From 50c8d3d4adeed1e6666cf44216075d1fb53a3ef0 Mon Sep 17 00:00:00 2001 From: Harald Anlauf Date: Mon, 1 May 2023 18:01:25 +0200 Subject: [PATCH] Fortran: overloading of intrinsic binary operators [PR109641] Fortran allows overloading of intrinsic operators also for operands of numeric intrinsic types. The intrinsic operator versions are used according to the rules of F2018 table 10.2 and imply type conversion as long as the operand ranks are conformable. Otherwise no type conversion shall be performed to allow the resolution of a matching user-defined operator. gcc/fortran/ChangeLog: PR fortran/109641 * arith.cc (eval_intrinsic): Check conformability of ranks of operands for intrinsic binary operators before performing type conversions. * gfortran.h (gfc_op_rank_conformable): Add prototype. * resolve.cc (resolve_operator): Check conformability of ranks of operands for intrinsic binary operators before performing type conversions. (gfc_op_rank_conformable): New helper function to compare ranks of operands of binary operator. gcc/testsuite/ChangeLog: PR fortran/109641 * gfortran.dg/overload_5.f90: New test. --- gcc/fortran/arith.cc | 6 ++ gcc/fortran/gfortran.h | 1 + gcc/fortran/resolve.cc | 39 ++++++++ gcc/testsuite/gfortran.dg/overload_5.f90 | 118 +++++++++++++++++++++++ 4 files changed, 164 insertions(+) create mode 100644 gcc/testsuite/gfortran.dg/overload_5.f90 diff --git a/gcc/fortran/arith.cc b/gcc/fortran/arith.cc index d1d814b3ae1..86d56406047 100644 --- a/gcc/fortran/arith.cc +++ b/gcc/fortran/arith.cc @@ -1663,6 +1663,12 @@ eval_intrinsic (gfc_intrinsic_op op, if (!gfc_numeric_ts (&op1->ts) || !gfc_numeric_ts (&op2->ts)) goto runtime; + /* Do not perform conversions if operands are not conformable as + required for the binary intrinsic operators (F2018:10.1.5). + Defer to a possibly overloading user-defined operator. */ + if (!gfc_op_rank_conformable (op1, op2)) + goto runtime; + /* Insert any necessary type conversions to make the operands compatible. */ diff --git a/gcc/fortran/gfortran.h b/gcc/fortran/gfortran.h index a15ff90e228..ac21e1813d9 100644 --- a/gcc/fortran/gfortran.h +++ b/gcc/fortran/gfortran.h @@ -3730,6 +3730,7 @@ void gfc_free_association_list (gfc_association_list *); /* resolve.cc */ void gfc_expression_rank (gfc_expr *); +bool gfc_op_rank_conformable (gfc_expr *, gfc_expr *); bool gfc_resolve_ref (gfc_expr *); bool gfc_resolve_expr (gfc_expr *); void gfc_resolve (gfc_namespace *); diff --git a/gcc/fortran/resolve.cc b/gcc/fortran/resolve.cc index c3d508fb45d..341909d7de7 100644 --- a/gcc/fortran/resolve.cc +++ b/gcc/fortran/resolve.cc @@ -4200,6 +4200,17 @@ resolve_operator (gfc_expr *e) case INTRINSIC_POWER: if (gfc_numeric_ts (&op1->ts) && gfc_numeric_ts (&op2->ts)) { + /* Do not perform conversions if operands are not conformable as + required for the binary intrinsic operators (F2018:10.1.5). + Defer to a possibly overloading user-defined operator. */ + if (!gfc_op_rank_conformable (op1, op2)) + { + dual_locus_error = true; + snprintf (msg, sizeof (msg), + _("Inconsistent ranks for operator at %%L and %%L")); + goto bad_op; + } + gfc_type_convert_binary (e, 1); break; } @@ -4372,6 +4383,17 @@ resolve_operator (gfc_expr *e) if (gfc_numeric_ts (&op1->ts) && gfc_numeric_ts (&op2->ts)) { + /* Do not perform conversions if operands are not conformable as + required for the binary intrinsic operators (F2018:10.1.5). + Defer to a possibly overloading user-defined operator. */ + if (!gfc_op_rank_conformable (op1, op2)) + { + dual_locus_error = true; + snprintf (msg, sizeof (msg), + _("Inconsistent ranks for operator at %%L and %%L")); + goto bad_op; + } + gfc_type_convert_binary (e, 1); e->ts.type = BT_LOGICAL; @@ -5644,6 +5666,23 @@ done: } +/* Given two expressions, check that their rank is conformable, i.e. either + both have the same rank or at least one is a scalar. */ + +bool +gfc_op_rank_conformable (gfc_expr *op1, gfc_expr *op2) +{ +// if (op1->expr_type == EXPR_VARIABLE && op1->ref) + if (op1->expr_type == EXPR_VARIABLE) + gfc_expression_rank (op1); +// if (op2->expr_type == EXPR_VARIABLE && op2->ref) + if (op2->expr_type == EXPR_VARIABLE) + gfc_expression_rank (op2); + + return (op1->rank == 0 || op2->rank == 0 || op1->rank == op2->rank); +} + + static void add_caf_get_intrinsic (gfc_expr *e) { diff --git a/gcc/testsuite/gfortran.dg/overload_5.f90 b/gcc/testsuite/gfortran.dg/overload_5.f90 new file mode 100644 index 00000000000..f8c93af3518 --- /dev/null +++ b/gcc/testsuite/gfortran.dg/overload_5.f90 @@ -0,0 +1,118 @@ +! { dg-do run } +! PR fortran/109641 +! +! Check overloading of intrinsic binary operators for numeric operands +! Reported by Adelson Oliveira + +MODULE TESTEOP + IMPLICIT NONE + INTERFACE OPERATOR(.MULT.) + MODULE PROCEDURE MULTr4 + MODULE PROCEDURE MULTc4 + END INTERFACE + INTERFACE OPERATOR(*) + MODULE PROCEDURE MULTr4 + MODULE PROCEDURE MULTc4 + END INTERFACE + INTERFACE OPERATOR(==) + MODULE PROCEDURE MULTr4 + MODULE PROCEDURE MULTc4 + MODULE PROCEDURE MULTr8 + END INTERFACE + INTERFACE OPERATOR(<) + MODULE PROCEDURE MULTc4 + MODULE PROCEDURE MULTi4 + END INTERFACE + INTERFACE OPERATOR(**) + MODULE PROCEDURE MULTc4 + MODULE PROCEDURE MULTi4 + END INTERFACE + interface copy + MODULE PROCEDURE copy + end interface copy +CONTAINS + elemental function copy (z) + complex, intent(in) :: z + complex :: copy + copy = z + end function copy + FUNCTION MULTr4(v,m) + REAL, INTENT(IN) :: v(:) + REAL, INTENT(IN) :: m(:,:) + REAL :: MULTr4(SIZE(m,DIM=1),SIZE(m,DIM=2)) + INTEGER :: i + FORALL(i=1:SIZE(v)) MULTr4(:,i)=m(:,i)*v(i) + END FUNCTION MULTr4 + FUNCTION MULTr8(v,m) + REAL, INTENT(IN) :: v(:) + double precision, INTENT(IN) :: m(:,:) + double precision :: MULTr8(SIZE(m,DIM=1),SIZE(m,DIM=2)) + INTEGER :: i + FORALL(i=1:SIZE(v)) MULTr8(:,i)=m(:,i)*v(i) + END FUNCTION MULTr8 + FUNCTION MULTc4(v,m) + REAL, INTENT(IN) :: v(:) + COMPLEX, INTENT(IN) :: m(:,:) + COMPLEX :: MULTc4(SIZE(m,DIM=1),SIZE(m,DIM=2)) + INTEGER :: i + FORALL(i=1:SIZE(v)) MULTc4(:,i)=m(:,i)*v(i) + END FUNCTION MULTc4 + FUNCTION MULTi4(v,m) + REAL, INTENT(IN) :: v(:) + integer, INTENT(IN) :: m(:,:) + REAL :: MULTi4(SIZE(m,DIM=1),SIZE(m,DIM=2)) + INTEGER :: i + FORALL(i=1:SIZE(v)) MULTi4(:,i)=m(:,i)*v(i) + END FUNCTION MULTi4 +END MODULE TESTEOP +PROGRAM TESTE + USE TESTEOP + implicit none + type t + complex :: c(3,3) + end type t + real, parameter :: vv(3) = 42. + complex, parameter :: zz(3,3) = (1.0,0.0) + integer, parameter :: kk(3,3) = 2 + double precision :: dd(3,3) = 3.d0 + COMPLEX, ALLOCATABLE :: m(:,:),r(:,:), s(:,:) + REAL, ALLOCATABLE :: v(:) + type(t) :: z(1) = t(zz) + ALLOCATE(v(3),m(3,3),r(3,3),s(3,3)) + v = vv + m = zz + ! Original bug report + r=v.MULT.m ! Reference + s=v*m + if (any (r /= s)) stop 1 + if (.not. all (r == s)) stop 2 + ! Check other binary intrinsics + s=v==m + if (any (r /= s)) stop 3 + s=v==copy(m) + if (any (r /= s)) stop 4 + s=v==zz + if (any (r /= s)) stop 5 + s=v==copy(zz) + if (any (r /= s)) stop 6 + s=vv==m + if (any (r /= s)) stop 7 + s=vv==copy(m) + if (any (r /= s)) stop 8 + s=vv==zz + if (any (r /= s)) stop 9 + s=vv==copy(zz) + if (any (r /= s)) stop 10 + ! check if .eq. same operator as == etc. + s=v.eq.m + if (any (r /= s)) stop 11 + s=v.lt.z(1)%c + if (any (r /= s)) stop 12 + s=v<((z(1)%c)) + if (any (r /= s)) stop 13 + if (.not. all ( 1. < (vv**kk))) stop 14 + if (.not. all ( 1. < (vv< kk))) stop 15 + if (.not. all ((42.,0.) == (v < m ))) stop 16 + if (.not. all ((42.,0.) == (v** m ))) stop 17 + if (.not. all ( 126.d0 == (vv==dd))) stop 18 +END PROGRAM TESTE -- 2.35.3