!===-- module/ieee_arithmetic.f90 ------------------------------------------===! ! ! Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. ! See https://llvm.org/LICENSE.txt for license information. ! SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception ! !===------------------------------------------------------------------------===! ! Fortran 2018 Clause 17 module ieee_arithmetic ! 17.1: "The module IEEE_ARITHMETIC behaves as if it contained a ! USE statement for IEEE_EXCEPTIONS; everything that is public in ! IEEE_EXCEPTIONS is public in IEEE_ARITHMETIC." use __Fortran_ieee_exceptions use __Fortran_builtins, only: & ieee_is_nan => __builtin_ieee_is_nan, & ieee_is_negative => __builtin_ieee_is_negative, & ieee_is_normal => __builtin_ieee_is_normal, & ieee_next_after => __builtin_ieee_next_after, & ieee_next_down => __builtin_ieee_next_down, & ieee_next_up => __builtin_ieee_next_up, & ieee_scalb => scale, & ieee_selected_real_kind => __builtin_ieee_selected_real_kind, & ieee_support_datatype => __builtin_ieee_support_datatype, & ieee_support_denormal => __builtin_ieee_support_denormal, & ieee_support_divide => __builtin_ieee_support_divide, & ieee_support_inf => __builtin_ieee_support_inf, & ieee_support_io => __builtin_ieee_support_io, & ieee_support_nan => __builtin_ieee_support_nan, & ieee_support_sqrt => __builtin_ieee_support_sqrt, & ieee_support_standard => __builtin_ieee_support_standard, & ieee_support_subnormal => __builtin_ieee_support_subnormal, & ieee_support_underflow_control => __builtin_ieee_support_underflow_control implicit none type :: ieee_class_type private integer(kind=1) :: which = 0 end type ieee_class_type type(ieee_class_type), parameter :: & ieee_signaling_nan = ieee_class_type(1), & ieee_quiet_nan = ieee_class_type(2), & ieee_negative_inf = ieee_class_type(3), & ieee_negative_normal = ieee_class_type(4), & ieee_negative_denormal = ieee_class_type(5), & ieee_negative_zero = ieee_class_type(6), & ieee_positive_zero = ieee_class_type(7), & ieee_positive_subnormal = ieee_class_type(8), & ieee_positive_normal = ieee_class_type(9), & ieee_positive_inf = ieee_class_type(10), & ieee_other_value = ieee_class_type(11) type(ieee_class_type), parameter :: & ieee_negative_subnormal = ieee_negative_denormal, & ieee_positive_denormal = ieee_negative_subnormal type :: ieee_round_type private integer(kind=1) :: mode = 0 end type ieee_round_type type(ieee_round_type), parameter :: & ieee_nearest = ieee_round_type(1), & ieee_to_zero = ieee_round_type(2), & ieee_up = ieee_round_type(3), & ieee_down = ieee_round_type(4), & ieee_away = ieee_round_type(5), & ieee_other = ieee_round_type(6) interface operator(==) elemental logical function ieee_class_eq(x, y) import ieee_class_type type(ieee_class_type), intent(in) :: x, y end function ieee_class_eq elemental logical function ieee_round_eq(x, y) import ieee_round_type type(ieee_round_type), intent(in) :: x, y end function ieee_round_eq end interface operator(==) interface operator(/=) elemental logical function ieee_class_ne(x, y) import ieee_class_type type(ieee_class_type), intent(in) :: x, y end function ieee_class_ne elemental logical function ieee_round_ne(x, y) import ieee_round_type type(ieee_round_type), intent(in) :: x, y end function ieee_round_ne end interface operator(/=) private :: ieee_class_eq, ieee_round_eq, ieee_class_ne, ieee_round_ne ! Define specifics with 1 or 2 INTEGER, LOGICAL, or REAL arguments for ! generic G. #define SPECIFICS_I(G) \ G(1) G(2) G(4) G(8) G(16) #define SPECIFICS_L(G) \ G(1) G(2) G(4) G(8) #if __x86_64__ #define SPECIFICS_R(G) \ G(2) G(3) G(4) G(8) G(10) G(16) #else #define SPECIFICS_R(G) \ G(2) G(3) G(4) G(8) G(16) #endif #define SPECIFICS_II(G) \ G(1,1) G(1,2) G(1,4) G(1,8) G(1,16) \ G(2,1) G(2,2) G(2,4) G(2,8) G(2,16) \ G(4,1) G(4,2) G(4,4) G(4,8) G(4,16) \ G(8,1) G(8,2) G(8,4) G(8,8) G(8,16) \ G(16,1) G(16,2) G(16,4) G(16,8) G(16,16) #if __x86_64__ #define SPECIFICS_RI(G) \ G(2,1) G(2,2) G(2,4) G(2,8) G(2,16) \ G(3,1) G(3,2) G(3,4) G(3,8) G(3,16) \ G(4,1) G(4,2) G(4,4) G(4,8) G(4,16) \ G(8,1) G(8,2) G(8,4) G(8,8) G(8,16) \ G(10,1) G(10,2) G(10,4) G(10,8) G(10,16) \ G(16,1) G(16,2) G(16,4) G(16,8) G(16,16) #else #define SPECIFICS_RI(G) \ G(2,1) G(2,2) G(2,4) G(2,8) G(2,16) \ G(3,1) G(3,2) G(3,4) G(3,8) G(3,16) \ G(4,1) G(4,2) G(4,4) G(4,8) G(4,16) \ G(8,1) G(8,2) G(8,4) G(8,8) G(8,16) \ G(16,1) G(16,2) G(16,4) G(16,8) G(16,16) #endif #if __x86_64__ #define SPECIFICS_RR(G) \ G(2,2) G(2,3) G(2,4) G(2,8) G(2,10) G(2,16) \ G(3,2) G(3,3) G(3,4) G(3,8) G(3,10) G(3,16) \ G(4,2) G(4,3) G(4,4) G(4,8) G(4,10) G(4,16) \ G(8,2) G(8,3) G(8,4) G(8,8) G(8,10) G(8,16) \ G(10,2) G(10,3) G(10,4) G(10,8) G(10,10) G(10,16) \ G(16,2) G(16,3) G(16,4) G(16,8) G(16,10) G(16,16) #else #define SPECIFICS_RR(G) \ G(2,2) G(2,3) G(2,4) G(2,8) G(2,16) \ G(3,2) G(3,3) G(3,4) G(3,8) G(3,16) \ G(4,2) G(4,3) G(4,4) G(4,8) G(4,16) \ G(8,2) G(8,3) G(8,4) G(8,8) G(8,16) \ G(16,2) G(16,3) G(16,4) G(16,8) G(16,16) #endif ! Set PRIVATE accessibility for specifics with 1 or 2 INTEGER, LOGICAL, or REAL ! arguments for generic G. #define PRIVATE_I(G) private :: \ G##_i1, G##_i2, G##_i4, G##_i8, G##_i16 #define PRIVATE_L(G) private :: \ G##_l1, G##_l2, G##_l4, G##_l8 #if __x86_64__ #define PRIVATE_R(G) private :: \ G##_a2, G##_a3, G##_a4, G##_a8, G##_a10, G##_a16 #else #define PRIVATE_R(G) private :: \ G##_a2, G##_a3, G##_a4, G##_a8, G##_a16 #endif #define PRIVATE_II(G) private :: \ G##_i1_i1, G##_i1_i2, G##_i1_i4, G##_i1_i8, G##_i1_i16, \ G##_i2_i1, G##_i2_i2, G##_i2_i4, G##_i2_i8, G##_i2_i16, \ G##_i4_i1, G##_i4_i2, G##_i4_i4, G##_i4_i8, G##_i4_i16, \ G##_i8_i1, G##_i8_i2, G##_i8_i4, G##_i8_i8, G##_i8_i16, \ G##_i16_i1, G##_i16_i2, G##_i16_i4, G##_i16_i8, G##_i16_i16 #if __x86_64__ #define PRIVATE_RI(G) private :: \ G##_a2_i1, G##_a2_i2, G##_a2_i4, G##_a2_i8, G##_a2_i16, \ G##_a3_i1, G##_a3_i2, G##_a3_i4, G##_a3_i8, G##_a3_i16, \ G##_a4_i1, G##_a4_i2, G##_a4_i4, G##_a4_i8, G##_a4_i16, \ G##_a8_i1, G##_a8_i2, G##_a8_i4, G##_a8_i8, G##_a8_i16, \ G##_a10_i1, G##_a10_i2, G##_a10_i4, G##_a10_i8, G##_a10_i16, \ G##_a16_i1, G##_a16_i2, G##_a16_i4, G##_a16_i8, G##_a16_i16 #else #define PRIVATE_RI(G) private :: \ G##_a2_i1, G##_a2_i2, G##_a2_i4, G##_a2_i8, G##_a2_i16, \ G##_a3_i1, G##_a3_i2, G##_a3_i4, G##_a3_i8, G##_a3_i16, \ G##_a4_i1, G##_a4_i2, G##_a4_i4, G##_a4_i8, G##_a4_i16, \ G##_a8_i1, G##_a8_i2, G##_a8_i4, G##_a8_i8, G##_a8_i16, \ G##_a16_i1, G##_a16_i2, G##_a16_i4, G##_a16_i8, G##_a16_i16 #endif #if __x86_64__ #define PRIVATE_RR(G) private :: \ G##_a2_a2, G##_a2_a3, G##_a2_a4, G##_a2_a8, G##_a2_a10, G##_a2_a16, \ G##_a3_a2, G##_a3_a3, G##_a3_a4, G##_a3_a8, G##_a3_a10, G##_a3_a16, \ G##_a4_a2, G##_a4_a3, G##_a4_a4, G##_a4_a8, G##_a4_a10, G##_a4_a16, \ G##_a8_a2, G##_a8_a3, G##_a8_a4, G##_a8_a8, G##_a8_a10, G##_a8_a16, \ G##_a10_a2, G##_a10_a3, G##_a10_a4, G##_a10_a8, G##_a10_a10, G##_a10_a16, \ G##_a16_a2, G##_a16_a3, G##_a16_a4, G##_a16_a8, G##_a16_a10, G##_a16_a16 #else #define PRIVATE_RR(G) private :: \ G##_a2_a2, G##_a2_a3, G##_a2_a4, G##_a2_a8, G##_a2_a16, \ G##_a3_a2, G##_a3_a3, G##_a3_a4, G##_a3_a8, G##_a3_a16, \ G##_a4_a2, G##_a4_a3, G##_a4_a4, G##_a4_a8, G##_a4_a16, \ G##_a8_a2, G##_a8_a3, G##_a8_a4, G##_a8_a8, G##_a8_a16, \ G##_a16_a2, G##_a16_a3, G##_a16_a4, G##_a16_a8, G##_a16_a16 #endif #define IEEE_CLASS_R(XKIND) \ elemental type(ieee_class_type) function ieee_class_a##XKIND(x); \ import ieee_class_type; \ real(XKIND), intent(in) :: x; \ end function ieee_class_a##XKIND; interface ieee_class SPECIFICS_R(IEEE_CLASS_R) end interface ieee_class PRIVATE_R(IEEE_CLASS) #undef IEEE_CLASS_R #define IEEE_COPY_SIGN_RR(XKIND, YKIND) \ elemental real(XKIND) function ieee_copy_sign_a##XKIND##_a##YKIND(x, y); \ real(XKIND), intent(in) :: x; \ real(YKIND), intent(in) :: y; \ end function ieee_copy_sign_a##XKIND##_a##YKIND; interface ieee_copy_sign SPECIFICS_RR(IEEE_COPY_SIGN_RR) end interface ieee_copy_sign PRIVATE_RR(IEEE_COPY_SIGN) #undef IEEE_COPY_SIGN_RR #define IEEE_FMA_R(AKIND) \ elemental real(AKIND) function ieee_fma_a##AKIND(a, b, c); \ real(AKIND), intent(in) :: a, b, c; \ end function ieee_fma_a##AKIND; interface ieee_fma SPECIFICS_R(IEEE_FMA_R) end interface ieee_fma PRIVATE_R(IEEE_FMA) #undef IEEE_FMA_R #define IEEE_GET_ROUNDING_MODE_I(RKIND) \ subroutine ieee_get_rounding_mode_i##RKIND(round_value, radix); \ import ieee_round_type; \ type(ieee_round_type), intent(out) :: round_value; \ integer(RKIND), intent(in) :: radix; \ end subroutine ieee_get_rounding_mode_i##RKIND; interface ieee_get_rounding_mode subroutine ieee_get_rounding_mode_0(round_value) import ieee_round_type type(ieee_round_type), intent(out) :: round_value end subroutine ieee_get_rounding_mode_0 SPECIFICS_I(IEEE_GET_ROUNDING_MODE_I) end interface ieee_get_rounding_mode PRIVATE_I(IEEE_GET_ROUNDING_MODE) #undef IEEE_GET_ROUNDING_MODE_I #define IEEE_GET_UNDERFLOW_MODE_L(GKIND) \ subroutine ieee_get_underflow_mode_l##GKIND(gradual); \ logical(GKIND), intent(out) :: gradual; \ end subroutine ieee_get_underflow_mode_l##GKIND; interface ieee_get_underflow_mode SPECIFICS_L(IEEE_GET_UNDERFLOW_MODE_L) end interface ieee_get_underflow_mode PRIVATE_L(IEEE_GET_UNDERFLOW_MODE) #undef IEEE_GET_UNDERFLOW_MODE_L ! When kind argument is present, kind(result) is value(kind), not kind(kind). ! That is not known here, so return integer(16). #define IEEE_INT_R(AKIND) \ elemental integer function ieee_int_a##AKIND(a, round); \ import ieee_round_type; \ real(AKIND), intent(in) :: a; \ type(ieee_round_type), intent(in) :: round; \ end function ieee_int_a##AKIND; #define IEEE_INT_RI(AKIND, KKIND) \ elemental integer(16) function ieee_int_a##AKIND##_i##KKIND(a, round, kind); \ import ieee_round_type; \ real(AKIND), intent(in) :: a; \ type(ieee_round_type), intent(in) :: round; \ integer(KKIND), intent(in) :: kind; \ end function ieee_int_a##AKIND##_i##KKIND; interface ieee_int SPECIFICS_R(IEEE_INT_R) SPECIFICS_RI(IEEE_INT_RI) end interface ieee_int PRIVATE_R(IEEE_INT) PRIVATE_RI(IEEE_INT) #undef IEEE_INT_R #undef IEEE_INT_RI #define IEEE_IS_FINITE_R(XKIND) \ elemental logical function ieee_is_finite_a##XKIND(x); \ real(XKIND), intent(in) :: x; \ end function ieee_is_finite_a##XKIND; interface ieee_is_finite SPECIFICS_R(IEEE_IS_FINITE_R) end interface ieee_is_finite PRIVATE_R(IEEE_IS_FINITE) #undef IEEE_IS_FINITE_R #define IEEE_LOGB_R(XKIND) \ elemental real(XKIND) function ieee_logb_a##XKIND(x); \ real(XKIND), intent(in) :: x; \ end function ieee_logb_a##XKIND; interface ieee_logb SPECIFICS_R(IEEE_LOGB_R) end interface ieee_logb PRIVATE_R(IEEE_LOGB) #undef IEEE_LOGB_R #define IEEE_MAX_NUM_R(XKIND) \ elemental real(XKIND) function ieee_max_num_a##XKIND(x, y); \ real(XKIND), intent(in) :: x, y; \ end function ieee_max_num_a##XKIND; interface ieee_max_num SPECIFICS_R(IEEE_MAX_NUM_R) end interface ieee_max_num PRIVATE_R(IEEE_MAX_NUM) #undef IEEE_MAX_NUM_R #define IEEE_MAX_NUM_MAG_R(XKIND) \ elemental real(XKIND) function ieee_max_num_mag_a##XKIND(x, y); \ real(XKIND), intent(in) :: x, y; \ end function ieee_max_num_mag_a##XKIND; interface ieee_max_num_mag SPECIFICS_R(IEEE_MAX_NUM_MAG_R) end interface ieee_max_num_mag PRIVATE_R(IEEE_MAX_NUM_MAG) #undef IEEE_MAX_NUM_MAG_R #define IEEE_MIN_NUM_R(XKIND) \ elemental real(XKIND) function ieee_min_num_a##XKIND(x, y); \ real(XKIND), intent(in) :: x, y; \ end function ieee_min_num_a##XKIND; interface ieee_min_num SPECIFICS_R(IEEE_MIN_NUM_R) end interface ieee_min_num PRIVATE_R(IEEE_MIN_NUM) #undef IEEE_MIN_NUM_R #define IEEE_MIN_NUM_MAG_R(XKIND) \ elemental real(XKIND) function ieee_min_num_mag_a##XKIND(x, y); \ real(XKIND), intent(in) :: x, y; \ end function ieee_min_num_mag_a##XKIND; interface ieee_min_num_mag SPECIFICS_R(IEEE_MIN_NUM_MAG_R) end interface ieee_min_num_mag PRIVATE_R(IEEE_MIN_NUM_MAG) #undef IEEE_MIN_NUM_MAG_R #define IEEE_QUIET_EQ_R(AKIND) \ elemental logical function ieee_quiet_eq_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_eq_a##AKIND; interface ieee_quiet_eq SPECIFICS_R(IEEE_QUIET_EQ_R) end interface ieee_quiet_eq PRIVATE_R(IEEE_QUIET_EQ) #undef IEEE_QUIET_EQ_R #define IEEE_QUIET_GE_R(AKIND) \ elemental logical function ieee_quiet_ge_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_ge_a##AKIND; interface ieee_quiet_ge SPECIFICS_R(IEEE_QUIET_GE_R) end interface ieee_quiet_ge PRIVATE_R(IEEE_QUIET_GE) #undef IEEE_QUIET_GE_R #define IEEE_QUIET_GT_R(AKIND) \ elemental logical function ieee_quiet_gt_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_gt_a##AKIND; interface ieee_quiet_gt SPECIFICS_R(IEEE_QUIET_GT_R) end interface ieee_quiet_gt PRIVATE_R(IEEE_QUIET_GT) #undef IEEE_QUIET_GT_R #define IEEE_QUIET_LE_R(AKIND) \ elemental logical function ieee_quiet_le_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_le_a##AKIND; interface ieee_quiet_le SPECIFICS_R(IEEE_QUIET_LE_R) end interface ieee_quiet_le PRIVATE_R(IEEE_QUIET_LE) #undef IEEE_QUIET_LE_R #define IEEE_QUIET_LT_R(AKIND) \ elemental logical function ieee_quiet_lt_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_lt_a##AKIND; interface ieee_quiet_lt SPECIFICS_R(IEEE_QUIET_LT_R) end interface ieee_quiet_lt PRIVATE_R(IEEE_QUIET_LT) #undef IEEE_QUIET_LT_R #define IEEE_QUIET_NE_R(AKIND) \ elemental logical function ieee_quiet_ne_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_quiet_ne_a##AKIND; interface ieee_quiet_ne SPECIFICS_R(IEEE_QUIET_NE_R) end interface ieee_quiet_ne PRIVATE_R(IEEE_QUIET_NE) #undef IEEE_QUIET_NE_R ! When kind argument is present, kind(result) is value(kind), not kind(kind). ! That is not known here, so return real(16). #define IEEE_REAL_I(AKIND) \ elemental real function ieee_real_i##AKIND(a); \ integer(AKIND), intent(in) :: a; \ end function ieee_real_i##AKIND; #define IEEE_REAL_R(AKIND) \ elemental real function ieee_real_a##AKIND(a); \ real(AKIND), intent(in) :: a; \ end function ieee_real_a##AKIND; #define IEEE_REAL_II(AKIND, KKIND) \ elemental real(16) function ieee_real_i##AKIND##_i##KKIND(a, kind); \ integer(AKIND), intent(in) :: a; \ integer(KKIND), intent(in) :: kind; \ end function ieee_real_i##AKIND##_i##KKIND; #define IEEE_REAL_RI(AKIND, KKIND) \ elemental real(16) function ieee_real_a##AKIND##_i##KKIND(a, kind); \ real(AKIND), intent(in) :: a; \ integer(KKIND), intent(in) :: kind; \ end function ieee_real_a##AKIND##_i##KKIND; interface ieee_real SPECIFICS_I(IEEE_REAL_I) SPECIFICS_R(IEEE_REAL_R) SPECIFICS_II(IEEE_REAL_II) SPECIFICS_RI(IEEE_REAL_RI) end interface ieee_real PRIVATE_I(IEEE_REAL) PRIVATE_R(IEEE_REAL) PRIVATE_II(IEEE_REAL) PRIVATE_RI(IEEE_REAL) #undef IEEE_REAL_I #undef IEEE_REAL_R #undef IEEE_REAL_II #undef IEEE_REAL_RI #define IEEE_REM_RR(XKIND, YKIND) \ elemental real(XKIND) function ieee_rem_a##XKIND##_a##YKIND(x, y); \ real(XKIND), intent(in) :: x; \ real(YKIND), intent(in) :: y; \ end function ieee_rem_a##XKIND##_a##YKIND; interface ieee_rem SPECIFICS_RR(IEEE_REM_RR) end interface ieee_rem PRIVATE_RR(IEEE_REM) #undef IEEE_REM_RR #define IEEE_RINT_R(XKIND) \ elemental real(XKIND) function ieee_rint_a##XKIND(x, round); \ import ieee_round_type; \ real(XKIND), intent(in) :: x; \ type(ieee_round_type), optional, intent(in) :: round; \ end function ieee_rint_a##XKIND; interface ieee_rint SPECIFICS_R(IEEE_RINT_R) end interface ieee_rint PRIVATE_R(IEEE_RINT) #undef IEEE_RINT_R #define IEEE_SET_ROUNDING_MODE_I(RKIND) \ subroutine ieee_set_rounding_mode_i##RKIND(round_value, radix); \ import ieee_round_type; \ type(ieee_round_type), intent(in) :: round_value; \ integer(RKIND), intent(in) :: radix; \ end subroutine ieee_set_rounding_mode_i##RKIND; interface ieee_set_rounding_mode subroutine ieee_set_rounding_mode_0(round_value) import ieee_round_type type(ieee_round_type), intent(in) :: round_value end subroutine ieee_set_rounding_mode_0 SPECIFICS_I(IEEE_SET_ROUNDING_MODE_I) end interface ieee_set_rounding_mode PRIVATE_I(IEEE_SET_ROUNDING_MODE) #undef IEEE_SET_ROUNDING_MODE_I #define IEEE_SET_UNDERFLOW_MODE_L(GKIND) \ subroutine ieee_set_underflow_mode_l##GKIND(gradual); \ logical(GKIND), intent(in) :: gradual; \ end subroutine ieee_set_underflow_mode_l##GKIND; interface ieee_set_underflow_mode SPECIFICS_L(IEEE_SET_UNDERFLOW_MODE_L) end interface ieee_set_underflow_mode PRIVATE_L(IEEE_SET_UNDERFLOW_MODE) #undef IEEE_SET_UNDERFLOW_MODE_L #define IEEE_SIGNALING_EQ_R(AKIND) \ elemental logical function ieee_signaling_eq_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_eq_a##AKIND; interface ieee_signaling_eq SPECIFICS_R(IEEE_SIGNALING_EQ_R) end interface ieee_signaling_eq PRIVATE_R(IEEE_SIGNALING_EQ) #undef IEEE_SIGNALING_EQ_R #define IEEE_SIGNALING_GE_R(AKIND) \ elemental logical function ieee_signaling_ge_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_ge_a##AKIND; interface ieee_signaling_ge SPECIFICS_R(IEEE_SIGNALING_GE_R) end interface ieee_signaling_ge PRIVATE_R(IEEE_SIGNALING_GE) #undef IEEE_SIGNALING_GE_R #define IEEE_SIGNALING_GT_R(AKIND) \ elemental logical function ieee_signaling_gt_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_gt_a##AKIND; interface ieee_signaling_gt SPECIFICS_R(IEEE_SIGNALING_GT_R) end interface ieee_signaling_gt PRIVATE_R(IEEE_SIGNALING_GT) #undef IEEE_SIGNALING_GT_R #define IEEE_SIGNALING_LE_R(AKIND) \ elemental logical function ieee_signaling_le_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_le_a##AKIND; interface ieee_signaling_le SPECIFICS_R(IEEE_SIGNALING_LE_R) end interface ieee_signaling_le PRIVATE_R(IEEE_SIGNALING_LE) #undef IEEE_SIGNALING_LE_R #define IEEE_SIGNALING_LT_R(AKIND) \ elemental logical function ieee_signaling_lt_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_lt_a##AKIND; interface ieee_signaling_lt SPECIFICS_R(IEEE_SIGNALING_LT_R) end interface ieee_signaling_lt PRIVATE_R(IEEE_SIGNALING_LT) #undef IEEE_SIGNALING_LT_R #define IEEE_SIGNALING_NE_R(AKIND) \ elemental logical function ieee_signaling_ne_a##AKIND(a, b); \ real(AKIND), intent(in) :: a, b; \ end function ieee_signaling_ne_a##AKIND; interface ieee_signaling_ne SPECIFICS_R(IEEE_SIGNALING_NE_R) end interface ieee_signaling_ne PRIVATE_R(IEEE_SIGNALING_NE) #undef IEEE_SIGNALING_NE_R #define IEEE_SIGNBIT_R(XKIND) \ elemental logical function ieee_signbit_a##XKIND(x); \ real(XKIND), intent(in) :: x; \ end function ieee_signbit_a##XKIND; interface ieee_signbit SPECIFICS_R(IEEE_SIGNBIT_R) end interface ieee_signbit PRIVATE_R(IEEE_SIGNBIT) #undef IEEE_SIGNBIT_R #define IEEE_SUPPORT_ROUNDING_R(XKIND) \ pure logical function ieee_support_rounding_a##XKIND(round_value, x); \ import ieee_round_type; \ type(ieee_round_type), intent(in) :: round_value; \ real(XKIND), intent(in) :: x(..); \ end function ieee_support_rounding_a##XKIND; interface ieee_support_rounding pure logical function ieee_support_rounding_0(round_value) import ieee_round_type type(ieee_round_type), intent(in) :: round_value end function ieee_support_rounding_0 SPECIFICS_R(IEEE_SUPPORT_ROUNDING_R) end interface ieee_support_rounding PRIVATE_R(IEEE_SUPPORT_ROUNDING) #undef IEEE_SUPPORT_ROUNDING_R #define IEEE_UNORDERED_RR(XKIND, YKIND) \ elemental logical function ieee_unordered_a##XKIND##_a##YKIND(x, y); \ real(XKIND), intent(in) :: x; \ real(YKIND), intent(in) :: y; \ end function ieee_unordered_a##XKIND##_a##YKIND; interface ieee_unordered SPECIFICS_RR(IEEE_UNORDERED_RR) end interface ieee_unordered PRIVATE_RR(IEEE_UNORDERED) #undef IEEE_UNORDERED_RR #define IEEE_VALUE_R(XKIND) \ elemental real(XKIND) function ieee_value_a##XKIND(x, class); \ import ieee_class_type; \ real(XKIND), intent(in) :: x; \ type(ieee_class_type), intent(in) :: class; \ end function ieee_value_a##XKIND; interface ieee_value SPECIFICS_R(IEEE_VALUE_R) end interface ieee_value PRIVATE_R(IEEE_VALUE) #undef IEEE_VALUE_R end module ieee_arithmetic