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| author | kono |
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| date | Fri, 27 Oct 2017 22:46:09 +0900 |
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-- CXA4023.A -- -- Grant of Unlimited Rights -- -- Under contracts F33600-87-D-0337, F33600-84-D-0280, MDA903-79-C-0687, -- F08630-91-C-0015, and DCA100-97-D-0025, the U.S. Government obtained -- unlimited rights in the software and documentation contained herein. -- Unlimited rights are defined in DFAR 252.227-7013(a)(19). By making -- this public release, the Government intends to confer upon all -- recipients unlimited rights equal to those held by the Government. -- These rights include rights to use, duplicate, release or disclose the -- released technical data and computer software in whole or in part, in -- any manner and for any purpose whatsoever, and to have or permit others -- to do so. -- -- DISCLAIMER -- -- ALL MATERIALS OR INFORMATION HEREIN RELEASED, MADE AVAILABLE OR -- DISCLOSED ARE AS IS. THE GOVERNMENT MAKES NO EXPRESS OR IMPLIED -- WARRANTY AS TO ANY MATTER WHATSOEVER, INCLUDING THE CONDITIONS OF THE -- SOFTWARE, DOCUMENTATION OR OTHER INFORMATION RELEASED, MADE AVAILABLE -- OR DISCLOSED, OR THE OWNERSHIP, MERCHANTABILITY, OR FITNESS FOR A -- PARTICULAR PURPOSE OF SAID MATERIAL. --* -- -- OBJECTIVE: -- Check that the subprograms defined in package -- Ada.Strings.Wide_Unbounded are available, and that they produce -- correct results. Specifically, check the subprograms Delete, -- Find_Token, Translate, Trim, and "*". -- -- TEST DESCRIPTION: -- This test demonstrates the uses of many of the subprograms defined -- in package Ada.Strings.Wide_Unbounded for use with unbounded wide -- strings. The test simulates how unbounded wide strings -- will be processed in a user environment, using the subprograms -- provided in this package. -- -- This test, when taken in conjunction with tests CXA4021-22, will -- constitute a test of the functionality contained in package -- Ada.Strings.Wide_Unbounded. This test uses a variety -- of the subprograms defined in the unbounded wide string package -- in ways typical of common usage, with different combinations of -- available subprograms being used to accomplish similar -- unbounded wide string processing goals. -- -- -- CHANGE HISTORY: -- 06 Dec 94 SAIC ACVC 2.0 -- 08 Nov 95 SAIC Corrected accessibility level and type -- visibility problems for ACVC 2.0.1. -- --! with Ada.Characters.Handling; with Ada.Strings; package CXA40230 is -- The following two functions are used to translate character and string -- values to non-character "Wide" values. They will be applied to all the -- Wide_Bounded subprogram character and string parameters to simulate the -- use of Wide_Characters and Wide_Strings in actual practice. -- Note: These functions do not actually return "equivalent" wide -- characters to their character inputs, just "non-character" -- wide characters. function Equiv (Ch : Character) return Wide_Character; function Equiv (Str : String) return Wide_String; -- Functions and access-to-subprogram object used to supply mapping -- capability to the appropriate versions of Translate. function AB_to_US_Mapping_Function (From : Wide_Character) return Wide_Character; function AB_to_Blank_Mapping_Function (From : Wide_Character) return Wide_Character; end CXA40230; package body CXA40230 is function Equiv (Ch : Character) return Wide_Character is C : Character := Ch; begin if Ch = ' ' then return Ada.Characters.Handling.To_Wide_Character(C); else return Wide_Character'Val(Character'Pos(Ch) + Character'Pos(Character'Last) + 1); end if; end Equiv; function Equiv (Str : String) return Wide_String is WS : Wide_String(Str'First..Str'Last); begin for i in Str'First..Str'Last loop WS(i) := Equiv(Str(i)); end loop; return WS; end Equiv; function AB_to_US_Mapping_Function (From : Wide_Character) return Wide_Character is UnderScore : constant Wide_Character := Equiv('_'); begin if From = Equiv('a') or From = Equiv('b') then return UnderScore; else return From; end if; end AB_to_US_Mapping_Function; function AB_to_Blank_Mapping_Function (From : Wide_Character) return Wide_Character is begin if From = Equiv('a') or From = Equiv('b') then return Ada.Strings.Wide_Space; else return From; end if; end AB_to_Blank_Mapping_Function; end CXA40230; with CXA40230; with Report; with Ada.Characters.Handling; with Ada.Strings.Wide_Maps; with Ada.Strings.Wide_Unbounded; procedure CXA4023 is begin Report.Test ("CXA4023", "Check that the subprograms defined in " & "package Ada.Strings.Wide_Unbounded are " & "available, and that they produce correct " & "results"); Test_Block: declare use CXA40230; package ASW renames Ada.Strings.Wide_Unbounded; use Ada.Strings; use type Wide_Maps.Wide_Character_Set; use type ASW.Unbounded_Wide_String; Test_String : ASW.Unbounded_Wide_String; AtoE_Str : ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("abcde")); Cad_String : ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("cad")); Magic_String : ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("abracadabra")); Incantation : ASW.Unbounded_Wide_String := Magic_String; A_Small_G : Wide_Character := Equiv('g'); ABCD_Set : Wide_Maps.Wide_Character_Set := Wide_Maps.To_Set(Equiv("abcd")); B_Set : Wide_Maps.Wide_Character_Set := Wide_Maps.To_Set(Equiv('b')); AB_Set : Wide_Maps.Wide_Character_Set := Wide_Maps."OR"(Wide_Maps.To_Set(Equiv('a')), B_Set); AB_to_YZ_Map : Wide_Maps.Wide_Character_Mapping := Wide_Maps.To_Mapping(From => Equiv("ab"), To => Equiv("yz")); Code_Map : Wide_Maps.Wide_Character_Mapping := Wide_Maps.To_Mapping(Equiv("abcd"), Equiv("wxyz")); Reverse_Code_Map : Wide_Maps.Wide_Character_Mapping := Wide_Maps.To_Mapping(Equiv("wxyz"), Equiv("abcd")); Non_Existent_Map : Wide_Maps.Wide_Character_Mapping := Wide_Maps.To_Mapping(Equiv("jkl"), Equiv("mno")); Token_Start : Positive; Token_End : Natural := 0; Map_Ptr : Wide_Maps.Wide_Character_Mapping_Function := AB_to_US_Mapping_Function'Access; begin -- Find_Token ASW.Find_Token(Magic_String, -- Find location of first "ab" equiv. AB_Set, -- Should be (1..2). Ada.Strings.Inside, Token_Start, Token_End); if Natural(Token_Start) /= ASW.To_Wide_String(Magic_String)'First or Token_End /= ASW.Index(Magic_String, B_Set) or Token_End /= 2 then Report.Failed("Incorrect result from Procedure Find_Token - 1"); end if; ASW.Find_Token(Source => Magic_String, -- Find location of char 'r'equiv Set => ABCD_Set, -- in wide str, should be (3..3) Test => Ada.Strings.Outside, First => Token_Start, Last => Token_End); if Natural(Token_Start) /= 3 or Token_End /= 3 then Report.Failed("Incorrect result from Procedure Find_Token - 2"); end if; ASW.Find_Token(Magic_String, -- No 'g' "equivalent in Wide_Maps.To_Set(A_Small_G), -- the wide str, so the Ada.Strings.Inside, -- result params should be First => Token_Start, -- First = Source'First and Last => Token_End); -- Last = 0. if Token_Start /= ASW.To_Wide_String(Magic_String)'First or Token_End /= 0 then Report.Failed("Incorrect result from Procedure Find_Token - 3"); end if; ASW.Find_Token(ASW.To_Unbounded_Wide_String(Equiv("abpqpqrttrcpqr")), Wide_Maps.To_Set(Equiv("trpq")), Ada.Strings.Inside, Token_Start, Token_End); if Token_Start /= 3 or Token_End /= 10 then Report.Failed("Incorrect result from Procedure Find_Token - 4"); end if; ASW.Find_Token(ASW.To_Unbounded_Wide_String(Equiv("abpqpqrttrcpqr")), Wide_Maps.To_Set(Equiv("abpq")), Ada.Strings.Outside, Token_Start, Token_End); if Token_Start /= 7 or Token_End /= 11 then Report.Failed("Incorrect result from Procedure Find_Token - 5"); end if; -- Translate -- Use a mapping ("abcd" -> "wxyz") to transform the contents of -- the unbounded wide string. -- Magic_String = "abracadabra" Incantation := ASW.Translate(Magic_String, Code_Map); if Incantation /= ASW.To_Unbounded_Wide_String(Equiv("wxrwywzwxrw")) then Report.Failed("Incorrect result from Function Translate - 1"); end if; -- (Note: See below for additional testing of Function Translate) -- Use the inverse mapping of the one above to return the "translated" -- unbounded wide string to its original form. ASW.Translate(Incantation, Reverse_Code_Map); -- The map contained in the following call to Translate contains three -- elements, and these elements are not found in the unbounded wide -- string, so this call to Translate should have no effect on it. if Incantation /= ASW.Translate(Magic_String, Non_Existent_Map) then Report.Failed("Incorrect result from Procedure Translate - 1"); end if; -- Partial mapping of source. Test_String := ASW.To_Unbounded_Wide_String(Equiv("abcdeabcab")); ASW.Translate(Source => Test_String, Mapping => AB_to_YZ_Map); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv("yzcdeyzcyz")) then Report.Failed("Incorrect result from Procedure Translate - 2"); end if; -- Total mapping of source. Test_String := ASW.To_Unbounded_Wide_String(Equiv("abbaaababb")); ASW.Translate(Source => Test_String, Mapping => AB_to_YZ_Map); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv("yzzyyyzyzz")) then Report.Failed("Incorrect result from Procedure Translate - 3"); end if; -- No mapping of source. Test_String := ASW.To_Unbounded_Wide_String(Equiv("xyzsypcc")); ASW.Translate(Source => Test_String, Mapping => AB_to_YZ_Map); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv("xyzsypcc")) then Report.Failed("Incorrect result from Procedure Translate - 4"); end if; -- Map > 2 characters, partial mapping. Test_String := ASW.To_Unbounded_Wide_String(Equiv("opabcdelmn")); ASW.Translate(Test_String, Wide_Maps.To_Mapping(Equiv("abcde"), Equiv("lmnop"))); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv("oplmnoplmn")) then Report.Failed("Incorrect result from Procedure Translate - 5"); end if; -- Various degrees of mapping of source (full, partial, none) used -- with Function Translate. if ASW.Translate( ASW.To_Unbounded_Wide_String(Equiv("abcdeabcabbbaaacaa")), AB_to_YZ_Map) /= ASW.To_Unbounded_Wide_String(Equiv("yzcdeyzcyzzzyyycyy")) or ASW.Translate( ASW.To_Unbounded_Wide_String(Equiv("abbaaababbaaaaba")), AB_to_YZ_Map) /= ASW.To_Unbounded_Wide_String(Equiv("yzzyyyzyzzyyyyzy")) or ASW.Translate(ASW.To_Unbounded_Wide_String(Equiv("cABcABBAc")), Mapping => AB_to_YZ_Map) /= ASW.To_Unbounded_Wide_String(Equiv("cABcABBAc")) or ASW.Translate(ASW.To_Unbounded_Wide_String("opabcdelmnddeaccabec"), Wide_Maps.To_Mapping("abcde", "lmnop")) /= ASW.To_Unbounded_Wide_String("oplmnoplmnooplnnlmpn") then Report.Failed("Incorrect result from Function Translate - 2"); end if; -- Procedure Translate using access-to-subprogram mapping. -- Partial mapping of source. Map_Ptr := AB_to_Blank_Mapping_Function'Access; Test_String := ASW.To_Unbounded_Wide_String(Equiv("abABaABbaBAbba")); ASW.Translate(Source => Test_String, -- change equivalent of 'a' and Mapping => Map_Ptr); -- 'b' to ' ' if Test_String /= ASW.To_Unbounded_Wide_String(Equiv(" AB AB BA ")) then Report.Failed ("Incorrect result from Proc Translate, w/ access value map - 1"); end if; -- Total mapping of source to blanks. Test_String := ASW.To_Unbounded_Wide_String(Equiv("abbbab")); ASW.Translate(Source => Test_String, Mapping => Map_Ptr); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv(" ")) then Report.Failed ("Incorrect result from Proc Translate, w/ access value map - 2"); end if; -- No mapping of source. Map_Ptr := AB_to_US_Mapping_Function'Access; Test_String := ASW.To_Unbounded_Wide_String(Equiv("xyzsypcc")); ASW.Translate(Source => Test_String, Mapping => Map_Ptr); if Test_String /= ASW.To_Unbounded_Wide_String(Equiv("xyzsypcc")) -- no change then Report.Failed ("Incorrect result from Proc Translate, w/ access value map - 3"); end if; -- Function Translate using access-to-subprogram mapping value. Map_Ptr := AB_to_Blank_Mapping_Function'Access; Test_String := ASW.To_Unbounded_Wide_String(Equiv("abAbBBAabbacD")); if ASW.Translate(ASW.Translate(Test_String, Map_Ptr), Map_Ptr) /= ASW.To_Unbounded_Wide_String(Equiv(" A BBA cD")) then Report.Failed ("Incorrect result from Function Translate, access value map - 1"); end if; if ASW.Translate(Source => ASW.To_Unbounded_Wide_String(Equiv("a")), Mapping => Map_Ptr) /= ASW.To_Unbounded_Wide_String(Equiv(" ")) or ASW.Translate(ASW.To_Unbounded_Wide_String (Equiv(" aa Aa A AAaaa a aA")), Map_Ptr) /= ASW.To_Unbounded_Wide_String(Equiv(" A A AA A")) or ASW.Translate(Source => ASW.To_Unbounded_Wide_String(Equiv("a ")), Mapping => Map_Ptr) /= ASW.To_Unbounded_Wide_String(Equiv(" ")) or ASW.Translate(Source => ASW.To_Unbounded_Wide_String(Equiv("xyz")), Mapping => Map_Ptr) /= ASW.To_Unbounded_Wide_String(Equiv("xyz")) then Report.Failed ("Incorrect result from Function Translate, access value map - 2"); end if; -- Trim Trim_Block: declare XYZ_Set : Wide_Maps.Wide_Character_Set := Wide_Maps.To_Set(Equiv("xyz")); PQR_Set : Wide_Maps.Wide_Character_Set := Wide_Maps.To_Set(Equiv("pqr")); Pad : constant ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("Pad")); The_New_Ada : constant ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("Ada9X")); Space_Array : array (1..4) of ASW.Unbounded_Wide_String := (ASW.To_Unbounded_Wide_String(Equiv(" Pad ")), ASW.To_Unbounded_Wide_String(Equiv("Pad ")), ASW.To_Unbounded_Wide_String(Equiv(" Pad")), Pad); String_Array : array (1..5) of ASW.Unbounded_Wide_String := (ASW.To_Unbounded_Wide_String(Equiv("xyzxAda9Xpqr")), ASW.To_Unbounded_Wide_String(Equiv("Ada9Xqqrp")), ASW.To_Unbounded_Wide_String(Equiv("zxyxAda9Xqpqr")), ASW.To_Unbounded_Wide_String(Equiv("xxxyAda9X")), The_New_Ada); begin -- Examine the version of Trim that removes blanks from -- the left and/or right of a wide string. for i in 1..4 loop if ASW.Trim(Space_Array(i), Ada.Strings.Both) /= Pad then Report.Failed("Incorrect result from Trim for spaces - " & Integer'Image(i)); end if; end loop; -- Examine the version of Trim that removes set characters from -- the left and right of a wide string. for i in 1..5 loop if ASW.Trim(String_Array(i), Left => XYZ_Set, Right => PQR_Set) /= The_New_Ada then Report.Failed ("Incorrect result from Trim for set characters - " & Integer'Image(i)); end if; end loop; -- No trimming. if ASW.Trim( ASW.To_Unbounded_Wide_String(Equiv("prqqprAda9Xyzzxyzzyz")), XYZ_Set, PQR_Set) /= ASW.To_Unbounded_Wide_String(Equiv("prqqprAda9Xyzzxyzzyz")) then Report.Failed ("Incorrect result from Trim for set, no trimming"); end if; end Trim_Block; -- Delete -- Use the Delete function to remove the first four and last four -- characters from the wide string. if ASW.Delete(Source => ASW.Delete(Magic_String, 8, ASW.Length(Magic_String)), From => ASW.To_Wide_String(Magic_String)'First, Through => 4) /= Cad_String then Report.Failed("Incorrect results from Function Delete"); end if; -- Constructors ("*") Constructor_Block: declare SOS : ASW.Unbounded_Wide_String; Dot : constant ASW.Unbounded_Wide_String := ASW.To_Unbounded_Wide_String(Equiv("Dot_")); Dash : constant Wide_String := Equiv("Dash_"); Distress : ASW.Unbounded_Wide_String := ASW."&"(ASW.To_Unbounded_Wide_String (Equiv("Dot_Dot_Dot_")), ASW."&"(ASW.To_Unbounded_Wide_String (Equiv("Dash_Dash_Dash_")), ASW.To_Unbounded_Wide_String (Equiv("Dot_Dot_Dot")))); Repeat : constant Natural := 3; Separator : constant Wide_Character := Equiv('_'); Separator_Set : Wide_Maps.Wide_Character_Set := Wide_Maps.To_Set(Separator); begin -- Use the following constructor forms to construct the wide string -- "Dot_Dot_Dot_Dash_Dash_Dash_Dot_Dot_Dot". Note that the -- trailing underscore in the wide string is removed in the call to -- Trim in the If statement condition. SOS := ASW."*"(Repeat, Dot); -- "*"(#, W Unb Str) SOS := ASW."&"(SOS, ASW."&"(ASW."*"(Repeat, Dash), -- "*"(#, W Str) ASW."*"(Repeat, Dot))); -- "*"(#, W Unb Str) if ASW.Trim(SOS, Wide_Maps.Null_Set, Separator_Set) /= Distress then Report.Failed("Incorrect results from Function ""*"""); end if; end Constructor_Block; exception when others => Report.Failed ("Exception raised in Test_Block"); end Test_Block; Report.Result; end CXA4023;