From: Paul Thomas Date: Sat, 26 Dec 2020 16:44:24 +0000 (+0000) Subject: Fortran: Correction to recent patch in light of comments [PR98022]. X-Git-Tag: basepoints/gcc-12~1915 X-Git-Url: http://git.ipfire.org/?a=commitdiff_plain;h=c7256c8260afa313e019fd531574ad33ec49b9f6;p=thirdparty%2Fgcc.git Fortran: Correction to recent patch in light of comments [PR98022]. 2020-12-26 Paul Thomas gcc/fortran PR fortran/98022 * data.c (gfc_assign_data_value): Throw an error for inquiry references. Follow with corrected code that would provide the expected result and provides clean error recovery. gcc/testsuite/ PR fortran/98022 * gfortran.dg/data_inquiry_ref.f90: Change to dg-compile and add errors for inquiry references. --- diff --git a/gcc/fortran/data.c b/gcc/fortran/data.c index 76ddd9dab7f8..07fa1c5e9ba1 100644 --- a/gcc/fortran/data.c +++ b/gcc/fortran/data.c @@ -221,11 +221,14 @@ gfc_assign_data_value (gfc_expr *lvalue, gfc_expr *rvalue, mpz_t index, gfc_ref *ref; gfc_expr *init; gfc_expr *expr = NULL; + gfc_expr *rexpr; gfc_constructor *con; gfc_constructor *last_con; gfc_symbol *symbol; gfc_typespec *last_ts; mpz_t offset; + const char *msg = "F18(R841): data-implied-do object at %L is neither an " + "array-element nor a scalar-structure-component"; symbol = lvalue->symtree->n.sym; init = symbol->value; @@ -466,21 +469,38 @@ gfc_assign_data_value (gfc_expr *lvalue, gfc_expr *rvalue, mpz_t index, case REF_INQUIRY: + /* After some discussion on clf it was determined that the following + violates F18(R841). If the error is removed, the expected result + is obtained. Leaving the code in place ensures a clean error + recovery. */ + gfc_error (msg, &lvalue->where); + /* This breaks with the other reference types in that the output constructor has to be of type COMPLEX, whereas the lvalue is of type REAL. The rvalue is copied to the real or imaginary - part as appropriate. */ + part as appropriate. In addition, for all except scalar + complex variables, a complex expression has to provided, where + the constructor does not have it, and the expression modified + with a new value for the real or imaginary part. */ gcc_assert (ref->next == NULL && last_ts->type == BT_COMPLEX); - expr = gfc_copy_expr (rvalue); - if (!gfc_compare_types (&lvalue->ts, &expr->ts)) - gfc_convert_type (expr, &lvalue->ts, 0); - - if (last_con->expr) - gfc_free_expr (last_con->expr); - - last_con->expr = gfc_get_constant_expr (BT_COMPLEX, - last_ts->kind, - &lvalue->where); + rexpr = gfc_copy_expr (rvalue); + if (!gfc_compare_types (&lvalue->ts, &rexpr->ts)) + gfc_convert_type (rexpr, &lvalue->ts, 0); + + /* This is the scalar, complex case, where an initializer exists. */ + if (init && ref == lvalue->ref) + expr = symbol->value; + /* Then all cases, where a complex expression does not exist. */ + else if (!last_con || !last_con->expr) + { + expr = gfc_get_constant_expr (BT_COMPLEX, lvalue->ts.kind, + &lvalue->where); + if (last_con) + last_con->expr = expr; + } + else + /* Finally, and existing constructor expression to be modified. */ + expr = last_con->expr; /* Rejection of LEN and KIND inquiry references is handled elsewhere. The error here is added as backup. The assertion @@ -493,22 +513,25 @@ gfc_assign_data_value (gfc_expr *lvalue, gfc_expr *rvalue, mpz_t index, &lvalue->where); goto abort; case INQUIRY_RE: - mpfr_set (mpc_realref (last_con->expr->value.complex), - expr->value.real, + mpfr_set (mpc_realref (expr->value.complex), + rexpr->value.real, GFC_RND_MODE); - mpfr_set_ui (mpc_imagref (last_con->expr->value.complex), - 0.0, GFC_RND_MODE); break; case INQUIRY_IM: - mpfr_set (mpc_imagref (last_con->expr->value.complex), - expr->value.real, + mpfr_set (mpc_imagref (expr->value.complex), + rexpr->value.real, GFC_RND_MODE); - mpfr_set_ui (mpc_realref (last_con->expr->value.complex), - 0.0, GFC_RND_MODE); break; } - gfc_free_expr (expr); + /* Only the scalar, complex expression needs to be saved as the + symbol value since the last constructor expression is already + provided as the initializer in the code after the reference + cases. */ + if (ref == lvalue->ref) + symbol->value = expr; + + gfc_free_expr (rexpr); mpz_clear (offset); return true; diff --git a/gcc/testsuite/gfortran.dg/data_inquiry_ref.f90 b/gcc/testsuite/gfortran.dg/data_inquiry_ref.f90 index 38c76abf590b..de320f178ed8 100644 --- a/gcc/testsuite/gfortran.dg/data_inquiry_ref.f90 +++ b/gcc/testsuite/gfortran.dg/data_inquiry_ref.f90 @@ -1,6 +1,8 @@ -! { dg-do run } +! { dg-do compile } ! -! Test the fix for PR98022. +! Test the fix for PR98022. Code is in place to deliver the expected result. +! However, it was determined that the data statements below violate F18(R841) +! and so an error results. ! ! Contributed by Arseny Solokha ! @@ -8,9 +10,11 @@ module ur contains ! The reporter's test. function kn1() result(hm2) - complex :: hm(1:2), hm2(1:2) - data (hm(md)%re, md=1,2)/1.0, 2.0/ - hm2 = hm + complex :: hm(1:2), hm2(1:3), scalar + data (hm(md)%re, md=1,2)/1.0, 2.0/, scalar%re/42.0/ ! { dg-error "neither an array-element" } + data (hm(md)%im, md=1,2)/0.0, 0.0/, scalar%im/-42.0/ ! { dg-error "neither an array-element" } + hm2(1:2) = hm + hm2(3) = scalar end function kn1 ! Check for derived types with complex components. @@ -19,15 +23,17 @@ contains complex :: c integer :: i end type - type (t) :: hm(1:2) - complex :: hm2(1:2) - data (hm(md)%c%im, md=1,2)/1.0, 2.0/ + type (t) :: hm(1:2), scalar + complex :: hm2(1:3) + data (hm(md)%c%re, md=1,2)/0.0, 0.0/, scalar%c%re/42.0/ ! { dg-error "neither an array-element" } + data (hm(md)%c%im, md=1,2)/1.0, 2.0/, scalar%c%im/-42.0/ ! { dg-error "neither an array-element" } data (hm(md)%i, md=1,2)/1, 2/ - hm2 = hm%c + hm2(1:2) = hm%c + hm2(3) = scalar%c end function kn2 end module ur - use ur - if (any (kn1() .ne. [(1.0,0.0),(2.0,0.0)])) stop 1 - if (any (kn2() .ne. [(0.0,1.0),(0.0,2.0)])) stop 2 +! use ur +! if (any (kn1() .ne. [(1.0,0.0),(2.0,0.0),(42.0,-42.0)])) stop 1 +! if (any (kn2() .ne. [(0.0,1.0),(0.0,2.0),(42.0,-42.0)])) stop 2 end