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test_median.fypp
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#:include "common.fypp"
#:set IR_KINDS_TYPES = INT_KINDS_TYPES + REAL_KINDS_TYPES
#:set NRANK = 3
module test_stats_median
use testdrive, only : new_unittest, unittest_type, error_type, check
use stdlib_stats, only: median
use stdlib_kinds, only : int8, int16, int32, int64, sp, dp, xdp, qp
use, intrinsic :: ieee_arithmetic, only : ieee_is_nan
implicit none
private
public :: collect_stats_median
real(sp), parameter :: sptol = 1000 * epsilon(1._sp)
real(dp), parameter :: dptol = 2000 * epsilon(1._dp)
#:if WITH_XDP
real(xdp), parameter :: xdptol = 2000 * epsilon(1._xdp)
#:endif
#:if WITH_QP
real(qp), parameter :: qptol = 2000 * epsilon(1._qp)
#:endif
#:for k1,t1 in IR_KINDS_TYPES
${t1}$ , parameter :: d1_${k1}$(12) = [${t1}$ :: 10, 2, -3, -4, 6, -6, 7, -8, 9, 0, 1, 20]
${t1}$ :: d2_${k1}$(3, 4) = reshape(d1_${k1}$, [3, 4])
${t1}$ :: d3_${k1}$(2, 3, 2) = reshape(d1_${k1}$, [2, 3, 2])
${t1}$ , parameter :: d1odd_${k1}$(13) = [${t1}$ :: d1_${k1}$, 20]
${t1}$ :: d2odd_${k1}$(3, 5) = reshape(d1odd_${k1}$, [3, 5], [${t1}$ :: 0])
${t1}$ :: d3odd_${k1}$(1, 3, 5) = reshape(d1odd_${k1}$, [1, 3, 5], [${t1}$ :: 0])
#:endfor
contains
!> Collect all exported unit tests
subroutine collect_stats_median(testsuite)
!> Collection of tests
type(unittest_type), allocatable, intent(out) :: testsuite(:)
testsuite = [ &
new_unittest("test_stats_median_size_int8", test_stats_median_size_int8) &
#:for k1,t1 in IR_KINDS_TYPES
, new_unittest("test_stats_median_size_${k1}$", test_stats_median_size_${k1}$) &
, new_unittest("test_stats_median_odd_size_${k1}$", test_stats_median_odd_size_${k1}$) &
, new_unittest("test_stats_median_all_${k1}$", test_stats_median_all_${k1}$) &
, new_unittest("test_stats_median_all_odd_${k1}$", test_stats_median_all_odd_${k1}$) &
, new_unittest("test_stats_median_all_optmask_${k1}$", test_stats_median_all_optmask_${k1}$) &
, new_unittest("test_stats_median_${k1}$", test_stats_median_${k1}$) &
, new_unittest("test_stats_median_odd_${k1}$", test_stats_median_odd_${k1}$) &
, new_unittest("test_stats_median_optmask_${k1}$", test_stats_median_optmask_${k1}$) &
, new_unittest("test_stats_median_mask_all_${k1}$", test_stats_median_mask_all_${k1}$) &
, new_unittest("test_stats_median_mask_${k1}$", test_stats_median_mask_${k1}$) &
#:endfor
]
end subroutine collect_stats_median
#:for k1,t1 in INT_KINDS_TYPES
subroutine test_stats_median_size_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
!check just to be sure that the setup of d0 is correct
call check(error, size(d0), 0, 'size(d0): should be of size 0')
#:for rank in range(1, NRANK + 1)
call check(error, mod(size(d${rank}$_${k1}$), 2), 0&
, 'mod(size(d${rank}$_${k1}$), 2): should be an even number'&
)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_odd_size_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
#:for rank in range(1, NRANK + 1)
call check(error, mod(size(d${rank}$odd_${k1}$), 2), 1&
, 'mod(size(d${rank}$)_${k1}$, 2): should be an odd number'&
)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_all_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0)), 'median(d0): should be NaN' )
if (allocated(error)) return
#:for rank in range(1, NRANK + 1)
call check(error, median(d${rank}$_${k1}$), 1.5_dp&
, 'median(d${rank}$_${k1}$): uncorrect answer'&
, thr = dptol)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_all_odd_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
call check(error, median(d1odd_${k1}$), 2._dp&
, 'median(d1odd_${k1}$): uncorrect answer'&
, thr = dptol)
if (allocated(error)) return
call check(error, median(d2odd_${k1}$), 1._dp&
, 'median(d2odd_${k1}$): uncorrect answer'&
, thr = dptol)
end subroutine
subroutine test_stats_median_all_optmask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0_${k1}$(:)
allocate(d0_${k1}$(0))
#:for rank in range(0, NRANK + 1)
call check(error, ieee_is_nan(median(d${rank}$_${k1}$, .false.))&
, 'median(d${rank}$_${k1}$, .false.): uncorrect answer')
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, 1)), 'median(d0, 1): should return NaN' )
call check(error&
, abs(median(d1_${k1}$, 1) - 1.5_dp) < dptol&
, 'median(d1_${k1}$, 1): uncorrect answer'&
)
if (allocated(error)) return
call check(error&
, sum(abs(median(d2_${k1}$, 1) - [2._dp, -4._dp, 7._dp, 1._dp])) < dptol&
, 'median(d2_${k1}$, 1): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2_${k1}$, 2) - [3.5_dp, 1.5_dp, 3._dp])) < dptol&
,'median(d2_${k1}$, 2): uncorrect answer')
if (allocated(error)) return
end subroutine
subroutine test_stats_median_odd_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
call check(error&
, abs(median(d1odd_${k1}$, 1) - 2._dp) < dptol&
, 'median(d1odd_${k1}$, 1): wrong answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2odd_${k1}$, 1) - [2._dp, -4._dp, 7._dp, 1._dp, 0._dp])) < dptol&
, 'median(d2odd_${k1}$, 1): wrong answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2odd_${k1}$, 2) - [7._dp, 1._dp, 0._dp])) < dptol&
, 'median(d2odd_${k1}$, 2): wrong answer')
if (allocated(error)) return
end subroutine
subroutine test_stats_median_optmask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, 1, .false.))&
, 'median(d0, 1, .false.): uncorrect answer'&
)
if (allocated(error)) return
call check(error, ieee_is_nan(median(d1_${k1}$, 1, .false.))&
, 'median(d1_${k1}$, 1, .false.): uncorrect answer'&
)
if (allocated(error)) return
#:for rank in range(2, NRANK+1)
#:for dim in range(1, rank+1)
call check(error, any(ieee_is_nan(median(d${rank}$_${k1}$, ${dim}$, .false.)))&
, 'median(d${rank}$_${k1}$, ${dim}$, .false.): uncorrect answer')
if (allocated(error)) return
#:endfor
#:endfor
end subroutine
subroutine test_stats_median_mask_all_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, d0 > 0))&
, 'median(d0, d0 > 0): should be NaN' )
if (allocated(error)) return
#:for rank in range(1, NRANK+1)
call check(error&
, ieee_is_nan(median(d${rank}$_${k1}$, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$)))&
, 'median(d${rank}$_${k1}$, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$))' )
if (allocated(error)) return
#:endfor
#:for rank in range(1, NRANK+1)
call check(error&
, (median(d${rank}$_${k1}$, d${rank}$_${k1}$ > 0) - 7._dp) < dptol&
, 'median(d${rank}$_${k1}$, d${rank}$_${k1}$> 0)' )
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_mask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error&
, ieee_is_nan(median(d0, 1, d0 > 0))&
, 'median(d0, 1, d0 > 0): uncorrect answer' )
if (allocated(error)) return
call check(error&
, ieee_is_nan(median(d1_${k1}$, 1, d1_${k1}$ > huge(d1_${k1}$)))&
, 'median(d1_${k1}$, 1_${k1}$, d1_${k1}$ > huge(d1_${k1}$)): answer should be IEEE NaN' )
if (allocated(error)) return
#:for rank in range(2, NRANK+1)
call check(error&
, any(ieee_is_nan(median(d${rank}$_${k1}$, 1, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$))))&
, 'median(d${rank}$_${k1}$, 1_${k1}$, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$)): answer should be IEEE NaN' )
if (allocated(error)) return
#:endfor
call check(error&
, (median(d1_${k1}$, 1, d1_${k1}$ > 0) - 7._dp) < dptol&
, 'median(d1_${k1}$, 1, d1_${k1}$ >0): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs( (median(d2_${k1}$, 1, d2_${k1}$ > 0) - [ 6._dp, 6._dp, 8._dp, 10.5_dp] ) )) &
< dptol&
, 'median(d2_${k1}$, 1, d2_${k1}$ > 0): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs((median(d2_${k1}$, 2, d2_${k1}$ > 0) - [ 8.5_dp, 2._dp, 14.5_dp] )))&
< dptol&
, 'median(d2_${k1}$, 2, d2_${k1}$ > 0)')
if (allocated(error)) return
call check(error&
, any(ieee_is_nan(median(d3_${k1}$, 1, d3_${k1}$ > 0)))&
, 'median(d3_${k1}$, 1, d3_${k1}$ > 0): should contain at least 1 IEEE NaN')
end subroutine
#:endfor
#:for k1,t1 in REAL_KINDS_TYPES
subroutine test_stats_median_size_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
!check just to be sure that the setup of d0 is correct
call check(error, size(d0), 0, 'size(d0): should be of size 0')
#:for rank in range(1, NRANK + 1)
call check(error, mod(size(d${rank}$_${k1}$), 2), 0&
, 'mod(size(d${rank}$_${k1}$), 2): should be an even number'&
)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_odd_size_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
#:for rank in range(1, NRANK + 1)
call check(error, mod(size(d${rank}$odd_${k1}$), 2), 1&
, 'mod(size(d${rank}$_${k1}$), 2): should be an odd number'&
)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_all_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0)), 'median(d0): should be NaN' )
if (allocated(error)) return
#:for rank in range(1, NRANK + 1)
call check(error, median(d${rank}$_${k1}$), 1.5_${k1}$&
, 'median(d${rank}$_${k1}$): uncorrect answer'&
, thr = ${k1}$tol)
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_all_odd_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
call check(error, median(d1odd_${k1}$), 2._${k1}$&
, 'median(d1odd_${k1}$): uncorrect answer'&
, thr = ${k1}$tol)
if (allocated(error)) return
call check(error, median(d2odd_${k1}$), 1._${k1}$&
, 'median(d2odd_${k1}$): uncorrect answer'&
, thr = ${k1}$tol)
if (allocated(error)) return
call check(error, median(d2odd_${k1}$), 1._${k1}$&
, 'median(d2odd_${k1}$): uncorrect answer'&
, thr = ${k1}$tol)
if (allocated(error)) return
end subroutine
subroutine test_stats_median_all_optmask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0_${k1}$(:)
allocate(d0_${k1}$(0))
#:for rank in range(0, NRANK + 1)
call check(error, ieee_is_nan(median(d${rank}$_${k1}$, .false.))&
, 'median(d${rank}$_${k1}$, .false.): uncorrect answer')
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, 1)), 'median(d0, 1): should return NaN' )
call check(error&
, abs(median(d1_${k1}$, 1) - 1.5_${k1}$) < ${k1}$tol&
, 'median(d1_${k1}$, 1): uncorrect answer'&
)
if (allocated(error)) return
call check(error&
, sum(abs(median(d2_${k1}$, 1) - [2._${k1}$, -4._${k1}$, 7._${k1}$, 1._${k1}$])) < ${k1}$tol&
, 'median(d2_${k1}$, 1): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2_${k1}$, 2) - [3.5_${k1}$, 1.5_${k1}$, 3._${k1}$])) < ${k1}$tol&
,'median(d2_${k1}$, 2): uncorrect answer')
if (allocated(error)) return
end subroutine
subroutine test_stats_median_odd_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
call check(error&
, abs(median(d1odd_${k1}$, 1) - 2._${k1}$) < ${k1}$tol&
, 'median(d1odd_${k1}$, 1): wrong answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2odd_${k1}$, 1) - [2._${k1}$, -4._${k1}$, 7._${k1}$, 1._${k1}$, 0._${k1}$])) < ${k1}$tol&
, 'median(d2odd_${k1}$, 1): wrong answer')
if (allocated(error)) return
call check(error&
, sum(abs(median(d2odd_${k1}$, 2) - [7._${k1}$, 1._${k1}$, 0._${k1}$])) < ${k1}$tol&
, 'median(d2odd_${k1}$, 2): wrong answer')
if (allocated(error)) return
end subroutine
subroutine test_stats_median_optmask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, 1, .false.))&
, 'median(d0, 1, .false.): uncorrect answer'&
)
if (allocated(error)) return
call check(error, ieee_is_nan(median(d1_${k1}$, 1, .false.))&
, 'median(d1_${k1}$, 1, .false.): uncorrect answer'&
)
if (allocated(error)) return
#:for rank in range(2, NRANK+1)
#:for dim in range(1, rank+1)
call check(error, any(ieee_is_nan(median(d${rank}$_${k1}$, ${dim}$, .false.)))&
, 'median(d${rank}$_${k1}$, ${dim}$, .false.): uncorrect answer')
if (allocated(error)) return
#:endfor
#:endfor
end subroutine
subroutine test_stats_median_mask_all_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error, ieee_is_nan(median(d0, d0 > 0))&
, 'median(d0, d0 > 0): should be NaN' )
if (allocated(error)) return
#:for rank in range(1, NRANK+1)
call check(error&
, ieee_is_nan(median(d${rank}$_${k1}$, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$)))&
, 'median(d${rank}$_${k1}$, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$))' )
if (allocated(error)) return
#:endfor
#:for rank in range(1, NRANK+1)
call check(error&
, (median(d${rank}$_${k1}$, d${rank}$_${k1}$ > 0) - 7._${k1}$) < ${k1}$tol&
, 'median(d${rank}$_${k1}$, d${rank}$_${k1}$ > 0)' )
if (allocated(error)) return
#:endfor
end subroutine
subroutine test_stats_median_mask_${k1}$(error)
!> Error handling
type(error_type), allocatable, intent(out) :: error
${t1}$, allocatable :: d0(:)
allocate(d0(0))
call check(error&
, ieee_is_nan(median(d0, 1, d0 > 0))&
, 'median(d0, 1, d0 > 0): uncorrect answer' )
if (allocated(error)) return
call check(error&
, ieee_is_nan(median(d1_${k1}$, 1, d1_${k1}$ > huge(d1_${k1}$)))&
, 'median(d1_${k1}$, 1, d1_${k1}$ > huge(d1_${k1}$)): answer should be IEEE NaN' )
if (allocated(error)) return
#:for rank in range(2, NRANK+1)
call check(error&
, any(ieee_is_nan(median(d${rank}$_${k1}$, 1, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$))))&
, 'median(d${rank}$_${k1}$, 1, d${rank}$_${k1}$ > huge(d${rank}$_${k1}$)): answer should be IEEE NaN' )
if (allocated(error)) return
#:endfor
call check(error&
, (median(d1_${k1}$, 1, d1_${k1}$ > 0) - 7._${k1}$) < ${k1}$tol&
, 'median(d1_${k1}$, 1, d1_${k1}$ >0): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs( (median(d2_${k1}$, 1, d2_${k1}$ > 0) - [ 6._${k1}$, 6._${k1}$, 8._${k1}$, 10.5_${k1}$] ) )) &
< ${k1}$tol&
, 'median(d2_${k1}$, 1, d2_${k1}$ > 0): uncorrect answer')
if (allocated(error)) return
call check(error&
, sum(abs((median(d2_${k1}$, 2, d2_${k1}$ > 0) - [ 8.5_${k1}$, 2._${k1}$, 14.5_${k1}$] )))&
< ${k1}$tol&
, 'median(d2_${k1}$, 2, d2_${k1}$ > 0)')
if (allocated(error)) return
call check(error&
, any(ieee_is_nan(median(d3_${k1}$, 1, d3_${k1}$ > 0)))&
, 'median(d3_${k1}$, 1, d3_${k1}$ > 0): should contain at least 1 IEEE NaN')
end subroutine
#:endfor
end module test_stats_median
program tester
use, intrinsic :: iso_fortran_env, only : error_unit
use testdrive, only : run_testsuite, new_testsuite, testsuite_type
use test_stats_median, only : collect_stats_median
implicit none
integer :: stat, is
type(testsuite_type), allocatable :: testsuites(:)
character(len=*), parameter :: fmt = '("#", *(1x, a))'
stat = 0
testsuites = [ &
new_testsuite("stats_median", collect_stats_median) &
]
do is = 1, size(testsuites)
write(error_unit, fmt) "Testing:", testsuites(is)%name
call run_testsuite(testsuites(is)%collect, error_unit, stat)
end do
if (stat > 0) then
write(error_unit, '(i0, 1x, a)') stat, "test(s) failed!"
error stop
end if
end program