path: root/gcc/ada/bindo-graphs.adb

------------------------------------------------------------------------------
--                                                                          --
--                         GNAT COMPILER COMPONENTS                         --
--                                                                          --
--                         B I N D O . G R A P H S                          --
--                                                                          --
--                                 B o d y                                  --
--                                                                          --
--             Copyright (C) 2019-2024, Free Software Foundation, Inc.      --
--                                                                          --
-- GNAT is free software;  you can  redistribute it  and/or modify it under --
-- terms of the  GNU General Public License as published  by the Free Soft- --
-- ware  Foundation;  either version 3,  or (at your option) any later ver- --
-- sion.  GNAT is distributed in the hope that it will be useful, but WITH- --
-- OUT ANY WARRANTY;  without even the  implied warranty of MERCHANTABILITY --
-- or FITNESS FOR A PARTICULAR PURPOSE.  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 COPYING3.  If not, go to --
-- http://www.gnu.org/licenses for a complete copy of the license.          --
--                                                                          --
-- GNAT was originally developed  by the GNAT team at  New York University. --
-- Extensive contributions were provided by Ada Core Technologies Inc.      --
--                                                                          --
------------------------------------------------------------------------------

with Ada.Unchecked_Deallocation;

with Butil;  use Butil;
with Debug;  use Debug;
with Output; use Output;

with Bindo.Writers;
use  Bindo.Writers;
use  Bindo.Writers.Phase_Writers;

package body Bindo.Graphs is

   -----------------------
   -- Local subprograms --
   -----------------------

   function Sequence_Next_Cycle return Library_Graph_Cycle_Id;
   pragma Inline (Sequence_Next_Cycle);
   --  Generate a new unique library graph cycle handle

   function Sequence_Next_Edge return Invocation_Graph_Edge_Id;
   pragma Inline (Sequence_Next_Edge);
   --  Generate a new unique invocation graph edge handle

   function Sequence_Next_Edge return Library_Graph_Edge_Id;
   pragma Inline (Sequence_Next_Edge);
   --  Generate a new unique library graph edge handle

   function Sequence_Next_Vertex return Invocation_Graph_Vertex_Id;
   pragma Inline (Sequence_Next_Vertex);
   --  Generate a new unique invocation graph vertex handle

   function Sequence_Next_Vertex return Library_Graph_Vertex_Id;
   pragma Inline (Sequence_Next_Vertex);
   --  Generate a new unique library graph vertex handle

   -----------------------------------
   -- Destroy_Invocation_Graph_Edge --
   -----------------------------------

   procedure Destroy_Invocation_Graph_Edge
     (Edge : in out Invocation_Graph_Edge_Id)
   is
      pragma Unreferenced (Edge);
   begin
      null;
   end Destroy_Invocation_Graph_Edge;

   ---------------------------------
   -- Destroy_Library_Graph_Cycle --
   ---------------------------------

   procedure Destroy_Library_Graph_Cycle
     (Cycle : in out Library_Graph_Cycle_Id)
   is
      pragma Unreferenced (Cycle);
   begin
      null;
   end Destroy_Library_Graph_Cycle;

   --------------------------------
   -- Destroy_Library_Graph_Edge --
   --------------------------------

   procedure Destroy_Library_Graph_Edge
     (Edge : in out Library_Graph_Edge_Id)
   is
      pragma Unreferenced (Edge);
   begin
      null;
   end Destroy_Library_Graph_Edge;

   ----------------------------------
   -- Destroy_Library_Graph_Vertex --
   ----------------------------------

   procedure Destroy_Library_Graph_Vertex
     (Vertex : in out Library_Graph_Vertex_Id)
   is
      pragma Unreferenced (Vertex);
   begin
      null;
   end Destroy_Library_Graph_Vertex;

   --------------------------------
   -- Hash_Invocation_Graph_Edge --
   --------------------------------

   function Hash_Invocation_Graph_Edge
     (Edge : Invocation_Graph_Edge_Id) return Bucket_Range_Type
   is
   begin
      pragma Assert (Present (Edge));

      return Bucket_Range_Type (Edge);
   end Hash_Invocation_Graph_Edge;

   ----------------------------------
   -- Hash_Invocation_Graph_Vertex --
   ----------------------------------

   function Hash_Invocation_Graph_Vertex
     (Vertex : Invocation_Graph_Vertex_Id) return Bucket_Range_Type
   is
   begin
      pragma Assert (Present (Vertex));

      return Bucket_Range_Type (Vertex);
   end Hash_Invocation_Graph_Vertex;

   ------------------------------
   -- Hash_Library_Graph_Cycle --
   ------------------------------

   function Hash_Library_Graph_Cycle
     (Cycle : Library_Graph_Cycle_Id) return Bucket_Range_Type
   is
   begin
      pragma Assert (Present (Cycle));

      return Bucket_Range_Type (Cycle);
   end Hash_Library_Graph_Cycle;

   -----------------------------
   -- Hash_Library_Graph_Edge --
   -----------------------------

   function Hash_Library_Graph_Edge
     (Edge : Library_Graph_Edge_Id) return Bucket_Range_Type
   is
   begin
      pragma Assert (Present (Edge));

      return Bucket_Range_Type (Edge);
   end Hash_Library_Graph_Edge;

   -------------------------------
   -- Hash_Library_Graph_Vertex --
   -------------------------------

   function Hash_Library_Graph_Vertex
     (Vertex : Library_Graph_Vertex_Id) return Bucket_Range_Type
   is
   begin
      pragma Assert (Present (Vertex));

      return Bucket_Range_Type (Vertex);
   end Hash_Library_Graph_Vertex;

   --------------------
   -- Library_Graphs --
   --------------------

   package body Library_Graphs is

      -----------------------
      -- Local subprograms --
      -----------------------

      procedure Add_Body_Before_Spec_Edge
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Edges  : LGE_Lists.Doubly_Linked_List);
      pragma Inline (Add_Body_Before_Spec_Edge);
      --  Create a new edge in library graph G between vertex Vertex and its
      --  corresponding spec or body, where the body is a predecessor and the
      --  spec a successor. Add the edge to list Edges.

      procedure Add_Body_Before_Spec_Edges
        (G     : Library_Graph;
         Edges : LGE_Lists.Doubly_Linked_List);
      pragma Inline (Add_Body_Before_Spec_Edges);
      --  Create new edges in library graph G for all vertices and their
      --  corresponding specs or bodies, where the body is a predecessor
      --  and the spec is a successor. Add all edges to list Edges.

      procedure Add_Edge_Kind_Check
        (G              : Library_Graph;
         Pred           : Library_Graph_Vertex_Id;
         Succ           : Library_Graph_Vertex_Id;
         New_Kind       : Library_Graph_Edge_Kind);
      --  This is called by Add_Edge in the case where there is already a
      --  Pred-->Succ edge, to assert that the New_Kind is appropriate. Raises
      --  Program_Error if a bug is detected. The purpose is to prevent bugs
      --  where calling Add_Edge in different orders produces different output.

      function Add_Edge
        (G              : Library_Graph;
         Pred           : Library_Graph_Vertex_Id;
         Succ           : Library_Graph_Vertex_Id;
         Kind           : Library_Graph_Edge_Kind;
         Activates_Task : Boolean) return Library_Graph_Edge_Id;
      pragma Inline (Add_Edge);
      --  Create a new edge in library graph G with source vertex Pred and
      --  destination vertex Succ, and return its handle. Kind denotes the
      --  nature of the edge. Activates_Task should be set when the edge
      --  involves a task activation. If Pred and Succ are already related,
      --  no edge is created and No_Library_Graph_Edge is returned, but if
      --  Activates_Task is True, then the flag of the existing edge is
      --  updated.

      function At_Least_One_Edge_Satisfies
        (G         : Library_Graph;
         Cycle     : Library_Graph_Cycle_Id;
         Predicate : LGE_Predicate_Ptr) return Boolean;
      pragma Inline (At_Least_One_Edge_Satisfies);
      --  Determine whether at least one edge of cycle Cycle of library graph G
      --  satisfies predicate Predicate.

      function Copy_Cycle_Path
        (Cycle_Path : LGE_Lists.Doubly_Linked_List)
         return LGE_Lists.Doubly_Linked_List;
      pragma Inline (Copy_Cycle_Path);
      --  Create a deep copy of list Cycle_Path

      function Cycle_End_Vertices
        (G                    : Library_Graph;
         Vertex               : Library_Graph_Vertex_Id;
         Elaborate_All_Active : Boolean) return LGV_Sets.Membership_Set;
      pragma Inline (Cycle_End_Vertices);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Collect the vertices that terminate a cycle starting
      --  from vertex Vertex of library graph G in a set. This is usually the
      --  vertex itself, unless the vertex is part of an Elaborate_Body pair,
      --  or flag Elaborate_All_Active is set. In that case the complementary
      --  vertex is also added to the set.

      function Cycle_Kind_Of
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Cycle_Kind;
      pragma Inline (Cycle_Kind_Of);
      --  Determine the cycle kind of edge Edge of library graph G if the edge
      --  participated in a circuit.

      function Cycle_Kind_Precedence
        (Kind        : Library_Graph_Cycle_Kind;
         Compared_To : Library_Graph_Cycle_Kind) return Precedence_Kind;
      pragma Inline (Cycle_Kind_Precedence);
      --  Determine the precedence of cycle kind Kind compared to cycle kind
      --  Compared_To.

      function Cycle_Path_Precedence
        (G           : Library_Graph;
         Path        : LGE_Lists.Doubly_Linked_List;
         Compared_To : LGE_Lists.Doubly_Linked_List) return Precedence_Kind;
      pragma Inline (Cycle_Path_Precedence);
      --  Determine the precedence of cycle path Path of library graph G
      --  compared to path Compared_To.

      function Cycle_Precedence
        (G           : Library_Graph;
         Cycle       : Library_Graph_Cycle_Id;
         Compared_To : Library_Graph_Cycle_Id) return Precedence_Kind;
      pragma Inline (Cycle_Precedence);
      --  Determine the precedence of cycle Cycle of library graph G compared
      --  to cycle Compared_To.

      procedure Decrement_Library_Graph_Edge_Count
        (G    : Library_Graph;
         Kind : Library_Graph_Edge_Kind);
      pragma Inline (Decrement_Library_Graph_Edge_Count);
      --  Decrement the number of edges of kind King in library graph G by one

      procedure Delete_Body_Before_Spec_Edges
        (G     : Library_Graph;
         Edges : LGE_Lists.Doubly_Linked_List);
      pragma Inline (Delete_Body_Before_Spec_Edges);
      --  Delete all edges in list Edges from library graph G, that link spec
      --  and bodies, where the body acts as the predecessor and the spec as a
      --  successor.

      procedure Delete_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id);
      pragma Inline (Delete_Edge);
      --  Delete edge Edge from library graph G

      function Edge_Precedence
        (G           : Library_Graph;
         Edge        : Library_Graph_Edge_Id;
         Compared_To : Library_Graph_Edge_Id) return Precedence_Kind;
      pragma Inline (Edge_Precedence);
      --  Determine the precedence of edge Edge of library graph G compared to
      --  edge Compared_To.

      procedure Find_Cycles_From_Successor
        (G                     : Library_Graph;
         Edge                  : Library_Graph_Edge_Id;
         End_Vertices          : LGV_Sets.Membership_Set;
         Deleted_Vertices      : LGV_Sets.Membership_Set;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path_Stack      : LGE_Lists.Doubly_Linked_List;
         Visited_Set           : LGV_Sets.Membership_Set;
         Visited_Stack         : LGV_Lists.Doubly_Linked_List;
         Cycle_Count           : in out Natural;
         Cycle_Limit           : Natural;
         Elaborate_All_Active  : Boolean;
         Has_Cycle             : out Boolean;
         Indent                : Indentation_Level);
      pragma Inline (Find_Cycles_From_Successor);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Find all cycles from the successor indicated by edge
      --  Edge of library graph G. If at least one cycle exists, set Has_Cycle
      --  to True. The remaining parameters are as follows:
      --
      --    * End vertices is the set of vertices that terminate a potential
      --      cycle.
      --
      --    * Deleted vertices is the set of vertices that have been expanded
      --      during previous depth-first searches and should not be visited
      --      for the rest of the algorithm.
      --
      --    * Most_Significant_Edge is the current highest-precedence edge on
      --      the path of the potential cycle.
      --
      --    * Invocation_Edge_Count is the number of invocation edges on the
      --      path of the potential cycle.
      --
      --    * Cycle_Path_Stack is the path of the potential cycle.
      --
      --    * Visited_Set is the set of vertices that have been visited during
      --      the current depth-first search.
      --
      --    * Visited_Stack maintains the vertices of Visited_Set in a stack
      --      for later unvisiting.
      --
      --    * Cycle_Count is the number of cycles discovered so far.
      --
      --    * Cycle_Limit is the upper bound of the number of cycles to be
      --      discovered.
      --
      --    * Elaborate_All_Active should be set when the component currently
      --      being examined for cycles contains an Elaborate_All edge.
      --
      --    * Indent in the desired indentation level for tracing.

      procedure Find_Cycles_From_Vertex
        (G                     : Library_Graph;
         Vertex                : Library_Graph_Vertex_Id;
         End_Vertices          : LGV_Sets.Membership_Set;
         Deleted_Vertices      : LGV_Sets.Membership_Set;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path_Stack      : LGE_Lists.Doubly_Linked_List;
         Visited_Set           : LGV_Sets.Membership_Set;
         Visited_Stack         : LGV_Lists.Doubly_Linked_List;
         Cycle_Count           : in out Natural;
         Cycle_Limit           : Natural;
         Elaborate_All_Active  : Boolean;
         Is_Start_Vertex       : Boolean;
         Has_Cycle             : out Boolean;
         Indent                : Indentation_Level);
      pragma Inline (Find_Cycles_From_Vertex);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Find all cycles from vertex Vertex of library graph
      --  G. If at least one cycle exists, set Has_Cycle to True. The remaining
      --  parameters are as follows:
      --
      --    * End_Vertices is the set of vertices that terminate a potential
      --      cycle.
      --
      --    * Deleted_Vertices is the set of vertices that have been expanded
      --      during previous depth-first searches and should not be visited
      --      for the rest of the algorithm.
      --
      --    * Most_Significant_Edge is the current highest-precedence edge on
      --      the path of the potential cycle.
      --
      --    * Invocation_Edge_Count is the number of invocation edges on the
      --      path of the potential cycle.
      --
      --    * Cycle_Path_Stack is the path of the potential cycle.
      --
      --    * Visited_Set is the set of vertices that have been visited during
      --      the current depth-first search.
      --
      --    * Visited_Stack maintains the vertices of Visited_Set in a stack
      --      for later unvisiting.
      --
      --    * Cycle_Count is the number of cycles discovered so far.
      --
      --    * Cycle_Limit is the upper bound of the number of cycles to be
      --      discovered.
      --
      --    * Elaborate_All_Active should be set when the component currently
      --      being examined for cycles contains an Elaborate_All edge.
      --
      --    * Indent in the desired indentation level for tracing.

      procedure Find_Cycles_In_Component
        (G           : Library_Graph;
         Comp        : Component_Id;
         Cycle_Count : in out Natural;
         Cycle_Limit : Natural);
      pragma Inline (Find_Cycles_In_Component);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Find all cycles in component Comp of library graph
      --  G. The remaining parameters are as follows:
      --
      --    * Cycle_Count is the number of cycles discovered so far.
      --
      --    * Cycle_Limit is the upper bound of the number of cycles to be
      --      discovered.

      function Find_Edge
        (G    : Library_Graph;
         Pred : Library_Graph_Vertex_Id;
         Succ : Library_Graph_Vertex_Id) return Library_Graph_Edge_Id;
      --  There must be an edge Pred-->Succ; this returns it

      function Find_First_Lower_Precedence_Cycle
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Library_Graph_Cycle_Id;
      pragma Inline (Find_First_Lower_Precedence_Cycle);
      --  Inspect the list of cycles of library graph G and return the first
      --  cycle whose precedence is lower than that of cycle Cycle. If there
      --  is no such cycle, return No_Library_Graph_Cycle.

      procedure Free is
        new Ada.Unchecked_Deallocation
              (Library_Graph_Attributes, Library_Graph);

      function Get_Component_Attributes
        (G    : Library_Graph;
         Comp : Component_Id) return Component_Attributes;
      pragma Inline (Get_Component_Attributes);
      --  Obtain the attributes of component Comp of library graph G

      function Get_LGC_Attributes
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Library_Graph_Cycle_Attributes;
      pragma Inline (Get_LGC_Attributes);
      --  Obtain the attributes of cycle Cycle of library graph G

      function Get_LGE_Attributes
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id)
         return Library_Graph_Edge_Attributes;
      pragma Inline (Get_LGE_Attributes);
      --  Obtain the attributes of edge Edge of library graph G

      function Get_LGV_Attributes
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id)
         return Library_Graph_Vertex_Attributes;
      pragma Inline (Get_LGV_Attributes);
      --  Obtain the attributes of vertex Edge of library graph G

      function Has_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean;
      pragma Inline (Has_Elaborate_Body);
      --  Determine whether vertex Vertex of library graph G is subject to
      --  pragma Elaborate_Body.

      function Has_Elaborate_All_Edge
        (G    : Library_Graph;
         Comp : Component_Id) return Boolean;
      pragma Inline (Has_Elaborate_All_Edge);
      --  Determine whether component Comp of library graph G contains an
      --  Elaborate_All edge that links two vertices in the same component.

      function Has_Elaborate_All_Edge
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean;
      pragma Inline (Has_Elaborate_All_Edge);
      --  Determine whether vertex Vertex of library graph G contains an
      --  Elaborate_All edge to a successor where both the vertex and the
      --  successor reside in the same component.

      function Highest_Precedence_Edge
        (G     : Library_Graph;
         Left  : Library_Graph_Edge_Id;
         Right : Library_Graph_Edge_Id) return Library_Graph_Edge_Id;
      pragma Inline (Highest_Precedence_Edge);
      --  Return the edge with highest precedence among edges Left and Right of
      --  library graph G.

      procedure Increment_Library_Graph_Edge_Count
        (G    : Library_Graph;
         Kind : Library_Graph_Edge_Kind);
      pragma Inline (Increment_Library_Graph_Edge_Count);
      --  Increment the number of edges of king Kind in library graph G by one

      procedure Increment_Pending_Predecessors
        (G    : Library_Graph;
         Comp : Component_Id;
         Edge : Library_Graph_Edge_Id);
      pragma Inline (Increment_Pending_Predecessors);
      --  Increment the number of pending predecessors component Comp which was
      --  reached via edge Edge of library graph G must wait on before it can
      --  be elaborated by one.

      procedure Increment_Pending_Predecessors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Edge   : Library_Graph_Edge_Id);
      pragma Inline (Increment_Pending_Predecessors);
      --  Increment the number of pending predecessors vertex Vertex which was
      --  reached via edge Edge of library graph G must wait on before it can
      --  be elaborated by one.

      procedure Initialize_Components (G : Library_Graph);
      pragma Inline (Initialize_Components);
      --  Initialize on the initial call or re-initialize on subsequent calls
      --  all components of library graph G.

      function Is_Cycle_Initiating_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cycle_Initiating_Edge);
      --  Determine whether edge Edge of library graph G starts a cycle

      function Is_Cyclic_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle.

      function Is_Cyclic_Elaborate_All_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Elaborate_All_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and has a predecessor that is subject to pragma Elaborate_All.

      function Is_Cyclic_Elaborate_Body_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Elaborate_Body_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and has a successor that is either a spec subject to pragma
      --  Elaborate_Body, or a body that completes such a spec.

      function Is_Cyclic_Elaborate_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Elaborate_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and has a predecessor that is subject to pragma Elaborate.

      function Is_Cyclic_Forced_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Forced_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and came from the forced-elaboration-order file.

      function Is_Cyclic_Invocation_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_Invocation_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and came from the traversal of the invocation graph.

      function Is_Cyclic_With_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Cyclic_With_Edge);
      --  Determine whether edge Edge of library graph G participates in a
      --  cycle and is the result of a with dependency between its successor
      --  and predecessor.

      function Is_Recorded_Edge
        (G   : Library_Graph;
         Rel : Predecessor_Successor_Relation) return Boolean;
      pragma Inline (Is_Recorded_Edge);
      --  Determine whether a predecessor vertex and a successor vertex
      --  described by relation Rel are already linked in library graph G.

      function Is_Static_Successor_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Is_Static_Successor_Edge);
      --  Determine whether the successor of invocation edge Edge represents a
      --  unit that was compiled with the static model.

      function Is_Vertex_With_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean;
      pragma Inline (Is_Vertex_With_Elaborate_Body);
      --  Determine whether vertex Vertex of library graph G denotes a spec
      --  subject to pragma Elaborate_Body or the completing body of such a
      --  spec.

      function Links_Vertices_In_Same_Component
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean;
      pragma Inline (Links_Vertices_In_Same_Component);
      --  Determine whether edge Edge of library graph G links a predecessor
      --  and successor that reside in the same component.

      function Maximum_Invocation_Edge_Count
        (G     : Library_Graph;
         Edge  : Library_Graph_Edge_Id;
         Count : Natural) return Natural;
      pragma Inline (Maximum_Invocation_Edge_Count);
      --  Determine whether edge Edge of library graph G is an invocation edge,
      --  and if it is return Count + 1, otherwise return Count.

      procedure Normalize_Cycle_Path
        (Cycle_Path            : LGE_Lists.Doubly_Linked_List;
         Most_Significant_Edge : Library_Graph_Edge_Id);
      pragma Inline (Normalize_Cycle_Path);
      --  Normalize cycle path Path by rotating it until its starting edge is
      --  Sig_Edge.

      procedure Order_Cycle
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id);
      pragma Inline (Order_Cycle);
      --  Insert cycle Cycle in library graph G and sort it based on its
      --  precedence relative to all recorded cycles.

      function Path
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return LGE_Lists.Doubly_Linked_List;
      pragma Inline (Path);
      --  Obtain the path of edges which comprises cycle Cycle of library
      --  graph G.

      procedure Record_Cycle
        (G                     : Library_Graph;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path            : LGE_Lists.Doubly_Linked_List;
         Indent                : Indentation_Level);
      pragma Inline (Record_Cycle);
      --  Normalize a cycle described by its path Cycle_Path and add it to
      --  library graph G. Most_Significant_Edge denotes the edge with the
      --  highest significance along the cycle path. Invocation_Edge_Count
      --  is the number of invocation edges along the cycle path. Indent is
      --  the desired indentation level for tracing.

      procedure Set_Activates_Task
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id);
      --  Set the Activates_Task flag of the Edge to True

      procedure Set_Component_Attributes
        (G    : Library_Graph;
         Comp : Component_Id;
         Val  : Component_Attributes);
      pragma Inline (Set_Component_Attributes);
      --  Set the attributes of component Comp of library graph G to value Val

      procedure Set_Corresponding_Vertex
        (G    : Library_Graph;
         U_Id : Unit_Id;
         Val  : Library_Graph_Vertex_Id);
      pragma Inline (Set_Corresponding_Vertex);
      --  Associate vertex Val of library graph G with unit U_Id

      procedure Set_Is_Recorded_Edge
        (G   : Library_Graph;
         Rel : Predecessor_Successor_Relation);
      pragma Inline (Set_Is_Recorded_Edge);
      --  Mark a predecessor vertex and a successor vertex described by
      --  relation Rel as already linked.

      procedure Set_LGC_Attributes
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id;
         Val   : Library_Graph_Cycle_Attributes);
      pragma Inline (Set_LGC_Attributes);
      --  Set the attributes of cycle Cycle of library graph G to value Val

      procedure Set_LGE_Attributes
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id;
         Val  : Library_Graph_Edge_Attributes);
      pragma Inline (Set_LGE_Attributes);
      --  Set the attributes of edge Edge of library graph G to value Val

      procedure Set_LGV_Attributes
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Val    : Library_Graph_Vertex_Attributes);
      pragma Inline (Set_LGV_Attributes);
      --  Set the attributes of vertex Vertex of library graph G to value Val

      procedure Trace_Component
        (G      : Library_Graph;
         Comp   : Component_Id;
         Indent : Indentation_Level);
      pragma Inline (Trace_Component);
      --  Write the contents of component Comp of library graph G to standard
      --  output. Indent is the desired indentation level for tracing.

      procedure Trace_Cycle
        (G      : Library_Graph;
         Cycle  : Library_Graph_Cycle_Id;
         Indent : Indentation_Level);
      pragma Inline (Trace_Cycle);
      --  Write the contents of cycle Cycle of library graph G to standard
      --  output. Indent is the desired indentation level for tracing.

      procedure Trace_Edge
        (G      : Library_Graph;
         Edge   : Library_Graph_Edge_Id;
         Indent : Indentation_Level);
      pragma Inline (Trace_Edge);
      --  Write the contents of edge Edge of library graph G to standard
      --  output. Indent is the desired indentation level for tracing.

      procedure Trace_Vertex
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Indent : Indentation_Level);
      pragma Inline (Trace_Vertex);
      --  Write the contents of vertex Vertex of library graph G to standard
      --  output. Indent is the desired indentation level for tracing.

      procedure Unvisit
        (Vertex        : Library_Graph_Vertex_Id;
         Visited_Set   : LGV_Sets.Membership_Set;
         Visited_Stack : LGV_Lists.Doubly_Linked_List);
      pragma Inline (Unvisit);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Unwind the Visited_Stack by removing the top vertex
      --  from set Visited_Set until vertex Vertex is reached, inclusive.

      procedure Update_Pending_Predecessors
        (Strong_Predecessors : in out Natural;
         Weak_Predecessors   : in out Natural;
         Update_Weak         : Boolean;
         Value               : Integer);
      pragma Inline (Update_Pending_Predecessors);
      --  Update the number of pending strong or weak predecessors denoted by
      --  Strong_Predecessors and Weak_Predecessors respectively depending on
      --  flag Update_Weak by adding value Value.

      procedure Update_Pending_Predecessors_Of_Components (G : Library_Graph);
      pragma Inline (Update_Pending_Predecessors_Of_Components);
      --  Update the number of pending predecessors all components of library
      --  graph G must wait on before they can be elaborated.

      procedure Update_Pending_Predecessors_Of_Components
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id);
      pragma Inline (Update_Pending_Predecessors_Of_Components);
      --  Update the number of pending predecessors the component of edge
      --  LGE_Is's successor vertex of library graph G must wait on before
      --  it can be elaborated.

      function Vertex_Precedence
        (G           : Library_Graph;
         Vertex      : Library_Graph_Vertex_Id;
         Compared_To : Library_Graph_Vertex_Id) return Precedence_Kind;
      pragma Inline (Vertex_Precedence);
      --  Determine the precedence of vertex Vertex of library graph G compared
      --  to vertex Compared_To.

      procedure Visit
        (Vertex        : Library_Graph_Vertex_Id;
         Visited_Set   : LGV_Sets.Membership_Set;
         Visited_Stack : LGV_Lists.Doubly_Linked_List);
      pragma Inline (Visit);
      --  Part of Tarjan's enumeration of the elementary circuits of a directed
      --  graph algorithm. Push vertex Vertex on the Visited_Stack and add it
      --  to set Visited_Set.

      --------------------
      -- Activates_Task --
      --------------------

      function Activates_Task
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         return Get_LGE_Attributes (G, Edge).Activates_Task;
      end Activates_Task;

      -------------------------------
      -- Add_Body_Before_Spec_Edge --
      -------------------------------

      procedure Add_Body_Before_Spec_Edge
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Edges  : LGE_Lists.Doubly_Linked_List)
      is
         Edge : Library_Graph_Edge_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));
         pragma Assert (LGE_Lists.Present (Edges));

         --  A vertex requires a special Body_Before_Spec edge to its
         --  Corresponding_Item when it either denotes a
         --
         --    * Body that completes a previous spec
         --
         --    * Spec with a completing body
         --
         --  The edge creates an intentional circularity between the spec and
         --  body in order to emulate a library unit, and guarantees that both
         --  will appear in the same component.
         --
         --  Due to the structure of the library graph, either the spec or
         --  the body may be visited first, yet Corresponding_Item will still
         --  attempt to create the Body_Before_Spec edge. This is OK because
         --  successor and predecessor are kept consistent in both cases, and
         --  Add_Edge will prevent the creation of the second edge.

         --  Assume that no Body_Before_Spec is necessary

         Edge := No_Library_Graph_Edge;

         --  A body that completes a previous spec

         if Is_Body_With_Spec (G, Vertex) then
            Edge :=
              Add_Edge
                (G              => G,
                 Pred           => Vertex,
                 Succ           => Corresponding_Item (G, Vertex),
                 Kind           => Body_Before_Spec_Edge,
                 Activates_Task => False);

         --  A spec with a completing body

         elsif Is_Spec_With_Body (G, Vertex) then
            Edge :=
              Add_Edge
                (G              => G,
                 Pred           => Corresponding_Item (G, Vertex),
                 Succ           => Vertex,
                 Kind           => Body_Before_Spec_Edge,
                 Activates_Task => False);
         end if;

         if Present (Edge) then
            LGE_Lists.Append (Edges, Edge);
         end if;
      end Add_Body_Before_Spec_Edge;

      --------------------------------
      -- Add_Body_Before_Spec_Edges --
      --------------------------------

      procedure Add_Body_Before_Spec_Edges
        (G     : Library_Graph;
         Edges : LGE_Lists.Doubly_Linked_List)
      is
         Iter : Elaborable_Units_Iterator;
         U_Id : Unit_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (LGE_Lists.Present (Edges));

         Iter := Iterate_Elaborable_Units;
         while Has_Next (Iter) loop
            Next (Iter, U_Id);

            Add_Body_Before_Spec_Edge
              (G      => G,
               Vertex => Corresponding_Vertex (G, U_Id),
               Edges  => Edges);
         end loop;
      end Add_Body_Before_Spec_Edges;

      --------------
      -- Add_Edge --
      --------------

      procedure Add_Edge
        (G              : Library_Graph;
         Pred           : Library_Graph_Vertex_Id;
         Succ           : Library_Graph_Vertex_Id;
         Kind           : Library_Graph_Edge_Kind;
         Activates_Task : Boolean)
      is
         Ignore : constant Library_Graph_Edge_Id :=
           Add_Edge
             (G              => G,
              Pred           => Pred,
              Succ           => Succ,
              Kind           => Kind,
              Activates_Task => Activates_Task);
      begin
         null;
      end Add_Edge;

      -------------------------
      -- Add_Edge_Kind_Check --
      -------------------------

      procedure Add_Edge_Kind_Check
        (G              : Library_Graph;
         Pred           : Library_Graph_Vertex_Id;
         Succ           : Library_Graph_Vertex_Id;
         New_Kind       : Library_Graph_Edge_Kind)
      is
         Old_Edge : constant Library_Graph_Edge_Id :=
           Find_Edge (G, Pred, Succ);
         Old_Kind : constant Library_Graph_Edge_Kind :=
           Get_LGE_Attributes (G, Old_Edge).Kind;
         OK : Boolean;
      begin
         case New_Kind is
            when Spec_Before_Body_Edge =>
               OK := False;
               --  Spec_Before_Body_Edge comes first, and there is never more
               --  than one Spec_Before_Body_Edge for a given unit, so we can't
               --  have a preexisting edge in the Spec_Before_Body_Edge case.

            when With_Edge | Elaborate_Edge | Elaborate_All_Edge
              | Forced_Edge | Invocation_Edge =>
               OK := Old_Kind <= New_Kind;
               --  These edges are created in the order of the enumeration
               --  type, and there can be duplicates; hence "<=".

            when Body_Before_Spec_Edge =>
               OK := Old_Kind = Body_Before_Spec_Edge
               --  We call Add_Edge with Body_Before_Spec_Edge twice -- once
               --  for the spec and once for the body.

                 or else Old_Kind = Forced_Edge
                 or else Old_Kind = Invocation_Edge;
               --  The old one can be Forced_Edge or Invocation_Edge, which
               --  necessarily results in an elaboration cycle (in the static
               --  model), but this assertion happens before cycle detection,
               --  so we need to allow these cases.

            when No_Edge =>
               OK := False;
         end case;

         if not OK then
            raise Program_Error with Old_Kind'Img & "-->" & New_Kind'Img;
         end if;
      end Add_Edge_Kind_Check;

      --------------
      -- Add_Edge --
      --------------

      function Add_Edge
        (G              : Library_Graph;
         Pred           : Library_Graph_Vertex_Id;
         Succ           : Library_Graph_Vertex_Id;
         Kind           : Library_Graph_Edge_Kind;
         Activates_Task : Boolean) return Library_Graph_Edge_Id
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Pred));
         pragma Assert (Present (Succ));
         pragma Assert (Kind = Invocation_Edge or else not Activates_Task);
         --  Only invocation edges can activate tasks

         Rel : constant Predecessor_Successor_Relation :=
           (Predecessor => Pred, Successor => Succ);

         Edge : Library_Graph_Edge_Id;

      begin
         --  If we already have a Pred-->Succ edge, we don't add another
         --  one. But we need to update Activates_Task, in order to avoid
         --  depending on the order of processing of edges. If we have
         --  Pred-->Succ with Activates_Task=True, and another Pred-->Succ with
         --  Activates_Task=False, we want Activates_Task to be True no matter
         --  which order we processed those two Add_Edge calls.

         if Is_Recorded_Edge (G, Rel) then
            pragma Debug (Add_Edge_Kind_Check (G, Pred, Succ, Kind));

            if Activates_Task then
               Set_Activates_Task (G, Find_Edge (G, Pred, Succ));
            end if;

            return No_Library_Graph_Edge;
         end if;

         Edge := Sequence_Next_Edge;

         --  Add the edge to the underlying graph. Note that the predecessor
         --  is the source of the edge because it will later need to notify
         --  all its successors that it has been elaborated.

         DG.Add_Edge
           (G           => G.Graph,
            E           => Edge,
            Source      => Pred,
            Destination => Succ);

         --  Construct and save the attributes of the edge

         Set_LGE_Attributes
           (G    => G,
            Edge => Edge,
            Val  =>
              (Activates_Task => Activates_Task,
               Kind           => Kind));

         --  Mark the predecessor and successor as related by the new edge.
         --  This prevents all further attempts to link the same predecessor
         --  and successor.

         Set_Is_Recorded_Edge (G, Rel);

         --  Update the number of pending predecessors the successor must wait
         --  on before it is elaborated.

         Increment_Pending_Predecessors
           (G      => G,
            Vertex => Succ,
            Edge   => Edge);

         --  Update the edge statistics

         Increment_Library_Graph_Edge_Count (G, Kind);

         return Edge;
      end Add_Edge;

      ----------------
      -- Add_Vertex --
      ----------------

      procedure Add_Vertex
        (G    : Library_Graph;
         U_Id : Unit_Id)
      is
         Vertex : Library_Graph_Vertex_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (U_Id));

         --  Nothing to do when the unit already has a vertex

         if Present (Corresponding_Vertex (G, U_Id)) then
            return;
         end if;

         Vertex := Sequence_Next_Vertex;

         --  Add the vertex to the underlying graph

         DG.Add_Vertex (G.Graph, Vertex);

         --  Construct and save the attributes of the vertex

         Set_LGV_Attributes
           (G      => G,
            Vertex => Vertex,
            Val    =>
              (Corresponding_Item          => No_Library_Graph_Vertex,
               In_Elaboration_Order        => False,
               Pending_Strong_Predecessors => 0,
               Pending_Weak_Predecessors   => 0,
               Unit                        => U_Id));

         --  Associate the unit with its corresponding vertex

         Set_Corresponding_Vertex (G, U_Id, Vertex);
      end Add_Vertex;

      ---------------------------------
      -- At_Least_One_Edge_Satisfies --
      ---------------------------------

      function At_Least_One_Edge_Satisfies
        (G         : Library_Graph;
         Cycle     : Library_Graph_Cycle_Id;
         Predicate : LGE_Predicate_Ptr) return Boolean
      is
         Edge      : Library_Graph_Edge_Id;
         Iter      : Edges_Of_Cycle_Iterator;
         Satisfied : Boolean;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));
         pragma Assert (Predicate /= null);

         --  Assume that the predicate cannot be satisfied

         Satisfied := False;

         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      edges of the cycle.

         Iter := Iterate_Edges_Of_Cycle (G, Cycle);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            Satisfied := Satisfied or else Predicate.all (G, Edge);
         end loop;

         return Satisfied;
      end At_Least_One_Edge_Satisfies;

      --------------------------
      -- Complementary_Vertex --
      --------------------------

      function Complementary_Vertex
        (G                : Library_Graph;
         Vertex           : Library_Graph_Vertex_Id;
         Force_Complement : Boolean) return Library_Graph_Vertex_Id
      is
         Complement : Library_Graph_Vertex_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         --  Assume that there is no complementary vertex

         Complement := No_Library_Graph_Vertex;

         --  The caller requests the complement explicitly

         if Force_Complement then
            Complement := Corresponding_Item (G, Vertex);

         --  The vertex is a completing body of a spec subject to pragma
         --  Elaborate_Body. The complementary vertex is the spec.

         elsif Is_Body_Of_Spec_With_Elaborate_Body (G, Vertex) then
            Complement := Proper_Spec (G, Vertex);

         --  The vertex is a spec subject to pragma Elaborate_Body. The
         --  complementary vertex is the body.

         elsif Is_Spec_With_Elaborate_Body (G, Vertex) then
            Complement := Proper_Body (G, Vertex);
         end if;

         return Complement;
      end Complementary_Vertex;

      ---------------
      -- Component --
      ---------------

      function Component
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Component_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return DG.Component (G.Graph, Vertex);
      end Component;

      ---------------------------------
      -- Contains_Elaborate_All_Edge --
      ---------------------------------

      function Contains_Elaborate_All_Edge
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return
           At_Least_One_Edge_Satisfies
             (G         => G,
              Cycle     => Cycle,
              Predicate => Is_Elaborate_All_Edge'Access);
      end Contains_Elaborate_All_Edge;

      ------------------------------------
      -- Contains_Static_Successor_Edge --
      ------------------------------------

      function Contains_Static_Successor_Edge
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return
           At_Least_One_Edge_Satisfies
             (G         => G,
              Cycle     => Cycle,
              Predicate => Is_Static_Successor_Edge'Access);
      end Contains_Static_Successor_Edge;

      ------------------------------
      -- Contains_Task_Activation --
      ------------------------------

      function Contains_Task_Activation
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return
           At_Least_One_Edge_Satisfies
             (G         => G,
              Cycle     => Cycle,
              Predicate => Activates_Task'Access);
      end Contains_Task_Activation;

      ---------------------
      -- Copy_Cycle_Path --
      ---------------------

      function Copy_Cycle_Path
        (Cycle_Path : LGE_Lists.Doubly_Linked_List)
         return LGE_Lists.Doubly_Linked_List
      is
         Edge : Library_Graph_Edge_Id;
         Iter : LGE_Lists.Iterator;
         Path : LGE_Lists.Doubly_Linked_List;

      begin
         pragma Assert (LGE_Lists.Present (Cycle_Path));

         Path := LGE_Lists.Create;
         Iter := LGE_Lists.Iterate (Cycle_Path);
         while LGE_Lists.Has_Next (Iter) loop
            LGE_Lists.Next (Iter, Edge);

            LGE_Lists.Append (Path, Edge);
         end loop;

         return Path;
      end Copy_Cycle_Path;

      ------------------------
      -- Corresponding_Item --
      ------------------------

      function Corresponding_Item
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_LGV_Attributes (G, Vertex).Corresponding_Item;
      end Corresponding_Item;

      --------------------------
      -- Corresponding_Vertex --
      --------------------------

      function Corresponding_Vertex
        (G    : Library_Graph;
         U_Id : Unit_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (U_Id));

         return Unit_Tables.Get (G.Unit_To_Vertex, U_Id);
      end Corresponding_Vertex;

      ------------
      -- Create --
      ------------

      function Create
        (Initial_Vertices : Positive;
         Initial_Edges    : Positive) return Library_Graph
      is
         G : constant Library_Graph := new Library_Graph_Attributes;

      begin
         G.Component_Attributes := Component_Tables.Create (Initial_Vertices);
         G.Cycle_Attributes     := LGC_Tables.Create       (Initial_Vertices);
         G.Cycles               := LGC_Lists.Create;
         G.Edge_Attributes      := LGE_Tables.Create       (Initial_Edges);
         G.Graph                :=
           DG.Create
             (Initial_Vertices => Initial_Vertices,
              Initial_Edges    => Initial_Edges);
         G.Recorded_Edges       := RE_Sets.Create          (Initial_Edges);
         G.Unit_To_Vertex       := Unit_Tables.Create      (Initial_Vertices);
         G.Vertex_Attributes    := LGV_Tables.Create       (Initial_Vertices);

         return G;
      end Create;

      ------------------------
      -- Cycle_End_Vertices --
      ------------------------

      function Cycle_End_Vertices
        (G                    : Library_Graph;
         Vertex               : Library_Graph_Vertex_Id;
         Elaborate_All_Active : Boolean) return LGV_Sets.Membership_Set
      is
         Complement   : Library_Graph_Vertex_Id;
         End_Vertices : LGV_Sets.Membership_Set := LGV_Sets.Nil;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         End_Vertices := LGV_Sets.Create (2);

         --  The input vertex always terminates a cycle path

         LGV_Sets.Insert (End_Vertices, Vertex);

         --  Add the complementary vertex to the set of cycle terminating
         --  vertices when either Elaborate_All is in effect, or the input
         --  vertex is part of an Elaborat_Body pair.

         if Elaborate_All_Active
           or else Is_Vertex_With_Elaborate_Body (G, Vertex)
         then
            Complement :=
              Complementary_Vertex
                (G                => G,
                 Vertex           => Vertex,
                 Force_Complement => Elaborate_All_Active);

            if Present (Complement) then
               LGV_Sets.Insert (End_Vertices, Complement);
            end if;
         end if;

         return End_Vertices;
      end Cycle_End_Vertices;

      -------------------
      -- Cycle_Kind_Of --
      -------------------

      function Cycle_Kind_Of
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Cycle_Kind
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

      begin
         if Is_Cyclic_Elaborate_All_Edge (G, Edge) then
            return Elaborate_All_Cycle;

         elsif Is_Cyclic_Elaborate_Body_Edge (G, Edge) then
            return Elaborate_Body_Cycle;

         elsif Is_Cyclic_Elaborate_Edge (G, Edge) then
            return Elaborate_Cycle;

         elsif Is_Cyclic_Forced_Edge (G, Edge) then
            return Forced_Cycle;

         elsif Is_Cyclic_Invocation_Edge (G, Edge) then
            return Invocation_Cycle;

         else
            return No_Cycle_Kind;
         end if;
      end Cycle_Kind_Of;

      ---------------------------
      -- Cycle_Kind_Precedence --
      ---------------------------

      function Cycle_Kind_Precedence
        (Kind        : Library_Graph_Cycle_Kind;
         Compared_To : Library_Graph_Cycle_Kind) return Precedence_Kind
      is
         Comp_Pos : constant Integer :=
                      Library_Graph_Cycle_Kind'Pos (Compared_To);
         Kind_Pos : constant Integer := Library_Graph_Cycle_Kind'Pos (Kind);

      begin
         --  A lower ordinal indicates a higher precedence

         if Kind_Pos < Comp_Pos then
            return Higher_Precedence;

         elsif Kind_Pos > Comp_Pos then
            return Lower_Precedence;

         else
            return Equal_Precedence;
         end if;
      end Cycle_Kind_Precedence;

      ---------------------------
      -- Cycle_Path_Precedence --
      ---------------------------

      function Cycle_Path_Precedence
        (G           : Library_Graph;
         Path        : LGE_Lists.Doubly_Linked_List;
         Compared_To : LGE_Lists.Doubly_Linked_List) return Precedence_Kind
      is
         procedure Next_Available
           (Iter : in out LGE_Lists.Iterator;
            Edge : out Library_Graph_Edge_Id);
         pragma Inline (Next_Available);
         --  Obtain the next edge available through iterator Iter, or return
         --  No_Library_Graph_Edge if the iterator has been exhausted.

         --------------------
         -- Next_Available --
         --------------------

         procedure Next_Available
           (Iter : in out LGE_Lists.Iterator;
            Edge : out Library_Graph_Edge_Id)
         is
         begin
            --  Assume that the iterator has been exhausted

            Edge := No_Library_Graph_Edge;

            if LGE_Lists.Has_Next (Iter) then
               LGE_Lists.Next (Iter, Edge);
            end if;
         end Next_Available;

         --  Local variables

         Comp_Edge : Library_Graph_Edge_Id;
         Comp_Iter : LGE_Lists.Iterator;
         Path_Edge : Library_Graph_Edge_Id;
         Path_Iter : LGE_Lists.Iterator;
         Prec      : Precedence_Kind;

      --  Start of processing for Cycle_Path_Precedence

      begin
         pragma Assert (Present (G));
         pragma Assert (LGE_Lists.Present (Path));
         pragma Assert (LGE_Lists.Present (Compared_To));

         --  Assume that the paths have equal precedence

         Prec := Equal_Precedence;

         Comp_Iter := LGE_Lists.Iterate (Compared_To);
         Path_Iter := LGE_Lists.Iterate (Path);

         Next_Available (Comp_Iter, Comp_Edge);
         Next_Available (Path_Iter, Path_Edge);

         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      edges of both paths.

         while Present (Comp_Edge) or else Present (Path_Edge) loop
            if Prec = Equal_Precedence
              and then Present (Comp_Edge)
              and then Present (Path_Edge)
            then
               Prec :=
                 Edge_Precedence
                   (G           => G,
                    Edge        => Path_Edge,
                    Compared_To => Comp_Edge);
            end if;

            Next_Available (Comp_Iter, Comp_Edge);
            Next_Available (Path_Iter, Path_Edge);
         end loop;

         return Prec;
      end Cycle_Path_Precedence;

      ----------------------
      -- Cycle_Precedence --
      ----------------------

      function Cycle_Precedence
        (G           : Library_Graph;
         Cycle       : Library_Graph_Cycle_Id;
         Compared_To : Library_Graph_Cycle_Id) return Precedence_Kind
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));
         pragma Assert (Present (Compared_To));

         Comp_Invs  : constant Natural :=
                        Invocation_Edge_Count (G, Compared_To);
         Comp_Len   : constant Natural := Length (G, Compared_To);
         Cycle_Invs : constant Natural := Invocation_Edge_Count (G, Cycle);
         Cycle_Len  : constant Natural := Length (G, Cycle);
         Kind_Prec  : constant Precedence_Kind :=
                        Cycle_Kind_Precedence
                          (Kind        => Kind (G, Cycle),
                           Compared_To => Kind (G, Compared_To));

      begin
         --  Prefer a cycle with higher precedence based on its kind

         if Kind_Prec = Higher_Precedence
              or else
            Kind_Prec = Lower_Precedence
         then
            return Kind_Prec;

         --  Prefer a shorter cycle

         elsif Cycle_Len < Comp_Len then
            return Higher_Precedence;

         elsif Cycle_Len > Comp_Len then
            return Lower_Precedence;

         --  Prefer a cycle wih fewer invocation edges

         elsif Cycle_Invs < Comp_Invs then
            return Higher_Precedence;

         elsif Cycle_Invs > Comp_Invs then
            return Lower_Precedence;

         --  Prefer a cycle with a higher path precedence

         else
            return
              Cycle_Path_Precedence
                (G           => G,
                 Path        => Path (G, Cycle),
                 Compared_To => Path (G, Compared_To));
         end if;
      end Cycle_Precedence;

      ----------------------------------------
      -- Decrement_Library_Graph_Edge_Count --
      ----------------------------------------

      procedure Decrement_Library_Graph_Edge_Count
        (G    : Library_Graph;
         Kind : Library_Graph_Edge_Kind)
      is
         pragma Assert (Present (G));

         Count : Natural renames G.Counts (Kind);

      begin
         Count := Count - 1;
      end Decrement_Library_Graph_Edge_Count;

      ------------------------------------
      -- Decrement_Pending_Predecessors --
      ------------------------------------

      procedure Decrement_Pending_Predecessors
        (G    : Library_Graph;
         Comp : Component_Id;
         Edge : Library_Graph_Edge_Id)
      is
         Attrs : Component_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         Attrs := Get_Component_Attributes (G, Comp);

         Update_Pending_Predecessors
           (Strong_Predecessors => Attrs.Pending_Strong_Predecessors,
            Weak_Predecessors   => Attrs.Pending_Weak_Predecessors,
            Update_Weak         => Is_Invocation_Edge (G, Edge),
            Value               => -1);

         Set_Component_Attributes (G, Comp, Attrs);
      end Decrement_Pending_Predecessors;

      ------------------------------------
      -- Decrement_Pending_Predecessors --
      ------------------------------------

      procedure Decrement_Pending_Predecessors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Edge   : Library_Graph_Edge_Id)
      is
         Attrs : Library_Graph_Vertex_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Attrs := Get_LGV_Attributes (G, Vertex);

         Update_Pending_Predecessors
           (Strong_Predecessors => Attrs.Pending_Strong_Predecessors,
            Weak_Predecessors   => Attrs.Pending_Weak_Predecessors,
            Update_Weak         => Is_Invocation_Edge (G, Edge),
            Value               => -1);

         Set_LGV_Attributes (G, Vertex, Attrs);
      end Decrement_Pending_Predecessors;

      -----------------------------------
      -- Delete_Body_Before_Spec_Edges --
      -----------------------------------

      procedure Delete_Body_Before_Spec_Edges
        (G     : Library_Graph;
         Edges : LGE_Lists.Doubly_Linked_List)
      is
         Edge : Library_Graph_Edge_Id;
         Iter : LGE_Lists.Iterator;

      begin
         pragma Assert (Present (G));
         pragma Assert (LGE_Lists.Present (Edges));

         Iter := LGE_Lists.Iterate (Edges);
         while LGE_Lists.Has_Next (Iter) loop
            LGE_Lists.Next (Iter, Edge);
            pragma Assert (Kind (G, Edge) = Body_Before_Spec_Edge);

            Delete_Edge (G, Edge);
         end loop;
      end Delete_Body_Before_Spec_Edges;

      -----------------
      -- Delete_Edge --
      -----------------

      procedure Delete_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         Pred : constant Library_Graph_Vertex_Id := Predecessor (G, Edge);
         Succ : constant Library_Graph_Vertex_Id := Successor   (G, Edge);
         Rel  : constant Predecessor_Successor_Relation :=
                  (Predecessor => Pred,
                   Successor   => Succ);

      begin
         --  Update the edge statistics

         Decrement_Library_Graph_Edge_Count (G, Kind (G, Edge));

         --  Update the number of pending predecessors the successor must wait
         --  on before it is elaborated.

         Decrement_Pending_Predecessors
           (G      => G,
            Vertex => Succ,
            Edge   => Edge);

         --  Delete the link between the predecessor and successor. This allows
         --  for further attempts to link the same predecessor and successor.

         RE_Sets.Delete (G.Recorded_Edges, Rel);

         --  Delete the attributes of the edge

         LGE_Tables.Delete (G.Edge_Attributes, Edge);

         --  Delete the edge from the underlying graph

         DG.Delete_Edge (G.Graph, Edge);
      end Delete_Edge;

      -------------
      -- Destroy --
      -------------

      procedure Destroy (G : in out Library_Graph) is
      begin
         pragma Assert (Present (G));

         Component_Tables.Destroy (G.Component_Attributes);
         LGC_Tables.Destroy       (G.Cycle_Attributes);
         LGC_Lists.Destroy        (G.Cycles);
         LGE_Tables.Destroy       (G.Edge_Attributes);
         DG.Destroy               (G.Graph);
         RE_Sets.Destroy          (G.Recorded_Edges);
         Unit_Tables.Destroy      (G.Unit_To_Vertex);
         LGV_Tables.Destroy       (G.Vertex_Attributes);

         Free (G);
      end Destroy;

      ----------------------------------
      -- Destroy_Component_Attributes --
      ----------------------------------

      procedure Destroy_Component_Attributes
        (Attrs : in out Component_Attributes)
      is
         pragma Unreferenced (Attrs);
      begin
         null;
      end Destroy_Component_Attributes;

      --------------------------------------------
      -- Destroy_Library_Graph_Cycle_Attributes --
      --------------------------------------------

      procedure Destroy_Library_Graph_Cycle_Attributes
        (Attrs : in out Library_Graph_Cycle_Attributes)
      is
      begin
         LGE_Lists.Destroy (Attrs.Path);
      end Destroy_Library_Graph_Cycle_Attributes;

      -------------------------------------------
      -- Destroy_Library_Graph_Edge_Attributes --
      -------------------------------------------

      procedure Destroy_Library_Graph_Edge_Attributes
        (Attrs : in out Library_Graph_Edge_Attributes)
      is
         pragma Unreferenced (Attrs);
      begin
         null;
      end Destroy_Library_Graph_Edge_Attributes;

      ---------------------------------------------
      -- Destroy_Library_Graph_Vertex_Attributes --
      ---------------------------------------------

      procedure Destroy_Library_Graph_Vertex_Attributes
        (Attrs : in out Library_Graph_Vertex_Attributes)
      is
         pragma Unreferenced (Attrs);
      begin
         null;
      end Destroy_Library_Graph_Vertex_Attributes;

      ---------------------
      -- Edge_Precedence --
      ---------------------

      function Edge_Precedence
        (G           : Library_Graph;
         Edge        : Library_Graph_Edge_Id;
         Compared_To : Library_Graph_Edge_Id) return Precedence_Kind
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));
         pragma Assert (Present (Compared_To));

         Comp_Succ : constant Library_Graph_Vertex_Id :=
                       Successor (G, Compared_To);
         Edge_Succ : constant Library_Graph_Vertex_Id :=
                       Successor (G, Edge);
         Kind_Prec : constant Precedence_Kind :=
                       Cycle_Kind_Precedence
                         (Kind        => Cycle_Kind_Of (G, Edge),
                          Compared_To => Cycle_Kind_Of (G, Compared_To));
         Succ_Prec : constant Precedence_Kind :=
                       Vertex_Precedence
                         (G           => G,
                          Vertex      => Edge_Succ,
                          Compared_To => Comp_Succ);

      begin
         --  Prefer an edge with a higher cycle kind precedence

         if Kind_Prec = Higher_Precedence
              or else
            Kind_Prec = Lower_Precedence
         then
            return Kind_Prec;

         --  Prefer an edge whose successor has a higher precedence

         elsif Comp_Succ /= Edge_Succ
           and then (Succ_Prec = Higher_Precedence
                       or else
                     Succ_Prec = Lower_Precedence)
         then
            return Succ_Prec;

         --  Prefer an edge whose predecessor has a higher precedence

         else
            return
              Vertex_Precedence
                (G           => G,
                 Vertex      => Predecessor (G, Edge),
                 Compared_To => Predecessor (G, Compared_To));
         end if;
      end Edge_Precedence;

      ---------------
      -- File_Name --
      ---------------

      function File_Name
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return File_Name_Type
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return File_Name (Unit (G, Vertex));
      end File_Name;

      ---------------------
      -- Find_Components --
      ---------------------

      procedure Find_Components (G : Library_Graph) is
         Edges : LGE_Lists.Doubly_Linked_List;

      begin
         pragma Assert (Present (G));

         Start_Phase (Component_Discovery);

         --  Initialize or reinitialize the components of the graph

         Initialize_Components (G);

         --  Create a set of special edges that link a predecessor body with a
         --  successor spec. This is an illegal dependency, however using such
         --  edges eliminates the need to create yet another graph, where both
         --  spec and body are collapsed into a single vertex.

         Edges := LGE_Lists.Create;
         Add_Body_Before_Spec_Edges (G, Edges);

         DG.Find_Components (G.Graph);

         --  Remove the special edges that link a predecessor body with a
         --  successor spec because they cause unresolvable circularities.

         Delete_Body_Before_Spec_Edges (G, Edges);
         LGE_Lists.Destroy (Edges);

         --  Update the number of predecessors various components must wait on
         --  before they can be elaborated.

         Update_Pending_Predecessors_Of_Components (G);
         End_Phase (Component_Discovery);
      end Find_Components;

      -----------------
      -- Find_Cycles --
      -----------------

      procedure Find_Cycles (G : Library_Graph) is
         All_Cycle_Limit : constant Natural := 64;
         --  The performance of Tarjan's algorithm may degrate to exponential
         --  when pragma Elaborate_All is in effect, or some vertex is part of
         --  an Elaborate_Body pair. In this case the algorithm discovers all
         --  combinations of edges that close a circuit starting and ending on
         --  some start vertex while going through different vertices. Use a
         --  limit on the total number of cycles within a component to guard
         --  against such degradation.

         Comp        : Component_Id;
         Cycle_Count : Natural;
         Iter        : Component_Iterator;

      begin
         pragma Assert (Present (G));

         Start_Phase (Cycle_Discovery);

         --  The cycles of graph G are discovered using Tarjan's enumeration
         --  of the elementary circuits of a directed-graph algorithm. Do not
         --  modify this code unless you intimately understand the algorithm.
         --
         --  The logic of the algorithm is split among the following routines:
         --
         --    Cycle_End_Vertices
         --    Find_Cycles_From_Successor
         --    Find_Cycles_From_Vertex
         --    Find_Cycles_In_Component
         --    Unvisit
         --    Visit
         --
         --  The original algorithm has been significantly modified in order to
         --
         --    * Accommodate the semantics of Elaborate_All and Elaborate_Body.
         --
         --    * Capture cycle paths as edges rather than vertices.
         --
         --    * Take advantage of graph components.

         --  Assume that the graph does not contain a cycle

         Cycle_Count := 0;

         --  Run the modified version of the algorithm on each component of the
         --  graph.

         Iter := Iterate_Components (G);
         while Has_Next (Iter) loop
            Next (Iter, Comp);

            Find_Cycles_In_Component
              (G           => G,
               Comp        => Comp,
               Cycle_Count => Cycle_Count,
               Cycle_Limit => All_Cycle_Limit);
         end loop;

         End_Phase (Cycle_Discovery);
      end Find_Cycles;

      --------------------------------
      -- Find_Cycles_From_Successor --
      --------------------------------

      procedure Find_Cycles_From_Successor
        (G                     : Library_Graph;
         Edge                  : Library_Graph_Edge_Id;
         End_Vertices          : LGV_Sets.Membership_Set;
         Deleted_Vertices      : LGV_Sets.Membership_Set;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path_Stack      : LGE_Lists.Doubly_Linked_List;
         Visited_Set           : LGV_Sets.Membership_Set;
         Visited_Stack         : LGV_Lists.Doubly_Linked_List;
         Cycle_Count           : in out Natural;
         Cycle_Limit           : Natural;
         Elaborate_All_Active  : Boolean;
         Has_Cycle             : out Boolean;
         Indent                : Indentation_Level)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));
         pragma Assert (LGV_Sets.Present  (End_Vertices));
         pragma Assert (LGV_Sets.Present  (Deleted_Vertices));
         pragma Assert (LGE_Lists.Present (Cycle_Path_Stack));
         pragma Assert (LGV_Sets.Present  (Visited_Set));
         pragma Assert (LGV_Lists.Present (Visited_Stack));

         Succ        : constant Library_Graph_Vertex_Id := Successor (G, Edge);
         Succ_Indent : constant Indentation_Level       :=
                         Indent + Nested_Indentation;

      begin
         --  Assume that the successor reached via the edge does not result in
         --  a cycle.

         Has_Cycle := False;

         --  Nothing to do when the edge connects two vertices residing in two
         --  different components.

         if not Is_Cyclic_Edge (G, Edge) then
            return;
         end if;

         Trace_Edge (G, Edge, Indent);

         --  The modified version does not place vertices on the "point stack",
         --  but instead collects the edges comprising the cycle. Prepare the
         --  edge for backtracking.

         LGE_Lists.Prepend (Cycle_Path_Stack, Edge);

         Find_Cycles_From_Vertex
           (G                     => G,
            Vertex                => Succ,
            End_Vertices          => End_Vertices,
            Deleted_Vertices      => Deleted_Vertices,
            Most_Significant_Edge => Most_Significant_Edge,
            Invocation_Edge_Count => Invocation_Edge_Count,
            Cycle_Path_Stack      => Cycle_Path_Stack,
            Visited_Set           => Visited_Set,
            Visited_Stack         => Visited_Stack,
            Cycle_Count           => Cycle_Count,
            Cycle_Limit           => Cycle_Limit,
            Elaborate_All_Active  => Elaborate_All_Active,
            Is_Start_Vertex       => False,
            Has_Cycle             => Has_Cycle,
            Indent                => Succ_Indent);

         --  The modified version does not place vertices on the "point stack",
         --  but instead collects the edges comprising the cycle. Backtrack the
         --  edge.

         LGE_Lists.Delete_First (Cycle_Path_Stack);
      end Find_Cycles_From_Successor;

      -----------------------------
      -- Find_Cycles_From_Vertex --
      -----------------------------

      procedure Find_Cycles_From_Vertex
        (G                     : Library_Graph;
         Vertex                : Library_Graph_Vertex_Id;
         End_Vertices          : LGV_Sets.Membership_Set;
         Deleted_Vertices      : LGV_Sets.Membership_Set;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path_Stack      : LGE_Lists.Doubly_Linked_List;
         Visited_Set           : LGV_Sets.Membership_Set;
         Visited_Stack         : LGV_Lists.Doubly_Linked_List;
         Cycle_Count           : in out Natural;
         Cycle_Limit           : Natural;
         Elaborate_All_Active  : Boolean;
         Is_Start_Vertex       : Boolean;
         Has_Cycle             : out Boolean;
         Indent                : Indentation_Level)
      is
         Edge_Indent : constant Indentation_Level :=
                         Indent + Nested_Indentation;

         Complement : Library_Graph_Vertex_Id;
         Edge       : Library_Graph_Edge_Id;
         Iter       : Edges_To_Successors_Iterator;

         Complement_Has_Cycle : Boolean;
         --  This flag is set when either Elaborate_All is in effect or the
         --  current vertex is part of an Elaborate_Body pair, and visiting
         --  the "complementary" vertex resulted in a cycle.

         Successor_Has_Cycle : Boolean;
         --  This flag is set when visiting at least one successor of the
         --  current vertex resulted in a cycle.

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));
         pragma Assert (LGV_Sets.Present  (End_Vertices));
         pragma Assert (LGV_Sets.Present  (Deleted_Vertices));
         pragma Assert (LGE_Lists.Present (Cycle_Path_Stack));
         pragma Assert (LGV_Sets.Present  (Visited_Set));
         pragma Assert (LGV_Lists.Present (Visited_Stack));

         --  Assume that the vertex does not close a circuit

         Has_Cycle := False;

         --  Nothing to do when the limit on the number of saved cycles has
         --  been reached. This protects against a combinatorial explosion
         --  in components with Elaborate_All cycles.

         if Cycle_Count >= Cycle_Limit then
            return;

         --  The vertex closes the circuit, thus resulting in a cycle. Save
         --  the cycle for later diagnostics. The initial invocation of the
         --  routine always ignores the starting vertex, to prevent a spurious
         --  self-cycle.

         elsif not Is_Start_Vertex
           and then LGV_Sets.Contains (End_Vertices, Vertex)
         then
            Trace_Vertex (G, Vertex, Indent);

            Record_Cycle
              (G                     => G,
               Most_Significant_Edge => Most_Significant_Edge,
               Invocation_Edge_Count => Invocation_Edge_Count,
               Cycle_Path            => Cycle_Path_Stack,
               Indent                => Indent);

            Has_Cycle   := True;
            Cycle_Count := Cycle_Count + 1;
            return;

         --  Nothing to do when the vertex has already been deleted. This
         --  indicates that all available cycles involving the vertex have
         --  been discovered, and the vertex cannot contribute further to
         --  the depth-first search.

         elsif LGV_Sets.Contains (Deleted_Vertices, Vertex) then
            return;

         --  Nothing to do when the vertex has already been visited. This
         --  indicates that the depth-first search initiated from some start
         --  vertex already encountered this vertex, and the visited stack has
         --  not been unrolled yet.

         elsif LGV_Sets.Contains (Visited_Set, Vertex) then
            return;
         end if;

         Trace_Vertex (G, Vertex, Indent);

         --  Mark the vertex as visited

         Visit
           (Vertex        => Vertex,
            Visited_Set   => Visited_Set,
            Visited_Stack => Visited_Stack);

         --  Extend the depth-first search via all the edges to successors

         Iter := Iterate_Edges_To_Successors (G, Vertex);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            Find_Cycles_From_Successor
              (G                     => G,
               Edge                  => Edge,
               End_Vertices          => End_Vertices,
               Deleted_Vertices      => Deleted_Vertices,

               --  The edge may be more important than the most important edge
               --  up to this point, thus "upgrading" the nature of the cycle,
               --  and shifting its point of normalization.

               Most_Significant_Edge =>
                 Highest_Precedence_Edge
                   (G     => G,
                    Left  => Edge,
                    Right => Most_Significant_Edge),

               --  The edge may be an invocation edge, in which case the count
               --  of invocation edges increases by one.

               Invocation_Edge_Count =>
                 Maximum_Invocation_Edge_Count
                   (G     => G,
                    Edge  => Edge,
                    Count => Invocation_Edge_Count),

               Cycle_Path_Stack      => Cycle_Path_Stack,
               Visited_Set           => Visited_Set,
               Visited_Stack         => Visited_Stack,
               Cycle_Count           => Cycle_Count,
               Cycle_Limit           => Cycle_Limit,
               Elaborate_All_Active  => Elaborate_All_Active,
               Has_Cycle             => Successor_Has_Cycle,
               Indent                => Edge_Indent);

            Has_Cycle := Has_Cycle or Successor_Has_Cycle;
         end loop;

         --  Visit the complementary vertex of the current vertex when pragma
         --  Elaborate_All is in effect, or the current vertex is part of an
         --  Elaborate_Body pair.

         if Elaborate_All_Active
           or else Is_Vertex_With_Elaborate_Body (G, Vertex)
         then
            Complement :=
              Complementary_Vertex
                (G                => G,
                 Vertex           => Vertex,
                 Force_Complement => Elaborate_All_Active);

            if Present (Complement) then
               Find_Cycles_From_Vertex
                 (G                     => G,
                  Vertex                => Complement,
                  End_Vertices          => End_Vertices,
                  Deleted_Vertices      => Deleted_Vertices,
                  Most_Significant_Edge => Most_Significant_Edge,
                  Invocation_Edge_Count => Invocation_Edge_Count,
                  Cycle_Path_Stack      => Cycle_Path_Stack,
                  Visited_Set           => Visited_Set,
                  Visited_Stack         => Visited_Stack,
                  Cycle_Count           => Cycle_Count,
                  Cycle_Limit           => Cycle_Limit,
                  Elaborate_All_Active  => Elaborate_All_Active,
                  Is_Start_Vertex       => Is_Start_Vertex,
                  Has_Cycle             => Complement_Has_Cycle,
                  Indent                => Indent);

               Has_Cycle := Has_Cycle or Complement_Has_Cycle;
            end if;
         end if;

         --  The original algorithm clears the "marked stack" in two places:
         --
         --     * When the depth-first search starting from the current vertex
         --       discovers at least one cycle, and
         --
         --     * When the depth-first search initiated from a start vertex
         --       completes.
         --
         --  The modified version handles both cases in one place.

         if Has_Cycle or else Is_Start_Vertex then
            Unvisit
              (Vertex        => Vertex,
               Visited_Set   => Visited_Set,
               Visited_Stack => Visited_Stack);
         end if;

         --  Delete a start vertex from the graph once its depth-first search
         --  completes. This action preserves the invariant where a cycle is
         --  not rediscovered "later" in some permuted form.

         if Is_Start_Vertex then
            LGV_Sets.Insert (Deleted_Vertices, Vertex);
         end if;
      end Find_Cycles_From_Vertex;

      ------------------------------
      -- Find_Cycles_In_Component --
      ------------------------------

      procedure Find_Cycles_In_Component
        (G           : Library_Graph;
         Comp        : Component_Id;
         Cycle_Count : in out Natural;
         Cycle_Limit : Natural)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         Num_Of_Vertices : constant Natural :=
                             Number_Of_Component_Vertices (G, Comp);

         Elaborate_All_Active : constant Boolean :=
                                  Has_Elaborate_All_Edge (G, Comp);
         --  The presence of an Elaborate_All edge within a component causes
         --  all spec-body pairs to be treated as one vertex.

         Has_Cycle : Boolean;
         Iter      : Component_Vertex_Iterator;
         Vertex    : Library_Graph_Vertex_Id;

         Cycle_Path_Stack : LGE_Lists.Doubly_Linked_List := LGE_Lists.Nil;
         --  The "point stack" of Tarjan's algorithm. The original maintains
         --  a stack of vertices, however for diagnostic purposes using edges
         --  is preferable.

         Deleted_Vertices : LGV_Sets.Membership_Set := LGV_Sets.Nil;
         --  The original algorithm alters the graph by deleting vertices with
         --  lower ordinals compared to some starting vertex. Since the graph
         --  must remain intact for diagnostic purposes, vertices are instead
         --  inserted in this set and treated as "deleted".

         End_Vertices : LGV_Sets.Membership_Set := LGV_Sets.Nil;
         --  The original algorithm uses a single vertex to indicate the start
         --  and end vertex of a cycle. The semantics of pragmas Elaborate_All
         --  and Elaborate_Body increase this number by one. The end vertices
         --  are added to this set and treated as "cycle-terminating".

         Visited_Set : LGV_Sets.Membership_Set := LGV_Sets.Nil;
         --  The "mark" array of Tarjan's algorithm. Since the original visits
         --  all vertices in increasing ordinal number 1 .. N, the array offers
         --  a one-to-one mapping between a vertex and its "marked" state. The
         --  modified version however visits vertices within components, where
         --  their ordinals are not contiguous. Vertices are added to this set
         --  and treated as "marked".

         Visited_Stack : LGV_Lists.Doubly_Linked_List := LGV_Lists.Nil;
         --  The "marked stack" of Tarjan's algorithm

      begin
         Trace_Component (G, Comp, No_Indentation);

         --  Initialize all component-level data structures

         Cycle_Path_Stack := LGE_Lists.Create;
         Deleted_Vertices := LGV_Sets.Create (Num_Of_Vertices);
         Visited_Set      := LGV_Sets.Create (Num_Of_Vertices);
         Visited_Stack    := LGV_Lists.Create;

         --  The modified version does not use ordinals to visit vertices in
         --  1 .. N fashion. To preserve the invariant of the original, this
         --  version deletes a vertex after its depth-first search completes.
         --  The timing of the deletion is sound because all cycles through
         --  that vertex have already been discovered, thus the vertex cannot
         --  contribute to any cycles discovered "later" in the algorithm.

         Iter := Iterate_Component_Vertices (G, Comp);
         while Has_Next (Iter) loop
            Next (Iter, Vertex);

            --  Construct the set of vertices (at most 2) that terminates a
            --  potential cycle that starts from the current vertex.

            End_Vertices :=
              Cycle_End_Vertices
                (G                    => G,
                 Vertex               => Vertex,
                 Elaborate_All_Active => Elaborate_All_Active);

            --  The modified version maintains two additional attributes while
            --  performing the depth-first search:
            --
            --    * The most significant edge of the current potential cycle.
            --
            --    * The number of invocation edges encountered along the path
            --      of the current potential cycle.
            --
            --  Both attributes are used in the heuristic that determines the
            --  importance of cycles.

            Find_Cycles_From_Vertex
              (G                     => G,
               Vertex                => Vertex,
               End_Vertices          => End_Vertices,
               Deleted_Vertices      => Deleted_Vertices,
               Most_Significant_Edge => No_Library_Graph_Edge,
               Invocation_Edge_Count => 0,
               Cycle_Path_Stack      => Cycle_Path_Stack,
               Visited_Set           => Visited_Set,
               Visited_Stack         => Visited_Stack,
               Cycle_Count           => Cycle_Count,
               Cycle_Limit           => Cycle_Limit,
               Elaborate_All_Active  => Elaborate_All_Active,
               Is_Start_Vertex       => True,
               Has_Cycle             => Has_Cycle,
               Indent                => Nested_Indentation);

            --  Destroy the cycle-terminating vertices because a new set must
            --  be constructed for the next vertex.

            LGV_Sets.Destroy (End_Vertices);
         end loop;

         --  Destroy all component-level data structures

         LGE_Lists.Destroy (Cycle_Path_Stack);
         LGV_Sets.Destroy  (Deleted_Vertices);
         LGV_Sets.Destroy  (Visited_Set);
         LGV_Lists.Destroy (Visited_Stack);
      end Find_Cycles_In_Component;

      ---------------
      -- Find_Edge --
      ---------------

      function Find_Edge
        (G    : Library_Graph;
         Pred : Library_Graph_Vertex_Id;
         Succ : Library_Graph_Vertex_Id) return Library_Graph_Edge_Id
      is
         Result : Library_Graph_Edge_Id := No_Library_Graph_Edge;
         Edge : Library_Graph_Edge_Id;
         Iter : Edges_To_Successors_Iterator :=
           Iterate_Edges_To_Successors (G, Pred);

      begin
         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      edges to successors.

         --  This does a linear search through the successors of Pred.
         --  Efficiency is not a problem, because this is called only when
         --  Activates_Task is True, which is rare, and anyway, there aren't
         --  usually large numbers of successors.

         while Has_Next (Iter) loop
            Next (Iter, Edge);

            if Succ = Successor (G, Edge) then
               pragma Assert (not Present (Result));
               Result := Edge;
            end if;
         end loop;

         pragma Assert (Present (Result));
         return Result;
      end Find_Edge;

      ---------------------------------------
      -- Find_First_Lower_Precedence_Cycle --
      ---------------------------------------

      function Find_First_Lower_Precedence_Cycle
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Library_Graph_Cycle_Id
      is
         Current_Cycle : Library_Graph_Cycle_Id;
         Iter          : All_Cycle_Iterator;
         Lesser_Cycle  : Library_Graph_Cycle_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         --  Assume that there is no lesser cycle

         Lesser_Cycle := No_Library_Graph_Cycle;

         --  Find a cycle with a slightly lower precedence than the input
         --  cycle.
         --
         --  IMPORTANT:
         --
         --    * The iterator must run to completion in order to unlock the
         --      list of all cycles.

         Iter := Iterate_All_Cycles (G);
         while Has_Next (Iter) loop
            Next (Iter, Current_Cycle);

            if not Present (Lesser_Cycle)
              and then Cycle_Precedence
                         (G           => G,
                          Cycle       => Cycle,
                          Compared_To => Current_Cycle) = Higher_Precedence
            then
               Lesser_Cycle := Current_Cycle;
            end if;
         end loop;

         return Lesser_Cycle;
      end Find_First_Lower_Precedence_Cycle;

      ------------------------------
      -- Get_Component_Attributes --
      ------------------------------

      function Get_Component_Attributes
        (G    : Library_Graph;
         Comp : Component_Id) return Component_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         return Component_Tables.Get (G.Component_Attributes, Comp);
      end Get_Component_Attributes;

      ------------------------
      -- Get_LGC_Attributes --
      ------------------------

      function Get_LGC_Attributes
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Library_Graph_Cycle_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return LGC_Tables.Get (G.Cycle_Attributes, Cycle);
      end Get_LGC_Attributes;

      ------------------------
      -- Get_LGE_Attributes --
      ------------------------

      function Get_LGE_Attributes
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Edge_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return LGE_Tables.Get (G.Edge_Attributes, Edge);
      end Get_LGE_Attributes;

      ------------------------
      -- Get_LGV_Attributes --
      ------------------------

      function Get_LGV_Attributes
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id)
         return Library_Graph_Vertex_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return LGV_Tables.Get (G.Vertex_Attributes, Vertex);
      end Get_LGV_Attributes;

      -----------------------------
      -- Has_Elaborate_All_Cycle --
      -----------------------------

      function Has_Elaborate_All_Cycle (G : Library_Graph) return Boolean is
         Edge : Library_Graph_Edge_Id;
         Iter : All_Edge_Iterator;
         Seen : Boolean;

      begin
         pragma Assert (Present (G));

         --  Assume that no cyclic Elaborate_All edge has been seen

         Seen := False;

         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      graph.

         Iter := Iterate_All_Edges (G);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            if not Seen and then Is_Cyclic_Elaborate_All_Edge (G, Edge) then
               Seen := True;
            end if;
         end loop;

         return Seen;
      end Has_Elaborate_All_Cycle;

      ----------------------------
      -- Has_Elaborate_All_Edge --
      ----------------------------

      function Has_Elaborate_All_Edge
        (G    : Library_Graph;
         Comp : Component_Id) return Boolean
      is
         Has_Edge : Boolean;
         Iter     : Component_Vertex_Iterator;
         Vertex   : Library_Graph_Vertex_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         --  Assume that there is no Elaborate_All edge

         Has_Edge := False;

         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      component vertices.

         Iter := Iterate_Component_Vertices (G, Comp);
         while Has_Next (Iter) loop
            Next (Iter, Vertex);

            Has_Edge := Has_Edge or else Has_Elaborate_All_Edge (G, Vertex);
         end loop;

         return Has_Edge;
      end Has_Elaborate_All_Edge;

      ----------------------------
      -- Has_Elaborate_All_Edge --
      ----------------------------

      function Has_Elaborate_All_Edge
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         Edge     : Library_Graph_Edge_Id;
         Has_Edge : Boolean;
         Iter     : Edges_To_Successors_Iterator;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         --  Assume that there is no Elaborate_All edge

         Has_Edge := False;

         --  IMPORTANT:
         --
         --    * The iteration must run to completion in order to unlock the
         --      edges to successors.

         Iter := Iterate_Edges_To_Successors (G, Vertex);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            Has_Edge :=
              Has_Edge or else Is_Cyclic_Elaborate_All_Edge (G, Edge);
         end loop;

         return Has_Edge;
      end Has_Elaborate_All_Edge;

      ------------------------
      -- Has_Elaborate_Body --
      ------------------------

      function Has_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         --  Treat the spec and body as decoupled when switch -d_b (ignore the
         --  effects of pragma Elaborate_Body) is in effect.

         return U_Rec.Elaborate_Body and not Debug_Flag_Underscore_B;
      end Has_Elaborate_Body;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : All_Cycle_Iterator) return Boolean is
      begin
         return LGC_Lists.Has_Next (LGC_Lists.Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : All_Edge_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.All_Edge_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : All_Vertex_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.All_Vertex_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Component_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.Component_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Component_Vertex_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.Component_Vertex_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Edges_Of_Cycle_Iterator) return Boolean is
      begin
         return LGE_Lists.Has_Next (LGE_Lists.Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Edges_To_Successors_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.Outgoing_Edge_Iterator (Iter));
      end Has_Next;

      -----------------------------
      -- Has_No_Elaboration_Code --
      -----------------------------

      function Has_No_Elaboration_Code
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Has_No_Elaboration_Code (Unit (G, Vertex));
      end Has_No_Elaboration_Code;

      -----------------------------------------
      -- Hash_Library_Graph_Cycle_Attributes --
      -----------------------------------------

      function Hash_Library_Graph_Cycle_Attributes
        (Attrs : Library_Graph_Cycle_Attributes) return Bucket_Range_Type
      is
         Edge : Library_Graph_Edge_Id;
         Hash : Bucket_Range_Type;
         Iter : LGE_Lists.Iterator;

      begin
         pragma Assert (LGE_Lists.Present (Attrs.Path));

         --  The hash is obtained in the following manner:
         --
         --    (((edge1 * 31) + edge2) * 31) + edgeN

         Hash := 0;
         Iter := LGE_Lists.Iterate (Attrs.Path);
         while LGE_Lists.Has_Next (Iter) loop
            LGE_Lists.Next (Iter, Edge);

            Hash := (Hash * 31) + Bucket_Range_Type (Edge);
         end loop;

         return Hash;
      end Hash_Library_Graph_Cycle_Attributes;

      -----------------------------------------
      -- Hash_Predecessor_Successor_Relation --
      -----------------------------------------

      function Hash_Predecessor_Successor_Relation
        (Rel : Predecessor_Successor_Relation) return Bucket_Range_Type
      is
      begin
         pragma Assert (Present (Rel.Predecessor));
         pragma Assert (Present (Rel.Successor));

         return
           Hash_Two_Keys
             (Bucket_Range_Type (Rel.Predecessor),
              Bucket_Range_Type (Rel.Successor));
      end Hash_Predecessor_Successor_Relation;

      ------------------------------
      -- Highest_Precedence_Cycle --
      ------------------------------

      function Highest_Precedence_Cycle
        (G : Library_Graph) return Library_Graph_Cycle_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (LGC_Lists.Present (G.Cycles));

         if LGC_Lists.Is_Empty (G.Cycles) then
            return No_Library_Graph_Cycle;

         --  The highest precedence cycle is always the first in the list of
         --  all cycles.

         else
            return LGC_Lists.First (G.Cycles);
         end if;
      end Highest_Precedence_Cycle;

      -----------------------------
      -- Highest_Precedence_Edge --
      -----------------------------

      function Highest_Precedence_Edge
        (G     : Library_Graph;
         Left  : Library_Graph_Edge_Id;
         Right : Library_Graph_Edge_Id) return Library_Graph_Edge_Id
      is
         Edge_Prec : Precedence_Kind;

      begin
         pragma Assert (Present (G));

         --  Both edges are available, pick the one with highest precedence

         if Present (Left) and then Present (Right) then
            Edge_Prec :=
              Edge_Precedence
                (G           => G,
                 Edge        => Left,
                 Compared_To => Right);

            if Edge_Prec = Higher_Precedence then
               return Left;

            --  The precedence rules for edges are such that no two edges can
            --  ever have the same precedence.

            else
               pragma Assert (Edge_Prec = Lower_Precedence);
               return Right;
            end if;

         --  Otherwise at least one edge must be present

         elsif Present (Left) then
            return Left;

         else
            pragma Assert (Present (Right));

            return Right;
         end if;
      end Highest_Precedence_Edge;

      --------------------------
      -- In_Elaboration_Order --
      --------------------------

      function In_Elaboration_Order
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_LGV_Attributes (G, Vertex).In_Elaboration_Order;
      end In_Elaboration_Order;

      -----------------------
      -- In_Same_Component --
      -----------------------

      function In_Same_Component
        (G     : Library_Graph;
         Left  : Library_Graph_Vertex_Id;
         Right : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Left));
         pragma Assert (Present (Right));

         return Component (G, Left) = Component (G, Right);
      end In_Same_Component;

      ----------------------------------------
      -- Increment_Library_Graph_Edge_Count --
      ----------------------------------------

      procedure Increment_Library_Graph_Edge_Count
        (G    : Library_Graph;
         Kind : Library_Graph_Edge_Kind)
      is
         pragma Assert (Present (G));

         Count : Natural renames G.Counts (Kind);

      begin
         Count := Count + 1;
      end Increment_Library_Graph_Edge_Count;

      ------------------------------------
      -- Increment_Pending_Predecessors --
      ------------------------------------

      procedure Increment_Pending_Predecessors
        (G    : Library_Graph;
         Comp : Component_Id;
         Edge : Library_Graph_Edge_Id)
      is
         Attrs : Component_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         Attrs := Get_Component_Attributes (G, Comp);

         Update_Pending_Predecessors
           (Strong_Predecessors => Attrs.Pending_Strong_Predecessors,
            Weak_Predecessors   => Attrs.Pending_Weak_Predecessors,
            Update_Weak         => Is_Invocation_Edge (G, Edge),
            Value               => 1);

         Set_Component_Attributes (G, Comp, Attrs);
      end Increment_Pending_Predecessors;

      ------------------------------------
      -- Increment_Pending_Predecessors --
      ------------------------------------

      procedure Increment_Pending_Predecessors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Edge   : Library_Graph_Edge_Id)
      is
         Attrs : Library_Graph_Vertex_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Attrs := Get_LGV_Attributes (G, Vertex);

         Update_Pending_Predecessors
           (Strong_Predecessors => Attrs.Pending_Strong_Predecessors,
            Weak_Predecessors   => Attrs.Pending_Weak_Predecessors,
            Update_Weak         => Is_Invocation_Edge (G, Edge),
            Value               => 1);

         Set_LGV_Attributes (G, Vertex, Attrs);
      end Increment_Pending_Predecessors;

      ---------------------------
      -- Initialize_Components --
      ---------------------------

      procedure Initialize_Components (G : Library_Graph) is
      begin
         pragma Assert (Present (G));

         --  The graph already contains a set of components. Reinitialize
         --  them in order to accommodate the new set of components about to
         --  be computed.

         if Number_Of_Components (G) > 0 then
            Component_Tables.Destroy (G.Component_Attributes);

            G.Component_Attributes :=
              Component_Tables.Create (Number_Of_Vertices (G));
         end if;
      end Initialize_Components;

      ---------------------------
      -- Invocation_Edge_Count --
      ---------------------------

      function Invocation_Edge_Count
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return Get_LGC_Attributes (G, Cycle).Invocation_Edge_Count;
      end Invocation_Edge_Count;

      -------------------------------
      -- Invocation_Graph_Encoding --
      -------------------------------

      function Invocation_Graph_Encoding
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id)
         return Invocation_Graph_Encoding_Kind
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Invocation_Graph_Encoding (Unit (G, Vertex));
      end Invocation_Graph_Encoding;

      -------------
      -- Is_Body --
      -------------

      function Is_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         return U_Rec.Utype = Is_Body or else U_Rec.Utype = Is_Body_Only;
      end Is_Body;

      -----------------------------------------
      -- Is_Body_Of_Spec_With_Elaborate_Body --
      -----------------------------------------

      function Is_Body_Of_Spec_With_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         if Is_Body_With_Spec (G, Vertex) then
            return
              Is_Spec_With_Elaborate_Body
                (G      => G,
                 Vertex => Proper_Spec (G, Vertex));
         end if;

         return False;
      end Is_Body_Of_Spec_With_Elaborate_Body;

      -----------------------
      -- Is_Body_With_Spec --
      -----------------------

      function Is_Body_With_Spec
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         return U_Rec.Utype = Is_Body;
      end Is_Body_With_Spec;

      ------------------------------
      -- Is_Cycle_Initiating_Edge --
      ------------------------------

      function Is_Cycle_Initiating_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Cyclic_Elaborate_All_Edge (G, Edge)
             or else Is_Cyclic_Elaborate_Body_Edge (G, Edge)
             or else Is_Cyclic_Elaborate_Edge (G, Edge)
             or else Is_Cyclic_Forced_Edge (G, Edge)
             or else Is_Cyclic_Invocation_Edge (G, Edge);
      end Is_Cycle_Initiating_Edge;

      --------------------
      -- Is_Cyclic_Edge --
      --------------------

      function Is_Cyclic_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Cycle_Initiating_Edge (G, Edge)
             or else Is_Cyclic_With_Edge (G, Edge);
      end Is_Cyclic_Edge;

      ----------------------------------
      -- Is_Cyclic_Elaborate_All_Edge --
      ----------------------------------

      function Is_Cyclic_Elaborate_All_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Elaborate_All_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge);
      end Is_Cyclic_Elaborate_All_Edge;

      -----------------------------------
      -- Is_Cyclic_Elaborate_Body_Edge --
      -----------------------------------

      function Is_Cyclic_Elaborate_Body_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Elaborate_Body_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge);
      end Is_Cyclic_Elaborate_Body_Edge;

      ------------------------------
      -- Is_Cyclic_Elaborate_Edge --
      ------------------------------

      function Is_Cyclic_Elaborate_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Elaborate_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge);
      end Is_Cyclic_Elaborate_Edge;

      ---------------------------
      -- Is_Cyclic_Forced_Edge --
      ---------------------------

      function Is_Cyclic_Forced_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Forced_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge);
      end Is_Cyclic_Forced_Edge;

      -------------------------------
      -- Is_Cyclic_Invocation_Edge --
      -------------------------------

      function Is_Cyclic_Invocation_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Invocation_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge);
      end Is_Cyclic_Invocation_Edge;

      -------------------------
      -- Is_Cyclic_With_Edge --
      -------------------------

      function Is_Cyclic_With_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         --  Ignore Elaborate_Body edges because they also appear as with
         --  edges, but have special successors.

         return
           Is_With_Edge (G, Edge)
             and then Links_Vertices_In_Same_Component (G, Edge)
             and then not Is_Elaborate_Body_Edge (G, Edge);
      end Is_Cyclic_With_Edge;

      -------------------------------
      -- Is_Dynamically_Elaborated --
      -------------------------------

      function Is_Dynamically_Elaborated
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Is_Dynamically_Elaborated (Unit (G, Vertex));
      end Is_Dynamically_Elaborated;

      -----------------------------
      -- Is_Elaborable_Component --
      -----------------------------

      function Is_Elaborable_Component
        (G    : Library_Graph;
         Comp : Component_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         --  A component is elaborable when:
         --
         --    * It is not waiting on strong predecessors, and
         --    * It is not waiting on weak predecessors

         return
           Pending_Strong_Predecessors (G, Comp) = 0
             and then Pending_Weak_Predecessors (G, Comp) = 0;
      end Is_Elaborable_Component;

      --------------------------
      -- Is_Elaborable_Vertex --
      --------------------------

      function Is_Elaborable_Vertex
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Complement : constant Library_Graph_Vertex_Id :=
                        Complementary_Vertex
                          (G                => G,
                           Vertex           => Vertex,
                           Force_Complement => False);

         Strong_Preds : Natural;
         Weak_Preds   : Natural;

      begin
         --  A vertex is elaborable when:
         --
         --    * It has not been elaborated yet, and
         --    * The complement vertex of an Elaborate_Body pair has not been
         --      elaborated yet, and
         --    * It resides within an elaborable component, and
         --    * It is not waiting on strong predecessors, and
         --    * It is not waiting on weak predecessors

         if In_Elaboration_Order (G, Vertex) then
            return False;

         elsif Present (Complement)
           and then In_Elaboration_Order (G, Complement)
         then
            return False;

         elsif not Is_Elaborable_Component (G, Component (G, Vertex)) then
            return False;
         end if;

         Pending_Predecessors_For_Elaboration
           (G            => G,
            Vertex       => Vertex,
            Strong_Preds => Strong_Preds,
            Weak_Preds   => Weak_Preds);

         return Strong_Preds = 0 and then Weak_Preds = 0;
      end Is_Elaborable_Vertex;

      ---------------------------
      -- Is_Elaborate_All_Edge --
      ---------------------------

      function Is_Elaborate_All_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = Elaborate_All_Edge;
      end Is_Elaborate_All_Edge;

      ----------------------------
      -- Is_Elaborate_Body_Edge --
      ----------------------------

      function Is_Elaborate_Body_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Kind (G, Edge) = With_Edge
             and then Is_Vertex_With_Elaborate_Body (G, Successor (G, Edge));
      end Is_Elaborate_Body_Edge;

      -----------------------
      -- Is_Elaborate_Edge --
      -----------------------

      function Is_Elaborate_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = Elaborate_Edge;
      end Is_Elaborate_Edge;

      ----------------------------
      -- Is_Elaborate_Body_Pair --
      ----------------------------

      function Is_Elaborate_Body_Pair
        (G           : Library_Graph;
         Spec_Vertex : Library_Graph_Vertex_Id;
         Body_Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Spec_Vertex));
         pragma Assert (Present (Body_Vertex));

         return
           Is_Spec_With_Elaborate_Body (G, Spec_Vertex)
             and then Is_Body_Of_Spec_With_Elaborate_Body (G, Body_Vertex)
             and then Proper_Body (G, Spec_Vertex) = Body_Vertex;
      end Is_Elaborate_Body_Pair;

      --------------------
      -- Is_Forced_Edge --
      --------------------

      function Is_Forced_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = Forced_Edge;
      end Is_Forced_Edge;

      ----------------------
      -- Is_Internal_Unit --
      ----------------------

      function Is_Internal_Unit
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Is_Internal_Unit (Unit (G, Vertex));
      end Is_Internal_Unit;

      ------------------------
      -- Is_Invocation_Edge --
      ------------------------

      function Is_Invocation_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = Invocation_Edge;
      end Is_Invocation_Edge;

      ------------------------
      -- Is_Predefined_Unit --
      ------------------------

      function Is_Predefined_Unit
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Is_Predefined_Unit (Unit (G, Vertex));
      end Is_Predefined_Unit;

      ---------------------------
      -- Is_Preelaborated_Unit --
      ---------------------------

      function Is_Preelaborated_Unit
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         return U_Rec.Preelab or else U_Rec.Pure;
      end Is_Preelaborated_Unit;

      ----------------------
      -- Is_Recorded_Edge --
      ----------------------

      function Is_Recorded_Edge
        (G   : Library_Graph;
         Rel : Predecessor_Successor_Relation) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Rel.Predecessor));
         pragma Assert (Present (Rel.Successor));

         return RE_Sets.Contains (G.Recorded_Edges, Rel);
      end Is_Recorded_Edge;

      -------------
      -- Is_Spec --
      -------------

      function Is_Spec
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         return U_Rec.Utype = Is_Spec or else U_Rec.Utype = Is_Spec_Only;
      end Is_Spec;

      ------------------------------
      -- Is_Spec_Before_Body_Edge --
      ------------------------------

      function Is_Spec_Before_Body_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = Spec_Before_Body_Edge;
      end Is_Spec_Before_Body_Edge;

      -----------------------
      -- Is_Spec_With_Body --
      -----------------------

      function Is_Spec_With_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         U_Id  : constant Unit_Id := Unit (G, Vertex);
         U_Rec : Unit_Record renames ALI.Units.Table (U_Id);

      begin
         return U_Rec.Utype = Is_Spec;
      end Is_Spec_With_Body;

      ---------------------------------
      -- Is_Spec_With_Elaborate_Body --
      ---------------------------------

      function Is_Spec_With_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return
           Is_Spec_With_Body (G, Vertex)
             and then Has_Elaborate_Body (G, Vertex);
      end Is_Spec_With_Elaborate_Body;

      ------------------------------
      -- Is_Static_Successor_Edge --
      ------------------------------

      function Is_Static_Successor_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return
           Is_Invocation_Edge (G, Edge)
             and then not Is_Dynamically_Elaborated (G, Successor (G, Edge));
      end Is_Static_Successor_Edge;

      -----------------------------------
      -- Is_Vertex_With_Elaborate_Body --
      -----------------------------------

      function Is_Vertex_With_Elaborate_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return
           Is_Spec_With_Elaborate_Body (G, Vertex)
             or else
           Is_Body_Of_Spec_With_Elaborate_Body (G, Vertex);
      end Is_Vertex_With_Elaborate_Body;

      ---------------------------------
      -- Is_Weakly_Elaborable_Vertex --
      ----------------------------------

      function Is_Weakly_Elaborable_Vertex
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Complement : constant Library_Graph_Vertex_Id :=
                        Complementary_Vertex
                          (G                => G,
                           Vertex           => Vertex,
                           Force_Complement => False);

         Strong_Preds : Natural;
         Weak_Preds   : Natural;

      begin
         --  A vertex is weakly elaborable when:
         --
         --    * It has not been elaborated yet, and
         --    * The complement vertex of an Elaborate_Body pair has not been
         --      elaborated yet, and
         --    * It resides within an elaborable component, and
         --    * It is not waiting on strong predecessors, and
         --    * It is waiting on at least one weak predecessor

         if In_Elaboration_Order (G, Vertex) then
            return False;

         elsif Present (Complement)
           and then In_Elaboration_Order (G, Complement)
         then
            return False;

         elsif not Is_Elaborable_Component (G, Component (G, Vertex)) then
            return False;
         end if;

         Pending_Predecessors_For_Elaboration
           (G            => G,
            Vertex       => Vertex,
            Strong_Preds => Strong_Preds,
            Weak_Preds   => Weak_Preds);

         return Strong_Preds = 0 and then Weak_Preds >= 1;
      end Is_Weakly_Elaborable_Vertex;

      ------------------
      -- Is_With_Edge --
      ------------------

      function Is_With_Edge
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (G, Edge) = With_Edge;
      end Is_With_Edge;

      ------------------------
      -- Iterate_All_Cycles --
      ------------------------

      function Iterate_All_Cycles
        (G : Library_Graph) return All_Cycle_Iterator
      is
      begin
         pragma Assert (Present (G));

         return All_Cycle_Iterator (LGC_Lists.Iterate (G.Cycles));
      end Iterate_All_Cycles;

      -----------------------
      -- Iterate_All_Edges --
      -----------------------

      function Iterate_All_Edges
        (G : Library_Graph) return All_Edge_Iterator
      is
      begin
         pragma Assert (Present (G));

         return All_Edge_Iterator (DG.Iterate_All_Edges (G.Graph));
      end Iterate_All_Edges;

      --------------------------
      -- Iterate_All_Vertices --
      --------------------------

      function Iterate_All_Vertices
        (G : Library_Graph) return All_Vertex_Iterator
      is
      begin
         pragma Assert (Present (G));

         return All_Vertex_Iterator (DG.Iterate_All_Vertices (G.Graph));
      end Iterate_All_Vertices;

      ------------------------
      -- Iterate_Components --
      ------------------------

      function Iterate_Components
        (G : Library_Graph) return Component_Iterator
      is
      begin
         pragma Assert (Present (G));

         return Component_Iterator (DG.Iterate_Components (G.Graph));
      end Iterate_Components;

      --------------------------------
      -- Iterate_Component_Vertices --
      --------------------------------

      function Iterate_Component_Vertices
        (G    : Library_Graph;
         Comp : Component_Id) return Component_Vertex_Iterator
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         return
           Component_Vertex_Iterator
             (DG.Iterate_Component_Vertices (G.Graph, Comp));
      end Iterate_Component_Vertices;

      ----------------------------
      -- Iterate_Edges_Of_Cycle --
      ----------------------------

      function Iterate_Edges_Of_Cycle
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Edges_Of_Cycle_Iterator
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return Edges_Of_Cycle_Iterator (LGE_Lists.Iterate (Path (G, Cycle)));
      end Iterate_Edges_Of_Cycle;

      ---------------------------------
      -- Iterate_Edges_To_Successors --
      ---------------------------------

      function Iterate_Edges_To_Successors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Edges_To_Successors_Iterator
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return
           Edges_To_Successors_Iterator
             (DG.Iterate_Outgoing_Edges (G.Graph, Vertex));
      end Iterate_Edges_To_Successors;

      ----------
      -- Kind --
      ----------

      function Kind
        (G      : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Library_Graph_Cycle_Kind
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return Get_LGC_Attributes (G, Cycle).Kind;
      end Kind;

      ----------
      -- Kind --
      ----------

      function Kind
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Edge_Kind
      is
      begin
         return Get_LGE_Attributes (G, Edge).Kind;
      end Kind;

      ------------
      -- Length --
      ------------

      function Length
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return LGE_Lists.Size (Path (G, Cycle));
      end Length;

      ------------------------------
      -- Library_Graph_Edge_Count --
      ------------------------------

      function Library_Graph_Edge_Count
        (G    : Library_Graph;
         Kind : Library_Graph_Edge_Kind) return Natural
      is
      begin
         pragma Assert (Present (G));

         return G.Counts (Kind);
      end Library_Graph_Edge_Count;

      --------------------------------------
      -- Links_Vertices_In_Same_Component --
      --------------------------------------

      function Links_Vertices_In_Same_Component
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         --  An edge is part of a cycle when both the successor and predecessor
         --  reside in the same component.

         return
           In_Same_Component
             (G     => G,
              Left  => Predecessor (G, Edge),
              Right => Successor   (G, Edge));
      end Links_Vertices_In_Same_Component;

      -----------------------------------
      -- Maximum_Invocation_Edge_Count --
      -----------------------------------

      function Maximum_Invocation_Edge_Count
        (G     : Library_Graph;
         Edge  : Library_Graph_Edge_Id;
         Count : Natural) return Natural
      is
         New_Count : Natural;

      begin
         pragma Assert (Present (G));

         New_Count := Count;

         if Present (Edge) and then Is_Invocation_Edge (G, Edge) then
            New_Count := New_Count + 1;
         end if;

         return New_Count;
      end Maximum_Invocation_Edge_Count;

      ----------
      -- Name --
      ----------

      function Name
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Unit_Name_Type
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Name (Unit (G, Vertex));
      end Name;

      -----------------------
      -- Needs_Elaboration --
      -----------------------

      function Needs_Elaboration
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Boolean
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Needs_Elaboration (Unit (G, Vertex));
      end Needs_Elaboration;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter  : in out All_Cycle_Iterator;
         Cycle : out Library_Graph_Cycle_Id)
      is
      begin
         LGC_Lists.Next (LGC_Lists.Iterator (Iter), Cycle);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out All_Edge_Iterator;
         Edge : out Library_Graph_Edge_Id)
      is
      begin
         DG.Next (DG.All_Edge_Iterator (Iter), Edge);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter   : in out All_Vertex_Iterator;
         Vertex : out Library_Graph_Vertex_Id)
      is
      begin
         DG.Next (DG.All_Vertex_Iterator (Iter), Vertex);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out Edges_Of_Cycle_Iterator;
         Edge : out Library_Graph_Edge_Id)
      is
      begin
         LGE_Lists.Next (LGE_Lists.Iterator (Iter), Edge);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out Component_Iterator;
         Comp : out Component_Id)
      is
      begin
         DG.Next (DG.Component_Iterator (Iter), Comp);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out Edges_To_Successors_Iterator;
         Edge : out Library_Graph_Edge_Id)
      is
      begin
         DG.Next (DG.Outgoing_Edge_Iterator (Iter), Edge);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter   : in out Component_Vertex_Iterator;
         Vertex : out Library_Graph_Vertex_Id)
      is
      begin
         DG.Next (DG.Component_Vertex_Iterator (Iter), Vertex);
      end Next;

      --------------------------
      -- Normalize_Cycle_Path --
      --------------------------

      procedure Normalize_Cycle_Path
        (Cycle_Path            : LGE_Lists.Doubly_Linked_List;
         Most_Significant_Edge : Library_Graph_Edge_Id)
      is
         Edge : Library_Graph_Edge_Id;

      begin
         pragma Assert (LGE_Lists.Present (Cycle_Path));
         pragma Assert (Present (Most_Significant_Edge));

         --  Perform at most |Cycle_Path| rotations in case the cycle is
         --  malformed and the significant edge does not appear within.

         for Rotation in 1 .. LGE_Lists.Size (Cycle_Path) loop
            Edge := LGE_Lists.First (Cycle_Path);

            --  The cycle is already rotated such that the most significant
            --  edge is first.

            if Edge = Most_Significant_Edge then
               return;

            --  Otherwise rotate the cycle by relocating the current edge from
            --  the start to the end of the path. This preserves the order of
            --  the path.

            else
               LGE_Lists.Delete_First (Cycle_Path);
               LGE_Lists.Append (Cycle_Path, Edge);
            end if;
         end loop;

         pragma Assert (False);
      end Normalize_Cycle_Path;

      ----------------------------------
      -- Number_Of_Component_Vertices --
      ----------------------------------

      function Number_Of_Component_Vertices
        (G    : Library_Graph;
         Comp : Component_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         return DG.Number_Of_Component_Vertices (G.Graph, Comp);
      end Number_Of_Component_Vertices;

      --------------------------
      -- Number_Of_Components --
      --------------------------

      function Number_Of_Components (G : Library_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Components (G.Graph);
      end Number_Of_Components;

      ----------------------
      -- Number_Of_Cycles --
      ----------------------

      function Number_Of_Cycles (G : Library_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return LGC_Lists.Size (G.Cycles);
      end Number_Of_Cycles;

      ---------------------
      -- Number_Of_Edges --
      ---------------------

      function Number_Of_Edges (G : Library_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Edges (G.Graph);
      end Number_Of_Edges;

      -----------------------------------
      -- Number_Of_Edges_To_Successors --
      -----------------------------------

      function Number_Of_Edges_To_Successors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Natural
      is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Outgoing_Edges (G.Graph, Vertex);
      end Number_Of_Edges_To_Successors;

      ------------------------
      -- Number_Of_Vertices --
      ------------------------

      function Number_Of_Vertices (G : Library_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Vertices (G.Graph);
      end Number_Of_Vertices;

      -----------------
      -- Order_Cycle --
      -----------------

      procedure Order_Cycle
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id)
      is
         Lesser_Cycle : Library_Graph_Cycle_Id;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));
         pragma Assert (LGC_Lists.Present (G.Cycles));

         --  The input cycle is the first to be inserted

         if LGC_Lists.Is_Empty (G.Cycles) then
            LGC_Lists.Prepend (G.Cycles, Cycle);

         --  Otherwise the list of all cycles contains at least one cycle.
         --  Insert the input cycle based on its precedence.

         else
            Lesser_Cycle := Find_First_Lower_Precedence_Cycle (G, Cycle);

            --  The list contains at least one cycle, and the input cycle has a
            --  higher precedence compared to some cycle in the list.

            if Present (Lesser_Cycle) then
               LGC_Lists.Insert_Before
                 (L      => G.Cycles,
                  Before => Lesser_Cycle,
                  Elem   => Cycle);

            --  Otherwise the input cycle has the lowest precedence among all
            --  cycles.

            else
               LGC_Lists.Append (G.Cycles, Cycle);
            end if;
         end if;
      end Order_Cycle;

      ----------
      -- Path --
      ----------

      function Path
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id) return LGE_Lists.Doubly_Linked_List
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         return Get_LGC_Attributes (G, Cycle).Path;
      end Path;

      ------------------------------------------
      -- Pending_Predecessors_For_Elaboration --
      ------------------------------------------

      procedure Pending_Predecessors_For_Elaboration
        (G            : Library_Graph;
         Vertex       : Library_Graph_Vertex_Id;
         Strong_Preds : out Natural;
         Weak_Preds   : out Natural)
      is
         Complement         : Library_Graph_Vertex_Id;
         Spec_Vertex        : Library_Graph_Vertex_Id;
         Total_Strong_Preds : Natural;
         Total_Weak_Preds   : Natural;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Total_Strong_Preds := Pending_Strong_Predecessors (G, Vertex);
         Total_Weak_Preds   := Pending_Weak_Predecessors   (G, Vertex);

         --  Assume that there is no complementary vertex that needs to be
         --  examined.

         Complement  := No_Library_Graph_Vertex;
         Spec_Vertex := No_Library_Graph_Vertex;

         if Is_Body_Of_Spec_With_Elaborate_Body (G, Vertex) then
            Complement  := Proper_Spec (G, Vertex);
            Spec_Vertex := Complement;

         elsif Is_Spec_With_Elaborate_Body (G, Vertex) then
            Complement  := Proper_Body (G, Vertex);
            Spec_Vertex := Vertex;
         end if;

         --  The vertex is part of an Elaborate_Body pair. Take into account
         --  the strong and weak predecessors of the complementary vertex.

         if Present (Complement) then
            Total_Strong_Preds :=
              Pending_Strong_Predecessors (G, Complement) + Total_Strong_Preds;
            Total_Weak_Preds :=
              Pending_Weak_Predecessors   (G, Complement) + Total_Weak_Preds;

            --  The body of an Elaborate_Body pair is the successor of a strong
            --  edge where the predecessor is the spec. This edge must not be
            --  considered for elaboration purposes because the pair is treated
            --  as one vertex. Account for the edge only when the spec has not
            --  been elaborated yet.

            if not In_Elaboration_Order (G, Spec_Vertex) then
               Total_Strong_Preds := Total_Strong_Preds - 1;
            end if;
         end if;

         Strong_Preds := Total_Strong_Preds;
         Weak_Preds   := Total_Weak_Preds;
      end Pending_Predecessors_For_Elaboration;

      ---------------------------------
      -- Pending_Strong_Predecessors --
      ---------------------------------

      function Pending_Strong_Predecessors
        (G    : Library_Graph;
         Comp : Component_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         return Get_Component_Attributes (G, Comp).Pending_Strong_Predecessors;
      end Pending_Strong_Predecessors;

      ---------------------------------
      -- Pending_Strong_Predecessors --
      ---------------------------------

      function Pending_Strong_Predecessors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_LGV_Attributes (G, Vertex).Pending_Strong_Predecessors;
      end Pending_Strong_Predecessors;

      -------------------------------
      -- Pending_Weak_Predecessors --
      -------------------------------

      function Pending_Weak_Predecessors
        (G    : Library_Graph;
         Comp : Component_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         return Get_Component_Attributes (G, Comp).Pending_Weak_Predecessors;
      end Pending_Weak_Predecessors;

      -------------------------------
      -- Pending_Weak_Predecessors --
      -------------------------------

      function Pending_Weak_Predecessors
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_LGV_Attributes (G, Vertex).Pending_Weak_Predecessors;
      end Pending_Weak_Predecessors;

      -----------------
      -- Predecessor --
      -----------------

      function Predecessor
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return DG.Source_Vertex (G.Graph, Edge);
      end Predecessor;

      -------------
      -- Present --
      -------------

      function Present (G : Library_Graph) return Boolean is
      begin
         return G /= Nil;
      end Present;

      -----------------
      -- Proper_Body --
      -----------------

      function Proper_Body
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         --  When the vertex denotes a spec with a completing body, return the
         --  body.

         if Is_Spec_With_Body (G, Vertex) then
            return Corresponding_Item (G, Vertex);

         --  Otherwise the vertex must be a body

         else
            pragma Assert (Is_Body (G, Vertex));
            return Vertex;
         end if;
      end Proper_Body;

      -----------------
      -- Proper_Spec --
      -----------------

      function Proper_Spec
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         --  When the vertex denotes a body that completes a spec, return the
         --  spec.

         if Is_Body_With_Spec (G, Vertex) then
            return Corresponding_Item (G, Vertex);

         --  Otherwise the vertex must denote a spec

         else
            pragma Assert (Is_Spec (G, Vertex));
            return Vertex;
         end if;
      end Proper_Spec;

      ------------------
      -- Record_Cycle --
      ------------------

      procedure Record_Cycle
        (G                     : Library_Graph;
         Most_Significant_Edge : Library_Graph_Edge_Id;
         Invocation_Edge_Count : Natural;
         Cycle_Path            : LGE_Lists.Doubly_Linked_List;
         Indent                : Indentation_Level)
      is
         Cycle : Library_Graph_Cycle_Id;
         Path  : LGE_Lists.Doubly_Linked_List;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Most_Significant_Edge));
         pragma Assert (LGE_Lists.Present (Cycle_Path));

         --  Replicate the path of the cycle in order to avoid sharing lists

         Path := Copy_Cycle_Path (Cycle_Path);

         --  Normalize the path of the cycle such that its most significant
         --  edge is the first in the list of edges.

         Normalize_Cycle_Path
           (Cycle_Path            => Path,
            Most_Significant_Edge => Most_Significant_Edge);

         --  Save the cycle for diagnostic purposes. Its kind is determined by
         --  its most significant edge.

         Cycle := Sequence_Next_Cycle;

         Set_LGC_Attributes
           (G     => G,
            Cycle => Cycle,
            Val   =>
              (Invocation_Edge_Count => Invocation_Edge_Count,
               Kind                  =>
                 Cycle_Kind_Of
                   (G    => G,
                    Edge => Most_Significant_Edge),
               Path                  => Path));

         Trace_Cycle (G, Cycle, Indent);

         --  Order the cycle based on its precedence relative to previously
         --  discovered cycles.

         Order_Cycle (G, Cycle);
      end Record_Cycle;

      -----------------------------------------
      -- Same_Library_Graph_Cycle_Attributes --
      -----------------------------------------

      function Same_Library_Graph_Cycle_Attributes
        (Left  : Library_Graph_Cycle_Attributes;
         Right : Library_Graph_Cycle_Attributes) return Boolean
      is
      begin
         --  Two cycles are the same when
         --
         --    * They are of the same kind
         --    * They have the same number of invocation edges in their paths
         --    * Their paths are the same length
         --    * The edges comprising their paths are the same

         return
            Left.Invocation_Edge_Count = Right.Invocation_Edge_Count
              and then Left.Kind = Right.Kind
              and then LGE_Lists.Equal (Left.Path, Right.Path);
      end Same_Library_Graph_Cycle_Attributes;

      ------------------------
      -- Set_Activates_Task --
      ------------------------

      procedure Set_Activates_Task
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id)
      is
         Attributes : Library_Graph_Edge_Attributes :=
           Get_LGE_Attributes (G, Edge);
      begin
         Attributes.Activates_Task := True;
         Set_LGE_Attributes (G, Edge, Attributes);
      end Set_Activates_Task;

      ------------------------------
      -- Set_Component_Attributes --
      ------------------------------

      procedure Set_Component_Attributes
        (G    : Library_Graph;
         Comp : Component_Id;
         Val  : Component_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         Component_Tables.Put (G.Component_Attributes, Comp, Val);
      end Set_Component_Attributes;

      ----------------------------
      -- Set_Corresponding_Item --
      ----------------------------

      procedure Set_Corresponding_Item
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Val    : Library_Graph_Vertex_Id)
      is
         Attrs : Library_Graph_Vertex_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Attrs := Get_LGV_Attributes (G, Vertex);
         Attrs.Corresponding_Item := Val;
         Set_LGV_Attributes (G, Vertex, Attrs);
      end Set_Corresponding_Item;

      ------------------------------
      -- Set_Corresponding_Vertex --
      ------------------------------

      procedure Set_Corresponding_Vertex
        (G    : Library_Graph;
         U_Id : Unit_Id;
         Val  : Library_Graph_Vertex_Id)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (U_Id));

         Unit_Tables.Put (G.Unit_To_Vertex, U_Id, Val);
      end Set_Corresponding_Vertex;

      ------------------------------
      -- Set_In_Elaboration_Order --
      ------------------------------

      procedure Set_In_Elaboration_Order
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Val    : Boolean := True)
      is
         Attrs : Library_Graph_Vertex_Attributes;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Attrs := Get_LGV_Attributes (G, Vertex);
         Attrs.In_Elaboration_Order := Val;
         Set_LGV_Attributes (G, Vertex, Attrs);
      end Set_In_Elaboration_Order;

      --------------------------
      -- Set_Is_Recorded_Edge --
      --------------------------

      procedure Set_Is_Recorded_Edge
        (G   : Library_Graph;
         Rel : Predecessor_Successor_Relation)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Rel.Predecessor));
         pragma Assert (Present (Rel.Successor));

         RE_Sets.Insert (G.Recorded_Edges, Rel);
      end Set_Is_Recorded_Edge;

      ------------------------
      -- Set_LGC_Attributes --
      ------------------------

      procedure Set_LGC_Attributes
        (G     : Library_Graph;
         Cycle : Library_Graph_Cycle_Id;
         Val   : Library_Graph_Cycle_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         LGC_Tables.Put (G.Cycle_Attributes, Cycle, Val);
      end Set_LGC_Attributes;

      ------------------------
      -- Set_LGE_Attributes --
      ------------------------

      procedure Set_LGE_Attributes
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id;
         Val  : Library_Graph_Edge_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         LGE_Tables.Put (G.Edge_Attributes, Edge, Val);
      end Set_LGE_Attributes;

      ------------------------
      -- Set_LGV_Attributes --
      ------------------------

      procedure Set_LGV_Attributes
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Val    : Library_Graph_Vertex_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         LGV_Tables.Put (G.Vertex_Attributes, Vertex, Val);
      end Set_LGV_Attributes;

      ---------------
      -- Successor --
      ---------------

      function Successor
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return DG.Destination_Vertex (G.Graph, Edge);
      end Successor;

      ---------------------
      -- Trace_Component --
      ---------------------

      procedure Trace_Component
        (G      : Library_Graph;
         Comp   : Component_Id;
         Indent : Indentation_Level)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Comp));

         --  Nothing to do when switch -d_t (output cycle-detection trace
         --  information) is not in effect.

         if not Debug_Flag_Underscore_T then
            return;
         end if;

         Write_Eol;
         Indent_By (Indent);
         Write_Str ("component (Comp_");
         Write_Int (Int (Comp));
         Write_Str (")");
         Write_Eol;
      end Trace_Component;

      -----------------
      -- Trace_Cycle --
      -----------------

      procedure Trace_Cycle
        (G      : Library_Graph;
         Cycle  : Library_Graph_Cycle_Id;
         Indent : Indentation_Level)
      is
         Attr_Indent : constant Indentation_Level :=
                         Indent + Nested_Indentation;
         Edge_Indent : constant Indentation_Level :=
                         Attr_Indent + Nested_Indentation;

         Edge : Library_Graph_Edge_Id;
         Iter : Edges_Of_Cycle_Iterator;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Cycle));

         --  Nothing to do when switch -d_t (output cycle-detection trace
         --  information) is not in effect.

         if not Debug_Flag_Underscore_T then
            return;
         end if;

         Indent_By (Indent);
         Write_Str ("cycle (LGC_Id_");
         Write_Int (Int (Cycle));
         Write_Str (")");
         Write_Eol;

         Indent_By (Attr_Indent);
         Write_Str ("kind = ");
         Write_Str (Kind (G, Cycle)'Img);
         Write_Eol;

         Indent_By (Attr_Indent);
         Write_Str ("invocation edges = ");
         Write_Int (Int (Invocation_Edge_Count (G, Cycle)));
         Write_Eol;

         Indent_By (Attr_Indent);
         Write_Str ("length: ");
         Write_Int (Int (Length (G, Cycle)));
         Write_Eol;

         Iter := Iterate_Edges_Of_Cycle (G, Cycle);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            Indent_By (Edge_Indent);
            Write_Str ("library graph edge (LGE_Id_");
            Write_Int (Int (Edge));
            Write_Str (")");
            Write_Eol;
         end loop;
      end Trace_Cycle;

      ----------------
      -- Trace_Edge --
      ----------------

      procedure Trace_Edge
        (G      : Library_Graph;
         Edge   : Library_Graph_Edge_Id;
         Indent : Indentation_Level)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         Attr_Indent : constant Indentation_Level :=
                         Indent + Nested_Indentation;

         Pred : constant Library_Graph_Vertex_Id := Predecessor (G, Edge);
         Succ : constant Library_Graph_Vertex_Id := Successor   (G, Edge);

      begin
         --  Nothing to do when switch -d_t (output cycle-detection trace
         --  information) is not in effect.

         if not Debug_Flag_Underscore_T then
            return;
         end if;

         Indent_By (Indent);
         Write_Str ("library graph edge (LGE_Id_");
         Write_Int (Int (Edge));
         Write_Str (")");
         Write_Eol;

         Indent_By (Attr_Indent);
         Write_Str ("kind = ");
         Write_Str (Kind (G, Edge)'Img);
         Write_Eol;

         Indent_By  (Attr_Indent);
         Write_Str  ("Predecessor (LGV_Id_");
         Write_Int  (Int (Pred));
         Write_Str  (") name = ");
         Write_Name (Name (G, Pred));
         Write_Eol;

         Indent_By  (Attr_Indent);
         Write_Str  ("Successor   (LGV_Id_");
         Write_Int  (Int (Succ));
         Write_Str  (") name = ");
         Write_Name (Name (G, Succ));
         Write_Eol;
      end Trace_Edge;

      ------------------
      -- Trace_Vertex --
      ------------------

      procedure Trace_Vertex
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id;
         Indent : Indentation_Level)
      is
         Attr_Indent : constant Indentation_Level :=
                         Indent + Nested_Indentation;

      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         --  Nothing to do when switch -d_t (output cycle-detection trace
         --  information) is not in effect.

         if not Debug_Flag_Underscore_T then
            return;
         end if;

         Indent_By (Indent);
         Write_Str ("library graph vertex (LGV_Id_");
         Write_Int (Int (Vertex));
         Write_Str (")");
         Write_Eol;

         Indent_By  (Attr_Indent);
         Write_Str  ("Unit (U_Id_");
         Write_Int  (Int (Unit (G, Vertex)));
         Write_Str  (") name = ");
         Write_Name (Name (G, Vertex));
         Write_Eol;
      end Trace_Vertex;

      ----------
      -- Unit --
      ----------

      function Unit
        (G      : Library_Graph;
         Vertex : Library_Graph_Vertex_Id) return Unit_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_LGV_Attributes (G, Vertex).Unit;
      end Unit;

      -------------
      -- Unvisit --
      -------------

      procedure Unvisit
        (Vertex        : Library_Graph_Vertex_Id;
         Visited_Set   : LGV_Sets.Membership_Set;
         Visited_Stack : LGV_Lists.Doubly_Linked_List)
      is
         Current_Vertex : Library_Graph_Vertex_Id;

      begin
         pragma Assert (Present (Vertex));
         pragma Assert (LGV_Sets.Present  (Visited_Set));
         pragma Assert (LGV_Lists.Present (Visited_Stack));

         while not LGV_Lists.Is_Empty (Visited_Stack) loop
            Current_Vertex := LGV_Lists.First (Visited_Stack);

            LGV_Lists.Delete_First (Visited_Stack);
            LGV_Sets.Delete (Visited_Set, Current_Vertex);

            exit when Current_Vertex = Vertex;
         end loop;
      end Unvisit;

      ---------------------------------
      -- Update_Pending_Predecessors --
      ---------------------------------

      procedure Update_Pending_Predecessors
        (Strong_Predecessors : in out Natural;
         Weak_Predecessors   : in out Natural;
         Update_Weak         : Boolean;
         Value               : Integer)
      is
      begin
         if Update_Weak then
            Weak_Predecessors := Weak_Predecessors + Value;
         else
            Strong_Predecessors := Strong_Predecessors + Value;
         end if;
      end Update_Pending_Predecessors;

      -----------------------------------------------
      -- Update_Pending_Predecessors_Of_Components --
      -----------------------------------------------

      procedure Update_Pending_Predecessors_Of_Components
        (G : Library_Graph)
      is
         Edge : Library_Graph_Edge_Id;
         Iter : All_Edge_Iterator;

      begin
         pragma Assert (Present (G));

         Iter := Iterate_All_Edges (G);
         while Has_Next (Iter) loop
            Next (Iter, Edge);

            Update_Pending_Predecessors_Of_Components (G, Edge);
         end loop;
      end Update_Pending_Predecessors_Of_Components;

      -----------------------------------------------
      -- Update_Pending_Predecessors_Of_Components --
      -----------------------------------------------

      procedure Update_Pending_Predecessors_Of_Components
        (G    : Library_Graph;
         Edge : Library_Graph_Edge_Id)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         Pred_Comp : constant Component_Id :=
                       Component (G, Predecessor (G, Edge));
         Succ_Comp : constant Component_Id :=
                       Component (G, Successor   (G, Edge));

         pragma Assert (Present (Pred_Comp));
         pragma Assert (Present (Succ_Comp));

      begin
         --  The edge links a successor and a predecessor coming from two
         --  different SCCs. This indicates that the SCC of the successor
         --  must wait on another predecessor until it can be elaborated.

         if Pred_Comp /= Succ_Comp then
            Increment_Pending_Predecessors
              (G    => G,
               Comp => Succ_Comp,
               Edge => Edge);
         end if;
      end Update_Pending_Predecessors_Of_Components;

      -----------------------
      -- Vertex_Precedence --
      -----------------------

      function Vertex_Precedence
        (G           : Library_Graph;
         Vertex      : Library_Graph_Vertex_Id;
         Compared_To : Library_Graph_Vertex_Id) return Precedence_Kind
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));
         pragma Assert (Present (Compared_To));

         --  Use lexicographical order to determine precedence and ensure
         --  deterministic behavior.

         if Uname_Less (Name (G, Vertex), Name (G, Compared_To)) then
            return Higher_Precedence;
         else
            return Lower_Precedence;
         end if;
      end Vertex_Precedence;

      -----------
      -- Visit --
      -----------

      procedure Visit
        (Vertex        : Library_Graph_Vertex_Id;
         Visited_Set   : LGV_Sets.Membership_Set;
         Visited_Stack : LGV_Lists.Doubly_Linked_List)
      is
      begin
         pragma Assert (Present (Vertex));
         pragma Assert (LGV_Sets.Present  (Visited_Set));
         pragma Assert (LGV_Lists.Present (Visited_Stack));

         LGV_Sets.Insert   (Visited_Set,   Vertex);
         LGV_Lists.Prepend (Visited_Stack, Vertex);
      end Visit;
   end Library_Graphs;

   -----------------------
   -- Invocation_Graphs --
   -----------------------

   package body Invocation_Graphs is

      -----------------------
      -- Local subprograms --
      -----------------------

      procedure Free is
        new Ada.Unchecked_Deallocation
              (Invocation_Graph_Attributes, Invocation_Graph);

      function Get_IGE_Attributes
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id)
         return Invocation_Graph_Edge_Attributes;
      pragma Inline (Get_IGE_Attributes);
      --  Obtain the attributes of edge Edge of invocation graph G

      function Get_IGV_Attributes
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id)
         return Invocation_Graph_Vertex_Attributes;
      pragma Inline (Get_IGV_Attributes);
      --  Obtain the attributes of vertex Vertex of invocation graph G

      procedure Increment_Invocation_Graph_Edge_Count
        (G    : Invocation_Graph;
         Kind : Invocation_Kind);
      pragma Inline (Increment_Invocation_Graph_Edge_Count);
      --  Increment the number of edges of king Kind in invocation graph G by
      --  one.

      function Is_Elaboration_Root
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Boolean;
      pragma Inline (Is_Elaboration_Root);
      --  Determine whether vertex Vertex of invocation graph denotes the
      --  elaboration procedure of a spec or a body.

      function Is_Existing_Source_Target_Relation
        (G   : Invocation_Graph;
         Rel : Source_Target_Relation) return Boolean;
      pragma Inline (Is_Existing_Source_Target_Relation);
      --  Determine whether a source vertex and a target vertex described by
      --  relation Rel are already related in invocation graph G.

      procedure Save_Elaboration_Root
        (G    : Invocation_Graph;
         Root : Invocation_Graph_Vertex_Id);
      pragma Inline (Save_Elaboration_Root);
      --  Save elaboration root Root of invocation graph G

      procedure Set_Corresponding_Vertex
        (G      : Invocation_Graph;
         IS_Id  : Invocation_Signature_Id;
         Vertex : Invocation_Graph_Vertex_Id);
      pragma Inline (Set_Corresponding_Vertex);
      --  Associate vertex Vertex of invocation graph G with signature IS_Id

      procedure Set_Is_Existing_Source_Target_Relation
        (G   : Invocation_Graph;
         Rel : Source_Target_Relation);
      pragma Inline (Set_Is_Existing_Source_Target_Relation);
      --  Mark a source vertex and a target vertex described by relation Rel as
      --  already related in invocation graph G.

      procedure Set_IGE_Attributes
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id;
         Val  : Invocation_Graph_Edge_Attributes);
      pragma Inline (Set_IGE_Attributes);
      --  Set the attributes of edge Edge of invocation graph G to value Val

      procedure Set_IGV_Attributes
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id;
         Val    : Invocation_Graph_Vertex_Attributes);
      pragma Inline (Set_IGV_Attributes);
      --  Set the attributes of vertex Vertex of invocation graph G to value
      --  Val.

      --------------
      -- Add_Edge --
      --------------

      procedure Add_Edge
        (G      : Invocation_Graph;
         Source : Invocation_Graph_Vertex_Id;
         Target : Invocation_Graph_Vertex_Id;
         IR_Id  : Invocation_Relation_Id)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Source));
         pragma Assert (Present (Target));
         pragma Assert (Present (IR_Id));

         Rel : constant Source_Target_Relation :=
                 (Source => Source,
                  Target => Target);

         Edge : Invocation_Graph_Edge_Id;

      begin
         --  Nothing to do when the source and target are already related by an
         --  edge.

         if Is_Existing_Source_Target_Relation (G, Rel) then
            return;
         end if;

         Edge := Sequence_Next_Edge;

         --  Add the edge to the underlying graph

         DG.Add_Edge
           (G           => G.Graph,
            E           => Edge,
            Source      => Source,
            Destination => Target);

         --  Build and save the attributes of the edge

         Set_IGE_Attributes
           (G    => G,
            Edge => Edge,
            Val  => (Relation => IR_Id));

         --  Mark the source and target as related by the new edge. This
         --  prevents all further attempts to link the same source and target.

         Set_Is_Existing_Source_Target_Relation (G, Rel);

         --  Update the edge statistics

         Increment_Invocation_Graph_Edge_Count (G, Kind (IR_Id));
      end Add_Edge;

      ----------------
      -- Add_Vertex --
      ----------------

      procedure Add_Vertex
        (G           : Invocation_Graph;
         IC_Id       : Invocation_Construct_Id;
         Body_Vertex : Library_Graph_Vertex_Id;
         Spec_Vertex : Library_Graph_Vertex_Id)
      is
         pragma Assert (Present (G));
         pragma Assert (Present (IC_Id));
         pragma Assert (Present (Body_Vertex));
         pragma Assert (Present (Spec_Vertex));

         Construct_Signature : constant Invocation_Signature_Id :=
                                 Signature (IC_Id);
         Vertex : Invocation_Graph_Vertex_Id;

      begin
         --  Nothing to do when the construct already has a vertex

         if Present (Corresponding_Vertex (G, Construct_Signature)) then
            return;
         end if;

         Vertex := Sequence_Next_Vertex;

         --  Add the vertex to the underlying graph

         DG.Add_Vertex (G.Graph, Vertex);

         --  Build and save the attributes of the vertex

         Set_IGV_Attributes
           (G      => G,
            Vertex => Vertex,
            Val    => (Body_Vertex => Body_Vertex,
                       Construct   => IC_Id,
                       Spec_Vertex => Spec_Vertex));

         --  Associate the construct with its corresponding vertex

         Set_Corresponding_Vertex (G, Construct_Signature, Vertex);

         --  Save the vertex for later processing when it denotes a spec or
         --  body elaboration procedure.

         if Is_Elaboration_Root (G, Vertex) then
            Save_Elaboration_Root (G, Vertex);
         end if;
      end Add_Vertex;

      -----------------
      -- Body_Vertex --
      -----------------

      function Body_Vertex
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_IGV_Attributes (G, Vertex).Body_Vertex;
      end Body_Vertex;

      ------------
      -- Column --
      ------------

      function Column
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Nat
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Column (Signature (Construct (G, Vertex)));
      end Column;

      ---------------
      -- Construct --
      ---------------

      function Construct
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Invocation_Construct_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_IGV_Attributes (G, Vertex).Construct;
      end Construct;

      --------------------------
      -- Corresponding_Vertex --
      --------------------------

      function Corresponding_Vertex
        (G     : Invocation_Graph;
         IS_Id : Invocation_Signature_Id) return Invocation_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (IS_Id));

         return Signature_Tables.Get (G.Signature_To_Vertex, IS_Id);
      end Corresponding_Vertex;

      ------------
      -- Create --
      ------------

      function Create
        (Initial_Vertices : Positive;
         Initial_Edges    : Positive;
         Lib_Graph        : Library_Graphs.Library_Graph)
        return Invocation_Graph
      is
         G : constant Invocation_Graph := new Invocation_Graph_Attributes'
           (Counts              => <>,
            Edge_Attributes     => IGE_Tables.Create       (Initial_Edges),
            Graph               =>
              DG.Create
                (Initial_Vertices => Initial_Vertices,
                 Initial_Edges    => Initial_Edges),
            Relations           => Relation_Sets.Create    (Initial_Edges),
            Roots               => IGV_Sets.Create         (Initial_Vertices),
            Signature_To_Vertex => Signature_Tables.Create (Initial_Vertices),
            Vertex_Attributes   => IGV_Tables.Create       (Initial_Vertices),
            Lib_Graph           => Lib_Graph);
      begin
         return G;
      end Create;

      -------------
      -- Destroy --
      -------------

      procedure Destroy (G : in out Invocation_Graph) is
      begin
         pragma Assert (Present (G));

         IGE_Tables.Destroy       (G.Edge_Attributes);
         DG.Destroy               (G.Graph);
         Relation_Sets.Destroy    (G.Relations);
         IGV_Sets.Destroy         (G.Roots);
         Signature_Tables.Destroy (G.Signature_To_Vertex);
         IGV_Tables.Destroy       (G.Vertex_Attributes);

         Free (G);
      end Destroy;

      -----------------------------------
      -- Destroy_Invocation_Graph_Edge --
      -----------------------------------

      procedure Destroy_Invocation_Graph_Edge
        (Edge : in out Invocation_Graph_Edge_Id)
      is
         pragma Unreferenced (Edge);
      begin
         null;
      end Destroy_Invocation_Graph_Edge;

      ----------------------------------------------
      -- Destroy_Invocation_Graph_Edge_Attributes --
      ----------------------------------------------

      procedure Destroy_Invocation_Graph_Edge_Attributes
        (Attrs : in out Invocation_Graph_Edge_Attributes)
      is
         pragma Unreferenced (Attrs);
      begin
         null;
      end Destroy_Invocation_Graph_Edge_Attributes;

      -------------------------------------
      -- Destroy_Invocation_Graph_Vertex --
      -------------------------------------

      procedure Destroy_Invocation_Graph_Vertex
        (Vertex : in out Invocation_Graph_Vertex_Id)
      is
         pragma Unreferenced (Vertex);
      begin
         null;
      end Destroy_Invocation_Graph_Vertex;

      ------------------------------------------------
      -- Destroy_Invocation_Graph_Vertex_Attributes --
      ------------------------------------------------

      procedure Destroy_Invocation_Graph_Vertex_Attributes
        (Attrs : in out Invocation_Graph_Vertex_Attributes)
      is
         pragma Unreferenced (Attrs);
      begin
         null;
      end Destroy_Invocation_Graph_Vertex_Attributes;

      -----------
      -- Extra --
      -----------

      function Extra
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id) return Name_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Extra (Relation (G, Edge));
      end Extra;

      ------------------------
      -- Get_IGE_Attributes --
      ------------------------

      function Get_IGE_Attributes
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id)
         return Invocation_Graph_Edge_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return IGE_Tables.Get (G.Edge_Attributes, Edge);
      end Get_IGE_Attributes;

      ------------------------
      -- Get_IGV_Attributes --
      ------------------------

      function Get_IGV_Attributes
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id)
         return Invocation_Graph_Vertex_Attributes
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return IGV_Tables.Get (G.Vertex_Attributes, Vertex);
      end Get_IGV_Attributes;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : All_Edge_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.All_Edge_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : All_Vertex_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.All_Vertex_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Edges_To_Targets_Iterator) return Boolean is
      begin
         return DG.Has_Next (DG.Outgoing_Edge_Iterator (Iter));
      end Has_Next;

      --------------
      -- Has_Next --
      --------------

      function Has_Next (Iter : Elaboration_Root_Iterator) return Boolean is
      begin
         return IGV_Sets.Has_Next (IGV_Sets.Iterator (Iter));
      end Has_Next;

      -------------------------------
      -- Hash_Invocation_Signature --
      -------------------------------

      function Hash_Invocation_Signature
        (IS_Id : Invocation_Signature_Id) return Bucket_Range_Type
      is
      begin
         pragma Assert (Present (IS_Id));

         return Bucket_Range_Type (IS_Id);
      end Hash_Invocation_Signature;

      ---------------------------------
      -- Hash_Source_Target_Relation --
      ---------------------------------

      function Hash_Source_Target_Relation
        (Rel : Source_Target_Relation) return Bucket_Range_Type
      is
      begin
         pragma Assert (Present (Rel.Source));
         pragma Assert (Present (Rel.Target));

         return
           Hash_Two_Keys
             (Bucket_Range_Type (Rel.Source),
              Bucket_Range_Type (Rel.Target));
      end Hash_Source_Target_Relation;

      -------------------------------------------
      -- Increment_Invocation_Graph_Edge_Count --
      -------------------------------------------

      procedure Increment_Invocation_Graph_Edge_Count
        (G    : Invocation_Graph;
         Kind : Invocation_Kind)
      is
         pragma Assert (Present (G));

         Count : Natural renames G.Counts (Kind);

      begin
         Count := Count + 1;
      end Increment_Invocation_Graph_Edge_Count;

      ---------------------------------
      -- Invocation_Graph_Edge_Count --
      ---------------------------------

      function Invocation_Graph_Edge_Count
        (G    : Invocation_Graph;
         Kind : Invocation_Kind) return Natural
      is
      begin
         pragma Assert (Present (G));

         return G.Counts (Kind);
      end Invocation_Graph_Edge_Count;

      -------------------------
      -- Is_Elaboration_Root --
      -------------------------

      function Is_Elaboration_Root
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Boolean
      is
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         Vertex_Kind : constant Invocation_Construct_Kind :=
                         Kind (Construct (G, Vertex));

      begin
         return
           Vertex_Kind = Elaborate_Body_Procedure
             or else
           Vertex_Kind = Elaborate_Spec_Procedure;
      end Is_Elaboration_Root;

      ----------------------------------------
      -- Is_Existing_Source_Target_Relation --
      ----------------------------------------

      function Is_Existing_Source_Target_Relation
        (G   : Invocation_Graph;
         Rel : Source_Target_Relation) return Boolean
      is
      begin
         pragma Assert (Present (G));

         return Relation_Sets.Contains (G.Relations, Rel);
      end Is_Existing_Source_Target_Relation;

      -----------------------
      -- Iterate_All_Edges --
      -----------------------

      function Iterate_All_Edges
        (G : Invocation_Graph) return All_Edge_Iterator
      is
      begin
         pragma Assert (Present (G));

         return All_Edge_Iterator (DG.Iterate_All_Edges (G.Graph));
      end Iterate_All_Edges;

      --------------------------
      -- Iterate_All_Vertices --
      --------------------------

      function Iterate_All_Vertices
        (G : Invocation_Graph) return All_Vertex_Iterator
      is
      begin
         pragma Assert (Present (G));

         return All_Vertex_Iterator (DG.Iterate_All_Vertices (G.Graph));
      end Iterate_All_Vertices;

      ------------------------------
      -- Iterate_Edges_To_Targets --
      ------------------------------

      function Iterate_Edges_To_Targets
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Edges_To_Targets_Iterator
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return
           Edges_To_Targets_Iterator
             (DG.Iterate_Outgoing_Edges (G.Graph, Vertex));
      end Iterate_Edges_To_Targets;

      -------------------------------
      -- Iterate_Elaboration_Roots --
      -------------------------------

      function Iterate_Elaboration_Roots
        (G : Invocation_Graph) return Elaboration_Root_Iterator
      is
      begin
         pragma Assert (Present (G));

         return Elaboration_Root_Iterator (IGV_Sets.Iterate (G.Roots));
      end Iterate_Elaboration_Roots;

      ----------
      -- Kind --
      ----------

      function Kind
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id) return Invocation_Kind
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Kind (Relation (G, Edge));
      end Kind;

      -------------------
      -- Get_Lib_Graph --
      -------------------

      function Get_Lib_Graph
        (G : Invocation_Graph) return Library_Graphs.Library_Graph
      is
         pragma Assert (Present (G));
      begin
         return G.Lib_Graph;
      end Get_Lib_Graph;

      ----------
      -- Line --
      ----------

      function Line
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Nat
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Line (Signature (Construct (G, Vertex)));
      end Line;

      ----------
      -- Name --
      ----------

      function Name
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Name_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Name (Signature (Construct (G, Vertex)));
      end Name;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out All_Edge_Iterator;
         Edge : out Invocation_Graph_Edge_Id)
      is
      begin
         DG.Next (DG.All_Edge_Iterator (Iter), Edge);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter   : in out All_Vertex_Iterator;
         Vertex : out Invocation_Graph_Vertex_Id)
      is
      begin
         DG.Next (DG.All_Vertex_Iterator (Iter), Vertex);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out Edges_To_Targets_Iterator;
         Edge : out Invocation_Graph_Edge_Id)
      is
      begin
         DG.Next (DG.Outgoing_Edge_Iterator (Iter), Edge);
      end Next;

      ----------
      -- Next --
      ----------

      procedure Next
        (Iter : in out Elaboration_Root_Iterator;
         Root : out Invocation_Graph_Vertex_Id)
      is
      begin
         IGV_Sets.Next (IGV_Sets.Iterator (Iter), Root);
      end Next;

      ---------------------
      -- Number_Of_Edges --
      ---------------------

      function Number_Of_Edges (G : Invocation_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Edges (G.Graph);
      end Number_Of_Edges;

      --------------------------------
      -- Number_Of_Edges_To_Targets --
      --------------------------------

      function Number_Of_Edges_To_Targets
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Natural
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return DG.Number_Of_Outgoing_Edges (G.Graph, Vertex);
      end Number_Of_Edges_To_Targets;

      ---------------------------------
      -- Number_Of_Elaboration_Roots --
      ---------------------------------

      function Number_Of_Elaboration_Roots
        (G : Invocation_Graph) return Natural
      is
      begin
         pragma Assert (Present (G));

         return IGV_Sets.Size (G.Roots);
      end Number_Of_Elaboration_Roots;

      ------------------------
      -- Number_Of_Vertices --
      ------------------------

      function Number_Of_Vertices (G : Invocation_Graph) return Natural is
      begin
         pragma Assert (Present (G));

         return DG.Number_Of_Vertices (G.Graph);
      end Number_Of_Vertices;

      -------------
      -- Present --
      -------------

      function Present (G : Invocation_Graph) return Boolean is
      begin
         return G /= Nil;
      end Present;

      --------------
      -- Relation --
      --------------

      function Relation
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id) return Invocation_Relation_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return Get_IGE_Attributes (G, Edge).Relation;
      end Relation;

      ---------------------------
      -- Save_Elaboration_Root --
      ---------------------------

      procedure Save_Elaboration_Root
        (G    : Invocation_Graph;
         Root : Invocation_Graph_Vertex_Id)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Root));

         IGV_Sets.Insert (G.Roots, Root);
      end Save_Elaboration_Root;

      ------------------------------
      -- Set_Corresponding_Vertex --
      ------------------------------

      procedure Set_Corresponding_Vertex
        (G      : Invocation_Graph;
         IS_Id  : Invocation_Signature_Id;
         Vertex : Invocation_Graph_Vertex_Id)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (IS_Id));
         pragma Assert (Present (Vertex));

         Signature_Tables.Put (G.Signature_To_Vertex, IS_Id, Vertex);
      end Set_Corresponding_Vertex;

      --------------------------------------------
      -- Set_Is_Existing_Source_Target_Relation --
      --------------------------------------------

      procedure Set_Is_Existing_Source_Target_Relation
        (G   : Invocation_Graph;
         Rel : Source_Target_Relation)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Rel.Source));
         pragma Assert (Present (Rel.Target));

         Relation_Sets.Insert (G.Relations, Rel);
      end Set_Is_Existing_Source_Target_Relation;

      ------------------------
      -- Set_IGE_Attributes --
      ------------------------

      procedure Set_IGE_Attributes
        (G    : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id;
         Val  : Invocation_Graph_Edge_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         IGE_Tables.Put (G.Edge_Attributes, Edge, Val);
      end Set_IGE_Attributes;

      ------------------------
      -- Set_IGV_Attributes --
      ------------------------

      procedure Set_IGV_Attributes
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id;
         Val    : Invocation_Graph_Vertex_Attributes)
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         IGV_Tables.Put (G.Vertex_Attributes, Vertex, Val);
      end Set_IGV_Attributes;

      -----------------
      -- Spec_Vertex --
      -----------------

      function Spec_Vertex
        (G      : Invocation_Graph;
         Vertex : Invocation_Graph_Vertex_Id) return Library_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Vertex));

         return Get_IGV_Attributes (G, Vertex).Spec_Vertex;
      end Spec_Vertex;

      ------------
      -- Target --
      ------------

      function Target
        (G      : Invocation_Graph;
         Edge : Invocation_Graph_Edge_Id) return Invocation_Graph_Vertex_Id
      is
      begin
         pragma Assert (Present (G));
         pragma Assert (Present (Edge));

         return DG.Destination_Vertex (G.Graph, Edge);
      end Target;
   end Invocation_Graphs;

   -------------
   -- Present --
   -------------

   function Present (Edge : Invocation_Graph_Edge_Id) return Boolean is
   begin
      return Edge /= No_Invocation_Graph_Edge;
   end Present;

   -------------
   -- Present --
   -------------

   function Present (Vertex : Invocation_Graph_Vertex_Id) return Boolean is
   begin
      return Vertex /= No_Invocation_Graph_Vertex;
   end Present;

   -------------
   -- Present --
   -------------

   function Present (Cycle : Library_Graph_Cycle_Id) return Boolean is
   begin
      return Cycle /= No_Library_Graph_Cycle;
   end Present;

   -------------
   -- Present --
   -------------

   function Present (Edge : Library_Graph_Edge_Id) return Boolean is
   begin
      return Edge /= No_Library_Graph_Edge;
   end Present;

   -------------
   -- Present --
   -------------

   function Present (Vertex : Library_Graph_Vertex_Id) return Boolean is
   begin
      return Vertex /= No_Library_Graph_Vertex;
   end Present;

   --------------------------
   -- Sequence_Next_Edge --
   --------------------------

   IGE_Sequencer : Invocation_Graph_Edge_Id := First_Invocation_Graph_Edge;
   --  The counter for invocation graph edges. Do not directly manipulate its
   --  value.

   function Sequence_Next_Edge return Invocation_Graph_Edge_Id is
      Edge : constant Invocation_Graph_Edge_Id := IGE_Sequencer;

   begin
      IGE_Sequencer := IGE_Sequencer + 1;
      return Edge;
   end Sequence_Next_Edge;

   --------------------------
   -- Sequence_Next_Vertex --
   --------------------------

   IGV_Sequencer : Invocation_Graph_Vertex_Id := First_Invocation_Graph_Vertex;
   --  The counter for invocation graph vertices. Do not directly manipulate
   --  its value.

   function Sequence_Next_Vertex return Invocation_Graph_Vertex_Id is
      Vertex : constant Invocation_Graph_Vertex_Id := IGV_Sequencer;

   begin
      IGV_Sequencer := IGV_Sequencer + 1;
      return Vertex;
   end Sequence_Next_Vertex;

   --------------------------
   -- Sequence_Next_Cycle --
   --------------------------

   LGC_Sequencer : Library_Graph_Cycle_Id := First_Library_Graph_Cycle;
   --  The counter for library graph cycles. Do not directly manipulate its
   --  value.

   function Sequence_Next_Cycle return Library_Graph_Cycle_Id is
      Cycle : constant Library_Graph_Cycle_Id := LGC_Sequencer;

   begin
      LGC_Sequencer := LGC_Sequencer + 1;
      return Cycle;
   end Sequence_Next_Cycle;

   --------------------------
   -- Sequence_Next_Edge --
   --------------------------

   LGE_Sequencer : Library_Graph_Edge_Id := First_Library_Graph_Edge;
   --  The counter for library graph edges. Do not directly manipulate its
   --  value.

   function Sequence_Next_Edge return Library_Graph_Edge_Id is
      Edge : constant Library_Graph_Edge_Id := LGE_Sequencer;

   begin
      LGE_Sequencer := LGE_Sequencer + 1;
      return Edge;
   end Sequence_Next_Edge;

   --------------------------
   -- Sequence_Next_Vertex --
   --------------------------

   LGV_Sequencer : Library_Graph_Vertex_Id := First_Library_Graph_Vertex;
   --  The counter for library graph vertices. Do not directly manipulate its
   --  value.

   function Sequence_Next_Vertex return Library_Graph_Vertex_Id is
      Vertex : constant Library_Graph_Vertex_Id := LGV_Sequencer;

   begin
      LGV_Sequencer := LGV_Sequencer + 1;
      return Vertex;
   end Sequence_Next_Vertex;

end Bindo.Graphs;