Class dc_test
In: dc_utils/dc_test.f90

テストプログラム作成支援

Support making test programs

Note that Japanese and English are described in parallel.

Fortran 90/95 におけるテストプログラム作成を補助するための モジュールです.

オブジェクト指向スクリプト言語 RubyTest::Unit クラス の機能の一部を模倣しています.

This module supports making Fortran 90/95 test programs.

A part of Test::Unit class in Object-oriented programming language Ruby is imitated.

Procedures List

AssertEqual :正答とチェックすべき値が等しいことをチェックする.
AssertGreaterThan :ある値よりもチェックすべき値が大きいことをチェックする.
AssertLessThan :ある値よりもチェックすべき値が小さいことをチェックする.
———— :————
AssertEqual :It is verified that a examined value is equal to a right answer.
AssertGreaterThan :It is verified that examined value is greater than a certain value.
AssertLessThan :It is verified that examined value is less than a certain value.

Usage

AssertEqual サブルーチンの使用例として, 以下に簡単な テストプログラムを記します. message にはテストプログラムを実行した際に表示する 任意の長さの文字列を与えます. そして, answer には正答を, check には照合すべき値を与えます. answercheck にはそれぞれ文字型, 整数型, 単精度実数型, 倍精度実数型, 論理型の変数および 配列 (1 〜 7次元) を与えることができます. 2 つの引数の型および次元数は一致している必要があります.

A simple test program is showed as an example of how "AssertEqual" subroutine is used as follows. Give arbitrary length string to message. This string is displayed when the test program is execute. And give the right answer to answer, examined value to check. Character, integer, simple precision real, double precision real, logical variables and arrays (rank 1 - 7) are allowed to give to answer and check. The types of answer and check must be same.

  program test
    use dc_test, only: AssertEqual
    implicit none
    character(32):: str1
    real:: r1(2)

    str1 = 'foo'
    r1 = (/ 1.0, 2.0 /)
    call AssertEqual(message='String test', answer='foo', check=str1)
    call AssertEqual(message='Float test', &
      & answer=(/1.0, 2.0/), check=r1)
  end program test

checkanswer との値, および配列のサイズが一致する場合に テストプログラムは「Checking <message に与えられた文字> OK」 というメッセージを表示します. プログラムは続行します. AssertEqual の代わりに AssertGreaterThan を使用する場合には checkanswer よりも大きい場合, AssertLessThan を使用する場合には checkanswer よりも小さい場合に プログラムは続行します.

一方で answercheck の値, もしくは配列のサイズが異なる場合には, テストプログラムは「Checking <message に与えられた文字> FAILURE」 というメッセージを表示します. プログラムはエラーを発生させて終了します. AssertEqual の代わりに AssertGreaterThan を使用する場合には checkanswer よりも大きくない場合, AssertLessThan を使用する場合には checkanswer よりも 小さくない場合にプログラムは終了します.

When the values and array sizes of check and answer are same, the test program displays a message "Checking <string given to message> OK", and the program continues. Using "AssertGreaterThan" instead of "AssertEqual", the program continues when check is greater than answer. Using "AssertLessThan", the program continues when check is less than answer.

On the other hand, when the values or array sizes of check and answer are different, the test program displays a message "Checking <string given to message> FAILURE", and the program aborts. Using "AssertGreaterThan" instead of "AssertEqual", the program aborts when check is not greater than answer. Using "AssertLessThan", the program aborts when check is not less than answer.

精度の指定

Specification of accuracy

単精度実数型, 倍精度実数型同士の比較において, 丸め誤差や情報落ち誤差を考慮したい場合には, 引数 significant_digits, ignore_digits に整数型を与えてください. significant_digits には有効数字の桁数を, ignore_digits には 無視するオーダーを与えます. 以下の例では, 有効数字の桁数を 7 とし, 1.0e-6 以下の数値を無視して値の比較を行っています.

About comparison of single precision reals or double precision reals, in order to consider rounding errors and information loss errors, specify integer to significant_digits, ignore_digits arguments. Specify significant digits to significant_digits, and negligible order to ignore_digits. In the following example, significant digits is 7, and numerical value less than 1.0e-6 is ignored.

  program test2
    use dc_test, only: AssertEqual
    implicit none
    real:: numd1(2,3)

    numd1 = reshape((/-19.432,  75.3, 3.183, &
      &                 0.023,  -0.9, 328.2/), &
      &              (/2,3/))

    call AssertEqual( 'Float (single precision) test', &
      & answer = numd1, &
      & check = ( numd1 / 3.0 ) * 3.0, &
      & significant_digits = 7, ignore_digits = -6 )

  end program test2

負の値の取り扱い

Treatment of negative values

比較される answer の値と check の値が両方とも負の場合, AssertGreaterThan および AssertLessThan は 2 つの値の絶対値の 比較を行います. エラーメッセージは以下のようになります. オプショナル引数 negative_support に .false. を与える場合, 絶対値での比較を行いません.

"AssertGreaterThan" and "AssertLessThan" compare absolute values of answer and check when both compared two values are negative. In this case, error message is as follows. When an optional argument negative_support is .false., the comparison with absolute values is not done.

  ABSOLUTE value of check(14,1)  =  -1.189774221E-09
    is NOT LESS THAN
  ABSOLUTE value of answer(14,1) =  -1.189774405E-09

使用例

Example

使用例は以下の通りです.

Example of use is showed as follows.

  program test_sample
    use dc_types, only: STRING, DP
    use dc_test, only: AssertEqual, AssertGreaterThan, AssertLessThan
    implicit none
    character(STRING):: str1, str2
    real:: r1(2)
    integer:: int1
    real:: numr1(2)
    real(DP):: numd1(2,3), numd2(2,3)
    logical:: y_n
  continue

    str1 = 'foo'
    r1 = (/ 1.0_DP, 2.0_DP /)
    call AssertEqual( message = 'String test', answer = 'foo', check = str1 )
    call AssertEqual( message = 'Float test', &
      & answer = (/1.0e0, 2.0e0/), check = r1 )

    str2 = "foo"
    call AssertEqual( 'Character test', answer = 'foo', check = str2 )
    int1 = 1
    call AssertEqual( 'Integer test', answer = 1, check = int1 )
    numr1(:) = (/ 0.001235423, 0.248271 /)
    call AssertGreaterThan( 'Float test 1', &
      & answer = (/ 0.00061771142, 0.1241354 /), check = numr1 / 2.0 )
    call AssertLessThan( 'Float test 2', &
      & answer = (/ 0.00061771158, 0.1241358 /), check = numr1 / 2.0 )
    y_n = .true.
    call AssertEqual( 'Logical test', answer = .true., check = y_n )

    numd1 = reshape( (/ -19.432_DP, 75.3_DP, 3.183_DP, &
      &                  0.023_DP,  -0.9_DP, 328.2_DP /), &
      &              (/ 2,3 /) )
    call AssertGreaterThan( 'Double precision test 1', &
      & answer = reshape( (/ -38.8639_DP, 150.5999_DP, 6.365999_DP, &
      &                     0.0459999_DP,  -1.7999_DP, 656.3999_DP /), &
      &                   (/ 2,3 /) ), &
      & check = numd1*2.0_DP )
    call AssertLessThan( 'Double precision test 2', &
      & answer = reshape( (/ -38.86401_DP, 150.60001_DP,  6.3660001_DP, &
      &                     0.04600001_DP, -1.8000001_DP,     656.6_DP /), &
      &                   (/ 2,3 /) ), &
      & check = numd1*2.0_DP, negative_support=.true. )

    call AssertEqual( 'Double precision test 3', &
      & answer = numd1, &
      & check = ( numd1 / 3.0_DP ) * 3.0_DP, &
      & significant_digits = 10, ignore_digits = -10 )

    numd2 = reshape( (/  19.4e+7_DP,     75.3_DP, 3.18e-7_DP, &
      &                   0.023e-7_DP, 0.9e+7_DP,   328.2_DP /), &
      &              (/ 2,3 /) )

    call AssertEqual( 'Double precision test 4', &
      & answer = numd2, &
      & check = ( ( ( numd2 + 0.008_DP - 0.008_DP ) / 1.5_DP ) * 3.0_DP ) / 2.0_DP, &
      & significant_digits = 10, ignore_digits = -15 )

    call AssertEqual( 'Double precision test 5', &
      & answer = numd2, &
      & check = ( ( ( numd2 + 0.008_DP - 0.008_DP ) / 1.5_DP ) * 3.0_DP ) / 2.0_DP, &
      & significant_digits = 15, ignore_digits = -19 )

  end program test_sample

上記の例では, 最後のテストで敢えて小さすぎる値を無視するオーダー として設定しているため, 以下のようなメッセージを出力して プログラムは強制終了します.

In above example, too small negligible order is specified on purpose in the last test. Then the program displays a following message, and aborts.

    *** MESSAGE [AssertEQ] *** Checking String test OK
    *** MESSAGE [AssertEQ] *** Checking Float test OK
    *** MESSAGE [AssertEQ] *** Checking Character test OK
    *** MESSAGE [AssertEQ] *** Checking Integer test OK
    *** MESSAGE [AssertGT] *** Checking Float test 1 OK
    *** MESSAGE [AssertLT] *** Checking Float test 2 OK
    *** MESSAGE [AssertEQ] *** Checking Logical test OK
    *** MESSAGE [AssertGT] *** Checking Double precision test 1 OK
    *** MESSAGE [AssertLT] *** Checking Double precision test 2 OK
    *** MESSAGE [AssertEQ] *** Checking Double precision test 3 OK
    *** MESSAGE [AssertEQ] *** Checking Double precision test 4 OK
    *** Error [AssertEQ] *** Checking Double precision test 5 FAILURE

     check(1,2)  =  3.179999999991523E-07
       is NOT EQUAL to
                    3.179999999998997E-07  <
     answer(1,2) <  3.180000000001004E-07

Methods

AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertEqual   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertGreaterThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan   AssertLessThan  

Included Modules

dc_types sysdep

Public Instance methods

Subroutine :
message :character(*), intent(in)
answer :character(*), intent(in)
check :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar0(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer
    character(*), intent(in):: check
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                                        

                                                                
                    

  continue
    err_flag = .false.

                    
    err_flag = .not. trim(answer) == trim(check)
    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar0
Subroutine :
message :character(*), intent(in)
answer :integer, intent(in)
check :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt0(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer
    integer, intent(in):: check
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                                        

                    

  continue
    err_flag = .false.

                    
    err_flag = .not. answer == check
    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt0
Subroutine :
message :character(*), intent(in)
answer :logical, intent(in)
check :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical0(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer
    logical, intent(in):: check

                        character(STRING):: answer_str
    character(STRING):: check_str
                    


  continue

                    
    if (answer) then
      answer_str = ".true."
    else
      answer_str = ".false."
    end if

    if (check) then
      check_str = ".true."
    else
      check_str = ".false."
    end if

                    

    call DCTestAssertEqualChar0(message, answer_str, check_str)

                                        

  end subroutine DCTestAssertEqualLogical0
Subroutine :
message :character(*), intent(in)
answer :real(DP), intent(in)
check :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble0(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer
    real(DP), intent(in):: check
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                                        

                    

  continue
    err_flag = .false.

                    
    err_flag = .not. answer == check
    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble0
Subroutine :
message :character(*), intent(in)
answer :real, intent(in)
check :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal0(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer
    real, intent(in):: check
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                                        

                    

  continue
    err_flag = .false.

                    
    err_flag = .not. answer == check
    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal0
Subroutine :
message :character(*), intent(in)
answer(:) :character(*), intent(in)
check(:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar1(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:)
    character(*), intent(in):: check(:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:)
    character(STRING), allocatable:: check_fixed_length(:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1)  ) )

    allocate( check_fixed_length ( check_shape(1)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar1
Subroutine :
message :character(*), intent(in)
answer(:) :integer, intent(in)
check(:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt1(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:)
    integer, intent(in):: check(:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt1
Subroutine :
message :character(*), intent(in)
answer(:) :logical, intent(in)
check(:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical1(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:)
    logical, intent(in):: check(:)

                        integer:: answer_shape(1), check_shape(1), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:)
    character(STRING), allocatable:: check_str(:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1)  ) )

    allocate( check_str ( check_shape(1)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar1(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical1
Subroutine :
message :character(*), intent(in)
answer(:) :real(DP), intent(in)
check(:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble1(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:)
    real(DP), intent(in):: check(:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble1
Subroutine :
message :character(*), intent(in)
answer(:) :real, intent(in)
check(:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal1(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:)
    real, intent(in):: check(:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal1
Subroutine :
message :character(*), intent(in)
answer(:,:) :character(*), intent(in)
check(:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar2(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:)
    character(*), intent(in):: check(:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:)
    character(STRING), allocatable:: check_fixed_length(:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar2
Subroutine :
message :character(*), intent(in)
answer(:,:) :integer, intent(in)
check(:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt2(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:)
    integer, intent(in):: check(:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt2
Subroutine :
message :character(*), intent(in)
answer(:,:) :logical, intent(in)
check(:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical2(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:)
    logical, intent(in):: check(:,:)

                        integer:: answer_shape(2), check_shape(2), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:)
    character(STRING), allocatable:: check_str(:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_str ( check_shape(1), check_shape(2)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar2(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real(DP), intent(in)
check(:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble2(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:)
    real(DP), intent(in):: check(:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real, intent(in)
check(:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal2(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:)
    real, intent(in):: check(:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal2
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :character(*), intent(in)
check(:,:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar3(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:,:)
    character(*), intent(in):: check(:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:,:)
    character(STRING), allocatable:: check_fixed_length(:,:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2), check_shape(3)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :integer, intent(in)
check(:,:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt3(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:)
    integer, intent(in):: check(:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :logical, intent(in)
check(:,:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical3(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:,:)
    logical, intent(in):: check(:,:,:)

                        integer:: answer_shape(3), check_shape(3), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:,:)
    character(STRING), allocatable:: check_str(:,:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_str ( check_shape(1), check_shape(2), check_shape(3)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar3(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real(DP), intent(in)
check(:,:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble3(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:)
    real(DP), intent(in):: check(:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real, intent(in)
check(:,:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal3(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:)
    real, intent(in):: check(:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal3
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :character(*), intent(in)
check(:,:,:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar4(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:,:,:)
    character(*), intent(in):: check(:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:,:,:)
    character(STRING), allocatable:: check_fixed_length(:,:,:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2), check_shape(3), check_shape(4)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :integer, intent(in)
check(:,:,:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt4(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:)
    integer, intent(in):: check(:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :logical, intent(in)
check(:,:,:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical4(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:,:,:)
    logical, intent(in):: check(:,:,:,:)

                        integer:: answer_shape(4), check_shape(4), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:,:,:)
    character(STRING), allocatable:: check_str(:,:,:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_str ( check_shape(1), check_shape(2), check_shape(3), check_shape(4)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar4(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real(DP), intent(in)
check(:,:,:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble4(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real, intent(in)
check(:,:,:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal4(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:)
    real, intent(in):: check(:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :character(*), intent(in)
check(:,:,:,:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar5(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:,:,:,:)
    character(*), intent(in):: check(:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:,:,:,:)
    character(STRING), allocatable:: check_fixed_length(:,:,:,:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt5(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :logical, intent(in)
check(:,:,:,:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical5(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:,:,:,:)
    logical, intent(in):: check(:,:,:,:,:)

                        integer:: answer_shape(5), check_shape(5), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:,:,:,:)
    character(STRING), allocatable:: check_str(:,:,:,:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_str ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar5(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble5(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal5(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :character(*), intent(in)
check(:,:,:,:,:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar6(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:,:,:,:,:)
    character(*), intent(in):: check(:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:,:,:,:,:)
    character(STRING), allocatable:: check_fixed_length(:,:,:,:,:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5), check_shape(6)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt6(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :logical, intent(in)
check(:,:,:,:,:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical6(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:,:,:,:,:)
    logical, intent(in):: check(:,:,:,:,:,:)

                        integer:: answer_shape(6), check_shape(6), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:,:,:,:,:)
    character(STRING), allocatable:: check_str(:,:,:,:,:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_str ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5), check_shape(6)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar6(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble6(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal6(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :character(*), intent(in)
check(:,:,:,:,:,:,:) :character(*), intent(in)

[Source]

  subroutine DCTestAssertEqualChar7(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    character(*), intent(in):: answer(:,:,:,:,:,:,:)
    character(*), intent(in):: check(:,:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    character(STRING):: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
                    

                                              character(STRING), allocatable:: answer_fixed_length(:,:,:,:,:,:,:)
    character(STRING), allocatable:: check_fixed_length(:,:,:,:,:,:,:)
                      
                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

                      
    allocate( answer_fixed_length ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_fixed_length ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5), check_shape(6), check_shape(7)  ) )

    answer_fixed_length = answer
    check_fixed_length = check

    judge = answer_fixed_length == check_fixed_length
    deallocate(answer_fixed_length, check_fixed_length)

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', trim(wrong)
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', trim(right)

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualChar7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:,:) :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualInt7(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    integer:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualInt7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :logical, intent(in)
check(:,:,:,:,:,:,:) :logical, intent(in)

[Source]

  subroutine DCTestAssertEqualLogical7(message, answer, check)
    use dc_types, only: STRING
    implicit none
    character(*), intent(in):: message
    logical, intent(in):: answer(:,:,:,:,:,:,:)
    logical, intent(in):: check(:,:,:,:,:,:,:)

                        integer:: answer_shape(7), check_shape(7), i
    logical, allocatable:: answer_tmp(:), check_tmp(:)
    character(STRING), allocatable:: answer_str_tmp(:), check_str_tmp(:)
    character(STRING), allocatable:: answer_str(:,:,:,:,:,:,:)
    character(STRING), allocatable:: check_str(:,:,:,:,:,:,:)
                    


  continue

                    
    allocate(answer_tmp(size(answer)))
    allocate(check_tmp(size(check)))
    allocate(answer_str_tmp(size(answer)))
    allocate(check_str_tmp(size(check)))
    answer_tmp = pack(answer, .true.)
    check_tmp = pack(check, .true.)

    do i = 1, size(answer_tmp)
      if (answer_tmp(i)) then
        answer_str_tmp(i) = '.true.'
      else
        answer_str_tmp(i) = '.false.'
      end if
    end do

    do i = 1, size(check_tmp)
      if (check_tmp(i)) then
        check_str_tmp(i) = '.true.'
      else
        check_str_tmp(i) = '.false.'
      end if
    end do

    answer_shape = shape(answer)
    check_shape = shape(check)

    allocate( answer_str ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_str ( check_shape(1), check_shape(2), check_shape(3), check_shape(4), check_shape(5), check_shape(6), check_shape(7)  ) )

    answer_str = reshape(answer_str_tmp, answer_shape)
    check_str = reshape(check_str_tmp, check_shape)

                    

    call DCTestAssertEqualChar7(message, answer_str, check_str)

                        deallocate(answer_str, answer_tmp, answer_str_tmp)
    deallocate(check_str, check_tmp, check_str_tmp)
                    

  end subroutine DCTestAssertEqualLogical7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:,:) :real(DP), intent(in)

[Source]

  subroutine DCTestAssertEqualDouble7(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:,:) :real, intent(in)

[Source]

  subroutine DCTestAssertEqualReal7(message, answer, check)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:,:)
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
                    

                    

  continue
    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

                      
    judge = answer == check

                      

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '  answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal7
Subroutine :
message :character(*), intent(in)
answer :real(DP), intent(in)
check :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble0Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer
    real(DP), intent(in):: check
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        real(DP):: answer_max
    real(DP):: answer_min
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    if ( answer < 0.0_DP .and. check < 0.0_DP ) then
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    else

      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end if

    wrong = check
    right_max = answer_max
    right_min = answer_min
    if ( right_max < right_min ) then
      right_tmp = right_max
      right_max = right_min
      right_min = right_tmp
    end if

    err_flag = .not. (answer_max > check .and. check > answer_min)

    pos_str = ''

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble0Digits
Subroutine :
message :character(*), intent(in)
answer :real, intent(in)
check :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal0Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer
    real, intent(in):: check
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        real:: answer_max
    real:: answer_min
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    if ( answer < 0.0 .and. check < 0.0 ) then
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    else

      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end if

    wrong = check
    right_max = answer_max
    right_min = answer_min
    if ( right_max < right_min ) then
      right_tmp = right_max
      right_max = right_min
      right_min = right_tmp
    end if

    err_flag = .not. (answer_max > check .and. check > answer_min)

    pos_str = ''

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal0Digits
Subroutine :
message :character(*), intent(in)
answer(:) :real(DP), intent(in)
check(:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble1Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:)
    real(DP), intent(in):: check(:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
    real(DP), allocatable:: answer_max(:)
    real(DP), allocatable:: answer_min(:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    allocate( answer_max ( answer_shape(1)  ) )

    allocate( answer_min ( answer_shape(1)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right_max = answer_max ( pos(1)  )

      right_min = answer_min ( pos(1)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble1Digits
Subroutine :
message :character(*), intent(in)
answer(:) :real, intent(in)
check(:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal1Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:)
    real, intent(in):: check(:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
    real, allocatable:: answer_max(:)
    real, allocatable:: answer_min(:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    allocate( answer_max ( answer_shape(1)  ) )

    allocate( answer_min ( answer_shape(1)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right_max = answer_max ( pos(1)  )

      right_min = answer_min ( pos(1)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal1Digits
Subroutine :
message :character(*), intent(in)
answer(:,:) :real(DP), intent(in)
check(:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble2Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:)
    real(DP), intent(in):: check(:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
    real(DP), allocatable:: answer_max(:,:)
    real(DP), allocatable:: answer_min(:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right_max = answer_max ( pos(1), pos(2)  )

      right_min = answer_min ( pos(1), pos(2)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble2Digits
Subroutine :
message :character(*), intent(in)
answer(:,:) :real, intent(in)
check(:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal2Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:)
    real, intent(in):: check(:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
    real, allocatable:: answer_max(:,:)
    real, allocatable:: answer_min(:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right_max = answer_max ( pos(1), pos(2)  )

      right_min = answer_min ( pos(1), pos(2)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal2Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real(DP), intent(in)
check(:,:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble3Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:)
    real(DP), intent(in):: check(:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
    real(DP), allocatable:: answer_max(:,:,:)
    real(DP), allocatable:: answer_min(:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right_max = answer_max ( pos(1), pos(2), pos(3)  )

      right_min = answer_min ( pos(1), pos(2), pos(3)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble3Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real, intent(in)
check(:,:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal3Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:)
    real, intent(in):: check(:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
    real, allocatable:: answer_max(:,:,:)
    real, allocatable:: answer_min(:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right_max = answer_max ( pos(1), pos(2), pos(3)  )

      right_min = answer_min ( pos(1), pos(2), pos(3)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal3Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real(DP), intent(in)
check(:,:,:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble4Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
    real(DP), allocatable:: answer_max(:,:,:,:)
    real(DP), allocatable:: answer_min(:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble4Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real, intent(in)
check(:,:,:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal4Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:)
    real, intent(in):: check(:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
    real, allocatable:: answer_max(:,:,:,:)
    real, allocatable:: answer_min(:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal4Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble5Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
    real(DP), allocatable:: answer_max(:,:,:,:,:)
    real(DP), allocatable:: answer_min(:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble5Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal5Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
    real, allocatable:: answer_max(:,:,:,:,:)
    real, allocatable:: answer_min(:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal5Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble6Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
    real(DP), allocatable:: answer_max(:,:,:,:,:,:)
    real(DP), allocatable:: answer_min(:,:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble6Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal6Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
    real, allocatable:: answer_max(:,:,:,:,:,:)
    real, allocatable:: answer_min(:,:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal6Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:,:) :real(DP), intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualDouble7Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real(DP):: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real(DP):: right_tmp

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
    real(DP), allocatable:: answer_max(:,:,:,:,:,:,:)
    real(DP), allocatable:: answer_min(:,:,:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0_DP - 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP + 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0_DP + 0.1_DP ** significant_digits ) + 0.1_DP ** (- ignore_digits)

      answer_min = answer * (   1.0_DP - 0.1_DP ** significant_digits ) - 0.1_DP ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualDouble7Digits
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:,:) :real, intent(in)
significant_digits :integer, intent(in)
ignore_digits :integer, intent(in)

[Source]

  subroutine DCTestAssertEqualReal7Digits( message, answer, check, significant_digits, ignore_digits )
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:,:)
    integer, intent(in):: significant_digits
    integer, intent(in):: ignore_digits
    logical:: err_flag
    character(STRING):: pos_str
    real:: wrong, right_max, right_min
    character(STRING):: pos_str_space
    integer:: pos_str_len
    real:: right_tmp

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
    real, allocatable:: answer_max(:,:,:,:,:,:,:)
    real, allocatable:: answer_min(:,:,:,:,:,:,:)
                    
  continue
    err_flag = .false.

    if ( significant_digits < 1 ) then
      write(*,*) ' *** Error [AssertEQ] *** '
      write(*,*) '  Specify a number more than 1 to "significant_digits"'
      call AbortProgram('')
    end if
                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_max ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_min ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative

    where (both_negative)
      answer_max = answer * (   1.0 - 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 + 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    elsewhere
      answer_max = answer * (   1.0 + 0.1 ** significant_digits ) + 0.1 ** (- ignore_digits)

      answer_min = answer * (   1.0 - 0.1 ** significant_digits ) - 0.1 ** (- ignore_digits)
    end where

    judge = answer_max > check .and. check > answer_min
    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right_max = answer_max ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right_min = answer_min ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      if ( right_max < right_min ) then
        right_tmp = right_max
        right_max = right_min
        right_min = right_tmp
      end if

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)
    deallocate(answer_max, answer_min)

                    

    if (err_flag) then
      pos_str_space = ''
      pos_str_len = len_trim(pos_str)

      write(*,*) ' *** Error [AssertEQ] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  check' // trim(pos_str)  // '  = ', wrong
      write(*,*) '    is NOT EQUAL to'
      write(*,*) '        ' // pos_str_space(1:pos_str_len) // '   ', right_min, ' < '
      write(*,*) '  answer' // trim(pos_str)  // ' < ', right_max

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertEQ] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertEqualReal7Digits
Subroutine :
message :character(*), intent(in)
answer :integer, intent(in)
check :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer
    integer, intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    err_flag = .not. answer < check
    abs_mes = ''

    if ( answer < 0 .and. check < 0 .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt0
Subroutine :
message :character(*), intent(in)
answer :real(DP), intent(in)
check :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer
    real(DP), intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    err_flag = .not. answer < check
    abs_mes = ''

    if ( answer < 0.0_DP .and. check < 0.0_DP .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble0
Subroutine :
message :character(*), intent(in)
answer :real, intent(in)
check :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer
    real, intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    err_flag = .not. answer < check
    abs_mes = ''

    if ( answer < 0.0 .and. check < 0.0 .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal0
Subroutine :
message :character(*), intent(in)
answer(:) :integer, intent(in)
check(:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:)
    integer, intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt1
Subroutine :
message :character(*), intent(in)
answer(:) :real(DP), intent(in)
check(:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:)
    real(DP), intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble1
Subroutine :
message :character(*), intent(in)
answer(:) :real, intent(in)
check(:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:)
    real, intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal1
Subroutine :
message :character(*), intent(in)
answer(:,:) :integer, intent(in)
check(:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:)
    integer, intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real(DP), intent(in)
check(:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:)
    real(DP), intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real, intent(in)
check(:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:)
    real, intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal2
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :integer, intent(in)
check(:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:)
    integer, intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real(DP), intent(in)
check(:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:)
    real(DP), intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real, intent(in)
check(:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:)
    real, intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal3
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :integer, intent(in)
check(:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:)
    integer, intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real(DP), intent(in)
check(:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real, intent(in)
check(:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:)
    real, intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanInt7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanInt7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanDouble7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanDouble7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertGreaterThanReal7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer < check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertGT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT GREATER THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertGT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertGreaterThanReal7
Subroutine :
message :character(*), intent(in)
answer :integer, intent(in)
check :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer
    integer, intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    


    err_flag = .not. answer > check
    abs_mes = ''

    if ( answer < 0 .and. check < 0 .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt0
Subroutine :
message :character(*), intent(in)
answer :real(DP), intent(in)
check :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer
    real(DP), intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    


    err_flag = .not. answer > check
    abs_mes = ''

    if ( answer < 0.0_DP .and. check < 0.0_DP .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble0
Subroutine :
message :character(*), intent(in)
answer :real, intent(in)
check :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal0( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer
    real, intent(in):: check
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                                        

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    


    err_flag = .not. answer > check
    abs_mes = ''

    if ( answer < 0.0 .and. check < 0.0 .and. negative_support_on ) then

      err_flag = .not. err_flag
      abs_mes = 'ABSOLUTE value of'
    end if

    wrong = check
    right = answer
    pos_str = ''

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal0
Subroutine :
message :character(*), intent(in)
answer(:) :integer, intent(in)
check(:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:)
    integer, intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt1
Subroutine :
message :character(*), intent(in)
answer(:) :real(DP), intent(in)
check(:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:)
    real(DP), intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble1
Subroutine :
message :character(*), intent(in)
answer(:) :real, intent(in)
check(:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal1( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:)
    real, intent(in):: check(:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(1), check_shape(1), pos(1)
    logical:: consist_shape(1)
    character(TOKEN):: pos_array(1)
    integer, allocatable:: mask_array(:)
    logical, allocatable:: judge(:)
    logical, allocatable:: judge_rev(:)
    logical, allocatable:: answer_negative(:)
    logical, allocatable:: check_negative(:)
    logical, allocatable:: both_negative(:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1)  ) )

    allocate( judge ( answer_shape(1)  ) )

    allocate( judge_rev ( answer_shape(1)  ) )

    allocate( answer_negative ( answer_shape(1)  ) )

    allocate( check_negative ( answer_shape(1)  ) )

    allocate( both_negative ( answer_shape(1)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1)  )

      right = answer ( pos(1)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ')'

      if ( both_negative ( pos(1)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal1
Subroutine :
message :character(*), intent(in)
answer(:,:) :integer, intent(in)
check(:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:)
    integer, intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real(DP), intent(in)
check(:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:)
    real(DP), intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble2
Subroutine :
message :character(*), intent(in)
answer(:,:) :real, intent(in)
check(:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal2( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:)
    real, intent(in):: check(:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(2), check_shape(2), pos(2)
    logical:: consist_shape(2)
    character(TOKEN):: pos_array(2)
    integer, allocatable:: mask_array(:,:)
    logical, allocatable:: judge(:,:)
    logical, allocatable:: judge_rev(:,:)
    logical, allocatable:: answer_negative(:,:)
    logical, allocatable:: check_negative(:,:)
    logical, allocatable:: both_negative(:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2)  )

      right = answer ( pos(1), pos(2)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ')'

      if ( both_negative ( pos(1), pos(2)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal2
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :integer, intent(in)
check(:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:)
    integer, intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real(DP), intent(in)
check(:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:)
    real(DP), intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble3
Subroutine :
message :character(*), intent(in)
answer(:,:,:) :real, intent(in)
check(:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal3( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:)
    real, intent(in):: check(:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(3), check_shape(3), pos(3)
    logical:: consist_shape(3)
    character(TOKEN):: pos_array(3)
    integer, allocatable:: mask_array(:,:,:)
    logical, allocatable:: judge(:,:,:)
    logical, allocatable:: judge_rev(:,:,:)
    logical, allocatable:: answer_negative(:,:,:)
    logical, allocatable:: check_negative(:,:,:)
    logical, allocatable:: both_negative(:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3)  )

      right = answer ( pos(1), pos(2), pos(3)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal3
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :integer, intent(in)
check(:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:)
    integer, intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real(DP), intent(in)
check(:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:) :real, intent(in)
check(:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal4( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:)
    real, intent(in):: check(:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(4), check_shape(4), pos(4)
    logical:: consist_shape(4)
    character(TOKEN):: pos_array(4)
    integer, allocatable:: mask_array(:,:,:,:)
    logical, allocatable:: judge(:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal4
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal5( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(5), check_shape(5), pos(5)
    logical:: consist_shape(5)
    character(TOKEN):: pos_array(5)
    integer, allocatable:: mask_array(:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal5
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal6( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(6), check_shape(6), pos(6)
    logical:: consist_shape(6)
    character(TOKEN):: pos_array(6)
    integer, allocatable:: mask_array(:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal6
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :integer, intent(in)
check(:,:,:,:,:,:,:) :integer, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanInt7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    integer, intent(in):: answer(:,:,:,:,:,:,:)
    integer, intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    integer:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0
    check_negative = check < 0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanInt7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real(DP), intent(in)
check(:,:,:,:,:,:,:) :real(DP), intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanDouble7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real(DP), intent(in):: answer(:,:,:,:,:,:,:)
    real(DP), intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real(DP):: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0_DP
    check_negative = check < 0.0_DP
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanDouble7
Subroutine :
message :character(*), intent(in)
answer(:,:,:,:,:,:,:) :real, intent(in)
check(:,:,:,:,:,:,:) :real, intent(in)
negative_support :logical, intent(in), optional

[Source]

  subroutine DCTestAssertLessThanReal7( message, answer, check, negative_support)
    use sysdep, only: AbortProgram
    use dc_types, only: STRING, TOKEN
    implicit none
    character(*), intent(in):: message
    real, intent(in):: answer(:,:,:,:,:,:,:)
    real, intent(in):: check(:,:,:,:,:,:,:)
    logical, intent(in), optional:: negative_support
    logical:: err_flag
    logical:: negative_support_on
    character(STRING):: pos_str
    character(TOKEN):: abs_mes
    real:: wrong, right

                        integer:: answer_shape(7), check_shape(7), pos(7)
    logical:: consist_shape(7)
    character(TOKEN):: pos_array(7)
    integer, allocatable:: mask_array(:,:,:,:,:,:,:)
    logical, allocatable:: judge(:,:,:,:,:,:,:)
    logical, allocatable:: judge_rev(:,:,:,:,:,:,:)
    logical, allocatable:: answer_negative(:,:,:,:,:,:,:)
    logical, allocatable:: check_negative(:,:,:,:,:,:,:)
    logical, allocatable:: both_negative(:,:,:,:,:,:,:)
                    

  continue
    if (present(negative_support)) then
      negative_support_on = negative_support
    else
      negative_support_on = .true.
    end if

    err_flag = .false.

                    
    answer_shape = shape(answer)
    check_shape = shape(check)

    consist_shape = answer_shape == check_shape

    if (.not. all(consist_shape)) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) '  shape of check is (', check_shape, ')'
      write(*,*) '    is INCORRECT'
      write(*,*) '  Correct shape of answer is (', answer_shape, ')'

      call AbortProgram('')
    end if


    allocate( mask_array ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( judge_rev ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( answer_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( check_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    allocate( both_negative ( answer_shape(1), answer_shape(2), answer_shape(3), answer_shape(4), answer_shape(5), answer_shape(6), answer_shape(7)  ) )

    answer_negative = answer < 0.0
    check_negative = check < 0.0
    both_negative = answer_negative .and. check_negative
    if (.not. negative_support_on) both_negative = .false.

    judge = answer > check
    where (both_negative) judge = .not. judge

    judge_rev = .not. judge
    err_flag = any(judge_rev)
    mask_array = 1
    pos = maxloc(mask_array, judge_rev)

    if (err_flag) then

      wrong = check ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

      right = answer ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )

                            write(unit=pos_array(1), fmt="(i20)") pos(1)
                      
      write(unit=pos_array(2), fmt="(i20)") pos(2)
                      
      write(unit=pos_array(3), fmt="(i20)") pos(3)
                      
      write(unit=pos_array(4), fmt="(i20)") pos(4)
                      
      write(unit=pos_array(5), fmt="(i20)") pos(5)
                      
      write(unit=pos_array(6), fmt="(i20)") pos(6)
                      
      write(unit=pos_array(7), fmt="(i20)") pos(7)
                      

      pos_str = '(' // trim(adjustl(pos_array(1))) // ',' // trim(adjustl(pos_array(2))) // ',' // trim(adjustl(pos_array(3))) // ',' // trim(adjustl(pos_array(4))) // ',' // trim(adjustl(pos_array(5))) // ',' // trim(adjustl(pos_array(6))) // ',' // trim(adjustl(pos_array(7))) // ')'

      if ( both_negative ( pos(1), pos(2), pos(3), pos(4), pos(5), pos(6), pos(7)  )  ) then

        abs_mes = 'ABSOLUTE value of'
      else
        abs_mes = ''

      end if

    end if
    deallocate(mask_array, judge, judge_rev)
    deallocate(answer_negative, check_negative, both_negative)

                    


    if (err_flag) then
      write(*,*) ' *** Error [AssertLT] *** Checking ' // trim(message) // ' FAILURE'
      write(*,*) ''
      write(*,*) ' ' // trim(abs_mes) // ' check' // trim(pos_str) // '  = ', wrong
      write(*,*) '    is NOT LESS THAN'
      write(*,*) ' ' // trim(abs_mes) // ' answer' // trim(pos_str) // ' = ', right

      call AbortProgram('')
    else
      write(*,*) ' *** MESSAGE [AssertLT] *** Checking ' // trim(message) // ' OK'
    end if


  end subroutine DCTestAssertLessThanReal7