Argument (Node1-Sem) (set to Empty if not dispatching) -- Do_Tag_Check (Flag13-Sem) -- No_Elaboration_Check (Flag14-Sem) -- Parameter_List_Truncated (Flag17-Sem) -- ABE_Is_Certain (Flag18-Sem) -- plus fields for expression -------------------------------- -- 6.4 Actual Parameter Part -- -------------------------------- -- ACTUAL_PARAMETER_PART ::= -- (PARAMETER_ASSOCIATION {,PARAMETER_ASSOCIATION}) -------------------------------- -- 6.4 Parameter Association -- -------------------------------- -- PARAMETER_ASSOCIATION ::= -- [formal_parameter_SELECTOR_NAME =>] EXPLICIT_ACTUAL_PARAMETER -- Note: the N_Parameter_Association node is built only if a formal -- parameter selector name is present, otherwise the parameter -- association appears in the tree simply as the node for the -- explicit actual parameter. -- N_Parameter_Association -- Sloc points to formal parameter -- Selector_Name (Node2) (always non-Empty, since this node is -- only used if a formal parameter selector name is present) -- Explicit_Actual_Parameter (Node3) -- Next_Named_Actual (Node4-Sem) --------------------------- -- 6.4 Actual Parameter -- --------------------------- -- EXPLICIT_ACTUAL_PARAMETER ::= EXPRESSION | variable_NAME --------------------------- -- 6.5 Return Statement -- --------------------------- -- RETURN_STATEMENT ::= return [EXPRESSION]; -- N_Return_Statement -- Sloc points to RETURN -- Expression (Node3) (set to Empty if no expression present) -- Storage_Pool (Node1-Sem) -- Procedure_To_Call (Node4-Sem) -- Do_Tag_Check (Flag13-Sem) -- Return_Type (Node2-Sem) -- By_Ref (Flag5-Sem) -- Note: if a range check is required, then Do_Range_Check is set -- on the Expression. The range check is against Return_Type. ------------------------------ -- 7.1 Package Declaration -- ------------------------------ -- PACKAGE_DECLARATION ::= PACKAGE_SPECIFICATION; -- Note: the activation chain entity for a package spec is used for -- all tasks declared in the package spec, or in the package body. -- N_Package_Declaration -- Sloc points to PACKAGE -- Specification (Node1) -- Corresponding_Body (Node5-Sem) -- Parent_Spec (Node4-Sem) -- Activation_Chain_Entity (Node3-Sem) -------------------------------- -- 7.1 Package Specification -- -------------------------------- -- PACKAGE_SPECIFICATION ::= -- package DEFINING_PROGRAM_UNIT_NAME is -- {BASIC_DECLARATIVE_ITEM} -- [private -- {BASIC_DECLARATIVE_ITEM}] -- end [[PARENT_UNIT_NAME .] IDENTIFIER] -- N_Package_Specification -- Sloc points to PACKAGE -- Defining_Unit_Name (Node1) -- Visible_Declarations (List2) -- Private_Declarations (List3) (set to No_List if no private -- part present) -- End_Label (Node4) -- Generic_Parent (Node5-Sem) -- Limited_View_Installed (Flag18-Sem) ----------------------- -- 7.1 Package Body -- ----------------------- -- PACKAGE_BODY ::= -- package body DEFINING_PROGRAM_UNIT_NAME is -- DECLARATIVE_PART -- [begin -- HANDLED_SEQUENCE_OF_STATEMENTS] -- end [[PARENT_UNIT_NAME .] IDENTIFIER]; -- N_Package_Body -- Sloc points to PACKAGE -- Defining_Unit_Name (Node1) -- Declarations (List2) -- Handled_Statement_Sequence (Node4) (set to Empty if no HSS present) -- Corresponding_Spec (Node5-Sem) -- Was_Originally_Stub (Flag13-Sem) -- Note: if a source level package does not contain a handled sequence -- of statements, then the parser supplies a dummy one with a null -- sequence of statements. Comes_From_Source will be False in this -- constructed sequence. The reason we need this is for the End_Label -- field in the HSS. ----------------------------------- -- 7.4 Private Type Declaration -- ----------------------------------- -- PRIVATE_TYPE_DECLARATION ::= -- type DEFINING_IDENTIFIER [DISCRIMINANT_PART] -- is [[abstract] tagged] [limited] private; -- Note: TAGGED is not permitted in Ada 83 mode -- N_Private_Type_Declaration -- Sloc points to TYPE -- Defining_Identifier (Node1) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part) -- Unknown_Discriminants_Present (Flag13) set if (<>) discriminant -- Abstract_Present (Flag4) -- Tagged_Present (Flag15) -- Limited_Present (Flag17) ---------------------------------------- -- 7.4 Private Extension Declaration -- ---------------------------------------- -- PRIVATE_EXTENSION_DECLARATION ::= -- type DEFINING_IDENTIFIER [DISCRIMINANT_PART] is -- [abstract] new ancestor_SUBTYPE_INDICATION with private; -- Note: private extension declarations are not allowed in Ada 83 mode -- N_Private_Extension_Declaration -- Sloc points to TYPE -- Defining_Identifier (Node1) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part) -- Unknown_Discriminants_Present (Flag13) set if (<>) discriminant -- Abstract_Present (Flag4) -- Subtype_Indication (Node5) --------------------- -- 8.4 Use Clause -- --------------------- -- USE_CLAUSE ::= USE_PACKAGE_CLAUSE | USE_TYPE_CLAUSE ----------------------------- -- 8.4 Use Package Clause -- ----------------------------- -- USE_PACKAGE_CLAUSE ::= use package_NAME {, package_NAME}; -- N_Use_Package_Clause -- Sloc points to USE -- Names (List2) -- Next_Use_Clause (Node3-Sem) -- Hidden_By_Use_Clause (Elist4-Sem) -------------------------- -- 8.4 Use Type Clause -- -------------------------- -- USE_TYPE_CLAUSE ::= use type SUBTYPE_MARK {, SUBTYPE_MARK}; -- Note: use type clause is not permitted in Ada 83 mode -- N_Use_Type_Clause -- Sloc points to USE -- Subtype_Marks (List2) -- Next_Use_Clause (Node3-Sem) -- Hidden_By_Use_Clause (Elist4-Sem) ------------------------------- -- 8.5 Renaming Declaration -- ------------------------------- -- RENAMING_DECLARATION ::= -- OBJECT_RENAMING_DECLARATION -- | EXCEPTION_RENAMING_DECLARATION -- | PACKAGE_RENAMING_DECLARATION -- | SUBPROGRAM_RENAMING_DECLARATION -- | GENERIC_RENAMING_DECLARATION -------------------------------------- -- 8.5 Object Renaming Declaration -- -------------------------------------- -- OBJECT_RENAMING_DECLARATION ::= -- DEFINING_IDENTIFIER : SUBTYPE_MARK renames object_NAME; -- | DEFINING_IDENTIFIER : ACCESS_DEFINITION renames object_NAME; -- Note: Access_Definition is an optional field that gives support to -- Ada 2005 (AI-230). The parser generates nodes that have either the -- Subtype_Indication field or else the Access_Definition field. -- N_Object_Renaming_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Subtype_Mark (Node4) (set to Empty if not present) -- Access_Definition (Node3) (set to Empty if not present) -- Name (Node2) -- Corresponding_Generic_Association (Node5-Sem) ----------------------------------------- -- 8.5 Exception Renaming Declaration -- ----------------------------------------- -- EXCEPTION_RENAMING_DECLARATION ::= -- DEFINING_IDENTIFIER : exception renames exception_NAME; -- N_Exception_Renaming_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- Name (Node2) --------------------------------------- -- 8.5 Package Renaming Declaration -- --------------------------------------- -- PACKAGE_RENAMING_DECLARATION ::= -- package DEFINING_PROGRAM_UNIT_NAME renames package_NAME; -- N_Package_Renaming_Declaration -- Sloc points to PACKAGE -- Defining_Unit_Name (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) ------------------------------------------ -- 8.5 Subprogram Renaming Declaration -- ------------------------------------------ -- SUBPROGRAM_RENAMING_DECLARATION ::= -- SUBPROGRAM_SPECIFICATION renames callable_entity_NAME; -- N_Subprogram_Renaming_Declaration -- Sloc points to RENAMES -- Specification (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) -- Corresponding_Spec (Node5-Sem) -- Corresponding_Formal_Spec (Node3-Sem) -- From_Default (Flag6-Sem) ----------------------------------------- -- 8.5.5 Generic Renaming Declaration -- ----------------------------------------- -- GENERIC_RENAMING_DECLARATION ::= -- generic package DEFINING_PROGRAM_UNIT_NAME -- renames generic_package_NAME -- | generic procedure DEFINING_PROGRAM_UNIT_NAME -- renames generic_procedure_NAME -- | generic function DEFINING_PROGRAM_UNIT_NAME -- renames generic_function_NAME -- N_Generic_Package_Renaming_Declaration -- Sloc points to GENERIC -- Defining_Unit_Name (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) -- N_Generic_Procedure_Renaming_Declaration -- Sloc points to GENERIC -- Defining_Unit_Name (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) -- N_Generic_Function_Renaming_Declaration -- Sloc points to GENERIC -- Defining_Unit_Name (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) -------------------------------- -- 9.1 Task Type Declaration -- -------------------------------- -- TASK_TYPE_DECLARATION ::= -- task type DEFINING_IDENTIFIER [KNOWN_DISCRIMINANT_PART] -- [is TASK_DEFINITITION]; -- N_Task_Type_Declaration -- Sloc points to TASK -- Defining_Identifier (Node1) -- Task_Body_Procedure (Node2-Sem) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part) -- Task_Definition (Node3) (set to Empty if not present) -- Corresponding_Body (Node5-Sem) ---------------------------------- -- 9.1 Single Task Declaration -- ---------------------------------- -- SINGLE_TASK_DECLARATION ::= -- task DEFINING_IDENTIFIER [is TASK_DEFINITION]; -- N_Single_Task_Declaration -- Sloc points to TASK -- Defining_Identifier (Node1) -- Task_Definition (Node3) (set to Empty if not present) -------------------------- -- 9.1 Task Definition -- -------------------------- -- TASK_DEFINITION ::= -- {TASK_ITEM} -- [private -- {TASK_ITEM}] -- end [task_IDENTIFIER] -- Note: as a result of semantic analysis, the list of task items can -- include implicit type declarations resulting from entry families. -- N_Task_Definition -- Sloc points to first token of task definition -- Visible_Declarations (List2) -- Private_Declarations (List3) (set to No_List if no private part) -- End_Label (Node4) -- Has_Priority_Pragma (Flag6-Sem) -- Has_Storage_Size_Pragma (Flag5-Sem) -- Has_Task_Info_Pragma (Flag7-Sem) -- Has_Task_Name_Pragma (Flag8-Sem) -------------------- -- 9.1 Task Item -- -------------------- -- TASK_ITEM ::= ENTRY_DECLARATION | REPRESENTATION_CLAUSE -------------------- -- 9.1 Task Body -- -------------------- -- TASK_BODY ::= -- task body task_DEFINING_IDENTIFIER is -- DECLARATIVE_PART -- begin -- HANDLED_SEQUENCE_OF_STATEMENTS -- end [task_IDENTIFIER]; -- Gigi restriction: This node never appears. -- N_Task_Body -- Sloc points to TASK -- Defining_Identifier (Node1) -- Declarations (List2) -- Handled_Statement_Sequence (Node4) -- Is_Task_Master (Flag5-Sem) -- Activation_Chain_Entity (Node3-Sem) -- Corresponding_Spec (Node5-Sem) -- Was_Originally_Stub (Flag13-Sem) ------------------------------------- -- 9.4 Protected Type Declaration -- ------------------------------------- -- PROTECTED_TYPE_DECLARATION ::= -- protected type DEFINING_IDENTIFIER [KNOWN_DISCRIMINANT_PART] -- is PROTECTED_DEFINITION; -- Note: protected type declarations are not permitted in Ada 83 mode -- N_Protected_Type_Declaration -- Sloc points to PROTECTED -- Defining_Identifier (Node1) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part) -- Protected_Definition (Node3) -- Corresponding_Body (Node5-Sem) --------------------------------------- -- 9.4 Single Protected Declaration -- --------------------------------------- -- SINGLE_PROTECTED_DECLARATION ::= -- protected DEFINING_IDENTIFIER is PROTECTED_DEFINITION; -- Note: single protected declarations are not allowed in Ada 83 mode -- N_Single_Protected_Declaration -- Sloc points to PROTECTED -- Defining_Identifier (Node1) -- Protected_Definition (Node3) ------------------------------- -- 9.4 Protected Definition -- ------------------------------- -- PROTECTED_DEFINITION ::= -- {PROTECTED_OPERATION_DECLARATION} -- [private -- {PROTECTED_ELEMENT_DECLARATION}] -- end [protected_IDENTIFIER] -- N_Protected_Definition -- Sloc points to first token of protected definition -- Visible_Declarations (List2) -- Private_Declarations (List3) (set to No_List if no private part) -- End_Label (Node4) -- Has_Priority_Pragma (Flag6-Sem) ------------------------------------------ -- 9.4 Protected Operation Declaration -- ------------------------------------------ -- PROTECTED_OPERATION_DECLARATION ::= -- SUBPROGRAM_DECLARATION -- | ENTRY_DECLARATION -- | REPRESENTATION_CLAUSE ---------------------------------------- -- 9.4 Protected Element Declaration -- ---------------------------------------- -- PROTECTED_ELEMENT_DECLARATION ::= -- PROTECTED_OPERATION_DECLARATION | COMPONENT_DECLARATION ------------------------- -- 9.4 Protected Body -- ------------------------- -- PROTECTED_BODY ::= -- protected body DEFINING_IDENTIFIER is -- {PROTECTED_OPERATION_ITEM} -- end [protected_IDENTIFIER]; -- Note: protected bodies are not allowed in Ada 83 mode -- Gigi restriction: This node never appears. -- N_Protected_Body -- Sloc points to PROTECTED -- Defining_Identifier (Node1) -- Declarations (List2) protected operation items (and pragmas) -- End_Label (Node4) -- Corresponding_Spec (Node5-Sem) -- Was_Originally_Stub (Flag13-Sem) ----------------------------------- -- 9.4 Protected Operation Item -- ----------------------------------- -- PROTECTED_OPERATION_ITEM ::= -- SUBPROGRAM_DECLARATION -- | SUBPROGRAM_BODY -- | ENTRY_BODY -- | REPRESENTATION_CLAUSE ------------------------------ -- 9.5.2 Entry Declaration -- ------------------------------ -- ENTRY_DECLARATION ::= -- entry DEFINING_IDENTIFIER -- [(DISCRETE_SUBTYPE_DEFINITION)] PARAMETER_PROFILE; -- N_Entry_Declaration -- Sloc points to ENTRY -- Defining_Identifier (Node1) -- Discrete_Subtype_Definition (Node4) (set to Empty if not present) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Corresponding_Body (Node5-Sem) ----------------------------- -- 9.5.2 Accept statement -- ----------------------------- -- ACCEPT_STATEMENT ::= -- accept entry_DIRECT_NAME -- [(ENTRY_INDEX)] PARAMETER_PROFILE [do -- HANDLED_SEQUENCE_OF_STATEMENTS -- end [entry_IDENTIFIER]]; -- Gigi restriction: This node never appears. -- Note: there are no explicit declarations allowed in an accept -- statement. However, the implicit declarations for any statement -- identifiers (labels and block/loop identifiers) are declarations -- that belong logically to the accept statement, and that is why -- there is a Declarations field in this node. -- N_Accept_Statement -- Sloc points to ACCEPT -- Entry_Direct_Name (Node1) -- Entry_Index (Node5) (set to Empty if not present) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Handled_Statement_Sequence (Node4) -- Declarations (List2) (set to No_List if no declarations) ------------------------ -- 9.5.2 Entry Index -- ------------------------ -- ENTRY_INDEX ::= EXPRESSION ----------------------- -- 9.5.2 Entry Body -- ----------------------- -- ENTRY_BODY ::= -- entry DEFINING_IDENTIFIER ENTRY_BODY_FORMAL_PART ENTRY_BARRIER is -- DECLARATIVE_PART -- begin -- HANDLED_SEQUENCE_OF_STATEMENTS -- end [entry_IDENTIFIER]; -- ENTRY_BARRIER ::= when CONDITION -- Note: we store the CONDITION of the ENTRY_BARRIER in the node for -- the ENTRY_BODY_FORMAL_PART to avoid the N_Entry_Body node getting -- too full (it would otherwise have too many fields) -- Gigi restriction: This node never appears. -- N_Entry_Body -- Sloc points to ENTRY -- Defining_Identifier (Node1) -- Entry_Body_Formal_Part (Node5) -- Declarations (List2) -- Handled_Statement_Sequence (Node4) -- Activation_Chain_Entity (Node3-Sem) ----------------------------------- -- 9.5.2 Entry Body Formal Part -- ----------------------------------- -- ENTRY_BODY_FORMAL_PART ::= -- [(ENTRY_INDEX_SPECIFICATION)] PARAMETER_PROFILE -- Note that an entry body formal part node is present even if it is -- empty. This reflects the grammar, in which it is the components of -- the entry body formal part that are optional, not the entry body -- formal part itself. Also this means that the barrier condition -- always has somewhere to be stored. -- Gigi restriction: This node never appears. -- N_Entry_Body_Formal_Part -- Sloc points to first token -- Entry_Index_Specification (Node4) (set to Empty if not present) -- Parameter_Specifications (List3) (set to No_List if no formal part) -- Condition (Node1) from entry barrier of entry body -------------------------- -- 9.5.2 Entry Barrier -- -------------------------- -- ENTRY_BARRIER ::= when CONDITION -------------------------------------- -- 9.5.2 Entry Index Specification -- -------------------------------------- -- ENTRY_INDEX_SPECIFICATION ::= -- for DEFINING_IDENTIFIER in DISCRETE_SUBTYPE_DEFINITION -- Gigi restriction: This node never appears. -- N_Entry_Index_Specification -- Sloc points to FOR -- Defining_Identifier (Node1) -- Discrete_Subtype_Definition (Node4) --------------------------------- -- 9.5.3 Entry Call Statement -- --------------------------------- -- ENTRY_CALL_STATEMENT ::= entry_NAME [ACTUAL_PARAMETER_PART]; -- The parser may generate a procedure call for this construct. The -- semantic pass must correct this misidentification where needed. -- Gigi restriction: This node never appears. -- N_Entry_Call_Statement -- Sloc points to first token of name -- Name (Node2) -- Parameter_Associations (List3) (set to No_List if no -- actual parameter part) -- First_Named_Actual (Node4-Sem) ------------------------------ -- 9.5.4 Requeue Statement -- ------------------------------ -- REQUEUE_STATEMENT ::= requeue entry_NAME [with abort]; -- Note: requeue statements are not permitted in Ada 83 mode -- Gigi restriction: This node never appears. -- N_Requeue_Statement -- Sloc points to REQUEUE -- Name (Node2) -- Abort_Present (Flag15) -------------------------- -- 9.6 Delay Statement -- -------------------------- -- DELAY_STATEMENT ::= -- DELAY_UNTIL_STATEMENT -- | DELAY_RELATIVE_STATEMENT -------------------------------- -- 9.6 Delay Until Statement -- -------------------------------- -- DELAY_UNTIL_STATEMENT ::= delay until delay_EXPRESSION; -- Note: delay until statements are not permitted in Ada 83 mode -- Gigi restriction: This node never appears. -- N_Delay_Until_Statement -- Sloc points to DELAY -- Expression (Node3) ----------------------------------- -- 9.6 Delay Relative Statement -- ----------------------------------- -- DELAY_RELATIVE_STATEMENT ::= delay delay_EXPRESSION; -- Gigi restriction: This node never appears. -- N_Delay_Relative_Statement -- Sloc points to DELAY -- Expression (Node3) --------------------------- -- 9.7 Select Statement -- --------------------------- -- SELECT_STATEMENT ::= -- SELECTIVE_ACCEPT -- | TIMED_ENTRY_CALL -- | CONDITIONAL_ENTRY_CALL -- | ASYNCHRONOUS_SELECT ----------------------------- -- 9.7.1 Selective Accept -- ----------------------------- -- SELECTIVE_ACCEPT ::= -- select -- [GUARD] -- SELECT_ALTERNATIVE -- {or -- [GUARD] -- SELECT_ALTERNATIVE} -- [else -- SEQUENCE_OF_STATEMENTS] -- end select; -- Gigi restriction: This node never appears. -- Note: the guard expression, if present, appears in the node for -- the select alternative. -- N_Selective_Accept -- Sloc points to SELECT -- Select_Alternatives (List1) -- Else_Statements (List4) (set to No_List if no else part) ------------------ -- 9.7.1 Guard -- ------------------ -- GUARD ::= when CONDITION => -- As noted above, the CONDITION that is part of a GUARD is included -- in the node for the select alernative for convenience. ------------------------------- -- 9.7.1 Select Alternative -- ------------------------------- -- SELECT_ALTERNATIVE ::= -- ACCEPT_ALTERNATIVE -- | DELAY_ALTERNATIVE -- | TERMINATE_ALTERNATIVE ------------------------------- -- 9.7.1 Accept Alternative -- ------------------------------- -- ACCEPT_ALTERNATIVE ::= -- ACCEPT_STATEMENT [SEQUENCE_OF_STATEMENTS] -- Gigi restriction: This node never appears. -- N_Accept_Alternative -- Sloc points to ACCEPT -- Accept_Statement (Node2) -- Condition (Node1) from the guard (set to Empty if no guard present) -- Statements (List3) (set to Empty_List if no statements) -- Pragmas_Before (List4) pragmas before alt (set to No_List if none) -- Accept_Handler_Records (List5-Sem) ------------------------------ -- 9.7.1 Delay Alternative -- ------------------------------ -- DELAY_ALTERNATIVE ::= -- DELAY_STATEMENT [SEQUENCE_OF_STATEMENTS] -- Gigi restriction: This node never appears. -- N_Delay_Alternative -- Sloc points to DELAY -- Delay_Statement (Node2) -- Condition (Node1) from the guard (set to Empty if no guard present) -- Statements (List3) (set to Empty_List if no statements) -- Pragmas_Before (List4) pragmas before alt (set to No_List if none) ---------------------------------- -- 9.7.1 Terminate Alternative -- ---------------------------------- -- TERMINATE_ALTERNATIVE ::= terminate; -- Gigi restriction: This node never appears. -- N_Terminate_Alternative -- Sloc points to TERMINATE -- Condition (Node1) from the guard (set to Empty if no guard present) -- Pragmas_Before (List4) pragmas before alt (set to No_List if none) -- Pragmas_After (List5) pragmas after alt (set to No_List if none) ----------------------------- -- 9.7.2 Timed Entry Call -- ----------------------------- -- TIMED_ENTRY_CALL ::= -- select -- ENTRY_CALL_ALTERNATIVE -- or -- DELAY_ALTERNATIVE -- end select; -- Gigi restriction: This node never appears. -- N_Timed_Entry_Call -- Sloc points to SELECT -- Entry_Call_Alternative (Node1) -- Delay_Alternative (Node4) ----------------------------------- -- 9.7.2 Entry Call Alternative -- ----------------------------------- -- ENTRY_CALL_ALTERNATIVE ::= -- ENTRY_CALL_STATEMENT [SEQUENCE_OF_STATEMENTS] -- Gigi restriction: This node never appears. -- N_Entry_Call_Alternative -- Sloc points to first token of entry call statement -- Entry_Call_Statement (Node1) -- Statements (List3) (set to Empty_List if no statements) -- Pragmas_Before (List4) pragmas before alt (set to No_List if none) ----------------------------------- -- 9.7.3 Conditional Entry Call -- ----------------------------------- -- CONDITIONAL_ENTRY_CALL ::= -- select -- ENTRY_CALL_ALTERNATIVE -- else -- SEQUENCE_OF_STATEMENTS -- end select; -- Gigi restriction: This node never appears. -- N_Conditional_Entry_Call -- Sloc points to SELECT -- Entry_Call_Alternative (Node1) -- Else_Statements (List4) -------------------------------- -- 9.7.4 Asynchronous Select -- -------------------------------- -- ASYNCHRONOUS_SELECT ::= -- select -- TRIGGERING_ALTERNATIVE -- then abort -- ABORTABLE_PART -- end select; -- Note: asynchronous select is not permitted in Ada 83 mode -- Gigi restriction: This node never appears. -- N_Asynchronous_Select -- Sloc points to SELECT -- Triggering_Alternative (Node1) -- Abortable_Part (Node2) ----------------------------------- -- 9.7.4 Triggering Alternative -- ----------------------------------- -- TRIGGERING_ALTERNATIVE ::= -- TRIGGERING_STATEMENT [SEQUENCE_OF_STATEMENTS] -- Gigi restriction: This node never appears. -- N_Triggering_Alternative -- Sloc points to first token of triggering statement -- Triggering_Statement (Node1) -- Statements (List3) (set to Empty_List if no statements) -- Pragmas_Before (List4) pragmas before alt (set to No_List if none) --------------------------------- -- 9.7.4 Triggering Statement -- --------------------------------- -- TRIGGERING_STATEMENT ::= ENTRY_CALL_STATEMENT | DELAY_STATEMENT --------------------------- -- 9.7.4 Abortable Part -- --------------------------- -- ABORTABLE_PART ::= SEQUENCE_OF_STATEMENTS -- Gigi restriction: This node never appears. -- N_Abortable_Part -- Sloc points to ABORT -- Statements (List3) -------------------------- -- 9.8 Abort Statement -- -------------------------- -- ABORT_STATEMENT ::= abort task_NAME {, task_NAME}; -- Gigi restriction: This node never appears. -- N_Abort_Statement -- Sloc points to ABORT -- Names (List2) ------------------------- -- 10.1.1 Compilation -- ------------------------- -- COMPILATION ::= {COMPILATION_UNIT} -- There is no explicit node in the tree for a compilation, since in -- general the compiler is processing only a single compilation unit -- at a time. It is possible to parse multiple units in syntax check -- only mode, but they the trees are discarded in any case. ------------------------------ -- 10.1.1 Compilation Unit -- ------------------------------ -- COMPILATION_UNIT ::= -- CONTEXT_CLAUSE LIBRARY_ITEM -- | CONTEXT_CLAUSE SUBUNIT -- The N_Compilation_Unit node itself respresents the above syntax. -- However, there are two additional items not reflected in the above -- syntax. First we have the global declarations that are added by the -- code generator. These are outer level declarations (so they cannot -- be represented as being inside the units). An example is the wrapper -- subprograms that are created to do ABE checking. As always a list of -- declarations can contain actions as well (i.e. statements), and such -- statements are executed as part of the elaboration of the unit. Note -- that all such declarations are elaborated before the library unit. -- Similarly, certain actions need to be elaborated at the completion -- of elaboration of the library unit (notably the statement that sets -- the Boolean flag indicating that elaboration is complete). -- The third item not reflected in the syntax is pragmas that appear -- after the compilation unit. As always pragmas are a problem since -- they are not part of the formal syntax, but can be stuck into the -- source following a set of ad hoc rules, and we have to find an ad -- hoc way of sticking them into the tree. For pragmas that appear -- before the library unit, we just consider them to be part of the -- context clause, and pragmas can appear in the Context_Items list -- of the compilation unit. However, pragmas can also appear after -- the library item. -- To deal with all these problems, we create an auxiliary node for -- a compilation unit, referenced from the N_Compilation_Unit node -- that contains these three items. -- N_Compilation_Unit -- Sloc points to first token of defining unit name -- Library_Unit (Node4-Sem) corresponding/parent spec/body -- Context_Items (List1) context items and pragmas preceding unit -- Private_Present (Flag15) set if library unit has private keyword -- Unit (Node2) library item or subunit -- Aux_Decls_Node (Node5) points to the N_Compilation_Unit_Aux node -- Has_No_Elaboration_Code (Flag17-Sem) -- Body_Required (Flag13-Sem) set for spec if body is required -- Acts_As_Spec (Flag4-Sem) flag for subprogram body with no spec -- First_Inlined_Subprogram (Node3-Sem) -- N_Compilation_Unit_Aux -- Sloc is a copy of the Sloc from the N_Compilation_Unit node -- Declarations (List2) (set to No_List if no global declarations) -- Actions (List1) (set to No_List if no actions) -- Pragmas_After (List5) pragmas after unit (set to No_List if none) -- Config_Pragmas (List4) config pragmas (set to Empty_List if none) -------------------------- -- 10.1.1 Library Item -- -------------------------- -- LIBRARY_ITEM ::= -- [private] LIBRARY_UNIT_DECLARATION -- | LIBRARY_UNIT_BODY -- | [private] LIBRARY_UNIT_RENAMING_DECLARATION -- Note: PRIVATE is not allowed in Ada 83 mode -- There is no explicit node in the tree for library item, instead -- the declaration or body, and the flag for private if present, -- appear in the N_Compilation_Unit clause. ---------------------------------------- -- 10.1.1 Library Unit Declararation -- ---------------------------------------- -- LIBRARY_UNIT_DECLARATION ::= -- SUBPROGRAM_DECLARATION | PACKAGE_DECLARATION -- | GENERIC_DECLARATION | GENERIC_INSTANTIATION ------------------------------------------------- -- 10.1.1 Library Unit Renaming Declararation -- ------------------------------------------------- -- LIBRARY_UNIT_RENAMING_DECLARATION ::= -- PACKAGE_RENAMING_DECLARATION -- | GENERIC_RENAMING_DECLARATION -- | SUBPROGRAM_RENAMING_DECLARATION ------------------------------- -- 10.1.1 Library unit body -- ------------------------------- -- LIBRARY_UNIT_BODY ::= SUBPROGRAM_BODY | PACKAGE_BODY ------------------------------ -- 10.1.1 Parent Unit Name -- ------------------------------ -- PARENT_UNIT_NAME ::= NAME ---------------------------- -- 10.1.2 Context clause -- ---------------------------- -- CONTEXT_CLAUSE ::= {CONTEXT_ITEM} -- The context clause can include pragmas, and any pragmas that appear -- before the context clause proper (i.e. all configuration pragmas, -- also appear at the front of this list). -------------------------- -- 10.1.2 Context_Item -- -------------------------- -- CONTEXT_ITEM ::= WITH_CLAUSE | USE_CLAUSE | WITH_TYPE_CLAUSE ------------------------- -- 10.1.2 With clause -- ------------------------- -- WITH_CLAUSE ::= -- with library_unit_NAME {,library_unit_NAME}; -- A separate With clause is built for each name, so that we have -- a Corresponding_Spec field for each with'ed spec. The flags -- First_Name and Last_Name are used to reconstruct the exact -- source form. When a list of names appears in one with clause, -- the first name in the list has First_Name set, and the last -- has Last_Name set. If the with clause has only one name, then -- both of the flags First_Name and Last_Name are set in this name. -- Note: in the case of implicit with's that are installed by the -- Rtsfind routine, Implicit_With is set, and the Sloc is typically -- set to Standard_Location, but it is incorrect to test the Sloc -- to find out if a with clause is implicit, test the flag instead. -- N_With_Clause -- Sloc points to first token of library unit name -- Name (Node2) -- Library_Unit (Node4-Sem) -- Corresponding_Spec (Node5-Sem) -- First_Name (Flag5) (set to True if first name or only one name) -- Last_Name (Flag6) (set to True if last name or only one name) -- Context_Installed (Flag13-Sem) -- Elaborate_Present (Flag4-Sem) -- Elaborate_All_Present (Flag14-Sem) -- Private_Present (Flag15) set if with_clause has private keyword -- Implicit_With (Flag16-Sem) -- Limited_Present (Flag17) set if LIMITED is present -- Limited_View_Installed (Flag18-Sem) -- Unreferenced_In_Spec (Flag7-Sem) -- No_Entities_Ref_In_Spec (Flag8-Sem) -- Note: Limited_Present and Limited_View_Installed give support to -- Ada 2005 (AI-50217). -- Similarly, Private_Present gives support to AI-50262. ---------------------- -- With_Type clause -- ---------------------- -- This is a GNAT extension, used to implement mutually recursive -- types declared in different packages. -- WITH_TYPE_CLAUSE ::= -- with type type_NAME is access | with type type_NAME is tagged -- N_With_Type_Clause -- Sloc points to first token of type name -- Name (Node2) -- Tagged_Present (Flag15) --------------------- -- 10.2 Body stub -- --------------------- -- BODY_STUB ::= -- SUBPROGRAM_BODY_STUB -- | PACKAGE_BODY_STUB -- | TASK_BODY_STUB -- | PROTECTED_BODY_STUB ---------------------------------- -- 10.1.3 Subprogram Body Stub -- ---------------------------------- -- SUBPROGRAM_BODY_STUB ::= -- SUBPROGRAM_SPECIFICATION is separate; -- N_Subprogram_Body_Stub -- Sloc points to FUNCTION or PROCEDURE -- Specification (Node1) -- Library_Unit (Node4-Sem) points to the subunit -- Corresponding_Body (Node5-Sem) ------------------------------- -- 10.1.3 Package Body Stub -- ------------------------------- -- PACKAGE_BODY_STUB ::= -- package body DEFINING_IDENTIFIER is separate; -- N_Package_Body_Stub -- Sloc points to PACKAGE -- Defining_Identifier (Node1) -- Library_Unit (Node4-Sem) points to the subunit -- Corresponding_Body (Node5-Sem) ---------------------------- -- 10.1.3 Task Body Stub -- ---------------------------- -- TASK_BODY_STUB ::= -- task body DEFINING_IDENTIFIER is separate; -- N_Task_Body_Stub -- Sloc points to TASK -- Defining_Identifier (Node1) -- Library_Unit (Node4-Sem) points to the subunit -- Corresponding_Body (Node5-Sem) --------------------------------- -- 10.1.3 Protected Body Stub -- --------------------------------- -- PROTECTED_BODY_STUB ::= -- protected body DEFINING_IDENTIFIER is separate; -- Note: protected body stubs are not allowed in Ada 83 mode -- N_Protected_Body_Stub -- Sloc points to PROTECTED -- Defining_Identifier (Node1) -- Library_Unit (Node4-Sem) points to the subunit -- Corresponding_Body (Node5-Sem) --------------------- -- 10.1.3 Subunit -- --------------------- -- SUBUNIT ::= separate (PARENT_UNIT_NAME) PROPER_BODY -- N_Subunit -- Sloc points to SEPARATE -- Name (Node2) is the name of the parent unit -- Proper_Body (Node1) is the subunit body -- Corresponding_Stub (Node3-Sem) is the stub declaration for the unit. --------------------------------- -- 11.1 Exception Declaration -- --------------------------------- -- EXCEPTION_DECLARATION ::= DEFINING_IDENTIFIER_LIST : exception; -- For consistency with object declarations etc, the parser converts -- the case of multiple identifiers being declared to a series of -- declarations in which the expression is copied, using the More_Ids -- and Prev_Ids flags to remember the souce form as described in the -- section on "Handling of Defining Identifier Lists". -- N_Exception_Declaration -- Sloc points to EXCEPTION -- Defining_Identifier (Node1) -- Expression (Node3-Sem) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) ------------------------------------------ -- 11.2 Handled Sequence Of Statements -- ------------------------------------------ -- HANDLED_SEQUENCE_OF_STATEMENTS ::= -- SEQUENCE_OF_STATEMENTS -- [exception -- EXCEPTION_HANDLER -- {EXCEPTION_HANDLER}] -- [at end -- cleanup_procedure_call (param, param, param, ...);] -- The AT END phrase is a GNAT extension to provide for cleanups. It is -- used only internally currently, but is considered to be syntactic. -- At the moment, the only cleanup action allowed is a single call to -- a parameterless procedure, and the Identifier field of the node is -- the procedure to be called. Also there is a current restriction -- that exception handles and a cleanup cannot be present in the same -- frame, so at least one of Exception_Handlers or the Identifier must -- be missing. -- Actually, more accurately, this restriction applies to the original -- source program. In the expanded tree, if the At_End_Proc field is -- present, then there will also be an exception handler of the form: -- when all others => -- cleanup; -- raise; -- where cleanup is the procedure to be generated. The reason we do -- this is so that the front end can handle the necessary entries in -- the exception tables, and other exception handler actions required -- as part of the normal handling for exception handlers. -- The AT END cleanup handler protects only the sequence of statements -- (not the associated declarations of the parent), just like exception -- handlers. The big difference is that the cleanup procedure is called -- on either a normal or an abnormal exit from the statement sequence. -- Note: the list of Exception_Handlers can contain pragmas as well -- as actual handlers. In practice these pragmas can only occur at -- the start of the list, since any pragmas occurring later on will -- be included in the statement list of the corresponding handler. -- Note: although in the Ada syntax, the sequence of statements in -- a handled sequence of statements can only contain statements, we -- allow free mixing of declarations and statements in the resulting -- expanded tree. This is for example used to deal with the case of -- a cleanup procedure that must handle declarations as well as the -- statements of a block. -- N_Handled_Sequence_Of_Statements -- Sloc points to first token of first statement -- Statements (List3) -- End_Label (Node4) (set to Empty if expander generated) -- Exception_Handlers (List5) (set to No_List if none present) -- At_End_Proc (Node1) (set to Empty if no clean up procedure) -- First_Real_Statement (Node2-Sem) -- Zero_Cost_Handling (Flag5-Sem) -- Note: the parent always contains a Declarations field which contains -- declarations associated with the handled sequence of statements. This -- is true even in the case of an accept statement (see description of -- the N_Accept_Statement node). -- End_Label refers to the containing construct. ----------------------------- -- 11.2 Exception Handler -- ----------------------------- -- EXCEPTION_HANDLER ::= -- when [CHOICE_PARAMETER_SPECIFICATION :] -- EXCEPTION_CHOICE {| EXCEPTION_CHOICE} => -- SEQUENCE_OF_STATEMENTS -- Note: choice parameter specification is not allowed in Ada 83 mode -- N_Exception_Handler -- Sloc points to WHEN -- Choice_Parameter (Node2) (set to Empty if not present) -- Exception_Choices (List4) -- Statements (List3) -- Zero_Cost_Handling (Flag5-Sem) ------------------------------------------ -- 11.2 Choice parameter specification -- ------------------------------------------ -- CHOICE_PARAMETER_SPECIFICATION ::= DEFINING_IDENTIFIER ---------------------------- -- 11.2 Exception Choice -- ---------------------------- -- EXCEPTION_CHOICE ::= exception_NAME | others -- Except in the case of OTHERS, no explicit node appears in the tree -- for exception choice. Instead the exception name appears directly. -- An OTHERS choice is represented by a N_Others_Choice node (see -- section 3.8.1. -- Note: for the exception choice created for an at end handler, the -- exception choice is an N_Others_Choice node with All_Others set. --------------------------- -- 11.3 Raise Statement -- --------------------------- -- RAISE_STATEMENT ::= raise [exception_NAME]; -- N_Raise_Statement -- Sloc points to RAISE -- Name (Node2) (set to Empty if no exception name present) ------------------------------- -- 12.1 Generic Declaration -- ------------------------------- -- GENERIC_DECLARATION ::= -- GENERIC_SUBPROGRAM_DECLARATION | GENERIC_PACKAGE_DECLARATION ------------------------------------------ -- 12.1 Generic Subprogram Declaration -- ------------------------------------------ -- GENERIC_SUBPROGRAM_DECLARATION ::= -- GENERIC_FORMAL_PART SUBPROGRAM_SPECIFICATION; -- Note: Generic_Formal_Declarations can include pragmas -- N_Generic_Subprogram_Declaration -- Sloc points to GENERIC -- Specification (Node1) subprogram specification -- Corresponding_Body (Node5-Sem) -- Generic_Formal_Declarations (List2) from generic formal part -- Parent_Spec (Node4-Sem) --------------------------------------- -- 12.1 Generic Package Declaration -- --------------------------------------- -- GENERIC_PACKAGE_DECLARATION ::= -- GENERIC_FORMAL_PART PACKAGE_SPECIFICATION; -- Note: when we do generics right, the Activation_Chain_Entity entry -- for this node can be removed (since the expander won't see generic -- units any more)???. -- Note: Generic_Formal_Declarations can include pragmas -- N_Generic_Package_Declaration -- Sloc points to GENERIC -- Specification (Node1) package specification -- Corresponding_Body (Node5-Sem) -- Generic_Formal_Declarations (List2) from generic formal part -- Parent_Spec (Node4-Sem) -- Activation_Chain_Entity (Node3-Sem) ------------------------------- -- 12.1 Generic Formal Part -- ------------------------------- -- GENERIC_FORMAL_PART ::= -- generic {GENERIC_FORMAL_PARAMETER_DECLARATION | USE_CLAUSE} ------------------------------------------------ -- 12.1 Generic Formal Parameter Declaration -- ------------------------------------------------ -- GENERIC_FORMAL_PARAMETER_DECLARATION ::= -- FORMAL_OBJECT_DECLARATION -- | FORMAL_TYPE_DECLARATION -- | FORMAL_SUBPROGRAM_DECLARATION -- | FORMAL_PACKAGE_DECLARATION --------------------------------- -- 12.3 Generic Instantiation -- --------------------------------- -- GENERIC_INSTANTIATION ::= -- package DEFINING_PROGRAM_UNIT_NAME is -- new generic_package_NAME [GENERIC_ACTUAL_PART]; -- | procedure DEFINING_PROGRAM_UNIT_NAME is -- new generic_procedure_NAME [GENERIC_ACTUAL_PART]; -- | function DEFINING_DESIGNATOR is -- new generic_function_NAME [GENERIC_ACTUAL_PART]; -- N_Package_Instantiation -- Sloc points to PACKAGE -- Defining_Unit_Name (Node1) -- Name (Node2) -- Generic_Associations (List3) (set to No_List if no -- generic actual part) -- Parent_Spec (Node4-Sem) -- Instance_Spec (Node5-Sem) -- ABE_Is_Certain (Flag18-Sem) -- N_Procedure_Instantiation -- Sloc points to PROCEDURE -- Defining_Unit_Name (Node1) -- Name (Node2) -- Parent_Spec (Node4-Sem) -- Generic_Associations (List3) (set to No_List if no -- generic actual part) -- Instance_Spec (Node5-Sem) -- ABE_Is_Certain (Flag18-Sem) -- N_Function_Instantiation -- Sloc points to FUNCTION -- Defining_Unit_Name (Node1) -- Name (Node2) -- Generic_Associations (List3) (set to No_List if no -- generic actual part) -- Parent_Spec (Node4-Sem) -- Instance_Spec (Node5-Sem) -- ABE_Is_Certain (Flag18-Sem) ------------------------------ -- 12.3 Generic Actual Part -- ------------------------------ -- GENERIC_ACTUAL_PART ::= -- (GENERIC_ASSOCIATION {, GENERIC_ASSOCIATION}) ------------------------------- -- 12.3 Generic Association -- ------------------------------- -- GENERIC_ASSOCIATION ::= -- [generic_formal_parameter_SELECTOR_NAME =>] -- EXPLICIT_GENERIC_ACTUAL_PARAMETER -- Note: unlike the procedure call case, a generic association node -- is generated for every association, even if no formal is present. -- In this case the parser will leave the Selector_Name field set -- to Empty, to be filled in later by the semantic pass. -- N_Generic_Association -- Sloc points to first token of generic association -- Selector_Name (Node2) (set to Empty if no formal -- parameter selector name) -- Explicit_Generic_Actual_Parameter (Node1) --------------------------------------------- -- 12.3 Explicit Generic Actual Parameter -- --------------------------------------------- -- EXPLICIT_GENERIC_ACTUAL_PARAMETER ::= -- EXPRESSION | variable_NAME | subprogram_NAME -- | entry_NAME | SUBTYPE_MARK | package_instance_NAME ------------------------------------- -- 12.4 Formal Object Declaration -- ------------------------------------- -- FORMAL_OBJECT_DECLARATION ::= -- DEFINING_IDENTIFIER_LIST : -- MODE SUBTYPE_MARK [:= DEFAULT_EXPRESSION]; -- Although the syntax allows multiple identifiers in the list, the -- semantics is as though successive declarations were given with -- identical type definition and expression components. To simplify -- semantic processing, the parser represents a multiple declaration -- case as a sequence of single declarations, using the More_Ids and -- Prev_Ids flags to preserve the original source form as described -- in the section on "Handling of Defining Identifier Lists". -- N_Formal_Object_Declaration -- Sloc points to first identifier -- Defining_Identifier (Node1) -- In_Present (Flag15) -- Out_Present (Flag17) -- Subtype_Mark (Node4) -- Expression (Node3) (set to Empty if no default expression) -- More_Ids (Flag5) (set to False if no more identifiers in list) -- Prev_Ids (Flag6) (set to False if no previous identifiers in list) ----------------------------------- -- 12.5 Formal Type Declaration -- ----------------------------------- -- FORMAL_TYPE_DECLARATION ::= -- type DEFINING_IDENTIFIER [DISCRIMINANT_PART] -- is FORMAL_TYPE_DEFINITION; -- N_Formal_Type_Declaration -- Sloc points to TYPE -- Defining_Identifier (Node1) -- Formal_Type_Definition (Node3) -- Discriminant_Specifications (List4) (set to No_List if no -- discriminant part) -- Unknown_Discriminants_Present (Flag13) set if (<>) discriminant ---------------------------------- -- 12.5 Formal type definition -- ---------------------------------- -- FORMAL_TYPE_DEFINITION ::= -- FORMAL_PRIVATE_TYPE_DEFINITION -- | FORMAL_DERIVED_TYPE_DEFINITION -- | FORMAL_DISCRETE_TYPE_DEFINITION -- | FORMAL_SIGNED_INTEGER_TYPE_DEFINITION -- | FORMAL_MODULAR_TYPE_DEFINITION -- | FORMAL_FLOATING_POINT_DEFINITION -- | FORMAL_ORDINARY_FIXED_POINT_DEFINITION -- | FORMAL_DECIMAL_FIXED_POINT_DEFINITION -- | FORMAL_ARRAY_TYPE_DEFINITION -- | FORMAL_ACCESS_TYPE_DEFINITION --------------------------------------------- -- 12.5.1 Formal Private Type Definition -- --------------------------------------------- -- FORMAL_PRIVATE_TYPE_DEFINITION ::= -- [[abstract] tagged] [limited] private -- Note: TAGGED is not allowed in Ada 83 mode -- N_Formal_Private_Type_Definition -- Sloc points to PRIVATE -- Abstract_Present (Flag4) -- Tagged_Present (Flag15) -- Limited_Present (Flag17) -------------------------------------------- -- 12.5.1 Formal Derived Type Definition -- -------------------------------------------- -- FORMAL_DERIVED_TYPE_DEFINITION ::= -- [abstract] new SUBTYPE_MARK [with private] -- Note: this construct is not allowed in Ada 83 mode -- N_Formal_Derived_Type_Definition -- Sloc points to NEW -- Subtype_Mark (Node4) -- Private_Present (Flag15) -- Abstract_Present (Flag4) --------------------------------------------- -- 12.5.2 Formal Discrete Type Definition -- --------------------------------------------- -- FORMAL_DISCRETE_TYPE_DEFINITION ::= (<>) -- N_Formal_Discrete_Type_Definition -- Sloc points to ( --------------------------------------------------- -- 12.5.2 Formal Signed Integer Type Definition -- --------------------------------------------------- -- FORMAL_SIGNED_INTEGER_TYPE_DEFINITION ::= range <> -- N_Formal_Signed_Integer_Type_Definition -- Sloc points to RANGE -------------------------------------------- -- 12.5.2 Formal Modular Type Definition -- -------------------------------------------- -- FORMAL_MODULAR_TYPE_DEFINITION ::= mod <> -- N_Formal_Modular_Type_Definition -- Sloc points to MOD ---------------------------------------------- -- 12.5.2 Formal Floating Point Definition -- ---------------------------------------------- -- FORMAL_FLOATING_POINT_DEFINITION ::= digits <> -- N_Formal_Floating_Point_Definition -- Sloc points to DIGITS ---------------------------------------------------- -- 12.5.2 Formal Ordinary Fixed Point Definition -- ---------------------------------------------------- -- FORMAL_ORDINARY_FIXED_POINT_DEFINITION ::= delta <> -- N_Formal_Ordinary_Fixed_Point_Definition -- Sloc points to DELTA --------------------------------------------------- -- 12.5.2 Formal Decimal Fixed Point Definition -- --------------------------------------------------- -- FORMAL_DECIMAL_FIXED_POINT_DEFINITION ::= delta <> digits <> -- Note: formal decimal fixed point definition not allowed in Ada 83 -- N_Formal_Decimal_Fixed_Point_Definition -- Sloc points to DELTA ------------------------------------------ -- 12.5.3 Formal Array Type Definition -- ------------------------------------------ -- FORMAL_ARRAY_TYPE_DEFINITION ::= ARRAY_TYPE_DEFINITION ------------------------------------------- -- 12.5.4 Formal Access Type Definition -- ------------------------------------------- -- FORMAL_ACCESS_TYPE_DEFINITION ::= ACCESS_TYPE_DEFINITION ----------------------------------------- -- 12.6 Formal Subprogram Declaration -- ----------------------------------------- -- FORMAL_SUBPROGRAM_DECLARATION ::= -- FORMAL_CONCRETE_SUBPROGRAM_DECLARATION -- | FORMAL_ABSTRACT_SUBPROGRAM_DECLARATION -------------------------------------------------- -- 12.6 Formal Concrete Subprogram Declaration -- -------------------------------------------------- -- FORMAL_CONCRETE_SUBPROGRAM_DECLARATION ::= -- with SUBPROGRAM_SPECIFICATION [is SUBPROGRAM_DEFAULT]; -- N_Formal_Concrete_Subprogram_Declaration -- Sloc points to WITH -- Specification (Node1) -- Default_Name (Node2) (set to Empty if no subprogram default) -- Box_Present (Flag15) -- Note: if no subprogram default is present, then Name is set -- to Empty, and Box_Present is False. -------------------------------------------------- -- 12.6 Formal Abstract Subprogram Declaration -- -------------------------------------------------- -- FORMAL_ABSTRACT_SUBPROGRAM_DECLARATION ::= -- with SUBPROGRAM_SPECIFICATION is abstract [SUBPROGRAM_DEFAULT]; -- N_Formal_Abstract_Subprogram_Declaration -- Sloc points to WITH -- Specification (Node1) -- Default_Name (Node2) (set to Empty if no subprogram default) -- Box_Present (Flag15) -- Note: if no subprogram default is present, then Name is set -- to Empty, and Box_Present is False. ------------------------------ -- 12.6 Subprogram Default -- ------------------------------ -- SUBPROGRAM_DEFAULT ::= DEFAULT_NAME | <> -- There is no separate node in the tree for a subprogram default. -- Instead the parent (N_Formal_Concrete_Subprogram_Declaration -- or N_Formal_Abstract_Subprogram_Declaration) node contains the -- default name or box indication, as needed. ------------------------ -- 12.6 Default Name -- ------------------------ -- DEFAULT_NAME ::= NAME -------------------------------------- -- 12.7 Formal Package Declaration -- -------------------------------------- -- FORMAL_PACKAGE_DECLARATION ::= -- with package DEFINING_IDENTIFIER -- is new generic_package_NAME FORMAL_PACKAGE_ACTUAL_PART; -- Note: formal package declarations not allowed in Ada 83 mode -- N_Formal_Package_Declaration -- Sloc points to WITH -- Defining_Identifier (Node1) -- Name (Node2) -- Generic_Associations (List3) (set to No_List if (<>) case or -- empty generic actual part) -- Box_Present (Flag15) -- Instance_Spec (Node5-Sem) -- ABE_Is_Certain (Flag18-Sem) -------------------------------------- -- 12.7 Formal Package Actual Part -- -------------------------------------- -- FORMAL_PACKAGE_ACTUAL_PART ::= -- (<>) | [GENERIC_ACTUAL_PART] -- There is no explicit node in the tree for a formal package -- actual part. Instead the information appears in the parent node -- (i.e. the formal package declaration node itself). --------------------------------- -- 13.1 Representation clause -- --------------------------------- -- REPRESENTATION_CLAUSE ::= -- ATTRIBUTE_DEFINITION_CLAUSE -- | ENUMERATION_REPRESENTATION_CLAUSE -- | RECORD_REPRESENTATION_CLAUSE -- | AT_CLAUSE ---------------------- -- 13.1 Local Name -- ---------------------- -- LOCAL_NAME := -- DIRECT_NAME -- | DIRECT_NAME'ATTRIBUTE_DESIGNATOR -- | library_unit_NAME -- The construct DIRECT_NAME'ATTRIBUTE_DESIGNATOR appears in the tree -- as an attribute reference, which has essentially the same form. --------------------------------------- -- 13.3 Attribute definition clause -- --------------------------------------- -- ATTRIBUTE_DEFINITION_CLAUSE ::= -- for LOCAL_NAME'ATTRIBUTE_DESIGNATOR use EXPRESSION; -- | for LOCAL_NAME'ATTRIBUTE_DESIGNATOR use NAME; -- In Ada 83, the expression must be a simple expression and the -- local name must be a direct name. -- Note: the only attribute definition clause that is processed by -- gigi is an address clause. For all other cases, the information -- is extracted by the front end and either results in setting entity -- information, e.g. Esize for the Size clause, or in appropriate -- expansion actions (e.g. in the case of Storage_Size). -- For an address clause, Gigi constructs the appropriate addressing -- code. It also ensures that no aliasing optimizations are made -- for the object for which the address clause appears. -- Note: for an address clause used to achieve an overlay: -- A : Integer; -- B : Integer; -- for B'Address use A'Address; -- the above rule means that Gigi will ensure that no optimizations -- will be made for B that would violate the implementation advice -- of RM 13.3(19). However, this advice applies only to B and not -- to A, which seems unfortunate. The GNAT front end will mark the -- object A as volatile to also prevent unwanted optimization -- assumptions based on no aliasing being made for B. -- N_Attribute_Definition_Clause -- Sloc points to FOR -- Name (Node2) the local name -- Chars (Name1) the identifier name from the attribute designator -- Expression (Node3) the expression or name -- Next_Rep_Item (Node4-Sem) -- From_At_Mod (Flag4-Sem) -- Check_Address_Alignment (Flag11-Sem) --------------------------------------------- -- 13.4 Enumeration representation clause -- --------------------------------------------- -- ENUMERATION_REPRESENTATION_CLAUSE ::= -- for first_subtype_LOCAL_NAME use ENUMERATION_AGGREGATE; -- In Ada 83, the name must be a direct name -- N_Enumeration_Representation_Clause -- Sloc points to FOR -- Identifier (Node1) direct name -- Array_Aggregate (Node3) -- Next_Rep_Item (Node4-Sem) --------------------------------- -- 13.4 Enumeration aggregate -- --------------------------------- -- ENUMERATION_AGGREGATE ::= ARRAY_AGGREGATE ------------------------------------------ -- 13.5.1 Record representation clause -- ------------------------------------------ -- RECORD_REPRESENTATION_CLAUSE ::= -- for first_subtype_LOCAL_NAME use -- record [MOD_CLAUSE] -- {COMPONENT_CLAUSE} -- end record; -- Gigi restriction: Mod_Clause is always Empty (if present it is -- replaced by a corresponding Alignment attribute definition clause). -- Note: Component_Clauses can include pragmas -- N_Record_Representation_Clause -- Sloc points to FOR -- Identifier (Node1) direct name -- Mod_Clause (Node2) (set to Empty if no mod clause present) -- Component_Clauses (List3) -- Next_Rep_Item (Node4-Sem) ------------------------------ -- 13.5.1 Component clause -- ------------------------------ -- COMPONENT_CLAUSE ::= -- component_LOCAL_NAME at POSITION -- range FIRST_BIT .. LAST_BIT; -- N_Component_Clause -- Sloc points to AT -- Component_Name (Node1) points to Name or Attribute_Reference -- Position (Node2) -- First_Bit (Node3) -- Last_Bit (Node4) ---------------------- -- 13.5.1 Position -- ---------------------- -- POSITION ::= static_EXPRESSION ----------------------- -- 13.5.1 First_Bit -- ----------------------- -- FIRST_BIT ::= static_SIMPLE_EXPRESSION ---------------------- -- 13.5.1 Last_Bit -- ---------------------- -- LAST_BIT ::= static_SIMPLE_EXPRESSION -------------------------- -- 13.8 Code statement -- -------------------------- -- CODE_STATEMENT ::= QUALIFIED_EXPRESSION; -- Note: in GNAT, the qualified expression has the form -- Asm_Insn'(Asm (...)); -- or -- Asm_Insn'(Asm_Volatile (...)) -- See package System.Machine_Code in file s-maccod.ads for details -- on the allowed parameters to Asm[_Volatile]. There are two ways -- this node can arise, as a code statement, in which case the -- expression is the qualified expression, or as a result of the -- expansion of an intrinsic call to the Asm or Asm_Input procedure. -- N_Code_Statement -- Sloc points to first token of the expression -- Expression (Node3) -- Note: package Exp_Code contains an abstract functional interface -- for use by Gigi in accessing the data from N_Code_Statement nodes. ------------------------ -- 13.12 Restriction -- ------------------------ -- RESTRICTION ::= -- restriction_IDENTIFIER -- | restriction_parameter_IDENTIFIER => EXPRESSION -- There is no explicit node for restrictions. Instead the restriction -- appears in normal pragma syntax as a pragma argument association, -- which has the same syntactic form. -------------------------- -- B.2 Shift Operators -- -------------------------- -- Calls to the intrinsic shift functions are converted to one of -- the following shift nodes, which have the form of normal binary -- operator names. Note that for a given shift operation, one node -- covers all possible types, as for normal operators. -- Note: it is perfectly permissible for the expander to generate -- shift operation nodes directly, in which case they will be analyzed -- and parsed in the usual manner. -- Sprint syntax: shift-function-name!(expr, count) -- Note: the Left_Opnd field holds the first argument (the value to -- be shifted). The Right_Opnd field holds the second argument (the -- shift count). The Chars field is the name of the intrinsic function. -- N_Op_Rotate_Left -- Sloc points to the function name -- plus fields for binary operator -- plus fields for expression -- Shift_Count_OK (Flag4-Sem) -- N_Op_Rotate_Right -- Sloc points to the function name -- plus fields for binary operator -- plus fields for expression -- Shift_Count_OK (Flag4-Sem) -- N_Op_Shift_Left -- Sloc points to the function name -- plus fields for binary operator -- plus fields for expression -- Shift_Count_OK (Flag4-Sem) -- N_Op_Shift_Right_Arithmetic -- Sloc points to the function name -- plus fields for binary operator -- plus fields for expression -- Shift_Count_OK (Flag4-Sem) -- N_Op_Shift_Right -- Sloc points to the function name -- plus fields for binary operator -- plus fields for expression -- Shift_Count_OK (Flag4-Sem) -------------------------- -- Obsolescent Features -- -------------------------- -- The syntax descriptions and tree nodes for obsolescent features are -- grouped together, corresponding to their location in appendix I in -- the RM. However, parsing and semantic analysis for these constructs -- is located in an appropriate chapter (see individual notes). --------------------------- -- J.3 Delta Constraint -- --------------------------- -- Note: the parse routine for this construct is located in section -- 3.5.9 of Par-Ch3, and semantic analysis is in Sem_Ch3, which is -- where delta constraint logically belongs. -- DELTA_CONSTRAINT ::= DELTA static_EXPRESSION [RANGE_CONSTRAINT] -- N_Delta_Constraint -- Sloc points to DELTA -- Delta_Expression (Node3) -- Range_Constraint (Node4) (set to Empty if not present) -------------------- -- J.7 At Clause -- -------------------- -- AT_CLAUSE ::= for DIRECT_NAME use at EXPRESSION; -- Note: the parse routine for this construct is located in Par-Ch13, -- and the semantic analysis is in Sem_Ch13, where at clause logically -- belongs if it were not obsolescent. -- Note: in Ada 83 the expression must be a simple expression -- Gigi restriction: This node never appears, it is rewritten as an -- address attribute definition clause. -- N_At_Clause -- Sloc points to FOR -- Identifier (Node1) -- Expression (Node3) --------------------- -- J.8 Mod clause -- --------------------- -- MOD_CLAUSE ::= at mod static_EXPRESSION; -- Note: the parse routine for this construct is located in Par-Ch13, -- and the semantic analysis is in Sem_Ch13, where mod clause logically -- belongs if it were not obsolescent. -- Note: in Ada 83, the expression must be a simple expression -- Gigi restriction: this node never appears. It is replaced -- by a corresponding Alignment attribute definition clause. -- Note: pragmas can appear before and after the MOD_CLAUSE since -- its name has "clause" in it. This is rather strange, but is quite -- definitely specified. The pragmas before are collected in the -- Pragmas_Before field of the mod clause node itself, and pragmas -- after are simply swallowed up in the list of component clauses. -- N_Mod_Clause -- Sloc points to AT -- Expression (Node3) -- Pragmas_Before (List4) Pragmas before mod clause (No_List if none) -------------------- -- Semantic Nodes -- -------------------- -- These semantic nodes are used to hold additional semantic information. -- They are inserted into the tree as a result of semantic processing. -- Although there are no legitimate source syntax constructions that -- correspond directly to these nodes, we need a source syntax for the -- reconstructed tree printed by Sprint, and the node descriptions here -- show this syntax. ---------------------------- -- Conditional Expression -- ---------------------------- -- This node is used to represent an expression corresponding to the -- C construct (condition ? then-expression : else_expression), where -- Expressions is a three element list, whose first expression is the -- condition, and whose second and third expressions are the then and -- else expressions respectively. -- Note: the Then_Actions and Else_Actions fields are always set to -- No_List in the tree passed to Gigi. These fields are used only -- for temporary processing purposes in the expander. -- Sprint syntax: (if expr then expr else expr) -- N_Conditional_Expression -- Sloc points to related node -- Expressions (List1) -- Then_Actions (List2-Sem) -- Else_Actions (List3-Sem) -- plus fields for expression -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the IF keyword in the Sprint file output. ------------------- -- Expanded_Name -- ------------------- -- The N_Expanded_Name node is used to represent a selected component -- name that has been resolved to an expanded name. The semantic phase -- replaces N_Selected_Component nodes that represent names by the use -- of this node, leaving the N_Selected_Component node used only when -- the prefix is a record or protected type. -- The fields of the N_Expanded_Name node are layed out identically -- to those of the N_Selected_Component node, allowing conversion of -- an expanded name node to a selected component node to be done -- easily, see Sinfo.CN.Change_Selected_Component_To_Expanded_Name. -- There is no special sprint syntax for an expanded name. -- N_Expanded_Name -- Sloc points to the period -- Chars (Name1) copy of Chars field of selector name -- Prefix (Node3) -- Selector_Name (Node2) -- Entity (Node4-Sem) -- Associated_Node (Node4-Sem) -- Redundant_Use (Flag13-Sem) -- Has_Private_View (Flag11-Sem) set in generic units. -- plus fields for expression -------------------- -- Free Statement -- -------------------- -- The N_Free_Statement node is generated as a result of a call to an -- instantiation of Unchecked_Deallocation. The instantiation of this -- generic is handled specially and generates this node directly. -- Sprint syntax: free expression -- N_Free_Statement -- Sloc is copied from the unchecked deallocation call -- Expression (Node3) argument to unchecked deallocation call -- Storage_Pool (Node1-Sem) -- Procedure_To_Call (Node4-Sem) -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the FREE keyword in the Sprint file output. ------------------- -- Freeze Entity -- ------------------- -- This node marks the point in a declarative part at which an entity -- declared therein becomes frozen. The expander places initialization -- procedures for types at those points. Gigi uses the freezing point -- to elaborate entities that may depend on previous private types. -- See the section in Einfo "Delayed Freezing and Elaboration" for -- a full description of the use of this node. -- The Entity field points back to the entity for the type (whose -- Freeze_Node field points back to this freeze node). -- The Actions field contains a list of declarations and statements -- generated by the expander which are associated with the freeze -- node, and are elaborated as though the freeze node were replaced -- by this sequence of actions. -- Note: the Sloc field in the freeze node references a construct -- associated with the freezing point. This is used for posting -- messages in some error/warning situations, e.g. the case where -- a primitive operation of a tagged type is declared too late. -- Sprint syntax: freeze entity-name [ -- freeze actions -- ] -- N_Freeze_Entity -- Sloc points near freeze point (see above special note) -- Entity (Node4-Sem) -- Access_Types_To_Process (Elist2-Sem) (set to No_Elist if none) -- TSS_Elist (Elist3-Sem) (set to No_Elist if no associated TSS's) -- Actions (List1) (set to No_List if no freeze actions) -- First_Subtype_Link (Node5-Sem) (set to Empty if no link) -- The Actions field holds actions associated with the freeze. These -- actions are elaborated at the point where the type is frozen. -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the FREEZE keyword in the Sprint file output. -------------------------------- -- Implicit Label Declaration -- -------------------------------- -- An implicit label declaration is created for every occurrence of a -- label on a statement or a label on a block or loop. It is chained -- in the declarations of the innermost enclosing block as specified -- in RM section 5.1 (3). -- The Defining_Identifier is the actual identifier for the -- statement identifier. Note that the occurrence of the label -- is a reference, NOT the defining occurrence. The defining -- occurrence occurs at the head of the innermost enclosing -- block, and is represented by this node. -- Note: from the grammar, this might better be called an implicit -- statement identifier declaration, but the term we choose seems -- friendlier, since at least informally statement identifiers are -- called labels in both cases (i.e. when used in labels, and when -- used as the identifiers of blocks and loops). -- Note: although this is logically a semantic node, since it does -- not correspond directly to a source syntax construction, these -- nodes are actually created by the parser in a post pass done just -- after parsing is complete, before semantic analysis is started (see -- the Par.Labl subunit in file par-labl.adb). -- Sprint syntax: labelname : label; -- N_Implicit_Label_Declaration -- Sloc points to the << of the label -- Defining_Identifier (Node1) -- Label_Construct (Node2-Sem) -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the label name in the generated declaration. --------------------- -- Itype_Reference -- --------------------- -- This node is used to create a reference to an Itype. The only -- purpose is to make sure that the Itype is defined if this is the -- first reference. -- A typical use of this node is when an Itype is to be referenced in -- two branches of an if statement. In this case it is important that -- the first use of the Itype not be inside the conditional, since -- then it might not be defined if the wrong branch of the if is -- taken in the case where the definition generates elaboration code. -- The Itype field points to the referenced Itype -- sprint syntax: reference itype-name -- N_Itype_Reference -- Sloc points to the node generating the reference -- Itype (Node1-Sem) -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the REFERENCE keyword in the file output. --------------------- -- Raise_xxx_Error -- --------------------- -- One of these nodes is created during semantic analysis to replace -- a node for an expression that is determined to definitely raise -- the corresponding exception. -- The N_Raise_xxx_Error node may also stand alone in place -- of a declaration or statement, in which case it simply causes -- the exception to be raised (i.e. it is equivalent to a raise -- statement that raises the corresponding exception). This use -- is distinguished by the fact that the Etype in this case is -- Standard_Void_Type, In the subexprssion case, the Etype is the -- same as the type of the subexpression which it replaces. -- If Condition is empty, then the raise is unconditional. If the -- Condition field is non-empty, it is a boolean expression which -- is first evaluated, and the exception is raised only if the -- value of the expression is True. In the unconditional case, the -- creation of this node is usually accompanied by a warning message -- error. The creation of this node will usually be accompanied by a -- message (unless it appears within the right operand of a short -- circuit form whose left argument is static and decisively -- eliminates elaboration of the raise operation. -- The exception is generated with a message that contains the -- file name and line number, and then appended text. The Reason -- code shows the text to be added. The Reason code is an element -- of the type Types.RT_Exception_Code, and indicates both the -- message to be added, and the exception to be raised (which must -- match the node type). The value is stored by storing a Uint which -- is the Pos value of the enumeration element in this type. -- Gigi restriction: This expander ensures that the type of the -- Condition field is always Standard.Boolean, even if the type -- in the source is some non-standard boolean type. -- Sprint syntax: [xxx_error "msg"] -- or: [xxx_error when condition "msg"] -- N_Raise_Constraint_Error -- Sloc references related construct -- Condition (Node1) (set to Empty if no condition) -- Reason (Uint3) -- plus fields for expression -- N_Raise_Program_Error -- Sloc references related construct -- Condition (Node1) (set to Empty if no condition) -- Reason (Uint3) -- plus fields for expression -- N_Raise_Storage_Error -- Sloc references related construct -- Condition (Node1) (set to Empty if no condition) -- Reason (Uint3) -- plus fields for expression -- Note: Sloc is copied from the expression generating the exception. -- In the case where a debug source file is generated, the Sloc for -- this node points to the left bracket in the Sprint file output. --------------- -- Reference -- --------------- -- For a number of purposes, we need to construct references to objects. -- These references are subsequently treated as normal access values. -- An example is the construction of the parameter block passed to a -- task entry. The N_Reference node is provided for this purpose. It is -- similar in effect to the use of the Unrestricted_Access attribute, -- and like Unrestricted_Access can be applied to objects which would -- not be valid prefixes for the Unchecked_Access attribute (e.g. -- objects which are not aliased, and slices). In addition it can be -- applied to composite type values as well as objects, including string -- values and aggregates. -- Note: we use the Prefix field for this expression so that the -- resulting node can be treated using common code with the attribute -- nodes for the 'Access and related attributes. Logically it would make -- more sense to call it an Expression field, but then we would have to -- special case the treatment of the N_Reference node. -- Sprint syntax: prefix'reference -- N_Reference -- Sloc is copied from the expression -- Prefix (Node3) -- plus fields for expression -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the quote in the Sprint file output. --------------------- -- Subprogram_Info -- --------------------- -- This node generates the appropriate Subprogram_Info value for a -- given procedure. See Ada.Exceptions for further details -- Sprint syntax: subprog'subprogram_info -- N_Subprogram_Info -- Sloc points to the entity for the procedure -- Identifier (Node1) identifier referencing the procedure -- Etype (Node5-Sem) type (always set to Ada.Exceptions.Code_Loc -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the quote in the Sprint file output. -------------------------- -- Unchecked Expression -- -------------------------- -- An unchecked expression is one that must be analyzed and resolved -- with all checks off, regardless of the current setting of scope -- suppress flags. -- Sprint syntax: `(expression). -- Note: this node is always removed from the tree (and replaced by -- its constituent expression) on completion of analysis, so it only -- appears in intermediate trees, and will never be seen by Gigi. -- N_Unchecked_Expression -- Sloc is a copy of the Sloc of the expression -- Expression (Node3) -- plus fields for expression -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the back quote in the Sprint file output. ------------------------------- -- Unchecked Type Conversion -- ------------------------------- -- An unchecked type conversion node represents the semantic action -- corresponding to a call to an instantiation of Unchecked_Conversion. -- It is generated as a result of actual use of Unchecked_Conversion -- and also the expander generates unchecked type conversion nodes -- directly for expansion of complex semantic actions. -- Note: an unchecked type conversion is a variable as far as the -- semantics are concerned, which is convenient for the expander. -- This does not change what Ada source programs are legal, since -- clearly a function call to an instantiation of Unchecked_Conversion -- is not a variable in any case. -- Sprint syntax: subtype-mark!(expression). -- N_Unchecked_Type_Conversion -- Sloc points to related node in source -- Subtype_Mark (Node4) -- Expression (Node3) -- Kill_Range_Check (Flag11-Sem) -- No_Truncation (Flag17-Sem) -- plus fields for expression -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the exclamation in the Sprint file output. ----------------------------------- -- Validate_Unchecked_Conversion -- ----------------------------------- -- The front end does most of the validation of unchecked conversion, -- including checking sizes (this is done after the back end is called -- to take advantage of back-annotation of calculated sizes). -- The front end also deals with specific cases that are not allowed -- e.g. involving unconstrained array types. -- For the case of the standard gigi backend, this means that all -- checks are done in the front-end. -- However, in the case of specialized back-ends, notably the JVM -- backend for JGNAT, additional requirements and restrictions apply -- to unchecked conversion, and these are most conveniently performed -- in the specialized back-end. -- To accommodate this requirement, for such back ends, the following -- special node is generated recording an unchecked conversion that -- needs to be validated. The back end should post an appropriate -- error message if the unchecked conversion is invalid or warrants -- a special warning message. -- Source_Type and Target_Type point to the entities for the two -- types involved in the unchecked conversion instantiation that -- is to be validated. -- Sprint syntax: validate Unchecked_Conversion (source, target); -- N_Validate_Unchecked_Conversion -- Sloc points to instantiation (location for warning message) -- Source_Type (Node1-Sem) -- Target_Type (Node2-Sem) -- Note: in the case where a debug source file is generated, the Sloc -- for this node points to the VALIDATE keyword in the file output. ----------- -- Empty -- ----------- -- Used as the contents of the Nkind field of the dummy Empty node -- and in some other situations to indicate an uninitialized value. -- N_Empty -- Chars (Name1) is set to No_Name ----------- -- Error -- ----------- -- Used as the contents of the Nkind field of the dummy Error node. -- Has an Etype field, which gets set to Any_Type later on, to help -- error recovery (Error_Posted is also set in the Error node). -- N_Error -- Chars (Name1) is set to Error_Name -- Etype (Node5-Sem) -------------------------- -- Node Type Definition -- -------------------------- -- The following is the definition of the Node_Kind type. As previously -- discussed, this is separated off to allow rearrangement of the order -- to facilitiate definition of subtype ranges. The comments show the -- subtype classes which apply to each set of node kinds. The first -- entry in the comment characterizes the following list of nodes. type Node_Kind is ( N_Unused_At_Start, -- N_Representation_Clause N_At_Clause, N_Component_Clause, N_Enumeration_Representation_Clause, N_Mod_Clause, N_Record_Representation_Clause, -- N_Representation_Clause, N_Has_Chars N_Attribute_Definition_Clause, -- N_Has_Chars N_Empty, N_Pragma, N_Pragma_Argument_Association, -- N_Has_Etype N_Error, -- N_Entity, N_Has_Etype, N_Has_Chars N_Defining_Character_Literal, N_Defining_Identifier, N_Defining_Operator_Symbol, -- N_Subexpr, N_Has_Etype, N_Has_Chars, N_Has_Entity N_Expanded_Name, -- N_Direct_Name, N_Subexpr, N_Has_Etype, -- N_Has_Chars, N_Has_Entity N_Identifier, N_Operator_Symbol, -- N_Direct_Name, N_Subexpr, N_Has_Etype, -- N_Has_Chars, N_Has_Entity N_Character_Literal, -- N_Binary_Op, N_Op, N_Subexpr, -- N_Has_Etype, N_Has_Chars, N_Has_Entity N_Op_Add, N_Op_Concat, N_Op_Expon, N_Op_Subtract, -- N_Binary_Op, N_Op, N_Subexpr, N_Has_Treat_Fixed_As_Integer -- N_Has_Etype, N_Has_Chars, N_Has_Entity N_Op_Divide, N_Op_Mod, N_Op_Multiply, N_Op_Rem, -- N_Binary_Op, N_Op, N_Subexpr, N_Has_Etype -- N_Has_Entity, N_Has_Chars, N_Op_Boolean N_Op_And, -- N_Binary_Op, N_Op, N_Subexpr, N_Has_Etype -- N_Has_Entity, N_Has_Chars, N_Op_Boolean, -- N_Op_Compare N_Op_Eq, N_Op_Ge, N_Op_Gt, N_Op_Le, N_Op_Lt, N_Op_Ne, -- N_Binary_Op, N_Op, N_Subexpr, N_Has_Etype -- N_Has_Entity, N_Has_Chars, N_Op_Boolean N_Op_Or, N_Op_Xor, -- N_Binary_Op, N_Op, N_Subexpr, N_Has_Etype, -- N_Op_Shift, N_Has_Chars, N_Has_Entity N_Op_Rotate_Left, N_Op_Rotate_Right, N_Op_Shift_Left, N_Op_Shift_Right, N_Op_Shift_Right_Arithmetic, -- N_Unary_Op, N_Op, N_Subexpr, N_Has_Etype, -- N_Has_Chars, N_Has_Entity N_Op_Abs, N_Op_Minus, N_Op_Not, N_Op_Plus, -- N_Subexpr, N_Has_Etype, N_Has_Entity N_Attribute_Reference, -- N_Subexpr, N_Has_Etype N_And_Then, N_Conditional_Expression, N_Explicit_Dereference, N_Function_Call, N_In, N_Indexed_Component, N_Integer_Literal, N_Not_In, N_Null, N_Or_Else, N_Procedure_Call_Statement, N_Qualified_Expression, -- N_Raise_xxx_Error, N_Subexpr, N_Has_Etype N_Raise_Constraint_Error, N_Raise_Program_Error, N_Raise_Storage_Error, -- N_Subexpr, N_Has_Etype N_Aggregate, N_Allocator, N_Extension_Aggregate, N_Range, N_Real_Literal, N_Reference, N_Selected_Component, N_Slice, N_String_Literal, N_Subprogram_Info, N_Type_Conversion, N_Unchecked_Expression, N_Unchecked_Type_Conversion, -- N_Has_Etype N_Subtype_Indication, -- N_Declaration N_Component_Declaration, N_Entry_Declaration, N_Formal_Object_Declaration, N_Formal_Type_Declaration, N_Full_Type_Declaration, N_Incomplete_Type_Declaration, N_Loop_Parameter_Specification, N_Object_Declaration, N_Protected_Type_Declaration, N_Private_Extension_Declaration, N_Private_Type_Declaration, N_Subtype_Declaration, -- N_Subprogram_Specification, N_Declaration N_Function_Specification, N_Procedure_Specification, -- (nothing special) N_Entry_Index_Specification, N_Freeze_Entity, -- N_Access_To_Subprogram_Definition N_Access_Function_Definition, N_Access_Procedure_Definition, -- N_Later_Decl_Item, N_Task_Type_Declaration, -- N_Body_Stub, N_Later_Decl_Item N_Package_Body_Stub, N_Protected_Body_Stub, N_Subprogram_Body_Stub, N_Task_Body_Stub, -- N_Generic_Instantiation, N_Later_Decl_Item N_Function_Instantiation, N_Package_Instantiation, N_Procedure_Instantiation, -- N_Unit_Body, N_Later_Decl_Item, N_Proper_Body N_Package_Body, N_Subprogram_Body, -- N_Later_Decl_Item, N_Proper_Body N_Protected_Body, N_Task_Body, -- N_Later_Decl_Item N_Implicit_Label_Declaration, N_Package_Declaration, N_Single_Task_Declaration, N_Subprogram_Declaration, N_Use_Package_Clause, -- N_Generic_Declaration, N_Later_Decl_Item N_Generic_Package_Declaration, N_Generic_Subprogram_Declaration, -- N_Array_Type_Definition N_Constrained_Array_Definition, N_Unconstrained_Array_Definition, -- N_Renaming_Declaration N_Exception_Renaming_Declaration, N_Object_Renaming_Declaration, N_Package_Renaming_Declaration, N_Subprogram_Renaming_Declaration, -- N_Generic_Renaming_Declarations, N_Renaming_Declaration N_Generic_Function_Renaming_Declaration, N_Generic_Package_Renaming_Declaration, N_Generic_Procedure_Renaming_Declaration, -- N_Statement_Other_Than_Procedure_Call N_Abort_Statement, N_Accept_Statement, N_Assignment_Statement, N_Asynchronous_Select, N_Block_Statement, N_Case_Statement, N_Code_Statement, N_Conditional_Entry_Call, N_Delay_Relative_Statement, N_Delay_Until_Statement, N_Entry_Call_Statement, N_Free_Statement, N_Goto_Statement, N_Loop_Statement, N_Null_Statement, N_Raise_Statement, N_Requeue_Statement, N_Return_Statement, N_Selective_Accept, N_Timed_Entry_Call, -- N_Statement_Other_Than_Procedure_Call, N_Has_Condition N_Exit_Statement, N_If_Statement, -- N_Has_Condition N_Accept_Alternative, N_Delay_Alternative, N_Elsif_Part, N_Entry_Body_Formal_Part, N_Iteration_Scheme, N_Terminate_Alternative, -- Other nodes (not part of any subtype class) N_Abortable_Part, N_Abstract_Subprogram_Declaration, N_Access_Definition, N_Access_To_Object_Definition, N_Case_Statement_Alternative, N_Compilation_Unit, N_Compilation_Unit_Aux, N_Component_Association, N_Component_Definition, N_Component_List, N_Derived_Type_Definition, N_Decimal_Fixed_Point_Definition, N_Defining_Program_Unit_Name, N_Delta_Constraint, N_Designator, N_Digits_Constraint, N_Discriminant_Association, N_Discriminant_Specification, N_Enumeration_Type_Definition, N_Entry_Body, N_Entry_Call_Alternative, N_Exception_Declaration, N_Exception_Handler, N_Floating_Point_Definition, N_Formal_Abstract_Subprogram_Declaration, N_Formal_Concrete_Subprogram_Declaration, N_Formal_Decimal_Fixed_Point_Definition, N_Formal_Derived_Type_Definition, N_Formal_Discrete_Type_Definition, N_Formal_Floating_Point_Definition, N_Formal_Modular_Type_Definition, N_Formal_Ordinary_Fixed_Point_Definition, N_Formal_Package_Declaration, N_Formal_Private_Type_Definition, N_Formal_Signed_Integer_Type_Definition, N_Generic_Association, N_Handled_Sequence_Of_Statements, N_Index_Or_Discriminant_Constraint, N_Itype_Reference, N_Label, N_Modular_Type_Definition, N_Number_Declaration, N_Ordinary_Fixed_Point_Definition, N_Others_Choice, N_Package_Specification, N_Parameter_Association, N_Parameter_Specification, N_Protected_Definition, N_Range_Constraint, N_Real_Range_Specification, N_Record_Definition, N_Signed_Integer_Type_Definition, N_Single_Protected_Declaration, N_Subunit, N_Task_Definition, N_Triggering_Alternative, N_Use_Type_Clause, N_Validate_Unchecked_Conversion, N_Variant, N_Variant_Part, N_With_Clause, N_With_Type_Clause, N_Unused_At_End); for Node_Kind'Size use 8; -- The data structures in Atree assume this! ---------------------------- -- Node Class Definitions -- ---------------------------- subtype N_Access_To_Subprogram_Definition is Node_Kind range N_Access_Function_Definition .. N_Access_Procedure_Definition; subtype N_Array_Type_Definition is Node_Kind range N_Constrained_Array_Definition .. N_Unconstrained_Array_Definition; subtype N_Binary_Op is Node_Kind range N_Op_Add .. N_Op_Shift_Right_Arithmetic; subtype N_Body_Stub is Node_Kind range N_Package_Body_Stub .. N_Task_Body_Stub; subtype N_Declaration is Node_Kind range N_Component_Declaration .. N_Procedure_Specification; -- Note: this includes all constructs normally thought of as declarations -- except those which are separately grouped as later declarations. subtype N_Direct_Name is Node_Kind range N_Identifier .. N_Character_Literal; subtype N_Entity is Node_Kind range N_Defining_Character_Literal .. N_Defining_Operator_Symbol; subtype N_Formal_Subprogram_Declaration is Node_Kind range N_Formal_Abstract_Subprogram_Declaration .. N_Formal_Concrete_Subprogram_Declaration; subtype N_Generic_Declaration is Node_Kind range N_Generic_Package_Declaration .. N_Generic_Subprogram_Declaration; subtype N_Generic_Instantiation is Node_Kind range N_Function_Instantiation .. N_Procedure_Instantiation; subtype N_Generic_Renaming_Declaration is Node_Kind range N_Generic_Function_Renaming_Declaration .. N_Generic_Procedure_Renaming_Declaration; subtype N_Has_Chars is Node_Kind range N_Attribute_Definition_Clause .. N_Op_Plus; subtype N_Has_Entity is Node_Kind range N_Expanded_Name .. N_Attribute_Reference; -- Nodes that have Entity fields -- Warning: DOES NOT INCLUDE N_Freeze_Entity! subtype N_Has_Etype is Node_Kind range N_Error .. N_Subtype_Indication; subtype N_Has_Treat_Fixed_As_Integer is Node_Kind range N_Op_Divide .. N_Op_Rem; subtype N_Later_Decl_Item is Node_Kind range N_Task_Type_Declaration .. N_Generic_Subprogram_Declaration; -- Note: this is Ada 83 relevant only (see Ada 83 RM 3.9 (2)) and -- includes only those items which can appear as later declarative -- items. This also includes N_Implicit_Label_Declaration which is -- not specifically in the grammar but may appear as a valid later -- declarative items. It does NOT include N_Pragma which can also -- appear among later declarative items. It does however include -- N_Protected_Body, which is a bit peculiar, but harmless since -- this cannot appear in Ada 83 mode anyway. subtype N_Op is Node_Kind range N_Op_Add .. N_Op_Plus; subtype N_Op_Boolean is Node_Kind range N_Op_And .. N_Op_Xor; -- Binary operators which take operands of a boolean type, and yield -- a result of a boolean type. subtype N_Op_Compare is Node_Kind range N_Op_Eq .. N_Op_Ne; subtype N_Op_Shift is Node_Kind range N_Op_Rotate_Left .. N_Op_Shift_Right_Arithmetic; subtype N_Proper_Body is Node_Kind range N_Package_Body .. N_Task_Body; subtype N_Raise_xxx_Error is Node_Kind range N_Raise_Constraint_Error .. N_Raise_Storage_Error; subtype N_Renaming_Declaration is Node_Kind range N_Exception_Renaming_Declaration .. N_Generic_Procedure_Renaming_Declaration; subtype N_Representation_Clause is Node_Kind range N_At_Clause .. N_Attribute_Definition_Clause; subtype N_Statement_Other_Than_Procedure_Call is Node_Kind range N_Abort_Statement .. N_If_Statement; -- Note that this includes all statement types except for the cases of the -- N_Procedure_Call_Statement which is considered to be a subexpression -- (since overloading is possible, so it needs to go through the normal -- overloading resolution for expressions). subtype N_Has_Condition is Node_Kind range N_Exit_Statement .. N_Terminate_Alternative; -- Nodes with condition fields (does not include N_Raise_xxx_Error) subtype N_Subexpr is Node_Kind range N_Expanded_Name .. N_Unchecked_Type_Conversion; -- Nodes with expression fields subtype N_Subprogram_Specification is Node_Kind range N_Function_Specification .. N_Procedure_Specification; subtype N_Unary_Op is Node_Kind range N_Op_Abs .. N_Op_Plus; subtype N_Unit_Body is Node_Kind range N_Package_Body .. N_Subprogram_Body; --------------------------- -- 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. They provide -- logical access to fields in the node which could be accessed using the -- Atree.Unchecked_Access package, but the idea is always to use these -- higher level routines which preserve strong typing. In debug mode, -- these routines check that they are being applied to an appropriate -- node, as well as checking that the node is in range. function ABE_Is_Certain (N : Node_Id) return Boolean; -- Flag18 function Abort_Present (N : Node_Id) return Boolean; -- Flag15 function Abortable_Part (N : Node_Id) return Node_Id; -- Node2 function Abstract_Present (N : Node_Id) return Boolean; -- Flag4 function Accept_Handler_Records (N : Node_Id) return List_Id; -- List5 function Accept_Statement (N : Node_Id) return Node_Id; -- Node2 function Access_Definition (N : Node_Id) return Node_Id; -- Node3 function Access_To_Subprogram_Definition (N : Node_Id) return Node_Id; -- Node3 function Access_Types_To_Process (N : Node_Id) return Elist_Id; -- Elist2 function Actions (N : Node_Id) return List_Id; -- List1 function Activation_Chain_Entity (N : Node_Id) return Node_Id; -- Node3 function Acts_As_Spec (N : Node_Id) return Boolean; -- Flag4 function Aggregate_Bounds (N : Node_Id) return Node_Id; -- Node3 function Aliased_Present (N : Node_Id) return Boolean; -- Flag4 function All_Others (N : Node_Id) return Boolean; -- Flag11 function All_Present (N : Node_Id) return Boolean; -- Flag15 function Alternatives (N : Node_Id) return List_Id; -- List4 function Ancestor_Part (N : Node_Id) return Node_Id; -- Node3 function Array_Aggregate (N : Node_Id) return Node_Id; -- Node3 function Assignment_OK (N : Node_Id) return Boolean; -- Flag15 function Associated_Node (N : Node_Id) return Node_Id; -- Node4 function At_End_Proc (N : Node_Id) return Node_Id; -- Node1 function Attribute_Name (N : Node_Id) return Name_Id; -- Name2 function Aux_Decls_Node (N : Node_Id) return Node_Id; -- Node5 function Backwards_OK (N : Node_Id) return Boolean; -- Flag6 function Bad_Is_Detected (N : Node_Id) return Boolean; -- Flag15 function By_Ref (N : Node_Id) return Boolean; -- Flag5 function Body_Required (N : Node_Id) return Boolean; -- Flag13 function Body_To_Inline (N : Node_Id) return Node_Id; -- Node3 function Box_Present (N : Node_Id) return Boolean; -- Flag15 function Char_Literal_Value (N : Node_Id) return Uint; -- Uint2 function Chars (N : Node_Id) return Name_Id; -- Name1 function Check_Address_Alignment (N : Node_Id) return Boolean; -- Flag11 function Choice_Parameter (N : Node_Id) return Node_Id; -- Node2 function Choices (N : Node_Id) return List_Id; -- List1 function Compile_Time_Known_Aggregate (N : Node_Id) return Boolean; -- Flag18 function Component_Associations (N : Node_Id) return List_Id; -- List2 function Component_Clauses (N : Node_Id) return List_Id; -- List3 function Component_Definition (N : Node_Id) return Node_Id; -- Node4 function Component_Items (N : Node_Id) return List_Id; -- List3 function Component_List (N : Node_Id) return Node_Id; -- Node1 function Component_Name (N : Node_Id) return Node_Id; -- Node1 function Condition (N : Node_Id) return Node_Id; -- Node1 function Condition_Actions (N : Node_Id) return List_Id; -- List3 function Config_Pragmas (N : Node_Id) return List_Id; -- List4 function Constant_Present (N : Node_Id) return Boolean; -- Flag17 function Constraint (N : Node_Id) return Node_Id; -- Node3 function Constraints (N : Node_Id) return List_Id; -- List1 function Context_Installed (N : Node_Id) return Boolean; -- Flag13 function Context_Items (N : Node_Id) return List_Id; -- List1 function Controlling_Argument (N : Node_Id) return Node_Id; -- Node1 function Conversion_OK (N : Node_Id) return Boolean; -- Flag14 function Corresponding_Body (N : Node_Id) return Node_Id; -- Node5 function Corresponding_Formal_Spec (N : Node_Id) return Node_Id; -- Node3 function Corresponding_Generic_Association (N : Node_Id) return Node_Id; -- Node5 function Corresponding_Integer_Value (N : Node_Id) return Uint; -- Uint4 function Corresponding_Spec (N : Node_Id) return Node_Id; -- Node5 function Corresponding_Stub (N : Node_Id) return Node_Id; -- Node3 function Dcheck_Function (N : Node_Id) return Entity_Id; -- Node5 function Debug_Statement (N : Node_Id) return Node_Id; -- Node3 function Declarations (N : Node_Id) return List_Id; -- List2 function Default_Expression (N : Node_Id) return Node_Id; -- Node5 function Default_Name (N : Node_Id) return Node_Id; -- Node2 function Defining_Identifier (N : Node_Id) return Entity_Id; -- Node1 function Defining_Unit_Name (N : Node_Id) return Node_Id; -- Node1 function Delay_Alternative (N : Node_Id) return Node_Id; -- Node4 function Delay_Finalize_Attach (N : Node_Id) return Boolean; -- Flag14 function Delay_Statement (N : Node_Id) return Node_Id; -- Node2 function Delta_Expression (N : Node_Id) return Node_Id; -- Node3 function Digits_Expression (N : Node_Id) return Node_Id; -- Node2 function Discr_Check_Funcs_Built (N : Node_Id) return Boolean; -- Flag11 function Discrete_Choices (N : Node_Id) return List_Id; -- List4 function Discrete_Range (N : Node_Id) return Node_Id; -- Node4 function Discrete_Subtype_Definition (N : Node_Id) return Node_Id; -- Node4 function Discrete_Subtype_Definitions (N : Node_Id) return List_Id; -- List2 function Discriminant_Specifications (N : Node_Id) return List_Id; -- List4 function Discriminant_Type (N : Node_Id) return Node_Id; -- Node5 function Do_Accessibility_Check (N : Node_Id) return Boolean; -- Flag13 function Do_Discriminant_Check (N : Node_Id) return Boolean; -- Flag13 function Do_Division_Check (N : Node_Id) return Boolean; -- Flag13 function Do_Length_Check (N : Node_Id) return Boolean; -- Flag4 function Do_Overflow_Check (N : Node_Id) return Boolean; -- Flag17 function Do_Range_Check (N : Node_Id) return Boolean; -- Flag9 function Do_Storage_Check (N : Node_Id) return Boolean; -- Flag17 function Do_Tag_Check (N : Node_Id) return Boolean; -- Flag13 function Elaborate_All_Present (N : Node_Id) return Boolean; -- Flag14 function Elaborate_Present (N : Node_Id) return Boolean; -- Flag4 function Elaboration_Boolean (N : Node_Id) return Node_Id; -- Node2 function Else_Actions (N : Node_Id) return List_Id; -- List3 function Else_Statements (N : Node_Id) return List_Id; -- List4 function Elsif_Parts (N : Node_Id) return List_Id; -- List3 function Enclosing_Variant (N : Node_Id) return Node_Id; -- Node2 function End_Label (N : Node_Id) return Node_Id; -- Node4 function End_Span (N : Node_Id) return Uint; -- Uint5 function Entity (N : Node_Id) return Node_Id; -- Node4 function Entity_Or_Associated_Node (N : Node_Id) return Node_Id; -- Node4 function Entry_Body_Formal_Part (N : Node_Id) return Node_Id; -- Node5 function Entry_Call_Alternative (N : Node_Id) return Node_Id; -- Node1 function Entry_Call_Statement (N : Node_Id) return Node_Id; -- Node1 function Entry_Direct_Name (N : Node_Id) return Node_Id; -- Node1 function Entry_Index (N : Node_Id) return Node_Id; -- Node5 function Entry_Index_Specification (N : Node_Id) return Node_Id; -- Node4 function Etype (N : Node_Id) return Node_Id; -- Node5 function Exception_Choices (N : Node_Id) return List_Id; -- List4 function Exception_Handlers (N : Node_Id) return List_Id; -- List5 function Exception_Junk (N : Node_Id) return Boolean; -- Flag11 function Explicit_Actual_Parameter (N : Node_Id) return Node_Id; -- Node3 function Expansion_Delayed (N : Node_Id) return Boolean; -- Flag11 function Explicit_Generic_Actual_Parameter (N : Node_Id) return Node_Id; -- Node1 function Expression (N : Node_Id) return Node_Id; -- Node3 function Expressions (N : Node_Id) return List_Id; -- List1 function First_Bit (N : Node_Id) return Node_Id; -- Node3 function First_Inlined_Subprogram (N : Node_Id) return Entity_Id; -- Node3 function First_Name (N : Node_Id) return Boolean; -- Flag5 function First_Named_Actual (N : Node_Id) return Node_Id; -- Node4 function First_Real_Statement (N : Node_Id) return Node_Id; -- Node2 function First_Subtype_Link (N : Node_Id) return Entity_Id; -- Node5 function Float_Truncate (N : Node_Id) return Boolean; -- Flag11 function Formal_Type_Definition (N : Node_Id) return Node_Id; -- Node3 function Forwards_OK (N : Node_Id) return Boolean; -- Flag5 function From_At_Mod (N : Node_Id) return Boolean; -- Flag4 function From_Default (N : Node_Id) return Boolean; -- Flag6 function Generic_Associations (N : Node_Id) return List_Id; -- List3 function Generic_Formal_Declarations (N : Node_Id) return List_Id; -- List2 function Generic_Parent (N : Node_Id) return Node_Id; -- Node5 function Generic_Parent_Type (N : Node_Id) return Node_Id; -- Node4 function Handled_Statement_Sequence (N : Node_Id) return Node_Id; -- Node4 function Handler_List_Entry (N : Node_Id) return Node_Id; -- Node2 function Has_Created_Identifier (N : Node_Id) return Boolean; -- Flag15 function Has_Dynamic_Length_Check (N : Node_Id) return Boolean; -- Flag10 function Has_Dynamic_Range_Check (N : Node_Id) return Boolean; -- Flag12 function Has_No_Elaboration_Code (N : Node_Id) return Boolean; -- Flag17 function Has_Priority_Pragma (N : Node_Id) return Boolean; -- Flag6 function Has_Private_View (N : Node_Id) return Boolean; -- Flag11 function Has_Storage_Size_Pragma (N : Node_Id) return Boolean; -- Flag5 function Has_Task_Info_Pragma (N : Node_Id) return Boolean; -- Flag7 function Has_Task_Name_Pragma (N : Node_Id) return Boolean; -- Flag8 function Has_Wide_Character (N : Node_Id) return Boolean; -- Flag11 function Hidden_By_Use_Clause (N : Node_Id) return Elist_Id; -- Elist4 function High_Bound (N : Node_Id) return Node_Id; -- Node2 function Identifier (N : Node_Id) return Node_Id; -- Node1 function Implicit_With (N : Node_Id) return Boolean; -- Flag16 function In_Present (N : Node_Id) return Boolean; -- Flag15 function Includes_Infinities (N : Node_Id) return Boolean; -- Flag11 function Instance_Spec (N : Node_Id) return Node_Id; -- Node5 function Intval (N : Node_Id) return Uint; -- Uint3 function Is_Asynchronous_Call_Block (N : Node_Id) return Boolean; -- Flag7 function Is_Component_Left_Opnd (N : Node_Id) return Boolean; -- Flag13 function Is_Component_Right_Opnd (N : Node_Id) return Boolean; -- Flag14 function Is_Controlling_Actual (N : Node_Id) return Boolean; -- Flag16 function Is_In_Discriminant_Check (N : Node_Id) return Boolean; -- Flag11 function Is_Machine_Number (N : Node_Id) return Boolean; -- Flag11 function Is_Null_Loop (N : Node_Id) return Boolean; -- Flag16 function Is_Overloaded (N : Node_Id) return Boolean; -- Flag5 function Is_Power_Of_2_For_Shift (N : Node_Id) return Boolean; -- Flag13 function Is_Protected_Subprogram_Body (N : Node_Id) return Boolean; -- Flag7 function Is_Static_Expression (N : Node_Id) return Boolean; -- Flag6 function Is_Subprogram_Descriptor (N : Node_Id) return Boolean; -- Flag16 function Is_Task_Allocation_Block (N : Node_Id) return Boolean; -- Flag6 function Is_Task_Master (N : Node_Id) return Boolean; -- Flag5 function Iteration_Scheme (N : Node_Id) return Node_Id; -- Node2 function Itype (N : Node_Id) return Entity_Id; -- Node1 function Kill_Range_Check (N : Node_Id) return Boolean; -- Flag11 function Label_Construct (N : Node_Id) return Node_Id; -- Node2 function Left_Opnd (N : Node_Id) return Node_Id; -- Node2 function Last_Bit (N : Node_Id) return Node_Id; -- Node4 function Last_Name (N : Node_Id) return Boolean; -- Flag6 function Library_Unit (N : Node_Id) return Node_Id; -- Node4 function Limited_View_Installed (N : Node_Id) return Boolean; -- Flag18 function Limited_Present (N : Node_Id) return Boolean; -- Flag17 function Literals (N : Node_Id) return List_Id; -- List1 function Loop_Actions (N : Node_Id) return List_Id; -- List2 function Loop_Parameter_Specification (N : Node_Id) return Node_Id; -- Node4 function Low_Bound (N : Node_Id) return Node_Id; -- Node1 function Mod_Clause (N : Node_Id) return Node_Id; -- Node2 function More_Ids (N : Node_Id) return Boolean; -- Flag5 function Must_Be_Byte_Aligned (N : Node_Id) return Boolean; -- Flag14 function Must_Not_Freeze (N : Node_Id) return Boolean; -- Flag8 function Name (N : Node_Id) return Node_Id; -- Node2 function Names (N : Node_Id) return List_Id; -- List2 function Next_Entity (N : Node_Id) return Node_Id; -- Node2 function Next_Named_Actual (N : Node_Id) return Node_Id; -- Node4 function Next_Rep_Item (N : Node_Id) return Node_Id; -- Node4 function Next_Use_Clause (N : Node_Id) return Node_Id; -- Node3 function No_Ctrl_Actions (N : Node_Id) return Boolean; -- Flag7 function No_Elaboration_Check (N : Node_Id) return Boolean; -- Flag14 function No_Entities_Ref_In_Spec (N : Node_Id) return Boolean; -- Flag8 function No_Initialization (N : Node_Id) return Boolean; -- Flag13 function No_Truncation (N : Node_Id) return Boolean; -- Flag17 function Null_Present (N : Node_Id) return Boolean; -- Flag13 function Null_Exclusion_Present (N : Node_Id) return Boolean; -- Flag9 function Null_Record_Present (N : Node_Id) return Boolean; -- Flag17 function Object_Definition (N : Node_Id) return Node_Id; -- Node4 function OK_For_Stream (N : Node_Id) return Boolean; -- Flag4 function Original_Discriminant (N : Node_Id) return Node_Id; -- Node2 function Original_Entity (N : Node_Id) return Entity_Id; -- Node2 function Others_Discrete_Choices (N : Node_Id) return List_Id; -- List1 function Out_Present (N : Node_Id) return Boolean; -- Flag17 function Parameter_Associations (N : Node_Id) return List_Id; -- List3 function Parameter_List_Truncated (N : Node_Id) return Boolean; -- Flag17 function Parameter_Specifications (N : Node_Id) return List_Id; -- List3 function Parameter_Type (N : Node_Id) return Node_Id; -- Node2 function Parent_Spec (N : Node_Id) return Node_Id; -- Node4 function Position (N : Node_Id) return Node_Id; -- Node2 function Pragma_Argument_Associations (N : Node_Id) return List_Id; -- List2 function Pragmas_After (N : Node_Id) return List_Id; -- List5 function Pragmas_Before (N : Node_Id) return List_Id; -- List4 function Prefix (N : Node_Id) return Node_Id; -- Node3 function Present_Expr (N : Node_Id) return Uint; -- Uint3 function Prev_Ids (N : Node_Id) return Boolean; -- Flag6 function Print_In_Hex (N : Node_Id) return Boolean; -- Flag13 function Private_Declarations (N : Node_Id) return List_Id; -- List3 function Private_Present (N : Node_Id) return Boolean; -- Flag15 function Procedure_To_Call (N : Node_Id) return Node_Id; -- Node4 function Proper_Body (N : Node_Id) return Node_Id; -- Node1 function Protected_Definition (N : Node_Id) return Node_Id; -- Node3 function Protected_Present (N : Node_Id) return Boolean; -- Flag15 function Raises_Constraint_Error (N : Node_Id) return Boolean; -- Flag7 function Range_Constraint (N : Node_Id) return Node_Id; -- Node4 function Range_Expression (N : Node_Id) return Node_Id; -- Node4 function Real_Range_Specification (N : Node_Id) return Node_Id; -- Node4 function Realval (N : Node_Id) return Ureal; -- Ureal3 function Reason (N : Node_Id) return Uint; -- Uint3 function Record_Extension_Part (N : Node_Id) return Node_Id; -- Node3 function Redundant_Use (N : Node_Id) return Boolean; -- Flag13 function Return_Type (N : Node_Id) return Node_Id; -- Node2 function Reverse_Present (N : Node_Id) return Boolean; -- Flag15 function Right_Opnd (N : Node_Id) return Node_Id; -- Node3 function Rounded_Result (N : Node_Id) return Boolean; -- Flag18 function Scope (N : Node_Id) return Node_Id; -- Node3 function Select_Alternatives (N : Node_Id) return List_Id; -- List1 function Selector_Name (N : Node_Id) return Node_Id; -- Node2 function Selector_Names (N : Node_Id) return List_Id; -- List1 function Shift_Count_OK (N : Node_Id) return Boolean; -- Flag4 function Source_Type (N : Node_Id) return Entity_Id; -- Node1 function Specification (N : Node_Id) return Node_Id; -- Node1 function Statements (N : Node_Id) return List_Id; -- List3 function Static_Processing_OK (N : Node_Id) return Boolean; -- Flag4 function Storage_Pool (N : Node_Id) return Node_Id; -- Node1 function Strval (N : Node_Id) return String_Id; -- Str3 function Subtype_Indication (N : Node_Id) return Node_Id; -- Node5 function Subtype_Mark (N : Node_Id) return Node_Id; -- Node4 function Subtype_Marks (N : Node_Id) return List_Id; -- List2 function Tagged_Present (N : Node_Id) return Boolean; -- Flag15 function Target_Type (N : Node_Id) return Entity_Id; -- Node2 function Task_Body_Procedure (N : Node_Id) return Entity_Id; -- Node2 function Task_Definition (N : Node_Id) return Node_Id; -- Node3 function Then_Actions (N : Node_Id) return List_Id; -- List2 function Then_Statements (N : Node_Id) return List_Id; -- List2 function Treat_Fixed_As_Integer (N : Node_Id) return Boolean; -- Flag14 function Triggering_Alternative (N : Node_Id) return Node_Id; -- Node1 function Triggering_Statement (N : Node_Id) return Node_Id; -- Node1 function TSS_Elist (N : Node_Id) return Elist_Id; -- Elist3 function Type_Definition (N : Node_Id) return Node_Id; -- Node3 function Unit (N : Node_Id) return Node_Id; -- Node2 function Unknown_Discriminants_Present (N : Node_Id) return Boolean; -- Flag13 function Unreferenced_In_Spec (N : Node_Id) return Boolean; -- Flag7 function Variant_Part (N : Node_Id) return Node_Id; -- Node4 function Variants (N : Node_Id) return List_Id; -- List1 function Visible_Declarations (N : Node_Id) return List_Id; -- List2 function Was_Originally_Stub (N : Node_Id) return Boolean; -- Flag13 function Zero_Cost_Handling (N : Node_Id) return Boolean; -- Flag5 -- End functions (note used by xsinfo utility program to end processing) ---------------------------- -- Node Update Procedures -- ---------------------------- -- These are the corresponding node update routines, which again provide -- a high level logical access with type checking. In addition to setting -- the indicated field of the node N to the given Val, in the case of -- tree pointers (List1-4), the parent pointer of the Val node is set to -- point back to node N. This automates the setting of the parent pointer. procedure Set_ABE_Is_Certain (N : Node_Id; Val : Boolean := True); -- Flag18 procedure Set_Abort_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Abortable_Part (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Abstract_Present (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Accept_Handler_Records (N : Node_Id; Val : List_Id); -- List5 procedure Set_Accept_Statement (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Access_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Access_To_Subprogram_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Access_Types_To_Process (N : Node_Id; Val : Elist_Id); -- Elist2 procedure Set_Actions (N : Node_Id; Val : List_Id); -- List1 procedure Set_Activation_Chain_Entity (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Acts_As_Spec (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Aggregate_Bounds (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Aliased_Present (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_All_Others (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_All_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Alternatives (N : Node_Id; Val : List_Id); -- List4 procedure Set_Ancestor_Part (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Array_Aggregate (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Assignment_OK (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Associated_Node (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Attribute_Name (N : Node_Id; Val : Name_Id); -- Name2 procedure Set_At_End_Proc (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Aux_Decls_Node (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Backwards_OK (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Bad_Is_Detected (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Body_Required (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Body_To_Inline (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Box_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_By_Ref (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_Char_Literal_Value (N : Node_Id; Val : Uint); -- Uint2 procedure Set_Chars (N : Node_Id; Val : Name_Id); -- Name1 procedure Set_Check_Address_Alignment (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Choice_Parameter (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Choices (N : Node_Id; Val : List_Id); -- List1 procedure Set_Compile_Time_Known_Aggregate (N : Node_Id; Val : Boolean := True); -- Flag18 procedure Set_Component_Associations (N : Node_Id; Val : List_Id); -- List2 procedure Set_Component_Clauses (N : Node_Id; Val : List_Id); -- List3 procedure Set_Component_Definition (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Component_Items (N : Node_Id; Val : List_Id); -- List3 procedure Set_Component_List (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Component_Name (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Condition (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Condition_Actions (N : Node_Id; Val : List_Id); -- List3 procedure Set_Config_Pragmas (N : Node_Id; Val : List_Id); -- List4 procedure Set_Constant_Present (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Constraint (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Constraints (N : Node_Id; Val : List_Id); -- List1 procedure Set_Context_Installed (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Context_Items (N : Node_Id; Val : List_Id); -- List1 procedure Set_Controlling_Argument (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Conversion_OK (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Corresponding_Body (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Corresponding_Formal_Spec (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Corresponding_Generic_Association (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Corresponding_Integer_Value (N : Node_Id; Val : Uint); -- Uint4 procedure Set_Corresponding_Spec (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Corresponding_Stub (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Dcheck_Function (N : Node_Id; Val : Entity_Id); -- Node5 procedure Set_Debug_Statement (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Declarations (N : Node_Id; Val : List_Id); -- List2 procedure Set_Default_Expression (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Default_Name (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Defining_Identifier (N : Node_Id; Val : Entity_Id); -- Node1 procedure Set_Defining_Unit_Name (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Delay_Alternative (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Delay_Finalize_Attach (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Delay_Statement (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Delta_Expression (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Digits_Expression (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Discr_Check_Funcs_Built (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Discrete_Choices (N : Node_Id; Val : List_Id); -- List4 procedure Set_Discrete_Range (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Discrete_Subtype_Definition (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Discrete_Subtype_Definitions (N : Node_Id; Val : List_Id); -- List2 procedure Set_Discriminant_Specifications (N : Node_Id; Val : List_Id); -- List4 procedure Set_Discriminant_Type (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Do_Accessibility_Check (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Do_Discriminant_Check (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Do_Division_Check (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Do_Length_Check (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Do_Overflow_Check (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Do_Range_Check (N : Node_Id; Val : Boolean := True); -- Flag9 procedure Set_Do_Storage_Check (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Do_Tag_Check (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Elaborate_All_Present (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Elaborate_Present (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Elaboration_Boolean (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Else_Actions (N : Node_Id; Val : List_Id); -- List3 procedure Set_Else_Statements (N : Node_Id; Val : List_Id); -- List4 procedure Set_Elsif_Parts (N : Node_Id; Val : List_Id); -- List3 procedure Set_Enclosing_Variant (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_End_Label (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_End_Span (N : Node_Id; Val : Uint); -- Uint5 procedure Set_Entity (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Entry_Body_Formal_Part (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Entry_Call_Alternative (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Entry_Call_Statement (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Entry_Direct_Name (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Entry_Index (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Entry_Index_Specification (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Etype (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Exception_Choices (N : Node_Id; Val : List_Id); -- List4 procedure Set_Exception_Handlers (N : Node_Id; Val : List_Id); -- List5 procedure Set_Exception_Junk (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Expansion_Delayed (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Explicit_Actual_Parameter (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Explicit_Generic_Actual_Parameter (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Expression (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Expressions (N : Node_Id; Val : List_Id); -- List1 procedure Set_First_Bit (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_First_Inlined_Subprogram (N : Node_Id; Val : Entity_Id); -- Node3 procedure Set_First_Name (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_First_Named_Actual (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_First_Real_Statement (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_First_Subtype_Link (N : Node_Id; Val : Entity_Id); -- Node5 procedure Set_Float_Truncate (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Formal_Type_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Forwards_OK (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_From_At_Mod (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_From_Default (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Generic_Associations (N : Node_Id; Val : List_Id); -- List3 procedure Set_Generic_Formal_Declarations (N : Node_Id; Val : List_Id); -- List2 procedure Set_Generic_Parent (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Generic_Parent_Type (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Handled_Statement_Sequence (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Handler_List_Entry (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Has_Created_Identifier (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Has_Dynamic_Length_Check (N : Node_Id; Val : Boolean := True); -- Flag10 procedure Set_Has_Dynamic_Range_Check (N : Node_Id; Val : Boolean := True); -- Flag12 procedure Set_Has_No_Elaboration_Code (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Has_Priority_Pragma (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Has_Private_View (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Has_Storage_Size_Pragma (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_Has_Task_Info_Pragma (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_Has_Task_Name_Pragma (N : Node_Id; Val : Boolean := True); -- Flag8 procedure Set_Has_Wide_Character (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Hidden_By_Use_Clause (N : Node_Id; Val : Elist_Id); -- Elist4 procedure Set_High_Bound (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Identifier (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Implicit_With (N : Node_Id; Val : Boolean := True); -- Flag16 procedure Set_In_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Includes_Infinities (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Instance_Spec (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Intval (N : Node_Id; Val : Uint); -- Uint3 procedure Set_Is_Asynchronous_Call_Block (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_Is_Component_Left_Opnd (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Is_Component_Right_Opnd (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Is_Controlling_Actual (N : Node_Id; Val : Boolean := True); -- Flag16 procedure Set_Is_In_Discriminant_Check (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Is_Machine_Number (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Is_Null_Loop (N : Node_Id; Val : Boolean := True); -- Flag16 procedure Set_Is_Overloaded (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_Is_Power_Of_2_For_Shift (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Is_Protected_Subprogram_Body (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_Is_Static_Expression (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Is_Subprogram_Descriptor (N : Node_Id; Val : Boolean := True); -- Flag16 procedure Set_Is_Task_Allocation_Block (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Is_Task_Master (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_Iteration_Scheme (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Itype (N : Node_Id; Val : Entity_Id); -- Node1 procedure Set_Kill_Range_Check (N : Node_Id; Val : Boolean := True); -- Flag11 procedure Set_Last_Bit (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Last_Name (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Library_Unit (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Label_Construct (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Left_Opnd (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Limited_View_Installed (N : Node_Id; Val : Boolean := True); -- Flag18 procedure Set_Limited_Present (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Literals (N : Node_Id; Val : List_Id); -- List1 procedure Set_Loop_Actions (N : Node_Id; Val : List_Id); -- List2 procedure Set_Loop_Parameter_Specification (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Low_Bound (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Mod_Clause (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_More_Ids (N : Node_Id; Val : Boolean := True); -- Flag5 procedure Set_Must_Be_Byte_Aligned (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Must_Not_Freeze (N : Node_Id; Val : Boolean := True); -- Flag8 procedure Set_Name (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Names (N : Node_Id; Val : List_Id); -- List2 procedure Set_Next_Entity (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Next_Named_Actual (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Next_Rep_Item (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Next_Use_Clause (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_No_Ctrl_Actions (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_No_Elaboration_Check (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_No_Entities_Ref_In_Spec (N : Node_Id; Val : Boolean := True); -- Flag8 procedure Set_No_Initialization (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_No_Truncation (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Null_Present (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Null_Exclusion_Present (N : Node_Id; Val : Boolean := True); -- Flag9 procedure Set_Null_Record_Present (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Object_Definition (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_OK_For_Stream (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Original_Discriminant (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Original_Entity (N : Node_Id; Val : Entity_Id); -- Node2 procedure Set_Others_Discrete_Choices (N : Node_Id; Val : List_Id); -- List1 procedure Set_Out_Present (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Parameter_Associations (N : Node_Id; Val : List_Id); -- List3 procedure Set_Parameter_List_Truncated (N : Node_Id; Val : Boolean := True); -- Flag17 procedure Set_Parameter_Specifications (N : Node_Id; Val : List_Id); -- List3 procedure Set_Parameter_Type (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Parent_Spec (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Position (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Pragma_Argument_Associations (N : Node_Id; Val : List_Id); -- List2 procedure Set_Pragmas_After (N : Node_Id; Val : List_Id); -- List5 procedure Set_Pragmas_Before (N : Node_Id; Val : List_Id); -- List4 procedure Set_Prefix (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Present_Expr (N : Node_Id; Val : Uint); -- Uint3 procedure Set_Prev_Ids (N : Node_Id; Val : Boolean := True); -- Flag6 procedure Set_Print_In_Hex (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Private_Declarations (N : Node_Id; Val : List_Id); -- List3 procedure Set_Private_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Procedure_To_Call (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Proper_Body (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Protected_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Protected_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Raises_Constraint_Error (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_Range_Constraint (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Range_Expression (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Real_Range_Specification (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Realval (N : Node_Id; Val : Ureal); -- Ureal3 procedure Set_Reason (N : Node_Id; Val : Uint); -- Uint3 procedure Set_Record_Extension_Part (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Redundant_Use (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Return_Type (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Reverse_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Right_Opnd (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Rounded_Result (N : Node_Id; Val : Boolean := True); -- Flag18 procedure Set_Scope (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Select_Alternatives (N : Node_Id; Val : List_Id); -- List1 procedure Set_Selector_Name (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Selector_Names (N : Node_Id; Val : List_Id); -- List1 procedure Set_Shift_Count_OK (N : Node_Id; Val : Boolean := True); -- Flag4 procedure Set_Source_Type (N : Node_Id; Val : Entity_Id); -- Node1 procedure Set_Specification (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Statements (N : Node_Id; Val : List_Id); -- List3 procedure Set_Static_Processing_OK (N : Node_Id; Val : Boolean); -- Flag4 procedure Set_Storage_Pool (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Strval (N : Node_Id; Val : String_Id); -- Str3 procedure Set_Subtype_Indication (N : Node_Id; Val : Node_Id); -- Node5 procedure Set_Subtype_Mark (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Subtype_Marks (N : Node_Id; Val : List_Id); -- List2 procedure Set_Tagged_Present (N : Node_Id; Val : Boolean := True); -- Flag15 procedure Set_Target_Type (N : Node_Id; Val : Entity_Id); -- Node2 procedure Set_Task_Body_Procedure (N : Node_Id; Val : Entity_Id); -- Node2 procedure Set_Task_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Then_Actions (N : Node_Id; Val : List_Id); -- List2 procedure Set_Then_Statements (N : Node_Id; Val : List_Id); -- List2 procedure Set_Treat_Fixed_As_Integer (N : Node_Id; Val : Boolean := True); -- Flag14 procedure Set_Triggering_Alternative (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_Triggering_Statement (N : Node_Id; Val : Node_Id); -- Node1 procedure Set_TSS_Elist (N : Node_Id; Val : Elist_Id); -- Elist3 procedure Set_Type_Definition (N : Node_Id; Val : Node_Id); -- Node3 procedure Set_Unit (N : Node_Id; Val : Node_Id); -- Node2 procedure Set_Unknown_Discriminants_Present (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Unreferenced_In_Spec (N : Node_Id; Val : Boolean := True); -- Flag7 procedure Set_Variant_Part (N : Node_Id; Val : Node_Id); -- Node4 procedure Set_Variants (N : Node_Id; Val : List_Id); -- List1 procedure Set_Visible_Declarations (N : Node_Id; Val : List_Id); -- List2 procedure Set_Was_Originally_Stub (N : Node_Id; Val : Boolean := True); -- Flag13 procedure Set_Zero_Cost_Handling (N : Node_Id; Val : Boolean := True); -- Flag5 ------------------------- -- Iterator Procedures -- ------------------------- -- The call to Next_xxx (N) is equivalent to N := Next_xxx (N) procedure Next_Entity (N : in out Node_Id); procedure Next_Named_Actual (N : in out Node_Id); procedure Next_Rep_Item (N : in out Node_Id); procedure Next_Use_Clause (N : in out Node_Id); -------------------------------------- -- Logical Access to End_Span Field -- -------------------------------------- function End_Location (N : Node_Id) return Source_Ptr; -- N is an N_If_Statement or N_Case_Statement node, and this -- function returns the location of the IF token in the END IF -- sequence by translating the value of the End_Span field. procedure Set_End_Location (N : Node_Id; S : Source_Ptr); -- N is an N_If_Statement or N_Case_Statement node. This procedure -- sets the End_Span field to correspond to the given value S. In -- other words, End_Span is set to the difference between S and -- Sloc (N), the starting location. -------------------- -- Inline Pragmas -- -------------------- pragma Inline (ABE_Is_Certain); pragma Inline (Abort_Present); pragma Inline (Abortable_Part); pragma Inline (Abstract_Present); pragma Inline (Accept_Handler_Records); pragma Inline (Accept_Statement); pragma Inline (Access_Definition); pragma Inline (Access_To_Subprogram_Definition); pragma Inline (Access_Types_To_Process); pragma Inline (Actions); pragma Inline (Activation_Chain_Entity); pragma Inline (Acts_As_Spec); pragma Inline (Aggregate_Bounds); pragma Inline (Aliased_Present); pragma Inline (All_Others); pragma Inline (All_Present); pragma Inline (Alternatives); pragma Inline (Ancestor_Part); pragma Inline (Array_Aggregate); pragma Inline (Assignment_OK); pragma Inline (Associated_Node); pragma Inline (At_End_Proc); pragma Inline (Attribute_Name); pragma Inline (Aux_Decls_Node); pragma Inline (Backwards_OK); pragma Inline (Bad_Is_Detected); pragma Inline (Body_To_Inline); pragma Inline (Body_Required); pragma Inline (By_Ref); pragma Inline (Box_Present); pragma Inline (Char_Literal_Value); pragma Inline (Chars); pragma Inline (Check_Address_Alignment); pragma Inline (Choice_Parameter); pragma Inline (Choices); pragma Inline (Compile_Time_Known_Aggregate); pragma Inline (Component_Associations); pragma Inline (Component_Clauses); pragma Inline (Component_Definition); pragma Inline (Component_Items); pragma Inline (Component_List); pragma Inline (Component_Name); pragma Inline (Condition); pragma Inline (Condition_Actions); pragma Inline (Config_Pragmas); pragma Inline (Constant_Present); pragma Inline (Constraint); pragma Inline (Constraints); pragma Inline (Context_Installed); pragma Inline (Context_Items); pragma Inline (Controlling_Argument); pragma Inline (Conversion_OK); pragma Inline (Corresponding_Body); pragma Inline (Corresponding_Formal_Spec); pragma Inline (Corresponding_Generic_Association); pragma Inline (Corresponding_Integer_Value); pragma Inline (Corresponding_Spec); pragma Inline (Corresponding_Stub); pragma Inline (Dcheck_Function); pragma Inline (Debug_Statement); pragma Inline (Declarations); pragma Inline (Default_Expression); pragma Inline (Default_Name); pragma Inline (Defining_Identifier); pragma Inline (Defining_Unit_Name); pragma Inline (Delay_Alternative); pragma Inline (Delay_Finalize_Attach); pragma Inline (Delay_Statement); pragma Inline (Delta_Expression); pragma Inline (Digits_Expression); pragma Inline (Discr_Check_Funcs_Built); pragma Inline (Discrete_Choices); pragma Inline (Discrete_Range); pragma Inline (Discrete_Subtype_Definition); pragma Inline (Discrete_Subtype_Definitions); pragma Inline (Discriminant_Specifications); pragma Inline (Discriminant_Type); pragma Inline (Do_Accessibility_Check); pragma Inline (Do_Discriminant_Check); pragma Inline (Do_Length_Check); pragma Inline (Do_Division_Check); pragma Inline (Do_Overflow_Check); pragma Inline (Do_Range_Check); pragma Inline (Do_Storage_Check); pragma Inline (Do_Tag_Check); pragma Inline (Elaborate_Present); pragma Inline (Elaborate_All_Present); pragma Inline (Elaboration_Boolean); pragma Inline (Else_Actions); pragma Inline (Else_Statements); pragma Inline (Elsif_Parts); pragma Inline (Enclosing_Variant); pragma Inline (End_Label); pragma Inline (End_Span); pragma Inline (Entity); pragma Inline (Entity_Or_Associated_Node); pragma Inline (Entry_Body_Formal_Part); pragma Inline (Entry_Call_Alternative); pragma Inline (Entry_Call_Statement); pragma Inline (Entry_Direct_Name); pragma Inline (Entry_Index); pragma Inline (Entry_Index_Specification); pragma Inline (Etype); pragma Inline (Exception_Choices); pragma Inline (Exception_Junk); pragma Inline (Exception_Handlers); pragma Inline (Expansion_Delayed); pragma Inline (Explicit_Actual_Parameter); pragma Inline (Explicit_Generic_Actual_Parameter); pragma Inline (Expression); pragma Inline (Expressions); pragma Inline (First_Bit); pragma Inline (First_Inlined_Subprogram); pragma Inline (First_Name); pragma Inline (First_Named_Actual); pragma Inline (First_Real_Statement); pragma Inline (First_Subtype_Link); pragma Inline (Float_Truncate); pragma Inline (Formal_Type_Definition); pragma Inline (Forwards_OK); pragma Inline (From_At_Mod); pragma Inline (From_Default); pragma Inline (Generic_Associations); pragma Inline (Generic_Formal_Declarations); pragma Inline (Generic_Parent); pragma Inline (Generic_Parent_Type); pragma Inline (Handled_Statement_Sequence); pragma Inline (Handler_List_Entry); pragma Inline (Has_Created_Identifier); pragma Inline (Has_Dynamic_Length_Check); pragma Inline (Has_Dynamic_Range_Check); pragma Inline (Has_No_Elaboration_Code); pragma Inline (Has_Priority_Pragma); pragma Inline (Has_Private_View); pragma Inline (Has_Storage_Size_Pragma); pragma Inline (Has_Task_Info_Pragma); pragma Inline (Has_Task_Name_Pragma); pragma Inline (Has_Wide_Character); pragma Inline (Hidden_By_Use_Clause); pragma Inline (High_Bound); pragma Inline (Identifier); pragma Inline (Implicit_With); pragma Inline (Includes_Infinities); pragma Inline (In_Present); pragma Inline (Instance_Spec); pragma Inline (Intval); pragma Inline (Is_Asynchronous_Call_Block); pragma Inline (Is_Component_Left_Opnd); pragma Inline (Is_Component_Right_Opnd); pragma Inline (Is_Controlling_Actual); pragma Inline (Is_In_Discriminant_Check); pragma Inline (Is_Machine_Number); pragma Inline (Is_Null_Loop); pragma Inline (Is_Overloaded); pragma Inline (Is_Power_Of_2_For_Shift); pragma Inline (Is_Protected_Subprogram_Body); pragma Inline (Is_Static_Expression); pragma Inline (Is_Subprogram_Descriptor); pragma Inline (Is_Task_Allocation_Block); pragma Inline (Is_Task_Master); pragma Inline (Iteration_Scheme); pragma Inline (Itype); pragma Inline (Kill_Range_Check); pragma Inline (Last_Bit); pragma Inline (Last_Name); pragma Inline (Library_Unit); pragma Inline (Label_Construct); pragma Inline (Left_Opnd); pragma Inline (Limited_View_Installed); pragma Inline (Limited_Present); pragma Inline (Literals); pragma Inline (Loop_Actions); pragma Inline (Loop_Parameter_Specification); pragma Inline (Low_Bound); pragma Inline (Mod_Clause); pragma Inline (More_Ids); pragma Inline (Must_Be_Byte_Aligned); pragma Inline (Must_Not_Freeze); pragma Inline (Name); pragma Inline (Names); pragma Inline (Next_Entity); pragma Inline (Next_Named_Actual); pragma Inline (Next_Rep_Item); pragma Inline (Next_Use_Clause); pragma Inline (No_Ctrl_Actions); pragma Inline (No_Elaboration_Check); pragma Inline (No_Entities_Ref_In_Spec); pragma Inline (No_Initialization); pragma Inline (No_Truncation); pragma Inline (Null_Present); pragma Inline (Null_Exclusion_Present); pragma Inline (Null_Record_Present); pragma Inline (Object_Definition); pragma Inline (OK_For_Stream); pragma Inline (Original_Discriminant); pragma Inline (Original_Entity); pragma Inline (Others_Discrete_Choices); pragma Inline (Out_Present); pragma Inline (Parameter_Associations); pragma Inline (Parameter_Specifications); pragma Inline (Parameter_List_Truncated); pragma Inline (Parameter_Type); pragma Inline (Parent_Spec); pragma Inline (Position); pragma Inline (Pragma_Argument_Associations); pragma Inline (Pragmas_After); pragma Inline (Pragmas_Before); pragma Inline (Prefix); pragma Inline (Present_Expr); pragma Inline (Prev_Ids); pragma Inline (Print_In_Hex); pragma Inline (Private_Declarations); pragma Inline (Private_Present); pragma Inline (Procedure_To_Call); pragma Inline (Proper_Body); pragma Inline (Protected_Definition); pragma Inline (Protected_Present); pragma Inline (Raises_Constraint_Error); pragma Inline (Range_Constraint); pragma Inline (Range_Expression); pragma Inline (Real_Range_Specification); pragma Inline (Realval); pragma Inline (Reason); pragma Inline (Record_Extension_Part); pragma Inline (Redundant_Use); pragma Inline (Return_Type); pragma Inline (Reverse_Present); pragma Inline (Right_Opnd); pragma Inline (Rounded_Result); pragma Inline (Scope); pragma Inline (Select_Alternatives); pragma Inline (Selector_Name); pragma Inline (Selector_Names); pragma Inline (Shift_Count_OK); pragma Inline (Source_Type); pragma Inline (Specification); pragma Inline (Statements); pragma Inline (Static_Processing_OK); pragma Inline (Storage_Pool); pragma Inline (Strval); pragma Inline (Subtype_Indication); pragma Inline (Subtype_Mark); pragma Inline (Subtype_Marks); pragma Inline (Tagged_Present); pragma Inline (Target_Type); pragma Inline (Task_Body_Procedure); pragma Inline (Task_Definition); pragma Inline (Then_Actions); pragma Inline (Then_Statements); pragma Inline (Triggering_Alternative); pragma Inline (Triggering_Statement); pragma Inline (Treat_Fixed_As_Integer); pragma Inline (TSS_Elist); pragma Inline (Type_Definition); pragma Inline (Unit); pragma Inline (Unknown_Discriminants_Present); pragma Inline (Unreferenced_In_Spec); pragma Inline (Variant_Part); pragma Inline (Variants); pragma Inline (Visible_Declarations); pragma Inline (Was_Originally_Stub); pragma Inline (Zero_Cost_Handling); pragma Inline (Set_ABE_Is_Certain); pragma Inline (Set_Abort_Present); pragma Inline (Set_Abortable_Part); pragma Inline (Set_Abstract_Present); pragma Inline (Set_Accept_Handler_Records); pragma Inline (Set_Accept_Statement); pragma Inline (Set_Access_Definition); pragma Inline (Set_Access_To_Subprogram_Definition); pragma Inline (Set_Access_Types_To_Process); pragma Inline (Set_Actions); pragma Inline (Set_Activation_Chain_Entity); pragma Inline (Set_Acts_As_Spec); pragma Inline (Set_Aggregate_Bounds); pragma Inline (Set_Aliased_Present); pragma Inline (Set_All_Others); pragma Inline (Set_All_Present); pragma Inline (Set_Alternatives); pragma Inline (Set_Ancestor_Part); pragma Inline (Set_Array_Aggregate); pragma Inline (Set_Assignment_OK); pragma Inline (Set_Associated_Node); pragma Inline (Set_At_End_Proc); pragma Inline (Set_Attribute_Name); pragma Inline (Set_Aux_Decls_Node); pragma Inline (Set_Backwards_OK); pragma Inline (Set_Bad_Is_Detected); pragma Inline (Set_Body_To_Inline); pragma Inline (Set_Body_Required); pragma Inline (Set_By_Ref); pragma Inline (Set_Box_Present); pragma Inline (Set_Char_Literal_Value); pragma Inline (Set_Chars); pragma Inline (Set_Check_Address_Alignment); pragma Inline (Set_Choice_Parameter); pragma Inline (Set_Choices); pragma Inline (Set_Compile_Time_Known_Aggregate); pragma Inline (Set_Component_Associations); pragma Inline (Set_Component_Clauses); pragma Inline (Set_Component_Definition); pragma Inline (Set_Component_Items); pragma Inline (Set_Component_List); pragma Inline (Set_Component_Name); pragma Inline (Set_Condition); pragma Inline (Set_Condition_Actions); pragma Inline (Set_Config_Pragmas); pragma Inline (Set_Constant_Present); pragma Inline (Set_Constraint); pragma Inline (Set_Constraints); pragma Inline (Set_Context_Installed); pragma Inline (Set_Context_Items); pragma Inline (Set_Controlling_Argument); pragma Inline (Set_Conversion_OK); pragma Inline (Set_Corresponding_Body); pragma Inline (Set_Corresponding_Formal_Spec); pragma Inline (Set_Corresponding_Generic_Association); pragma Inline (Set_Corresponding_Integer_Value); pragma Inline (Set_Corresponding_Spec); pragma Inline (Set_Corresponding_Stub); pragma Inline (Set_Dcheck_Function); pragma Inline (Set_Debug_Statement); pragma Inline (Set_Declarations); pragma Inline (Set_Default_Expression); pragma Inline (Set_Default_Name); pragma Inline (Set_Defining_Identifier); pragma Inline (Set_Defining_Unit_Name); pragma Inline (Set_Delay_Alternative); pragma Inline (Set_Delay_Finalize_Attach); pragma Inline (Set_Delay_Statement); pragma Inline (Set_Delta_Expression); pragma Inline (Set_Digits_Expression); pragma Inline (Set_Discr_Check_Funcs_Built); pragma Inline (Set_Discrete_Choices); pragma Inline (Set_Discrete_Range); pragma Inline (Set_Discrete_Subtype_Definition); pragma Inline (Set_Discrete_Subtype_Definitions); pragma Inline (Set_Discriminant_Specifications); pragma Inline (Set_Discriminant_Type); pragma Inline (Set_Do_Accessibility_Check); pragma Inline (Set_Do_Discriminant_Check); pragma Inline (Set_Do_Length_Check); pragma Inline (Set_Do_Division_Check); pragma Inline (Set_Do_Overflow_Check); pragma Inline (Set_Do_Range_Check); pragma Inline (Set_Do_Storage_Check); pragma Inline (Set_Do_Tag_Check); pragma Inline (Set_Elaborate_Present); pragma Inline (Set_Elaborate_All_Present); pragma Inline (Set_Elaboration_Boolean); pragma Inline (Set_Else_Actions); pragma Inline (Set_Else_Statements); pragma Inline (Set_Elsif_Parts); pragma Inline (Set_Enclosing_Variant); pragma Inline (Set_End_Label); pragma Inline (Set_End_Span); pragma Inline (Set_Entity); pragma Inline (Set_Entry_Body_Formal_Part); pragma Inline (Set_Entry_Call_Alternative); pragma Inline (Set_Entry_Call_Statement); pragma Inline (Set_Entry_Direct_Name); pragma Inline (Set_Entry_Index); pragma Inline (Set_Entry_Index_Specification); pragma Inline (Set_Etype); pragma Inline (Set_Exception_Choices); pragma Inline (Set_Exception_Junk); pragma Inline (Set_Exception_Handlers); pragma Inline (Set_Expansion_Delayed); pragma Inline (Set_Explicit_Actual_Parameter); pragma Inline (Set_Explicit_Generic_Actual_Parameter); pragma Inline (Set_Expression); pragma Inline (Set_Expressions); pragma Inline (Set_First_Bit); pragma Inline (Set_First_Inlined_Subprogram); pragma Inline (Set_First_Name); pragma Inline (Set_First_Named_Actual); pragma Inline (Set_First_Real_Statement); pragma Inline (Set_First_Subtype_Link); pragma Inline (Set_Float_Truncate); pragma Inline (Set_Formal_Type_Definition); pragma Inline (Set_Forwards_OK); pragma Inline (Set_From_At_Mod); pragma Inline (Set_From_Default); pragma Inline (Set_Generic_Associations); pragma Inline (Set_Generic_Formal_Declarations); pragma Inline (Set_Generic_Parent); pragma Inline (Set_Generic_Parent_Type); pragma Inline (Set_Handled_Statement_Sequence); pragma Inline (Set_Handler_List_Entry); pragma Inline (Set_Has_Created_Identifier); pragma Inline (Set_Has_Dynamic_Length_Check); pragma Inline (Set_Has_Dynamic_Range_Check); pragma Inline (Set_Has_No_Elaboration_Code); pragma Inline (Set_Has_Priority_Pragma); pragma Inline (Set_Has_Private_View); pragma Inline (Set_Has_Storage_Size_Pragma); pragma Inline (Set_Has_Task_Info_Pragma); pragma Inline (Set_Has_Task_Name_Pragma); pragma Inline (Set_Has_Wide_Character); pragma Inline (Set_Hidden_By_Use_Clause); pragma Inline (Set_High_Bound); pragma Inline (Set_Identifier); pragma Inline (Set_Implicit_With); pragma Inline (Set_Includes_Infinities); pragma Inline (Set_In_Present); pragma Inline (Set_Instance_Spec); pragma Inline (Set_Intval); pragma Inline (Set_Is_Asynchronous_Call_Block); pragma Inline (Set_Is_Component_Left_Opnd); pragma Inline (Set_Is_Component_Right_Opnd); pragma Inline (Set_Is_Controlling_Actual); pragma Inline (Set_Is_In_Discriminant_Check); pragma Inline (Set_Is_Machine_Number); pragma Inline (Set_Is_Null_Loop); pragma Inline (Set_Is_Overloaded); pragma Inline (Set_Is_Power_Of_2_For_Shift); pragma Inline (Set_Is_Protected_Subprogram_Body); pragma Inline (Set_Is_Static_Expression); pragma Inline (Set_Is_Subprogram_Descriptor); pragma Inline (Set_Is_Task_Allocation_Block); pragma Inline (Set_Is_Task_Master); pragma Inline (Set_Iteration_Scheme); pragma Inline (Set_Itype); pragma Inline (Set_Kill_Range_Check); pragma Inline (Set_Last_Bit); pragma Inline (Set_Last_Name); pragma Inline (Set_Library_Unit); pragma Inline (Set_Label_Construct); pragma Inline (Set_Left_Opnd); pragma Inline (Set_Limited_View_Installed); pragma Inline (Set_Limited_Present); pragma Inline (Set_Literals); pragma Inline (Set_Loop_Actions); pragma Inline (Set_Loop_Parameter_Specification); pragma Inline (Set_Low_Bound); pragma Inline (Set_Mod_Clause); pragma Inline (Set_More_Ids); pragma Inline (Set_Must_Be_Byte_Aligned); pragma Inline (Set_Must_Not_Freeze); pragma Inline (Set_Name); pragma Inline (Set_Names); pragma Inline (Set_Next_Entity); pragma Inline (Set_Next_Named_Actual); pragma Inline (Set_Next_Use_Clause); pragma Inline (Set_No_Ctrl_Actions); pragma Inline (Set_No_Elaboration_Check); pragma Inline (Set_No_Entities_Ref_In_Spec); pragma Inline (Set_No_Initialization); pragma Inline (Set_No_Truncation); pragma Inline (Set_Null_Present); pragma Inline (Set_Null_Exclusion_Present); pragma Inline (Set_Null_Record_Present); pragma Inline (Set_Object_Definition); pragma Inline (Set_OK_For_Stream); pragma Inline (Set_Original_Discriminant); pragma Inline (Set_Original_Entity); pragma Inline (Set_Others_Discrete_Choices); pragma Inline (Set_Out_Present); pragma Inline (Set_Parameter_Associations); pragma Inline (Set_Parameter_Specifications); pragma Inline (Set_Parameter_List_Truncated); pragma Inline (Set_Parameter_Type); pragma Inline (Set_Parent_Spec); pragma Inline (Set_Position); pragma Inline (Set_Pragma_Argument_Associations); pragma Inline (Set_Pragmas_After); pragma Inline (Set_Pragmas_Before); pragma Inline (Set_Prefix); pragma Inline (Set_Present_Expr); pragma Inline (Set_Prev_Ids); pragma Inline (Set_Print_In_Hex); pragma Inline (Set_Private_Declarations); pragma Inline (Set_Private_Present); pragma Inline (Set_Procedure_To_Call); pragma Inline (Set_Proper_Body); pragma Inline (Set_Protected_Definition); pragma Inline (Set_Protected_Present); pragma Inline (Set_Raises_Constraint_Error); pragma Inline (Set_Range_Constraint); pragma Inline (Set_Range_Expression); pragma Inline (Set_Real_Range_Specification); pragma Inline (Set_Realval); pragma Inline (Set_Reason); pragma Inline (Set_Record_Extension_Part); pragma Inline (Set_Redundant_Use); pragma Inline (Set_Return_Type); pragma Inline (Set_Reverse_Present); pragma Inline (Set_Right_Opnd); pragma Inline (Set_Rounded_Result); pragma Inline (Set_Scope); pragma Inline (Set_Select_Alternatives); pragma Inline (Set_Selector_Name); pragma Inline (Set_Selector_Names); pragma Inline (Set_Shift_Count_OK); pragma Inline (Set_Source_Type); pragma Inline (Set_Specification); pragma Inline (Set_Statements); pragma Inline (Set_Static_Processing_OK); pragma Inline (Set_Storage_Pool); pragma Inline (Set_Strval); pragma Inline (Set_Subtype_Indication); pragma Inline (Set_Subtype_Mark); pragma Inline (Set_Subtype_Marks); pragma Inline (Set_Tagged_Present); pragma Inline (Set_Target_Type); pragma Inline (Set_Task_Body_Procedure); pragma Inline (Set_Task_Definition); pragma Inline (Set_Then_Actions); pragma Inline (Set_Then_Statements); pragma Inline (Set_Triggering_Alternative); pragma Inline (Set_Triggering_Statement); pragma Inline (Set_Treat_Fixed_As_Integer); pragma Inline (Set_TSS_Elist); pragma Inline (Set_Type_Definition); pragma Inline (Set_Unit); pragma Inline (Set_Unknown_Discriminants_Present); pragma Inline (Set_Unreferenced_In_Spec); pragma Inline (Set_Variant_Part); pragma Inline (Set_Variants); pragma Inline (Set_Visible_Declarations); pragma Inline (Set_Was_Originally_Stub); pragma Inline (Set_Zero_Cost_Handling); end Sinfo;