/* Intrinsic translation Copyright (C) 2002-2022 Free Software Foundation, Inc. Contributed by Paul Brook and Steven Bosscher This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ /* trans-intrinsic.cc-- generate GENERIC trees for calls to intrinsics. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "memmodel.h" #include "tm.h" /* For UNITS_PER_WORD. */ #include "tree.h" #include "gfortran.h" #include "trans.h" #include "stringpool.h" #include "fold-const.h" #include "internal-fn.h" #include "tree-nested.h" #include "stor-layout.h" #include "toplev.h" /* For rest_of_decl_compilation. */ #include "arith.h" #include "trans-const.h" #include "trans-types.h" #include "trans-array.h" #include "dependency.h" /* For CAF array alias analysis. */ #include "attribs.h" /* Only for gfc_trans_assign and gfc_trans_pointer_assign. */ /* This maps Fortran intrinsic math functions to external library or GCC builtin functions. */ typedef struct GTY(()) gfc_intrinsic_map_t { /* The explicit enum is required to work around inadequacies in the garbage collection/gengtype parsing mechanism. */ enum gfc_isym_id id; /* Enum value from the "language-independent", aka C-centric, part of gcc, or END_BUILTINS of no such value set. */ enum built_in_function float_built_in; enum built_in_function double_built_in; enum built_in_function long_double_built_in; enum built_in_function complex_float_built_in; enum built_in_function complex_double_built_in; enum built_in_function complex_long_double_built_in; /* True if the naming pattern is to prepend "c" for complex and append "f" for kind=4. False if the naming pattern is to prepend "_gfortran_" and append "[rc](4|8|10|16)". */ bool libm_name; /* True if a complex version of the function exists. */ bool complex_available; /* True if the function should be marked const. */ bool is_constant; /* The base library name of this function. */ const char *name; /* Cache decls created for the various operand types. */ tree real4_decl; tree real8_decl; tree real10_decl; tree real16_decl; tree complex4_decl; tree complex8_decl; tree complex10_decl; tree complex16_decl; } gfc_intrinsic_map_t; /* ??? The NARGS==1 hack here is based on the fact that (c99 at least) defines complex variants of all of the entries in mathbuiltins.def except for atan2. */ #define DEFINE_MATH_BUILTIN(ID, NAME, ARGTYPE) \ { GFC_ISYM_ ## ID, BUILT_IN_ ## ID ## F, BUILT_IN_ ## ID, \ BUILT_IN_ ## ID ## L, END_BUILTINS, END_BUILTINS, END_BUILTINS, \ true, false, true, NAME, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, \ NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE}, #define DEFINE_MATH_BUILTIN_C(ID, NAME, ARGTYPE) \ { GFC_ISYM_ ## ID, BUILT_IN_ ## ID ## F, BUILT_IN_ ## ID, \ BUILT_IN_ ## ID ## L, BUILT_IN_C ## ID ## F, BUILT_IN_C ## ID, \ BUILT_IN_C ## ID ## L, true, true, true, NAME, NULL_TREE, NULL_TREE, \ NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE}, #define LIB_FUNCTION(ID, NAME, HAVE_COMPLEX) \ { GFC_ISYM_ ## ID, END_BUILTINS, END_BUILTINS, END_BUILTINS, \ END_BUILTINS, END_BUILTINS, END_BUILTINS, \ false, HAVE_COMPLEX, true, NAME, NULL_TREE, NULL_TREE, NULL_TREE, \ NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE } #define OTHER_BUILTIN(ID, NAME, TYPE, CONST) \ { GFC_ISYM_NONE, BUILT_IN_ ## ID ## F, BUILT_IN_ ## ID, \ BUILT_IN_ ## ID ## L, END_BUILTINS, END_BUILTINS, END_BUILTINS, \ true, false, CONST, NAME, NULL_TREE, NULL_TREE, \ NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE}, static GTY(()) gfc_intrinsic_map_t gfc_intrinsic_map[] = { /* Functions built into gcc itself (DEFINE_MATH_BUILTIN and DEFINE_MATH_BUILTIN_C), then the built-ins that don't correspond to any GFC_ISYM id directly, which use the OTHER_BUILTIN macro. */ #include "mathbuiltins.def" /* Functions in libgfortran. */ LIB_FUNCTION (ERFC_SCALED, "erfc_scaled", false), LIB_FUNCTION (SIND, "sind", false), LIB_FUNCTION (COSD, "cosd", false), LIB_FUNCTION (TAND, "tand", false), /* End the list. */ LIB_FUNCTION (NONE, NULL, false) }; #undef OTHER_BUILTIN #undef LIB_FUNCTION #undef DEFINE_MATH_BUILTIN #undef DEFINE_MATH_BUILTIN_C enum rounding_mode { RND_ROUND, RND_TRUNC, RND_CEIL, RND_FLOOR }; /* Find the correct variant of a given builtin from its argument. */ static tree builtin_decl_for_precision (enum built_in_function base_built_in, int precision) { enum built_in_function i = END_BUILTINS; gfc_intrinsic_map_t *m; for (m = gfc_intrinsic_map; m->double_built_in != base_built_in ; m++) ; if (precision == TYPE_PRECISION (float_type_node)) i = m->float_built_in; else if (precision == TYPE_PRECISION (double_type_node)) i = m->double_built_in; else if (precision == TYPE_PRECISION (long_double_type_node) && (!gfc_real16_is_float128 || long_double_type_node != gfc_float128_type_node)) i = m->long_double_built_in; else if (precision == TYPE_PRECISION (gfc_float128_type_node)) { /* Special treatment, because it is not exactly a built-in, but a library function. */ return m->real16_decl; } return (i == END_BUILTINS ? NULL_TREE : builtin_decl_explicit (i)); } tree gfc_builtin_decl_for_float_kind (enum built_in_function double_built_in, int kind) { int i = gfc_validate_kind (BT_REAL, kind, false); if (gfc_real_kinds[i].c_float128) { /* For _Float128, the story is a bit different, because we return a decl to a library function rather than a built-in. */ gfc_intrinsic_map_t *m; for (m = gfc_intrinsic_map; m->double_built_in != double_built_in ; m++) ; return m->real16_decl; } return builtin_decl_for_precision (double_built_in, gfc_real_kinds[i].mode_precision); } /* Evaluate the arguments to an intrinsic function. The value of NARGS may be less than the actual number of arguments in EXPR to allow optional "KIND" arguments that are not included in the generated code to be ignored. */ static void gfc_conv_intrinsic_function_args (gfc_se *se, gfc_expr *expr, tree *argarray, int nargs) { gfc_actual_arglist *actual; gfc_expr *e; gfc_intrinsic_arg *formal; gfc_se argse; int curr_arg; formal = expr->value.function.isym->formal; actual = expr->value.function.actual; for (curr_arg = 0; curr_arg < nargs; curr_arg++, actual = actual->next, formal = formal ? formal->next : NULL) { gcc_assert (actual); e = actual->expr; /* Skip omitted optional arguments. */ if (!e) { --curr_arg; continue; } /* Evaluate the parameter. This will substitute scalarized references automatically. */ gfc_init_se (&argse, se); if (e->ts.type == BT_CHARACTER) { gfc_conv_expr (&argse, e); gfc_conv_string_parameter (&argse); argarray[curr_arg++] = argse.string_length; gcc_assert (curr_arg < nargs); } else gfc_conv_expr_val (&argse, e); /* If an optional argument is itself an optional dummy argument, check its presence and substitute a null if absent. */ if (e->expr_type == EXPR_VARIABLE && e->symtree->n.sym->attr.optional && formal && formal->optional) gfc_conv_missing_dummy (&argse, e, formal->ts, 0); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); argarray[curr_arg] = argse.expr; } } /* Count the number of actual arguments to the intrinsic function EXPR including any "hidden" string length arguments. */ static unsigned int gfc_intrinsic_argument_list_length (gfc_expr *expr) { int n = 0; gfc_actual_arglist *actual; for (actual = expr->value.function.actual; actual; actual = actual->next) { if (!actual->expr) continue; if (actual->expr->ts.type == BT_CHARACTER) n += 2; else n++; } return n; } /* Conversions between different types are output by the frontend as intrinsic functions. We implement these directly with inline code. */ static void gfc_conv_intrinsic_conversion (gfc_se * se, gfc_expr * expr) { tree type; tree *args; int nargs; nargs = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, nargs); /* Evaluate all the arguments passed. Whilst we're only interested in the first one here, there are other parts of the front-end that assume this and will trigger an ICE if it's not the case. */ type = gfc_typenode_for_spec (&expr->ts); gcc_assert (expr->value.function.actual->expr); gfc_conv_intrinsic_function_args (se, expr, args, nargs); /* Conversion between character kinds involves a call to a library function. */ if (expr->ts.type == BT_CHARACTER) { tree fndecl, var, addr, tmp; if (expr->ts.kind == 1 && expr->value.function.actual->expr->ts.kind == 4) fndecl = gfor_fndecl_convert_char4_to_char1; else if (expr->ts.kind == 4 && expr->value.function.actual->expr->ts.kind == 1) fndecl = gfor_fndecl_convert_char1_to_char4; else gcc_unreachable (); /* Create the variable storing the converted value. */ type = gfc_get_pchar_type (expr->ts.kind); var = gfc_create_var (type, "str"); addr = gfc_build_addr_expr (build_pointer_type (type), var); /* Call the library function that will perform the conversion. */ gcc_assert (nargs >= 2); tmp = build_call_expr_loc (input_location, fndecl, 3, addr, args[0], args[1]); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards. */ tmp = gfc_call_free (var); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = args[0]; return; } /* Conversion from complex to non-complex involves taking the real component of the value. */ if (TREE_CODE (TREE_TYPE (args[0])) == COMPLEX_TYPE && expr->ts.type != BT_COMPLEX) { tree artype; artype = TREE_TYPE (TREE_TYPE (args[0])); args[0] = fold_build1_loc (input_location, REALPART_EXPR, artype, args[0]); } se->expr = convert (type, args[0]); } /* This is needed because the gcc backend only implements FIX_TRUNC_EXPR, which is the same as INT() in Fortran. FLOOR(x) = INT(x) <= x ? INT(x) : INT(x) - 1 Similarly for CEILING. */ static tree build_fixbound_expr (stmtblock_t * pblock, tree arg, tree type, int up) { tree tmp; tree cond; tree argtype; tree intval; argtype = TREE_TYPE (arg); arg = gfc_evaluate_now (arg, pblock); intval = convert (type, arg); intval = gfc_evaluate_now (intval, pblock); tmp = convert (argtype, intval); cond = fold_build2_loc (input_location, up ? GE_EXPR : LE_EXPR, logical_type_node, tmp, arg); tmp = fold_build2_loc (input_location, up ? PLUS_EXPR : MINUS_EXPR, type, intval, build_int_cst (type, 1)); tmp = fold_build3_loc (input_location, COND_EXPR, type, cond, intval, tmp); return tmp; } /* Round to nearest integer, away from zero. */ static tree build_round_expr (tree arg, tree restype) { tree argtype; tree fn; int argprec, resprec; argtype = TREE_TYPE (arg); argprec = TYPE_PRECISION (argtype); resprec = TYPE_PRECISION (restype); /* Depending on the type of the result, choose the int intrinsic (iround, available only as a builtin, therefore cannot use it for _Float128), long int intrinsic (lround family) or long long intrinsic (llround). If we don't have an appropriate function that converts directly to the integer type (such as kind == 16), just use ROUND, and then convert the result to an integer. We might also need to convert the result afterwards. */ if (resprec <= INT_TYPE_SIZE && argprec <= LONG_DOUBLE_TYPE_SIZE) fn = builtin_decl_for_precision (BUILT_IN_IROUND, argprec); else if (resprec <= LONG_TYPE_SIZE) fn = builtin_decl_for_precision (BUILT_IN_LROUND, argprec); else if (resprec <= LONG_LONG_TYPE_SIZE) fn = builtin_decl_for_precision (BUILT_IN_LLROUND, argprec); else if (resprec >= argprec) fn = builtin_decl_for_precision (BUILT_IN_ROUND, argprec); else gcc_unreachable (); return convert (restype, build_call_expr_loc (input_location, fn, 1, arg)); } /* Convert a real to an integer using a specific rounding mode. Ideally we would just build the corresponding GENERIC node, however the RTL expander only actually supports FIX_TRUNC_EXPR. */ static tree build_fix_expr (stmtblock_t * pblock, tree arg, tree type, enum rounding_mode op) { switch (op) { case RND_FLOOR: return build_fixbound_expr (pblock, arg, type, 0); case RND_CEIL: return build_fixbound_expr (pblock, arg, type, 1); case RND_ROUND: return build_round_expr (arg, type); case RND_TRUNC: return fold_build1_loc (input_location, FIX_TRUNC_EXPR, type, arg); default: gcc_unreachable (); } } /* Round a real value using the specified rounding mode. We use a temporary integer of that same kind size as the result. Values larger than those that can be represented by this kind are unchanged, as they will not be accurate enough to represent the rounding. huge = HUGE (KIND (a)) aint (a) = ((a > huge) || (a < -huge)) ? a : (real)(int)a */ static void gfc_conv_intrinsic_aint (gfc_se * se, gfc_expr * expr, enum rounding_mode op) { tree type; tree itype; tree arg[2]; tree tmp; tree cond; tree decl; mpfr_t huge; int n, nargs; int kind; kind = expr->ts.kind; nargs = gfc_intrinsic_argument_list_length (expr); decl = NULL_TREE; /* We have builtin functions for some cases. */ switch (op) { case RND_ROUND: decl = gfc_builtin_decl_for_float_kind (BUILT_IN_ROUND, kind); break; case RND_TRUNC: decl = gfc_builtin_decl_for_float_kind (BUILT_IN_TRUNC, kind); break; default: gcc_unreachable (); } /* Evaluate the argument. */ gcc_assert (expr->value.function.actual->expr); gfc_conv_intrinsic_function_args (se, expr, arg, nargs); /* Use a builtin function if one exists. */ if (decl != NULL_TREE) { se->expr = build_call_expr_loc (input_location, decl, 1, arg[0]); return; } /* This code is probably redundant, but we'll keep it lying around just in case. */ type = gfc_typenode_for_spec (&expr->ts); arg[0] = gfc_evaluate_now (arg[0], &se->pre); /* Test if the value is too large to handle sensibly. */ gfc_set_model_kind (kind); mpfr_init (huge); n = gfc_validate_kind (BT_INTEGER, kind, false); mpfr_set_z (huge, gfc_integer_kinds[n].huge, GFC_RND_MODE); tmp = gfc_conv_mpfr_to_tree (huge, kind, 0); cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, arg[0], tmp); mpfr_neg (huge, huge, GFC_RND_MODE); tmp = gfc_conv_mpfr_to_tree (huge, kind, 0); tmp = fold_build2_loc (input_location, GT_EXPR, logical_type_node, arg[0], tmp); cond = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, cond, tmp); itype = gfc_get_int_type (kind); tmp = build_fix_expr (&se->pre, arg[0], itype, op); tmp = convert (type, tmp); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, tmp, arg[0]); mpfr_clear (huge); } /* Convert to an integer using the specified rounding mode. */ static void gfc_conv_intrinsic_int (gfc_se * se, gfc_expr * expr, enum rounding_mode op) { tree type; tree *args; int nargs; nargs = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, nargs); /* Evaluate the argument, we process all arguments even though we only use the first one for code generation purposes. */ type = gfc_typenode_for_spec (&expr->ts); gcc_assert (expr->value.function.actual->expr); gfc_conv_intrinsic_function_args (se, expr, args, nargs); if (TREE_CODE (TREE_TYPE (args[0])) == INTEGER_TYPE) { /* Conversion to a different integer kind. */ se->expr = convert (type, args[0]); } else { /* Conversion from complex to non-complex involves taking the real component of the value. */ if (TREE_CODE (TREE_TYPE (args[0])) == COMPLEX_TYPE && expr->ts.type != BT_COMPLEX) { tree artype; artype = TREE_TYPE (TREE_TYPE (args[0])); args[0] = fold_build1_loc (input_location, REALPART_EXPR, artype, args[0]); } se->expr = build_fix_expr (&se->pre, args[0], type, op); } } /* Get the imaginary component of a value. */ static void gfc_conv_intrinsic_imagpart (gfc_se * se, gfc_expr * expr) { tree arg; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); se->expr = fold_build1_loc (input_location, IMAGPART_EXPR, TREE_TYPE (TREE_TYPE (arg)), arg); } /* Get the complex conjugate of a value. */ static void gfc_conv_intrinsic_conjg (gfc_se * se, gfc_expr * expr) { tree arg; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); se->expr = fold_build1_loc (input_location, CONJ_EXPR, TREE_TYPE (arg), arg); } static tree define_quad_builtin (const char *name, tree type, bool is_const) { tree fndecl; fndecl = build_decl (input_location, FUNCTION_DECL, get_identifier (name), type); /* Mark the decl as external. */ DECL_EXTERNAL (fndecl) = 1; TREE_PUBLIC (fndecl) = 1; /* Mark it __attribute__((const)). */ TREE_READONLY (fndecl) = is_const; rest_of_decl_compilation (fndecl, 1, 0); return fndecl; } /* Add SIMD attribute for FNDECL built-in if the built-in name is in VECTORIZED_BUILTINS. */ static void add_simd_flag_for_built_in (tree fndecl) { if (gfc_vectorized_builtins == NULL || fndecl == NULL_TREE) return; const char *name = IDENTIFIER_POINTER (DECL_NAME (fndecl)); int *clauses = gfc_vectorized_builtins->get (name); if (clauses) { for (unsigned i = 0; i < 3; i++) if (*clauses & (1 << i)) { gfc_simd_clause simd_type = (gfc_simd_clause)*clauses; tree omp_clause = NULL_TREE; if (simd_type == SIMD_NONE) ; /* No SIMD clause. */ else { omp_clause_code code = (simd_type == SIMD_INBRANCH ? OMP_CLAUSE_INBRANCH : OMP_CLAUSE_NOTINBRANCH); omp_clause = build_omp_clause (UNKNOWN_LOCATION, code); omp_clause = build_tree_list (NULL_TREE, omp_clause); } DECL_ATTRIBUTES (fndecl) = tree_cons (get_identifier ("omp declare simd"), omp_clause, DECL_ATTRIBUTES (fndecl)); } } } /* Set SIMD attribute to all built-in functions that are mentioned in gfc_vectorized_builtins vector. */ void gfc_adjust_builtins (void) { gfc_intrinsic_map_t *m; for (m = gfc_intrinsic_map; m->id != GFC_ISYM_NONE || m->double_built_in != END_BUILTINS; m++) { add_simd_flag_for_built_in (m->real4_decl); add_simd_flag_for_built_in (m->complex4_decl); add_simd_flag_for_built_in (m->real8_decl); add_simd_flag_for_built_in (m->complex8_decl); add_simd_flag_for_built_in (m->real10_decl); add_simd_flag_for_built_in (m->complex10_decl); add_simd_flag_for_built_in (m->real16_decl); add_simd_flag_for_built_in (m->complex16_decl); add_simd_flag_for_built_in (m->real16_decl); add_simd_flag_for_built_in (m->complex16_decl); } /* Release all strings. */ if (gfc_vectorized_builtins != NULL) { for (hash_map::iterator it = gfc_vectorized_builtins->begin (); it != gfc_vectorized_builtins->end (); ++it) free (CONST_CAST (char *, (*it).first)); delete gfc_vectorized_builtins; gfc_vectorized_builtins = NULL; } } /* Initialize function decls for library functions. The external functions are created as required. Builtin functions are added here. */ void gfc_build_intrinsic_lib_fndecls (void) { gfc_intrinsic_map_t *m; tree quad_decls[END_BUILTINS + 1]; if (gfc_real16_is_float128) { /* If we have soft-float types, we create the decls for their C99-like library functions. For now, we only handle _Float128 q-suffixed or IEC 60559 f128-suffixed functions. */ tree type, complex_type, func_1, func_2, func_cabs, func_frexp; tree func_iround, func_lround, func_llround, func_scalbn, func_cpow; memset (quad_decls, 0, sizeof(tree) * (END_BUILTINS + 1)); type = gfc_float128_type_node; complex_type = gfc_complex_float128_type_node; /* type (*) (type) */ func_1 = build_function_type_list (type, type, NULL_TREE); /* int (*) (type) */ func_iround = build_function_type_list (integer_type_node, type, NULL_TREE); /* long (*) (type) */ func_lround = build_function_type_list (long_integer_type_node, type, NULL_TREE); /* long long (*) (type) */ func_llround = build_function_type_list (long_long_integer_type_node, type, NULL_TREE); /* type (*) (type, type) */ func_2 = build_function_type_list (type, type, type, NULL_TREE); /* type (*) (type, &int) */ func_frexp = build_function_type_list (type, type, build_pointer_type (integer_type_node), NULL_TREE); /* type (*) (type, int) */ func_scalbn = build_function_type_list (type, type, integer_type_node, NULL_TREE); /* type (*) (complex type) */ func_cabs = build_function_type_list (type, complex_type, NULL_TREE); /* complex type (*) (complex type, complex type) */ func_cpow = build_function_type_list (complex_type, complex_type, complex_type, NULL_TREE); #define DEFINE_MATH_BUILTIN(ID, NAME, ARGTYPE) #define DEFINE_MATH_BUILTIN_C(ID, NAME, ARGTYPE) #define LIB_FUNCTION(ID, NAME, HAVE_COMPLEX) /* Only these built-ins are actually needed here. These are used directly from the code, when calling builtin_decl_for_precision() or builtin_decl_for_float_type(). The others are all constructed by gfc_get_intrinsic_lib_fndecl(). */ #define OTHER_BUILTIN(ID, NAME, TYPE, CONST) \ quad_decls[BUILT_IN_ ## ID] \ = define_quad_builtin (gfc_real16_use_iec_60559 \ ? NAME "f128" : NAME "q", func_ ## TYPE, \ CONST); #include "mathbuiltins.def" #undef OTHER_BUILTIN #undef LIB_FUNCTION #undef DEFINE_MATH_BUILTIN #undef DEFINE_MATH_BUILTIN_C /* There is one built-in we defined manually, because it gets called with builtin_decl_for_precision() or builtin_decl_for_float_type() even though it is not an OTHER_BUILTIN: it is SQRT. */ quad_decls[BUILT_IN_SQRT] = define_quad_builtin (gfc_real16_use_iec_60559 ? "sqrtf128" : "sqrtq", func_1, true); } /* Add GCC builtin functions. */ for (m = gfc_intrinsic_map; m->id != GFC_ISYM_NONE || m->double_built_in != END_BUILTINS; m++) { if (m->float_built_in != END_BUILTINS) m->real4_decl = builtin_decl_explicit (m->float_built_in); if (m->complex_float_built_in != END_BUILTINS) m->complex4_decl = builtin_decl_explicit (m->complex_float_built_in); if (m->double_built_in != END_BUILTINS) m->real8_decl = builtin_decl_explicit (m->double_built_in); if (m->complex_double_built_in != END_BUILTINS) m->complex8_decl = builtin_decl_explicit (m->complex_double_built_in); /* If real(kind=10) exists, it is always long double. */ if (m->long_double_built_in != END_BUILTINS) m->real10_decl = builtin_decl_explicit (m->long_double_built_in); if (m->complex_long_double_built_in != END_BUILTINS) m->complex10_decl = builtin_decl_explicit (m->complex_long_double_built_in); if (!gfc_real16_is_float128) { if (m->long_double_built_in != END_BUILTINS) m->real16_decl = builtin_decl_explicit (m->long_double_built_in); if (m->complex_long_double_built_in != END_BUILTINS) m->complex16_decl = builtin_decl_explicit (m->complex_long_double_built_in); } else if (quad_decls[m->double_built_in] != NULL_TREE) { /* Quad-precision function calls are constructed when first needed by builtin_decl_for_precision(), except for those that will be used directly (define by OTHER_BUILTIN). */ m->real16_decl = quad_decls[m->double_built_in]; } else if (quad_decls[m->complex_double_built_in] != NULL_TREE) { /* Same thing for the complex ones. */ m->complex16_decl = quad_decls[m->double_built_in]; } } } /* Create a fndecl for a simple intrinsic library function. */ static tree gfc_get_intrinsic_lib_fndecl (gfc_intrinsic_map_t * m, gfc_expr * expr) { tree type; vec *argtypes; tree fndecl; gfc_actual_arglist *actual; tree *pdecl; gfc_typespec *ts; char name[GFC_MAX_SYMBOL_LEN + 3]; ts = &expr->ts; if (ts->type == BT_REAL) { switch (ts->kind) { case 4: pdecl = &m->real4_decl; break; case 8: pdecl = &m->real8_decl; break; case 10: pdecl = &m->real10_decl; break; case 16: pdecl = &m->real16_decl; break; default: gcc_unreachable (); } } else if (ts->type == BT_COMPLEX) { gcc_assert (m->complex_available); switch (ts->kind) { case 4: pdecl = &m->complex4_decl; break; case 8: pdecl = &m->complex8_decl; break; case 10: pdecl = &m->complex10_decl; break; case 16: pdecl = &m->complex16_decl; break; default: gcc_unreachable (); } } else gcc_unreachable (); if (*pdecl) return *pdecl; if (m->libm_name) { int n = gfc_validate_kind (BT_REAL, ts->kind, false); if (gfc_real_kinds[n].c_float) snprintf (name, sizeof (name), "%s%s%s", ts->type == BT_COMPLEX ? "c" : "", m->name, "f"); else if (gfc_real_kinds[n].c_double) snprintf (name, sizeof (name), "%s%s", ts->type == BT_COMPLEX ? "c" : "", m->name); else if (gfc_real_kinds[n].c_long_double) snprintf (name, sizeof (name), "%s%s%s", ts->type == BT_COMPLEX ? "c" : "", m->name, "l"); else if (gfc_real_kinds[n].c_float128) snprintf (name, sizeof (name), "%s%s%s", ts->type == BT_COMPLEX ? "c" : "", m->name, gfc_real_kinds[n].use_iec_60559 ? "f128" : "q"); else gcc_unreachable (); } else { snprintf (name, sizeof (name), PREFIX ("%s_%c%d"), m->name, ts->type == BT_COMPLEX ? 'c' : 'r', gfc_type_abi_kind (ts)); } argtypes = NULL; for (actual = expr->value.function.actual; actual; actual = actual->next) { type = gfc_typenode_for_spec (&actual->expr->ts); vec_safe_push (argtypes, type); } type = build_function_type_vec (gfc_typenode_for_spec (ts), argtypes); fndecl = build_decl (input_location, FUNCTION_DECL, get_identifier (name), type); /* Mark the decl as external. */ DECL_EXTERNAL (fndecl) = 1; TREE_PUBLIC (fndecl) = 1; /* Mark it __attribute__((const)), if possible. */ TREE_READONLY (fndecl) = m->is_constant; rest_of_decl_compilation (fndecl, 1, 0); (*pdecl) = fndecl; return fndecl; } /* Convert an intrinsic function into an external or builtin call. */ static void gfc_conv_intrinsic_lib_function (gfc_se * se, gfc_expr * expr) { gfc_intrinsic_map_t *m; tree fndecl; tree rettype; tree *args; unsigned int num_args; gfc_isym_id id; id = expr->value.function.isym->id; /* Find the entry for this function. */ for (m = gfc_intrinsic_map; m->id != GFC_ISYM_NONE || m->double_built_in != END_BUILTINS; m++) { if (id == m->id) break; } if (m->id == GFC_ISYM_NONE) { gfc_internal_error ("Intrinsic function %qs (%d) not recognized", expr->value.function.name, id); } /* Get the decl and generate the call. */ num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); fndecl = gfc_get_intrinsic_lib_fndecl (m, expr); rettype = TREE_TYPE (TREE_TYPE (fndecl)); fndecl = build_addr (fndecl); se->expr = build_call_array_loc (input_location, rettype, fndecl, num_args, args); } /* If bounds-checking is enabled, create code to verify at runtime that the string lengths for both expressions are the same (needed for e.g. MERGE). If bounds-checking is not enabled, does nothing. */ void gfc_trans_same_strlen_check (const char* intr_name, locus* where, tree a, tree b, stmtblock_t* target) { tree cond; tree name; /* If bounds-checking is disabled, do nothing. */ if (!(gfc_option.rtcheck & GFC_RTCHECK_BOUNDS)) return; /* Compare the two string lengths. */ cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, a, b); /* Output the runtime-check. */ name = gfc_build_cstring_const (intr_name); name = gfc_build_addr_expr (pchar_type_node, name); gfc_trans_runtime_check (true, false, cond, target, where, "Unequal character lengths (%ld/%ld) in %s", fold_convert (long_integer_type_node, a), fold_convert (long_integer_type_node, b), name); } /* The EXPONENT(X) intrinsic function is translated into int ret; return isfinite(X) ? (frexp (X, &ret) , ret) : huge so that if X is a NaN or infinity, the result is HUGE(0). */ static void gfc_conv_intrinsic_exponent (gfc_se *se, gfc_expr *expr) { tree arg, type, res, tmp, frexp, cond, huge; int i; frexp = gfc_builtin_decl_for_float_kind (BUILT_IN_FREXP, expr->value.function.actual->expr->ts.kind); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); i = gfc_validate_kind (BT_INTEGER, gfc_c_int_kind, false); huge = gfc_conv_mpz_to_tree (gfc_integer_kinds[i].huge, gfc_c_int_kind); cond = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISFINITE), 1, arg); res = gfc_create_var (integer_type_node, NULL); tmp = build_call_expr_loc (input_location, frexp, 2, arg, gfc_build_addr_expr (NULL_TREE, res)); tmp = fold_build2_loc (input_location, COMPOUND_EXPR, integer_type_node, tmp, res); se->expr = fold_build3_loc (input_location, COND_EXPR, integer_type_node, cond, tmp, huge); type = gfc_typenode_for_spec (&expr->ts); se->expr = fold_convert (type, se->expr); } /* Fill in the following structure struct caf_vector_t { size_t nvec; // size of the vector union { struct { void *vector; int kind; } v; struct { ptrdiff_t lower_bound; ptrdiff_t upper_bound; ptrdiff_t stride; } triplet; } u; } */ static void conv_caf_vector_subscript_elem (stmtblock_t *block, int i, tree desc, tree lower, tree upper, tree stride, tree vector, int kind, tree nvec) { tree field, type, tmp; desc = gfc_build_array_ref (desc, gfc_rank_cst[i], NULL_TREE); type = TREE_TYPE (desc); field = gfc_advance_chain (TYPE_FIELDS (type), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), nvec)); /* Access union. */ field = gfc_advance_chain (TYPE_FIELDS (type), 1); desc = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); type = TREE_TYPE (desc); /* Access the inner struct. */ field = gfc_advance_chain (TYPE_FIELDS (type), vector != NULL_TREE ? 0 : 1); desc = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); type = TREE_TYPE (desc); if (vector != NULL_TREE) { /* Set vector and kind. */ field = gfc_advance_chain (TYPE_FIELDS (type), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), vector)); field = gfc_advance_chain (TYPE_FIELDS (type), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, build_int_cst (integer_type_node, kind)); } else { /* Set dim.lower/upper/stride. */ field = gfc_advance_chain (TYPE_FIELDS (type), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), lower)); field = gfc_advance_chain (TYPE_FIELDS (type), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), upper)); field = gfc_advance_chain (TYPE_FIELDS (type), 2); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), desc, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), stride)); } } static tree conv_caf_vector_subscript (stmtblock_t *block, tree desc, gfc_array_ref *ar) { gfc_se argse; tree var, lower, upper = NULL_TREE, stride = NULL_TREE, vector, nvec; tree lbound, ubound, tmp; int i; var = gfc_create_var (gfc_get_caf_vector_type (ar->dimen), "vector"); for (i = 0; i < ar->dimen; i++) switch (ar->dimen_type[i]) { case DIMEN_RANGE: if (ar->end[i]) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, ar->end[i]); gfc_add_block_to_block (block, &argse.pre); upper = gfc_evaluate_now (argse.expr, block); } else upper = gfc_conv_descriptor_ubound_get (desc, gfc_rank_cst[i]); if (ar->stride[i]) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, ar->stride[i]); gfc_add_block_to_block (block, &argse.pre); stride = gfc_evaluate_now (argse.expr, block); } else stride = gfc_index_one_node; /* Fall through. */ case DIMEN_ELEMENT: if (ar->start[i]) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, ar->start[i]); gfc_add_block_to_block (block, &argse.pre); lower = gfc_evaluate_now (argse.expr, block); } else lower = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[i]); if (ar->dimen_type[i] == DIMEN_ELEMENT) { upper = lower; stride = gfc_index_one_node; } vector = NULL_TREE; nvec = size_zero_node; conv_caf_vector_subscript_elem (block, i, var, lower, upper, stride, vector, 0, nvec); break; case DIMEN_VECTOR: gfc_init_se (&argse, NULL); argse.descriptor_only = 1; gfc_conv_expr_descriptor (&argse, ar->start[i]); gfc_add_block_to_block (block, &argse.pre); vector = argse.expr; lbound = gfc_conv_descriptor_lbound_get (vector, gfc_rank_cst[0]); ubound = gfc_conv_descriptor_ubound_get (vector, gfc_rank_cst[0]); nvec = gfc_conv_array_extent_dim (lbound, ubound, NULL); tmp = gfc_conv_descriptor_stride_get (vector, gfc_rank_cst[0]); nvec = fold_build2_loc (input_location, TRUNC_DIV_EXPR, TREE_TYPE (nvec), nvec, tmp); lower = gfc_index_zero_node; upper = gfc_index_zero_node; stride = gfc_index_zero_node; vector = gfc_conv_descriptor_data_get (vector); conv_caf_vector_subscript_elem (block, i, var, lower, upper, stride, vector, ar->start[i]->ts.kind, nvec); break; default: gcc_unreachable(); } return gfc_build_addr_expr (NULL_TREE, var); } static tree compute_component_offset (tree field, tree type) { tree tmp; if (DECL_FIELD_BIT_OFFSET (field) != NULL_TREE && !integer_zerop (DECL_FIELD_BIT_OFFSET (field))) { tmp = fold_build2 (TRUNC_DIV_EXPR, type, DECL_FIELD_BIT_OFFSET (field), bitsize_unit_node); return fold_build2 (PLUS_EXPR, type, DECL_FIELD_OFFSET (field), tmp); } else return DECL_FIELD_OFFSET (field); } static tree conv_expr_ref_to_caf_ref (stmtblock_t *block, gfc_expr *expr) { gfc_ref *ref = expr->ref, *last_comp_ref; tree caf_ref = NULL_TREE, prev_caf_ref = NULL_TREE, reference_type, tmp, tmp2, field, last_type, inner_struct, mode, mode_rhs, dim_array, dim, dim_type, start, end, stride, vector, nvec; gfc_se se; bool ref_static_array = false; tree last_component_ref_tree = NULL_TREE; int i, last_type_n; if (expr->symtree) { last_component_ref_tree = expr->symtree->n.sym->backend_decl; ref_static_array = !expr->symtree->n.sym->attr.allocatable && !expr->symtree->n.sym->attr.pointer; } /* Prevent uninit-warning. */ reference_type = NULL_TREE; /* Skip refs upto the first coarray-ref. */ last_comp_ref = NULL; while (ref && (ref->type != REF_ARRAY || ref->u.ar.codimen == 0)) { /* Remember the type of components skipped. */ if (ref->type == REF_COMPONENT) last_comp_ref = ref; ref = ref->next; } /* When a component was skipped, get the type information of the last component ref, else get the type from the symbol. */ if (last_comp_ref) { last_type = gfc_typenode_for_spec (&last_comp_ref->u.c.component->ts); last_type_n = last_comp_ref->u.c.component->ts.type; } else { last_type = gfc_typenode_for_spec (&expr->symtree->n.sym->ts); last_type_n = expr->symtree->n.sym->ts.type; } while (ref) { if (ref->type == REF_ARRAY && ref->u.ar.codimen > 0 && ref->u.ar.dimen == 0) { /* Skip pure coindexes. */ ref = ref->next; continue; } tmp = gfc_create_var (gfc_get_caf_reference_type (), "caf_ref"); reference_type = TREE_TYPE (tmp); if (caf_ref == NULL_TREE) caf_ref = tmp; /* Construct the chain of refs. */ if (prev_caf_ref != NULL_TREE) { field = gfc_advance_chain (TYPE_FIELDS (reference_type), 0); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); gfc_add_modify (block, tmp2, gfc_build_addr_expr (TREE_TYPE (field), tmp)); } prev_caf_ref = tmp; switch (ref->type) { case REF_COMPONENT: last_type = gfc_typenode_for_spec (&ref->u.c.component->ts); last_type_n = ref->u.c.component->ts.type; /* Set the type of the ref. */ field = gfc_advance_chain (TYPE_FIELDS (reference_type), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); gfc_add_modify (block, tmp, build_int_cst (integer_type_node, GFC_CAF_REF_COMPONENT)); /* Ref the c in union u. */ field = gfc_advance_chain (TYPE_FIELDS (reference_type), 3); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (field)), 0); inner_struct = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); /* Set the offset. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (inner_struct)), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), inner_struct, field, NULL_TREE); /* Computing the offset is somewhat harder. The bit_offset has to be taken into account. When the bit_offset in the field_decl is non- null, divide it by the bitsize_unit and add it to the regular offset. */ tmp2 = compute_component_offset (ref->u.c.component->backend_decl, TREE_TYPE (tmp)); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (tmp), tmp2)); /* Set caf_token_offset. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (inner_struct)), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), inner_struct, field, NULL_TREE); if ((ref->u.c.component->attr.allocatable || ref->u.c.component->attr.pointer) && ref->u.c.component->attr.dimension) { tree arr_desc_token_offset; /* Get the token field from the descriptor. */ arr_desc_token_offset = TREE_OPERAND ( gfc_conv_descriptor_token (ref->u.c.component->backend_decl), 1); arr_desc_token_offset = compute_component_offset (arr_desc_token_offset, TREE_TYPE (tmp)); tmp2 = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (tmp2), tmp2, arr_desc_token_offset); } else if (ref->u.c.component->caf_token) tmp2 = compute_component_offset (ref->u.c.component->caf_token, TREE_TYPE (tmp)); else tmp2 = integer_zero_node; gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (tmp), tmp2)); /* Remember whether this ref was to a non-allocatable/non-pointer component so the next array ref can be tailored correctly. */ ref_static_array = !ref->u.c.component->attr.allocatable && !ref->u.c.component->attr.pointer; last_component_ref_tree = ref_static_array ? ref->u.c.component->backend_decl : NULL_TREE; break; case REF_ARRAY: if (ref_static_array && ref->u.ar.as->type == AS_DEFERRED) ref_static_array = false; /* Set the type of the ref. */ field = gfc_advance_chain (TYPE_FIELDS (reference_type), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); gfc_add_modify (block, tmp, build_int_cst (integer_type_node, ref_static_array ? GFC_CAF_REF_STATIC_ARRAY : GFC_CAF_REF_ARRAY)); /* Ref the a in union u. */ field = gfc_advance_chain (TYPE_FIELDS (reference_type), 3); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (field)), 1); inner_struct = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); /* Set the static_array_type in a for static arrays. */ if (ref_static_array) { field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (inner_struct)), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), inner_struct, field, NULL_TREE); gfc_add_modify (block, tmp, build_int_cst (TREE_TYPE (tmp), last_type_n)); } /* Ref the mode in the inner_struct. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (inner_struct)), 0); mode = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), inner_struct, field, NULL_TREE); /* Ref the dim in the inner_struct. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (inner_struct)), 2); dim_array = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), inner_struct, field, NULL_TREE); for (i = 0; i < ref->u.ar.dimen; ++i) { /* Ref dim i. */ dim = gfc_build_array_ref (dim_array, gfc_rank_cst[i], NULL_TREE); dim_type = TREE_TYPE (dim); mode_rhs = start = end = stride = NULL_TREE; switch (ref->u.ar.dimen_type[i]) { case DIMEN_RANGE: if (ref->u.ar.end[i]) { gfc_init_se (&se, NULL); gfc_conv_expr (&se, ref->u.ar.end[i]); gfc_add_block_to_block (block, &se.pre); if (ref_static_array) { /* Make the index zero-based, when reffing a static array. */ end = se.expr; gfc_init_se (&se, NULL); gfc_conv_expr (&se, ref->u.ar.as->lower[i]); gfc_add_block_to_block (block, &se.pre); se.expr = fold_build2 (MINUS_EXPR, gfc_array_index_type, end, fold_convert ( gfc_array_index_type, se.expr)); } end = gfc_evaluate_now (fold_convert ( gfc_array_index_type, se.expr), block); } else if (ref_static_array) end = fold_build2 (MINUS_EXPR, gfc_array_index_type, gfc_conv_array_ubound ( last_component_ref_tree, i), gfc_conv_array_lbound ( last_component_ref_tree, i)); else { end = NULL_TREE; mode_rhs = build_int_cst (unsigned_char_type_node, GFC_CAF_ARR_REF_OPEN_END); } if (ref->u.ar.stride[i]) { gfc_init_se (&se, NULL); gfc_conv_expr (&se, ref->u.ar.stride[i]); gfc_add_block_to_block (block, &se.pre); stride = gfc_evaluate_now (fold_convert ( gfc_array_index_type, se.expr), block); if (ref_static_array) { /* Make the index zero-based, when reffing a static array. */ stride = fold_build2 (MULT_EXPR, gfc_array_index_type, gfc_conv_array_stride ( last_component_ref_tree, i), stride); gcc_assert (end != NULL_TREE); /* Multiply with the product of array's stride and the step of the ref to a virtual upper bound. We cannot compute the actual upper bound here or the caflib would compute the extend incorrectly. */ end = fold_build2 (MULT_EXPR, gfc_array_index_type, end, gfc_conv_array_stride ( last_component_ref_tree, i)); end = gfc_evaluate_now (end, block); stride = gfc_evaluate_now (stride, block); } } else if (ref_static_array) { stride = gfc_conv_array_stride (last_component_ref_tree, i); end = fold_build2 (MULT_EXPR, gfc_array_index_type, end, stride); end = gfc_evaluate_now (end, block); } else /* Always set a ref stride of one to make caflib's handling easier. */ stride = gfc_index_one_node; /* Fall through. */ case DIMEN_ELEMENT: if (ref->u.ar.start[i]) { gfc_init_se (&se, NULL); gfc_conv_expr (&se, ref->u.ar.start[i]); gfc_add_block_to_block (block, &se.pre); if (ref_static_array) { /* Make the index zero-based, when reffing a static array. */ start = fold_convert (gfc_array_index_type, se.expr); gfc_init_se (&se, NULL); gfc_conv_expr (&se, ref->u.ar.as->lower[i]); gfc_add_block_to_block (block, &se.pre); se.expr = fold_build2 (MINUS_EXPR, gfc_array_index_type, start, fold_convert ( gfc_array_index_type, se.expr)); /* Multiply with the stride. */ se.expr = fold_build2 (MULT_EXPR, gfc_array_index_type, se.expr, gfc_conv_array_stride ( last_component_ref_tree, i)); } start = gfc_evaluate_now (fold_convert ( gfc_array_index_type, se.expr), block); if (mode_rhs == NULL_TREE) mode_rhs = build_int_cst (unsigned_char_type_node, ref->u.ar.dimen_type[i] == DIMEN_ELEMENT ? GFC_CAF_ARR_REF_SINGLE : GFC_CAF_ARR_REF_RANGE); } else if (ref_static_array) { start = integer_zero_node; mode_rhs = build_int_cst (unsigned_char_type_node, ref->u.ar.start[i] == NULL ? GFC_CAF_ARR_REF_FULL : GFC_CAF_ARR_REF_RANGE); } else if (end == NULL_TREE) mode_rhs = build_int_cst (unsigned_char_type_node, GFC_CAF_ARR_REF_FULL); else mode_rhs = build_int_cst (unsigned_char_type_node, GFC_CAF_ARR_REF_OPEN_START); /* Ref the s in dim. */ field = gfc_advance_chain (TYPE_FIELDS (dim_type), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), dim, field, NULL_TREE); /* Set start in s. */ if (start != NULL_TREE) { field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 0); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, fold_convert (TREE_TYPE (tmp2), start)); } /* Set end in s. */ if (end != NULL_TREE) { field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 1); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, fold_convert (TREE_TYPE (tmp2), end)); } /* Set end in s. */ if (stride != NULL_TREE) { field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 2); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, fold_convert (TREE_TYPE (tmp2), stride)); } break; case DIMEN_VECTOR: /* TODO: In case of static array. */ gcc_assert (!ref_static_array); mode_rhs = build_int_cst (unsigned_char_type_node, GFC_CAF_ARR_REF_VECTOR); gfc_init_se (&se, NULL); se.descriptor_only = 1; gfc_conv_expr_descriptor (&se, ref->u.ar.start[i]); gfc_add_block_to_block (block, &se.pre); vector = se.expr; tmp = gfc_conv_descriptor_lbound_get (vector, gfc_rank_cst[0]); tmp2 = gfc_conv_descriptor_ubound_get (vector, gfc_rank_cst[0]); nvec = gfc_conv_array_extent_dim (tmp, tmp2, NULL); tmp = gfc_conv_descriptor_stride_get (vector, gfc_rank_cst[0]); nvec = fold_build2_loc (input_location, TRUNC_DIV_EXPR, TREE_TYPE (nvec), nvec, tmp); vector = gfc_conv_descriptor_data_get (vector); /* Ref the v in dim. */ field = gfc_advance_chain (TYPE_FIELDS (dim_type), 1); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), dim, field, NULL_TREE); /* Set vector in v. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 0); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, fold_convert (TREE_TYPE (tmp2), vector)); /* Set nvec in v. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 1); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, fold_convert (TREE_TYPE (tmp2), nvec)); /* Set kind in v. */ field = gfc_advance_chain (TYPE_FIELDS (TREE_TYPE (tmp)), 2); tmp2 = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); gfc_add_modify (block, tmp2, build_int_cst (integer_type_node, ref->u.ar.start[i]->ts.kind)); break; default: gcc_unreachable (); } /* Set the mode for dim i. */ tmp = gfc_build_array_ref (mode, gfc_rank_cst[i], NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (tmp), mode_rhs)); } /* Set the mode for dim i+1 to GFC_ARR_REF_NONE. */ if (i < GFC_MAX_DIMENSIONS) { tmp = gfc_build_array_ref (mode, gfc_rank_cst[i], NULL_TREE); gfc_add_modify (block, tmp, build_int_cst (unsigned_char_type_node, GFC_CAF_ARR_REF_NONE)); } break; default: gcc_unreachable (); } /* Set the size of the current type. */ field = gfc_advance_chain (TYPE_FIELDS (reference_type), 2); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), TYPE_SIZE_UNIT (last_type))); ref = ref->next; } if (prev_caf_ref != NULL_TREE) { field = gfc_advance_chain (TYPE_FIELDS (reference_type), 0); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), prev_caf_ref, field, NULL_TREE); gfc_add_modify (block, tmp, fold_convert (TREE_TYPE (field), null_pointer_node)); } return caf_ref != NULL_TREE ? gfc_build_addr_expr (NULL_TREE, caf_ref) : NULL_TREE; } /* Get data from a remote coarray. */ static void gfc_conv_intrinsic_caf_get (gfc_se *se, gfc_expr *expr, tree lhs, tree lhs_kind, tree may_require_tmp, bool may_realloc, symbol_attribute *caf_attr) { gfc_expr *array_expr, *tmp_stat; gfc_se argse; tree caf_decl, token, offset, image_index, tmp; tree res_var, dst_var, type, kind, vec, stat; tree caf_reference; symbol_attribute caf_attr_store; gcc_assert (flag_coarray == GFC_FCOARRAY_LIB); if (se->ss && se->ss->info->useflags) { /* Access the previously obtained result. */ gfc_conv_tmp_array_ref (se); return; } /* If lhs is set, the CAF_GET intrinsic has already been stripped. */ array_expr = (lhs == NULL_TREE) ? expr->value.function.actual->expr : expr; type = gfc_typenode_for_spec (&array_expr->ts); if (caf_attr == NULL) { caf_attr_store = gfc_caf_attr (array_expr); caf_attr = &caf_attr_store; } res_var = lhs; dst_var = lhs; vec = null_pointer_node; tmp_stat = gfc_find_stat_co (expr); if (tmp_stat) { gfc_se stat_se; gfc_init_se (&stat_se, NULL); gfc_conv_expr_reference (&stat_se, tmp_stat); stat = stat_se.expr; gfc_add_block_to_block (&se->pre, &stat_se.pre); gfc_add_block_to_block (&se->post, &stat_se.post); } else stat = null_pointer_node; /* Only use the new get_by_ref () where it is necessary. I.e., when the lhs is reallocatable or the right-hand side has allocatable components. */ if (caf_attr->alloc_comp || caf_attr->pointer_comp || may_realloc) { /* Get using caf_get_by_ref. */ caf_reference = conv_expr_ref_to_caf_ref (&se->pre, array_expr); if (caf_reference != NULL_TREE) { if (lhs == NULL_TREE) { if (array_expr->ts.type == BT_CHARACTER) gfc_init_se (&argse, NULL); if (array_expr->rank == 0) { symbol_attribute attr; gfc_clear_attr (&attr); if (array_expr->ts.type == BT_CHARACTER) { res_var = gfc_conv_string_tmp (se, build_pointer_type (type), array_expr->ts.u.cl->backend_decl); argse.string_length = array_expr->ts.u.cl->backend_decl; } else res_var = gfc_create_var (type, "caf_res"); dst_var = gfc_conv_scalar_to_descriptor (se, res_var, attr); dst_var = gfc_build_addr_expr (NULL_TREE, dst_var); } else { /* Create temporary. */ if (array_expr->ts.type == BT_CHARACTER) gfc_conv_expr_descriptor (&argse, array_expr); may_realloc = gfc_trans_create_temp_array (&se->pre, &se->post, se->ss, type, NULL_TREE, false, false, false, &array_expr->where) == NULL_TREE; res_var = se->ss->info->data.array.descriptor; dst_var = gfc_build_addr_expr (NULL_TREE, res_var); if (may_realloc) { tmp = gfc_conv_descriptor_data_get (res_var); tmp = gfc_deallocate_with_status (tmp, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, true, NULL, GFC_CAF_COARRAY_NOCOARRAY); gfc_add_expr_to_block (&se->post, tmp); } } } kind = build_int_cst (integer_type_node, expr->ts.kind); if (lhs_kind == NULL_TREE) lhs_kind = kind; caf_decl = gfc_get_tree_for_caf_expr (array_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); image_index = gfc_caf_get_image_index (&se->pre, array_expr, caf_decl); gfc_get_caf_token_offset (se, &token, NULL, caf_decl, NULL, array_expr); /* No overlap possible as we have generated a temporary. */ if (lhs == NULL_TREE) may_require_tmp = boolean_false_node; /* It guarantees memory consistency within the same segment. */ tmp = gfc_build_string_const (strlen ("memory") + 1, "memory"); tmp = build5_loc (input_location, ASM_EXPR, void_type_node, gfc_build_string_const (1, ""), NULL_TREE, NULL_TREE, tree_cons (NULL_TREE, tmp, NULL_TREE), NULL_TREE); ASM_VOLATILE_P (tmp) = 1; gfc_add_expr_to_block (&se->pre, tmp); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_get_by_ref, 10, token, image_index, dst_var, caf_reference, lhs_kind, kind, may_require_tmp, may_realloc ? boolean_true_node : boolean_false_node, stat, build_int_cst (integer_type_node, array_expr->ts.type)); gfc_add_expr_to_block (&se->pre, tmp); if (se->ss) gfc_advance_se_ss_chain (se); se->expr = res_var; if (array_expr->ts.type == BT_CHARACTER) se->string_length = argse.string_length; return; } } gfc_init_se (&argse, NULL); if (array_expr->rank == 0) { symbol_attribute attr; gfc_clear_attr (&attr); gfc_conv_expr (&argse, array_expr); if (lhs == NULL_TREE) { gfc_clear_attr (&attr); if (array_expr->ts.type == BT_CHARACTER) res_var = gfc_conv_string_tmp (se, build_pointer_type (type), argse.string_length); else res_var = gfc_create_var (type, "caf_res"); dst_var = gfc_conv_scalar_to_descriptor (&argse, res_var, attr); dst_var = gfc_build_addr_expr (NULL_TREE, dst_var); } argse.expr = gfc_conv_scalar_to_descriptor (&argse, argse.expr, attr); argse.expr = gfc_build_addr_expr (NULL_TREE, argse.expr); } else { /* If has_vector, pass descriptor for whole array and the vector bounds separately. */ gfc_array_ref *ar, ar2; bool has_vector = false; if (gfc_is_coindexed (expr) && gfc_has_vector_subscript (expr)) { has_vector = true; ar = gfc_find_array_ref (expr); ar2 = *ar; memset (ar, '\0', sizeof (*ar)); ar->as = ar2.as; ar->type = AR_FULL; } // TODO: Check whether argse.want_coarray = 1 can help with the below. gfc_conv_expr_descriptor (&argse, array_expr); /* Using gfc_conv_expr_descriptor, we only get the descriptor, but that has the wrong type if component references are done. */ gfc_add_modify (&argse.pre, gfc_conv_descriptor_dtype (argse.expr), gfc_get_dtype_rank_type (has_vector ? ar2.dimen : array_expr->rank, type)); if (has_vector) { vec = conv_caf_vector_subscript (&argse.pre, argse.expr, &ar2); *ar = ar2; } if (lhs == NULL_TREE) { /* Create temporary. */ for (int n = 0; n < se->ss->loop->dimen; n++) if (se->loop->to[n] == NULL_TREE) { se->loop->from[n] = gfc_conv_descriptor_lbound_get (argse.expr, gfc_rank_cst[n]); se->loop->to[n] = gfc_conv_descriptor_ubound_get (argse.expr, gfc_rank_cst[n]); } gfc_trans_create_temp_array (&argse.pre, &argse.post, se->ss, type, NULL_TREE, false, true, false, &array_expr->where); res_var = se->ss->info->data.array.descriptor; dst_var = gfc_build_addr_expr (NULL_TREE, res_var); } argse.expr = gfc_build_addr_expr (NULL_TREE, argse.expr); } kind = build_int_cst (integer_type_node, expr->ts.kind); if (lhs_kind == NULL_TREE) lhs_kind = kind; gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); caf_decl = gfc_get_tree_for_caf_expr (array_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); image_index = gfc_caf_get_image_index (&se->pre, array_expr, caf_decl); gfc_get_caf_token_offset (se, &token, &offset, caf_decl, argse.expr, array_expr); /* No overlap possible as we have generated a temporary. */ if (lhs == NULL_TREE) may_require_tmp = boolean_false_node; /* It guarantees memory consistency within the same segment. */ tmp = gfc_build_string_const (strlen ("memory") + 1, "memory"); tmp = build5_loc (input_location, ASM_EXPR, void_type_node, gfc_build_string_const (1, ""), NULL_TREE, NULL_TREE, tree_cons (NULL_TREE, tmp, NULL_TREE), NULL_TREE); ASM_VOLATILE_P (tmp) = 1; gfc_add_expr_to_block (&se->pre, tmp); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_get, 10, token, offset, image_index, argse.expr, vec, dst_var, kind, lhs_kind, may_require_tmp, stat); gfc_add_expr_to_block (&se->pre, tmp); if (se->ss) gfc_advance_se_ss_chain (se); se->expr = res_var; if (array_expr->ts.type == BT_CHARACTER) se->string_length = argse.string_length; } /* Send data to a remote coarray. */ static tree conv_caf_send (gfc_code *code) { gfc_expr *lhs_expr, *rhs_expr, *tmp_stat, *tmp_team; gfc_se lhs_se, rhs_se; stmtblock_t block; tree caf_decl, token, offset, image_index, tmp, lhs_kind, rhs_kind; tree may_require_tmp, src_stat, dst_stat, dst_team; tree lhs_type = NULL_TREE; tree vec = null_pointer_node, rhs_vec = null_pointer_node; symbol_attribute lhs_caf_attr, rhs_caf_attr; gcc_assert (flag_coarray == GFC_FCOARRAY_LIB); lhs_expr = code->ext.actual->expr; rhs_expr = code->ext.actual->next->expr; may_require_tmp = gfc_check_dependency (lhs_expr, rhs_expr, true) == 0 ? boolean_false_node : boolean_true_node; gfc_init_block (&block); lhs_caf_attr = gfc_caf_attr (lhs_expr); rhs_caf_attr = gfc_caf_attr (rhs_expr); src_stat = dst_stat = null_pointer_node; dst_team = null_pointer_node; /* LHS. */ gfc_init_se (&lhs_se, NULL); if (lhs_expr->rank == 0) { if (lhs_expr->ts.type == BT_CHARACTER && lhs_expr->ts.deferred) { lhs_se.expr = gfc_get_tree_for_caf_expr (lhs_expr); lhs_se.expr = gfc_build_addr_expr (NULL_TREE, lhs_se.expr); } else { symbol_attribute attr; gfc_clear_attr (&attr); gfc_conv_expr (&lhs_se, lhs_expr); lhs_type = TREE_TYPE (lhs_se.expr); lhs_se.expr = gfc_conv_scalar_to_descriptor (&lhs_se, lhs_se.expr, attr); lhs_se.expr = gfc_build_addr_expr (NULL_TREE, lhs_se.expr); } } else if ((lhs_caf_attr.alloc_comp || lhs_caf_attr.pointer_comp) && lhs_caf_attr.codimension) { lhs_se.want_pointer = 1; gfc_conv_expr_descriptor (&lhs_se, lhs_expr); /* Using gfc_conv_expr_descriptor, we only get the descriptor, but that has the wrong type if component references are done. */ lhs_type = gfc_typenode_for_spec (&lhs_expr->ts); tmp = build_fold_indirect_ref_loc (input_location, lhs_se.expr); gfc_add_modify (&lhs_se.pre, gfc_conv_descriptor_dtype (tmp), gfc_get_dtype_rank_type ( gfc_has_vector_subscript (lhs_expr) ? gfc_find_array_ref (lhs_expr)->dimen : lhs_expr->rank, lhs_type)); } else { bool has_vector = gfc_has_vector_subscript (lhs_expr); if (gfc_is_coindexed (lhs_expr) || !has_vector) { /* If has_vector, pass descriptor for whole array and the vector bounds separately. */ gfc_array_ref *ar, ar2; bool has_tmp_lhs_array = false; if (has_vector) { has_tmp_lhs_array = true; ar = gfc_find_array_ref (lhs_expr); ar2 = *ar; memset (ar, '\0', sizeof (*ar)); ar->as = ar2.as; ar->type = AR_FULL; } lhs_se.want_pointer = 1; gfc_conv_expr_descriptor (&lhs_se, lhs_expr); /* Using gfc_conv_expr_descriptor, we only get the descriptor, but that has the wrong type if component references are done. */ lhs_type = gfc_typenode_for_spec (&lhs_expr->ts); tmp = build_fold_indirect_ref_loc (input_location, lhs_se.expr); gfc_add_modify (&lhs_se.pre, gfc_conv_descriptor_dtype (tmp), gfc_get_dtype_rank_type (has_vector ? ar2.dimen : lhs_expr->rank, lhs_type)); if (has_tmp_lhs_array) { vec = conv_caf_vector_subscript (&block, lhs_se.expr, &ar2); *ar = ar2; } } else { /* Special casing for arr1 ([...]) = arr2[...], i.e. caf_get to indexed array expression. This is rewritten to: tmp_array = arr2[...] arr1 ([...]) = tmp_array because using the standard gfc_conv_expr (lhs_expr) did the assignment with lhs and rhs exchanged. */ gfc_ss *lss_for_tmparray, *lss_real; gfc_loopinfo loop; gfc_se se; stmtblock_t body; tree tmparr_desc, src; tree index = gfc_index_zero_node; tree stride = gfc_index_zero_node; int n; /* Walk both sides of the assignment, once to get the shape of the temporary array to create right. */ lss_for_tmparray = gfc_walk_expr (lhs_expr); /* And a second time to be able to create an assignment of the temporary to the lhs_expr. gfc_trans_create_temp_array replaces the tree in the descriptor with the one for the temporary array. */ lss_real = gfc_walk_expr (lhs_expr); gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, lss_for_tmparray); gfc_add_ss_to_loop (&loop, lss_real); gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &lhs_expr->where); lhs_type = gfc_typenode_for_spec (&lhs_expr->ts); gfc_trans_create_temp_array (&lhs_se.pre, &lhs_se.post, lss_for_tmparray, lhs_type, NULL_TREE, false, true, false, &lhs_expr->where); tmparr_desc = lss_for_tmparray->info->data.array.descriptor; gfc_start_scalarized_body (&loop, &body); gfc_init_se (&se, NULL); gfc_copy_loopinfo_to_se (&se, &loop); se.ss = lss_real; gfc_conv_expr (&se, lhs_expr); gfc_add_block_to_block (&body, &se.pre); /* Walk over all indexes of the loop. */ for (n = loop.dimen - 1; n > 0; --n) { tmp = loop.loopvar[n]; tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, tmp, loop.from[n]); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, tmp, index); stride = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, loop.to[n - 1], loop.from[n - 1]); stride = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, stride, gfc_index_one_node); index = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, tmp, stride); } index = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, index, loop.from[0]); index = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, loop.loopvar[0], index); src = build_fold_indirect_ref (gfc_conv_array_data (tmparr_desc)); src = gfc_build_array_ref (src, index, NULL); /* Now create the assignment of lhs_expr = tmp_array. */ gfc_add_modify (&body, se.expr, src); gfc_add_block_to_block (&body, &se.post); lhs_se.expr = gfc_build_addr_expr (NULL_TREE, tmparr_desc); gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&loop.pre, &loop.post); gfc_add_expr_to_block (&lhs_se.post, gfc_finish_block (&loop.pre)); gfc_free_ss (lss_for_tmparray); gfc_free_ss (lss_real); } } lhs_kind = build_int_cst (integer_type_node, lhs_expr->ts.kind); /* Special case: RHS is a coarray but LHS is not; this code path avoids a temporary and a loop. */ if (!gfc_is_coindexed (lhs_expr) && (!lhs_caf_attr.codimension || !(lhs_expr->rank > 0 && (lhs_caf_attr.allocatable || lhs_caf_attr.pointer)))) { bool lhs_may_realloc = lhs_expr->rank > 0 && lhs_caf_attr.allocatable; gcc_assert (gfc_is_coindexed (rhs_expr)); gfc_init_se (&rhs_se, NULL); if (lhs_expr->rank == 0 && lhs_caf_attr.allocatable) { gfc_se scal_se; gfc_init_se (&scal_se, NULL); scal_se.want_pointer = 1; gfc_conv_expr (&scal_se, lhs_expr); /* Ensure scalar on lhs is allocated. */ gfc_add_block_to_block (&block, &scal_se.pre); gfc_allocate_using_malloc (&scal_se.pre, scal_se.expr, TYPE_SIZE_UNIT ( gfc_typenode_for_spec (&lhs_expr->ts)), NULL_TREE); tmp = fold_build2 (EQ_EXPR, logical_type_node, scal_se.expr, null_pointer_node); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, tmp, gfc_finish_block (&scal_se.pre), build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } else lhs_may_realloc = lhs_may_realloc && gfc_full_array_ref_p (lhs_expr->ref, NULL); gfc_add_block_to_block (&block, &lhs_se.pre); gfc_conv_intrinsic_caf_get (&rhs_se, rhs_expr, lhs_se.expr, lhs_kind, may_require_tmp, lhs_may_realloc, &rhs_caf_attr); gfc_add_block_to_block (&block, &rhs_se.pre); gfc_add_block_to_block (&block, &rhs_se.post); gfc_add_block_to_block (&block, &lhs_se.post); return gfc_finish_block (&block); } gfc_add_block_to_block (&block, &lhs_se.pre); /* Obtain token, offset and image index for the LHS. */ caf_decl = gfc_get_tree_for_caf_expr (lhs_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); image_index = gfc_caf_get_image_index (&block, lhs_expr, caf_decl); tmp = lhs_se.expr; if (lhs_caf_attr.alloc_comp) gfc_get_caf_token_offset (&lhs_se, &token, NULL, caf_decl, NULL_TREE, NULL); else gfc_get_caf_token_offset (&lhs_se, &token, &offset, caf_decl, tmp, lhs_expr); lhs_se.expr = tmp; /* RHS. */ gfc_init_se (&rhs_se, NULL); if (rhs_expr->expr_type == EXPR_FUNCTION && rhs_expr->value.function.isym && rhs_expr->value.function.isym->id == GFC_ISYM_CONVERSION) rhs_expr = rhs_expr->value.function.actual->expr; if (rhs_expr->rank == 0) { symbol_attribute attr; gfc_clear_attr (&attr); gfc_conv_expr (&rhs_se, rhs_expr); rhs_se.expr = gfc_conv_scalar_to_descriptor (&rhs_se, rhs_se.expr, attr); rhs_se.expr = gfc_build_addr_expr (NULL_TREE, rhs_se.expr); } else if ((rhs_caf_attr.alloc_comp || rhs_caf_attr.pointer_comp) && rhs_caf_attr.codimension) { tree tmp2; rhs_se.want_pointer = 1; gfc_conv_expr_descriptor (&rhs_se, rhs_expr); /* Using gfc_conv_expr_descriptor, we only get the descriptor, but that has the wrong type if component references are done. */ tmp2 = gfc_typenode_for_spec (&rhs_expr->ts); tmp = build_fold_indirect_ref_loc (input_location, rhs_se.expr); gfc_add_modify (&rhs_se.pre, gfc_conv_descriptor_dtype (tmp), gfc_get_dtype_rank_type ( gfc_has_vector_subscript (rhs_expr) ? gfc_find_array_ref (rhs_expr)->dimen : rhs_expr->rank, tmp2)); } else { /* If has_vector, pass descriptor for whole array and the vector bounds separately. */ gfc_array_ref *ar, ar2; bool has_vector = false; tree tmp2; if (gfc_is_coindexed (rhs_expr) && gfc_has_vector_subscript (rhs_expr)) { has_vector = true; ar = gfc_find_array_ref (rhs_expr); ar2 = *ar; memset (ar, '\0', sizeof (*ar)); ar->as = ar2.as; ar->type = AR_FULL; } rhs_se.want_pointer = 1; gfc_conv_expr_descriptor (&rhs_se, rhs_expr); /* Using gfc_conv_expr_descriptor, we only get the descriptor, but that has the wrong type if component references are done. */ tmp = build_fold_indirect_ref_loc (input_location, rhs_se.expr); tmp2 = gfc_typenode_for_spec (&rhs_expr->ts); gfc_add_modify (&rhs_se.pre, gfc_conv_descriptor_dtype (tmp), gfc_get_dtype_rank_type (has_vector ? ar2.dimen : rhs_expr->rank, tmp2)); if (has_vector) { rhs_vec = conv_caf_vector_subscript (&block, rhs_se.expr, &ar2); *ar = ar2; } } gfc_add_block_to_block (&block, &rhs_se.pre); rhs_kind = build_int_cst (integer_type_node, rhs_expr->ts.kind); tmp_stat = gfc_find_stat_co (lhs_expr); if (tmp_stat) { gfc_se stat_se; gfc_init_se (&stat_se, NULL); gfc_conv_expr_reference (&stat_se, tmp_stat); dst_stat = stat_se.expr; gfc_add_block_to_block (&block, &stat_se.pre); gfc_add_block_to_block (&block, &stat_se.post); } tmp_team = gfc_find_team_co (lhs_expr); if (tmp_team) { gfc_se team_se; gfc_init_se (&team_se, NULL); gfc_conv_expr_reference (&team_se, tmp_team); dst_team = team_se.expr; gfc_add_block_to_block (&block, &team_se.pre); gfc_add_block_to_block (&block, &team_se.post); } if (!gfc_is_coindexed (rhs_expr)) { if (lhs_caf_attr.alloc_comp || lhs_caf_attr.pointer_comp) { tree reference, dst_realloc; reference = conv_expr_ref_to_caf_ref (&block, lhs_expr); dst_realloc = lhs_caf_attr.allocatable ? boolean_true_node : boolean_false_node; tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_send_by_ref, 10, token, image_index, rhs_se.expr, reference, lhs_kind, rhs_kind, may_require_tmp, dst_realloc, src_stat, build_int_cst (integer_type_node, lhs_expr->ts.type)); } else tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_send, 11, token, offset, image_index, lhs_se.expr, vec, rhs_se.expr, lhs_kind, rhs_kind, may_require_tmp, src_stat, dst_team); } else { tree rhs_token, rhs_offset, rhs_image_index; /* It guarantees memory consistency within the same segment. */ tmp = gfc_build_string_const (strlen ("memory") + 1, "memory"); tmp = build5_loc (input_location, ASM_EXPR, void_type_node, gfc_build_string_const (1, ""), NULL_TREE, NULL_TREE, tree_cons (NULL_TREE, tmp, NULL_TREE), NULL_TREE); ASM_VOLATILE_P (tmp) = 1; gfc_add_expr_to_block (&block, tmp); caf_decl = gfc_get_tree_for_caf_expr (rhs_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); rhs_image_index = gfc_caf_get_image_index (&block, rhs_expr, caf_decl); tmp = rhs_se.expr; if (rhs_caf_attr.alloc_comp || rhs_caf_attr.pointer_comp) { tmp_stat = gfc_find_stat_co (lhs_expr); if (tmp_stat) { gfc_se stat_se; gfc_init_se (&stat_se, NULL); gfc_conv_expr_reference (&stat_se, tmp_stat); src_stat = stat_se.expr; gfc_add_block_to_block (&block, &stat_se.pre); gfc_add_block_to_block (&block, &stat_se.post); } gfc_get_caf_token_offset (&rhs_se, &rhs_token, NULL, caf_decl, NULL_TREE, NULL); tree lhs_reference, rhs_reference; lhs_reference = conv_expr_ref_to_caf_ref (&block, lhs_expr); rhs_reference = conv_expr_ref_to_caf_ref (&block, rhs_expr); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sendget_by_ref, 13, token, image_index, lhs_reference, rhs_token, rhs_image_index, rhs_reference, lhs_kind, rhs_kind, may_require_tmp, dst_stat, src_stat, build_int_cst (integer_type_node, lhs_expr->ts.type), build_int_cst (integer_type_node, rhs_expr->ts.type)); } else { gfc_get_caf_token_offset (&rhs_se, &rhs_token, &rhs_offset, caf_decl, tmp, rhs_expr); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sendget, 14, token, offset, image_index, lhs_se.expr, vec, rhs_token, rhs_offset, rhs_image_index, tmp, rhs_vec, lhs_kind, rhs_kind, may_require_tmp, src_stat); } } gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&block, &lhs_se.post); gfc_add_block_to_block (&block, &rhs_se.post); /* It guarantees memory consistency within the same segment. */ tmp = gfc_build_string_const (strlen ("memory") + 1, "memory"); tmp = build5_loc (input_location, ASM_EXPR, void_type_node, gfc_build_string_const (1, ""), NULL_TREE, NULL_TREE, tree_cons (NULL_TREE, tmp, NULL_TREE), NULL_TREE); ASM_VOLATILE_P (tmp) = 1; gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } static void trans_this_image (gfc_se * se, gfc_expr *expr) { stmtblock_t loop; tree type, desc, dim_arg, cond, tmp, m, loop_var, exit_label, min_var, lbound, ubound, extent, ml; gfc_se argse; int rank, corank; gfc_expr *distance = expr->value.function.actual->next->next->expr; if (expr->value.function.actual->expr && !gfc_is_coarray (expr->value.function.actual->expr)) distance = expr->value.function.actual->expr; /* The case -fcoarray=single is handled elsewhere. */ gcc_assert (flag_coarray != GFC_FCOARRAY_SINGLE); /* Argument-free version: THIS_IMAGE(). */ if (distance || expr->value.function.actual->expr == NULL) { if (distance) { gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, distance); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); tmp = fold_convert (integer_type_node, argse.expr); } else tmp = integer_zero_node; tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_this_image, 1, tmp); se->expr = fold_convert (gfc_get_int_type (gfc_default_integer_kind), tmp); return; } /* Coarray-argument version: THIS_IMAGE(coarray [, dim]). */ type = gfc_get_int_type (gfc_default_integer_kind); corank = gfc_get_corank (expr->value.function.actual->expr); rank = expr->value.function.actual->expr->rank; /* Obtain the descriptor of the COARRAY. */ gfc_init_se (&argse, NULL); argse.want_coarray = 1; gfc_conv_expr_descriptor (&argse, expr->value.function.actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = argse.expr; if (se->ss) { /* Create an implicit second parameter from the loop variable. */ gcc_assert (!expr->value.function.actual->next->expr); gcc_assert (corank > 0); gcc_assert (se->loop->dimen == 1); gcc_assert (se->ss->info->expr == expr); dim_arg = se->loop->loopvar[0]; dim_arg = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, dim_arg, build_int_cst (TREE_TYPE (dim_arg), 1)); gfc_advance_se_ss_chain (se); } else { /* Use the passed DIM= argument. */ gcc_assert (expr->value.function.actual->next->expr); gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, expr->value.function.actual->next->expr, gfc_array_index_type); gfc_add_block_to_block (&se->pre, &argse.pre); dim_arg = argse.expr; if (INTEGER_CST_P (dim_arg)) { if (wi::ltu_p (wi::to_wide (dim_arg), 1) || wi::gtu_p (wi::to_wide (dim_arg), GFC_TYPE_ARRAY_CORANK (TREE_TYPE (desc)))) gfc_error ("% argument of %s intrinsic at %L is not a valid " "dimension index", expr->value.function.isym->name, &expr->where); } else if (gfc_option.rtcheck & GFC_RTCHECK_BOUNDS) { dim_arg = gfc_evaluate_now (dim_arg, &se->pre); cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, dim_arg, build_int_cst (TREE_TYPE (dim_arg), 1)); tmp = gfc_rank_cst[GFC_TYPE_ARRAY_CORANK (TREE_TYPE (desc))]; tmp = fold_build2_loc (input_location, GT_EXPR, logical_type_node, dim_arg, tmp); cond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, cond, tmp); gfc_trans_runtime_check (true, false, cond, &se->pre, &expr->where, gfc_msg_fault); } } /* Used algorithm; cf. Fortran 2008, C.10. Note, due to the scalarizer, one always has a dim_arg argument. m = this_image() - 1 if (corank == 1) { sub(1) = m + lcobound(corank) return; } i = rank min_var = min (rank + corank - 2, rank + dim_arg - 1) for (;;) { extent = gfc_extent(i) ml = m m = m/extent if (i >= min_var) goto exit_label i++ } exit_label: sub(dim_arg) = (dim_arg < corank) ? ml - m*extent + lcobound(dim_arg) : m + lcobound(corank) */ /* this_image () - 1. */ tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_this_image, 1, integer_zero_node); tmp = fold_build2_loc (input_location, MINUS_EXPR, type, fold_convert (type, tmp), build_int_cst (type, 1)); if (corank == 1) { /* sub(1) = m + lcobound(corank). */ lbound = gfc_conv_descriptor_lbound_get (desc, build_int_cst (TREE_TYPE (gfc_array_index_type), corank+rank-1)); lbound = fold_convert (type, lbound); tmp = fold_build2_loc (input_location, PLUS_EXPR, type, tmp, lbound); se->expr = tmp; return; } m = gfc_create_var (type, NULL); ml = gfc_create_var (type, NULL); loop_var = gfc_create_var (integer_type_node, NULL); min_var = gfc_create_var (integer_type_node, NULL); /* m = this_image () - 1. */ gfc_add_modify (&se->pre, m, tmp); /* min_var = min (rank + corank-2, rank + dim_arg - 1). */ tmp = fold_build2_loc (input_location, PLUS_EXPR, integer_type_node, fold_convert (integer_type_node, dim_arg), build_int_cst (integer_type_node, rank - 1)); tmp = fold_build2_loc (input_location, MIN_EXPR, integer_type_node, build_int_cst (integer_type_node, rank + corank - 2), tmp); gfc_add_modify (&se->pre, min_var, tmp); /* i = rank. */ tmp = build_int_cst (integer_type_node, rank); gfc_add_modify (&se->pre, loop_var, tmp); exit_label = gfc_build_label_decl (NULL_TREE); TREE_USED (exit_label) = 1; /* Loop body. */ gfc_init_block (&loop); /* ml = m. */ gfc_add_modify (&loop, ml, m); /* extent = ... */ lbound = gfc_conv_descriptor_lbound_get (desc, loop_var); ubound = gfc_conv_descriptor_ubound_get (desc, loop_var); extent = gfc_conv_array_extent_dim (lbound, ubound, NULL); extent = fold_convert (type, extent); /* m = m/extent. */ gfc_add_modify (&loop, m, fold_build2_loc (input_location, TRUNC_DIV_EXPR, type, m, extent)); /* Exit condition: if (i >= min_var) goto exit_label. */ cond = fold_build2_loc (input_location, GE_EXPR, logical_type_node, loop_var, min_var); tmp = build1_v (GOTO_EXPR, exit_label); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&loop, tmp); /* Increment loop variable: i++. */ gfc_add_modify (&loop, loop_var, fold_build2_loc (input_location, PLUS_EXPR, integer_type_node, loop_var, build_int_cst (integer_type_node, 1))); /* Making the loop... actually loop! */ tmp = gfc_finish_block (&loop); tmp = build1_v (LOOP_EXPR, tmp); gfc_add_expr_to_block (&se->pre, tmp); /* The exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&se->pre, tmp); /* sub(co_dim) = (co_dim < corank) ? ml - m*extent + lcobound(dim_arg) : m + lcobound(corank) */ cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, dim_arg, build_int_cst (TREE_TYPE (dim_arg), corank)); lbound = gfc_conv_descriptor_lbound_get (desc, fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, dim_arg, build_int_cst (TREE_TYPE (dim_arg), rank-1))); lbound = fold_convert (type, lbound); tmp = fold_build2_loc (input_location, MINUS_EXPR, type, ml, fold_build2_loc (input_location, MULT_EXPR, type, m, extent)); tmp = fold_build2_loc (input_location, PLUS_EXPR, type, tmp, lbound); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, tmp, fold_build2_loc (input_location, PLUS_EXPR, type, m, lbound)); } /* Convert a call to image_status. */ static void conv_intrinsic_image_status (gfc_se *se, gfc_expr *expr) { unsigned int num_args; tree *args, tmp; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); /* In args[0] the number of the image the status is desired for has to be given. */ if (flag_coarray == GFC_FCOARRAY_SINGLE) { tree arg; arg = gfc_evaluate_now (args[0], &se->pre); tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, fold_convert (integer_type_node, arg), integer_one_node); tmp = fold_build3_loc (input_location, COND_EXPR, integer_type_node, tmp, integer_zero_node, build_int_cst (integer_type_node, GFC_STAT_STOPPED_IMAGE)); } else if (flag_coarray == GFC_FCOARRAY_LIB) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_image_status, 2, args[0], build_int_cst (integer_type_node, -1)); else gcc_unreachable (); se->expr = fold_convert (gfc_get_int_type (gfc_default_integer_kind), tmp); } static void conv_intrinsic_team_number (gfc_se *se, gfc_expr *expr) { unsigned int num_args; tree *args, tmp; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); if (flag_coarray == GFC_FCOARRAY_SINGLE && expr->value.function.actual->expr) { tree arg; arg = gfc_evaluate_now (args[0], &se->pre); tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, fold_convert (integer_type_node, arg), integer_one_node); tmp = fold_build3_loc (input_location, COND_EXPR, integer_type_node, tmp, integer_zero_node, build_int_cst (integer_type_node, GFC_STAT_STOPPED_IMAGE)); } else if (flag_coarray == GFC_FCOARRAY_SINGLE) { // the value -1 represents that no team has been created yet tmp = build_int_cst (integer_type_node, -1); } else if (flag_coarray == GFC_FCOARRAY_LIB && expr->value.function.actual->expr) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_team_number, 1, args[0], build_int_cst (integer_type_node, -1)); else if (flag_coarray == GFC_FCOARRAY_LIB) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_team_number, 1, integer_zero_node, build_int_cst (integer_type_node, -1)); else gcc_unreachable (); se->expr = fold_convert (gfc_get_int_type (gfc_default_integer_kind), tmp); } static void trans_image_index (gfc_se * se, gfc_expr *expr) { tree num_images, cond, coindex, type, lbound, ubound, desc, subdesc, tmp, invalid_bound; gfc_se argse, subse; int rank, corank, codim; type = gfc_get_int_type (gfc_default_integer_kind); corank = gfc_get_corank (expr->value.function.actual->expr); rank = expr->value.function.actual->expr->rank; /* Obtain the descriptor of the COARRAY. */ gfc_init_se (&argse, NULL); argse.want_coarray = 1; gfc_conv_expr_descriptor (&argse, expr->value.function.actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = argse.expr; /* Obtain a handle to the SUB argument. */ gfc_init_se (&subse, NULL); gfc_conv_expr_descriptor (&subse, expr->value.function.actual->next->expr); gfc_add_block_to_block (&se->pre, &subse.pre); gfc_add_block_to_block (&se->post, &subse.post); subdesc = build_fold_indirect_ref_loc (input_location, gfc_conv_descriptor_data_get (subse.expr)); /* Fortran 2008 does not require that the values remain in the cobounds, thus we need explicitly check this - and return 0 if they are exceeded. */ lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[rank+corank-1]); tmp = gfc_build_array_ref (subdesc, gfc_rank_cst[corank-1], NULL); invalid_bound = fold_build2_loc (input_location, LT_EXPR, logical_type_node, fold_convert (gfc_array_index_type, tmp), lbound); for (codim = corank + rank - 2; codim >= rank; codim--) { lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[codim]); ubound = gfc_conv_descriptor_ubound_get (desc, gfc_rank_cst[codim]); tmp = gfc_build_array_ref (subdesc, gfc_rank_cst[codim-rank], NULL); cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, fold_convert (gfc_array_index_type, tmp), lbound); invalid_bound = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, invalid_bound, cond); cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, fold_convert (gfc_array_index_type, tmp), ubound); invalid_bound = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, invalid_bound, cond); } invalid_bound = gfc_unlikely (invalid_bound, PRED_FORTRAN_INVALID_BOUND); /* See Fortran 2008, C.10 for the following algorithm. */ /* coindex = sub(corank) - lcobound(n). */ coindex = fold_convert (gfc_array_index_type, gfc_build_array_ref (subdesc, gfc_rank_cst[corank-1], NULL)); lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[rank+corank-1]); coindex = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, fold_convert (gfc_array_index_type, coindex), lbound); for (codim = corank + rank - 2; codim >= rank; codim--) { tree extent, ubound; /* coindex = coindex*extent(codim) + sub(codim) - lcobound(codim). */ lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[codim]); ubound = gfc_conv_descriptor_ubound_get (desc, gfc_rank_cst[codim]); extent = gfc_conv_array_extent_dim (lbound, ubound, NULL); /* coindex *= extent. */ coindex = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, coindex, extent); /* coindex += sub(codim). */ tmp = gfc_build_array_ref (subdesc, gfc_rank_cst[codim-rank], NULL); coindex = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, coindex, fold_convert (gfc_array_index_type, tmp)); /* coindex -= lbound(codim). */ lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[codim]); coindex = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, coindex, lbound); } coindex = fold_build2_loc (input_location, PLUS_EXPR, type, fold_convert(type, coindex), build_int_cst (type, 1)); /* Return 0 if "coindex" exceeds num_images(). */ if (flag_coarray == GFC_FCOARRAY_SINGLE) num_images = build_int_cst (type, 1); else { tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_num_images, 2, integer_zero_node, build_int_cst (integer_type_node, -1)); num_images = fold_convert (type, tmp); } tmp = gfc_create_var (type, NULL); gfc_add_modify (&se->pre, tmp, coindex); cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, tmp, num_images); cond = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, cond, fold_convert (logical_type_node, invalid_bound)); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, build_int_cst (type, 0), tmp); } static void trans_num_images (gfc_se * se, gfc_expr *expr) { tree tmp, distance, failed; gfc_se argse; if (expr->value.function.actual->expr) { gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, expr->value.function.actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); distance = fold_convert (integer_type_node, argse.expr); } else distance = integer_zero_node; if (expr->value.function.actual->next->expr) { gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, expr->value.function.actual->next->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); failed = fold_convert (integer_type_node, argse.expr); } else failed = build_int_cst (integer_type_node, -1); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_num_images, 2, distance, failed); se->expr = fold_convert (gfc_get_int_type (gfc_default_integer_kind), tmp); } static void gfc_conv_intrinsic_rank (gfc_se *se, gfc_expr *expr) { gfc_se argse; gfc_init_se (&argse, NULL); argse.data_not_needed = 1; argse.descriptor_only = 1; gfc_conv_expr_descriptor (&argse, expr->value.function.actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); se->expr = gfc_conv_descriptor_rank (argse.expr); se->expr = fold_convert (gfc_get_int_type (gfc_default_integer_kind), se->expr); } static void gfc_conv_intrinsic_is_contiguous (gfc_se * se, gfc_expr * expr) { gfc_expr *arg; arg = expr->value.function.actual->expr; gfc_conv_is_contiguous_expr (se, arg); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* This function does the work for gfc_conv_intrinsic_is_contiguous, plus it can be called directly. */ void gfc_conv_is_contiguous_expr (gfc_se *se, gfc_expr *arg) { gfc_ss *ss; gfc_se argse; tree desc, tmp, stride, extent, cond; int i; tree fncall0; gfc_array_spec *as; if (arg->ts.type == BT_CLASS) gfc_add_class_array_ref (arg); ss = gfc_walk_expr (arg); gcc_assert (ss != gfc_ss_terminator); gfc_init_se (&argse, NULL); argse.data_not_needed = 1; gfc_conv_expr_descriptor (&argse, arg); as = gfc_get_full_arrayspec_from_expr (arg); /* Create: stride[0] == 1 && stride[1] == extend[0]*stride[0] && ... Note in addition that zero-sized arrays don't count as contiguous. */ if (as && as->type == AS_ASSUMED_RANK) { /* Build the call to is_contiguous0. */ argse.want_pointer = 1; gfc_conv_expr_descriptor (&argse, arg); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = gfc_evaluate_now (argse.expr, &se->pre); fncall0 = build_call_expr_loc (input_location, gfor_fndecl_is_contiguous0, 1, desc); se->expr = fncall0; se->expr = convert (logical_type_node, se->expr); } else { gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = gfc_evaluate_now (argse.expr, &se->pre); stride = gfc_conv_descriptor_stride_get (desc, gfc_rank_cst[0]); cond = fold_build2_loc (input_location, EQ_EXPR, boolean_type_node, stride, build_int_cst (TREE_TYPE (stride), 1)); for (i = 0; i < arg->rank - 1; i++) { tmp = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[i]); extent = gfc_conv_descriptor_ubound_get (desc, gfc_rank_cst[i]); extent = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, extent, tmp); extent = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, extent, gfc_index_one_node); tmp = gfc_conv_descriptor_stride_get (desc, gfc_rank_cst[i]); tmp = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), tmp, extent); stride = gfc_conv_descriptor_stride_get (desc, gfc_rank_cst[i+1]); tmp = fold_build2_loc (input_location, EQ_EXPR, boolean_type_node, stride, tmp); cond = fold_build2_loc (input_location, TRUTH_AND_EXPR, boolean_type_node, cond, tmp); } se->expr = cond; } } /* Evaluate a single upper or lower bound. */ /* TODO: bound intrinsic generates way too much unnecessary code. */ static void gfc_conv_intrinsic_bound (gfc_se * se, gfc_expr * expr, enum gfc_isym_id op) { gfc_actual_arglist *arg; gfc_actual_arglist *arg2; tree desc; tree type; tree bound; tree tmp; tree cond, cond1; tree ubound; tree lbound; tree size; gfc_se argse; gfc_array_spec * as; bool assumed_rank_lb_one; arg = expr->value.function.actual; arg2 = arg->next; if (se->ss) { /* Create an implicit second parameter from the loop variable. */ gcc_assert (!arg2->expr || op == GFC_ISYM_SHAPE); gcc_assert (se->loop->dimen == 1); gcc_assert (se->ss->info->expr == expr); gfc_advance_se_ss_chain (se); bound = se->loop->loopvar[0]; bound = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, bound, se->loop->from[0]); } else { /* use the passed argument. */ gcc_assert (arg2->expr); gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, arg2->expr, gfc_array_index_type); gfc_add_block_to_block (&se->pre, &argse.pre); bound = argse.expr; /* Convert from one based to zero based. */ bound = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, bound, gfc_index_one_node); } /* TODO: don't re-evaluate the descriptor on each iteration. */ /* Get a descriptor for the first parameter. */ gfc_init_se (&argse, NULL); gfc_conv_expr_descriptor (&argse, arg->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = argse.expr; as = gfc_get_full_arrayspec_from_expr (arg->expr); if (INTEGER_CST_P (bound)) { gcc_assert (op != GFC_ISYM_SHAPE); if (((!as || as->type != AS_ASSUMED_RANK) && wi::geu_p (wi::to_wide (bound), GFC_TYPE_ARRAY_RANK (TREE_TYPE (desc)))) || wi::gtu_p (wi::to_wide (bound), GFC_MAX_DIMENSIONS)) gfc_error ("% argument of %s intrinsic at %L is not a valid " "dimension index", (op == GFC_ISYM_UBOUND) ? "UBOUND" : "LBOUND", &expr->where); } if (!INTEGER_CST_P (bound) || (as && as->type == AS_ASSUMED_RANK)) { if (gfc_option.rtcheck & GFC_RTCHECK_BOUNDS) { bound = gfc_evaluate_now (bound, &se->pre); cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, bound, build_int_cst (TREE_TYPE (bound), 0)); if (as && as->type == AS_ASSUMED_RANK) tmp = gfc_conv_descriptor_rank (desc); else tmp = gfc_rank_cst[GFC_TYPE_ARRAY_RANK (TREE_TYPE (desc))]; tmp = fold_build2_loc (input_location, GE_EXPR, logical_type_node, bound, fold_convert(TREE_TYPE (bound), tmp)); cond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, cond, tmp); gfc_trans_runtime_check (true, false, cond, &se->pre, &expr->where, gfc_msg_fault); } } /* Take care of the lbound shift for assumed-rank arrays that are nonallocatable and nonpointers. Those have a lbound of 1. */ assumed_rank_lb_one = as && as->type == AS_ASSUMED_RANK && ((arg->expr->ts.type != BT_CLASS && !arg->expr->symtree->n.sym->attr.allocatable && !arg->expr->symtree->n.sym->attr.pointer) || (arg->expr->ts.type == BT_CLASS && !CLASS_DATA (arg->expr)->attr.allocatable && !CLASS_DATA (arg->expr)->attr.class_pointer)); ubound = gfc_conv_descriptor_ubound_get (desc, bound); lbound = gfc_conv_descriptor_lbound_get (desc, bound); size = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, ubound, lbound); size = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, size, gfc_index_one_node); /* 13.14.53: Result value for LBOUND Case (i): For an array section or for an array expression other than a whole array or array structure component, LBOUND(ARRAY, DIM) has the value 1. For a whole array or array structure component, LBOUND(ARRAY, DIM) has the value: (a) equal to the lower bound for subscript DIM of ARRAY if dimension DIM of ARRAY does not have extent zero or if ARRAY is an assumed-size array of rank DIM, or (b) 1 otherwise. 13.14.113: Result value for UBOUND Case (i): For an array section or for an array expression other than a whole array or array structure component, UBOUND(ARRAY, DIM) has the value equal to the number of elements in the given dimension; otherwise, it has a value equal to the upper bound for subscript DIM of ARRAY if dimension DIM of ARRAY does not have size zero and has value zero if dimension DIM has size zero. */ if (op == GFC_ISYM_LBOUND && assumed_rank_lb_one) se->expr = gfc_index_one_node; else if (as) { if (op == GFC_ISYM_UBOUND) { cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, size, gfc_index_zero_node); se->expr = fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, cond, (assumed_rank_lb_one ? size : ubound), gfc_index_zero_node); } else if (op == GFC_ISYM_LBOUND) { cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, size, gfc_index_zero_node); if (as->type == AS_ASSUMED_SIZE) { cond1 = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, bound, build_int_cst (TREE_TYPE (bound), arg->expr->rank - 1)); cond = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, cond, cond1); } se->expr = fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, cond, lbound, gfc_index_one_node); } else if (op == GFC_ISYM_SHAPE) se->expr = size; else gcc_unreachable (); /* According to F2018 16.9.172, para 5, an assumed rank object, argument associated with and assumed size array, has the ubound of the final dimension set to -1 and UBOUND must return this. Similarly for the SHAPE intrinsic. */ if (op != GFC_ISYM_LBOUND && assumed_rank_lb_one) { tree minus_one = build_int_cst (gfc_array_index_type, -1); tree rank = fold_convert (gfc_array_index_type, gfc_conv_descriptor_rank (desc)); rank = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, rank, minus_one); /* Fix the expression to stop it from becoming even more complicated. */ se->expr = gfc_evaluate_now (se->expr, &se->pre); /* Descriptors for assumed-size arrays have ubound = -1 in the last dimension. */ cond1 = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, ubound, minus_one); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, bound, rank); cond = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, cond, cond1); se->expr = fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, cond, minus_one, se->expr); } } else /* as is null; this is an old-fashioned 1-based array. */ { if (op != GFC_ISYM_LBOUND) { se->expr = fold_build2_loc (input_location, MAX_EXPR, gfc_array_index_type, size, gfc_index_zero_node); } else se->expr = gfc_index_one_node; } type = gfc_typenode_for_spec (&expr->ts); se->expr = convert (type, se->expr); } static void conv_intrinsic_cobound (gfc_se * se, gfc_expr * expr) { gfc_actual_arglist *arg; gfc_actual_arglist *arg2; gfc_se argse; tree bound, resbound, resbound2, desc, cond, tmp; tree type; int corank; gcc_assert (expr->value.function.isym->id == GFC_ISYM_LCOBOUND || expr->value.function.isym->id == GFC_ISYM_UCOBOUND || expr->value.function.isym->id == GFC_ISYM_THIS_IMAGE); arg = expr->value.function.actual; arg2 = arg->next; gcc_assert (arg->expr->expr_type == EXPR_VARIABLE); corank = gfc_get_corank (arg->expr); gfc_init_se (&argse, NULL); argse.want_coarray = 1; gfc_conv_expr_descriptor (&argse, arg->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = argse.expr; if (se->ss) { /* Create an implicit second parameter from the loop variable. */ gcc_assert (!arg2->expr); gcc_assert (corank > 0); gcc_assert (se->loop->dimen == 1); gcc_assert (se->ss->info->expr == expr); bound = se->loop->loopvar[0]; bound = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, bound, gfc_rank_cst[arg->expr->rank]); gfc_advance_se_ss_chain (se); } else { /* use the passed argument. */ gcc_assert (arg2->expr); gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, arg2->expr, gfc_array_index_type); gfc_add_block_to_block (&se->pre, &argse.pre); bound = argse.expr; if (INTEGER_CST_P (bound)) { if (wi::ltu_p (wi::to_wide (bound), 1) || wi::gtu_p (wi::to_wide (bound), GFC_TYPE_ARRAY_CORANK (TREE_TYPE (desc)))) gfc_error ("% argument of %s intrinsic at %L is not a valid " "dimension index", expr->value.function.isym->name, &expr->where); } else if (gfc_option.rtcheck & GFC_RTCHECK_BOUNDS) { bound = gfc_evaluate_now (bound, &se->pre); cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, bound, build_int_cst (TREE_TYPE (bound), 1)); tmp = gfc_rank_cst[GFC_TYPE_ARRAY_CORANK (TREE_TYPE (desc))]; tmp = fold_build2_loc (input_location, GT_EXPR, logical_type_node, bound, tmp); cond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, cond, tmp); gfc_trans_runtime_check (true, false, cond, &se->pre, &expr->where, gfc_msg_fault); } /* Subtract 1 to get to zero based and add dimensions. */ switch (arg->expr->rank) { case 0: bound = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, bound, gfc_index_one_node); case 1: break; default: bound = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, bound, gfc_rank_cst[arg->expr->rank - 1]); } } resbound = gfc_conv_descriptor_lbound_get (desc, bound); /* Handle UCOBOUND with special handling of the last codimension. */ if (expr->value.function.isym->id == GFC_ISYM_UCOBOUND) { /* Last codimension: For -fcoarray=single just return the lcobound - otherwise add ceiling (real (num_images ()) / real (size)) - 1 = (num_images () + size - 1) / size - 1 = (num_images - 1) / size(), where size is the product of the extent of all but the last codimension. */ if (flag_coarray != GFC_FCOARRAY_SINGLE && corank > 1) { tree cosize; cosize = gfc_conv_descriptor_cosize (desc, arg->expr->rank, corank); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_num_images, 2, integer_zero_node, build_int_cst (integer_type_node, -1)); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, fold_convert (gfc_array_index_type, tmp), build_int_cst (gfc_array_index_type, 1)); tmp = fold_build2_loc (input_location, TRUNC_DIV_EXPR, gfc_array_index_type, tmp, fold_convert (gfc_array_index_type, cosize)); resbound = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, resbound, tmp); } else if (flag_coarray != GFC_FCOARRAY_SINGLE) { /* ubound = lbound + num_images() - 1. */ tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_num_images, 2, integer_zero_node, build_int_cst (integer_type_node, -1)); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, fold_convert (gfc_array_index_type, tmp), build_int_cst (gfc_array_index_type, 1)); resbound = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, resbound, tmp); } if (corank > 1) { cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, bound, build_int_cst (TREE_TYPE (bound), arg->expr->rank + corank - 1)); resbound2 = gfc_conv_descriptor_ubound_get (desc, bound); se->expr = fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, cond, resbound, resbound2); } else se->expr = resbound; } else se->expr = resbound; type = gfc_typenode_for_spec (&expr->ts); se->expr = convert (type, se->expr); } static void conv_intrinsic_stride (gfc_se * se, gfc_expr * expr) { gfc_actual_arglist *array_arg; gfc_actual_arglist *dim_arg; gfc_se argse; tree desc, tmp; array_arg = expr->value.function.actual; dim_arg = array_arg->next; gcc_assert (array_arg->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_descriptor (&argse, array_arg->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); desc = argse.expr; gcc_assert (dim_arg->expr); gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, dim_arg->expr, gfc_array_index_type); gfc_add_block_to_block (&se->pre, &argse.pre); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, argse.expr, gfc_index_one_node); se->expr = gfc_conv_descriptor_stride_get (desc, tmp); } static void gfc_conv_intrinsic_abs (gfc_se * se, gfc_expr * expr) { tree arg, cabs; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); switch (expr->value.function.actual->expr->ts.type) { case BT_INTEGER: case BT_REAL: se->expr = fold_build1_loc (input_location, ABS_EXPR, TREE_TYPE (arg), arg); break; case BT_COMPLEX: cabs = gfc_builtin_decl_for_float_kind (BUILT_IN_CABS, expr->ts.kind); se->expr = build_call_expr_loc (input_location, cabs, 1, arg); break; default: gcc_unreachable (); } } /* Create a complex value from one or two real components. */ static void gfc_conv_intrinsic_cmplx (gfc_se * se, gfc_expr * expr, int both) { tree real; tree imag; tree type; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, args, num_args); real = convert (TREE_TYPE (type), args[0]); if (both) imag = convert (TREE_TYPE (type), args[1]); else if (TREE_CODE (TREE_TYPE (args[0])) == COMPLEX_TYPE) { imag = fold_build1_loc (input_location, IMAGPART_EXPR, TREE_TYPE (TREE_TYPE (args[0])), args[0]); imag = convert (TREE_TYPE (type), imag); } else imag = build_real_from_int_cst (TREE_TYPE (type), integer_zero_node); se->expr = fold_build2_loc (input_location, COMPLEX_EXPR, type, real, imag); } /* Remainder function MOD(A, P) = A - INT(A / P) * P MODULO(A, P) = A - FLOOR (A / P) * P The obvious algorithms above are numerically instable for large arguments, hence these intrinsics are instead implemented via calls to the fmod family of functions. It is the responsibility of the user to ensure that the second argument is non-zero. */ static void gfc_conv_intrinsic_mod (gfc_se * se, gfc_expr * expr, int modulo) { tree type; tree tmp; tree test; tree test2; tree fmod; tree zero; tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); switch (expr->ts.type) { case BT_INTEGER: /* Integer case is easy, we've got a builtin op. */ type = TREE_TYPE (args[0]); if (modulo) se->expr = fold_build2_loc (input_location, FLOOR_MOD_EXPR, type, args[0], args[1]); else se->expr = fold_build2_loc (input_location, TRUNC_MOD_EXPR, type, args[0], args[1]); break; case BT_REAL: fmod = NULL_TREE; /* Check if we have a builtin fmod. */ fmod = gfc_builtin_decl_for_float_kind (BUILT_IN_FMOD, expr->ts.kind); /* The builtin should always be available. */ gcc_assert (fmod != NULL_TREE); tmp = build_addr (fmod); se->expr = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (fmod)), tmp, 2, args); if (modulo == 0) return; type = TREE_TYPE (args[0]); args[0] = gfc_evaluate_now (args[0], &se->pre); args[1] = gfc_evaluate_now (args[1], &se->pre); /* Definition: modulo = arg - floor (arg/arg2) * arg2 In order to calculate the result accurately, we use the fmod function as follows. res = fmod (arg, arg2); if (res) { if ((arg < 0) xor (arg2 < 0)) res += arg2; } else res = copysign (0., arg2); => As two nested ternary exprs: res = res ? (((arg < 0) xor (arg2 < 0)) ? res + arg2 : res) : copysign (0., arg2); */ zero = gfc_build_const (type, integer_zero_node); tmp = gfc_evaluate_now (se->expr, &se->pre); if (!flag_signed_zeros) { test = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[0], zero); test2 = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], zero); test2 = fold_build2_loc (input_location, TRUTH_XOR_EXPR, logical_type_node, test, test2); test = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, zero); test = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, test, test2); test = gfc_evaluate_now (test, &se->pre); se->expr = fold_build3_loc (input_location, COND_EXPR, type, test, fold_build2_loc (input_location, PLUS_EXPR, type, tmp, args[1]), tmp); } else { tree expr1, copysign, cscall; copysign = gfc_builtin_decl_for_float_kind (BUILT_IN_COPYSIGN, expr->ts.kind); test = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[0], zero); test2 = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], zero); test2 = fold_build2_loc (input_location, TRUTH_XOR_EXPR, logical_type_node, test, test2); expr1 = fold_build3_loc (input_location, COND_EXPR, type, test2, fold_build2_loc (input_location, PLUS_EXPR, type, tmp, args[1]), tmp); test = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, zero); cscall = build_call_expr_loc (input_location, copysign, 2, zero, args[1]); se->expr = fold_build3_loc (input_location, COND_EXPR, type, test, expr1, cscall); } return; default: gcc_unreachable (); } } /* DSHIFTL(I,J,S) = (I << S) | (J >> (BITSIZE(J) - S)) DSHIFTR(I,J,S) = (I << (BITSIZE(I) - S)) | (J >> S) where the right shifts are logical (i.e. 0's are shifted in). Because SHIFT_EXPR's want shifts strictly smaller than the integral type width, we have to special-case both S == 0 and S == BITSIZE(J): DSHIFTL(I,J,0) = I DSHIFTL(I,J,BITSIZE) = J DSHIFTR(I,J,0) = J DSHIFTR(I,J,BITSIZE) = I. */ static void gfc_conv_intrinsic_dshift (gfc_se * se, gfc_expr * expr, bool dshiftl) { tree type, utype, stype, arg1, arg2, shift, res, left, right; tree args[3], cond, tmp; int bitsize; gfc_conv_intrinsic_function_args (se, expr, args, 3); gcc_assert (TREE_TYPE (args[0]) == TREE_TYPE (args[1])); type = TREE_TYPE (args[0]); bitsize = TYPE_PRECISION (type); utype = unsigned_type_for (type); stype = TREE_TYPE (args[2]); arg1 = gfc_evaluate_now (args[0], &se->pre); arg2 = gfc_evaluate_now (args[1], &se->pre); shift = gfc_evaluate_now (args[2], &se->pre); /* The generic case. */ tmp = fold_build2_loc (input_location, MINUS_EXPR, stype, build_int_cst (stype, bitsize), shift); left = fold_build2_loc (input_location, LSHIFT_EXPR, type, arg1, dshiftl ? shift : tmp); right = fold_build2_loc (input_location, RSHIFT_EXPR, utype, fold_convert (utype, arg2), dshiftl ? tmp : shift); right = fold_convert (type, right); res = fold_build2_loc (input_location, BIT_IOR_EXPR, type, left, right); /* Special cases. */ cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, shift, build_int_cst (stype, 0)); res = fold_build3_loc (input_location, COND_EXPR, type, cond, dshiftl ? arg1 : arg2, res); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, shift, build_int_cst (stype, bitsize)); res = fold_build3_loc (input_location, COND_EXPR, type, cond, dshiftl ? arg2 : arg1, res); se->expr = res; } /* Positive difference DIM (x, y) = ((x - y) < 0) ? 0 : x - y. */ static void gfc_conv_intrinsic_dim (gfc_se * se, gfc_expr * expr) { tree val; tree tmp; tree type; tree zero; tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); type = TREE_TYPE (args[0]); val = fold_build2_loc (input_location, MINUS_EXPR, type, args[0], args[1]); val = gfc_evaluate_now (val, &se->pre); zero = gfc_build_const (type, integer_zero_node); tmp = fold_build2_loc (input_location, LE_EXPR, logical_type_node, val, zero); se->expr = fold_build3_loc (input_location, COND_EXPR, type, tmp, zero, val); } /* SIGN(A, B) is absolute value of A times sign of B. The real value versions use library functions to ensure the correct handling of negative zero. Integer case implemented as: SIGN(A, B) = { tmp = (A ^ B) >> C; (A + tmp) ^ tmp } */ static void gfc_conv_intrinsic_sign (gfc_se * se, gfc_expr * expr) { tree tmp; tree type; tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); if (expr->ts.type == BT_REAL) { tree abs; tmp = gfc_builtin_decl_for_float_kind (BUILT_IN_COPYSIGN, expr->ts.kind); abs = gfc_builtin_decl_for_float_kind (BUILT_IN_FABS, expr->ts.kind); /* We explicitly have to ignore the minus sign. We do so by using result = (arg1 == 0) ? abs(arg0) : copysign(arg0, arg1). */ if (!flag_sign_zero && MODE_HAS_SIGNED_ZEROS (TYPE_MODE (TREE_TYPE (args[1])))) { tree cond, zero; zero = build_real_from_int_cst (TREE_TYPE (args[1]), integer_zero_node); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, args[1], zero); se->expr = fold_build3_loc (input_location, COND_EXPR, TREE_TYPE (args[0]), cond, build_call_expr_loc (input_location, abs, 1, args[0]), build_call_expr_loc (input_location, tmp, 2, args[0], args[1])); } else se->expr = build_call_expr_loc (input_location, tmp, 2, args[0], args[1]); return; } /* Having excluded floating point types, we know we are now dealing with signed integer types. */ type = TREE_TYPE (args[0]); /* Args[0] is used multiple times below. */ args[0] = gfc_evaluate_now (args[0], &se->pre); /* Construct (A ^ B) >> 31, which generates a bit mask of all zeros if the signs of A and B are the same, and of all ones if they differ. */ tmp = fold_build2_loc (input_location, BIT_XOR_EXPR, type, args[0], args[1]); tmp = fold_build2_loc (input_location, RSHIFT_EXPR, type, tmp, build_int_cst (type, TYPE_PRECISION (type) - 1)); tmp = gfc_evaluate_now (tmp, &se->pre); /* Construct (A + tmp) ^ tmp, which is A if tmp is zero, and -A if tmp] is all ones (i.e. -1). */ se->expr = fold_build2_loc (input_location, BIT_XOR_EXPR, type, fold_build2_loc (input_location, PLUS_EXPR, type, args[0], tmp), tmp); } /* Test for the presence of an optional argument. */ static void gfc_conv_intrinsic_present (gfc_se * se, gfc_expr * expr) { gfc_expr *arg; arg = expr->value.function.actual->expr; gcc_assert (arg->expr_type == EXPR_VARIABLE); se->expr = gfc_conv_expr_present (arg->symtree->n.sym); se->expr = convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Calculate the double precision product of two single precision values. */ static void gfc_conv_intrinsic_dprod (gfc_se * se, gfc_expr * expr) { tree type; tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); /* Convert the args to double precision before multiplying. */ type = gfc_typenode_for_spec (&expr->ts); args[0] = convert (type, args[0]); args[1] = convert (type, args[1]); se->expr = fold_build2_loc (input_location, MULT_EXPR, type, args[0], args[1]); } /* Return a length one character string containing an ascii character. */ static void gfc_conv_intrinsic_char (gfc_se * se, gfc_expr * expr) { tree arg[2]; tree var; tree type; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr); gfc_conv_intrinsic_function_args (se, expr, arg, num_args); type = gfc_get_char_type (expr->ts.kind); var = gfc_create_var (type, "char"); arg[0] = fold_build1_loc (input_location, NOP_EXPR, type, arg[0]); gfc_add_modify (&se->pre, var, arg[0]); se->expr = gfc_build_addr_expr (build_pointer_type (type), var); se->string_length = build_int_cst (gfc_charlen_type_node, 1); } static void gfc_conv_intrinsic_ctime (gfc_se * se, gfc_expr * expr) { tree var; tree len; tree tmp; tree cond; tree fndecl; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr) + 2; args = XALLOCAVEC (tree, num_args); var = gfc_create_var (pchar_type_node, "pstr"); len = gfc_create_var (gfc_charlen_type_node, "len"); gfc_conv_intrinsic_function_args (se, expr, &args[2], num_args - 2); args[0] = gfc_build_addr_expr (NULL_TREE, var); args[1] = gfc_build_addr_expr (NULL_TREE, len); fndecl = build_addr (gfor_fndecl_ctime); tmp = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (gfor_fndecl_ctime)), fndecl, num_args, args); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards, if necessary. */ cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); tmp = gfc_call_free (var); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = len; } static void gfc_conv_intrinsic_fdate (gfc_se * se, gfc_expr * expr) { tree var; tree len; tree tmp; tree cond; tree fndecl; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr) + 2; args = XALLOCAVEC (tree, num_args); var = gfc_create_var (pchar_type_node, "pstr"); len = gfc_create_var (gfc_charlen_type_node, "len"); gfc_conv_intrinsic_function_args (se, expr, &args[2], num_args - 2); args[0] = gfc_build_addr_expr (NULL_TREE, var); args[1] = gfc_build_addr_expr (NULL_TREE, len); fndecl = build_addr (gfor_fndecl_fdate); tmp = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (gfor_fndecl_fdate)), fndecl, num_args, args); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards, if necessary. */ cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); tmp = gfc_call_free (var); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = len; } /* Generate a direct call to free() for the FREE subroutine. */ static tree conv_intrinsic_free (gfc_code *code) { stmtblock_t block; gfc_se argse; tree arg, call; gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, code->ext.actual->expr); arg = fold_convert (ptr_type_node, argse.expr); gfc_init_block (&block); call = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_FREE), 1, arg); gfc_add_expr_to_block (&block, call); return gfc_finish_block (&block); } /* Call the RANDOM_INIT library subroutine with a hidden argument for handling seeding on coarray images. */ static tree conv_intrinsic_random_init (gfc_code *code) { stmtblock_t block; gfc_se se; tree arg1, arg2, tmp; /* On none coarray == lib compiles use LOGICAL(4) else regular LOGICAL. */ tree used_bool_type_node = flag_coarray == GFC_FCOARRAY_LIB ? logical_type_node : gfc_get_logical_type (4); /* Make the function call. */ gfc_init_block (&block); gfc_init_se (&se, NULL); /* Convert REPEATABLE to the desired LOGICAL entity. */ gfc_conv_expr (&se, code->ext.actual->expr); gfc_add_block_to_block (&block, &se.pre); arg1 = fold_convert (used_bool_type_node, gfc_evaluate_now (se.expr, &block)); gfc_add_block_to_block (&block, &se.post); /* Convert IMAGE_DISTINCT to the desired LOGICAL entity. */ gfc_conv_expr (&se, code->ext.actual->next->expr); gfc_add_block_to_block (&block, &se.pre); arg2 = fold_convert (used_bool_type_node, gfc_evaluate_now (se.expr, &block)); gfc_add_block_to_block (&block, &se.post); if (flag_coarray == GFC_FCOARRAY_LIB) { tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_random_init, 2, arg1, arg2); } else { /* The ABI for libgfortran needs to be maintained, so a hidden argument must be include if code is compiled with -fcoarray=single or without the option. Set to 0. */ tree arg3 = build_int_cst (gfc_get_int_type (4), 0); tmp = build_call_expr_loc (input_location, gfor_fndecl_random_init, 3, arg1, arg2, arg3); } gfc_add_expr_to_block (&block, tmp); return gfc_finish_block (&block); } /* Call the SYSTEM_CLOCK library functions, handling the type and kind conversions. */ static tree conv_intrinsic_system_clock (gfc_code *code) { stmtblock_t block; gfc_se count_se, count_rate_se, count_max_se; tree arg1 = NULL_TREE, arg2 = NULL_TREE, arg3 = NULL_TREE; tree tmp; int least; gfc_expr *count = code->ext.actual->expr; gfc_expr *count_rate = code->ext.actual->next->expr; gfc_expr *count_max = code->ext.actual->next->next->expr; /* Evaluate our arguments. */ if (count) { gfc_init_se (&count_se, NULL); gfc_conv_expr (&count_se, count); } if (count_rate) { gfc_init_se (&count_rate_se, NULL); gfc_conv_expr (&count_rate_se, count_rate); } if (count_max) { gfc_init_se (&count_max_se, NULL); gfc_conv_expr (&count_max_se, count_max); } /* Find the smallest kind found of the arguments. */ least = 16; least = (count && count->ts.kind < least) ? count->ts.kind : least; least = (count_rate && count_rate->ts.kind < least) ? count_rate->ts.kind : least; least = (count_max && count_max->ts.kind < least) ? count_max->ts.kind : least; /* Prepare temporary variables. */ if (count) { if (least >= 8) arg1 = gfc_create_var (gfc_get_int_type (8), "count"); else if (least == 4) arg1 = gfc_create_var (gfc_get_int_type (4), "count"); else if (count->ts.kind == 1) arg1 = gfc_conv_mpz_to_tree (gfc_integer_kinds[0].pedantic_min_int, count->ts.kind); else arg1 = gfc_conv_mpz_to_tree (gfc_integer_kinds[1].pedantic_min_int, count->ts.kind); } if (count_rate) { if (least >= 8) arg2 = gfc_create_var (gfc_get_int_type (8), "count_rate"); else if (least == 4) arg2 = gfc_create_var (gfc_get_int_type (4), "count_rate"); else arg2 = integer_zero_node; } if (count_max) { if (least >= 8) arg3 = gfc_create_var (gfc_get_int_type (8), "count_max"); else if (least == 4) arg3 = gfc_create_var (gfc_get_int_type (4), "count_max"); else arg3 = integer_zero_node; } /* Make the function call. */ gfc_init_block (&block); if (least <= 2) { if (least == 1) { arg1 ? gfc_build_addr_expr (NULL_TREE, arg1) : null_pointer_node; arg2 ? gfc_build_addr_expr (NULL_TREE, arg2) : null_pointer_node; arg3 ? gfc_build_addr_expr (NULL_TREE, arg3) : null_pointer_node; } if (least == 2) { arg1 ? gfc_build_addr_expr (NULL_TREE, arg1) : null_pointer_node; arg2 ? gfc_build_addr_expr (NULL_TREE, arg2) : null_pointer_node; arg3 ? gfc_build_addr_expr (NULL_TREE, arg3) : null_pointer_node; } } else { if (least == 4) { tmp = build_call_expr_loc (input_location, gfor_fndecl_system_clock4, 3, arg1 ? gfc_build_addr_expr (NULL_TREE, arg1) : null_pointer_node, arg2 ? gfc_build_addr_expr (NULL_TREE, arg2) : null_pointer_node, arg3 ? gfc_build_addr_expr (NULL_TREE, arg3) : null_pointer_node); gfc_add_expr_to_block (&block, tmp); } /* Handle kind>=8, 10, or 16 arguments */ if (least >= 8) { tmp = build_call_expr_loc (input_location, gfor_fndecl_system_clock8, 3, arg1 ? gfc_build_addr_expr (NULL_TREE, arg1) : null_pointer_node, arg2 ? gfc_build_addr_expr (NULL_TREE, arg2) : null_pointer_node, arg3 ? gfc_build_addr_expr (NULL_TREE, arg3) : null_pointer_node); gfc_add_expr_to_block (&block, tmp); } } /* And store values back if needed. */ if (arg1 && arg1 != count_se.expr) gfc_add_modify (&block, count_se.expr, fold_convert (TREE_TYPE (count_se.expr), arg1)); if (arg2 && arg2 != count_rate_se.expr) gfc_add_modify (&block, count_rate_se.expr, fold_convert (TREE_TYPE (count_rate_se.expr), arg2)); if (arg3 && arg3 != count_max_se.expr) gfc_add_modify (&block, count_max_se.expr, fold_convert (TREE_TYPE (count_max_se.expr), arg3)); return gfc_finish_block (&block); } /* Return a character string containing the tty name. */ static void gfc_conv_intrinsic_ttynam (gfc_se * se, gfc_expr * expr) { tree var; tree len; tree tmp; tree cond; tree fndecl; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr) + 2; args = XALLOCAVEC (tree, num_args); var = gfc_create_var (pchar_type_node, "pstr"); len = gfc_create_var (gfc_charlen_type_node, "len"); gfc_conv_intrinsic_function_args (se, expr, &args[2], num_args - 2); args[0] = gfc_build_addr_expr (NULL_TREE, var); args[1] = gfc_build_addr_expr (NULL_TREE, len); fndecl = build_addr (gfor_fndecl_ttynam); tmp = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (gfor_fndecl_ttynam)), fndecl, num_args, args); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards, if necessary. */ cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); tmp = gfc_call_free (var); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = len; } /* Get the minimum/maximum value of all the parameters. minmax (a1, a2, a3, ...) { mvar = a1; mvar = COMP (mvar, a2) mvar = COMP (mvar, a3) ... return mvar; } Where COMP is MIN/MAX_EXPR for integral types or when we don't care about NaNs, or IFN_FMIN/MAX when the target has support for fast NaN-honouring min/max. When neither holds expand a sequence of explicit comparisons. */ /* TODO: Mismatching types can occur when specific names are used. These should be handled during resolution. */ static void gfc_conv_intrinsic_minmax (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree tmp; tree mvar; tree val; tree *args; tree type; tree argtype; gfc_actual_arglist *argexpr; unsigned int i, nargs; nargs = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, nargs); gfc_conv_intrinsic_function_args (se, expr, args, nargs); type = gfc_typenode_for_spec (&expr->ts); /* Only evaluate the argument once. */ if (!VAR_P (args[0]) && !TREE_CONSTANT (args[0])) args[0] = gfc_evaluate_now (args[0], &se->pre); /* Determine suitable type of temporary, as a GNU extension allows different argument kinds. */ argtype = TREE_TYPE (args[0]); argexpr = expr->value.function.actual; for (i = 1, argexpr = argexpr->next; i < nargs; i++, argexpr = argexpr->next) { tree tmptype = TREE_TYPE (args[i]); if (TYPE_PRECISION (tmptype) > TYPE_PRECISION (argtype)) argtype = tmptype; } mvar = gfc_create_var (argtype, "M"); gfc_add_modify (&se->pre, mvar, convert (argtype, args[0])); argexpr = expr->value.function.actual; for (i = 1, argexpr = argexpr->next; i < nargs; i++, argexpr = argexpr->next) { tree cond = NULL_TREE; val = args[i]; /* Handle absent optional arguments by ignoring the comparison. */ if (argexpr->expr->expr_type == EXPR_VARIABLE && argexpr->expr->symtree->n.sym->attr.optional && TREE_CODE (val) == INDIRECT_REF) { cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, TREE_OPERAND (val, 0), build_int_cst (TREE_TYPE (TREE_OPERAND (val, 0)), 0)); } else if (!VAR_P (val) && !TREE_CONSTANT (val)) /* Only evaluate the argument once. */ val = gfc_evaluate_now (val, &se->pre); tree calc; /* For floating point types, the question is what MAX(a, NaN) or MIN(a, NaN) should return (where "a" is a normal number). There are valid usecase for returning either one, but the Fortran standard doesn't specify which one should be chosen. Also, there is no consensus among other tested compilers. In short, it's a mess. So lets just do whatever is fastest. */ tree_code code = op == GT_EXPR ? MAX_EXPR : MIN_EXPR; calc = fold_build2_loc (input_location, code, argtype, convert (argtype, val), mvar); tmp = build2_v (MODIFY_EXPR, mvar, calc); if (cond != NULL_TREE) tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->pre, tmp); } se->expr = convert (type, mvar); } /* Generate library calls for MIN and MAX intrinsics for character variables. */ static void gfc_conv_intrinsic_minmax_char (gfc_se * se, gfc_expr * expr, int op) { tree *args; tree var, len, fndecl, tmp, cond, function; unsigned int nargs; nargs = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, nargs + 4); gfc_conv_intrinsic_function_args (se, expr, &args[4], nargs); /* Create the result variables. */ len = gfc_create_var (gfc_charlen_type_node, "len"); args[0] = gfc_build_addr_expr (NULL_TREE, len); var = gfc_create_var (gfc_get_pchar_type (expr->ts.kind), "pstr"); args[1] = gfc_build_addr_expr (ppvoid_type_node, var); args[2] = build_int_cst (integer_type_node, op); args[3] = build_int_cst (integer_type_node, nargs / 2); if (expr->ts.kind == 1) function = gfor_fndecl_string_minmax; else if (expr->ts.kind == 4) function = gfor_fndecl_string_minmax_char4; else gcc_unreachable (); /* Make the function call. */ fndecl = build_addr (function); tmp = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (function)), fndecl, nargs + 4, args); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards, if necessary. */ cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); tmp = gfc_call_free (var); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = len; } /* Create a symbol node for this intrinsic. The symbol from the frontend has the generic name. */ static gfc_symbol * gfc_get_symbol_for_expr (gfc_expr * expr, bool ignore_optional) { gfc_symbol *sym; /* TODO: Add symbols for intrinsic function to the global namespace. */ gcc_assert (strlen (expr->value.function.name) <= GFC_MAX_SYMBOL_LEN - 5); sym = gfc_new_symbol (expr->value.function.name, NULL); sym->ts = expr->ts; sym->attr.external = 1; sym->attr.function = 1; sym->attr.always_explicit = 1; sym->attr.proc = PROC_INTRINSIC; sym->attr.flavor = FL_PROCEDURE; sym->result = sym; if (expr->rank > 0) { sym->attr.dimension = 1; sym->as = gfc_get_array_spec (); sym->as->type = AS_ASSUMED_SHAPE; sym->as->rank = expr->rank; } gfc_copy_formal_args_intr (sym, expr->value.function.isym, ignore_optional ? expr->value.function.actual : NULL); return sym; } /* Remove empty actual arguments. */ static void remove_empty_actual_arguments (gfc_actual_arglist **ap) { while (*ap) { if ((*ap)->expr == NULL) { gfc_actual_arglist *r = *ap; *ap = r->next; r->next = NULL; gfc_free_actual_arglist (r); } else ap = &((*ap)->next); } } #define MAX_SPEC_ARG 12 /* Make up an fn spec that's right for intrinsic functions that we want to call. */ static char * intrinsic_fnspec (gfc_expr *expr) { static char fnspec_buf[MAX_SPEC_ARG*2+1]; char *fp; int i; int num_char_args; #define ADD_CHAR(c) do { *fp++ = c; *fp++ = ' '; } while(0) /* Set the fndecl. */ fp = fnspec_buf; /* Function return value. FIXME: Check if the second letter could be something other than a space, for further optimization. */ ADD_CHAR ('.'); if (expr->rank == 0) { if (expr->ts.type == BT_CHARACTER) { ADD_CHAR ('w'); /* Address of character. */ ADD_CHAR ('.'); /* Length of character. */ } } else ADD_CHAR ('w'); /* Return value is a descriptor. */ num_char_args = 0; for (gfc_actual_arglist *a = expr->value.function.actual; a; a = a->next) { if (a->expr == NULL) continue; if (a->name && strcmp (a->name,"%VAL") == 0) ADD_CHAR ('.'); else { if (a->expr->rank > 0) ADD_CHAR ('r'); else ADD_CHAR ('R'); } num_char_args += a->expr->ts.type == BT_CHARACTER; gcc_assert (fp - fnspec_buf + num_char_args <= MAX_SPEC_ARG*2); } for (i = 0; i < num_char_args; i++) ADD_CHAR ('.'); *fp = '\0'; return fnspec_buf; } #undef MAX_SPEC_ARG #undef ADD_CHAR /* Generate the right symbol for the specific intrinsic function and modify the expr accordingly. This assumes that absent optional arguments should be removed. */ gfc_symbol * specific_intrinsic_symbol (gfc_expr *expr) { gfc_symbol *sym; sym = gfc_find_intrinsic_symbol (expr); if (sym == NULL) { sym = gfc_get_intrinsic_function_symbol (expr); sym->ts = expr->ts; if (sym->ts.type == BT_CHARACTER && sym->ts.u.cl) sym->ts.u.cl = gfc_new_charlen (sym->ns, NULL); gfc_copy_formal_args_intr (sym, expr->value.function.isym, expr->value.function.actual, true); sym->backend_decl = gfc_get_extern_function_decl (sym, expr->value.function.actual, intrinsic_fnspec (expr)); } remove_empty_actual_arguments (&(expr->value.function.actual)); return sym; } /* Generate a call to an external intrinsic function. FIXME: So far, this only works for functions which are called with well-defined types; CSHIFT and friends will come later. */ static void gfc_conv_intrinsic_funcall (gfc_se * se, gfc_expr * expr) { gfc_symbol *sym; vec *append_args; bool specific_symbol; gcc_assert (!se->ss || se->ss->info->expr == expr); if (se->ss) gcc_assert (expr->rank > 0); else gcc_assert (expr->rank == 0); switch (expr->value.function.isym->id) { case GFC_ISYM_ANY: case GFC_ISYM_ALL: case GFC_ISYM_FINDLOC: case GFC_ISYM_MAXLOC: case GFC_ISYM_MINLOC: case GFC_ISYM_MAXVAL: case GFC_ISYM_MINVAL: case GFC_ISYM_NORM2: case GFC_ISYM_PRODUCT: case GFC_ISYM_SUM: specific_symbol = true; break; default: specific_symbol = false; } if (specific_symbol) { /* Need to copy here because specific_intrinsic_symbol modifies expr to omit the absent optional arguments. */ expr = gfc_copy_expr (expr); sym = specific_intrinsic_symbol (expr); } else sym = gfc_get_symbol_for_expr (expr, se->ignore_optional); /* Calls to libgfortran_matmul need to be appended special arguments, to be able to call the BLAS ?gemm functions if required and possible. */ append_args = NULL; if (expr->value.function.isym->id == GFC_ISYM_MATMUL && !expr->external_blas && sym->ts.type != BT_LOGICAL) { tree cint = gfc_get_int_type (gfc_c_int_kind); if (flag_external_blas && (sym->ts.type == BT_REAL || sym->ts.type == BT_COMPLEX) && (sym->ts.kind == 4 || sym->ts.kind == 8)) { tree gemm_fndecl; if (sym->ts.type == BT_REAL) { if (sym->ts.kind == 4) gemm_fndecl = gfor_fndecl_sgemm; else gemm_fndecl = gfor_fndecl_dgemm; } else { if (sym->ts.kind == 4) gemm_fndecl = gfor_fndecl_cgemm; else gemm_fndecl = gfor_fndecl_zgemm; } vec_alloc (append_args, 3); append_args->quick_push (build_int_cst (cint, 1)); append_args->quick_push (build_int_cst (cint, flag_blas_matmul_limit)); append_args->quick_push (gfc_build_addr_expr (NULL_TREE, gemm_fndecl)); } else { vec_alloc (append_args, 3); append_args->quick_push (build_int_cst (cint, 0)); append_args->quick_push (build_int_cst (cint, 0)); append_args->quick_push (null_pointer_node); } } gfc_conv_procedure_call (se, sym, expr->value.function.actual, expr, append_args); if (specific_symbol) gfc_free_expr (expr); else gfc_free_symbol (sym); } /* ANY and ALL intrinsics. ANY->op == NE_EXPR, ALL->op == EQ_EXPR. Implemented as any(a) { forall (i=...) if (a[i] != 0) return 1 end forall return 0 } all(a) { forall (i=...) if (a[i] == 0) return 0 end forall return 1 } */ static void gfc_conv_intrinsic_anyall (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree resvar; stmtblock_t block; stmtblock_t body; tree type; tree tmp; tree found; gfc_loopinfo loop; gfc_actual_arglist *actual; gfc_ss *arrayss; gfc_se arrayse; tree exit_label; if (se->ss) { gfc_conv_intrinsic_funcall (se, expr); return; } actual = expr->value.function.actual; type = gfc_typenode_for_spec (&expr->ts); /* Initialize the result. */ resvar = gfc_create_var (type, "test"); if (op == EQ_EXPR) tmp = convert (type, boolean_true_node); else tmp = convert (type, boolean_false_node); gfc_add_modify (&se->pre, resvar, tmp); /* Walk the arguments. */ arrayss = gfc_walk_expr (actual->expr); gcc_assert (arrayss != gfc_ss_terminator); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); exit_label = gfc_build_label_decl (NULL_TREE); TREE_USED (exit_label) = 1; gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); gfc_mark_ss_chain_used (arrayss, 1); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); /* If the condition matches then set the return value. */ gfc_start_block (&block); if (op == EQ_EXPR) tmp = convert (type, boolean_false_node); else tmp = convert (type, boolean_true_node); gfc_add_modify (&block, resvar, tmp); /* And break out of the loop. */ tmp = build1_v (GOTO_EXPR, exit_label); gfc_add_expr_to_block (&block, tmp); found = gfc_finish_block (&block); /* Check this element. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, actual->expr); gfc_add_block_to_block (&body, &arrayse.pre); tmp = fold_build2_loc (input_location, op, logical_type_node, arrayse.expr, build_int_cst (TREE_TYPE (arrayse.expr), 0)); tmp = build3_v (COND_EXPR, tmp, found, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); gfc_add_block_to_block (&body, &arrayse.post); gfc_trans_scalarizing_loops (&loop, &body); /* Add the exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&loop.pre, tmp); gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->pre, &loop.post); gfc_cleanup_loop (&loop); se->expr = resvar; } /* Generate the constant 180 / pi, which is used in the conversion of acosd(), asind(), atand(), atan2d(). */ static tree rad2deg (int kind) { tree retval; mpfr_t pi, t0; gfc_set_model_kind (kind); mpfr_init (pi); mpfr_init (t0); mpfr_set_si (t0, 180, GFC_RND_MODE); mpfr_const_pi (pi, GFC_RND_MODE); mpfr_div (t0, t0, pi, GFC_RND_MODE); retval = gfc_conv_mpfr_to_tree (t0, kind, 0); mpfr_clear (t0); mpfr_clear (pi); return retval; } static gfc_intrinsic_map_t * gfc_lookup_intrinsic (gfc_isym_id id) { gfc_intrinsic_map_t *m = gfc_intrinsic_map; for (; m->id != GFC_ISYM_NONE || m->double_built_in != END_BUILTINS; m++) if (id == m->id) break; gcc_assert (id == m->id); return m; } /* ACOSD(x) is translated into ACOS(x) * 180 / pi. ASIND(x) is translated into ASIN(x) * 180 / pi. ATAND(x) is translated into ATAN(x) * 180 / pi. */ static void gfc_conv_intrinsic_atrigd (gfc_se * se, gfc_expr * expr, gfc_isym_id id) { tree arg; tree atrigd; tree type; gfc_intrinsic_map_t *m; type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); switch (id) { case GFC_ISYM_ACOSD: m = gfc_lookup_intrinsic (GFC_ISYM_ACOS); break; case GFC_ISYM_ASIND: m = gfc_lookup_intrinsic (GFC_ISYM_ASIN); break; case GFC_ISYM_ATAND: m = gfc_lookup_intrinsic (GFC_ISYM_ATAN); break; default: gcc_unreachable (); } atrigd = gfc_get_intrinsic_lib_fndecl (m, expr); atrigd = build_call_expr_loc (input_location, atrigd, 1, arg); se->expr = fold_build2_loc (input_location, MULT_EXPR, type, atrigd, fold_convert (type, rad2deg (expr->ts.kind))); } /* COTAN(X) is translated into -TAN(X+PI/2) for REAL argument and COS(X) / SIN(X) for COMPLEX argument. */ static void gfc_conv_intrinsic_cotan (gfc_se *se, gfc_expr *expr) { gfc_intrinsic_map_t *m; tree arg; tree type; type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); if (expr->ts.type == BT_REAL) { tree tan; tree tmp; mpfr_t pio2; /* Create pi/2. */ gfc_set_model_kind (expr->ts.kind); mpfr_init (pio2); mpfr_const_pi (pio2, GFC_RND_MODE); mpfr_div_ui (pio2, pio2, 2, GFC_RND_MODE); tmp = gfc_conv_mpfr_to_tree (pio2, expr->ts.kind, 0); mpfr_clear (pio2); /* Find tan builtin function. */ m = gfc_lookup_intrinsic (GFC_ISYM_TAN); tan = gfc_get_intrinsic_lib_fndecl (m, expr); tmp = fold_build2_loc (input_location, PLUS_EXPR, type, arg, tmp); tan = build_call_expr_loc (input_location, tan, 1, tmp); se->expr = fold_build1_loc (input_location, NEGATE_EXPR, type, tan); } else { tree sin; tree cos; /* Find cos builtin function. */ m = gfc_lookup_intrinsic (GFC_ISYM_COS); cos = gfc_get_intrinsic_lib_fndecl (m, expr); cos = build_call_expr_loc (input_location, cos, 1, arg); /* Find sin builtin function. */ m = gfc_lookup_intrinsic (GFC_ISYM_SIN); sin = gfc_get_intrinsic_lib_fndecl (m, expr); sin = build_call_expr_loc (input_location, sin, 1, arg); /* Divide cos by sin. */ se->expr = fold_build2_loc (input_location, RDIV_EXPR, type, cos, sin); } } /* COTAND(X) is translated into -TAND(X+90) for REAL argument. */ static void gfc_conv_intrinsic_cotand (gfc_se *se, gfc_expr *expr) { tree arg; tree type; tree ninety_tree; mpfr_t ninety; type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); gfc_set_model_kind (expr->ts.kind); /* Build the tree for x + 90. */ mpfr_init_set_ui (ninety, 90, GFC_RND_MODE); ninety_tree = gfc_conv_mpfr_to_tree (ninety, expr->ts.kind, 0); arg = fold_build2_loc (input_location, PLUS_EXPR, type, arg, ninety_tree); mpfr_clear (ninety); /* Find tand. */ gfc_intrinsic_map_t *m = gfc_lookup_intrinsic (GFC_ISYM_TAND); tree tand = gfc_get_intrinsic_lib_fndecl (m, expr); tand = build_call_expr_loc (input_location, tand, 1, arg); se->expr = fold_build1_loc (input_location, NEGATE_EXPR, type, tand); } /* ATAN2D(Y,X) is translated into ATAN2(Y,X) * 180 / PI. */ static void gfc_conv_intrinsic_atan2d (gfc_se *se, gfc_expr *expr) { tree args[2]; tree atan2d; tree type; gfc_conv_intrinsic_function_args (se, expr, args, 2); type = TREE_TYPE (args[0]); gfc_intrinsic_map_t *m = gfc_lookup_intrinsic (GFC_ISYM_ATAN2); atan2d = gfc_get_intrinsic_lib_fndecl (m, expr); atan2d = build_call_expr_loc (input_location, atan2d, 2, args[0], args[1]); se->expr = fold_build2_loc (input_location, MULT_EXPR, type, atan2d, rad2deg (expr->ts.kind)); } /* COUNT(A) = Number of true elements in A. */ static void gfc_conv_intrinsic_count (gfc_se * se, gfc_expr * expr) { tree resvar; tree type; stmtblock_t body; tree tmp; gfc_loopinfo loop; gfc_actual_arglist *actual; gfc_ss *arrayss; gfc_se arrayse; if (se->ss) { gfc_conv_intrinsic_funcall (se, expr); return; } actual = expr->value.function.actual; type = gfc_typenode_for_spec (&expr->ts); /* Initialize the result. */ resvar = gfc_create_var (type, "count"); gfc_add_modify (&se->pre, resvar, build_int_cst (type, 0)); /* Walk the arguments. */ arrayss = gfc_walk_expr (actual->expr); gcc_assert (arrayss != gfc_ss_terminator); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); gfc_mark_ss_chain_used (arrayss, 1); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (resvar), resvar, build_int_cst (TREE_TYPE (resvar), 1)); tmp = build2_v (MODIFY_EXPR, resvar, tmp); gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, actual->expr); tmp = build3_v (COND_EXPR, arrayse.expr, tmp, build_empty_stmt (input_location)); gfc_add_block_to_block (&body, &arrayse.pre); gfc_add_expr_to_block (&body, tmp); gfc_add_block_to_block (&body, &arrayse.post); gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->pre, &loop.post); gfc_cleanup_loop (&loop); se->expr = resvar; } /* Update given gfc_se to have ss component pointing to the nested gfc_ss struct and return the corresponding loopinfo. */ static gfc_loopinfo * enter_nested_loop (gfc_se *se) { se->ss = se->ss->nested_ss; gcc_assert (se->ss == se->ss->loop->ss); return se->ss->loop; } /* Build the condition for a mask, which may be optional. */ static tree conv_mask_condition (gfc_se *maskse, gfc_expr *maskexpr, bool optional_mask) { tree present; tree type; if (optional_mask) { type = TREE_TYPE (maskse->expr); present = gfc_conv_expr_present (maskexpr->symtree->n.sym); present = convert (type, present); present = fold_build1_loc (input_location, TRUTH_NOT_EXPR, type, present); return fold_build2_loc (input_location, TRUTH_ORIF_EXPR, type, present, maskse->expr); } else return maskse->expr; } /* Inline implementation of the sum and product intrinsics. */ static void gfc_conv_intrinsic_arith (gfc_se * se, gfc_expr * expr, enum tree_code op, bool norm2) { tree resvar; tree scale = NULL_TREE; tree type; stmtblock_t body; stmtblock_t block; tree tmp; gfc_loopinfo loop, *ploop; gfc_actual_arglist *arg_array, *arg_mask; gfc_ss *arrayss = NULL; gfc_ss *maskss = NULL; gfc_se arrayse; gfc_se maskse; gfc_se *parent_se; gfc_expr *arrayexpr; gfc_expr *maskexpr; bool optional_mask; if (expr->rank > 0) { gcc_assert (gfc_inline_intrinsic_function_p (expr)); parent_se = se; } else parent_se = NULL; type = gfc_typenode_for_spec (&expr->ts); /* Initialize the result. */ resvar = gfc_create_var (type, "val"); if (norm2) { /* result = 0.0; scale = 1.0. */ scale = gfc_create_var (type, "scale"); gfc_add_modify (&se->pre, scale, gfc_build_const (type, integer_one_node)); tmp = gfc_build_const (type, integer_zero_node); } else if (op == PLUS_EXPR || op == BIT_IOR_EXPR || op == BIT_XOR_EXPR) tmp = gfc_build_const (type, integer_zero_node); else if (op == NE_EXPR) /* PARITY. */ tmp = convert (type, boolean_false_node); else if (op == BIT_AND_EXPR) tmp = gfc_build_const (type, fold_build1_loc (input_location, NEGATE_EXPR, type, integer_one_node)); else tmp = gfc_build_const (type, integer_one_node); gfc_add_modify (&se->pre, resvar, tmp); arg_array = expr->value.function.actual; arrayexpr = arg_array->expr; if (op == NE_EXPR || norm2) { /* PARITY and NORM2. */ maskexpr = NULL; optional_mask = false; } else { arg_mask = arg_array->next->next; gcc_assert (arg_mask != NULL); maskexpr = arg_mask->expr; optional_mask = maskexpr && maskexpr->expr_type == EXPR_VARIABLE && maskexpr->symtree->n.sym->attr.dummy && maskexpr->symtree->n.sym->attr.optional; } if (expr->rank == 0) { /* Walk the arguments. */ arrayss = gfc_walk_expr (arrayexpr); gcc_assert (arrayss != gfc_ss_terminator); if (maskexpr && maskexpr->rank > 0) { maskss = gfc_walk_expr (maskexpr); gcc_assert (maskss != gfc_ss_terminator); } else maskss = NULL; /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); /* We add the mask first because the number of iterations is taken from the last ss, and this breaks if an absent optional argument is used for mask. */ if (maskexpr && maskexpr->rank > 0) gfc_add_ss_to_loop (&loop, maskss); gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); if (maskexpr && maskexpr->rank > 0) gfc_mark_ss_chain_used (maskss, 1); gfc_mark_ss_chain_used (arrayss, 1); ploop = &loop; } else /* All the work has been done in the parent loops. */ ploop = enter_nested_loop (se); gcc_assert (ploop); /* Generate the loop body. */ gfc_start_scalarized_body (ploop, &body); /* If we have a mask, only add this element if the mask is set. */ if (maskexpr && maskexpr->rank > 0) { gfc_init_se (&maskse, parent_se); gfc_copy_loopinfo_to_se (&maskse, ploop); if (expr->rank == 0) maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); gfc_start_block (&block); } else gfc_init_block (&block); /* Do the actual summation/product. */ gfc_init_se (&arrayse, parent_se); gfc_copy_loopinfo_to_se (&arrayse, ploop); if (expr->rank == 0) arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, arrayexpr); gfc_add_block_to_block (&block, &arrayse.pre); if (norm2) { /* if (x (i) != 0.0) { absX = abs(x(i)) if (absX > scale) { val = scale/absX; result = 1.0 + result * val * val; scale = absX; } else { val = absX/scale; result += val * val; } } */ tree res1, res2, cond, absX, val; stmtblock_t ifblock1, ifblock2, ifblock3; gfc_init_block (&ifblock1); absX = gfc_create_var (type, "absX"); gfc_add_modify (&ifblock1, absX, fold_build1_loc (input_location, ABS_EXPR, type, arrayse.expr)); val = gfc_create_var (type, "val"); gfc_add_expr_to_block (&ifblock1, val); gfc_init_block (&ifblock2); gfc_add_modify (&ifblock2, val, fold_build2_loc (input_location, RDIV_EXPR, type, scale, absX)); res1 = fold_build2_loc (input_location, MULT_EXPR, type, val, val); res1 = fold_build2_loc (input_location, MULT_EXPR, type, resvar, res1); res1 = fold_build2_loc (input_location, PLUS_EXPR, type, res1, gfc_build_const (type, integer_one_node)); gfc_add_modify (&ifblock2, resvar, res1); gfc_add_modify (&ifblock2, scale, absX); res1 = gfc_finish_block (&ifblock2); gfc_init_block (&ifblock3); gfc_add_modify (&ifblock3, val, fold_build2_loc (input_location, RDIV_EXPR, type, absX, scale)); res2 = fold_build2_loc (input_location, MULT_EXPR, type, val, val); res2 = fold_build2_loc (input_location, PLUS_EXPR, type, resvar, res2); gfc_add_modify (&ifblock3, resvar, res2); res2 = gfc_finish_block (&ifblock3); cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, absX, scale); tmp = build3_v (COND_EXPR, cond, res1, res2); gfc_add_expr_to_block (&ifblock1, tmp); tmp = gfc_finish_block (&ifblock1); cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, arrayse.expr, gfc_build_const (type, integer_zero_node)); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } else { tmp = fold_build2_loc (input_location, op, type, resvar, arrayse.expr); gfc_add_modify (&block, resvar, tmp); } gfc_add_block_to_block (&block, &arrayse.post); if (maskexpr && maskexpr->rank > 0) { /* We enclose the above in if (mask) {...} . If the mask is an optional argument, generate IF (.NOT. PRESENT(MASK) .OR. MASK(I)). */ tree ifmask; tmp = gfc_finish_block (&block); ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } else tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&body, tmp); gfc_trans_scalarizing_loops (ploop, &body); /* For a scalar mask, enclose the loop in an if statement. */ if (maskexpr && maskexpr->rank == 0) { gfc_init_block (&block); gfc_add_block_to_block (&block, &ploop->pre); gfc_add_block_to_block (&block, &ploop->post); tmp = gfc_finish_block (&block); if (expr->rank > 0) { tmp = build3_v (COND_EXPR, se->ss->info->data.scalar.value, tmp, build_empty_stmt (input_location)); gfc_advance_se_ss_chain (se); } else { tree ifmask; gcc_assert (expr->rank == 0); gfc_init_se (&maskse, NULL); gfc_conv_expr_val (&maskse, maskexpr); ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&se->pre, &block); gcc_assert (se->post.head == NULL); } else { gfc_add_block_to_block (&se->pre, &ploop->pre); gfc_add_block_to_block (&se->pre, &ploop->post); } if (expr->rank == 0) gfc_cleanup_loop (ploop); if (norm2) { /* result = scale * sqrt(result). */ tree sqrt; sqrt = gfc_builtin_decl_for_float_kind (BUILT_IN_SQRT, expr->ts.kind); resvar = build_call_expr_loc (input_location, sqrt, 1, resvar); resvar = fold_build2_loc (input_location, MULT_EXPR, type, scale, resvar); } se->expr = resvar; } /* Inline implementation of the dot_product intrinsic. This function is based on gfc_conv_intrinsic_arith (the previous function). */ static void gfc_conv_intrinsic_dot_product (gfc_se * se, gfc_expr * expr) { tree resvar; tree type; stmtblock_t body; stmtblock_t block; tree tmp; gfc_loopinfo loop; gfc_actual_arglist *actual; gfc_ss *arrayss1, *arrayss2; gfc_se arrayse1, arrayse2; gfc_expr *arrayexpr1, *arrayexpr2; type = gfc_typenode_for_spec (&expr->ts); /* Initialize the result. */ resvar = gfc_create_var (type, "val"); if (expr->ts.type == BT_LOGICAL) tmp = build_int_cst (type, 0); else tmp = gfc_build_const (type, integer_zero_node); gfc_add_modify (&se->pre, resvar, tmp); /* Walk argument #1. */ actual = expr->value.function.actual; arrayexpr1 = actual->expr; arrayss1 = gfc_walk_expr (arrayexpr1); gcc_assert (arrayss1 != gfc_ss_terminator); /* Walk argument #2. */ actual = actual->next; arrayexpr2 = actual->expr; arrayss2 = gfc_walk_expr (arrayexpr2); gcc_assert (arrayss2 != gfc_ss_terminator); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, arrayss1); gfc_add_ss_to_loop (&loop, arrayss2); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); gfc_mark_ss_chain_used (arrayss1, 1); gfc_mark_ss_chain_used (arrayss2, 1); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); gfc_init_block (&block); /* Make the tree expression for [conjg(]array1[)]. */ gfc_init_se (&arrayse1, NULL); gfc_copy_loopinfo_to_se (&arrayse1, &loop); arrayse1.ss = arrayss1; gfc_conv_expr_val (&arrayse1, arrayexpr1); if (expr->ts.type == BT_COMPLEX) arrayse1.expr = fold_build1_loc (input_location, CONJ_EXPR, type, arrayse1.expr); gfc_add_block_to_block (&block, &arrayse1.pre); /* Make the tree expression for array2. */ gfc_init_se (&arrayse2, NULL); gfc_copy_loopinfo_to_se (&arrayse2, &loop); arrayse2.ss = arrayss2; gfc_conv_expr_val (&arrayse2, arrayexpr2); gfc_add_block_to_block (&block, &arrayse2.pre); /* Do the actual product and sum. */ if (expr->ts.type == BT_LOGICAL) { tmp = fold_build2_loc (input_location, TRUTH_AND_EXPR, type, arrayse1.expr, arrayse2.expr); tmp = fold_build2_loc (input_location, TRUTH_OR_EXPR, type, resvar, tmp); } else { tmp = fold_build2_loc (input_location, MULT_EXPR, type, arrayse1.expr, arrayse2.expr); tmp = fold_build2_loc (input_location, PLUS_EXPR, type, resvar, tmp); } gfc_add_modify (&block, resvar, tmp); /* Finish up the loop block and the loop. */ tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&body, tmp); gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->pre, &loop.post); gfc_cleanup_loop (&loop); se->expr = resvar; } /* Remove unneeded kind= argument from actual argument list when the result conversion is dealt with in a different place. */ static void strip_kind_from_actual (gfc_actual_arglist * actual) { for (gfc_actual_arglist *a = actual; a; a = a->next) { if (a && a->name && strcmp (a->name, "kind") == 0) { gfc_free_expr (a->expr); a->expr = NULL; } } } /* Emit code for minloc or maxloc intrinsic. There are many different cases we need to handle. For performance reasons we sometimes create two loops instead of one, where the second one is much simpler. Examples for minloc intrinsic: 1) Result is an array, a call is generated 2) Array mask is used and NaNs need to be supported: limit = Infinity; pos = 0; S = from; while (S <= to) { if (mask[S]) { if (pos == 0) pos = S + (1 - from); if (a[S] <= limit) { limit = a[S]; pos = S + (1 - from); goto lab1; } } S++; } goto lab2; lab1:; while (S <= to) { if (mask[S]) if (a[S] < limit) { limit = a[S]; pos = S + (1 - from); } S++; } lab2:; 3) NaNs need to be supported, but it is known at compile time or cheaply at runtime whether array is nonempty or not: limit = Infinity; pos = 0; S = from; while (S <= to) { if (a[S] <= limit) { limit = a[S]; pos = S + (1 - from); goto lab1; } S++; } if (from <= to) pos = 1; goto lab2; lab1:; while (S <= to) { if (a[S] < limit) { limit = a[S]; pos = S + (1 - from); } S++; } lab2:; 4) NaNs aren't supported, array mask is used: limit = infinities_supported ? Infinity : huge (limit); pos = 0; S = from; while (S <= to) { if (mask[S]) { limit = a[S]; pos = S + (1 - from); goto lab1; } S++; } goto lab2; lab1:; while (S <= to) { if (mask[S]) if (a[S] < limit) { limit = a[S]; pos = S + (1 - from); } S++; } lab2:; 5) Same without array mask: limit = infinities_supported ? Infinity : huge (limit); pos = (from <= to) ? 1 : 0; S = from; while (S <= to) { if (a[S] < limit) { limit = a[S]; pos = S + (1 - from); } S++; } For 3) and 5), if mask is scalar, this all goes into a conditional, setting pos = 0; in the else branch. Since we now also support the BACK argument, instead of using if (a[S] < limit), we now use if (back) cond = a[S] <= limit; else cond = a[S] < limit; if (cond) { .... The optimizer is smart enough to move the condition out of the loop. The are now marked as unlikely to for further speedup. */ static void gfc_conv_intrinsic_minmaxloc (gfc_se * se, gfc_expr * expr, enum tree_code op) { stmtblock_t body; stmtblock_t block; stmtblock_t ifblock; stmtblock_t elseblock; tree limit; tree type; tree tmp; tree cond; tree elsetmp; tree ifbody; tree offset; tree nonempty; tree lab1, lab2; tree b_if, b_else; gfc_loopinfo loop; gfc_actual_arglist *actual; gfc_ss *arrayss; gfc_ss *maskss; gfc_se arrayse; gfc_se maskse; gfc_expr *arrayexpr; gfc_expr *maskexpr; gfc_expr *backexpr; gfc_se backse; tree pos; int n; bool optional_mask; actual = expr->value.function.actual; /* The last argument, BACK, is passed by value. Ensure that by setting its name to %VAL. */ for (gfc_actual_arglist *a = actual; a; a = a->next) { if (a->next == NULL) a->name = "%VAL"; } if (se->ss) { gfc_conv_intrinsic_funcall (se, expr); return; } arrayexpr = actual->expr; /* Special case for character maxloc. Remove unneeded actual arguments, then call a library function. */ if (arrayexpr->ts.type == BT_CHARACTER) { gfc_actual_arglist *a; a = actual; strip_kind_from_actual (a); while (a) { if (a->name && strcmp (a->name, "dim") == 0) { gfc_free_expr (a->expr); a->expr = NULL; } a = a->next; } gfc_conv_intrinsic_funcall (se, expr); return; } /* Initialize the result. */ pos = gfc_create_var (gfc_array_index_type, "pos"); offset = gfc_create_var (gfc_array_index_type, "offset"); type = gfc_typenode_for_spec (&expr->ts); /* Walk the arguments. */ arrayss = gfc_walk_expr (arrayexpr); gcc_assert (arrayss != gfc_ss_terminator); actual = actual->next->next; gcc_assert (actual); maskexpr = actual->expr; optional_mask = maskexpr && maskexpr->expr_type == EXPR_VARIABLE && maskexpr->symtree->n.sym->attr.dummy && maskexpr->symtree->n.sym->attr.optional; backexpr = actual->next->next->expr; nonempty = NULL; if (maskexpr && maskexpr->rank != 0) { maskss = gfc_walk_expr (maskexpr); gcc_assert (maskss != gfc_ss_terminator); } else { mpz_t asize; if (gfc_array_size (arrayexpr, &asize)) { nonempty = gfc_conv_mpz_to_tree (asize, gfc_index_integer_kind); mpz_clear (asize); nonempty = fold_build2_loc (input_location, GT_EXPR, logical_type_node, nonempty, gfc_index_zero_node); } maskss = NULL; } limit = gfc_create_var (gfc_typenode_for_spec (&arrayexpr->ts), "limit"); switch (arrayexpr->ts.type) { case BT_REAL: tmp = gfc_build_inf_or_huge (TREE_TYPE (limit), arrayexpr->ts.kind); break; case BT_INTEGER: n = gfc_validate_kind (arrayexpr->ts.type, arrayexpr->ts.kind, false); tmp = gfc_conv_mpz_to_tree (gfc_integer_kinds[n].huge, arrayexpr->ts.kind); break; default: gcc_unreachable (); } /* We start with the most negative possible value for MAXLOC, and the most positive possible value for MINLOC. The most negative possible value is -HUGE for BT_REAL and (-HUGE - 1) for BT_INTEGER; the most positive possible value is HUGE in both cases. */ if (op == GT_EXPR) tmp = fold_build1_loc (input_location, NEGATE_EXPR, TREE_TYPE (tmp), tmp); if (op == GT_EXPR && arrayexpr->ts.type == BT_INTEGER) tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (tmp), tmp, build_int_cst (TREE_TYPE (tmp), 1)); gfc_add_modify (&se->pre, limit, tmp); /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); /* We add the mask first because the number of iterations is taken from the last ss, and this breaks if an absent optional argument is used for mask. */ if (maskss) gfc_add_ss_to_loop (&loop, maskss); gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); /* The code generated can have more than one loop in sequence (see the comment at the function header). This doesn't work well with the scalarizer, which changes arrays' offset when the scalarization loops are generated (see gfc_trans_preloop_setup). Fortunately, {min,max}loc are currently inlined in the scalar case only (for which loop is of rank one). As there is no dependency to care about in that case, there is no temporary, so that we can use the scalarizer temporary code to handle multiple loops. Thus, we set temp_dim here, we call gfc_mark_ss_chain_used with flag=3 later, and we use gfc_trans_scalarized_loop_boundary even later to restore offset. TODO: this prevents inlining of rank > 0 minmaxloc calls, so this should eventually go away. We could either create two loops properly, or find another way to save/restore the array offsets between the two loops (without conflicting with temporary management), or use a single loop minmaxloc implementation. See PR 31067. */ loop.temp_dim = loop.dimen; gfc_conv_loop_setup (&loop, &expr->where); gcc_assert (loop.dimen == 1); if (nonempty == NULL && maskss == NULL && loop.from[0] && loop.to[0]) nonempty = fold_build2_loc (input_location, LE_EXPR, logical_type_node, loop.from[0], loop.to[0]); lab1 = NULL; lab2 = NULL; /* Initialize the position to zero, following Fortran 2003. We are free to do this because Fortran 95 allows the result of an entirely false mask to be processor dependent. If we know at compile time the array is non-empty and no MASK is used, we can initialize to 1 to simplify the inner loop. */ if (nonempty != NULL && !HONOR_NANS (DECL_MODE (limit))) gfc_add_modify (&loop.pre, pos, fold_build3_loc (input_location, COND_EXPR, gfc_array_index_type, nonempty, gfc_index_one_node, gfc_index_zero_node)); else { gfc_add_modify (&loop.pre, pos, gfc_index_zero_node); lab1 = gfc_build_label_decl (NULL_TREE); TREE_USED (lab1) = 1; lab2 = gfc_build_label_decl (NULL_TREE); TREE_USED (lab2) = 1; } /* An offset must be added to the loop counter to obtain the required position. */ gcc_assert (loop.from[0]); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, loop.from[0]); gfc_add_modify (&loop.pre, offset, tmp); gfc_mark_ss_chain_used (arrayss, lab1 ? 3 : 1); if (maskss) gfc_mark_ss_chain_used (maskss, lab1 ? 3 : 1); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); /* If we have a mask, only check this element if the mask is set. */ if (maskss) { gfc_init_se (&maskse, NULL); gfc_copy_loopinfo_to_se (&maskse, &loop); maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); gfc_start_block (&block); } else gfc_init_block (&block); /* Compare with the current limit. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, arrayexpr); gfc_add_block_to_block (&block, &arrayse.pre); gfc_init_se (&backse, NULL); gfc_conv_expr_val (&backse, backexpr); gfc_add_block_to_block (&block, &backse.pre); /* We do the following if this is a more extreme value. */ gfc_start_block (&ifblock); /* Assign the value to the limit... */ gfc_add_modify (&ifblock, limit, arrayse.expr); if (nonempty == NULL && HONOR_NANS (DECL_MODE (limit))) { stmtblock_t ifblock2; tree ifbody2; gfc_start_block (&ifblock2); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (pos), loop.loopvar[0], offset); gfc_add_modify (&ifblock2, pos, tmp); ifbody2 = gfc_finish_block (&ifblock2); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, pos, gfc_index_zero_node); tmp = build3_v (COND_EXPR, cond, ifbody2, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (pos), loop.loopvar[0], offset); gfc_add_modify (&ifblock, pos, tmp); if (lab1) gfc_add_expr_to_block (&ifblock, build1_v (GOTO_EXPR, lab1)); ifbody = gfc_finish_block (&ifblock); if (!lab1 || HONOR_NANS (DECL_MODE (limit))) { if (lab1) cond = fold_build2_loc (input_location, op == GT_EXPR ? GE_EXPR : LE_EXPR, logical_type_node, arrayse.expr, limit); else { tree ifbody2, elsebody2; /* We switch to > or >= depending on the value of the BACK argument. */ cond = gfc_create_var (logical_type_node, "cond"); gfc_start_block (&ifblock); b_if = fold_build2_loc (input_location, op == GT_EXPR ? GE_EXPR : LE_EXPR, logical_type_node, arrayse.expr, limit); gfc_add_modify (&ifblock, cond, b_if); ifbody2 = gfc_finish_block (&ifblock); gfc_start_block (&elseblock); b_else = fold_build2_loc (input_location, op, logical_type_node, arrayse.expr, limit); gfc_add_modify (&elseblock, cond, b_else); elsebody2 = gfc_finish_block (&elseblock); tmp = fold_build3_loc (input_location, COND_EXPR, logical_type_node, backse.expr, ifbody2, elsebody2); gfc_add_expr_to_block (&block, tmp); } cond = gfc_unlikely (cond, PRED_BUILTIN_EXPECT); ifbody = build3_v (COND_EXPR, cond, ifbody, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&block, ifbody); if (maskss) { /* We enclose the above in if (mask) {...}. If the mask is an optional argument, generate IF (.NOT. PRESENT(MASK) .OR. MASK(I)). */ tree ifmask; ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = gfc_finish_block (&block); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } else tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&body, tmp); if (lab1) { gfc_trans_scalarized_loop_boundary (&loop, &body); if (HONOR_NANS (DECL_MODE (limit))) { if (nonempty != NULL) { ifbody = build2_v (MODIFY_EXPR, pos, gfc_index_one_node); tmp = build3_v (COND_EXPR, nonempty, ifbody, build_empty_stmt (input_location)); gfc_add_expr_to_block (&loop.code[0], tmp); } } gfc_add_expr_to_block (&loop.code[0], build1_v (GOTO_EXPR, lab2)); gfc_add_expr_to_block (&loop.code[0], build1_v (LABEL_EXPR, lab1)); /* If we have a mask, only check this element if the mask is set. */ if (maskss) { gfc_init_se (&maskse, NULL); gfc_copy_loopinfo_to_se (&maskse, &loop); maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); gfc_start_block (&block); } else gfc_init_block (&block); /* Compare with the current limit. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, arrayexpr); gfc_add_block_to_block (&block, &arrayse.pre); /* We do the following if this is a more extreme value. */ gfc_start_block (&ifblock); /* Assign the value to the limit... */ gfc_add_modify (&ifblock, limit, arrayse.expr); tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (pos), loop.loopvar[0], offset); gfc_add_modify (&ifblock, pos, tmp); ifbody = gfc_finish_block (&ifblock); /* We switch to > or >= depending on the value of the BACK argument. */ { tree ifbody2, elsebody2; cond = gfc_create_var (logical_type_node, "cond"); gfc_start_block (&ifblock); b_if = fold_build2_loc (input_location, op == GT_EXPR ? GE_EXPR : LE_EXPR, logical_type_node, arrayse.expr, limit); gfc_add_modify (&ifblock, cond, b_if); ifbody2 = gfc_finish_block (&ifblock); gfc_start_block (&elseblock); b_else = fold_build2_loc (input_location, op, logical_type_node, arrayse.expr, limit); gfc_add_modify (&elseblock, cond, b_else); elsebody2 = gfc_finish_block (&elseblock); tmp = fold_build3_loc (input_location, COND_EXPR, logical_type_node, backse.expr, ifbody2, elsebody2); } gfc_add_expr_to_block (&block, tmp); cond = gfc_unlikely (cond, PRED_BUILTIN_EXPECT); tmp = build3_v (COND_EXPR, cond, ifbody, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); if (maskss) { /* We enclose the above in if (mask) {...}. If the mask is an optional argument, generate IF (.NOT. PRESENT(MASK) .OR. MASK(I)).*/ tree ifmask; ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = gfc_finish_block (&block); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } else tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&body, tmp); /* Avoid initializing loopvar[0] again, it should be left where it finished by the first loop. */ loop.from[0] = loop.loopvar[0]; } gfc_trans_scalarizing_loops (&loop, &body); if (lab2) gfc_add_expr_to_block (&loop.pre, build1_v (LABEL_EXPR, lab2)); /* For a scalar mask, enclose the loop in an if statement. */ if (maskexpr && maskss == NULL) { tree ifmask; gfc_init_se (&maskse, NULL); gfc_conv_expr_val (&maskse, maskexpr); gfc_init_block (&block); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); tmp = gfc_finish_block (&block); /* For the else part of the scalar mask, just initialize the pos variable the same way as above. */ gfc_init_block (&elseblock); gfc_add_modify (&elseblock, pos, gfc_index_zero_node); elsetmp = gfc_finish_block (&elseblock); ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, elsetmp); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&se->pre, &block); } else { gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->pre, &loop.post); } gfc_cleanup_loop (&loop); se->expr = convert (type, pos); } /* Emit code for findloc. */ static void gfc_conv_intrinsic_findloc (gfc_se *se, gfc_expr *expr) { gfc_actual_arglist *array_arg, *value_arg, *dim_arg, *mask_arg, *kind_arg, *back_arg; gfc_expr *value_expr; int ikind; tree resvar; stmtblock_t block; stmtblock_t body; stmtblock_t loopblock; tree type; tree tmp; tree found; tree forward_branch = NULL_TREE; tree back_branch; gfc_loopinfo loop; gfc_ss *arrayss; gfc_ss *maskss; gfc_se arrayse; gfc_se valuese; gfc_se maskse; gfc_se backse; tree exit_label; gfc_expr *maskexpr; tree offset; int i; bool optional_mask; array_arg = expr->value.function.actual; value_arg = array_arg->next; dim_arg = value_arg->next; mask_arg = dim_arg->next; kind_arg = mask_arg->next; back_arg = kind_arg->next; /* Remove kind and set ikind. */ if (kind_arg->expr) { ikind = mpz_get_si (kind_arg->expr->value.integer); gfc_free_expr (kind_arg->expr); kind_arg->expr = NULL; } else ikind = gfc_default_integer_kind; value_expr = value_arg->expr; /* Unless it's a string, pass VALUE by value. */ if (value_expr->ts.type != BT_CHARACTER) value_arg->name = "%VAL"; /* Pass BACK argument by value. */ back_arg->name = "%VAL"; /* Call the library if we have a character function or if rank > 0. */ if (se->ss || array_arg->expr->ts.type == BT_CHARACTER) { se->ignore_optional = 1; if (expr->rank == 0) { /* Remove dim argument. */ gfc_free_expr (dim_arg->expr); dim_arg->expr = NULL; } gfc_conv_intrinsic_funcall (se, expr); return; } type = gfc_get_int_type (ikind); /* Initialize the result. */ resvar = gfc_create_var (gfc_array_index_type, "pos"); gfc_add_modify (&se->pre, resvar, build_int_cst (gfc_array_index_type, 0)); offset = gfc_create_var (gfc_array_index_type, "offset"); maskexpr = mask_arg->expr; optional_mask = maskexpr && maskexpr->expr_type == EXPR_VARIABLE && maskexpr->symtree->n.sym->attr.dummy && maskexpr->symtree->n.sym->attr.optional; /* Generate two loops, one for BACK=.true. and one for BACK=.false. */ for (i = 0 ; i < 2; i++) { /* Walk the arguments. */ arrayss = gfc_walk_expr (array_arg->expr); gcc_assert (arrayss != gfc_ss_terminator); if (maskexpr && maskexpr->rank != 0) { maskss = gfc_walk_expr (maskexpr); gcc_assert (maskss != gfc_ss_terminator); } else maskss = NULL; /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); exit_label = gfc_build_label_decl (NULL_TREE); TREE_USED (exit_label) = 1; /* We add the mask first because the number of iterations is taken from the last ss, and this breaks if an absent optional argument is used for mask. */ if (maskss) gfc_add_ss_to_loop (&loop, maskss); gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &expr->where); /* Calculate the offset. */ tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, gfc_index_one_node, loop.from[0]); gfc_add_modify (&loop.pre, offset, tmp); gfc_mark_ss_chain_used (arrayss, 1); if (maskss) gfc_mark_ss_chain_used (maskss, 1); /* The first loop is for BACK=.true. */ if (i == 0) loop.reverse[0] = GFC_REVERSE_SET; /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); /* If we have an array mask, only add the element if it is set. */ if (maskss) { gfc_init_se (&maskse, NULL); gfc_copy_loopinfo_to_se (&maskse, &loop); maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); } /* If the condition matches then set the return value. */ gfc_start_block (&block); /* Add the offset. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (resvar), loop.loopvar[0], offset); gfc_add_modify (&block, resvar, tmp); /* And break out of the loop. */ tmp = build1_v (GOTO_EXPR, exit_label); gfc_add_expr_to_block (&block, tmp); found = gfc_finish_block (&block); /* Check this element. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, array_arg->expr); gfc_add_block_to_block (&body, &arrayse.pre); gfc_init_se (&valuese, NULL); gfc_conv_expr_val (&valuese, value_arg->expr); gfc_add_block_to_block (&body, &valuese.pre); tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arrayse.expr, valuese.expr); tmp = build3_v (COND_EXPR, tmp, found, build_empty_stmt (input_location)); if (maskss) { /* We enclose the above in if (mask) {...}. If the mask is an optional argument, generate IF (.NOT. PRESENT(MASK) .OR. MASK(I)). */ tree ifmask; ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&body, tmp); gfc_add_block_to_block (&body, &arrayse.post); gfc_trans_scalarizing_loops (&loop, &body); /* Add the exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&loop.pre, tmp); gfc_start_block (&loopblock); gfc_add_block_to_block (&loopblock, &loop.pre); gfc_add_block_to_block (&loopblock, &loop.post); if (i == 0) forward_branch = gfc_finish_block (&loopblock); else back_branch = gfc_finish_block (&loopblock); gfc_cleanup_loop (&loop); } /* Enclose the two loops in an IF statement. */ gfc_init_se (&backse, NULL); gfc_conv_expr_val (&backse, back_arg->expr); gfc_add_block_to_block (&se->pre, &backse.pre); tmp = build3_v (COND_EXPR, backse.expr, forward_branch, back_branch); /* For a scalar mask, enclose the loop in an if statement. */ if (maskexpr && maskss == NULL) { tree ifmask; tree if_stmt; gfc_init_se (&maskse, NULL); gfc_conv_expr_val (&maskse, maskexpr); gfc_init_block (&block); gfc_add_expr_to_block (&block, maskse.expr); ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); if_stmt = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, if_stmt); tmp = gfc_finish_block (&block); } gfc_add_expr_to_block (&se->pre, tmp); se->expr = convert (type, resvar); } /* Emit code for minval or maxval intrinsic. There are many different cases we need to handle. For performance reasons we sometimes create two loops instead of one, where the second one is much simpler. Examples for minval intrinsic: 1) Result is an array, a call is generated 2) Array mask is used and NaNs need to be supported, rank 1: limit = Infinity; nonempty = false; S = from; while (S <= to) { if (mask[S]) { nonempty = true; if (a[S] <= limit) goto lab; } S++; } limit = nonempty ? NaN : huge (limit); lab: while (S <= to) { if(mask[S]) limit = min (a[S], limit); S++; } 3) NaNs need to be supported, but it is known at compile time or cheaply at runtime whether array is nonempty or not, rank 1: limit = Infinity; S = from; while (S <= to) { if (a[S] <= limit) goto lab; S++; } limit = (from <= to) ? NaN : huge (limit); lab: while (S <= to) { limit = min (a[S], limit); S++; } 4) Array mask is used and NaNs need to be supported, rank > 1: limit = Infinity; nonempty = false; fast = false; S1 = from1; while (S1 <= to1) { S2 = from2; while (S2 <= to2) { if (mask[S1][S2]) { if (fast) limit = min (a[S1][S2], limit); else { nonempty = true; if (a[S1][S2] <= limit) { limit = a[S1][S2]; fast = true; } } } S2++; } S1++; } if (!fast) limit = nonempty ? NaN : huge (limit); 5) NaNs need to be supported, but it is known at compile time or cheaply at runtime whether array is nonempty or not, rank > 1: limit = Infinity; fast = false; S1 = from1; while (S1 <= to1) { S2 = from2; while (S2 <= to2) { if (fast) limit = min (a[S1][S2], limit); else { if (a[S1][S2] <= limit) { limit = a[S1][S2]; fast = true; } } S2++; } S1++; } if (!fast) limit = (nonempty_array) ? NaN : huge (limit); 6) NaNs aren't supported, but infinities are. Array mask is used: limit = Infinity; nonempty = false; S = from; while (S <= to) { if (mask[S]) { nonempty = true; limit = min (a[S], limit); } S++; } limit = nonempty ? limit : huge (limit); 7) Same without array mask: limit = Infinity; S = from; while (S <= to) { limit = min (a[S], limit); S++; } limit = (from <= to) ? limit : huge (limit); 8) Neither NaNs nor infinities are supported (-ffast-math or BT_INTEGER): limit = huge (limit); S = from; while (S <= to) { limit = min (a[S], limit); S++); } (or while (S <= to) { if (mask[S]) limit = min (a[S], limit); S++; } with array mask instead). For 3), 5), 7) and 8), if mask is scalar, this all goes into a conditional, setting limit = huge (limit); in the else branch. */ static void gfc_conv_intrinsic_minmaxval (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree limit; tree type; tree tmp; tree ifbody; tree nonempty; tree nonempty_var; tree lab; tree fast; tree huge_cst = NULL, nan_cst = NULL; stmtblock_t body; stmtblock_t block, block2; gfc_loopinfo loop; gfc_actual_arglist *actual; gfc_ss *arrayss; gfc_ss *maskss; gfc_se arrayse; gfc_se maskse; gfc_expr *arrayexpr; gfc_expr *maskexpr; int n; bool optional_mask; if (se->ss) { gfc_conv_intrinsic_funcall (se, expr); return; } actual = expr->value.function.actual; arrayexpr = actual->expr; if (arrayexpr->ts.type == BT_CHARACTER) { gfc_actual_arglist *dim = actual->next; if (expr->rank == 0 && dim->expr != 0) { gfc_free_expr (dim->expr); dim->expr = NULL; } gfc_conv_intrinsic_funcall (se, expr); return; } type = gfc_typenode_for_spec (&expr->ts); /* Initialize the result. */ limit = gfc_create_var (type, "limit"); n = gfc_validate_kind (expr->ts.type, expr->ts.kind, false); switch (expr->ts.type) { case BT_REAL: huge_cst = gfc_conv_mpfr_to_tree (gfc_real_kinds[n].huge, expr->ts.kind, 0); if (HONOR_INFINITIES (DECL_MODE (limit))) { REAL_VALUE_TYPE real; real_inf (&real); tmp = build_real (type, real); } else tmp = huge_cst; if (HONOR_NANS (DECL_MODE (limit))) nan_cst = gfc_build_nan (type, ""); break; case BT_INTEGER: tmp = gfc_conv_mpz_to_tree (gfc_integer_kinds[n].huge, expr->ts.kind); break; default: gcc_unreachable (); } /* We start with the most negative possible value for MAXVAL, and the most positive possible value for MINVAL. The most negative possible value is -HUGE for BT_REAL and (-HUGE - 1) for BT_INTEGER; the most positive possible value is HUGE in both cases. */ if (op == GT_EXPR) { tmp = fold_build1_loc (input_location, NEGATE_EXPR, TREE_TYPE (tmp), tmp); if (huge_cst) huge_cst = fold_build1_loc (input_location, NEGATE_EXPR, TREE_TYPE (huge_cst), huge_cst); } if (op == GT_EXPR && expr->ts.type == BT_INTEGER) tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (tmp), tmp, build_int_cst (type, 1)); gfc_add_modify (&se->pre, limit, tmp); /* Walk the arguments. */ arrayss = gfc_walk_expr (arrayexpr); gcc_assert (arrayss != gfc_ss_terminator); actual = actual->next->next; gcc_assert (actual); maskexpr = actual->expr; optional_mask = maskexpr && maskexpr->expr_type == EXPR_VARIABLE && maskexpr->symtree->n.sym->attr.dummy && maskexpr->symtree->n.sym->attr.optional; nonempty = NULL; if (maskexpr && maskexpr->rank != 0) { maskss = gfc_walk_expr (maskexpr); gcc_assert (maskss != gfc_ss_terminator); } else { mpz_t asize; if (gfc_array_size (arrayexpr, &asize)) { nonempty = gfc_conv_mpz_to_tree (asize, gfc_index_integer_kind); mpz_clear (asize); nonempty = fold_build2_loc (input_location, GT_EXPR, logical_type_node, nonempty, gfc_index_zero_node); } maskss = NULL; } /* Initialize the scalarizer. */ gfc_init_loopinfo (&loop); /* We add the mask first because the number of iterations is taken from the last ss, and this breaks if an absent optional argument is used for mask. */ if (maskss) gfc_add_ss_to_loop (&loop, maskss); gfc_add_ss_to_loop (&loop, arrayss); /* Initialize the loop. */ gfc_conv_ss_startstride (&loop); /* The code generated can have more than one loop in sequence (see the comment at the function header). This doesn't work well with the scalarizer, which changes arrays' offset when the scalarization loops are generated (see gfc_trans_preloop_setup). Fortunately, {min,max}val are currently inlined in the scalar case only. As there is no dependency to care about in that case, there is no temporary, so that we can use the scalarizer temporary code to handle multiple loops. Thus, we set temp_dim here, we call gfc_mark_ss_chain_used with flag=3 later, and we use gfc_trans_scalarized_loop_boundary even later to restore offset. TODO: this prevents inlining of rank > 0 minmaxval calls, so this should eventually go away. We could either create two loops properly, or find another way to save/restore the array offsets between the two loops (without conflicting with temporary management), or use a single loop minmaxval implementation. See PR 31067. */ loop.temp_dim = loop.dimen; gfc_conv_loop_setup (&loop, &expr->where); if (nonempty == NULL && maskss == NULL && loop.dimen == 1 && loop.from[0] && loop.to[0]) nonempty = fold_build2_loc (input_location, LE_EXPR, logical_type_node, loop.from[0], loop.to[0]); nonempty_var = NULL; if (nonempty == NULL && (HONOR_INFINITIES (DECL_MODE (limit)) || HONOR_NANS (DECL_MODE (limit)))) { nonempty_var = gfc_create_var (logical_type_node, "nonempty"); gfc_add_modify (&se->pre, nonempty_var, logical_false_node); nonempty = nonempty_var; } lab = NULL; fast = NULL; if (HONOR_NANS (DECL_MODE (limit))) { if (loop.dimen == 1) { lab = gfc_build_label_decl (NULL_TREE); TREE_USED (lab) = 1; } else { fast = gfc_create_var (logical_type_node, "fast"); gfc_add_modify (&se->pre, fast, logical_false_node); } } gfc_mark_ss_chain_used (arrayss, lab ? 3 : 1); if (maskss) gfc_mark_ss_chain_used (maskss, lab ? 3 : 1); /* Generate the loop body. */ gfc_start_scalarized_body (&loop, &body); /* If we have a mask, only add this element if the mask is set. */ if (maskss) { gfc_init_se (&maskse, NULL); gfc_copy_loopinfo_to_se (&maskse, &loop); maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); gfc_start_block (&block); } else gfc_init_block (&block); /* Compare with the current limit. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, arrayexpr); gfc_add_block_to_block (&block, &arrayse.pre); gfc_init_block (&block2); if (nonempty_var) gfc_add_modify (&block2, nonempty_var, logical_true_node); if (HONOR_NANS (DECL_MODE (limit))) { tmp = fold_build2_loc (input_location, op == GT_EXPR ? GE_EXPR : LE_EXPR, logical_type_node, arrayse.expr, limit); if (lab) ifbody = build1_v (GOTO_EXPR, lab); else { stmtblock_t ifblock; gfc_init_block (&ifblock); gfc_add_modify (&ifblock, limit, arrayse.expr); gfc_add_modify (&ifblock, fast, logical_true_node); ifbody = gfc_finish_block (&ifblock); } tmp = build3_v (COND_EXPR, tmp, ifbody, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block2, tmp); } else { /* MIN_EXPR/MAX_EXPR has unspecified behavior with NaNs or signed zeros. */ tmp = fold_build2_loc (input_location, op == GT_EXPR ? MAX_EXPR : MIN_EXPR, type, arrayse.expr, limit); gfc_add_modify (&block2, limit, tmp); } if (fast) { tree elsebody = gfc_finish_block (&block2); /* MIN_EXPR/MAX_EXPR has unspecified behavior with NaNs or signed zeros. */ if (HONOR_NANS (DECL_MODE (limit))) { tmp = fold_build2_loc (input_location, op, logical_type_node, arrayse.expr, limit); ifbody = build2_v (MODIFY_EXPR, limit, arrayse.expr); ifbody = build3_v (COND_EXPR, tmp, ifbody, build_empty_stmt (input_location)); } else { tmp = fold_build2_loc (input_location, op == GT_EXPR ? MAX_EXPR : MIN_EXPR, type, arrayse.expr, limit); ifbody = build2_v (MODIFY_EXPR, limit, tmp); } tmp = build3_v (COND_EXPR, fast, ifbody, elsebody); gfc_add_expr_to_block (&block, tmp); } else gfc_add_block_to_block (&block, &block2); gfc_add_block_to_block (&block, &arrayse.post); tmp = gfc_finish_block (&block); if (maskss) { /* We enclose the above in if (mask) {...}. If the mask is an optional argument, generate IF (.NOT. PRESENT(MASK) .OR. MASK(I)). */ tree ifmask; ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&body, tmp); if (lab) { gfc_trans_scalarized_loop_boundary (&loop, &body); tmp = fold_build3_loc (input_location, COND_EXPR, type, nonempty, nan_cst, huge_cst); gfc_add_modify (&loop.code[0], limit, tmp); gfc_add_expr_to_block (&loop.code[0], build1_v (LABEL_EXPR, lab)); /* If we have a mask, only add this element if the mask is set. */ if (maskss) { gfc_init_se (&maskse, NULL); gfc_copy_loopinfo_to_se (&maskse, &loop); maskse.ss = maskss; gfc_conv_expr_val (&maskse, maskexpr); gfc_add_block_to_block (&body, &maskse.pre); gfc_start_block (&block); } else gfc_init_block (&block); /* Compare with the current limit. */ gfc_init_se (&arrayse, NULL); gfc_copy_loopinfo_to_se (&arrayse, &loop); arrayse.ss = arrayss; gfc_conv_expr_val (&arrayse, arrayexpr); gfc_add_block_to_block (&block, &arrayse.pre); /* MIN_EXPR/MAX_EXPR has unspecified behavior with NaNs or signed zeros. */ if (HONOR_NANS (DECL_MODE (limit))) { tmp = fold_build2_loc (input_location, op, logical_type_node, arrayse.expr, limit); ifbody = build2_v (MODIFY_EXPR, limit, arrayse.expr); tmp = build3_v (COND_EXPR, tmp, ifbody, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } else { tmp = fold_build2_loc (input_location, op == GT_EXPR ? MAX_EXPR : MIN_EXPR, type, arrayse.expr, limit); gfc_add_modify (&block, limit, tmp); } gfc_add_block_to_block (&block, &arrayse.post); tmp = gfc_finish_block (&block); if (maskss) /* We enclose the above in if (mask) {...}. */ { tree ifmask; ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, build_empty_stmt (input_location)); } gfc_add_expr_to_block (&body, tmp); /* Avoid initializing loopvar[0] again, it should be left where it finished by the first loop. */ loop.from[0] = loop.loopvar[0]; } gfc_trans_scalarizing_loops (&loop, &body); if (fast) { tmp = fold_build3_loc (input_location, COND_EXPR, type, nonempty, nan_cst, huge_cst); ifbody = build2_v (MODIFY_EXPR, limit, tmp); tmp = build3_v (COND_EXPR, fast, build_empty_stmt (input_location), ifbody); gfc_add_expr_to_block (&loop.pre, tmp); } else if (HONOR_INFINITIES (DECL_MODE (limit)) && !lab) { tmp = fold_build3_loc (input_location, COND_EXPR, type, nonempty, limit, huge_cst); gfc_add_modify (&loop.pre, limit, tmp); } /* For a scalar mask, enclose the loop in an if statement. */ if (maskexpr && maskss == NULL) { tree else_stmt; tree ifmask; gfc_init_se (&maskse, NULL); gfc_conv_expr_val (&maskse, maskexpr); gfc_init_block (&block); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); tmp = gfc_finish_block (&block); if (HONOR_INFINITIES (DECL_MODE (limit))) else_stmt = build2_v (MODIFY_EXPR, limit, huge_cst); else else_stmt = build_empty_stmt (input_location); ifmask = conv_mask_condition (&maskse, maskexpr, optional_mask); tmp = build3_v (COND_EXPR, ifmask, tmp, else_stmt); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&se->pre, &block); } else { gfc_add_block_to_block (&se->pre, &loop.pre); gfc_add_block_to_block (&se->pre, &loop.post); } gfc_cleanup_loop (&loop); se->expr = limit; } /* BTEST (i, pos) = (i & (1 << pos)) != 0. */ static void gfc_conv_intrinsic_btest (gfc_se * se, gfc_expr * expr) { tree args[2]; tree type; tree tmp; gfc_conv_intrinsic_function_args (se, expr, args, 2); type = TREE_TYPE (args[0]); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], build_int_cst (TREE_TYPE (args[1]), 0)); tree nbits = build_int_cst (TREE_TYPE (args[1]), TYPE_PRECISION (type)); tree above = fold_build2_loc (input_location, GE_EXPR, logical_type_node, args[1], nbits); tree scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "POS argument (%ld) out of range 0:%ld " "in intrinsic BTEST", fold_convert (long_integer_type_node, args[1]), fold_convert (long_integer_type_node, nbits)); } tmp = fold_build2_loc (input_location, LSHIFT_EXPR, type, build_int_cst (type, 1), args[1]); tmp = fold_build2_loc (input_location, BIT_AND_EXPR, type, args[0], tmp); tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, build_int_cst (type, 0)); type = gfc_typenode_for_spec (&expr->ts); se->expr = convert (type, tmp); } /* Generate code for BGE, BGT, BLE and BLT intrinsics. */ static void gfc_conv_intrinsic_bitcomp (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); /* Convert both arguments to the unsigned type of the same size. */ args[0] = fold_convert (unsigned_type_for (TREE_TYPE (args[0])), args[0]); args[1] = fold_convert (unsigned_type_for (TREE_TYPE (args[1])), args[1]); /* If they have unequal type size, convert to the larger one. */ if (TYPE_PRECISION (TREE_TYPE (args[0])) > TYPE_PRECISION (TREE_TYPE (args[1]))) args[1] = fold_convert (TREE_TYPE (args[0]), args[1]); else if (TYPE_PRECISION (TREE_TYPE (args[1])) > TYPE_PRECISION (TREE_TYPE (args[0]))) args[0] = fold_convert (TREE_TYPE (args[1]), args[0]); /* Now, we compare them. */ se->expr = fold_build2_loc (input_location, op, logical_type_node, args[0], args[1]); } /* Generate code to perform the specified operation. */ static void gfc_conv_intrinsic_bitop (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); se->expr = fold_build2_loc (input_location, op, TREE_TYPE (args[0]), args[0], args[1]); } /* Bitwise not. */ static void gfc_conv_intrinsic_not (gfc_se * se, gfc_expr * expr) { tree arg; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); se->expr = fold_build1_loc (input_location, BIT_NOT_EXPR, TREE_TYPE (arg), arg); } /* Set or clear a single bit. */ static void gfc_conv_intrinsic_singlebitop (gfc_se * se, gfc_expr * expr, int set) { tree args[2]; tree type; tree tmp; enum tree_code op; gfc_conv_intrinsic_function_args (se, expr, args, 2); type = TREE_TYPE (args[0]); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], build_int_cst (TREE_TYPE (args[1]), 0)); tree nbits = build_int_cst (TREE_TYPE (args[1]), TYPE_PRECISION (type)); tree above = fold_build2_loc (input_location, GE_EXPR, logical_type_node, args[1], nbits); tree scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); size_t len_name = strlen (expr->value.function.isym->name); char *name = XALLOCAVEC (char, len_name + 1); for (size_t i = 0; i < len_name; i++) name[i] = TOUPPER (expr->value.function.isym->name[i]); name[len_name] = '\0'; tree iname = gfc_build_addr_expr (pchar_type_node, gfc_build_cstring_const (name)); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "POS argument (%ld) out of range 0:%ld " "in intrinsic %s", fold_convert (long_integer_type_node, args[1]), fold_convert (long_integer_type_node, nbits), iname); } tmp = fold_build2_loc (input_location, LSHIFT_EXPR, type, build_int_cst (type, 1), args[1]); if (set) op = BIT_IOR_EXPR; else { op = BIT_AND_EXPR; tmp = fold_build1_loc (input_location, BIT_NOT_EXPR, type, tmp); } se->expr = fold_build2_loc (input_location, op, type, args[0], tmp); } /* Extract a sequence of bits. IBITS(I, POS, LEN) = (I >> POS) & ~((~0) << LEN). */ static void gfc_conv_intrinsic_ibits (gfc_se * se, gfc_expr * expr) { tree args[3]; tree type; tree tmp; tree mask; gfc_conv_intrinsic_function_args (se, expr, args, 3); type = TREE_TYPE (args[0]); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree tmp1 = fold_convert (long_integer_type_node, args[1]); tree tmp2 = fold_convert (long_integer_type_node, args[2]); tree nbits = build_int_cst (long_integer_type_node, TYPE_PRECISION (type)); tree below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], build_int_cst (TREE_TYPE (args[1]), 0)); tree above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, tmp1, nbits); tree scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "POS argument (%ld) out of range 0:%ld " "in intrinsic IBITS", tmp1, nbits); below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[2], build_int_cst (TREE_TYPE (args[2]), 0)); above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, tmp2, nbits); scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "LEN argument (%ld) out of range 0:%ld " "in intrinsic IBITS", tmp2, nbits); above = fold_build2_loc (input_location, PLUS_EXPR, long_integer_type_node, tmp1, tmp2); scond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, above, nbits); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "POS(%ld)+LEN(%ld)>BIT_SIZE(%ld) " "in intrinsic IBITS", tmp1, tmp2, nbits); } mask = build_int_cst (type, -1); mask = fold_build2_loc (input_location, LSHIFT_EXPR, type, mask, args[2]); mask = fold_build1_loc (input_location, BIT_NOT_EXPR, type, mask); tmp = fold_build2_loc (input_location, RSHIFT_EXPR, type, args[0], args[1]); se->expr = fold_build2_loc (input_location, BIT_AND_EXPR, type, tmp, mask); } static void gfc_conv_intrinsic_shift (gfc_se * se, gfc_expr * expr, bool right_shift, bool arithmetic) { tree args[2], type, num_bits, cond; tree bigshift; gfc_conv_intrinsic_function_args (se, expr, args, 2); args[0] = gfc_evaluate_now (args[0], &se->pre); args[1] = gfc_evaluate_now (args[1], &se->pre); type = TREE_TYPE (args[0]); if (!arithmetic) args[0] = fold_convert (unsigned_type_for (type), args[0]); else gcc_assert (right_shift); se->expr = fold_build2_loc (input_location, right_shift ? RSHIFT_EXPR : LSHIFT_EXPR, TREE_TYPE (args[0]), args[0], args[1]); if (!arithmetic) se->expr = fold_convert (type, se->expr); if (!arithmetic) bigshift = build_int_cst (type, 0); else { tree nonneg = fold_build2_loc (input_location, GE_EXPR, logical_type_node, args[0], build_int_cst (TREE_TYPE (args[0]), 0)); bigshift = fold_build3_loc (input_location, COND_EXPR, type, nonneg, build_int_cst (type, 0), build_int_cst (type, -1)); } /* The Fortran standard allows shift widths <= BIT_SIZE(I), whereas gcc requires a shift width < BIT_SIZE(I), so we have to catch this special case. */ num_bits = build_int_cst (TREE_TYPE (args[1]), TYPE_PRECISION (type)); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, args[1], build_int_cst (TREE_TYPE (args[1]), 0)); tree above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, args[1], num_bits); tree scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); size_t len_name = strlen (expr->value.function.isym->name); char *name = XALLOCAVEC (char, len_name + 1); for (size_t i = 0; i < len_name; i++) name[i] = TOUPPER (expr->value.function.isym->name[i]); name[len_name] = '\0'; tree iname = gfc_build_addr_expr (pchar_type_node, gfc_build_cstring_const (name)); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "SHIFT argument (%ld) out of range 0:%ld " "in intrinsic %s", fold_convert (long_integer_type_node, args[1]), fold_convert (long_integer_type_node, num_bits), iname); } cond = fold_build2_loc (input_location, GE_EXPR, logical_type_node, args[1], num_bits); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, bigshift, se->expr); } /* ISHFT (I, SHIFT) = (abs (shift) >= BIT_SIZE (i)) ? 0 : ((shift >= 0) ? i << shift : i >> -shift) where all shifts are logical shifts. */ static void gfc_conv_intrinsic_ishft (gfc_se * se, gfc_expr * expr) { tree args[2]; tree type; tree utype; tree tmp; tree width; tree num_bits; tree cond; tree lshift; tree rshift; gfc_conv_intrinsic_function_args (se, expr, args, 2); args[0] = gfc_evaluate_now (args[0], &se->pre); args[1] = gfc_evaluate_now (args[1], &se->pre); type = TREE_TYPE (args[0]); utype = unsigned_type_for (type); width = fold_build1_loc (input_location, ABS_EXPR, TREE_TYPE (args[1]), args[1]); /* Left shift if positive. */ lshift = fold_build2_loc (input_location, LSHIFT_EXPR, type, args[0], width); /* Right shift if negative. We convert to an unsigned type because we want a logical shift. The standard doesn't define the case of shifting negative numbers, and we try to be compatible with other compilers, most notably g77, here. */ rshift = fold_convert (type, fold_build2_loc (input_location, RSHIFT_EXPR, utype, convert (utype, args[0]), width)); tmp = fold_build2_loc (input_location, GE_EXPR, logical_type_node, args[1], build_int_cst (TREE_TYPE (args[1]), 0)); tmp = fold_build3_loc (input_location, COND_EXPR, type, tmp, lshift, rshift); /* The Fortran standard allows shift widths <= BIT_SIZE(I), whereas gcc requires a shift width < BIT_SIZE(I), so we have to catch this special case. */ num_bits = build_int_cst (TREE_TYPE (args[1]), TYPE_PRECISION (type)); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree outside = fold_build2_loc (input_location, GT_EXPR, logical_type_node, width, num_bits); gfc_trans_runtime_check (true, false, outside, &se->pre, &expr->where, "SHIFT argument (%ld) out of range -%ld:%ld " "in intrinsic ISHFT", fold_convert (long_integer_type_node, args[1]), fold_convert (long_integer_type_node, num_bits), fold_convert (long_integer_type_node, num_bits)); } cond = fold_build2_loc (input_location, GE_EXPR, logical_type_node, width, num_bits); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, build_int_cst (type, 0), tmp); } /* Circular shift. AKA rotate or barrel shift. */ static void gfc_conv_intrinsic_ishftc (gfc_se * se, gfc_expr * expr) { tree *args; tree type; tree tmp; tree lrot; tree rrot; tree zero; tree nbits; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); type = TREE_TYPE (args[0]); nbits = build_int_cst (long_integer_type_node, TYPE_PRECISION (type)); if (num_args == 3) { /* Use a library function for the 3 parameter version. */ tree int4type = gfc_get_int_type (4); /* We convert the first argument to at least 4 bytes, and convert back afterwards. This removes the need for library functions for all argument sizes, and function will be aligned to at least 32 bits, so there's no loss. */ if (expr->ts.kind < 4) args[0] = convert (int4type, args[0]); /* Convert the SHIFT and SIZE args to INTEGER*4 otherwise we would need loads of library functions. They cannot have values > BIT_SIZE (I) so the conversion is safe. */ args[1] = convert (int4type, args[1]); args[2] = convert (int4type, args[2]); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree size = fold_convert (long_integer_type_node, args[2]); tree below = fold_build2_loc (input_location, LE_EXPR, logical_type_node, size, build_int_cst (TREE_TYPE (args[1]), 0)); tree above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, size, nbits); tree scond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "SIZE argument (%ld) out of range 1:%ld " "in intrinsic ISHFTC", size, nbits); tree width = fold_convert (long_integer_type_node, args[1]); width = fold_build1_loc (input_location, ABS_EXPR, long_integer_type_node, width); scond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, width, size); gfc_trans_runtime_check (true, false, scond, &se->pre, &expr->where, "SHIFT argument (%ld) out of range -%ld:%ld " "in intrinsic ISHFTC", fold_convert (long_integer_type_node, args[1]), size, size); } switch (expr->ts.kind) { case 1: case 2: case 4: tmp = gfor_fndecl_math_ishftc4; break; case 8: tmp = gfor_fndecl_math_ishftc8; break; case 16: tmp = gfor_fndecl_math_ishftc16; break; default: gcc_unreachable (); } se->expr = build_call_expr_loc (input_location, tmp, 3, args[0], args[1], args[2]); /* Convert the result back to the original type, if we extended the first argument's width above. */ if (expr->ts.kind < 4) se->expr = convert (type, se->expr); return; } /* Evaluate arguments only once. */ args[0] = gfc_evaluate_now (args[0], &se->pre); args[1] = gfc_evaluate_now (args[1], &se->pre); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree width = fold_convert (long_integer_type_node, args[1]); width = fold_build1_loc (input_location, ABS_EXPR, long_integer_type_node, width); tree outside = fold_build2_loc (input_location, GT_EXPR, logical_type_node, width, nbits); gfc_trans_runtime_check (true, false, outside, &se->pre, &expr->where, "SHIFT argument (%ld) out of range -%ld:%ld " "in intrinsic ISHFTC", fold_convert (long_integer_type_node, args[1]), nbits, nbits); } /* Rotate left if positive. */ lrot = fold_build2_loc (input_location, LROTATE_EXPR, type, args[0], args[1]); /* Rotate right if negative. */ tmp = fold_build1_loc (input_location, NEGATE_EXPR, TREE_TYPE (args[1]), args[1]); rrot = fold_build2_loc (input_location,RROTATE_EXPR, type, args[0], tmp); zero = build_int_cst (TREE_TYPE (args[1]), 0); tmp = fold_build2_loc (input_location, GT_EXPR, logical_type_node, args[1], zero); rrot = fold_build3_loc (input_location, COND_EXPR, type, tmp, lrot, rrot); /* Do nothing if shift == 0. */ tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, args[1], zero); se->expr = fold_build3_loc (input_location, COND_EXPR, type, tmp, args[0], rrot); } /* LEADZ (i) = (i == 0) ? BIT_SIZE (i) : __builtin_clz(i) - (BIT_SIZE('int') - BIT_SIZE(i)) The conditional expression is necessary because the result of LEADZ(0) is defined, but the result of __builtin_clz(0) is undefined for most targets. For INTEGER kinds smaller than the C 'int' type, we have to subtract the difference in bit size between the argument of LEADZ and the C int. */ static void gfc_conv_intrinsic_leadz (gfc_se * se, gfc_expr * expr) { tree arg; tree arg_type; tree cond; tree result_type; tree leadz; tree bit_size; tree tmp; tree func; int s, argsize; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); argsize = TYPE_PRECISION (TREE_TYPE (arg)); /* Which variant of __builtin_clz* should we call? */ if (argsize <= INT_TYPE_SIZE) { arg_type = unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CLZ); } else if (argsize <= LONG_TYPE_SIZE) { arg_type = long_unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CLZL); } else if (argsize <= LONG_LONG_TYPE_SIZE) { arg_type = long_long_unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CLZLL); } else { gcc_assert (argsize == 2 * LONG_LONG_TYPE_SIZE); arg_type = gfc_build_uint_type (argsize); func = NULL_TREE; } /* Convert the actual argument twice: first, to the unsigned type of the same size; then, to the proper argument type for the built-in function. But the return type is of the default INTEGER kind. */ arg = fold_convert (gfc_build_uint_type (argsize), arg); arg = fold_convert (arg_type, arg); arg = gfc_evaluate_now (arg, &se->pre); result_type = gfc_get_int_type (gfc_default_integer_kind); /* Compute LEADZ for the case i .ne. 0. */ if (func) { s = TYPE_PRECISION (arg_type) - argsize; tmp = fold_convert (result_type, build_call_expr_loc (input_location, func, 1, arg)); leadz = fold_build2_loc (input_location, MINUS_EXPR, result_type, tmp, build_int_cst (result_type, s)); } else { /* We end up here if the argument type is larger than 'long long'. We generate this code: if (x & (ULL_MAX << ULL_SIZE) != 0) return clzll ((unsigned long long) (x >> ULLSIZE)); else return ULL_SIZE + clzll ((unsigned long long) x); where ULL_MAX is the largest value that a ULL_MAX can hold (0xFFFFFFFFFFFFFFFF for a 64-bit long long type), and ULLSIZE is the bit-size of the long long type (64 in this example). */ tree ullsize, ullmax, tmp1, tmp2, btmp; ullsize = build_int_cst (result_type, LONG_LONG_TYPE_SIZE); ullmax = fold_build1_loc (input_location, BIT_NOT_EXPR, long_long_unsigned_type_node, build_int_cst (long_long_unsigned_type_node, 0)); cond = fold_build2_loc (input_location, LSHIFT_EXPR, arg_type, fold_convert (arg_type, ullmax), ullsize); cond = fold_build2_loc (input_location, BIT_AND_EXPR, arg_type, arg, cond); cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, cond, build_int_cst (arg_type, 0)); tmp1 = fold_build2_loc (input_location, RSHIFT_EXPR, arg_type, arg, ullsize); tmp1 = fold_convert (long_long_unsigned_type_node, tmp1); btmp = builtin_decl_explicit (BUILT_IN_CLZLL); tmp1 = fold_convert (result_type, build_call_expr_loc (input_location, btmp, 1, tmp1)); tmp2 = fold_convert (long_long_unsigned_type_node, arg); btmp = builtin_decl_explicit (BUILT_IN_CLZLL); tmp2 = fold_convert (result_type, build_call_expr_loc (input_location, btmp, 1, tmp2)); tmp2 = fold_build2_loc (input_location, PLUS_EXPR, result_type, tmp2, ullsize); leadz = fold_build3_loc (input_location, COND_EXPR, result_type, cond, tmp1, tmp2); } /* Build BIT_SIZE. */ bit_size = build_int_cst (result_type, argsize); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, build_int_cst (arg_type, 0)); se->expr = fold_build3_loc (input_location, COND_EXPR, result_type, cond, bit_size, leadz); } /* TRAILZ(i) = (i == 0) ? BIT_SIZE (i) : __builtin_ctz(i) The conditional expression is necessary because the result of TRAILZ(0) is defined, but the result of __builtin_ctz(0) is undefined for most targets. */ static void gfc_conv_intrinsic_trailz (gfc_se * se, gfc_expr *expr) { tree arg; tree arg_type; tree cond; tree result_type; tree trailz; tree bit_size; tree func; int argsize; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); argsize = TYPE_PRECISION (TREE_TYPE (arg)); /* Which variant of __builtin_ctz* should we call? */ if (argsize <= INT_TYPE_SIZE) { arg_type = unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CTZ); } else if (argsize <= LONG_TYPE_SIZE) { arg_type = long_unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CTZL); } else if (argsize <= LONG_LONG_TYPE_SIZE) { arg_type = long_long_unsigned_type_node; func = builtin_decl_explicit (BUILT_IN_CTZLL); } else { gcc_assert (argsize == 2 * LONG_LONG_TYPE_SIZE); arg_type = gfc_build_uint_type (argsize); func = NULL_TREE; } /* Convert the actual argument twice: first, to the unsigned type of the same size; then, to the proper argument type for the built-in function. But the return type is of the default INTEGER kind. */ arg = fold_convert (gfc_build_uint_type (argsize), arg); arg = fold_convert (arg_type, arg); arg = gfc_evaluate_now (arg, &se->pre); result_type = gfc_get_int_type (gfc_default_integer_kind); /* Compute TRAILZ for the case i .ne. 0. */ if (func) trailz = fold_convert (result_type, build_call_expr_loc (input_location, func, 1, arg)); else { /* We end up here if the argument type is larger than 'long long'. We generate this code: if ((x & ULL_MAX) == 0) return ULL_SIZE + ctzll ((unsigned long long) (x >> ULLSIZE)); else return ctzll ((unsigned long long) x); where ULL_MAX is the largest value that a ULL_MAX can hold (0xFFFFFFFFFFFFFFFF for a 64-bit long long type), and ULLSIZE is the bit-size of the long long type (64 in this example). */ tree ullsize, ullmax, tmp1, tmp2, btmp; ullsize = build_int_cst (result_type, LONG_LONG_TYPE_SIZE); ullmax = fold_build1_loc (input_location, BIT_NOT_EXPR, long_long_unsigned_type_node, build_int_cst (long_long_unsigned_type_node, 0)); cond = fold_build2_loc (input_location, BIT_AND_EXPR, arg_type, arg, fold_convert (arg_type, ullmax)); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, cond, build_int_cst (arg_type, 0)); tmp1 = fold_build2_loc (input_location, RSHIFT_EXPR, arg_type, arg, ullsize); tmp1 = fold_convert (long_long_unsigned_type_node, tmp1); btmp = builtin_decl_explicit (BUILT_IN_CTZLL); tmp1 = fold_convert (result_type, build_call_expr_loc (input_location, btmp, 1, tmp1)); tmp1 = fold_build2_loc (input_location, PLUS_EXPR, result_type, tmp1, ullsize); tmp2 = fold_convert (long_long_unsigned_type_node, arg); btmp = builtin_decl_explicit (BUILT_IN_CTZLL); tmp2 = fold_convert (result_type, build_call_expr_loc (input_location, btmp, 1, tmp2)); trailz = fold_build3_loc (input_location, COND_EXPR, result_type, cond, tmp1, tmp2); } /* Build BIT_SIZE. */ bit_size = build_int_cst (result_type, argsize); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, build_int_cst (arg_type, 0)); se->expr = fold_build3_loc (input_location, COND_EXPR, result_type, cond, bit_size, trailz); } /* Using __builtin_popcount for POPCNT and __builtin_parity for POPPAR; for types larger than "long long", we call the long long built-in for the lower and higher bits and combine the result. */ static void gfc_conv_intrinsic_popcnt_poppar (gfc_se * se, gfc_expr *expr, int parity) { tree arg; tree arg_type; tree result_type; tree func; int argsize; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); argsize = TYPE_PRECISION (TREE_TYPE (arg)); result_type = gfc_get_int_type (gfc_default_integer_kind); /* Which variant of the builtin should we call? */ if (argsize <= INT_TYPE_SIZE) { arg_type = unsigned_type_node; func = builtin_decl_explicit (parity ? BUILT_IN_PARITY : BUILT_IN_POPCOUNT); } else if (argsize <= LONG_TYPE_SIZE) { arg_type = long_unsigned_type_node; func = builtin_decl_explicit (parity ? BUILT_IN_PARITYL : BUILT_IN_POPCOUNTL); } else if (argsize <= LONG_LONG_TYPE_SIZE) { arg_type = long_long_unsigned_type_node; func = builtin_decl_explicit (parity ? BUILT_IN_PARITYLL : BUILT_IN_POPCOUNTLL); } else { /* Our argument type is larger than 'long long', which mean none of the POPCOUNT builtins covers it. We thus call the 'long long' variant multiple times, and add the results. */ tree utype, arg2, call1, call2; /* For now, we only cover the case where argsize is twice as large as 'long long'. */ gcc_assert (argsize == 2 * LONG_LONG_TYPE_SIZE); func = builtin_decl_explicit (parity ? BUILT_IN_PARITYLL : BUILT_IN_POPCOUNTLL); /* Convert it to an integer, and store into a variable. */ utype = gfc_build_uint_type (argsize); arg = fold_convert (utype, arg); arg = gfc_evaluate_now (arg, &se->pre); /* Call the builtin twice. */ call1 = build_call_expr_loc (input_location, func, 1, fold_convert (long_long_unsigned_type_node, arg)); arg2 = fold_build2_loc (input_location, RSHIFT_EXPR, utype, arg, build_int_cst (utype, LONG_LONG_TYPE_SIZE)); call2 = build_call_expr_loc (input_location, func, 1, fold_convert (long_long_unsigned_type_node, arg2)); /* Combine the results. */ if (parity) se->expr = fold_build2_loc (input_location, BIT_XOR_EXPR, integer_type_node, call1, call2); else se->expr = fold_build2_loc (input_location, PLUS_EXPR, integer_type_node, call1, call2); se->expr = convert (result_type, se->expr); return; } /* Convert the actual argument twice: first, to the unsigned type of the same size; then, to the proper argument type for the built-in function. */ arg = fold_convert (gfc_build_uint_type (argsize), arg); arg = fold_convert (arg_type, arg); se->expr = fold_convert (result_type, build_call_expr_loc (input_location, func, 1, arg)); } /* Process an intrinsic with unspecified argument-types that has an optional argument (which could be of type character), e.g. EOSHIFT. For those, we need to append the string length of the optional argument if it is not present and the type is really character. primary specifies the position (starting at 1) of the non-optional argument specifying the type and optional gives the position of the optional argument in the arglist. */ static void conv_generic_with_optional_char_arg (gfc_se* se, gfc_expr* expr, unsigned primary, unsigned optional) { gfc_actual_arglist* prim_arg; gfc_actual_arglist* opt_arg; unsigned cur_pos; gfc_actual_arglist* arg; gfc_symbol* sym; vec *append_args; /* Find the two arguments given as position. */ cur_pos = 0; prim_arg = NULL; opt_arg = NULL; for (arg = expr->value.function.actual; arg; arg = arg->next) { ++cur_pos; if (cur_pos == primary) prim_arg = arg; if (cur_pos == optional) opt_arg = arg; if (cur_pos >= primary && cur_pos >= optional) break; } gcc_assert (prim_arg); gcc_assert (prim_arg->expr); gcc_assert (opt_arg); /* If we do have type CHARACTER and the optional argument is really absent, append a dummy 0 as string length. */ append_args = NULL; if (prim_arg->expr->ts.type == BT_CHARACTER && !opt_arg->expr) { tree dummy; dummy = build_int_cst (gfc_charlen_type_node, 0); vec_alloc (append_args, 1); append_args->quick_push (dummy); } /* Build the call itself. */ gcc_assert (!se->ignore_optional); sym = gfc_get_symbol_for_expr (expr, false); gfc_conv_procedure_call (se, sym, expr->value.function.actual, expr, append_args); gfc_free_symbol (sym); } /* The length of a character string. */ static void gfc_conv_intrinsic_len (gfc_se * se, gfc_expr * expr) { tree len; tree type; tree decl; gfc_symbol *sym; gfc_se argse; gfc_expr *arg; gcc_assert (!se->ss); arg = expr->value.function.actual->expr; type = gfc_typenode_for_spec (&expr->ts); switch (arg->expr_type) { case EXPR_CONSTANT: len = build_int_cst (gfc_charlen_type_node, arg->value.character.length); break; case EXPR_ARRAY: /* Obtain the string length from the function used by trans-array.cc(gfc_trans_array_constructor). */ len = NULL_TREE; get_array_ctor_strlen (&se->pre, arg->value.constructor, &len); break; case EXPR_VARIABLE: if (arg->ref == NULL || (arg->ref->next == NULL && arg->ref->type == REF_ARRAY)) { /* This doesn't catch all cases. See http://gcc.gnu.org/ml/fortran/2004-06/msg00165.html and the surrounding thread. */ sym = arg->symtree->n.sym; decl = gfc_get_symbol_decl (sym); if (decl == current_function_decl && sym->attr.function && (sym->result == sym)) decl = gfc_get_fake_result_decl (sym, 0); len = sym->ts.u.cl->backend_decl; gcc_assert (len); break; } /* Fall through. */ default: gfc_init_se (&argse, se); if (arg->rank == 0) gfc_conv_expr (&argse, arg); else gfc_conv_expr_descriptor (&argse, arg); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); len = argse.string_length; break; } se->expr = convert (type, len); } /* The length of a character string not including trailing blanks. */ static void gfc_conv_intrinsic_len_trim (gfc_se * se, gfc_expr * expr) { int kind = expr->value.function.actual->expr->ts.kind; tree args[2], type, fndecl; gfc_conv_intrinsic_function_args (se, expr, args, 2); type = gfc_typenode_for_spec (&expr->ts); if (kind == 1) fndecl = gfor_fndecl_string_len_trim; else if (kind == 4) fndecl = gfor_fndecl_string_len_trim_char4; else gcc_unreachable (); se->expr = build_call_expr_loc (input_location, fndecl, 2, args[0], args[1]); se->expr = convert (type, se->expr); } /* Returns the starting position of a substring within a string. */ static void gfc_conv_intrinsic_index_scan_verify (gfc_se * se, gfc_expr * expr, tree function) { tree logical4_type_node = gfc_get_logical_type (4); tree type; tree fndecl; tree *args; unsigned int num_args; args = XALLOCAVEC (tree, 5); /* Get number of arguments; characters count double due to the string length argument. Kind= is not passed to the library and thus ignored. */ if (expr->value.function.actual->next->next->expr == NULL) num_args = 4; else num_args = 5; gfc_conv_intrinsic_function_args (se, expr, args, num_args); type = gfc_typenode_for_spec (&expr->ts); if (num_args == 4) args[4] = build_int_cst (logical4_type_node, 0); else args[4] = convert (logical4_type_node, args[4]); fndecl = build_addr (function); se->expr = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (function)), fndecl, 5, args); se->expr = convert (type, se->expr); } /* The ascii value for a single character. */ static void gfc_conv_intrinsic_ichar (gfc_se * se, gfc_expr * expr) { tree args[3], type, pchartype; int nargs; nargs = gfc_intrinsic_argument_list_length (expr); gfc_conv_intrinsic_function_args (se, expr, args, nargs); gcc_assert (POINTER_TYPE_P (TREE_TYPE (args[1]))); pchartype = gfc_get_pchar_type (expr->value.function.actual->expr->ts.kind); args[1] = fold_build1_loc (input_location, NOP_EXPR, pchartype, args[1]); type = gfc_typenode_for_spec (&expr->ts); se->expr = build_fold_indirect_ref_loc (input_location, args[1]); se->expr = convert (type, se->expr); } /* Intrinsic ISNAN calls __builtin_isnan. */ static void gfc_conv_intrinsic_isnan (gfc_se * se, gfc_expr * expr) { tree arg; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); se->expr = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISNAN), 1, arg); STRIP_TYPE_NOPS (se->expr); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Intrinsics IS_IOSTAT_END and IS_IOSTAT_EOR just need to compare their argument against a constant integer value. */ static void gfc_conv_has_intvalue (gfc_se * se, gfc_expr * expr, const int value) { tree arg; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); se->expr = fold_build2_loc (input_location, EQ_EXPR, gfc_typenode_for_spec (&expr->ts), arg, build_int_cst (TREE_TYPE (arg), value)); } /* MERGE (tsource, fsource, mask) = mask ? tsource : fsource. */ static void gfc_conv_intrinsic_merge (gfc_se * se, gfc_expr * expr) { tree tsource; tree fsource; tree mask; tree type; tree len, len2; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); if (expr->ts.type != BT_CHARACTER) { tsource = args[0]; fsource = args[1]; mask = args[2]; } else { /* We do the same as in the non-character case, but the argument list is different because of the string length arguments. We also have to set the string length for the result. */ len = args[0]; tsource = args[1]; len2 = args[2]; fsource = args[3]; mask = args[4]; gfc_trans_same_strlen_check ("MERGE intrinsic", &expr->where, len, len2, &se->pre); se->string_length = len; } type = TREE_TYPE (tsource); se->expr = fold_build3_loc (input_location, COND_EXPR, type, mask, tsource, fold_convert (type, fsource)); } /* MERGE_BITS (I, J, MASK) = (I & MASK) | (I & (~MASK)). */ static void gfc_conv_intrinsic_merge_bits (gfc_se * se, gfc_expr * expr) { tree args[3], mask, type; gfc_conv_intrinsic_function_args (se, expr, args, 3); mask = gfc_evaluate_now (args[2], &se->pre); type = TREE_TYPE (args[0]); gcc_assert (TREE_TYPE (args[1]) == type); gcc_assert (TREE_TYPE (mask) == type); args[0] = fold_build2_loc (input_location, BIT_AND_EXPR, type, args[0], mask); args[1] = fold_build2_loc (input_location, BIT_AND_EXPR, type, args[1], fold_build1_loc (input_location, BIT_NOT_EXPR, type, mask)); se->expr = fold_build2_loc (input_location, BIT_IOR_EXPR, type, args[0], args[1]); } /* MASKL(n) = n == 0 ? 0 : (~0) << (BIT_SIZE - n) MASKR(n) = n == BIT_SIZE ? ~0 : ~((~0) << n) */ static void gfc_conv_intrinsic_mask (gfc_se * se, gfc_expr * expr, int left) { tree arg, allones, type, utype, res, cond, bitsize; int i; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); type = gfc_get_int_type (expr->ts.kind); utype = unsigned_type_for (type); i = gfc_validate_kind (BT_INTEGER, expr->ts.kind, false); bitsize = build_int_cst (TREE_TYPE (arg), gfc_integer_kinds[i].bit_size); allones = fold_build1_loc (input_location, BIT_NOT_EXPR, utype, build_int_cst (utype, 0)); if (left) { /* Left-justified mask. */ res = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (arg), bitsize, arg); res = fold_build2_loc (input_location, LSHIFT_EXPR, utype, allones, fold_convert (utype, res)); /* Special case arg == 0, because SHIFT_EXPR wants a shift strictly smaller than type width. */ cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, build_int_cst (TREE_TYPE (arg), 0)); res = fold_build3_loc (input_location, COND_EXPR, utype, cond, build_int_cst (utype, 0), res); } else { /* Right-justified mask. */ res = fold_build2_loc (input_location, LSHIFT_EXPR, utype, allones, fold_convert (utype, arg)); res = fold_build1_loc (input_location, BIT_NOT_EXPR, utype, res); /* Special case agr == bit_size, because SHIFT_EXPR wants a shift strictly smaller than type width. */ cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, bitsize); res = fold_build3_loc (input_location, COND_EXPR, utype, cond, allones, res); } se->expr = fold_convert (type, res); } /* FRACTION (s) is translated into: isfinite (s) ? frexp (s, &dummy_int) : NaN */ static void gfc_conv_intrinsic_fraction (gfc_se * se, gfc_expr * expr) { tree arg, type, tmp, res, frexp, cond; frexp = gfc_builtin_decl_for_float_kind (BUILT_IN_FREXP, expr->ts.kind); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); cond = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISFINITE), 1, arg); tmp = gfc_create_var (integer_type_node, NULL); res = build_call_expr_loc (input_location, frexp, 2, fold_convert (type, arg), gfc_build_addr_expr (NULL_TREE, tmp)); res = fold_convert (type, res); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, res, gfc_build_nan (type, "")); } /* NEAREST (s, dir) is translated into tmp = copysign (HUGE_VAL, dir); return nextafter (s, tmp); */ static void gfc_conv_intrinsic_nearest (gfc_se * se, gfc_expr * expr) { tree args[2], type, tmp, nextafter, copysign, huge_val; nextafter = gfc_builtin_decl_for_float_kind (BUILT_IN_NEXTAFTER, expr->ts.kind); copysign = gfc_builtin_decl_for_float_kind (BUILT_IN_COPYSIGN, expr->ts.kind); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, args, 2); huge_val = gfc_build_inf_or_huge (type, expr->ts.kind); tmp = build_call_expr_loc (input_location, copysign, 2, huge_val, fold_convert (type, args[1])); se->expr = build_call_expr_loc (input_location, nextafter, 2, fold_convert (type, args[0]), tmp); se->expr = fold_convert (type, se->expr); } /* SPACING (s) is translated into int e; if (!isfinite (s)) res = NaN; else if (s == 0) res = tiny; else { frexp (s, &e); e = e - prec; e = MAX_EXPR (e, emin); res = scalbn (1., e); } return res; where prec is the precision of s, gfc_real_kinds[k].digits, emin is min_exponent - 1, gfc_real_kinds[k].min_exponent - 1, and tiny is tiny(s), gfc_real_kinds[k].tiny. */ static void gfc_conv_intrinsic_spacing (gfc_se * se, gfc_expr * expr) { tree arg, type, prec, emin, tiny, res, e; tree cond, nan, tmp, frexp, scalbn; int k; stmtblock_t block; k = gfc_validate_kind (BT_REAL, expr->ts.kind, false); prec = build_int_cst (integer_type_node, gfc_real_kinds[k].digits); emin = build_int_cst (integer_type_node, gfc_real_kinds[k].min_exponent - 1); tiny = gfc_conv_mpfr_to_tree (gfc_real_kinds[k].tiny, expr->ts.kind, 0); frexp = gfc_builtin_decl_for_float_kind (BUILT_IN_FREXP, expr->ts.kind); scalbn = gfc_builtin_decl_for_float_kind (BUILT_IN_SCALBN, expr->ts.kind); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); type = gfc_typenode_for_spec (&expr->ts); e = gfc_create_var (integer_type_node, NULL); res = gfc_create_var (type, NULL); /* Build the block for s /= 0. */ gfc_start_block (&block); tmp = build_call_expr_loc (input_location, frexp, 2, arg, gfc_build_addr_expr (NULL_TREE, e)); gfc_add_expr_to_block (&block, tmp); tmp = fold_build2_loc (input_location, MINUS_EXPR, integer_type_node, e, prec); gfc_add_modify (&block, e, fold_build2_loc (input_location, MAX_EXPR, integer_type_node, tmp, emin)); tmp = build_call_expr_loc (input_location, scalbn, 2, build_real_from_int_cst (type, integer_one_node), e); gfc_add_modify (&block, res, tmp); /* Finish by building the IF statement for value zero. */ cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, build_real_from_int_cst (type, integer_zero_node)); tmp = build3_v (COND_EXPR, cond, build2_v (MODIFY_EXPR, res, tiny), gfc_finish_block (&block)); /* And deal with infinities and NaNs. */ cond = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISFINITE), 1, arg); nan = gfc_build_nan (type, ""); tmp = build3_v (COND_EXPR, cond, tmp, build2_v (MODIFY_EXPR, res, nan)); gfc_add_expr_to_block (&se->pre, tmp); se->expr = res; } /* RRSPACING (s) is translated into int e; real x; x = fabs (s); if (isfinite (x)) { if (x != 0) { frexp (s, &e); x = scalbn (x, precision - e); } } else x = NaN; return x; where precision is gfc_real_kinds[k].digits. */ static void gfc_conv_intrinsic_rrspacing (gfc_se * se, gfc_expr * expr) { tree arg, type, e, x, cond, nan, stmt, tmp, frexp, scalbn, fabs; int prec, k; stmtblock_t block; k = gfc_validate_kind (BT_REAL, expr->ts.kind, false); prec = gfc_real_kinds[k].digits; frexp = gfc_builtin_decl_for_float_kind (BUILT_IN_FREXP, expr->ts.kind); scalbn = gfc_builtin_decl_for_float_kind (BUILT_IN_SCALBN, expr->ts.kind); fabs = gfc_builtin_decl_for_float_kind (BUILT_IN_FABS, expr->ts.kind); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); e = gfc_create_var (integer_type_node, NULL); x = gfc_create_var (type, NULL); gfc_add_modify (&se->pre, x, build_call_expr_loc (input_location, fabs, 1, arg)); gfc_start_block (&block); tmp = build_call_expr_loc (input_location, frexp, 2, arg, gfc_build_addr_expr (NULL_TREE, e)); gfc_add_expr_to_block (&block, tmp); tmp = fold_build2_loc (input_location, MINUS_EXPR, integer_type_node, build_int_cst (integer_type_node, prec), e); tmp = build_call_expr_loc (input_location, scalbn, 2, x, tmp); gfc_add_modify (&block, x, tmp); stmt = gfc_finish_block (&block); /* if (x != 0) */ cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, x, build_real_from_int_cst (type, integer_zero_node)); tmp = build3_v (COND_EXPR, cond, stmt, build_empty_stmt (input_location)); /* And deal with infinities and NaNs. */ cond = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISFINITE), 1, x); nan = gfc_build_nan (type, ""); tmp = build3_v (COND_EXPR, cond, tmp, build2_v (MODIFY_EXPR, x, nan)); gfc_add_expr_to_block (&se->pre, tmp); se->expr = fold_convert (type, x); } /* SCALE (s, i) is translated into scalbn (s, i). */ static void gfc_conv_intrinsic_scale (gfc_se * se, gfc_expr * expr) { tree args[2], type, scalbn; scalbn = gfc_builtin_decl_for_float_kind (BUILT_IN_SCALBN, expr->ts.kind); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, args, 2); se->expr = build_call_expr_loc (input_location, scalbn, 2, fold_convert (type, args[0]), fold_convert (integer_type_node, args[1])); se->expr = fold_convert (type, se->expr); } /* SET_EXPONENT (s, i) is translated into isfinite(s) ? scalbn (frexp (s, &dummy_int), i) : NaN */ static void gfc_conv_intrinsic_set_exponent (gfc_se * se, gfc_expr * expr) { tree args[2], type, tmp, frexp, scalbn, cond, nan, res; frexp = gfc_builtin_decl_for_float_kind (BUILT_IN_FREXP, expr->ts.kind); scalbn = gfc_builtin_decl_for_float_kind (BUILT_IN_SCALBN, expr->ts.kind); type = gfc_typenode_for_spec (&expr->ts); gfc_conv_intrinsic_function_args (se, expr, args, 2); args[0] = gfc_evaluate_now (args[0], &se->pre); tmp = gfc_create_var (integer_type_node, NULL); tmp = build_call_expr_loc (input_location, frexp, 2, fold_convert (type, args[0]), gfc_build_addr_expr (NULL_TREE, tmp)); res = build_call_expr_loc (input_location, scalbn, 2, tmp, fold_convert (integer_type_node, args[1])); res = fold_convert (type, res); /* Call to isfinite */ cond = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISFINITE), 1, args[0]); nan = gfc_build_nan (type, ""); se->expr = fold_build3_loc (input_location, COND_EXPR, type, cond, res, nan); } static void gfc_conv_intrinsic_size (gfc_se * se, gfc_expr * expr) { gfc_actual_arglist *actual; tree arg1; tree type; tree size; gfc_se argse; gfc_expr *e; gfc_symbol *sym = NULL; gfc_init_se (&argse, NULL); actual = expr->value.function.actual; if (actual->expr->ts.type == BT_CLASS) gfc_add_class_array_ref (actual->expr); e = actual->expr; /* These are emerging from the interface mapping, when a class valued function appears as the rhs in a realloc on assign statement, where the size of the result is that of one of the actual arguments. */ if (e->expr_type == EXPR_VARIABLE && e->symtree->n.sym->ns == NULL /* This is distinctive! */ && e->symtree->n.sym->ts.type == BT_CLASS && e->ref && e->ref->type == REF_COMPONENT && strcmp (e->ref->u.c.component->name, "_data") == 0) sym = e->symtree->n.sym; if ((gfc_option.rtcheck & GFC_RTCHECK_POINTER) && e && (e->expr_type == EXPR_VARIABLE || e->expr_type == EXPR_FUNCTION)) { symbol_attribute attr; char *msg; tree temp; tree cond; if (e->symtree->n.sym && IS_CLASS_ARRAY (e->symtree->n.sym)) { attr = CLASS_DATA (e->symtree->n.sym)->attr; attr.pointer = attr.class_pointer; } else attr = gfc_expr_attr (e); if (attr.allocatable) msg = xasprintf ("Allocatable argument '%s' is not allocated", e->symtree->n.sym->name); else if (attr.pointer) msg = xasprintf ("Pointer argument '%s' is not associated", e->symtree->n.sym->name); else goto end_arg_check; if (sym) { temp = gfc_class_data_get (sym->backend_decl); temp = gfc_conv_descriptor_data_get (temp); } else { argse.descriptor_only = 1; gfc_conv_expr_descriptor (&argse, actual->expr); temp = gfc_conv_descriptor_data_get (argse.expr); } cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, temp, fold_convert (TREE_TYPE (temp), null_pointer_node)); gfc_trans_runtime_check (true, false, cond, &argse.pre, &e->where, msg); free (msg); } end_arg_check: argse.data_not_needed = 1; if (gfc_is_class_array_function (e)) { /* For functions that return a class array conv_expr_descriptor is not able to get the descriptor right. Therefore this special case. */ gfc_conv_expr_reference (&argse, e); argse.expr = gfc_class_data_get (argse.expr); } else if (sym && sym->backend_decl) { gcc_assert (GFC_CLASS_TYPE_P (TREE_TYPE (sym->backend_decl))); argse.expr = gfc_class_data_get (sym->backend_decl); } else gfc_conv_expr_descriptor (&argse, actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); arg1 = argse.expr; actual = actual->next; if (actual->expr) { stmtblock_t block; gfc_init_block (&block); gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, actual->expr, gfc_array_index_type); gfc_add_block_to_block (&block, &argse.pre); tree tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, argse.expr, gfc_index_one_node); size = gfc_tree_array_size (&block, arg1, e, tmp); /* Unusually, for an intrinsic, size does not exclude an optional arg2, so we must test for it. */ if (actual->expr->expr_type == EXPR_VARIABLE && actual->expr->symtree->n.sym->attr.dummy && actual->expr->symtree->n.sym->attr.optional) { tree cond; stmtblock_t block2; gfc_init_block (&block2); gfc_init_se (&argse, NULL); argse.want_pointer = 1; argse.data_not_needed = 1; gfc_conv_expr (&argse, actual->expr); gfc_add_block_to_block (&se->pre, &argse.pre); cond = fold_build2_loc (input_location, NE_EXPR, logical_type_node, argse.expr, null_pointer_node); cond = gfc_evaluate_now (cond, &se->pre); /* 'block2' contains the arg2 absent case, 'block' the arg2 present case; size_var can be used in both blocks. */ tree size_var = gfc_create_var (TREE_TYPE (size), "size"); tmp = fold_build2_loc (input_location, MODIFY_EXPR, TREE_TYPE (size_var), size_var, size); gfc_add_expr_to_block (&block, tmp); size = gfc_tree_array_size (&block2, arg1, e, NULL_TREE); tmp = fold_build2_loc (input_location, MODIFY_EXPR, TREE_TYPE (size_var), size_var, size); gfc_add_expr_to_block (&block2, tmp); tmp = build3_v (COND_EXPR, cond, gfc_finish_block (&block), gfc_finish_block (&block2)); gfc_add_expr_to_block (&se->pre, tmp); size = size_var; } else gfc_add_block_to_block (&se->pre, &block); } else size = gfc_tree_array_size (&se->pre, arg1, e, NULL_TREE); type = gfc_typenode_for_spec (&expr->ts); se->expr = convert (type, size); } /* Helper function to compute the size of a character variable, excluding the terminating null characters. The result has gfc_array_index_type type. */ tree size_of_string_in_bytes (int kind, tree string_length) { tree bytesize; int i = gfc_validate_kind (BT_CHARACTER, kind, false); bytesize = build_int_cst (gfc_array_index_type, gfc_character_kinds[i].bit_size / 8); return fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, bytesize, fold_convert (gfc_array_index_type, string_length)); } static void gfc_conv_intrinsic_sizeof (gfc_se *se, gfc_expr *expr) { gfc_expr *arg; gfc_se argse; tree source_bytes; tree tmp; tree lower; tree upper; tree byte_size; tree field; int n; gfc_init_se (&argse, NULL); arg = expr->value.function.actual->expr; if (arg->rank || arg->ts.type == BT_ASSUMED) gfc_conv_expr_descriptor (&argse, arg); else gfc_conv_expr_reference (&argse, arg); if (arg->ts.type == BT_ASSUMED) { /* This only works if an array descriptor has been passed; thus, extract the size from the descriptor. */ gcc_assert (TYPE_PRECISION (gfc_array_index_type) == TYPE_PRECISION (size_type_node)); tmp = arg->symtree->n.sym->backend_decl; tmp = DECL_LANG_SPECIFIC (tmp) && GFC_DECL_SAVED_DESCRIPTOR (tmp) != NULL_TREE ? GFC_DECL_SAVED_DESCRIPTOR (tmp) : tmp; if (POINTER_TYPE_P (TREE_TYPE (tmp))) tmp = build_fold_indirect_ref_loc (input_location, tmp); tmp = gfc_conv_descriptor_dtype (tmp); field = gfc_advance_chain (TYPE_FIELDS (get_dtype_type_node ()), GFC_DTYPE_ELEM_LEN); tmp = fold_build3_loc (input_location, COMPONENT_REF, TREE_TYPE (field), tmp, field, NULL_TREE); byte_size = fold_convert (gfc_array_index_type, tmp); } else if (arg->ts.type == BT_CLASS) { /* Conv_expr_descriptor returns a component_ref to _data component of the class object. The class object may be a non-pointer object, e.g. located on the stack, or a memory location pointed to, e.g. a parameter, i.e., an indirect_ref. */ if (POINTER_TYPE_P (TREE_TYPE (argse.expr)) && GFC_CLASS_TYPE_P (TREE_TYPE (TREE_TYPE (argse.expr)))) byte_size = gfc_class_vtab_size_get (build_fold_indirect_ref (argse.expr)); else if (GFC_CLASS_TYPE_P (TREE_TYPE (argse.expr))) byte_size = gfc_class_vtab_size_get (argse.expr); else if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (argse.expr)) && TREE_CODE (argse.expr) == COMPONENT_REF) byte_size = gfc_class_vtab_size_get (TREE_OPERAND (argse.expr, 0)); else if (arg->rank > 0 || (arg->rank == 0 && arg->ref && arg->ref->type == REF_COMPONENT)) /* The scalarizer added an additional temp. To get the class' vptr one has to look at the original backend_decl. */ byte_size = gfc_class_vtab_size_get ( GFC_DECL_SAVED_DESCRIPTOR (arg->symtree->n.sym->backend_decl)); else gcc_unreachable (); } else { if (arg->ts.type == BT_CHARACTER) byte_size = size_of_string_in_bytes (arg->ts.kind, argse.string_length); else { if (arg->rank == 0) byte_size = TREE_TYPE (build_fold_indirect_ref_loc (input_location, argse.expr)); else byte_size = gfc_get_element_type (TREE_TYPE (argse.expr)); byte_size = fold_convert (gfc_array_index_type, size_in_bytes (byte_size)); } } if (arg->rank == 0) se->expr = byte_size; else { source_bytes = gfc_create_var (gfc_array_index_type, "bytes"); gfc_add_modify (&argse.pre, source_bytes, byte_size); if (arg->rank == -1) { tree cond, loop_var, exit_label; stmtblock_t body; tmp = fold_convert (gfc_array_index_type, gfc_conv_descriptor_rank (argse.expr)); loop_var = gfc_create_var (gfc_array_index_type, "i"); gfc_add_modify (&argse.pre, loop_var, gfc_index_zero_node); exit_label = gfc_build_label_decl (NULL_TREE); /* Create loop: for (;;) { if (i >= rank) goto exit; source_bytes = source_bytes * array.dim[i].extent; i = i + 1; } exit: */ gfc_start_block (&body); cond = fold_build2_loc (input_location, GE_EXPR, logical_type_node, loop_var, tmp); tmp = build1_v (GOTO_EXPR, exit_label); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); lower = gfc_conv_descriptor_lbound_get (argse.expr, loop_var); upper = gfc_conv_descriptor_ubound_get (argse.expr, loop_var); tmp = gfc_conv_array_extent_dim (lower, upper, NULL); tmp = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, tmp, source_bytes); gfc_add_modify (&body, source_bytes, tmp); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, loop_var, gfc_index_one_node); gfc_add_modify_loc (input_location, &body, loop_var, tmp); tmp = gfc_finish_block (&body); tmp = fold_build1_loc (input_location, LOOP_EXPR, void_type_node, tmp); gfc_add_expr_to_block (&argse.pre, tmp); tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&argse.pre, tmp); } else { /* Obtain the size of the array in bytes. */ for (n = 0; n < arg->rank; n++) { tree idx; idx = gfc_rank_cst[n]; lower = gfc_conv_descriptor_lbound_get (argse.expr, idx); upper = gfc_conv_descriptor_ubound_get (argse.expr, idx); tmp = gfc_conv_array_extent_dim (lower, upper, NULL); tmp = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, tmp, source_bytes); gfc_add_modify (&argse.pre, source_bytes, tmp); } } se->expr = source_bytes; } gfc_add_block_to_block (&se->pre, &argse.pre); } static void gfc_conv_intrinsic_storage_size (gfc_se *se, gfc_expr *expr) { gfc_expr *arg; gfc_se argse; tree type, result_type, tmp; arg = expr->value.function.actual->expr; gfc_init_se (&argse, NULL); result_type = gfc_get_int_type (expr->ts.kind); if (arg->rank == 0) { if (arg->ts.type == BT_CLASS) { gfc_add_vptr_component (arg); gfc_add_size_component (arg); gfc_conv_expr (&argse, arg); tmp = fold_convert (result_type, argse.expr); goto done; } gfc_conv_expr_reference (&argse, arg); type = TREE_TYPE (build_fold_indirect_ref_loc (input_location, argse.expr)); } else { argse.want_pointer = 0; gfc_conv_expr_descriptor (&argse, arg); if (arg->ts.type == BT_CLASS) { if (arg->rank > 0) tmp = gfc_class_vtab_size_get ( GFC_DECL_SAVED_DESCRIPTOR (arg->symtree->n.sym->backend_decl)); else tmp = gfc_class_vtab_size_get (TREE_OPERAND (argse.expr, 0)); tmp = fold_convert (result_type, tmp); goto done; } type = gfc_get_element_type (TREE_TYPE (argse.expr)); } /* Obtain the argument's word length. */ if (arg->ts.type == BT_CHARACTER) tmp = size_of_string_in_bytes (arg->ts.kind, argse.string_length); else tmp = size_in_bytes (type); tmp = fold_convert (result_type, tmp); done: se->expr = fold_build2_loc (input_location, MULT_EXPR, result_type, tmp, build_int_cst (result_type, BITS_PER_UNIT)); gfc_add_block_to_block (&se->pre, &argse.pre); } /* Intrinsic string comparison functions. */ static void gfc_conv_intrinsic_strcmp (gfc_se * se, gfc_expr * expr, enum tree_code op) { tree args[4]; gfc_conv_intrinsic_function_args (se, expr, args, 4); se->expr = gfc_build_compare_string (args[0], args[1], args[2], args[3], expr->value.function.actual->expr->ts.kind, op); se->expr = fold_build2_loc (input_location, op, gfc_typenode_for_spec (&expr->ts), se->expr, build_int_cst (TREE_TYPE (se->expr), 0)); } /* Generate a call to the adjustl/adjustr library function. */ static void gfc_conv_intrinsic_adjust (gfc_se * se, gfc_expr * expr, tree fndecl) { tree args[3]; tree len; tree type; tree var; tree tmp; gfc_conv_intrinsic_function_args (se, expr, &args[1], 2); len = args[1]; type = TREE_TYPE (args[2]); var = gfc_conv_string_tmp (se, type, len); args[0] = var; tmp = build_call_expr_loc (input_location, fndecl, 3, args[0], args[1], args[2]); gfc_add_expr_to_block (&se->pre, tmp); se->expr = var; se->string_length = len; } /* Generate code for the TRANSFER intrinsic: For scalar results: DEST = TRANSFER (SOURCE, MOLD) where: typeof = typeof and: MOLD is scalar. For array results: DEST(1:N) = TRANSFER (SOURCE, MOLD[, SIZE]) where: typeof = typeof and: N = min (sizeof (SOURCE(:)), sizeof (DEST(:)), sizeof (DEST(0) * SIZE). */ static void gfc_conv_intrinsic_transfer (gfc_se * se, gfc_expr * expr) { tree tmp; tree tmpdecl; tree ptr; tree extent; tree source; tree source_type; tree source_bytes; tree mold_type; tree dest_word_len; tree size_words; tree size_bytes; tree upper; tree lower; tree stmt; tree class_ref = NULL_TREE; gfc_actual_arglist *arg; gfc_se argse; gfc_array_info *info; stmtblock_t block; int n; bool scalar_mold; gfc_expr *source_expr, *mold_expr, *class_expr; info = NULL; if (se->loop) info = &se->ss->info->data.array; /* Convert SOURCE. The output from this stage is:- source_bytes = length of the source in bytes source = pointer to the source data. */ arg = expr->value.function.actual; source_expr = arg->expr; /* Ensure double transfer through LOGICAL preserves all the needed bits. */ if (arg->expr->expr_type == EXPR_FUNCTION && arg->expr->value.function.esym == NULL && arg->expr->value.function.isym != NULL && arg->expr->value.function.isym->id == GFC_ISYM_TRANSFER && arg->expr->ts.type == BT_LOGICAL && expr->ts.type != arg->expr->ts.type) arg->expr->value.function.name = "__transfer_in_transfer"; gfc_init_se (&argse, NULL); source_bytes = gfc_create_var (gfc_array_index_type, NULL); /* Obtain the pointer to source and the length of source in bytes. */ if (arg->expr->rank == 0) { gfc_conv_expr_reference (&argse, arg->expr); if (arg->expr->ts.type == BT_CLASS) { tmp = build_fold_indirect_ref_loc (input_location, argse.expr); if (GFC_CLASS_TYPE_P (TREE_TYPE (tmp))) source = gfc_class_data_get (tmp); else { /* Array elements are evaluated as a reference to the data. To obtain the vptr for the element size, the argument expression must be stripped to the class reference and re-evaluated. The pre and post blocks are not needed. */ gcc_assert (arg->expr->expr_type == EXPR_VARIABLE); source = argse.expr; class_expr = gfc_find_and_cut_at_last_class_ref (arg->expr); gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, class_expr); class_ref = argse.expr; } } else source = argse.expr; /* Obtain the source word length. */ switch (arg->expr->ts.type) { case BT_CHARACTER: tmp = size_of_string_in_bytes (arg->expr->ts.kind, argse.string_length); break; case BT_CLASS: if (class_ref != NULL_TREE) tmp = gfc_class_vtab_size_get (class_ref); else tmp = gfc_class_vtab_size_get (argse.expr); break; default: source_type = TREE_TYPE (build_fold_indirect_ref_loc (input_location, source)); tmp = fold_convert (gfc_array_index_type, size_in_bytes (source_type)); break; } } else { argse.want_pointer = 0; gfc_conv_expr_descriptor (&argse, arg->expr); source = gfc_conv_descriptor_data_get (argse.expr); source_type = gfc_get_element_type (TREE_TYPE (argse.expr)); /* Repack the source if not simply contiguous. */ if (!gfc_is_simply_contiguous (arg->expr, false, true)) { tmp = gfc_build_addr_expr (NULL_TREE, argse.expr); if (warn_array_temporaries) gfc_warning (OPT_Warray_temporaries, "Creating array temporary at %L", &expr->where); source = build_call_expr_loc (input_location, gfor_fndecl_in_pack, 1, tmp); source = gfc_evaluate_now (source, &argse.pre); /* Free the temporary. */ gfc_start_block (&block); tmp = gfc_call_free (source); gfc_add_expr_to_block (&block, tmp); stmt = gfc_finish_block (&block); /* Clean up if it was repacked. */ gfc_init_block (&block); tmp = gfc_conv_array_data (argse.expr); tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, source, tmp); tmp = build3_v (COND_EXPR, tmp, stmt, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&block, &se->post); gfc_init_block (&se->post); gfc_add_block_to_block (&se->post, &block); } /* Obtain the source word length. */ if (arg->expr->ts.type == BT_CHARACTER) tmp = size_of_string_in_bytes (arg->expr->ts.kind, argse.string_length); else tmp = fold_convert (gfc_array_index_type, size_in_bytes (source_type)); /* Obtain the size of the array in bytes. */ extent = gfc_create_var (gfc_array_index_type, NULL); for (n = 0; n < arg->expr->rank; n++) { tree idx; idx = gfc_rank_cst[n]; gfc_add_modify (&argse.pre, source_bytes, tmp); lower = gfc_conv_descriptor_lbound_get (argse.expr, idx); upper = gfc_conv_descriptor_ubound_get (argse.expr, idx); tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, upper, lower); gfc_add_modify (&argse.pre, extent, tmp); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, extent, gfc_index_one_node); tmp = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, tmp, source_bytes); } } gfc_add_modify (&argse.pre, source_bytes, tmp); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); /* Now convert MOLD. The outputs are: mold_type = the TREE type of MOLD dest_word_len = destination word length in bytes. */ arg = arg->next; mold_expr = arg->expr; gfc_init_se (&argse, NULL); scalar_mold = arg->expr->rank == 0; if (arg->expr->rank == 0) { gfc_conv_expr_reference (&argse, arg->expr); mold_type = TREE_TYPE (build_fold_indirect_ref_loc (input_location, argse.expr)); } else { gfc_init_se (&argse, NULL); argse.want_pointer = 0; gfc_conv_expr_descriptor (&argse, arg->expr); mold_type = gfc_get_element_type (TREE_TYPE (argse.expr)); } gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); if (strcmp (expr->value.function.name, "__transfer_in_transfer") == 0) { /* If this TRANSFER is nested in another TRANSFER, use a type that preserves all bits. */ if (arg->expr->ts.type == BT_LOGICAL) mold_type = gfc_get_int_type (arg->expr->ts.kind); } /* Obtain the destination word length. */ switch (arg->expr->ts.type) { case BT_CHARACTER: tmp = size_of_string_in_bytes (arg->expr->ts.kind, argse.string_length); mold_type = gfc_get_character_type_len (arg->expr->ts.kind, argse.string_length); break; case BT_CLASS: tmp = gfc_class_vtab_size_get (argse.expr); break; default: tmp = fold_convert (gfc_array_index_type, size_in_bytes (mold_type)); break; } dest_word_len = gfc_create_var (gfc_array_index_type, NULL); gfc_add_modify (&se->pre, dest_word_len, tmp); /* Finally convert SIZE, if it is present. */ arg = arg->next; size_words = gfc_create_var (gfc_array_index_type, NULL); if (arg->expr) { gfc_init_se (&argse, NULL); gfc_conv_expr_reference (&argse, arg->expr); tmp = convert (gfc_array_index_type, build_fold_indirect_ref_loc (input_location, argse.expr)); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); } else tmp = NULL_TREE; /* Separate array and scalar results. */ if (scalar_mold && tmp == NULL_TREE) goto scalar_transfer; size_bytes = gfc_create_var (gfc_array_index_type, NULL); if (tmp != NULL_TREE) tmp = fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, tmp, dest_word_len); else tmp = source_bytes; gfc_add_modify (&se->pre, size_bytes, tmp); gfc_add_modify (&se->pre, size_words, fold_build2_loc (input_location, CEIL_DIV_EXPR, gfc_array_index_type, size_bytes, dest_word_len)); /* Evaluate the bounds of the result. If the loop range exists, we have to check if it is too large. If so, we modify loop->to be consistent with min(size, size(source)). Otherwise, size is made consistent with the loop range, so that the right number of bytes is transferred.*/ n = se->loop->order[0]; if (se->loop->to[n] != NULL_TREE) { tmp = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, se->loop->to[n], se->loop->from[n]); tmp = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, tmp, gfc_index_one_node); tmp = fold_build2_loc (input_location, MIN_EXPR, gfc_array_index_type, tmp, size_words); gfc_add_modify (&se->pre, size_words, tmp); gfc_add_modify (&se->pre, size_bytes, fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, size_words, dest_word_len)); upper = fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, size_words, se->loop->from[n]); upper = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, upper, gfc_index_one_node); } else { upper = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, size_words, gfc_index_one_node); se->loop->from[n] = gfc_index_zero_node; } se->loop->to[n] = upper; /* Build a destination descriptor, using the pointer, source, as the data field. */ gfc_trans_create_temp_array (&se->pre, &se->post, se->ss, mold_type, NULL_TREE, false, true, false, &expr->where); /* Cast the pointer to the result. */ tmp = gfc_conv_descriptor_data_get (info->descriptor); tmp = fold_convert (pvoid_type_node, tmp); /* Use memcpy to do the transfer. */ tmp = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MEMCPY), 3, tmp, fold_convert (pvoid_type_node, source), fold_convert (size_type_node, fold_build2_loc (input_location, MIN_EXPR, gfc_array_index_type, size_bytes, source_bytes))); gfc_add_expr_to_block (&se->pre, tmp); se->expr = info->descriptor; if (expr->ts.type == BT_CHARACTER) { tmp = fold_convert (gfc_charlen_type_node, TYPE_SIZE_UNIT (gfc_get_char_type (expr->ts.kind))); se->string_length = fold_build2_loc (input_location, TRUNC_DIV_EXPR, gfc_charlen_type_node, dest_word_len, tmp); } return; /* Deal with scalar results. */ scalar_transfer: extent = fold_build2_loc (input_location, MIN_EXPR, gfc_array_index_type, dest_word_len, source_bytes); extent = fold_build2_loc (input_location, MAX_EXPR, gfc_array_index_type, extent, gfc_index_zero_node); if (expr->ts.type == BT_CHARACTER) { tree direct, indirect, free; ptr = convert (gfc_get_pchar_type (expr->ts.kind), source); tmpdecl = gfc_create_var (gfc_get_pchar_type (expr->ts.kind), "transfer"); /* If source is longer than the destination, use a pointer to the source directly. */ gfc_init_block (&block); gfc_add_modify (&block, tmpdecl, ptr); direct = gfc_finish_block (&block); /* Otherwise, allocate a string with the length of the destination and copy the source into it. */ gfc_init_block (&block); tmp = gfc_get_pchar_type (expr->ts.kind); tmp = gfc_call_malloc (&block, tmp, dest_word_len); gfc_add_modify (&block, tmpdecl, fold_convert (TREE_TYPE (ptr), tmp)); tmp = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MEMCPY), 3, fold_convert (pvoid_type_node, tmpdecl), fold_convert (pvoid_type_node, ptr), fold_convert (size_type_node, extent)); gfc_add_expr_to_block (&block, tmp); indirect = gfc_finish_block (&block); /* Wrap it up with the condition. */ tmp = fold_build2_loc (input_location, LE_EXPR, logical_type_node, dest_word_len, source_bytes); tmp = build3_v (COND_EXPR, tmp, direct, indirect); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary string, if necessary. */ free = gfc_call_free (tmpdecl); tmp = fold_build2_loc (input_location, GT_EXPR, logical_type_node, dest_word_len, source_bytes); tmp = build3_v (COND_EXPR, tmp, free, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = tmpdecl; tmp = fold_convert (gfc_charlen_type_node, TYPE_SIZE_UNIT (gfc_get_char_type (expr->ts.kind))); se->string_length = fold_build2_loc (input_location, TRUNC_DIV_EXPR, gfc_charlen_type_node, dest_word_len, tmp); } else { tmpdecl = gfc_create_var (mold_type, "transfer"); ptr = convert (build_pointer_type (mold_type), source); /* For CLASS results, allocate the needed memory first. */ if (mold_expr->ts.type == BT_CLASS) { tree cdata; cdata = gfc_class_data_get (tmpdecl); tmp = gfc_call_malloc (&se->pre, TREE_TYPE (cdata), dest_word_len); gfc_add_modify (&se->pre, cdata, tmp); } /* Use memcpy to do the transfer. */ if (mold_expr->ts.type == BT_CLASS) tmp = gfc_class_data_get (tmpdecl); else tmp = gfc_build_addr_expr (NULL_TREE, tmpdecl); tmp = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MEMCPY), 3, fold_convert (pvoid_type_node, tmp), fold_convert (pvoid_type_node, ptr), fold_convert (size_type_node, extent)); gfc_add_expr_to_block (&se->pre, tmp); /* For CLASS results, set the _vptr. */ if (mold_expr->ts.type == BT_CLASS) { tree vptr; gfc_symbol *vtab; vptr = gfc_class_vptr_get (tmpdecl); vtab = gfc_find_derived_vtab (source_expr->ts.u.derived); gcc_assert (vtab); tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify (&se->pre, vptr, fold_convert (TREE_TYPE (vptr), tmp)); } se->expr = tmpdecl; } } /* Generate a call to caf_is_present. */ static tree trans_caf_is_present (gfc_se *se, gfc_expr *expr) { tree caf_reference, caf_decl, token, image_index; /* Compile the reference chain. */ caf_reference = conv_expr_ref_to_caf_ref (&se->pre, expr); gcc_assert (caf_reference != NULL_TREE); caf_decl = gfc_get_tree_for_caf_expr (expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); image_index = gfc_caf_get_image_index (&se->pre, expr, caf_decl); gfc_get_caf_token_offset (se, &token, NULL, caf_decl, NULL, expr); return build_call_expr_loc (input_location, gfor_fndecl_caf_is_present, 3, token, image_index, caf_reference); } /* Test whether this ref-chain refs this image only. */ static bool caf_this_image_ref (gfc_ref *ref) { for ( ; ref; ref = ref->next) if (ref->type == REF_ARRAY && ref->u.ar.codimen) return ref->u.ar.dimen_type[ref->u.ar.dimen] == DIMEN_THIS_IMAGE; return false; } /* Generate code for the ALLOCATED intrinsic. Generate inline code that directly check the address of the argument. */ static void gfc_conv_allocated (gfc_se *se, gfc_expr *expr) { gfc_se arg1se; tree tmp; bool coindexed_caf_comp = false; gfc_expr *e = expr->value.function.actual->expr; gfc_init_se (&arg1se, NULL); if (e->ts.type == BT_CLASS) { /* Make sure that class array expressions have both a _data component reference and an array reference.... */ if (CLASS_DATA (e)->attr.dimension) gfc_add_class_array_ref (e); /* .... whilst scalars only need the _data component. */ else gfc_add_data_component (e); } /* When 'e' references an allocatable component in a coarray, then call the caf-library function caf_is_present (). */ if (flag_coarray == GFC_FCOARRAY_LIB && e->expr_type == EXPR_FUNCTION && e->value.function.isym && e->value.function.isym->id == GFC_ISYM_CAF_GET) { e = e->value.function.actual->expr; if (gfc_expr_attr (e).codimension) { /* Last partref is the coindexed coarray. As coarrays are collectively (de)allocated, the allocation status must be the same as the one of the local allocation. Convert to local access. */ for (gfc_ref *ref = e->ref; ref; ref = ref->next) if (ref->type == REF_ARRAY && ref->u.ar.codimen) { for (int i = ref->u.ar.dimen; i < ref->u.ar.dimen + ref->u.ar.codimen; ++i) ref->u.ar.dimen_type[i] = DIMEN_THIS_IMAGE; break; } } else if (!caf_this_image_ref (e->ref)) coindexed_caf_comp = true; } if (coindexed_caf_comp) tmp = trans_caf_is_present (se, e); else { if (e->rank == 0) { /* Allocatable scalar. */ arg1se.want_pointer = 1; gfc_conv_expr (&arg1se, e); tmp = arg1se.expr; } else { /* Allocatable array. */ arg1se.descriptor_only = 1; gfc_conv_expr_descriptor (&arg1se, e); tmp = gfc_conv_descriptor_data_get (arg1se.expr); } tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, fold_convert (TREE_TYPE (tmp), null_pointer_node)); } /* Components of pointer array references sometimes come back with a pre block. */ if (arg1se.pre.head) gfc_add_block_to_block (&se->pre, &arg1se.pre); se->expr = convert (gfc_typenode_for_spec (&expr->ts), tmp); } /* Generate code for the ASSOCIATED intrinsic. If both POINTER and TARGET are arrays, generate a call to library function _gfor_associated, and pass descriptors of POINTER and TARGET to it. In other cases, generate inline code that directly compare the address of POINTER with the address of TARGET. */ static void gfc_conv_associated (gfc_se *se, gfc_expr *expr) { gfc_actual_arglist *arg1; gfc_actual_arglist *arg2; gfc_se arg1se; gfc_se arg2se; tree tmp2; tree tmp; tree nonzero_arraylen = NULL_TREE; gfc_ss *ss; bool scalar; gfc_init_se (&arg1se, NULL); gfc_init_se (&arg2se, NULL); arg1 = expr->value.function.actual; arg2 = arg1->next; /* Check whether the expression is a scalar or not; we cannot use arg1->expr->rank as it can be nonzero for proc pointers. */ ss = gfc_walk_expr (arg1->expr); scalar = ss == gfc_ss_terminator; if (!scalar) gfc_free_ss_chain (ss); if (!arg2->expr) { /* No optional target. */ if (scalar) { /* A pointer to a scalar. */ arg1se.want_pointer = 1; gfc_conv_expr (&arg1se, arg1->expr); if (arg1->expr->symtree->n.sym->attr.proc_pointer && arg1->expr->symtree->n.sym->attr.dummy) arg1se.expr = build_fold_indirect_ref_loc (input_location, arg1se.expr); if (arg1->expr->ts.type == BT_CLASS) { tmp2 = gfc_class_data_get (arg1se.expr); if (GFC_DESCRIPTOR_TYPE_P (TREE_TYPE (tmp2))) tmp2 = gfc_conv_descriptor_data_get (tmp2); } else tmp2 = arg1se.expr; } else { /* A pointer to an array. */ gfc_conv_expr_descriptor (&arg1se, arg1->expr); tmp2 = gfc_conv_descriptor_data_get (arg1se.expr); } gfc_add_block_to_block (&se->pre, &arg1se.pre); gfc_add_block_to_block (&se->post, &arg1se.post); tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp2, fold_convert (TREE_TYPE (tmp2), null_pointer_node)); se->expr = tmp; } else { /* An optional target. */ if (arg2->expr->ts.type == BT_CLASS && arg2->expr->expr_type != EXPR_FUNCTION) gfc_add_data_component (arg2->expr); if (scalar) { /* A pointer to a scalar. */ arg1se.want_pointer = 1; gfc_conv_expr (&arg1se, arg1->expr); if (arg1->expr->symtree->n.sym->attr.proc_pointer && arg1->expr->symtree->n.sym->attr.dummy) arg1se.expr = build_fold_indirect_ref_loc (input_location, arg1se.expr); if (arg1->expr->ts.type == BT_CLASS) arg1se.expr = gfc_class_data_get (arg1se.expr); arg2se.want_pointer = 1; gfc_conv_expr (&arg2se, arg2->expr); if (arg2->expr->symtree->n.sym->attr.proc_pointer && arg2->expr->symtree->n.sym->attr.dummy) arg2se.expr = build_fold_indirect_ref_loc (input_location, arg2se.expr); if (arg2->expr->ts.type == BT_CLASS) { arg2se.expr = gfc_evaluate_now (arg2se.expr, &arg2se.pre); arg2se.expr = gfc_class_data_get (arg2se.expr); } gfc_add_block_to_block (&se->pre, &arg1se.pre); gfc_add_block_to_block (&se->post, &arg1se.post); gfc_add_block_to_block (&se->pre, &arg2se.pre); gfc_add_block_to_block (&se->post, &arg2se.post); tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg1se.expr, arg2se.expr); tmp2 = fold_build2_loc (input_location, NE_EXPR, logical_type_node, arg1se.expr, null_pointer_node); se->expr = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, tmp, tmp2); } else { /* An array pointer of zero length is not associated if target is present. */ arg1se.descriptor_only = 1; gfc_conv_expr_lhs (&arg1se, arg1->expr); if (arg1->expr->rank == -1) { tmp = gfc_conv_descriptor_rank (arg1se.expr); tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (tmp), tmp, build_int_cst (TREE_TYPE (tmp), 1)); } else tmp = gfc_rank_cst[arg1->expr->rank - 1]; tmp = gfc_conv_descriptor_stride_get (arg1se.expr, tmp); if (arg2->expr->rank != 0) nonzero_arraylen = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, build_int_cst (TREE_TYPE (tmp), 0)); /* A pointer to an array, call library function _gfor_associated. */ arg1se.want_pointer = 1; gfc_conv_expr_descriptor (&arg1se, arg1->expr); gfc_add_block_to_block (&se->pre, &arg1se.pre); gfc_add_block_to_block (&se->post, &arg1se.post); arg2se.want_pointer = 1; arg2se.force_no_tmp = 1; if (arg2->expr->rank != 0) gfc_conv_expr_descriptor (&arg2se, arg2->expr); else { gfc_conv_expr (&arg2se, arg2->expr); arg2se.expr = gfc_conv_scalar_to_descriptor (&arg2se, arg2se.expr, gfc_expr_attr (arg2->expr)); arg2se.expr = gfc_build_addr_expr (NULL_TREE, arg2se.expr); } gfc_add_block_to_block (&se->pre, &arg2se.pre); gfc_add_block_to_block (&se->post, &arg2se.post); se->expr = build_call_expr_loc (input_location, gfor_fndecl_associated, 2, arg1se.expr, arg2se.expr); se->expr = convert (logical_type_node, se->expr); if (arg2->expr->rank != 0) se->expr = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, se->expr, nonzero_arraylen); } /* If target is present zero character length pointers cannot be associated. */ if (arg1->expr->ts.type == BT_CHARACTER) { tmp = arg1se.string_length; tmp = fold_build2_loc (input_location, NE_EXPR, logical_type_node, tmp, build_zero_cst (TREE_TYPE (tmp))); se->expr = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, se->expr, tmp); } } se->expr = convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Generate code for the SAME_TYPE_AS intrinsic. Generate inline code that directly checks the vindices. */ static void gfc_conv_same_type_as (gfc_se *se, gfc_expr *expr) { gfc_expr *a, *b; gfc_se se1, se2; tree tmp; tree conda = NULL_TREE, condb = NULL_TREE; gfc_init_se (&se1, NULL); gfc_init_se (&se2, NULL); a = expr->value.function.actual->expr; b = expr->value.function.actual->next->expr; bool unlimited_poly_a = UNLIMITED_POLY (a); bool unlimited_poly_b = UNLIMITED_POLY (b); if (unlimited_poly_a) { se1.want_pointer = 1; gfc_add_vptr_component (a); } else if (a->ts.type == BT_CLASS) { gfc_add_vptr_component (a); gfc_add_hash_component (a); } else if (a->ts.type == BT_DERIVED) a = gfc_get_int_expr (gfc_default_integer_kind, NULL, a->ts.u.derived->hash_value); if (unlimited_poly_b) { se2.want_pointer = 1; gfc_add_vptr_component (b); } else if (b->ts.type == BT_CLASS) { gfc_add_vptr_component (b); gfc_add_hash_component (b); } else if (b->ts.type == BT_DERIVED) b = gfc_get_int_expr (gfc_default_integer_kind, NULL, b->ts.u.derived->hash_value); gfc_conv_expr (&se1, a); gfc_conv_expr (&se2, b); if (unlimited_poly_a) { conda = fold_build2_loc (input_location, NE_EXPR, logical_type_node, se1.expr, build_int_cst (TREE_TYPE (se1.expr), 0)); se1.expr = gfc_vptr_hash_get (se1.expr); } if (unlimited_poly_b) { condb = fold_build2_loc (input_location, NE_EXPR, logical_type_node, se2.expr, build_int_cst (TREE_TYPE (se2.expr), 0)); se2.expr = gfc_vptr_hash_get (se2.expr); } tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, se1.expr, fold_convert (TREE_TYPE (se1.expr), se2.expr)); if (conda) tmp = fold_build2_loc (input_location, TRUTH_ANDIF_EXPR, logical_type_node, conda, tmp); if (condb) tmp = fold_build2_loc (input_location, TRUTH_ANDIF_EXPR, logical_type_node, condb, tmp); se->expr = convert (gfc_typenode_for_spec (&expr->ts), tmp); } /* Generate code for SELECTED_CHAR_KIND (NAME) intrinsic function. */ static void gfc_conv_intrinsic_sc_kind (gfc_se *se, gfc_expr *expr) { tree args[2]; gfc_conv_intrinsic_function_args (se, expr, args, 2); se->expr = build_call_expr_loc (input_location, gfor_fndecl_sc_kind, 2, args[0], args[1]); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Generate code for SELECTED_INT_KIND (R) intrinsic function. */ static void gfc_conv_intrinsic_si_kind (gfc_se *se, gfc_expr *expr) { tree arg, type; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); /* The argument to SELECTED_INT_KIND is INTEGER(4). */ type = gfc_get_int_type (4); arg = gfc_build_addr_expr (NULL_TREE, fold_convert (type, arg)); /* Convert it to the required type. */ type = gfc_typenode_for_spec (&expr->ts); se->expr = build_call_expr_loc (input_location, gfor_fndecl_si_kind, 1, arg); se->expr = fold_convert (type, se->expr); } /* Generate code for SELECTED_REAL_KIND (P, R, RADIX) intrinsic function. */ static void gfc_conv_intrinsic_sr_kind (gfc_se *se, gfc_expr *expr) { gfc_actual_arglist *actual; tree type; gfc_se argse; vec *args = NULL; for (actual = expr->value.function.actual; actual; actual = actual->next) { gfc_init_se (&argse, se); /* Pass a NULL pointer for an absent arg. */ if (actual->expr == NULL) argse.expr = null_pointer_node; else { gfc_typespec ts; gfc_clear_ts (&ts); if (actual->expr->ts.kind != gfc_c_int_kind) { /* The arguments to SELECTED_REAL_KIND are INTEGER(4). */ ts.type = BT_INTEGER; ts.kind = gfc_c_int_kind; gfc_convert_type (actual->expr, &ts, 2); } gfc_conv_expr_reference (&argse, actual->expr); } gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); vec_safe_push (args, argse.expr); } /* Convert it to the required type. */ type = gfc_typenode_for_spec (&expr->ts); se->expr = build_call_expr_loc_vec (input_location, gfor_fndecl_sr_kind, args); se->expr = fold_convert (type, se->expr); } /* Generate code for TRIM (A) intrinsic function. */ static void gfc_conv_intrinsic_trim (gfc_se * se, gfc_expr * expr) { tree var; tree len; tree addr; tree tmp; tree cond; tree fndecl; tree function; tree *args; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr) + 2; args = XALLOCAVEC (tree, num_args); var = gfc_create_var (gfc_get_pchar_type (expr->ts.kind), "pstr"); addr = gfc_build_addr_expr (ppvoid_type_node, var); len = gfc_create_var (gfc_charlen_type_node, "len"); gfc_conv_intrinsic_function_args (se, expr, &args[2], num_args - 2); args[0] = gfc_build_addr_expr (NULL_TREE, len); args[1] = addr; if (expr->ts.kind == 1) function = gfor_fndecl_string_trim; else if (expr->ts.kind == 4) function = gfor_fndecl_string_trim_char4; else gcc_unreachable (); fndecl = build_addr (function); tmp = build_call_array_loc (input_location, TREE_TYPE (TREE_TYPE (function)), fndecl, num_args, args); gfc_add_expr_to_block (&se->pre, tmp); /* Free the temporary afterwards, if necessary. */ cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); tmp = gfc_call_free (var); tmp = build3_v (COND_EXPR, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&se->post, tmp); se->expr = var; se->string_length = len; } /* Generate code for REPEAT (STRING, NCOPIES) intrinsic function. */ static void gfc_conv_intrinsic_repeat (gfc_se * se, gfc_expr * expr) { tree args[3], ncopies, dest, dlen, src, slen, ncopies_type; tree type, cond, tmp, count, exit_label, n, max, largest; tree size; stmtblock_t block, body; int i; /* We store in charsize the size of a character. */ i = gfc_validate_kind (BT_CHARACTER, expr->ts.kind, false); size = build_int_cst (sizetype, gfc_character_kinds[i].bit_size / 8); /* Get the arguments. */ gfc_conv_intrinsic_function_args (se, expr, args, 3); slen = fold_convert (sizetype, gfc_evaluate_now (args[0], &se->pre)); src = args[1]; ncopies = gfc_evaluate_now (args[2], &se->pre); ncopies_type = TREE_TYPE (ncopies); /* Check that NCOPIES is not negative. */ cond = fold_build2_loc (input_location, LT_EXPR, logical_type_node, ncopies, build_int_cst (ncopies_type, 0)); gfc_trans_runtime_check (true, false, cond, &se->pre, &expr->where, "Argument NCOPIES of REPEAT intrinsic is negative " "(its value is %ld)", fold_convert (long_integer_type_node, ncopies)); /* If the source length is zero, any non negative value of NCOPIES is valid, and nothing happens. */ n = gfc_create_var (ncopies_type, "ncopies"); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, slen, size_zero_node); tmp = fold_build3_loc (input_location, COND_EXPR, ncopies_type, cond, build_int_cst (ncopies_type, 0), ncopies); gfc_add_modify (&se->pre, n, tmp); ncopies = n; /* Check that ncopies is not too large: ncopies should be less than (or equal to) MAX / slen, where MAX is the maximal integer of the gfc_charlen_type_node type. If slen == 0, we need a special case to avoid the division by zero. */ max = fold_build2_loc (input_location, TRUNC_DIV_EXPR, sizetype, fold_convert (sizetype, TYPE_MAX_VALUE (gfc_charlen_type_node)), slen); largest = TYPE_PRECISION (sizetype) > TYPE_PRECISION (ncopies_type) ? sizetype : ncopies_type; cond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, fold_convert (largest, ncopies), fold_convert (largest, max)); tmp = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, slen, size_zero_node); cond = fold_build3_loc (input_location, COND_EXPR, logical_type_node, tmp, logical_false_node, cond); gfc_trans_runtime_check (true, false, cond, &se->pre, &expr->where, "Argument NCOPIES of REPEAT intrinsic is too large"); /* Compute the destination length. */ dlen = fold_build2_loc (input_location, MULT_EXPR, gfc_charlen_type_node, fold_convert (gfc_charlen_type_node, slen), fold_convert (gfc_charlen_type_node, ncopies)); type = gfc_get_character_type (expr->ts.kind, expr->ts.u.cl); dest = gfc_conv_string_tmp (se, build_pointer_type (type), dlen); /* Generate the code to do the repeat operation: for (i = 0; i < ncopies; i++) memmove (dest + (i * slen * size), src, slen*size); */ gfc_start_block (&block); count = gfc_create_var (sizetype, "count"); gfc_add_modify (&block, count, size_zero_node); exit_label = gfc_build_label_decl (NULL_TREE); /* Start the loop body. */ gfc_start_block (&body); /* Exit the loop if count >= ncopies. */ cond = fold_build2_loc (input_location, GE_EXPR, logical_type_node, count, fold_convert (sizetype, ncopies)); tmp = build1_v (GOTO_EXPR, exit_label); TREE_USED (exit_label) = 1; tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&body, tmp); /* Call memmove (dest + (i*slen*size), src, slen*size). */ tmp = fold_build2_loc (input_location, MULT_EXPR, sizetype, slen, count); tmp = fold_build2_loc (input_location, MULT_EXPR, sizetype, tmp, size); tmp = fold_build_pointer_plus_loc (input_location, fold_convert (pvoid_type_node, dest), tmp); tmp = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MEMMOVE), 3, tmp, src, fold_build2_loc (input_location, MULT_EXPR, size_type_node, slen, size)); gfc_add_expr_to_block (&body, tmp); /* Increment count. */ tmp = fold_build2_loc (input_location, PLUS_EXPR, sizetype, count, size_one_node); gfc_add_modify (&body, count, tmp); /* Build the loop. */ tmp = build1_v (LOOP_EXPR, gfc_finish_block (&body)); gfc_add_expr_to_block (&block, tmp); /* Add the exit label. */ tmp = build1_v (LABEL_EXPR, exit_label); gfc_add_expr_to_block (&block, tmp); /* Finish the block. */ tmp = gfc_finish_block (&block); gfc_add_expr_to_block (&se->pre, tmp); /* Set the result value. */ se->expr = dest; se->string_length = dlen; } /* Generate code for the IARGC intrinsic. */ static void gfc_conv_intrinsic_iargc (gfc_se * se, gfc_expr * expr) { tree tmp; tree fndecl; tree type; /* Call the library function. This always returns an INTEGER(4). */ fndecl = gfor_fndecl_iargc; tmp = build_call_expr_loc (input_location, fndecl, 0); /* Convert it to the required type. */ type = gfc_typenode_for_spec (&expr->ts); tmp = fold_convert (type, tmp); se->expr = tmp; } /* Generate code for the KILL intrinsic. */ static void conv_intrinsic_kill (gfc_se *se, gfc_expr *expr) { tree *args; tree int4_type_node = gfc_get_int_type (4); tree pid; tree sig; tree tmp; unsigned int num_args; num_args = gfc_intrinsic_argument_list_length (expr); args = XALLOCAVEC (tree, num_args); gfc_conv_intrinsic_function_args (se, expr, args, num_args); /* Convert PID to a INTEGER(4) entity. */ pid = convert (int4_type_node, args[0]); /* Convert SIG to a INTEGER(4) entity. */ sig = convert (int4_type_node, args[1]); tmp = build_call_expr_loc (input_location, gfor_fndecl_kill, 2, pid, sig); se->expr = fold_convert (TREE_TYPE (args[0]), tmp); } static tree conv_intrinsic_kill_sub (gfc_code *code) { stmtblock_t block; gfc_se se, se_stat; tree int4_type_node = gfc_get_int_type (4); tree pid; tree sig; tree statp; tree tmp; /* Make the function call. */ gfc_init_block (&block); gfc_init_se (&se, NULL); /* Convert PID to a INTEGER(4) entity. */ gfc_conv_expr (&se, code->ext.actual->expr); gfc_add_block_to_block (&block, &se.pre); pid = fold_convert (int4_type_node, gfc_evaluate_now (se.expr, &block)); gfc_add_block_to_block (&block, &se.post); /* Convert SIG to a INTEGER(4) entity. */ gfc_conv_expr (&se, code->ext.actual->next->expr); gfc_add_block_to_block (&block, &se.pre); sig = fold_convert (int4_type_node, gfc_evaluate_now (se.expr, &block)); gfc_add_block_to_block (&block, &se.post); /* Deal with an optional STATUS. */ if (code->ext.actual->next->next->expr) { gfc_init_se (&se_stat, NULL); gfc_conv_expr (&se_stat, code->ext.actual->next->next->expr); statp = gfc_create_var (gfc_get_int_type (4), "_statp"); } else statp = NULL_TREE; tmp = build_call_expr_loc (input_location, gfor_fndecl_kill_sub, 3, pid, sig, statp ? gfc_build_addr_expr (NULL_TREE, statp) : null_pointer_node); gfc_add_expr_to_block (&block, tmp); if (statp && statp != se_stat.expr) gfc_add_modify (&block, se_stat.expr, fold_convert (TREE_TYPE (se_stat.expr), statp)); return gfc_finish_block (&block); } /* The loc intrinsic returns the address of its argument as gfc_index_integer_kind integer. */ static void gfc_conv_intrinsic_loc (gfc_se * se, gfc_expr * expr) { tree temp_var; gfc_expr *arg_expr; gcc_assert (!se->ss); arg_expr = expr->value.function.actual->expr; if (arg_expr->rank == 0) { if (arg_expr->ts.type == BT_CLASS) gfc_add_data_component (arg_expr); gfc_conv_expr_reference (se, arg_expr); } else gfc_conv_array_parameter (se, arg_expr, true, NULL, NULL, NULL); se->expr = convert (gfc_get_int_type (gfc_index_integer_kind), se->expr); /* Create a temporary variable for loc return value. Without this, we get an error an ICE in gcc/expr.cc(expand_expr_addr_expr_1). */ temp_var = gfc_create_var (gfc_get_int_type (gfc_index_integer_kind), NULL); gfc_add_modify (&se->pre, temp_var, se->expr); se->expr = temp_var; } /* The following routine generates code for the intrinsic functions from the ISO_C_BINDING module: * C_LOC * C_FUNLOC * C_ASSOCIATED */ static void conv_isocbinding_function (gfc_se *se, gfc_expr *expr) { gfc_actual_arglist *arg = expr->value.function.actual; if (expr->value.function.isym->id == GFC_ISYM_C_LOC) { if (arg->expr->rank == 0) gfc_conv_expr_reference (se, arg->expr); else if (gfc_is_simply_contiguous (arg->expr, false, false)) gfc_conv_array_parameter (se, arg->expr, true, NULL, NULL, NULL); else { gfc_conv_expr_descriptor (se, arg->expr); se->expr = gfc_conv_descriptor_data_get (se->expr); } /* TODO -- the following two lines shouldn't be necessary, but if they're removed, a bug is exposed later in the code path. This workaround was thus introduced, but will have to be removed; please see PR 35150 for details about the issue. */ se->expr = convert (pvoid_type_node, se->expr); se->expr = gfc_evaluate_now (se->expr, &se->pre); } else if (expr->value.function.isym->id == GFC_ISYM_C_FUNLOC) gfc_conv_expr_reference (se, arg->expr); else if (expr->value.function.isym->id == GFC_ISYM_C_ASSOCIATED) { gfc_se arg1se; gfc_se arg2se; /* Build the addr_expr for the first argument. The argument is already an *address* so we don't need to set want_pointer in the gfc_se. */ gfc_init_se (&arg1se, NULL); gfc_conv_expr (&arg1se, arg->expr); gfc_add_block_to_block (&se->pre, &arg1se.pre); gfc_add_block_to_block (&se->post, &arg1se.post); /* See if we were given two arguments. */ if (arg->next->expr == NULL) /* Only given one arg so generate a null and do a not-equal comparison against the first arg. */ se->expr = fold_build2_loc (input_location, NE_EXPR, logical_type_node, arg1se.expr, fold_convert (TREE_TYPE (arg1se.expr), null_pointer_node)); else { tree eq_expr; tree not_null_expr; /* Given two arguments so build the arg2se from second arg. */ gfc_init_se (&arg2se, NULL); gfc_conv_expr (&arg2se, arg->next->expr); gfc_add_block_to_block (&se->pre, &arg2se.pre); gfc_add_block_to_block (&se->post, &arg2se.post); /* Generate test to compare that the two args are equal. */ eq_expr = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg1se.expr, arg2se.expr); /* Generate test to ensure that the first arg is not null. */ not_null_expr = fold_build2_loc (input_location, NE_EXPR, logical_type_node, arg1se.expr, null_pointer_node); /* Finally, the generated test must check that both arg1 is not NULL and that it is equal to the second arg. */ se->expr = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, not_null_expr, eq_expr); } } else gcc_unreachable (); } /* The following routine generates code for the intrinsic subroutines from the ISO_C_BINDING module: * C_F_POINTER * C_F_PROCPOINTER. */ static tree conv_isocbinding_subroutine (gfc_code *code) { gfc_se se; gfc_se cptrse; gfc_se fptrse; gfc_se shapese; gfc_ss *shape_ss; tree desc, dim, tmp, stride, offset; stmtblock_t body, block; gfc_loopinfo loop; gfc_actual_arglist *arg = code->ext.actual; gfc_init_se (&se, NULL); gfc_init_se (&cptrse, NULL); gfc_conv_expr (&cptrse, arg->expr); gfc_add_block_to_block (&se.pre, &cptrse.pre); gfc_add_block_to_block (&se.post, &cptrse.post); gfc_init_se (&fptrse, NULL); if (arg->next->expr->rank == 0) { fptrse.want_pointer = 1; gfc_conv_expr (&fptrse, arg->next->expr); gfc_add_block_to_block (&se.pre, &fptrse.pre); gfc_add_block_to_block (&se.post, &fptrse.post); if (arg->next->expr->symtree->n.sym->attr.proc_pointer && arg->next->expr->symtree->n.sym->attr.dummy) fptrse.expr = build_fold_indirect_ref_loc (input_location, fptrse.expr); se.expr = fold_build2_loc (input_location, MODIFY_EXPR, TREE_TYPE (fptrse.expr), fptrse.expr, fold_convert (TREE_TYPE (fptrse.expr), cptrse.expr)); gfc_add_expr_to_block (&se.pre, se.expr); gfc_add_block_to_block (&se.pre, &se.post); return gfc_finish_block (&se.pre); } gfc_start_block (&block); /* Get the descriptor of the Fortran pointer. */ fptrse.descriptor_only = 1; gfc_conv_expr_descriptor (&fptrse, arg->next->expr); gfc_add_block_to_block (&block, &fptrse.pre); desc = fptrse.expr; /* Set the span field. */ tmp = TYPE_SIZE_UNIT (gfc_get_element_type (TREE_TYPE (desc))); tmp = fold_convert (gfc_array_index_type, tmp); gfc_conv_descriptor_span_set (&block, desc, tmp); /* Set data value, dtype, and offset. */ tmp = GFC_TYPE_ARRAY_DATAPTR_TYPE (TREE_TYPE (desc)); gfc_conv_descriptor_data_set (&block, desc, fold_convert (tmp, cptrse.expr)); gfc_add_modify (&block, gfc_conv_descriptor_dtype (desc), gfc_get_dtype (TREE_TYPE (desc))); /* Start scalarization of the bounds, using the shape argument. */ shape_ss = gfc_walk_expr (arg->next->next->expr); gcc_assert (shape_ss != gfc_ss_terminator); gfc_init_se (&shapese, NULL); gfc_init_loopinfo (&loop); gfc_add_ss_to_loop (&loop, shape_ss); gfc_conv_ss_startstride (&loop); gfc_conv_loop_setup (&loop, &arg->next->expr->where); gfc_mark_ss_chain_used (shape_ss, 1); gfc_copy_loopinfo_to_se (&shapese, &loop); shapese.ss = shape_ss; stride = gfc_create_var (gfc_array_index_type, "stride"); offset = gfc_create_var (gfc_array_index_type, "offset"); gfc_add_modify (&block, stride, gfc_index_one_node); gfc_add_modify (&block, offset, gfc_index_zero_node); /* Loop body. */ gfc_start_scalarized_body (&loop, &body); dim = fold_build2_loc (input_location, MINUS_EXPR, gfc_array_index_type, loop.loopvar[0], loop.from[0]); /* Set bounds and stride. */ gfc_conv_descriptor_lbound_set (&body, desc, dim, gfc_index_one_node); gfc_conv_descriptor_stride_set (&body, desc, dim, stride); gfc_conv_expr (&shapese, arg->next->next->expr); gfc_add_block_to_block (&body, &shapese.pre); gfc_conv_descriptor_ubound_set (&body, desc, dim, shapese.expr); gfc_add_block_to_block (&body, &shapese.post); /* Calculate offset. */ gfc_add_modify (&body, offset, fold_build2_loc (input_location, PLUS_EXPR, gfc_array_index_type, offset, stride)); /* Update stride. */ gfc_add_modify (&body, stride, fold_build2_loc (input_location, MULT_EXPR, gfc_array_index_type, stride, fold_convert (gfc_array_index_type, shapese.expr))); /* Finish scalarization loop. */ gfc_trans_scalarizing_loops (&loop, &body); gfc_add_block_to_block (&block, &loop.pre); gfc_add_block_to_block (&block, &loop.post); gfc_add_block_to_block (&block, &fptrse.post); gfc_cleanup_loop (&loop); gfc_add_modify (&block, offset, fold_build1_loc (input_location, NEGATE_EXPR, gfc_array_index_type, offset)); gfc_conv_descriptor_offset_set (&block, desc, offset); gfc_add_expr_to_block (&se.pre, gfc_finish_block (&block)); gfc_add_block_to_block (&se.pre, &se.post); return gfc_finish_block (&se.pre); } /* Save and restore floating-point state. */ tree gfc_save_fp_state (stmtblock_t *block) { tree type, fpstate, tmp; type = build_array_type (char_type_node, build_range_type (size_type_node, size_zero_node, size_int (GFC_FPE_STATE_BUFFER_SIZE))); fpstate = gfc_create_var (type, "fpstate"); fpstate = gfc_build_addr_expr (pvoid_type_node, fpstate); tmp = build_call_expr_loc (input_location, gfor_fndecl_ieee_procedure_entry, 1, fpstate); gfc_add_expr_to_block (block, tmp); return fpstate; } void gfc_restore_fp_state (stmtblock_t *block, tree fpstate) { tree tmp; tmp = build_call_expr_loc (input_location, gfor_fndecl_ieee_procedure_exit, 1, fpstate); gfc_add_expr_to_block (block, tmp); } /* Generate code for arguments of IEEE functions. */ static void conv_ieee_function_args (gfc_se *se, gfc_expr *expr, tree *argarray, int nargs) { gfc_actual_arglist *actual; gfc_expr *e; gfc_se argse; int arg; actual = expr->value.function.actual; for (arg = 0; arg < nargs; arg++, actual = actual->next) { gcc_assert (actual); e = actual->expr; gfc_init_se (&argse, se); gfc_conv_expr_val (&argse, e); gfc_add_block_to_block (&se->pre, &argse.pre); gfc_add_block_to_block (&se->post, &argse.post); argarray[arg] = argse.expr; } } /* Generate code for intrinsics IEEE_IS_NAN, IEEE_IS_FINITE, and IEEE_UNORDERED, which translate directly to GCC type-generic built-ins. */ static void conv_intrinsic_ieee_builtin (gfc_se * se, gfc_expr * expr, enum built_in_function code, int nargs) { tree args[2]; gcc_assert ((unsigned) nargs <= ARRAY_SIZE (args)); conv_ieee_function_args (se, expr, args, nargs); se->expr = build_call_expr_loc_array (input_location, builtin_decl_explicit (code), nargs, args); STRIP_TYPE_NOPS (se->expr); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Generate code for IEEE_IS_NORMAL intrinsic: IEEE_IS_NORMAL(x) --> (__builtin_isnormal(x) || x == 0) */ static void conv_intrinsic_ieee_is_normal (gfc_se * se, gfc_expr * expr) { tree arg, isnormal, iszero; /* Convert arg, evaluate it only once. */ conv_ieee_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); isnormal = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISNORMAL), 1, arg); iszero = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, arg, build_real_from_int_cst (TREE_TYPE (arg), integer_zero_node)); se->expr = fold_build2_loc (input_location, TRUTH_OR_EXPR, logical_type_node, isnormal, iszero); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Generate code for IEEE_IS_NEGATIVE intrinsic: IEEE_IS_NEGATIVE(x) --> (__builtin_signbit(x) && !__builtin_isnan(x)) */ static void conv_intrinsic_ieee_is_negative (gfc_se * se, gfc_expr * expr) { tree arg, signbit, isnan; /* Convert arg, evaluate it only once. */ conv_ieee_function_args (se, expr, &arg, 1); arg = gfc_evaluate_now (arg, &se->pre); isnan = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_ISNAN), 1, arg); STRIP_TYPE_NOPS (isnan); signbit = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_SIGNBIT), 1, arg); signbit = fold_build2_loc (input_location, NE_EXPR, logical_type_node, signbit, integer_zero_node); se->expr = fold_build2_loc (input_location, TRUTH_AND_EXPR, logical_type_node, signbit, fold_build1_loc (input_location, TRUTH_NOT_EXPR, TREE_TYPE(isnan), isnan)); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), se->expr); } /* Generate code for IEEE_LOGB and IEEE_RINT. */ static void conv_intrinsic_ieee_logb_rint (gfc_se * se, gfc_expr * expr, enum built_in_function code) { tree arg, decl, call, fpstate; int argprec; conv_ieee_function_args (se, expr, &arg, 1); argprec = TYPE_PRECISION (TREE_TYPE (arg)); decl = builtin_decl_for_precision (code, argprec); /* Save floating-point state. */ fpstate = gfc_save_fp_state (&se->pre); /* Make the function call. */ call = build_call_expr_loc (input_location, decl, 1, arg); se->expr = fold_convert (gfc_typenode_for_spec (&expr->ts), call); /* Restore floating-point state. */ gfc_restore_fp_state (&se->post, fpstate); } /* Generate code for IEEE_REM. */ static void conv_intrinsic_ieee_rem (gfc_se * se, gfc_expr * expr) { tree args[2], decl, call, fpstate; int argprec; conv_ieee_function_args (se, expr, args, 2); /* If arguments have unequal size, convert them to the larger. */ if (TYPE_PRECISION (TREE_TYPE (args[0])) > TYPE_PRECISION (TREE_TYPE (args[1]))) args[1] = fold_convert (TREE_TYPE (args[0]), args[1]); else if (TYPE_PRECISION (TREE_TYPE (args[1])) > TYPE_PRECISION (TREE_TYPE (args[0]))) args[0] = fold_convert (TREE_TYPE (args[1]), args[0]); argprec = TYPE_PRECISION (TREE_TYPE (args[0])); decl = builtin_decl_for_precision (BUILT_IN_REMAINDER, argprec); /* Save floating-point state. */ fpstate = gfc_save_fp_state (&se->pre); /* Make the function call. */ call = build_call_expr_loc_array (input_location, decl, 2, args); se->expr = fold_convert (TREE_TYPE (args[0]), call); /* Restore floating-point state. */ gfc_restore_fp_state (&se->post, fpstate); } /* Generate code for IEEE_NEXT_AFTER. */ static void conv_intrinsic_ieee_next_after (gfc_se * se, gfc_expr * expr) { tree args[2], decl, call, fpstate; int argprec; conv_ieee_function_args (se, expr, args, 2); /* Result has the characteristics of first argument. */ args[1] = fold_convert (TREE_TYPE (args[0]), args[1]); argprec = TYPE_PRECISION (TREE_TYPE (args[0])); decl = builtin_decl_for_precision (BUILT_IN_NEXTAFTER, argprec); /* Save floating-point state. */ fpstate = gfc_save_fp_state (&se->pre); /* Make the function call. */ call = build_call_expr_loc_array (input_location, decl, 2, args); se->expr = fold_convert (TREE_TYPE (args[0]), call); /* Restore floating-point state. */ gfc_restore_fp_state (&se->post, fpstate); } /* Generate code for IEEE_SCALB. */ static void conv_intrinsic_ieee_scalb (gfc_se * se, gfc_expr * expr) { tree args[2], decl, call, huge, type; int argprec, n; conv_ieee_function_args (se, expr, args, 2); /* Result has the characteristics of first argument. */ argprec = TYPE_PRECISION (TREE_TYPE (args[0])); decl = builtin_decl_for_precision (BUILT_IN_SCALBN, argprec); if (TYPE_PRECISION (TREE_TYPE (args[1])) > TYPE_PRECISION (integer_type_node)) { /* We need to fold the integer into the range of a C int. */ args[1] = gfc_evaluate_now (args[1], &se->pre); type = TREE_TYPE (args[1]); n = gfc_validate_kind (BT_INTEGER, gfc_c_int_kind, false); huge = gfc_conv_mpz_to_tree (gfc_integer_kinds[n].huge, gfc_c_int_kind); huge = fold_convert (type, huge); args[1] = fold_build2_loc (input_location, MIN_EXPR, type, args[1], huge); args[1] = fold_build2_loc (input_location, MAX_EXPR, type, args[1], fold_build1_loc (input_location, NEGATE_EXPR, type, huge)); } args[1] = fold_convert (integer_type_node, args[1]); /* Make the function call. */ call = build_call_expr_loc_array (input_location, decl, 2, args); se->expr = fold_convert (TREE_TYPE (args[0]), call); } /* Generate code for IEEE_COPY_SIGN. */ static void conv_intrinsic_ieee_copy_sign (gfc_se * se, gfc_expr * expr) { tree args[2], decl, sign; int argprec; conv_ieee_function_args (se, expr, args, 2); /* Get the sign of the second argument. */ sign = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_SIGNBIT), 1, args[1]); sign = fold_build2_loc (input_location, NE_EXPR, logical_type_node, sign, integer_zero_node); /* Create a value of one, with the right sign. */ sign = fold_build3_loc (input_location, COND_EXPR, integer_type_node, sign, fold_build1_loc (input_location, NEGATE_EXPR, integer_type_node, integer_one_node), integer_one_node); args[1] = fold_convert (TREE_TYPE (args[0]), sign); argprec = TYPE_PRECISION (TREE_TYPE (args[0])); decl = builtin_decl_for_precision (BUILT_IN_COPYSIGN, argprec); se->expr = build_call_expr_loc_array (input_location, decl, 2, args); } /* Generate code for an intrinsic function from the IEEE_ARITHMETIC module. */ bool gfc_conv_ieee_arithmetic_function (gfc_se * se, gfc_expr * expr) { const char *name = expr->value.function.name; if (startswith (name, "_gfortran_ieee_is_nan")) conv_intrinsic_ieee_builtin (se, expr, BUILT_IN_ISNAN, 1); else if (startswith (name, "_gfortran_ieee_is_finite")) conv_intrinsic_ieee_builtin (se, expr, BUILT_IN_ISFINITE, 1); else if (startswith (name, "_gfortran_ieee_unordered")) conv_intrinsic_ieee_builtin (se, expr, BUILT_IN_ISUNORDERED, 2); else if (startswith (name, "_gfortran_ieee_is_normal")) conv_intrinsic_ieee_is_normal (se, expr); else if (startswith (name, "_gfortran_ieee_is_negative")) conv_intrinsic_ieee_is_negative (se, expr); else if (startswith (name, "_gfortran_ieee_copy_sign")) conv_intrinsic_ieee_copy_sign (se, expr); else if (startswith (name, "_gfortran_ieee_scalb")) conv_intrinsic_ieee_scalb (se, expr); else if (startswith (name, "_gfortran_ieee_next_after")) conv_intrinsic_ieee_next_after (se, expr); else if (startswith (name, "_gfortran_ieee_rem")) conv_intrinsic_ieee_rem (se, expr); else if (startswith (name, "_gfortran_ieee_logb")) conv_intrinsic_ieee_logb_rint (se, expr, BUILT_IN_LOGB); else if (startswith (name, "_gfortran_ieee_rint")) conv_intrinsic_ieee_logb_rint (se, expr, BUILT_IN_RINT); else /* It is not among the functions we translate directly. We return false, so a library function call is emitted. */ return false; return true; } /* Generate a direct call to malloc() for the MALLOC intrinsic. */ static void gfc_conv_intrinsic_malloc (gfc_se * se, gfc_expr * expr) { tree arg, res, restype; gfc_conv_intrinsic_function_args (se, expr, &arg, 1); arg = fold_convert (size_type_node, arg); res = build_call_expr_loc (input_location, builtin_decl_explicit (BUILT_IN_MALLOC), 1, arg); restype = gfc_typenode_for_spec (&expr->ts); se->expr = fold_convert (restype, res); } /* Generate code for an intrinsic function. Some map directly to library calls, others get special handling. In some cases the name of the function used depends on the type specifiers. */ void gfc_conv_intrinsic_function (gfc_se * se, gfc_expr * expr) { const char *name; int lib, kind; tree fndecl; name = &expr->value.function.name[2]; if (expr->rank > 0) { lib = gfc_is_intrinsic_libcall (expr); if (lib != 0) { if (lib == 1) se->ignore_optional = 1; switch (expr->value.function.isym->id) { case GFC_ISYM_EOSHIFT: case GFC_ISYM_PACK: case GFC_ISYM_RESHAPE: /* For all of those the first argument specifies the type and the third is optional. */ conv_generic_with_optional_char_arg (se, expr, 1, 3); break; case GFC_ISYM_FINDLOC: gfc_conv_intrinsic_findloc (se, expr); break; case GFC_ISYM_MINLOC: gfc_conv_intrinsic_minmaxloc (se, expr, LT_EXPR); break; case GFC_ISYM_MAXLOC: gfc_conv_intrinsic_minmaxloc (se, expr, GT_EXPR); break; default: gfc_conv_intrinsic_funcall (se, expr); break; } return; } } switch (expr->value.function.isym->id) { case GFC_ISYM_NONE: gcc_unreachable (); case GFC_ISYM_REPEAT: gfc_conv_intrinsic_repeat (se, expr); break; case GFC_ISYM_TRIM: gfc_conv_intrinsic_trim (se, expr); break; case GFC_ISYM_SC_KIND: gfc_conv_intrinsic_sc_kind (se, expr); break; case GFC_ISYM_SI_KIND: gfc_conv_intrinsic_si_kind (se, expr); break; case GFC_ISYM_SR_KIND: gfc_conv_intrinsic_sr_kind (se, expr); break; case GFC_ISYM_EXPONENT: gfc_conv_intrinsic_exponent (se, expr); break; case GFC_ISYM_SCAN: kind = expr->value.function.actual->expr->ts.kind; if (kind == 1) fndecl = gfor_fndecl_string_scan; else if (kind == 4) fndecl = gfor_fndecl_string_scan_char4; else gcc_unreachable (); gfc_conv_intrinsic_index_scan_verify (se, expr, fndecl); break; case GFC_ISYM_VERIFY: kind = expr->value.function.actual->expr->ts.kind; if (kind == 1) fndecl = gfor_fndecl_string_verify; else if (kind == 4) fndecl = gfor_fndecl_string_verify_char4; else gcc_unreachable (); gfc_conv_intrinsic_index_scan_verify (se, expr, fndecl); break; case GFC_ISYM_ALLOCATED: gfc_conv_allocated (se, expr); break; case GFC_ISYM_ASSOCIATED: gfc_conv_associated(se, expr); break; case GFC_ISYM_SAME_TYPE_AS: gfc_conv_same_type_as (se, expr); break; case GFC_ISYM_ABS: gfc_conv_intrinsic_abs (se, expr); break; case GFC_ISYM_ADJUSTL: if (expr->ts.kind == 1) fndecl = gfor_fndecl_adjustl; else if (expr->ts.kind == 4) fndecl = gfor_fndecl_adjustl_char4; else gcc_unreachable (); gfc_conv_intrinsic_adjust (se, expr, fndecl); break; case GFC_ISYM_ADJUSTR: if (expr->ts.kind == 1) fndecl = gfor_fndecl_adjustr; else if (expr->ts.kind == 4) fndecl = gfor_fndecl_adjustr_char4; else gcc_unreachable (); gfc_conv_intrinsic_adjust (se, expr, fndecl); break; case GFC_ISYM_AIMAG: gfc_conv_intrinsic_imagpart (se, expr); break; case GFC_ISYM_AINT: gfc_conv_intrinsic_aint (se, expr, RND_TRUNC); break; case GFC_ISYM_ALL: gfc_conv_intrinsic_anyall (se, expr, EQ_EXPR); break; case GFC_ISYM_ANINT: gfc_conv_intrinsic_aint (se, expr, RND_ROUND); break; case GFC_ISYM_AND: gfc_conv_intrinsic_bitop (se, expr, BIT_AND_EXPR); break; case GFC_ISYM_ANY: gfc_conv_intrinsic_anyall (se, expr, NE_EXPR); break; case GFC_ISYM_ACOSD: case GFC_ISYM_ASIND: case GFC_ISYM_ATAND: gfc_conv_intrinsic_atrigd (se, expr, expr->value.function.isym->id); break; case GFC_ISYM_COTAN: gfc_conv_intrinsic_cotan (se, expr); break; case GFC_ISYM_COTAND: gfc_conv_intrinsic_cotand (se, expr); break; case GFC_ISYM_ATAN2D: gfc_conv_intrinsic_atan2d (se, expr); break; case GFC_ISYM_BTEST: gfc_conv_intrinsic_btest (se, expr); break; case GFC_ISYM_BGE: gfc_conv_intrinsic_bitcomp (se, expr, GE_EXPR); break; case GFC_ISYM_BGT: gfc_conv_intrinsic_bitcomp (se, expr, GT_EXPR); break; case GFC_ISYM_BLE: gfc_conv_intrinsic_bitcomp (se, expr, LE_EXPR); break; case GFC_ISYM_BLT: gfc_conv_intrinsic_bitcomp (se, expr, LT_EXPR); break; case GFC_ISYM_C_ASSOCIATED: case GFC_ISYM_C_FUNLOC: case GFC_ISYM_C_LOC: conv_isocbinding_function (se, expr); break; case GFC_ISYM_ACHAR: case GFC_ISYM_CHAR: gfc_conv_intrinsic_char (se, expr); break; case GFC_ISYM_CONVERSION: case GFC_ISYM_DBLE: case GFC_ISYM_DFLOAT: case GFC_ISYM_FLOAT: case GFC_ISYM_LOGICAL: case GFC_ISYM_REAL: case GFC_ISYM_REALPART: case GFC_ISYM_SNGL: gfc_conv_intrinsic_conversion (se, expr); break; /* Integer conversions are handled separately to make sure we get the correct rounding mode. */ case GFC_ISYM_INT: case GFC_ISYM_INT2: case GFC_ISYM_INT8: case GFC_ISYM_LONG: gfc_conv_intrinsic_int (se, expr, RND_TRUNC); break; case GFC_ISYM_NINT: gfc_conv_intrinsic_int (se, expr, RND_ROUND); break; case GFC_ISYM_CEILING: gfc_conv_intrinsic_int (se, expr, RND_CEIL); break; case GFC_ISYM_FLOOR: gfc_conv_intrinsic_int (se, expr, RND_FLOOR); break; case GFC_ISYM_MOD: gfc_conv_intrinsic_mod (se, expr, 0); break; case GFC_ISYM_MODULO: gfc_conv_intrinsic_mod (se, expr, 1); break; case GFC_ISYM_CAF_GET: gfc_conv_intrinsic_caf_get (se, expr, NULL_TREE, NULL_TREE, NULL_TREE, false, NULL); break; case GFC_ISYM_CMPLX: gfc_conv_intrinsic_cmplx (se, expr, name[5] == '1'); break; case GFC_ISYM_COMMAND_ARGUMENT_COUNT: gfc_conv_intrinsic_iargc (se, expr); break; case GFC_ISYM_COMPLEX: gfc_conv_intrinsic_cmplx (se, expr, 1); break; case GFC_ISYM_CONJG: gfc_conv_intrinsic_conjg (se, expr); break; case GFC_ISYM_COUNT: gfc_conv_intrinsic_count (se, expr); break; case GFC_ISYM_CTIME: gfc_conv_intrinsic_ctime (se, expr); break; case GFC_ISYM_DIM: gfc_conv_intrinsic_dim (se, expr); break; case GFC_ISYM_DOT_PRODUCT: gfc_conv_intrinsic_dot_product (se, expr); break; case GFC_ISYM_DPROD: gfc_conv_intrinsic_dprod (se, expr); break; case GFC_ISYM_DSHIFTL: gfc_conv_intrinsic_dshift (se, expr, true); break; case GFC_ISYM_DSHIFTR: gfc_conv_intrinsic_dshift (se, expr, false); break; case GFC_ISYM_FDATE: gfc_conv_intrinsic_fdate (se, expr); break; case GFC_ISYM_FRACTION: gfc_conv_intrinsic_fraction (se, expr); break; case GFC_ISYM_IALL: gfc_conv_intrinsic_arith (se, expr, BIT_AND_EXPR, false); break; case GFC_ISYM_IAND: gfc_conv_intrinsic_bitop (se, expr, BIT_AND_EXPR); break; case GFC_ISYM_IANY: gfc_conv_intrinsic_arith (se, expr, BIT_IOR_EXPR, false); break; case GFC_ISYM_IBCLR: gfc_conv_intrinsic_singlebitop (se, expr, 0); break; case GFC_ISYM_IBITS: gfc_conv_intrinsic_ibits (se, expr); break; case GFC_ISYM_IBSET: gfc_conv_intrinsic_singlebitop (se, expr, 1); break; case GFC_ISYM_IACHAR: case GFC_ISYM_ICHAR: /* We assume ASCII character sequence. */ gfc_conv_intrinsic_ichar (se, expr); break; case GFC_ISYM_IARGC: gfc_conv_intrinsic_iargc (se, expr); break; case GFC_ISYM_IEOR: gfc_conv_intrinsic_bitop (se, expr, BIT_XOR_EXPR); break; case GFC_ISYM_INDEX: kind = expr->value.function.actual->expr->ts.kind; if (kind == 1) fndecl = gfor_fndecl_string_index; else if (kind == 4) fndecl = gfor_fndecl_string_index_char4; else gcc_unreachable (); gfc_conv_intrinsic_index_scan_verify (se, expr, fndecl); break; case GFC_ISYM_IOR: gfc_conv_intrinsic_bitop (se, expr, BIT_IOR_EXPR); break; case GFC_ISYM_IPARITY: gfc_conv_intrinsic_arith (se, expr, BIT_XOR_EXPR, false); break; case GFC_ISYM_IS_IOSTAT_END: gfc_conv_has_intvalue (se, expr, LIBERROR_END); break; case GFC_ISYM_IS_IOSTAT_EOR: gfc_conv_has_intvalue (se, expr, LIBERROR_EOR); break; case GFC_ISYM_IS_CONTIGUOUS: gfc_conv_intrinsic_is_contiguous (se, expr); break; case GFC_ISYM_ISNAN: gfc_conv_intrinsic_isnan (se, expr); break; case GFC_ISYM_KILL: conv_intrinsic_kill (se, expr); break; case GFC_ISYM_LSHIFT: gfc_conv_intrinsic_shift (se, expr, false, false); break; case GFC_ISYM_RSHIFT: gfc_conv_intrinsic_shift (se, expr, true, true); break; case GFC_ISYM_SHIFTA: gfc_conv_intrinsic_shift (se, expr, true, true); break; case GFC_ISYM_SHIFTL: gfc_conv_intrinsic_shift (se, expr, false, false); break; case GFC_ISYM_SHIFTR: gfc_conv_intrinsic_shift (se, expr, true, false); break; case GFC_ISYM_ISHFT: gfc_conv_intrinsic_ishft (se, expr); break; case GFC_ISYM_ISHFTC: gfc_conv_intrinsic_ishftc (se, expr); break; case GFC_ISYM_LEADZ: gfc_conv_intrinsic_leadz (se, expr); break; case GFC_ISYM_TRAILZ: gfc_conv_intrinsic_trailz (se, expr); break; case GFC_ISYM_POPCNT: gfc_conv_intrinsic_popcnt_poppar (se, expr, 0); break; case GFC_ISYM_POPPAR: gfc_conv_intrinsic_popcnt_poppar (se, expr, 1); break; case GFC_ISYM_LBOUND: gfc_conv_intrinsic_bound (se, expr, GFC_ISYM_LBOUND); break; case GFC_ISYM_LCOBOUND: conv_intrinsic_cobound (se, expr); break; case GFC_ISYM_TRANSPOSE: /* The scalarizer has already been set up for reversed dimension access order ; now we just get the argument value normally. */ gfc_conv_expr (se, expr->value.function.actual->expr); break; case GFC_ISYM_LEN: gfc_conv_intrinsic_len (se, expr); break; case GFC_ISYM_LEN_TRIM: gfc_conv_intrinsic_len_trim (se, expr); break; case GFC_ISYM_LGE: gfc_conv_intrinsic_strcmp (se, expr, GE_EXPR); break; case GFC_ISYM_LGT: gfc_conv_intrinsic_strcmp (se, expr, GT_EXPR); break; case GFC_ISYM_LLE: gfc_conv_intrinsic_strcmp (se, expr, LE_EXPR); break; case GFC_ISYM_LLT: gfc_conv_intrinsic_strcmp (se, expr, LT_EXPR); break; case GFC_ISYM_MALLOC: gfc_conv_intrinsic_malloc (se, expr); break; case GFC_ISYM_MASKL: gfc_conv_intrinsic_mask (se, expr, 1); break; case GFC_ISYM_MASKR: gfc_conv_intrinsic_mask (se, expr, 0); break; case GFC_ISYM_MAX: if (expr->ts.type == BT_CHARACTER) gfc_conv_intrinsic_minmax_char (se, expr, 1); else gfc_conv_intrinsic_minmax (se, expr, GT_EXPR); break; case GFC_ISYM_MAXLOC: gfc_conv_intrinsic_minmaxloc (se, expr, GT_EXPR); break; case GFC_ISYM_FINDLOC: gfc_conv_intrinsic_findloc (se, expr); break; case GFC_ISYM_MAXVAL: gfc_conv_intrinsic_minmaxval (se, expr, GT_EXPR); break; case GFC_ISYM_MERGE: gfc_conv_intrinsic_merge (se, expr); break; case GFC_ISYM_MERGE_BITS: gfc_conv_intrinsic_merge_bits (se, expr); break; case GFC_ISYM_MIN: if (expr->ts.type == BT_CHARACTER) gfc_conv_intrinsic_minmax_char (se, expr, -1); else gfc_conv_intrinsic_minmax (se, expr, LT_EXPR); break; case GFC_ISYM_MINLOC: gfc_conv_intrinsic_minmaxloc (se, expr, LT_EXPR); break; case GFC_ISYM_MINVAL: gfc_conv_intrinsic_minmaxval (se, expr, LT_EXPR); break; case GFC_ISYM_NEAREST: gfc_conv_intrinsic_nearest (se, expr); break; case GFC_ISYM_NORM2: gfc_conv_intrinsic_arith (se, expr, PLUS_EXPR, true); break; case GFC_ISYM_NOT: gfc_conv_intrinsic_not (se, expr); break; case GFC_ISYM_OR: gfc_conv_intrinsic_bitop (se, expr, BIT_IOR_EXPR); break; case GFC_ISYM_PARITY: gfc_conv_intrinsic_arith (se, expr, NE_EXPR, false); break; case GFC_ISYM_PRESENT: gfc_conv_intrinsic_present (se, expr); break; case GFC_ISYM_PRODUCT: gfc_conv_intrinsic_arith (se, expr, MULT_EXPR, false); break; case GFC_ISYM_RANK: gfc_conv_intrinsic_rank (se, expr); break; case GFC_ISYM_RRSPACING: gfc_conv_intrinsic_rrspacing (se, expr); break; case GFC_ISYM_SET_EXPONENT: gfc_conv_intrinsic_set_exponent (se, expr); break; case GFC_ISYM_SCALE: gfc_conv_intrinsic_scale (se, expr); break; case GFC_ISYM_SHAPE: gfc_conv_intrinsic_bound (se, expr, GFC_ISYM_SHAPE); break; case GFC_ISYM_SIGN: gfc_conv_intrinsic_sign (se, expr); break; case GFC_ISYM_SIZE: gfc_conv_intrinsic_size (se, expr); break; case GFC_ISYM_SIZEOF: case GFC_ISYM_C_SIZEOF: gfc_conv_intrinsic_sizeof (se, expr); break; case GFC_ISYM_STORAGE_SIZE: gfc_conv_intrinsic_storage_size (se, expr); break; case GFC_ISYM_SPACING: gfc_conv_intrinsic_spacing (se, expr); break; case GFC_ISYM_STRIDE: conv_intrinsic_stride (se, expr); break; case GFC_ISYM_SUM: gfc_conv_intrinsic_arith (se, expr, PLUS_EXPR, false); break; case GFC_ISYM_TEAM_NUMBER: conv_intrinsic_team_number (se, expr); break; case GFC_ISYM_TRANSFER: if (se->ss && se->ss->info->useflags) /* Access the previously obtained result. */ gfc_conv_tmp_array_ref (se); else gfc_conv_intrinsic_transfer (se, expr); break; case GFC_ISYM_TTYNAM: gfc_conv_intrinsic_ttynam (se, expr); break; case GFC_ISYM_UBOUND: gfc_conv_intrinsic_bound (se, expr, GFC_ISYM_UBOUND); break; case GFC_ISYM_UCOBOUND: conv_intrinsic_cobound (se, expr); break; case GFC_ISYM_XOR: gfc_conv_intrinsic_bitop (se, expr, BIT_XOR_EXPR); break; case GFC_ISYM_LOC: gfc_conv_intrinsic_loc (se, expr); break; case GFC_ISYM_THIS_IMAGE: /* For num_images() == 1, handle as LCOBOUND. */ if (expr->value.function.actual->expr && flag_coarray == GFC_FCOARRAY_SINGLE) conv_intrinsic_cobound (se, expr); else trans_this_image (se, expr); break; case GFC_ISYM_IMAGE_INDEX: trans_image_index (se, expr); break; case GFC_ISYM_IMAGE_STATUS: conv_intrinsic_image_status (se, expr); break; case GFC_ISYM_NUM_IMAGES: trans_num_images (se, expr); break; case GFC_ISYM_ACCESS: case GFC_ISYM_CHDIR: case GFC_ISYM_CHMOD: case GFC_ISYM_DTIME: case GFC_ISYM_ETIME: case GFC_ISYM_EXTENDS_TYPE_OF: case GFC_ISYM_FGET: case GFC_ISYM_FGETC: case GFC_ISYM_FNUM: case GFC_ISYM_FPUT: case GFC_ISYM_FPUTC: case GFC_ISYM_FSTAT: case GFC_ISYM_FTELL: case GFC_ISYM_GETCWD: case GFC_ISYM_GETGID: case GFC_ISYM_GETPID: case GFC_ISYM_GETUID: case GFC_ISYM_HOSTNM: case GFC_ISYM_IERRNO: case GFC_ISYM_IRAND: case GFC_ISYM_ISATTY: case GFC_ISYM_JN2: case GFC_ISYM_LINK: case GFC_ISYM_LSTAT: case GFC_ISYM_MATMUL: case GFC_ISYM_MCLOCK: case GFC_ISYM_MCLOCK8: case GFC_ISYM_RAND: case GFC_ISYM_RENAME: case GFC_ISYM_SECOND: case GFC_ISYM_SECNDS: case GFC_ISYM_SIGNAL: case GFC_ISYM_STAT: case GFC_ISYM_SYMLNK: case GFC_ISYM_SYSTEM: case GFC_ISYM_TIME: case GFC_ISYM_TIME8: case GFC_ISYM_UMASK: case GFC_ISYM_UNLINK: case GFC_ISYM_YN2: gfc_conv_intrinsic_funcall (se, expr); break; case GFC_ISYM_EOSHIFT: case GFC_ISYM_PACK: case GFC_ISYM_RESHAPE: /* For those, expr->rank should always be >0 and thus the if above the switch should have matched. */ gcc_unreachable (); break; default: gfc_conv_intrinsic_lib_function (se, expr); break; } } static gfc_ss * walk_inline_intrinsic_transpose (gfc_ss *ss, gfc_expr *expr) { gfc_ss *arg_ss, *tmp_ss; gfc_actual_arglist *arg; arg = expr->value.function.actual; gcc_assert (arg->expr); arg_ss = gfc_walk_subexpr (gfc_ss_terminator, arg->expr); gcc_assert (arg_ss != gfc_ss_terminator); for (tmp_ss = arg_ss; ; tmp_ss = tmp_ss->next) { if (tmp_ss->info->type != GFC_SS_SCALAR && tmp_ss->info->type != GFC_SS_REFERENCE) { gcc_assert (tmp_ss->dimen == 2); /* We just invert dimensions. */ std::swap (tmp_ss->dim[0], tmp_ss->dim[1]); } /* Stop when tmp_ss points to the last valid element of the chain... */ if (tmp_ss->next == gfc_ss_terminator) break; } /* ... so that we can attach the rest of the chain to it. */ tmp_ss->next = ss; return arg_ss; } /* Move the given dimension of the given gfc_ss list to a nested gfc_ss list. This has the side effect of reversing the nested list, so there is no need to call gfc_reverse_ss on it (the given list is assumed not to be reversed yet). */ static gfc_ss * nest_loop_dimension (gfc_ss *ss, int dim) { int ss_dim, i; gfc_ss *new_ss, *prev_ss = gfc_ss_terminator; gfc_loopinfo *new_loop; gcc_assert (ss != gfc_ss_terminator); for (; ss != gfc_ss_terminator; ss = ss->next) { new_ss = gfc_get_ss (); new_ss->next = prev_ss; new_ss->parent = ss; new_ss->info = ss->info; new_ss->info->refcount++; if (ss->dimen != 0) { gcc_assert (ss->info->type != GFC_SS_SCALAR && ss->info->type != GFC_SS_REFERENCE); new_ss->dimen = 1; new_ss->dim[0] = ss->dim[dim]; gcc_assert (dim < ss->dimen); ss_dim = --ss->dimen; for (i = dim; i < ss_dim; i++) ss->dim[i] = ss->dim[i + 1]; ss->dim[ss_dim] = 0; } prev_ss = new_ss; if (ss->nested_ss) { ss->nested_ss->parent = new_ss; new_ss->nested_ss = ss->nested_ss; } ss->nested_ss = new_ss; } new_loop = gfc_get_loopinfo (); gfc_init_loopinfo (new_loop); gcc_assert (prev_ss != NULL); gcc_assert (prev_ss != gfc_ss_terminator); gfc_add_ss_to_loop (new_loop, prev_ss); return new_ss->parent; } /* Create the gfc_ss list for the SUM/PRODUCT arguments when the function is to be inlined. */ static gfc_ss * walk_inline_intrinsic_arith (gfc_ss *ss, gfc_expr *expr) { gfc_ss *tmp_ss, *tail, *array_ss; gfc_actual_arglist *arg1, *arg2, *arg3; int sum_dim; bool scalar_mask = false; /* The rank of the result will be determined later. */ arg1 = expr->value.function.actual; arg2 = arg1->next; arg3 = arg2->next; gcc_assert (arg3 != NULL); if (expr->rank == 0) return ss; tmp_ss = gfc_ss_terminator; if (arg3->expr) { gfc_ss *mask_ss; mask_ss = gfc_walk_subexpr (tmp_ss, arg3->expr); if (mask_ss == tmp_ss) scalar_mask = 1; tmp_ss = mask_ss; } array_ss = gfc_walk_subexpr (tmp_ss, arg1->expr); gcc_assert (array_ss != tmp_ss); /* Odd thing: If the mask is scalar, it is used by the frontend after the array (to make an if around the nested loop). Thus it shall be after array_ss once the gfc_ss list is reversed. */ if (scalar_mask) tmp_ss = gfc_get_scalar_ss (array_ss, arg3->expr); else tmp_ss = array_ss; /* "Hide" the dimension on which we will sum in the first arg's scalarization chain. */ sum_dim = mpz_get_si (arg2->expr->value.integer) - 1; tail = nest_loop_dimension (tmp_ss, sum_dim); tail->next = ss; return tmp_ss; } static gfc_ss * walk_inline_intrinsic_function (gfc_ss * ss, gfc_expr * expr) { switch (expr->value.function.isym->id) { case GFC_ISYM_PRODUCT: case GFC_ISYM_SUM: return walk_inline_intrinsic_arith (ss, expr); case GFC_ISYM_TRANSPOSE: return walk_inline_intrinsic_transpose (ss, expr); default: gcc_unreachable (); } gcc_unreachable (); } /* This generates code to execute before entering the scalarization loop. Currently does nothing. */ void gfc_add_intrinsic_ss_code (gfc_loopinfo * loop ATTRIBUTE_UNUSED, gfc_ss * ss) { switch (ss->info->expr->value.function.isym->id) { case GFC_ISYM_UBOUND: case GFC_ISYM_LBOUND: case GFC_ISYM_UCOBOUND: case GFC_ISYM_LCOBOUND: case GFC_ISYM_THIS_IMAGE: case GFC_ISYM_SHAPE: break; default: gcc_unreachable (); } } /* The LBOUND, LCOBOUND, UBOUND, UCOBOUND, and SHAPE intrinsics with one parameter are expanded into code inside the scalarization loop. */ static gfc_ss * gfc_walk_intrinsic_bound (gfc_ss * ss, gfc_expr * expr) { if (expr->value.function.actual->expr->ts.type == BT_CLASS) gfc_add_class_array_ref (expr->value.function.actual->expr); /* The two argument version returns a scalar. */ if (expr->value.function.isym->id != GFC_ISYM_SHAPE && expr->value.function.actual->next->expr) return ss; return gfc_get_array_ss (ss, expr, 1, GFC_SS_INTRINSIC); } /* Walk an intrinsic array libcall. */ static gfc_ss * gfc_walk_intrinsic_libfunc (gfc_ss * ss, gfc_expr * expr) { gcc_assert (expr->rank > 0); return gfc_get_array_ss (ss, expr, expr->rank, GFC_SS_FUNCTION); } /* Return whether the function call expression EXPR will be expanded inline by gfc_conv_intrinsic_function. */ bool gfc_inline_intrinsic_function_p (gfc_expr *expr) { gfc_actual_arglist *args, *dim_arg, *mask_arg; gfc_expr *maskexpr; if (!expr->value.function.isym) return false; switch (expr->value.function.isym->id) { case GFC_ISYM_PRODUCT: case GFC_ISYM_SUM: /* Disable inline expansion if code size matters. */ if (optimize_size) return false; args = expr->value.function.actual; dim_arg = args->next; /* We need to be able to subset the SUM argument at compile-time. */ if (dim_arg->expr && dim_arg->expr->expr_type != EXPR_CONSTANT) return false; /* FIXME: If MASK is optional for a more than two-dimensional argument, the scalarizer gets confused if the mask is absent. See PR 82995. For now, fall back to the library function. */ mask_arg = dim_arg->next; maskexpr = mask_arg->expr; if (expr->rank > 0 && maskexpr && maskexpr->expr_type == EXPR_VARIABLE && maskexpr->symtree->n.sym->attr.dummy && maskexpr->symtree->n.sym->attr.optional) return false; return true; case GFC_ISYM_TRANSPOSE: return true; default: return false; } } /* Returns nonzero if the specified intrinsic function call maps directly to an external library call. Should only be used for functions that return arrays. */ int gfc_is_intrinsic_libcall (gfc_expr * expr) { gcc_assert (expr->expr_type == EXPR_FUNCTION && expr->value.function.isym); gcc_assert (expr->rank > 0); if (gfc_inline_intrinsic_function_p (expr)) return 0; switch (expr->value.function.isym->id) { case GFC_ISYM_ALL: case GFC_ISYM_ANY: case GFC_ISYM_COUNT: case GFC_ISYM_FINDLOC: case GFC_ISYM_JN2: case GFC_ISYM_IANY: case GFC_ISYM_IALL: case GFC_ISYM_IPARITY: case GFC_ISYM_MATMUL: case GFC_ISYM_MAXLOC: case GFC_ISYM_MAXVAL: case GFC_ISYM_MINLOC: case GFC_ISYM_MINVAL: case GFC_ISYM_NORM2: case GFC_ISYM_PARITY: case GFC_ISYM_PRODUCT: case GFC_ISYM_SUM: case GFC_ISYM_SPREAD: case GFC_ISYM_YN2: /* Ignore absent optional parameters. */ return 1; case GFC_ISYM_CSHIFT: case GFC_ISYM_EOSHIFT: case GFC_ISYM_GET_TEAM: case GFC_ISYM_FAILED_IMAGES: case GFC_ISYM_STOPPED_IMAGES: case GFC_ISYM_PACK: case GFC_ISYM_RESHAPE: case GFC_ISYM_UNPACK: /* Pass absent optional parameters. */ return 2; default: return 0; } } /* Walk an intrinsic function. */ gfc_ss * gfc_walk_intrinsic_function (gfc_ss * ss, gfc_expr * expr, gfc_intrinsic_sym * isym) { gcc_assert (isym); if (isym->elemental) return gfc_walk_elemental_function_args (ss, expr->value.function.actual, expr->value.function.isym, GFC_SS_SCALAR); if (expr->rank == 0) return ss; if (gfc_inline_intrinsic_function_p (expr)) return walk_inline_intrinsic_function (ss, expr); if (gfc_is_intrinsic_libcall (expr)) return gfc_walk_intrinsic_libfunc (ss, expr); /* Special cases. */ switch (isym->id) { case GFC_ISYM_LBOUND: case GFC_ISYM_LCOBOUND: case GFC_ISYM_UBOUND: case GFC_ISYM_UCOBOUND: case GFC_ISYM_THIS_IMAGE: case GFC_ISYM_SHAPE: return gfc_walk_intrinsic_bound (ss, expr); case GFC_ISYM_TRANSFER: case GFC_ISYM_CAF_GET: return gfc_walk_intrinsic_libfunc (ss, expr); default: /* This probably meant someone forgot to add an intrinsic to the above list(s) when they implemented it, or something's gone horribly wrong. */ gcc_unreachable (); } } static tree conv_co_collective (gfc_code *code) { gfc_se argse; stmtblock_t block, post_block; tree fndecl, array = NULL_TREE, strlen, image_index, stat, errmsg, errmsg_len; gfc_expr *image_idx_expr, *stat_expr, *errmsg_expr, *opr_expr; gfc_start_block (&block); gfc_init_block (&post_block); if (code->resolved_isym->id == GFC_ISYM_CO_REDUCE) { opr_expr = code->ext.actual->next->expr; image_idx_expr = code->ext.actual->next->next->expr; stat_expr = code->ext.actual->next->next->next->expr; errmsg_expr = code->ext.actual->next->next->next->next->expr; } else { opr_expr = NULL; image_idx_expr = code->ext.actual->next->expr; stat_expr = code->ext.actual->next->next->expr; errmsg_expr = code->ext.actual->next->next->next->expr; } /* stat. */ if (stat_expr) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, stat_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); stat = argse.expr; if (flag_coarray != GFC_FCOARRAY_SINGLE) stat = gfc_build_addr_expr (NULL_TREE, stat); } else if (flag_coarray == GFC_FCOARRAY_SINGLE) stat = NULL_TREE; else stat = null_pointer_node; /* Early exit for GFC_FCOARRAY_SINGLE. */ if (flag_coarray == GFC_FCOARRAY_SINGLE) { if (stat != NULL_TREE) { /* For optional stats, check the pointer is valid before zero'ing. */ if (gfc_expr_attr (stat_expr).optional) { tree tmp; stmtblock_t ass_block; gfc_start_block (&ass_block); gfc_add_modify (&ass_block, stat, fold_convert (TREE_TYPE (stat), integer_zero_node)); tmp = fold_build2 (NE_EXPR, logical_type_node, gfc_build_addr_expr (NULL_TREE, stat), null_pointer_node); tmp = fold_build3 (COND_EXPR, void_type_node, tmp, gfc_finish_block (&ass_block), build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } else gfc_add_modify (&block, stat, fold_convert (TREE_TYPE (stat), integer_zero_node)); } return gfc_finish_block (&block); } gfc_symbol *derived = code->ext.actual->expr->ts.type == BT_DERIVED ? code->ext.actual->expr->ts.u.derived : NULL; /* Handle the array. */ gfc_init_se (&argse, NULL); if (!derived || !derived->attr.alloc_comp || code->resolved_isym->id != GFC_ISYM_CO_BROADCAST) { if (code->ext.actual->expr->rank == 0) { symbol_attribute attr; gfc_clear_attr (&attr); gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, code->ext.actual->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); array = gfc_conv_scalar_to_descriptor (&argse, argse.expr, attr); array = gfc_build_addr_expr (NULL_TREE, array); } else { argse.want_pointer = 1; gfc_conv_expr_descriptor (&argse, code->ext.actual->expr); array = argse.expr; } } gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); if (code->ext.actual->expr->ts.type == BT_CHARACTER) strlen = argse.string_length; else strlen = integer_zero_node; /* image_index. */ if (image_idx_expr) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, image_idx_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); image_index = fold_convert (integer_type_node, argse.expr); } else image_index = integer_zero_node; /* errmsg. */ if (errmsg_expr) { gfc_init_se (&argse, NULL); gfc_conv_expr (&argse, errmsg_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); errmsg = argse.expr; errmsg_len = fold_convert (size_type_node, argse.string_length); } else { errmsg = null_pointer_node; errmsg_len = build_zero_cst (size_type_node); } /* Generate the function call. */ switch (code->resolved_isym->id) { case GFC_ISYM_CO_BROADCAST: fndecl = gfor_fndecl_co_broadcast; break; case GFC_ISYM_CO_MAX: fndecl = gfor_fndecl_co_max; break; case GFC_ISYM_CO_MIN: fndecl = gfor_fndecl_co_min; break; case GFC_ISYM_CO_REDUCE: fndecl = gfor_fndecl_co_reduce; break; case GFC_ISYM_CO_SUM: fndecl = gfor_fndecl_co_sum; break; default: gcc_unreachable (); } if (derived && derived->attr.alloc_comp && code->resolved_isym->id == GFC_ISYM_CO_BROADCAST) /* The derived type has the attribute 'alloc_comp'. */ { tree tmp = gfc_bcast_alloc_comp (derived, code->ext.actual->expr, code->ext.actual->expr->rank, image_index, stat, errmsg, errmsg_len); gfc_add_expr_to_block (&block, tmp); } else { if (code->resolved_isym->id == GFC_ISYM_CO_SUM || code->resolved_isym->id == GFC_ISYM_CO_BROADCAST) fndecl = build_call_expr_loc (input_location, fndecl, 5, array, image_index, stat, errmsg, errmsg_len); else if (code->resolved_isym->id != GFC_ISYM_CO_REDUCE) fndecl = build_call_expr_loc (input_location, fndecl, 6, array, image_index, stat, errmsg, strlen, errmsg_len); else { tree opr, opr_flags; // FIXME: Handle TS29113's bind(C) strings with descriptor. int opr_flag_int; if (gfc_is_proc_ptr_comp (opr_expr)) { gfc_symbol *sym = gfc_get_proc_ptr_comp (opr_expr)->ts.interface; opr_flag_int = sym->attr.dimension || (sym->ts.type == BT_CHARACTER && !sym->attr.is_bind_c) ? GFC_CAF_BYREF : 0; opr_flag_int |= opr_expr->ts.type == BT_CHARACTER && !sym->attr.is_bind_c ? GFC_CAF_HIDDENLEN : 0; opr_flag_int |= sym->formal->sym->attr.value ? GFC_CAF_ARG_VALUE : 0; } else { opr_flag_int = gfc_return_by_reference (opr_expr->symtree->n.sym) ? GFC_CAF_BYREF : 0; opr_flag_int |= opr_expr->ts.type == BT_CHARACTER && !opr_expr->symtree->n.sym->attr.is_bind_c ? GFC_CAF_HIDDENLEN : 0; opr_flag_int |= opr_expr->symtree->n.sym->formal->sym->attr.value ? GFC_CAF_ARG_VALUE : 0; } opr_flags = build_int_cst (integer_type_node, opr_flag_int); gfc_conv_expr (&argse, opr_expr); opr = argse.expr; fndecl = build_call_expr_loc (input_location, fndecl, 8, array, opr, opr_flags, image_index, stat, errmsg, strlen, errmsg_len); } } gfc_add_expr_to_block (&block, fndecl); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } static tree conv_intrinsic_atomic_op (gfc_code *code) { gfc_se argse; tree tmp, atom, value, old = NULL_TREE, stat = NULL_TREE; stmtblock_t block, post_block; gfc_expr *atom_expr = code->ext.actual->expr; gfc_expr *stat_expr; built_in_function fn; if (atom_expr->expr_type == EXPR_FUNCTION && atom_expr->value.function.isym && atom_expr->value.function.isym->id == GFC_ISYM_CAF_GET) atom_expr = atom_expr->value.function.actual->expr; gfc_start_block (&block); gfc_init_block (&post_block); gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, atom_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); atom = argse.expr; gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB && code->ext.actual->next->expr->ts.kind == atom_expr->ts.kind) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); value = argse.expr; switch (code->resolved_isym->id) { case GFC_ISYM_ATOMIC_ADD: case GFC_ISYM_ATOMIC_AND: case GFC_ISYM_ATOMIC_DEF: case GFC_ISYM_ATOMIC_OR: case GFC_ISYM_ATOMIC_XOR: stat_expr = code->ext.actual->next->next->expr; if (flag_coarray == GFC_FCOARRAY_LIB) old = null_pointer_node; break; default: gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->next->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); old = argse.expr; stat_expr = code->ext.actual->next->next->next->expr; } /* STAT= */ if (stat_expr != NULL) { gcc_assert (stat_expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr_val (&argse, stat_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (flag_coarray == GFC_FCOARRAY_LIB) { tree image_index, caf_decl, offset, token; int op; switch (code->resolved_isym->id) { case GFC_ISYM_ATOMIC_ADD: case GFC_ISYM_ATOMIC_FETCH_ADD: op = (int) GFC_CAF_ATOMIC_ADD; break; case GFC_ISYM_ATOMIC_AND: case GFC_ISYM_ATOMIC_FETCH_AND: op = (int) GFC_CAF_ATOMIC_AND; break; case GFC_ISYM_ATOMIC_OR: case GFC_ISYM_ATOMIC_FETCH_OR: op = (int) GFC_CAF_ATOMIC_OR; break; case GFC_ISYM_ATOMIC_XOR: case GFC_ISYM_ATOMIC_FETCH_XOR: op = (int) GFC_CAF_ATOMIC_XOR; break; case GFC_ISYM_ATOMIC_DEF: op = 0; /* Unused. */ break; default: gcc_unreachable (); } caf_decl = gfc_get_tree_for_caf_expr (atom_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); if (gfc_is_coindexed (atom_expr)) image_index = gfc_caf_get_image_index (&block, atom_expr, caf_decl); else image_index = integer_zero_node; if (!POINTER_TYPE_P (TREE_TYPE (value))) { tmp = gfc_create_var (TREE_TYPE (TREE_TYPE (atom)), "value"); gfc_add_modify (&block, tmp, fold_convert (TREE_TYPE (tmp), value)); value = gfc_build_addr_expr (NULL_TREE, tmp); } gfc_init_se (&argse, NULL); gfc_get_caf_token_offset (&argse, &token, &offset, caf_decl, atom, atom_expr); gfc_add_block_to_block (&block, &argse.pre); if (code->resolved_isym->id == GFC_ISYM_ATOMIC_DEF) tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_atomic_def, 7, token, offset, image_index, value, stat, build_int_cst (integer_type_node, (int) atom_expr->ts.type), build_int_cst (integer_type_node, (int) atom_expr->ts.kind)); else tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_atomic_op, 9, build_int_cst (integer_type_node, op), token, offset, image_index, value, old, stat, build_int_cst (integer_type_node, (int) atom_expr->ts.type), build_int_cst (integer_type_node, (int) atom_expr->ts.kind)); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&block, &argse.post); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } switch (code->resolved_isym->id) { case GFC_ISYM_ATOMIC_ADD: case GFC_ISYM_ATOMIC_FETCH_ADD: fn = BUILT_IN_ATOMIC_FETCH_ADD_N; break; case GFC_ISYM_ATOMIC_AND: case GFC_ISYM_ATOMIC_FETCH_AND: fn = BUILT_IN_ATOMIC_FETCH_AND_N; break; case GFC_ISYM_ATOMIC_DEF: fn = BUILT_IN_ATOMIC_STORE_N; break; case GFC_ISYM_ATOMIC_OR: case GFC_ISYM_ATOMIC_FETCH_OR: fn = BUILT_IN_ATOMIC_FETCH_OR_N; break; case GFC_ISYM_ATOMIC_XOR: case GFC_ISYM_ATOMIC_FETCH_XOR: fn = BUILT_IN_ATOMIC_FETCH_XOR_N; break; default: gcc_unreachable (); } tmp = TREE_TYPE (TREE_TYPE (atom)); fn = (built_in_function) ((int) fn + exact_log2 (tree_to_uhwi (TYPE_SIZE_UNIT (tmp))) + 1); tree itype = TREE_TYPE (TREE_TYPE (atom)); tmp = builtin_decl_explicit (fn); switch (code->resolved_isym->id) { case GFC_ISYM_ATOMIC_ADD: case GFC_ISYM_ATOMIC_AND: case GFC_ISYM_ATOMIC_DEF: case GFC_ISYM_ATOMIC_OR: case GFC_ISYM_ATOMIC_XOR: tmp = build_call_expr_loc (input_location, tmp, 3, atom, fold_convert (itype, value), build_int_cst (NULL, MEMMODEL_RELAXED)); gfc_add_expr_to_block (&block, tmp); break; default: tmp = build_call_expr_loc (input_location, tmp, 3, atom, fold_convert (itype, value), build_int_cst (NULL, MEMMODEL_RELAXED)); gfc_add_modify (&block, old, fold_convert (TREE_TYPE (old), tmp)); break; } if (stat != NULL_TREE) gfc_add_modify (&block, stat, build_int_cst (TREE_TYPE (stat), 0)); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } static tree conv_intrinsic_atomic_ref (gfc_code *code) { gfc_se argse; tree tmp, atom, value, stat = NULL_TREE; stmtblock_t block, post_block; built_in_function fn; gfc_expr *atom_expr = code->ext.actual->next->expr; if (atom_expr->expr_type == EXPR_FUNCTION && atom_expr->value.function.isym && atom_expr->value.function.isym->id == GFC_ISYM_CAF_GET) atom_expr = atom_expr->value.function.actual->expr; gfc_start_block (&block); gfc_init_block (&post_block); gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, atom_expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); atom = argse.expr; gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB && code->ext.actual->expr->ts.kind == atom_expr->ts.kind) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); value = argse.expr; /* STAT= */ if (code->ext.actual->next->next->expr != NULL) { gcc_assert (code->ext.actual->next->next->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr_val (&argse, code->ext.actual->next->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (flag_coarray == GFC_FCOARRAY_LIB) { tree image_index, caf_decl, offset, token; tree orig_value = NULL_TREE, vardecl = NULL_TREE; caf_decl = gfc_get_tree_for_caf_expr (atom_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); if (gfc_is_coindexed (atom_expr)) image_index = gfc_caf_get_image_index (&block, atom_expr, caf_decl); else image_index = integer_zero_node; gfc_init_se (&argse, NULL); gfc_get_caf_token_offset (&argse, &token, &offset, caf_decl, atom, atom_expr); gfc_add_block_to_block (&block, &argse.pre); /* Different type, need type conversion. */ if (!POINTER_TYPE_P (TREE_TYPE (value))) { vardecl = gfc_create_var (TREE_TYPE (TREE_TYPE (atom)), "value"); orig_value = value; value = gfc_build_addr_expr (NULL_TREE, vardecl); } tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_atomic_ref, 7, token, offset, image_index, value, stat, build_int_cst (integer_type_node, (int) atom_expr->ts.type), build_int_cst (integer_type_node, (int) atom_expr->ts.kind)); gfc_add_expr_to_block (&block, tmp); if (vardecl != NULL_TREE) gfc_add_modify (&block, orig_value, fold_convert (TREE_TYPE (orig_value), vardecl)); gfc_add_block_to_block (&block, &argse.post); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } tmp = TREE_TYPE (TREE_TYPE (atom)); fn = (built_in_function) ((int) BUILT_IN_ATOMIC_LOAD_N + exact_log2 (tree_to_uhwi (TYPE_SIZE_UNIT (tmp))) + 1); tmp = builtin_decl_explicit (fn); tmp = build_call_expr_loc (input_location, tmp, 2, atom, build_int_cst (integer_type_node, MEMMODEL_RELAXED)); gfc_add_modify (&block, value, fold_convert (TREE_TYPE (value), tmp)); if (stat != NULL_TREE) gfc_add_modify (&block, stat, build_int_cst (TREE_TYPE (stat), 0)); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } static tree conv_intrinsic_atomic_cas (gfc_code *code) { gfc_se argse; tree tmp, atom, old, new_val, comp, stat = NULL_TREE; stmtblock_t block, post_block; built_in_function fn; gfc_expr *atom_expr = code->ext.actual->expr; if (atom_expr->expr_type == EXPR_FUNCTION && atom_expr->value.function.isym && atom_expr->value.function.isym->id == GFC_ISYM_CAF_GET) atom_expr = atom_expr->value.function.actual->expr; gfc_init_block (&block); gfc_init_block (&post_block); gfc_init_se (&argse, NULL); argse.want_pointer = 1; gfc_conv_expr (&argse, atom_expr); atom = argse.expr; gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); old = argse.expr; gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->next->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); comp = argse.expr; gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB && code->ext.actual->next->next->next->expr->ts.kind == atom_expr->ts.kind) argse.want_pointer = 1; gfc_conv_expr (&argse, code->ext.actual->next->next->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); new_val = argse.expr; /* STAT= */ if (code->ext.actual->next->next->next->next->expr != NULL) { gcc_assert (code->ext.actual->next->next->next->next->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); if (flag_coarray == GFC_FCOARRAY_LIB) argse.want_pointer = 1; gfc_conv_expr_val (&argse, code->ext.actual->next->next->next->next->expr); gfc_add_block_to_block (&block, &argse.pre); gfc_add_block_to_block (&post_block, &argse.post); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (flag_coarray == GFC_FCOARRAY_LIB) { tree image_index, caf_decl, offset, token; caf_decl = gfc_get_tree_for_caf_expr (atom_expr); if (TREE_CODE (TREE_TYPE (caf_decl)) == REFERENCE_TYPE) caf_decl = build_fold_indirect_ref_loc (input_location, caf_decl); if (gfc_is_coindexed (atom_expr)) image_index = gfc_caf_get_image_index (&block, atom_expr, caf_decl); else image_index = integer_zero_node; if (TREE_TYPE (TREE_TYPE (new_val)) != TREE_TYPE (TREE_TYPE (old))) { tmp = gfc_create_var (TREE_TYPE (TREE_TYPE (old)), "new"); gfc_add_modify (&block, tmp, fold_convert (TREE_TYPE (tmp), new_val)); new_val = gfc_build_addr_expr (NULL_TREE, tmp); } /* Convert a constant to a pointer. */ if (!POINTER_TYPE_P (TREE_TYPE (comp))) { tmp = gfc_create_var (TREE_TYPE (TREE_TYPE (old)), "comp"); gfc_add_modify (&block, tmp, fold_convert (TREE_TYPE (tmp), comp)); comp = gfc_build_addr_expr (NULL_TREE, tmp); } gfc_init_se (&argse, NULL); gfc_get_caf_token_offset (&argse, &token, &offset, caf_decl, atom, atom_expr); gfc_add_block_to_block (&block, &argse.pre); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_atomic_cas, 9, token, offset, image_index, old, comp, new_val, stat, build_int_cst (integer_type_node, (int) atom_expr->ts.type), build_int_cst (integer_type_node, (int) atom_expr->ts.kind)); gfc_add_expr_to_block (&block, tmp); gfc_add_block_to_block (&block, &argse.post); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } tmp = TREE_TYPE (TREE_TYPE (atom)); fn = (built_in_function) ((int) BUILT_IN_ATOMIC_COMPARE_EXCHANGE_N + exact_log2 (tree_to_uhwi (TYPE_SIZE_UNIT (tmp))) + 1); tmp = builtin_decl_explicit (fn); gfc_add_modify (&block, old, comp); tmp = build_call_expr_loc (input_location, tmp, 6, atom, gfc_build_addr_expr (NULL, old), fold_convert (TREE_TYPE (old), new_val), boolean_false_node, build_int_cst (NULL, MEMMODEL_RELAXED), build_int_cst (NULL, MEMMODEL_RELAXED)); gfc_add_expr_to_block (&block, tmp); if (stat != NULL_TREE) gfc_add_modify (&block, stat, build_int_cst (TREE_TYPE (stat), 0)); gfc_add_block_to_block (&block, &post_block); return gfc_finish_block (&block); } static tree conv_intrinsic_event_query (gfc_code *code) { gfc_se se, argse; tree stat = NULL_TREE, stat2 = NULL_TREE; tree count = NULL_TREE, count2 = NULL_TREE; gfc_expr *event_expr = code->ext.actual->expr; if (code->ext.actual->next->next->expr) { gcc_assert (code->ext.actual->next->next->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->ext.actual->next->next->expr); stat = argse.expr; } else if (flag_coarray == GFC_FCOARRAY_LIB) stat = null_pointer_node; if (code->ext.actual->next->expr) { gcc_assert (code->ext.actual->next->expr->expr_type == EXPR_VARIABLE); gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->ext.actual->next->expr); count = argse.expr; } gfc_start_block (&se.pre); if (flag_coarray == GFC_FCOARRAY_LIB) { tree tmp, token, image_index; tree index = build_zero_cst (gfc_array_index_type); if (event_expr->expr_type == EXPR_FUNCTION && event_expr->value.function.isym && event_expr->value.function.isym->id == GFC_ISYM_CAF_GET) event_expr = event_expr->value.function.actual->expr; tree caf_decl = gfc_get_tree_for_caf_expr (event_expr); if (event_expr->symtree->n.sym->ts.type != BT_DERIVED || event_expr->symtree->n.sym->ts.u.derived->from_intmod != INTMOD_ISO_FORTRAN_ENV || event_expr->symtree->n.sym->ts.u.derived->intmod_sym_id != ISOFORTRAN_EVENT_TYPE) { gfc_error ("Sorry, the event component of derived type at %L is not " "yet supported", &event_expr->where); return NULL_TREE; } if (gfc_is_coindexed (event_expr)) { gfc_error ("The event variable at %L shall not be coindexed", &event_expr->where); return NULL_TREE; } image_index = integer_zero_node; gfc_get_caf_token_offset (&se, &token, NULL, caf_decl, NULL_TREE, event_expr); /* For arrays, obtain the array index. */ if (gfc_expr_attr (event_expr).dimension) { tree desc, tmp, extent, lbound, ubound; gfc_array_ref *ar, ar2; int i; /* TODO: Extend this, once DT components are supported. */ ar = &event_expr->ref->u.ar; ar2 = *ar; memset (ar, '\0', sizeof (*ar)); ar->as = ar2.as; ar->type = AR_FULL; gfc_init_se (&argse, NULL); argse.descriptor_only = 1; gfc_conv_expr_descriptor (&argse, event_expr); gfc_add_block_to_block (&se.pre, &argse.pre); desc = argse.expr; *ar = ar2; extent = build_one_cst (gfc_array_index_type); for (i = 0; i < ar->dimen; i++) { gfc_init_se (&argse, NULL); gfc_conv_expr_type (&argse, ar->start[i], gfc_array_index_type); gfc_add_block_to_block (&argse.pre, &argse.pre); lbound = gfc_conv_descriptor_lbound_get (desc, gfc_rank_cst[i]); tmp = fold_build2_loc (input_location, MINUS_EXPR, TREE_TYPE (lbound), argse.expr, lbound); tmp = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), extent, tmp); index = fold_build2_loc (input_location, PLUS_EXPR, TREE_TYPE (tmp), index, tmp); if (i < ar->dimen - 1) { ubound = gfc_conv_descriptor_ubound_get (desc, gfc_rank_cst[i]); tmp = gfc_conv_array_extent_dim (lbound, ubound, NULL); extent = fold_build2_loc (input_location, MULT_EXPR, TREE_TYPE (tmp), extent, tmp); } } } if (count != null_pointer_node && TREE_TYPE (count) != integer_type_node) { count2 = count; count = gfc_create_var (integer_type_node, "count"); } if (stat != null_pointer_node && TREE_TYPE (stat) != integer_type_node) { stat2 = stat; stat = gfc_create_var (integer_type_node, "stat"); } index = fold_convert (size_type_node, index); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_event_query, 5, token, index, image_index, count ? gfc_build_addr_expr (NULL, count) : count, stat != null_pointer_node ? gfc_build_addr_expr (NULL, stat) : stat); gfc_add_expr_to_block (&se.pre, tmp); if (count2 != NULL_TREE) gfc_add_modify (&se.pre, count2, fold_convert (TREE_TYPE (count2), count)); if (stat2 != NULL_TREE) gfc_add_modify (&se.pre, stat2, fold_convert (TREE_TYPE (stat2), stat)); return gfc_finish_block (&se.pre); } gfc_init_se (&argse, NULL); gfc_conv_expr_val (&argse, code->ext.actual->expr); gfc_add_modify (&se.pre, count, fold_convert (TREE_TYPE (count), argse.expr)); if (stat != NULL_TREE) gfc_add_modify (&se.pre, stat, build_int_cst (TREE_TYPE (stat), 0)); return gfc_finish_block (&se.pre); } /* This is a peculiar case because of the need to do dependency checking. It is called via trans-stmt.cc(gfc_trans_call), where it is picked out as a special case and this function called instead of gfc_conv_procedure_call. */ void gfc_conv_intrinsic_mvbits (gfc_se *se, gfc_actual_arglist *actual_args, gfc_loopinfo *loop) { gfc_actual_arglist *actual; gfc_se argse[5]; gfc_expr *arg[5]; gfc_ss *lss; int n; tree from, frompos, len, to, topos; tree lenmask, oldbits, newbits, bitsize; tree type, utype, above, mask1, mask2; if (loop) lss = loop->ss; else lss = gfc_ss_terminator; actual = actual_args; for (n = 0; n < 5; n++, actual = actual->next) { arg[n] = actual->expr; gfc_init_se (&argse[n], NULL); if (lss != gfc_ss_terminator) { gfc_copy_loopinfo_to_se (&argse[n], loop); /* Find the ss for the expression if it is there. */ argse[n].ss = lss; gfc_mark_ss_chain_used (lss, 1); } gfc_conv_expr (&argse[n], arg[n]); if (loop) lss = argse[n].ss; } from = argse[0].expr; frompos = argse[1].expr; len = argse[2].expr; to = argse[3].expr; topos = argse[4].expr; /* The type of the result (TO). */ type = TREE_TYPE (to); bitsize = build_int_cst (integer_type_node, TYPE_PRECISION (type)); /* Optionally generate code for runtime argument check. */ if (gfc_option.rtcheck & GFC_RTCHECK_BITS) { tree nbits, below, ccond; tree fp = fold_convert (long_integer_type_node, frompos); tree ln = fold_convert (long_integer_type_node, len); tree tp = fold_convert (long_integer_type_node, topos); below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, frompos, build_int_cst (TREE_TYPE (frompos), 0)); above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, frompos, fold_convert (TREE_TYPE (frompos), bitsize)); ccond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, ccond, &argse[1].pre, &arg[1]->where, "FROMPOS argument (%ld) out of range 0:%d " "in intrinsic MVBITS", fp, bitsize); below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, len, build_int_cst (TREE_TYPE (len), 0)); above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, len, fold_convert (TREE_TYPE (len), bitsize)); ccond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, ccond, &argse[2].pre, &arg[2]->where, "LEN argument (%ld) out of range 0:%d " "in intrinsic MVBITS", ln, bitsize); below = fold_build2_loc (input_location, LT_EXPR, logical_type_node, topos, build_int_cst (TREE_TYPE (topos), 0)); above = fold_build2_loc (input_location, GT_EXPR, logical_type_node, topos, fold_convert (TREE_TYPE (topos), bitsize)); ccond = fold_build2_loc (input_location, TRUTH_ORIF_EXPR, logical_type_node, below, above); gfc_trans_runtime_check (true, false, ccond, &argse[4].pre, &arg[4]->where, "TOPOS argument (%ld) out of range 0:%d " "in intrinsic MVBITS", tp, bitsize); /* The tests above ensure that FROMPOS, LEN and TOPOS fit into short integers. Additions below cannot overflow. */ nbits = fold_convert (long_integer_type_node, bitsize); above = fold_build2_loc (input_location, PLUS_EXPR, long_integer_type_node, fp, ln); ccond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, above, nbits); gfc_trans_runtime_check (true, false, ccond, &argse[1].pre, &arg[1]->where, "FROMPOS(%ld)+LEN(%ld)>BIT_SIZE(%d) " "in intrinsic MVBITS", fp, ln, bitsize); above = fold_build2_loc (input_location, PLUS_EXPR, long_integer_type_node, tp, ln); ccond = fold_build2_loc (input_location, GT_EXPR, logical_type_node, above, nbits); gfc_trans_runtime_check (true, false, ccond, &argse[4].pre, &arg[4]->where, "TOPOS(%ld)+LEN(%ld)>BIT_SIZE(%d) " "in intrinsic MVBITS", tp, ln, bitsize); } for (n = 0; n < 5; n++) { gfc_add_block_to_block (&se->pre, &argse[n].pre); gfc_add_block_to_block (&se->post, &argse[n].post); } /* lenmask = (LEN >= bit_size (TYPE)) ? ~(TYPE)0 : ((TYPE)1 << LEN) - 1 */ above = fold_build2_loc (input_location, GE_EXPR, logical_type_node, len, fold_convert (TREE_TYPE (len), bitsize)); mask1 = build_int_cst (type, -1); mask2 = fold_build2_loc (input_location, LSHIFT_EXPR, type, build_int_cst (type, 1), len); mask2 = fold_build2_loc (input_location, MINUS_EXPR, type, mask2, build_int_cst (type, 1)); lenmask = fold_build3_loc (input_location, COND_EXPR, type, above, mask1, mask2); /* newbits = (((UTYPE)(FROM) >> FROMPOS) & lenmask) << TOPOS. * For valid frompos+len <= bit_size(FROM) the conversion to unsigned is * not strictly necessary; artificial bits from rshift will be masked. */ utype = unsigned_type_for (type); newbits = fold_build2_loc (input_location, RSHIFT_EXPR, utype, fold_convert (utype, from), frompos); newbits = fold_build2_loc (input_location, BIT_AND_EXPR, type, fold_convert (type, newbits), lenmask); newbits = fold_build2_loc (input_location, LSHIFT_EXPR, type, newbits, topos); /* oldbits = TO & (~(lenmask << TOPOS)). */ oldbits = fold_build2_loc (input_location, LSHIFT_EXPR, type, lenmask, topos); oldbits = fold_build1_loc (input_location, BIT_NOT_EXPR, type, oldbits); oldbits = fold_build2_loc (input_location, BIT_AND_EXPR, type, oldbits, to); /* TO = newbits | oldbits. */ se->expr = fold_build2_loc (input_location, BIT_IOR_EXPR, type, oldbits, newbits); /* Return the assignment. */ se->expr = fold_build2_loc (input_location, MODIFY_EXPR, void_type_node, to, se->expr); } static tree conv_intrinsic_move_alloc (gfc_code *code) { stmtblock_t block; gfc_expr *from_expr, *to_expr; gfc_expr *to_expr2, *from_expr2 = NULL; gfc_se from_se, to_se; tree tmp; bool coarray; gfc_start_block (&block); from_expr = code->ext.actual->expr; to_expr = code->ext.actual->next->expr; gfc_init_se (&from_se, NULL); gfc_init_se (&to_se, NULL); gcc_assert (from_expr->ts.type != BT_CLASS || to_expr->ts.type == BT_CLASS); coarray = gfc_get_corank (from_expr) != 0; if (from_expr->rank == 0 && !coarray) { if (from_expr->ts.type != BT_CLASS) from_expr2 = from_expr; else { from_expr2 = gfc_copy_expr (from_expr); gfc_add_data_component (from_expr2); } if (to_expr->ts.type != BT_CLASS) to_expr2 = to_expr; else { to_expr2 = gfc_copy_expr (to_expr); gfc_add_data_component (to_expr2); } from_se.want_pointer = 1; to_se.want_pointer = 1; gfc_conv_expr (&from_se, from_expr2); gfc_conv_expr (&to_se, to_expr2); gfc_add_block_to_block (&block, &from_se.pre); gfc_add_block_to_block (&block, &to_se.pre); /* Deallocate "to". */ tmp = gfc_deallocate_scalar_with_status (to_se.expr, NULL_TREE, NULL_TREE, true, to_expr, to_expr->ts); gfc_add_expr_to_block (&block, tmp); /* Assign (_data) pointers. */ gfc_add_modify_loc (input_location, &block, to_se.expr, fold_convert (TREE_TYPE (to_se.expr), from_se.expr)); /* Set "from" to NULL. */ gfc_add_modify_loc (input_location, &block, from_se.expr, fold_convert (TREE_TYPE (from_se.expr), null_pointer_node)); gfc_add_block_to_block (&block, &from_se.post); gfc_add_block_to_block (&block, &to_se.post); /* Set _vptr. */ if (to_expr->ts.type == BT_CLASS) { gfc_symbol *vtab; gfc_free_expr (to_expr2); gfc_init_se (&to_se, NULL); to_se.want_pointer = 1; gfc_add_vptr_component (to_expr); gfc_conv_expr (&to_se, to_expr); if (from_expr->ts.type == BT_CLASS) { if (UNLIMITED_POLY (from_expr)) vtab = NULL; else { vtab = gfc_find_derived_vtab (from_expr->ts.u.derived); gcc_assert (vtab); } gfc_free_expr (from_expr2); gfc_init_se (&from_se, NULL); from_se.want_pointer = 1; gfc_add_vptr_component (from_expr); gfc_conv_expr (&from_se, from_expr); gfc_add_modify_loc (input_location, &block, to_se.expr, fold_convert (TREE_TYPE (to_se.expr), from_se.expr)); /* Reset _vptr component to declared type. */ if (vtab == NULL) /* Unlimited polymorphic. */ gfc_add_modify_loc (input_location, &block, from_se.expr, fold_convert (TREE_TYPE (from_se.expr), null_pointer_node)); else { tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify_loc (input_location, &block, from_se.expr, fold_convert (TREE_TYPE (from_se.expr), tmp)); } } else { vtab = gfc_find_vtab (&from_expr->ts); gcc_assert (vtab); tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify_loc (input_location, &block, to_se.expr, fold_convert (TREE_TYPE (to_se.expr), tmp)); } } if (to_expr->ts.type == BT_CHARACTER && to_expr->ts.deferred) { gfc_add_modify_loc (input_location, &block, to_se.string_length, fold_convert (TREE_TYPE (to_se.string_length), from_se.string_length)); if (from_expr->ts.deferred) gfc_add_modify_loc (input_location, &block, from_se.string_length, build_int_cst (TREE_TYPE (from_se.string_length), 0)); } return gfc_finish_block (&block); } /* Update _vptr component. */ if (to_expr->ts.type == BT_CLASS) { gfc_symbol *vtab; to_se.want_pointer = 1; to_expr2 = gfc_copy_expr (to_expr); gfc_add_vptr_component (to_expr2); gfc_conv_expr (&to_se, to_expr2); if (from_expr->ts.type == BT_CLASS) { if (UNLIMITED_POLY (from_expr)) vtab = NULL; else { vtab = gfc_find_derived_vtab (from_expr->ts.u.derived); gcc_assert (vtab); } from_se.want_pointer = 1; from_expr2 = gfc_copy_expr (from_expr); gfc_add_vptr_component (from_expr2); gfc_conv_expr (&from_se, from_expr2); gfc_add_modify_loc (input_location, &block, to_se.expr, fold_convert (TREE_TYPE (to_se.expr), from_se.expr)); /* Reset _vptr component to declared type. */ if (vtab == NULL) /* Unlimited polymorphic. */ gfc_add_modify_loc (input_location, &block, from_se.expr, fold_convert (TREE_TYPE (from_se.expr), null_pointer_node)); else { tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify_loc (input_location, &block, from_se.expr, fold_convert (TREE_TYPE (from_se.expr), tmp)); } } else { vtab = gfc_find_vtab (&from_expr->ts); gcc_assert (vtab); tmp = gfc_build_addr_expr (NULL_TREE, gfc_get_symbol_decl (vtab)); gfc_add_modify_loc (input_location, &block, to_se.expr, fold_convert (TREE_TYPE (to_se.expr), tmp)); } gfc_free_expr (to_expr2); gfc_init_se (&to_se, NULL); if (from_expr->ts.type == BT_CLASS) { gfc_free_expr (from_expr2); gfc_init_se (&from_se, NULL); } } /* Deallocate "to". */ if (from_expr->rank == 0) { to_se.want_coarray = 1; from_se.want_coarray = 1; } gfc_conv_expr_descriptor (&to_se, to_expr); gfc_conv_expr_descriptor (&from_se, from_expr); /* For coarrays, call SYNC ALL if TO is already deallocated as MOVE_ALLOC is an image control "statement", cf. IR F08/0040 in 12-006A. */ if (coarray && flag_coarray == GFC_FCOARRAY_LIB) { tree cond; tmp = gfc_deallocate_with_status (to_se.expr, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, true, to_expr, GFC_CAF_COARRAY_DEALLOCATE_ONLY); gfc_add_expr_to_block (&block, tmp); tmp = gfc_conv_descriptor_data_get (to_se.expr); cond = fold_build2_loc (input_location, EQ_EXPR, logical_type_node, tmp, fold_convert (TREE_TYPE (tmp), null_pointer_node)); tmp = build_call_expr_loc (input_location, gfor_fndecl_caf_sync_all, 3, null_pointer_node, null_pointer_node, build_int_cst (integer_type_node, 0)); tmp = fold_build3_loc (input_location, COND_EXPR, void_type_node, cond, tmp, build_empty_stmt (input_location)); gfc_add_expr_to_block (&block, tmp); } else { if (to_expr->ts.type == BT_DERIVED && to_expr->ts.u.derived->attr.alloc_comp) { tmp = gfc_deallocate_alloc_comp (to_expr->ts.u.derived, to_se.expr, to_expr->rank); gfc_add_expr_to_block (&block, tmp); } tmp = gfc_conv_descriptor_data_get (to_se.expr); tmp = gfc_deallocate_with_status (tmp, NULL_TREE, NULL_TREE, NULL_TREE, NULL_TREE, true, to_expr, GFC_CAF_COARRAY_NOCOARRAY); gfc_add_expr_to_block (&block, tmp); } /* Move the pointer and update the array descriptor data. */ gfc_add_modify_loc (input_location, &block, to_se.expr, from_se.expr); /* Set "from" to NULL. */ tmp = gfc_conv_descriptor_data_get (from_se.expr); gfc_add_modify_loc (input_location, &block, tmp, fold_convert (TREE_TYPE (tmp), null_pointer_node)); if (to_expr->ts.type == BT_CHARACTER && to_expr->ts.deferred) { gfc_add_modify_loc (input_location, &block, to_se.string_length, fold_convert (TREE_TYPE (to_se.string_length), from_se.string_length)); if (from_expr->ts.deferred) gfc_add_modify_loc (input_location, &block, from_se.string_length, build_int_cst (TREE_TYPE (from_se.string_length), 0)); } return gfc_finish_block (&block); } tree gfc_conv_intrinsic_subroutine (gfc_code *code) { tree res; gcc_assert (code->resolved_isym); switch (code->resolved_isym->id) { case GFC_ISYM_MOVE_ALLOC: res = conv_intrinsic_move_alloc (code); break; case GFC_ISYM_ATOMIC_CAS: res = conv_intrinsic_atomic_cas (code); break; case GFC_ISYM_ATOMIC_ADD: case GFC_ISYM_ATOMIC_AND: case GFC_ISYM_ATOMIC_DEF: case GFC_ISYM_ATOMIC_OR: case GFC_ISYM_ATOMIC_XOR: case GFC_ISYM_ATOMIC_FETCH_ADD: case GFC_ISYM_ATOMIC_FETCH_AND: case GFC_ISYM_ATOMIC_FETCH_OR: case GFC_ISYM_ATOMIC_FETCH_XOR: res = conv_intrinsic_atomic_op (code); break; case GFC_ISYM_ATOMIC_REF: res = conv_intrinsic_atomic_ref (code); break; case GFC_ISYM_EVENT_QUERY: res = conv_intrinsic_event_query (code); break; case GFC_ISYM_C_F_POINTER: case GFC_ISYM_C_F_PROCPOINTER: res = conv_isocbinding_subroutine (code); break; case GFC_ISYM_CAF_SEND: res = conv_caf_send (code); break; case GFC_ISYM_CO_BROADCAST: case GFC_ISYM_CO_MIN: case GFC_ISYM_CO_MAX: case GFC_ISYM_CO_REDUCE: case GFC_ISYM_CO_SUM: res = conv_co_collective (code); break; case GFC_ISYM_FREE: res = conv_intrinsic_free (code); break; case GFC_ISYM_RANDOM_INIT: res = conv_intrinsic_random_init (code); break; case GFC_ISYM_KILL: res = conv_intrinsic_kill_sub (code); break; case GFC_ISYM_MVBITS: res = NULL_TREE; break; case GFC_ISYM_SYSTEM_CLOCK: res = conv_intrinsic_system_clock (code); break; default: res = NULL_TREE; break; } return res; } #include "gt-fortran-trans-intrinsic.h"